Autosubst Header for Scoped Syntax Our development utilises well-scoped de Bruijn syntax. This means that the de Bruijn indices are taken from finite types. As a consequence, any kind of substitution or environment used in conjunction with well-scoped syntax takes the form of a mapping from some finite type I^n. In particular, renamings are mappings I^n -> I^m. Here we develop the theory of how these parts interact.
Version: December 11, 2019.
Require Export axioms.
Set Implicit Arguments.
Unset Strict Implicit.

Definition ap {X Y} (f : X -> Y) {x y : X} (p : x = y) : f x = f y :=
  match p with eq_refl => eq_refl end.

Definition apc {X Y} {f g : X -> Y} {x y : X} (p : f = g) (q : x = y) : f x = g y :=
  match q with eq_refl => match p with eq_refl => eq_refl end end.

Primitives of the Sigma Calculus We implement the finite type with n elements, I^n, as the n-fold iteration of the Option Type. I^0 is implemented as the empty type.

Fixpoint fin (n : nat) : Type :=
  match n with
  | 0 => False
  | S m => option (fin m)
  end.

Renamings and Injective Renamings Renamings are mappings between finite types.
Definition ren (m n : nat) : Type := fin m -> fin n.

Definition id {X} (x : X) := x.

Definition idren {k: nat} : ren k k :=
  fun x => x.

We give a special name, to the newest element in a non-empty finite type, as it usually corresponds to a freshly bound variable.
Definition var_zero {n : nat} : fin (S n) := None.

Definition null {T} (i : fin 0) : T := match i with end.

Definition shift {n : nat} : ren n (S n) :=
  Some.

Definition comp := @funcomp.

Extension of Finite Mappings Assume we are given a mapping f from I^n to some type X, then we can extend this mapping with a new value from x : X to a mapping from I^n+1 to X. We denote this operation by x . f and define it as follows:
Definition scons {X : Type} {n : nat} (x : X) (f : fin n -> X) (m : fin (S n)) : X :=
  match m with
  | None => x
  | Some i => f i
  end.

Type Class Instances for Notation

Type classes for renamings.


Class Ren1 (X1 : Type) (Y Z : Type) :=
  ren1 : X1 -> Y -> Z.

Class Ren2 (X1 X2 : Type) (Y Z : Type) :=
  ren2 : X1 -> X2 -> Y -> Z.

Class Ren3 (X1 X2 X3 : Type) (Y Z : Type) :=
  ren3 : X1 -> X2 -> X3 -> Y -> Z.

Class Ren4 (X1 X2 X3 X4 : Type) (Y Z : Type) :=
  ren4 : X1 -> X2 -> X3 -> X4 -> Y -> Z.

Class Ren5 (X1 X2 X3 X4 X5 : Type) (Y Z : Type) :=
  ren5 : X1 -> X2 -> X3 -> X4 -> X5 -> Y -> Z.

Notation "s ⟨ xi1 ⟩" := (ren1 xi1 s) (at level 7, left associativity, format "s ⟨ xi1 ⟩") : subst_scope.

Notation "s ⟨ xi1 ; xi2 ⟩" := (ren2 xi1 xi2 s) (at level 7, left associativity, format "s ⟨ xi1 ; xi2 ⟩") : subst_scope.

Notation "s ⟨ xi1 ; xi2 ; xi3 ⟩" := (ren3 xi1 xi2 xi3 s) (at level 7, left associativity, format "s ⟨ xi1 ; xi2 ; xi3 ⟩") : subst_scope.

Notation "s ⟨ xi1 ; xi2 ; xi3 ; xi4 ⟩" := (ren4 xi1 xi2 xi3 xi4 s) (at level 7, left associativity, format "s ⟨ xi1 ; xi2 ; xi3 ; xi4 ⟩") : subst_scope.

Notation "s ⟨ xi1 ; xi2 ; xi3 ; xi4 ; xi5 ⟩" := (ren5 xi1 xi2 xi3 xi4 xi5 s) (at level 7, left associativity, format "s ⟨ xi1 ; xi2 ; xi3 ; xi4 ; xi5 ⟩") : subst_scope.

Notation "⟨ xi ⟩" := (ren1 xi) (at level 1, left associativity, format "⟨ xi ⟩") : fscope.

Notation "⟨ xi1 ; xi2 ⟩" := (ren2 xi1 xi2) (at level 1, left associativity, format "⟨ xi1 ; xi2 ⟩") : fscope.

(**** Type Classes for Substiution *)

Class Subst1 (X1 : Type) (Y Z: Type) :=
  subst1 : X1 -> Y -> Z.

Class Subst2 (X1 X2 : Type) (Y Z: Type) :=
  subst2 : X1 -> X2 -> Y -> Z.

Class Subst3 (X1 X2 X3 : Type) (Y Z: Type) :=
  subst3 : X1 -> X2 -> X3 -> Y -> Z.

Class Subst4 (X1 X2 X3 X4: Type) (Y Z: Type) :=
  subst4 : X1 -> X2 -> X3 -> X4 -> Y -> Z.

Class Subst5 (X1 X2 X3 X4 X5 : Type) (Y Z: Type) :=
  subst5 : X1 -> X2 -> X3 -> X4 -> X5 -> Y -> Z.

Notation "s [ sigma ]" := (subst1 sigma s) (at level 7, left associativity, format "s '/' [ sigma ]") : subst_scope.

Notation "s [ sigma ; tau ]" := (subst2 sigma tau s) (at level 7, left associativity, format "s '/' [ sigma ; '/' tau ]") : subst_scope.

Type Class for Variables
Class Var X Y :=
  ids : X -> Y.

Proofs for substitution primitives
Forward Function Composition Substitutions represented as functions are ubiquitious in this development and we often have to compose them, without talking about their pointwise behaviour. That is, we are interested in the forward compostion of functions, f o g, for which we introduce a convenient notation, "f >> g". The direction of the arrow serves as a reminder of the forward nature of this composition, that is first apply f, then g.

Arguments funcomp {X Y Z} (g)%fscope (f)%fscope.

Notation "f >> g" := (funcomp g f) (at level 50).
Open Scope subst_scope.

Notation "x .: f" := (@scons _ _ x f) (at level 55) : subst_scope.

Generic lifting operation for renamings
Definition up_ren m n (xi : ren m n) : ren (S m) (S n) :=
  var_zero .: xi >> shift.

Generic proof that lifting of renamings composes.
Lemma up_ren_ren k l m (xi: ren k l) (zeta : ren l m) (rho: ren k m) (E: forall x, (xi >> zeta) x = rho x) :
  forall x, (up_ren xi >> up_ren zeta) x = up_ren rho x.
Proof.
  intros [x|].
  - simpl. unfold funcomp. now rewrite <- E.
  - reflexivity.
Qed.

Arguments up_ren_ren {k l m} xi zeta rho E.

Lemma scons_eta {T} {n : nat} (f : fin (S n) -> T) :
  f var_zero .: shift >> f = f.
Proof. fext. intros [x|]; reflexivity. Qed.

Lemma scons_eta_id {n : nat} : var_zero .: shift = id :> (fin (S n) -> fin (S n)).
Proof. fext. intros [x|]; reflexivity. Qed.

Lemma scons_comp (T: Type) U {m} (s: T) (sigma: fin m -> T) (tau: T -> U ) :
  (s .: sigma) >> tau = (tau s) .: (sigma >> tau) .
Proof.
  fext. intros [x|]. reflexivity. simpl. reflexivity.
Qed.

Lemma fin_eta {X} (f g : fin 0 -> X) :
  forall x, f x = g x.
Proof. intros []. Qed.

Variadic Substitution Primitives

Fixpoint shift_p (p : nat) {n} : ren n (p + n) :=
  fun n => match p with
        | 0 => n
        | S p => Some (shift_p p n)
        end.

Fixpoint scons_p {X: Type} {m : nat} : forall {n} (f : fin m -> X) (g : fin n -> X), fin (m + n) -> X.
Proof.
  destruct m.
  - intros n f g. exact g.
  - intros n f g. cbn. apply scons.
    + exact (f var_zero).
    + apply scons_p.
      * intros z. exact (f (Some z)).
      * exact g.
Defined.

Definition zero_p {m : nat} {n} : fin m -> fin (m + n).
Proof.
  induction m.
  - intros [].
  - intros [x|].
    + exact (shift_p 1 (IHm x)).
    + exact var_zero.
Defined.

Lemma scons_p_head' {X} {m n} (f : fin m -> X) (g : fin n -> X) z:
  (scons_p f g) (zero_p z) = f z.
Proof.
 induction m.
  - inversion z.
  - destruct z.
    + simpl. simpl. now rewrite IHm.
    + reflexivity.
Qed.

Lemma scons_p_head X m n (f : fin m -> X) (g : fin n -> X) :
  (zero_p >> scons_p f g) = f.
Proof. fext. intros z. unfold funcomp. apply scons_p_head'. Qed.

Lemma scons_p_tail' X m n (f : fin m -> X) (g : fin n -> X) z :
  scons_p f g (shift_p m z) = g z.
Proof. induction m; cbn; eauto. Qed.

Lemma scons_p_tail X m n (f : fin m -> X) (g : fin n -> X) :
  shift_p m >> scons_p f g = g.
Proof. fext. intros z. unfold funcomp. apply scons_p_tail'. Qed.

Lemma destruct_fin {m n} (x : fin (m + n)):
  (exists x', x = zero_p x') \/ exists x', x = shift_p m x'.
Proof.
  induction m; simpl in *.
  - right. eauto.
  - destruct x as [x|].
    + destruct (IHm x) as [[x' ->] |[x' ->]].
      * left. now exists (Some x').
      * right. eauto.
    + left. exists None. eauto.
Qed.

Lemma scons_p_comp' X Y m n (f : fin m -> X) (g : fin n -> X) (h : X -> Y) x:
 h (scons_p f g x) = scons_p (f >> h) (g >> h) x.
Proof.
  destruct (destruct_fin x) as [[x' ->]|[x' ->]].
  - now rewrite !scons_p_head'.
  - now rewrite !scons_p_tail'.
Qed.

Lemma scons_p_comp {X Y m n} {f : fin m -> X} {g : fin n -> X} {h : X -> Y} :
  (scons_p f g) >> h = scons_p (f >> h) (g >> h).
Proof. fext. intros z. unfold funcomp. apply scons_p_comp'. Qed.

Lemma scons_p_congr {X} {m n} (f f' : fin m -> X) (g g': fin n -> X) z:
  (forall x, f x = f' x) -> (forall x, g x = g' x) -> scons_p f g z = scons_p f' g' z.
Proof. intros H1 H2. induction m; eauto. cbn. destruct z; eauto. Qed.

Generic n-ary lifting operation.
Definition upRen_p p { m : nat } { n : nat } (xi : (fin) (m) -> (fin) (n)) : fin (p + m) -> fin (p + n) :=
   scons_p (zero_p ) (xi >> shift_p _).

Arguments upRen_p p {m n} xi.

Generic proof for composition of n-ary lifting.
Lemma up_ren_ren_p p k l m (xi: ren k l) (zeta : ren l m) (rho: ren k m) (E: forall x, (xi >> zeta) x = rho x) :
  forall x, (upRen_p p xi >> upRen_p p zeta) x = upRen_p p rho x.
Proof.
  intros x. destruct (destruct_fin x) as [[? ->]|[? ->]].
  - unfold upRen_p. unfold funcomp. now repeat rewrite scons_p_head'.
  - unfold upRen_p. unfold funcomp. repeat rewrite scons_p_tail'.
    now rewrite <- E.
Qed.

Arguments zero_p m {n}.
Arguments scons_p {X} m {n} f g.

Lemma scons_p_eta {X} {m n} {f : fin m -> X}
      {g : fin n -> X} (h: fin (m + n) -> X) {z: fin (m + n)}:
  (forall x, g x = h (shift_p m x)) -> (forall x, f x = h (zero_p m x)) -> scons_p m f g z = h z.
Proof.
  intros H1 H2. destruct (destruct_fin z) as [[? ->] |[? ->]].
  - rewrite scons_p_head'. eauto.
  - rewrite scons_p_tail'. eauto.
Qed.

Arguments scons_p_eta {X} {m n} {f g} h {z}.
Arguments scons_p_congr {X} {m n} {f f'} {g g'} {z}.

Opaque scons.
Opaque var_zero.
Opaque null.
Opaque shift.
Opaque up_ren.
Opaque var_zero.
Opaque idren.
Opaque comp.
Opaque funcomp.
Opaque id.

Notations for Scoped Syntax

Module CommaNotation.
Notation "s , sigma" := (scons s sigma) (at level 60, format "s , sigma", right associativity) : subst_scope.
End CommaNotation.

Notation "s '..'" := (scons s ids) (at level 1, format "s ..") : subst_scope.

Notation "↑" := (shift) : subst_scope.

Ltac unfold_funcomp := match goal with
                           | |- context[(?f >> ?g) ?s] => change ((f >> g) s) with (g (f s))
                           end.

Tactics for Scoped Syntax
Generic fsimpl tactic: simplifies the above primitives in a goal.
Ltac fsimpl :=
  repeat match goal with
         | [|- context[id >> ?f]] => change (id >> f) with f (* AsimplCompIdL *)
         | [|- context[?f >> id]] => change (f >> id) with f (* AsimplCompIdR *)
         | [|- context [id ?s]] => change (id s) with s
         | [|- context[comp ?f ?g]] => change (comp f g) with (g >> f) (* AsimplCompIdL *)
         | [|- context[(?f >> ?g) >> ?h]] =>
           change ((f >> g) >> h) with (f >> (g >> h)) (* AsimplComp *)

         | [|- zero_p >> scons_p ?f ?g] => rewrite scons_p_head

         | [|- context[(?s.:?sigma) var_zero]] => change ((s.:sigma) var_zero) with s
         | [|- context[(?s.:?sigma) (shift ?m)]] => change ((s.:sigma) (shift m)) with (sigma m)

         | [|- context[idren >> ?f]] => change (idren >> f) with f
         | [|- context[?f >> idren]] => change (f >> idren) with f
         | [|- context[?f >> (?x .: ?g)]] => change (f >> (x .: g)) with g
         | [|- context[?x2 .: shift >> ?f]] => change x2 with (f var_zero); rewrite (@scons_eta _ _ f)
         | [|- context[?f var_zero .: ?g]] => change g with (shift >> f); rewrite scons_eta

         |[|- _ = ?h (?f ?s)] => change (h (f s)) with ((f >> h) s)
         |[|- ?h (?f ?s) = _] => change (h (f s)) with ((f >> h) s)

         | _ => first [progress (rewrite scons_comp) | progress (rewrite scons_eta_id) | progress (autorewrite with FunctorInstances)]
         end.

Generic fsimpl tactic: simplifies the above primitives in the context
Ltac fsimplc :=
  repeat match goal with
         | [H: context[id >> ?f] |- _] => change (id >> f) with f in H(* AsimplCompIdL *)
         | [H: context[?f >> id]|- _] => change (f >> id) with f in H(* AsimplCompIdR *)
         | [H: context [id ?s]|- _] => change (id s) with s in H
         | [H: context[comp ?f ?g]|- _] => change (comp f g) with (g >> f) in H (* AsimplCompIdL *)
         | [H: context[(?f >> ?g) >> ?h]|- _] =>
           change ((f >> g) >> h) with (f >> (g >> h)) in H (* AsimplComp *)
         | [H: context[(?s.:?sigma) var_zero]|- _] => change ((s.:sigma) var_zero) with s in H
         | [H: context[(?s.:?sigma) var_zero]|- _] => change ((s.:sigma) var_zero) with s in H
         | [H: context[(?s.:?sigma) (shift ?m)]|- _] => change ((s.:sigma) (shift m)) with (sigma m) in H
                                                                                      |[H : context[ _ = ?h (?f ?s)]|- _] => change (h (f s)) with ((f >> h) s) in H
         |[H: context[?h (?f ?s) = _]|- _] => change (h (f s)) with ((f >> h) s) in H
         | [H: context[idren >> ?f]|- _] => change (idren >> f) with f in H
         | [H: context[?f >> idren]|- _] => change (f >> idren) with f in H
         | [H: context[?f >> (?x .: ?g)]|- _] =>
           change (f >> (x .: g)) with g in H
         | [H: context[?x2 .: shift >> ?f]|- _] =>
           change x2 with (f var_zero) in H; rewrite (@scons_eta _ _ f) in H
         | [H: context[?f var_zero .: ?g]|- _] =>
           change g with (shift >> f) in H; rewrite scons_eta in H
         | _ => first [progress (rewrite scons_comp in *) | progress (rewrite scons_eta_id in *) | progress (autorewrite with FunctorInstances in *)]
         end.

Simplification in both the goal and the context
Tactic Notation "fsimpl" "in" "*" :=
  fsimpl; fsimplc.

Tactic Notation "auto_case" tactic(t) := (match goal with
                                           | [|- forall (i : fin 0), _] => intros []; t
                                           | [|- forall (i : fin (S (S (S (S _))))), _] => intros [[[[|]|]|]|]; t
                                           | [|- forall (i : fin (S (S (S _)))), _] => intros [[[|]|]|]; t
                                           | [|- forall (i : fin (S (S _))), _] => intros [[?|]|]; t
                                           | [|- forall (i : fin (S _)), _] => intros [?|]; t
                                           end).

Hint Rewrite @scons_p_comp scons_p_head scons_p_tail @scons_p_head' @scons_p_tail': FunctorInstances.