Copyright	(C) 2012-2016 University of Twente 2017 Google Inc.
License	BSD2 (see the file LICENSE)
Maintainer	Christiaan Baaij <christiaan.baaij@gmail.com>
Safe Haskell	None
Language	Haskell2010

Clash.Core.Subst

Contents

Substitution into types
- Substitution environments
- Applying substitutions
Substitution into terms
- Substitution environments
- Applying substitutions
Variable renaming
Alpha equivalence
Orphan instances

Description

Capture-free substitution function for CoreHW

Synopsis

data TvSubst = TvSubst InScopeSet TvSubstEnv
type TvSubstEnv = VarEnv Type
extendTvSubst :: Subst -> TyVar -> Type -> Subst
extendTvSubstList :: Subst -> [(TyVar, Type)] -> Subst
substTy :: HasCallStack => Subst -> Type -> Type
substTyWith :: HasCallStack => [TyVar] -> [Type] -> Type -> Type
substTyInVar :: HasCallStack => Subst -> Var a -> Var a
substGlobalsInExistentials :: HasCallStack => InScopeSet -> [TyVar] -> [(TyVar, Type)] -> [TyVar]
substInExistentials :: HasCallStack => InScopeSet -> [TyVar] -> (TyVar, Type) -> [TyVar]
substInExistentialsList :: HasCallStack => InScopeSet -> [TyVar] -> [(TyVar, Type)] -> [TyVar]
data Subst = Subst {
- substInScope :: InScopeSet
- substTmEnv :: IdSubstEnv
- substTyEnv :: TvSubstEnv
- substGblEnv :: IdSubstEnv
}
mkSubst :: InScopeSet -> Subst
mkTvSubst :: InScopeSet -> VarEnv Type -> Subst
extendInScopeId :: Subst -> Id -> Subst
extendInScopeIdList :: Subst -> [Id] -> Subst
extendIdSubst :: Subst -> Id -> Term -> Subst
extendIdSubstList :: Subst -> [(Id, Term)] -> Subst
extendGblSubstList :: Subst -> [(Id, Term)] -> Subst
substTm :: HasCallStack => Doc () -> Subst -> Term -> Term
maybeSubstTm :: HasCallStack => Doc () -> Maybe Subst -> Term -> Term
substAlt :: HasCallStack => Doc () -> Subst -> (Pat, Term) -> (Pat, Term)
substId :: HasCallStack => Subst -> Id -> Id
deShadowTerm :: HasCallStack => InScopeSet -> Term -> Term
deShadowAlt :: HasCallStack => InScopeSet -> (Pat, Term) -> (Pat, Term)
freshenTm :: InScopeSet -> Term -> (InScopeSet, Term)
deshadowLetExpr :: HasCallStack => InScopeSet -> [LetBinding] -> Term -> ([LetBinding], Term)
aeqType :: Type -> Type -> Bool
aeqTerm :: Term -> Term -> Bool

Substitution into types

Substitution environments

data TvSubst Source #

Type substitution

The following invariants must hold:

The InScopeSet is needed only to guide the generation of fresh uniques
In particular, the kind of the type variables in the InScopeSet is not relevant.
The substitution is only applied once

Note [Apply Once]

We might instantiate forall a b. ty with the types [a, b] or [b, a]. So the substitution might go like [a -> b, b -> a]. A similar situation arises in terms when we find a redex like (a -> b -> e) b a. Then we also end up with a substitution that permutes variables. Other variations happen to; for example [a -> (a,b)].

SO A TvSubst MUST BE APPLIED PRECISELY ONCE, OR THINGS MIGHT LOOP

Note [The substitution invariant]

When calling (substTy subst ty) it should be the case that the InScopeSet is a superset of both:

The free variables of the range of the substitution
The free variables of ty minus the domain of the substitution

Constructors

TvSubst InScopeSet TvSubstEnv

Instances

Instances details

ClashPretty TvSubst Source #
Instance details Defined in Clash.Core.Subst Methods clashPretty :: TvSubst -> Doc () Source #

type TvSubstEnv = VarEnv Type Source #

A substitution of Types for TyVars

Note [Extending the TvSubstEnv] See TvSubst for the invariants that must hold

This invariant allows a short-cut when the subst env is empty: if the TvSubstEnv is empty, i.e. nullVarEnv TvSubstEnv holds, then (substTy subst ty) does nothing.

For example, consider:

(a -> b(a ~ Int) -> ... b ...) Int

We substitute Int for a. The Unique of b does not change, but nevertheless we add b to the TvSubstEnv because b's kind does change

This invariant has several consequences:

In substTyVarBndr, we extend TvSubstEnv if the unique has changed, or if the kind has changed
In substTyVar, we do not need to consult the InScopeSet; the TvSubstEnv is enough
In substTy, we can short-circuit when TvSubstEnv is empty

extendTvSubst :: Subst -> TyVar -> Type -> Subst Source #

Extend the substitution environment with a new TyVar substitution

extendTvSubstList :: Subst -> [(TyVar, Type)] -> Subst Source #

Extend the substitution environment with a list of TyVar substitutions

Applying substitutions

substTy :: HasCallStack => Subst -> Type -> Type Source #

Substitute within a Type

The substitution has to satisfy the invariant described in TvSubsts Note [The substitution environment]

substTyWith :: HasCallStack => [TyVar] -> [Type] -> Type -> Type Source #

Type substitution, see zipTvSubst

Works only if the domain of the substitution is superset of the type being substituted into

substTyInVar :: HasCallStack => Subst -> Var a -> Var a Source #

Substitute within a TyVar. See substTy.

substGlobalsInExistentials Source #

Arguments

:: HasCallStack
=> InScopeSet	Variables in scope
-> [TyVar]	List of existentials to apply the substitution for
-> [(TyVar, Type)]	Substitutions
-> [TyVar]

substInExistentials Source #

Arguments

:: HasCallStack
=> InScopeSet	Variables in scope
-> [TyVar]	List of existentials to apply the substitution for
-> (TyVar, Type)	Substitution
-> [TyVar]

Safely substitute a type variable in a list of existentials. This function will account for cases where existentials shadow each other.

substInExistentialsList Source #

Arguments

:: HasCallStack
=> InScopeSet	Variables in scope
-> [TyVar]	List of existentials to apply the substitution for
-> [(TyVar, Type)]	Substitutions
-> [TyVar]

Safely substitute type variables in a list of existentials. This function will account for cases where existentials shadow each other.

Substitution into terms

Substitution environments

data Subst Source #

A substitution environment containing containing both Id and TyVar substitutions.

Some invariants apply to how you use the substitution:

The InScopeSet contains at least those Ids and TyVars that will be in scope after applying the substitution to a term. Precisely, the in-scope set must be a superset of the free variables of the substitution range that might possibly clash with locally-bound variables in the thing being substituted in.
You may only apply the substitution once. See TvSubst

There are various ways of setting up the in-scope set such that the first of of these invariants holds:

Arrange that the in-scope set really is all the things in scope
Arrange that it's the free vars of the range of the substitution
Make it empty, if you know that all the free variables of the substitution are fresh, and hence can´t possibly clash

Constructors

Subst
Fields substInScope :: InScopeSet substTmEnv :: IdSubstEnv substTyEnv :: TvSubstEnv substGblEnv :: IdSubstEnv

mkSubst :: InScopeSet -> Subst Source #

An empty substitution, starting the variables currently in scope

mkTvSubst :: InScopeSet -> VarEnv Type -> Subst Source #

Create a type substitution

extendInScopeId :: Subst -> Id -> Subst Source #

Add an Id to the in-scope set: as a side effect, remove any existing substitutions for it.

extendInScopeIdList :: Subst -> [Id] -> Subst Source #

Add Ids to the in-scope set. See also extendInScopeId

extendIdSubst :: Subst -> Id -> Term -> Subst Source #

Extend the substitution environment with a new Id substitution

extendIdSubstList :: Subst -> [(Id, Term)] -> Subst Source #

Extend the substitution environment with a list of Id substitutions

extendGblSubstList :: Subst -> [(Id, Term)] -> Subst Source #

Extend the substitution environment with a list of global Id substitutions

Applying substitutions

substTm :: HasCallStack => Doc () -> Subst -> Term -> Term Source #

Substitute within a Term

maybeSubstTm :: HasCallStack => Doc () -> Maybe Subst -> Term -> Term Source #

Substitute within a Term. Just return original term if given substitution is Nothing.

substAlt Source #

Arguments

:: HasCallStack
=> Doc ()
-> Subst	The substitution
-> (Pat, Term)	The alternative in which to apply the substitution
-> (Pat, Term)

Substitute within a case-alternative

substId :: HasCallStack => Subst -> Id -> Id Source #

Variable renaming

deShadowTerm :: HasCallStack => InScopeSet -> Term -> Term Source #

Ensure that non of the binders in an expression shadow each-other, nor conflict with he in-scope set

deShadowAlt :: HasCallStack => InScopeSet -> (Pat, Term) -> (Pat, Term) Source #

Ensure that non of the binders in an alternative shadow each-other, nor conflict with the in-scope set

freshenTm Source #

Arguments

:: InScopeSet	Current set of variables in scope
-> Term
-> (InScopeSet, Term)

A much stronger variant of deShadowTerm that ensures that all bound variables are unique.

Also returns an extended InScopeSet additionally containing the (renamed) unique bound variables of the term.

deshadowLetExpr Source #

Arguments

:: HasCallStack
=> InScopeSet	Current InScopeSet
-> [LetBinding]	Bindings of the let-expression
-> Term	The body of the let-expression
-> ([LetBinding], Term)	Deshadowed let-bindings, where let-bound expressions and the let-body properly reference the renamed variables

Ensure that non of the let-bindings of a let-expression shadow w.r.t the in-scope set

Alpha equivalence

aeqType :: Type -> Type -> Bool Source #

Alpha equality for types

aeqTerm :: Term -> Term -> Bool Source #

Alpha equality for terms

Orphan instances

Eq Type Source #
Instance details Methods (==) :: Type -> Type -> Bool # (/=) :: Type -> Type -> Bool #
Eq Term Source #
Instance details Methods (==) :: Term -> Term -> Bool # (/=) :: Term -> Term -> Bool #
Ord Type Source #
Instance details Methods compare :: Type -> Type -> Ordering # (<) :: Type -> Type -> Bool # (<=) :: Type -> Type -> Bool # (>) :: Type -> Type -> Bool # (>=) :: Type -> Type -> Bool # max :: Type -> Type -> Type # min :: Type -> Type -> Type #
Ord Term Source #
Instance details Methods compare :: Term -> Term -> Ordering # (<) :: Term -> Term -> Bool # (<=) :: Term -> Term -> Bool # (>) :: Term -> Term -> Bool # (>=) :: Term -> Term -> Bool # max :: Term -> Term -> Term # min :: Term -> Term -> Term #