266 lines
9.1 KiB
Idris
266 lines
9.1 KiB
Idris
module Quox.Whnf.Interface
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import public Quox.No
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import public Quox.Log
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import public Quox.Syntax
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import public Quox.Definition
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import public Quox.Typing.Context
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import public Quox.Typing.Error
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import public Data.Maybe
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import public Control.Eff
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%default total
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public export
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Whnf : List (Type -> Type)
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Whnf = [Except Error, NameGen, Log]
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public export
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0 RedexTest : TermLike -> Type
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RedexTest tm =
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{0 d, n : Nat} -> Definitions -> WhnfContext d n -> SQty -> tm d n -> Bool
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public export
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interface CanWhnf (0 tm : TermLike) (0 isRedex : RedexTest tm) | tm
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where
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whnf, whnfNoLog :
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(defs : Definitions) -> (ctx : WhnfContext d n) -> (q : SQty) ->
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tm d n -> Eff Whnf (Subset (tm d n) (No . isRedex defs ctx q))
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-- having isRedex be part of the class header, and needing to be explicitly
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-- quantified on every use since idris can't infer its type, is a little ugly.
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-- but none of the alternatives i've thought of so far work. e.g. in some
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-- cases idris can't tell that `isRedex` and `isRedexT` are the same thing
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public export %inline
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whnf0, whnfNoLog0 :
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{0 isRedex : RedexTest tm} -> CanWhnf tm isRedex =>
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Definitions -> WhnfContext d n -> SQty -> tm d n -> Eff Whnf (tm d n)
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whnf0 defs ctx q t = fst <$> whnf defs ctx q t
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whnfNoLog0 defs ctx q t = fst <$> whnfNoLog defs ctx q t
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public export
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0 IsRedex, NotRedex : {isRedex : RedexTest tm} -> CanWhnf tm isRedex =>
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Definitions -> WhnfContext d n -> SQty -> Pred (tm d n)
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IsRedex defs ctx q = So . isRedex defs ctx q
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NotRedex defs ctx q = No . isRedex defs ctx q
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public export
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0 NonRedex : (tm : TermLike) -> {isRedex : RedexTest tm} ->
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CanWhnf tm isRedex => (d, n : Nat) ->
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Definitions -> WhnfContext d n -> SQty -> Type
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NonRedex tm d n defs ctx q = Subset (tm d n) (NotRedex defs ctx q)
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public export %inline
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nred : {0 isRedex : RedexTest tm} -> (0 _ : CanWhnf tm isRedex) =>
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(t : tm d n) -> (0 nr : NotRedex defs ctx q t) =>
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NonRedex tm d n defs ctx q
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nred t = Element t nr
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||| an expression like `(λ x ⇒ s) ∷ π.(x : A) → B`
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public export %inline
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isLamHead : Elim {} -> Bool
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isLamHead (Ann (Lam {}) (Pi {}) _) = True
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isLamHead (Coe {}) = True
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isLamHead _ = False
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||| an expression like `(δ 𝑖 ⇒ s) ∷ Eq (𝑖 ⇒ A) s t`
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public export %inline
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isDLamHead : Elim {} -> Bool
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isDLamHead (Ann (DLam {}) (Eq {}) _) = True
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isDLamHead (Coe {}) = True
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isDLamHead _ = False
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||| an expression like `(s, t) ∷ (x : A) × B`
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public export %inline
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isPairHead : Elim {} -> Bool
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isPairHead (Ann (Pair {}) (Sig {}) _) = True
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isPairHead (Coe {}) = True
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isPairHead _ = False
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||| an expression like `'a ∷ {a, b, c}`
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public export %inline
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isTagHead : Elim {} -> Bool
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isTagHead (Ann (Tag {}) (Enum {}) _) = True
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isTagHead (Coe {}) = True
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isTagHead _ = False
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||| an expression like `𝑘 ∷ ℕ` for a natural constant 𝑘, or `suc n ∷ ℕ`
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public export %inline
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isNatHead : Elim {} -> Bool
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isNatHead (Ann (Nat {}) (NAT {}) _) = True
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isNatHead (Ann (Succ {}) (NAT {}) _) = True
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isNatHead (Coe {}) = True
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isNatHead _ = False
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||| a natural constant, with or without an annotation
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public export %inline
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isNatConst : Term d n -> Bool
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isNatConst (Nat {}) = True
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isNatConst (E (Ann (Nat {}) _ _)) = True
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isNatConst _ = False
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||| an expression like `[s] ∷ [π. A]`
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public export %inline
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isBoxHead : Elim {} -> Bool
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isBoxHead (Ann (Box {}) (BOX {}) _) = True
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isBoxHead (Coe {}) = True
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isBoxHead _ = False
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||| an elimination in a term context
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public export %inline
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isE : Term {} -> Bool
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isE (E {}) = True
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isE _ = False
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||| an expression like `s ∷ A`
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public export %inline
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isAnn : Elim {} -> Bool
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isAnn (Ann {}) = True
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isAnn _ = False
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||| a syntactic type
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public export %inline
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isTyCon : Term {} -> Bool
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isTyCon (TYPE {}) = True
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isTyCon (IOState {}) = True
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isTyCon (Pi {}) = True
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isTyCon (Lam {}) = False
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isTyCon (Sig {}) = True
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isTyCon (Pair {}) = False
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isTyCon (Enum {}) = True
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isTyCon (Tag {}) = False
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isTyCon (Eq {}) = True
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isTyCon (DLam {}) = False
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isTyCon (NAT {}) = True
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isTyCon (Nat {}) = False
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isTyCon (Succ {}) = False
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isTyCon (STRING {}) = True
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isTyCon (Str {}) = False
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isTyCon (BOX {}) = True
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isTyCon (Box {}) = False
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isTyCon (Let {}) = False
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isTyCon (E {}) = False
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isTyCon (CloT {}) = False
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isTyCon (DCloT {}) = False
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||| a syntactic type, or a neutral
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public export %inline
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isTyConE : Term {} -> Bool
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isTyConE s = isTyCon s || isE s
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||| a syntactic type with an annotation `★ᵢ`
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public export %inline
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isAnnTyCon : Elim {} -> Bool
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isAnnTyCon (Ann ty (TYPE {}) _) = isTyCon ty
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isAnnTyCon _ = False
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||| 0 or 1
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public export %inline
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isK : Dim d -> Bool
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isK (K {}) = True
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isK _ = False
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||| true if `ty` is a type constructor, and `val` is a value of that type where
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||| a coercion can be reduced
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|||
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||| 1. `ty` is an atomic type
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||| 2. `ty` has an η law that is usable in this context
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||| (e.g. η for pairs only exists when σ=0, not when σ=1)
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||| 3. `val` is a constructor form
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public export %inline
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canPushCoe : SQty -> (ty, val : Term {}) -> Bool
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canPushCoe sg (TYPE {}) _ = True
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canPushCoe sg (IOState {}) _ = True
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canPushCoe sg (Pi {}) _ = True
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canPushCoe sg (Lam {}) _ = False
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canPushCoe sg (Sig {}) (Pair {}) = True
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canPushCoe sg (Sig {}) _ = False
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canPushCoe sg (Pair {}) _ = False
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canPushCoe sg (Enum {}) _ = True
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canPushCoe sg (Tag {}) _ = False
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canPushCoe sg (Eq {}) _ = True
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canPushCoe sg (DLam {}) _ = False
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canPushCoe sg (NAT {}) _ = True
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canPushCoe sg (Nat {}) _ = False
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canPushCoe sg (Succ {}) _ = False
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canPushCoe sg (STRING {}) _ = True
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canPushCoe sg (Str {}) _ = False
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canPushCoe sg (BOX {}) _ = True
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canPushCoe sg (Box {}) _ = False
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canPushCoe sg (Let {}) _ = False
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canPushCoe sg (E {}) _ = False
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canPushCoe sg (CloT {}) _ = False
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canPushCoe sg (DCloT {}) _ = False
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mutual
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||| a reducible elimination
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||| 1. a free variable, if its definition is known
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||| 2. a bound variable pointing to a `let`
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||| 3. an elimination whose head is reducible
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||| 4. an "active" elimination:
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||| an application whose head is an annotated lambda,
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||| a case expression whose head is an annotated constructor form, etc
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||| 5. a redundant annotation, or one whose term or type is reducible
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||| 6. a coercion `coe (𝑖 ⇒ A) @p @q s` where:
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||| a. `A` is reducible or a type constructor, or
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||| b. `𝑖` is not mentioned in `A`
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||| ([fixme] should be A‹0/𝑖› = A‹1/𝑖›), or
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||| c. `p = q`
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||| 7. a composition `comp A @p @q s @r {⋯}`
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||| where `p = q`, `r = 0`, or `r = 1`
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||| 8. a closure
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public export
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isRedexE : RedexTest Elim
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isRedexE defs ctx sg (F {x, u, _}) = isJust $ lookupElim0 x u defs
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isRedexE _ ctx sg (B {i, _}) = isJust (ctx.tctx !! i).term
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isRedexE defs ctx sg (App {fun, _}) =
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isRedexE defs ctx sg fun || isLamHead fun
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isRedexE defs ctx sg (CasePair {pair, _}) =
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isRedexE defs ctx sg pair || isPairHead pair || isYes (sg `decEq` SZero)
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isRedexE defs ctx sg (Fst pair _) =
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isRedexE defs ctx sg pair || isPairHead pair
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isRedexE defs ctx sg (Snd pair _) =
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isRedexE defs ctx sg pair || isPairHead pair
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isRedexE defs ctx sg (CaseEnum {tag, _}) =
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isRedexE defs ctx sg tag || isTagHead tag
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isRedexE defs ctx sg (CaseNat {nat, _}) =
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isRedexE defs ctx sg nat || isNatHead nat
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isRedexE defs ctx sg (CaseBox {box, _}) =
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isRedexE defs ctx sg box || isBoxHead box
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isRedexE defs ctx sg (DApp {fun, arg, _}) =
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isRedexE defs ctx sg fun || isDLamHead fun || isK arg
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isRedexE defs ctx sg (Ann {tm, ty, _}) =
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isE tm || isRedexT defs ctx sg tm || isRedexT defs ctx SZero ty
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isRedexE defs ctx sg (Coe {ty = S _ (N _), _}) = True
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isRedexE defs ctx sg (Coe {ty = S [< i] (Y ty), p, q, val, _}) =
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isRedexT defs (extendDim i ctx) SZero ty ||
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canPushCoe sg ty val || isYes (p `decEqv` q)
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isRedexE defs ctx sg (Comp {ty, p, q, r, _}) =
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isYes (p `decEqv` q) || isK r
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isRedexE defs ctx sg (TypeCase {ty, ret, _}) =
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isRedexE defs ctx sg ty || isRedexT defs ctx sg ret || isAnnTyCon ty
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isRedexE _ _ _ (CloE {}) = True
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isRedexE _ _ _ (DCloE {}) = True
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||| a reducible term
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||| 1. a reducible elimination, as `isRedexE`
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||| 2. an annotated elimination
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||| (the annotation is redundant in a checkable context)
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||| 3. a closure
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||| 4. `succ` applied to a natural constant
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||| 5. a `let` expression
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public export
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isRedexT : RedexTest Term
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isRedexT _ _ _ (CloT {}) = True
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isRedexT _ _ _ (DCloT {}) = True
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isRedexT _ _ _ (Let {}) = True
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isRedexT defs ctx sg (E {e, _}) = isAnn e || isRedexE defs ctx sg e
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isRedexT _ _ _ (Succ p {}) = isNatConst p
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isRedexT _ _ _ _ = False
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