NormNormalization of STLC

Set Warnings "-notation-overridden,-parsing".
From Coq Require Import Lists.List. Import ListNotations.
From Coq Require Import Strings.String.
From PLF Require Import Maps.
From PLF Require Import Smallstep.

Hint Constructors multi.

(* Chapter written and maintained by Andrew Tolmach *)

This optional chapter is based on chapter 12 of Types and Programming Languages (Pierce). It may be useful to look at the two together, as that chapter includes explanations and informal proofs that are not repeated here.

In this chapter, we consider another fundamental theoretical property of the simply typed lambda-calculus: the fact that the evaluation of a well-typed program is guaranteed to halt in a finite number of steps—-i.e., every well-typed term is normalizable.

Unlike the type-safety properties we have considered so far, the normalization property does not extend to full-blown programming languages, because these languages nearly always extend the simply typed lambda-calculus with constructs, such as general recursion (see the MoreStlc chapter) or recursive types, that can be used to write nonterminating programs. However, the issue of normalization reappears at the level of types when we consider the metatheory of polymorphic versions of the lambda calculus such as System F-omega: in this system, the language of types effectively contains a copy of the simply typed lambda-calculus, and the termination of the typechecking algorithm will hinge on the fact that a "normalization" operation on type expressions is guaranteed to terminate.

Another reason for studying normalization proofs is that they are some of the most beautiful—-and mind-blowing—-mathematics to be found in the type theory literature, often (as here) involving the fundamental proof technique of logical relations.

The calculus we shall consider here is the simply typed lambda-calculus over a single base type bool and with pairs. We'll give most details of the development for the basic lambda-calculus terms treating bool as an uninterpreted base type, and leave the extension to the boolean operators and pairs to the reader. Even for the base calculus, normalization is not entirely trivial to prove, since each reduction of a term can duplicate redexes in subterms.

Exercise: 2 stars, standard (norm_fail)

Where do we fail if we attempt to prove normalization by a straightforward induction on the size of a well-typed term?

(* FILL IN HERE *)

(* Do not modify the following line: *)
Definition manual_grade_for_norm_fail : option (nat*string) := None.

☐

Exercise: 5 stars, standard, recommended (norm)

The best ways to understand an intricate proof like this is are (1) to help fill it in and (2) to extend it. We've left out some parts of the following development, including some proofs of lemmas and the all the cases involving products and conditionals. Fill them in.

(* Do not modify the following line: *)
Definition manual_grade_for_norm : option (nat*string) := None.

☐

Language

We begin by repeating the relevant language definition, which is similar to those in the MoreStlc chapter, plus supporting results including type preservation and step determinism. (We won't need progress.) You may just wish to skip down to the Normalization section...

Syntax and Operational Semantics

Inductive ty : Type :=
  | Bool : ty
  | Arrow : ty → ty → ty
  | Prod : ty → ty → ty
.

Substitution

Fixpoint subst (x:string) (s:tm) (t:tm) : tm :=
  match t with
  | var y ⇒ if eqb_string x y then s else t
  | abs y T t₁ ⇒
      abs y T (if eqb_string x y then t₁ else (subst x s t₁))
  | app t₁ t₂ ⇒ app (subst x s t₁) (subst x s t₂)
  | pair t₁ t₂ ⇒ pair (subst x s t₁) (subst x s t₂)
  | fst t₁ ⇒ fst (subst x s t₁)
  | snd t₁ ⇒ snd (subst x s t₁)
  | tru ⇒ tru
  | fls ⇒ fls
  | test t₀ t₁ t₂ ⇒
      test (subst x s t₀) (subst x s t₁) (subst x s t₂)
  end.

Notation "'[' x ':=' s ']' t" := (subst x s t) (at level 20).

Reduction

Inductive value : tm → Prop :=
  | v_abs : ∀x T₁₁ t₁₂,
      value (abs x T₁₁ t₁₂)
  | v_pair : ∀v₁ v₂,
      value v₁ →
      value v₂ →
      value (pair v₁ v₂)
  | v_tru : value tru
  | v_fls : value fls
.

Hint Constructors value.

Reserved Notation "t₁ '-->' t₂" (at level 40).

Inductive step : tm → tm → Prop :=
  | ST_AppAbs : ∀x T₁₁ t₁₂ v₂,
         value v₂ →
         (app (abs x T₁₁ t₁₂) v₂) --> [x:=v₂]t₁₂
  | ST_App1 : ∀t₁ t₁' t₂,
         t₁ --> t₁' →
         (app t₁ t₂) --> (app t₁' t₂)
  | ST_App2 : ∀v₁ t₂ t₂',
         value v₁ →
         t₂ --> t₂' →
         (app v₁ t₂) --> (app v₁ t₂')
  (* pairs *)
  | ST_Pair1 : ∀t₁ t₁' t₂,
        t₁ --> t₁' →
        (pair t₁ t₂) --> (pair t₁' t₂)
  | ST_Pair2 : ∀v₁ t₂ t₂',
        value v₁ →
        t₂ --> t₂' →
        (pair v₁ t₂) --> (pair v₁ t₂')
  | ST_Fst : ∀t₁ t₁',
        t₁ --> t₁' →
        (fst t₁) --> (fst t₁')
  | ST_FstPair : ∀v₁ v₂,
        value v₁ →
        value v₂ →
        (fst (pair v₁ v₂)) --> v₁
  | ST_Snd : ∀t₁ t₁',
        t₁ --> t₁' →
        (snd t₁) --> (snd t₁')
  | ST_SndPair : ∀v₁ v₂,
        value v₁ →
        value v₂ →
        (snd (pair v₁ v₂)) --> v₂
  (* booleans *)
  | ST_TestTrue : ∀t₁ t₂,
        (test tru t₁ t₂) --> t₁
  | ST_TestFalse : ∀t₁ t₂,
        (test fls t₁ t₂) --> t₂
  | ST_Test : ∀t₀ t₀' t₁ t₂,
        t₀ --> t₀' →
        (test t₀ t₁ t₂) --> (test t₀' t₁ t₂)

where "t₁ '-->' t₂" := (step t₁ t₂).

Notation multistep := (multi step).
Notation "t₁ '-->*' t₂" := (multistep t₁ t₂) (at level 40).

Hint Constructors step.

Notation step_normal_form := (normal_form step).

Lemma value__normal : ∀t, value t → step_normal_form t.

Proof with eauto.
intros t H; induction H; intros [t' ST]; inversion ST...
Qed.

Typing

Definition context := partial_map ty.

Inductive has_type : context → tm → ty → Prop :=
  (* Typing rules for proper terms *)
  | T_Var : ∀Gamma x T,
      Gamma x = Some T →
      has_type Gamma (var x) T
  | T_Abs : ∀Gamma x T₁₁ T₁₂ t₁₂,
      has_type (update Gamma x T₁₁) t₁₂ T₁₂ →
      has_type Gamma (abs x T₁₁ t₁₂) (Arrow T₁₁ T₁₂)
  | T_App : ∀T₁ T₂ Gamma t₁ t₂,
      has_type Gamma t₁ (Arrow T₁ T₂) →
      has_type Gamma t₂ T₁ →
      has_type Gamma (app t₁ t₂) T₂
  (* pairs *)
  | T_Pair : ∀Gamma t₁ t₂ T₁ T₂,
      has_type Gamma t₁ T₁ →
      has_type Gamma t₂ T₂ →
      has_type Gamma (pair t₁ t₂) (Prod T₁ T₂)
  | T_Fst : ∀Gamma t T₁ T₂,
      has_type Gamma t (Prod T₁ T₂) →
      has_type Gamma (fst t) T₁
  | T_Snd : ∀Gamma t T₁ T₂,
      has_type Gamma t (Prod T₁ T₂) →
      has_type Gamma (snd t) T₂
  (* booleans *)
  | T_True : ∀Gamma,
      has_type Gamma tru Bool
  | T_False : ∀Gamma,
      has_type Gamma fls Bool
  | T_Test : ∀Gamma t₀ t₁ t₂ T,
      has_type Gamma t₀ Bool →
      has_type Gamma t₁ T →
      has_type Gamma t₂ T →
      has_type Gamma (test t₀ t₁ t₂) T
.

Hint Constructors has_type.

Hint Extern 2 (has_type _ (app _ _) _) ⇒ eapply T_App; auto.
Hint Extern 2 (_ = _) ⇒ compute; reflexivity.

Context Invariance

Inductive appears_free_in : string → tm → Prop :=
  | afi_var : ∀x,
      appears_free_in x (var x)
  | afi_app1 : ∀x t₁ t₂,
      appears_free_in x t₁ → appears_free_in x (app t₁ t₂)
  | afi_app2 : ∀x t₁ t₂,
      appears_free_in x t₂ → appears_free_in x (app t₁ t₂)
  | afi_abs : ∀x y T₁₁ t₁₂,
        y ≠ x →
        appears_free_in x t₁₂ →
        appears_free_in x (abs y T₁₁ t₁₂)
  (* pairs *)
  | afi_pair1 : ∀x t₁ t₂,
      appears_free_in x t₁ →
      appears_free_in x (pair t₁ t₂)
  | afi_pair2 : ∀x t₁ t₂,
      appears_free_in x t₂ →
      appears_free_in x (pair t₁ t₂)
  | afi_fst : ∀x t,
      appears_free_in x t →
      appears_free_in x (fst t)
  | afi_snd : ∀x t,
      appears_free_in x t →
      appears_free_in x (snd t)
  (* booleans *)
  | afi_test0 : ∀x t₀ t₁ t₂,
      appears_free_in x t₀ →
      appears_free_in x (test t₀ t₁ t₂)
  | afi_test1 : ∀x t₀ t₁ t₂,
      appears_free_in x t₁ →
      appears_free_in x (test t₀ t₁ t₂)
  | afi_test2 : ∀x t₀ t₁ t₂,
      appears_free_in x t₂ →
      appears_free_in x (test t₀ t₁ t₂)
.

Hint Constructors appears_free_in.

Definition closed (t:tm) :=
∀x, ¬appears_free_in x t.

Lemma context_invariance : ∀Gamma Gamma' t S,
     has_type Gamma t S →
     (∀x, appears_free_in x t → Gamma x = Gamma' x) →
     has_type Gamma' t S.

Proof with eauto.
  intros. generalize dependent Gamma'.
  induction H;
    intros Gamma' Heqv...
  - (* T_Var *)
    apply T_Var... rewrite <- Heqv...
  - (* T_Abs *)
    apply T_Abs... apply IHhas_type. intros y Hafi.
    unfold update, t_update. destruct (eqb_stringP x y)...
  - (* T_Pair *)
    apply T_Pair...
  - (* T_Test *)
    eapply T_Test...
Qed.

Lemma free_in_context : ∀x t T Gamma,
   appears_free_in x t →
   has_type Gamma t T →
   ∃T', Gamma x = Some T'.

Proof with eauto.
  intros x t T Gamma Hafi Htyp.
  induction Htyp; inversion Hafi; subst...
  - (* T_Abs *)
    destruct IHHtyp as [T' Hctx]... ∃T'.
    unfold update, t_update in Hctx.
    rewrite false_eqb_string in Hctx...
Qed.

Corollary typable_empty__closed : ∀t T,
has_type empty t T →
closed t.

Proof.
  intros. unfold closed. intros x H₁.
  destruct (free_in_context _ _ _ _ H₁ H) as [T' C].
  inversion C. Qed.

Preservation

Lemma substitution_preserves_typing : ∀Gamma x U v t S,
     has_type (update Gamma x U) t S →
     has_type empty v U →
     has_type Gamma ([x:=v]t) S.

Proof with eauto.
  (* Theorem: If Gamma,x:U ⊢ t : S and empty ⊢ v : U, then
     Gamma ⊢ (x:=vt) S. *)
  intros Gamma x U v t S Htypt Htypv.
  generalize dependent Gamma. generalize dependent S.
  (* Proof: By induction on the term t.  Most cases follow directly
     from the IH, with the exception of var and abs.
     The former aren't automatic because we must reason about how the
     variables interact. *)
  induction t;
    intros S Gamma Htypt; simpl; inversion Htypt; subst...
  - (* var *)
    simpl. rename s into y.
    (* If t = y, we know that
         empty ⊢ v : U and
         Gamma,x:U ⊢ y : S
       and, by inversion, update Gamma x U y = Some S.  We want to
       show that Gamma ⊢ [x:=v]y : S.

       There are two cases to consider: either x=y or x≠y. *)
    unfold update, t_update in H₁.
    destruct (eqb_stringP x y).
    + (* x=y *)
    (* If x = y, then we know that U = S, and that [x:=v]y = v.
       So what we really must show is that if empty ⊢ v : U then
       Gamma ⊢ v : U.  We have already proven a more general version
       of this theorem, called context invariance. *)
      subst.
      inversion H₁; subst. clear H₁.
      eapply context_invariance...
      intros x Hcontra.
      destruct (free_in_context _ _ S empty Hcontra) as [T' HT']...
      inversion HT'.
    + (* x<>y *)
      (* If x ≠ y, then Gamma y = Some S and the substitution has no
         effect.  We can show that Gamma ⊢ y : S by T_Var. *)
      apply T_Var...
  - (* abs *)
    rename s into y. rename t into T₁₁.
    (* If t = abs y T₁₁ t₀, then we know that
         Gamma,x:U ⊢ abs y T₁₁ t₀ : T₁₁→T₁₂
         Gamma,x:U,y:T₁₁ ⊢ t₀ : T₁₂
         empty ⊢ v : U
       As our IH, we know that forall S Gamma,
         Gamma,x:U ⊢ t₀ : S → Gamma ⊢ [x:=v]t₀ S.

       We can calculate that
         x:=vt = abs y T₁₁ (if eqb_string x y then t₀ else x:=vt₀)
       And we must show that Gamma ⊢ [x:=v]t : T₁₁→T₁₂.  We know
       we will do so using T_Abs, so it remains to be shown that:
         Gamma,y:T₁₁ ⊢ if eqb_string x y then t₀ else [x:=v]t₀ : T₁₂
       We consider two cases: x = y and x ≠ y.
    *)
    apply T_Abs...
    destruct (eqb_stringP x y).
    + (* x=y *)
    (* If x = y, then the substitution has no effect.  Context
       invariance shows that Gamma,y:U,y:T₁₁ and Gamma,y:T₁₁ are
       equivalent.  Since the former context shows that t₀ : T₁₂, so
       does the latter. *)
      eapply context_invariance...
      subst.
      intros x Hafi. unfold update, t_update.
      destruct (eqb_string y x)...
    + (* x<>y *)
    (* If x ≠ y, then the IH and context invariance allow us to show that
         Gamma,x:U,y:T₁₁ ⊢ t₀ : T₁₂       =>
         Gamma,y:T₁₁,x:U ⊢ t₀ : T₁₂       =>
         Gamma,y:T₁₁ ⊢ [x:=v]t₀ : T₁₂ *)
      apply IHt. eapply context_invariance...
      intros z Hafi. unfold update, t_update.
      destruct (eqb_stringP y z)...
      subst. rewrite false_eqb_string...
Qed.

Theorem preservation : ∀t t' T,
     has_type empty t T →
     t --> t' →
     has_type empty t' T.

Proof with eauto.
  intros t t' T HT.
  (* Theorem: If empty ⊢ t : T and t --> t', then empty ⊢ t' : T. *)
  remember (@empty ty) as Gamma. generalize dependent HeqGamma.
  generalize dependent t'.
  (* Proof: By induction on the given typing derivation.  Many cases are
     contradictory (T_Var, T_Abs).  We show just the interesting ones. *)
  induction HT;
    intros t' HeqGamma HE; subst; inversion HE; subst...
  - (* T_App *)
    (* If the last rule used was T_App, then t = t₁ t₂, and three rules
       could have been used to show t --> t': ST_App1, ST_App2, and
       ST_AppAbs. In the first two cases, the result follows directly from
       the IH. *)
    inversion HE; subst...
    + (* ST_AppAbs *)
      (* For the third case, suppose
           t₁ = abs x T₁₁ t₁₂
         and
           t₂ = v₂.
         We must show that empty ⊢ [x:=v₂]t₁₂ : T₂.
         We know by assumption that
             empty ⊢ abs x T₁₁ t₁₂ : T₁→T₂
         and by inversion
             x:T₁ ⊢ t₁₂ : T₂
         We have already proven that substitution_preserves_typing and
             empty ⊢ v₂ : T₁
         by assumption, so we are done. *)
      apply substitution_preserves_typing with T₁...
      inversion HT₁...
  - (* T_Fst *)
    inversion HT...
  - (* T_Snd *)
    inversion HT...
Qed.

Determinism

Lemma step_deterministic :
deterministic step.

Proof with eauto.
   unfold deterministic.
   intros t t' t'' E₁ E₂.
   generalize dependent t''.
   induction E₁; intros t'' E₂; inversion E₂; subst; clear E₂...
  (* ST_AppAbs *)
   - inversion H₃.
   - exfalso; apply value__normal in H...
   (* ST_App1 *)
   - inversion E₁.
   - f_equal...
   - exfalso; apply value__normal in H₁...
   (* ST_App2 *)
   - exfalso; apply value__normal in H₃...
   - exfalso; apply value__normal in H...
   - f_equal...
   (* ST_Pair1 *)
   - f_equal...
   - exfalso; apply value__normal in H₁...
   (* ST_Pair2 *)
   - exfalso; apply value__normal in H...
   - f_equal...
   (* ST_Fst *)
   - f_equal...
   - exfalso.
     inversion E₁; subst.
     + apply value__normal in H₀...
     + apply value__normal in H₁...
   (* ST_FstPair *)
   - exfalso.
     inversion H₂; subst.
     + apply value__normal in H...
     + apply value__normal in H₀...
   (* ST_Snd *)
   - f_equal...
   - exfalso.
     inversion E₁; subst.
     + apply value__normal in H₀...
     + apply value__normal in H₁...
   (* ST_SndPair *)
   - exfalso.
     inversion H₂; subst.
     + apply value__normal in H...
     + apply value__normal in H₀...
   - (* ST_TestTrue *)
       inversion H₃.
   - (* ST_TestFalse *)
       inversion H₃.
   (* ST_Test *)
   - inversion E₁.
   - inversion E₁.
   - f_equal...
Qed.

Normalization

Now for the actual normalization proof.

Our goal is to prove that every well-typed term reduces to a normal form. In fact, it turns out to be convenient to prove something slightly stronger, namely that every well-typed term reduces to a value. This follows from the weaker property anyway via Progress (why?) but otherwise we don't need Progress, and we didn't bother re-proving it above.

Here's the key definition:

Definition halts (t:tm) : Prop := ∃t', t -->* t' ∧ value t'.

A trivial fact:

Lemma value_halts : ∀v, value v → halts v.

Proof.
  intros v H. unfold halts.
  ∃v. split.
  apply multi_refl.
  assumption.
Qed.

The key issue in the normalization proof (as in many proofs by induction) is finding a strong enough induction hypothesis. To this end, we begin by defining, for each type T, a set R_T of closed terms of type T. We will specify these sets using a relation R and write R T t when t is in R_T. (The sets R_T are sometimes called saturated sets or reducibility candidates.)

Here is the definition of R for the base language:

R bool t iff t is a closed term of type bool and t halts in a value
R (T₁ → T₂) t iff t is a closed term of type T₁ → T₂ and t halts in a value and for any term s such that R T₁ s, we have R T₂ (t s).

This definition gives us the strengthened induction hypothesis that we need. Our primary goal is to show that all programs —-i.e., all closed terms of base type—-halt. But closed terms of base type can contain subterms of functional type, so we need to know something about these as well. Moreover, it is not enough to know that these subterms halt, because the application of a normalized function to a normalized argument involves a substitution, which may enable more reduction steps. So we need a stronger condition for terms of functional type: not only should they halt themselves, but, when applied to halting arguments, they should yield halting results.

The form of R is characteristic of the logical relations proof technique. (Since we are just dealing with unary relations here, we could perhaps more properly say logical properties.) If we want to prove some property P of all closed terms of type A, we proceed by proving, by induction on types, that all terms of type A possess property P, all terms of type A→A preserve property P, all terms of type (A→A)->(A→A) preserve the property of preserving property P, and so on. We do this by defining a family of properties, indexed by types. For the base type A, the property is just P. For functional types, it says that the function should map values satisfying the property at the input type to values satisfying the property at the output type.

When we come to formalize the definition of R in Coq, we hit a problem. The most obvious formulation would be as a parameterized Inductive proposition like this:

      Inductive R : ty → tm → Prop :=
      | R_bool : ∀b t, has_type empty t Bool →
                      halts t →
                      R Bool t
      | R_arrow : ∀T₁ T₂ t, has_type empty t (Arrow T₁ T₂) →
                      halts t →
                      (∀s, R T₁ s → R T₂ (app t s)) →
                      R (Arrow T₁ T₂) t.

Unfortunately, Coq rejects this definition because it violates the strict positivity requirement for inductive definitions, which says that the type being defined must not occur to the left of an arrow in the type of a constructor argument. Here, it is the third argument to R_arrow, namely (∀ s, R T₁ s → R TS (app t s)), and specifically the R T₁ s part, that violates this rule. (The outermost arrows separating the constructor arguments don't count when applying this rule; otherwise we could never have genuinely inductive properties at all!) The reason for the rule is that types defined with non-positive recursion can be used to build non-terminating functions, which as we know would be a disaster for Coq's logical soundness. Even though the relation we want in this case might be perfectly innocent, Coq still rejects it because it fails the positivity test.

Fortunately, it turns out that we can define R using a Fixpoint:

Fixpoint R (T:ty) (t:tm) {struct T} : Prop :=
  has_type empty t T ∧ halts t ∧
  (match T with
   | Bool ⇒ True
   | Arrow T₁ T₂ ⇒ (∀s, R T₁ s → R T₂ (app t s))

   (* ... edit the next line when dealing with products *)
   | Prod T₁ T₂ ⇒ False (* FILL IN HERE *)
   end).

As immediate consequences of this definition, we have that every element of every set R_T halts in a value and is closed with type t :

Lemma R_halts : ∀{T} {t}, R T t → halts t.

Proof.
intros. destruct T; unfold R in H; inversion H; inversion H₁; assumption.
Qed.

Lemma R_typable_empty : ∀{T} {t}, R T t → has_type empty t T.

Proof.
intros. destruct T; unfold R in H; inversion H; inversion H₁; assumption.
Qed.

Now we proceed to show the main result, which is that every well-typed term of type T is an element of R_T. Together with R_halts, that will show that every well-typed term halts in a value.

Membership in R_T Is Invariant Under Reduction

We start with a preliminary lemma that shows a kind of strong preservation property, namely that membership in R_T is invariant under reduction. We will need this property in both directions, i.e., both to show that a term in R_T stays in R_T when it takes a forward step, and to show that any term that ends up in R_T after a step must have been in R_T to begin with.

First of all, an easy preliminary lemma. Note that in the forward direction the proof depends on the fact that our language is determinstic. This lemma might still be true for nondeterministic languages, but the proof would be harder!

Lemma step_preserves_halting : ∀t t', (t --> t') → (halts t ↔ halts t').

Proof.
intros t t' ST. unfold halts.
split.
- (* -> *)
  intros [t'' [STM V]].
  inversion STM; subst.
   exfalso. apply value__normal in V. unfold normal_form in V. apply V. ∃t'. auto.
   rewrite (step_deterministic _ _ _ ST H). ∃t''. split; assumption.
- (* <- *)
  intros [t'0 [STM V]].
  ∃t'0. split; eauto.
Qed.

Now the main lemma, which comes in two parts, one for each direction. Each proceeds by induction on the structure of the type T. In fact, this is where we make fundamental use of the structure of types.

One requirement for staying in R_T is to stay in type T. In the forward direction, we get this from ordinary type Preservation.

Lemma step_preserves_R : ∀T t t', (t --> t') → R T t → R T t'.

Proof.
induction T; intros t t' E Rt; unfold R; fold R; unfold R in Rt; fold R in Rt;
               destruct Rt as [typable_empty_t [halts_t RRt]].
  (* Bool *)
  split. eapply preservation; eauto.
  split. apply (step_preserves_halting _ _ E); eauto.
  auto.
  (* Arrow *)
  split. eapply preservation; eauto.
  split. apply (step_preserves_halting _ _ E); eauto.
  intros.
  eapply IHT2.
  apply ST_App1. apply E.
  apply RRt; auto.
  (* FILL IN HERE *) Admitted.

The generalization to multiple steps is trivial:

Lemma multistep_preserves_R : ∀T t t',
(t -->* t') → R T t → R T t'.

Proof.
  intros T t t' STM; induction STM; intros.
  assumption.
  apply IHSTM. eapply step_preserves_R. apply H. assumption.
Qed.

In the reverse direction, we must add the fact that t has type T before stepping as an additional hypothesis.

Lemma step_preserves_R' : ∀T t t',
has_type empty t T → (t --> t') → R T t' → R T t.

Proof.
(* FILL IN HERE *) Admitted.

Lemma multistep_preserves_R' : ∀T t t',
has_type empty t T → (t -->* t') → R T t' → R T t.

Proof.
  intros T t t' HT STM.
  induction STM; intros.
    assumption.
    eapply step_preserves_R'. assumption. apply H. apply IHSTM.
    eapply preservation; eauto. auto.
Qed.

Closed Instances of Terms of Type t Belong to R_T

Now we proceed to show that every term of type T belongs to R_T. Here, the induction will be on typing derivations (it would be surprising to see a proof about well-typed terms that did not somewhere involve induction on typing derivations!). The only technical difficulty here is in dealing with the abstraction case. Since we are arguing by induction, the demonstration that a term abs x T₁ t₂ belongs to R_(T₁→T₂) should involve applying the induction hypothesis to show that t₂ belongs to R_(T₂). But R_(T₂) is defined to be a set of closed terms, while t₂ may contain x free, so this does not make sense.

This problem is resolved by using a standard trick to suitably generalize the induction hypothesis: instead of proving a statement involving a closed term, we generalize it to cover all closed instances of an open term t. Informally, the statement of the lemma will look like this:

If x₁:T₁,..xn:Tn ⊢ t : T and v₁,...,vn are values such that R T₁ v₁, R T₂ v₂, ..., R Tn vn, then R T ([x₁:=v₁][x₂:=v₂]...[xn:=vn]t).

The proof will proceed by induction on the typing derivation x₁:T₁,..xn:Tn ⊢ t : T; the most interesting case will be the one for abstraction.

Multisubstitutions, Multi-Extensions, and Instantiations

However, before we can proceed to formalize the statement and proof of the lemma, we'll need to build some (rather tedious) machinery to deal with the fact that we are performing multiple substitutions on term t and multiple extensions of the typing context. In particular, we must be precise about the order in which the substitutions occur and how they act on each other. Often these details are simply elided in informal paper proofs, but of course Coq won't let us do that. Since here we are substituting closed terms, we don't need to worry about how one substitution might affect the term put in place by another. But we still do need to worry about the order of substitutions, because it is quite possible for the same identifier to appear multiple times among the x₁,...xn with different associated vi and Ti.

To make everything precise, we will assume that environments are extended from left to right, and multiple substitutions are performed from right to left. To see that this is consistent, suppose we have an environment written as ...,y:bool,...,y:nat,... and a corresponding term substitution written as ...[y:=(tbool true)]...[y:=(const 3)]...t. Since environments are extended from left to right, the binding y:nat hides the binding y:bool; since substitutions are performed right to left, we do the substitution y:=(const 3) first, so that the substitution y:=(tbool true) has no effect. Substitution thus correctly preserves the type of the term.

With these points in mind, the following definitions should make sense.

A multisubstitution is the result of applying a list of substitutions, which we call an environment.

Definition env := list (string * tm).

Fixpoint msubst (ss:env) (t:tm) {struct ss} : tm :=
match ss with
| nil ⇒ t
| ((x,s)::ss') ⇒ msubst ss' ([x:=s]t)
end.

We need similar machinery to talk about repeated extension of a typing context using a list of (identifier, type) pairs, which we call a type assignment.

Definition tass := list (string * ty).

Fixpoint mupdate (Gamma : context) (xts : tass) :=
  match xts with
  | nil ⇒ Gamma
  | ((x,v)::xts') ⇒ update (mupdate Gamma xts') x v
  end.

We will need some simple operations that work uniformly on environments and type assigments

Fixpoint lookup {X:Set} (k : string) (l : list (string * X)) {struct l}
              : option X :=
  match l with
    | nil ⇒ None
    | (j,x) :: l' ⇒
      if eqb_string j k then Some x else lookup k l'
  end.

Fixpoint drop {X:Set} (n:string) (nxs:list (string * X)) {struct nxs}
            : list (string * X) :=
  match nxs with
    | nil ⇒ nil
    | ((n',x)::nxs') ⇒
        if eqb_string n' n then drop n nxs'
        else (n',x)::(drop n nxs')
  end.

An instantiation combines a type assignment and a value environment with the same domains, where corresponding elements are in R.

Inductive instantiation : tass → env → Prop :=
| V_nil :
    instantiation nil nil
| V_cons : ∀x T v c e,
    value v → R T v →
    instantiation c e →
    instantiation ((x,T)::c) ((x,v)::e).

We now proceed to prove various properties of these definitions.

More Substitution Facts

First we need some additional lemmas on (ordinary) substitution.

Lemma vacuous_substitution : ∀ t x,
¬appears_free_in x t →
∀t', [x:=t']t = t.

Proof with eauto.
(* FILL IN HERE *) Admitted.

Lemma subst_closed: ∀t,
closed t →
∀x t', [x:=t']t = t.

Proof.
intros. apply vacuous_substitution. apply H. Qed.

Lemma subst_not_afi : ∀t x v,
closed v → ¬appears_free_in x ([x:=v]t).

Proof with eauto. (* rather slow this way *)
  unfold closed, not.
  induction t; intros x v P A; simpl in A.
    - (* var *)
     destruct (eqb_stringP x s)...
     inversion A; subst. auto.
    - (* app *)
     inversion A; subst...
    - (* abs *)
     destruct (eqb_stringP x s)...
     + inversion A; subst...
     + inversion A; subst...
    - (* pair *)
     inversion A; subst...
    - (* fst *)
     inversion A; subst...
    - (* snd *)
     inversion A; subst...
    - (* tru *)
     inversion A.
    - (* fls *)
     inversion A.
    - (* test *)
     inversion A; subst...
Qed.

Lemma duplicate_subst : ∀t' x t v,
closed v → [x:=t]([x:=v]t') = [x:=v]t'.

Proof.
intros. eapply vacuous_substitution. apply subst_not_afi. auto.
Qed.

Lemma swap_subst : ∀t x x₁ v v₁,
    x ≠ x₁ →
    closed v → closed v₁ →
    [x₁:=v₁]([x:=v]t) = [x:=v]([x₁:=v₁]t).

Proof with eauto.
induction t; intros; simpl.
  - (* var *)
   destruct (eqb_stringP x s); destruct (eqb_stringP x₁ s).
   + subst. exfalso...
   + subst. simpl. rewrite <- eqb_string_refl. apply subst_closed...
   + subst. simpl. rewrite <- eqb_string_refl. rewrite subst_closed...
   + simpl. rewrite false_eqb_string... rewrite false_eqb_string...
  (* FILL IN HERE *) Admitted.

Properties of Multi-Substitutions

Lemma msubst_closed: ∀t, closed t → ∀ss, msubst ss t = t.

Proof.
  induction ss.
    reflexivity.
    destruct a. simpl. rewrite subst_closed; assumption.
Qed.

Closed environments are those that contain only closed terms.

Fixpoint closed_env (env:env) {struct env} :=
  match env with
  | nil ⇒ True
  | (x,t)::env' ⇒ closed t ∧ closed_env env'
  end.

Next come a series of lemmas charcterizing how msubst of closed terms distributes over subst and over each term form

Lemma subst_msubst: ∀env x v t, closed v → closed_env env →
msubst env ([x:=v]t) = [x:=v](msubst (drop x env) t).

Proof.
  induction env0; intros; auto.
  destruct a. simpl.
  inversion H₀. fold closed_env in H₂.
  destruct (eqb_stringP s x).
  - subst. rewrite duplicate_subst; auto.
  - simpl. rewrite swap_subst; eauto.
Qed.

Lemma msubst_var: ∀ss x, closed_env ss →
   msubst ss (var x) =
   match lookup x ss with
   | Some t ⇒ t
   | None ⇒ var x
  end.

Proof.
  induction ss; intros.
    reflexivity.
    destruct a.
     simpl. destruct (eqb_string s x).
      apply msubst_closed. inversion H; auto.
      apply IHss. inversion H; auto.
Qed.

Lemma msubst_abs: ∀ss x T t,
msubst ss (abs x T t) = abs x T (msubst (drop x ss) t).

Proof.
  induction ss; intros.
    reflexivity.
    destruct a.
      simpl. destruct (eqb_string s x); simpl; auto.
Qed.

Lemma msubst_app : ∀ss t₁ t₂, msubst ss (app t₁ t₂) = app (msubst ss t₁) (msubst ss t₂).

Proof.
induction ss; intros.
   reflexivity.
   destruct a.
    simpl. rewrite <- IHss. auto.
Qed.

You'll need similar functions for the other term constructors.

(* FILL IN HERE *)

Properties of Multi-Extensions

We need to connect the behavior of type assignments with that of their corresponding contexts.

Lemma mupdate_lookup : ∀(c : tass) (x:string),
lookup x c = (mupdate empty c) x.

Proof.
  induction c; intros.
    auto.
    destruct a. unfold lookup, mupdate, update, t_update. destruct (eqb_string s x); auto.
Qed.

Lemma mupdate_drop : ∀(c: tass) Gamma x x',
mupdate Gamma (drop x c) x'
= if eqb_string x x' then Gamma x' else mupdate Gamma c x'.

Proof.
  induction c; intros.
  - destruct (eqb_stringP x x'); auto.
  - destruct a. simpl.
    destruct (eqb_stringP s x).
    + subst. rewrite IHc.
      unfold update, t_update. destruct (eqb_stringP x x'); auto.
    + simpl. unfold update, t_update. destruct (eqb_stringP s x'); auto.
      subst. rewrite false_eqb_string; congruence.
Qed.

Properties of Instantiations

These are strightforward.

Lemma instantiation_domains_match: ∀{c} {e},
    instantiation c e →
    ∀{x} {T},
      lookup x c = Some T → ∃t, lookup x e = Some t.

Proof.
  intros c e V. induction V; intros x₀ T₀ C.
    solve_by_invert.
    simpl in *.
    destruct (eqb_string x x₀); eauto.
Qed.

Lemma instantiation_env_closed : ∀c e,
instantiation c e → closed_env e.

Proof.
  intros c e V; induction V; intros.
    econstructor.
    unfold closed_env. fold closed_env.
    split. eapply typable_empty__closed. eapply R_typable_empty. eauto.
        auto.
Qed.

Lemma instantiation_R : ∀c e,
    instantiation c e →
    ∀x t T,
      lookup x c = Some T →
      lookup x e = Some t → R T t.

Proof.
  intros c e V. induction V; intros x' t' T' G E.
    solve_by_invert.
    unfold lookup in *. destruct (eqb_string x x').
      inversion G; inversion E; subst. auto.
      eauto.
Qed.

Lemma instantiation_drop : ∀c env,
instantiation c env →
∀x, instantiation (drop x c) (drop x env).

Proof.
  intros c e V. induction V.
    intros. simpl. constructor.
    intros. unfold drop. destruct (eqb_string x x₀); auto. constructor; eauto.
Qed.

Congruence Lemmas on Multistep

We'll need just a few of these; add them as the demand arises.

Lemma multistep_App2 : ∀v t t',
value v → (t -->* t') → (app v t) -->* (app v t').

Proof.
  intros v t t' V STM. induction STM.
   apply multi_refl.
   eapply multi_step.
     apply ST_App2; eauto. auto.
Qed.

(* FILL IN HERE *)

The R Lemma.

We can finally put everything together.

The key lemma about preservation of typing under substitution can be lifted to multi-substitutions:

Lemma msubst_preserves_typing : ∀c e,
     instantiation c e →
     ∀Gamma t S, has_type (mupdate Gamma c) t S →
     has_type Gamma (msubst e t) S.

Proof.
  induction 1; intros.
    simpl in H. simpl. auto.
    simpl in H₂. simpl.
    apply IHinstantiation.
    eapply substitution_preserves_typing; eauto.
    apply (R_typable_empty H₀).
Qed.

And at long last, the main lemma.

Lemma msubst_R : ∀c env t T,
    has_type (mupdate empty c) t T →
    instantiation c env →
    R T (msubst env t).

Proof.
  intros c env0 t T HT V.
  generalize dependent env0.
  (* We need to generalize the hypothesis a bit before setting up the induction. *)
  remember (mupdate empty c) as Gamma.
  assert (∀x, Gamma x = lookup x c).
    intros. rewrite HeqGamma. rewrite mupdate_lookup. auto.
  clear HeqGamma.
  generalize dependent c.
  induction HT; intros.

  - (* T_Var *)
   rewrite H₀ in H. destruct (instantiation_domains_match V H) as [t P].
   eapply instantiation_R; eauto.
   rewrite msubst_var. rewrite P. auto. eapply instantiation_env_closed; eauto.

  - (* T_Abs *)
    rewrite msubst_abs.
    (* We'll need variants of the following fact several times, so its simplest to
       establish it just once. *)
    assert (WT: has_type empty (abs x T₁₁ (msubst (drop x env0) t₁₂)) (Arrow T₁₁ T₁₂)).
    { eapply T_Abs. eapply msubst_preserves_typing.
      { eapply instantiation_drop; eauto. }
      eapply context_invariance.
      { apply HT. }
      intros.
      unfold update, t_update. rewrite mupdate_drop. destruct (eqb_stringP x x₀).
      + auto.
      + rewrite H.
        clear - c n. induction c.
        simpl. rewrite false_eqb_string; auto.
        simpl. destruct a. unfold update, t_update.
        destruct (eqb_string s x₀); auto. }
    unfold R. fold R. split.
       auto.
     split. apply value_halts. apply v_abs.
     intros.
     destruct (R_halts H₀) as [v [P Q]].
     pose proof (multistep_preserves_R _ _ _ P H₀).
     apply multistep_preserves_R' with (msubst ((x,v)::env0) t₁₂).
       eapply T_App. eauto.
       apply R_typable_empty; auto.
       eapply multi_trans. eapply multistep_App2; eauto.
       eapply multi_R.
       simpl. rewrite subst_msubst.
       eapply ST_AppAbs; eauto.
       eapply typable_empty__closed.
       apply (R_typable_empty H₁).
       eapply instantiation_env_closed; eauto.
       eapply (IHHT ((x,T₁₁)::c)).
          intros. unfold update, t_update, lookup. destruct (eqb_string x x₀); auto.
       constructor; auto.

  - (* T_App *)
    rewrite msubst_app.
    destruct (IHHT1 c H env0 V) as [_ [_ P₁]].
    pose proof (IHHT2 c H env0 V) as P₂. fold R in P₁. auto.

(* FILL IN HERE *) Admitted.

Normalization Theorem

And the final theorem:

Theorem normalization : ∀t T, has_type empty t T → halts t.

Proof.
  intros.
  replace t with (msubst nil t) by reflexivity.
  apply (@R_halts T).
  apply (msubst_R nil); eauto.
  eapply V_nil.
Qed.

(* Mon Mar 25 14:39:39 EDT 2019 *)