From Undecidability.PCP Require Import PCP Util.PCP_facts.
From Undecidability.FOL Require Import Util.Deduction Util.Tarski Util.Syntax_facts FOL.
From Undecidability.Synthetic Require Import Definitions DecidabilityFacts EnumerabilityFacts ReducibilityFacts.
Require Import Undecidability.PCP.Reductions.PCPb_iff_dPCPb.


Local Definition BSRS := list(card bool).
Local Notation "x / y" := (x, y).

Notation t_f b t := (func (s_f b) (Vector.cons _ t _ (Vector.nil _))).
Notation t_e := (func s_e (Vector.nil _)).
Notation Pr t t' := (@atom _ sig_pred _ _ sPr (Vector.cons _ t _ (Vector.cons _ t' _ (Vector.nil _)))).
Notation Q := (atom sQ (Vector.nil _)).

Notation i_f b i :=
  (@i_func _ _ _ _ (s_f b) (Vector.cons _ i _ (Vector.nil _))).

Notation i_Pr i i' :=
  (@i_atom _ _ _ _ sPr (Vector.cons _ i _ (Vector.cons _ i' _ (Vector.nil _)))).

Section validity.

  Context {ff : falsity_flag}.
  Variable R : BSRS.

  Fixpoint prep (x : string bool) (t : term) : term :=
    match x with
    | nil => t
    | b::x => t_f b (prep x t)
    end.

  Definition enc s := (prep s t_e).

  Lemma prep_app x y t :
    prep (x ++ y) t = prep x (prep y t).
  Proof.
    induction x; cbn; trivial. now rewrite <- IHx.
  Qed.

  Fixpoint iprep {domain} {I : interp domain} (x : list bool) (y : domain) :=
    match x with
    | nil => y
    | b::x => i_f b (iprep x y)
    end.

  Definition F1 := map (fun '(x,y) => Pr (enc x) (enc y)) R.
  Definition F2 := map (fun '(x, y) => Pr $1 $0 --> Pr (prep x $1) (prep y $0)) R.
  Definition F3 := ( Pr $0 $0 --> Q).

  Definition F : form := F1 ==> F2 ==> F3 --> Q.

  Lemma iprep_eval domain (I : interp domain) rho x s :
    eval rho (prep x s) = iprep x (eval rho s).
  Proof.
    induction x; cbn; trivial. now rewrite <- IHx.
  Qed.

  Lemma iprep_app domain (I : interp domain) x y d :
    iprep (x ++ y) d = iprep x (iprep y d).
  Proof.
    induction x; cbn; trivial. now rewrite <- IHx.
  Qed.

  Global Instance IB : interp (string bool).
  Proof.
    split; intros [] v.
    - exact (b :: Vector.hd v).
    - exact nil.
    - exact (derivable R (Vector.hd v) (Vector.hd (Vector.tl v))).
    - exact (dPCPb R).
  Defined.

  Lemma IB_prep rho s t :
    eval rho (prep s t) = s ++ eval rho t.
  Proof.
    induction s; cbn; trivial.
    rewrite <- IHs. reflexivity.
  Qed.

  Lemma IB_enc rho s :
    eval rho (enc s) = s.
  Proof.
    unfold enc. rewrite IB_prep.
    cbn. apply app_nil_r.
  Qed.

  Lemma IB_drv rho t1 t2 :
    rho (Pr t1 t2) <-> derivable R (eval rho t1) (eval rho t2).
  Proof.
    cbn. reflexivity.
  Qed.

  Lemma IB_F1 rho :
    rho F1.
  Proof.
    unfold F1.
    intros ? ([x y] & <- & ?) % in_map_iff.
    cbn. econstructor. now rewrite !IB_enc.
  Qed.

  Lemma IB_F2 rho :
    rho F2.
  Proof.
    unfold F2. intros ? ([x y] & <- & ?) % in_map_iff u v ?. cbn.
    rewrite !IB_prep. cbn in *. eauto using der_sing, der_cons.
  Qed.

  Lemma IB_F3 rho :
    rho F3.
  Proof.
    cbn. unfold dPCPb, dPCP. eauto.
  Qed.

  Lemma IB_F rho :
    rho F -> dPCPb R.
  Proof.
    intros H. unfold F in H. rewrite !impl_sat in H. eapply H.
    - eapply IB_F1.
    - eapply IB_F2.
    - apply IB_F3.
  Qed.

  Lemma drv_val domain (I : interp domain) rho u v :
    derivable R u v -> rho (F1 ==> F2 ==> Pr (enc u) (enc v)).
  Proof.
    rewrite !impl_sat. intros. induction H.
    - eapply H0. eapply in_map_iff. exists (x/y). eauto.
    - eapply (H1 ( Pr $1 $0 --> Pr (prep x $1) (prep y $0))) in IHderivable.
      + cbn in *. unfold enc in *. rewrite !iprep_eval in *. cbn in *.
        rewrite <- !iprep_app in IHderivable. eapply IHderivable.
      + eapply in_map_iff. exists (x/y). eauto.
  Qed.

  Theorem BPCP_valid :
    PCPb R <-> valid F.
  Proof.
    rewrite PCPb_iff_dPCPb. split.
    - intros [u H] D I rho.
      eapply (@drv_val _ I) in H. unfold F. cbn in *.
      rewrite !impl_sat in *. cbn in *.
      intros. eapply (H2 (eval rho (enc u))). eauto.
    - intros H. apply IB_F with (rho := fun _ => nil), H.
  Qed.


  Definition ctx_S :=
    F3 :: rev F2 ++ rev F1.

  Lemma prep_subst sigma t x :
    subst_term sigma (prep x t) = prep x (subst_term sigma t).
  Proof.
    induction x; cbn; congruence.
  Qed.

  Lemma drv_prv (s : peirce) u v :
    derivable R u v -> ctx_S Pr (enc u) (enc v).
  Proof.
    induction 1.
    - apply Ctx. right. eapply in_app_iff. right.
      rewrite <- in_rev. eapply in_map_iff. exists (x/y). eauto.
    - assert (ctx_S Pr $1 $0 --> Pr (prep x $1) (prep y $0)).
      + apply Ctx. right. eapply in_app_iff. left.
        rewrite <- in_rev. eapply in_map_iff. exists (x/y). eauto.
      + eapply AllE with (t := enc u) in H1; eauto.
        cbn in H1. rewrite !prep_subst in H1. cbn in H1.
        eapply AllE with (t := enc v) in H1; eauto. cbn in H1.
        unfold enc in H1. rewrite !prep_subst in H1. cbn in H1.
        unfold enc. rewrite !prep_app.
        eapply (IE H1). eassumption.
  Qed.

  Lemma BPCP_prv' (s : peirce) :
    dPCPb R -> [] F.
  Proof.
    intros [u H].
    apply drv_prv with (s:=s) in H. unfold F.
    repeat eapply impl_prv. simpl_list. eapply II.
    assert (ctx_S ( Pr $0 $0 --> Q)).
    apply Ctx. now unfold ctx_S. eapply AllE with (t := enc u) in H0.
    cbn in H0. now eapply (IE H0).
  Qed.

End validity.

Theorem BPCP_prv R :
  PCPb R <-> nil M (F R).
Proof.
  rewrite PCPb_iff_dPCPb. split.
  - apply BPCP_prv'.
  - intros H % soundness'. eapply PCPb_iff_dPCPb. now apply (@BPCP_valid falsity_off R).
Qed.


Lemma valid_satis phi :
  valid phi -> ~ satis (¬ phi).
Proof.
  intros H1 (D & I & rho & H2).
  apply H2, (H1 D I rho).
Qed.

Theorem BPCP_satis R :
  ~ PCPb R <-> satis (¬ F R).
Proof.
  rewrite PCPb_iff_dPCPb. split.
  - intros H. exists (list bool), (IB R), (fun _ => nil).
    intros H'. cbn. apply H, (IB_F H').
  - rewrite <- PCPb_iff_dPCPb. intros H1 H2 % (BPCP_valid R (ff:=falsity_on)).
    apply (valid_satis H2), H1.
Qed.


Corollary valid_star_red :
  PCPb FOL*_valid.
Proof.
  exists (fun R => F R). intros R. apply (BPCP_valid R).
Qed.

Theorem prv_red :
  PCPb FOL*_prv_intu.
Proof.
  exists (fun R => F R). intros R. apply (BPCP_prv R).
Qed.

Corollary valid_red :
  PCPb FOL_valid.
Proof.
  exists (fun R => F R). intros R. apply (BPCP_valid R).
Qed.

Theorem satis_red :
  complement PCPb FOL_satis.
Proof.
  exists (fun R => ¬ F R). intros R. apply (BPCP_satis R).
Qed.


Lemma form_discrete {ff : falsity_flag} :
  discrete (form ff).
Proof.
  apply discrete_iff. constructor. apply dec_form.
  - intros ? ?. unfold dec. repeat decide equality.
  - intros ? ?. unfold dec. repeat decide equality.
  - intros [] []. now left.
  - intros [] []. now left.
Qed.

Hint Resolve stack_enum form_discrete : core.

Definition UA :=
  ~ enumerable (complement PCPb).

Corollary valid_undec :
  UA -> ~ decidable (@valid _ _ falsity_off).
Proof.
  intros H. now apply (not_decidable valid_star_red).
Qed.

Corollary valid_unenum :
  UA -> ~ enumerable (complement (@valid _ _ falsity_off)).
Proof.
  intros H. now apply (not_coenumerable valid_star_red).
Qed.

Corollary prv_undec :
  UA -> ~ decidable (@prv _ _ falsity_off intu nil).
Proof.
  intros H. now apply (not_decidable prv_red).
Qed.

Corollary prv_unenum :
  UA -> ~ enumerable (complement (@prv _ _ falsity_off intu nil)).
Proof.
  intros H. apply (not_coenumerable prv_red); trivial.
Qed.

Corollary satis_undec :
  UA -> ~ decidable (@satis _ _ falsity_on).
Proof.
  intros H1 H2 % (dec_red satis_red).
  now apply H1, dec_count_enum.
Qed.

Corollary satis_enum :
  UA -> ~ enumerable (@satis _ _ falsity_on).
Proof.
  intros H1 H2 % (enumerable_red satis_red); auto.
Qed.



Module NonStan. Section Nonstan.

  Variable R : BSRS.
  Context {ff : falsity_flag}.

  Instance IB : interp (option (string bool)).
  Proof.
    split; intros [] v.
    - exact (match Vector.hd v with Some u => Some (b :: u) | None => None end).
    - exact (Some nil).
    - exact (match Vector.hd v, Vector.hd (Vector.tl v) with Some u, Some v => derivable R u v | _, _ => True end).
    - exact False.
  Defined.

  Lemma IB_eval_Some rho t u v :
    eval rho t = Some v -> eval rho (prep u t) = Some (u ++ v).
  Proof.
    intros H. induction u; cbn; trivial.
    unfold prep in IHu. fold prep in IHu. now rewrite IHu.
  Qed.

  Lemma IB_eval_None rho t u :
    eval rho t = None -> eval rho (prep u t) = None.
  Proof.
    intros H. induction u; cbn; trivial.
    unfold prep in IHu. fold prep in IHu. now rewrite IHu.
  Qed.

  Lemma IB_enc rho u :
    eval rho (enc u) = Some u.
  Proof.
    unfold enc. rewrite <- (app_nil_r u) at 2.
    now apply IB_eval_Some.
  Qed.

  Lemma IB_deriv rho u v :
    rho (Pr (enc u) (enc v)) <-> derivable R u v.
  Proof.
    cbn. rewrite !IB_enc. reflexivity.
  Qed.

  Lemma IB_deriv' rho t1 t2 u v :
    eval rho t1 = Some u -> eval rho t2 = Some v ->
    rho (Pr t1 t2) <-> derivable R u v.
  Proof.
    intros H1 H2. cbn. rewrite H1, H2. reflexivity.
  Qed.

  Lemma IB_F1 rho :
    rho F1 R.
  Proof.
    unfold F1.
    intros ? ([x y] & <- & ?) % in_map_iff.
    cbn. rewrite !IB_enc. now constructor.
  Qed.

  Lemma IB_F2 rho :
    rho F2 R.
  Proof.
    unfold F2. intros ? ([x y] & <- & ?) % in_map_iff [u|] [v|] ?; cbn in *.
    - erewrite !IB_eval_Some; cbn; auto. now constructor 2.
    - erewrite IB_eval_Some, IB_eval_None; cbn; auto.
    - erewrite IB_eval_None; cbn; auto.
    - erewrite !IB_eval_None; cbn; auto.
  Qed.

  Lemma IB_F rho :
    rho F R.
  Proof.
    unfold F. rewrite !impl_sat. intros _ _ H.
    apply (H None). cbn. auto.
  Qed.

  Lemma IB_nonstandard rho :
    rho ¬ ¬ Pr $0 $0.
  Proof.
    intros H. apply (H None). cbn. auto.
  Qed.

End Nonstan. End NonStan.