rename term types to expr_term
and type_term
and type_abs
->type_univ
, type_app
->type_spec
This commit is contained in:
parent
ec1a2ab4a4
commit
292234c247
6 changed files with 91 additions and 83 deletions
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@ -1,9 +1,17 @@
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From Coq Require Import Strings.String.
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Require Import terms.
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Require Import subst.
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Require Import smallstep.
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Include Terms.
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Include Subst.
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Include Smallstep.
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(* let bb_zero = Λα ↦ λs: α->α ↦ λz: α ↦ z
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* ∀α.(α->α)->α->α
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*)
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Definition bb_zero : expr :=
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Definition bb_zero : expr_term :=
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(expr_ty_abs "α"
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(expr_tm_abs "s" (type_fun (type_var "α") (type_var "α"))
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(expr_tm_abs "z" (type_var "α")
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@ -11,7 +19,7 @@ Definition bb_zero : expr :=
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(* let bb_one = Λα ↦ λs: α->α ↦ λz: α ↦ s z
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*)
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Definition bb_one : expr :=
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Definition bb_one : expr_term :=
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(expr_ty_abs "α"
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(expr_tm_abs "s" (type_fun (type_var "α") (type_var "α"))
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(expr_tm_abs "z" (type_var "α")
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@ -19,21 +27,21 @@ Definition bb_one : expr :=
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(* let bb_two = Λα ↦ λs: α->α ↦ λz: α ↦ s (s z)
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*)
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Definition bb_two : expr :=
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Definition bb_two : expr_term :=
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(expr_ty_abs "α"
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(expr_tm_abs "s" (type_fun (type_var "α") (type_var "α"))
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(expr_tm_abs "z" (type_var "α")
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(expr_tm_app (expr_var "s") (expr_tm_app (expr_var "s") (expr_var "z")))))).
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Definition bb_succ : expr :=
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(expr_tm_abs "n" (type_rung (type_id "ℕ")
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(type_rung (type_id "BBNat")
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(type_abs "α"
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Definition bb_succ : expr_term :=
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(expr_tm_abs "n" (type_ladder (type_id "ℕ")
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(type_ladder (type_id "BBNat")
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(type_univ "α"
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(type_fun (type_fun (type_var "α") (type_var "α"))
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(type_fun (type_var "α") (type_var "α"))))))
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(expr_ascend (type_rung (type_id "ℕ") (type_id "BBNat"))
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(expr_ascend (type_ladder (type_id "ℕ") (type_id "BBNat"))
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(expr_ty_abs "α"
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(expr_tm_abs "s" (type_fun (type_var "α") (type_var "α"))
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(expr_tm_abs "z" (type_var "α")
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@ -43,17 +51,17 @@ Definition bb_succ : expr :=
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(expr_var "s"))
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(expr_var "z")))))))).
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Definition e1 : expr :=
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(expr_let "bb-zero" (type_rung (type_id "ℕ")
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(type_rung (type_id "BBNat")
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(type_abs "α"
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Definition e1 : expr_term :=
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(expr_let "bb-zero" (type_ladder (type_id "ℕ")
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(type_ladder (type_id "BBNat")
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(type_univ "α"
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(type_fun (type_fun (type_var "α") (type_var "α"))
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(type_fun (type_var "α") (type_var "α"))))))
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bb_zero
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(expr_tm_app (expr_tm_app (expr_var "+") (expr_var "bb-zero")) (expr_var "bb-zero"))
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).
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Definition t1 : expr := (expr_tm_app (expr_var "x") (expr_var "x")).
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Definition t1 : expr_term := (expr_tm_app (expr_var "x") (expr_var "x")).
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Compute (expr_subst "x"
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(expr_ty_abs "α" (expr_tm_abs "a" (type_var "α") (expr_var "a")))
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68
coq/equiv.v
68
coq/equiv.v
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@ -40,42 +40,42 @@ Module Equiv.
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(** Define all rewrite steps *)
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Reserved Notation "S '-->distribute-ladder' T" (at level 40).
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Inductive type_distribute_ladder : ladder_type -> ladder_type -> Prop :=
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Inductive type_distribute_ladder : type_term -> type_term -> Prop :=
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| L_DistributeOverApp : forall x y y',
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(type_app x (type_rung y y'))
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(type_spec x (type_ladder y y'))
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-->distribute-ladder
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(type_rung (type_app x y) (type_app x y'))
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(type_ladder (type_spec x y) (type_spec x y'))
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| L_DistributeOverFun1 : forall x x' y,
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(type_fun (type_rung x x') y)
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(type_fun (type_ladder x x') y)
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-->distribute-ladder
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(type_rung (type_fun x y) (type_fun x' y))
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(type_ladder (type_fun x y) (type_fun x' y))
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| L_DistributeOverFun2 : forall x y y',
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(type_fun x (type_rung y y'))
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(type_fun x (type_ladder y y'))
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-->distribute-ladder
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(type_rung (type_fun x y) (type_fun x y'))
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(type_ladder (type_fun x y) (type_fun x y'))
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where "S '-->distribute-ladder' T" := (type_distribute_ladder S T).
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Reserved Notation "S '-->condense-ladder' T" (at level 40).
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Inductive type_condense_ladder : ladder_type -> ladder_type -> Prop :=
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Inductive type_condense_ladder : type_term -> type_term -> Prop :=
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| L_CondenseOverApp : forall x y y',
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(type_rung (type_app x y) (type_app x y'))
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(type_ladder (type_spec x y) (type_spec x y'))
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-->condense-ladder
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(type_app x (type_rung y y'))
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(type_spec x (type_ladder y y'))
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| L_CondenseOverFun1 : forall x x' y,
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(type_rung (type_fun x y) (type_fun x' y))
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(type_ladder (type_fun x y) (type_fun x' y))
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-->condense-ladder
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(type_fun (type_rung x x') y)
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(type_fun (type_ladder x x') y)
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| L_CondenseOverFun2 : forall x y y',
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(type_rung (type_fun x y) (type_fun x y'))
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(type_ladder (type_fun x y) (type_fun x y'))
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-->condense-ladder
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(type_fun x (type_rung y y'))
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(type_fun x (type_ladder y y'))
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where "S '-->condense-ladder' T" := (type_condense_ladder S T).
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@ -114,7 +114,7 @@ Qed.
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(** Define the equivalence relation as reflexive, transitive hull. *)
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Reserved Notation " S '===' T " (at level 40).
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Inductive type_eq : ladder_type -> ladder_type -> Prop :=
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Inductive type_eq : type_term -> type_term -> Prop :=
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| L_Refl : forall x,
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x === x
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@ -164,7 +164,7 @@ Proof.
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Qed.
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(** "flat" types do not contain ladders *)
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Inductive type_is_flat : ladder_type -> Prop :=
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Inductive type_is_flat : type_term -> Prop :=
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| FlatUnit : (type_is_flat type_unit)
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| FlatVar : forall x, (type_is_flat (type_var x))
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| FlatNum : forall x, (type_is_flat (type_num x))
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@ -172,7 +172,7 @@ Inductive type_is_flat : ladder_type -> Prop :=
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| FlatApp : forall x y,
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(type_is_flat x) ->
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(type_is_flat y) ->
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(type_is_flat (type_app x y))
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(type_is_flat (type_spec x y))
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| FlatFun : forall x y,
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(type_is_flat x) ->
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@ -181,31 +181,31 @@ Inductive type_is_flat : ladder_type -> Prop :=
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| FlatSub : forall x v,
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(type_is_flat x) ->
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(type_is_flat (type_abs v x))
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(type_is_flat (type_univ v x))
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.
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(** Ladder Normal Form:
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exhaustive application of -->distribute-ladder
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*)
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Inductive type_is_lnf : ladder_type -> Prop :=
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| LNF : forall x : ladder_type,
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(not (exists y:ladder_type, x -->distribute-ladder y))
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Inductive type_is_lnf : type_term -> Prop :=
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| LNF : forall x : type_term,
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(not (exists y:type_term, x -->distribute-ladder y))
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-> (type_is_lnf x)
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.
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(** Parameter Normal Form:
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exhaustive application of -->condense-ladder
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*)
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Inductive type_is_pnf : ladder_type -> Prop :=
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| PNF : forall x : ladder_type,
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(not (exists y:ladder_type, x -->condense-ladder y))
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Inductive type_is_pnf : type_term -> Prop :=
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| PNF : forall x : type_term,
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(not (exists y:type_term, x -->condense-ladder y))
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-> (type_is_pnf x)
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.
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(** Any term in LNF either is flat, or is a ladder T1~T2 where T1 is flat and T2 is in LNF *)
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Lemma lnf_shape :
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forall τ:ladder_type,
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(type_is_lnf τ) -> ((type_is_flat τ) \/ (exists τ1 τ2, τ = (type_rung τ1 τ2) /\ (type_is_flat τ1) /\ (type_is_lnf τ2)))
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forall τ:type_term,
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(type_is_lnf τ) -> ((type_is_flat τ) \/ (exists τ1 τ2, τ = (type_ladder τ1 τ2) /\ (type_is_flat τ1) /\ (type_is_lnf τ2)))
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.
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Proof.
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intros τ H.
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apply LNF.
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admit.
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exists (type_abs s t).
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admit.
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exists (type_univ s t).
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split. apply L_Refl.
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apply LNF.
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@ -280,7 +282,7 @@ Admitted.
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*)
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Example example_flat_type :
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(type_is_flat (type_app (type_id "PosInt") (type_num 10))).
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(type_is_flat (type_spec (type_id "PosInt") (type_num 10))).
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Proof.
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apply FlatApp.
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apply FlatId.
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@ -289,16 +291,16 @@ Qed.
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Example example_lnf_type :
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(type_is_lnf
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(type_rung (type_app (type_id "Seq") (type_id "Char"))
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(type_app (type_id "Seq") (type_id "Byte")))).
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(type_ladder (type_spec (type_id "Seq") (type_id "Char"))
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(type_spec (type_id "Seq") (type_id "Byte")))).
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Proof.
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Admitted.
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Example example_type_eq :
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(type_app (type_id "Seq") (type_rung (type_id "Char") (type_id "Byte")))
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(type_spec (type_id "Seq") (type_ladder (type_id "Char") (type_id "Byte")))
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===
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(type_rung (type_app (type_id "Seq") (type_id "Char"))
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(type_app (type_id "Seq") (type_id "Byte"))).
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(type_ladder (type_spec (type_id "Seq") (type_id "Char"))
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(type_spec (type_id "Seq") (type_id "Byte"))).
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Proof.
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apply L_Distribute.
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apply L_DistributeOverApp.
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@ -11,7 +11,7 @@ Reserved Notation " s '-->α' t " (at level 40).
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Reserved Notation " s '-->β' t " (at level 40).
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Reserved Notation " s '-->δ' t " (at level 40).
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Inductive beta_step : expr -> expr -> Prop :=
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Inductive beta_step : expr_term -> expr_term -> Prop :=
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| E_AppLeft : forall e1 e1' e2,
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e1 -->β e1' ->
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(expr_tm_app e1 e2) -->β (expr_tm_app e1' e2)
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@ -43,7 +43,7 @@ Notation " s -->β* t " := (multi beta_step s t) (at level 40).
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*)
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(*
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Inductive delta_expand : expr -> expr -> Prop :=
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Inductive delta_expand : expr_term -> expr_term -> Prop :=
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| E_ImplicitCast
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(expr_tm_app e1 e2)
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*)
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13
coq/subst.v
13
coq/subst.v
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@ -6,18 +6,18 @@ Include Terms.
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Module Subst.
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(* scoped variable substitution in type terms *)
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Fixpoint type_subst (v:string) (n:ladder_type) (t0:ladder_type) :=
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Fixpoint type_subst (v:string) (n:type_term) (t0:type_term) :=
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match t0 with
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| type_var name => if (eqb v name) then n else t0
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| type_abs x t => if (eqb v x) then t0 else type_abs x (type_subst v n t)
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| type_app t1 t2 => (type_app (type_subst v n t1) (type_subst v n t2))
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| type_fun t1 t2 => (type_fun (type_subst v n t1) (type_subst v n t2))
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| type_rung t1 t2 => (type_rung (type_subst v n t1) (type_subst v n t2))
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| type_univ x t => if (eqb v x) then t0 else type_univ x (type_subst v n t)
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| type_spec t1 t2 => (type_spec (type_subst v n t1) (type_subst v n t2))
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| type_ladder t1 t2 => (type_ladder (type_subst v n t1) (type_subst v n t2))
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| t => t
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end.
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(* scoped variable substitution, replaces free occurences of v with n in expression e *)
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Fixpoint expr_subst (v:string) (n:expr) (e0:expr) :=
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Fixpoint expr_subst (v:string) (n:expr_term) (e0:expr_term) :=
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match e0 with
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| expr_var name => if (eqb v name) then n else e0
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| expr_ty_abs x e => if (eqb v x) then e0 else expr_ty_abs x (expr_subst v n e)
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end.
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(* replace only type variables in expression *)
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Fixpoint expr_specialize (v:string) (n:ladder_type) (e0:expr) :=
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Fixpoint expr_specialize (v:string) (n:type_term) (e0:expr_term) :=
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match e0 with
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| expr_ty_app e t => expr_ty_app (expr_specialize v n e) (type_subst v n t)
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| expr_ascend t e => expr_ascend (type_subst v n t) (expr_specialize v n e)
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@ -38,5 +38,4 @@ Fixpoint expr_specialize (v:string) (n:ladder_type) (e0:expr) :=
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| e => e
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end.
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End Subst.
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41
coq/terms.v
41
coq/terms.v
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@ -7,32 +7,31 @@ From Coq Require Import Strings.String.
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Module Terms.
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(* types *)
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Inductive ladder_type : Type :=
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| type_unit : ladder_type
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| type_id : string -> ladder_type
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| type_var : string -> ladder_type
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| type_num : nat -> ladder_type
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| type_abs : string -> ladder_type -> ladder_type
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| type_app : ladder_type -> ladder_type -> ladder_type
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| type_fun : ladder_type -> ladder_type -> ladder_type
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| type_rung : ladder_type -> ladder_type -> ladder_type
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Inductive type_term : Type :=
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| type_unit : type_term
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| type_id : string -> type_term
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| type_var : string -> type_term
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| type_num : nat -> type_term
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| type_fun : type_term -> type_term -> type_term
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| type_univ : string -> type_term -> type_term
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| type_spec : type_term -> type_term -> type_term
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| type_ladder : type_term -> type_term -> type_term
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.
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(* expressions *)
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Inductive expr : Type :=
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| expr_var : string -> expr
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| expr_ty_abs : string -> expr -> expr
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| expr_ty_app : expr -> ladder_type -> expr
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| expr_tm_abs : string -> ladder_type -> expr -> expr
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| expr_tm_app : expr -> expr -> expr
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| expr_let : string -> ladder_type -> expr -> expr -> expr
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| expr_ascend : ladder_type -> expr -> expr
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| expr_descend : ladder_type -> expr -> expr
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Inductive expr_term : Type :=
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| expr_var : string -> expr_term
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| expr_ty_abs : string -> expr_term -> expr_term
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| expr_ty_app : expr_term -> type_term -> expr_term
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| expr_tm_abs : string -> type_term -> expr_term -> expr_term
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| expr_tm_app : expr_term -> expr_term -> expr_term
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| expr_let : string -> type_term -> expr_term -> expr_term -> expr_term
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| expr_ascend : type_term -> expr_term -> expr_term
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| expr_descend : type_term -> expr_term -> expr_term
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.
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Coercion type_var : string >-> ladder_type.
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Coercion expr_var : string >-> expr.
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Coercion type_var : string >-> type_term.
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Coercion expr_var : string >-> expr_term.
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(*
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Notation "( x )" := x (at level 70).
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12
coq/typing.v
12
coq/typing.v
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@ -3,19 +3,19 @@
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*)
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From Coq Require Import Strings.String.
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Require Import terms.
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Require Import subst.
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Include Terms.
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Include Subst.
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Module Typing.
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Inductive context : Type :=
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| ctx_assign : string -> ladder_type -> context -> context
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| ctx_assign : string -> type_term -> context -> context
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| ctx_empty : context
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.
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Inductive context_contains : context -> string -> ladder_type -> Prop :=
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| C_take : forall (x:string) (X:ladder_type) (Γ:context),
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Inductive context_contains : context -> string -> type_term -> Prop :=
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| C_take : forall (x:string) (X:type_term) (Γ:context),
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(context_contains (ctx_assign x X Γ) x X)
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| C_shuffle : forall x X y Y Γ,
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(context_contains Γ x X) ->
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@ -48,7 +48,7 @@ where "Γ '|-' x '\in' X" := (expr_type Γ x X).
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Example typing1 :
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ctx_empty |-
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(expr_ty_abs "T" (expr_tm_abs "x" (type_var "T") (expr_var "x"))) \in
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(type_abs "T" (type_fun (type_var "T") (type_var "T"))).
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(type_univ "T" (type_fun (type_var "T") (type_var "T"))).
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Proof.
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Admitted.
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