Copyright	(c) The University of Glasgow 2003
License	BSD-style (see the file libraries/base/LICENSE)
Maintainer	libraries@haskell.org
Stability	experimental
Portability	portable
Safe Haskell	None
Language	Haskell2010

Language.Haskell.TH.Syntax

Description

Abstract syntax definitions for Template Haskell.

Synopsis

Documentation

class (Monad m, Applicative m) => Quasi m whereSource

Methods

qNewName Source

Arguments

:: String
-> m Name	Fresh names

qReport Source

Arguments

:: Bool
-> String
-> m ()	Report an error (True) or warning (False) ...but carry on; use `fail` to stop

qRecover Source

Arguments

:: m a	the error handler
-> m a	action which may fail
-> m a	Recover from the monadic `fail`

qLookupName :: Bool -> String -> m (Maybe Name)Source

qReify :: Name -> m Info Source

qReifyInstances :: Name -> [Type] -> m [Dec]Source

qReifyRoles :: Name -> m [Role]Source

qReifyAnnotations :: Data a => AnnLookup -> m [a]Source

qReifyModule :: Module -> m ModuleInfo Source

qLocation :: m Loc Source

qRunIO :: IO a -> m aSource

Input/output (dangerous)

qAddDependentFile :: FilePath -> m ()Source

qAddTopDecls :: [Dec] -> m ()Source

qAddModFinalizer :: Q () -> m ()Source

qGetQ :: Typeable a => m (Maybe a)Source

qPutQ :: Typeable a => a -> m ()Source

Instances

Quasi IO
Quasi Q

badIO :: String -> IO aSource

counter :: IORef Int Source

newtype Q aSource

Constructors

Q
Fields unQ :: forall m. Quasi m => m a

Instances

Monad Q
Functor Q
Applicative Q
Quasi Q

runQ :: Quasi m => Q a -> m aSource

newtype TExp aSource

Constructors

TExp
Fields unType :: Exp

unTypeQ :: Q (TExp a) -> Q Exp Source

unsafeTExpCoerce :: Q Exp -> Q (TExp a)Source

newName :: String -> Q Name Source

Generate a fresh name, which cannot be captured.

For example, this:

f = $(do
  nm1 <- newName "x"
  let nm2 = mkName "x"
  return (LamE [VarP nm1] (LamE [VarP nm2] (VarE nm1)))
 )

will produce the splice

f = \x0 -> \x -> x0

In particular, the occurrence VarE nm1 refers to the binding VarP nm1, and is not captured by the binding VarP nm2.

Although names generated by newName cannot be captured, they can capture other names. For example, this:

g = $(do
  nm1 <- newName "x"
  let nm2 = mkName "x"
  return (LamE [VarP nm2] (LamE [VarP nm1] (VarE nm2)))
 )

will produce the splice

g = \x -> \x0 -> x0

since the occurrence VarE nm2 is captured by the innermost binding of x, namely VarP nm1.

report :: Bool -> String -> Q ()Source

Deprecated: Use reportError or reportWarning instead

Report an error (True) or warning (False), but carry on; use fail to stop.

reportError :: String -> Q ()Source

Report an error to the user, but allow the current splice's computation to carry on. To abort the computation, use fail.

reportWarning :: String -> Q ()Source

Report a warning to the user, and carry on.

recover Source

Arguments

:: Q a	handler to invoke on failure
-> Q a	computation to run
-> Q a

Recover from errors raised by reportError or fail.

lookupName :: Bool -> String -> Q (Maybe Name)Source

lookupTypeName :: String -> Q (Maybe Name)Source

Look up the given name in the (type namespace of the) current splice's scope. See "Language.Haskell.TH.Syntax#namelookup" for more details.

lookupValueName :: String -> Q (Maybe Name)Source

Look up the given name in the (value namespace of the) current splice's scope. See "Language.Haskell.TH.Syntax#namelookup" for more details.

The functions lookupTypeName and lookupValueName provide a way to query the current splice's context for what names are in scope. The function lookupTypeName queries the type namespace, whereas lookupValueName queries the value namespace, but the functions are otherwise identical.

A call lookupValueName s will check if there is a value with name s in scope at the current splice's location. If there is, the Name of this value is returned; if not, then Nothing is returned.

The returned name cannot be "captured". For example:

 f = "global"
 g = $( do
          Just nm <- lookupValueName "f"
          [| let f = "local" in $( varE nm ) |]

In this case, g = "global"; the call to lookupValueName returned the global f, and this name was not captured by the local definition of f.

The lookup is performed in the context of the top-level splice being run. For example:

 f = "global"
 g = $( [| let f = "local" in
            $(do
                Just nm <- lookupValueName "f"
                varE nm
             ) |] )

Again in this example, g = "global", because the call to lookupValueName queries the context of the outer-most $(...).

Operators should be queried without any surrounding parentheses, like so:

 lookupValueName "+"

Qualified names are also supported, like so:

 lookupValueName "Prelude.+"
 lookupValueName "Prelude.map"

reify :: Name -> Q Info Source

reify looks up information about the Name.

It is sometimes useful to construct the argument name using lookupTypeName or lookupValueName to ensure that we are reifying from the right namespace. For instance, in this context:

 data D = D

which D does reify (mkName "D") return information about? (Answer: D-the-type, but don't rely on it.) To ensure we get information about D-the-value, use lookupValueName:

 do
   Just nm <- lookupValueName "D"
   reify nm

and to get information about D-the-type, use lookupTypeName.

reifyInstances :: Name -> [Type] -> Q [InstanceDec]Source

reifyInstances nm tys returns a list of visible instances of nm tys. That is, if nm is the name of a type class, then all instances of this class at the types tys are returned. Alternatively, if nm is the name of a data family or type family, all instances of this family at the types tys are returned.

reifyRoles :: Name -> Q [Role]Source

reifyRoles nm returns the list of roles associated with the parameters of the tycon nm. Fails if nm cannot be found or is not a tycon. The returned list should never contain InferR.

reifyAnnotations :: Data a => AnnLookup -> Q [a]Source

reifyAnnotations target returns the list of annotations associated with target. Only the annotations that are appropriately typed is returned. So if you have Int and String annotations for the same target, you have to call this function twice.

reifyModule :: Module -> Q ModuleInfo Source

reifyModule mod looks up information about module mod. To look up the current module, call this function with the return value of thisModule.

isInstance :: Name -> [Type] -> Q Bool Source

Is the list of instances returned by reifyInstances nonempty?

location :: Q Loc Source

The location at which this computation is spliced.

runIO :: IO a -> Q aSource

The runIO function lets you run an I/O computation in the Q monad. Take care: you are guaranteed the ordering of calls to runIO within a single Q computation, but not about the order in which splices are run.

Note: for various murky reasons, stdout and stderr handles are not necesarily flushed when the compiler finishes running, so you should flush them yourself.

addDependentFile :: FilePath -> Q ()Source

Record external files that runIO is using (dependent upon). The compiler can then recognize that it should re-compile the file using this TH when the external file changes. Note that ghc -M will still not know about these dependencies - it does not execute TH. Expects an absolute file path.

addTopDecls :: [Dec] -> Q ()Source

Add additional top-level declarations. The added declarations will be type checked along with the current declaration group.

addModFinalizer :: Q () -> Q ()Source

Add a finalizer that will run in the Q monad after the current module has been type checked. This only makes sense when run within a top-level splice.

getQ :: Typeable a => Q (Maybe a)Source

Get state from the Q monad.

putQ :: Typeable a => a -> Q ()Source

Replace the state in the Q monad.

returnQ :: a -> Q aSource

bindQ :: Q a -> (a -> Q b) -> Q bSource

sequenceQ :: [Q a] -> Q [a]Source

class Lift t whereSource

Methods

lift :: t -> Q Exp Source

Instances

Lift Bool
Lift Char
Lift Int
Lift Integer
Lift a => Lift [a]
Lift a => Lift (Maybe a)
(Lift a, Lift b) => Lift (Either a b)
(Lift a, Lift b) => Lift (a, b)
(Lift a, Lift b, Lift c) => Lift (a, b, c)
(Lift a, Lift b, Lift c, Lift d) => Lift (a, b, c, d)
(Lift a, Lift b, Lift c, Lift d, Lift e) => Lift (a, b, c, d, e)
(Lift a, Lift b, Lift c, Lift d, Lift e, Lift f) => Lift (a, b, c, d, e, f)
(Lift a, Lift b, Lift c, Lift d, Lift e, Lift f, Lift g) => Lift (a, b, c, d, e, f, g)

liftString :: String -> Q Exp Source

trueName :: Name Source

falseName :: Name Source

nothingName :: Name Source

justName :: Name Source

leftName :: Name Source

rightName :: Name Source

newtype ModName Source

Constructors

ModName String

Instances

Eq ModName
Data ModName
Ord ModName
Show ModName
Typeable * ModName

newtype PkgName Source

Constructors

PkgName String

Instances

Eq PkgName
Data PkgName
Ord PkgName
Show PkgName
Typeable * PkgName

data Module Source

Obtained from reifyModule and thisModule.

Constructors

Module PkgName ModName

Instances

Eq Module
Data Module
Ord Module
Show Module
Ppr Module
Typeable * Module

newtype OccName Source

Constructors

OccName String

Instances

Eq OccName
Data OccName
Ord OccName
Show OccName
Typeable * OccName

mkModName :: String -> ModName Source

modString :: ModName -> String Source

mkPkgName :: String -> PkgName Source

pkgString :: PkgName -> String Source

mkOccName :: String -> OccName Source

occString :: OccName -> String Source

Much of Name API is concerned with the problem of name capture, which can be seen in the following example.

 f expr = [| let x = 0 in $expr |]
 ...
 g x = $( f [| x |] )
 h y = $( f [| y |] )

A naive desugaring of this would yield:

 g x = let x = 0 in x
 h y = let x = 0 in y

All of a sudden, g and h have different meanings! In this case, we say that the x in the RHS of g has been captured by the binding of x in f.

What we actually want is for the x in f to be distinct from the x in g, so we get the following desugaring:

 g x = let x' = 0 in x
 h y = let x' = 0 in y

which avoids name capture as desired.

In the general case, we say that a Name can be captured if the thing it refers to can be changed by adding new declarations.

data Name Source

An abstract type representing names in the syntax tree.

Names can be constructed in several ways, which come with different name-capture guarantees (see "Language.Haskell.TH.Syntax#namecapture" for an explanation of name capture):

the built-in syntax 'f and ''T can be used to construct names, The expression 'f gives a Name which refers to the value f currently in scope, and ''T gives a Name which refers to the type T currently in scope. These names can never be captured.
lookupValueName and lookupTypeName are similar to 'f and ''T respectively, but the Names are looked up at the point where the current splice is being run. These names can never be captured.
newName monadically generates a new name, which can never be captured.
mkName generates a capturable name.

Names constructed using newName and mkName may be used in bindings (such as let x = ... or x -> ...), but names constructed using lookupValueName, lookupTypeName, 'f, ''T may not.

Constructors

Name OccName NameFlavour

Instances

Eq Name
Data Name
Ord Name
Show Name
Ppr Name
Typeable * Name

data NameFlavour Source

Constructors

NameS	An unqualified name; dynamically bound
NameQ ModName	A qualified name; dynamically bound
NameU Int#	A unique local name
NameL Int#	Local name bound outside of the TH AST
NameG NameSpace PkgName ModName	Global name bound outside of the TH AST: An original name (occurrences only, not binders) Need the namespace too to be sure which thing we are naming

Instances

Eq NameFlavour
Data NameFlavour	Although the NameFlavour type is abstract, the Data instance is not. The reason for this is that currently we use Data to serialize values in annotations, and in order for that to work for Template Haskell names introduced via the 'x syntax we need gunfold on NameFlavour to work. Bleh! The long term solution to this is to use the binary package for annotation serialization and then remove this instance. However, to do _that_ we need to wait on binary to become stable, since boot libraries cannot be upgraded separately from GHC itself. This instance cannot be derived automatically due to bug #2701
Ord NameFlavour
Typeable * NameFlavour

con_NameS :: Constr Source

con_NameG :: Constr Source

con_NameL :: Constr Source

con_NameU :: Constr Source

con_NameQ :: Constr Source

ty_NameFlavour :: DataType Source

data NameSpace Source

Constructors

VarName	Variables
DataName	Data constructors
TcClsName	Type constructors and classes; Haskell has them in the same name space for now.

Instances

Eq NameSpace
Data NameSpace
Ord NameSpace
Typeable * NameSpace

type Uniq = Int Source

nameBase :: Name -> String Source

The name without its module prefix

nameModule :: Name -> Maybe String Source

Module prefix of a name, if it exists

mkName :: String -> Name Source

Generate a capturable name. Occurrences of such names will be resolved according to the Haskell scoping rules at the occurrence site.

For example:

 f = [| pi + $(varE (mkName "pi")) |]
 ...
 g = let pi = 3 in $f

In this case, g is desugared to

 g = Prelude.pi + 3

Note that mkName may be used with qualified names:

 mkName "Prelude.pi"

See also dyn for a useful combinator. The above example could be rewritten using dyn as

 f = [| pi + $(dyn "pi") |]

mkNameU :: String -> Uniq -> Name Source

Only used internally

mkNameL :: String -> Uniq -> Name Source

Only used internally

mkNameG :: NameSpace -> String -> String -> String -> Name Source

Used for 'x etc, but not available to the programmer

mkNameG_v :: String -> String -> String -> Name Source

mkNameG_d :: String -> String -> String -> Name Source

mkNameG_tc :: String -> String -> String -> Name Source

data NameIs Source

Constructors

Alone
Applied
Infix

showName :: Name -> String Source

showName' :: NameIs -> Name -> String Source

tupleDataName :: Int -> Name Source

Tuple data constructor

tupleTypeName :: Int -> Name Source

Tuple type constructor

mk_tup_name :: Int -> NameSpace -> Name Source

unboxedTupleDataName :: Int -> Name Source

Unboxed tuple data constructor

unboxedTupleTypeName :: Int -> Name Source

Unboxed tuple type constructor

mk_unboxed_tup_name :: Int -> NameSpace -> Name Source

data Loc Source

Constructors

Loc
Fields loc_filename :: String loc_package :: String loc_module :: String loc_start :: CharPos loc_end :: CharPos

type CharPos Source

Arguments

= (Int, Int)

Line and character position

data Info Source

Obtained from reify in the Q Monad.

Constructors

ClassI Dec [InstanceDec]	A class, with a list of its visible instances
ClassOpI Name Type ParentName Fixity	A class method
TyConI Dec	A "plain" type constructor. "Fancier" type constructors are returned using `PrimTyConI` or `FamilyI` as appropriate
FamilyI Dec [InstanceDec]	A type or data family, with a list of its visible instances. A closed type family is returned with 0 instances.
PrimTyConI Name Arity Unlifted	A "primitive" type constructor, which can't be expressed with a `Dec`. Examples: `(->)`, `Int#`.
DataConI Name Type ParentName Fixity	A data constructor
VarI Name Type (Maybe Dec) Fixity	A "value" variable (as opposed to a type variable, see `TyVarI`). The `Maybe Dec` field contains `Just` the declaration which defined the variable -- including the RHS of the declaration -- or else `Nothing`, in the case where the RHS is unavailable to the compiler. At present, this value is _always_ `Nothing`: returning the RHS has not yet been implemented because of lack of interest.
TyVarI Name Type	A type variable. The `Type` field contains the type which underlies the variable. At present, this is always `VarT theName`, but future changes may permit refinement of this.

Instances

Data Info
Show Info
Ppr Info
Typeable * Info

data ModuleInfo Source

Obtained from reifyModule in the Q Monad.

Constructors

ModuleInfo [Module]

Contains the import list of the module.

Instances

Data ModuleInfo
Show ModuleInfo
Ppr ModuleInfo
Typeable * ModuleInfo

type ParentName = Name Source

In ClassOpI and DataConI, name of the parent class or type

type Arity = Int Source

In PrimTyConI, arity of the type constructor

type Unlifted = Bool Source

In PrimTyConI, is the type constructor unlifted?

type InstanceDec = Dec Source

InstanceDec desribes a single instance of a class or type function. It is just a Dec, but guaranteed to be one of the following:

InstanceD (with empty [Dec])
DataInstD or NewtypeInstD (with empty derived [Name])
TySynInstD

data Fixity Source

Constructors

Fixity Int FixityDirection

Instances

Eq Fixity
Data Fixity
Show Fixity
Typeable * Fixity

data FixityDirection Source

Constructors

InfixL
InfixR
InfixN

Instances

Eq FixityDirection
Data FixityDirection
Show FixityDirection
Typeable * FixityDirection

maxPrecedence :: Int Source

Highest allowed operator precedence for Fixity constructor (answer: 9)

defaultFixity :: Fixity Source

Default fixity: infixl 9

When implementing antiquotation for quasiquoters, one often wants to parse strings into expressions:

 parse :: String -> Maybe Exp

But how should we parse a + b * c? If we don't know the fixities of + and *, we don't know whether to parse it as a + (b * c) or (a + b) * c.

In cases like this, use UInfixE or UInfixP, which stand for "unresolved infix expression" and "unresolved infix pattern". When the compiler is given a splice containing a tree of UInfixE applications such as

 UInfixE
   (UInfixE e1 op1 e2)
   op2
   (UInfixE e3 op3 e4)

it will look up and the fixities of the relevant operators and reassociate the tree as necessary.

trees will not be reassociated across ParensE or ParensP, which are of use for parsing expressions like
```
 (a + b * c) + d * e
```
InfixE and InfixP expressions are never reassociated.
The UInfixE constructor doesn't support sections. Sections such as (a *) have no ambiguity, so InfixE suffices. For longer sections such as (a + b * c -), use an InfixE constructor for the outer-most section, and use UInfixE constructors for all other operators:
```
 InfixE
   Just (UInfixE ...a + b * c...)
   op
   Nothing
```
Sections such as (a + b +) and ((a + b) +) should be rendered into Exps differently:
```
 (+ a + b)   ---> InfixE Nothing + (Just $ UInfixE a + b)
                    -- will result in a fixity error if (+) is left-infix
 (+ (a + b)) ---> InfixE Nothing + (Just $ ParensE $ UInfixE a + b)
                    -- no fixity errors
```
Quoted expressions such as
```
 [| a * b + c |] :: Q Exp
 [p| a : b : c |] :: Q Pat
```
will never contain UInfixE, UInfixP, ParensE, or ParensP constructors.

data Lit Source

Constructors

CharL Char
StringL String
IntegerL Integer	Used for overloaded and non-overloaded literals. We don't have a good way to represent non-overloaded literals at the moment. Maybe that doesn't matter?
RationalL Rational
IntPrimL Integer
WordPrimL Integer
FloatPrimL Rational
DoublePrimL Rational
StringPrimL [Word8]	A primitive C-style string, type Addr#

Instances

Eq Lit
Data Lit
Show Lit
Typeable * Lit

data Pat Source

Pattern in Haskell given in {}

Constructors

LitP Lit	{ 5 or `c` }
VarP Name	{ x }
TupP [Pat]	{ (p1,p2) }
UnboxedTupP [Pat]	{ (# p1,p2 #) }
ConP Name [Pat]	data T1 = C1 t1 t2; {C1 p1 p1} = e
InfixP Pat Name Pat	foo ({x :+ y}) = e
UInfixP Pat Name Pat	foo ({x :+ y}) = e See "Language.Haskell.TH.Syntax#infix"
ParensP Pat	{(p)} See "Language.Haskell.TH.Syntax#infix"
TildeP Pat	{ ~p }
BangP Pat	{ !p }
AsP Name Pat	{ x @ p }
WildP	{ _ }
RecP Name [FieldPat]	f (Pt { pointx = x }) = g x
ListP [Pat]	{ [1,2,3] }
SigP Pat Type	{ p :: t }
ViewP Exp Pat	{ e -> p }

Instances

Eq Pat
Data Pat
Show Pat
Ppr Pat
Typeable * Pat

type FieldPat = (Name, Pat)Source

data Match Source

Constructors

Match Pat Body [Dec]

case e of { pat -> body where decs }

Instances

Eq Match
Data Match
Show Match
Ppr Match
Typeable * Match

data Clause Source

Constructors

Clause [Pat] Body [Dec]

f { p1 p2 = body where decs }

Instances

Eq Clause
Data Clause
Show Clause
Ppr Clause
Typeable * Clause

data Exp Source

Constructors

VarE Name	{ x }
ConE Name	data T1 = C1 t1 t2; p = {C1} e1 e2
LitE Lit	{ 5 or `c`}
AppE Exp Exp	{ f x }
InfixE (Maybe Exp) Exp (Maybe Exp)	{x + y} or {(x+)} or {(+ x)} or {(+)}
UInfixE Exp Exp Exp	{x + y} See "Language.Haskell.TH.Syntax#infix"
ParensE Exp	{ (e) } See "Language.Haskell.TH.Syntax#infix"
LamE [Pat] Exp	{ p1 p2 -> e }
LamCaseE [Match]	{ case m1; m2 }
TupE [Exp]	{ (e1,e2) }
UnboxedTupE [Exp]	{ (# e1,e2 #) }
CondE Exp Exp Exp	{ if e1 then e2 else e3 }
MultiIfE [(Guard, Exp)]	{ if \| g1 -> e1 \| g2 -> e2 }
LetE [Dec] Exp	{ let x=e1; y=e2 in e3 }
CaseE Exp [Match]	{ case e of m1; m2 }
DoE [Stmt]	{ do { p <- e1; e2 } }
CompE [Stmt]	{ [ (x,y) \| x <- xs, y <- ys ] } The result expression of the comprehension is the last of the `Stmt`s, and should be a `NoBindS`. E.g. translation: [ f x \| x <- xs ] CompE [BindS (VarP x) (VarE xs), NoBindS (AppE (VarE f) (VarE x))]
ArithSeqE Range	{ [ 1 ,2 .. 10 ] }
ListE [Exp]	{ [1,2,3] }
SigE Exp Type	{ e :: t }
RecConE Name [FieldExp]	{ T { x = y, z = w } }
RecUpdE Exp [FieldExp]	{ (f x) { z = w } }

Instances

Eq Exp
Data Exp
Show Exp
Ppr Exp
Typeable * Exp

type FieldExp = (Name, Exp)Source

data Body Source

Constructors

GuardedB [(Guard, Exp)]	f p { \| e1 = e2 \| e3 = e4 } where ds
NormalB Exp	f p { = e } where ds

Instances

Eq Body
Data Body
Show Body
Typeable * Body

data Guard Source

Constructors

NormalG Exp	f x { \| odd x } = x
PatG [Stmt]	f x { \| Just y <- x, Just z <- y } = z

Instances

Eq Guard
Data Guard
Show Guard
Typeable * Guard

data Stmt Source

Constructors

BindS Pat Exp
LetS [Dec]
NoBindS Exp
ParS [[Stmt]]

Instances

Eq Stmt
Data Stmt
Show Stmt
Ppr Stmt
Typeable * Stmt

data Range Source

Constructors

FromR Exp
FromThenR Exp Exp
FromToR Exp Exp
FromThenToR Exp Exp Exp

Instances

Eq Range
Data Range
Show Range
Ppr Range
Typeable * Range

data Dec Source

Constructors

FunD Name [Clause]	{ f p1 p2 = b where decs }
ValD Pat Body [Dec]	{ p = b where decs }
DataD Cxt Name [TyVarBndr] [Con] [Name]	{ data Cxt x => T x = A x \| B (T x) deriving (Z,W)}
NewtypeD Cxt Name [TyVarBndr] Con [Name]	{ newtype Cxt x => T x = A (B x) deriving (Z,W)}
TySynD Name [TyVarBndr] Type	{ type T x = (x,x) }
ClassD Cxt Name [TyVarBndr] [FunDep] [Dec]	{ class Eq a => Ord a where ds }
InstanceD Cxt Type [Dec]	{ instance Show w => Show [w] where ds }
SigD Name Type	{ length :: [a] -> Int }
ForeignD Foreign	{ foreign import ... } { foreign export ... }
InfixD Fixity Name	{ infix 3 foo }
PragmaD Pragma	{ {-# INLINE [1] foo #-} }
FamilyD FamFlavour Name [TyVarBndr] (Maybe Kind)	{ type family T a b c :: * }
DataInstD Cxt Name [Type] [Con] [Name]	{ data instance Cxt x => T [x] = A x \| B (T x) deriving (Z,W)}
NewtypeInstD Cxt Name [Type] Con [Name]	{ newtype instance Cxt x => T [x] = A (B x) deriving (Z,W)}
TySynInstD Name TySynEqn	{ type instance ... }
ClosedTypeFamilyD Name [TyVarBndr] (Maybe Kind) [TySynEqn]	{ type family F a b :: * where ... }
RoleAnnotD Name [Role]	{ type role T nominal representational }

Instances

Eq Dec
Data Dec
Show Dec
Ppr Dec
Typeable * Dec

data TySynEqn Source

One equation of a type family instance or closed type family. The arguments are the left-hand-side type patterns and the right-hand-side result.

Constructors

TySynEqn [Type] Type

Instances

Eq TySynEqn
Data TySynEqn
Show TySynEqn
Typeable * TySynEqn

data FunDep Source

Constructors

FunDep [Name] [Name]

Instances

Eq FunDep
Data FunDep
Show FunDep
Ppr FunDep
Typeable * FunDep

data FamFlavour Source

Constructors

TypeFam
DataFam

Instances

Eq FamFlavour
Data FamFlavour
Show FamFlavour
Ppr FamFlavour
Typeable * FamFlavour

data Foreign Source

Constructors

ImportF Callconv Safety String Name Type
ExportF Callconv String Name Type

Instances

Eq Foreign
Data Foreign
Show Foreign
Ppr Foreign
Typeable * Foreign

data Callconv Source

Constructors

CCall
StdCall

Instances

Eq Callconv
Data Callconv
Show Callconv
Typeable * Callconv

data Safety Source

Constructors

Unsafe
Safe
Interruptible

Instances

Eq Safety
Data Safety
Show Safety
Typeable * Safety

data Pragma Source

Constructors

InlineP Name Inline RuleMatch Phases
SpecialiseP Name Type (Maybe Inline) Phases
SpecialiseInstP Type
RuleP String [RuleBndr] Exp Exp Phases
AnnP AnnTarget Exp

Instances

Eq Pragma
Data Pragma
Show Pragma
Ppr Pragma
Typeable * Pragma

data Inline Source

Constructors

NoInline
Inline
Inlinable

Instances

Eq Inline
Data Inline
Show Inline
Ppr Inline
Typeable * Inline

data RuleMatch Source

Constructors

ConLike
FunLike

Instances

Eq RuleMatch
Data RuleMatch
Show RuleMatch
Ppr RuleMatch
Typeable * RuleMatch

data Phases Source

Constructors

AllPhases
FromPhase Int
BeforePhase Int

Instances

Eq Phases
Data Phases
Show Phases
Ppr Phases
Typeable * Phases

data RuleBndr Source

Constructors

RuleVar Name
TypedRuleVar Name Type

Instances

Eq RuleBndr
Data RuleBndr
Show RuleBndr
Ppr RuleBndr
Typeable * RuleBndr

data AnnTarget Source

Constructors

ModuleAnnotation
TypeAnnotation Name
ValueAnnotation Name

Instances

Eq AnnTarget
Data AnnTarget
Show AnnTarget
Typeable * AnnTarget

type Cxt Source

Arguments

= [Pred]

(Eq a, Ord b)

data Pred Source

Constructors

ClassP Name [Type]	Eq (Int, a)
EqualP Type Type	F a ~ Bool

Instances

Eq Pred
Data Pred
Show Pred
Ppr Pred
Typeable * Pred

data Strict Source

Constructors

IsStrict
NotStrict
Unpacked

Instances

Eq Strict
Data Strict
Show Strict
Typeable * Strict

data Con Source

Constructors

NormalC Name [StrictType]	C Int a
RecC Name [VarStrictType]	C { v :: Int, w :: a }
InfixC StrictType Name StrictType	Int :+ a
ForallC [TyVarBndr] Cxt Con	forall a. Eq a => C [a]

Instances

Eq Con
Data Con
Show Con
Ppr Con
Typeable * Con

type StrictType = (Strict, Type)Source

type VarStrictType = (Name, Strict, Type)Source

data Type Source

Constructors

ForallT [TyVarBndr] Cxt Type	forall <vars>. <ctxt> -> <type>
AppT Type Type	T a b
SigT Type Kind	t :: k
VarT Name	a
ConT Name	T
PromotedT Name	'T
TupleT Int	(,), (,,), etc.
UnboxedTupleT Int	(#,#), (#,,#), etc.
ArrowT	->
ListT	[]
PromotedTupleT Int	'(), '(,), '(,,), etc.
PromotedNilT	'[]
PromotedConsT	(':)
StarT	*
ConstraintT	Constraint
LitT TyLit	0,1,2, etc.

Instances

Eq Type
Data Type
Show Type
Ppr Type
Typeable * Type

data TyVarBndr Source

Constructors

PlainTV Name	a
KindedTV Name Kind	(a :: k)

Instances

Eq TyVarBndr
Data TyVarBndr
Show TyVarBndr
Ppr TyVarBndr
Typeable * TyVarBndr

data TyLit Source

Constructors

NumTyLit Integer	2
StrTyLit String	Hello

Instances

Eq TyLit
Data TyLit
Show TyLit
Ppr TyLit
Typeable * TyLit

data Role Source

Role annotations

Constructors

NominalR	nominal
RepresentationalR	representational
PhantomR	phantom
InferR	_

Instances

Eq Role
Data Role
Show Role
Ppr Role
Typeable * Role

data AnnLookup Source

Annotation target for reifyAnnotations

Constructors

AnnLookupModule Module
AnnLookupName Name

Instances

Eq AnnLookup
Data AnnLookup
Show AnnLookup
Typeable * AnnLookup

type Kind = Type Source

To avoid duplication between kinds and types, they are defined to be the same. Naturally, you would never have a type be StarT and you would never have a kind be SigT, but many of the other constructors are shared. Note that the kind Bool is denoted with ConT, not PromotedT. Similarly, tuple kinds are made with TupleT, not PromotedTupleT.

cmpEq :: Ordering -> Bool Source

thenCmp :: Ordering -> Ordering -> Ordering Source