Rule_PCF ec ([pcfjudg _ [_]],,[pcfjudg (_,,[_]) [_]]) [pcfjudg (_,,_) [_]]
(RLet Γ Δ (Σ@@@(ec::nil)) (Σ'@@@(ec::nil)) σ₂ p (ec::nil))
- | PCF_REmptyGroup : Rule_PCF ec [ ] [ pcfjudg [] [] ] (REmptyGroup Γ Δ )
+ | PCF_RVoid : Rule_PCF ec [ ] [ pcfjudg [] [] ] (RVoid Γ Δ )
(*| PCF_RLetRec : ∀ Σ₁ τ₁ τ₂ , Rule_PCF (ec::nil) _ _ (RLetRec Γ Δ Σ₁ τ₁ τ₂ (ec::nil) )*)
- | PCF_RBindingGroup : ∀ Σ₁ Σ₂ τ₁ τ₂, Rule_PCF ec ([pcfjudg _ _],,[pcfjudg _ _]) [pcfjudg (_,,_) (_,,_)]
- (RBindingGroup Γ Δ (Σ₁@@@(ec::nil)) (Σ₂@@@(ec::nil)) (τ₁@@@(ec::nil)) (τ₂@@@(ec::nil))).
+ | PCF_RJoin : ∀ Σ₁ Σ₂ τ₁ τ₂, Rule_PCF ec ([pcfjudg _ _],,[pcfjudg _ _]) [pcfjudg (_,,_) (_,,_)]
+ (RJoin Γ Δ (Σ₁@@@(ec::nil)) (Σ₂@@@(ec::nil)) (τ₁@@@(ec::nil)) (τ₂@@@(ec::nil))).
(* need int/boolean case *)
Implicit Arguments Rule_PCF [ ].
admit.
admit.
admit.
- admit.
- admit.
Defined.
(*
Require Import Coq.Logic.Eqdep.
Lemma magic a b c d ec e :
- ClosedND(Rule:=Rule) [a > b > c |- [d @@ (ec :: e)]] ->
- ClosedND(Rule:=Rule) [a > b > pcf_vars ec c @@@ (ec :: nil) |- [d @@ (ec :: nil)]].
+ ClosedSIND(Rule:=Rule) [a > b > c |- [d @@ (ec :: e)]] ->
+ ClosedSIND(Rule:=Rule) [a > b > pcf_vars ec c @@@ (ec :: nil) |- [d @@ (ec :: nil)]].
admit.
Defined.
- Definition orgify : forall Γ Δ Σ τ (pf:ClosedND(Rule:=Rule) [Γ > Δ > Σ |- τ]), Alternating [Γ > Δ > Σ |- τ].
+ Definition orgify : forall Γ Δ Σ τ (pf:ClosedSIND(Rule:=Rule) [Γ > Δ > Σ |- τ]), Alternating [Γ > Δ > Σ |- τ].
refine (
- fix orgify_fc' Γ Δ Σ τ (pf:ClosedND [Γ > Δ > Σ |- τ]) {struct pf} : Alternating [Γ > Δ > Σ |- τ] :=
+ fix orgify_fc' Γ Δ Σ τ (pf:ClosedSIND [Γ > Δ > Σ |- τ]) {struct pf} : Alternating [Γ > Δ > Σ |- τ] :=
let case_main := tt in _
- with orgify_fc c (pf:ClosedND c) {struct pf} : Alternating c :=
+ with orgify_fc c (pf:ClosedSIND c) {struct pf} : Alternating c :=
(match c as C return C=c -> Alternating C with
| T_Leaf None => fun _ => alt_nil
| T_Leaf (Some (Γ > Δ > Σ |- τ)) => let case_leaf := tt in fun eqpf => _
| T_Branch b1 b2 => let case_branch := tt in fun eqpf => _
end (refl_equal _))
with orgify_pcf Γ Δ ec pcfj j (m:MatchingJudgments pcfj j)
- (pf:ClosedND (mapOptionTree (pcfjudg2judg ec) pcfj)) {struct pf} : Alternating j :=
+ (pf:ClosedSIND (mapOptionTree (pcfjudg2judg ec) pcfj)) {struct pf} : Alternating j :=
let case_pcf := tt in _
for orgify_fc').
Admitted.
Definition pcfify Γ Δ ec : forall Σ τ,
- ClosedND(Rule:=Rule) [ Γ > Δ > Σ@@@(ec::nil) |- τ @@@ (ec::nil)]
+ ClosedSIND(Rule:=Rule) [ Γ > Δ > Σ@@@(ec::nil) |- τ @@@ (ec::nil)]
-> ND (PCFRule Γ Δ ec) [] [pcfjudg Σ τ].
refine ((
- fix pcfify Σ τ (pn:@ClosedND _ Rule [ Γ > Δ > Σ@@@(ec::nil) |- τ @@@ (ec::nil)]) {struct pn}
+ fix pcfify Σ τ (pn:@ClosedSIND _ Rule [ Γ > Δ > Σ@@@(ec::nil) |- τ @@@ (ec::nil)]) {struct pn}
: ND (PCFRule Γ Δ ec) [] [pcfjudg Σ τ] :=
- (match pn in @ClosedND _ _ J return J=[Γ > Δ > Σ@@@(ec::nil) |- τ @@@ (ec::nil)] -> _ with
+ (match pn in @ClosedSIND _ _ J return J=[Γ > Δ > Σ@@@(ec::nil) |- τ @@@ (ec::nil)] -> _ with
| cnd_weak => let case_nil := tt in _
| cnd_rule h c cnd' r => let case_rule := tt in _
| cnd_branch _ _ c1 c2 => let case_branch := tt in _
admit.
admit.
admit.
- admit.
- admit.
Defined.
Hint Constructors Rule_Flat.
- Instance PCF_sequents Γ Δ lev : @SequentCalculus _ (PCFRule Γ Δ lev) _ pcfjudg.
- apply Build_SequentCalculus.
- intros.
- induction a.
- destruct a; simpl.
- apply nd_rule.
- exists (RVar _ _ _ _).
- apply PCF_RVar.
- apply nd_rule.
- exists (REmptyGroup _ _ ).
- apply PCF_REmptyGroup.
- eapply nd_comp.
- eapply nd_comp; [ apply nd_llecnac | idtac ].
- apply (nd_prod IHa1 IHa2).
- apply nd_rule.
- exists (RBindingGroup _ _ _ _ _ _).
- apply PCF_RBindingGroup.
- Defined.
-
Definition PCF_Arrange {Γ}{Δ}{lev} : forall x y z, Arrange x y -> ND (PCFRule Γ Δ lev) [pcfjudg x z] [pcfjudg y z].
admit.
Defined.
admit.
Defined.
- Instance PCF_cutrule Γ Δ lev : CutRule (PCF_sequents Γ Δ lev) :=
- { nd_cut := PCF_cut Γ Δ lev }.
- admit.
- admit.
- admit.
- Defined.
+ Instance PCF_sequents Γ Δ lev : @SequentND _ (PCFRule Γ Δ lev) _ pcfjudg :=
+ { snd_cut := PCF_cut Γ Δ lev }.
+ apply Build_SequentND.
+ intros.
+ induction a.
+ destruct a; simpl.
+ apply nd_rule.
+ exists (RVar _ _ _ _).
+ apply PCF_RVar.
+ apply nd_rule.
+ exists (RVoid _ _ ).
+ apply PCF_RVoid.
+ eapply nd_comp.
+ eapply nd_comp; [ apply nd_llecnac | idtac ].
+ apply (nd_prod IHa1 IHa2).
+ apply nd_rule.
+ exists (RJoin _ _ _ _ _ _).
+ apply PCF_RJoin.
+ admit.
+ Defined.
Definition PCF_left Γ Δ lev a b c : ND (PCFRule Γ Δ lev) [pcfjudg b c] [pcfjudg (a,,b) (a,,c)].
eapply nd_comp; [ apply nd_llecnac | eapply nd_comp; [ idtac | idtac ] ].
- eapply nd_prod; [ apply nd_seq_reflexive | apply nd_id ].
+ eapply nd_prod; [ apply snd_initial | apply nd_id ].
apply nd_rule.
- set (@PCF_RBindingGroup Γ Δ lev a b a c) as q'.
+ set (@PCF_RJoin Γ Δ lev a b a c) as q'.
refine (existT _ _ _).
apply q'.
Defined.
Definition PCF_right Γ Δ lev a b c : ND (PCFRule Γ Δ lev) [pcfjudg b c] [pcfjudg (b,,a) (c,,a)].
eapply nd_comp; [ apply nd_rlecnac | eapply nd_comp; [ idtac | idtac ] ].
- eapply nd_prod; [ apply nd_id | apply nd_seq_reflexive ].
+ eapply nd_prod; [ apply nd_id | apply snd_initial ].
apply nd_rule.
- set (@PCF_RBindingGroup Γ Δ lev b a c a) as q'.
+ set (@PCF_RJoin Γ Δ lev b a c a) as q'.
refine (existT _ _ _).
apply q'.
Defined.
- Instance PCF_sequent_join Γ Δ lev : @SequentExpansion _ _ _ _ _ (PCF_sequents Γ Δ lev) (PCF_cutrule Γ Δ lev) :=
- { se_expand_left := PCF_left Γ Δ lev
- ; se_expand_right := PCF_right Γ Δ lev }.
+ Instance PCF_sequent_join Γ Δ lev : @ContextND _ (PCFRule Γ Δ lev) _ pcfjudg _ :=
+ { cnd_expand_left := fun a b c => PCF_left Γ Δ lev c a b
+ ; cnd_expand_right := fun a b c => PCF_right Γ Δ lev c a b }.
+ admit.
+ admit.
+ admit.
+ admit.
admit.
admit.
+ Defined.
+
+ Instance OrgPCF_SequentND_Relation Γ Δ lev : SequentND_Relation (PCF_sequent_join Γ Δ lev) OrgND.
admit.
+ Defined.
+
+ Instance OrgPCF_ContextND_Relation Γ Δ lev : ContextND_Relation (PCF_sequent_join Γ Δ lev).
admit.
Defined.
(* 5.1.3 *)
Instance PCF Γ Δ lev : @ProgrammingLanguage _ _ pcfjudg (PCFRule Γ Δ lev) :=
- { pl_eqv := OrgPCF Γ Δ lev
- ; pl_sc := PCF_sequents Γ Δ lev
- ; pl_subst := PCF_cutrule Γ Δ lev
- ; pl_sequent_join := PCF_sequent_join Γ Δ lev
+ { pl_eqv := OrgPCF_ContextND_Relation Γ Δ lev
+ ; pl_snd := PCF_sequents Γ Δ lev
}.
+ (*
apply Build_TreeStructuralRules; intros; unfold eqv; unfold hom; simpl.
apply nd_rule. unfold PCFRule. simpl.
exists (RArrange _ _ _ _ _ (RuCanR _)).
apply (PCF_RArrange lev _ (a,,[]) _).
Defined.
-
- Instance SystemFCa_sequents Γ Δ : @SequentCalculus _ OrgR _ (mkJudg Γ Δ).
- apply Build_SequentCalculus.
- intros.
- induction a.
- destruct a; simpl.
- apply nd_rule.
- destruct l.
- apply org_fc with (r:=RVar _ _ _ _).
- auto.
- apply nd_rule.
- apply org_fc with (r:=REmptyGroup _ _ ).
- auto.
- eapply nd_comp.
- eapply nd_comp; [ apply nd_llecnac | idtac ].
- apply (nd_prod IHa1 IHa2).
- apply nd_rule.
- apply org_fc with (r:=RBindingGroup _ _ _ _ _ _).
- auto.
- Defined.
+*)
Definition SystemFCa_cut Γ Δ : forall a b c, ND OrgR ([ Γ > Δ > a |- b ],,[ Γ > Δ > b |- c ]) [ Γ > Δ > a |- c ].
intros.
apply (Prelude_error "systemfc rule invoked with [a|=[b,,c]] [[b,,c]|=z]").
Defined.
- Instance SystemFCa_cutrule Γ Δ : CutRule (SystemFCa_sequents Γ Δ) :=
- { nd_cut := SystemFCa_cut Γ Δ }.
- admit.
- admit.
- admit.
- Defined.
+ Instance SystemFCa_sequents Γ Δ : @SequentND _ OrgR _ (mkJudg Γ Δ) :=
+ { snd_cut := SystemFCa_cut Γ Δ }.
+ apply Build_SequentND.
+ intros.
+ induction a.
+ destruct a; simpl.
+ apply nd_rule.
+ destruct l.
+ apply org_fc with (r:=RVar _ _ _ _).
+ auto.
+ apply nd_rule.
+ apply org_fc with (r:=RVoid _ _ ).
+ auto.
+ eapply nd_comp.
+ eapply nd_comp; [ apply nd_llecnac | idtac ].
+ apply (nd_prod IHa1 IHa2).
+ apply nd_rule.
+ apply org_fc with (r:=RJoin _ _ _ _ _ _).
+ auto.
+ admit.
+ Defined.
Definition SystemFCa_left Γ Δ a b c : ND OrgR [Γ > Δ > b |- c] [Γ > Δ > (a,,b) |- (a,,c)].
eapply nd_comp; [ apply nd_llecnac | eapply nd_comp; [ idtac | idtac ] ].
- eapply nd_prod; [ apply nd_seq_reflexive | apply nd_id ].
+ eapply nd_prod; [ apply snd_initial | apply nd_id ].
apply nd_rule.
- apply org_fc with (r:=RBindingGroup Γ Δ a b a c).
+ apply org_fc with (r:=RJoin Γ Δ a b a c).
auto.
Defined.
Definition SystemFCa_right Γ Δ a b c : ND OrgR [Γ > Δ > b |- c] [Γ > Δ > (b,,a) |- (c,,a)].
eapply nd_comp; [ apply nd_rlecnac | eapply nd_comp; [ idtac | idtac ] ].
- eapply nd_prod; [ apply nd_id | apply nd_seq_reflexive ].
+ eapply nd_prod; [ apply nd_id | apply snd_initial ].
apply nd_rule.
- apply org_fc with (r:=RBindingGroup Γ Δ b a c a).
+ apply org_fc with (r:=RJoin Γ Δ b a c a).
auto.
Defined.
+(*
Instance SystemFCa_sequent_join Γ Δ : @SequentExpansion _ _ _ _ _ (SystemFCa_sequents Γ Δ) (SystemFCa_cutrule Γ Δ) :=
{ se_expand_left := SystemFCa_left Γ Δ
; se_expand_right := SystemFCa_right Γ Δ }.
admit.
admit.
Defined.
-
+*)
(* 5.1.2 *)
- Instance SystemFCa Γ Δ : @ProgrammingLanguage _ _ (mkJudg Γ Δ) OrgR :=
+ Instance SystemFCa Γ Δ : @ProgrammingLanguage _ _ (mkJudg Γ Δ) OrgR.
+(*
{ pl_eqv := OrgNDR
- ; pl_sc := SystemFCa_sequents Γ Δ
+ ; pl_sn := SystemFCa_sequents Γ Δ
; pl_subst := SystemFCa_cutrule Γ Δ
; pl_sequent_join := SystemFCa_sequent_join Γ Δ
}.
apply nd_rule. apply (org_fc _ _ (RArrange _ _ _ _ _ (RCanR a ))). apply Flat_RArrange.
apply nd_rule. apply (org_fc _ _ (RArrange _ _ _ _ _ (RuCanL a ))). apply Flat_RArrange.
apply nd_rule. apply (org_fc _ _ (RArrange _ _ _ _ _ (RuCanR a ))). apply Flat_RArrange.
+*)
+admit.
Defined.
End HaskProofStratified.