unbound-0.5.0: Generic support for programming with names and binders

LicenseBSD-like (see LICENSE)
MaintainerBrent Yorgey <byorgey@cis.upenn.edu>
Stabilityexperimental
PortabilityGHC only
Safe HaskellNone
LanguageHaskell2010

Unbound.LocallyNameless.Types

Contents

Description

Special type combinators for specifying binding structure.

Synopsis

Documentation

data GenBind order card p t Source #

Generic binding combinator for a pattern p within a term t. Flexible over the order and cardinality of the variables bound in the pattern

Constructors

B p t 

Instances

(Rep order0, Rep card0, Rep p0, Rep t0, Sat (ctx0 p0), Sat (ctx0 t0)) => Rep1 ctx0 (GenBind order0 card0 p0 t0) Source # 

Methods

rep1 :: R1 ctx0 (GenBind order0 card0 p0 t0) #

(Rep order, Rep card, Alpha p, Alpha t, Subst b p, Subst b t) => Subst b (GenBind order card p t) Source # 

Methods

isvar :: GenBind order card p t -> Maybe (SubstName (GenBind order card p t) b) Source #

isCoerceVar :: GenBind order card p t -> Maybe (SubstCoerce (GenBind order card p t) b) Source #

subst :: Name b -> b -> GenBind order card p t -> GenBind order card p t Source #

substs :: [(Name b, b)] -> GenBind order card p t -> GenBind order card p t Source #

substPat :: AlphaCtx -> b -> GenBind order card p t -> GenBind order card p t Source #

substPats :: Proxy * b -> AlphaCtx -> [Dyn] -> GenBind order card p t -> GenBind order card p t Source #

(Show a, Show b) => Show (GenBind order card a b) Source # 

Methods

showsPrec :: Int -> GenBind order card a b -> ShowS #

show :: GenBind order card a b -> String #

showList :: [GenBind order card a b] -> ShowS #

(Rep order0, Rep card0, Rep p0, Rep t0) => Rep (GenBind order0 card0 p0 t0) Source # 

Methods

rep :: R (GenBind order0 card0 p0 t0) #

(Binary p, Binary t) => Binary (GenBind order card p t) Source # 

Methods

put :: GenBind order card p t -> Put #

get :: Get (GenBind order card p t) #

putList :: [GenBind order card p t] -> Put #

(Rep order, Rep card, Alpha p, Alpha t) => Alpha (GenBind order card p t) Source # 

Methods

swaps' :: AlphaCtx -> Perm AnyName -> GenBind order card p t -> GenBind order card p t Source #

fv' :: Collection f => AlphaCtx -> GenBind order card p t -> f AnyName Source #

lfreshen' :: LFresh m => AlphaCtx -> GenBind order card p t -> (GenBind order card p t -> Perm AnyName -> m b) -> m b Source #

freshen' :: Fresh m => AlphaCtx -> GenBind order card p t -> m (GenBind order card p t, Perm AnyName) Source #

aeq' :: AlphaCtx -> GenBind order card p t -> GenBind order card p t -> Bool Source #

acompare' :: AlphaCtx -> GenBind order card p t -> GenBind order card p t -> Ordering Source #

close :: Alpha b => AlphaCtx -> b -> GenBind order card p t -> GenBind order card p t Source #

open :: Alpha b => AlphaCtx -> b -> GenBind order card p t -> GenBind order card p t Source #

isPat :: GenBind order card p t -> Maybe [AnyName] Source #

isTerm :: GenBind order card p t -> Bool Source #

isEmbed :: GenBind order card p t -> Bool Source #

nthpatrec :: GenBind order card p t -> NthCont Source #

findpatrec :: GenBind order card p t -> AnyName -> FindResult Source #

type Bind p t = GenBind StrictOrder StrictCard p t Source #

The most fundamental combinator for expressing binding structure is Bind. The term type Bind p t represents a pattern p paired with a term t, where names in p are bound within t.

Like Name, Bind is also abstract. You can create bindings using bind and take them apart with unbind and friends.

type SetBind p t = GenBind RelaxedOrder StrictCard p t Source #

A variant of Bind where alpha-equivalence allows multiple variables bound in the same pattern to be reordered

type SetPlusBind p t = GenBind RelaxedOrder RelaxedCard p t Source #

A variant of Bind where alpha-equivalence allows multiple variables bound in the same pattern to be reordered, and allows the binding of unused variables For example, { a b c } . a b aeq { b a } . a b

data Rebind p1 p2 Source #

Rebind allows for nested bindings. If p1 and p2 are pattern types, then Rebind p1 p2 is also a pattern type, similar to the pattern type (p1,p2) except that p1 scopes over p2. That is, names within terms embedded in p2 may refer to binders in p1.

Constructors

R p1 p2 

Instances

(Rep p10, Rep p20, Sat (ctx0 p10), Sat (ctx0 p20)) => Rep1 ctx0 (Rebind p10 p20) Source # 

Methods

rep1 :: R1 ctx0 (Rebind p10 p20) #

(Alpha p, Alpha q, Subst b p, Subst b q) => Subst b (Rebind p q) Source # 

Methods

isvar :: Rebind p q -> Maybe (SubstName (Rebind p q) b) Source #

isCoerceVar :: Rebind p q -> Maybe (SubstCoerce (Rebind p q) b) Source #

subst :: Name b -> b -> Rebind p q -> Rebind p q Source #

substs :: [(Name b, b)] -> Rebind p q -> Rebind p q Source #

substPat :: AlphaCtx -> b -> Rebind p q -> Rebind p q Source #

substPats :: Proxy * b -> AlphaCtx -> [Dyn] -> Rebind p q -> Rebind p q Source #

(Show a, Show b) => Show (Rebind a b) Source # 

Methods

showsPrec :: Int -> Rebind a b -> ShowS #

show :: Rebind a b -> String #

showList :: [Rebind a b] -> ShowS #

(Rep p10, Rep p20) => Rep (Rebind p10 p20) Source # 

Methods

rep :: R (Rebind p10 p20) #

(Binary p1, Binary p2) => Binary (Rebind p1 p2) Source # 

Methods

put :: Rebind p1 p2 -> Put #

get :: Get (Rebind p1 p2) #

putList :: [Rebind p1 p2] -> Put #

(Alpha p, Alpha q) => Alpha (Rebind p q) Source # 

Methods

swaps' :: AlphaCtx -> Perm AnyName -> Rebind p q -> Rebind p q Source #

fv' :: Collection f => AlphaCtx -> Rebind p q -> f AnyName Source #

lfreshen' :: LFresh m => AlphaCtx -> Rebind p q -> (Rebind p q -> Perm AnyName -> m b) -> m b Source #

freshen' :: Fresh m => AlphaCtx -> Rebind p q -> m (Rebind p q, Perm AnyName) Source #

aeq' :: AlphaCtx -> Rebind p q -> Rebind p q -> Bool Source #

acompare' :: AlphaCtx -> Rebind p q -> Rebind p q -> Ordering Source #

close :: Alpha b => AlphaCtx -> b -> Rebind p q -> Rebind p q Source #

open :: Alpha b => AlphaCtx -> b -> Rebind p q -> Rebind p q Source #

isPat :: Rebind p q -> Maybe [AnyName] Source #

isTerm :: Rebind p q -> Bool Source #

isEmbed :: Rebind p q -> Bool Source #

nthpatrec :: Rebind p q -> NthCont Source #

findpatrec :: Rebind p q -> AnyName -> FindResult Source #

data Rec p Source #

If p is a pattern type, then Rec p is also a pattern type, which is recursive in the sense that p may bind names in terms embedded within itself. Useful for encoding e.g. lectrec and Agda's dot notation.

Constructors

Rec p 

Instances

(Rep p0, Sat (ctx0 p0)) => Rep1 ctx0 (Rec p0) Source # 

Methods

rep1 :: R1 ctx0 (Rec p0) #

(Alpha p, Subst b p) => Subst b (Rec p) Source # 

Methods

isvar :: Rec p -> Maybe (SubstName (Rec p) b) Source #

isCoerceVar :: Rec p -> Maybe (SubstCoerce (Rec p) b) Source #

subst :: Name b -> b -> Rec p -> Rec p Source #

substs :: [(Name b, b)] -> Rec p -> Rec p Source #

substPat :: AlphaCtx -> b -> Rec p -> Rec p Source #

substPats :: Proxy * b -> AlphaCtx -> [Dyn] -> Rec p -> Rec p Source #

Show a => Show (Rec a) Source # 

Methods

showsPrec :: Int -> Rec a -> ShowS #

show :: Rec a -> String #

showList :: [Rec a] -> ShowS #

Rep p0 => Rep (Rec p0) Source # 

Methods

rep :: R (Rec p0) #

Alpha p => Alpha (Rec p) Source # 

Methods

swaps' :: AlphaCtx -> Perm AnyName -> Rec p -> Rec p Source #

fv' :: Collection f => AlphaCtx -> Rec p -> f AnyName Source #

lfreshen' :: LFresh m => AlphaCtx -> Rec p -> (Rec p -> Perm AnyName -> m b) -> m b Source #

freshen' :: Fresh m => AlphaCtx -> Rec p -> m (Rec p, Perm AnyName) Source #

aeq' :: AlphaCtx -> Rec p -> Rec p -> Bool Source #

acompare' :: AlphaCtx -> Rec p -> Rec p -> Ordering Source #

close :: Alpha b => AlphaCtx -> b -> Rec p -> Rec p Source #

open :: Alpha b => AlphaCtx -> b -> Rec p -> Rec p Source #

isPat :: Rec p -> Maybe [AnyName] Source #

isTerm :: Rec p -> Bool Source #

isEmbed :: Rec p -> Bool Source #

nthpatrec :: Rec p -> NthCont Source #

findpatrec :: Rec p -> AnyName -> FindResult Source #

newtype TRec p Source #

TRec is a standalone variant of Rec: the only difference is that whereas Rec p is a pattern type, TRec p is a term type. It is isomorphic to Bind (Rec p) ().

Note that TRec corresponds to Pottier's abstraction construct from alpha-Caml. In this context, Embed t corresponds to alpha-Caml's inner t, and Shift (Embed t) corresponds to alpha-Caml's outer t.

Constructors

TRec (Bind (Rec p) ()) 

Instances

Show a => Show (TRec a) Source # 

Methods

showsPrec :: Int -> TRec a -> ShowS #

show :: TRec a -> String #

showList :: [TRec a] -> ShowS #

newtype Embed t Source #

Embed allows for terms to be embedded within patterns. Such embedded terms do not bind names along with the rest of the pattern. For examples, see the tutorial or examples directories.

If t is a term type, then Embed t is a pattern type.

Embed is not abstract since it involves no binding, and hence it is safe to manipulate directly. To create and destruct Embed terms, you may use the Embed constructor directly. (You may also use the functions embed and unembed, which additionally can construct or destruct any number of enclosing Shifts at the same time.)

Constructors

Embed t 

Instances

(Rep t0, Sat (ctx0 t0)) => Rep1 ctx0 (Embed t0) Source # 

Methods

rep1 :: R1 ctx0 (Embed t0) #

(Alpha t, Subst b t) => Subst b (Embed t) Source # 

Methods

isvar :: Embed t -> Maybe (SubstName (Embed t) b) Source #

isCoerceVar :: Embed t -> Maybe (SubstCoerce (Embed t) b) Source #

subst :: Name b -> b -> Embed t -> Embed t Source #

substs :: [(Name b, b)] -> Embed t -> Embed t Source #

substPat :: AlphaCtx -> b -> Embed t -> Embed t Source #

substPats :: Proxy * b -> AlphaCtx -> [Dyn] -> Embed t -> Embed t Source #

Eq t => Eq (Embed t) Source # 

Methods

(==) :: Embed t -> Embed t -> Bool #

(/=) :: Embed t -> Embed t -> Bool #

Show a => Show (Embed a) Source # 

Methods

showsPrec :: Int -> Embed a -> ShowS #

show :: Embed a -> String #

showList :: [Embed a] -> ShowS #

Rep t0 => Rep (Embed t0) Source # 

Methods

rep :: R (Embed t0) #

Binary p => Binary (Embed p) Source # 

Methods

put :: Embed p -> Put #

get :: Get (Embed p) #

putList :: [Embed p] -> Put #

IsEmbed (Embed t) Source # 

Associated Types

type Embedded (Embed t) :: * Source #

Alpha t => Alpha (Embed t) Source # 
type Embedded (Embed t) Source # 
type Embedded (Embed t) = t

newtype Shift p Source #

Shift the scope of an embedded term one level outwards.

Constructors

Shift p 

Instances

(Rep p0, Sat (ctx0 p0)) => Rep1 ctx0 (Shift p0) Source # 

Methods

rep1 :: R1 ctx0 (Shift p0) #

(Alpha a, Subst b a) => Subst b (Shift a) Source # 

Methods

isvar :: Shift a -> Maybe (SubstName (Shift a) b) Source #

isCoerceVar :: Shift a -> Maybe (SubstCoerce (Shift a) b) Source #

subst :: Name b -> b -> Shift a -> Shift a Source #

substs :: [(Name b, b)] -> Shift a -> Shift a Source #

substPat :: AlphaCtx -> b -> Shift a -> Shift a Source #

substPats :: Proxy * b -> AlphaCtx -> [Dyn] -> Shift a -> Shift a Source #

Eq p => Eq (Shift p) Source # 

Methods

(==) :: Shift p -> Shift p -> Bool #

(/=) :: Shift p -> Shift p -> Bool #

Show a => Show (Shift a) Source # 

Methods

showsPrec :: Int -> Shift a -> ShowS #

show :: Shift a -> String #

showList :: [Shift a] -> ShowS #

Rep p0 => Rep (Shift p0) Source # 

Methods

rep :: R (Shift p0) #

IsEmbed e => IsEmbed (Shift e) Source # 

Associated Types

type Embedded (Shift e) :: * Source #

Alpha a => Alpha (Shift a) Source # 
type Embedded (Shift e) Source # 
type Embedded (Shift e) = Embedded e

Pay no attention to the man behind the curtain

These type representation objects are exported so they can be referenced by auto-generated code. Please pretend they do not exist.

rGenBind :: forall order card p t. (Rep order, Rep card, Rep p, Rep t) => R (GenBind order card p t) Source #

rRebind :: forall p1 p2. (Rep p1, Rep p2) => R (Rebind p1 p2) Source #

rEmbed :: forall t. Rep t => R (Embed t) Source #

rRec :: forall p. Rep p => R (Rec p) Source #

rShift :: forall p. Rep p => R (Shift p) Source #

Orphan instances

Rep a => Binary (Name a) Source # 

Methods

put :: Name a -> Put #

get :: Get (Name a) #

putList :: [Name a] -> Put #