| Safe Haskell | None |
|---|---|
| Language | Haskell2010 |
Lorentz
Synopsis
- ($) :: forall (r :: RuntimeRep) a (b :: TYPE r). (a -> b) -> a -> b
- class Bounded a where
- class Eq a
- return :: Monad m => a -> m a
- negate :: Num a => a -> a
- fromInteger :: Num a => Integer -> a
- class Eq a => Ord a
- class Show a
- fromString :: IsString a => String -> a
- pure :: Applicative f => a -> f a
- class Generic a
- fromLabel :: IsLabel x a => a
- class Semigroup a where
- class Semigroup a => Monoid a where
- data Bool
- data Integer
- data Natural
- data Maybe a
- data Either a b
- data ByteString
- data Text
- (.) :: (b -> c) -> (a -> b) -> a -> c
- data Map k a
- data Proxy (t :: k) = Proxy
- withDict :: HasDict c e => e -> (c => r) -> r
- data Set a
- class Default a where
- def :: a
- argDef :: forall (name :: Symbol) a. Name name -> a -> (name :? a) -> a
- argF :: forall (name :: Symbol) f a. Name name -> NamedF f a name -> f a
- arg :: forall (name :: Symbol) a. Name name -> (name :! a) -> a
- type (:!) (name :: Symbol) a = NamedF Identity a name
- type (:?) (name :: Symbol) a = NamedF Maybe a name
- toSnake :: Text -> Text
- toPascal :: Text -> Text
- toCamel :: Text -> Text
- type ($) (f :: k1 -> k) (a :: k1) = f a
- undefined :: forall (r :: RuntimeRep) (a :: TYPE r). HasCallStack => a
- error :: forall (r :: RuntimeRep) (a :: TYPE r). HasCallStack => Text -> a
- data Rec (a :: u -> Type) (b :: [u]) where
- mt :: QuasiQuoter
- data MText
- data Label (name :: Symbol) where
- Label :: forall (name :: Symbol). KnownSymbol name => Label name
- insertTypeAnn :: forall (b :: T). TypeAnn -> Notes b -> Notes b
- mkUType :: forall (x :: T). SingI x => Notes x -> Ty
- ligoCombLayout :: GenericStrategy
- ligoLayout :: GenericStrategy
- concreteTypeDocHaskellRep :: (Typeable a, GenericIsoValue a, GTypeHasDoc (Rep a), HaveCommonTypeCtor b a) => TypeDocHaskellRep b
- concreteTypeDocHaskellRepUnsafe :: (Typeable a, GenericIsoValue a, GTypeHasDoc (Rep a)) => TypeDocHaskellRep b
- concreteTypeDocMichelsonRep :: forall k a (b :: k). (Typeable a, SingI (ToT a), HaveCommonTypeCtor b a) => TypeDocMichelsonRep b
- concreteTypeDocMichelsonRepUnsafe :: forall k a (b :: k). (Typeable a, SingI (ToT a)) => TypeDocMichelsonRep b
- customTypeDocMdReference :: (Text, DType) -> [DType] -> WithinParens -> Markdown
- dStorage :: TypeHasDoc store => DStorageType
- dTypeDep :: TypeHasDoc t => SomeDocDefinitionItem
- genericTypeDocDependencies :: (Generic a, GTypeHasDoc (Rep a)) => Proxy a -> [SomeDocDefinitionItem]
- haskellAddNewtypeField :: Text -> TypeDocHaskellRep a -> TypeDocHaskellRep a
- haskellRepNoFields :: TypeDocHaskellRep a -> TypeDocHaskellRep a
- haskellRepStripFieldPrefix :: HasCallStack => TypeDocHaskellRep a -> TypeDocHaskellRep a
- homomorphicTypeDocHaskellRep :: (Generic a, GTypeHasDoc (Rep a)) => TypeDocHaskellRep a
- homomorphicTypeDocMdReference :: (Typeable t, TypeHasDoc t, IsHomomorphic t) => Proxy t -> WithinParens -> Markdown
- homomorphicTypeDocMichelsonRep :: SingI (ToT a) => TypeDocMichelsonRep a
- poly1TypeDocMdReference :: forall (t :: Type -> Type) r a. (r ~ t a, Typeable t, Each '[TypeHasDoc] '[r, a], IsHomomorphic t) => Proxy r -> WithinParens -> Markdown
- poly2TypeDocMdReference :: forall (t :: Type -> Type -> Type) r a b. (r ~ t a b, Typeable t, Each '[TypeHasDoc] '[r, a, b], IsHomomorphic t) => Proxy r -> WithinParens -> Markdown
- coerceContractRef :: ToT a ~ ToT b => ContractRef a -> ContractRef b
- pattern DefEpName :: EpName
- opSizeHardLimit :: OpSize
- smallTransferOpSize :: OpSize
- type Operation = Operation' Instr
- type Value = Value' Instr
- data EpAddress = EpAddress {}
- data DType where
- DType :: forall a. TypeHasDoc a => Proxy a -> DType
- class HaveCommonTypeCtor (a :: k) (b :: k1)
- class IsHomomorphic (a :: k)
- data SomeTypeWithDoc where
- SomeTypeWithDoc :: forall td. TypeHasDoc td => Proxy td -> SomeTypeWithDoc
- type family TypeDocFieldDescriptions a :: FieldDescriptions
- class (Typeable a, SingI (TypeDocFieldDescriptions a), FieldDescriptionsValid (TypeDocFieldDescriptions a) a) => TypeHasDoc a where
- type TypeDocFieldDescriptions a :: FieldDescriptions
- typeDocName :: Proxy a -> Text
- typeDocMdDescription :: Markdown
- typeDocMdReference :: Proxy a -> WithinParens -> Markdown
- typeDocDependencies :: Proxy a -> [SomeDocDefinitionItem]
- typeDocHaskellRep :: TypeDocHaskellRep a
- typeDocMichelsonRep :: TypeDocMichelsonRep a
- type ConstructorFieldTypes dt = GFieldTypes (Rep dt)
- type InstrConstructC dt = (GenericIsoValue dt, GInstrConstruct (Rep dt))
- newtype BigMap k v = BigMap {}
- data ContractRef arg = ContractRef {
- crAddress :: Address
- crEntrypoint :: SomeEntrypointCall arg
- type EntrypointCall param arg = EntrypointCallT (ToT param) (ToT arg)
- class WellTypedToT a => IsoValue a where
- type family ToT a :: T
- type SomeEntrypointCall arg = SomeEntrypointCallT (ToT arg)
- type WellTypedIsoValue a = (WellTyped (ToT a), IsoValue a)
- data EpName
- newtype OpSize = OpSize {}
- data Address
- data Bls12381Fr
- data Bls12381G1
- data Bls12381G2
- data ChainId
- data KeyHash
- data Mutez
- data PublicKey
- data Signature
- data Timestamp
- oneMutez :: Mutez
- timestampFromSeconds :: Integer -> Timestamp
- timestampFromUTCTime :: UTCTime -> Timestamp
- timestampQuote :: QuasiQuoter
- toMutez :: Word32 -> Mutez
- zeroMutez :: Mutez
- class ContainsDoc a where
- buildDocUnfinalized :: a -> ContractDoc
- class ContainsDoc a => ContainsUpdateableDoc a where
- modifyDocEntirely :: (SomeDocItem -> SomeDocItem) -> a -> a
- data SomeDocDefinitionItem where
- SomeDocDefinitionItem :: forall d. (DocItem d, DocItemPlacement d ~ 'DocItemInDefinitions) => d -> SomeDocDefinitionItem
- data SomeDocItem where
- SomeDocItem :: forall d. DocItem d => d -> SomeDocItem
- data ContractDoc = ContractDoc {
- cdContents :: DocBlock
- cdDefinitions :: DocBlock
- cdDefinitionsSet :: Set SomeDocDefinitionItem
- cdDefinitionIds :: Set DocItemId
- newtype SubDoc = SubDoc DocBlock
- newtype DocItemPos = DocItemPos (Natural, Text)
- data DocSection = DocItem d => DocSection (NonEmpty $ DocElem d)
- data DGitRevision
- = DGitRevisionKnown DGitRevisionInfo
- | DGitRevisionUnknown
- class (Typeable d, DOrd d) => DocItem d where
- type DocItemPlacement d :: DocItemPlacementKind
- type DocItemReferenced d :: DocItemReferencedKind
- docItemPos :: Natural
- docItemSectionName :: Maybe Text
- docItemSectionDescription :: Maybe Markdown
- docItemSectionNameStyle :: DocSectionNameStyle
- docItemRef :: d -> DocItemRef (DocItemPlacement d) (DocItemReferenced d)
- docItemToMarkdown :: HeaderLevel -> d -> Markdown
- docItemToToc :: HeaderLevel -> d -> Markdown
- docItemDependencies :: d -> [SomeDocDefinitionItem]
- docItemsOrder :: [d] -> [d]
- class GHasAnnotation a where
- gGetAnnotation :: AnnOptions -> FollowEntrypointFlag -> GenerateFieldAnnFlag -> (Notes (GValueType a), FieldAnn, VarAnn)
- class HasAnnotation a where
- getAnnotation :: FollowEntrypointFlag -> Notes (ToT a)
- annOptions :: AnnOptions
- data GenerateFieldAnnFlag
- data FollowEntrypointFlag
- data AnnOptions = AnnOptions {
- fieldAnnModifier :: Text -> Text
- defaultAnnOptions :: AnnOptions
- dropPrefixThen :: (Text -> Text) -> Text -> Text
- appendTo :: Text -> [Text] -> Text -> Text
- ctorNameToAnnWithOptions :: forall ctor. (KnownSymbol ctor, HasCallStack) => AnnOptions -> FieldAnn
- gGetAnnotationNoField :: forall a. (GHasAnnotation (Rep a), GValueType (Rep a) ~ ToT a) => FollowEntrypointFlag -> Notes (ToT a)
- type DocGrouping = SubDoc -> SomeDocItem
- attachDocCommons :: ContainsUpdateableDoc a => DGitRevision -> a -> WithFinalizedDoc a
- buildDoc :: ContainsDoc a => WithFinalizedDoc a -> ContractDoc
- buildMarkdownDoc :: ContainsDoc a => WithFinalizedDoc a -> LText
- contractDocToMarkdown :: ContractDoc -> LText
- docDefinitionRef :: (DocItem d, DocItemPlacement d ~ 'DocItemInDefinitions) => Markdown -> d -> Markdown
- docItemPosition :: DocItem d => DocItemPos
- docItemSectionRef :: DocItem di => Maybe Markdown
- finalizedAsIs :: a -> WithFinalizedDoc a
- mdTocFromRef :: (DocItem d, DocItemReferenced d ~ 'True) => HeaderLevel -> Markdown -> d -> Markdown
- mkDGitRevision :: ExpQ
- modifyDoc :: (ContainsUpdateableDoc a, DocItem i1, DocItem i2) => (i1 -> Maybe i2) -> a -> a
- morleyRepoSettings :: GitRepoSettings
- subDocToMarkdown :: HeaderLevel -> SubDoc -> Markdown
- data DAnchor = DAnchor Anchor
- data DComment = DComment Text
- data DDescription = DDescription Markdown
- newtype DGeneralInfoSection = DGeneralInfoSection SubDoc
- data DName = DName Text SubDoc
- data DocElem d = DocElem {}
- type family DocItemPlacement d :: DocItemPlacementKind
- type family DocItemReferenced d :: DocItemReferencedKind
- newtype DocItemId = DocItemId Text
- data DocItemPlacementKind
- data DocItemRef (p :: DocItemPlacementKind) (r :: DocItemReferencedKind) where
- data DocSectionNameStyle
- newtype GitRepoSettings = GitRepoSettings {
- grsMkGitRevision :: Text -> Text
- data WithFinalizedDoc a
- type Markdown = Builder
- type NiceComparable n = (KnownValue n, Comparable (ToT n))
- type NicePrintedValue a = (KnownValue a, ProperPrintedValBetterErrors (ToT a))
- type NiceFullPackedValue a = (NicePackedValue a, NiceUnpackedValue a)
- type NiceUnpackedValue a = (KnownValue a, ProperUnpackedValBetterErrors (ToT a))
- type NicePackedValue a = (KnownValue a, ProperPackedValBetterErrors (ToT a))
- type NiceConstant a = (KnownValue a, ProperConstantBetterErrors (ToT a))
- type NiceStorage a = (HasAnnotation a, KnownValue a, ProperStorageBetterErrors (ToT a))
- type NiceParameter a = (KnownValue a, ProperParameterBetterErrors (ToT a))
- class (IsoValue a, HasNoNestedBigMaps (ToT a)) => CanHaveBigMap a
- class (IsoValue a, ForbidBigMap (ToT a)) => NoBigMap a
- class (IsoValue a, ForbidContract (ToT a)) => NoContractType a
- class (IsoValue a, ForbidOp (ToT a)) => NoOperation a
- class (IsoValue a, Typeable a) => KnownValue a
- niceParameterEvi :: forall a. NiceParameter a :- ParameterScope (ToT a)
- niceStorageEvi :: forall a. NiceStorage a :- StorageScope (ToT a)
- niceConstantEvi :: forall a. NiceConstant a :- ConstantScope (ToT a)
- nicePackedValueEvi :: forall a. NicePackedValue a :- PackedValScope (ToT a)
- niceUnpackedValueEvi :: forall a. NiceUnpackedValue a :- UnpackedValScope (ToT a)
- nicePrintedValueEvi :: forall a. NicePrintedValue a :- PrintedValScope (ToT a)
- newtype ShouldHaveEntrypoints a = ShouldHaveEntrypoints {
- unHasEntrypoints :: a
- data EpdNone
- type family ParameterContainsEntrypoints param (fields :: [NamedEp]) :: Constraint where ...
- type (:>) n ty = 'NamedEp n ty
- type HasEntrypointOfType param con exp = (GetEntrypointArgCustom param ('Just con) ~ exp, ParameterDeclaresEntrypoints param)
- newtype TrustEpName = TrustEpName EpName
- type HasDefEntrypointArg cp defEpName defArg = (defEpName ~ EntrypointRef 'Nothing, HasEntrypointArg cp defEpName defArg)
- class HasEntrypointArg cp name arg where
- useHasEntrypointArg :: name -> (Dict (ParameterScope (ToT arg)), EpName)
- type family GetEntrypointArgCustom cp mname :: Type where ...
- data EntrypointRef (mname :: Maybe Symbol) where
- CallDefault :: EntrypointRef 'Nothing
- Call :: NiceEntrypointName name => EntrypointRef ('Just name)
- type NoExplicitDefaultEntrypoint cp = Eval (LookupParameterEntrypoint cp DefaultEpName) ~ 'Nothing
- type ForbidExplicitDefaultEntrypoint cp = Eval (LiftM3 UnMaybe (Pure (Pure (() :: Constraint))) (TError ('Text "Parameter used here must have no explicit \"default\" entrypoint" :$$: (('Text "In parameter type `" :<>: 'ShowType cp) :<>: 'Text "`"))) (LookupParameterEntrypoint cp DefaultEpName))
- type GetDefaultEntrypointArg cp = Eval (LiftM2 FromMaybe (Pure cp) (LookupParameterEntrypoint cp DefaultEpName))
- type GetEntrypointArg cp name = Eval (LiftM2 FromMaybe (TError (('Text "Entrypoint not found: " :<>: 'ShowType name) :$$: (('Text "In contract parameter `" :<>: 'ShowType cp) :<>: 'Text "`"))) (LookupParameterEntrypoint cp name))
- type family LookupParameterEntrypoint (cp :: Type) :: Symbol -> Exp (Maybe Type) where ...
- type family AllParameterEntrypoints (cp :: Type) :: [(Symbol, Type)] where ...
- type ParameterDeclaresEntrypoints cp = (If (CanHaveEntrypoints cp) (ParameterHasEntrypoints cp) (() :: Constraint), NiceParameter cp, EntrypointsDerivation (GetParameterEpDerivation cp) cp)
- class (EntrypointsDerivation (ParameterEntrypointsDerivation cp) cp, RequireAllUniqueEntrypoints cp) => ParameterHasEntrypoints cp where
- type ParameterEntrypointsDerivation cp :: Type
- type RequireAllUniqueEntrypoints cp = RequireAllUniqueEntrypoints' (ParameterEntrypointsDerivation cp) cp
- class EntrypointsDerivation deriv cp where
- type EpdAllEntrypoints deriv cp :: [(Symbol, Type)]
- type EpdLookupEntrypoint deriv cp :: Symbol -> Exp (Maybe Type)
- epdNotes :: (Notes (ToT cp), RootAnn)
- epdCall :: ParameterScope (ToT cp) => Label name -> EpConstructionRes (ToT cp) (Eval (EpdLookupEntrypoint deriv cp name))
- epdDescs :: Rec EpCallingDesc (EpdAllEntrypoints deriv cp)
- parameterEntrypointsToNotes :: forall cp. ParameterDeclaresEntrypoints cp => ParamNotes (ToT cp)
- parameterEntrypointCall :: forall cp name. ParameterDeclaresEntrypoints cp => Label name -> EntrypointCall cp (GetEntrypointArg cp name)
- parameterEntrypointCallDefault :: forall cp. ParameterDeclaresEntrypoints cp => EntrypointCall cp (GetDefaultEntrypointArg cp)
- sepcCallRootChecked :: forall cp. (NiceParameter cp, ForbidExplicitDefaultEntrypoint cp) => SomeEntrypointCall cp
- eprName :: forall mname. EntrypointRef mname -> EpName
- parameterEntrypointCallCustom :: forall cp mname. ParameterDeclaresEntrypoints cp => EntrypointRef mname -> EntrypointCall cp (GetEntrypointArgCustom cp mname)
- type NiceParameterFull cp = (Typeable cp, ParameterDeclaresEntrypoints cp)
- class MapLorentzInstr instr where
- mapLorentzInstr :: (forall i o. (i :-> o) -> i :-> o) -> instr -> instr
- type Lambda i o = '[i] :-> '[o]
- type (&) (a :: Type) (b :: [Type]) = a ': b
- data SomeContractCode where
- SomeContractCode :: (NiceParameterFull cp, NiceStorage st) => ContractCode cp st -> SomeContractCode
- type ContractCode cp st = '[(cp, st)] :-> ContractOut st
- type ContractOut st = '[([Operation], st)]
- type (%>) = (:->)
- newtype (inp :: [Type]) :-> (out :: [Type]) = LorentzInstr {
- unLorentzInstr :: RemFail Instr (ToTs inp) (ToTs out)
- pattern FI :: (forall out'. Instr (ToTs inp) out') -> inp :-> out
- pattern I :: Instr (ToTs inp) (ToTs out) -> inp :-> out
- iGenericIf :: (forall s'. Instr (ToTs a) s' -> Instr (ToTs b) s' -> Instr (ToTs c) s') -> (a :-> s) -> (b :-> s) -> c :-> s
- iAnyCode :: (inp :-> out) -> Instr (ToTs inp) (ToTs out)
- iNonFailingCode :: HasCallStack => (inp :-> out) -> Instr (ToTs inp) (ToTs out)
- iMapAnyCode :: (forall o'. Instr (ToTs i1) o' -> Instr (ToTs i2) o') -> (i1 :-> o) -> i2 :-> o
- iForceNotFail :: (i :-> o) -> i :-> o
- iWithVarAnnotations :: HasCallStack => [Text] -> (inp :-> out) -> inp :-> out
- (#) :: (a :-> b) -> (b :-> c) -> a :-> c
- parseLorentzValue :: forall v. KnownValue v => Text -> Either ParseLorentzError v
- transformStringsLorentz :: Bool -> (MText -> MText) -> (inp :-> out) -> inp :-> out
- transformBytesLorentz :: Bool -> (ByteString -> ByteString) -> (inp :-> out) -> inp :-> out
- optimizeLorentzWithConf :: OptimizerConf -> (inp :-> out) -> inp :-> out
- optimizeLorentz :: (inp :-> out) -> inp :-> out
- type Entrypoint_ store = '[store] :-> ContractOut store
- type Entrypoint param store = '[param, store] :-> ContractOut store
- class FromContractRef (cp :: Type) (contract :: Type) where
- fromContractRef :: ContractRef cp -> contract
- class ToContractRef (cp :: Type) (contract :: Type) where
- toContractRef :: HasCallStack => contract -> ContractRef cp
- class ToTAddress (cp :: Type) (a :: Type) where
- toTAddress :: a -> TAddress cp
- class ToAddress a where
- newtype FutureContract arg = FutureContract {
- unFutureContract :: ContractRef arg
- newtype TAddress p = TAddress {}
- callingTAddress :: forall cp mname. NiceParameterFull cp => TAddress cp -> EntrypointRef mname -> ContractRef (GetEntrypointArgCustom cp mname)
- callingDefTAddress :: forall cp. NiceParameterFull cp => TAddress cp -> ContractRef (GetDefaultEntrypointArg cp)
- toTAddress_ :: forall cp addr s. ToTAddress_ cp addr => (addr ': s) :-> (TAddress cp ': s)
- convertContractRef :: forall cp contract2 contract1. (ToContractRef cp contract1, FromContractRef cp contract2) => contract1 -> contract2
- stackRef :: forall (gn :: Nat) st n. (n ~ ToPeano gn, SingI n, KnownPeano n, RequireLongerThan st n) => PrintComment st
- printComment :: PrintComment (ToTs s) -> s :-> s
- testAssert :: (Typeable (ToTs out), HasCallStack) => Text -> PrintComment (ToTs inp) -> (inp :-> (Bool ': out)) -> inp :-> inp
- stackType :: forall s. s :-> s
- class (EDivOp (ToT n) (ToT m), NiceComparable n, NiceComparable m, ToT (EDivOpResHs n m) ~ EDivOpRes (ToT n) (ToT m), ToT (EModOpResHs n m) ~ EModOpRes (ToT n) (ToT m)) => EDivOpHs n m where
- type EDivOpResHs n m :: Type
- type EModOpResHs n m :: Type
- class SliceOp (ToT c) => SliceOpHs c
- class ConcatOp (ToT c) => ConcatOpHs c
- class (GetOp (ToT c), ToT (GetOpKeyHs c) ~ GetOpKey (ToT c), ToT (GetOpValHs c) ~ GetOpVal (ToT c)) => GetOpHs c where
- type GetOpKeyHs c :: Type
- type GetOpValHs c :: Type
- class (UpdOp (ToT c), ToT (UpdOpKeyHs c) ~ UpdOpKey (ToT c), ToT (UpdOpParamsHs c) ~ UpdOpParams (ToT c)) => UpdOpHs c where
- type UpdOpKeyHs c :: Type
- type UpdOpParamsHs c :: Type
- class SizeOp (ToT c) => SizeOpHs c
- class (IterOp (ToT c), ToT (IterOpElHs c) ~ IterOpEl (ToT c)) => IterOpHs c where
- type IterOpElHs c :: Type
- class (MapOp (ToT c), ToT (MapOpInpHs c) ~ MapOpInp (ToT c), ToT (MapOpResHs c ()) ~ MapOpRes (ToT c) (ToT ())) => MapOpHs c where
- type MapOpInpHs c :: Type
- type MapOpResHs c :: Type -> Type
- type family IsoMapOpRes c b where ...
- class (MemOp (ToT c), ToT (MemOpKeyHs c) ~ MemOpKey (ToT c)) => MemOpHs c where
- type MemOpKeyHs c :: Type
- data GenericStrategy
- rightComb :: GenericStrategy
- alphabetically :: EntriesReorder
- forbidUnnamedFields :: UnnamedEntriesReorder
- cstr :: forall (n :: Nat). KnownNat n => [Natural] -> CstrDepth
- customGeneric :: String -> GenericStrategy -> Q [Dec]
- customGeneric' :: Maybe Type -> Name -> Type -> [Con] -> GenericStrategy -> Q [Dec]
- deriveFullType :: Name -> Maybe Kind -> [TyVarBndr] -> TypeQ
- fld :: forall (n :: Nat). KnownNat n => Natural
- fromDepthsStrategy :: (Int -> [Natural]) -> GenericStrategy
- haskellBalanced :: GenericStrategy
- leaveUnnamedFields :: UnnamedEntriesReorder
- leftBalanced :: GenericStrategy
- leftComb :: GenericStrategy
- reifyDataType :: Name -> Q (Name, Cxt, Maybe Kind, [TyVarBndr], [Con])
- reorderingConstrs :: EntriesReorder -> GenericStrategy -> GenericStrategy
- reorderingData :: UnnamedEntriesReorder -> EntriesReorder -> GenericStrategy -> GenericStrategy
- reorderingFields :: UnnamedEntriesReorder -> EntriesReorder -> GenericStrategy -> GenericStrategy
- rightBalanced :: GenericStrategy
- withDepths :: [CstrDepth] -> GenericStrategy
- newtype PrintAsValue a = PrintAsValue a
- data Never
- type List = []
- data EpdWithRoot (r :: Symbol) epd
- data EpdDelegate
- data EpdRecursive
- data EpdPlain
- class ToIntArithOp (ToT n) => ToIntegerArithOpHs (n :: Type)
- class (UnaryArithOp aop (ToT n), ToT (UnaryArithResHs aop n) ~ UnaryArithRes aop (ToT n)) => UnaryArithOpHs (aop :: Type) (n :: Type) where
- type UnaryArithResHs aop n :: Type
- class (ArithOp aop (ToT n) (ToT m), ToT (ArithResHs aop n m) ~ ArithRes aop (ToT n) (ToT m)) => ArithOpHs (aop :: Type) (n :: Type) (m :: Type) where
- type ArithResHs aop n m :: Type
- class ToT s ~ ToT (Unwrappable s) => Wrappable (s :: Type) where
- type Unwrappable s :: Type
- newtype ParameterWrapper (deriv :: Type) cp = ParameterWrapper {
- unParameterWraper :: cp
- data DEntrypointExample = forall t.ParameterScope t => DEntrypointExample (Value t)
- doc :: DocItem di => di -> s :-> s
- docGroup :: DocItem di => (SubDoc -> di) -> (inp :-> out) -> inp :-> out
- docStorage :: forall storage s. TypeHasDoc storage => s :-> s
- contractName :: Text -> (inp :-> out) -> inp :-> out
- buildLorentzDoc :: (inp :-> out) -> ContractDoc
- contractGeneral :: (inp :-> out) -> inp :-> out
- contractGeneralDefault :: s :-> s
- buildLorentzDocWithGitRev :: DGitRevision -> (inp :-> out) -> ContractDoc
- renderLorentzDoc :: (inp :-> out) -> LText
- renderLorentzDocWithGitRev :: DGitRevision -> (inp :-> out) -> LText
- cutLorentzNonDoc :: (inp :-> out) -> s :-> s
- mkDEntrypointExample :: forall a. NiceParameter a => a -> DEntrypointExample
- data Keccak :: HashAlgorithmKind
- data Sha3 :: HashAlgorithmKind
- data Blake2b :: HashAlgorithmKind
- data Sha512 :: HashAlgorithmKind
- data Sha256 :: HashAlgorithmKind
- data DHashAlgorithm
- class Typeable alg => KnownHashAlgorithm (alg :: HashAlgorithmKind) where
- hashAlgorithmName :: Proxy alg -> Text
- computeHash :: ByteString -> ByteString
- toHash :: BytesLike bs => (bs ': s) :-> (Hash alg bs ': s)
- newtype Hash (alg :: HashAlgorithmKind) a = HashUnsafe {
- unHash :: ByteString
- newtype TSignature a = TSignature {}
- newtype Packed a = Packed {}
- class (KnownValue bs, ToT bs ~ ToT ByteString) => BytesLike bs where
- toBytes :: bs -> ByteString
- lSignEd22519 :: BytesLike a => SecretKey -> a -> TSignature a
- toHashHs :: forall alg bs. (BytesLike bs, KnownHashAlgorithm alg) => bs -> Hash alg bs
- lPackValueRaw :: forall a. NicePackedValue a => a -> ByteString
- lUnpackValueRaw :: forall a. NiceUnpackedValue a => ByteString -> Either UnpackError a
- lPackValue :: forall a. NicePackedValue a => a -> Packed a
- lUnpackValue :: forall a. NiceUnpackedValue a => Packed a -> Either UnpackError a
- lEncodeValue :: forall a. NicePrintedValue a => a -> ByteString
- valueToScriptExpr :: forall t. NicePackedValue t => t -> ByteString
- expressionToScriptExpr :: Expression -> ByteString
- type Coercible_ a b = (MichelsonCoercible a b, CanCastTo a b, CanCastTo b a)
- type Castable_ a b = (MichelsonCoercible a b, CanCastTo a b)
- class CanCastTo a b where
- type MichelsonCoercible a b = ToT a ~ ToT b
- forcedCoerce :: Coercible a b => a -> b
- forcedCoerce_ :: MichelsonCoercible a b => (a ': s) :-> (b ': s)
- gForcedCoerce_ :: MichelsonCoercible (t a) (t b) => (t a ': s) :-> (t b ': s)
- fakeCoerce :: s1 :-> s2
- fakeCoercing :: (s1 :-> s2) -> s1' :-> s2'
- coerceWrap :: forall a s. Wrappable a => (Unwrappable a ': s) :-> (a ': s)
- coerceUnwrap :: forall a s. Wrappable a => (a ': s) :-> (Unwrappable a ': s)
- toNamed :: Label name -> (a ': s) :-> (NamedF Identity a name ': s)
- fromNamed :: Label name -> (NamedF Identity a name ': s) :-> (a ': s)
- checkedCoerce :: forall a b. (CanCastTo a b, Coercible a b) => a -> b
- checkedCoerce_ :: forall a b s. Castable_ a b => (a ': s) :-> (b ': s)
- checkedCoercing_ :: forall a b s. Coercible_ a b => ((b ': s) :-> (b ': s)) -> (a ': s) :-> (a ': s)
- allowCheckedCoerceTo :: forall b a. Dict (CanCastTo a b)
- allowCheckedCoerce :: forall a b. Dict (CanCastTo a b, CanCastTo b a)
- castDummyG :: (Generic a, Generic b, GCanCastTo (Rep a) (Rep b)) => Proxy a -> Proxy b -> ()
- type CaseTC dt out inp clauses = (InstrCaseC dt, RMap (CaseClauses dt), RecFromTuple clauses, clauses ~ Rec (CaseClauseL inp out) (CaseClauses dt))
- class CaseArrow name body clause | clause -> name, clause -> body where
- data CaseClauseL (inp :: [Type]) (out :: [Type]) (param :: CaseClauseParam) where
- CaseClauseL :: (AppendCtorField x inp :-> out) -> CaseClauseL inp out ('CaseClauseParam ctor x)
- type family HasFieldsOfType (dt :: Type) (fs :: [NamedField]) :: Constraint where ...
- type (:=) n ty = 'NamedField n ty
- data NamedField = NamedField Symbol Type
- type HasFieldOfType dt fname fieldTy = (HasField dt fname, GetFieldType dt fname ~ fieldTy)
- type HasField dt fname = (InstrGetFieldC dt fname, InstrSetFieldC dt fname)
- toField :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> (GetFieldType dt name ': st)
- toFieldNamed :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> ((name :! GetFieldType dt name) ': st)
- getField :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> (GetFieldType dt name ': (dt ': st))
- getFieldNamed :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> ((name :! GetFieldType dt name) ': (dt ': st))
- setField :: forall dt name st. InstrSetFieldC dt name => Label name -> (GetFieldType dt name ': (dt ': st)) :-> (dt ': st)
- modifyField :: forall dt name st. (InstrGetFieldC dt name, InstrSetFieldC dt name) => Label name -> (forall st0. (GetFieldType dt name ': st0) :-> (GetFieldType dt name ': st0)) -> (dt ': st) :-> (dt ': st)
- construct :: forall dt st. (InstrConstructC dt, RMap (ConstructorFieldTypes dt)) => Rec (FieldConstructor st) (ConstructorFieldTypes dt) -> st :-> (dt ': st)
- constructT :: forall dt fctors st. (InstrConstructC dt, RMap (ConstructorFieldTypes dt), fctors ~ Rec (FieldConstructor st) (ConstructorFieldTypes dt), RecFromTuple fctors) => IsoRecTuple fctors -> st :-> (dt ': st)
- constructStack :: forall dt fields st. (InstrConstructC dt, ToTs fields ~ ToTs (ConstructorFieldTypes dt), KnownList fields) => (fields ++ st) :-> (dt ': st)
- deconstruct :: forall dt fields st. (InstrDeconstructC dt, KnownList fields, ToTs fields ~ ToTs (ConstructorFieldTypes dt)) => (dt ': st) :-> (fields ++ st)
- fieldCtor :: HasCallStack => (st :-> (f ': st)) -> FieldConstructor st f
- wrap_ :: forall dt name st. InstrWrapC dt name => Label name -> AppendCtorField (GetCtorField dt name) st :-> (dt ': st)
- wrapOne :: forall dt name st. InstrWrapOneC dt name => Label name -> (CtorOnlyField name dt ': st) :-> (dt ': st)
- case_ :: forall dt out inp. (InstrCaseC dt, RMap (CaseClauses dt)) => Rec (CaseClauseL inp out) (CaseClauses dt) -> (dt ': inp) :-> out
- caseT :: forall dt out inp clauses. CaseTC dt out inp clauses => IsoRecTuple clauses -> (dt ': inp) :-> out
- unwrapUnsafe_ :: forall dt name st. InstrUnwrapC dt name => Label name -> (dt ': st) :-> (CtorOnlyField name dt ': st)
- type family RequireFlatEpDerivation cp deriv :: Constraint where ...
- type family RequireFlatParamEps cp :: Constraint where ...
- class EntryArrow kind name body where
- type DocumentEntrypoints kind a = (Generic a, GDocumentEntrypoints kind (Rep a))
- class KnownSymbol con => DeriveCtorFieldDoc con (cf :: CtorField) where
- data DEntrypointArg = DEntrypointArg {}
- data SomeEntrypointArg = forall a.(NiceParameter a, TypeHasDoc a) => SomeEntrypointArg (Proxy a)
- data ParamBuildingStep
- data ParamBuildingDesc = ParamBuildingDesc {}
- newtype ParamBuilder = ParamBuilder {
- unParamBuilder :: Markdown -> Markdown
- data DEntrypointReference = DEntrypointReference Text Anchor
- data CommonEntrypointsBehaviourKind kind
- data CommonContractBehaviourKind
- data PlainEntrypointsKind
- class Typeable ep => EntrypointKindHasDoc (ep :: Type) where
- data DEntrypoint (kind :: Type) = DEntrypoint {}
- pattern DEntrypointDocItem :: DEntrypoint kind -> SomeDocItem
- diEntrypointToMarkdown :: HeaderLevel -> DEntrypoint level -> Markdown
- entrypointSection :: EntrypointKindHasDoc kind => Text -> Proxy kind -> (i :-> o) -> i :-> o
- mkPbsWrapIn :: Text -> ParamBuilder -> ParamBuildingStep
- constructDEpArg :: forall arg. (NiceParameter arg, TypeHasDoc arg) => DEntrypointArg
- emptyDEpArg :: DEntrypointArg
- mkDEpUType :: forall t. (KnownValue t, HasAnnotation t) => Ty
- mkDEntrypointArgSimple :: forall t. (NiceParameter t, TypeHasDoc t) => DEntrypointArg
- clarifyParamBuildingSteps :: ParamBuildingStep -> (inp :-> out) -> inp :-> out
- entryCase_ :: forall dt entrypointKind out inp. (InstrCaseC dt, RMap (CaseClauses dt), DocumentEntrypoints entrypointKind dt) => Proxy entrypointKind -> Rec (CaseClauseL inp out) (CaseClauses dt) -> (dt ': inp) :-> out
- entryCase :: forall dt entrypointKind out inp clauses. (CaseTC dt out inp clauses, DocumentEntrypoints entrypointKind dt) => Proxy entrypointKind -> IsoRecTuple clauses -> (dt ': inp) :-> out
- documentEntrypoint :: forall kind epName param s out. (KnownSymbol epName, DocItem (DEntrypoint kind), NiceParameter param, TypeHasDoc param) => ((param ': s) :-> out) -> (param ': s) :-> out
- finalizeParamCallingDoc' :: forall cp inp out. (NiceParameterFull cp, HasCallStack) => Proxy cp -> (inp :-> out) -> inp :-> out
- finalizeParamCallingDoc :: forall cp inp out. (NiceParameterFull cp, RequireSumType cp, HasCallStack) => ((cp ': inp) :-> out) -> (cp ': inp) :-> out
- areFinalizedParamBuildingSteps :: [ParamBuildingStep] -> Bool
- entryCaseSimple_ :: forall cp out inp. (InstrCaseC cp, RMap (CaseClauses cp), DocumentEntrypoints PlainEntrypointsKind cp, RequireFlatParamEps cp) => Rec (CaseClauseL inp out) (CaseClauses cp) -> (cp ': inp) :-> out
- entryCaseSimple :: forall cp out inp clauses. (CaseTC cp out inp clauses, DocumentEntrypoints PlainEntrypointsKind cp, RequireFlatParamEps cp) => IsoRecTuple clauses -> (cp ': inp) :-> out
- data Contract cp st = Contract {}
- data CompilationOptions = CompilationOptions {
- coOptimizerConf :: Maybe OptimizerConf
- coStringTransformer :: (Bool, MText -> MText)
- coBytesTransformer :: (Bool, ByteString -> ByteString)
- defaultCompilationOptions :: CompilationOptions
- intactCompilationOptions :: CompilationOptions
- compileLorentz :: (inp :-> out) -> Instr (ToTs inp) (ToTs out)
- compileLorentzWithOptions :: CompilationOptions -> (inp :-> out) -> Instr (ToTs inp) (ToTs out)
- defaultContract :: forall cp st. (NiceParameterFull cp, HasCallStack) => ContractCode cp st -> Contract cp st
- compileLorentzContract :: forall cp st. (NiceParameterFull cp, NiceStorage st) => Contract cp st -> Contract (ToT cp) (ToT st)
- interpretLorentzInstr :: (IsoValuesStack inp, IsoValuesStack out) => ContractEnv -> (inp :-> out) -> Rec Identity inp -> Either MichelsonFailed (Rec Identity out)
- interpretLorentzLambda :: (IsoValue inp, IsoValue out) => ContractEnv -> Lambda inp out -> inp -> Either MichelsonFailed out
- analyzeLorentz :: (inp :-> out) -> AnalyzerRes
- coBytesTransformerL :: Lens' CompilationOptions (Bool, ByteString -> ByteString)
- coOptimizerConfL :: Lens' CompilationOptions (Maybe OptimizerConf)
- coStringTransformerL :: Lens' CompilationOptions (Bool, MText -> MText)
- cCodeL :: forall cp st cp st. Lens (Contract cp st) (Contract cp st) (ContractCode cp st) (ContractCode cp st)
- cCompilationOptionsL :: forall cp st. Lens' (Contract cp st) CompilationOptions
- cDisableInitialCastL :: forall cp st. Lens' (Contract cp st) Bool
- (-$?) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out) => (inps :-> '[out]) -> ZippedStack inps -> Either MichelsonFailed out
- (-$) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out, HasCallStack) => (inps :-> '[out]) -> ZippedStack inps -> out
- (&?-) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out) => ZippedStack inps -> (inps :-> '[out]) -> Either MichelsonFailed out
- (&-) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out, HasCallStack) => ZippedStack inps -> (inps :-> '[out]) -> out
- (<-$>) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out, HasCallStack) => (inps :-> '[out]) -> [ZippedStack inps] -> [out]
- printLorentzValue :: forall v. NicePrintedValue v => Bool -> v -> LText
- printLorentzContract :: forall cp st. (NiceParameterFull cp, NiceStorage st) => Bool -> Contract cp st -> LText
- contractOpSize :: (NiceParameterFull cp, NiceStorage st) => Contract cp st -> OpSize
- valueOpSize :: forall a. NicePrintedValue a => a -> OpSize
- class NonZero t where
- class LorentzFunctor (c :: Type -> Type) where
- lmap :: KnownValue b => ((a ': s) :-> (b ': s)) -> (c a ': s) :-> (c b ': s)
- type ConstraintDIPNLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (s :: [Type]) (s' :: [Type]) = (ConstraintDIPN n (ToTs inp) (ToTs out) (ToTs s) (ToTs s'), ConstraintDIPN' Type n inp out s s')
- type family PairUpdateHs (ix :: Peano) (val :: Type) (pair :: Type) :: Type where ...
- type ConstraintPairUpdateLorentz (n :: Nat) (val :: Type) (pair :: Type) = (ConstraintUpdateN (ToPeano n) (ToT pair), ToT (PairUpdateHs (ToPeano n) val pair) ~ UpdateN (ToPeano n) (ToT val) (ToT pair))
- type family PairGetHs (ix :: Peano) (pair :: Type) :: Type where ...
- type ConstraintPairGetLorentz (n :: Nat) (pair :: Type) = (ConstraintGetN (ToPeano n) (ToT pair), ToT (PairGetHs (ToPeano n) pair) ~ GetN (ToPeano n) (ToT pair))
- type ConstraintDUGLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (a :: Type) = (ConstraintDUG n (ToTs inp) (ToTs out) (ToT a), ConstraintDUG' Type n inp out a)
- type ConstraintDIGLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (a :: Type) = (ConstraintDIG n (ToTs inp) (ToTs out) (ToT a), ConstraintDIG' Type n inp out a)
- type ConstraintDUPNLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (a :: Type) = (ConstraintDUPN n (ToTs inp) (ToTs out) (ToT a), ConstraintDUPN' Type n inp out a)
- nop :: s :-> s
- justComment :: Text -> s :-> s
- comment :: CommentType -> s :-> s
- commentAroundFun :: Text -> (i :-> o) -> i :-> o
- commentAroundStmt :: Text -> (i :-> o) -> i :-> o
- drop :: (a ': s) :-> s
- dropN :: forall (n :: Nat) (s :: [Type]). (SingI (ToPeano n), KnownPeano (ToPeano n), RequireLongerOrSameLength (ToTs s) (ToPeano n), Drop (ToPeano n) (ToTs s) ~ ToTs (Drop (ToPeano n) s)) => s :-> Drop (ToPeano n) s
- dup :: (a ': s) :-> (a ': (a ': s))
- dupNPeano :: forall (n :: Peano) inp out a. ConstraintDUPNLorentz n inp out a => inp :-> out
- dupN :: forall (n :: Nat) inp out a. ConstraintDUPNLorentz (ToPeano n) inp out a => inp :-> out
- swap :: (a ': (b ': s)) :-> (b ': (a ': s))
- digPeano :: forall (n :: Peano) inp out a. ConstraintDIGLorentz n inp out a => inp :-> out
- dig :: forall (n :: Nat) inp out a. ConstraintDIGLorentz (ToPeano n) inp out a => inp :-> out
- dugPeano :: forall (n :: Peano) inp out a. ConstraintDUGLorentz n inp out a => inp :-> out
- dug :: forall (n :: Nat) inp out a. ConstraintDUGLorentz (ToPeano n) inp out a => inp :-> out
- push :: forall t s. NiceConstant t => t -> s :-> (t ': s)
- some :: (a ': s) :-> (Maybe a ': s)
- none :: forall a s. KnownValue a => s :-> (Maybe a ': s)
- unit :: s :-> (() ': s)
- ifNone :: (s :-> s') -> ((a ': s) :-> s') -> (Maybe a ': s) :-> s'
- pair :: (a ': (b ': s)) :-> ((a, b) ': s)
- car :: ((a, b) ': s) :-> (a ': s)
- cdr :: ((a, b) ': s) :-> (b ': s)
- left :: forall a b s. KnownValue b => (a ': s) :-> (Either a b ': s)
- right :: forall a b s. KnownValue a => (b ': s) :-> (Either a b ': s)
- ifLeft :: ((a ': s) :-> s') -> ((b ': s) :-> s') -> (Either a b ': s) :-> s'
- nil :: KnownValue p => s :-> (List p ': s)
- cons :: (a ': (List a ': s)) :-> (List a ': s)
- ifCons :: ((a ': (List a ': s)) :-> s') -> (s :-> s') -> (List a ': s) :-> s'
- size :: SizeOpHs c => (c ': s) :-> (Natural ': s)
- emptySet :: NiceComparable e => s :-> (Set e ': s)
- emptyMap :: (NiceComparable k, KnownValue v) => s :-> (Map k v ': s)
- emptyBigMap :: (NiceComparable k, KnownValue v) => s :-> (BigMap k v ': s)
- map :: (MapOpHs c, IsoMapOpRes c b, KnownValue b, HasCallStack) => ((MapOpInpHs c ': s) :-> (b ': s)) -> (c ': s) :-> (MapOpResHs c b ': s)
- iter :: (IterOpHs c, HasCallStack) => ((IterOpElHs c ': s) :-> s) -> (c ': s) :-> s
- mem :: MemOpHs c => (MemOpKeyHs c ': (c ': s)) :-> (Bool ': s)
- get :: (GetOpHs c, KnownValue (GetOpValHs c)) => (GetOpKeyHs c ': (c ': s)) :-> (Maybe (GetOpValHs c) ': s)
- pairGet :: forall (n :: Nat) (pair :: Type) (s :: [Type]). ConstraintPairGetLorentz n pair => (pair ': s) :-> (PairGetHs (ToPeano n) pair ': s)
- update :: UpdOpHs c => (UpdOpKeyHs c ': (UpdOpParamsHs c ': (c ': s))) :-> (c ': s)
- pairUpdate :: forall (n :: Nat) (val :: Type) (pair :: Type) (s :: [Type]). ConstraintPairUpdateLorentz n val pair => (val ': (pair ': s)) :-> (PairUpdateHs (ToPeano n) val pair ': s)
- if_ :: (s :-> s') -> (s :-> s') -> (Bool ': s) :-> s'
- loop :: (s :-> (Bool ': s)) -> (Bool ': s) :-> s
- loopLeft :: ((a ': s) :-> (Either a b ': s)) -> (Either a b ': s) :-> (b ': s)
- lambda :: ZipInstrs [i, o] => (i :-> o) -> s :-> ((i :-> o) ': s)
- exec :: (a ': (Lambda a b ': s)) :-> (b ': s)
- execute :: forall i o s. Each [KnownList, ZipInstr] [i, o] => ((i :-> o) ': (i ++ s)) :-> (o ++ s)
- apply :: forall a b c s. (NiceConstant a, KnownValue b) => (a ': (Lambda (a, b) c ': s)) :-> (Lambda b c ': s)
- applicate :: forall a b c inp2nd inpTail s. (NiceConstant a, ZipInstr b, b ~ (inp2nd ': inpTail)) => (a ': (((a ': b) :-> c) ': s)) :-> ((b :-> c) ': s)
- dip :: forall a s s'. HasCallStack => (s :-> s') -> (a ': s) :-> (a ': s')
- dipNPeano :: forall (n :: Peano) (inp :: [Type]) (out :: [Type]) (s :: [Type]) (s' :: [Type]). ConstraintDIPNLorentz n inp out s s' => (s :-> s') -> inp :-> out
- dipN :: forall (n :: Nat) (inp :: [Type]) (out :: [Type]) (s :: [Type]) (s' :: [Type]). ConstraintDIPNLorentz (ToPeano n) inp out s s' => (s :-> s') -> inp :-> out
- failWith :: forall a s t. NiceConstant a => (a ': s) :-> t
- cast :: KnownValue a => (a ': s) :-> (a ': s)
- pack :: forall a s. NicePackedValue a => (a ': s) :-> (Packed a ': s)
- unpack :: forall a s. NiceUnpackedValue a => (Packed a ': s) :-> (Maybe a ': s)
- packRaw :: forall a s. NicePackedValue a => (a ': s) :-> (ByteString ': s)
- unpackRaw :: forall a s. NiceUnpackedValue a => (ByteString ': s) :-> (Maybe a ': s)
- concat :: ConcatOpHs c => (c ': (c ': s)) :-> (c ': s)
- concat' :: ConcatOpHs c => (List c ': s) :-> (c ': s)
- slice :: (SliceOpHs c, KnownValue c) => (Natural ': (Natural ': (c ': s))) :-> (Maybe c ': s)
- isNat :: (Integer ': s) :-> (Maybe Natural ': s)
- add :: ArithOpHs Add n m => (n ': (m ': s)) :-> (ArithResHs Add n m ': s)
- sub :: ArithOpHs Sub n m => (n ': (m ': s)) :-> (ArithResHs Sub n m ': s)
- rsub :: ArithOpHs Sub n m => (m ': (n ': s)) :-> (ArithResHs Sub n m ': s)
- mul :: ArithOpHs Mul n m => (n ': (m ': s)) :-> (ArithResHs Mul n m ': s)
- ediv :: EDivOpHs n m => (n ': (m ': s)) :-> (Maybe (EDivOpResHs n m, EModOpResHs n m) ': s)
- abs :: UnaryArithOpHs Abs n => (n ': s) :-> (UnaryArithResHs Abs n ': s)
- neg :: UnaryArithOpHs Neg n => (n ': s) :-> (UnaryArithResHs Neg n ': s)
- lsl :: ArithOpHs Lsl n m => (n ': (m ': s)) :-> (ArithResHs Lsl n m ': s)
- lsr :: ArithOpHs Lsr n m => (n ': (m ': s)) :-> (ArithResHs Lsr n m ': s)
- or :: ArithOpHs Or n m => (n ': (m ': s)) :-> (ArithResHs Or n m ': s)
- and :: ArithOpHs And n m => (n ': (m ': s)) :-> (ArithResHs And n m ': s)
- xor :: ArithOpHs Xor n m => (n ': (m ': s)) :-> (ArithResHs Xor n m ': s)
- not :: UnaryArithOpHs Not n => (n ': s) :-> (UnaryArithResHs Not n ': s)
- compare :: NiceComparable n => (n ': (n ': s)) :-> (Integer ': s)
- eq0 :: UnaryArithOpHs Eq' n => (n ': s) :-> (UnaryArithResHs Eq' n ': s)
- neq0 :: UnaryArithOpHs Neq n => (n ': s) :-> (UnaryArithResHs Neq n ': s)
- lt0 :: UnaryArithOpHs Lt n => (n ': s) :-> (UnaryArithResHs Lt n ': s)
- gt0 :: UnaryArithOpHs Gt n => (n ': s) :-> (UnaryArithResHs Gt n ': s)
- le0 :: UnaryArithOpHs Le n => (n ': s) :-> (UnaryArithResHs Le n ': s)
- ge0 :: UnaryArithOpHs Ge n => (n ': s) :-> (UnaryArithResHs Ge n ': s)
- int :: ToIntegerArithOpHs i => (i ': s) :-> (Integer ': s)
- self :: forall p s. (NiceParameterFull p, ForbidExplicitDefaultEntrypoint p) => s :-> (ContractRef p ': s)
- selfCalling :: forall p mname s. NiceParameterFull p => EntrypointRef mname -> s :-> (ContractRef (GetEntrypointArgCustom p mname) ': s)
- contract :: forall p addr s. (NiceParameterFull p, ForbidExplicitDefaultEntrypoint p, ToTAddress_ p addr) => (addr ': s) :-> (Maybe (ContractRef p) ': s)
- contractCalling :: forall cp epRef epArg addr s. (HasEntrypointArg cp epRef epArg, ToTAddress_ cp addr) => epRef -> (addr ': s) :-> (Maybe (ContractRef epArg) ': s)
- contractCallingUnsafe :: forall arg s. NiceParameter arg => EpName -> (Address ': s) :-> (Maybe (ContractRef arg) ': s)
- runFutureContract :: forall p s. NiceParameter p => (FutureContract p ': s) :-> (Maybe (ContractRef p) ': s)
- epAddressToContract :: forall p s. NiceParameter p => (EpAddress ': s) :-> (Maybe (ContractRef p) ': s)
- transferTokens :: forall p s. NiceParameter p => (p ': (Mutez ': (ContractRef p ': s))) :-> (Operation ': s)
- setDelegate :: (Maybe KeyHash ': s) :-> (Operation ': s)
- createContract :: forall p g s. (NiceStorage g, NiceParameterFull p) => Contract p g -> (Maybe KeyHash ': (Mutez ': (g ': s))) :-> (Operation ': (Address ': s))
- implicitAccount :: (KeyHash ': s) :-> (ContractRef () ': s)
- now :: s :-> (Timestamp ': s)
- amount :: s :-> (Mutez ': s)
- balance :: s :-> (Mutez ': s)
- votingPower :: (KeyHash ': s) :-> (Natural ': s)
- totalVotingPower :: s :-> (Natural ': s)
- checkSignature :: BytesLike bs => (PublicKey ': (TSignature bs ': (bs ': s))) :-> (Bool ': s)
- sha256 :: BytesLike bs => (bs ': s) :-> (Hash Sha256 bs ': s)
- sha512 :: BytesLike bs => (bs ': s) :-> (Hash Sha512 bs ': s)
- blake2B :: BytesLike bs => (bs ': s) :-> (Hash Blake2b bs ': s)
- sha3 :: BytesLike bs => (bs ': s) :-> (Hash Sha3 bs ': s)
- keccak :: BytesLike bs => (bs ': s) :-> (Hash Keccak bs ': s)
- hashKey :: (PublicKey ': s) :-> (KeyHash ': s)
- pairingCheck :: ([(Bls12381G1, Bls12381G2)] ': s) :-> (Bool ': s)
- source :: s :-> (Address ': s)
- sender :: s :-> (Address ': s)
- address :: (ContractRef a ': s) :-> (Address ': s)
- chainId :: s :-> (ChainId ': s)
- level :: s :-> (Natural ': s)
- selfAddress :: s :-> (Address ': s)
- never :: (Never ': s) :-> s'
- framed :: forall s i o. (KnownList i, KnownList o) => (i :-> o) -> (i ++ s) :-> (o ++ s)
- failingWhenPresent :: forall c k s v st e. (MemOpHs c, k ~ MemOpKeyHs c, NiceConstant e, st ~ (k ': (v ': (c ': s)))) => (forall s0. (k ': s0) :-> (e ': s0)) -> st :-> st
- updateNew :: forall c k s e. (UpdOpHs c, MemOpHs c, k ~ UpdOpKeyHs c, k ~ MemOpKeyHs c, NiceConstant e) => (forall s0. (k ': s0) :-> (e ': s0)) -> (k ': (UpdOpParamsHs c ': (c ': s))) :-> (c ': s)
- type family HasNamedVars (s :: [Type]) (vs :: [NamedField]) :: Constraint where ...
- class HasNamedVar (s :: [Type]) (name :: Symbol) (var :: Type) | s name -> var
- type VarIsUnnamed x = VarName x ~ 'VarUnnamed
- dupLNamed :: forall var name s. HasNamedVar s name var => Label name -> s :-> ((name :! var) ': s)
- dupL :: forall var name s. HasNamedVar s name var => Label name -> s :-> (var ': s)
- dupT :: forall a st. DupT st a st => st :-> (a ': st)
- dipT :: forall a inp dinp dout out. DipT inp a inp dinp dout out => (dinp :-> dout) -> inp :-> out
- dropT :: forall a inp dinp dout out. (DipT inp a inp dinp dout out, dinp ~ (a ': dout)) => inp :-> out
- data DThrows where
- DThrows :: ErrorHasDoc e => Proxy e -> DThrows
- data DError where
- DError :: ErrorHasDoc e => Proxy e -> DError
- class (KnownSymbol tag, TypeHasDoc (CustomErrorRep tag), IsError (CustomError tag)) => CustomErrorHasDoc tag where
- data ErrorClass
- type MustHaveErrorArg errorTag expectedArgRep = (TypeErrorUnless (CustomErrorRep errorTag == expectedArgRep) ((('Text "Error argument type is " :<>: 'ShowType expectedArgRep) :<>: 'Text " but given error requires argument of type ") :<>: 'ShowType (CustomErrorRep errorTag)), CustomErrorRep errorTag ~ expectedArgRep)
- class IsCustomErrorArgRep a where
- verifyErrorTag :: MText -> a -> Either Text a
- customErrorRepDocDeps :: [SomeDocDefinitionItem]
- customErrorHaskellRep :: (KnownSymbol tag, CustomErrorHasDoc tag) => Proxy tag -> Markdown
- type CustomErrorRep tag = CustomErrorArgRep (ErrorArg tag)
- data UnitErrorArg
- data NoErrorArg
- data CustomError (tag :: Symbol) = CustomError {
- ceTag :: Label tag
- ceArg :: CustomErrorRep tag
- type family ErrorArg (tag :: Symbol) :: Type
- data SomeError = forall e.(IsError e, Eq e) => SomeError e
- data UnspecifiedError = UnspecifiedError
- class Typeable e => ErrorHasDoc (e :: Type) where
- class (Typeable e, ErrorHasDoc e) => IsError e where
- errorToVal :: e -> (forall t. ErrorScope t => Value t -> r) -> r
- errorFromVal :: KnownT t => Value t -> Either Text e
- type ErrorScope t = (Typeable t, ConstantScope t)
- isoErrorToVal :: (KnownError e, IsoValue e) => e -> (forall t. ErrorScope t => Value t -> r) -> r
- isoErrorFromVal :: (Typeable t, Typeable (ToT e), IsoValue e) => Value t -> Either Text e
- failUsing :: forall e s t. IsError e => e -> s :-> t
- failUnexpected :: MText -> s :-> t
- errorTagToMText :: Label tag -> MText
- errorTagToText :: forall tag. KnownSymbol tag => Text
- failCustom :: forall tag err s any. (MustHaveErrorArg tag (MText, err), CustomErrorHasDoc tag, KnownError err) => Label tag -> (err ': s) :-> any
- failCustomNoArg :: forall tag s any. (MustHaveErrorArg tag MText, CustomErrorHasDoc tag) => Label tag -> s :-> any
- failCustom_ :: forall tag s any. (MustHaveErrorArg tag (MText, ()), CustomErrorHasDoc tag) => Label tag -> s :-> any
- isInternalErrorClass :: ErrorClass -> Bool
- typeDocMdDescriptionReferToError :: forall e. IsError e => Markdown
- entrypointDoc :: QuasiQuoter
- errorDoc :: QuasiQuoter
- typeDoc :: QuasiQuoter
- newtype VoidResult r = VoidResult {
- unVoidResult :: r
- data Void_ (a :: Type) (b :: Type) = Void_ {
- voidParam :: a
- voidResProxy :: Lambda b b
- data View (a :: Type) (r :: Type) = View {
- viewParam :: a
- viewCallbackTo :: ContractRef r
- class UpdateN (n :: Peano) (s :: [Type]) (a :: Type) (b :: Type) mid tail where
- updateNImpl :: ('[a, b] :-> '[b]) -> (a ': s) :-> s
- type ConstraintUpdateNLorentz (n :: Peano) (s :: [Type]) (a :: Type) (b :: Type) (mid :: [Type]) (tail :: [Type]) = (UpdateNConstraint' T n (ToTs s) (ToT a) (ToT b) (ToTs mid) (ToTs tail), UpdateNConstraint' Type n s a b mid tail)
- class ReplaceN (n :: Peano) (s :: [Type]) (a :: Type) mid tail where
- replaceNImpl :: (a ': s) :-> s
- type ConstraintReplaceNLorentz (n :: Peano) (s :: [Type]) (a :: Type) (mid :: [Type]) (tail :: [Type]) = (ReplaceNConstraint' T n (ToTs s) (ToT a) (ToTs mid) (ToTs tail), ReplaceNConstraint' Type n s a mid tail)
- deleteMap :: forall k v s. (MapInstrs map, NiceComparable k, KnownValue v) => (k ': (map k v ': s)) :-> (map k v ': s)
- mapInsert :: (MapInstrs map, NiceComparable k) => (k ': (v ': (map k v ': s))) :-> (map k v ': s)
- mapInsertNew :: (MapInstrs map, NiceComparable k, NiceConstant e) => (forall s0. (k ': s0) :-> (e ': s0)) -> (k ': (v ': (map k v ': s))) :-> (map k v ': s)
- eq :: NiceComparable n => (n ': (n ': s)) :-> (Bool ': s)
- neq :: NiceComparable n => (n ': (n ': s)) :-> (Bool ': s)
- gt :: NiceComparable n => (n ': (n ': s)) :-> (Bool ': s)
- le :: NiceComparable n => (n ': (n ': s)) :-> (Bool ': s)
- ge :: NiceComparable n => (n ': (n ': s)) :-> (Bool ': s)
- lt :: NiceComparable n => (n ': (n ': s)) :-> (Bool ': s)
- ifEq0 :: IfCmp0Constraints a Eq' => (s :-> s') -> (s :-> s') -> (a ': s) :-> s'
- ifNeq0 :: IfCmp0Constraints a Neq => (s :-> s') -> (s :-> s') -> (a ': s) :-> s'
- ifLt0 :: IfCmp0Constraints a Lt => (s :-> s') -> (s :-> s') -> (a ': s) :-> s'
- ifGt0 :: IfCmp0Constraints a Gt => (s :-> s') -> (s :-> s') -> (a ': s) :-> s'
- ifLe0 :: IfCmp0Constraints a Le => (s :-> s') -> (s :-> s') -> (a ': s) :-> s'
- ifGe0 :: IfCmp0Constraints a Ge => (s :-> s') -> (s :-> s') -> (a ': s) :-> s'
- ifEq :: NiceComparable a => (s :-> s') -> (s :-> s') -> (a ': (a ': s)) :-> s'
- ifNeq :: NiceComparable a => (s :-> s') -> (s :-> s') -> (a ': (a ': s)) :-> s'
- ifLt :: NiceComparable a => (s :-> s') -> (s :-> s') -> (a ': (a ': s)) :-> s'
- ifGt :: NiceComparable a => (s :-> s') -> (s :-> s') -> (a ': (a ': s)) :-> s'
- ifLe :: NiceComparable a => (s :-> s') -> (s :-> s') -> (a ': (a ': s)) :-> s'
- ifGe :: NiceComparable a => (s :-> s') -> (s :-> s') -> (a ': (a ': s)) :-> s'
- fail_ :: a :-> c
- assert :: IsError err => err -> (Bool ': s) :-> s
- assertEq0 :: (IfCmp0Constraints a Eq', IsError err) => err -> (a ': s) :-> s
- assertNeq0 :: (IfCmp0Constraints a Neq, IsError err) => err -> (a ': s) :-> s
- assertLt0 :: (IfCmp0Constraints a Lt, IsError err) => err -> (a ': s) :-> s
- assertGt0 :: (IfCmp0Constraints a Gt, IsError err) => err -> (a ': s) :-> s
- assertLe0 :: (IfCmp0Constraints a Le, IsError err) => err -> (a ': s) :-> s
- assertGe0 :: (IfCmp0Constraints a Ge, IsError err) => err -> (a ': s) :-> s
- assertEq :: (NiceComparable a, IsError err) => err -> (a ': (a ': s)) :-> s
- assertNeq :: (NiceComparable a, IsError err) => err -> (a ': (a ': s)) :-> s
- assertLt :: (NiceComparable a, IsError err) => err -> (a ': (a ': s)) :-> s
- assertGt :: (NiceComparable a, IsError err) => err -> (a ': (a ': s)) :-> s
- assertLe :: (NiceComparable a, IsError err) => err -> (a ': (a ': s)) :-> s
- assertGe :: (NiceComparable a, IsError err) => err -> (a ': (a ': s)) :-> s
- assertNone :: IsError err => err -> (Maybe a ': s) :-> s
- assertSome :: IsError err => err -> (Maybe a ': s) :-> (a ': s)
- assertLeft :: IsError err => err -> (Either a b ': s) :-> (a ': s)
- assertRight :: IsError err => err -> (Either a b ': s) :-> (b ': s)
- assertUsing :: IsError a => a -> (Bool ': s) :-> s
- dropX :: forall (n :: Nat) a inp out s s'. (ConstraintDIPNLorentz (ToPeano n) inp out s s', s ~ (a ': s')) => inp :-> out
- cloneX :: forall (n :: Nat) a s. CloneX (ToPeano n) a s => (a ': s) :-> CloneXT (ToPeano n) a s
- duupX :: forall (n :: Nat) s s' a. ConstraintDUPNLorentz (ToPeano n) s s' a => s :-> (a ': s)
- framedN :: forall n nNat s i i' o o'. (nNat ~ ToPeano n, i' ~ Take nNat i, s ~ Drop nNat i, i ~ (i' ++ s), o ~ (o' ++ s), KnownList i', KnownList o') => (i' :-> o') -> i :-> o
- carN :: forall (n :: Nat) (pair :: Type) (s :: [Type]). ConstraintPairGetLorentz ((2 * n) + 1) pair => (pair ': s) :-> (PairGetHs (ToPeano ((2 * n) + 1)) pair ': s)
- cdrN :: forall (n :: Nat) (pair :: Type) (s :: [Type]). ConstraintPairGetLorentz (2 * n) pair => (pair ': s) :-> (PairGetHs (ToPeano (2 * n)) pair ': s)
- papair :: (a ': (b ': (c ': s))) :-> (((a, b), c) ': s)
- ppaiir :: (a ': (b ': (c ': s))) :-> ((a, (b, c)) ': s)
- unpair :: ((a, b) ': s) :-> (a ': (b ': s))
- cdar :: ((a1, (a2, b)) ': s) :-> (a2 ': s)
- cddr :: ((a1, (a2, b)) ': s) :-> (b ': s)
- caar :: (((a, b1), b2) ': s) :-> (a ': s)
- cadr :: (((a, b1), b2) ': s) :-> (b1 ': s)
- setCar :: ((a, b1) ': (b2 ': s)) :-> ((b2, b1) ': s)
- setCdr :: ((a, b1) ': (b2 ': s)) :-> ((a, b2) ': s)
- mapCar :: ((a ': s) :-> (a1 ': s)) -> ((a, b) ': s) :-> ((a1, b) ': s)
- mapCdr :: ((b ': ((a, b) ': s)) :-> (b1 ': ((a, b) ': s))) -> ((a, b) ': s) :-> ((a, b1) ': s)
- ifRight :: ((b ': s) :-> s') -> ((a ': s) :-> s') -> (Either a b ': s) :-> s'
- ifSome :: ((a ': s) :-> s') -> (s :-> s') -> (Maybe a ': s) :-> s'
- when_ :: (s :-> s) -> (Bool ': s) :-> s
- unless_ :: (s :-> s) -> (Bool ': s) :-> s
- whenSome :: ((a ': s) :-> s) -> (Maybe a ': s) :-> s
- whenNone :: (s :-> (a ': s)) -> (Maybe a ': s) :-> (a ': s)
- setInsert :: NiceComparable e => (e ': (Set e ': s)) :-> (Set e ': s)
- setInsertNew :: (NiceComparable e, NiceConstant err) => (forall s0. (e ': s0) :-> (err ': s0)) -> (e ': (Set e ': s)) :-> (Set e ': s)
- setDelete :: NiceComparable e => (e ': (Set e ': s)) :-> (Set e ': s)
- replaceN :: forall (n :: Nat) a (s :: [Type]) (s1 :: [Type]) (tail :: [Type]). (ConstraintReplaceNLorentz (ToPeano (n - 1)) s a s1 tail, ReplaceN (ToPeano n) s a s1 tail) => (a ': s) :-> s
- updateN :: forall (n :: Nat) a b (s :: [Type]) (mid :: [Type]) (tail :: [Type]). (ConstraintUpdateNLorentz (ToPeano (n - 1)) s a b mid tail, UpdateN (ToPeano n) s a b mid tail) => ('[a, b] :-> '[b]) -> (a ': s) :-> s
- buildViewTuple :: (WellTypedIsoValue r, TupleF a) => View a r -> Builder
- buildView :: WellTypedIsoValue r => (a -> Builder) -> View a r -> Builder
- mkView :: ToContractRef r contract => a -> contract -> View a r
- wrapView :: ((a, ContractRef r) ': s) :-> (View a r ': s)
- unwrapView :: (View a r ': s) :-> ((a, ContractRef r) ': s)
- view_ :: NiceParameter r => (forall s0. (a ': (storage ': s0)) :-> (r ': s0)) -> (View a r ': (storage ': s)) :-> ((List Operation, storage) ': s)
- voidResultTag :: MText
- mkVoid :: forall b a. a -> Void_ a b
- void_ :: forall a b s s' anything. (IsError (VoidResult b), NiceConstant b) => ((a ': s) :-> (b ': s')) -> (Void_ a b ': s) :-> anything
- wrapVoid :: ((a, Lambda b b) ': s) :-> (Void_ a b ': s)
- unwrapVoid :: (Void_ a b ': s) :-> ((a, Lambda b b) ': s)
- addressToEpAddress :: (Address ': s) :-> (EpAddress ': s)
- pushContractRef :: NiceParameter arg => (forall s0. (FutureContract arg ': s) :-> s0) -> ContractRef arg -> s :-> (ContractRef arg ': s)
- dupTop2 :: forall (a :: Type) (b :: Type) (s :: [Type]). (a ': (b ': s)) :-> (a ': (b ': (a ': (b ': s))))
- fromOption :: NiceConstant a => a -> (Maybe a ': s) :-> (a ': s)
- isSome :: (Maybe a ': s) :-> (Bool ': s)
- non :: (NiceConstant a, NiceComparable a) => a -> (a ': s) :-> (Maybe a ': s)
- non' :: NiceConstant a => Lambda a Bool -> (a ': s) :-> (Maybe a ': s)
- isEmpty :: SizeOpHs c => (c ': s) :-> (Bool ': s)
- type UParamLinearized p = GUParamLinearized (Rep p)
- type UParamLinearize p = (Generic p, GUParamLinearize (Rep p))
- class CaseUParam (entries :: [EntrypointKind])
- type UParamFallback inp out = ((MText, ByteString) ': inp) :-> out
- type EntrypointsImpl inp out entries = Rec (CaseClauseU inp out) entries
- data EntrypointLookupError
- class UnpackUParam (c :: Type -> Constraint) entries where
- unpackUParam :: UParam entries -> Either EntrypointLookupError (MText, ConstrainedSome c)
- data ConstrainedSome (c :: Type -> Constraint) where
- ConstrainedSome :: c a => a -> ConstrainedSome c
- type family RequireUniqueEntrypoints (entries :: [EntrypointKind]) :: Constraint where ...
- type family LookupEntrypoint (name :: Symbol) (entries :: [EntrypointKind]) :: Type where ...
- type UParam_ = UParam SomeInterface
- type SomeInterface = '['("SomeEntrypoints", Void)]
- newtype UParam (entries :: [EntrypointKind]) = UParamUnsafe (MText, ByteString)
- type (?:) (n :: Symbol) (a :: k) = '(n, a)
- type EntrypointKind = (Symbol, Type)
- mkUParam :: (NicePackedValue a, LookupEntrypoint name entries ~ a, RequireUniqueEntrypoints entries) => Label name -> a -> UParam entries
- unwrapUParam :: (UParam entries ': s) :-> ((MText, ByteString) ': s)
- uparamFallbackFail :: UParamFallback inp out
- caseUParam :: (CaseUParam entries, RequireUniqueEntrypoints entries) => Rec (CaseClauseU inp out) entries -> UParamFallback inp out -> (UParam entries ': inp) :-> out
- caseUParamT :: forall entries inp out clauses. (clauses ~ Rec (CaseClauseU inp out) entries, RecFromTuple clauses, CaseUParam entries) => IsoRecTuple clauses -> UParamFallback inp out -> (UParam entries ': inp) :-> out
- uparamFromAdt :: UParamLinearize up => up -> UParam (UParamLinearized up)
- pbsUParam :: forall ctorName. KnownSymbol ctorName => ParamBuildingStep
- data Condition arg argl argr outb out where
- Holds :: Condition (Bool ': s) s s o o
- IsSome :: Condition (Maybe a ': s) (a ': s) s o o
- IsNone :: Condition (Maybe a ': s) s (a ': s) o o
- IsLeft :: Condition (Either l r ': s) (l ': s) (r ': s) o o
- IsRight :: Condition (Either l r ': s) (r ': s) (l ': s) o o
- IsCons :: Condition ([a] ': s) (a ': ([a] ': s)) s o o
- IsNil :: Condition ([a] ': s) s (a ': ([a] ': s)) o o
- IsZero :: (UnaryArithOpHs Eq' a, UnaryArithResHs Eq' a ~ Bool) => Condition (a ': s) s s o o
- IsNotZero :: (UnaryArithOpHs Eq' a, UnaryArithResHs Eq' a ~ Bool) => Condition (a ': s) s s o o
- IsEq :: NiceComparable a => Condition (a ': (a ': s)) s s o o
- IsNeq :: NiceComparable a => Condition (a ': (a ': s)) s s o o
- IsLt :: NiceComparable a => Condition (a ': (a ': s)) s s o o
- IsGt :: NiceComparable a => Condition (a ': (a ': s)) s s o o
- IsLe :: NiceComparable a => Condition (a ': (a ': s)) s s o o
- IsGe :: NiceComparable a => Condition (a ': (a ': s)) s s o o
- NamedBinCondition :: Condition (a ': (a ': s)) s s o o -> Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- PreserveArgsBinCondition :: (forall st o. Condition (a ': (b ': st)) st st o o) -> Condition (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) s
- (>>) :: (a :-> b) -> (b :-> c) -> a :-> c
- ifThenElse :: Condition arg argl argr outb out -> (argl :-> outb) -> (argr :-> outb) -> arg :-> out
- (<.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- (>.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- (<=.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- (>=.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- (==.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- (/=.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o
- keepIfArgs :: (forall st o. Condition (a ': (b ': st)) st st o o) -> Condition (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) s
- type ErrorTagExclusions = HashSet MText
- type ErrorTagMap = Bimap Natural MText
- gatherErrorTags :: (inp :-> out) -> HashSet MText
- addNewErrorTags :: ErrorTagMap -> HashSet MText -> ErrorTagMap
- buildErrorTagMap :: HashSet MText -> ErrorTagMap
- excludeErrorTags :: HasCallStack => ErrorTagExclusions -> ErrorTagMap -> ErrorTagMap
- applyErrorTagMap :: HasCallStack => ErrorTagMap -> (inp :-> out) -> inp :-> out
- applyErrorTagMapWithExclusions :: HasCallStack => ErrorTagMap -> ErrorTagExclusions -> (inp :-> out) -> inp :-> out
- useNumericErrors :: HasCallStack => (inp :-> out) -> (inp :-> out, ErrorTagMap)
- errorFromValNumeric :: (KnownT t, IsError e) => ErrorTagMap -> Value t -> Either Text e
- errorToValNumeric :: IsError e => ErrorTagMap -> e -> (forall t. ErrorScope t => Value t -> r) -> r
- data NumericErrorWrapper (numTag :: Nat) (err :: Type)
- data NumericErrorDocHandler
- data NumericErrorDocHandlerError
- data DDescribeErrorTagMap = DDescribeErrorTagMap {
- detmSrcLoc :: Text
- applyErrorTagToErrorsDoc :: HasCallStack => ErrorTagMap -> (inp :-> out) -> inp :-> out
- applyErrorTagToErrorsDocWith :: HasCallStack => [NumericErrorDocHandler] -> ErrorTagMap -> (inp :-> out) -> inp :-> out
- customErrorDocHandler :: NumericErrorDocHandler
- voidResultDocHandler :: NumericErrorDocHandler
- baseErrorDocHandlers :: [NumericErrorDocHandler]
- data Empty
- absurd_ :: (Empty ': s) :-> s'
- data LIso a b = LIso {}
- invertIso :: LIso a b -> LIso b a
- involutedIso :: Lambda a a -> LIso a a
- checkedCoerceIso :: Coercible_ a b => LIso a b
- forcedCoerceIso :: MichelsonCoercible a b => LIso a b
- namedIso :: Label n -> LIso a (n :! a)
- nonIso :: (NiceConstant a, NiceComparable a) => a -> LIso (Maybe a) a
- nonDefIso :: (LDefault a, NiceConstant a) => LIso (Maybe a) a
- type family StorageContains store (content :: [NamedField]) :: Constraint where ...
- data param ::-> store
- data k ~> v
- type FieldNickname alias = FieldAlias (alias :: Symbol)
- data FieldAlias (alias :: k) (p :: FieldRefTag)
- data SelfRef (p :: FieldRefTag) = SelfRef
- data ((l :: k1) :-| (r :: k2)) (p :: FieldRefTag) = (FieldRef l) :-| (FieldRef r)
- class StoreHasEntrypoint store epName epParam epStore | store epName -> epParam epStore where
- storeEpOps :: StoreEntrypointOps store epName epParam epStore
- data StoreEntrypointOps store epName epParam epStore = StoreEntrypointOps {
- sopToEpLambda :: forall s. Label epName -> (store ': s) :-> (EntrypointLambda epParam epStore ': s)
- sopSetEpLambda :: forall s. Label epName -> (EntrypointLambda epParam epStore ': (store ': s)) :-> (store ': s)
- sopToEpStore :: forall s. Label epName -> (store ': s) :-> (epStore ': s)
- sopSetEpStore :: forall s. Label epName -> (epStore ': (store ': s)) :-> (store ': s)
- type EntrypointsField param store = BigMap MText (EntrypointLambda param store)
- type EntrypointLambda param store = Lambda (param, store) ([Operation], store)
- class StoreHasSubmap store mname key value | store mname -> key value where
- storeSubmapOps :: StoreSubmapOps store mname key value
- data StoreSubmapOps store mname key value = StoreSubmapOps {
- sopMem :: forall s. FieldRef mname -> (key ': (store ': s)) :-> (Bool ': s)
- sopGet :: forall s. KnownValue value => FieldRef mname -> (key ': (store ': s)) :-> (Maybe value ': s)
- sopUpdate :: forall s. FieldRef mname -> (key ': (Maybe value ': (store ': s))) :-> (store ': s)
- sopDelete :: forall s. FieldRef mname -> (key ': (store ': s)) :-> (store ': s)
- sopInsert :: forall s. FieldRef mname -> (key ': (value ': (store ': s))) :-> (store ': s)
- class StoreHasField store fname ftype | store fname -> ftype where
- storeFieldOps :: StoreFieldOps store fname ftype
- data StoreFieldOps store fname ftype = StoreFieldOps {
- sopToField :: forall s. FieldRef fname -> (store ': s) :-> (ftype ': s)
- sopSetField :: forall s. FieldRef fname -> (ftype ': (store ': s)) :-> (store ': s)
- class FieldRefHasFinalName fr where
- type FieldRefFinalName fr :: Symbol
- fieldRefFinalName :: FieldRef fr -> Label (FieldRefFinalName fr)
- type FieldSymRef name = FieldRef (name :: Symbol)
- data FieldName (n :: Symbol) (p :: FieldRefTag)
- type FieldRef name = FieldRefObject name 'FieldRefTag
- class KnownFieldRef (ty :: k) where
- type FieldRefObject ty = (fr :: FieldRefKind) | fr -> ty
- mkFieldRef :: FieldRefObject ty p
- data FieldRefTag
- type FieldRefKind = FieldRefTag -> Type
- fieldNameToLabel :: FieldSymRef n -> Label n
- fieldNameFromLabel :: Label n -> FieldSymRef n
- stToField :: StoreHasField store fname ftype => FieldRef fname -> (store ': s) :-> (ftype ': s)
- stGetField :: StoreHasField store fname ftype => FieldRef fname -> (store ': s) :-> (ftype ': (store ': s))
- stToFieldNamed :: (StoreHasField store fname ftype, FieldRefHasFinalName fname) => FieldRef fname -> (store ': s) :-> ((FieldRefFinalName fname :! ftype) ': s)
- stGetFieldNamed :: (StoreHasField store fname ftype, FieldRefHasFinalName fname) => FieldRef fname -> (store ': s) :-> ((FieldRefFinalName fname :! ftype) ': (store ': s))
- stSetField :: StoreHasField store fname ftype => FieldRef fname -> (ftype ': (store ': s)) :-> (store ': s)
- stMem :: StoreHasSubmap store mname key value => FieldRef mname -> (key ': (store ': s)) :-> (Bool ': s)
- stGet :: (StoreHasSubmap store mname key value, KnownValue value) => FieldRef mname -> (key ': (store ': s)) :-> (Maybe value ': s)
- stUpdate :: StoreHasSubmap store mname key value => FieldRef mname -> (key ': (Maybe value ': (store ': s))) :-> (store ': s)
- stDelete :: forall store mname key value s. StoreHasSubmap store mname key value => FieldRef mname -> (key ': (store ': s)) :-> (store ': s)
- stInsert :: StoreHasSubmap store mname key value => FieldRef mname -> (key ': (value ': (store ': s))) :-> (store ': s)
- stInsertNew :: StoreHasSubmap store mname key value => FieldRef mname -> (forall s0 any. (key ': s0) :-> any) -> (key ': (value ': (store ': s))) :-> (store ': s)
- stEntrypoint :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (epParam ': (store ': s)) :-> (([Operation], store) ': s)
- stToEpLambda :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (EntrypointLambda epParam epStore ': s)
- stGetEpLambda :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (EntrypointLambda epParam epStore ': (store ': s))
- stSetEpLambda :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (EntrypointLambda epParam epStore ': (store ': s)) :-> (store ': s)
- stToEpStore :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (epStore ': s)
- stGetEpStore :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (epStore ': (store ': s))
- stSetEpStore :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (epStore ': (store ': s)) :-> (store ': s)
- storeFieldOpsADT :: HasFieldOfType dt fname ftype => StoreFieldOps dt (fname :: Symbol) ftype
- storeEntrypointOpsADT :: (HasFieldOfType store epmName (EntrypointsField epParam epStore), HasFieldOfType store epsName epStore, KnownValue epParam, KnownValue epStore) => Label epmName -> Label epsName -> StoreEntrypointOps store epName epParam epStore
- storeEntrypointOpsFields :: (StoreHasField store epmName (EntrypointsField epParam epStore), StoreHasField store epsName epStore, KnownValue epParam, KnownValue epStore) => Label epmName -> Label epsName -> StoreEntrypointOps store epName epParam epStore
- storeEntrypointOpsSubmapField :: (StoreHasSubmap store epmName MText (EntrypointLambda epParam epStore), StoreHasField store epsName epStore, KnownValue epParam, KnownValue epStore) => Label epmName -> Label epsName -> StoreEntrypointOps store epName epParam epStore
- storeFieldOpsDeeper :: (HasFieldOfType storage fieldsPartName fields, StoreHasField fields fname ftype) => FieldRef fieldsPartName -> StoreFieldOps storage fname ftype
- storeSubmapOpsDeeper :: (HasFieldOfType storage bigMapPartName fields, StoreHasSubmap fields SelfRef key value) => FieldRef bigMapPartName -> StoreSubmapOps storage mname key value
- storeEntrypointOpsDeeper :: (HasFieldOfType store nameInStore substore, StoreHasEntrypoint substore epName epParam epStore) => FieldRef nameInStore -> StoreEntrypointOps store epName epParam epStore
- storeSubmapOpsReferTo :: FieldRef name -> StoreSubmapOps storage name key value -> StoreSubmapOps storage desiredName key value
- storeFieldOpsReferTo :: FieldRef name -> StoreFieldOps storage name field -> StoreFieldOps storage desiredName field
- storeEntrypointOpsReferTo :: Label epName -> StoreEntrypointOps store epName epParam epStore -> StoreEntrypointOps store desiredName epParam epStore
- mapStoreFieldOps :: LIso field1 field2 -> StoreFieldOps store name field1 -> StoreFieldOps store name field2
- mapStoreSubmapOpsKey :: Lambda key2 key1 -> StoreSubmapOps store name key1 value -> StoreSubmapOps store name key2 value
- mapStoreSubmapOpsValue :: KnownValue value1 => LIso value1 value2 -> StoreSubmapOps store name key value1 -> StoreSubmapOps store name key value2
- composeStoreFieldOps :: FieldRef nameInStore -> StoreFieldOps store nameInStore substore -> StoreFieldOps substore nameInSubstore field -> StoreFieldOps store nameInSubstore field
- composeStoreSubmapOps :: FieldRef nameInStore -> StoreFieldOps store nameInStore substore -> StoreSubmapOps substore mname key value -> StoreSubmapOps store mname key value
- sequenceStoreSubmapOps :: forall store substore value name subName key1 key2. (NiceConstant substore, KnownValue value) => FieldRef name -> LIso (Maybe substore) substore -> StoreSubmapOps store name key1 substore -> StoreSubmapOps substore subName key2 value -> StoreSubmapOps store subName (key1, key2) value
- composeStoreEntrypointOps :: FieldRef nameInStore -> StoreFieldOps store nameInStore substore -> StoreEntrypointOps substore epName epParam epStore -> StoreEntrypointOps store epName epParam epStore
- zoomStoreSubmapOps :: forall store submapName nameInSubmap key value subvalue. (NiceConstant value, NiceConstant subvalue) => FieldRef submapName -> LIso (Maybe value) value -> LIso (Maybe subvalue) subvalue -> StoreSubmapOps store submapName key value -> StoreFieldOps value nameInSubmap subvalue -> StoreSubmapOps store nameInSubmap key subvalue
- mkStoreEp :: Label epName -> EntrypointLambda epParam epStore -> EntrypointsField epParam epStore
- this :: SelfRef p
- stNested :: StNestedImpl f SelfRef => f
- stAlias :: forall alias. FieldRef (FieldAlias alias)
- stNickname :: Label name -> FieldRef (FieldAlias name)
Documentation
($) :: forall (r :: RuntimeRep) a (b :: TYPE r). (a -> b) -> a -> b infixr 0 #
Application operator. This operator is redundant, since ordinary
application (f x) means the same as (f . However, $ x)$ has
low, right-associative binding precedence, so it sometimes allows
parentheses to be omitted; for example:
f $ g $ h x = f (g (h x))
It is also useful in higher-order situations, such as map ($ 0) xszipWith ($) fs xs
Note that ( is levity-polymorphic in its result type, so that
$)foo where $ Truefoo :: Bool -> Int# is well-typed.
The Bounded class is used to name the upper and lower limits of a
type. Ord is not a superclass of Bounded since types that are not
totally ordered may also have upper and lower bounds.
The Bounded class may be derived for any enumeration type;
minBound is the first constructor listed in the data declaration
and maxBound is the last.
Bounded may also be derived for single-constructor datatypes whose
constituent types are in Bounded.
Instances
| Bounded Bool | Since: base-2.1 |
| Bounded Char | Since: base-2.1 |
| Bounded Int | Since: base-2.1 |
| Bounded Int8 | Since: base-2.1 |
| Bounded Int16 | Since: base-2.1 |
| Bounded Int32 | Since: base-2.1 |
| Bounded Int64 | Since: base-2.1 |
| Bounded Ordering | Since: base-2.1 |
| Bounded Word | Since: base-2.1 |
| Bounded Word8 | Since: base-2.1 |
| Bounded Word16 | Since: base-2.1 |
| Bounded Word32 | Since: base-2.1 |
| Bounded Word64 | Since: base-2.1 |
| Bounded VecCount | Since: base-4.10.0.0 |
| Bounded VecElem | Since: base-4.10.0.0 |
| Bounded () | Since: base-2.1 |
| Bounded All | Since: base-2.1 |
| Bounded Any | Since: base-2.1 |
| Bounded Associativity | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| Bounded SourceUnpackedness | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| Bounded SourceStrictness | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| Bounded DecidedStrictness | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| Bounded GeneralCategory | Since: base-2.1 |
Defined in GHC.Unicode | |
| Bounded UTF32_Invalid | |
Defined in Basement.String.Encoding.UTF32 | |
| Bounded Encoding | |
| Bounded Bit | |
| Bounded Extension | |
| Bounded Mod2 | |
| Bounded Undefined | |
| Bounded Bls12381Fr | |
Defined in Tezos.Crypto.BLS12381 | |
| Bounded Mutez | |
| Bounded EntriesOrder | |
Defined in Michelson.Untyped.Contract | |
| Bounded KeyHashTag | |
Defined in Tezos.Crypto | |
| Class () (Bounded a) | |
Defined in Data.Constraint | |
| a :=> (Bounded (Dict a)) | |
| () :=> (Bounded Bool) | |
| () :=> (Bounded Char) | |
| () :=> (Bounded Int) | |
| () :=> (Bounded Ordering) | |
| () :=> (Bounded Word) | |
| () :=> (Bounded ()) | |
Defined in Data.Constraint | |
| Bounded a => Bounded (Min a) | Since: base-4.9.0.0 |
| Bounded a => Bounded (Max a) | Since: base-4.9.0.0 |
| Bounded a => Bounded (First a) | Since: base-4.9.0.0 |
| Bounded a => Bounded (Last a) | Since: base-4.9.0.0 |
| Bounded m => Bounded (WrappedMonoid m) | Since: base-4.9.0.0 |
Defined in Data.Semigroup | |
| Bounded a => Bounded (Identity a) | Since: base-4.9.0.0 |
| Bounded a => Bounded (Dual a) | Since: base-2.1 |
| Bounded a => Bounded (Sum a) | Since: base-2.1 |
| Bounded a => Bounded (Product a) | Since: base-2.1 |
| Bounded a => Bounded (Down a) | Since: base-4.14.0.0 |
| a => Bounded (Dict a) | |
| KnownNat n => Bounded (Finite n) | Throws an error for |
| KnownNat m => Bounded (Mod m) | |
| Bounded a => Bounded (Add a) | |
| Bounded a => Bounded (Mul a) | |
| Bounded a => Bounded (WrappedNum a) | |
Defined in Data.Semiring | |
| KnownNat p => Bounded (Prime p) | |
Defined in Data.Field.Galois.Prime | |
| KnownNat p => Bounded (Binary p) | |
Defined in Data.Field.Galois.Binary | |
| Bounded a => Bounded (StringEncode a) | |
Defined in Morley.Micheline.Json | |
| (Bounded a) :=> (Bounded (Identity a)) | |
| (Bounded a) :=> (Bounded (Const a b)) | |
| (Bounded a, Bounded b) => Bounded (a, b) | Since: base-2.1 |
| Bounded (Proxy t) | Since: base-4.7.0.0 |
| (Bounded a, Bounded b) => Bounded (Pair a b) | |
| (Bounded a, Bounded b) :=> (Bounded (a, b)) | |
| (Bounded a, Bounded b, Bounded c) => Bounded (a, b, c) | Since: base-2.1 |
| Bounded a => Bounded (Const a b) | Since: base-4.9.0.0 |
| (Applicative f, Bounded a) => Bounded (Ap f a) | Since: base-4.12.0.0 |
| a ~ b => Bounded (a :~: b) | Since: base-4.7.0.0 |
| Bounded b => Bounded (Tagged s b) | |
| (Bounded a, Bounded b, Bounded c, Bounded d) => Bounded (a, b, c, d) | Since: base-2.1 |
| a ~~ b => Bounded (a :~~: b) | Since: base-4.10.0.0 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e) => Bounded (a, b, c, d, e) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f) => Bounded (a, b, c, d, e, f) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g) => Bounded (a, b, c, d, e, f, g) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h) => Bounded (a, b, c, d, e, f, g, h) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i) => Bounded (a, b, c, d, e, f, g, h, i) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j) => Bounded (a, b, c, d, e, f, g, h, i, j) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k) => Bounded (a, b, c, d, e, f, g, h, i, j, k) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l, Bounded m) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l, m) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l, Bounded m, Bounded n) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l, m, n) | Since: base-2.1 |
| (Bounded a, Bounded b, Bounded c, Bounded d, Bounded e, Bounded f, Bounded g, Bounded h, Bounded i, Bounded j, Bounded k, Bounded l, Bounded m, Bounded n, Bounded o) => Bounded (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o) | Since: base-2.1 |
The Eq class defines equality (==) and inequality (/=).
All the basic datatypes exported by the Prelude are instances of Eq,
and Eq may be derived for any datatype whose constituents are also
instances of Eq.
The Haskell Report defines no laws for Eq. However, == is customarily
expected to implement an equivalence relationship where two values comparing
equal are indistinguishable by "public" functions, with a "public" function
being one not allowing to see implementation details. For example, for a
type representing non-normalised natural numbers modulo 100, a "public"
function doesn't make the difference between 1 and 201. It is expected to
have the following properties:
Instances
fromInteger :: Num a => Integer -> a #
Conversion from an Integer.
An integer literal represents the application of the function
fromInteger to the appropriate value of type Integer,
so such literals have type (.Num a) => a
The Ord class is used for totally ordered datatypes.
Instances of Ord can be derived for any user-defined datatype whose
constituent types are in Ord. The declared order of the constructors in
the data declaration determines the ordering in derived Ord instances. The
Ordering datatype allows a single comparison to determine the precise
ordering of two objects.
The Haskell Report defines no laws for Ord. However, <= is customarily
expected to implement a non-strict partial order and have the following
properties:
- Transitivity
- if
x <= y && y <= z=True, thenx <= z=True - Reflexivity
x <= x=True- Antisymmetry
- if
x <= y && y <= x=True, thenx == y=True
Note that the following operator interactions are expected to hold:
x >= y=y <= xx < y=x <= y && x /= yx > y=y < xx < y=compare x y == LTx > y=compare x y == GTx == y=compare x y == EQmin x y == if x <= y then x else y=Truemax x y == if x >= y then x else y=True
Note that (7.) and (8.) do not require min and max to return either of
their arguments. The result is merely required to equal one of the
arguments in terms of (==).
Minimal complete definition: either compare or <=.
Using compare can be more efficient for complex types.
Instances
Conversion of values to readable Strings.
Derived instances of Show have the following properties, which
are compatible with derived instances of Read:
- The result of
showis a syntactically correct Haskell expression containing only constants, given the fixity declarations in force at the point where the type is declared. It contains only the constructor names defined in the data type, parentheses, and spaces. When labelled constructor fields are used, braces, commas, field names, and equal signs are also used. - If the constructor is defined to be an infix operator, then
showsPrecwill produce infix applications of the constructor. - the representation will be enclosed in parentheses if the
precedence of the top-level constructor in
xis less thand(associativity is ignored). Thus, ifdis0then the result is never surrounded in parentheses; ifdis11it is always surrounded in parentheses, unless it is an atomic expression. - If the constructor is defined using record syntax, then
showwill produce the record-syntax form, with the fields given in the same order as the original declaration.
For example, given the declarations
infixr 5 :^: data Tree a = Leaf a | Tree a :^: Tree a
the derived instance of Show is equivalent to
instance (Show a) => Show (Tree a) where
showsPrec d (Leaf m) = showParen (d > app_prec) $
showString "Leaf " . showsPrec (app_prec+1) m
where app_prec = 10
showsPrec d (u :^: v) = showParen (d > up_prec) $
showsPrec (up_prec+1) u .
showString " :^: " .
showsPrec (up_prec+1) v
where up_prec = 5Note that right-associativity of :^: is ignored. For example,
show(Leaf 1 :^: Leaf 2 :^: Leaf 3)"Leaf 1 :^: (Leaf 2 :^: Leaf 3)".
Instances
fromString :: IsString a => String -> a #
pure :: Applicative f => a -> f a #
Lift a value.
Representable types of kind *.
This class is derivable in GHC with the DeriveGeneric flag on.
A Generic instance must satisfy the following laws:
from.to≡idto.from≡id
Instances
The class of semigroups (types with an associative binary operation).
Instances should satisfy the following:
Since: base-4.9.0.0
Minimal complete definition
Methods
(<>) :: a -> a -> a infixr 6 #
An associative operation.
>>>[1,2,3] <> [4,5,6][1,2,3,4,5,6]
Reduce a non-empty list with <>
The default definition should be sufficient, but this can be overridden for efficiency.
>>>import Data.List.NonEmpty>>>sconcat $ "Hello" :| [" ", "Haskell", "!"]"Hello Haskell!"
stimes :: Integral b => b -> a -> a #
Repeat a value n times.
Given that this works on a Semigroup it is allowed to fail if
you request 0 or fewer repetitions, and the default definition
will do so.
By making this a member of the class, idempotent semigroups
and monoids can upgrade this to execute in \(\mathcal{O}(1)\) by
picking stimes = or stimesIdempotentstimes =
respectively.stimesIdempotentMonoid
>>>stimes 4 [1][1,1,1,1]
Instances
class Semigroup a => Monoid a where #
The class of monoids (types with an associative binary operation that has an identity). Instances should satisfy the following:
- Right identity
x<>mempty= x- Left identity
mempty<>x = x- Associativity
x(<>(y<>z) = (x<>y)<>zSemigrouplaw)- Concatenation
mconcat=foldr(<>)mempty
The method names refer to the monoid of lists under concatenation, but there are many other instances.
Some types can be viewed as a monoid in more than one way,
e.g. both addition and multiplication on numbers.
In such cases we often define newtypes and make those instances
of Monoid, e.g. Sum and Product.
NOTE: Semigroup is a superclass of Monoid since base-4.11.0.0.
Minimal complete definition
Methods
Identity of mappend
>>>"Hello world" <> mempty"Hello world"
An associative operation
NOTE: This method is redundant and has the default
implementation mappend = (<>)mappend is a synonym for
(<>), it is expected that the two functions are defined the same
way. In a future GHC release mappend will be removed from Monoid.
Fold a list using the monoid.
For most types, the default definition for mconcat will be
used, but the function is included in the class definition so
that an optimized version can be provided for specific types.
>>>mconcat ["Hello", " ", "Haskell", "!"]"Hello Haskell!"
Instances
| Monoid Ordering | Since: base-2.1 |
| Monoid () | Since: base-2.1 |
| Monoid ByteString | |
Defined in Data.ByteString.Internal Methods mempty :: ByteString # mappend :: ByteString -> ByteString -> ByteString # mconcat :: [ByteString] -> ByteString # | |
| Monoid ByteString | |
Defined in Data.ByteString.Lazy.Internal Methods mempty :: ByteString # mappend :: ByteString -> ByteString -> ByteString # mconcat :: [ByteString] -> ByteString # | |
| Monoid Builder | |
| Monoid Builder | |
| Monoid More | |
| Monoid All | Since: base-2.1 |
| Monoid Any | Since: base-2.1 |
| Monoid String | |
| Monoid ShortByteString | |
Defined in Data.ByteString.Short.Internal Methods mappend :: ShortByteString -> ShortByteString -> ShortByteString # mconcat :: [ShortByteString] -> ShortByteString # | |
| Monoid IntSet | |
| Monoid Bytes | |
| Monoid PrefsMod | |
| Monoid ParseError | |
Defined in Options.Applicative.Types Methods mempty :: ParseError # mappend :: ParseError -> ParseError -> ParseError # mconcat :: [ParseError] -> ParseError # | |
| Monoid Completer | |
| Monoid Doc | |
| Monoid ByteArray | |
| Monoid PromDPatInfos | |
| Monoid ULetDecEnv | |
| Monoid Doc | |
| Monoid MText | |
| Monoid OpSize | |
| Monoid AnnotationSet | |
| Monoid VarAnn | |
| Monoid ContractDoc | |
Defined in Michelson.Doc Methods mempty :: ContractDoc # mappend :: ContractDoc -> ContractDoc -> ContractDoc # mconcat :: [ContractDoc] -> ContractDoc # | |
| Monoid AnalyzerRes | |
| a :=> (Monoid (Dict a)) | |
| () :=> (Monoid [a]) | |
Defined in Data.Constraint | |
| () :=> (Monoid Ordering) | |
| () :=> (Monoid ()) | |
Defined in Data.Constraint | |
| Monoid [a] | Since: base-2.1 |
| Semigroup a => Monoid (Maybe a) | Lift a semigroup into Since 4.11.0: constraint on inner Since: base-2.1 |
| Monoid a => Monoid (IO a) | Since: base-4.9.0.0 |
| Monoid p => Monoid (Par1 p) | Since: base-4.12.0.0 |
| Monoid (IResult a) | |
| Monoid (Result a) | |
| Monoid (Parser a) | |
| (Ord a, Bounded a) => Monoid (Min a) | Since: base-4.9.0.0 |
| (Ord a, Bounded a) => Monoid (Max a) | Since: base-4.9.0.0 |
| Monoid m => Monoid (WrappedMonoid m) | Since: base-4.9.0.0 |
Defined in Data.Semigroup Methods mempty :: WrappedMonoid m # mappend :: WrappedMonoid m -> WrappedMonoid m -> WrappedMonoid m # mconcat :: [WrappedMonoid m] -> WrappedMonoid m # | |
| Semigroup a => Monoid (Option a) | Since: base-4.9.0.0 |
| Monoid a => Monoid (Identity a) | Since: base-4.9.0.0 |
| Monoid (First a) | Since: base-2.1 |
| Monoid (Last a) | Since: base-2.1 |
| Monoid a => Monoid (Dual a) | Since: base-2.1 |
| Monoid (Endo a) | Since: base-2.1 |
| Num a => Monoid (Sum a) | Since: base-2.1 |
| Num a => Monoid (Product a) | Since: base-2.1 |
| Monoid a => Monoid (Down a) | Since: base-4.11.0.0 |
| PrimType ty => Monoid (UArray ty) | |
| PrimType ty => Monoid (Block ty) | |
| Monoid (CountOf ty) | |
| Num a => Monoid (Colour a) | |
| Num a => Monoid (AlphaColour a) | |
Defined in Data.Colour.Internal Methods mempty :: AlphaColour a # mappend :: AlphaColour a -> AlphaColour a -> AlphaColour a # mconcat :: [AlphaColour a] -> AlphaColour a # | |
| a => Monoid (Dict a) | |
| Monoid (IntMap a) | |
| Monoid (Seq a) | |
| Ord a => Monoid (Set a) | |
| Monoid (DList a) | |
| Prim a => Monoid (Vector a) | |
| Storable a => Monoid (Vector a) | |
| (Hashable a, Eq a) => Monoid (HashSet a) | O(n+m) To obtain good performance, the smaller set must be presented as the first argument. Examples
|
| Monoid (Vector a) | |
| Monoid a => Monoid (May a) | |
| Monoid (InfoMod a) | |
| Monoid (DefaultProp a) | |
Defined in Options.Applicative.Builder.Internal Methods mempty :: DefaultProp a # mappend :: DefaultProp a -> DefaultProp a -> DefaultProp a # mconcat :: [DefaultProp a] -> DefaultProp a # | |
| Monoid (Doc a) | |
| Monoid (PrimArray a) | Since: primitive-0.6.4.0 |
| Monoid (SmallArray a) | |
Defined in Data.Primitive.SmallArray Methods mempty :: SmallArray a # mappend :: SmallArray a -> SmallArray a -> SmallArray a # mconcat :: [SmallArray a] -> SmallArray a # | |
| Monoid (Array a) | |
| Semiring a => Monoid (Add a) | |
| Semiring a => Monoid (Mul a) | |
| Monoid (IntSetOf a) | |
| Semigroup a => Monoid (Maybe a) | |
| (KnownSymbol s, Monoid t) => Monoid (ElField '(s, t)) | |
| Monoid (ComposeResult a) | |
| Monoid (PrintComment st) | |
| KnownNat p => Monoid (Prime p) | |
| Monoid (MergeSet a) | |
| KnownNat p => Monoid (Binary p) | |
| Class (Semigroup a) (Monoid a) | |
| (Monoid a) :=> (Monoid (Maybe a)) | |
| (Monoid a) :=> (Monoid (Const a b)) | |
| (Monoid a) :=> (Monoid (Identity a)) | |
| (Monoid a) :=> (Monoid (IO a)) | |
| (Monoid a) :=> (Applicative ((,) a)) | |
Defined in Data.Constraint | |
| (Monoid a) :=> (Applicative (Const a :: Type -> Type)) | |
Defined in Data.Constraint | |
| Monoid b => Monoid (a -> b) | Since: base-2.1 |
| Monoid (U1 p) | Since: base-4.12.0.0 |
| (Monoid a, Monoid b) => Monoid (a, b) | Since: base-2.1 |
| Monoid a => Monoid (ST s a) | Since: base-4.11.0.0 |
| (Eq k, Hashable k) => Monoid (HashMap k v) | If a key occurs in both maps, the mapping from the first will be the mapping in the result. Examples
|
| Ord k => Monoid (Map k v) | |
| Monoid (Parser i a) | |
| Monoid (Proxy s) | Since: base-4.7.0.0 |
| Monoid (ReifiedFold s a) | |
Defined in Control.Lens.Reified Methods mempty :: ReifiedFold s a # mappend :: ReifiedFold s a -> ReifiedFold s a -> ReifiedFold s a # mconcat :: [ReifiedFold s a] -> ReifiedFold s a # | |
| Monoid (f a) => Monoid (Indexing f a) |
|
| (Stream s, Ord e) => Monoid (ParseError s e) | |
Defined in Text.Megaparsec.Error Methods mempty :: ParseError s e # mappend :: ParseError s e -> ParseError s e -> ParseError s e # mconcat :: [ParseError s e] -> ParseError s e # | |
| Monoid a => Monoid (Err e a) | |
| Monoid (Mod f a) | |
| Monoid (IntMapOf k v) | |
| (Monoid a, Monoid b) => Monoid (Pair a b) | |
| Ord k => Monoid (BigMap k v) | |
| Monoid (Instr s s) | |
| (KnownNat n, GaloisField k) => Monoid (RootsOfUnity n k) | |
| IrreducibleMonic p k => Monoid (Extension p k) | |
| Applicative f => Monoid (Traversed a f) | |
| Monoid (s :-> s) Source # | |
| (Monoid a, Monoid b) :=> (Monoid (a, b)) | |
| Monoid (f p) => Monoid (Rec1 f p) | Since: base-4.12.0.0 |
| (Monoid a, Monoid b, Monoid c) => Monoid (a, b, c) | Since: base-2.1 |
| Monoid a => Monoid (Const a b) | Since: base-4.9.0.0 |
| (Applicative f, Monoid a) => Monoid (Ap f a) | Since: base-4.12.0.0 |
| Alternative f => Monoid (Alt f a) | Since: base-4.8.0.0 |
| (Semigroup a, Monoid a) => Monoid (Tagged s a) | |
| Monoid (ReifiedIndexedFold i s a) | |
Defined in Control.Lens.Reified Methods mempty :: ReifiedIndexedFold i s a # mappend :: ReifiedIndexedFold i s a -> ReifiedIndexedFold i s a -> ReifiedIndexedFold i s a # mconcat :: [ReifiedIndexedFold i s a] -> ReifiedIndexedFold i s a # | |
| (Monad m, Monoid r) => Monoid (Effect m r a) | |
| Reifies s (ReifiedMonoid a) => Monoid (ReflectedMonoid a s) | |
Defined in Data.Reflection Methods mempty :: ReflectedMonoid a s # mappend :: ReflectedMonoid a s -> ReflectedMonoid a s -> ReflectedMonoid a s # mconcat :: [ReflectedMonoid a s] -> ReflectedMonoid a s # | |
| Monoid (Rec f ('[] :: [u])) | |
| (Monoid (f r), Monoid (Rec f rs)) => Monoid (Rec f (r ': rs)) | |
| Monoid c => Monoid (K1 i c p) | Since: base-4.12.0.0 |
| (Monoid (f p), Monoid (g p)) => Monoid ((f :*: g) p) | Since: base-4.12.0.0 |
| (Monoid a, Monoid b, Monoid c, Monoid d) => Monoid (a, b, c, d) | Since: base-2.1 |
| Monoid (f p) => Monoid (M1 i c f p) | Since: base-4.12.0.0 |
| Monoid (f (g p)) => Monoid ((f :.: g) p) | Since: base-4.12.0.0 |
| (Monoid a, Monoid b, Monoid c, Monoid d, Monoid e) => Monoid (a, b, c, d, e) | Since: base-2.1 |
| Monoid (f (g a)) => Monoid (Compose f g a) | |
| Curve f c e q r => Monoid (Point f c e q r) | |
Instances
| Bounded Bool | Since: base-2.1 |
| Enum Bool | Since: base-2.1 |
| Eq Bool | |
| Ord Bool | |
| Read Bool | Since: base-2.1 |
| Show Bool | Since: base-2.1 |
| Generic Bool | Since: base-4.6.0.0 |
| Hashable Bool | |
Defined in Data.Hashable.Class | |
| ToJSON Bool | |
Defined in Data.Aeson.Types.ToJSON | |
| ToJSONKey Bool | |
Defined in Data.Aeson.Types.ToJSON | |
| Storable Bool | Since: base-2.1 |
Defined in Foreign.Storable | |
| NFData Bool | |
Defined in Control.DeepSeq | |
| Buildable Bool | |
Defined in Formatting.Buildable | |
| Unbox Bool | |
Defined in Data.Vector.Unboxed.Base | |
| Semiring Bool | |
| PShow Bool | |
| SShow Bool | |
Defined in Data.Singletons.Prelude.Show Methods sShowsPrec :: forall (t1 :: Nat) (t2 :: Bool) (t3 :: Symbol). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply ShowsPrecSym0 t1) t2) t3) # sShow_ :: forall (t :: Bool). Sing t -> Sing (Apply Show_Sym0 t) # sShowList :: forall (t1 :: [Bool]) (t2 :: Symbol). Sing t1 -> Sing t2 -> Sing (Apply (Apply ShowListSym0 t1) t2) # | |
| PEnum Bool | |
Defined in Data.Singletons.Prelude.Enum | |
| SEnum Bool | |
Defined in Data.Singletons.Prelude.Enum Methods sSucc :: forall (t :: Bool). Sing t -> Sing (Apply SuccSym0 t) # sPred :: forall (t :: Bool). Sing t -> Sing (Apply PredSym0 t) # sToEnum :: forall (t :: Nat). Sing t -> Sing (Apply ToEnumSym0 t) # sFromEnum :: forall (t :: Bool). Sing t -> Sing (Apply FromEnumSym0 t) # sEnumFromTo :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply EnumFromToSym0 t1) t2) # sEnumFromThenTo :: forall (t1 :: Bool) (t2 :: Bool) (t3 :: Bool). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply EnumFromThenToSym0 t1) t2) t3) # | |
| PBounded Bool | |
Defined in Data.Singletons.Prelude.Enum | |
| SBounded Bool | |
Defined in Data.Singletons.Prelude.Enum | |
| POrd Bool | |
| SOrd Bool | |
Defined in Data.Singletons.Prelude.Ord Methods sCompare :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply CompareSym0 t1) t2) # (%<) :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<@#@$) t1) t2) # (%<=) :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<=@#@$) t1) t2) # (%>) :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>@#@$) t1) t2) # (%>=) :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>=@#@$) t1) t2) # sMax :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply MaxSym0 t1) t2) # sMin :: forall (t1 :: Bool) (t2 :: Bool). Sing t1 -> Sing t2 -> Sing (Apply (Apply MinSym0 t1) t2) # | |
| SEq Bool | |
| PEq Bool | |
| Pretty Bool | |
Defined in Text.PrettyPrint.Leijen.Text | |
| SingKind Bool | Since: base-4.9.0.0 |
Defined in GHC.Generics Associated Types type DemoteRep Bool | |
| TypeHasDoc Bool | |
Defined in Michelson.Typed.Haskell.Doc Associated Types type TypeDocFieldDescriptions Bool :: FieldDescriptions # Methods typeDocName :: Proxy Bool -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy Bool -> WithinParens -> Markdown # typeDocDependencies :: Proxy Bool -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep Bool # typeDocMichelsonRep :: TypeDocMichelsonRep Bool # | |
| IsoValue Bool | |
| HasAnnotation Bool Source # | |
Defined in Lorentz.Annotation Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT Bool) Source # | |
| Lift Bool | |
| TestCoercion SBool | |
Defined in Data.Singletons.Prelude.Instances | |
| TestEquality SBool | |
Defined in Data.Singletons.Prelude.Instances | |
| Vector Vector Bool | |
Defined in Data.Vector.Unboxed.Base Methods basicUnsafeFreeze :: PrimMonad m => Mutable Vector (PrimState m) Bool -> m (Vector Bool) # basicUnsafeThaw :: PrimMonad m => Vector Bool -> m (Mutable Vector (PrimState m) Bool) # basicLength :: Vector Bool -> Int # basicUnsafeSlice :: Int -> Int -> Vector Bool -> Vector Bool # basicUnsafeIndexM :: Monad m => Vector Bool -> Int -> m Bool # basicUnsafeCopy :: PrimMonad m => Mutable Vector (PrimState m) Bool -> Vector Bool -> m () # | |
| MVector MVector Bool | |
Defined in Data.Vector.Unboxed.Base Methods basicLength :: MVector s Bool -> Int # basicUnsafeSlice :: Int -> Int -> MVector s Bool -> MVector s Bool # basicOverlaps :: MVector s Bool -> MVector s Bool -> Bool # basicUnsafeNew :: PrimMonad m => Int -> m (MVector (PrimState m) Bool) # basicInitialize :: PrimMonad m => MVector (PrimState m) Bool -> m () # basicUnsafeReplicate :: PrimMonad m => Int -> Bool -> m (MVector (PrimState m) Bool) # basicUnsafeRead :: PrimMonad m => MVector (PrimState m) Bool -> Int -> m Bool # basicUnsafeWrite :: PrimMonad m => MVector (PrimState m) Bool -> Int -> Bool -> m () # basicClear :: PrimMonad m => MVector (PrimState m) Bool -> m () # basicSet :: PrimMonad m => MVector (PrimState m) Bool -> Bool -> m () # basicUnsafeCopy :: PrimMonad m => MVector (PrimState m) Bool -> MVector (PrimState m) Bool -> m () # basicUnsafeMove :: PrimMonad m => MVector (PrimState m) Bool -> MVector (PrimState m) Bool -> m () # basicUnsafeGrow :: PrimMonad m => MVector (PrimState m) Bool -> Int -> m (MVector (PrimState m) Bool) # | |
| SingI 'False | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| SingI 'True | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| UnaryArithOpHs Not Bool Source # | |
Defined in Lorentz.Arith Associated Types type UnaryArithResHs Not Bool Source # | |
| ArithOpHs And Bool Bool Source # | |
Defined in Lorentz.Arith Associated Types type ArithResHs And Bool Bool Source # | |
| ArithOpHs Or Bool Bool Source # | |
Defined in Lorentz.Arith Associated Types type ArithResHs Or Bool Bool Source # | |
| ArithOpHs Xor Bool Bool Source # | |
Defined in Lorentz.Arith Associated Types type ArithResHs Xor Bool Bool Source # | |
| () :=> (Bounded Bool) | |
| () :=> (Enum Bool) | |
| () :=> (Eq Bool) | |
| () :=> (Ord Bool) | |
| () :=> (Read Bool) | |
| () :=> (Show Bool) | |
| () :=> (Bits Bool) | |
| SuppressUnusedWarnings NotSym0 | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings FromEnum_6989586621680203592Sym0 | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings All_Sym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings AllSym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings Any_Sym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings AnySym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (||@#@$) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (&&@#@$) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings Compare_6989586621679848336Sym0 | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ShowParenSym0 | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings OrSym0 | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings AndSym0 | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ToEnum_6989586621680203579Sym0 | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ShowsPrec_6989586621680653401Sym0 | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (<=?@#@$) | |
Defined in Data.Singletons.TypeLits.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings GetAllSym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings GetAnySym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SingI NotSym0 | |
Defined in Data.Singletons.Prelude.Bool | |
| SingI (||@#@$) | |
Defined in Data.Singletons.Prelude.Bool | |
| SingI (&&@#@$) | |
Defined in Data.Singletons.Prelude.Bool | |
| SingI (<=?@#@$) | |
Defined in Data.Singletons.TypeLits.Internal | |
| SingI All_Sym0 | |
| SingI AllSym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| SingI Any_Sym0 | |
| SingI AnySym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| SingI ShowParenSym0 | |
Defined in Data.Singletons.Prelude.Show Methods sing :: Sing ShowParenSym0 # | |
| SingI OrSym0 | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI AndSym0 | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI GetAllSym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods sing :: Sing GetAllSym0 # | |
| SingI GetAnySym0 | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods sing :: Sing GetAnySym0 # | |
| SuppressUnusedWarnings ((||@#@$$) a6989586621679815663 :: TyFun Bool Bool -> Type) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((&&@#@$$) a6989586621679815361 :: TyFun Bool Bool -> Type) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621679848336Sym1 a6989586621679848341 :: TyFun Bool Ordering -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GuardSym0 :: TyFun Bool (f ()) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ShowsPrec_6989586621680653401Sym1 a6989586621680653411 :: TyFun Bool (Symbol ~> Symbol) -> Type) | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (UnlessSym0 :: TyFun Bool (f () ~> f ()) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (WhenSym0 :: TyFun Bool (f () ~> f ()) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListnullSym0 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListisPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NullSym0 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsSuffixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsInfixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680822604Sym0 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((<=?@#@$$) a6989586621679910080 :: TyFun Nat Bool -> Type) | |
Defined in Data.Singletons.TypeLits.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListelemSym0 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NotElemSym0 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ElemSym0 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (OrSym0 :: TyFun (t Bool) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813469Scrutinee_6989586621680813411Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813445Scrutinee_6989586621680813409Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680823228Sym0 :: TyFun a (Product a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680823053Sym0 :: TyFun a (Sum a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822878Sym0 :: TyFun a (Dual a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822846Sym0 :: TyFun a (Proxy a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822470Sym0 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AndSym0 :: TyFun (t Bool) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (DefaultEqSym0 :: TyFun k (k ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Eq Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((==@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Eq Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((/=@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Eq Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Bool_Sym0 :: TyFun a (a ~> (Bool ~> a)) -> Type) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836822Sym0 :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836806Sym0 :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836790Sym0 :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836774Sym0 :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836863Scrutinee_6989586621679836691Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836847Scrutinee_6989586621679836689Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836766Scrutinee_6989586621679836679Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836762Scrutinee_6989586621679836677Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((>@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((>=@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((<@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((<=@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680786609Scrutinee_6989586621680786014Sym0 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621681011897Sym0 :: TyFun a (Identity a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Identity Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621681012013Sym0 :: TyFun (Identity a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Identity Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680823010Sym0 :: TyFun (Dual a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680823185Sym0 :: TyFun (Sum a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680823360Sym0 :: TyFun (Product a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListtakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListspanSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListpartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListnubBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListfilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListdropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (UnionBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (SpanSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (SelectSym0 :: TyFun (a ~> Bool) (a ~> (([a], [a]) ~> ([a], [a]))) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (PartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NubBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378869ZsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378869YsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378869X_6989586621680378870Sym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] ([k], [k]) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378834ZsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378834YsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378834X_6989586621680378835Sym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] ([k], [k]) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IntersectBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GroupBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [[a]]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindIndicesSym0 :: TyFun (a ~> Bool) ([a] ~> [Nat]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindIndexSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_bySym0 :: TyFun (a ~> (a ~> Bool)) (a ~> ([a] ~> Bool)) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (DropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (DropWhileEndSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (DeleteFirstsBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (DeleteBySym0 :: TyFun (a ~> (a ~> Bool)) (a ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (BreakSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AnySym0 :: TyFun (a ~> Bool) ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AllSym0 :: TyFun (a ~> Bool) ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (UntilSym0 :: TyFun (a ~> Bool) ((a ~> a) ~> (a ~> a)) -> Type) | |
Defined in Data.Singletons.Prelude.Base Methods suppressUnusedWarnings :: () # | |
| SingI x => SingI ((||@#@$$) x :: TyFun Bool Bool -> Type) | |
Defined in Data.Singletons.Prelude.Bool | |
| SingI x => SingI ((&&@#@$$) x :: TyFun Bool Bool -> Type) | |
Defined in Data.Singletons.Prelude.Bool | |
| SingI x => SingI ((<=?@#@$$) x :: TyFun Nat Bool -> Type) | |
Defined in Data.Singletons.TypeLits.Internal Methods sing :: Sing ((<=?@#@$$) x) # | |
| SAlternative f => SingI (GuardSym0 :: TyFun Bool (f ()) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| SApplicative f => SingI (UnlessSym0 :: TyFun Bool (f () ~> f ()) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods sing :: Sing UnlessSym0 # | |
| SApplicative f => SingI (WhenSym0 :: TyFun Bool (f () ~> f ()) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| SingI (ListnullSym0 :: TyFun [a] Bool -> Type) | |
| SEq a => SingI (ListisPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
| SingI (NullSym0 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SEq a => SingI (IsSuffixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing IsSuffixOfSym0 # | |
| SEq a => SingI (IsPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing IsPrefixOfSym0 # | |
| SEq a => SingI (IsInfixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing IsInfixOfSym0 # | |
| SingI (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing IsNothingSym0 # | |
| SingI (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing IsJustSym0 # | |
| SEq a => SingI (ListelemSym0 :: TyFun a ([a] ~> Bool) -> Type) | |
| SEq a => SingI (NotElemSym0 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SEq a => SingI (ElemSym0 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SFoldable t => SingI (OrSym0 :: TyFun (t Bool) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SFoldable t => SingI (AndSym0 :: TyFun (t Bool) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SEq a => SingI ((==@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Eq | |
| SEq a => SingI ((/=@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Eq | |
| SingI (Bool_Sym0 :: TyFun a (a ~> (Bool ~> a)) -> Type) | |
Defined in Data.Singletons.Prelude.Bool | |
| SOrd a => SingI ((>@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| SOrd a => SingI ((>=@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| SOrd a => SingI ((<@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| SOrd a => SingI ((<=@#@$) :: TyFun a (a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| SingI (ListtakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
| SingI (ListspanSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
| SingI (ListpartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
| SingI (ListnubBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [a]) -> Type) | |
| SingI (ListfilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
| SingI (ListdropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
| SingI (UnionBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing UnionBySym0 # | |
| SingI (TakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing TakeWhileSym0 # | |
| SingI (SpanSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (SelectSym0 :: TyFun (a ~> Bool) (a ~> (([a], [a]) ~> ([a], [a]))) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (PartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing PartitionSym0 # | |
| SingI (NubBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (IntersectBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing IntersectBySym0 # | |
| SingI (GroupBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [[a]]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing GroupBySym0 # | |
| SingI (FindSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (FindIndicesSym0 :: TyFun (a ~> Bool) ([a] ~> [Nat]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing FindIndicesSym0 # | |
| SingI (FindIndexSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing FindIndexSym0 # | |
| SingI (FilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing FilterSym0 # | |
| SingI (Elem_bySym0 :: TyFun (a ~> (a ~> Bool)) (a ~> ([a] ~> Bool)) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (DropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing DropWhileSym0 # | |
| SingI (DropWhileEndSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods | |
| SingI (DeleteFirstsBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods | |
| SingI (DeleteBySym0 :: TyFun (a ~> (a ~> Bool)) (a ~> ([a] ~> [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing DeleteBySym0 # | |
| SingI (BreakSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (AnySym0 :: TyFun (a ~> Bool) ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (AllSym0 :: TyFun (a ~> Bool) ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (UntilSym0 :: TyFun (a ~> Bool) ((a ~> a) ~> (a ~> a)) -> Type) | |
Defined in Data.Singletons.Prelude.Base | |
| SuppressUnusedWarnings (ListisPrefixOfSym1 a6989586621680748854 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListelemSym1 a6989586621680748782 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal.Disambiguation Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NotElemSym1 a6989586621680379352 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsSuffixOfSym1 a6989586621680379375 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsPrefixOfSym1 a6989586621680379382 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsInfixOfSym1 a6989586621680379368 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ElemSym1 a6989586621680379360 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AnySym1 a6989586621680379577 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AllSym1 a6989586621680379585 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822470Sym1 a6989586621680822479 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680822765Sym0 :: TyFun (Either a1 a2) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsRightSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378657Scrutinee_6989586621680375102Sym0 :: TyFun k1 (TyFun k Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_bySym1 a6989586621680378588 :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NotElemSym0 :: TyFun a (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813469Scrutinee_6989586621680813411Sym1 x6989586621680813464 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813445Scrutinee_6989586621680813409Sym1 x6989586621680813440 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822360Sym0 :: TyFun a (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ElemSym0 :: TyFun a (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (DefaultEqSym1 a6989586621679818750 :: TyFun k Bool -> Type) | |
Defined in Data.Singletons.Prelude.Eq Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((==@#@$$) a6989586621679818744 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Eq Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((/=@#@$$) a6989586621679818747 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Eq Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Bool_Sym1 a6989586621679814557 :: TyFun a (Bool ~> a) -> Type) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836822Sym1 a6989586621679836827 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836806Sym1 a6989586621679836811 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836790Sym1 a6989586621679836795 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621679836774Sym1 a6989586621679836779 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836863Scrutinee_6989586621679836691Sym1 x6989586621679836861 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836847Scrutinee_6989586621679836689Sym1 x6989586621679836845 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836766Scrutinee_6989586621679836679Sym1 x6989586621679836760 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679836762Scrutinee_6989586621679836677Sym1 x6989586621679836760 :: TyFun k1 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((>@#@$$) a6989586621679836734 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((>=@#@$$) a6989586621679836739 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((<@#@$$) a6989586621679836724 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings ((<=@#@$$) a6989586621679836729 :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621681202942Sym0 :: TyFun (Arg a b) (Arg a b ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621681011897Sym1 a6989586621681011902 :: TyFun (Identity a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Identity Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822878Sym1 a6989586621680822887 :: TyFun (Dual a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680823053Sym1 a6989586621680823062 :: TyFun (Sum a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680823228Sym1 a6989586621680823237 :: TyFun (Product a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822846Sym1 a6989586621680822851 :: TyFun (Proxy a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680822839Sym0 :: TyFun (Proxy a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786553Sym0 :: TyFun (Proxy s) (Proxy s ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MfilterSym0 :: TyFun (a ~> Bool) (m a ~> m a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FilterMSym0 :: TyFun (a ~> m Bool) ([a] ~> m [a]) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378736ZsSym0 :: TyFun (k1 ~> (a ~> Bool)) (TyFun k1 (TyFun [a] [a] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378736YsSym0 :: TyFun (k1 ~> (a ~> Bool)) (TyFun k1 (TyFun [a] [a] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378736X_6989586621680378737Sym0 :: TyFun (k1 ~> (a ~> Bool)) (TyFun k1 (TyFun [a] ([a], [a]) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378602NubBy'Sym0 :: TyFun (k1 ~> (k1 ~> Bool)) (TyFun k (TyFun [k1] ([k1] ~> [k1]) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680378897Sym0 :: TyFun (a ~> Bool) (TyFun k (TyFun a (TyFun [a] [a] -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680821893Sym0 :: TyFun (a ~> Bool) (TyFun k (TyFun a (First a) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindSym0 :: TyFun (a ~> Bool) (t a ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AnySym0 :: TyFun (a ~> Bool) (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AllSym0 :: TyFun (a ~> Bool) (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679989623GoSym0 :: TyFun (k1 ~> Bool) (TyFun (k1 ~> k1) (TyFun k2 (TyFun k1 k1 -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Base Methods suppressUnusedWarnings :: () # | |
| (SEq a, SingI d) => SingI (ListisPrefixOfSym1 d :: TyFun [a] Bool -> Type) | |
| (SEq a, SingI d) => SingI (ListelemSym1 d :: TyFun [a] Bool -> Type) | |
| (SEq a, SingI d) => SingI (NotElemSym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| (SEq a, SingI d) => SingI (IsSuffixOfSym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing (IsSuffixOfSym1 d) # | |
| (SEq a, SingI d) => SingI (IsPrefixOfSym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing (IsPrefixOfSym1 d) # | |
| (SEq a, SingI d) => SingI (IsInfixOfSym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing (IsInfixOfSym1 d) # | |
| (SEq a, SingI d) => SingI (ElemSym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI d => SingI (AnySym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI d => SingI (AllSym1 d :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (IsRightSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing IsRightSym0 # | |
| SingI (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing IsLeftSym0 # | |
| SingI d => SingI (Elem_bySym1 d :: TyFun a ([a] ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| (SFoldable t, SEq a) => SingI (NotElemSym0 :: TyFun a (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods sing :: Sing NotElemSym0 # | |
| (SFoldable t, SEq a) => SingI (ElemSym0 :: TyFun a (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| (SEq a, SingI x) => SingI ((==@#@$$) x :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Eq | |
| (SEq a, SingI x) => SingI ((/=@#@$$) x :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Eq | |
| SingI d => SingI (Bool_Sym1 d :: TyFun a (Bool ~> a) -> Type) | |
Defined in Data.Singletons.Prelude.Bool | |
| (SOrd a, SingI d) => SingI ((>@#@$$) d :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| (SOrd a, SingI d) => SingI ((>=@#@$$) d :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| (SOrd a, SingI d) => SingI ((<@#@$$) d :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| (SOrd a, SingI d) => SingI ((<=@#@$$) d :: TyFun a Bool -> Type) | |
Defined in Data.Singletons.Prelude.Ord | |
| SMonadPlus m => SingI (MfilterSym0 :: TyFun (a ~> Bool) (m a ~> m a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods sing :: Sing MfilterSym0 # | |
| SApplicative m => SingI (FilterMSym0 :: TyFun (a ~> m Bool) ([a] ~> m [a]) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods sing :: Sing FilterMSym0 # | |
| SFoldable t => SingI (FindSym0 :: TyFun (a ~> Bool) (t a ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SFoldable t => SingI (AnySym0 :: TyFun (a ~> Bool) (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SFoldable t => SingI (AllSym0 :: TyFun (a ~> Bool) (t a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SuppressUnusedWarnings (Bool_Sym2 a6989586621679814557 a6989586621679814558 :: TyFun Bool a -> Type) | |
Defined in Data.Singletons.Prelude.Bool Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_bySym2 a6989586621680378588 a6989586621680378589 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621681500761Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378901Scrutinee_6989586621680375080Sym0 :: TyFun k1 (TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378813Scrutinee_6989586621680375086Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378800Scrutinee_6989586621680375088Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378723Scrutinee_6989586621680375098Sym0 :: TyFun k1 (TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378657Scrutinee_6989586621680375102Sym1 n6989586621680378655 :: TyFun k Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378638Scrutinee_6989586621680375104Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378625Scrutinee_6989586621680375106Sym0 :: TyFun k1 (TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378609Scrutinee_6989586621680375108Sym0 :: TyFun k1 (TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680822324Sym0 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NullSym0 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (NotElemSym1 a6989586621680821907 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680822332Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822360Sym1 a6989586621680822369 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ElemSym1 a6989586621680822160 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AnySym1 a6989586621680821965 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (AllSym1 a6989586621680821956 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621681202942Sym1 a6989586621681202947 :: TyFun (Arg a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786553Sym1 a6989586621680786558 :: TyFun (Proxy s) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621681500758Sym0 :: TyFun (k2 ~> f Bool) (TyFun k3 (TyFun k2 (f [k2] ~> f [k2]) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621681500596Sym0 :: TyFun (k1 ~> Bool) (TyFun k (TyFun k1 (m k1) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| (SingI d1, SingI d2) => SingI (Bool_Sym2 d1 d2 :: TyFun Bool a -> Type) | |
Defined in Data.Singletons.Prelude.Bool | |
| (SingI d1, SingI d2) => SingI (Elem_bySym2 d1 d2 :: TyFun [a] Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SFoldable t => SingI (NullSym0 :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| (SFoldable t, SEq a, SingI d) => SingI (NotElemSym1 d :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods sing :: Sing (NotElemSym1 d) # | |
| (SFoldable t, SEq a, SingI d) => SingI (ElemSym1 d :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| (SFoldable t, SingI d) => SingI (AnySym1 d :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| (SFoldable t, SingI d) => SingI (AllSym1 d :: TyFun (t a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SuppressUnusedWarnings (Let6989586621680378901Scrutinee_6989586621680375080Sym1 x6989586621680378899 :: TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621681500761Sym1 x6989586621681500760 :: TyFun k2 (TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378813Scrutinee_6989586621680375086Sym1 n6989586621680378810 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378800Scrutinee_6989586621680375088Sym1 n6989586621680378797 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378723Scrutinee_6989586621680375098Sym1 key6989586621680378719 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378638Scrutinee_6989586621680375104Sym1 x6989586621680378635 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378625Scrutinee_6989586621680375106Sym1 x6989586621680378622 :: TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378609Scrutinee_6989586621680375108Sym1 y6989586621680378606 :: TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680822332Sym1 a_69895866216808223266989586621680822331 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180309Scrutinee_6989586621680180117Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378625Scrutinee_6989586621680375106Sym2 x6989586621680378622 xs6989586621680378623 :: TyFun [k1] (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378609Scrutinee_6989586621680375108Sym2 y6989586621680378606 ys6989586621680378607 :: TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621681500761Sym2 x6989586621681500760 p6989586621681500756 :: TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378813Scrutinee_6989586621680375086Sym2 n6989586621680378810 x6989586621680378811 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378800Scrutinee_6989586621680375088Sym2 n6989586621680378797 x6989586621680378798 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378723Scrutinee_6989586621680375098Sym2 key6989586621680378719 x6989586621680378720 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378638Scrutinee_6989586621680375104Sym2 x6989586621680378635 xs6989586621680378636 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680822332Sym2 a_69895866216808223266989586621680822331 arg_69895866216808217186989586621680822334 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180309Scrutinee_6989586621680180117Sym1 x6989586621680180308 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180255Scrutinee_6989586621680180131Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180218Scrutinee_6989586621680180141Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378901Scrutinee_6989586621680375080Sym2 x6989586621680378899 xs6989586621680378900 :: TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680378950Sym0 :: TyFun (b ~> (a ~> Bool)) (TyFun k1 (TyFun k2 (TyFun a (TyFun [a] (TyFun b (m b) -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621681500761Sym3 x6989586621681500760 p6989586621681500756 a_69895866216815007496989586621681500757 :: TyFun Bool ([k1] ~> [k1]) -> Type) | |
Defined in Data.Singletons.Prelude.Monad Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378901Scrutinee_6989586621680375080Sym3 x6989586621680378899 xs6989586621680378900 p6989586621680378895 :: TyFun k Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378723Scrutinee_6989586621680375098Sym3 key6989586621680378719 x6989586621680378720 y6989586621680378721 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378625Scrutinee_6989586621680375106Sym3 x6989586621680378622 xs6989586621680378623 ls6989586621680378624 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180309Scrutinee_6989586621680180117Sym2 x6989586621680180308 x06989586621680180303 :: TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180255Scrutinee_6989586621680180131Sym1 x16989586621680180250 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180218Scrutinee_6989586621680180141Sym1 x16989586621680180213 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378609Scrutinee_6989586621680375108Sym3 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 :: TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680378609Scrutinee_6989586621680375108Sym4 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 eq6989586621680378600 :: TyFun k3 Bool -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180309Scrutinee_6989586621680180117Sym3 x6989586621680180308 x06989586621680180303 y6989586621680180304 :: TyFun k3 (TyFun k4 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180255Scrutinee_6989586621680180131Sym2 x16989586621680180250 x26989586621680180251 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180218Scrutinee_6989586621680180141Sym2 x16989586621680180213 x26989586621680180214 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180309Scrutinee_6989586621680180117Sym4 x6989586621680180308 x06989586621680180303 y6989586621680180304 arg_69895866216801801136989586621680180299 :: TyFun k4 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180255Scrutinee_6989586621680180131Sym3 x16989586621680180250 x26989586621680180251 y6989586621680180252 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180218Scrutinee_6989586621680180141Sym3 x16989586621680180213 x26989586621680180214 y6989586621680180215 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180255Scrutinee_6989586621680180131Sym4 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180218Scrutinee_6989586621680180141Sym4 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180255Scrutinee_6989586621680180131Sym5 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 arg_69895866216801801276989586621680180246 :: TyFun k5 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680180218Scrutinee_6989586621680180141Sym5 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 arg_69895866216801801376989586621680180209 :: TyFun k5 Bool -> Type) | |
Defined in Data.Singletons.Prelude.Enum Methods suppressUnusedWarnings :: () # | |
| type Rep Bool | |
| newtype Vector Bool | |
| type MaxBound | |
Defined in Data.Singletons.Prelude.Enum type MaxBound = MaxBound_6989586621680176216Sym0 | |
| type MinBound | |
Defined in Data.Singletons.Prelude.Enum type MinBound = MinBound_6989586621680176213Sym0 | |
| type Sing | |
Defined in Data.Singletons.Prelude.Instances | |
| type Demote Bool | |
Defined in Data.Singletons.Prelude.Instances | |
| type DemoteRep Bool | |
Defined in GHC.Generics | |
| data Sing (a :: Bool) | |
| type TypeDocFieldDescriptions Bool | |
Defined in Michelson.Typed.Haskell.Doc | |
| type ToT Bool | |
Defined in Michelson.Typed.Haskell.Value | |
| newtype MVector s Bool | |
| type Show_ (arg :: Bool) | |
| type FromEnum (a :: Bool) | |
Defined in Data.Singletons.Prelude.Enum | |
| type ToEnum a | |
Defined in Data.Singletons.Prelude.Enum | |
| type Pred (arg :: Bool) | |
| type Succ (arg :: Bool) | |
| type UnaryArithResHs Not Bool Source # | |
Defined in Lorentz.Arith | |
| type ShowList (arg1 :: [Bool]) arg2 | |
| type EnumFromTo (arg1 :: Bool) (arg2 :: Bool) | |
| type Min (arg1 :: Bool) (arg2 :: Bool) | |
| type Max (arg1 :: Bool) (arg2 :: Bool) | |
| type (arg1 :: Bool) >= (arg2 :: Bool) | |
| type (arg1 :: Bool) > (arg2 :: Bool) | |
| type (arg1 :: Bool) <= (arg2 :: Bool) | |
| type (arg1 :: Bool) < (arg2 :: Bool) | |
| type Compare (a1 :: Bool) (a2 :: Bool) | |
| type (x :: Bool) /= (y :: Bool) | |
| type (a :: Bool) == (b :: Bool) | |
Defined in Data.Singletons.Prelude.Eq | |
| type ArithResHs And Bool Bool Source # | |
Defined in Lorentz.Arith | |
| type ArithResHs Or Bool Bool Source # | |
Defined in Lorentz.Arith | |
| type ArithResHs Xor Bool Bool Source # | |
Defined in Lorentz.Arith | |
| type ShowsPrec a1 (a2 :: Bool) a3 | |
| type EnumFromThenTo (arg1 :: Bool) (arg2 :: Bool) (arg3 :: Bool) | |
| type Apply NotSym0 (a6989586621679815944 :: Bool) | |
Defined in Data.Singletons.Prelude.Bool | |
| type Apply FromEnum_6989586621680203592Sym0 (a6989586621680203596 :: Bool) | |
Defined in Data.Singletons.Prelude.Enum | |
| type Apply All_Sym0 (a6989586621680362234 :: Bool) | |
| type Apply AllSym0 (a6989586621680249413 :: Bool) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| type Apply Any_Sym0 (a6989586621680362228 :: Bool) | |
| type Apply AnySym0 (a6989586621680249430 :: Bool) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| type Apply ToEnum_6989586621680203579Sym0 (a6989586621680203583 :: Nat) | |
Defined in Data.Singletons.Prelude.Enum | |
| type Apply GetAllSym0 (a6989586621680249416 :: All) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| type Apply GetAnySym0 (a6989586621680249433 :: Any) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| type Apply ((||@#@$$) a6989586621679815663 :: TyFun Bool Bool -> Type) (a6989586621679815664 :: Bool) | |
| type Apply ((&&@#@$$) a6989586621679815361 :: TyFun Bool Bool -> Type) (a6989586621679815362 :: Bool) | |
| type Apply (Compare_6989586621679848336Sym1 a6989586621679848341 :: TyFun Bool Ordering -> Type) (a6989586621679848342 :: Bool) | |
| type Apply ((<=?@#@$$) a6989586621679910080 :: TyFun Nat Bool -> Type) (a6989586621679910081 :: Nat) | |
Defined in Data.Singletons.TypeLits.Internal | |
| type Apply (Let6989586621680786609Scrutinee_6989586621680786014Sym0 :: TyFun k1 Bool -> Type) (n6989586621680786608 :: k1) | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Apply (Let6989586621680813445Scrutinee_6989586621680813409Sym1 x6989586621680813440 :: TyFun k1 Bool -> Type) (y6989586621680813441 :: k1) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Let6989586621680813469Scrutinee_6989586621680813411Sym1 x6989586621680813464 :: TyFun k1 Bool -> Type) (y6989586621680813465 :: k1) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply ((==@#@$$) a6989586621679818744 :: TyFun a Bool -> Type) (a6989586621679818745 :: a) | |
| type Apply ((/=@#@$$) a6989586621679818747 :: TyFun a Bool -> Type) (a6989586621679818748 :: a) | |
| type Apply (DefaultEqSym1 a6989586621679818750 :: TyFun k Bool -> Type) (a6989586621679818751 :: k) | |
Defined in Data.Singletons.Prelude.Eq type Apply (DefaultEqSym1 a6989586621679818750 :: TyFun k Bool -> Type) (a6989586621679818751 :: k) = DefaultEqSym2 a6989586621679818750 a6989586621679818751 | |
| type Apply (Let6989586621679836762Scrutinee_6989586621679836677Sym1 x6989586621679836760 :: TyFun k1 Bool -> Type) (y6989586621679836761 :: k1) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply (TFHelper_6989586621679836822Sym1 a6989586621679836827 :: TyFun a Bool -> Type) (a6989586621679836828 :: a) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply (TFHelper_6989586621679836806Sym1 a6989586621679836811 :: TyFun a Bool -> Type) (a6989586621679836812 :: a) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply (TFHelper_6989586621679836790Sym1 a6989586621679836795 :: TyFun a Bool -> Type) (a6989586621679836796 :: a) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply (TFHelper_6989586621679836774Sym1 a6989586621679836779 :: TyFun a Bool -> Type) (a6989586621679836780 :: a) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply ((<=@#@$$) a6989586621679836729 :: TyFun a Bool -> Type) (a6989586621679836730 :: a) | |
| type Apply ((>=@#@$$) a6989586621679836739 :: TyFun a Bool -> Type) (a6989586621679836740 :: a) | |
| type Apply ((>@#@$$) a6989586621679836734 :: TyFun a Bool -> Type) (a6989586621679836735 :: a) | |
| type Apply (Let6989586621679836863Scrutinee_6989586621679836691Sym1 x6989586621679836861 :: TyFun k1 Bool -> Type) (y6989586621679836862 :: k1) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply (Let6989586621679836847Scrutinee_6989586621679836689Sym1 x6989586621679836845 :: TyFun k1 Bool -> Type) (y6989586621679836846 :: k1) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply (Let6989586621679836766Scrutinee_6989586621679836679Sym1 x6989586621679836760 :: TyFun k1 Bool -> Type) (y6989586621679836761 :: k1) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply ((<@#@$$) a6989586621679836724 :: TyFun a Bool -> Type) (a6989586621679836725 :: a) | |
| type Apply (Bool_Sym2 a6989586621679814557 a6989586621679814558 :: TyFun Bool a -> Type) (a6989586621679814559 :: Bool) | |
| type Apply (Let6989586621680378657Scrutinee_6989586621680375102Sym1 n6989586621680378655 :: TyFun k Bool -> Type) (x6989586621680378656 :: k) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378638Scrutinee_6989586621680375104Sym2 x6989586621680378635 xs6989586621680378636 :: TyFun k3 Bool -> Type) (n6989586621680378637 :: k3) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378800Scrutinee_6989586621680375088Sym2 n6989586621680378797 x6989586621680378798 :: TyFun k3 Bool -> Type) (xs6989586621680378799 :: k3) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378813Scrutinee_6989586621680375086Sym2 n6989586621680378810 x6989586621680378811 :: TyFun k3 Bool -> Type) (xs6989586621680378812 :: k3) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Lambda_6989586621680822332Sym2 a_69895866216808223266989586621680822331 arg_69895866216808217186989586621680822334 :: TyFun k3 Bool -> Type) (arg_69895866216808217206989586621680822335 :: k3) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (Lambda_6989586621680822332Sym2 a_69895866216808223266989586621680822331 arg_69895866216808217186989586621680822334 :: TyFun k3 Bool -> Type) (arg_69895866216808217206989586621680822335 :: k3) = Lambda_6989586621680822332Sym3 a_69895866216808223266989586621680822331 arg_69895866216808217186989586621680822334 arg_69895866216808217206989586621680822335 | |
| type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym3 key6989586621680378719 x6989586621680378720 y6989586621680378721 :: TyFun k3 Bool -> Type) (xys6989586621680378722 :: k3) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym3 key6989586621680378719 x6989586621680378720 y6989586621680378721 :: TyFun k3 Bool -> Type) (xys6989586621680378722 :: k3) = Let6989586621680378723Scrutinee_6989586621680375098Sym4 key6989586621680378719 x6989586621680378720 y6989586621680378721 xys6989586621680378722 | |
| type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym3 x6989586621680378622 xs6989586621680378623 ls6989586621680378624 :: TyFun k3 Bool -> Type) (l6989586621680378617 :: k3) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym3 x6989586621680378622 xs6989586621680378623 ls6989586621680378624 :: TyFun k3 Bool -> Type) (l6989586621680378617 :: k3) = Let6989586621680378625Scrutinee_6989586621680375106Sym4 x6989586621680378622 xs6989586621680378623 ls6989586621680378624 l6989586621680378617 | |
| type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym3 x6989586621680378899 xs6989586621680378900 p6989586621680378895 :: TyFun k Bool -> Type) (a_69895866216803788886989586621680378896 :: k) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym3 x6989586621680378899 xs6989586621680378900 p6989586621680378895 :: TyFun k Bool -> Type) (a_69895866216803788886989586621680378896 :: k) = Let6989586621680378901Scrutinee_6989586621680375080Sym4 x6989586621680378899 xs6989586621680378900 p6989586621680378895 a_69895866216803788886989586621680378896 | |
| type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym4 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 eq6989586621680378600 :: TyFun k3 Bool -> Type) (l6989586621680378601 :: k3) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym4 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 eq6989586621680378600 :: TyFun k3 Bool -> Type) (l6989586621680378601 :: k3) = Let6989586621680378609Scrutinee_6989586621680375108Sym5 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 eq6989586621680378600 l6989586621680378601 | |
| type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym4 x6989586621680180308 x06989586621680180303 y6989586621680180304 arg_69895866216801801136989586621680180299 :: TyFun k4 Bool -> Type) (arg_69895866216801801156989586621680180300 :: k4) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym4 x6989586621680180308 x06989586621680180303 y6989586621680180304 arg_69895866216801801136989586621680180299 :: TyFun k4 Bool -> Type) (arg_69895866216801801156989586621680180300 :: k4) = Let6989586621680180309Scrutinee_6989586621680180117Sym5 x6989586621680180308 x06989586621680180303 y6989586621680180304 arg_69895866216801801136989586621680180299 arg_69895866216801801156989586621680180300 | |
| type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym5 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 arg_69895866216801801376989586621680180209 :: TyFun k5 Bool -> Type) (arg_69895866216801801396989586621680180210 :: k5) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym5 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 arg_69895866216801801376989586621680180209 :: TyFun k5 Bool -> Type) (arg_69895866216801801396989586621680180210 :: k5) = Let6989586621680180218Scrutinee_6989586621680180141Sym6 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 arg_69895866216801801376989586621680180209 arg_69895866216801801396989586621680180210 | |
| type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym5 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 arg_69895866216801801276989586621680180246 :: TyFun k5 Bool -> Type) (arg_69895866216801801296989586621680180247 :: k5) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym5 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 arg_69895866216801801276989586621680180246 :: TyFun k5 Bool -> Type) (arg_69895866216801801296989586621680180247 :: k5) = Let6989586621680180255Scrutinee_6989586621680180131Sym6 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 arg_69895866216801801276989586621680180246 arg_69895866216801801296989586621680180247 | |
| type Eval (Not 'False) | |
Defined in Fcf.Data.Bool | |
| type Eval (Not 'True) | |
Defined in Fcf.Data.Bool | |
| type Apply (GuardSym0 :: TyFun Bool (f ()) -> Type) (a6989586621680011056 :: Bool) | |
| type Eval (Null (a2 ': as) :: Bool -> Type) | |
| type Eval (Null ('[] :: [a]) :: Bool -> Type) | |
| type Eval (And lst :: Bool -> Type) | |
| type Eval (Or lst :: Bool -> Type) | |
| type Eval (a <= b :: Bool -> Type) | |
| type Eval (a >= b :: Bool -> Type) | |
| type Eval (a < b :: Bool -> Type) | |
| type Eval (a > b :: Bool -> Type) | |
| type Eval (IsNothing ('Nothing :: Maybe a) :: Bool -> Type) | |
| type Eval (IsNothing ('Just _a) :: Bool -> Type) | |
| type Eval (IsJust ('Nothing :: Maybe a) :: Bool -> Type) | |
| type Eval (IsJust ('Just _a) :: Bool -> Type) | |
| type Eval ('False || b :: Bool -> Type) | |
| type Eval ('True || b :: Bool -> Type) | |
| type Eval (a || 'False :: Bool -> Type) | |
| type Eval (a || 'True :: Bool -> Type) | |
| type Eval ('False && b :: Bool -> Type) | |
| type Eval ('True && b :: Bool -> Type) | |
| type Eval (a && 'True :: Bool -> Type) | |
| type Eval (a && 'False :: Bool -> Type) | |
| type Apply (||@#@$) (a6989586621679815663 :: Bool) | |
Defined in Data.Singletons.Prelude.Bool | |
| type Apply (&&@#@$) (a6989586621679815361 :: Bool) | |
Defined in Data.Singletons.Prelude.Bool | |
| type Apply Compare_6989586621679848336Sym0 (a6989586621679848341 :: Bool) | |
Defined in Data.Singletons.Prelude.Ord | |
| type Apply ShowParenSym0 (a6989586621680636038 :: Bool) | |
Defined in Data.Singletons.Prelude.Show | |
| type Apply ShowsPrec_6989586621680653401Sym0 (a6989586621680653411 :: Nat) | |
Defined in Data.Singletons.Prelude.Show | |
| type Apply (<=?@#@$) (a6989586621679910080 :: Nat) | |
Defined in Data.Singletons.TypeLits.Internal | |
| type Apply (ShowsPrec_6989586621680653401Sym1 a6989586621680653411 :: TyFun Bool (Symbol ~> Symbol) -> Type) (a6989586621680653412 :: Bool) | |
| type Apply (UnlessSym0 :: TyFun Bool (f () ~> f ()) -> Type) (a6989586621681500621 :: Bool) | |
Defined in Data.Singletons.Prelude.Monad type Apply (UnlessSym0 :: TyFun Bool (f () ~> f ()) -> Type) (a6989586621681500621 :: Bool) = UnlessSym1 a6989586621681500621 :: TyFun (f ()) (f ()) -> Type | |
| type Apply (WhenSym0 :: TyFun Bool (f () ~> f ()) -> Type) (a6989586621680011200 :: Bool) | |
| type Apply (ListelemSym0 :: TyFun a ([a] ~> Bool) -> Type) (a6989586621680748782 :: a) | |
| type Apply (NotElemSym0 :: TyFun a ([a] ~> Bool) -> Type) (a6989586621680379352 :: a) | |
| type Apply (ElemSym0 :: TyFun a ([a] ~> Bool) -> Type) (a6989586621680379360 :: a) | |
| type Apply (Let6989586621680813445Scrutinee_6989586621680813409Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) (x6989586621680813440 :: k1) | |
| type Apply (Let6989586621680813469Scrutinee_6989586621680813411Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) (x6989586621680813464 :: k1) | |
| type Apply (Elem_6989586621680822470Sym0 :: TyFun a ([a] ~> Bool) -> Type) (a6989586621680822479 :: a) | |
| type Apply (Elem_6989586621680822846Sym0 :: TyFun a (Proxy a ~> Bool) -> Type) (a6989586621680822851 :: a) | |
| type Apply (Elem_6989586621680822878Sym0 :: TyFun a (Dual a ~> Bool) -> Type) (a6989586621680822887 :: a) | |
| type Apply (Elem_6989586621680823053Sym0 :: TyFun a (Sum a ~> Bool) -> Type) (a6989586621680823062 :: a) | |
| type Apply (Elem_6989586621680823228Sym0 :: TyFun a (Product a ~> Bool) -> Type) (a6989586621680823237 :: a) | |
| type Apply ((==@#@$) :: TyFun a (a ~> Bool) -> Type) (a6989586621679818744 :: a) | |
| type Apply ((/=@#@$) :: TyFun a (a ~> Bool) -> Type) (a6989586621679818747 :: a) | |
| type Apply (DefaultEqSym0 :: TyFun k (k ~> Bool) -> Type) (a6989586621679818750 :: k) | |
Defined in Data.Singletons.Prelude.Eq type Apply (DefaultEqSym0 :: TyFun k (k ~> Bool) -> Type) (a6989586621679818750 :: k) = DefaultEqSym1 a6989586621679818750 | |
| type Apply (Bool_Sym0 :: TyFun a (a ~> (Bool ~> a)) -> Type) (a6989586621679814557 :: a) | |
| type Apply (Let6989586621679836762Scrutinee_6989586621679836677Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) (x6989586621679836760 :: k1) | |
| type Apply (TFHelper_6989586621679836822Sym0 :: TyFun a (a ~> Bool) -> Type) (a6989586621679836827 :: a) | |
| type Apply (TFHelper_6989586621679836806Sym0 :: TyFun a (a ~> Bool) -> Type) (a6989586621679836811 :: a) | |
| type Apply (TFHelper_6989586621679836790Sym0 :: TyFun a (a ~> Bool) -> Type) (a6989586621679836795 :: a) | |
| type Apply (TFHelper_6989586621679836774Sym0 :: TyFun a (a ~> Bool) -> Type) (a6989586621679836779 :: a) | |
| type Apply ((<=@#@$) :: TyFun a (a ~> Bool) -> Type) (a6989586621679836729 :: a) | |
| type Apply ((>=@#@$) :: TyFun a (a ~> Bool) -> Type) (a6989586621679836739 :: a) | |
| type Apply ((>@#@$) :: TyFun a (a ~> Bool) -> Type) (a6989586621679836734 :: a) | |
| type Apply (Let6989586621679836863Scrutinee_6989586621679836691Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) (x6989586621679836861 :: k1) | |
| type Apply (Let6989586621679836847Scrutinee_6989586621679836689Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) (x6989586621679836845 :: k1) | |
| type Apply (Let6989586621679836766Scrutinee_6989586621679836679Sym0 :: TyFun k1 (TyFun k1 Bool -> Type) -> Type) (x6989586621679836760 :: k1) | |
| type Apply ((<@#@$) :: TyFun a (a ~> Bool) -> Type) (a6989586621679836724 :: a) | |
| type Apply (Elem_6989586621681011897Sym0 :: TyFun a (Identity a ~> Bool) -> Type) (a6989586621681011902 :: a) | |
| type Apply (Let6989586621680378657Scrutinee_6989586621680375102Sym0 :: TyFun k1 (TyFun k Bool -> Type) -> Type) (n6989586621680378655 :: k1) | |
| type Apply (Elem_bySym1 a6989586621680378588 :: TyFun a ([a] ~> Bool) -> Type) (a6989586621680378589 :: a) | |
| type Apply (Elem_6989586621680822360Sym0 :: TyFun a (t a ~> Bool) -> Type) (a6989586621680822369 :: a) | |
| type Apply (ElemSym0 :: TyFun a (t a ~> Bool) -> Type) (a6989586621680822160 :: a) | |
| type Apply (NotElemSym0 :: TyFun a (t a ~> Bool) -> Type) (a6989586621680821907 :: a) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (NotElemSym0 :: TyFun a (t a ~> Bool) -> Type) (a6989586621680821907 :: a) = NotElemSym1 a6989586621680821907 :: TyFun (t a) Bool -> Type | |
| type Apply (Bool_Sym1 a6989586621679814557 :: TyFun a (Bool ~> a) -> Type) (a6989586621679814558 :: a) | |
| type Apply (Lambda_6989586621681500761Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) -> Type) -> Type) (x6989586621681500760 :: k1) | |
Defined in Data.Singletons.Prelude.Monad | |
| type Apply (Let6989586621680378638Scrutinee_6989586621680375104Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) (x6989586621680378635 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym0 :: TyFun k1 (TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) (key6989586621680378719 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym0 :: TyFun k1 (TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) (key6989586621680378719 :: k1) = Let6989586621680378723Scrutinee_6989586621680375098Sym1 key6989586621680378719 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680378800Scrutinee_6989586621680375088Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) (n6989586621680378797 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378813Scrutinee_6989586621680375086Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) (n6989586621680378810 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym0 :: TyFun k1 (TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (y6989586621680378606 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym0 :: TyFun k1 (TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (y6989586621680378606 :: k1) = Let6989586621680378609Scrutinee_6989586621680375108Sym1 y6989586621680378606 :: TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym0 :: TyFun k1 (TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) (x6989586621680378622 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym0 :: TyFun k1 (TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) (x6989586621680378622 :: k1) = Let6989586621680378625Scrutinee_6989586621680375106Sym1 x6989586621680378622 :: TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym0 :: TyFun k1 (TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type) -> Type) (x6989586621680378899 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym0 :: TyFun k1 (TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type) -> Type) (x6989586621680378899 :: k1) = Let6989586621680378901Scrutinee_6989586621680375080Sym1 x6989586621680378899 :: TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type | |
| type Apply (Lambda_6989586621680822332Sym0 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) (a_69895866216808223266989586621680822331 :: k1) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Lambda_6989586621681500761Sym1 x6989586621681500760 :: TyFun k2 (TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) -> Type) (p6989586621681500756 :: k2) | |
Defined in Data.Singletons.Prelude.Monad | |
| type Apply (Let6989586621680378638Scrutinee_6989586621680375104Sym1 x6989586621680378635 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (xs6989586621680378636 :: k2) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym1 key6989586621680378719 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) (x6989586621680378720 :: k1) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym1 key6989586621680378719 :: TyFun k1 (TyFun k2 (TyFun k3 Bool -> Type) -> Type) -> Type) (x6989586621680378720 :: k1) = Let6989586621680378723Scrutinee_6989586621680375098Sym2 key6989586621680378719 x6989586621680378720 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type | |
| type Apply (Let6989586621680378800Scrutinee_6989586621680375088Sym1 n6989586621680378797 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (x6989586621680378798 :: k2) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378813Scrutinee_6989586621680375086Sym1 n6989586621680378810 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (x6989586621680378811 :: k2) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym1 y6989586621680378606 :: TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) (ys6989586621680378607 :: k2) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym1 y6989586621680378606 :: TyFun k2 (TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) -> Type) (ys6989586621680378607 :: k2) = Let6989586621680378609Scrutinee_6989586621680375108Sym2 y6989586621680378606 ys6989586621680378607 :: TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym1 x6989586621680378622 :: TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type) (xs6989586621680378623 :: k2) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym1 x6989586621680378622 :: TyFun k2 (TyFun [k1] (TyFun k3 Bool -> Type) -> Type) -> Type) (xs6989586621680378623 :: k2) = Let6989586621680378625Scrutinee_6989586621680375106Sym2 x6989586621680378622 xs6989586621680378623 :: TyFun [k1] (TyFun k3 Bool -> Type) -> Type | |
| type Apply (Lambda_6989586621680822332Sym1 a_69895866216808223266989586621680822331 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (arg_69895866216808217186989586621680822334 :: k2) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (Lambda_6989586621680822332Sym1 a_69895866216808223266989586621680822331 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (arg_69895866216808217186989586621680822334 :: k2) = Lambda_6989586621680822332Sym2 a_69895866216808223266989586621680822331 arg_69895866216808217186989586621680822334 :: TyFun k3 Bool -> Type | |
| type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (x6989586621680180308 :: k1) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (x6989586621680180308 :: k1) = Let6989586621680180309Scrutinee_6989586621680180117Sym1 x6989586621680180308 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type | |
| type Apply (Lambda_6989586621681500761Sym2 x6989586621681500760 p6989586621681500756 :: TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) (a_69895866216815007496989586621681500757 :: k3) | |
Defined in Data.Singletons.Prelude.Monad type Apply (Lambda_6989586621681500761Sym2 x6989586621681500760 p6989586621681500756 :: TyFun k3 (TyFun Bool ([k1] ~> [k1]) -> Type) -> Type) (a_69895866216815007496989586621681500757 :: k3) = Lambda_6989586621681500761Sym3 x6989586621681500760 p6989586621681500756 a_69895866216815007496989586621681500757 | |
| type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym2 key6989586621680378719 x6989586621680378720 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (y6989586621680378721 :: k2) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378723Scrutinee_6989586621680375098Sym2 key6989586621680378719 x6989586621680378720 :: TyFun k2 (TyFun k3 Bool -> Type) -> Type) (y6989586621680378721 :: k2) = Let6989586621680378723Scrutinee_6989586621680375098Sym3 key6989586621680378719 x6989586621680378720 y6989586621680378721 :: TyFun k3 Bool -> Type | |
| type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) (x16989586621680180213 :: k1) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) (x16989586621680180213 :: k1) = Let6989586621680180218Scrutinee_6989586621680180141Sym1 x16989586621680180213 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) (x16989586621680180250 :: k1) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym0 :: TyFun k1 (TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) (x16989586621680180250 :: k1) = Let6989586621680180255Scrutinee_6989586621680180131Sym1 x16989586621680180250 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym1 x6989586621680180308 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type) (x06989586621680180303 :: k2) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym1 x6989586621680180308 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) -> Type) (x06989586621680180303 :: k2) = Let6989586621680180309Scrutinee_6989586621680180117Sym2 x6989586621680180308 x06989586621680180303 :: TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type | |
| type Apply (Lambda_6989586621681500761Sym3 x6989586621681500760 p6989586621681500756 a_69895866216815007496989586621681500757 :: TyFun Bool ([k1] ~> [k1]) -> Type) (flg6989586621681500763 :: Bool) | |
Defined in Data.Singletons.Prelude.Monad type Apply (Lambda_6989586621681500761Sym3 x6989586621681500760 p6989586621681500756 a_69895866216815007496989586621681500757 :: TyFun Bool ([k1] ~> [k1]) -> Type) (flg6989586621681500763 :: Bool) = Lambda_6989586621681500761Sym4 x6989586621681500760 p6989586621681500756 a_69895866216815007496989586621681500757 flg6989586621681500763 | |
| type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym1 x16989586621680180213 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (x26989586621680180214 :: k2) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym1 x16989586621680180213 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (x26989586621680180214 :: k2) = Let6989586621680180218Scrutinee_6989586621680180141Sym2 x16989586621680180213 x26989586621680180214 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym1 x16989586621680180250 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (x26989586621680180251 :: k2) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym1 x16989586621680180250 :: TyFun k2 (TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) -> Type) (x26989586621680180251 :: k2) = Let6989586621680180255Scrutinee_6989586621680180131Sym2 x16989586621680180250 x26989586621680180251 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym2 x6989586621680180308 x06989586621680180303 :: TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) (y6989586621680180304 :: k1) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym2 x6989586621680180308 x06989586621680180303 :: TyFun k1 (TyFun k3 (TyFun k4 Bool -> Type) -> Type) -> Type) (y6989586621680180304 :: k1) = Let6989586621680180309Scrutinee_6989586621680180117Sym3 x6989586621680180308 x06989586621680180303 y6989586621680180304 :: TyFun k3 (TyFun k4 Bool -> Type) -> Type | |
| type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym2 x16989586621680180213 x26989586621680180214 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) (y6989586621680180215 :: k1) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym2 x16989586621680180213 x26989586621680180214 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) (y6989586621680180215 :: k1) = Let6989586621680180218Scrutinee_6989586621680180141Sym3 x16989586621680180213 x26989586621680180214 y6989586621680180215 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym2 x16989586621680180250 x26989586621680180251 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) (y6989586621680180252 :: k1) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym2 x16989586621680180250 x26989586621680180251 :: TyFun k1 (TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) -> Type) (y6989586621680180252 :: k1) = Let6989586621680180255Scrutinee_6989586621680180131Sym3 x16989586621680180250 x26989586621680180251 y6989586621680180252 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym3 x6989586621680180308 x06989586621680180303 y6989586621680180304 :: TyFun k3 (TyFun k4 Bool -> Type) -> Type) (arg_69895866216801801136989586621680180299 :: k3) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180309Scrutinee_6989586621680180117Sym3 x6989586621680180308 x06989586621680180303 y6989586621680180304 :: TyFun k3 (TyFun k4 Bool -> Type) -> Type) (arg_69895866216801801136989586621680180299 :: k3) = Let6989586621680180309Scrutinee_6989586621680180117Sym4 x6989586621680180308 x06989586621680180303 y6989586621680180304 arg_69895866216801801136989586621680180299 :: TyFun k4 Bool -> Type | |
| type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym3 x16989586621680180213 x26989586621680180214 y6989586621680180215 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) (arg_69895866216801801356989586621680180208 :: k3) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym3 x16989586621680180213 x26989586621680180214 y6989586621680180215 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) (arg_69895866216801801356989586621680180208 :: k3) = Let6989586621680180218Scrutinee_6989586621680180141Sym4 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type | |
| type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym3 x16989586621680180250 x26989586621680180251 y6989586621680180252 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) (arg_69895866216801801256989586621680180245 :: k3) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym3 x16989586621680180250 x26989586621680180251 y6989586621680180252 :: TyFun k3 (TyFun k4 (TyFun k5 Bool -> Type) -> Type) -> Type) (arg_69895866216801801256989586621680180245 :: k3) = Let6989586621680180255Scrutinee_6989586621680180131Sym4 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type | |
| type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym4 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type) (arg_69895866216801801376989586621680180209 :: k4) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180218Scrutinee_6989586621680180141Sym4 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type) (arg_69895866216801801376989586621680180209 :: k4) = Let6989586621680180218Scrutinee_6989586621680180141Sym5 x16989586621680180213 x26989586621680180214 y6989586621680180215 arg_69895866216801801356989586621680180208 arg_69895866216801801376989586621680180209 :: TyFun k5 Bool -> Type | |
| type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym4 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type) (arg_69895866216801801276989586621680180246 :: k4) | |
Defined in Data.Singletons.Prelude.Enum type Apply (Let6989586621680180255Scrutinee_6989586621680180131Sym4 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 :: TyFun k4 (TyFun k5 Bool -> Type) -> Type) (arg_69895866216801801276989586621680180246 :: k4) = Let6989586621680180255Scrutinee_6989586621680180131Sym5 x16989586621680180250 x26989586621680180251 y6989586621680180252 arg_69895866216801801256989586621680180245 arg_69895866216801801276989586621680180246 :: TyFun k5 Bool -> Type | |
| type Eval (IsPrefixOf xs ys :: Bool -> Type) | |
Defined in Fcf.Data.List | |
| type Eval (IsSuffixOf xs ys :: Bool -> Type) | |
Defined in Fcf.Data.List | |
| type Eval (IsInfixOf xs ys :: Bool -> Type) | |
| type Eval (Elem a2 as :: Bool -> Type) | |
| type Eval (IsLeft ('Right _a :: Either a b) :: Bool -> Type) | |
| type Eval (IsLeft ('Left _a :: Either a b) :: Bool -> Type) | |
| type Eval (IsRight ('Right _a :: Either a b) :: Bool -> Type) | |
| type Eval (IsRight ('Left _a :: Either a b) :: Bool -> Type) | |
| type Eval (TyEq a b :: Bool -> Type) | |
| type Eval (All p lst :: Bool -> Type) | |
| type Eval (Any p lst :: Bool -> Type) | |
| type Eval (TyEqSing a b :: Bool -> Type) | |
| type Apply OrSym0 (a6989586621680379592 :: [Bool]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply AndSym0 (a6989586621680379597 :: [Bool]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (ListnullSym0 :: TyFun [a] Bool -> Type) (a6989586621680748691 :: [a]) | |
| type Apply (NullSym0 :: TyFun [a] Bool -> Type) (a6989586621680379770 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Null_6989586621680822604Sym0 :: TyFun [a] Bool -> Type) (a6989586621680822610 :: [a]) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958803 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958803 :: Maybe a) = IsNothingSym1 a6989586621679958803 | |
| type Apply (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958806 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958806 :: Maybe a) = IsJustSym1 a6989586621679958806 | |
| type Apply (AndSym0 :: TyFun (t Bool) Bool -> Type) (a6989586621680821979 :: t Bool) | |
| type Apply (OrSym0 :: TyFun (t Bool) Bool -> Type) (a6989586621680821973 :: t Bool) | |
| type Apply (Null_6989586621681012013Sym0 :: TyFun (Identity a) Bool -> Type) (a6989586621681012017 :: Identity a) | |
| type Apply (Null_6989586621680823010Sym0 :: TyFun (Dual a) Bool -> Type) (a6989586621680823014 :: Dual a) | |
| type Apply (Null_6989586621680823185Sym0 :: TyFun (Sum a) Bool -> Type) (a6989586621680823189 :: Sum a) | |
| type Apply (Null_6989586621680823360Sym0 :: TyFun (Product a) Bool -> Type) (a6989586621680823364 :: Product a) | |
| type Apply (ListelemSym1 a6989586621680748782 :: TyFun [a] Bool -> Type) (a6989586621680748783 :: [a]) | |
| type Apply (ListisPrefixOfSym1 a6989586621680748854 :: TyFun [a] Bool -> Type) (a6989586621680748855 :: [a]) | |
| type Apply (NotElemSym1 a6989586621680379352 :: TyFun [a] Bool -> Type) (a6989586621680379353 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (ElemSym1 a6989586621680379360 :: TyFun [a] Bool -> Type) (a6989586621680379361 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (IsPrefixOfSym1 a6989586621680379382 :: TyFun [a] Bool -> Type) (a6989586621680379383 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (IsPrefixOfSym1 a6989586621680379382 :: TyFun [a] Bool -> Type) (a6989586621680379383 :: [a]) = IsPrefixOfSym2 a6989586621680379382 a6989586621680379383 | |
| type Apply (AnySym1 a6989586621680379577 :: TyFun [a] Bool -> Type) (a6989586621680379578 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (IsInfixOfSym1 a6989586621680379368 :: TyFun [a] Bool -> Type) (a6989586621680379369 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (IsInfixOfSym1 a6989586621680379368 :: TyFun [a] Bool -> Type) (a6989586621680379369 :: [a]) = IsInfixOfSym2 a6989586621680379368 a6989586621680379369 | |
| type Apply (AllSym1 a6989586621680379585 :: TyFun [a] Bool -> Type) (a6989586621680379586 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (IsSuffixOfSym1 a6989586621680379375 :: TyFun [a] Bool -> Type) (a6989586621680379376 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (IsSuffixOfSym1 a6989586621680379375 :: TyFun [a] Bool -> Type) (a6989586621680379376 :: [a]) = IsSuffixOfSym2 a6989586621680379375 a6989586621680379376 | |
| type Apply (Elem_6989586621680822470Sym1 a6989586621680822479 :: TyFun [a] Bool -> Type) (a6989586621680822480 :: [a]) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Elem_6989586621681011897Sym1 a6989586621681011902 :: TyFun (Identity a) Bool -> Type) (a6989586621681011903 :: Identity a) | |
| type Apply (Elem_6989586621680822878Sym1 a6989586621680822887 :: TyFun (Dual a) Bool -> Type) (a6989586621680822888 :: Dual a) | |
| type Apply (Elem_6989586621680823053Sym1 a6989586621680823062 :: TyFun (Sum a) Bool -> Type) (a6989586621680823063 :: Sum a) | |
| type Apply (Elem_6989586621680823228Sym1 a6989586621680823237 :: TyFun (Product a) Bool -> Type) (a6989586621680823238 :: Product a) | |
| type Apply (Elem_bySym2 a6989586621680378588 a6989586621680378589 :: TyFun [a] Bool -> Type) (a6989586621680378590 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Elem_6989586621680822360Sym1 a6989586621680822369 :: TyFun (t a) Bool -> Type) (a6989586621680822370 :: t a) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Null_6989586621680822324Sym0 :: TyFun (t a) Bool -> Type) (a6989586621680822330 :: t a) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (AnySym1 a6989586621680821965 :: TyFun (t a) Bool -> Type) (a6989586621680821966 :: t a) | |
| type Apply (ElemSym1 a6989586621680822160 :: TyFun (t a) Bool -> Type) (a6989586621680822161 :: t a) | |
| type Apply (NotElemSym1 a6989586621680821907 :: TyFun (t a) Bool -> Type) (a6989586621680821908 :: t a) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (NotElemSym1 a6989586621680821907 :: TyFun (t a) Bool -> Type) (a6989586621680821908 :: t a) = NotElemSym2 a6989586621680821907 a6989586621680821908 | |
| type Apply (NullSym0 :: TyFun (t a) Bool -> Type) (a6989586621680822153 :: t a) | |
| type Apply (AllSym1 a6989586621680821956 :: TyFun (t a) Bool -> Type) (a6989586621680821957 :: t a) | |
| type Apply (ListisPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680748854 :: [a]) | |
| type Apply (IsPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680379382 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (IsPrefixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680379382 :: [a]) = IsPrefixOfSym1 a6989586621680379382 | |
| type Apply (IsInfixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680379368 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (IsInfixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680379368 :: [a]) = IsInfixOfSym1 a6989586621680379368 | |
| type Apply (IsSuffixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680379375 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (IsSuffixOfSym0 :: TyFun [a] ([a] ~> Bool) -> Type) (a6989586621680379375 :: [a]) = IsSuffixOfSym1 a6989586621680379375 | |
| type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym1 x6989586621680378899 :: TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type) (xs6989586621680378900 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym1 x6989586621680378899 :: TyFun [a] (TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) -> Type) (xs6989586621680378900 :: [a]) = Let6989586621680378901Scrutinee_6989586621680375080Sym2 x6989586621680378899 xs6989586621680378900 :: TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type | |
| type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym2 y6989586621680378606 ys6989586621680378607 :: TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) (xs6989586621680378608 :: [k1]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym2 y6989586621680378606 ys6989586621680378607 :: TyFun [k1] (TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) -> Type) (xs6989586621680378608 :: [k1]) = Let6989586621680378609Scrutinee_6989586621680375108Sym3 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 :: TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type | |
| type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym2 x6989586621680378622 xs6989586621680378623 :: TyFun [k1] (TyFun k3 Bool -> Type) -> Type) (ls6989586621680378624 :: [k1]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378625Scrutinee_6989586621680375106Sym2 x6989586621680378622 xs6989586621680378623 :: TyFun [k1] (TyFun k3 Bool -> Type) -> Type) (ls6989586621680378624 :: [k1]) = Let6989586621680378625Scrutinee_6989586621680375106Sym3 x6989586621680378622 xs6989586621680378623 ls6989586621680378624 :: TyFun k3 Bool -> Type | |
| type Apply (Null_6989586621680822765Sym0 :: TyFun (Either a1 a2) Bool -> Type) (a6989586621680822771 :: Either a1 a2) | |
| type Apply (IsRightSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803379 :: Either a b) | |
Defined in Data.Singletons.Prelude.Either type Apply (IsRightSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803379 :: Either a b) = IsRightSym1 a6989586621680803379 | |
| type Apply (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803382 :: Either a b) | |
Defined in Data.Singletons.Prelude.Either type Apply (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803382 :: Either a b) = IsLeftSym1 a6989586621680803382 | |
| type Apply (Elem_6989586621680822846Sym1 a6989586621680822851 :: TyFun (Proxy a) Bool -> Type) (a6989586621680822852 :: Proxy a) | |
| type Apply (Null_6989586621680822839Sym0 :: TyFun (Proxy a) Bool -> Type) (a6989586621680822843 :: Proxy a) | |
| type Apply (TFHelper_6989586621681202942Sym1 a6989586621681202947 :: TyFun (Arg a b) Bool -> Type) (a6989586621681202948 :: Arg a b) | |
| type Apply (TFHelper_6989586621680786553Sym1 a6989586621680786558 :: TyFun (Proxy s) Bool -> Type) (a6989586621680786559 :: Proxy s) | |
| type Apply (ListnubBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [a]) -> Type) (a6989586621680748816 :: a ~> (a ~> Bool)) | |
| type Apply (ListpartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) (a6989586621680748876 :: a ~> Bool) | |
| type Apply (ListfilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680748887 :: a ~> Bool) | |
| type Apply (ListspanSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) (a6989586621680748898 :: a ~> Bool) | |
| type Apply (ListdropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680748909 :: a ~> Bool) | |
| type Apply (ListtakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680748920 :: a ~> Bool) | |
| type Apply (Elem_bySym0 :: TyFun (a ~> (a ~> Bool)) (a ~> ([a] ~> Bool)) -> Type) (a6989586621680378588 :: a ~> (a ~> Bool)) | |
| type Apply (NubBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [a]) -> Type) (a6989586621680378598 :: a ~> (a ~> Bool)) | |
| type Apply (SelectSym0 :: TyFun (a ~> Bool) (a ~> (([a], [a]) ~> ([a], [a]))) -> Type) (a6989586621680378694 :: a ~> Bool) | |
| type Apply (PartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) (a6989586621680378709 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (PartitionSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) (a6989586621680378709 :: a ~> Bool) = PartitionSym1 a6989586621680378709 | |
| type Apply (BreakSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) (a6989586621680378821 :: a ~> Bool) | |
| type Apply (Let6989586621680378834YsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) (p6989586621680378825 :: k ~> Bool) | |
| type Apply (Let6989586621680378834ZsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) (p6989586621680378825 :: k ~> Bool) | |
| type Apply (Let6989586621680378834X_6989586621680378835Sym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] ([k], [k]) -> Type) -> Type) -> Type) (p6989586621680378825 :: k ~> Bool) | |
| type Apply (SpanSym0 :: TyFun (a ~> Bool) ([a] ~> ([a], [a])) -> Type) (a6989586621680378856 :: a ~> Bool) | |
| type Apply (Let6989586621680378869YsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) (p6989586621680378860 :: k ~> Bool) | |
| type Apply (Let6989586621680378869ZsSym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] [k] -> Type) -> Type) -> Type) (p6989586621680378860 :: k ~> Bool) | |
| type Apply (Let6989586621680378869X_6989586621680378870Sym0 :: TyFun (k ~> Bool) (TyFun k (TyFun [k] ([k], [k]) -> Type) -> Type) -> Type) (p6989586621680378860 :: k ~> Bool) | |
| type Apply (GroupBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> [[a]]) -> Type) (a6989586621680378731 :: a ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (DropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680378910 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (DropWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680378910 :: a ~> Bool) = DropWhileSym1 a6989586621680378910 | |
| type Apply (TakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680378925 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (TakeWhileSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680378925 :: a ~> Bool) = TakeWhileSym1 a6989586621680378925 | |
| type Apply (FilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680379025 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (FilterSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680379025 :: a ~> Bool) = FilterSym1 a6989586621680379025 | |
| type Apply (FindSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe a) -> Type) (a6989586621680379018 :: a ~> Bool) | |
| type Apply (DeleteBySym0 :: TyFun (a ~> (a ~> Bool)) (a ~> ([a] ~> [a])) -> Type) (a6989586621680379124 :: a ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (DeleteFirstsBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) (a6989586621680379114 :: a ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (UnionBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) (a6989586621680378578 :: a ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (FindIndicesSym0 :: TyFun (a ~> Bool) ([a] ~> [Nat]) -> Type) (a6989586621680378968 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (FindIndexSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe Nat) -> Type) (a6989586621680378991 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (AnySym0 :: TyFun (a ~> Bool) ([a] ~> Bool) -> Type) (a6989586621680379577 :: a ~> Bool) | |
| type Apply (IntersectBySym0 :: TyFun (a ~> (a ~> Bool)) ([a] ~> ([a] ~> [a])) -> Type) (a6989586621680378939 :: a ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (AllSym0 :: TyFun (a ~> Bool) ([a] ~> Bool) -> Type) (a6989586621680379585 :: a ~> Bool) | |
| type Apply (DropWhileEndSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680378893 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (DropWhileEndSym0 :: TyFun (a ~> Bool) ([a] ~> [a]) -> Type) (a6989586621680378893 :: a ~> Bool) = DropWhileEndSym1 a6989586621680378893 | |
| type Apply (UntilSym0 :: TyFun (a ~> Bool) ((a ~> a) ~> (a ~> a)) -> Type) (a6989586621679989617 :: a ~> Bool) | |
| type Apply (TFHelper_6989586621681202942Sym0 :: TyFun (Arg a b) (Arg a b ~> Bool) -> Type) (a6989586621681202947 :: Arg a b) | |
| type Apply (TFHelper_6989586621680786553Sym0 :: TyFun (Proxy s) (Proxy s ~> Bool) -> Type) (a6989586621680786558 :: Proxy s) | |
| type Apply (MfilterSym0 :: TyFun (a ~> Bool) (m a ~> m a) -> Type) (a6989586621681500592 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.Monad | |
| type Apply (FilterMSym0 :: TyFun (a ~> m Bool) ([a] ~> m [a]) -> Type) (a6989586621681500754 :: a ~> m Bool) | |
Defined in Data.Singletons.Prelude.Monad type Apply (FilterMSym0 :: TyFun (a ~> m Bool) ([a] ~> m [a]) -> Type) (a6989586621681500754 :: a ~> m Bool) = FilterMSym1 a6989586621681500754 | |
| type Apply (Let6989586621680378602NubBy'Sym0 :: TyFun (k1 ~> (k1 ~> Bool)) (TyFun k (TyFun [k1] ([k1] ~> [k1]) -> Type) -> Type) -> Type) (eq6989586621680378600 :: k1 ~> (k1 ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Let6989586621680378736YsSym0 :: TyFun (k1 ~> (a ~> Bool)) (TyFun k1 (TyFun [a] [a] -> Type) -> Type) -> Type) (eq6989586621680378733 :: k1 ~> (a ~> Bool)) | |
| type Apply (Let6989586621680378736ZsSym0 :: TyFun (k1 ~> (a ~> Bool)) (TyFun k1 (TyFun [a] [a] -> Type) -> Type) -> Type) (eq6989586621680378733 :: k1 ~> (a ~> Bool)) | |
| type Apply (Let6989586621680378736X_6989586621680378737Sym0 :: TyFun (k1 ~> (a ~> Bool)) (TyFun k1 (TyFun [a] ([a], [a]) -> Type) -> Type) -> Type) (eq6989586621680378733 :: k1 ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Lambda_6989586621680378897Sym0 :: TyFun (a ~> Bool) (TyFun k (TyFun a (TyFun [a] [a] -> Type) -> Type) -> Type) -> Type) (p6989586621680378895 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Lambda_6989586621680821893Sym0 :: TyFun (a ~> Bool) (TyFun k (TyFun a (First a) -> Type) -> Type) -> Type) (p6989586621680821891 :: a ~> Bool) | |
| type Apply (AnySym0 :: TyFun (a ~> Bool) (t a ~> Bool) -> Type) (a6989586621680821965 :: a ~> Bool) | |
| type Apply (AllSym0 :: TyFun (a ~> Bool) (t a ~> Bool) -> Type) (a6989586621680821956 :: a ~> Bool) | |
| type Apply (FindSym0 :: TyFun (a ~> Bool) (t a ~> Maybe a) -> Type) (a6989586621680821889 :: a ~> Bool) | |
| type Apply (Let6989586621679989623GoSym0 :: TyFun (k1 ~> Bool) (TyFun (k1 ~> k1) (TyFun k2 (TyFun k1 k1 -> Type) -> Type) -> Type) -> Type) (p6989586621679989620 :: k1 ~> Bool) | |
Defined in Data.Singletons.Prelude.Base | |
| type Apply (Lambda_6989586621681500596Sym0 :: TyFun (k1 ~> Bool) (TyFun k (TyFun k1 (m k1) -> Type) -> Type) -> Type) (p6989586621681500594 :: k1 ~> Bool) | |
| type Apply (Lambda_6989586621681500758Sym0 :: TyFun (k2 ~> f Bool) (TyFun k3 (TyFun k2 (f [k2] ~> f [k2]) -> Type) -> Type) -> Type) (p6989586621681500756 :: k2 ~> f Bool) | |
Defined in Data.Singletons.Prelude.Monad | |
| type Apply (Lambda_6989586621680378950Sym0 :: TyFun (b ~> (a ~> Bool)) (TyFun k1 (TyFun k2 (TyFun a (TyFun [a] (TyFun b (m b) -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) (eq6989586621680378942 :: b ~> (a ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Lambda_6989586621680378950Sym0 :: TyFun (b ~> (a ~> Bool)) (TyFun k1 (TyFun k2 (TyFun a (TyFun [a] (TyFun b (m b) -> Type) -> Type) -> Type) -> Type) -> Type) -> Type) (eq6989586621680378942 :: b ~> (a ~> Bool)) = Lambda_6989586621680378950Sym1 eq6989586621680378942 :: TyFun k1 (TyFun k2 (TyFun a (TyFun [a] (TyFun b (m b) -> Type) -> Type) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym2 x6989586621680378899 xs6989586621680378900 :: TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) (p6989586621680378895 :: k1 ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378901Scrutinee_6989586621680375080Sym2 x6989586621680378899 xs6989586621680378900 :: TyFun (k1 ~> Bool) (TyFun k Bool -> Type) -> Type) (p6989586621680378895 :: k1 ~> Bool) = Let6989586621680378901Scrutinee_6989586621680375080Sym3 x6989586621680378899 xs6989586621680378900 p6989586621680378895 :: TyFun k Bool -> Type | |
| type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym3 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 :: TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) (eq6989586621680378600 :: k1 ~> (k1 ~> Bool)) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (Let6989586621680378609Scrutinee_6989586621680375108Sym3 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 :: TyFun (k1 ~> (k1 ~> Bool)) (TyFun k3 Bool -> Type) -> Type) (eq6989586621680378600 :: k1 ~> (k1 ~> Bool)) = Let6989586621680378609Scrutinee_6989586621680375108Sym4 y6989586621680378606 ys6989586621680378607 xs6989586621680378608 eq6989586621680378600 :: TyFun k3 Bool -> Type | |
Arbitrary precision integers. In contrast with fixed-size integral types
such as Int, the Integer type represents the entire infinite range of
integers.
For more information about this type's representation, see the comments in its implementation.
Instances
Type representing arbitrary-precision non-negative integers.
>>>2^100 :: Natural1267650600228229401496703205376
Operations whose result would be negative throw
(Underflow :: ArithException)
>>>-1 :: Natural*** Exception: arithmetic underflow
Since: base-4.8.0.0
Instances
The Maybe type encapsulates an optional value. A value of type
Maybe aa (represented as Just aNothing). Using Maybe is a good way to
deal with errors or exceptional cases without resorting to drastic
measures such as error.
The Maybe type is also a monad. It is a simple kind of error
monad, where all errors are represented by Nothing. A richer
error monad can be built using the Either type.
Instances
| Monad Maybe | Since: base-2.1 |
| Functor Maybe | Since: base-2.1 |
| MonadFail Maybe | Since: base-4.9.0.0 |
Defined in Control.Monad.Fail | |
| Applicative Maybe | Since: base-2.1 |
| Foldable Maybe | Since: base-2.1 |
Defined in Data.Foldable Methods fold :: Monoid m => Maybe m -> m # foldMap :: Monoid m => (a -> m) -> Maybe a -> m # foldMap' :: Monoid m => (a -> m) -> Maybe a -> m # foldr :: (a -> b -> b) -> b -> Maybe a -> b # foldr' :: (a -> b -> b) -> b -> Maybe a -> b # foldl :: (b -> a -> b) -> b -> Maybe a -> b # foldl' :: (b -> a -> b) -> b -> Maybe a -> b # foldr1 :: (a -> a -> a) -> Maybe a -> a # foldl1 :: (a -> a -> a) -> Maybe a -> a # elem :: Eq a => a -> Maybe a -> Bool # maximum :: Ord a => Maybe a -> a # minimum :: Ord a => Maybe a -> a # | |
| Traversable Maybe | Since: base-2.1 |
| MonadPlus Maybe | Since: base-2.1 |
| ToJSON1 Maybe | |
Defined in Data.Aeson.Types.ToJSON Methods liftToJSON :: (a -> Value) -> ([a] -> Value) -> Maybe a -> Value # liftToJSONList :: (a -> Value) -> ([a] -> Value) -> [Maybe a] -> Value # liftToEncoding :: (a -> Encoding) -> ([a] -> Encoding) -> Maybe a -> Encoding # liftToEncodingList :: (a -> Encoding) -> ([a] -> Encoding) -> [Maybe a] -> Encoding # | |
| Alternative Maybe | Since: base-2.1 |
| Eq1 Maybe | Since: base-4.9.0.0 |
| Ord1 Maybe | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes | |
| Read1 Maybe | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes | |
| Show1 Maybe | Since: base-4.9.0.0 |
| MonadFailure Maybe | |
| NFData1 Maybe | Since: deepseq-1.4.3.0 |
Defined in Control.DeepSeq | |
| MonadThrow Maybe | |
Defined in Control.Monad.Catch | |
| Hashable1 Maybe | |
Defined in Data.Hashable.Class | |
| InjValue Maybe | |
Defined in Named.Internal | |
| PTraversable Maybe | |
| STraversable Maybe | |
Defined in Data.Singletons.Prelude.Traversable Methods sTraverse :: forall a (f :: Type -> Type) b (t1 :: a ~> f b) (t2 :: Maybe a). SApplicative f => Sing t1 -> Sing t2 -> Sing (Apply (Apply TraverseSym0 t1) t2) # sSequenceA :: forall (f :: Type -> Type) a (t1 :: Maybe (f a)). SApplicative f => Sing t1 -> Sing (Apply SequenceASym0 t1) # sMapM :: forall a (m :: Type -> Type) b (t1 :: a ~> m b) (t2 :: Maybe a). SMonad m => Sing t1 -> Sing t2 -> Sing (Apply (Apply MapMSym0 t1) t2) # sSequence :: forall (m :: Type -> Type) a (t1 :: Maybe (m a)). SMonad m => Sing t1 -> Sing (Apply SequenceSym0 t1) # | |
| PFoldable Maybe | |
| SFoldable Maybe | |
Defined in Data.Singletons.Prelude.Foldable Methods sFold :: forall m (t1 :: Maybe m). SMonoid m => Sing t1 -> Sing (Apply FoldSym0 t1) # sFoldMap :: forall a m (t1 :: a ~> m) (t2 :: Maybe a). SMonoid m => Sing t1 -> Sing t2 -> Sing (Apply (Apply FoldMapSym0 t1) t2) # sFoldr :: forall a b (t1 :: a ~> (b ~> b)) (t2 :: b) (t3 :: Maybe a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply FoldrSym0 t1) t2) t3) # sFoldr' :: forall a b (t1 :: a ~> (b ~> b)) (t2 :: b) (t3 :: Maybe a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply Foldr'Sym0 t1) t2) t3) # sFoldl :: forall b a (t1 :: b ~> (a ~> b)) (t2 :: b) (t3 :: Maybe a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply FoldlSym0 t1) t2) t3) # sFoldl' :: forall b a (t1 :: b ~> (a ~> b)) (t2 :: b) (t3 :: Maybe a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply Foldl'Sym0 t1) t2) t3) # sFoldr1 :: forall a (t1 :: a ~> (a ~> a)) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply Foldr1Sym0 t1) t2) # sFoldl1 :: forall a (t1 :: a ~> (a ~> a)) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply Foldl1Sym0 t1) t2) # sToList :: forall a (t1 :: Maybe a). Sing t1 -> Sing (Apply ToListSym0 t1) # sNull :: forall a (t1 :: Maybe a). Sing t1 -> Sing (Apply NullSym0 t1) # sLength :: forall a (t1 :: Maybe a). Sing t1 -> Sing (Apply LengthSym0 t1) # sElem :: forall a (t1 :: a) (t2 :: Maybe a). SEq a => Sing t1 -> Sing t2 -> Sing (Apply (Apply ElemSym0 t1) t2) # sMaximum :: forall a (t1 :: Maybe a). SOrd a => Sing t1 -> Sing (Apply MaximumSym0 t1) # sMinimum :: forall a (t1 :: Maybe a). SOrd a => Sing t1 -> Sing (Apply MinimumSym0 t1) # sSum :: forall a (t1 :: Maybe a). SNum a => Sing t1 -> Sing (Apply SumSym0 t1) # sProduct :: forall a (t1 :: Maybe a). SNum a => Sing t1 -> Sing (Apply ProductSym0 t1) # | |
| SMonadFail Maybe | |
| PFunctor Maybe | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| PApplicative Maybe | |
| PMonad Maybe | |
| SFunctor Maybe | |
| SApplicative Maybe | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods sPure :: forall a (t :: a). Sing t -> Sing (Apply PureSym0 t) # (%<*>) :: forall a b (t1 :: Maybe (a ~> b)) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<*>@#@$) t1) t2) # sLiftA2 :: forall a b c (t1 :: a ~> (b ~> c)) (t2 :: Maybe a) (t3 :: Maybe b). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply LiftA2Sym0 t1) t2) t3) # (%*>) :: forall a b (t1 :: Maybe a) (t2 :: Maybe b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (*>@#@$) t1) t2) # (%<*) :: forall a b (t1 :: Maybe a) (t2 :: Maybe b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<*@#@$) t1) t2) # | |
| SMonad Maybe | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods (%>>=) :: forall a b (t1 :: Maybe a) (t2 :: a ~> Maybe b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>>=@#@$) t1) t2) # (%>>) :: forall a b (t1 :: Maybe a) (t2 :: Maybe b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>>@#@$) t1) t2) # sReturn :: forall a (t :: a). Sing t -> Sing (Apply ReturnSym0 t) # | |
| SAlternative Maybe | |
| SMonadPlus Maybe | |
| KnownNamedFunctor Maybe | |
| LorentzFunctor Maybe Source # | |
Defined in Lorentz.Instr | |
| (Selector s, GToJSON' enc arity (K1 i (Maybe a) :: Type -> Type), KeyValuePair enc pairs, Monoid pairs) => RecordToPairs enc pairs arity (S1 s (K1 i (Maybe a) :: Type -> Type)) | |
Defined in Data.Aeson.Types.ToJSON | |
| Lift a => Lift (Maybe a :: Type) | |
| () :=> (Functor Maybe) | |
| () :=> (Applicative Maybe) | |
Defined in Data.Constraint Methods ins :: () :- Applicative Maybe # | |
| () :=> (MonadPlus Maybe) | |
| () :=> (Alternative Maybe) | |
Defined in Data.Constraint Methods ins :: () :- Alternative Maybe # | |
| Eq a => Eq (Maybe a) | Since: base-2.1 |
| Ord a => Ord (Maybe a) | Since: base-2.1 |
| Read a => Read (Maybe a) | Since: base-2.1 |
| Show a => Show (Maybe a) | Since: base-2.1 |
| Generic (Maybe a) | Since: base-4.6.0.0 |
| Semigroup a => Semigroup (Maybe a) | Since: base-4.9.0.0 |
| Semigroup a => Monoid (Maybe a) | Lift a semigroup into Since 4.11.0: constraint on inner Since: base-2.1 |
| Hashable a => Hashable (Maybe a) | |
Defined in Data.Hashable.Class | |
| ToJSON a => ToJSON (Maybe a) | |
Defined in Data.Aeson.Types.ToJSON | |
| NFData a => NFData (Maybe a) | |
Defined in Control.DeepSeq | |
| Default (Maybe a) | |
Defined in Data.Default.Class | |
| Buildable a => Buildable (Maybe a) | |
Defined in Formatting.Buildable | |
| Ixed (Maybe a) | |
Defined in Control.Lens.At | |
| At (Maybe a) | |
| Semiring a => Semiring (Maybe a) | |
| PMonoid (Maybe a) | |
| SSemigroup a => SMonoid (Maybe a) | |
| PShow (Maybe a) | |
| SShow a => SShow (Maybe a) | |
Defined in Data.Singletons.Prelude.Show Methods sShowsPrec :: forall (t1 :: Nat) (t2 :: Maybe a) (t3 :: Symbol). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply ShowsPrecSym0 t1) t2) t3) # sShow_ :: forall (t :: Maybe a). Sing t -> Sing (Apply Show_Sym0 t) # sShowList :: forall (t1 :: [Maybe a]) (t2 :: Symbol). Sing t1 -> Sing t2 -> Sing (Apply (Apply ShowListSym0 t1) t2) # | |
| PSemigroup (Maybe a) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| SSemigroup a => SSemigroup (Maybe a) | |
| POrd (Maybe a) | |
| SOrd a => SOrd (Maybe a) | |
Defined in Data.Singletons.Prelude.Ord Methods sCompare :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply CompareSym0 t1) t2) # (%<) :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<@#@$) t1) t2) # (%<=) :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<=@#@$) t1) t2) # (%>) :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>@#@$) t1) t2) # (%>=) :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>=@#@$) t1) t2) # sMax :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply MaxSym0 t1) t2) # sMin :: forall (t1 :: Maybe a) (t2 :: Maybe a). Sing t1 -> Sing t2 -> Sing (Apply (Apply MinSym0 t1) t2) # | |
| SEq a => SEq (Maybe a) | |
| PEq (Maybe a) | |
| (TypeError (DisallowInstance "Maybe") :: Constraint) => Container (Maybe a) | |
Defined in Universum.Container.Class Methods toList :: Maybe a -> [Element (Maybe a)] # foldr :: (Element (Maybe a) -> b -> b) -> b -> Maybe a -> b # foldl :: (b -> Element (Maybe a) -> b) -> b -> Maybe a -> b # foldl' :: (b -> Element (Maybe a) -> b) -> b -> Maybe a -> b # elem :: Element (Maybe a) -> Maybe a -> Bool # maximum :: Maybe a -> Element (Maybe a) # minimum :: Maybe a -> Element (Maybe a) # foldMap :: Monoid m => (Element (Maybe a) -> m) -> Maybe a -> m # fold :: Maybe a -> Element (Maybe a) # foldr' :: (Element (Maybe a) -> b -> b) -> b -> Maybe a -> b # foldr1 :: (Element (Maybe a) -> Element (Maybe a) -> Element (Maybe a)) -> Maybe a -> Element (Maybe a) # foldl1 :: (Element (Maybe a) -> Element (Maybe a) -> Element (Maybe a)) -> Maybe a -> Element (Maybe a) # notElem :: Element (Maybe a) -> Maybe a -> Bool # all :: (Element (Maybe a) -> Bool) -> Maybe a -> Bool # any :: (Element (Maybe a) -> Bool) -> Maybe a -> Bool # find :: (Element (Maybe a) -> Bool) -> Maybe a -> Maybe (Element (Maybe a)) # | |
| Pretty a => Pretty (Maybe a) | |
Defined in Text.PrettyPrint.Leijen.Text | |
| SingKind a => SingKind (Maybe a) | Since: base-4.9.0.0 |
Defined in GHC.Generics Associated Types type DemoteRep (Maybe a) | |
| PolyTypeHasDocC '[a] => TypeHasDoc (Maybe a) | |
Defined in Michelson.Typed.Haskell.Doc Associated Types type TypeDocFieldDescriptions (Maybe a) :: FieldDescriptions # Methods typeDocName :: Proxy (Maybe a) -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy (Maybe a) -> WithinParens -> Markdown # typeDocDependencies :: Proxy (Maybe a) -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep (Maybe a) # typeDocMichelsonRep :: TypeDocMichelsonRep (Maybe a) # | |
| IsoValue a => IsoValue (Maybe a) | |
| HasAnnotation a => HasAnnotation (Maybe a) Source # | |
Defined in Lorentz.Annotation Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT (Maybe a)) Source # | |
| Generic1 Maybe | Since: base-4.6.0.0 |
| PMonadFail Maybe | |
Defined in Data.Singletons.Prelude.Monad.Fail | |
| PAlternative Maybe | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| PMonadPlus Maybe | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| IsoHKD Maybe (a :: Type) | |
| SDecide a => TestCoercion (SMaybe :: Maybe a -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| SDecide a => TestEquality (SMaybe :: Maybe a -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| (Eq a) :=> (Eq (Maybe a)) | |
| (Ord a) :=> (Ord (Maybe a)) | |
| (Read a) :=> (Read (Maybe a)) | |
| (Show a) :=> (Show (Maybe a)) | |
| (Semigroup a) :=> (Semigroup (Maybe a)) | |
| (Monoid a) :=> (Monoid (Maybe a)) | |
| SingI ('Nothing :: Maybe a) | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| Each (Maybe a) (Maybe b) a b | |
| CanCastTo a b => CanCastTo (Maybe a :: Type) (Maybe b :: Type) Source # | |
| SingI a2 => SingI ('Just a2 :: Maybe a1) | Since: base-4.9.0.0 |
Defined in GHC.Generics | |
| SuppressUnusedWarnings (Fail_6989586621680155600Sym0 :: TyFun [Char] (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Fail Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (CatMaybesSym0 :: TyFun [Maybe a] [a] -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ListToMaybeSym0 :: TyFun [a] (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (StripPrefixSym0 :: TyFun [a] ([a] ~> Maybe [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072421Sym0 :: TyFun (Maybe a) (Maybe a ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MaybeToListSym0 :: TyFun (Maybe a) [a] -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FromJustSym0 :: TyFun (Maybe a) a -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MinInternalSym0 :: TyFun (Maybe a) (MinInternal a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MaxInternalSym0 :: TyFun (Maybe a) (MaxInternal a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621679847835Sym0 :: TyFun (Maybe a) (Maybe a ~> Ordering) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680240170Sym0 :: TyFun (Maybe a) (Maybe a ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (OptionSym0 :: TyFun (Maybe a) (Option a) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (LastSym0 :: TyFun (Maybe a) (Last a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FirstSym0 :: TyFun (Maybe a) (First a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ShowsPrec_6989586621680653283Sym0 :: TyFun Nat (Maybe a ~> (Symbol ~> Symbol)) -> Type) | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Pure_6989586621680072163Sym0 :: TyFun a (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680072430LSym0 :: TyFun k1 (Maybe k1) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FromMaybeSym0 :: TyFun a (Maybe a ~> a) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ElemIndexSym0 :: TyFun a ([a] ~> Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (JustSym0 :: TyFun a (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Instances Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GetOptionSym0 :: TyFun (Option a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GetFirstSym0 :: TyFun (First a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GetLastSym0 :: TyFun (Last a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindIndexSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GetMaxInternalSym0 :: TyFun (MaxInternal a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (GetMinInternalSym0 :: TyFun (MinInternal a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SingI (CatMaybesSym0 :: TyFun [Maybe a] [a] -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing CatMaybesSym0 # | |
| SingI (ListToMaybeSym0 :: TyFun [a] (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing ListToMaybeSym0 # | |
| SingI (MaybeToListSym0 :: TyFun (Maybe a) [a] -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing MaybeToListSym0 # | |
| SingI (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing IsNothingSym0 # | |
| SingI (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing IsJustSym0 # | |
| SingI (FromJustSym0 :: TyFun (Maybe a) a -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing FromJustSym0 # | |
| SingI (MinInternalSym0 :: TyFun (Maybe a) (MinInternal a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SingI (MaxInternalSym0 :: TyFun (Maybe a) (MaxInternal a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SingI (OptionSym0 :: TyFun (Maybe a) (Option a) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods sing :: Sing OptionSym0 # | |
| SingI (LastSym0 :: TyFun (Maybe a) (Last a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid | |
| SingI (FirstSym0 :: TyFun (Maybe a) (First a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid | |
| SingI (FromMaybeSym0 :: TyFun a (Maybe a ~> a) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing FromMaybeSym0 # | |
| SEq a => SingI (ElemIndexSym0 :: TyFun a ([a] ~> Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing ElemIndexSym0 # | |
| SingI (JustSym0 :: TyFun a (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| SingI (GetOptionSym0 :: TyFun (Option a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods sing :: Sing GetOptionSym0 # | |
| SingI (GetFirstSym0 :: TyFun (First a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods sing :: Sing GetFirstSym0 # | |
| SingI (GetLastSym0 :: TyFun (Last a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods sing :: Sing GetLastSym0 # | |
| SingI (FindSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI (FindIndexSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing FindIndexSym0 # | |
| SingI (GetMaxInternalSym0 :: TyFun (MaxInternal a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SingI (GetMinInternalSym0 :: TyFun (MinInternal a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SuppressUnusedWarnings (StripPrefixSym1 a6989586621680498340 :: TyFun [a] (Maybe [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindSym1 a6989586621680379018 :: TyFun [a] (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindIndexSym1 a6989586621680378991 :: TyFun [a] (Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ElemIndexSym1 a6989586621680379009 :: TyFun [a] (Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ShowsPrec_6989586621680653283Sym1 a6989586621680653293 :: TyFun (Maybe a) (Symbol ~> Symbol) -> Type) | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072421Sym1 a6989586621680072426 :: TyFun (Maybe a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072345Sym0 :: TyFun (Maybe a) (Maybe b ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072334Sym0 :: TyFun (Maybe a) ((a ~> Maybe b) ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072200Sym0 :: TyFun (Maybe a) (Maybe b ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FromMaybeSym1 a6989586621679958789 :: TyFun (Maybe a) a -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621679847835Sym1 a6989586621679847840 :: TyFun (Maybe a) Ordering -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680240170Sym1 a6989586621680240175 :: TyFun (Maybe a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072173Sym0 :: TyFun (Maybe (a ~> b)) (Maybe a ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (OptionalSym0 :: TyFun (f a) (f (Maybe a)) -> Type) | |
Defined in Data.Singletons.Prelude.Applicative Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072052Sym0 :: TyFun a (Maybe b ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Maybe_Sym0 :: TyFun b ((a ~> b) ~> (Maybe a ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (LookupSym0 :: TyFun a ([(a, b)] ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822397MkJustSym0 :: TyFun k (TyFun a6989586621680821555 (Maybe a6989586621680821555) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822382MkJustSym0 :: TyFun k (TyFun a6989586621680821554 (Maybe a6989586621680821554) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813466NSym0 :: TyFun k (TyFun k1 (Maybe k1) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813466MSym0 :: TyFun k1 (TyFun k (Maybe k1) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813442NSym0 :: TyFun k (TyFun k1 (Maybe k1) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813442MSym0 :: TyFun k1 (TyFun k (Maybe k1) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fmap_6989586621680072040Sym0 :: TyFun (a ~> b) (Maybe a ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MapMaybeSym0 :: TyFun (a ~> Maybe b) ([a] ~> [b]) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (UnfoldrSym0 :: TyFun (b ~> Maybe (a, b)) (b ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822439Sym0 :: TyFun (a ~> (b ~> b)) (b ~> (Maybe a ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl_6989586621680822455Sym0 :: TyFun (b ~> (a ~> b)) (b ~> (Maybe a ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FoldMap_6989586621680822423Sym0 :: TyFun (a ~> m) (Maybe a ~> m) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindSym0 :: TyFun (a ~> Bool) (t a ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SingI d => SingI (FindSym1 d :: TyFun [a] (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| SingI d => SingI (FindIndexSym1 d :: TyFun [a] (Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing (FindIndexSym1 d) # | |
| (SEq a, SingI d) => SingI (ElemIndexSym1 d :: TyFun [a] (Maybe Nat) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing (ElemIndexSym1 d) # | |
| SingI d => SingI (FromMaybeSym1 d :: TyFun (Maybe a) a -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing (FromMaybeSym1 d) # | |
| SAlternative f => SingI (OptionalSym0 :: TyFun (f a) (f (Maybe a)) -> Type) | |
Defined in Data.Singletons.Prelude.Applicative Methods sing :: Sing OptionalSym0 # | |
| SingI (Maybe_Sym0 :: TyFun b ((a ~> b) ~> (Maybe a ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing Maybe_Sym0 # | |
| SEq a => SingI (LookupSym0 :: TyFun a ([(a, b)] ~> Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing LookupSym0 # | |
| SingI (MapMaybeSym0 :: TyFun (a ~> Maybe b) ([a] ~> [b]) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing MapMaybeSym0 # | |
| SingI (UnfoldrSym0 :: TyFun (b ~> Maybe (a, b)) (b ~> [a]) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing UnfoldrSym0 # | |
| SFoldable t => SingI (FindSym0 :: TyFun (a ~> Bool) (t a ~> Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SuppressUnusedWarnings (LookupSym1 a6989586621680378716 :: TyFun [(a, b)] (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072345Sym1 a6989586621680072354 :: TyFun (Maybe b) (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072200Sym1 a6989586621680072205 :: TyFun (Maybe b) (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072173Sym1 a6989586621680072178 :: TyFun (Maybe a) (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072052Sym1 a6989586621680072057 :: TyFun (Maybe b) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fmap_6989586621680072040Sym1 a6989586621680072045 :: TyFun (Maybe a) (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FoldMap_6989586621680822423Sym1 a6989586621680822432 :: TyFun (Maybe a) m -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822397MkJustSym1 a_69895866216808223916989586621680822396 :: TyFun a6989586621680821555 (Maybe a6989586621680821555) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822382MkJustSym1 a_69895866216808223766989586621680822381 :: TyFun a6989586621680821554 (Maybe a6989586621680821554) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813466NSym1 x6989586621680813464 :: TyFun k1 (Maybe k1) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813466MSym1 x6989586621680813464 :: TyFun k (Maybe k1) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813442NSym1 x6989586621680813440 :: TyFun k1 (Maybe k1) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680813442MSym1 x6989586621680813440 :: TyFun k (Maybe k1) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822439Sym1 a6989586621680822445 :: TyFun b (Maybe a ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl_6989586621680822455Sym1 a6989586621680822461 :: TyFun b (Maybe a ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FindSym1 a6989586621680821889 :: TyFun (t a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680700471Sym0 :: TyFun k (TyFun (k1 ~> Last a) (TyFun k1 (Maybe a) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680700392Sym0 :: TyFun k (TyFun (k1 ~> First a) (TyFun k1 (Maybe a) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Traverse_6989586621681087642Sym0 :: TyFun (a ~> f b) (Maybe a ~> f (Maybe b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072334Sym1 a6989586621680072339 :: TyFun (a ~> Maybe b) (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (LiftA2_6989586621680072186Sym0 :: TyFun (a ~> (b ~> c)) (Maybe a ~> (Maybe b ~> Maybe c)) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Maybe_Sym1 a6989586621679957223 :: TyFun (a ~> b) (Maybe a ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621679958764RsSym0 :: TyFun (a ~> Maybe k1) (TyFun k (TyFun [a] [k1] -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822304MfSym0 :: TyFun (k2 ~> (k3 ~> k3)) (TyFun k (TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822283MfSym0 :: TyFun (k2 ~> (k3 ~> k2)) (TyFun k (TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| (SEq a, SingI d) => SingI (LookupSym1 d :: TyFun [(a, b)] (Maybe b) -> Type) | |
Defined in Data.Singletons.Prelude.List.Internal Methods sing :: Sing (LookupSym1 d) # | |
| (SFoldable t, SingI d) => SingI (FindSym1 d :: TyFun (t a) (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable | |
| SingI d => SingI (Maybe_Sym1 d :: TyFun (a ~> b) (Maybe a ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing (Maybe_Sym1 d) # | |
| SuppressUnusedWarnings (Traverse_6989586621681087642Sym1 a6989586621681087647 :: TyFun (Maybe a) (f (Maybe b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (LiftA2_6989586621680072186Sym1 a6989586621680072192 :: TyFun (Maybe a) (Maybe b ~> Maybe c) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Maybe_Sym2 a6989586621679957223 a6989586621679957224 :: TyFun (Maybe a) b -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822439Sym2 a6989586621680822445 a6989586621680822446 :: TyFun (Maybe a) b -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl_6989586621680822455Sym2 a6989586621680822461 a6989586621680822462 :: TyFun (Maybe a) b -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822304MfSym1 f6989586621680822302 :: TyFun k (TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822283MfSym1 f6989586621680822281 :: TyFun k (TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680700471Sym1 a6989586621680700469 :: TyFun (k1 ~> Last a) (TyFun k1 (Maybe a) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680700392Sym1 a6989586621680700390 :: TyFun (k1 ~> First a) (TyFun k1 (Maybe a) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| (SingI d1, SingI d2) => SingI (Maybe_Sym2 d1 d2 :: TyFun (Maybe a) b -> Type) | |
Defined in Data.Singletons.Prelude.Maybe Methods sing :: Sing (Maybe_Sym2 d1 d2) # | |
| SuppressUnusedWarnings (LiftA2_6989586621680072186Sym2 a6989586621680072192 a6989586621680072193 :: TyFun (Maybe b) (Maybe c) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822304MfSym2 f6989586621680822302 xs6989586621680822303 :: TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822283MfSym2 f6989586621680822281 xs6989586621680822282 :: TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680700471Sym2 a6989586621680700469 k6989586621680700470 :: TyFun k1 (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Lambda_6989586621680700392Sym2 a6989586621680700390 k6989586621680700391 :: TyFun k1 (Maybe a) -> Type) | |
Defined in Data.Singletons.Prelude.Monoid Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822283MfSym3 f6989586621680822281 xs6989586621680822282 a6989586621680822284 :: TyFun (Maybe k3) (Maybe k2) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680822304MfSym3 f6989586621680822302 xs6989586621680822303 a6989586621680822305 :: TyFun k3 (Maybe k3) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| IsoValue a => IsoValue (NamedF Maybe a name) | |
| (HasAnnotation (Maybe a), KnownSymbol name) => HasAnnotation (NamedF Maybe a name) Source # | |
Defined in Lorentz.Annotation Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT (NamedF Maybe a name)) Source # | |
| Wrappable (NamedF Maybe a name) Source # | |
Defined in Lorentz.Wrappable Associated Types type Unwrappable (NamedF Maybe a name) Source # | |
| type Failure Maybe | |
Defined in Basement.Monad | |
| type Product (arg :: Maybe a) | |
| type Sum (arg :: Maybe a) | |
| type Minimum (arg :: Maybe a) | |
| type Maximum (arg :: Maybe a) | |
| type Length (arg :: Maybe a) | |
| type Null (arg :: Maybe a) | |
| type ToList (arg :: Maybe a) | |
| type Fold (arg :: Maybe m) | |
| type Pure (a :: k1) | |
| type Return (arg :: a) | |
| type Sequence (arg :: Maybe (m a)) | |
| type SequenceA (arg :: Maybe (f a)) | |
| type Elem (arg1 :: a) (arg2 :: Maybe a) | |
| type Foldl1 (arg1 :: a ~> (a ~> a)) (arg2 :: Maybe a) | |
| type Foldr1 (arg1 :: a ~> (a ~> a)) (arg2 :: Maybe a) | |
| type FoldMap (a2 :: a1 ~> k2) (a3 :: Maybe a1) | |
| type (a1 :: k1) <$ (a2 :: Maybe b) | |
| type Fmap (a2 :: a1 ~> b) (a3 :: Maybe a1) | |
| type (arg1 :: Maybe a) <* (arg2 :: Maybe b) | |
| type (a2 :: Maybe a1) *> (a3 :: Maybe b) | |
| type (a2 :: Maybe (a1 ~> b)) <*> (a3 :: Maybe a1) | |
| type (a2 :: Maybe a1) >> (a3 :: Maybe b) | |
| type (a2 :: Maybe a1) >>= (a3 :: a1 ~> Maybe b) | |
| type MapM (arg1 :: a ~> m b) (arg2 :: Maybe a) | |
| type Traverse (a2 :: a1 ~> f b) (a3 :: Maybe a1) | |
| type Foldl' (arg1 :: b ~> (a ~> b)) (arg2 :: b) (arg3 :: Maybe a) | |
| type Foldl (a2 :: k2 ~> (a1 ~> k2)) (a3 :: k2) (a4 :: Maybe a1) | |
| type Foldr' (arg1 :: a ~> (b ~> b)) (arg2 :: b) (arg3 :: Maybe a) | |
| type Foldr (a2 :: a1 ~> (k2 ~> k2)) (a3 :: k2) (a4 :: Maybe a1) | |
| type LiftA2 (a2 :: a1 ~> (b ~> c)) (a3 :: Maybe a1) (a4 :: Maybe b) | |
| type Apply (Pure_6989586621680072163Sym0 :: TyFun a (Maybe a) -> Type) (a6989586621680072169 :: a) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| type Apply (Let6989586621680072430LSym0 :: TyFun k1 (Maybe k1) -> Type) (wild_69895866216800715286989586621680072429 :: k1) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| type Apply (JustSym0 :: TyFun a (Maybe a) -> Type) (a6989586621679749471 :: a) | |
| type Apply (Let6989586621680813442NSym1 x6989586621680813440 :: TyFun k1 (Maybe k1) -> Type) (y6989586621680813441 :: k1) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Let6989586621680813442MSym1 x6989586621680813440 :: TyFun k (Maybe k1) -> Type) (y6989586621680813441 :: k) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Let6989586621680813466NSym1 x6989586621680813464 :: TyFun k1 (Maybe k1) -> Type) (y6989586621680813465 :: k1) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Let6989586621680813466MSym1 x6989586621680813464 :: TyFun k (Maybe k1) -> Type) (y6989586621680813465 :: k) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Let6989586621680822382MkJustSym1 a_69895866216808223766989586621680822381 :: TyFun a6989586621680821554 (Maybe a6989586621680821554) -> Type) (a6989586621680822385 :: a6989586621680821554) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Let6989586621680822397MkJustSym1 a_69895866216808223916989586621680822396 :: TyFun a6989586621680821555 (Maybe a6989586621680821555) -> Type) (a6989586621680822400 :: a6989586621680821555) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (Lambda_6989586621680700392Sym2 a6989586621680700390 k6989586621680700391 :: TyFun k1 (Maybe a) -> Type) (x6989586621680700394 :: k1) | |
Defined in Data.Singletons.Prelude.Monoid | |
| type Apply (Lambda_6989586621680700471Sym2 a6989586621680700469 k6989586621680700470 :: TyFun k1 (Maybe a) -> Type) (x6989586621680700473 :: k1) | |
Defined in Data.Singletons.Prelude.Monoid | |
| type Apply (Let6989586621680822304MfSym3 f6989586621680822302 xs6989586621680822303 a6989586621680822305 :: TyFun k3 (Maybe k3) -> Type) (a6989586621680822306 :: k3) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (ShowsPrec_6989586621680653283Sym0 :: TyFun Nat (Maybe a ~> (Symbol ~> Symbol)) -> Type) (a6989586621680653293 :: Nat) | |
| type Apply (FromMaybeSym0 :: TyFun a (Maybe a ~> a) -> Type) (a6989586621679958789 :: a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (FromMaybeSym0 :: TyFun a (Maybe a ~> a) -> Type) (a6989586621679958789 :: a) = FromMaybeSym1 a6989586621679958789 | |
| type Apply (ElemIndexSym0 :: TyFun a ([a] ~> Maybe Nat) -> Type) (a6989586621680379009 :: a) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (ElemIndexSym0 :: TyFun a ([a] ~> Maybe Nat) -> Type) (a6989586621680379009 :: a) = ElemIndexSym1 a6989586621680379009 | |
| type Apply (TFHelper_6989586621680072052Sym0 :: TyFun a (Maybe b ~> Maybe a) -> Type) (a6989586621680072057 :: a) | |
| type Apply (Maybe_Sym0 :: TyFun b ((a ~> b) ~> (Maybe a ~> b)) -> Type) (a6989586621679957223 :: b) | |
Defined in Data.Singletons.Prelude.Maybe | |
| type Apply (LookupSym0 :: TyFun a ([(a, b)] ~> Maybe b) -> Type) (a6989586621680378716 :: a) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (LookupSym0 :: TyFun a ([(a, b)] ~> Maybe b) -> Type) (a6989586621680378716 :: a) = LookupSym1 a6989586621680378716 :: TyFun [(a, b)] (Maybe b) -> Type | |
| type Apply (Let6989586621680813442NSym0 :: TyFun k (TyFun k1 (Maybe k1) -> Type) -> Type) (x6989586621680813440 :: k) | |
| type Apply (Let6989586621680813442MSym0 :: TyFun k1 (TyFun k (Maybe k1) -> Type) -> Type) (x6989586621680813440 :: k1) | |
| type Apply (Let6989586621680813466NSym0 :: TyFun k (TyFun k1 (Maybe k1) -> Type) -> Type) (x6989586621680813464 :: k) | |
| type Apply (Let6989586621680813466MSym0 :: TyFun k1 (TyFun k (Maybe k1) -> Type) -> Type) (x6989586621680813464 :: k1) | |
| type Apply (Let6989586621680822382MkJustSym0 :: TyFun k (TyFun a6989586621680821554 (Maybe a6989586621680821554) -> Type) -> Type) (a_69895866216808223766989586621680822381 :: k) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (Let6989586621680822382MkJustSym0 :: TyFun k (TyFun a6989586621680821554 (Maybe a6989586621680821554) -> Type) -> Type) (a_69895866216808223766989586621680822381 :: k) = Let6989586621680822382MkJustSym1 a_69895866216808223766989586621680822381 :: TyFun a6989586621680821554 (Maybe a6989586621680821554) -> Type | |
| type Apply (Let6989586621680822397MkJustSym0 :: TyFun k (TyFun a6989586621680821555 (Maybe a6989586621680821555) -> Type) -> Type) (a_69895866216808223916989586621680822396 :: k) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (Let6989586621680822397MkJustSym0 :: TyFun k (TyFun a6989586621680821555 (Maybe a6989586621680821555) -> Type) -> Type) (a_69895866216808223916989586621680822396 :: k) = Let6989586621680822397MkJustSym1 a_69895866216808223916989586621680822396 :: TyFun a6989586621680821555 (Maybe a6989586621680821555) -> Type | |
| type Apply (Foldr_6989586621680822439Sym1 a6989586621680822445 :: TyFun b (Maybe a ~> b) -> Type) (a6989586621680822446 :: b) | |
| type Apply (Foldl_6989586621680822455Sym1 a6989586621680822461 :: TyFun b (Maybe a ~> b) -> Type) (a6989586621680822462 :: b) | |
| type Apply (Lambda_6989586621680700392Sym0 :: TyFun k (TyFun (k1 ~> First a) (TyFun k1 (Maybe a) -> Type) -> Type) -> Type) (a6989586621680700390 :: k) | |
Defined in Data.Singletons.Prelude.Monoid | |
| type Apply (Lambda_6989586621680700471Sym0 :: TyFun k (TyFun (k1 ~> Last a) (TyFun k1 (Maybe a) -> Type) -> Type) -> Type) (a6989586621680700469 :: k) | |
Defined in Data.Singletons.Prelude.Monoid | |
| type Apply (Let6989586621680822283MfSym1 f6989586621680822281 :: TyFun k (TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) -> Type) (xs6989586621680822282 :: k) | |
| type Apply (Let6989586621680822304MfSym1 f6989586621680822302 :: TyFun k (TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) -> Type) (xs6989586621680822303 :: k) | |
| type Apply (Let6989586621680822283MfSym2 f6989586621680822281 xs6989586621680822282 :: TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) (a6989586621680822284 :: k2) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Eval (FoldMap f ('Just x) :: a2 -> Type) | |
| type Eval (FoldMap f ('Nothing :: Maybe a1) :: a2 -> Type) | |
| type Eval (Foldr f y ('Just x) :: a2 -> Type) | |
| type Eval (Foldr f y ('Nothing :: Maybe a1) :: a2 -> Type) | |
| type Rep (Maybe a) | |
Defined in GHC.Generics | |
| type MEmpty | |
Defined in Fcf.Class.Monoid | |
| type Index (Maybe a) | |
Defined in Control.Lens.At | |
| type IxValue (Maybe a) | |
Defined in Control.Lens.At | |
| type Mempty | |
Defined in Data.Singletons.Prelude.Monoid | |
| type Sing | |
Defined in Data.Singletons.Prelude.Instances | |
| type Demote (Maybe a) | |
Defined in Data.Singletons.Prelude.Instances | |
| type Element (Maybe a) | |
Defined in Universum.Container.Class | |
| type DemoteRep (Maybe a) | |
Defined in GHC.Generics | |
| data Sing (b :: Maybe a) | |
| type TypeDocFieldDescriptions (Maybe a) | |
Defined in Michelson.Typed.Haskell.Doc | |
| type ToT (Maybe a) | |
Defined in Michelson.Typed.Haskell.Value | |
| type Rep1 Maybe | |
| type Mconcat (arg :: [Maybe a]) | |
| type Show_ (arg :: Maybe a) | |
| type Sconcat (arg :: NonEmpty (Maybe a)) | |
| type Mappend (arg1 :: Maybe a) (arg2 :: Maybe a) | |
| type ShowList (arg1 :: [Maybe a]) arg2 | |
| type (a2 :: Maybe a1) <> (a3 :: Maybe a1) | |
| type Empty | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| type Mzero | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| type Min (arg1 :: Maybe a) (arg2 :: Maybe a) | |
| type Max (arg1 :: Maybe a) (arg2 :: Maybe a) | |
| type (arg1 :: Maybe a) >= (arg2 :: Maybe a) | |
| type (arg1 :: Maybe a) > (arg2 :: Maybe a) | |
| type (arg1 :: Maybe a) <= (arg2 :: Maybe a) | |
| type (arg1 :: Maybe a) < (arg2 :: Maybe a) | |
| type Compare (a2 :: Maybe a1) (a3 :: Maybe a1) | |
| type (x :: Maybe a) /= (y :: Maybe a) | |
| type (a2 :: Maybe a1) == (b :: Maybe a1) | |
Defined in Data.Singletons.Prelude.Eq | |
| type HKD Maybe (a :: Type) | |
Defined in Data.Vinyl.XRec | |
| type ShowsPrec a2 (a3 :: Maybe a1) a4 | |
| type Fail a2 | |
| type (a2 :: Maybe a1) <|> (a3 :: Maybe a1) | |
| type Mplus (arg1 :: Maybe a) (arg2 :: Maybe a) | |
| type (a2 :: Maybe a1) <> ('Nothing :: Maybe a1) | |
Defined in Fcf.Class.Monoid | |
| type Apply (FromJustSym0 :: TyFun (Maybe a) a -> Type) (a6989586621679958799 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (FromJustSym0 :: TyFun (Maybe a) a -> Type) (a6989586621679958799 :: Maybe a) = FromJustSym1 a6989586621679958799 | |
| type Apply (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958803 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (IsNothingSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958803 :: Maybe a) = IsNothingSym1 a6989586621679958803 | |
| type Apply (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958806 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (IsJustSym0 :: TyFun (Maybe a) Bool -> Type) (a6989586621679958806 :: Maybe a) = IsJustSym1 a6989586621679958806 | |
| type Apply (FromMaybeSym1 a6989586621679958789 :: TyFun (Maybe a) a -> Type) (a6989586621679958790 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (FromMaybeSym1 a6989586621679958789 :: TyFun (Maybe a) a -> Type) (a6989586621679958790 :: Maybe a) = FromMaybeSym2 a6989586621679958789 a6989586621679958790 | |
| type Apply (Compare_6989586621679847835Sym1 a6989586621679847840 :: TyFun (Maybe a) Ordering -> Type) (a6989586621679847841 :: Maybe a) | |
| type Apply (FoldMap_6989586621680822423Sym1 a6989586621680822432 :: TyFun (Maybe a) m -> Type) (a6989586621680822433 :: Maybe a) | |
| type Apply (Maybe_Sym2 a6989586621679957223 a6989586621679957224 :: TyFun (Maybe a) b -> Type) (a6989586621679957225 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (Maybe_Sym2 a6989586621679957223 a6989586621679957224 :: TyFun (Maybe a) b -> Type) (a6989586621679957225 :: Maybe a) = Maybe_Sym3 a6989586621679957223 a6989586621679957224 a6989586621679957225 | |
| type Apply (Foldr_6989586621680822439Sym2 a6989586621680822445 a6989586621680822446 :: TyFun (Maybe a) b -> Type) (a6989586621680822447 :: Maybe a) | |
| type Apply (Foldl_6989586621680822455Sym2 a6989586621680822461 a6989586621680822462 :: TyFun (Maybe a) b -> Type) (a6989586621680822463 :: Maybe a) | |
| type ('Nothing :: Maybe a) <> (b :: Maybe a) | |
Defined in Fcf.Class.Monoid | |
| type Apply (Fail_6989586621680155600Sym0 :: TyFun [Char] (Maybe a) -> Type) (a6989586621680155604 :: [Char]) | |
| type Apply (CatMaybesSym0 :: TyFun [Maybe a] [a] -> Type) (a6989586621679958774 :: [Maybe a]) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (CatMaybesSym0 :: TyFun [Maybe a] [a] -> Type) (a6989586621679958774 :: [Maybe a]) = CatMaybesSym1 a6989586621679958774 | |
| type Apply (ListToMaybeSym0 :: TyFun [a] (Maybe a) -> Type) (a6989586621679958780 :: [a]) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (ListToMaybeSym0 :: TyFun [a] (Maybe a) -> Type) (a6989586621679958780 :: [a]) = ListToMaybeSym1 a6989586621679958780 | |
| type Apply (MaybeToListSym0 :: TyFun (Maybe a) [a] -> Type) (a6989586621679958784 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (MaybeToListSym0 :: TyFun (Maybe a) [a] -> Type) (a6989586621679958784 :: Maybe a) = MaybeToListSym1 a6989586621679958784 | |
| type Apply (MaxInternalSym0 :: TyFun (Maybe a) (MaxInternal a) -> Type) (a6989586621680811862 :: Maybe a) | |
| type Apply (MinInternalSym0 :: TyFun (Maybe a) (MinInternal a) -> Type) (a6989586621680811865 :: Maybe a) | |
| type Apply (OptionSym0 :: TyFun (Maybe a) (Option a) -> Type) (a6989586621680249373 :: Maybe a) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal type Apply (OptionSym0 :: TyFun (Maybe a) (Option a) -> Type) (a6989586621680249373 :: Maybe a) = OptionSym1 a6989586621680249373 | |
| type Apply (FirstSym0 :: TyFun (Maybe a) (First a) -> Type) (a6989586621680694166 :: Maybe a) | |
| type Apply (LastSym0 :: TyFun (Maybe a) (Last a) -> Type) (a6989586621680694193 :: Maybe a) | |
| type Apply (GetOptionSym0 :: TyFun (Option a) (Maybe a) -> Type) (a6989586621680249376 :: Option a) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal type Apply (GetOptionSym0 :: TyFun (Option a) (Maybe a) -> Type) (a6989586621680249376 :: Option a) = GetOptionSym1 a6989586621680249376 | |
| type Apply (GetFirstSym0 :: TyFun (First a) (Maybe a) -> Type) (a6989586621680694169 :: First a) | |
Defined in Data.Singletons.Prelude.Monoid type Apply (GetFirstSym0 :: TyFun (First a) (Maybe a) -> Type) (a6989586621680694169 :: First a) = GetFirstSym1 a6989586621680694169 | |
| type Apply (GetLastSym0 :: TyFun (Last a) (Maybe a) -> Type) (a6989586621680694196 :: Last a) | |
Defined in Data.Singletons.Prelude.Monoid type Apply (GetLastSym0 :: TyFun (Last a) (Maybe a) -> Type) (a6989586621680694196 :: Last a) = GetLastSym1 a6989586621680694196 | |
| type Apply (GetMaxInternalSym0 :: TyFun (MaxInternal a) (Maybe a) -> Type) (a6989586621680811872 :: MaxInternal a) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (GetMinInternalSym0 :: TyFun (MinInternal a) (Maybe a) -> Type) (a6989586621680811868 :: MinInternal a) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Apply (FindSym1 a6989586621680379018 :: TyFun [a] (Maybe a) -> Type) (a6989586621680379019 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (FindIndexSym1 a6989586621680378991 :: TyFun [a] (Maybe Nat) -> Type) (a6989586621680378992 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (FindIndexSym1 a6989586621680378991 :: TyFun [a] (Maybe Nat) -> Type) (a6989586621680378992 :: [a]) = FindIndexSym2 a6989586621680378991 a6989586621680378992 | |
| type Apply (ElemIndexSym1 a6989586621680379009 :: TyFun [a] (Maybe Nat) -> Type) (a6989586621680379010 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (ElemIndexSym1 a6989586621680379009 :: TyFun [a] (Maybe Nat) -> Type) (a6989586621680379010 :: [a]) = ElemIndexSym2 a6989586621680379009 a6989586621680379010 | |
| type Apply (StripPrefixSym1 a6989586621680498340 :: TyFun [a] (Maybe [a]) -> Type) (a6989586621680498341 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (StripPrefixSym1 a6989586621680498340 :: TyFun [a] (Maybe [a]) -> Type) (a6989586621680498341 :: [a]) = StripPrefixSym2 a6989586621680498340 a6989586621680498341 | |
| type Apply (TFHelper_6989586621680072421Sym1 a6989586621680072426 :: TyFun (Maybe a) (Maybe a) -> Type) (a6989586621680072427 :: Maybe a) | |
| type Apply (TFHelper_6989586621680240170Sym1 a6989586621680240175 :: TyFun (Maybe a) (Maybe a) -> Type) (a6989586621680240176 :: Maybe a) | |
| type Apply (OptionalSym0 :: TyFun (f a) (f (Maybe a)) -> Type) (a6989586621681492086 :: f a) | |
Defined in Data.Singletons.Prelude.Applicative type Apply (OptionalSym0 :: TyFun (f a) (f (Maybe a)) -> Type) (a6989586621681492086 :: f a) = OptionalSym1 a6989586621681492086 | |
| type Apply (LookupSym1 a6989586621680378716 :: TyFun [(a, b)] (Maybe b) -> Type) (a6989586621680378717 :: [(a, b)]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (LookupSym1 a6989586621680378716 :: TyFun [(a, b)] (Maybe b) -> Type) (a6989586621680378717 :: [(a, b)]) = LookupSym2 a6989586621680378716 a6989586621680378717 | |
| type Apply (Fmap_6989586621680072040Sym1 a6989586621680072045 :: TyFun (Maybe a) (Maybe b) -> Type) (a6989586621680072046 :: Maybe a) | |
| type Apply (TFHelper_6989586621680072052Sym1 a6989586621680072057 :: TyFun (Maybe b) (Maybe a) -> Type) (a6989586621680072058 :: Maybe b) | |
| type Apply (TFHelper_6989586621680072173Sym1 a6989586621680072178 :: TyFun (Maybe a) (Maybe b) -> Type) (a6989586621680072179 :: Maybe a) | |
| type Apply (TFHelper_6989586621680072200Sym1 a6989586621680072205 :: TyFun (Maybe b) (Maybe b) -> Type) (a6989586621680072206 :: Maybe b) | |
| type Apply (TFHelper_6989586621680072345Sym1 a6989586621680072354 :: TyFun (Maybe b) (Maybe b) -> Type) (a6989586621680072355 :: Maybe b) | |
| type Apply (FindSym1 a6989586621680821889 :: TyFun (t a) (Maybe a) -> Type) (a6989586621680821890 :: t a) | |
| type Apply (Traverse_6989586621681087642Sym1 a6989586621681087647 :: TyFun (Maybe a) (f (Maybe b)) -> Type) (a6989586621681087648 :: Maybe a) | |
| type Apply (LiftA2_6989586621680072186Sym2 a6989586621680072192 a6989586621680072193 :: TyFun (Maybe b) (Maybe c) -> Type) (a6989586621680072194 :: Maybe b) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| type Apply (Let6989586621680822283MfSym3 f6989586621680822281 xs6989586621680822282 a6989586621680822284 :: TyFun (Maybe k3) (Maybe k2) -> Type) (a6989586621680822285 :: Maybe k3) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Eval (Init '[a2] :: Maybe [a1] -> Type) | |
| type Eval (Init ('[] :: [a]) :: Maybe [a] -> Type) | |
| type Eval (Tail (_a ': as) :: Maybe [a] -> Type) | |
| type Eval (Tail ('[] :: [a]) :: Maybe [a] -> Type) | |
| type Eval (Init (a2 ': (b ': as)) :: Maybe [a1] -> Type) | |
| type Eval (Head (a2 ': _as) :: Maybe a1 -> Type) | |
| type Eval (Head ('[] :: [a]) :: Maybe a -> Type) | |
| type Eval (Last (a2 ': (b ': as)) :: Maybe a1 -> Type) | |
| type Eval (Last '[a2] :: Maybe a1 -> Type) | |
| type Eval (Last ('[] :: [a]) :: Maybe a -> Type) | |
| type Apply (StripPrefixSym0 :: TyFun [a] ([a] ~> Maybe [a]) -> Type) (a6989586621680498340 :: [a]) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (StripPrefixSym0 :: TyFun [a] ([a] ~> Maybe [a]) -> Type) (a6989586621680498340 :: [a]) = StripPrefixSym1 a6989586621680498340 | |
| type Apply (TFHelper_6989586621680072421Sym0 :: TyFun (Maybe a) (Maybe a ~> Maybe a) -> Type) (a6989586621680072426 :: Maybe a) | |
| type Apply (Compare_6989586621679847835Sym0 :: TyFun (Maybe a) (Maybe a ~> Ordering) -> Type) (a6989586621679847840 :: Maybe a) | |
| type Apply (TFHelper_6989586621680240170Sym0 :: TyFun (Maybe a) (Maybe a ~> Maybe a) -> Type) (a6989586621680240175 :: Maybe a) | |
| type ('Just a2 :: Maybe a1) <> ('Just b :: Maybe a1) | |
| type Apply (ShowsPrec_6989586621680653283Sym1 a6989586621680653293 :: TyFun (Maybe a) (Symbol ~> Symbol) -> Type) (a6989586621680653294 :: Maybe a) | |
| type Apply (TFHelper_6989586621680072200Sym0 :: TyFun (Maybe a) (Maybe b ~> Maybe b) -> Type) (a6989586621680072205 :: Maybe a) | |
| type Apply (TFHelper_6989586621680072334Sym0 :: TyFun (Maybe a) ((a ~> Maybe b) ~> Maybe b) -> Type) (a6989586621680072339 :: Maybe a) | |
| type Apply (TFHelper_6989586621680072345Sym0 :: TyFun (Maybe a) (Maybe b ~> Maybe b) -> Type) (a6989586621680072354 :: Maybe a) | |
| type Apply (TFHelper_6989586621680072173Sym0 :: TyFun (Maybe (a ~> b)) (Maybe a ~> Maybe b) -> Type) (a6989586621680072178 :: Maybe (a ~> b)) | |
| type Apply (LiftA2_6989586621680072186Sym1 a6989586621680072192 :: TyFun (Maybe a) (Maybe b ~> Maybe c) -> Type) (a6989586621680072193 :: Maybe a) | |
| type Apply (Let6989586621680822304MfSym2 f6989586621680822302 xs6989586621680822303 :: TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) (a6989586621680822305 :: Maybe k2) | |
Defined in Data.Singletons.Prelude.Foldable | |
| type Eval (FindIndex p (a2 ': as) :: Maybe Nat -> Type) | |
| type Eval (FindIndex _p ('[] :: [a]) :: Maybe Nat -> Type) | |
| type Eval (NumIter a s :: Maybe (k, Nat) -> Type) | |
| type Eval (Find p (a2 ': as) :: Maybe a1 -> Type) | |
| type Eval (Find _p ('[] :: [a]) :: Maybe a -> Type) | |
| type Eval (Lookup a as :: Maybe b -> Type) | |
| type Eval (Map f ('Just a3) :: Maybe a2 -> Type) | |
| type Eval (Map f ('Nothing :: Maybe a) :: Maybe b -> Type) | |
| type Eval ('Just x <|> _1 :: Maybe a -> Type) | |
| type Eval (('Nothing :: Maybe a) <|> m :: Maybe a -> Type) | |
| type Apply (TFHelper_6989586621680072334Sym1 a6989586621680072339 :: TyFun (a ~> Maybe b) (Maybe b) -> Type) (a6989586621680072340 :: a ~> Maybe b) | |
| type Apply (FindSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe a) -> Type) (a6989586621680379018 :: a ~> Bool) | |
| type Apply (FindIndexSym0 :: TyFun (a ~> Bool) ([a] ~> Maybe Nat) -> Type) (a6989586621680378991 :: a ~> Bool) | |
Defined in Data.Singletons.Prelude.List.Internal | |
| type Apply (Fmap_6989586621680072040Sym0 :: TyFun (a ~> b) (Maybe a ~> Maybe b) -> Type) (a6989586621680072045 :: a ~> b) | |
| type Apply (MapMaybeSym0 :: TyFun (a ~> Maybe b) ([a] ~> [b]) -> Type) (a6989586621679958759 :: a ~> Maybe b) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (MapMaybeSym0 :: TyFun (a ~> Maybe b) ([a] ~> [b]) -> Type) (a6989586621679958759 :: a ~> Maybe b) = MapMaybeSym1 a6989586621679958759 | |
| type Apply (UnfoldrSym0 :: TyFun (b ~> Maybe (a, b)) (b ~> [a]) -> Type) (a6989586621680379408 :: b ~> Maybe (a, b)) | |
Defined in Data.Singletons.Prelude.List.Internal type Apply (UnfoldrSym0 :: TyFun (b ~> Maybe (a, b)) (b ~> [a]) -> Type) (a6989586621680379408 :: b ~> Maybe (a, b)) = UnfoldrSym1 a6989586621680379408 | |
| type Apply (FindSym0 :: TyFun (a ~> Bool) (t a ~> Maybe a) -> Type) (a6989586621680821889 :: a ~> Bool) | |
| type Apply (FoldMap_6989586621680822423Sym0 :: TyFun (a ~> m) (Maybe a ~> m) -> Type) (a6989586621680822432 :: a ~> m) | |
| type Apply (Foldr_6989586621680822439Sym0 :: TyFun (a ~> (b ~> b)) (b ~> (Maybe a ~> b)) -> Type) (a6989586621680822445 :: a ~> (b ~> b)) | |
| type Apply (Foldl_6989586621680822455Sym0 :: TyFun (b ~> (a ~> b)) (b ~> (Maybe a ~> b)) -> Type) (a6989586621680822461 :: b ~> (a ~> b)) | |
| type Apply (Traverse_6989586621681087642Sym0 :: TyFun (a ~> f b) (Maybe a ~> f (Maybe b)) -> Type) (a6989586621681087647 :: a ~> f b) | |
| type Apply (LiftA2_6989586621680072186Sym0 :: TyFun (a ~> (b ~> c)) (Maybe a ~> (Maybe b ~> Maybe c)) -> Type) (a6989586621680072192 :: a ~> (b ~> c)) | |
| type Apply (Maybe_Sym1 a6989586621679957223 :: TyFun (a ~> b) (Maybe a ~> b) -> Type) (a6989586621679957224 :: a ~> b) | |
Defined in Data.Singletons.Prelude.Maybe type Apply (Maybe_Sym1 a6989586621679957223 :: TyFun (a ~> b) (Maybe a ~> b) -> Type) (a6989586621679957224 :: a ~> b) = Maybe_Sym2 a6989586621679957223 a6989586621679957224 | |
| type Apply (Let6989586621679958764RsSym0 :: TyFun (a ~> Maybe k1) (TyFun k (TyFun [a] [k1] -> Type) -> Type) -> Type) (f6989586621679958761 :: a ~> Maybe k1) | |
| type Apply (Let6989586621680822283MfSym0 :: TyFun (k2 ~> (k3 ~> k2)) (TyFun k (TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) -> Type) -> Type) (f6989586621680822281 :: k2 ~> (k3 ~> k2)) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (Let6989586621680822283MfSym0 :: TyFun (k2 ~> (k3 ~> k2)) (TyFun k (TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) -> Type) -> Type) (f6989586621680822281 :: k2 ~> (k3 ~> k2)) = Let6989586621680822283MfSym1 f6989586621680822281 :: TyFun k (TyFun k2 (TyFun (Maybe k3) (Maybe k2) -> Type) -> Type) -> Type | |
| type Apply (Let6989586621680822304MfSym0 :: TyFun (k2 ~> (k3 ~> k3)) (TyFun k (TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) -> Type) -> Type) (f6989586621680822302 :: k2 ~> (k3 ~> k3)) | |
Defined in Data.Singletons.Prelude.Foldable type Apply (Let6989586621680822304MfSym0 :: TyFun (k2 ~> (k3 ~> k3)) (TyFun k (TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) -> Type) -> Type) (f6989586621680822302 :: k2 ~> (k3 ~> k3)) = Let6989586621680822304MfSym1 f6989586621680822302 :: TyFun k (TyFun (Maybe k2) (TyFun k3 (Maybe k3) -> Type) -> Type) -> Type | |
| type Apply (Lambda_6989586621680700392Sym1 a6989586621680700390 :: TyFun (k1 ~> First a) (TyFun k1 (Maybe a) -> Type) -> Type) (k6989586621680700391 :: k1 ~> First a) | |
| type Apply (Lambda_6989586621680700471Sym1 a6989586621680700469 :: TyFun (k1 ~> Last a) (TyFun k1 (Maybe a) -> Type) -> Type) (k6989586621680700470 :: k1 ~> Last a) | |
| type ToT (NamedF Maybe a name) | |
| type Unwrappable (NamedF Maybe a name) Source # | |
Defined in Lorentz.Wrappable | |
The Either type represents values with two possibilities: a value of
type Either a bLeft aRight b
The Either type is sometimes used to represent a value which is
either correct or an error; by convention, the Left constructor is
used to hold an error value and the Right constructor is used to
hold a correct value (mnemonic: "right" also means "correct").
Examples
The type Either String IntString or an Int. The Left constructor can be used only on
Strings, and the Right constructor can be used only on Ints:
>>>let s = Left "foo" :: Either String Int>>>sLeft "foo">>>let n = Right 3 :: Either String Int>>>nRight 3>>>:type ss :: Either String Int>>>:type nn :: Either String Int
The fmap from our Functor instance will ignore Left values, but
will apply the supplied function to values contained in a Right:
>>>let s = Left "foo" :: Either String Int>>>let n = Right 3 :: Either String Int>>>fmap (*2) sLeft "foo">>>fmap (*2) nRight 6
The Monad instance for Either allows us to chain together multiple
actions which may fail, and fail overall if any of the individual
steps failed. First we'll write a function that can either parse an
Int from a Char, or fail.
>>>import Data.Char ( digitToInt, isDigit )>>>:{let parseEither :: Char -> Either String Int parseEither c | isDigit c = Right (digitToInt c) | otherwise = Left "parse error">>>:}
The following should work, since both '1' and '2' can be
parsed as Ints.
>>>:{let parseMultiple :: Either String Int parseMultiple = do x <- parseEither '1' y <- parseEither '2' return (x + y)>>>:}
>>>parseMultipleRight 3
But the following should fail overall, since the first operation where
we attempt to parse 'm' as an Int will fail:
>>>:{let parseMultiple :: Either String Int parseMultiple = do x <- parseEither 'm' y <- parseEither '2' return (x + y)>>>:}
>>>parseMultipleLeft "parse error"
Instances
| ToJSON2 Either | |
Defined in Data.Aeson.Types.ToJSON Methods liftToJSON2 :: (a -> Value) -> ([a] -> Value) -> (b -> Value) -> ([b] -> Value) -> Either a b -> Value # liftToJSONList2 :: (a -> Value) -> ([a] -> Value) -> (b -> Value) -> ([b] -> Value) -> [Either a b] -> Value # liftToEncoding2 :: (a -> Encoding) -> ([a] -> Encoding) -> (b -> Encoding) -> ([b] -> Encoding) -> Either a b -> Encoding # liftToEncodingList2 :: (a -> Encoding) -> ([a] -> Encoding) -> (b -> Encoding) -> ([b] -> Encoding) -> [Either a b] -> Encoding # | |
| Bifunctor Either | Since: base-4.8.0.0 |
| Eq2 Either | Since: base-4.9.0.0 |
| Ord2 Either | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes | |
| Read2 Either | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes Methods liftReadsPrec2 :: (Int -> ReadS a) -> ReadS [a] -> (Int -> ReadS b) -> ReadS [b] -> Int -> ReadS (Either a b) # liftReadList2 :: (Int -> ReadS a) -> ReadS [a] -> (Int -> ReadS b) -> ReadS [b] -> ReadS [Either a b] # liftReadPrec2 :: ReadPrec a -> ReadPrec [a] -> ReadPrec b -> ReadPrec [b] -> ReadPrec (Either a b) # liftReadListPrec2 :: ReadPrec a -> ReadPrec [a] -> ReadPrec b -> ReadPrec [b] -> ReadPrec [Either a b] # | |
| Show2 Either | Since: base-4.9.0.0 |
| NFData2 Either | Since: deepseq-1.4.3.0 |
Defined in Control.DeepSeq | |
| Hashable2 Either | |
Defined in Data.Hashable.Class | |
| () :=> (Monad (Either a)) | |
| () :=> (Functor (Either a)) | |
| () :=> (Applicative (Either a)) | |
Defined in Data.Constraint Methods ins :: () :- Applicative (Either a) # | |
| (Lift a, Lift b) => Lift (Either a b :: Type) | |
| Monad (Either e) | Since: base-4.4.0.0 |
| Functor (Either a) | Since: base-3.0 |
| Applicative (Either e) | Since: base-3.0 |
| Foldable (Either a) | Since: base-4.7.0.0 |
Defined in Data.Foldable Methods fold :: Monoid m => Either a m -> m # foldMap :: Monoid m => (a0 -> m) -> Either a a0 -> m # foldMap' :: Monoid m => (a0 -> m) -> Either a a0 -> m # foldr :: (a0 -> b -> b) -> b -> Either a a0 -> b # foldr' :: (a0 -> b -> b) -> b -> Either a a0 -> b # foldl :: (b -> a0 -> b) -> b -> Either a a0 -> b # foldl' :: (b -> a0 -> b) -> b -> Either a a0 -> b # foldr1 :: (a0 -> a0 -> a0) -> Either a a0 -> a0 # foldl1 :: (a0 -> a0 -> a0) -> Either a a0 -> a0 # toList :: Either a a0 -> [a0] # length :: Either a a0 -> Int # elem :: Eq a0 => a0 -> Either a a0 -> Bool # maximum :: Ord a0 => Either a a0 -> a0 # minimum :: Ord a0 => Either a a0 -> a0 # | |
| Traversable (Either a) | Since: base-4.7.0.0 |
Defined in Data.Traversable | |
| ToJSON a => ToJSON1 (Either a) | |
Defined in Data.Aeson.Types.ToJSON Methods liftToJSON :: (a0 -> Value) -> ([a0] -> Value) -> Either a a0 -> Value # liftToJSONList :: (a0 -> Value) -> ([a0] -> Value) -> [Either a a0] -> Value # liftToEncoding :: (a0 -> Encoding) -> ([a0] -> Encoding) -> Either a a0 -> Encoding # liftToEncodingList :: (a0 -> Encoding) -> ([a0] -> Encoding) -> [Either a a0] -> Encoding # | |
| Eq a => Eq1 (Either a) | Since: base-4.9.0.0 |
| Ord a => Ord1 (Either a) | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes | |
| Read a => Read1 (Either a) | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes Methods liftReadsPrec :: (Int -> ReadS a0) -> ReadS [a0] -> Int -> ReadS (Either a a0) # liftReadList :: (Int -> ReadS a0) -> ReadS [a0] -> ReadS [Either a a0] # liftReadPrec :: ReadPrec a0 -> ReadPrec [a0] -> ReadPrec (Either a a0) # liftReadListPrec :: ReadPrec a0 -> ReadPrec [a0] -> ReadPrec [Either a a0] # | |
| Show a => Show1 (Either a) | Since: base-4.9.0.0 |
| MonadFailure (Either a) | |
| NFData a => NFData1 (Either a) | Since: deepseq-1.4.3.0 |
Defined in Control.DeepSeq | |
| e ~ SomeException => MonadThrow (Either e) | |
Defined in Control.Monad.Catch | |
| e ~ SomeException => MonadCatch (Either e) | Since: exceptions-0.8.3 |
| e ~ SomeException => MonadMask (Either e) | Since: exceptions-0.8.3 |
Defined in Control.Monad.Catch | |
| Hashable a => Hashable1 (Either a) | |
Defined in Data.Hashable.Class | |
| PTraversable (Either a) | |
| STraversable (Either a) | |
Defined in Data.Singletons.Prelude.Traversable Methods sTraverse :: forall a0 (f :: Type -> Type) b (t1 :: a0 ~> f b) (t2 :: Either a a0). SApplicative f => Sing t1 -> Sing t2 -> Sing (Apply (Apply TraverseSym0 t1) t2) # sSequenceA :: forall (f :: Type -> Type) a0 (t1 :: Either a (f a0)). SApplicative f => Sing t1 -> Sing (Apply SequenceASym0 t1) # sMapM :: forall a0 (m :: Type -> Type) b (t1 :: a0 ~> m b) (t2 :: Either a a0). SMonad m => Sing t1 -> Sing t2 -> Sing (Apply (Apply MapMSym0 t1) t2) # sSequence :: forall (m :: Type -> Type) a0 (t1 :: Either a (m a0)). SMonad m => Sing t1 -> Sing (Apply SequenceSym0 t1) # | |
| PFoldable (Either a) | |
| SFoldable (Either a) | |
Defined in Data.Singletons.Prelude.Foldable Methods sFold :: forall m (t1 :: Either a m). SMonoid m => Sing t1 -> Sing (Apply FoldSym0 t1) # sFoldMap :: forall a0 m (t1 :: a0 ~> m) (t2 :: Either a a0). SMonoid m => Sing t1 -> Sing t2 -> Sing (Apply (Apply FoldMapSym0 t1) t2) # sFoldr :: forall a0 b (t1 :: a0 ~> (b ~> b)) (t2 :: b) (t3 :: Either a a0). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply FoldrSym0 t1) t2) t3) # sFoldr' :: forall a0 b (t1 :: a0 ~> (b ~> b)) (t2 :: b) (t3 :: Either a a0). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply Foldr'Sym0 t1) t2) t3) # sFoldl :: forall b a0 (t1 :: b ~> (a0 ~> b)) (t2 :: b) (t3 :: Either a a0). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply FoldlSym0 t1) t2) t3) # sFoldl' :: forall b a0 (t1 :: b ~> (a0 ~> b)) (t2 :: b) (t3 :: Either a a0). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply Foldl'Sym0 t1) t2) t3) # sFoldr1 :: forall a0 (t1 :: a0 ~> (a0 ~> a0)) (t2 :: Either a a0). Sing t1 -> Sing t2 -> Sing (Apply (Apply Foldr1Sym0 t1) t2) # sFoldl1 :: forall a0 (t1 :: a0 ~> (a0 ~> a0)) (t2 :: Either a a0). Sing t1 -> Sing t2 -> Sing (Apply (Apply Foldl1Sym0 t1) t2) # sToList :: forall a0 (t1 :: Either a a0). Sing t1 -> Sing (Apply ToListSym0 t1) # sNull :: forall a0 (t1 :: Either a a0). Sing t1 -> Sing (Apply NullSym0 t1) # sLength :: forall a0 (t1 :: Either a a0). Sing t1 -> Sing (Apply LengthSym0 t1) # sElem :: forall a0 (t1 :: a0) (t2 :: Either a a0). SEq a0 => Sing t1 -> Sing t2 -> Sing (Apply (Apply ElemSym0 t1) t2) # sMaximum :: forall a0 (t1 :: Either a a0). SOrd a0 => Sing t1 -> Sing (Apply MaximumSym0 t1) # sMinimum :: forall a0 (t1 :: Either a a0). SOrd a0 => Sing t1 -> Sing (Apply MinimumSym0 t1) # sSum :: forall a0 (t1 :: Either a a0). SNum a0 => Sing t1 -> Sing (Apply SumSym0 t1) # sProduct :: forall a0 (t1 :: Either a a0). SNum a0 => Sing t1 -> Sing (Apply ProductSym0 t1) # | |
| PFunctor (Either a) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| PApplicative (Either e) | |
| PMonad (Either e) | |
| SFunctor (Either a) | |
| SApplicative (Either e) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods sPure :: forall a (t :: a). Sing t -> Sing (Apply PureSym0 t) # (%<*>) :: forall a b (t1 :: Either e (a ~> b)) (t2 :: Either e a). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<*>@#@$) t1) t2) # sLiftA2 :: forall a b c (t1 :: a ~> (b ~> c)) (t2 :: Either e a) (t3 :: Either e b). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply LiftA2Sym0 t1) t2) t3) # (%*>) :: forall a b (t1 :: Either e a) (t2 :: Either e b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (*>@#@$) t1) t2) # (%<*) :: forall a b (t1 :: Either e a) (t2 :: Either e b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<*@#@$) t1) t2) # | |
| SMonad (Either e) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods (%>>=) :: forall a b (t1 :: Either e a) (t2 :: a ~> Either e b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>>=@#@$) t1) t2) # (%>>) :: forall a b (t1 :: Either e a) (t2 :: Either e b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>>@#@$) t1) t2) # sReturn :: forall a (t :: a). Sing t -> Sing (Apply ReturnSym0 t) # | |
| Generic1 (Either a :: Type -> Type) | Since: base-4.6.0.0 |
| IsoHKD (Either a :: Type -> Type) (b :: Type) | |
| (CanCastTo l1 l2, CanCastTo r1 r2) => CanCastTo (Either l1 r1 :: Type) (Either l2 r2 :: Type) Source # | |
| (Eq a, Eq b) => Eq (Either a b) | Since: base-2.1 |
| (Ord a, Ord b) => Ord (Either a b) | Since: base-2.1 |
| (Read a, Read b) => Read (Either a b) | Since: base-3.0 |
| (Show a, Show b) => Show (Either a b) | Since: base-3.0 |
| Generic (Either a b) | Since: base-4.6.0.0 |
| Semigroup (Either a b) | Since: base-4.9.0.0 |
| (Hashable a, Hashable b) => Hashable (Either a b) | |
Defined in Data.Hashable.Class | |
| (ToJSON a, ToJSON b) => ToJSON (Either a b) | |
Defined in Data.Aeson.Types.ToJSON | |
| (NFData a, NFData b) => NFData (Either a b) | |
Defined in Control.DeepSeq | |
| PShow (Either a b) | |
| (SShow a, SShow b) => SShow (Either a b) | |
Defined in Data.Singletons.Prelude.Show Methods sShowsPrec :: forall (t1 :: Nat) (t2 :: Either a b) (t3 :: Symbol). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply ShowsPrecSym0 t1) t2) t3) # sShow_ :: forall (t :: Either a b). Sing t -> Sing (Apply Show_Sym0 t) # sShowList :: forall (t1 :: [Either a b]) (t2 :: Symbol). Sing t1 -> Sing t2 -> Sing (Apply (Apply ShowListSym0 t1) t2) # | |
| PSemigroup (Either a b) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal | |
| SSemigroup (Either a b) | |
| POrd (Either a b) | |
| (SOrd a, SOrd b) => SOrd (Either a b) | |
Defined in Data.Singletons.Prelude.Ord Methods sCompare :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply CompareSym0 t1) t2) # (%<) :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<@#@$) t1) t2) # (%<=) :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (<=@#@$) t1) t2) # (%>) :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>@#@$) t1) t2) # (%>=) :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply (>=@#@$) t1) t2) # sMax :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply MaxSym0 t1) t2) # sMin :: forall (t1 :: Either a b) (t2 :: Either a b). Sing t1 -> Sing t2 -> Sing (Apply (Apply MinSym0 t1) t2) # | |
| (SEq a, SEq b) => SEq (Either a b) | |
| PEq (Either a b) | |
| (TypeError (DisallowInstance "Either") :: Constraint) => Container (Either a b) | |
Defined in Universum.Container.Class Methods toList :: Either a b -> [Element (Either a b)] # foldr :: (Element (Either a b) -> b0 -> b0) -> b0 -> Either a b -> b0 # foldl :: (b0 -> Element (Either a b) -> b0) -> b0 -> Either a b -> b0 # foldl' :: (b0 -> Element (Either a b) -> b0) -> b0 -> Either a b -> b0 # elem :: Element (Either a b) -> Either a b -> Bool # maximum :: Either a b -> Element (Either a b) # minimum :: Either a b -> Element (Either a b) # foldMap :: Monoid m => (Element (Either a b) -> m) -> Either a b -> m # fold :: Either a b -> Element (Either a b) # foldr' :: (Element (Either a b) -> b0 -> b0) -> b0 -> Either a b -> b0 # foldr1 :: (Element (Either a b) -> Element (Either a b) -> Element (Either a b)) -> Either a b -> Element (Either a b) # foldl1 :: (Element (Either a b) -> Element (Either a b) -> Element (Either a b)) -> Either a b -> Element (Either a b) # notElem :: Element (Either a b) -> Either a b -> Bool # all :: (Element (Either a b) -> Bool) -> Either a b -> Bool # any :: (Element (Either a b) -> Bool) -> Either a b -> Bool # find :: (Element (Either a b) -> Bool) -> Either a b -> Maybe (Element (Either a b)) # | |
| PolyTypeHasDocC '[l, r] => TypeHasDoc (Either l r) | |
Defined in Michelson.Typed.Haskell.Doc Associated Types type TypeDocFieldDescriptions (Either l r) :: FieldDescriptions # Methods typeDocName :: Proxy (Either l r) -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy (Either l r) -> WithinParens -> Markdown # typeDocDependencies :: Proxy (Either l r) -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep (Either l r) # typeDocMichelsonRep :: TypeDocMichelsonRep (Either l r) # | |
| (IsoValue l, IsoValue r) => IsoValue (Either l r) | |
| (HasAnnotation a, HasAnnotation b) => HasAnnotation (Either a b) Source # | |
Defined in Lorentz.Annotation Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT (Either a b)) Source # | |
| (Eq a, Eq b) :=> (Eq (Either a b)) | |
| (Ord a, Ord b) :=> (Ord (Either a b)) | |
| (Read a, Read b) :=> (Read (Either a b)) | |
| (Show a, Show b) :=> (Show (Either a b)) | |
| (SDecide a, SDecide b) => TestCoercion (SEither :: Either a b -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| (SDecide a, SDecide b) => TestEquality (SEither :: Either a b -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| SuppressUnusedWarnings (RightsSym0 :: TyFun [Either a b] [b] -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (PartitionEithersSym0 :: TyFun [Either a b] ([a], [b]) -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (LeftsSym0 :: TyFun [Either a b] [a] -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680822765Sym0 :: TyFun (Either a1 a2) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Length_6989586621680822759Sym0 :: TyFun (Either a1 a2) Nat -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsRightSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621679847911Sym0 :: TyFun (Either a b) (Either a b ~> Ordering) -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680240183Sym0 :: TyFun (Either a b) (Either a b ~> Either a b) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ShowsPrec_6989586621680653337Sym0 :: TyFun Nat (Either a b ~> (Symbol ~> Symbol)) -> Type) | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Pure_6989586621680072312Sym0 :: TyFun a (Either e a) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (RightSym0 :: TyFun b (Either a b) -> Type) | |
Defined in Data.Singletons.Prelude.Instances Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (LeftSym0 :: TyFun a (Either a b) -> Type) | |
Defined in Data.Singletons.Prelude.Instances Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Let6989586621680240192ASym0 :: TyFun k1 (Either a k1) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SingI (RightsSym0 :: TyFun [Either a b] [b] -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing RightsSym0 # | |
| SingI (PartitionEithersSym0 :: TyFun [Either a b] ([a], [b]) -> Type) | |
Defined in Data.Singletons.Prelude.Either | |
| SingI (LeftsSym0 :: TyFun [Either a b] [a] -> Type) | |
Defined in Data.Singletons.Prelude.Either | |
| SingI (IsRightSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing IsRightSym0 # | |
| SingI (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing IsLeftSym0 # | |
| SingI (RightSym0 :: TyFun b (Either a b) -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| SingI (LeftSym0 :: TyFun a (Either a b) -> Type) | |
Defined in Data.Singletons.Prelude.Instances | |
| (a ~ a', b ~ b') => Each (Either a a') (Either b b') a b | Since: microlens-0.4.11 |
| SuppressUnusedWarnings (ShowsPrec_6989586621680653337Sym1 a6989586621680653347 :: TyFun (Either a b) (Symbol ~> Symbol) -> Type) | |
Defined in Data.Singletons.Prelude.Show Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072406Sym0 :: TyFun (Either e a) ((a ~> Either e b) ~> Either e b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072322Sym0 :: TyFun (Either e (a ~> b)) (Either e a ~> Either e b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621679847911Sym1 a6989586621679847916 :: TyFun (Either a b) Ordering -> Type) | |
Defined in Data.Singletons.Prelude.Ord Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680240183Sym1 a6989586621680240188 :: TyFun (Either a b) (Either a b) -> Type) | |
Defined in Data.Singletons.Prelude.Semigroup.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072143Sym0 :: TyFun a1 (Either a2 b ~> Either a2 a1) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fmap_6989586621680072126Sym0 :: TyFun (a1 ~> b) (Either a2 a1 ~> Either a2 b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822745Sym0 :: TyFun (a1 ~> (b ~> b)) (b ~> (Either a2 a1 ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FoldMap_6989586621680822733Sym0 :: TyFun (a1 ~> m) (Either a2 a1 ~> m) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Either_Sym0 :: TyFun (a ~> c) ((b ~> c) ~> (Either a b ~> c)) -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SingI (Either_Sym0 :: TyFun (a ~> c) ((b ~> c) ~> (Either a b ~> c)) -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing Either_Sym0 # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072322Sym1 a6989586621680072327 :: TyFun (Either e a) (Either e b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072143Sym1 a6989586621680072148 :: TyFun (Either a2 b) (Either a2 a1) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fmap_6989586621680072126Sym1 a6989586621680072131 :: TyFun (Either a2 a1) (Either a2 b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FoldMap_6989586621680822733Sym1 a6989586621680822738 :: TyFun (Either a2 a1) m -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822745Sym1 a6989586621680822751 :: TyFun b (Either a2 a1 ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Traverse_6989586621681087679Sym0 :: TyFun (a1 ~> f b) (Either a2 a1 ~> f (Either a2 b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680072406Sym1 a6989586621680072411 :: TyFun (a ~> Either e b) (Either e b) -> Type) | |
Defined in Data.Singletons.Prelude.Monad.Internal Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Either_Sym1 a6989586621680801720 :: TyFun (b ~> c) (Either a b ~> c) -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| SingI d => SingI (Either_Sym1 d :: TyFun (b ~> c) (Either a b ~> c) -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing (Either_Sym1 d) # | |
| SuppressUnusedWarnings (Traverse_6989586621681087679Sym1 a6989586621681087684 :: TyFun (Either a2 a1) (f (Either a2 b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822745Sym2 a6989586621680822751 a6989586621680822752 :: TyFun (Either a2 a1) b -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Either_Sym2 a6989586621680801720 a6989586621680801721 :: TyFun (Either a b) c -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods suppressUnusedWarnings :: () # | |
| (SingI d1, SingI d2) => SingI (Either_Sym2 d1 d2 :: TyFun (Either a b) c -> Type) | |
Defined in Data.Singletons.Prelude.Either Methods sing :: Sing (Either_Sym2 d1 d2) # | |
| (Functor f, Functor g) => Functor (Lift Either f g) | |
| type MapM (arg1 :: a1 ~> m b) (arg2 :: Either a2 a1) | |
| type Traverse (a3 :: a1 ~> f b) (a4 :: Either a2 a1) | |
| type LiftA2 (arg1 :: a ~> (b ~> c)) (arg2 :: Either e a) (arg3 :: Either e b) | |
| type FoldMap (a3 :: a1 ~> k2) (a4 :: Either a2 a1) | |
| type Fmap (a3 :: a1 ~> b) (a4 :: Either a2 a1) | |
| type Foldl' (arg1 :: b ~> (a1 ~> b)) (arg2 :: b) (arg3 :: Either a2 a1) | |
| type Foldl (arg1 :: b ~> (a1 ~> b)) (arg2 :: b) (arg3 :: Either a2 a1) | |
| type Foldr' (arg1 :: a1 ~> (b ~> b)) (arg2 :: b) (arg3 :: Either a2 a1) | |
| type Foldr (a3 :: a1 ~> (k2 ~> k2)) (a4 :: k2) (a5 :: Either a2 a1) | |
| type Pure (a :: k1) | |
| type Return (arg :: a) | |
| type Elem (arg1 :: a1) (arg2 :: Either a2 a1) | |
| type Foldl1 (arg1 :: a1 ~> (a1 ~> a1)) (arg2 :: Either a2 a1) | |
| type Foldr1 (arg1 :: a1 ~> (a1 ~> a1)) (arg2 :: Either a2 a1) | |
| type (a2 :: k1) <$ (a3 :: Either a1 b) | |
| type Apply (ShowsPrec_6989586621680653337Sym0 :: TyFun Nat (Either a b ~> (Symbol ~> Symbol)) -> Type) (a6989586621680653347 :: Nat) | |
| type Apply (Pure_6989586621680072312Sym0 :: TyFun a (Either e a) -> Type) (a6989586621680072318 :: a) | |
| type Apply (LeftSym0 :: TyFun a (Either a b) -> Type) (a6989586621679749540 :: a) | |
| type Apply (RightSym0 :: TyFun b (Either a b) -> Type) (a6989586621679749542 :: b) | |
| type Apply (Let6989586621680240192ASym0 :: TyFun k1 (Either a k1) -> Type) (wild_69895866216802398566989586621680240191 :: k1) | |
| type Apply (TFHelper_6989586621680072143Sym0 :: TyFun a1 (Either a2 b ~> Either a2 a1) -> Type) (a6989586621680072148 :: a1) | |
| type Apply (Foldr_6989586621680822745Sym1 a6989586621680822751 :: TyFun b (Either a2 a1 ~> b) -> Type) (a6989586621680822752 :: b) | |
| type Eval (FoldMap f ('Right x :: Either a3 a1) :: a2 -> Type) | |
| type Eval (FoldMap f ('Left _a :: Either a3 a1) :: a2 -> Type) | |
| type Eval (Foldr f y ('Right x :: Either a3 a1) :: a2 -> Type) | |
| type Eval (Foldr f y ('Left _a :: Either a3 a1) :: a2 -> Type) | |
| type Failure (Either a) | |
Defined in Basement.Monad | |
| type Product (arg :: Either a1 a2) | |
| type Sum (arg :: Either a1 a2) | |
| type Minimum (arg :: Either a1 a2) | |
| type Maximum (arg :: Either a1 a2) | |
| type Length (a3 :: Either a1 a2) | |
| type Null (a3 :: Either a1 a2) | |
| type ToList (arg :: Either a1 a2) | |
| type Fold (arg :: Either a m) | |
| type Sequence (arg :: Either a1 (m a2)) | |
| type SequenceA (arg :: Either a1 (f a2)) | |
| type (arg1 :: Either e a) <* (arg2 :: Either e b) | |
| type (arg1 :: Either e a) *> (arg2 :: Either e b) | |
| type (a2 :: Either e (a1 ~> b)) <*> (a3 :: Either e a1) | |
| type (arg1 :: Either e a) >> (arg2 :: Either e b) | |
| type (a2 :: Either e a1) >>= (a3 :: a1 ~> Either e b) | |
| type Rep1 (Either a :: Type -> Type) | |
Defined in GHC.Generics type Rep1 (Either a :: Type -> Type) = D1 ('MetaData "Either" "Data.Either" "base" 'False) (C1 ('MetaCons "Left" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 a)) :+: C1 ('MetaCons "Right" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) Par1)) | |
| type HKD (Either a :: Type -> Type) (b :: Type) | |
| type Apply (RightsSym0 :: TyFun [Either a b] [b] -> Type) (a6989586621680803404 :: [Either a b]) | |
Defined in Data.Singletons.Prelude.Either type Apply (RightsSym0 :: TyFun [Either a b] [b] -> Type) (a6989586621680803404 :: [Either a b]) = RightsSym1 a6989586621680803404 | |
| type Apply (LeftsSym0 :: TyFun [Either a b] [a] -> Type) (a6989586621680803410 :: [Either a b]) | |
| type Apply (PartitionEithersSym0 :: TyFun [Either a b] ([a], [b]) -> Type) (a6989586621680803387 :: [Either a b]) | |
| type Rep (Either a b) | |
Defined in GHC.Generics type Rep (Either a b) = D1 ('MetaData "Either" "Data.Either" "base" 'False) (C1 ('MetaCons "Left" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 a)) :+: C1 ('MetaCons "Right" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 b))) | |
| type Sing | |
Defined in Data.Singletons.Prelude.Instances | |
| type Demote (Either a b) | |
| type Element (Either a b) | |
Defined in Universum.Container.Class | |
| type TypeDocFieldDescriptions (Either l r) | |
Defined in Michelson.Typed.Haskell.Doc | |
| type ToT (Either l r) | |
Defined in Michelson.Typed.Haskell.Value | |
| type Show_ (arg :: Either a b) | |
| type Sconcat (arg :: NonEmpty (Either a b)) | |
| type ShowList (arg1 :: [Either a b]) arg2 | |
| type (a2 :: Either a1 b) <> (a3 :: Either a1 b) | |
| type Min (arg1 :: Either a b) (arg2 :: Either a b) | |
| type Max (arg1 :: Either a b) (arg2 :: Either a b) | |
| type (arg1 :: Either a b) >= (arg2 :: Either a b) | |
| type (arg1 :: Either a b) > (arg2 :: Either a b) | |
| type (arg1 :: Either a b) <= (arg2 :: Either a b) | |
| type (arg1 :: Either a b) < (arg2 :: Either a b) | |
| type Compare (a2 :: Either a1 b) (a3 :: Either a1 b) | |
| type (x :: Either a b) /= (y :: Either a b) | |
| type (a2 :: Either a1 b1) == (b2 :: Either a1 b1) | |
Defined in Data.Singletons.Prelude.Eq | |
| type ShowsPrec a2 (a3 :: Either a1 b) a4 | |
| type Apply (Length_6989586621680822759Sym0 :: TyFun (Either a1 a2) Nat -> Type) (a6989586621680822763 :: Either a1 a2) | |
| type Apply (Null_6989586621680822765Sym0 :: TyFun (Either a1 a2) Bool -> Type) (a6989586621680822771 :: Either a1 a2) | |
| type Apply (IsRightSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803379 :: Either a b) | |
Defined in Data.Singletons.Prelude.Either type Apply (IsRightSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803379 :: Either a b) = IsRightSym1 a6989586621680803379 | |
| type Apply (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803382 :: Either a b) | |
Defined in Data.Singletons.Prelude.Either type Apply (IsLeftSym0 :: TyFun (Either a b) Bool -> Type) (a6989586621680803382 :: Either a b) = IsLeftSym1 a6989586621680803382 | |
| type Apply (Compare_6989586621679847911Sym1 a6989586621679847916 :: TyFun (Either a b) Ordering -> Type) (a6989586621679847917 :: Either a b) | |
| type Apply (FoldMap_6989586621680822733Sym1 a6989586621680822738 :: TyFun (Either a2 a1) m -> Type) (a6989586621680822739 :: Either a2 a1) | |
| type Apply (Foldr_6989586621680822745Sym2 a6989586621680822751 a6989586621680822752 :: TyFun (Either a2 a1) b -> Type) (a6989586621680822753 :: Either a2 a1) | |
| type Apply (Either_Sym2 a6989586621680801720 a6989586621680801721 :: TyFun (Either a b) c -> Type) (a6989586621680801722 :: Either a b) | |
Defined in Data.Singletons.Prelude.Either type Apply (Either_Sym2 a6989586621680801720 a6989586621680801721 :: TyFun (Either a b) c -> Type) (a6989586621680801722 :: Either a b) = Either_Sym3 a6989586621680801720 a6989586621680801721 a6989586621680801722 | |
| type Apply (Traverse_6989586621681087679Sym1 a6989586621681087684 :: TyFun (Either a2 a1) (f (Either a2 b)) -> Type) (a6989586621681087685 :: Either a2 a1) | |
| type Apply (Compare_6989586621679847911Sym0 :: TyFun (Either a b) (Either a b ~> Ordering) -> Type) (a6989586621679847916 :: Either a b) | |
| type Apply (TFHelper_6989586621680240183Sym0 :: TyFun (Either a b) (Either a b ~> Either a b) -> Type) (a6989586621680240188 :: Either a b) | |
| type Apply (ShowsPrec_6989586621680653337Sym1 a6989586621680653347 :: TyFun (Either a b) (Symbol ~> Symbol) -> Type) (a6989586621680653348 :: Either a b) | |
| type Apply (TFHelper_6989586621680072322Sym0 :: TyFun (Either e (a ~> b)) (Either e a ~> Either e b) -> Type) (a6989586621680072327 :: Either e (a ~> b)) | |
| type Apply (TFHelper_6989586621680072406Sym0 :: TyFun (Either e a) ((a ~> Either e b) ~> Either e b) -> Type) (a6989586621680072411 :: Either e a) | |
Defined in Data.Singletons.Prelude.Monad.Internal | |
| type Apply (TFHelper_6989586621680240183Sym1 a6989586621680240188 :: TyFun (Either a b) (Either a b) -> Type) (a6989586621680240189 :: Either a b) | |
| type Apply (Fmap_6989586621680072126Sym0 :: TyFun (a1 ~> b) (Either a2 a1 ~> Either a2 b) -> Type) (a6989586621680072131 :: a1 ~> b) | |
| type Apply (FoldMap_6989586621680822733Sym0 :: TyFun (a1 ~> m) (Either a2 a1 ~> m) -> Type) (a6989586621680822738 :: a1 ~> m) | |
| type Apply (Foldr_6989586621680822745Sym0 :: TyFun (a1 ~> (b ~> b)) (b ~> (Either a2 a1 ~> b)) -> Type) (a6989586621680822751 :: a1 ~> (b ~> b)) | |
| type Apply (Either_Sym0 :: TyFun (a ~> c) ((b ~> c) ~> (Either a b ~> c)) -> Type) (a6989586621680801720 :: a ~> c) | |
| type Apply (Fmap_6989586621680072126Sym1 a6989586621680072131 :: TyFun (Either a2 a1) (Either a2 b) -> Type) (a6989586621680072132 :: Either a2 a1) | |
| type Apply (TFHelper_6989586621680072143Sym1 a6989586621680072148 :: TyFun (Either a2 b) (Either a2 a1) -> Type) (a6989586621680072149 :: Either a2 b) | |
| type Apply (TFHelper_6989586621680072322Sym1 a6989586621680072327 :: TyFun (Either e a) (Either e b) -> Type) (a6989586621680072328 :: Either e a) | |
| type Apply (Traverse_6989586621681087679Sym0 :: TyFun (a1 ~> f b) (Either a2 a1 ~> f (Either a2 b)) -> Type) (a6989586621681087684 :: a1 ~> f b) | |
| type Apply (TFHelper_6989586621680072406Sym1 a6989586621680072411 :: TyFun (a ~> Either e b) (Either e b) -> Type) (a6989586621680072412 :: a ~> Either e b) | |
| type Apply (Either_Sym1 a6989586621680801720 :: TyFun (b ~> c) (Either a b ~> c) -> Type) (a6989586621680801721 :: b ~> c) | |
Defined in Data.Singletons.Prelude.Either type Apply (Either_Sym1 a6989586621680801720 :: TyFun (b ~> c) (Either a b ~> c) -> Type) (a6989586621680801721 :: b ~> c) = Either_Sym2 a6989586621680801720 a6989586621680801721 | |
| type Eval (Map f ('Right a3 :: Either a2 a1) :: Either a2 b -> Type) | |
| type Eval (Map f ('Left x :: Either a2 a1) :: Either a2 b -> Type) | |
| type Eval (Bimap f g ('Right y :: Either a b1) :: Either a' b2 -> Type) | |
| type Eval (Bimap f g ('Left x :: Either a1 b) :: Either a2 b' -> Type) | |
data ByteString #
A space-efficient representation of a Word8 vector, supporting many
efficient operations.
A ByteString contains 8-bit bytes, or by using the operations from
Data.ByteString.Char8 it can be interpreted as containing 8-bit
characters.
Instances
A space efficient, packed, unboxed Unicode text type.
Instances
A Map from keys k to values a.
The Semigroup operation for Map is union, which prefers
values from the left operand. If m1 maps a key k to a value
a1, and m2 maps the same key to a different value a2, then
their union m1 <> m2 maps k to a1.
Instances
| Eq2 Map | Since: containers-0.5.9 |
| Ord2 Map | Since: containers-0.5.9 |
Defined in Data.Map.Internal | |
| Show2 Map | Since: containers-0.5.9 |
| Functor (Map k) | |
| Foldable (Map k) | Folds in order of increasing key. |
Defined in Data.Map.Internal Methods fold :: Monoid m => Map k m -> m # foldMap :: Monoid m => (a -> m) -> Map k a -> m # foldMap' :: Monoid m => (a -> m) -> Map k a -> m # foldr :: (a -> b -> b) -> b -> Map k a -> b # foldr' :: (a -> b -> b) -> b -> Map k a -> b # foldl :: (b -> a -> b) -> b -> Map k a -> b # foldl' :: (b -> a -> b) -> b -> Map k a -> b # foldr1 :: (a -> a -> a) -> Map k a -> a # foldl1 :: (a -> a -> a) -> Map k a -> a # elem :: Eq a => a -> Map k a -> Bool # maximum :: Ord a => Map k a -> a # minimum :: Ord a => Map k a -> a # | |
| Traversable (Map k) | Traverses in order of increasing key. |
| ToJSONKey k => ToJSON1 (Map k) | |
Defined in Data.Aeson.Types.ToJSON Methods liftToJSON :: (a -> Value) -> ([a] -> Value) -> Map k a -> Value # liftToJSONList :: (a -> Value) -> ([a] -> Value) -> [Map k a] -> Value # liftToEncoding :: (a -> Encoding) -> ([a] -> Encoding) -> Map k a -> Encoding # liftToEncodingList :: (a -> Encoding) -> ([a] -> Encoding) -> [Map k a] -> Encoding # | |
| Eq k => Eq1 (Map k) | Since: containers-0.5.9 |
| Ord k => Ord1 (Map k) | Since: containers-0.5.9 |
Defined in Data.Map.Internal | |
| (Ord k, Read k) => Read1 (Map k) | Since: containers-0.5.9 |
Defined in Data.Map.Internal | |
| Show k => Show1 (Map k) | Since: containers-0.5.9 |
| (CanCastTo k1 k2, CanCastTo v1 v2) => CanCastTo (Map k1 v1 :: Type) (Map k2 v2 :: Type) Source # | |
| Ord k => IsList (Map k v) | Since: containers-0.5.6.2 |
| (Eq k, Eq a) => Eq (Map k a) | |
| (Data k, Data a, Ord k) => Data (Map k a) | |
Defined in Data.Map.Internal Methods gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> Map k a -> c (Map k a) # gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c (Map k a) # toConstr :: Map k a -> Constr # dataTypeOf :: Map k a -> DataType # dataCast1 :: Typeable t => (forall d. Data d => c (t d)) -> Maybe (c (Map k a)) # dataCast2 :: Typeable t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c (Map k a)) # gmapT :: (forall b. Data b => b -> b) -> Map k a -> Map k a # gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> Map k a -> r # gmapQr :: forall r r'. (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> Map k a -> r # gmapQ :: (forall d. Data d => d -> u) -> Map k a -> [u] # gmapQi :: Int -> (forall d. Data d => d -> u) -> Map k a -> u # gmapM :: Monad m => (forall d. Data d => d -> m d) -> Map k a -> m (Map k a) # gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> Map k a -> m (Map k a) # gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> Map k a -> m (Map k a) # | |
| (Ord k, Ord v) => Ord (Map k v) | |
| (Ord k, Read k, Read e) => Read (Map k e) | |
| (Show k, Show a) => Show (Map k a) | |
| Ord k => Semigroup (Map k v) | |
| Ord k => Monoid (Map k v) | |
| (ToJSON v, ToJSONKey k) => ToJSON (Map k v) | |
Defined in Data.Aeson.Types.ToJSON | |
| (NFData k, NFData a) => NFData (Map k a) | |
Defined in Data.Map.Internal | |
| Ord k => Ixed (Map k a) | |
Defined in Control.Lens.At | |
| Ord k => At (Map k a) | |
| Ord k => Wrapped (Map k a) | |
| (Ord k, Monoid k, Semiring v) => Semiring (Map k v) | The multiplication laws are satisfied for
any underlying |
| ToPairs (Map k v) | |
| Container (Map k v) | |
Defined in Universum.Container.Class Methods toList :: Map k v -> [Element (Map k v)] # foldr :: (Element (Map k v) -> b -> b) -> b -> Map k v -> b # foldl :: (b -> Element (Map k v) -> b) -> b -> Map k v -> b # foldl' :: (b -> Element (Map k v) -> b) -> b -> Map k v -> b # elem :: Element (Map k v) -> Map k v -> Bool # maximum :: Map k v -> Element (Map k v) # minimum :: Map k v -> Element (Map k v) # foldMap :: Monoid m => (Element (Map k v) -> m) -> Map k v -> m # fold :: Map k v -> Element (Map k v) # foldr' :: (Element (Map k v) -> b -> b) -> b -> Map k v -> b # foldr1 :: (Element (Map k v) -> Element (Map k v) -> Element (Map k v)) -> Map k v -> Element (Map k v) # foldl1 :: (Element (Map k v) -> Element (Map k v) -> Element (Map k v)) -> Map k v -> Element (Map k v) # notElem :: Element (Map k v) -> Map k v -> Bool # all :: (Element (Map k v) -> Bool) -> Map k v -> Bool # any :: (Element (Map k v) -> Bool) -> Map k v -> Bool # find :: (Element (Map k v) -> Bool) -> Map k v -> Maybe (Element (Map k v)) # | |
| One (Map k v) | |
| (PolyCTypeHasDocC '[k], PolyTypeHasDocC '[v], Ord k) => TypeHasDoc (Map k v) | |
Defined in Michelson.Typed.Haskell.Doc Associated Types type TypeDocFieldDescriptions (Map k v) :: FieldDescriptions # Methods typeDocName :: Proxy (Map k v) -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy (Map k v) -> WithinParens -> Markdown # typeDocDependencies :: Proxy (Map k v) -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep (Map k v) # typeDocMichelsonRep :: TypeDocMichelsonRep (Map k v) # | |
| (Comparable (ToT k), Ord k, IsoValue k, IsoValue v) => IsoValue (Map k v) | |
| (HasAnnotation k, HasAnnotation v) => HasAnnotation (Map k v) Source # | |
Defined in Lorentz.Annotation Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT (Map k v)) Source # | |
| NiceComparable k => GetOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable k => UpdOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| SizeOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable k => IterOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type IterOpElHs (Map k v) Source # | |
| NiceComparable k => MapOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MapOpInpHs (Map k v) Source # | |
| NiceComparable k => MemOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MemOpKeyHs (Map k v) Source # | |
| LDefault (Map k v) Source # | |
| (t ~ Map k' a', Ord k) => Rewrapped (Map k a) t | Use |
Defined in Control.Lens.Wrapped | |
| (NiceComparable key, KnownValue value) => StoreHasSubmap (Map key value) SelfRef key value Source # | |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps (Map key value) SelfRef key value Source # | |
| type Item (Map k v) | |
Defined in Data.Map.Internal | |
| type Index (Map k a) | |
Defined in Control.Lens.At | |
| type IxValue (Map k a) | |
Defined in Control.Lens.At | |
| type Unwrapped (Map k a) | |
Defined in Control.Lens.Wrapped | |
| type Val (Map k v) | |
Defined in Universum.Container.Class | |
| type Key (Map k v) | |
Defined in Universum.Container.Class | |
| type Element (Map k v) | |
Defined in Universum.Container.Class | |
| type OneItem (Map k v) | |
Defined in Universum.Container.Class | |
| type TypeDocFieldDescriptions (Map k v) | |
Defined in Michelson.Typed.Haskell.Doc | |
| type ToT (Map k v) | |
Defined in Michelson.Typed.Haskell.Value | |
| type GetOpKeyHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type GetOpValHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type UpdOpKeyHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type UpdOpParamsHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type IterOpElHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type MapOpInpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type MapOpResHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| type MemOpKeyHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
Proxy is a type that holds no data, but has a phantom parameter of
arbitrary type (or even kind). Its use is to provide type information, even
though there is no value available of that type (or it may be too costly to
create one).
Historically, Proxy :: Proxy aundefined :: a
>>>Proxy :: Proxy (Void, Int -> Int)Proxy
Proxy can even hold types of higher kinds,
>>>Proxy :: Proxy EitherProxy
>>>Proxy :: Proxy FunctorProxy
>>>Proxy :: Proxy complicatedStructureProxy
Constructors
| Proxy |
Instances
| Generic1 (Proxy :: k -> Type) | Since: base-4.6.0.0 |
| Monad (Proxy :: Type -> Type) | Since: base-4.7.0.0 |
| Functor (Proxy :: Type -> Type) | Since: base-4.7.0.0 |
| Applicative (Proxy :: Type -> Type) | Since: base-4.7.0.0 |
| Foldable (Proxy :: Type -> Type) | Since: base-4.7.0.0 |
Defined in Data.Foldable Methods fold :: Monoid m => Proxy m -> m # foldMap :: Monoid m => (a -> m) -> Proxy a -> m # foldMap' :: Monoid m => (a -> m) -> Proxy a -> m # foldr :: (a -> b -> b) -> b -> Proxy a -> b # foldr' :: (a -> b -> b) -> b -> Proxy a -> b # foldl :: (b -> a -> b) -> b -> Proxy a -> b # foldl' :: (b -> a -> b) -> b -> Proxy a -> b # foldr1 :: (a -> a -> a) -> Proxy a -> a # foldl1 :: (a -> a -> a) -> Proxy a -> a # elem :: Eq a => a -> Proxy a -> Bool # maximum :: Ord a => Proxy a -> a # minimum :: Ord a => Proxy a -> a # | |
| Traversable (Proxy :: Type -> Type) | Since: base-4.7.0.0 |
| MonadPlus (Proxy :: Type -> Type) | Since: base-4.9.0.0 |
| Representable (Proxy :: Type -> Type) | |
| ToJSON1 (Proxy :: Type -> Type) | |
Defined in Data.Aeson.Types.ToJSON Methods liftToJSON :: (a -> Value) -> ([a] -> Value) -> Proxy a -> Value # liftToJSONList :: (a -> Value) -> ([a] -> Value) -> [Proxy a] -> Value # liftToEncoding :: (a -> Encoding) -> ([a] -> Encoding) -> Proxy a -> Encoding # liftToEncodingList :: (a -> Encoding) -> ([a] -> Encoding) -> [Proxy a] -> Encoding # | |
| Alternative (Proxy :: Type -> Type) | Since: base-4.9.0.0 |
| Eq1 (Proxy :: Type -> Type) | Since: base-4.9.0.0 |
| Ord1 (Proxy :: Type -> Type) | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes | |
| Read1 (Proxy :: Type -> Type) | Since: base-4.9.0.0 |
Defined in Data.Functor.Classes | |
| Show1 (Proxy :: Type -> Type) | Since: base-4.9.0.0 |
| NFData1 (Proxy :: Type -> Type) | Since: deepseq-1.4.3.0 |
Defined in Control.DeepSeq | |
| Hashable1 (Proxy :: Type -> Type) | |
Defined in Data.Hashable.Class | |
| PTraversable (Proxy :: Type -> Type) | |
| STraversable (Proxy :: Type -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods sTraverse :: forall a (f :: Type -> Type) b (t1 :: a ~> f b) (t2 :: Proxy a). SApplicative f => Sing t1 -> Sing t2 -> Sing (Apply (Apply TraverseSym0 t1) t2) # sSequenceA :: forall (f :: Type -> Type) a (t1 :: Proxy (f a)). SApplicative f => Sing t1 -> Sing (Apply SequenceASym0 t1) # sMapM :: forall a (m :: Type -> Type) b (t1 :: a ~> m b) (t2 :: Proxy a). SMonad m => Sing t1 -> Sing t2 -> Sing (Apply (Apply MapMSym0 t1) t2) # sSequence :: forall (m :: Type -> Type) a (t1 :: Proxy (m a)). SMonad m => Sing t1 -> Sing (Apply SequenceSym0 t1) # | |
| PFoldable (Proxy :: Type -> Type) | |
| SFoldable (Proxy :: Type -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods sFold :: forall m (t1 :: Proxy m). SMonoid m => Sing t1 -> Sing (Apply FoldSym0 t1) # sFoldMap :: forall a m (t1 :: a ~> m) (t2 :: Proxy a). SMonoid m => Sing t1 -> Sing t2 -> Sing (Apply (Apply FoldMapSym0 t1) t2) # sFoldr :: forall a b (t1 :: a ~> (b ~> b)) (t2 :: b) (t3 :: Proxy a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply FoldrSym0 t1) t2) t3) # sFoldr' :: forall a b (t1 :: a ~> (b ~> b)) (t2 :: b) (t3 :: Proxy a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply Foldr'Sym0 t1) t2) t3) # sFoldl :: forall b a (t1 :: b ~> (a ~> b)) (t2 :: b) (t3 :: Proxy a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply FoldlSym0 t1) t2) t3) # sFoldl' :: forall b a (t1 :: b ~> (a ~> b)) (t2 :: b) (t3 :: Proxy a). Sing t1 -> Sing t2 -> Sing t3 -> Sing (Apply (Apply (Apply Foldl'Sym0 t1) t2) t3) # sFoldr1 :: forall a (t1 :: a ~> (a ~> a)) (t2 :: Proxy a). Sing t1 -> Sing t2 -> Sing (Apply (Apply Foldr1Sym0 t1) t2) # sFoldl1 :: forall a (t1 :: a ~> (a ~> a)) (t2 :: Proxy a). Sing t1 -> Sing t2 -> Sing (Apply (Apply Foldl1Sym0 t1) t2) # sToList :: forall a (t1 :: Proxy a). Sing t1 -> Sing (Apply ToListSym0 t1) # sNull :: forall a (t1 :: Proxy a). Sing t1 -> Sing (Apply NullSym0 t1) # sLength :: forall a (t1 :: Proxy a). Sing t1 -> Sing (Apply LengthSym0 t1) # sElem :: forall a (t1 :: a) (t2 :: Proxy a). SEq a => Sing t1 -> Sing t2 -> Sing (Apply (Apply ElemSym0 t1) t2) # sMaximum :: forall a (t1 :: Proxy a). SOrd a => Sing t1 -> Sing (Apply MaximumSym0 t1) # sMinimum :: forall a (t1 :: Proxy a). SOrd a => Sing t1 -> Sing (Apply MinimumSym0 t1) # sSum :: forall a (t1 :: Proxy a). SNum a => Sing t1 -> Sing (Apply SumSym0 t1) # sProduct :: forall a (t1 :: Proxy a). SNum a => Sing t1 -> Sing (Apply ProductSym0 t1) # | |
| Bounded (Proxy t) | Since: base-4.7.0.0 |
| Enum (Proxy s) | Since: base-4.7.0.0 |
| Eq (Proxy s) | Since: base-4.7.0.0 |
| Ord (Proxy s) | Since: base-4.7.0.0 |
| Read (Proxy t) | Since: base-4.7.0.0 |
| Show (Proxy s) | Since: base-4.7.0.0 |
| Ix (Proxy s) | Since: base-4.7.0.0 |
Defined in Data.Proxy | |
| Generic (Proxy t) | Since: base-4.6.0.0 |
| Semigroup (Proxy s) | Since: base-4.9.0.0 |
| Monoid (Proxy s) | Since: base-4.7.0.0 |
| Hashable (Proxy a) | |
Defined in Data.Hashable.Class | |
| ToJSON (Proxy a) | |
Defined in Data.Aeson.Types.ToJSON | |
| NFData (Proxy a) | Since: deepseq-1.4.0.0 |
Defined in Control.DeepSeq | |
| Semiring (Proxy a) | |
| SuppressUnusedWarnings (Elem_6989586621680822846Sym0 :: TyFun a (Proxy a ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Pure_6989586621680786669Sym0 :: TyFun a (Proxy a) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Sum_6989586621680822854Sym0 :: TyFun (Proxy a) a -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Product_6989586621680822860Sym0 :: TyFun (Proxy a) a -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fold_6989586621680822783Sym0 :: TyFun (Proxy m) m -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr1_6989586621680822825Sym0 :: TyFun (a ~> (a ~> a)) (Proxy a ~> a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl1_6989586621680822816Sym0 :: TyFun (a ~> (a ~> a)) (Proxy a ~> a) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| TestCoercion (SProxy :: Proxy t -> Type) | |
Defined in Data.Singletons.Prelude.Proxy | |
| TestEquality (SProxy :: Proxy t -> Type) | |
Defined in Data.Singletons.Prelude.Proxy | |
| SuppressUnusedWarnings (Mconcat_6989586621680786654Sym0 :: TyFun [Proxy s] (Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ToEnum_6989586621680786603Sym0 :: TyFun Nat (Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ShowsPrec_6989586621680786572Sym0 :: TyFun Nat (Proxy s ~> (Symbol ~> Symbol)) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Sequence_6989586621681087727Sym0 :: TyFun (Proxy (m a)) (m (Proxy a)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (SequenceA_6989586621681087712Sym0 :: TyFun (Proxy (f a)) (f (Proxy a)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr1_6989586621680822825Sym1 a6989586621680822830 :: TyFun (Proxy a) a -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl1_6989586621680822816Sym1 a6989586621680822821 :: TyFun (Proxy a) a -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786676Sym0 :: TyFun (Proxy (a ~> b)) (Proxy a ~> Proxy b) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Elem_6989586621680822846Sym1 a6989586621680822851 :: TyFun (Proxy a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Null_6989586621680822839Sym0 :: TyFun (Proxy a) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Length_6989586621680822833Sym0 :: TyFun (Proxy a) Nat -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786688Sym0 :: TyFun (Proxy a) (Proxy a ~> Proxy a) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786637Sym0 :: TyFun (Proxy s) (Proxy s ~> Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786553Sym0 :: TyFun (Proxy s) (Proxy s ~> Bool) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Succ_6989586621680786585Sym0 :: TyFun (Proxy s) (Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Pred_6989586621680786591Sym0 :: TyFun (Proxy s) (Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FromEnum_6989586621680786597Sym0 :: TyFun (Proxy s) Nat -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (EnumFromTo_6989586621680786628Sym0 :: TyFun (Proxy s) (Proxy s ~> [Proxy s]) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (EnumFromThenTo_6989586621680786617Sym0 :: TyFun (Proxy s) (Proxy s ~> (Proxy s ~> [Proxy s])) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621680786562Sym0 :: TyFun (Proxy s) (Proxy s ~> Ordering) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Sconcat_6989586621680786645Sym0 :: TyFun (NonEmpty (Proxy s)) (Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822791Sym0 :: TyFun (a ~> (b ~> b)) (b ~> (Proxy a ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl_6989586621680822804Sym0 :: TyFun (b ~> (a ~> b)) (b ~> (Proxy a ~> b)) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FoldMap_6989586621680822775Sym0 :: TyFun (a ~> m) (Proxy a ~> m) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fmap_6989586621680786661Sym0 :: TyFun (a ~> b) (Proxy a ~> Proxy b) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822791Sym1 a6989586621680822797 :: TyFun b (Proxy a ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl_6989586621680822804Sym1 a6989586621680822810 :: TyFun b (Proxy a ~> b) -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (FoldMap_6989586621680822775Sym1 a6989586621680822780 :: TyFun (Proxy a) m -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786697Sym0 :: TyFun (Proxy a) ((a ~> Proxy b) ~> Proxy b) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786676Sym1 a6989586621680786681 :: TyFun (Proxy a) (Proxy b) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Fmap_6989586621680786661Sym1 a6989586621680786666 :: TyFun (Proxy a) (Proxy b) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786688Sym1 a6989586621680786693 :: TyFun (Proxy a) (Proxy a) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786637Sym1 a6989586621680786642 :: TyFun (Proxy s) (Proxy s) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786553Sym1 a6989586621680786558 :: TyFun (Proxy s) Bool -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (ShowsPrec_6989586621680786572Sym1 a6989586621680786580 :: TyFun (Proxy s) (Symbol ~> Symbol) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (EnumFromTo_6989586621680786628Sym1 a6989586621680786633 :: TyFun (Proxy s) [Proxy s] -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (EnumFromThenTo_6989586621680786617Sym1 a6989586621680786623 :: TyFun (Proxy s) (Proxy s ~> [Proxy s]) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Compare_6989586621680786562Sym1 a6989586621680786567 :: TyFun (Proxy s) Ordering -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Traverse_6989586621681087704Sym0 :: TyFun (a ~> f b) (Proxy a ~> f (Proxy b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MapM_6989586621681087719Sym0 :: TyFun (a ~> m b) (Proxy a ~> m (Proxy b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Traverse_6989586621681087704Sym1 a6989586621681087709 :: TyFun (Proxy a) (f (Proxy b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (MapM_6989586621681087719Sym1 a6989586621681087724 :: TyFun (Proxy a) (m (Proxy b)) -> Type) | |
Defined in Data.Singletons.Prelude.Traversable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldr_6989586621680822791Sym2 a6989586621680822797 a6989586621680822798 :: TyFun (Proxy a) b -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (Foldl_6989586621680822804Sym2 a6989586621680822810 a6989586621680822811 :: TyFun (Proxy a) b -> Type) | |
Defined in Data.Singletons.Prelude.Foldable Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (EnumFromThenTo_6989586621680786617Sym2 a6989586621680786623 a6989586621680786624 :: TyFun (Proxy s) [Proxy s] -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| SuppressUnusedWarnings (TFHelper_6989586621680786697Sym1 a6989586621680786702 :: TyFun (a ~> Proxy b) (Proxy b) -> Type) | |
Defined in Data.Singletons.Prelude.Proxy Methods suppressUnusedWarnings :: () # | |
| type MapM (a2 :: a1 ~> m b) (a3 :: Proxy a1) | |
| type Traverse (a2 :: a1 ~> f b) (a3 :: Proxy a1) | |
| type LiftA2 (arg1 :: a ~> (b ~> c)) (arg2 :: Proxy a) (arg3 :: Proxy b) | |
| type FoldMap (a2 :: a1 ~> k2) (a3 :: Proxy a1) | |
| type Fmap (a2 :: a1 ~> b) (a3 :: Proxy a1) | |
| type Foldl' (arg1 :: b ~> (a ~> b)) (arg2 :: b) (arg3 :: Proxy a) | |
| type Foldl (a2 :: k2 ~> (a1 ~> k2)) (a3 :: k2) (a4 :: Proxy a1) | |
| type Foldr' (arg1 :: a ~> (b ~> b)) (arg2 :: b) (arg3 :: Proxy a) | |
| type Foldr (a2 :: a1 ~> (k2 ~> k2)) (a3 :: k2) (a4 :: Proxy a1) | |
| type Rep1 (Proxy :: k -> Type) | |
| type Pure (a :: k1) | |
| type Return (arg :: a) | |
| type Empty | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Mzero | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Elem (a1 :: k1) (a2 :: Proxy k1) | |
| type Foldl1 (a1 :: k2 ~> (k2 ~> k2)) (a2 :: Proxy k2) | |
| type Foldr1 (a1 :: k2 ~> (k2 ~> k2)) (a2 :: Proxy k2) | |
| type (arg1 :: a) <$ (arg2 :: Proxy b) | |
| type (a2 :: Proxy a1) <|> (a3 :: Proxy a1) | |
| type Mplus (arg1 :: Proxy a) (arg2 :: Proxy a) | |
| type Apply (Elem_6989586621680822846Sym0 :: TyFun a (Proxy a ~> Bool) -> Type) (a6989586621680822851 :: a) | |
| type Apply (Pure_6989586621680786669Sym0 :: TyFun a (Proxy a) -> Type) (a6989586621680786673 :: a) | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Apply (ToEnum_6989586621680786603Sym0 :: TyFun Nat (Proxy s) -> Type) (a6989586621680786607 :: Nat) | |
| type Apply (ShowsPrec_6989586621680786572Sym0 :: TyFun Nat (Proxy s ~> (Symbol ~> Symbol)) -> Type) (a6989586621680786580 :: Nat) | |
| type Apply (Foldr_6989586621680822791Sym1 a6989586621680822797 :: TyFun b (Proxy a ~> b) -> Type) (a6989586621680822798 :: b) | |
| type Apply (Foldl_6989586621680822804Sym1 a6989586621680822810 :: TyFun b (Proxy a ~> b) -> Type) (a6989586621680822811 :: b) | |
| type Rep (Proxy :: Type -> Type) | |
| type Product (a :: Proxy k2) | |
| type Sum (a :: Proxy k2) | |
| type Minimum (arg :: Proxy a) | |
| type Maximum (arg :: Proxy a) | |
| type Length (a2 :: Proxy a1) | |
| type Null (a2 :: Proxy a1) | |
| type ToList (arg :: Proxy a) | |
| type Fold (a :: Proxy k2) | |
| type Sequence (a2 :: Proxy (m a1)) | |
| type SequenceA (a2 :: Proxy (f a1)) | |
| type (arg1 :: Proxy a) <* (arg2 :: Proxy b) | |
| type (arg1 :: Proxy a) *> (arg2 :: Proxy b) | |
| type (a2 :: Proxy (a1 ~> b)) <*> (a3 :: Proxy a1) | |
| type (arg1 :: Proxy a) >> (arg2 :: Proxy b) | |
| type (a2 :: Proxy a1) >>= (a3 :: a1 ~> Proxy b) | |
| type Apply (Mconcat_6989586621680786654Sym0 :: TyFun [Proxy s] (Proxy s) -> Type) (a6989586621680786658 :: [Proxy s]) | |
| type Apply (Sconcat_6989586621680786645Sym0 :: TyFun (NonEmpty (Proxy s)) (Proxy s) -> Type) (a6989586621680786649 :: NonEmpty (Proxy s)) | |
| type Rep (Proxy t) | |
| type Mempty | |
Defined in Data.Singletons.Prelude.Proxy | |
| type MaxBound | |
Defined in Data.Singletons.Prelude.Proxy | |
| type MinBound | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Sing | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Demote (Proxy t) | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Mconcat (a :: [Proxy s]) | |
| type Show_ (arg :: Proxy s) | |
| type Sconcat (a :: NonEmpty (Proxy s)) | |
| type FromEnum (a :: Proxy s) | |
| type ToEnum a | |
| type Pred (a :: Proxy s) | |
| type Succ (a :: Proxy s) | |
| type Mappend (arg1 :: Proxy s) (arg2 :: Proxy s) | |
| type ShowList (arg1 :: [Proxy s]) arg2 | |
| type (a1 :: Proxy s) <> (a2 :: Proxy s) | |
| type EnumFromTo (a1 :: Proxy s) (a2 :: Proxy s) | |
| type Min (arg1 :: Proxy s) (arg2 :: Proxy s) | |
| type Max (arg1 :: Proxy s) (arg2 :: Proxy s) | |
| type (arg1 :: Proxy s) >= (arg2 :: Proxy s) | |
| type (arg1 :: Proxy s) > (arg2 :: Proxy s) | |
| type (arg1 :: Proxy s) <= (arg2 :: Proxy s) | |
| type (arg1 :: Proxy s) < (arg2 :: Proxy s) | |
| type Compare (a1 :: Proxy s) (a2 :: Proxy s) | |
| type (x :: Proxy s) /= (y :: Proxy s) | |
| type (a1 :: Proxy s) == (a2 :: Proxy s) | |
| type ShowsPrec a1 (a2 :: Proxy s) a3 | |
| type EnumFromThenTo (a1 :: Proxy s) (a2 :: Proxy s) (a3 :: Proxy s) | |
| type Apply (Fold_6989586621680822783Sym0 :: TyFun (Proxy m) m -> Type) (a6989586621680822787 :: Proxy m) | |
| type Apply (Sum_6989586621680822854Sym0 :: TyFun (Proxy a) a -> Type) (a6989586621680822858 :: Proxy a) | |
| type Apply (Product_6989586621680822860Sym0 :: TyFun (Proxy a) a -> Type) (a6989586621680822864 :: Proxy a) | |
| type Apply (Foldl1_6989586621680822816Sym1 a6989586621680822821 :: TyFun (Proxy a) a -> Type) (a6989586621680822822 :: Proxy a) | |
| type Apply (Foldr1_6989586621680822825Sym1 a6989586621680822830 :: TyFun (Proxy a) a -> Type) (a6989586621680822831 :: Proxy a) | |
| type Apply (Elem_6989586621680822846Sym1 a6989586621680822851 :: TyFun (Proxy a) Bool -> Type) (a6989586621680822852 :: Proxy a) | |
| type Apply (Length_6989586621680822833Sym0 :: TyFun (Proxy a) Nat -> Type) (a6989586621680822837 :: Proxy a) | |
| type Apply (Null_6989586621680822839Sym0 :: TyFun (Proxy a) Bool -> Type) (a6989586621680822843 :: Proxy a) | |
| type Apply (FromEnum_6989586621680786597Sym0 :: TyFun (Proxy s) Nat -> Type) (a6989586621680786601 :: Proxy s) | |
| type Apply (FoldMap_6989586621680822775Sym1 a6989586621680822780 :: TyFun (Proxy a) m -> Type) (a6989586621680822781 :: Proxy a) | |
| type Apply (TFHelper_6989586621680786553Sym1 a6989586621680786558 :: TyFun (Proxy s) Bool -> Type) (a6989586621680786559 :: Proxy s) | |
| type Apply (Compare_6989586621680786562Sym1 a6989586621680786567 :: TyFun (Proxy s) Ordering -> Type) (a6989586621680786568 :: Proxy s) | |
| type Apply (Foldr_6989586621680822791Sym2 a6989586621680822797 a6989586621680822798 :: TyFun (Proxy a) b -> Type) (a6989586621680822799 :: Proxy a) | |
| type Apply (Foldl_6989586621680822804Sym2 a6989586621680822810 a6989586621680822811 :: TyFun (Proxy a) b -> Type) (a6989586621680822812 :: Proxy a) | |
| type Apply (SequenceA_6989586621681087712Sym0 :: TyFun (Proxy (f a)) (f (Proxy a)) -> Type) (a6989586621681087716 :: Proxy (f a)) | |
| type Apply (Sequence_6989586621681087727Sym0 :: TyFun (Proxy (m a)) (m (Proxy a)) -> Type) (a6989586621681087731 :: Proxy (m a)) | |
| type Apply (EnumFromTo_6989586621680786628Sym1 a6989586621680786633 :: TyFun (Proxy s) [Proxy s] -> Type) (a6989586621680786634 :: Proxy s) | |
| type Apply (Traverse_6989586621681087704Sym1 a6989586621681087709 :: TyFun (Proxy a) (f (Proxy b)) -> Type) (a6989586621681087710 :: Proxy a) | |
| type Apply (MapM_6989586621681087719Sym1 a6989586621681087724 :: TyFun (Proxy a) (m (Proxy b)) -> Type) (a6989586621681087725 :: Proxy a) | |
| type Apply (EnumFromThenTo_6989586621680786617Sym2 a6989586621680786623 a6989586621680786624 :: TyFun (Proxy s) [Proxy s] -> Type) (a6989586621680786625 :: Proxy s) | |
Defined in Data.Singletons.Prelude.Proxy | |
| type Apply (Foldl1_6989586621680822816Sym0 :: TyFun (a ~> (a ~> a)) (Proxy a ~> a) -> Type) (a6989586621680822821 :: a ~> (a ~> a)) | |
| type Apply (Foldr1_6989586621680822825Sym0 :: TyFun (a ~> (a ~> a)) (Proxy a ~> a) -> Type) (a6989586621680822830 :: a ~> (a ~> a)) | |
| type Apply (TFHelper_6989586621680786676Sym0 :: TyFun (Proxy (a ~> b)) (Proxy a ~> Proxy b) -> Type) (a6989586621680786681 :: Proxy (a ~> b)) | |
| type Apply (TFHelper_6989586621680786553Sym0 :: TyFun (Proxy s) (Proxy s ~> Bool) -> Type) (a6989586621680786558 :: Proxy s) | |
| type Apply (Compare_6989586621680786562Sym0 :: TyFun (Proxy s) (Proxy s ~> Ordering) -> Type) (a6989586621680786567 :: Proxy s) | |
| type Apply (Succ_6989586621680786585Sym0 :: TyFun (Proxy s) (Proxy s) -> Type) (a6989586621680786589 :: Proxy s) | |
| type Apply (Pred_6989586621680786591Sym0 :: TyFun (Proxy s) (Proxy s) -> Type) (a6989586621680786595 :: Proxy s) | |
| type Apply (EnumFromThenTo_6989586621680786617Sym0 :: TyFun (Proxy s) (Proxy s ~> (Proxy s ~> [Proxy s])) -> Type) (a6989586621680786623 :: Proxy s) | |
| type Apply (EnumFromTo_6989586621680786628Sym0 :: TyFun (Proxy s) (Proxy s ~> [Proxy s]) -> Type) (a6989586621680786633 :: Proxy s) | |
| type Apply (TFHelper_6989586621680786637Sym0 :: TyFun (Proxy s) (Proxy s ~> Proxy s) -> Type) (a6989586621680786642 :: Proxy s) | |
| type Apply (TFHelper_6989586621680786688Sym0 :: TyFun (Proxy a) (Proxy a ~> Proxy a) -> Type) (a6989586621680786693 :: Proxy a) | |
| type Apply (FoldMap_6989586621680822775Sym0 :: TyFun (a ~> m) (Proxy a ~> m) -> Type) (a6989586621680822780 :: a ~> m) | |
| type Apply (Foldr_6989586621680822791Sym0 :: TyFun (a ~> (b ~> b)) (b ~> (Proxy a ~> b)) -> Type) (a6989586621680822797 :: a ~> (b ~> b)) | |
| type Apply (Foldl_6989586621680822804Sym0 :: TyFun (b ~> (a ~> b)) (b ~> (Proxy a ~> b)) -> Type) (a6989586621680822810 :: b ~> (a ~> b)) | |
| type Apply (Fmap_6989586621680786661Sym0 :: TyFun (a ~> b) (Proxy a ~> Proxy b) -> Type) (a6989586621680786666 :: a ~> b) | |
| type Apply (Fmap_6989586621680786661Sym1 a6989586621680786666 :: TyFun (Proxy a) (Proxy b) -> Type) (a6989586621680786667 :: Proxy a) | |
| type Apply (TFHelper_6989586621680786676Sym1 a6989586621680786681 :: TyFun (Proxy a) (Proxy b) -> Type) (a6989586621680786682 :: Proxy a) | |
| type Apply (TFHelper_6989586621680786697Sym0 :: TyFun (Proxy a) ((a ~> Proxy b) ~> Proxy b) -> Type) (a6989586621680786702 :: Proxy a) | |
| type Apply (ShowsPrec_6989586621680786572Sym1 a6989586621680786580 :: TyFun (Proxy s) (Symbol ~> Symbol) -> Type) (a6989586621680786581 :: Proxy s) | |
| type Apply (EnumFromThenTo_6989586621680786617Sym1 a6989586621680786623 :: TyFun (Proxy s) (Proxy s ~> [Proxy s]) -> Type) (a6989586621680786624 :: Proxy s) | |
| type Apply (TFHelper_6989586621680786637Sym1 a6989586621680786642 :: TyFun (Proxy s) (Proxy s) -> Type) (a6989586621680786643 :: Proxy s) | |
| type Apply (TFHelper_6989586621680786688Sym1 a6989586621680786693 :: TyFun (Proxy a) (Proxy a) -> Type) (a6989586621680786694 :: Proxy a) | |
| type Apply (Traverse_6989586621681087704Sym0 :: TyFun (a ~> f b) (Proxy a ~> f (Proxy b)) -> Type) (a6989586621681087709 :: a ~> f b) | |
| type Apply (MapM_6989586621681087719Sym0 :: TyFun (a ~> m b) (Proxy a ~> m (Proxy b)) -> Type) (a6989586621681087724 :: a ~> m b) | |
| type Apply (TFHelper_6989586621680786697Sym1 a6989586621680786702 :: TyFun (a ~> Proxy b) (Proxy b) -> Type) (a6989586621680786703 :: a ~> Proxy b) | |
withDict :: HasDict c e => e -> (c => r) -> r #
From a Dict, takes a value in an environment where the instance
witnessed by the Dict is in scope, and evaluates it.
Essentially a deconstruction of a Dict into its continuation-style
form.
Can also be used to deconstruct an entailment, a , using a context :- ba.
withDict ::Dictc -> (c => r) -> r withDict :: a => (a:-c) -> (c => r) -> r
A set of values a.
Instances
| Foldable Set | Folds in order of increasing key. |
Defined in Data.Set.Internal Methods fold :: Monoid m => Set m -> m # foldMap :: Monoid m => (a -> m) -> Set a -> m # foldMap' :: Monoid m => (a -> m) -> Set a -> m # foldr :: (a -> b -> b) -> b -> Set a -> b # foldr' :: (a -> b -> b) -> b -> Set a -> b # foldl :: (b -> a -> b) -> b -> Set a -> b # foldl' :: (b -> a -> b) -> b -> Set a -> b # foldr1 :: (a -> a -> a) -> Set a -> a # foldl1 :: (a -> a -> a) -> Set a -> a # elem :: Eq a => a -> Set a -> Bool # maximum :: Ord a => Set a -> a # | |
| ToJSON1 Set | |
Defined in Data.Aeson.Types.ToJSON Methods liftToJSON :: (a -> Value) -> ([a] -> Value) -> Set a -> Value # liftToJSONList :: (a -> Value) -> ([a] -> Value) -> [Set a] -> Value # liftToEncoding :: (a -> Encoding) -> ([a] -> Encoding) -> Set a -> Encoding # liftToEncodingList :: (a -> Encoding) -> ([a] -> Encoding) -> [Set a] -> Encoding # | |
| Eq1 Set | Since: containers-0.5.9 |
| Ord1 Set | Since: containers-0.5.9 |
Defined in Data.Set.Internal | |
| Show1 Set | Since: containers-0.5.9 |
| Ord a => IsList (Set a) | Since: containers-0.5.6.2 |
| Eq a => Eq (Set a) | |
| (Data a, Ord a) => Data (Set a) | |
Defined in Data.Set.Internal Methods gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> Set a -> c (Set a) # gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c (Set a) # dataTypeOf :: Set a -> DataType # dataCast1 :: Typeable t => (forall d. Data d => c (t d)) -> Maybe (c (Set a)) # dataCast2 :: Typeable t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c (Set a)) # gmapT :: (forall b. Data b => b -> b) -> Set a -> Set a # gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> Set a -> r # gmapQr :: forall r r'. (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> Set a -> r # gmapQ :: (forall d. Data d => d -> u) -> Set a -> [u] # gmapQi :: Int -> (forall d. Data d => d -> u) -> Set a -> u # gmapM :: Monad m => (forall d. Data d => d -> m d) -> Set a -> m (Set a) # gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> Set a -> m (Set a) # gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> Set a -> m (Set a) # | |
| Ord a => Ord (Set a) | |
| (Read a, Ord a) => Read (Set a) | |
| Show a => Show (Set a) | |
| Ord a => Semigroup (Set a) | Since: containers-0.5.7 |
| Ord a => Monoid (Set a) | |
| ToJSON a => ToJSON (Set a) | |
Defined in Data.Aeson.Types.ToJSON | |
| NFData a => NFData (Set a) | |
Defined in Data.Set.Internal | |
| Ord a => Contains (Set a) | |
| Ord k => Ixed (Set k) | |
Defined in Control.Lens.At | |
| Ord k => At (Set k) | |
| Ord a => Wrapped (Set a) | |
| (Ord a, Monoid a) => Semiring (Set a) | The multiplication laws are satisfied for
any underlying |
| Ord v => Container (Set v) | |
Defined in Universum.Container.Class Methods toList :: Set v -> [Element (Set v)] # foldr :: (Element (Set v) -> b -> b) -> b -> Set v -> b # foldl :: (b -> Element (Set v) -> b) -> b -> Set v -> b # foldl' :: (b -> Element (Set v) -> b) -> b -> Set v -> b # elem :: Element (Set v) -> Set v -> Bool # maximum :: Set v -> Element (Set v) # minimum :: Set v -> Element (Set v) # foldMap :: Monoid m => (Element (Set v) -> m) -> Set v -> m # fold :: Set v -> Element (Set v) # foldr' :: (Element (Set v) -> b -> b) -> b -> Set v -> b # foldr1 :: (Element (Set v) -> Element (Set v) -> Element (Set v)) -> Set v -> Element (Set v) # foldl1 :: (Element (Set v) -> Element (Set v) -> Element (Set v)) -> Set v -> Element (Set v) # notElem :: Element (Set v) -> Set v -> Bool # all :: (Element (Set v) -> Bool) -> Set v -> Bool # any :: (Element (Set v) -> Bool) -> Set v -> Bool # find :: (Element (Set v) -> Bool) -> Set v -> Maybe (Element (Set v)) # | |
| One (Set v) | |
| PolyCTypeHasDocC '[a] => TypeHasDoc (Set a) | |
Defined in Michelson.Typed.Haskell.Doc Associated Types type TypeDocFieldDescriptions (Set a) :: FieldDescriptions # Methods typeDocName :: Proxy (Set a) -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy (Set a) -> WithinParens -> Markdown # typeDocDependencies :: Proxy (Set a) -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep (Set a) # typeDocMichelsonRep :: TypeDocMichelsonRep (Set a) # | |
| (Comparable (ToT c), Ord c, IsoValue c) => IsoValue (Set c) | |
| KnownIsoT v => HasAnnotation (Set v) Source # | |
Defined in Lorentz.Annotation Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT (Set v)) Source # | |
| NiceComparable a => UpdOpHs (Set a) Source # | |
Defined in Lorentz.Polymorphic | |
| SizeOpHs (Set a) Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable e => IterOpHs (Set e) Source # | |
Defined in Lorentz.Polymorphic Associated Types type IterOpElHs (Set e) Source # | |
| NiceComparable e => MemOpHs (Set e) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MemOpKeyHs (Set e) Source # | |
| LDefault (Set k) Source # | |
| (t ~ Set a', Ord a) => Rewrapped (Set a) t | Use |
Defined in Control.Lens.Wrapped | |
| CanCastTo k1 k2 => CanCastTo (Set k1 :: Type) (Set k2 :: Type) Source # | |
| NiceComparable key => StoreHasSubmap (Set key) SelfRef key () Source # | |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps (Set key) SelfRef key () Source # | |
| type Item (Set a) | |
Defined in Data.Set.Internal | |
| type Index (Set a) | |
Defined in Control.Lens.At | |
| type IxValue (Set k) | |
Defined in Control.Lens.At | |
| type Unwrapped (Set a) | |
Defined in Control.Lens.Wrapped | |
| type Element (Set v) | |
Defined in Universum.Container.Class | |
| type OneItem (Set v) | |
Defined in Universum.Container.Class | |
| type TypeDocFieldDescriptions (Set a) | |
Defined in Michelson.Typed.Haskell.Doc | |
| type ToT (Set c) | |
Defined in Michelson.Typed.Haskell.Value | |
| type UpdOpKeyHs (Set a) Source # | |
Defined in Lorentz.Polymorphic | |
| type UpdOpParamsHs (Set a) Source # | |
Defined in Lorentz.Polymorphic | |
| type IterOpElHs (Set e) Source # | |
Defined in Lorentz.Polymorphic | |
| type MemOpKeyHs (Set e) Source # | |
Defined in Lorentz.Polymorphic | |
A class for types with a default value.
Minimal complete definition
Nothing
Instances
arg :: forall (name :: Symbol) a. Name name -> (name :! a) -> a #
arg unwraps a named parameter with the specified name. One way to use it is
to match on arguments with -XViewPatterns:
fn (arg #t -> t) (arg #f -> f) = ...
This way, the names of parameters can be inferred from the patterns: no type
signature for fn is required. In case a type signature for fn is
provided, the parameters must come in the same order:
fn :: "t" :! Integer -> "f" :! Integer -> ... fn (arg #t -> t) (arg #f -> f) = ... -- ok fn (arg #f -> f) (arg #t -> t) = ... -- does not typecheck
type (:!) (name :: Symbol) a = NamedF Identity a name #
Infix notation for the type of a named parameter.
type (:?) (name :: Symbol) a = NamedF Maybe a name #
Infix notation for the type of an optional named parameter.
type ($) (f :: k1 -> k) (a :: k1) = f a infixr 2 #
Infix application.
f :: Either String $ Maybe Int = f :: Either String (Maybe Int)
undefined :: forall (r :: RuntimeRep) (a :: TYPE r). HasCallStack => a #
undefined that leaves a warning in code on every usage.
error :: forall (r :: RuntimeRep) (a :: TYPE r). HasCallStack => Text -> a #
data Rec (a :: u -> Type) (b :: [u]) where #
A record is parameterized by a universe u, an interpretation f and a
list of rows rs. The labels or indices of the record are given by
inhabitants of the kind u; the type of values at any label r :: u is
given by its interpretation f r :: *.
Constructors
| RNil :: forall u (a :: u -> Type). Rec a ('[] :: [u]) | |
| (:&) :: forall u (a :: u -> Type) (r :: u) (rs :: [u]). !(a r) -> !(Rec a rs) -> Rec a (r ': rs) infixr 7 |
Instances
| RecSubset (Rec :: (k -> Type) -> [k] -> Type) ('[] :: [k]) (ss :: [k]) ('[] :: [Nat]) | |
Defined in Data.Vinyl.Lens Associated Types type RecSubsetFCtx Rec f # Methods rsubsetC :: forall g (f :: k0 -> Type). (Functor g, RecSubsetFCtx Rec f) => (Rec f '[] -> g (Rec f '[])) -> Rec f ss -> g (Rec f ss) # rcastC :: forall (f :: k0 -> Type). RecSubsetFCtx Rec f => Rec f ss -> Rec f '[] # rreplaceC :: forall (f :: k0 -> Type). RecSubsetFCtx Rec f => Rec f '[] -> Rec f ss -> Rec f ss # | |
| (RElem r ss i, RSubset rs ss is) => RecSubset (Rec :: (k -> Type) -> [k] -> Type) (r ': rs :: [k]) (ss :: [k]) (i ': is) | |
Defined in Data.Vinyl.Lens Associated Types type RecSubsetFCtx Rec f # Methods rsubsetC :: forall g (f :: k0 -> Type). (Functor g, RecSubsetFCtx Rec f) => (Rec f (r ': rs) -> g (Rec f (r ': rs))) -> Rec f ss -> g (Rec f ss) # rcastC :: forall (f :: k0 -> Type). RecSubsetFCtx Rec f => Rec f ss -> Rec f (r ': rs) # rreplaceC :: forall (f :: k0 -> Type). RecSubsetFCtx Rec f => Rec f (r ': rs) -> Rec f ss -> Rec f ss # | |
| RecElem (Rec :: (a -> Type) -> [a] -> Type) (r :: a) (r' :: a) (r ': rs :: [a]) (r' ': rs :: [a]) 'Z | |
Defined in Data.Vinyl.Lens Associated Types type RecElemFCtx Rec f # | |
| (RIndex r (s ': rs) ~ 'S i, RecElem (Rec :: (a -> Type) -> [a] -> Type) r r' rs rs' i) => RecElem (Rec :: (a -> Type) -> [a] -> Type) (r :: a) (r' :: a) (s ': rs :: [a]) (s ': rs' :: [a]) ('S i) | |
Defined in Data.Vinyl.Lens Associated Types type RecElemFCtx Rec f # | |
| TestCoercion f => TestCoercion (Rec f :: [u] -> Type) | |
Defined in Data.Vinyl.Core | |
| TestEquality f => TestEquality (Rec f :: [u] -> Type) | |
Defined in Data.Vinyl.Core | |
| Eq (Rec f ('[] :: [u])) | |
| (Eq (f r), Eq (Rec f rs)) => Eq (Rec f (r ': rs)) | |
| Ord (Rec f ('[] :: [u])) | |
| (Ord (f r), Ord (Rec f rs)) => Ord (Rec f (r ': rs)) | |
Defined in Data.Vinyl.Core Methods compare :: Rec f (r ': rs) -> Rec f (r ': rs) -> Ordering # (<) :: Rec f (r ': rs) -> Rec f (r ': rs) -> Bool # (<=) :: Rec f (r ': rs) -> Rec f (r ': rs) -> Bool # (>) :: Rec f (r ': rs) -> Rec f (r ': rs) -> Bool # (>=) :: Rec f (r ': rs) -> Rec f (r ': rs) -> Bool # max :: Rec f (r ': rs) -> Rec f (r ': rs) -> Rec f (r ': rs) # min :: Rec f (r ': rs) -> Rec f (r ': rs) -> Rec f (r ': rs) # | |
| (RMap rs, ReifyConstraint Show f rs, RecordToList rs) => Show (Rec f rs) | Records may be shown insofar as their points may be shown.
|
| Generic (Rec f ('[] :: [u])) | |
| Generic (Rec f rs) => Generic (Rec f (r ': rs)) | |
| Semigroup (Rec f ('[] :: [u])) | |
| (Semigroup (f r), Semigroup (Rec f rs)) => Semigroup (Rec f (r ': rs)) | |
| Monoid (Rec f ('[] :: [u])) | |
| (Monoid (f r), Monoid (Rec f rs)) => Monoid (Rec f (r ': rs)) | |
| Storable (Rec f ('[] :: [u])) | |
Defined in Data.Vinyl.Core | |
| (Storable (f r), Storable (Rec f rs)) => Storable (Rec f (r ': rs)) | |
Defined in Data.Vinyl.Core Methods sizeOf :: Rec f (r ': rs) -> Int # alignment :: Rec f (r ': rs) -> Int # peekElemOff :: Ptr (Rec f (r ': rs)) -> Int -> IO (Rec f (r ': rs)) # pokeElemOff :: Ptr (Rec f (r ': rs)) -> Int -> Rec f (r ': rs) -> IO () # peekByteOff :: Ptr b -> Int -> IO (Rec f (r ': rs)) # pokeByteOff :: Ptr b -> Int -> Rec f (r ': rs) -> IO () # | |
| type RecSubsetFCtx (Rec :: (k -> Type) -> [k] -> Type) (f :: k -> Type) | |
Defined in Data.Vinyl.Lens | |
| type RecSubsetFCtx (Rec :: (k -> Type) -> [k] -> Type) (f :: k -> Type) | |
Defined in Data.Vinyl.Lens | |
| type RecElemFCtx (Rec :: (a -> Type) -> [a] -> Type) (f :: a -> Type) | |
Defined in Data.Vinyl.Lens | |
| type RecElemFCtx (Rec :: (a -> Type) -> [a] -> Type) (f :: a -> Type) | |
Defined in Data.Vinyl.Lens | |
| type Rep (Rec f (r ': rs)) | |
Defined in Data.Vinyl.Core type Rep (Rec f (r ': rs)) = C1 ('MetaCons ":&" ('InfixI 'RightAssociative 7) 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'SourceStrict 'DecidedStrict) (Rec0 (f r)) :*: S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rep (Rec f rs))) | |
| type Rep (Rec f ('[] :: [u])) | |
Defined in Data.Vinyl.Core | |
| type IsoRecTuple (Rec f '[a]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[a]) = f a | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22, x23, x24, x25]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22, x23, x24, x25]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19, f x20, f x21, f x22, f x23, f x24, f x25) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22, x23, x24]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22, x23, x24]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19, f x20, f x21, f x22, f x23, f x24) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22, x23]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22, x23]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19, f x20, f x21, f x22, f x23) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21, x22]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19, f x20, f x21, f x22) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20, x21]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19, f x20, f x21) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19, x20]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19, f x20) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18, x19]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18, f x19) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17, x18]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17, f x18) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16, x17]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16, f x17) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15, x16]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15, f x16) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14, f x15) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13, f x14) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12, f x13) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11, f x12) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10, f x11) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9, f x10) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8, x9]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8, f x9) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7, x8]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7, f x8) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6, x7]) = (f x1, f x2, f x3, f x4, f x5, f x6, f x7) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5, x6]) = (f x1, f x2, f x3, f x4, f x5, f x6) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4, x5]) = (f x1, f x2, f x3, f x4, f x5) | |
| type IsoRecTuple (Rec f '[x1, x2, x3, x4]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3, x4]) = (f x1, f x2, f x3, f x4) | |
| type IsoRecTuple (Rec f '[x1, x2, x3]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2, x3]) = (f x1, f x2, f x3) | |
| type IsoRecTuple (Rec f '[x1, x2]) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f '[x1, x2]) = (f x1, f x2) | |
| type IsoRecTuple (Rec f ('[] :: [u])) | |
Defined in Util.TypeTuple.Instances type IsoRecTuple (Rec f ('[] :: [u])) = () | |
mt :: QuasiQuoter #
Instances
data Label (name :: Symbol) where #
Constructors
| Label :: forall (name :: Symbol). KnownSymbol name => Label name |
Instances
| (KnownSymbol name, s ~ name) => IsLabel s (Label name) | |
Defined in Util.Label | |
| Eq (Label name) | |
| Show (Label name) | |
| Buildable (Label name) | |
Defined in Util.Label | |
insertTypeAnn :: forall (b :: T). TypeAnn -> Notes b -> Notes b #
concreteTypeDocHaskellRep :: (Typeable a, GenericIsoValue a, GTypeHasDoc (Rep a), HaveCommonTypeCtor b a) => TypeDocHaskellRep b #
concreteTypeDocHaskellRepUnsafe :: (Typeable a, GenericIsoValue a, GTypeHasDoc (Rep a)) => TypeDocHaskellRep b #
concreteTypeDocMichelsonRep :: forall k a (b :: k). (Typeable a, SingI (ToT a), HaveCommonTypeCtor b a) => TypeDocMichelsonRep b #
concreteTypeDocMichelsonRepUnsafe :: forall k a (b :: k). (Typeable a, SingI (ToT a)) => TypeDocMichelsonRep b #
dStorage :: TypeHasDoc store => DStorageType #
dTypeDep :: TypeHasDoc t => SomeDocDefinitionItem #
genericTypeDocDependencies :: (Generic a, GTypeHasDoc (Rep a)) => Proxy a -> [SomeDocDefinitionItem] #
haskellAddNewtypeField :: Text -> TypeDocHaskellRep a -> TypeDocHaskellRep a #
haskellRepNoFields :: TypeDocHaskellRep a -> TypeDocHaskellRep a #
haskellRepStripFieldPrefix :: HasCallStack => TypeDocHaskellRep a -> TypeDocHaskellRep a #
homomorphicTypeDocHaskellRep :: (Generic a, GTypeHasDoc (Rep a)) => TypeDocHaskellRep a #
homomorphicTypeDocMdReference :: (Typeable t, TypeHasDoc t, IsHomomorphic t) => Proxy t -> WithinParens -> Markdown #
homomorphicTypeDocMichelsonRep :: SingI (ToT a) => TypeDocMichelsonRep a #
poly1TypeDocMdReference :: forall (t :: Type -> Type) r a. (r ~ t a, Typeable t, Each '[TypeHasDoc] '[r, a], IsHomomorphic t) => Proxy r -> WithinParens -> Markdown #
poly2TypeDocMdReference :: forall (t :: Type -> Type -> Type) r a b. (r ~ t a b, Typeable t, Each '[TypeHasDoc] '[r, a, b], IsHomomorphic t) => Proxy r -> WithinParens -> Markdown #
coerceContractRef :: ToT a ~ ToT b => ContractRef a -> ContractRef b #
Constructors
| EpAddress | |
Fields
| |
Instances
Constructors
| DType :: forall a. TypeHasDoc a => Proxy a -> DType |
Instances
| Eq DType | |
| Ord DType | |
| Show DType | |
| DocItem DType | |
Defined in Michelson.Typed.Haskell.Doc Associated Types type DocItemPlacement DType :: DocItemPlacementKind # type DocItemReferenced DType :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DType -> DocItemRef (DocItemPlacement DType) (DocItemReferenced DType) # docItemToMarkdown :: HeaderLevel -> DType -> Markdown # docItemToToc :: HeaderLevel -> DType -> Markdown # docItemDependencies :: DType -> [SomeDocDefinitionItem] # docItemsOrder :: [DType] -> [DType] # | |
| type DocItemPlacement DType | |
Defined in Michelson.Typed.Haskell.Doc | |
| type DocItemReferenced DType | |
Defined in Michelson.Typed.Haskell.Doc | |
class HaveCommonTypeCtor (a :: k) (b :: k1) #
Instances
| HaveCommonTypeCtor (a :: k) (a :: k) | |
Defined in Michelson.Typed.Haskell.Doc | |
| HaveCommonTypeCtor ac bc => HaveCommonTypeCtor (ac a :: k2) (bc b :: k4) | |
Defined in Michelson.Typed.Haskell.Doc | |
class IsHomomorphic (a :: k) #
Instances
| IsHomomorphic (a :: k) | |
Defined in Michelson.Typed.Haskell.Doc | |
| (TypeError ('Text "Type is not homomorphic: " :<>: 'ShowType (a b)) :: Constraint) => IsHomomorphic (a b :: k2) | |
Defined in Michelson.Typed.Haskell.Doc | |
data SomeTypeWithDoc where #
Constructors
| SomeTypeWithDoc :: forall td. TypeHasDoc td => Proxy td -> SomeTypeWithDoc |
type family TypeDocFieldDescriptions a :: FieldDescriptions #
Instances
class (Typeable a, SingI (TypeDocFieldDescriptions a), FieldDescriptionsValid (TypeDocFieldDescriptions a) a) => TypeHasDoc a where #
Minimal complete definition
Associated Types
type TypeDocFieldDescriptions a :: FieldDescriptions #
Methods
typeDocName :: Proxy a -> Text #
typeDocMdDescription :: Markdown #
typeDocMdReference :: Proxy a -> WithinParens -> Markdown #
typeDocDependencies :: Proxy a -> [SomeDocDefinitionItem] #
typeDocHaskellRep :: TypeDocHaskellRep a #
typeDocMichelsonRep :: TypeDocMichelsonRep a #
Instances
type ConstructorFieldTypes dt = GFieldTypes (Rep dt) #
type InstrConstructC dt = (GenericIsoValue dt, GInstrConstruct (Rep dt)) #
Instances
data ContractRef arg #
Constructors
| ContractRef | |
Fields
| |
Instances
type EntrypointCall param arg = EntrypointCallT (ToT param) (ToT arg) #
class WellTypedToT a => IsoValue a where #
Minimal complete definition
Nothing
Instances
Instances
type SomeEntrypointCall arg = SomeEntrypointCallT (ToT arg) #
type WellTypedIsoValue a = (WellTyped (ToT a), IsoValue a) #
Instances
| Eq EpName | |
| Ord EpName | |
| Show EpName | |
| Generic EpName | |
| ToJSON EpName | |
Defined in Michelson.Untyped.Entrypoints | |
| FromJSON EpName | |
| NFData EpName | |
Defined in Michelson.Untyped.Entrypoints | |
| Buildable EpName | |
Defined in Michelson.Untyped.Entrypoints | |
| HasCLReader EpName | |
Defined in Michelson.Untyped.Entrypoints | |
| type Rep EpName | |
Defined in Michelson.Untyped.Entrypoints | |
Instances
data Bls12381Fr #
Instances
data Bls12381G1 #
Instances
data Bls12381G2 #
Instances
Instances
Instances
Instances
Instances
Instances
Instances
class ContainsDoc a where #
Methods
buildDocUnfinalized :: a -> ContractDoc #
Instances
| ContainsDoc (i :-> o) Source # | |
Defined in Lorentz.Doc Methods buildDocUnfinalized :: (i :-> o) -> ContractDoc # | |
| ContainsDoc (Contract cp st) Source # | |
Defined in Lorentz.Run Methods buildDocUnfinalized :: Contract cp st -> ContractDoc # | |
class ContainsDoc a => ContainsUpdateableDoc a where #
Methods
modifyDocEntirely :: (SomeDocItem -> SomeDocItem) -> a -> a #
Instances
| ContainsUpdateableDoc (i :-> o) Source # | |
Defined in Lorentz.Doc Methods modifyDocEntirely :: (SomeDocItem -> SomeDocItem) -> (i :-> o) -> i :-> o # | |
| ContainsUpdateableDoc (Contract cp st) Source # | |
Defined in Lorentz.Run Methods modifyDocEntirely :: (SomeDocItem -> SomeDocItem) -> Contract cp st -> Contract cp st # | |
data SomeDocDefinitionItem where #
Constructors
| SomeDocDefinitionItem :: forall d. (DocItem d, DocItemPlacement d ~ 'DocItemInDefinitions) => d -> SomeDocDefinitionItem |
Instances
| Eq SomeDocDefinitionItem | |
Defined in Michelson.Doc Methods (==) :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Bool # (/=) :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Bool # | |
| Ord SomeDocDefinitionItem | |
Defined in Michelson.Doc Methods compare :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Ordering # (<) :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Bool # (<=) :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Bool # (>) :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Bool # (>=) :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> Bool # max :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> SomeDocDefinitionItem # min :: SomeDocDefinitionItem -> SomeDocDefinitionItem -> SomeDocDefinitionItem # | |
data SomeDocItem where #
Constructors
| SomeDocItem :: forall d. DocItem d => d -> SomeDocItem |
Instances
| Show SomeDocItem | |
Defined in Michelson.Doc Methods showsPrec :: Int -> SomeDocItem -> ShowS # show :: SomeDocItem -> String # showList :: [SomeDocItem] -> ShowS # | |
| Show DocGrouping | |
Defined in Michelson.Doc Methods showsPrec :: Int -> DocGrouping -> ShowS # show :: DocGrouping -> String # showList :: [DocGrouping] -> ShowS # | |
| NFData SomeDocItem | |
Defined in Michelson.Doc Methods rnf :: SomeDocItem -> () # | |
data ContractDoc #
Constructors
| ContractDoc | |
Fields
| |
Instances
| Semigroup ContractDoc | |
Defined in Michelson.Doc Methods (<>) :: ContractDoc -> ContractDoc -> ContractDoc # sconcat :: NonEmpty ContractDoc -> ContractDoc # stimes :: Integral b => b -> ContractDoc -> ContractDoc # | |
| Monoid ContractDoc | |
Defined in Michelson.Doc Methods mempty :: ContractDoc # mappend :: ContractDoc -> ContractDoc -> ContractDoc # mconcat :: [ContractDoc] -> ContractDoc # | |
Constructors
| SubDoc DocBlock |
Instances
| Show DocGrouping | |
Defined in Michelson.Doc Methods showsPrec :: Int -> DocGrouping -> ShowS # show :: DocGrouping -> String # showList :: [DocGrouping] -> ShowS # | |
| di ~ DName => IsString (SubDoc -> di) | |
Defined in Michelson.Doc Methods fromString :: String -> SubDoc -> di # | |
newtype DocItemPos #
Constructors
| DocItemPos (Natural, Text) |
Instances
| Eq DocItemPos | |
Defined in Michelson.Doc | |
| Ord DocItemPos | |
Defined in Michelson.Doc Methods compare :: DocItemPos -> DocItemPos -> Ordering # (<) :: DocItemPos -> DocItemPos -> Bool # (<=) :: DocItemPos -> DocItemPos -> Bool # (>) :: DocItemPos -> DocItemPos -> Bool # (>=) :: DocItemPos -> DocItemPos -> Bool # max :: DocItemPos -> DocItemPos -> DocItemPos # min :: DocItemPos -> DocItemPos -> DocItemPos # | |
| Show DocItemPos | |
Defined in Michelson.Doc Methods showsPrec :: Int -> DocItemPos -> ShowS # show :: DocItemPos -> String # showList :: [DocItemPos] -> ShowS # | |
| Buildable DocItemPos | |
Defined in Michelson.Doc Methods build :: DocItemPos -> Builder # | |
data DocSection #
Constructors
| DocItem d => DocSection (NonEmpty $ DocElem d) |
Instances
| Show DocSection | |
Defined in Michelson.Doc Methods showsPrec :: Int -> DocSection -> ShowS # show :: DocSection -> String # showList :: [DocSection] -> ShowS # | |
data DGitRevision #
Constructors
| DGitRevisionKnown DGitRevisionInfo | |
| DGitRevisionUnknown |
Instances
| DocItem DGitRevision | |
Defined in Michelson.Doc Associated Types type DocItemPlacement DGitRevision :: DocItemPlacementKind # type DocItemReferenced DGitRevision :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DGitRevision -> DocItemRef (DocItemPlacement DGitRevision) (DocItemReferenced DGitRevision) # docItemToMarkdown :: HeaderLevel -> DGitRevision -> Markdown # docItemToToc :: HeaderLevel -> DGitRevision -> Markdown # docItemDependencies :: DGitRevision -> [SomeDocDefinitionItem] # docItemsOrder :: [DGitRevision] -> [DGitRevision] # | |
| type DocItemPlacement DGitRevision | |
Defined in Michelson.Doc | |
| type DocItemReferenced DGitRevision | |
Defined in Michelson.Doc | |
class (Typeable d, DOrd d) => DocItem d where #
Minimal complete definition
Associated Types
type DocItemPlacement d :: DocItemPlacementKind #
type DocItemPlacement d = 'DocItemInlined
type DocItemReferenced d :: DocItemReferencedKind #
type DocItemReferenced d = 'False
Methods
docItemPos :: Natural #
docItemSectionName :: Maybe Text #
docItemSectionDescription :: Maybe Markdown #
docItemSectionNameStyle :: DocSectionNameStyle #
docItemRef :: d -> DocItemRef (DocItemPlacement d) (DocItemReferenced d) #
docItemToMarkdown :: HeaderLevel -> d -> Markdown #
docItemToToc :: HeaderLevel -> d -> Markdown #
docItemDependencies :: d -> [SomeDocDefinitionItem] #
docItemsOrder :: [d] -> [d] #
Instances
class GHasAnnotation a where Source #
A Generic HasAnnotation implementation
Methods
gGetAnnotation :: AnnOptions -> FollowEntrypointFlag -> GenerateFieldAnnFlag -> (Notes (GValueType a), FieldAnn, VarAnn) Source #
Instances
class HasAnnotation a where Source #
This class defines the type and field annotations for a given type. Right now the type annotations come from names in a named field, and field annotations are generated from the record fields.
Minimal complete definition
Nothing
Methods
getAnnotation :: FollowEntrypointFlag -> Notes (ToT a) Source #
default getAnnotation :: (GHasAnnotation (Rep a), GValueType (Rep a) ~ ToT a) => FollowEntrypointFlag -> Notes (ToT a) Source #
annOptions :: AnnOptions Source #
default annOptions :: AnnOptions Source #
Instances
data GenerateFieldAnnFlag Source #
Used in GHasAnnotation as a flag to track whether or not field/constructor
annotations should be generated.
Constructors
| GenerateFieldAnn | |
| NotGenerateFieldAnn |
data FollowEntrypointFlag Source #
Used in GHasAnnotation and HasAnnotation as a flag to track
whether or not it directly follows an entrypoint to avoid introducing
extra entrypoints.
Constructors
| FollowEntrypoint | |
| NotFollowEntrypoint |
data AnnOptions Source #
Allow customization of field annotation generated for a type
when declaring its HasAnnotation instance.
Constructors
| AnnOptions | |
Fields
| |
dropPrefixThen :: (Text -> Text) -> Text -> Text Source #
Drops the field name prefix from a field. We assume a convention of the prefix always being lower case, and the first letter of the actual field name being uppercase. It also accepts another function which will be applied directly after dropping the prefix.
appendTo :: Text -> [Text] -> Text -> Text Source #
appendTo suffix fields field appends the given suffix to field
if the field exists in the fields list.
ctorNameToAnnWithOptions :: forall ctor. (KnownSymbol ctor, HasCallStack) => AnnOptions -> FieldAnn Source #
gGetAnnotationNoField :: forall a. (GHasAnnotation (Rep a), GValueType (Rep a) ~ ToT a) => FollowEntrypointFlag -> Notes (ToT a) Source #
Use this in the instance of HasAnnotation when field annotations
should not be generated.
type DocGrouping = SubDoc -> SomeDocItem #
attachDocCommons :: ContainsUpdateableDoc a => DGitRevision -> a -> WithFinalizedDoc a #
buildDoc :: ContainsDoc a => WithFinalizedDoc a -> ContractDoc #
buildMarkdownDoc :: ContainsDoc a => WithFinalizedDoc a -> LText #
docDefinitionRef :: (DocItem d, DocItemPlacement d ~ 'DocItemInDefinitions) => Markdown -> d -> Markdown #
docItemPosition :: DocItem d => DocItemPos #
docItemSectionRef :: DocItem di => Maybe Markdown #
finalizedAsIs :: a -> WithFinalizedDoc a #
mdTocFromRef :: (DocItem d, DocItemReferenced d ~ 'True) => HeaderLevel -> Markdown -> d -> Markdown #
mkDGitRevision :: ExpQ #
subDocToMarkdown :: HeaderLevel -> SubDoc -> Markdown #
Constructors
| DAnchor Anchor |
Instances
| DocItem DAnchor | |
Defined in Michelson.Doc Associated Types type DocItemPlacement DAnchor :: DocItemPlacementKind # type DocItemReferenced DAnchor :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DAnchor -> DocItemRef (DocItemPlacement DAnchor) (DocItemReferenced DAnchor) # docItemToMarkdown :: HeaderLevel -> DAnchor -> Markdown # docItemToToc :: HeaderLevel -> DAnchor -> Markdown # docItemDependencies :: DAnchor -> [SomeDocDefinitionItem] # docItemsOrder :: [DAnchor] -> [DAnchor] # | |
| type DocItemPlacement DAnchor | |
Defined in Michelson.Doc | |
| type DocItemReferenced DAnchor | |
Defined in Michelson.Doc | |
Instances
| DocItem DComment | |
Defined in Michelson.Doc Associated Types type DocItemPlacement DComment :: DocItemPlacementKind # type DocItemReferenced DComment :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DComment -> DocItemRef (DocItemPlacement DComment) (DocItemReferenced DComment) # docItemToMarkdown :: HeaderLevel -> DComment -> Markdown # docItemToToc :: HeaderLevel -> DComment -> Markdown # docItemDependencies :: DComment -> [SomeDocDefinitionItem] # docItemsOrder :: [DComment] -> [DComment] # | |
| type DocItemPlacement DComment | |
Defined in Michelson.Doc | |
| type DocItemReferenced DComment | |
Defined in Michelson.Doc | |
data DDescription #
Constructors
| DDescription Markdown |
Instances
| DocItem DDescription | |
Defined in Michelson.Doc Associated Types type DocItemPlacement DDescription :: DocItemPlacementKind # type DocItemReferenced DDescription :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DDescription -> DocItemRef (DocItemPlacement DDescription) (DocItemReferenced DDescription) # docItemToMarkdown :: HeaderLevel -> DDescription -> Markdown # docItemToToc :: HeaderLevel -> DDescription -> Markdown # docItemDependencies :: DDescription -> [SomeDocDefinitionItem] # docItemsOrder :: [DDescription] -> [DDescription] # | |
| type DocItemPlacement DDescription | |
Defined in Michelson.Doc | |
| type DocItemReferenced DDescription | |
Defined in Michelson.Doc | |
newtype DGeneralInfoSection #
Constructors
| DGeneralInfoSection SubDoc |
Instances
| DocItem DGeneralInfoSection | |
Defined in Michelson.Doc Associated Types type DocItemPlacement DGeneralInfoSection :: DocItemPlacementKind # type DocItemReferenced DGeneralInfoSection :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DGeneralInfoSection -> DocItemRef (DocItemPlacement DGeneralInfoSection) (DocItemReferenced DGeneralInfoSection) # docItemToMarkdown :: HeaderLevel -> DGeneralInfoSection -> Markdown # docItemToToc :: HeaderLevel -> DGeneralInfoSection -> Markdown # docItemDependencies :: DGeneralInfoSection -> [SomeDocDefinitionItem] # docItemsOrder :: [DGeneralInfoSection] -> [DGeneralInfoSection] # | |
| type DocItemPlacement DGeneralInfoSection | |
Defined in Michelson.Doc | |
| type DocItemReferenced DGeneralInfoSection | |
Defined in Michelson.Doc | |
Instances
| DocItem DName | |
Defined in Michelson.Doc Associated Types type DocItemPlacement DName :: DocItemPlacementKind # type DocItemReferenced DName :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DName -> DocItemRef (DocItemPlacement DName) (DocItemReferenced DName) # docItemToMarkdown :: HeaderLevel -> DName -> Markdown # docItemToToc :: HeaderLevel -> DName -> Markdown # docItemDependencies :: DName -> [SomeDocDefinitionItem] # docItemsOrder :: [DName] -> [DName] # | |
| type DocItemPlacement DName | |
Defined in Michelson.Doc | |
| type DocItemReferenced DName | |
Defined in Michelson.Doc | |
type family DocItemPlacement d :: DocItemPlacementKind #
Instances
type family DocItemReferenced d :: DocItemReferencedKind #
Instances
Instances
| Eq DocItemId | |
| Ord DocItemId | |
| Show DocItemId | |
| ToAnchor DocItemId | |
Defined in Michelson.Doc | |
data DocItemPlacementKind #
Constructors
| DocItemInlined | |
| DocItemInDefinitions |
data DocItemRef (p :: DocItemPlacementKind) (r :: DocItemReferencedKind) where #
Constructors
| DocItemRef :: DocItemId -> DocItemRef 'DocItemInDefinitions 'True | |
| DocItemRefInlined :: DocItemId -> DocItemRef 'DocItemInlined 'True | |
| DocItemNoRef :: DocItemRef 'DocItemInlined 'False |
Instances
| ToAnchor (DocItemRef d 'True) | |
Defined in Michelson.Doc Methods toAnchor :: DocItemRef d 'True -> Anchor | |
data DocSectionNameStyle #
Constructors
| DocSectionNameBig | |
| DocSectionNameSmall |
newtype GitRepoSettings #
Constructors
| GitRepoSettings | |
Fields
| |
data WithFinalizedDoc a #
Instances
| Monad WithFinalizedDoc | |
Defined in Michelson.Doc Methods (>>=) :: WithFinalizedDoc a -> (a -> WithFinalizedDoc b) -> WithFinalizedDoc b # (>>) :: WithFinalizedDoc a -> WithFinalizedDoc b -> WithFinalizedDoc b # return :: a -> WithFinalizedDoc a # | |
| Functor WithFinalizedDoc | |
Defined in Michelson.Doc Methods fmap :: (a -> b) -> WithFinalizedDoc a -> WithFinalizedDoc b # (<$) :: a -> WithFinalizedDoc b -> WithFinalizedDoc a # | |
| Applicative WithFinalizedDoc | |
Defined in Michelson.Doc Methods pure :: a -> WithFinalizedDoc a # (<*>) :: WithFinalizedDoc (a -> b) -> WithFinalizedDoc a -> WithFinalizedDoc b # liftA2 :: (a -> b -> c) -> WithFinalizedDoc a -> WithFinalizedDoc b -> WithFinalizedDoc c # (*>) :: WithFinalizedDoc a -> WithFinalizedDoc b -> WithFinalizedDoc b # (<*) :: WithFinalizedDoc a -> WithFinalizedDoc b -> WithFinalizedDoc a # | |
type NiceComparable n = (KnownValue n, Comparable (ToT n)) Source #
type NicePrintedValue a = (KnownValue a, ProperPrintedValBetterErrors (ToT a)) Source #
type NiceFullPackedValue a = (NicePackedValue a, NiceUnpackedValue a) Source #
type NiceUnpackedValue a = (KnownValue a, ProperUnpackedValBetterErrors (ToT a)) Source #
type NicePackedValue a = (KnownValue a, ProperPackedValBetterErrors (ToT a)) Source #
type NiceConstant a = (KnownValue a, ProperConstantBetterErrors (ToT a)) Source #
type NiceStorage a = (HasAnnotation a, KnownValue a, ProperStorageBetterErrors (ToT a)) Source #
type NiceParameter a = (KnownValue a, ProperParameterBetterErrors (ToT a)) Source #
Constraint applied to any part of parameter type.
Note that you don't usually apply this constraint to the whole parameter,
consider using NiceParameterFull in such case.
Using this type is justified e.g. when calling another contract, there you usually supply an entrypoint argument, not the whole parameter.
class (IsoValue a, HasNoNestedBigMaps (ToT a)) => CanHaveBigMap a Source #
Instances
| (IsoValue a, HasNoNestedBigMaps (ToT a)) => CanHaveBigMap a Source # | |
Defined in Lorentz.Constraints.Scopes | |
class (IsoValue a, ForbidContract (ToT a)) => NoContractType a Source #
Instances
| (IsoValue a, ForbidContract (ToT a)) => NoContractType a Source # | |
Defined in Lorentz.Constraints.Scopes | |
class (IsoValue a, ForbidOp (ToT a)) => NoOperation a Source #
Ensure given type does not contain "operation".
Instances
| (IsoValue a, ForbidOp (ToT a)) => NoOperation a Source # | |
Defined in Lorentz.Constraints.Scopes | |
class (IsoValue a, Typeable a) => KnownValue a Source #
Gathers constraints, commonly required for values.
Instances
| (IsoValue a, Typeable a) => KnownValue a Source # | |
Defined in Lorentz.Constraints.Scopes | |
niceParameterEvi :: forall a. NiceParameter a :- ParameterScope (ToT a) Source #
niceStorageEvi :: forall a. NiceStorage a :- StorageScope (ToT a) Source #
niceConstantEvi :: forall a. NiceConstant a :- ConstantScope (ToT a) Source #
nicePackedValueEvi :: forall a. NicePackedValue a :- PackedValScope (ToT a) Source #
niceUnpackedValueEvi :: forall a. NiceUnpackedValue a :- UnpackedValScope (ToT a) Source #
nicePrintedValueEvi :: forall a. NicePrintedValue a :- PrintedValScope (ToT a) Source #
newtype ShouldHaveEntrypoints a Source #
A special type which wraps over a primitive type and states that it has entrypoints (one).
Assuming that any type can have entrypoints makes use of Lorentz entrypoints too annoying, so for declaring entrypoints for not sum types we require an explicit wrapper.
Constructors
| ShouldHaveEntrypoints | |
Fields
| |
Instances
No entrypoints declared, parameter type will serve as argument type of the only existing entrypoint (default one).
Instances
| HasAnnotation cp => EntrypointsDerivation EpdNone cp Source # | |
Defined in Lorentz.Entrypoints.Core | |
| type EpdAllEntrypoints EpdNone cp Source # | |
Defined in Lorentz.Entrypoints.Core | |
| type EpdLookupEntrypoint EpdNone cp Source # | |
type family ParameterContainsEntrypoints param (fields :: [NamedEp]) :: Constraint where ... Source #
Check that the given entrypoint has some fields inside. This interface allows for an abstraction of contract parameter so that it requires some *minimal* specification, but not a concrete one.
Equations
| ParameterContainsEntrypoints _ '[] = () | |
| ParameterContainsEntrypoints param ((n :> ty) ': rest) = (HasEntrypointOfType param n ty, ParameterContainsEntrypoints param rest) |
type HasEntrypointOfType param con exp = (GetEntrypointArgCustom param ('Just con) ~ exp, ParameterDeclaresEntrypoints param) Source #
Checks that the given parameter consists of some specific entrypoint. Similar as
HasEntrypointArg but ensures that the argument matches the following datatype.
newtype TrustEpName Source #
This wrapper allows to pass untyped EpName and bypass checking
that entrypoint with given name and type exists.
Constructors
| TrustEpName EpName |
Instances
| NiceParameter arg => HasEntrypointArg (cp :: k) TrustEpName arg Source # | |
Defined in Lorentz.Entrypoints.Core Methods useHasEntrypointArg :: TrustEpName -> (Dict (ParameterScope (ToT arg)), EpName) Source # | |
type HasDefEntrypointArg cp defEpName defArg = (defEpName ~ EntrypointRef 'Nothing, HasEntrypointArg cp defEpName defArg) Source #
HasEntrypointArg constraint specialized to default entrypoint.
class HasEntrypointArg cp name arg where Source #
When we call a Lorentz contract we should pass entrypoint name
and corresponding argument. Ideally we want to statically check
that parameter has entrypoint with given name and
argument. Constraint defined by this type class holds for contract
with parameter cp that have entrypoint matching name with type
arg.
In order to check this property statically, we need to know entrypoint
name in compile time, EntrypointRef type serves this purpose.
If entrypoint name is not known, one can use TrustEpName wrapper
to take responsibility for presence of this entrypoint.
If you want to call a function which has this constraint, you have
two options:
1. Pass contract parameter cp using type application, pass EntrypointRef
as a value and pass entrypoint argument. Type system will check that
cp has an entrypoint with given reference and type.
2. Pass EpName wrapped into TrustEpName and entrypoint argument.
In this case passing contract parameter is not necessary, you do not even
have to know it.
Methods
useHasEntrypointArg :: name -> (Dict (ParameterScope (ToT arg)), EpName) Source #
Data returned by this method may look somewhat arbitrary.
EpName is obviously needed because name can be
EntrypointRef or TrustEpName. Dict is returned because in
EntrypointRef case we get this evidence for free and don't want
to use it. We seem to always need it anyway.
Instances
| NiceParameter arg => HasEntrypointArg (cp :: k) TrustEpName arg Source # | |
Defined in Lorentz.Entrypoints.Core Methods useHasEntrypointArg :: TrustEpName -> (Dict (ParameterScope (ToT arg)), EpName) Source # | |
| (GetEntrypointArgCustom cp mname ~ arg, ParameterDeclaresEntrypoints cp) => HasEntrypointArg (cp :: Type) (EntrypointRef mname) arg Source # | |
Defined in Lorentz.Entrypoints.Core Methods useHasEntrypointArg :: EntrypointRef mname -> (Dict (ParameterScope (ToT arg)), EpName) Source # | |
type family GetEntrypointArgCustom cp mname :: Type where ... Source #
Universal entrypoint lookup.
Equations
| GetEntrypointArgCustom cp 'Nothing = GetDefaultEntrypointArg cp | |
| GetEntrypointArgCustom cp ('Just name) = GetEntrypointArg cp name |
data EntrypointRef (mname :: Maybe Symbol) where Source #
Which entrypoint to call.
We intentionally distinguish default and non-default cases because this makes API more details-agnostic.
Constructors
| CallDefault :: EntrypointRef 'Nothing | Call the default entrypoint, or root if no explicit default is assigned. |
| Call :: NiceEntrypointName name => EntrypointRef ('Just name) | Call the given entrypoint; calling default is not treated specially. You have to provide entrypoint name via passing it as type argument. Unfortunatelly, here we cannot accept a label because in most cases our entrypoints begin from capital letter (being derived from constructor name), while labels must start from a lower-case letter, and there is no way to make a conversion at type-level. |
Instances
| (GetEntrypointArgCustom cp mname ~ arg, ParameterDeclaresEntrypoints cp) => HasEntrypointArg (cp :: Type) (EntrypointRef mname) arg Source # | |
Defined in Lorentz.Entrypoints.Core Methods useHasEntrypointArg :: EntrypointRef mname -> (Dict (ParameterScope (ToT arg)), EpName) Source # | |
type NoExplicitDefaultEntrypoint cp = Eval (LookupParameterEntrypoint cp DefaultEpName) ~ 'Nothing Source #
Similar to ForbidExplicitDefaultEntrypoint, but in a version which
the compiler can work with (and which produces errors confusing for users :/)
type ForbidExplicitDefaultEntrypoint cp = Eval (LiftM3 UnMaybe (Pure (Pure (() :: Constraint))) (TError ('Text "Parameter used here must have no explicit \"default\" entrypoint" :$$: (('Text "In parameter type `" :<>: 'ShowType cp) :<>: 'Text "`"))) (LookupParameterEntrypoint cp DefaultEpName)) Source #
Ensure that there is no explicit "default" entrypoint.
type GetDefaultEntrypointArg cp = Eval (LiftM2 FromMaybe (Pure cp) (LookupParameterEntrypoint cp DefaultEpName)) Source #
Get type of entrypoint with given name, fail if not found.
type GetEntrypointArg cp name = Eval (LiftM2 FromMaybe (TError (('Text "Entrypoint not found: " :<>: 'ShowType name) :$$: (('Text "In contract parameter `" :<>: 'ShowType cp) :<>: 'Text "`"))) (LookupParameterEntrypoint cp name)) Source #
Get type of entrypoint with given name, fail if not found.
type family LookupParameterEntrypoint (cp :: Type) :: Symbol -> Exp (Maybe Type) where ... Source #
Lookup for entrypoint type by name.
Does not treat default entrypoints in a special way.
Equations
| LookupParameterEntrypoint cp = EpdLookupEntrypoint (GetParameterEpDerivation cp) cp |
type family AllParameterEntrypoints (cp :: Type) :: [(Symbol, Type)] where ... Source #
Get all entrypoints declared for parameter.
Equations
| AllParameterEntrypoints cp = EpdAllEntrypoints (GetParameterEpDerivation cp) cp |
type ParameterDeclaresEntrypoints cp = (If (CanHaveEntrypoints cp) (ParameterHasEntrypoints cp) (() :: Constraint), NiceParameter cp, EntrypointsDerivation (GetParameterEpDerivation cp) cp) Source #
Parameter declares some entrypoints.
This is a version of ParameterHasEntrypoints which we actually use in
constraints. When given type is a sum type or newtype, we refer to
ParameterHasEntrypoints instance, otherwise this instance is not
necessary.
class (EntrypointsDerivation (ParameterEntrypointsDerivation cp) cp, RequireAllUniqueEntrypoints cp) => ParameterHasEntrypoints cp Source #
Which entrypoints given parameter declares.
Note that usually this function should not be used as constraint, use
ParameterDeclaresEntrypoints for this purpose.
Associated Types
type ParameterEntrypointsDerivation cp :: Type Source #
Instances
| (NiceParameter cp, EntrypointsDerivation epd cp, RequireAllUniqueEntrypoints' epd cp) => ParameterHasEntrypoints (ParameterWrapper epd cp) Source # | |
Defined in Lorentz.Entrypoints.Manual Associated Types type ParameterEntrypointsDerivation (ParameterWrapper epd cp) Source # | |
type RequireAllUniqueEntrypoints cp = RequireAllUniqueEntrypoints' (ParameterEntrypointsDerivation cp) cp Source #
Ensure that all declared entrypoints are unique.
class EntrypointsDerivation deriv cp where Source #
Defines a generalized way to declare entrypoints for various parameter types.
When defining instances of this typeclass, set concrete deriv argument
and leave variable cp argument.
Also keep in mind, that in presence of explicit default entrypoint, all other
Or arms should be callable, though you can put this burden on user if very
necessary.
Methods of this typeclass aim to better type-safety when making up an implementation and they may be not too convenient to use; users should exploit their counterparts.
Associated Types
type EpdAllEntrypoints deriv cp :: [(Symbol, Type)] Source #
Name and argument of each entrypoint. This may include intermediate ones, even root if necessary.
Touching this type family is costly (O(N^2)), don't use it often.
Note [order of entrypoints children]:
If this contains entrypoints referring to indermediate nodes (not leaves)
in or tree, then each such entrypoint should be mentioned eariler than
all of its children.
type EpdLookupEntrypoint deriv cp :: Symbol -> Exp (Maybe Type) Source #
Get entrypoint argument by name.
Methods
epdNotes :: (Notes (ToT cp), RootAnn) Source #
Construct parameter annotations corresponding to expected entrypoints set.
This method is implementation detail, for actual notes construction
use parameterEntrypointsToNotes.
epdCall :: ParameterScope (ToT cp) => Label name -> EpConstructionRes (ToT cp) (Eval (EpdLookupEntrypoint deriv cp name)) Source #
Construct entrypoint caller.
This does not treat calls to default entrypoint in a special way.
This method is implementation detail, for actual entrypoint lookup
use parameterEntrypointCall.
epdDescs :: Rec EpCallingDesc (EpdAllEntrypoints deriv cp) Source #
Description of how each of the entrypoints is constructed.
Instances
parameterEntrypointsToNotes :: forall cp. ParameterDeclaresEntrypoints cp => ParamNotes (ToT cp) Source #
Derive annotations for given parameter.
parameterEntrypointCall :: forall cp name. ParameterDeclaresEntrypoints cp => Label name -> EntrypointCall cp (GetEntrypointArg cp name) Source #
Prepare call to given entrypoint.
This does not treat calls to default entrypoint in a special way.
To call default entrypoint properly use parameterEntrypointCallDefault.
parameterEntrypointCallDefault :: forall cp. ParameterDeclaresEntrypoints cp => EntrypointCall cp (GetDefaultEntrypointArg cp) Source #
Call the default entrypoint.
sepcCallRootChecked :: forall cp. (NiceParameter cp, ForbidExplicitDefaultEntrypoint cp) => SomeEntrypointCall cp Source #
Call root entrypoint safely.
eprName :: forall mname. EntrypointRef mname -> EpName Source #
parameterEntrypointCallCustom :: forall cp mname. ParameterDeclaresEntrypoints cp => EntrypointRef mname -> EntrypointCall cp (GetEntrypointArgCustom cp mname) Source #
Universal entrypoint calling.
type NiceParameterFull cp = (Typeable cp, ParameterDeclaresEntrypoints cp) Source #
Constraint applied to a whole parameter type.
class MapLorentzInstr instr where Source #
Applicable for wrappers over Lorentz code.
Methods
mapLorentzInstr :: (forall i o. (i :-> o) -> i :-> o) -> instr -> instr Source #
Modify all the code under given entity.
Instances
| MapLorentzInstr (i :-> o) Source # | |
Defined in Lorentz.Base | |
type (&) (a :: Type) (b :: [Type]) = a ': b infixr 2 Source #
An alias for :.
We discourage its use as this hinders reading error messages (the compiler inserts unnecessary parentheses and indentation).
data SomeContractCode where Source #
Constructors
| SomeContractCode :: (NiceParameterFull cp, NiceStorage st) => ContractCode cp st -> SomeContractCode |
type ContractCode cp st = '[(cp, st)] :-> ContractOut st Source #
type ContractOut st = '[([Operation], st)] Source #
type (%>) = (:->) infixr 1 Source #
Alias for :->, seems to make signatures more readable sometimes.
Let's someday decide which one of these two should remain.
newtype (inp :: [Type]) :-> (out :: [Type]) infixr 1 Source #
Alias for instruction which hides inner types representation via T.
Constructors
| LorentzInstr | |
Fields
| |
Instances
iGenericIf :: (forall s'. Instr (ToTs a) s' -> Instr (ToTs b) s' -> Instr (ToTs c) s') -> (a :-> s) -> (b :-> s) -> c :-> s Source #
iNonFailingCode :: HasCallStack => (inp :-> out) -> Instr (ToTs inp) (ToTs out) Source #
iMapAnyCode :: (forall o'. Instr (ToTs i1) o' -> Instr (ToTs i2) o') -> (i1 :-> o) -> i2 :-> o Source #
iForceNotFail :: (i :-> o) -> i :-> o Source #
iWithVarAnnotations :: HasCallStack => [Text] -> (inp :-> out) -> inp :-> out Source #
Wrap Lorentz instruction with variable annotations, annots list has to be
non-empty, otherwise this function raises an error.
parseLorentzValue :: forall v. KnownValue v => Text -> Either ParseLorentzError v Source #
Parse textual representation of a Michelson value and turn it into corresponding Haskell value.
Note: it won't work in some complex cases, e. g. if there is a lambda which uses an instruction which depends on current contract's type. Obviously it can not work, because we don't have any information about a contract to which this value belongs (there is no such contract at all).
transformStringsLorentz :: Bool -> (MText -> MText) -> (inp :-> out) -> inp :-> out Source #
Lorentz version of transformStrings.
transformBytesLorentz :: Bool -> (ByteString -> ByteString) -> (inp :-> out) -> inp :-> out Source #
Lorentz version of transformBytes.
optimizeLorentzWithConf :: OptimizerConf -> (inp :-> out) -> inp :-> out Source #
optimizeLorentz :: (inp :-> out) -> inp :-> out Source #
type Entrypoint_ store = '[store] :-> ContractOut store Source #
Version of Entrypoint which accepts no argument.
type Entrypoint param store = '[param, store] :-> ContractOut store Source #
Single entrypoint of a contract.
Note that we cannot make it return [[Operation], store] because
such entrypoint should've been followed by pair, and this is not
possible if entrypoint implementation ends with failWith.
class FromContractRef (cp :: Type) (contract :: Type) where Source #
Convert something from ContractAddr in Haskell world.
Methods
fromContractRef :: ContractRef cp -> contract Source #
Instances
| FromContractRef cp Address Source # | |
Defined in Lorentz.Address Methods fromContractRef :: ContractRef cp -> Address Source # | |
| FromContractRef cp EpAddress Source # | |
Defined in Lorentz.Address Methods fromContractRef :: ContractRef cp -> EpAddress Source # | |
| cp ~ cp' => FromContractRef cp (FutureContract cp') Source # | |
Defined in Lorentz.Address Methods fromContractRef :: ContractRef cp -> FutureContract cp' Source # | |
| cp ~ cp' => FromContractRef cp (ContractRef cp') Source # | |
Defined in Lorentz.Address Methods fromContractRef :: ContractRef cp -> ContractRef cp' Source # | |
class ToContractRef (cp :: Type) (contract :: Type) where Source #
Convert something to ContractRef in Haskell world.
Methods
toContractRef :: HasCallStack => contract -> ContractRef cp Source #
Instances
| (NiceParameter cp, cp ~ cp') => ToContractRef cp (FutureContract cp') Source # | |
Defined in Lorentz.Address Methods toContractRef :: FutureContract cp' -> ContractRef cp Source # | |
| cp ~ cp' => ToContractRef cp (ContractRef cp') Source # | |
Defined in Lorentz.Address Methods toContractRef :: ContractRef cp' -> ContractRef cp Source # | |
| (FailWhen cond msg, cond ~ (CanHaveEntrypoints cp && Not (ParameterEntrypointsDerivation cp == EpdNone)), msg ~ (((('Text "Cannot apply `ToContractRef` to `TAddress`" :$$: 'Text "Consider using call(Def)TAddress first`") :$$: 'Text "(or if you know your parameter type is primitive,") :$$: 'Text " make sure typechecker also knows about that)") :$$: (('Text "For parameter `" :<>: 'ShowType cp) :<>: 'Text "`")), cp ~ arg, NiceParameter arg, NiceParameterFull cp, GetDefaultEntrypointArg cp ~ cp) => ToContractRef arg (TAddress cp) Source # | |
Defined in Lorentz.Address Methods toContractRef :: TAddress cp -> ContractRef arg Source # | |
class ToTAddress (cp :: Type) (a :: Type) where Source #
Convert something referring to a contract (not specific entrypoint)
to TAddress in Haskell world.
Methods
toTAddress :: a -> TAddress cp Source #
Instances
| ToTAddress cp Address Source # | |
Defined in Lorentz.Address Methods toTAddress :: Address -> TAddress cp Source # | |
| cp ~ cp' => ToTAddress cp (TAddress cp') Source # | |
Defined in Lorentz.Address Methods toTAddress :: TAddress cp' -> TAddress cp Source # | |
class ToAddress a where Source #
Convert something to Address in Haskell world.
Use this when you want to access state of the contract and are not interested in calling it.
Instances
| ToAddress EpAddress Source # | |
| ToAddress Address Source # | |
| ToAddress (ContractRef cp) Source # | |
Defined in Lorentz.Address Methods toAddress :: ContractRef cp -> Address Source # | |
| ToAddress (FutureContract cp) Source # | |
Defined in Lorentz.Address Methods toAddress :: FutureContract cp -> Address Source # | |
| ToAddress (TAddress cp) Source # | |
newtype FutureContract arg Source #
Address associated with value of contract arg type.
Places where ContractRef can appear are now severely limited,
this type gives you type-safety of ContractRef but still can be used
everywhere.
This type is not a full-featured one rather a helper; in particular, once
pushing it on stack, you cannot return it back to Haskell world.
Note that it refers to an entrypoint of the contract, not just the contract
as a whole. In this sense this type differs from TAddress.
Unlike with ContractRef, having this type you still cannot be sure that
the referred contract exists and need to perform a lookup before calling it.
Constructors
| FutureContract | |
Fields
| |
Instances
Address which remembers the parameter type of the contract it refers to.
It differs from Michelson's contract type because it cannot contain
entrypoint, and it always refers to entire contract parameter even if this
contract has explicit default entrypoint.
Constructors
| TAddress | |
Fields | |
Instances
callingTAddress :: forall cp mname. NiceParameterFull cp => TAddress cp -> EntrypointRef mname -> ContractRef (GetEntrypointArgCustom cp mname) Source #
Turn TAddress to ContractRef in Haskell world.
This is an analogy of address to contract convertion in Michelson world,
thus you have to supply an entrypoint (or call the default one explicitly).
callingDefTAddress :: forall cp. NiceParameterFull cp => TAddress cp -> ContractRef (GetDefaultEntrypointArg cp) Source #
Specification of callTAddress to call the default entrypoint.
toTAddress_ :: forall cp addr s. ToTAddress_ cp addr => (addr ': s) :-> (TAddress cp ': s) Source #
Cast something appropriate to TAddress.
convertContractRef :: forall cp contract2 contract1. (ToContractRef cp contract1, FromContractRef cp contract2) => contract1 -> contract2 Source #
stackRef :: forall (gn :: Nat) st n. (n ~ ToPeano gn, SingI n, KnownPeano n, RequireLongerThan st n) => PrintComment st Source #
Include a value at given position on stack into comment produced
by printComment.
>>>stackRef @0<includes the top of the stack>
printComment :: PrintComment (ToTs s) -> s :-> s Source #
Print a comment. It will be visible in tests.
>>>printComment "Hello world!">>>printComment $ "On top of the stack I see " <> stackRef @0
testAssert :: (Typeable (ToTs out), HasCallStack) => Text -> PrintComment (ToTs inp) -> (inp :-> (Bool ': out)) -> inp :-> inp Source #
Test an invariant, fail if it does not hold.
This won't be included into production contract and is executed only in tests.
stackType :: forall s. s :-> s Source #
Fix the current type of the stack to be given one.
>>>stackType @'[Natural]>>>stackType @(Integer : Natural : s)>>>stackType @'["balance" :! Integer, "toSpend" :! Integer, BigMap Address Integer]
Note that you can omit arbitrary parts of the type.
>>>stackType @'["balance" :! Integer, "toSpend" :! _, BigMap _ _]
class (EDivOp (ToT n) (ToT m), NiceComparable n, NiceComparable m, ToT (EDivOpResHs n m) ~ EDivOpRes (ToT n) (ToT m), ToT (EModOpResHs n m) ~ EModOpRes (ToT n) (ToT m)) => EDivOpHs n m Source #
Lifted EDivOp.
Instances
| EDivOpHs Integer Integer Source # | |
Defined in Lorentz.Polymorphic | |
| EDivOpHs Integer Natural Source # | |
Defined in Lorentz.Polymorphic | |
| EDivOpHs Natural Integer Source # | |
Defined in Lorentz.Polymorphic | |
| EDivOpHs Natural Natural Source # | |
Defined in Lorentz.Polymorphic | |
| EDivOpHs Mutez Natural Source # | |
Defined in Lorentz.Polymorphic | |
| EDivOpHs Mutez Mutez Source # | |
Defined in Lorentz.Polymorphic | |
class SliceOp (ToT c) => SliceOpHs c Source #
Lifted SliceOp.
Instances
| SliceOpHs ByteString Source # | |
Defined in Lorentz.Polymorphic | |
| SliceOpHs MText Source # | |
Defined in Lorentz.Polymorphic | |
class ConcatOp (ToT c) => ConcatOpHs c Source #
Lifted ConcatOp.
Instances
| ConcatOpHs ByteString Source # | |
Defined in Lorentz.Polymorphic | |
| ConcatOpHs MText Source # | |
Defined in Lorentz.Polymorphic | |
class (GetOp (ToT c), ToT (GetOpKeyHs c) ~ GetOpKey (ToT c), ToT (GetOpValHs c) ~ GetOpVal (ToT c)) => GetOpHs c Source #
Lifted GetOp.
Instances
| NiceComparable k => GetOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable k => GetOpHs (BigMap k v) Source # | |
Defined in Lorentz.Polymorphic | |
class (UpdOp (ToT c), ToT (UpdOpKeyHs c) ~ UpdOpKey (ToT c), ToT (UpdOpParamsHs c) ~ UpdOpParams (ToT c)) => UpdOpHs c Source #
Lifted UpdOp.
Instances
| NiceComparable a => UpdOpHs (Set a) Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable k => UpdOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable k => UpdOpHs (BigMap k v) Source # | |
Defined in Lorentz.Polymorphic | |
class SizeOp (ToT c) => SizeOpHs c Source #
Lifted SizeOp.
This could be just a constraint alias, but to avoid T types appearance in
error messages we make a full type class with concrete instances.
Instances
| SizeOpHs ByteString Source # | |
Defined in Lorentz.Polymorphic | |
| SizeOpHs MText Source # | |
Defined in Lorentz.Polymorphic | |
| SizeOpHs [a] Source # | |
Defined in Lorentz.Polymorphic | |
| SizeOpHs (Set a) Source # | |
Defined in Lorentz.Polymorphic | |
| SizeOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic | |
class (IterOp (ToT c), ToT (IterOpElHs c) ~ IterOpEl (ToT c)) => IterOpHs c Source #
Lifted IterOp.
Associated Types
type IterOpElHs c :: Type Source #
Instances
| IterOpHs [e] Source # | |
Defined in Lorentz.Polymorphic Associated Types type IterOpElHs [e] Source # | |
| NiceComparable e => IterOpHs (Set e) Source # | |
Defined in Lorentz.Polymorphic Associated Types type IterOpElHs (Set e) Source # | |
| NiceComparable k => IterOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type IterOpElHs (Map k v) Source # | |
class (MapOp (ToT c), ToT (MapOpInpHs c) ~ MapOpInp (ToT c), ToT (MapOpResHs c ()) ~ MapOpRes (ToT c) (ToT ())) => MapOpHs c Source #
Lifted MapOp.
Instances
| MapOpHs [e] Source # | |
Defined in Lorentz.Polymorphic | |
| NiceComparable k => MapOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MapOpInpHs (Map k v) Source # | |
type family IsoMapOpRes c b where ... Source #
A useful property which holds for reasonable MapOp instances.
It's a separate thing from MapOpHs because it mentions b type parameter.
Equations
| IsoMapOpRes c b = ToT (MapOpResHs c b) ~ MapOpRes (ToT c) (ToT b) |
class (MemOp (ToT c), ToT (MemOpKeyHs c) ~ MemOpKey (ToT c)) => MemOpHs c Source #
Lifted MemOpKey.
Associated Types
type MemOpKeyHs c :: Type Source #
Instances
| NiceComparable e => MemOpHs (Set e) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MemOpKeyHs (Set e) Source # | |
| NiceComparable k => MemOpHs (Map k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MemOpKeyHs (Map k v) Source # | |
| NiceComparable k => MemOpHs (BigMap k v) Source # | |
Defined in Lorentz.Polymorphic Associated Types type MemOpKeyHs (BigMap k v) Source # | |
data GenericStrategy #
alphabetically :: EntriesReorder #
forbidUnnamedFields :: UnnamedEntriesReorder #
customGeneric :: String -> GenericStrategy -> Q [Dec] #
customGeneric' :: Maybe Type -> Name -> Type -> [Con] -> GenericStrategy -> Q [Dec] #
fromDepthsStrategy :: (Int -> [Natural]) -> GenericStrategy #
leaveUnnamedFields :: UnnamedEntriesReorder #
reorderingConstrs :: EntriesReorder -> GenericStrategy -> GenericStrategy #
reorderingData :: UnnamedEntriesReorder -> EntriesReorder -> GenericStrategy -> GenericStrategy #
reorderingFields :: UnnamedEntriesReorder -> EntriesReorder -> GenericStrategy -> GenericStrategy #
withDepths :: [CstrDepth] -> GenericStrategy #
newtype PrintAsValue a Source #
Provides Buildable instance that prints Lorentz value via Michelson's
Value.
Result won't be very pretty, but this avoids requiring Show or
Buildable instances.
Constructors
| PrintAsValue a |
Instances
| NicePrintedValue a => Buildable (PrintAsValue a) Source # | |
Defined in Lorentz.Value Methods build :: PrintAsValue a -> Builder # | |
Instances
| Eq Never Source # | |
| Ord Never Source # | |
| Show Never Source # | |
| Generic Never Source # | |
| NFData Never Source # | |
Defined in Lorentz.Value | |
| Buildable Never Source # | |
Defined in Lorentz.Value | |
| TypeHasDoc Never Source # | |
Defined in Lorentz.Value Associated Types type TypeDocFieldDescriptions Never :: FieldDescriptions # Methods typeDocName :: Proxy Never -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy Never -> WithinParens -> Markdown # typeDocDependencies :: Proxy Never -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep Never # typeDocMichelsonRep :: TypeDocMichelsonRep Never # | |
| IsoValue Never Source # | |
| HasAnnotation Never Source # | |
Defined in Lorentz.Value Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT Never) Source # | |
| type Rep Never Source # | |
| type TypeDocFieldDescriptions Never Source # | |
Defined in Lorentz.Value | |
| type ToT Never Source # | |
Defined in Lorentz.Value | |
data EpdWithRoot (r :: Symbol) epd Source #
Extension of EpdPlain, EpdRecursive, and EpdDelegate which allow specifying root annotation
for the parameters.
Instances
| (KnownSymbol r, PlainEntrypointsC deriv cp) => EntrypointsDerivation (EpdWithRoot r deriv :: Type) cp Source # | |
Defined in Lorentz.Entrypoints.Impl Associated Types type EpdAllEntrypoints (EpdWithRoot r deriv) cp :: [(Symbol, Type)] Source # type EpdLookupEntrypoint (EpdWithRoot r deriv) cp :: Symbol -> Exp (Maybe Type) Source # Methods epdNotes :: (Notes (ToT cp), RootAnn) Source # epdCall :: forall (name :: Symbol). ParameterScope (ToT cp) => Label name -> EpConstructionRes (ToT cp) (Eval (EpdLookupEntrypoint (EpdWithRoot r deriv) cp name)) Source # epdDescs :: Rec EpCallingDesc (EpdAllEntrypoints (EpdWithRoot r deriv) cp) Source # | |
| type EpdAllEntrypoints (EpdWithRoot r deriv :: Type) cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
| type EpdLookupEntrypoint (EpdWithRoot r deriv :: Type) cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
data EpdDelegate Source #
Extension of EpdPlain on parameters being defined as several nested
datatypes.
In particular, it will traverse the immediate sum type, and require another
ParameterHasEntrypoints for the inner complex datatypes. Only those
inner types are considered which are the only fields in their respective
constructors.
Inner types should not themselves declare default entrypoint, we enforce
this for better modularity.
Each top-level constructor will be treated as entrypoint even if it contains
a complex datatype within, in such case that would be an entrypoint
corresponding to intermediate node in or tree.
Comparing to EpdRecursive this gives you more control over where and how
entrypoints will be derived.
Instances
| PlainEntrypointsC EpdDelegate cp => EntrypointsDerivation EpdDelegate cp Source # | |
Defined in Lorentz.Entrypoints.Impl Associated Types type EpdAllEntrypoints EpdDelegate cp :: [(Symbol, Type)] Source # type EpdLookupEntrypoint EpdDelegate cp :: Symbol -> Exp (Maybe Type) Source # Methods epdNotes :: (Notes (ToT cp), RootAnn) Source # epdCall :: forall (name :: Symbol). ParameterScope (ToT cp) => Label name -> EpConstructionRes (ToT cp) (Eval (EpdLookupEntrypoint EpdDelegate cp name)) Source # epdDescs :: Rec EpCallingDesc (EpdAllEntrypoints EpdDelegate cp) Source # | |
| type EpdAllEntrypoints EpdDelegate cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
| type EpdLookupEntrypoint EpdDelegate cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
data EpdRecursive Source #
Extension of EpdPlain on parameters being defined as several nested
datatypes.
In particular, this will traverse sum types recursively, stopping at
Michelson primitives (like Natural) and constructors with number of
fields different from one.
It does not assign names to intermediate nodes of Or tree, only to the very
leaves.
If some entrypoint arguments have custom IsoValue instance, this
derivation way will not work. As a workaround, you can wrap your
argument into some primitive (e.g. :!).
Instances
| PlainEntrypointsC EpdRecursive cp => EntrypointsDerivation EpdRecursive cp Source # | |
Defined in Lorentz.Entrypoints.Impl Associated Types type EpdAllEntrypoints EpdRecursive cp :: [(Symbol, Type)] Source # type EpdLookupEntrypoint EpdRecursive cp :: Symbol -> Exp (Maybe Type) Source # Methods epdNotes :: (Notes (ToT cp), RootAnn) Source # epdCall :: forall (name :: Symbol). ParameterScope (ToT cp) => Label name -> EpConstructionRes (ToT cp) (Eval (EpdLookupEntrypoint EpdRecursive cp name)) Source # epdDescs :: Rec EpCallingDesc (EpdAllEntrypoints EpdRecursive cp) Source # | |
| type EpdAllEntrypoints EpdRecursive cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
| type EpdLookupEntrypoint EpdRecursive cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
Implementation of ParameterHasEntrypoints which fits for case when
your contract exposes multiple entrypoints via having sum type as its
parameter.
In particular, each constructor would produce a homonymous entrypoint with
argument type equal to type of constructor field (each constructor should
have only one field).
Constructor called Default will designate the default entrypoint.
Instances
| PlainEntrypointsC EpdPlain cp => EntrypointsDerivation EpdPlain cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
| type EpdAllEntrypoints EpdPlain cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
| type EpdLookupEntrypoint EpdPlain cp Source # | |
Defined in Lorentz.Entrypoints.Impl | |
class ToIntArithOp (ToT n) => ToIntegerArithOpHs (n :: Type) Source #
Instances
| ToIntegerArithOpHs Natural Source # | |
Defined in Lorentz.Arith | |
| ToIntegerArithOpHs Bls12381Fr Source # | |
Defined in Lorentz.Arith | |
class (UnaryArithOp aop (ToT n), ToT (UnaryArithResHs aop n) ~ UnaryArithRes aop (ToT n)) => UnaryArithOpHs (aop :: Type) (n :: Type) Source #
Lifted UnaryArithOp.
Associated Types
type UnaryArithResHs aop n :: Type Source #
Instances
class (ArithOp aop (ToT n) (ToT m), ToT (ArithResHs aop n m) ~ ArithRes aop (ToT n) (ToT m)) => ArithOpHs (aop :: Type) (n :: Type) (m :: Type) Source #
Lifted ArithOp.
Associated Types
type ArithResHs aop n m :: Type Source #
Instances
class ToT s ~ ToT (Unwrappable s) => Wrappable (s :: Type) Source #
Wrappable is similar to lens Wrapped class without the method.
It provides type family that is mainly used as constraint when
unwrapping Lorentz instruction into a Haskell newtype and vice versa.
Instances
| Wrappable (UParam entries) Source # | |
Defined in Lorentz.UParam Associated Types type Unwrappable (UParam entries) Source # | |
| Wrappable (ParameterWrapper deriv cp) Source # | |
Defined in Lorentz.Entrypoints.Manual Associated Types type Unwrappable (ParameterWrapper deriv cp) Source # | |
| Wrappable (Extensible x) Source # | |
Defined in Lorentz.Extensible Associated Types type Unwrappable (Extensible x) Source # | |
| Wrappable (NamedF Maybe a name) Source # | |
Defined in Lorentz.Wrappable Associated Types type Unwrappable (NamedF Maybe a name) Source # | |
| Wrappable (NamedF Identity a name) Source # | |
Defined in Lorentz.Wrappable Associated Types type Unwrappable (NamedF Identity a name) Source # | |
newtype ParameterWrapper (deriv :: Type) cp Source #
Wrap parameter into this to locally assign a way to derive entrypoints for it.
Constructors
| ParameterWrapper | |
Fields
| |
Instances
data DEntrypointExample Source #
Modify the example value of an entrypoint
Constructors
| forall t.ParameterScope t => DEntrypointExample (Value t) |
Instances
| DocItem DEntrypointExample Source # | |
Defined in Lorentz.Doc Associated Types type DocItemPlacement DEntrypointExample :: DocItemPlacementKind # type DocItemReferenced DEntrypointExample :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DEntrypointExample -> DocItemRef (DocItemPlacement DEntrypointExample) (DocItemReferenced DEntrypointExample) # docItemToMarkdown :: HeaderLevel -> DEntrypointExample -> Markdown # docItemToToc :: HeaderLevel -> DEntrypointExample -> Markdown # docItemDependencies :: DEntrypointExample -> [SomeDocDefinitionItem] # docItemsOrder :: [DEntrypointExample] -> [DEntrypointExample] # | |
| type DocItemPlacement DEntrypointExample Source # | |
Defined in Lorentz.Doc | |
| type DocItemReferenced DEntrypointExample Source # | |
Defined in Lorentz.Doc | |
docGroup :: DocItem di => (SubDoc -> di) -> (inp :-> out) -> inp :-> out Source #
Group documentation built in the given piece of code into block dedicated to one thing, e.g. to one entrypoint.
Examples of doc items you can pass here: DName, DGeneralInfoSection.
docStorage :: forall storage s. TypeHasDoc storage => s :-> s Source #
Deprecated: Use `doc (dStorage @storage)` instead.
Insert documentation of the contract storage type. The type should be passed using type applications.
contractName :: Text -> (inp :-> out) -> inp :-> out Source #
Deprecated: Use `docGroup name` instead.
Give a name to given contract. Apply it to the whole contract code.
buildLorentzDoc :: (inp :-> out) -> ContractDoc Source #
Deprecated: Use buildDoc instead.
contractGeneral :: (inp :-> out) -> inp :-> out Source #
Deprecated: Use `docGroup DGeneralInfoSection` instead.
Takes an instruction that inserts documentation items with
general information about the contract. Inserts it into general
section. See DGeneralInfoSection.
contractGeneralDefault :: s :-> s Source #
Inserts general information about the contract using the default format.
This includes git revision and some other information common
for all contracts.
Git revision is left unknown in the library code and is supposed
to be updated in an executable using e.g. buildLorentzDocWithGitRev.
buildLorentzDocWithGitRev :: DGitRevision -> (inp :-> out) -> ContractDoc Source #
Deprecated: Use `buildDoc . attachDocCommons gitRev` instead.
renderLorentzDoc :: (inp :-> out) -> LText Source #
Deprecated: Use buildMarkdownDoc instead.
renderLorentzDocWithGitRev :: DGitRevision -> (inp :-> out) -> LText Source #
Deprecated: Use `buildMarkdownDoc . attachDocCommons gitRev` instead.
cutLorentzNonDoc :: (inp :-> out) -> s :-> s Source #
Leave only instructions related to documentation.
This function is useful when your method executes a lambda coming from outside, but you know its properties and want to propagate its documentation to your contract code.
mkDEntrypointExample :: forall a. NiceParameter a => a -> DEntrypointExample Source #
data Keccak :: HashAlgorithmKind Source #
Instances
| KnownHashAlgorithm Keccak Source # | |
Defined in Lorentz.Bytes Methods hashAlgorithmName :: Proxy Keccak -> Text Source # computeHash :: ByteString -> ByteString Source # toHash :: forall bs (s :: [Type]). BytesLike bs => (bs ': s) :-> (Hash Keccak bs ': s) Source # | |
data Sha3 :: HashAlgorithmKind Source #
Instances
| KnownHashAlgorithm Sha3 Source # | |
Defined in Lorentz.Bytes Methods hashAlgorithmName :: Proxy Sha3 -> Text Source # computeHash :: ByteString -> ByteString Source # toHash :: forall bs (s :: [Type]). BytesLike bs => (bs ': s) :-> (Hash Sha3 bs ': s) Source # | |
data Blake2b :: HashAlgorithmKind Source #
Instances
| KnownHashAlgorithm Blake2b Source # | |
Defined in Lorentz.Bytes Methods hashAlgorithmName :: Proxy Blake2b -> Text Source # computeHash :: ByteString -> ByteString Source # toHash :: forall bs (s :: [Type]). BytesLike bs => (bs ': s) :-> (Hash Blake2b bs ': s) Source # | |
data Sha512 :: HashAlgorithmKind Source #
Instances
| KnownHashAlgorithm Sha512 Source # | |
Defined in Lorentz.Bytes Methods hashAlgorithmName :: Proxy Sha512 -> Text Source # computeHash :: ByteString -> ByteString Source # toHash :: forall bs (s :: [Type]). BytesLike bs => (bs ': s) :-> (Hash Sha512 bs ': s) Source # | |
data Sha256 :: HashAlgorithmKind Source #
Instances
| KnownHashAlgorithm Sha256 Source # | |
Defined in Lorentz.Bytes Methods hashAlgorithmName :: Proxy Sha256 -> Text Source # computeHash :: ByteString -> ByteString Source # toHash :: forall bs (s :: [Type]). BytesLike bs => (bs ': s) :-> (Hash Sha256 bs ': s) Source # | |
data DHashAlgorithm Source #
Documentation item for hash algorithms.
Instances
class Typeable alg => KnownHashAlgorithm (alg :: HashAlgorithmKind) where Source #
Hash algorithm used in Tezos.
Minimal complete definition
Methods
hashAlgorithmName :: Proxy alg -> Text Source #
computeHash :: ByteString -> ByteString Source #
toHash :: BytesLike bs => (bs ': s) :-> (Hash alg bs ': s) Source #
Instances
newtype Hash (alg :: HashAlgorithmKind) a Source #
Hash of type t evaluated from data of type a.
Constructors
| HashUnsafe | |
Fields
| |
Instances
newtype TSignature a Source #
Represents a signature, where signed data has given type.
Since we usually sign a packed data, a common pattern for this type is
TSignature (.
If you don't want to use Packed signedData)Packed, use plain TSignature ByteString instead.
Constructors
| TSignature | |
Fields | |
Instances
Represents a ByteString resulting from packing a value of type a.
This is not guaranteed to keep some packed value, and unpack can fail.
We do so because often we need to accept values of such type from user,
and also because there is no simple way to check validity of packed data
without performing full unpack.
So this wrapper is rather a hint for users.
Constructors
| Packed | |
Fields | |
Instances
class (KnownValue bs, ToT bs ~ ToT ByteString) => BytesLike bs where Source #
Everything which is represented as bytes inside.
Methods
toBytes :: bs -> ByteString Source #
Instances
| BytesLike ByteString Source # | |
Defined in Lorentz.Bytes Methods toBytes :: ByteString -> ByteString Source # | |
| Typeable a => BytesLike (Packed a) Source # | |
Defined in Lorentz.Bytes Methods toBytes :: Packed a -> ByteString Source # | |
| (Typeable alg, Typeable a) => BytesLike (Hash alg a) Source # | |
Defined in Lorentz.Bytes Methods toBytes :: Hash alg a -> ByteString Source # | |
lSignEd22519 :: BytesLike a => SecretKey -> a -> TSignature a Source #
Sign data using Ed25519 curve. TODO [#456]: handle other methods, either all at once (if viable) or each one separately
toHashHs :: forall alg bs. (BytesLike bs, KnownHashAlgorithm alg) => bs -> Hash alg bs Source #
Evaluate hash in Haskell world.
lPackValueRaw :: forall a. NicePackedValue a => a -> ByteString Source #
lUnpackValueRaw :: forall a. NiceUnpackedValue a => ByteString -> Either UnpackError a Source #
lPackValue :: forall a. NicePackedValue a => a -> Packed a Source #
lUnpackValue :: forall a. NiceUnpackedValue a => Packed a -> Either UnpackError a Source #
lEncodeValue :: forall a. NicePrintedValue a => a -> ByteString Source #
valueToScriptExpr :: forall t. NicePackedValue t => t -> ByteString Source #
This function transforms Lorentz values into script_expr.
script_expr is used in RPC as an argument in entrypoint
designed for getting value by key from the big_map in Babylon.
In order to convert value to the script_expr we have to pack it,
take blake2b hash and add specific expr prefix. Take a look at
https://gitlab.com/tezos/tezos/blob/6e25ae8eb385d9975a30388c7a7aa2a9a65bf184/src/proto_005_PsBabyM1/lib_protocol/script_expr_hash.ml
and https://gitlab.com/tezos/tezos/blob/6e25ae8eb385d9975a30388c7a7aa2a9a65bf184/src/proto_005_PsBabyM1/lib_protocol/contract_services.ml#L136
for more information.
expressionToScriptExpr :: Expression -> ByteString Source #
Similar to valueToScriptExpr, but for values encoded as Expressions.
This is only used in tests.
type Coercible_ a b = (MichelsonCoercible a b, CanCastTo a b, CanCastTo b a) Source #
Coercions between a to b are permitted and safe.
type Castable_ a b = (MichelsonCoercible a b, CanCastTo a b) Source #
Coercion from a to b is permitted and safe.
class CanCastTo a b where Source #
Explicitly allowed coercions.
a proclaims that CanCastTo ba can be casted to b without violating
any invariants of b.
This relation is reflexive; it may be symmetric or not.
It tends to be composable: casting complex types usually requires permission
to cast their respective parts; for such types consider using castDummyG
as implementation of the method of this typeclass.
For cases when a cast from a to b requires some validation, consider
rather making a dedicated function which performs the necessary checks and
then calls forcedCoerce.
Minimal complete definition
Nothing
Methods
castDummy :: Proxy a -> Proxy b -> () Source #
An optional method which helps passing -Wredundant-constraints check. Also, you can set specific implementation for it with specific sanity checks.
Instances
type MichelsonCoercible a b = ToT a ~ ToT b Source #
Whether two types have the same Michelson representation.
forcedCoerce :: Coercible a b => a -> b Source #
Coercion for Haskell world.
We discourage using this function on Lorentz types, consider using coerce
instead.
One of the reasons forthat is that in Lorentz it's common to declare types as
newtypes consisting of existing primitives, and forcedCoerce tends to ignore
all phantom type variables of newtypes thus violating their invariants.
forcedCoerce_ :: MichelsonCoercible a b => (a ': s) :-> (b ': s) Source #
Convert between values of types that have the same representation.
This function is not safe in a sense that this allows
* breaking invariants of casted type
(example: UStore from morley-upgradeable), or
* may stop compile on code changes
(example: coercion of pair to a datatype with two fields
will break if new field is added).
Still, produced Michelson code will always be valid.
Prefer using one of more specific functions from this module.
gForcedCoerce_ :: MichelsonCoercible (t a) (t b) => (t a ': s) :-> (t b ': s) Source #
fakeCoerce :: s1 :-> s2 Source #
Convert between two stacks via failing.
fakeCoercing :: (s1 :-> s2) -> s1' :-> s2' Source #
coerceWrap :: forall a s. Wrappable a => (Unwrappable a ': s) :-> (a ': s) Source #
Specialized version of coerce_ to wrap into a haskell newtype.
coerceUnwrap :: forall a s. Wrappable a => (a ': s) :-> (Unwrappable a ': s) Source #
Specialized version of coerce_ to unwrap a haskell newtype.
toNamed :: Label name -> (a ': s) :-> (NamedF Identity a name ': s) Source #
Lift given value to a named value.
checkedCoerce :: forall a b. (CanCastTo a b, Coercible a b) => a -> b Source #
Coercion in Haskell world which respects CanCastTo.
checkedCoerce_ :: forall a b s. Castable_ a b => (a ': s) :-> (b ': s) Source #
Coerce between types which have an explicit permission for that in the
face of CanCastTo constraint.
checkedCoercing_ :: forall a b s. Coercible_ a b => ((b ': s) :-> (b ': s)) -> (a ': s) :-> (a ': s) Source #
Pretends that the top item of the stack was coerced.
allowCheckedCoerceTo :: forall b a. Dict (CanCastTo a b) Source #
Locally provide given CanCastTo instance.
allowCheckedCoerce :: forall a b. Dict (CanCastTo a b, CanCastTo b a) Source #
Locally provide bidirectional CanCastTo instance.
castDummyG :: (Generic a, Generic b, GCanCastTo (Rep a) (Rep b)) => Proxy a -> Proxy b -> () Source #
Implementation of castDummy for types composed from smaller types.
It helps to ensure that all necessary constraints are requested in instance
head.
type CaseTC dt out inp clauses = (InstrCaseC dt, RMap (CaseClauses dt), RecFromTuple clauses, clauses ~ Rec (CaseClauseL inp out) (CaseClauses dt)) Source #
class CaseArrow name body clause | clause -> name, clause -> body where Source #
Provides "case" arrow which works on different wrappers for clauses.
Methods
(/->) :: Label name -> body -> clause infixr 0 Source #
Lift an instruction to case clause.
You should write out constructor name corresponding to the clause explicitly. Prefix constructor name with "c" letter, otherwise your label will not be recognized by Haskell parser. Passing constructor name can be circumvented but doing so is not recomended as mentioning contructor name improves readability and allows avoiding some mistakes.
Instances
| (name ~ AppendSymbol "c" ctor, body ~ (AppendCtorField x inp :-> out)) => CaseArrow name body (CaseClauseL inp out ('CaseClauseParam ctor x)) Source # | |
Defined in Lorentz.ADT Methods (/->) :: Label name -> body -> CaseClauseL inp out ('CaseClauseParam ctor x) Source # | |
data CaseClauseL (inp :: [Type]) (out :: [Type]) (param :: CaseClauseParam) where Source #
Lorentz analogy of CaseClause, it works on plain Type types.
Constructors
| CaseClauseL :: (AppendCtorField x inp :-> out) -> CaseClauseL inp out ('CaseClauseParam ctor x) |
Instances
| (name ~ AppendSymbol "c" ctor, body ~ (AppendCtorField x inp :-> out)) => CaseArrow name body (CaseClauseL inp out ('CaseClauseParam ctor x)) Source # | |
Defined in Lorentz.ADT Methods (/->) :: Label name -> body -> CaseClauseL inp out ('CaseClauseParam ctor x) Source # | |
type family HasFieldsOfType (dt :: Type) (fs :: [NamedField]) :: Constraint where ... Source #
Shortcut for multiple HasFieldOfType constraints.
Equations
| HasFieldsOfType _ '[] = () | |
| HasFieldsOfType dt ((n := ty) ': fs) = (HasFieldOfType dt n ty, HasFieldsOfType dt fs) |
type (:=) n ty = 'NamedField n ty infixr 0 Source #
type HasFieldOfType dt fname fieldTy = (HasField dt fname, GetFieldType dt fname ~ fieldTy) Source #
Like HasField, but allows constrainting field type.
type HasField dt fname = (InstrGetFieldC dt fname, InstrSetFieldC dt fname) Source #
Allows field access and modification.
toField :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> (GetFieldType dt name ': st) Source #
Extract a field of a datatype replacing the value of this datatype with the extracted field.
For this and the following functions you have to specify field name
which is either record name or name attached with (:!) operator.
toFieldNamed :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> ((name :! GetFieldType dt name) ': st) Source #
Like toField, but leaves field named.
getField :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> (GetFieldType dt name ': (dt ': st)) Source #
Extract a field of a datatype, leaving the original datatype on stack.
getFieldNamed :: forall dt name st. InstrGetFieldC dt name => Label name -> (dt ': st) :-> ((name :! GetFieldType dt name) ': (dt ': st)) Source #
Like getField, but leaves field named.
setField :: forall dt name st. InstrSetFieldC dt name => Label name -> (GetFieldType dt name ': (dt ': st)) :-> (dt ': st) Source #
Set a field of a datatype.
modifyField :: forall dt name st. (InstrGetFieldC dt name, InstrSetFieldC dt name) => Label name -> (forall st0. (GetFieldType dt name ': st0) :-> (GetFieldType dt name ': st0)) -> (dt ': st) :-> (dt ': st) Source #
Apply given modifier to a datatype field.
construct :: forall dt st. (InstrConstructC dt, RMap (ConstructorFieldTypes dt)) => Rec (FieldConstructor st) (ConstructorFieldTypes dt) -> st :-> (dt ': st) Source #
Make up a datatype. You provide a pack of individual fields constructors.
Each element of the accepted record should be an instruction wrapped with
fieldCtor function. This instruction will have access to the stack at
the moment of calling construct.
Instructions have to output fields of the built datatype, one per instruction;
instructions order is expected to correspond to the order of fields in the
datatype.
constructT :: forall dt fctors st. (InstrConstructC dt, RMap (ConstructorFieldTypes dt), fctors ~ Rec (FieldConstructor st) (ConstructorFieldTypes dt), RecFromTuple fctors) => IsoRecTuple fctors -> st :-> (dt ': st) Source #
Version of construct which accepts tuple of field constructors.
constructStack :: forall dt fields st. (InstrConstructC dt, ToTs fields ~ ToTs (ConstructorFieldTypes dt), KnownList fields) => (fields ++ st) :-> (dt ': st) Source #
Construct an object from fields on the stack.
deconstruct :: forall dt fields st. (InstrDeconstructC dt, KnownList fields, ToTs fields ~ ToTs (ConstructorFieldTypes dt)) => (dt ': st) :-> (fields ++ st) Source #
Decompose a complex object into its fields
fieldCtor :: HasCallStack => (st :-> (f ': st)) -> FieldConstructor st f Source #
Lift an instruction to field constructor.
wrap_ :: forall dt name st. InstrWrapC dt name => Label name -> AppendCtorField (GetCtorField dt name) st :-> (dt ': st) Source #
Wrap entry in constructor. Useful for sum types.
wrapOne :: forall dt name st. InstrWrapOneC dt name => Label name -> (CtorOnlyField name dt ': st) :-> (dt ': st) Source #
Wrap entry in single-field constructor. Useful for sum types.
case_ :: forall dt out inp. (InstrCaseC dt, RMap (CaseClauses dt)) => Rec (CaseClauseL inp out) (CaseClauses dt) -> (dt ': inp) :-> out Source #
caseT :: forall dt out inp clauses. CaseTC dt out inp clauses => IsoRecTuple clauses -> (dt ': inp) :-> out Source #
Like case_, accepts a tuple of clauses, which may be more convenient.
If user is experiencing problems with wierd errors about tuples while using
this function, he should take look at Instances and ensure
that his tuple isn't bigger than generated instances, if so, he should probably
extend number of generated instances.
unwrapUnsafe_ :: forall dt name st. InstrUnwrapC dt name => Label name -> (dt ': st) :-> (CtorOnlyField name dt ': st) Source #
Unwrap a constructor with the given name. Useful for sum types.
type family RequireFlatEpDerivation cp deriv :: Constraint where ... Source #
Equations
| RequireFlatEpDerivation _ EpdNone = () | |
| RequireFlatEpDerivation _ EpdPlain = () | |
| RequireFlatEpDerivation cp deriv = TypeError (('Text "Parameter is not flat" :$$: (('Text "For parameter `" :<>: 'ShowType cp) :<>: 'Text "`")) :$$: (('Text "With entrypoints derivation way `" :<>: 'ShowType deriv) :<>: 'Text "`")) |
type family RequireFlatParamEps cp :: Constraint where ... Source #
Equations
| RequireFlatParamEps cp = (NiceParameterFull cp, RequireFlatEpDerivation cp (GetParameterEpDerivation cp), RequireSumType cp) |
class EntryArrow kind name body where Source #
Provides arror for convenient entrypoint documentation
Methods
(#->) :: (Label name, Proxy kind) -> body -> body Source #
Lift entrypoint implementation.
Entrypoint names should go with "e" prefix.
Instances
| (name ~ AppendSymbol "e" epName, body ~ ((param ': s) :-> out), KnownSymbol epName, DocItem (DEntrypoint kind), NiceParameter param, TypeHasDoc param, KnownValue param) => EntryArrow (kind :: Type) name body Source # | |
type DocumentEntrypoints kind a = (Generic a, GDocumentEntrypoints kind (Rep a)) Source #
Constraint for documentEntrypoints.
class KnownSymbol con => DeriveCtorFieldDoc con (cf :: CtorField) where Source #
Pick a type documentation from CtorField.
Methods
Instances
| KnownSymbol con => DeriveCtorFieldDoc con 'NoFields Source # | |
Defined in Lorentz.Entrypoints.Doc Methods | |
| (NiceParameter ty, TypeHasDoc ty, KnownValue ty, KnownSymbol con) => DeriveCtorFieldDoc con ('OneField ty) Source # | |
Defined in Lorentz.Entrypoints.Doc Methods | |
data DEntrypointArg Source #
Describes argument of an entrypoint.
Constructors
| DEntrypointArg | |
Fields
| |
Instances
| DocItem DEntrypointArg Source # | |
Defined in Lorentz.Entrypoints.Doc Associated Types type DocItemPlacement DEntrypointArg :: DocItemPlacementKind # type DocItemReferenced DEntrypointArg :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DEntrypointArg -> DocItemRef (DocItemPlacement DEntrypointArg) (DocItemReferenced DEntrypointArg) # docItemToMarkdown :: HeaderLevel -> DEntrypointArg -> Markdown # docItemToToc :: HeaderLevel -> DEntrypointArg -> Markdown # docItemDependencies :: DEntrypointArg -> [SomeDocDefinitionItem] # docItemsOrder :: [DEntrypointArg] -> [DEntrypointArg] # | |
| type DocItemPlacement DEntrypointArg Source # | |
Defined in Lorentz.Entrypoints.Doc | |
| type DocItemReferenced DEntrypointArg Source # | |
Defined in Lorentz.Entrypoints.Doc | |
data SomeEntrypointArg Source #
Entrypoint argument type in typed representation.
Constructors
| forall a.(NiceParameter a, TypeHasDoc a) => SomeEntrypointArg (Proxy a) |
data ParamBuildingStep Source #
Describes a parameter building step.
This can be wrapping into (Haskell) constructor, or a more complex transformation.
Constructors
| PbsWrapIn Text ParamBuildingDesc | Wraps something into constructor with given name.
Constructor should be the one which corresponds to an entrypoint
defined via field annotation, for more complex cases use |
| PbsCallEntrypoint EpName | Directly call an entrypoint marked with a field annotation. |
| PbsCustom ParamBuildingDesc | Other action. |
| PbsUncallable [ParamBuildingStep] | This entrypoint cannot be called, which is possible when an explicit
default entrypoint is present. This is not a true entrypoint but just some
intermediate node in It contains dummy |
Instances
| Eq ParamBuildingStep Source # | |
Defined in Lorentz.Entrypoints.Doc Methods (==) :: ParamBuildingStep -> ParamBuildingStep -> Bool # (/=) :: ParamBuildingStep -> ParamBuildingStep -> Bool # | |
| Show ParamBuildingStep Source # | |
Defined in Lorentz.Entrypoints.Doc Methods showsPrec :: Int -> ParamBuildingStep -> ShowS # show :: ParamBuildingStep -> String # showList :: [ParamBuildingStep] -> ShowS # | |
| Buildable ParamBuildingStep Source # | |
Defined in Lorentz.Entrypoints.Doc Methods build :: ParamBuildingStep -> Builder # | |
data ParamBuildingDesc Source #
Constructors
| ParamBuildingDesc | |
Fields
| |
Instances
| Eq ParamBuildingDesc Source # | |
Defined in Lorentz.Entrypoints.Doc Methods (==) :: ParamBuildingDesc -> ParamBuildingDesc -> Bool # (/=) :: ParamBuildingDesc -> ParamBuildingDesc -> Bool # | |
| Show ParamBuildingDesc Source # | |
Defined in Lorentz.Entrypoints.Doc Methods showsPrec :: Int -> ParamBuildingDesc -> ShowS # show :: ParamBuildingDesc -> String # showList :: [ParamBuildingDesc] -> ShowS # | |
newtype ParamBuilder Source #
When describing the way of parameter construction - piece of incremental builder for this description.
Constructors
| ParamBuilder | |
Fields
| |
Instances
| Eq ParamBuilder Source # | |
Defined in Lorentz.Entrypoints.Doc | |
| Show ParamBuilder Source # | |
Defined in Lorentz.Entrypoints.Doc Methods showsPrec :: Int -> ParamBuilder -> ShowS # show :: ParamBuilder -> String # showList :: [ParamBuilder] -> ShowS # | |
| Buildable ParamBuilder Source # | |
Defined in Lorentz.Entrypoints.Doc Methods build :: ParamBuilder -> Builder # | |
data DEntrypointReference Source #
Inserts a reference to an existing entrypoint.
This helps to avoid duplication in the generated documentation, in order not to overwhelm the reader.
Constructors
| DEntrypointReference Text Anchor |
Instances
| DocItem DEntrypointReference Source # | |
Defined in Lorentz.Entrypoints.Doc Associated Types type DocItemPlacement DEntrypointReference :: DocItemPlacementKind # type DocItemReferenced DEntrypointReference :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DEntrypointReference -> DocItemRef (DocItemPlacement DEntrypointReference) (DocItemReferenced DEntrypointReference) # docItemToMarkdown :: HeaderLevel -> DEntrypointReference -> Markdown # docItemToToc :: HeaderLevel -> DEntrypointReference -> Markdown # docItemDependencies :: DEntrypointReference -> [SomeDocDefinitionItem] # docItemsOrder :: [DEntrypointReference] -> [DEntrypointReference] # | |
| type DocItemPlacement DEntrypointReference Source # | |
Defined in Lorentz.Entrypoints.Doc | |
| type DocItemReferenced DEntrypointReference Source # | |
Defined in Lorentz.Entrypoints.Doc | |
data CommonEntrypointsBehaviourKind kind Source #
Describes the behaviour common for entrypoints of given kind.
This has very special use cases, like contracts with mix of upgradeable and permanent entrypoints.
Instances
| EntrypointKindHasDoc kind => EntrypointKindHasDoc (CommonEntrypointsBehaviourKind kind) Source # | |
Defined in Lorentz.Entrypoints.Doc | |
data CommonContractBehaviourKind Source #
Describes the behaviour common for all entrypoints.
For instance, if your contract runs some checks before calling any
entrypoint, you probably want to wrap those checks into
entrypointSection "Prior checks" (Proxy @CommonContractBehaviourKind).
Instances
class Typeable ep => EntrypointKindHasDoc (ep :: Type) where Source #
Describes location of entrypoints of the given kind.
All such entrypoints will be placed under the same "entrypoints" section, and this instance defines characteristics of this section.
Minimal complete definition
Methods
entrypointKindPos :: Natural Source #
Position of the respective entrypoints section in the doc. This shares the same positions space with all other doc items.
entrypointKindSectionName :: Text Source #
Name of the respective entrypoints section.
entrypointKindSectionDescription :: Maybe Markdown Source #
Description in the respective entrypoints section.
Instances
| EntrypointKindHasDoc CommonContractBehaviourKind Source # | |
Defined in Lorentz.Entrypoints.Doc | |
| EntrypointKindHasDoc PlainEntrypointsKind Source # | |
Defined in Lorentz.Entrypoints.Doc | |
| EntrypointKindHasDoc kind => EntrypointKindHasDoc (CommonEntrypointsBehaviourKind kind) Source # | |
Defined in Lorentz.Entrypoints.Doc | |
data DEntrypoint (kind :: Type) Source #
Gathers information about single entrypoint.
We assume that entry points might be of different kinds,
which is designated by phantom type parameter.
For instance, you may want to have several groups of entry points
corresponding to various parts of a contract - specifying different kind
type argument for each of those groups will allow you defining different
DocItem instances with appropriate custom descriptions for them.
Constructors
| DEntrypoint | |
Instances
| EntrypointKindHasDoc ep => DocItem (DEntrypoint ep) Source # | |
Defined in Lorentz.Entrypoints.Doc Associated Types type DocItemPlacement (DEntrypoint ep) :: DocItemPlacementKind # type DocItemReferenced (DEntrypoint ep) :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DEntrypoint ep -> DocItemRef (DocItemPlacement (DEntrypoint ep)) (DocItemReferenced (DEntrypoint ep)) # docItemToMarkdown :: HeaderLevel -> DEntrypoint ep -> Markdown # docItemToToc :: HeaderLevel -> DEntrypoint ep -> Markdown # docItemDependencies :: DEntrypoint ep -> [SomeDocDefinitionItem] # docItemsOrder :: [DEntrypoint ep] -> [DEntrypoint ep] # | |
| type DocItemPlacement (DEntrypoint ep) Source # | |
Defined in Lorentz.Entrypoints.Doc | |
| type DocItemReferenced (DEntrypoint ep) Source # | |
Defined in Lorentz.Entrypoints.Doc | |
pattern DEntrypointDocItem :: DEntrypoint kind -> SomeDocItem Source #
Pattern that checks whether given SomeDocItem hides DEntrypoint inside
(of any entrypoint kind).
In case a specific kind is necessary, use plain (cast -> Just DEntrypoint{..})
construction instead.
diEntrypointToMarkdown :: HeaderLevel -> DEntrypoint level -> Markdown Source #
Default implementation of docItemToMarkdown for entrypoints.
entrypointSection :: EntrypointKindHasDoc kind => Text -> Proxy kind -> (i :-> o) -> i :-> o Source #
Mark code as part of entrypoint with given name.
This is automatically called at most of the appropriate situations, like
entryCase calls.
mkPbsWrapIn :: Text -> ParamBuilder -> ParamBuildingStep Source #
Make a ParamBuildingStep that tells about wrapping an argument into
a constructor with given name and uses given ParamBuilder as description of
Michelson part.
constructDEpArg :: forall arg. (NiceParameter arg, TypeHasDoc arg) => DEntrypointArg Source #
mkDEpUType :: forall t. (KnownValue t, HasAnnotation t) => Ty Source #
mkDEntrypointArgSimple :: forall t. (NiceParameter t, TypeHasDoc t) => DEntrypointArg Source #
clarifyParamBuildingSteps :: ParamBuildingStep -> (inp :-> out) -> inp :-> out Source #
Go over contract code and update every occurrence of DEntrypointArg
documentation item, adding the given step to its "how to build parameter"
description.
entryCase_ :: forall dt entrypointKind out inp. (InstrCaseC dt, RMap (CaseClauses dt), DocumentEntrypoints entrypointKind dt) => Proxy entrypointKind -> Rec (CaseClauseL inp out) (CaseClauses dt) -> (dt ': inp) :-> out Source #
Like case_, to be used for pattern-matching on a parameter
or its part.
Modifies documentation accordingly. Including description of
entrypoints' arguments, thus for them you will need to supply
TypeHasDoc instance.
entryCase :: forall dt entrypointKind out inp clauses. (CaseTC dt out inp clauses, DocumentEntrypoints entrypointKind dt) => Proxy entrypointKind -> IsoRecTuple clauses -> (dt ': inp) :-> out Source #
Version of entryCase_ for tuples.
documentEntrypoint :: forall kind epName param s out. (KnownSymbol epName, DocItem (DEntrypoint kind), NiceParameter param, TypeHasDoc param) => ((param ': s) :-> out) -> (param ': s) :-> out Source #
Wrapper for documenting single entrypoint which parameter isn't going to be unwrapped from some datatype.
entryCase unwraps a datatype, however, sometimes we want to
have entrypoint parameter to be not wrapped into some datatype.
finalizeParamCallingDoc' :: forall cp inp out. (NiceParameterFull cp, HasCallStack) => Proxy cp -> (inp :-> out) -> inp :-> out Source #
Modify param building steps with respect to entrypoints that given parameter declares.
Each contract with entrypoints should eventually call this function, otherwise, in case if contract uses built-in entrypoints feature, the resulting parameter building steps in the generated documentation will not consider entrypoints and thus may be incorrect.
Calling this twice over the same code is also prohibited.
This method is for internal use, if you want to apply it to a contract
manually, use finalizeParamCallingDoc.
finalizeParamCallingDoc :: forall cp inp out. (NiceParameterFull cp, RequireSumType cp, HasCallStack) => ((cp ': inp) :-> out) -> (cp ': inp) :-> out Source #
Version of 'finalizeParamCallingDoc'' more convenient for manual call in a contract.
areFinalizedParamBuildingSteps :: [ParamBuildingStep] -> Bool Source #
Whether finalizeParamCallingDoc has already been applied to these steps.
entryCaseSimple_ :: forall cp out inp. (InstrCaseC cp, RMap (CaseClauses cp), DocumentEntrypoints PlainEntrypointsKind cp, RequireFlatParamEps cp) => Rec (CaseClauseL inp out) (CaseClauses cp) -> (cp ': inp) :-> out Source #
entryCaseSimple :: forall cp out inp clauses. (CaseTC cp out inp clauses, DocumentEntrypoints PlainEntrypointsKind cp, RequireFlatParamEps cp) => IsoRecTuple clauses -> (cp ': inp) :-> out Source #
Code for a contract along with compilation options for the Lorentz compiler.
It is expected that a Contract is one packaged entity, wholly controlled by its author.
Therefore the author should be able to set all options that control contract's behavior.
This helps ensure that a given contract will be interpreted in the same way in all environments, like production and testing.
Raw ContractCode should not be used for distribution of contracts.
Constructors
| Contract | |
Fields
| |
Instances
| ContainsDoc (Contract cp st) Source # | |
Defined in Lorentz.Run Methods buildDocUnfinalized :: Contract cp st -> ContractDoc # | |
| ContainsUpdateableDoc (Contract cp st) Source # | |
Defined in Lorentz.Run Methods modifyDocEntirely :: (SomeDocItem -> SomeDocItem) -> Contract cp st -> Contract cp st # | |
data CompilationOptions Source #
Options to control Lorentz to Michelson compilation.
Constructors
| CompilationOptions | |
Fields
| |
defaultCompilationOptions :: CompilationOptions Source #
Runs Michelson optimizer with default config and does not touch strings and bytes.
intactCompilationOptions :: CompilationOptions Source #
Leave contract without any modifications. For testing purposes.
compileLorentz :: (inp :-> out) -> Instr (ToTs inp) (ToTs out) Source #
For use outside of Lorentz. Will use defaultCompilationOptions.
compileLorentzWithOptions :: CompilationOptions -> (inp :-> out) -> Instr (ToTs inp) (ToTs out) Source #
Compile Lorentz code, optionally running the optimizer, string and byte transformers.
defaultContract :: forall cp st. (NiceParameterFull cp, HasCallStack) => ContractCode cp st -> Contract cp st Source #
Compile contract with defaultCompilationOptions and cDisableInitialCast set to False.
compileLorentzContract :: forall cp st. (NiceParameterFull cp, NiceStorage st) => Contract cp st -> Contract (ToT cp) (ToT st) Source #
Compile a whole contract to Michelson.
Note that compiled contract can be ill-typed in terms of Michelson code
when some of the compilation options are used (e.g. when ccoDisableInitialCast
is True, resulted contract can be ill-typed).
However, compilation with defaultContractCompilationOptions should be valid.
interpretLorentzInstr :: (IsoValuesStack inp, IsoValuesStack out) => ContractEnv -> (inp :-> out) -> Rec Identity inp -> Either MichelsonFailed (Rec Identity out) Source #
Interpret a Lorentz instruction, for test purposes. Note that this does not run the optimizer.
interpretLorentzLambda :: (IsoValue inp, IsoValue out) => ContractEnv -> Lambda inp out -> inp -> Either MichelsonFailed out Source #
Like interpretLorentzInstr, but works on lambda rather than
arbitrary instruction.
analyzeLorentz :: (inp :-> out) -> AnalyzerRes Source #
Lorentz version of analyzer.
coOptimizerConfL :: Lens' CompilationOptions (Maybe OptimizerConf) Source #
coStringTransformerL :: Lens' CompilationOptions (Bool, MText -> MText) Source #
cCodeL :: forall cp st cp st. Lens (Contract cp st) (Contract cp st) (ContractCode cp st) (ContractCode cp st) Source #
cCompilationOptionsL :: forall cp st. Lens' (Contract cp st) CompilationOptions Source #
(-$?) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out) => (inps :-> '[out]) -> ZippedStack inps -> Either MichelsonFailed out infixr 2 Source #
Run a lambda with given input.
Note that this always returns one value, but can accept multiple input values (in such case they are grouped into nested pairs).
For testing and demonstration purposes.
(-$) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out, HasCallStack) => (inps :-> '[out]) -> ZippedStack inps -> out infixr 2 Source #
Like -$?
For testing and demonstration purposes.
>>>import Lorentz.Instr
>>>nop -$ 55>>>sub -$ (3, 2)1>>>push 9 -$ ()9>>>add # add -$ ((1, 2), 3)6
(&?-) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out) => ZippedStack inps -> (inps :-> '[out]) -> Either MichelsonFailed out infixl 2 Source #
Version of (-$?) with arguments flipped.
(&-) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out, HasCallStack) => ZippedStack inps -> (inps :-> '[out]) -> out infixl 2 Source #
Version of (-$) with arguments flipped.
(<-$>) :: (ZipInstr inps, IsoValue (ZippedStack inps), IsoValue out, HasCallStack) => (inps :-> '[out]) -> [ZippedStack inps] -> [out] infixl 2 Source #
Version of (-$) applicable to a series of values.
printLorentzValue :: forall v. NicePrintedValue v => Bool -> v -> LText Source #
Pretty-print a Haskell value as Michelson one.
printLorentzContract :: forall cp st. (NiceParameterFull cp, NiceStorage st) => Bool -> Contract cp st -> LText Source #
Pretty-print a Lorentz contract into Michelson code.
contractOpSize :: (NiceParameterFull cp, NiceStorage st) => Contract cp st -> OpSize Source #
Estimate code operation size.
valueOpSize :: forall a. NicePrintedValue a => a -> OpSize Source #
Estimate value operation size.
class LorentzFunctor (c :: Type -> Type) where Source #
Instances
| LorentzFunctor Maybe Source # | |
Defined in Lorentz.Instr | |
type ConstraintDIPNLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (s :: [Type]) (s' :: [Type]) = (ConstraintDIPN n (ToTs inp) (ToTs out) (ToTs s) (ToTs s'), ConstraintDIPN' Type n inp out s s') Source #
type family PairUpdateHs (ix :: Peano) (val :: Type) (pair :: Type) :: Type where ... Source #
Equations
| PairUpdateHs 'Z val _ = val | |
| PairUpdateHs ('S 'Z) val (_, right) = (val, right) | |
| PairUpdateHs ('S ('S n)) val (left, right) = (left, PairUpdateHs n val right) |
type ConstraintPairUpdateLorentz (n :: Nat) (val :: Type) (pair :: Type) = (ConstraintUpdateN (ToPeano n) (ToT pair), ToT (PairUpdateHs (ToPeano n) val pair) ~ UpdateN (ToPeano n) (ToT val) (ToT pair)) Source #
type ConstraintPairGetLorentz (n :: Nat) (pair :: Type) = (ConstraintGetN (ToPeano n) (ToT pair), ToT (PairGetHs (ToPeano n) pair) ~ GetN (ToPeano n) (ToT pair)) Source #
type ConstraintDUGLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (a :: Type) = (ConstraintDUG n (ToTs inp) (ToTs out) (ToT a), ConstraintDUG' Type n inp out a) Source #
type ConstraintDIGLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (a :: Type) = (ConstraintDIG n (ToTs inp) (ToTs out) (ToT a), ConstraintDIG' Type n inp out a) Source #
type ConstraintDUPNLorentz (n :: Peano) (inp :: [Type]) (out :: [Type]) (a :: Type) = (ConstraintDUPN n (ToTs inp) (ToTs out) (ToT a), ConstraintDUPN' Type n inp out a) Source #
justComment :: Text -> s :-> s Source #
dropN :: forall (n :: Nat) (s :: [Type]). (SingI (ToPeano n), KnownPeano (ToPeano n), RequireLongerOrSameLength (ToTs s) (ToPeano n), Drop (ToPeano n) (ToTs s) ~ ToTs (Drop (ToPeano n) s)) => s :-> Drop (ToPeano n) s Source #
Drop top n elements from the stack.
dupNPeano :: forall (n :: Peano) inp out a. ConstraintDUPNLorentz n inp out a => inp :-> out Source #
dupN :: forall (n :: Nat) inp out a. ConstraintDUPNLorentz (ToPeano n) inp out a => inp :-> out Source #
digPeano :: forall (n :: Peano) inp out a. ConstraintDIGLorentz n inp out a => inp :-> out Source #
Version of dig which uses Peano number.
It is intended for internal usage in Lorentz.
dig :: forall (n :: Nat) inp out a. ConstraintDIGLorentz (ToPeano n) inp out a => inp :-> out Source #
dugPeano :: forall (n :: Peano) inp out a. ConstraintDUGLorentz n inp out a => inp :-> out Source #
Version of dug which uses Peano number.
It is intended for internal usage in Lorentz.
dug :: forall (n :: Nat) inp out a. ConstraintDUGLorentz (ToPeano n) inp out a => inp :-> out Source #
push :: forall t s. NiceConstant t => t -> s :-> (t ': s) Source #
emptyMap :: (NiceComparable k, KnownValue v) => s :-> (Map k v ': s) Source #
emptyBigMap :: (NiceComparable k, KnownValue v) => s :-> (BigMap k v ': s) Source #
map :: (MapOpHs c, IsoMapOpRes c b, KnownValue b, HasCallStack) => ((MapOpInpHs c ': s) :-> (b ': s)) -> (c ': s) :-> (MapOpResHs c b ': s) Source #
iter :: (IterOpHs c, HasCallStack) => ((IterOpElHs c ': s) :-> s) -> (c ': s) :-> s Source #
get :: (GetOpHs c, KnownValue (GetOpValHs c)) => (GetOpKeyHs c ': (c ': s)) :-> (Maybe (GetOpValHs c) ': s) Source #
pairGet :: forall (n :: Nat) (pair :: Type) (s :: [Type]). ConstraintPairGetLorentz n pair => (pair ': s) :-> (PairGetHs (ToPeano n) pair ': s) Source #
update :: UpdOpHs c => (UpdOpKeyHs c ': (UpdOpParamsHs c ': (c ': s))) :-> (c ': s) Source #
pairUpdate :: forall (n :: Nat) (val :: Type) (pair :: Type) (s :: [Type]). ConstraintPairUpdateLorentz n val pair => (val ': (pair ': s)) :-> (PairUpdateHs (ToPeano n) val pair ': s) Source #
execute :: forall i o s. Each [KnownList, ZipInstr] [i, o] => ((i :-> o) ': (i ++ s)) :-> (o ++ s) Source #
Similar to exec but works for lambdas with arbitrary size of input
and output.
Note that this instruction has its arguments flipped, lambda goes first. This seems to be the only reasonable way to achieve good inference.
apply :: forall a b c s. (NiceConstant a, KnownValue b) => (a ': (Lambda (a, b) c ': s)) :-> (Lambda b c ': s) Source #
applicate :: forall a b c inp2nd inpTail s. (NiceConstant a, ZipInstr b, b ~ (inp2nd ': inpTail)) => (a ': (((a ': b) :-> c) ': s)) :-> ((b :-> c) ': s) Source #
Version of apply that works for lambdas with arbitrary length
input and output.
dipNPeano :: forall (n :: Peano) (inp :: [Type]) (out :: [Type]) (s :: [Type]) (s' :: [Type]). ConstraintDIPNLorentz n inp out s s' => (s :-> s') -> inp :-> out Source #
Version of dipN which uses Peano number.
It is intended for internal usage in Lorentz.
dipN :: forall (n :: Nat) (inp :: [Type]) (out :: [Type]) (s :: [Type]) (s' :: [Type]). ConstraintDIPNLorentz (ToPeano n) inp out s s' => (s :-> s') -> inp :-> out Source #
failWith :: forall a s t. NiceConstant a => (a ': s) :-> t Source #
cast :: KnownValue a => (a ': s) :-> (a ': s) Source #
packRaw :: forall a s. NicePackedValue a => (a ': s) :-> (ByteString ': s) Source #
unpackRaw :: forall a s. NiceUnpackedValue a => (ByteString ': s) :-> (Maybe a ': s) Source #
concat :: ConcatOpHs c => (c ': (c ': s)) :-> (c ': s) Source #
slice :: (SliceOpHs c, KnownValue c) => (Natural ': (Natural ': (c ': s))) :-> (Maybe c ': s) Source #
ediv :: EDivOpHs n m => (n ': (m ': s)) :-> (Maybe (EDivOpResHs n m, EModOpResHs n m) ': s) Source #
abs :: UnaryArithOpHs Abs n => (n ': s) :-> (UnaryArithResHs Abs n ': s) Source #
neg :: UnaryArithOpHs Neg n => (n ': s) :-> (UnaryArithResHs Neg n ': s) Source #
not :: UnaryArithOpHs Not n => (n ': s) :-> (UnaryArithResHs Not n ': s) Source #
eq0 :: UnaryArithOpHs Eq' n => (n ': s) :-> (UnaryArithResHs Eq' n ': s) Source #
neq0 :: UnaryArithOpHs Neq n => (n ': s) :-> (UnaryArithResHs Neq n ': s) Source #
lt0 :: UnaryArithOpHs Lt n => (n ': s) :-> (UnaryArithResHs Lt n ': s) Source #
gt0 :: UnaryArithOpHs Gt n => (n ': s) :-> (UnaryArithResHs Gt n ': s) Source #
le0 :: UnaryArithOpHs Le n => (n ': s) :-> (UnaryArithResHs Le n ': s) Source #
ge0 :: UnaryArithOpHs Ge n => (n ': s) :-> (UnaryArithResHs Ge n ': s) Source #
self :: forall p s. (NiceParameterFull p, ForbidExplicitDefaultEntrypoint p) => s :-> (ContractRef p ': s) Source #
Get a reference to the current contract.
Note that, similar to CONTRACT instruction, in Michelson SELF instruction
can accept an entrypoint as field annotation, and without annotation specified
it creates a contract value which calls the default entrypoint.
This particular function carries the behaviour of SELF before introduction
of lightweight entrypoints feature.
Thus the contract must not have explicit "default" entrypoint for this to
work.
If you are going to call a specific entrypoint of the contract, see selfCalling.
selfCalling :: forall p mname s. NiceParameterFull p => EntrypointRef mname -> s :-> (ContractRef (GetEntrypointArgCustom p mname) ': s) Source #
Make a reference to the current contract, maybe a specific entrypoint.
Note that, since information about parameter of the current contract is not
carried around, in this function you need to specify parameter type p
explicitly.
contract :: forall p addr s. (NiceParameterFull p, ForbidExplicitDefaultEntrypoint p, ToTAddress_ p addr) => (addr ': s) :-> (Maybe (ContractRef p) ': s) Source #
Get a reference to a contract by its address.
This instruction carries the behaviour of CONTRACT before introduction
of lightweight entrypoints feature.
The contract must not have explicit "default" entrypoint for this to work.
If you are going to call a specific entrypoint of the contract, see contractCalling.
contractCalling :: forall cp epRef epArg addr s. (HasEntrypointArg cp epRef epArg, ToTAddress_ cp addr) => epRef -> (addr ': s) :-> (Maybe (ContractRef epArg) ': s) Source #
Make a reference to a contract, maybe a specific entrypoint.
When calling this function, make sure that parameter type is known.
It's recommended that you supply TAddress with a concrete parameter as the
stack argument.
contractCallingUnsafe :: forall arg s. NiceParameter arg => EpName -> (Address ': s) :-> (Maybe (ContractRef arg) ': s) Source #
Specialized version of contractCalling for the case when you do
not have compile-time evidence of appropriate HasEntrypointArg.
For instance, if you have untyped EpName you can not have this
evidence (the value is only available in runtime).
If you have typed EntrypointRef, use eprName to construct EpName.
runFutureContract :: forall p s. NiceParameter p => (FutureContract p ': s) :-> (Maybe (ContractRef p) ': s) Source #
Version of contract instruction which may accept address with already
specified entrypoint name.
Also you cannot specify entrypoint name here because this could result in conflict.
epAddressToContract :: forall p s. NiceParameter p => (EpAddress ': s) :-> (Maybe (ContractRef p) ': s) Source #
Similar to runFutureContract, works with EpAddress.
Validity of such operation cannot be ensured at compile time.
transferTokens :: forall p s. NiceParameter p => (p ': (Mutez ': (ContractRef p ': s))) :-> (Operation ': s) Source #
createContract :: forall p g s. (NiceStorage g, NiceParameterFull p) => Contract p g -> (Maybe KeyHash ': (Mutez ': (g ': s))) :-> (Operation ': (Address ': s)) Source #
implicitAccount :: (KeyHash ': s) :-> (ContractRef () ': s) Source #
totalVotingPower :: s :-> (Natural ': s) Source #
checkSignature :: BytesLike bs => (PublicKey ': (TSignature bs ': (bs ': s))) :-> (Bool ': s) Source #
pairingCheck :: ([(Bls12381G1, Bls12381G2)] ': s) :-> (Bool ': s) Source #
selfAddress :: s :-> (Address ': s) Source #
framed :: forall s i o. (KnownList i, KnownList o) => (i :-> o) -> (i ++ s) :-> (o ++ s) Source #
Execute given instruction on truncated stack.
This instruction requires you to specify the piece of stack to truncate as type argument.
failingWhenPresent :: forall c k s v st e. (MemOpHs c, k ~ MemOpKeyHs c, NiceConstant e, st ~ (k ': (v ': (c ': s)))) => (forall s0. (k ': s0) :-> (e ': s0)) -> st :-> st Source #
Helper instruction.
Checks whether given key present in the storage and fails if it is. This instruction leaves stack intact.
updateNew :: forall c k s e. (UpdOpHs c, MemOpHs c, k ~ UpdOpKeyHs c, k ~ MemOpKeyHs c, NiceConstant e) => (forall s0. (k ': s0) :-> (e ': s0)) -> (k ': (UpdOpParamsHs c ': (c ': s))) :-> (c ': s) Source #
Like update, but throw an error on attempt to overwrite existing entry.
type family HasNamedVars (s :: [Type]) (vs :: [NamedField]) :: Constraint where ... Source #
Version of HasNamedVar for multiple variables.
>>>type HasContext = HasNamedVars s ["x" := Integer, "f" := Lambda MText MText]
Equations
| HasNamedVars _ '[] = () | |
| HasNamedVars s ((n := ty) ': vs) = (HasNamedVar s n ty, HasNamedVars s vs) |
class HasNamedVar (s :: [Type]) (name :: Symbol) (var :: Type) | s name -> var Source #
Indicates that stack s contains a name :! var or name :? var value.
Minimal complete definition
varPosition
Instances
| (TypeError (StackElemNotFound name) :: Constraint, var ~ NamedVariableNotFound name) => HasNamedVar ('[] :: [Type]) name var Source # | |
Defined in Lorentz.ReferencedByName Methods varPosition :: VarPosition '[] name var | |
| ElemHasNamedVar (ty ': s) name var (VarNamePretty ty == 'VarNamed name) => HasNamedVar (ty ': s) name var Source # | |
Defined in Lorentz.ReferencedByName Methods varPosition :: VarPosition (ty ': s) name var | |
type VarIsUnnamed x = VarName x ~ 'VarUnnamed Source #
Requires type x to be an unnamed variable.
When e.g. dupL sees a polymorphic variable, it can't judge whether
is it a variable we are seeking for or not; VarIsUnnamed helps to
assure the type system that given variable won't be named.
dupLNamed :: forall var name s. HasNamedVar s name var => Label name -> s :-> ((name :! var) ': s) Source #
Version of dupL that leaves a named variable on stack.
dupL :: forall var name s. HasNamedVar s name var => Label name -> s :-> (var ': s) Source #
Take the element with given label on stack and copy it on top.
If there are multiple variables with given label, the one closest to the top of the stack is picked.
dupT :: forall a st. DupT st a st => st :-> (a ': st) Source #
Duplicate an element of stack referring it by type.
If stack contains multiple entries of this type, compile error is raised.
dipT :: forall a inp dinp dout out. DipT inp a inp dinp dout out => (dinp :-> dout) -> inp :-> out Source #
Dip repeatedly until element of the given type is on top of the stack.
If stack contains multiple entries of this type, compile error is raised.
dropT :: forall a inp dinp dout out. (DipT inp a inp dinp dout out, dinp ~ (a ': dout)) => inp :-> out Source #
Remove element with the given type from the stack.
Documentation for custom errors.
Mentions that entrypoint throws given error.
Constructors
| DThrows :: ErrorHasDoc e => Proxy e -> DThrows |
Instances
| Eq DThrows Source # | |
| DocItem DThrows Source # | |
Defined in Lorentz.Errors Associated Types type DocItemPlacement DThrows :: DocItemPlacementKind # type DocItemReferenced DThrows :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DThrows -> DocItemRef (DocItemPlacement DThrows) (DocItemReferenced DThrows) # docItemToMarkdown :: HeaderLevel -> DThrows -> Markdown # docItemToToc :: HeaderLevel -> DThrows -> Markdown # docItemDependencies :: DThrows -> [SomeDocDefinitionItem] # docItemsOrder :: [DThrows] -> [DThrows] # | |
| type DocItemPlacement DThrows Source # | |
Defined in Lorentz.Errors | |
| type DocItemReferenced DThrows Source # | |
Defined in Lorentz.Errors | |
Mentions that contract uses given error.
Constructors
| DError :: ErrorHasDoc e => Proxy e -> DError |
Instances
| Eq DError Source # | |
| Ord DError Source # | |
| DocItem DError Source # | |
Defined in Lorentz.Errors Associated Types type DocItemPlacement DError :: DocItemPlacementKind # type DocItemReferenced DError :: DocItemReferencedKind # Methods docItemPos :: Natural # docItemSectionName :: Maybe Text # docItemSectionDescription :: Maybe Markdown # docItemSectionNameStyle :: DocSectionNameStyle # docItemRef :: DError -> DocItemRef (DocItemPlacement DError) (DocItemReferenced DError) # docItemToMarkdown :: HeaderLevel -> DError -> Markdown # docItemToToc :: HeaderLevel -> DError -> Markdown # docItemDependencies :: DError -> [SomeDocDefinitionItem] # docItemsOrder :: [DError] -> [DError] # | |
| type DocItemPlacement DError Source # | |
Defined in Lorentz.Errors | |
| type DocItemReferenced DError Source # | |
Defined in Lorentz.Errors | |
class (KnownSymbol tag, TypeHasDoc (CustomErrorRep tag), IsError (CustomError tag)) => CustomErrorHasDoc tag where Source #
Minimal complete definition
Methods
customErrDocMdCause :: Markdown Source #
What should happen for this error to be raised.
customErrDocMdCauseInEntrypoint :: Markdown Source #
Brief version of customErrDocMdCause.
This will appear along with the error when mentioned in entrypoint description.
By default, the first sentence of the full description is used.
customErrClass :: ErrorClass Source #
Error class.
By default this returns "unknown error" class; though you should provide explicit implementation in order to avoid a warning.
customErrArgumentSemantics :: Maybe Markdown Source #
Clarification of error argument meaning.
Provide when it's not obvious, e.g. argument is not named with :!.
NOTE: This should not be an entire sentence, rather just the semantic backbone.
Bad:
* Error argument stands for the previous value of approval.
Good:
* the previous value of approval
* pair, first argument of which is one thing, and the second is another
Instances
| CustomErrorHasDoc "emptySupplied" Source # | |
Defined in Lorentz.Empty | |
| CustomErrorHasDoc "senderIsNotAdmin" Source # | |
| CustomErrorHasDoc "uparamArgumentUnpackFailed" Source # | |
Defined in Lorentz.UParam | |
| CustomErrorHasDoc "uparamNoSuchEntrypoint" Source # | |
Defined in Lorentz.UParam | |
data ErrorClass Source #
Error class on how the error should be handled by the client.
Constructors
| ErrClassActionException | Normal expected error. Examples: "insufficient balance", "wallet does not exist". |
| ErrClassBadArgument | Invalid argument passed to entrypoint.
Examples: your entrypoint accepts an enum represented as |
| ErrClassContractInternal | Unexpected error. Most likely it means that there is a bug in the contract or the contract has been deployed incorrectly. |
| ErrClassUnknown | It's possible to leave error class unspecified. |
Instances
| Read ErrorClass Source # | |
Defined in Lorentz.Errors Methods readsPrec :: Int -> ReadS ErrorClass # readList :: ReadS [ErrorClass] # readPrec :: ReadPrec ErrorClass # readListPrec :: ReadPrec [ErrorClass] # | |
| Buildable ErrorClass Source # | |
Defined in Lorentz.Errors Methods build :: ErrorClass -> Builder # | |
| Lift ErrorClass Source # | |
Defined in Lorentz.Errors | |
type MustHaveErrorArg errorTag expectedArgRep = (TypeErrorUnless (CustomErrorRep errorTag == expectedArgRep) ((('Text "Error argument type is " :<>: 'ShowType expectedArgRep) :<>: 'Text " but given error requires argument of type ") :<>: 'ShowType (CustomErrorRep errorTag)), CustomErrorRep errorTag ~ expectedArgRep) Source #
class IsCustomErrorArgRep a where Source #
Typeclass implements various method that work with CustomErrorArgRep.
Methods
verifyErrorTag :: MText -> a -> Either Text a Source #
customErrorRepDocDeps :: [SomeDocDefinitionItem] Source #
customErrorHaskellRep :: (KnownSymbol tag, CustomErrorHasDoc tag) => Proxy tag -> Markdown Source #
Instances
| IsCustomErrorArgRep MText Source # | |
Defined in Lorentz.Errors Methods verifyErrorTag :: MText -> MText -> Either Text MText Source # customErrorRepDocDeps :: [SomeDocDefinitionItem] Source # customErrorHaskellRep :: forall (tag :: Symbol). (KnownSymbol tag, CustomErrorHasDoc tag) => Proxy tag -> Markdown Source # | |
| TypeHasDoc errArg => IsCustomErrorArgRep (MText, errArg) Source # | |
Defined in Lorentz.Errors Methods verifyErrorTag :: MText -> (MText, errArg) -> Either Text (MText, errArg) Source # customErrorRepDocDeps :: [SomeDocDefinitionItem] Source # customErrorHaskellRep :: forall (tag :: Symbol). (KnownSymbol tag, CustomErrorHasDoc tag) => Proxy tag -> Markdown Source # | |
type CustomErrorRep tag = CustomErrorArgRep (ErrorArg tag) Source #
How CustomError is actually represented in Michelson.
data UnitErrorArg Source #
To be used as ErrorArg instances. This is equivalent to using
() but using UnitErrorArg is preferred since () behavior could
be changed in the future.
data NoErrorArg Source #
To be used as ErrorArg instance when failing with just
a string instead of pair string x
data CustomError (tag :: Symbol) Source #
Material custom error.
Use this in pattern matches against error (e.g. in tests).
Constructors
| CustomError | |
Fields
| |
Instances
type family ErrorArg (tag :: Symbol) :: Type Source #
Declares a custom error, defining error name - error argument relation.
If your error is supposed to carry no argument, then provide ().
Note that this relation is defined globally rather than on per-contract basis, so define errors accordingly. If your error has argument specific to your contract, call it such that error name reflects its belonging to this contract.
This is the basic [error format].
Instances
| type ErrorArg "emptySupplied" Source # | Someone constructed |
Defined in Lorentz.Empty | |
| type ErrorArg "senderIsNotAdmin" Source # | Contract initiator should be contract admin in order to perform this operation. |
Defined in Lorentz.Errors.Common | |
| type ErrorArg "uparamArgumentUnpackFailed" Source # | |
Defined in Lorentz.UParam | |
| type ErrorArg "uparamNoSuchEntrypoint" Source # | |
Defined in Lorentz.UParam | |
Type wrapper for an IsError.
data UnspecifiedError Source #
Use this type as replacement for () when you really want to leave
error cause unspecified.
Constructors
| UnspecifiedError |
Instances
class Typeable e => ErrorHasDoc (e :: Type) where Source #
Minimal complete definition
errorDocName, errorDocMdCause, errorDocHaskellRep, errorDocDependencies
Associated Types
type ErrorRequirements e :: Constraint Source #
Constraints which we require in a particular instance. You are not oblidged to often instantiate this correctly, it is only useful for some utilities.
type ErrorRequirements _ = ()
Methods
errorDocName :: Text Source #
Name of error as it appears in the corresponding section title.
errorDocMdCause :: Markdown Source #
What should happen for this error to be raised.
errorDocMdCauseInEntrypoint :: Markdown Source #
Brief version of errorDocMdCause.
This will appear along with the error when mentioned in entrypoint description. By default, the first sentence of the full description is used.
errorDocHaskellRep :: Markdown Source #
How this error is represented in Haskell.
errorDocClass :: ErrorClass Source #
Error class.
errorDocDependencies :: [SomeDocDefinitionItem] Source #
Which definitions documentation for this error mentions.
errorDocRequirements :: Dict (ErrorRequirements e) Source #
Captured constraints which we require in a particular instance.
This is a way to encode a bidirectional instance in the nowaday Haskell,
for class MyConstraint => ErrorHasDoc MyType instance it lets deducing
MyConstraint by ErrorHasDoc MyType.
You are not oblidged to always instantiate, it is only useful for some utilities which otherwise would not compile.
default errorDocRequirements :: ErrorRequirements e => Dict (ErrorRequirements e) Source #
Instances
class (Typeable e, ErrorHasDoc e) => IsError e where Source #
Haskell type representing error.
Methods
errorToVal :: e -> (forall t. ErrorScope t => Value t -> r) -> r Source #
Converts a Haskell error into Value representation.
errorFromVal :: KnownT t => Value t -> Either Text e Source #
Converts a Value into Haskell error.
Instances
| (TypeError ('Text "Use representative error messages") :: Constraint) => IsError () Source # | |
Defined in Lorentz.Errors Methods errorToVal :: () -> (forall (t :: T). ErrorScope t => Value t -> r) -> r Source # errorFromVal :: forall (t :: T). KnownT t => Value t -> Either Text () Source # | |
| IsError MText Source # | Use this for internal errors only. Normal error scenarios should use the mechanism of custom errors, see below. |
Defined in Lorentz.Errors Methods errorToVal :: MText -> (forall (t :: T). ErrorScope t => Value t -> r) -> r Source # errorFromVal :: forall (t :: T). KnownT t => Value t -> Either Text MText Source # | |
| IsError UnspecifiedError Source # | |
Defined in Lorentz.Errors Methods errorToVal :: UnspecifiedError -> (forall (t :: T). ErrorScope t => Value t -> r) -> r Source # errorFromVal :: forall (t :: T). KnownT t => Value t -> Either Text UnspecifiedError Source # | |
| (CustomErrorHasDoc tag, KnownError (CustomErrorRep tag), IsoValue (CustomErrorRep tag), IsCustomErrorArgRep (CustomErrorRep tag)) => IsError (CustomError tag) Source # | |
Defined in Lorentz.Errors Methods errorToVal :: CustomError tag -> (forall (t :: T). ErrorScope t => Value t -> r) -> r Source # errorFromVal :: forall (t :: T). KnownT t => Value t -> Either Text (CustomError tag) Source # | |
| (Typeable r, NiceConstant r, ErrorHasDoc (VoidResult r)) => IsError (VoidResult r) Source # | |
Defined in Lorentz.Macro Methods errorToVal :: VoidResult r -> (forall (t :: T). ErrorScope t => Value t -> r0) -> r0 Source # errorFromVal :: forall (t :: T). KnownT t => Value t -> Either Text (VoidResult r) Source # | |
| (Typeable arg, IsError (CustomError tag), TypeErrorUnless (arg == ()) notVoidError, arg ~ ErrorArg tag, notVoidError ~ ('Text "This error requires argument of type " :<>: 'ShowType (ErrorArg tag))) => IsError (arg -> CustomError tag) Source # | If |
Defined in Lorentz.Errors Methods errorToVal :: (arg -> CustomError tag) -> (forall (t :: T). ErrorScope t => Value t -> r) -> r Source # errorFromVal :: forall (t :: T). KnownT t => Value t -> Either Text (arg -> CustomError tag) Source # | |
type ErrorScope t = (Typeable t, ConstantScope t) Source #
isoErrorToVal :: (KnownError e, IsoValue e) => e -> (forall t. ErrorScope t => Value t -> r) -> r Source #
Implementation of errorToVal via IsoValue.
isoErrorFromVal :: (Typeable t, Typeable (ToT e), IsoValue e) => Value t -> Either Text e Source #
Implementation of errorFromVal via IsoValue.
failUnexpected :: MText -> s :-> t Source #
Fail, providing a reference to the place in the code where this function is called.
Like error in Haskell code, this instruction is for internal errors only.
errorTagToMText :: Label tag -> MText Source #
Demote error tag to term level.
errorTagToText :: forall tag. KnownSymbol tag => Text Source #
failCustom :: forall tag err s any. (MustHaveErrorArg tag (MText, err), CustomErrorHasDoc tag, KnownError err) => Label tag -> (err ': s) :-> any Source #
Fail with given custom error.
failCustomNoArg :: forall tag s any. (MustHaveErrorArg tag MText, CustomErrorHasDoc tag) => Label tag -> s :-> any Source #
Fail with given custom error.
failCustom_ :: forall tag s any. (MustHaveErrorArg tag (MText, ()), CustomErrorHasDoc tag) => Label tag -> s :-> any Source #
Specialization of failCustom for unit-arg errors.
isInternalErrorClass :: ErrorClass -> Bool Source #
Whether given error class is about internal errors.
Internal errors are not enlisted on per-entrypoint basis, only once for the entire contract.
typeDocMdDescriptionReferToError :: forall e. IsError e => Markdown Source #
Implementation of typeDocMdDescription (of TypeHasDoc typeclass)
for Haskell types which sole purpose is to be error.
entrypointDoc :: QuasiQuoter Source #
QuasiQuote that helps generating ParameterHasEntrypoints instance.
Usage:
[entrypointDoc| Parameter <parameter-type> <optional-root-annotation> |] [entrypointDoc| Parameter plain |] [entrypointDoc| Parameter plain "root"|]
See this tutorial which includes this quasiquote.
errorDoc :: QuasiQuoter Source #
QuasiQuote that helps generating CustomErrorHasDoc instance.
Usage:
[errorDoc| <error-name> <error-type> <error-description> |] [errorDoc| "errorName" exception "Error description" |]
See this tutorial which includes this quasiquote.
typeDoc :: QuasiQuoter Source #
QuasiQuote that helps generating TypeHasDoc instance.
Usage:
[typeDoc| <type> <description> |] [typeDoc| Storage "This is storage description" |]
See this tutorial which includes this quasiquote.
newtype VoidResult r Source #
Newtype over void result type used in tests to distinguish successful void result from other errors.
Usage example: lExpectFailWith (== VoidResult roleMaster)`
This error is special - it can contain arguments of different types depending on entrypoint which raises it.
Constructors
| VoidResult | |
Fields
| |
Instances
data Void_ (a :: Type) (b :: Type) Source #
void type synonym as described in A1.
Constructors
| Void_ | |
Fields
| |
Instances
data View (a :: Type) (r :: Type) Source #
view type synonym as described in A1.
Constructors
| View | |
Fields
| |
Instances
class UpdateN (n :: Peano) (s :: [Type]) (a :: Type) (b :: Type) mid tail where Source #
Methods
updateNImpl :: ('[a, b] :-> '[b]) -> (a ': s) :-> s Source #
Instances
| s ~ (x ': (b ': tail)) => UpdateN ('S ('S 'Z)) s a b (mid :: k) (tail :: [Type]) Source # | |
Defined in Lorentz.Macro Methods updateNImpl :: ('[a, b] :-> '[b]) -> (a ': s) :-> s Source # | |
| s ~ (b ': tail) => UpdateN ('S 'Z) s a b (mid :: k) (tail :: [Type]) Source # | |
Defined in Lorentz.Macro Methods updateNImpl :: ('[a, b] :-> '[b]) -> (a ': s) :-> s Source # | |
| ConstraintUpdateNLorentz ('S ('S n)) s a b mid tail => UpdateN ('S ('S ('S n))) s a b (mid :: [Type]) (tail :: [Type]) Source # | |
Defined in Lorentz.Macro Methods updateNImpl :: ('[a, b] :-> '[b]) -> (a ': s) :-> s Source # | |
type ConstraintUpdateNLorentz (n :: Peano) (s :: [Type]) (a :: Type) (b :: Type) (mid :: [Type]) (tail :: [Type]) = (UpdateNConstraint' T n (ToTs s) (ToT a) (ToT b) (ToTs mid) (ToTs tail), UpdateNConstraint' Type n s a b mid tail) Source #
Constraint for updateN that combines kind-agnostic constraint for Lorentz (Haskell) types and for our typed Michelson.
class ReplaceN (n :: Peano) (s :: [Type]) (a :: Type) mid tail where Source #
Methods
replaceNImpl :: (a ': s) :-> s Source #
Instances
| s ~ (a ': xs) => ReplaceN ('S 'Z) s a (mid :: k1) (tail :: k2) Source # | |
Defined in Lorentz.Macro Methods replaceNImpl :: (a ': s) :-> s Source # | |
| ConstraintReplaceNLorentz ('S n) s a mid tail => ReplaceN ('S ('S n)) s a (mid :: [Type]) (tail :: [Type]) Source # | |
Defined in Lorentz.Macro Methods replaceNImpl :: (a ': s) :-> s Source # | |
type ConstraintReplaceNLorentz (n :: Peano) (s :: [Type]) (a :: Type) (mid :: [Type]) (tail :: [Type]) = (ReplaceNConstraint' T n (ToTs s) (ToT a) (ToTs mid) (ToTs tail), ReplaceNConstraint' Type n s a mid tail) Source #
Constraint for replaceN that combines kind-agnostic constraint for Lorentz (Haskell) types and for our typed Michelson.
deleteMap :: forall k v s. (MapInstrs map, NiceComparable k, KnownValue v) => (k ': (map k v ': s)) :-> (map k v ': s) Source #
Delete element from the map.
mapInsert :: (MapInstrs map, NiceComparable k) => (k ': (v ': (map k v ': s))) :-> (map k v ': s) Source #
Insert given element into map.
mapInsertNew :: (MapInstrs map, NiceComparable k, NiceConstant e) => (forall s0. (k ': s0) :-> (e ': s0)) -> (k ': (v ': (map k v ': s))) :-> (map k v ': s) Source #
Insert given element into map, ensuring that it does not overwrite any existing entry.
As first argument accepts container name (for error message).
Warning: fail_ remains in code
Analog of the FAIL macro in Michelson. Its usage is discouraged because it doesn't carry any information about failure.
assertNeq0 :: (IfCmp0Constraints a Neq, IsError err) => err -> (a ': s) :-> s Source #
dropX :: forall (n :: Nat) a inp out s s'. (ConstraintDIPNLorentz (ToPeano n) inp out s s', s ~ (a ': s')) => inp :-> out Source #
Custom Lorentz macro that drops element with given index (starting from 0) from the stack.
cloneX :: forall (n :: Nat) a s. CloneX (ToPeano n) a s => (a ': s) :-> CloneXT (ToPeano n) a s Source #
Duplicate the top of the stack n times.
For example, `cloneX @3` has type `a : s :-> a : a : a : a : s`.
duupX :: forall (n :: Nat) s s' a. ConstraintDUPNLorentz (ToPeano n) s s' a => s :-> (a ': s) Source #
DUU+P macro. For example, `duupX @3` is DUUUP, it puts
the 3-rd (starting from 1) element to the top of the stack.
Note that DUU+P has since been added as the DUP n instruction and so this
macro is defined simply as follows:
duupX = dupN @n
framedN :: forall n nNat s i i' o o'. (nNat ~ ToPeano n, i' ~ Take nNat i, s ~ Drop nNat i, i ~ (i' ++ s), o ~ (o' ++ s), KnownList i', KnownList o') => (i' :-> o') -> i :-> o Source #
Version of framed which accepts number of elements on input stack
which should be preserved.
You can treat this macro as calling a Michelson function with given number of arguments.
carN :: forall (n :: Nat) (pair :: Type) (s :: [Type]). ConstraintPairGetLorentz ((2 * n) + 1) pair => (pair ': s) :-> (PairGetHs (ToPeano ((2 * n) + 1)) pair ': s) Source #
cdrN :: forall (n :: Nat) (pair :: Type) (s :: [Type]). ConstraintPairGetLorentz (2 * n) pair => (pair ': s) :-> (PairGetHs (ToPeano (2 * n)) pair ': s) Source #
mapCdr :: ((b ': ((a, b) ': s)) :-> (b1 ': ((a, b) ': s))) -> ((a, b) ': s) :-> ((a, b1) ': s) Source #
setInsert :: NiceComparable e => (e ': (Set e ': s)) :-> (Set e ': s) Source #
Insert given element into set.
This is a separate function from updateMap because stacks they operate with
differ in length.
setInsertNew :: (NiceComparable e, NiceConstant err) => (forall s0. (e ': s0) :-> (err ': s0)) -> (e ': (Set e ': s)) :-> (Set e ': s) Source #
Insert given element into set, ensuring that it does not overwrite any existing entry.
As first argument accepts container name.
setDelete :: NiceComparable e => (e ': (Set e ': s)) :-> (Set e ': s) Source #
Delete given element from the set.
replaceN :: forall (n :: Nat) a (s :: [Type]) (s1 :: [Type]) (tail :: [Type]). (ConstraintReplaceNLorentz (ToPeano (n - 1)) s a s1 tail, ReplaceN (ToPeano n) s a s1 tail) => (a ': s) :-> s Source #
Replace nth element (0-indexed) with the one on the top of the stack.
For example, `replaceN 3` replaces the 3rd element with the 0th one.
`replaceN 0` is not a valid operation (and it is not implemented).
`replaceN 1` is equivalent to `swap # drop` (and is the only one implemented
like this).
In all other cases `replaceN n` will drop the nth element (`dipN n drop`)
and then put the 0th one in its place (`dug (n-1)`).
updateN :: forall (n :: Nat) a b (s :: [Type]) (mid :: [Type]) (tail :: [Type]). (ConstraintUpdateNLorentz (ToPeano (n - 1)) s a b mid tail, UpdateN (ToPeano n) s a b mid tail) => ('[a, b] :-> '[b]) -> (a ': s) :-> s Source #
Replaces the nth element (0-indexed) with the result of the given "updating"
instruction (binary with the return type equal to the second argument) applied
to the 0th element and the nth element itself.
For example, `updateN 3 cons` replaces the 3rd element with the result of
0 instr` is not a valid operation (and it is not implemented).
`updateN cons applied to the topmost element and the 3rd one.
`updateN 1 instr` is equivalent to 2 instr` is equivalent to `swap # dip instr` (and so is implemented).
In all other cases `updateN instr (and so is implemented).
`updateN n instr` will put the topmost element right above
the nth one (`dug (n-1)`) and then apply the function to them in place
(`dipN @(n-1) instr`).
buildViewTuple :: (WellTypedIsoValue r, TupleF a) => View a r -> Builder Source #
mkView :: ToContractRef r contract => a -> contract -> View a r Source #
Polymorphic version of View constructor.
unwrapView :: (View a r ': s) :-> ((a, ContractRef r) ': s) Source #
view_ :: NiceParameter r => (forall s0. (a ': (storage ': s0)) :-> (r ': s0)) -> (View a r ': (storage ': s)) :-> ((List Operation, storage) ': s) Source #
void_ :: forall a b s s' anything. (IsError (VoidResult b), NiceConstant b) => ((a ': s) :-> (b ': s')) -> (Void_ a b ': s) :-> anything Source #
pushContractRef :: NiceParameter arg => (forall s0. (FutureContract arg ': s) :-> s0) -> ContractRef arg -> s :-> (ContractRef arg ': s) Source #
Push a value of contract type.
Doing this via push instruction is not possible, so we need to perform
extra actions here.
Aside from contract value itself you will need to specify which error to
throw in case this value is not valid.
dupTop2 :: forall (a :: Type) (b :: Type) (s :: [Type]). (a ': (b ': s)) :-> (a ': (b ': (a ': (b ': s)))) Source #
Duplicate two topmost items on top of the stack.
fromOption :: NiceConstant a => a -> (Maybe a ': s) :-> (a ': s) Source #
non :: (NiceConstant a, NiceComparable a) => a -> (a ': s) :-> (Maybe a ': s) Source #
Retain the value if it is not equal to the given one.
>>>non 0 -$ 5Just 5>>>non 0 -$ 0Nothing
non' :: NiceConstant a => Lambda a Bool -> (a ': s) :-> (Maybe a ': s) Source #
Version of non with a custom predicate.
>>>non' eq0 -$ 5Just 5>>>non' eq0 -$ 0Nothing
type UParamLinearized p = GUParamLinearized (Rep p) Source #
Entry points template derived from given ADT sum.
type UParamLinearize p = (Generic p, GUParamLinearize (Rep p)) Source #
Constraint required by uparamFromAdt.
class CaseUParam (entries :: [EntrypointKind]) Source #
Make up a "case" over entry points.
Minimal complete definition
caseUParamUnsafe
Instances
| CaseUParam ('[] :: [EntrypointKind]) Source # | |
Defined in Lorentz.UParam Methods caseUParamUnsafe :: forall (inp :: [Type]) (out :: [Type]). Rec (CaseClauseU inp out) '[] -> UParamFallback inp out -> (UParam '[] ': inp) :-> out | |
| (KnownSymbol name, CaseUParam entries, NiceUnpackedValue arg) => CaseUParam ((name ?: arg) ': entries) Source # | |
Defined in Lorentz.UParam Methods caseUParamUnsafe :: forall (inp :: [Type]) (out :: [Type]). Rec (CaseClauseU inp out) ((name ?: arg) ': entries) -> UParamFallback inp out -> (UParam ((name ?: arg) ': entries) ': inp) :-> out | |
type UParamFallback inp out = ((MText, ByteString) ': inp) :-> out Source #
An action invoked when user-provided entrypoint is not found.
type EntrypointsImpl inp out entries = Rec (CaseClauseU inp out) entries Source #
Implementations of some entry points.
Note that this thing inherits properties of Rec, e.g. you can
Data.Vinyl.Core.rappend implementations for two entrypoint sets
when assembling scattered parts of a contract.
data EntrypointLookupError Source #
Constructors
| NoSuchEntrypoint MText | |
| ArgumentUnpackFailed |
Instances
class UnpackUParam (c :: Type -> Constraint) entries where Source #
This class is needed to implement unpackUParam.
Methods
unpackUParam :: UParam entries -> Either EntrypointLookupError (MText, ConstrainedSome c) Source #
Turn UParam into a Haskell value.
Since we don't know its type in compile time, we have to erase it using
ConstrainedSome. The user of this function can require arbitrary
constraint to hold (depending on how they want to use the result).
Instances
| UnpackUParam c ('[] :: [EntrypointKind]) Source # | |
Defined in Lorentz.UParam Methods unpackUParam :: UParam '[] -> Either EntrypointLookupError (MText, ConstrainedSome c) Source # | |
| (KnownSymbol name, UnpackUParam c entries, NiceUnpackedValue arg, c arg) => UnpackUParam c ((name ?: arg) ': entries) Source # | |
Defined in Lorentz.UParam Methods unpackUParam :: UParam ((name ?: arg) ': entries) -> Either EntrypointLookupError (MText, ConstrainedSome c) Source # | |
data ConstrainedSome (c :: Type -> Constraint) where Source #
This type can store any value that satisfies a certain constraint.
Constructors
| ConstrainedSome :: c a => a -> ConstrainedSome c |
Instances
| Show (ConstrainedSome Show) Source # | |
Defined in Lorentz.UParam | |
| Buildable (ConstrainedSome Buildable) Source # | |
Defined in Lorentz.UParam Methods build :: ConstrainedSome Buildable -> Builder # | |
type family RequireUniqueEntrypoints (entries :: [EntrypointKind]) :: Constraint where ... Source #
Ensure that given entry points do no contain duplicated names.
Equations
| RequireUniqueEntrypoints entries = RequireAllUnique "entrypoint" (Eval (Map Fst entries)) |
type family LookupEntrypoint (name :: Symbol) (entries :: [EntrypointKind]) :: Type where ... Source #
Get type of entrypoint argument by its name.
Equations
| LookupEntrypoint name ('(name, a) ': _) = a | |
| LookupEntrypoint name (_ ': entries) = LookupEntrypoint name entries | |
| LookupEntrypoint name '[] = TypeError (('Text "Entry point " :<>: 'ShowType name) :<>: 'Text " in not in the entry points list") |
type UParam_ = UParam SomeInterface Source #
Homomorphic version of UParam, forgets the exact interface.
type SomeInterface = '['("SomeEntrypoints", Void)] Source #
Pseudo value for UParam type variable.
newtype UParam (entries :: [EntrypointKind]) Source #
Encapsulates parameter for one of entry points. It keeps entrypoint name and corresponding argument serialized.
In Haskell world, we keep an invariant of that contained value relates
to one of entry points from entries list.
Constructors
| UParamUnsafe (MText, ByteString) |
Instances
type (?:) (n :: Symbol) (a :: k) = '(n, a) Source #
A convenient alias for type-level name-something pair.
type EntrypointKind = (Symbol, Type) Source #
An entrypoint is described by two types: its name and type of argument.
mkUParam :: (NicePackedValue a, LookupEntrypoint name entries ~ a, RequireUniqueEntrypoints entries) => Label name -> a -> UParam entries Source #
Construct a UParam safely.
unwrapUParam :: (UParam entries ': s) :-> ((MText, ByteString) ': s) Source #
Helper instruction which extracts content of UParam.
uparamFallbackFail :: UParamFallback inp out Source #
Default implementation for UParamFallback, simply reports an error.
caseUParam :: (CaseUParam entries, RequireUniqueEntrypoints entries) => Rec (CaseClauseU inp out) entries -> UParamFallback inp out -> (UParam entries ': inp) :-> out Source #
Pattern-match on given UParam entries.
You have to provide all case branches and a fallback action on case when entrypoint is not found.
caseUParamT :: forall entries inp out clauses. (clauses ~ Rec (CaseClauseU inp out) entries, RecFromTuple clauses, CaseUParam entries) => IsoRecTuple clauses -> UParamFallback inp out -> (UParam entries ': inp) :-> out Source #
Like caseUParam, but accepts a tuple of clauses, not a Rec.
uparamFromAdt :: UParamLinearize up => up -> UParam (UParamLinearized up) Source #
Make up UParam from ADT sum.
Entry points template will consist of
(constructorName, constructorFieldType) pairs.
Each constructor is expected to have exactly one field.
pbsUParam :: forall ctorName. KnownSymbol ctorName => ParamBuildingStep Source #
Note that calling given entrypoints involves constructing UParam.
data Condition arg argl argr outb out where Source #
Predicate for if ... then .. else ... construction,
defines a kind of operation applied to the top elements of the current stack.
Type arguments mean:
1. Input of if
2. Left branch input
3. Right branch input
4. Output of branches
5. Output of if
Constructors
| Holds :: Condition (Bool ': s) s s o o | |
| IsSome :: Condition (Maybe a ': s) (a ': s) s o o | |
| IsNone :: Condition (Maybe a ': s) s (a ': s) o o | |
| IsLeft :: Condition (Either l r ': s) (l ': s) (r ': s) o o | |
| IsRight :: Condition (Either l r ': s) (r ': s) (l ': s) o o | |
| IsCons :: Condition ([a] ': s) (a ': ([a] ': s)) s o o | |
| IsNil :: Condition ([a] ': s) s (a ': ([a] ': s)) o o | |
| IsZero :: (UnaryArithOpHs Eq' a, UnaryArithResHs Eq' a ~ Bool) => Condition (a ': s) s s o o | |
| IsNotZero :: (UnaryArithOpHs Eq' a, UnaryArithResHs Eq' a ~ Bool) => Condition (a ': s) s s o o | |
| IsEq :: NiceComparable a => Condition (a ': (a ': s)) s s o o | |
| IsNeq :: NiceComparable a => Condition (a ': (a ': s)) s s o o | |
| IsLt :: NiceComparable a => Condition (a ': (a ': s)) s s o o | |
| IsGt :: NiceComparable a => Condition (a ': (a ': s)) s s o o | |
| IsLe :: NiceComparable a => Condition (a ': (a ': s)) s s o o | |
| IsGe :: NiceComparable a => Condition (a ': (a ': s)) s s o o | |
| NamedBinCondition :: Condition (a ': (a ': s)) s s o o -> Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o | Explicitly named binary condition, to ensure proper order of stack arguments. |
| PreserveArgsBinCondition :: (forall st o. Condition (a ': (b ': st)) st st o o) -> Condition (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) s | Provide the compared arguments to |
ifThenElse :: Condition arg argl argr outb out -> (argl :-> outb) -> (argr :-> outb) -> arg :-> out Source #
Defines semantics of if ... then ... else ... construction.
(<.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o infix 4 Source #
Named version of IsLt.
In this and similar operators you provide names of accepted stack operands as a safety measure of that they go in the expected order.
(>.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o infix 4 Source #
Named version of IsGt.
(<=.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o infix 4 Source #
Named version of IsLe.
(>=.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o infix 4 Source #
Named version of IsGe.
(==.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o infix 4 Source #
Named version of IsEq.
(/=.) :: NiceComparable a => Label n1 -> Label n2 -> Condition ((n1 :! a) ': ((n2 :! a) ': s)) s s o o infix 4 Source #
Named version of IsNeq.
keepIfArgs :: (forall st o. Condition (a ': (b ': st)) st st o o) -> Condition (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) (a ': (b ': s)) s Source #
Condition modifier, makes stack operands of binary comparison to be
available within if branches.
type ErrorTagExclusions = HashSet MText Source #
Tags excluded from map.
type ErrorTagMap = Bimap Natural MText Source #
This is a bidirectional map with correspondence between numeric and textual error tags.
gatherErrorTags :: (inp :-> out) -> HashSet MText Source #
Find all textual error tags that are used in typical
FAILWITH patterns within given instruction.
Map them to natural numbers.
addNewErrorTags :: ErrorTagMap -> HashSet MText -> ErrorTagMap Source #
Add more error tags to an existing ErrorTagMap. It is useful when
your contract consists of multiple parts (e. g. in case of contract
upgrade), you have existing map for some part and want to add tags
from another part to it.
You can pass empty map as existing one if you just want to build
ErrorTagMap from a set of textual tags. See buildErrorTagMap.
buildErrorTagMap :: HashSet MText -> ErrorTagMap Source #
Build ErrorTagMap from a set of textual tags.
excludeErrorTags :: HasCallStack => ErrorTagExclusions -> ErrorTagMap -> ErrorTagMap Source #
Remove some error tags from map. This way you say to remain these string tags intact, while others will be converted to numbers when this map is applied.
Note that later you have to apply this map using
applyErrorTagMapWithExclusions, otherwise an error would be raised.
applyErrorTagMap :: HasCallStack => ErrorTagMap -> (inp :-> out) -> inp :-> out Source #
For each typical FAILWITH that uses a string to represent error
tag this function changes error tag to be a number using the
supplied conversion map.
It assumes that supplied map contains all such strings
(and will error out if it does not).
It will always be the case if you gather all error tags using
gatherErrorTags and build ErrorTagMap from them using addNewErrorTags.
applyErrorTagMapWithExclusions :: HasCallStack => ErrorTagMap -> ErrorTagExclusions -> (inp :-> out) -> inp :-> out Source #
Similar to applyErrorTagMap, but for case when you have excluded some
tags from map via excludeErrorTags.
Needed, because both excludeErrorTags and this function do not tolerate
unknown errors in contract code (for your safety).
useNumericErrors :: HasCallStack => (inp :-> out) -> (inp :-> out, ErrorTagMap) Source #
This function implements the simplest scenario of using this module's functionality: 1. Gather all error tags from a single instruction. 2. Turn them into error conversion map. 3. Apply this conversion.
errorFromValNumeric :: (KnownT t, IsError e) => ErrorTagMap -> Value t -> Either Text e Source #
If you apply numeric error representation in your contract, errorFromVal
will stop working because it doesn't know about this
transformation.
This function takes this transformation into account.
If a number is used as a tag, but it is not found in the passed
map, we conservatively preserve that number (because this whole
approach is rather a heuristic).
errorToValNumeric :: IsError e => ErrorTagMap -> e -> (forall t. ErrorScope t => Value t -> r) -> r Source #
If you apply numeric error representation in your contract, errorToVal
will stop working because it doesn't know about this
transformation.
This function takes this transformation into account.
If a string is used as a tag, but it is not found in the passed
map, we conservatively preserve that string (because this whole
approach is rather a heuristic).
data NumericErrorWrapper (numTag :: Nat) (err :: Type) Source #
Some error with a numeric tag attached.
Instances
| (ErrorHasDoc err, KnownNat numTag, ErrorHasNumericDoc err) => ErrorHasDoc (NumericErrorWrapper numTag err) Source # | |
Defined in Lorentz.Errors.Numeric.Doc Associated Types type ErrorRequirements (NumericErrorWrapper numTag err) Source # Methods errorDocName :: Text Source # errorDocMdCause :: Markdown Source # errorDocMdCauseInEntrypoint :: Markdown Source # errorDocHaskellRep :: Markdown Source # errorDocClass :: ErrorClass Source # errorDocDependencies :: [SomeDocDefinitionItem] Source # errorDocRequirements :: Dict (ErrorRequirements (NumericErrorWrapper numTag err)) Source # | |
| type ErrorRequirements (NumericErrorWrapper numTag err) Source # | |
Defined in Lorentz.Errors.Numeric.Doc | |
data NumericErrorDocHandler Source #
Handler which changes documentation for one particular error type.
data NumericErrorDocHandlerError Source #
Errors for NumericErrorDocHandler
data DDescribeErrorTagMap Source #
Adds a section which explains error tag mapping.
Constructors
| DDescribeErrorTagMap | |
Fields
| |
Instances
applyErrorTagToErrorsDoc :: HasCallStack => ErrorTagMap -> (inp :-> out) -> inp :-> out Source #
Modify documentation generated for given code so that all CustomError
mention not their textual error tag rather respective numeric one from the
given map.
If some documented error is not present in the map, it remains unmodified.
This function may fail with error if contract uses some uncommon errors,
see applyErrorTagToErrorsDocWith for details.
applyErrorTagToErrorsDocWith :: HasCallStack => [NumericErrorDocHandler] -> ErrorTagMap -> (inp :-> out) -> inp :-> out Source #
Extended version of applyErrorTagToErrorsDoc which accepts error
handlers.
In most cases that function should be enough for your purposes, but it uses a fixed set of base handlers which may be not enough in case when you define your own errors. In this case define and pass all the necessary handlers to this function.
It fails with error if some of the errors used in the contract cannot be
handled with given handlers.
customErrorDocHandler :: NumericErrorDocHandler Source #
Handler for all CustomErrors.
voidResultDocHandler :: NumericErrorDocHandler Source #
Handler for VoidResult.
baseErrorDocHandlers :: [NumericErrorDocHandler] Source #
Handlers for most common errors defined in Lorentz.
Deprecated: Use Never type instead
Replacement for uninhabited type.
Instances
| Generic Empty Source # | |
| TypeHasDoc Empty Source # | |
Defined in Lorentz.Empty Associated Types type TypeDocFieldDescriptions Empty :: FieldDescriptions # Methods typeDocName :: Proxy Empty -> Text # typeDocMdDescription :: Markdown # typeDocMdReference :: Proxy Empty -> WithinParens -> Markdown # typeDocDependencies :: Proxy Empty -> [SomeDocDefinitionItem] # typeDocHaskellRep :: TypeDocHaskellRep Empty # typeDocMichelsonRep :: TypeDocMichelsonRep Empty # | |
| IsoValue Empty Source # | |
| HasAnnotation Empty Source # | |
Defined in Lorentz.Empty Methods getAnnotation :: FollowEntrypointFlag -> Notes (ToT Empty) Source # | |
| type Rep Empty Source # | |
Defined in Lorentz.Empty | |
| type TypeDocFieldDescriptions Empty Source # | |
Defined in Lorentz.Empty | |
| type ToT Empty Source # | |
Defined in Lorentz.Empty | |
Lorentz version of Iso.
involutedIso :: Lambda a a -> LIso a a Source #
Given a function that is its own inverse, make an LIso using it
in both directions.
checkedCoerceIso :: Coercible_ a b => LIso a b Source #
The isomorphism between two values with identical representation and semantics.
forcedCoerceIso :: MichelsonCoercible a b => LIso a b Source #
The isomorphism between two values with identical representation.
The same precautions as for forcedCoerce apply here.
nonIso :: (NiceConstant a, NiceComparable a) => a -> LIso (Maybe a) a Source #
Absence of value on the left hand side is associated with the given value on the right hand side.
nonDefIso :: (LDefault a, NiceConstant a) => LIso (Maybe a) a Source #
Absence of value on the left hand side is associated with the default value on the right hand side.
This is more general version of nonIso ldef since it can
work with e.g. containers.
type family StorageContains store (content :: [NamedField]) :: Constraint where ... Source #
Concise way to write down constraints with expected content of a storage.
Use it like follows:
type StorageConstraint store = StorageContains store [ "fieldInt" := Int , "fieldNat" := Nat , "epsToNat" := Int ::-> Nat , "balances" := Address ~> Int ]
Note that this won't work with complex field references, they have to be
included using e.g. StoreHasField manually.
Equations
| StorageContains _ '[] = () | |
| StorageContains store ((n := Identity ty) ': ct) = (StoreHasField store n ty, StorageContains store ct) | |
| StorageContains store ((n := (k ~> v)) ': ct) = (StoreHasSubmap store n k v, StorageContains store ct) | |
| StorageContains store ((n := (ep ::-> es)) ': ct) = (StoreHasEntrypoint store n ep es, StorageContains store ct) | |
| StorageContains store ((n := ty) ': ct) = (StoreHasField store n ty, StorageContains store ct) |
data param ::-> store infix 9 Source #
Indicates a stored entrypoint with the given param and store types.
type FieldNickname alias = FieldAlias (alias :: Symbol) Source #
Kind-restricted version of FieldAlias to work solely with string labels.
data FieldAlias (alias :: k) (p :: FieldRefTag) Source #
Alias for a field reference.
This allows creating _custom_ field references; you will have to define
the respective StoreHasField and StoreHasSubmap instances manually.
Since this type occupies a different "namespace" than string labels
and :-|, no overlappable instances will be necessary.
Example:
-- Shortcut for a deeply nested field X data FieldX instance StoreHasField Storage (FieldAlias FieldX) Integer where ... accessX = stToField (stAlias @FieldX)
Note that alias type argument allows instantiations of any kind.
Instances
| KnownFieldRef (FieldAlias alias :: FieldRefTag -> Type) Source # | |
Defined in Lorentz.StoreClass Associated Types type FieldRefObject (FieldAlias alias) = (fr :: FieldRefKind) Source # Methods mkFieldRef :: forall (p :: FieldRefTag). FieldRefObject (FieldAlias alias) p Source # | |
| type FieldRefObject (FieldAlias alias :: FieldRefTag -> Type) Source # | |
Defined in Lorentz.StoreClass | |
data SelfRef (p :: FieldRefTag) Source #
Refer to no particular field, access itself.
Constructors
| SelfRef |
Instances
data ((l :: k1) :-| (r :: k2)) (p :: FieldRefTag) infixr 8 Source #
Refer to a nested entry in storage.
Example: stToField (b) fetches field b in the type under field a.
If not favouring this name much, you can try an alias from Lorentz.StoreClass.Extra.
Instances
class StoreHasEntrypoint store epName epParam epStore | store epName -> epParam epStore where Source #
Provides operations on stored entrypoints.
store is the storage containing both the entrypoint epName (note: it has
to be in a BigMap to take advantage of lazy evaluation) and the epStore
field this operates on.
Methods
storeEpOps :: StoreEntrypointOps store epName epParam epStore Source #
data StoreEntrypointOps store epName epParam epStore Source #
Datatype containing the full implementation of StoreHasEntrypoint typeclass.
We use this grouping because in most cases the implementation will be chosen
among the default ones, and initializing all methods at once is simpler
and more consistent.
(One can say that we are trying to emulate the DerivingVia extension.)
Constructors
| StoreEntrypointOps | |
Fields
| |
type EntrypointsField param store = BigMap MText (EntrypointLambda param store) Source #
Type synonym of a BigMap mapping MText (entrypoint names) to
EntrypointLambda.
This is useful when defining instances of StoreHasEntrypoint as a storage
field containing one or more entrypoints (lambdas) of the same type.
type EntrypointLambda param store = Lambda (param, store) ([Operation], store) Source #
Type synonym for a Lambda that can be used as an entrypoint
class StoreHasSubmap store mname key value | store mname -> key value where Source #
Provides operations on submaps of storage.
Methods
storeSubmapOps :: StoreSubmapOps store mname key value Source #
Instances
| (StoreHasField store name submap, StoreHasSubmap submap SelfRef key value, KnownSymbol name) => StoreHasSubmap store (name :: Symbol) key value Source # | Provides access to the submap via the respective field. Tricky storages that consolidate submaps in a non-trivial way can define instances overlapping this one. |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps store name key value Source # | |
| (StoreHasField store field substore, StoreHasSubmap substore subfield key value, KnownFieldRef field, KnownFieldRef subfield) => StoreHasSubmap store (field :-| subfield :: FieldRefTag -> Type) key value Source # | |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps store (field :-| subfield) key value Source # | |
| NiceComparable key => StoreHasSubmap (Set key) SelfRef key () Source # | |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps (Set key) SelfRef key () Source # | |
| (NiceComparable key, KnownValue value) => StoreHasSubmap (Map key value) SelfRef key value Source # | |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps (Map key value) SelfRef key value Source # | |
| (NiceComparable key, KnownValue value) => StoreHasSubmap (BigMap key value) SelfRef key value Source # | |
Defined in Lorentz.StoreClass Methods storeSubmapOps :: StoreSubmapOps (BigMap key value) SelfRef key value Source # | |
data StoreSubmapOps store mname key value Source #
Datatype containing the full implementation of StoreHasSubmap typeclass.
We use this grouping because in most cases the implementation will be chosen
among the default ones, and initializing all methods at once is simpler
and more consistent.
(One can say that we are trying to emulate the DerivingVia extension.)
Constructors
| StoreSubmapOps | |
Fields
| |
class StoreHasField store fname ftype | store fname -> ftype where Source #
Provides operations on fields for storage.
Methods
storeFieldOps :: StoreFieldOps store fname ftype Source #
Instances
| HasFieldOfType (a, b) fname ftype => StoreHasField (a, b) (fname :: Symbol) ftype Source # | |
Defined in Lorentz.StoreClass Methods storeFieldOps :: StoreFieldOps (a, b) fname ftype Source # | |
| HasFieldOfType (a, b, c) fname ftype => StoreHasField (a, b, c) (fname :: Symbol) ftype Source # | |
Defined in Lorentz.StoreClass Methods storeFieldOps :: StoreFieldOps (a, b, c) fname ftype Source # | |
| StoreHasField store SelfRef store Source # | |
Defined in Lorentz.StoreClass Methods storeFieldOps :: StoreFieldOps store SelfRef store Source # | |
| (StoreHasField store field substore, StoreHasField substore subfield ty, KnownFieldRef field, KnownFieldRef subfield) => StoreHasField store (field :-| subfield :: FieldRefTag -> Type) ty Source # | |
Defined in Lorentz.StoreClass Methods storeFieldOps :: StoreFieldOps store (field :-| subfield) ty Source # | |
data StoreFieldOps store fname ftype Source #
Datatype containing the full implementation of StoreHasField typeclass.
We use this grouping because in most cases the implementation will be chosen
among the default ones, and initializing all methods at once is simpler
and more consistent.
(One can say that we are trying to emulate the DerivingVia extension.)
Constructors
| StoreFieldOps | |
Fields
| |
class FieldRefHasFinalName fr where Source #
Provides access to the direct name of the referred field.
This is used in stToFieldNamed.
Associated Types
type FieldRefFinalName fr :: Symbol Source #
Methods
fieldRefFinalName :: FieldRef fr -> Label (FieldRefFinalName fr) Source #
Instances
| FieldRefHasFinalName (name :: Symbol) Source # | |
Defined in Lorentz.StoreClass Associated Types type FieldRefFinalName name :: Symbol Source # Methods fieldRefFinalName :: FieldRef name -> Label (FieldRefFinalName name) Source # | |
| FieldRefHasFinalName r => FieldRefHasFinalName (l :-| r :: FieldRefTag -> Type) Source # | |
Defined in Lorentz.StoreClass Associated Types type FieldRefFinalName (l :-| r) :: Symbol Source # Methods fieldRefFinalName :: FieldRef (l :-| r) -> Label (FieldRefFinalName (l :-| r)) Source # | |
type FieldSymRef name = FieldRef (name :: Symbol) Source #
Version of FieldRef restricted to symbolic labels.
FieldSymRef name ≡ FieldName name 'FieldRefTag
data FieldName (n :: Symbol) (p :: FieldRefTag) Source #
The simplest field reference - just a name. Behaves similarly to Label.
type FieldRef name = FieldRefObject name 'FieldRefTag Source #
Some kind of reference to a field.
The idea behind this type is that in trivial case (name :: Symbol) it can
be instantiated with a mere label, but it is generic enough to allow complex
field references as well.
class KnownFieldRef (ty :: k) where Source #
For a type-level field reference - an associated term-level representation.
This is similar to Sing + SingI pair but has small differences:
- Dedicated to field references, thus term-level thing has
FieldRefKindkind. - The type of term-level value (
FieldRefObject ty) determines the kind of the reference type.
Associated Types
type FieldRefObject ty = (fr :: FieldRefKind) | fr -> ty Source #
Methods
mkFieldRef :: FieldRefObject ty p Source #
Instances
data FieldRefTag Source #
Instances
type FieldRefKind = FieldRefTag -> Type Source #
Open kind for various field references.
The simplest field reference could be Label, pointing to a field
by its name, but we also support more complex scenarios like deep
fields identifiers.
fieldNameToLabel :: FieldSymRef n -> Label n Source #
Convert a symbolic FieldRef to a label, useful for compatibility with
other interfaces.
fieldNameFromLabel :: Label n -> FieldSymRef n Source #
Convert a label to FieldRef, useful for compatibility with
other interfaces.
stToField :: StoreHasField store fname ftype => FieldRef fname -> (store ': s) :-> (ftype ': s) Source #
Pick storage field.
stGetField :: StoreHasField store fname ftype => FieldRef fname -> (store ': s) :-> (ftype ': (store ': s)) Source #
Get storage field, preserving the storage itself on stack.
stToFieldNamed :: (StoreHasField store fname ftype, FieldRefHasFinalName fname) => FieldRef fname -> (store ': s) :-> ((FieldRefFinalName fname :! ftype) ': s) Source #
Pick storage field retaining a name label attached.
For complex refs this tries to attach the immediate name of the referred field.
stGetFieldNamed :: (StoreHasField store fname ftype, FieldRefHasFinalName fname) => FieldRef fname -> (store ': s) :-> ((FieldRefFinalName fname :! ftype) ': (store ': s)) Source #
Version of stToFieldNamed that preserves the storage on stack.
stSetField :: StoreHasField store fname ftype => FieldRef fname -> (ftype ': (store ': s)) :-> (store ': s) Source #
Update storage field.
stMem :: StoreHasSubmap store mname key value => FieldRef mname -> (key ': (store ': s)) :-> (Bool ': s) Source #
Check value presence in storage.
stGet :: (StoreHasSubmap store mname key value, KnownValue value) => FieldRef mname -> (key ': (store ': s)) :-> (Maybe value ': s) Source #
Get value in storage.
stUpdate :: StoreHasSubmap store mname key value => FieldRef mname -> (key ': (Maybe value ': (store ': s))) :-> (store ': s) Source #
Update a value in storage.
stDelete :: forall store mname key value s. StoreHasSubmap store mname key value => FieldRef mname -> (key ': (store ': s)) :-> (store ': s) Source #
Delete a value in storage.
stInsert :: StoreHasSubmap store mname key value => FieldRef mname -> (key ': (value ': (store ': s))) :-> (store ': s) Source #
Add a value in storage.
stInsertNew :: StoreHasSubmap store mname key value => FieldRef mname -> (forall s0 any. (key ': s0) :-> any) -> (key ': (value ': (store ': s))) :-> (store ': s) Source #
Add a value in storage, but fail if it will overwrite some existing entry.
stEntrypoint :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (epParam ': (store ': s)) :-> (([Operation], store) ': s) Source #
Extracts and executes the epName entrypoint lambda from storage, returing
the updated full storage (store) and the produced Operations.
stToEpLambda :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (EntrypointLambda epParam epStore ': s) Source #
Pick stored entrypoint lambda.
stGetEpLambda :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (EntrypointLambda epParam epStore ': (store ': s)) Source #
Get stored entrypoint lambda, preserving the storage itself on the stack.
stSetEpLambda :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (EntrypointLambda epParam epStore ': (store ': s)) :-> (store ': s) Source #
Stores the entrypoint lambda in the storage. Fails if already set.
stToEpStore :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (epStore ': s) Source #
Pick the sub-storage that the entrypoint operates on.
stGetEpStore :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (store ': s) :-> (epStore ': (store ': s)) Source #
Get the sub-storage that the entrypoint operates on, preserving the storage itself on the stack.
stSetEpStore :: StoreHasEntrypoint store epName epParam epStore => Label epName -> (epStore ': (store ': s)) :-> (store ': s) Source #
Update the sub-storage that the entrypoint operates on.
storeFieldOpsADT :: HasFieldOfType dt fname ftype => StoreFieldOps dt (fname :: Symbol) ftype Source #
Implementation of StoreHasField for case of datatype
keeping a pack of fields.
storeEntrypointOpsADT :: (HasFieldOfType store epmName (EntrypointsField epParam epStore), HasFieldOfType store epsName epStore, KnownValue epParam, KnownValue epStore) => Label epmName -> Label epsName -> StoreEntrypointOps store epName epParam epStore Source #
Implementation of StoreHasEntrypoint for a datatype keeping a pack of
fields, among which one contains the entrypoint and another is what such
entrypoint operates on.
storeEntrypointOpsFields :: (StoreHasField store epmName (EntrypointsField epParam epStore), StoreHasField store epsName epStore, KnownValue epParam, KnownValue epStore) => Label epmName -> Label epsName -> StoreEntrypointOps store epName epParam epStore Source #
Implementation of StoreHasEntrypoint for a datatype that has a StoreHasField
for an EntrypointsField that contains the entrypoint and a StoreHasField
for the field such entrypoint operates on.
storeEntrypointOpsSubmapField :: (StoreHasSubmap store epmName MText (EntrypointLambda epParam epStore), StoreHasField store epsName epStore, KnownValue epParam, KnownValue epStore) => Label epmName -> Label epsName -> StoreEntrypointOps store epName epParam epStore Source #
Implementation of StoreHasEntrypoint for a datatype that has a StoreHasSubmap
that contains the entrypoint and a StoreHasField for the field such
entrypoint operates on.
storeFieldOpsDeeper :: (HasFieldOfType storage fieldsPartName fields, StoreHasField fields fname ftype) => FieldRef fieldsPartName -> StoreFieldOps storage fname ftype Source #
Implementation of StoreHasField for a data type which has an
instance of StoreHasField inside.
For instance, it can be used for top-level storage.
storeSubmapOpsDeeper :: (HasFieldOfType storage bigMapPartName fields, StoreHasSubmap fields SelfRef key value) => FieldRef bigMapPartName -> StoreSubmapOps storage mname key value Source #
Implementation of StoreHasSubmap for a data type which has an
instance of StoreHasSubmap inside.
For instance, it can be used for top-level storage.
storeEntrypointOpsDeeper :: (HasFieldOfType store nameInStore substore, StoreHasEntrypoint substore epName epParam epStore) => FieldRef nameInStore -> StoreEntrypointOps store epName epParam epStore Source #
Implementation of StoreHasEntrypoint for a data type which has an
instance of StoreHasEntrypoint inside.
For instance, it can be used for top-level storage.
storeSubmapOpsReferTo :: FieldRef name -> StoreSubmapOps storage name key value -> StoreSubmapOps storage desiredName key value Source #
Pretend that given StoreSubmapOps implementation is made up
for submap with name desiredName, not its actual name.
Logic of the implementation remains the same.
Use case: imagine that your code requires access to submap named X,
but in your storage that submap is called Y.
Then you implement the instance which makes X refer to Y:
instance StoreHasSubmap Store X Key Value where storeSubmapOps = storeSubmapOpsReferTo #Y storeSubmapOpsForY
storeFieldOpsReferTo :: FieldRef name -> StoreFieldOps storage name field -> StoreFieldOps storage desiredName field Source #
Pretend that given StoreFieldOps implementation is made up
for field with name desiredName, not its actual name.
Logic of the implementation remains the same.
See also storeSubmapOpsReferTo.
storeEntrypointOpsReferTo :: Label epName -> StoreEntrypointOps store epName epParam epStore -> StoreEntrypointOps store desiredName epParam epStore Source #
Pretend that given StoreEntrypointOps implementation is made up
for entrypoint with name desiredName, not its actual name.
Logic of the implementation remains the same.
See also storeSubmapOpsReferTo.
mapStoreFieldOps :: LIso field1 field2 -> StoreFieldOps store name field1 -> StoreFieldOps store name field2 Source #
Change field operations so that they work on a modified field.
For instance, to go from
StoreFieldOps Storage "name" Integer
to
StoreFieldOps Storage "name" (value :! Integer)
you can use
mapStoreFieldOps (namedIso #value)
mapStoreSubmapOpsKey :: Lambda key2 key1 -> StoreSubmapOps store name key1 value -> StoreSubmapOps store name key2 value Source #
Change submap operations so that they work on a modified key.
mapStoreSubmapOpsValue :: KnownValue value1 => LIso value1 value2 -> StoreSubmapOps store name key value1 -> StoreSubmapOps store name key value2 Source #
Change submap operations so that they work on a modified value.
composeStoreFieldOps :: FieldRef nameInStore -> StoreFieldOps store nameInStore substore -> StoreFieldOps substore nameInSubstore field -> StoreFieldOps store nameInSubstore field Source #
Chain two implementations of field operations.
Suits for a case when your store does not contain its fields directly rather has a nested structure.
composeStoreSubmapOps :: FieldRef nameInStore -> StoreFieldOps store nameInStore substore -> StoreSubmapOps substore mname key value -> StoreSubmapOps store mname key value Source #
Chain implementations of field and submap operations.
sequenceStoreSubmapOps :: forall store substore value name subName key1 key2. (NiceConstant substore, KnownValue value) => FieldRef name -> LIso (Maybe substore) substore -> StoreSubmapOps store name key1 substore -> StoreSubmapOps substore subName key2 value -> StoreSubmapOps store subName (key1, key2) value Source #
Chain implementations of two submap operations sets. Used to provide shortcut access to a nested submap.
This is very inefficient since on each access to substore it has to be serialized/deserialized. Use this implementation only if due to historical reasons migrating storage is difficult.
LIso (Maybe substore) substore argument describes how to get
substore value if it was absent in map and how to detect when
it can be safely removed.
Example of use:
sequenceStoreSubmapOps #mySubmap nonDefIso storeSubmapOps storeSubmapOps
composeStoreEntrypointOps :: FieldRef nameInStore -> StoreFieldOps store nameInStore substore -> StoreEntrypointOps substore epName epParam epStore -> StoreEntrypointOps store epName epParam epStore Source #
zoomStoreSubmapOps :: forall store submapName nameInSubmap key value subvalue. (NiceConstant value, NiceConstant subvalue) => FieldRef submapName -> LIso (Maybe value) value -> LIso (Maybe subvalue) subvalue -> StoreSubmapOps store submapName key value -> StoreFieldOps value nameInSubmap subvalue -> StoreSubmapOps store nameInSubmap key subvalue Source #
Turn submap operations into operations on a part of the submap value.
Normally, if you need this set of operations, it would be better to split your submap into several separate submaps, each operating with its own part of the value. This set of operations is pretty inefficient and exists only as a temporary measure, if due to historical reasons you have to leave storage format intact.
This implementation puts no distinction between value == Nothing and
value == Just defValue cases.
Getters, when notice a value equal to the default value, report its absence.
Setters tend to remove the value from submap when possible.
LIso (Maybe value) value and LIso (Maybe subvalue) subvalue arguments
describe how to get a value if it was absent in map and how to detect when
it can be safely removed from map.
Example of use:
zoomStoreSubmapOps #mySubmap nonDefIso nonDefIso storeSubmapOps storeFieldOpsADT
mkStoreEp :: Label epName -> EntrypointLambda epParam epStore -> EntrypointsField epParam epStore Source #
Utility to create EntrypointsFields from an entrypoint name (epName) and
an EntrypointLambda implementation. Note that you need to merge multiple of
these (with <>) if your field contains more than one entrypoint lambda.
An alias for SelfRef.
Examples:
>>>push 5 # stMem this -$ (mempty :: Map Integer MText)... ... Nothing ...
>>>stGetField this # pair -$ (5 :: Integer)... ... (5, 5) ...
stAlias :: forall alias. FieldRef (FieldAlias alias) Source #
Construct an alias at term level.
This requires passing the alias via type annotation.
stNickname :: Label name -> FieldRef (FieldAlias name) Source #
Version of stAlias adopted to labels.