Require Import ADPUnif.
Require Import ADecomp.
Require Import ADuplicateSymb.
Require Import AGraph.
Require Import APolyInt_MA.
Require Import ATrs.
Require Import List.
Require Import LogicUtil.
Require Import MonotonePolynom.
Require Import Polynom.
Require Import SN.
Require Import VecUtil.
Open Scope nat_scope.
(* termination problem *)
Module M.
Inductive symb : Type :=
| a : symb
| b : symb
| c : symb
| d : symb
| e : symb
| f : symb
| g : symb.
End M.
Lemma eq_symb_dec : forall f g : M.symb, {f=g}+{~f=g}.
Proof.
decide equality.
Defined.
Open Scope nat_scope.
Definition ar (s : M.symb) : nat :=
match s with
| M.a => 0
| M.b => 0
| M.c => 1
| M.d => 1
| M.e => 1
| M.f => 1
| M.g => 1
end.
Definition s0 := ASignature.mkSignature ar eq_symb_dec.
Definition s0_p := s0.
Definition V0 := @ATerm.Var s0.
Definition F0 := @ATerm.Fun s0.
Definition R0 := @ATrs.mkRule s0.
Module S0.
Definition a := F0 M.a Vnil.
Definition b := F0 M.b Vnil.
Definition c x1 := F0 M.c (Vcons x1 Vnil).
Definition d x1 := F0 M.d (Vcons x1 Vnil).
Definition e x1 := F0 M.e (Vcons x1 Vnil).
Definition f x1 := F0 M.f (Vcons x1 Vnil).
Definition g x1 := F0 M.g (Vcons x1 Vnil).
End S0.
Definition E :=
@nil (@ATrs.rule s0).
Definition R :=
R0 (S0.f S0.a)
(S0.f (S0.c S0.a))
:: R0 (S0.f (S0.c (V0 0)))
(V0 0)
:: R0 (S0.f (S0.c S0.a))
(S0.f (S0.d S0.b))
:: R0 (S0.f S0.a)
(S0.f (S0.d S0.a))
:: R0 (S0.f (S0.d (V0 0)))
(V0 0)
:: R0 (S0.f (S0.c S0.b))
(S0.f (S0.d S0.a))
:: R0 (S0.e (S0.g (V0 0)))
(S0.e (V0 0))
:: @nil (@ATrs.rule s0).
Definition rel := ATrs.red_mod E R.
(* symbol marking *)
Definition s1 := dup_sig s0.
Definition s1_p := s0.
Definition V1 := @ATerm.Var s1.
Definition F1 := @ATerm.Fun s1.
Definition R1 := @ATrs.mkRule s1.
Module S1.
Definition ha := F1 (hd_symb s1_p M.a) Vnil.
Definition a := F1 (int_symb s1_p M.a) Vnil.
Definition hb := F1 (hd_symb s1_p M.b) Vnil.
Definition b := F1 (int_symb s1_p M.b) Vnil.
Definition hc x1 := F1 (hd_symb s1_p M.c) (Vcons x1 Vnil).
Definition c x1 := F1 (int_symb s1_p M.c) (Vcons x1 Vnil).
Definition hd x1 := F1 (hd_symb s1_p M.d) (Vcons x1 Vnil).
Definition d x1 := F1 (int_symb s1_p M.d) (Vcons x1 Vnil).
Definition he x1 := F1 (hd_symb s1_p M.e) (Vcons x1 Vnil).
Definition e x1 := F1 (int_symb s1_p M.e) (Vcons x1 Vnil).
Definition hf x1 := F1 (hd_symb s1_p M.f) (Vcons x1 Vnil).
Definition f x1 := F1 (int_symb s1_p M.f) (Vcons x1 Vnil).
Definition hg x1 := F1 (hd_symb s1_p M.g) (Vcons x1 Vnil).
Definition g x1 := F1 (int_symb s1_p M.g) (Vcons x1 Vnil).
End S1.
(* graph decomposition 1 *)
Definition cs1 : list (list (@ATrs.rule s1)) :=
( R1 (S1.he (S1.g (V1 0)))
(S1.he (V1 0))
:: nil)
:: ( R1 (S1.hf (S1.c (S1.b)))
(S1.hf (S1.d (S1.a)))
:: nil)
:: ( R1 (S1.hf (S1.a))
(S1.hf (S1.d (S1.a)))
:: nil)
:: ( R1 (S1.hf (S1.c (S1.a)))
(S1.hf (S1.d (S1.b)))
:: nil)
:: ( R1 (S1.hf (S1.a))
(S1.hf (S1.c (S1.a)))
:: nil)
:: nil.
(* polynomial interpretation 1 *)
Module PIS1 (*<: TPolyInt*).
Definition sig := s1.
Definition trsInt f :=
match f as f return poly (@ASignature.arity s1 f) with
| (hd_symb M.f) =>
nil
| (int_symb M.f) =>
(1%Z, (Vcons 1 Vnil))
:: nil
| (hd_symb M.a) =>
nil
| (int_symb M.a) =>
nil
| (hd_symb M.c) =>
nil
| (int_symb M.c) =>
(1%Z, (Vcons 1 Vnil))
:: nil
| (hd_symb M.d) =>
nil
| (int_symb M.d) =>
(1%Z, (Vcons 1 Vnil))
:: nil
| (hd_symb M.b) =>
nil
| (int_symb M.b) =>
nil
| (hd_symb M.e) =>
(2%Z, (Vcons 1 Vnil))
:: nil
| (int_symb M.e) =>
(1%Z, (Vcons 1 Vnil))
:: nil
| (hd_symb M.g) =>
nil
| (int_symb M.g) =>
(1%Z, (Vcons 0 Vnil))
:: (2%Z, (Vcons 1 Vnil))
:: nil
end.
Lemma trsInt_wm : forall f, pweak_monotone (trsInt f).
Proof.
pmonotone.
Qed.
End PIS1.
Module PI1 := PolyInt PIS1.
(* termination proof *)
Lemma termination : WF rel.
Proof.
unfold rel.
dp_trans.
mark.
let D := fresh "D" in let R := fresh "R" in set_rules_to D; set_mod_rules_to R;
graph_decomp (dpg_unif_N 100 R D) cs1; subst D; subst R.
dpg_unif_N_correct.
right. PI1.prove_termination.
termination_trivial.
left. co_scc.
left. co_scc.
left. co_scc.
left. co_scc.
Qed.