(*********************************************************************************************************************************)
(* ProgrammingLanguage *)
(* *)
-(* Basic assumptions about programming languages . *)
+(* Basic assumptions about programming languages. *)
(* *)
(*********************************************************************************************************************************)
Require Import Subcategories_ch7_1.
Require Import NaturalTransformations_ch7_4.
Require Import NaturalIsomorphisms_ch7_5.
+Require Import BinoidalCategories.
+Require Import PreMonoidalCategories.
Require Import MonoidalCategories_ch7_8.
Require Import Coherence_ch7_8.
Require Import Enrichment_ch2_8.
Require Import RepresentableStructure_ch7_2.
Require Import FunctorCategories_ch7_7.
+Require Import Enrichments.
Require Import NaturalDeduction.
Require Import NaturalDeductionCategory.
-Require Import FreydCategories.
-
-Require Import Reification.
-Require Import GeneralizedArrow.
-Require Import GeneralizedArrowFromReification.
-Require Import ReificationFromGeneralizedArrow.
-
-(*
- * Everything in the rest of this section is just groundwork meant to
- * build up to the definition of the ProgrammingLanguage class, which
- * appears at the end of the section. References to "the instance"
- * mean instances of that class. Think of this section as being one
- * big Class { ... } definition, except that we declare most of the
- * stuff outside the curly brackets in order to take advantage of
- * Coq's section mechanism.
- *)
Section Programming_Language.
Context {T : Type}. (* types of the language *)
Context (Judg : Type).
Context (sequent : Tree ??T -> Tree ??T -> Judg).
Notation "cs |= ss" := (sequent cs ss) : pl_scope.
- (* Because of term irrelevance we need only store the *erased* (def
- * 4.4) trees; for this reason there is no Coq type directly
- * corresponding to productions $e$ and $x$ of 4.1.1, and TreeOT can
- * be used for productions $\Gamma$ and $\Sigma$ *)
-
- (* to do: sequent calculus equals natural deduction over sequents, theorem equals sequent with null antecedent, *)
Context {Rule : Tree ??Judg -> Tree ??Judg -> Type}.
Open Scope nd_scope.
Open Scope pl_scope.
- (*
- *
- * Note that from this abstract interface, the terms (expressions)
- * in the proof are not accessible at all; they don't need to be --
- * so long as we have access to the equivalence relation upon
- * proof-conclusions. Moreover, hiding the expressions actually
- * makes the encoding in CiC work out easier for two reasons:
- *
- * 1. Because the denotation function is provided a proof rather
- * than a term, it is a total function (the denotation function is
- * often undefined for ill-typed terms).
- *
- * 2. We can define arr_composition of proofs without having to know how
- * to compose expressions. The latter task is left up to the client
- * function which extracts an expression from a completed proof.
- *
- * This also means that we don't need an explicit proof obligation for 4.1.2.
- *)
Class ProgrammingLanguage :=
- { pl_eqv : @ND_Relation Judg Rule where "pf1 === pf2" := (@ndr_eqv _ _ pl_eqv _ _ pf1 pf2)
- ; pl_tsr :> @TreeStructuralRules Judg Rule T sequent
- ; pl_sc :> @SequentCalculus Judg Rule _ sequent
- ; pl_subst :> @CutRule Judg Rule _ sequent pl_eqv pl_sc
- ; pl_sequent_join :> @SequentExpansion Judg Rule T sequent pl_eqv pl_sc pl_subst
+ { pl_eqv0 : @ND_Relation Judg Rule
+ ; pl_snd :> @SequentND Judg Rule _ sequent
+ ; pl_cnd :> @ContextND Judg Rule T sequent pl_snd
+ ; pl_eqv1 :> @SequentND_Relation Judg Rule _ sequent pl_snd pl_eqv0
+ ; pl_eqv :> @ContextND_Relation Judg Rule _ sequent pl_snd pl_cnd pl_eqv0 pl_eqv1
}.
Notation "pf1 === pf2" := (@ndr_eqv _ _ pl_eqv _ _ pf1 pf2) : temporary_scope3.
Definition identityProof t : [] ~~{JudgmentsL}~~> [t |= t].
unfold hom; simpl.
- apply nd_seq_reflexive.
+ apply snd_initial.
Defined.
Definition cutProof a b c : [a |= b],,[b |= c] ~~{JudgmentsL}~~> [a |= c].
unfold hom; simpl.
- apply pl_subst.
+ apply snd_cut.
Defined.
+ Existing Instance pl_eqv.
+
Definition TypesL : ECategory JudgmentsL (Tree ??T) (fun x y => [x|=y]).
refine
{| eid := identityProof
; ecomp := cutProof
|}; intros.
- apply MonoidalCat_all_central.
- apply MonoidalCat_all_central.
- unfold identityProof; unfold cutProof; simpl.
- apply nd_cut_left_identity.
- unfold identityProof; unfold cutProof; simpl.
- apply nd_cut_right_identity.
- unfold identityProof; unfold cutProof; simpl.
- symmetry.
- apply nd_cut_associativity.
- Defined.
-
- Definition Types_first c : EFunctor TypesL TypesL (fun x => x,,c ).
- refine {| efunc := fun x y => (nd_rule (@se_expand_right _ _ _ _ _ _ _ (@pl_sequent_join PL) c x y)) |}.
- intros; apply MonoidalCat_all_central.
+ apply (mon_commutative(MonoidalCat:=JudgmentsL)).
+ apply (mon_commutative(MonoidalCat:=JudgmentsL)).
+ unfold identityProof; unfold cutProof; simpl; eapply cndr_inert. apply pl_eqv. auto. auto.
+ unfold identityProof; unfold cutProof; simpl; eapply cndr_inert. apply pl_eqv. auto. auto.
+ unfold identityProof; unfold cutProof; simpl; eapply cndr_inert. apply pl_eqv. auto. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ Defined.
+
+ Instance Types_first c : EFunctor TypesL TypesL (fun x => x,,c ) :=
+ { efunc := fun x y => cnd_expand_right(ContextND:=pl_cnd) x y c }.
+ intros; apply (mon_commutative(MonoidalCat:=JudgmentsL)).
intros. unfold ehom. unfold hom. unfold identityProof. unfold eid. simpl. unfold identityProof.
- apply se_reflexive_right.
+ apply (cndr_inert pl_cnd); auto.
intros. unfold ehom. unfold comp. simpl. unfold cutProof.
- rewrite <- (@ndr_prod_preserves_comp _ _ pl_eqv _ _ [#se_expand_right _ c#] _ _ (nd_id1 (b|=c0))
- _ (nd_id1 (a,,c |= b,,c)) _ [#se_expand_right _ c#]).
+ rewrite <- (@ndr_prod_preserves_comp _ _ pl_eqv _ _ (cnd_expand_right _ _ c) _ _ (nd_id1 (b|=c0))
+ _ (nd_id1 (a,,c |= b,,c)) _ (cnd_expand_right _ _ c)).
setoid_rewrite (@ndr_comp_right_identity _ _ pl_eqv _ [a,, c |= b,, c]).
setoid_rewrite (@ndr_comp_left_identity _ _ pl_eqv [b |= c0]).
- apply se_cut_right.
+ simpl; eapply cndr_inert. apply pl_eqv. auto. auto.
Defined.
- Definition Types_second c : EFunctor TypesL TypesL (fun x => c,,x).
- eapply Build_EFunctor.
- instantiate (1:=(fun x y => (nd_rule (@se_expand_left _ _ _ _ _ _ _ (@pl_sequent_join PL) c x y)))).
- intros; apply MonoidalCat_all_central.
+ Instance Types_second c : EFunctor TypesL TypesL (fun x => c,,x) :=
+ { efunc := fun x y => ((@cnd_expand_left _ _ _ _ _ _ x y c)) }.
+ intros; apply (mon_commutative(MonoidalCat:=JudgmentsL)).
intros. unfold ehom. unfold hom. unfold identityProof. unfold eid. simpl. unfold identityProof.
- apply se_reflexive_left.
+ eapply cndr_inert; auto. apply pl_eqv.
intros. unfold ehom. unfold comp. simpl. unfold cutProof.
- rewrite <- (@ndr_prod_preserves_comp _ _ pl_eqv _ _ [#se_expand_left _ c#] _ _ (nd_id1 (b|=c0))
- _ (nd_id1 (c,,a |= c,,b)) _ [#se_expand_left _ c#]).
+ rewrite <- (@ndr_prod_preserves_comp _ _ pl_eqv _ _ (cnd_expand_left _ _ c) _ _ (nd_id1 (b|=c0))
+ _ (nd_id1 (c,,a |= c,,b)) _ (cnd_expand_left _ _ c)).
setoid_rewrite (@ndr_comp_right_identity _ _ pl_eqv _ [c,,a |= c,,b]).
setoid_rewrite (@ndr_comp_left_identity _ _ pl_eqv [b |= c0]).
- apply se_cut_left.
+ simpl; eapply cndr_inert. apply pl_eqv. auto. auto.
Defined.
- Definition Types_binoidal : BinoidalCat TypesL (@T_Branch _).
+ Definition Types_binoidal : EBinoidalCat TypesL.
refine
- {| bin_first := Types_first
- ; bin_second := Types_second
+ {| ebc_first := Types_first
+ ; ebc_second := Types_second
|}.
Defined.
- Definition Types_PreMonoidal : PreMonoidalCat Types_binoidal [].
+ Instance Types_assoc_iso a b c : Isomorphic(C:=TypesL) ((a,,b),,c) (a,,(b,,c)) :=
+ { iso_forward := snd_initial _ ;; cnd_ant_cossa _ a b c
+ ; iso_backward := snd_initial _ ;; cnd_ant_assoc _ a b c
+ }.
+ simpl; eapply cndr_inert. unfold identityProof; apply pl_eqv. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ auto.
+ simpl; eapply cndr_inert. unfold identityProof; apply pl_eqv. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ auto.
+ Defined.
+
+ Instance Types_cancelr_iso a : Isomorphic(C:=TypesL) (a,,[]) a :=
+ { iso_forward := snd_initial _ ;; cnd_ant_rlecnac _ a
+ ; iso_backward := snd_initial _ ;; cnd_ant_cancelr _ a
+ }.
+ unfold eqv; unfold comp; simpl.
+ eapply cndr_inert. apply pl_eqv. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ auto.
+ unfold eqv; unfold comp; simpl.
+ eapply cndr_inert. apply pl_eqv. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ auto.
+ Defined.
+
+ Instance Types_cancell_iso a : Isomorphic(C:=TypesL) ([],,a) a :=
+ { iso_forward := snd_initial _ ;; cnd_ant_llecnac _ a
+ ; iso_backward := snd_initial _ ;; cnd_ant_cancell _ a
+ }.
+ unfold eqv; unfold comp; simpl.
+ eapply cndr_inert. apply pl_eqv. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ auto.
+ unfold eqv; unfold comp; simpl.
+ eapply cndr_inert. apply pl_eqv. auto.
+ apply ndpc_comp; auto.
+ apply ndpc_comp; auto.
+ auto.
+ Defined.
+
+ Instance Types_assoc a b : Types_second a >>>> Types_first b <~~~> Types_first b >>>> Types_second a :=
+ { ni_iso := fun c => Types_assoc_iso a c b }.
+ intros; unfold eqv; simpl.
+ admit.
+ Defined.
+
+ Instance Types_cancelr : Types_first [] <~~~> functor_id _ :=
+ { ni_iso := Types_cancelr_iso }.
+ intros; simpl.
admit.
Defined.
+ Instance Types_cancell : Types_second [] <~~~> functor_id _ :=
+ { ni_iso := Types_cancell_iso }.
+ admit.
+ Defined.
+
+ Instance Types_assoc_ll a b : Types_second (a,,b) <~~~> Types_second b >>>> Types_second a :=
+ { ni_iso := fun c => Types_assoc_iso a b c }.
+ admit.
+ Defined.
+
+ Instance Types_assoc_rr a b : Types_first (a,,b) <~~~> Types_first a >>>> Types_first b :=
+ { ni_iso := fun c => iso_inv _ _ (Types_assoc_iso c a b) }.
+ admit.
+ Defined.
+
+ Instance Types_PreMonoidal : PreMonoidalCat Types_binoidal [] :=
+ { pmon_assoc := Types_assoc
+ ; pmon_cancell := Types_cancell
+ ; pmon_cancelr := Types_cancelr
+ ; pmon_assoc_rr := Types_assoc_rr
+ ; pmon_assoc_ll := Types_assoc_ll
+ }.
+(*
+ apply Build_Pentagon.
+ intros; simpl.
+ eapply cndr_inert. apply pl_eqv.
+ apply ndpc_comp.
+ apply ndpc_comp.
+ auto.
+ apply ndpc_comp.
+ apply ndpc_prod.
+ apply ndpc_comp.
+ apply ndpc_comp.
+ auto.
+ apply ndpc_comp.
+ auto.
+ auto.
+ auto.
+ auto.
+ auto.
+ auto.
+ apply ndpc_comp.
+ apply ndpc_comp.
+ auto.
+ apply ndpc_comp.
+ auto.
+ auto.
+ auto.
+ apply Build_Triangle; intros; simpl.
+ eapply cndr_inert. apply pl_eqv.
+ auto.
+ apply ndpc_comp.
+ apply ndpc_comp.
+ auto.
+ apply ndpc_comp.
+ auto.
+ auto.
+ auto.
+ eapply cndr_inert. apply pl_eqv. auto.
+ auto.
+*)
+admit.
+admit.
+ intros; simpl; reflexivity.
+ intros; simpl; reflexivity.
+ admit. (* assoc central *)
+ admit. (* cancelr central *)
+ admit. (* cancell central *)
+ Defined.
+
Definition TypesEnrichedInJudgments : Enrichment.
- refine {| enr_c := TypesL |}.
+ refine
+ {| enr_v_mon := Judgments_Category_monoidal _
+ ; enr_c_pm := Types_PreMonoidal
+ ; enr_c_bin := Types_binoidal
+ |}.
Defined.
Structure HasProductTypes :=
{
}.
+ (*
+ Lemma CartesianEnrMonoidal (e:PreMonoidalEnrichment)
+ `(C:CartesianCat(Ob:= _)(Hom:= _)(C:=Underlying (enr_c e))) : MonoidalEnrichment e.
+ admit.
+ Defined.
+ *)
+
(* need to prove that if we have cartesian tuples we have cartesian contexts *)
+ (*
Definition LanguagesWithProductsAreSMME : HasProductTypes -> SurjectiveMonicMonoidalEnrichment TypesEnrichedInJudgments.
admit.
Defined.
-
+ *)
End LanguageCategory.
-End Programming_Language.
+End Programming_Language.
+(*
Structure ProgrammingLanguageSMME :=
{ plsmme_t : Type
; plsmme_judg : Type
}.
Coercion plsmme_pl : ProgrammingLanguageSMME >-> ProgrammingLanguage.
Coercion plsmme_smme : ProgrammingLanguageSMME >-> SurjectiveMonicMonoidalEnrichment.
-
-Section ArrowInLanguage.
- Context (Host:ProgrammingLanguageSMME).
- Context `(CC:CartesianCat (me_mon Host)).
- Context `(K:@ECategory _ _ _ _ _ _ (@car_mn _ _ _ _ _ _ _ CC) C Kehom).
- Context `(pmc:PreMonoidalCat K bobj mobj (@one _ _ _ (cartesian_terminal C))).
- (* FIXME *)
- (*
- Definition ArrowInProgrammingLanguage :=
- @FreydCategory _ _ _ _ _ _ (@car_mn _ _ _ _ _ _ _ CC) _ _ _ _ pmc.
- *)
-End ArrowInLanguage.
-
-Section GArrowInLanguage.
- Context (Guest:ProgrammingLanguageSMME).
- Context (Host :ProgrammingLanguageSMME).
- Definition GeneralizedArrowInLanguage := GeneralizedArrow Guest Host.
-
- (* FIXME
- Definition ArrowsAreGeneralizedArrows : ArrowInProgrammingLanguage -> GeneralizedArrowInLanguage.
- *)
- Definition TwoLevelLanguage := Reification Guest Host (me_i Host).
-
- Context (GuestHost:TwoLevelLanguage).
-
- Definition FlatObject (x:TypesL _ _ Host) :=
- forall y1 y2, not ((reification_r_obj GuestHost y1 y2)=x).
-
- Definition FlatSubCategory := FullSubcategory (TypesL _ _ Host) FlatObject.
-
- Section Flattening.
-
- Context (F:Retraction (TypesL _ _ Host) FlatSubCategory).
- Definition FlatteningOfReification := garrow_from_reification Guest Host GuestHost >>>> F.
- Lemma FlatteningIsNotDestructive :
- FlatteningOfReification >>>> retraction_retraction F >>>> RepresentableFunctor _ (me_i Host) ~~~~ GuestHost.
- admit.
- Qed.
-
- End Flattening.
-
-End GArrowInLanguage.
-
-Inductive NLevelLanguage : nat -> ProgrammingLanguageSMME -> Type :=
-| NLevelLanguage_zero : forall lang, NLevelLanguage O lang
-| NLevelLanguage_succ : forall (L1 L2:ProgrammingLanguageSMME) n,
- TwoLevelLanguage L1 L2 -> NLevelLanguage n L1 -> NLevelLanguage (S n) L2.
-
-Definition OmegaLevelLanguage : Type :=
- { f : nat -> ProgrammingLanguageSMME
- & forall n, TwoLevelLanguage (f n) (f (S n)) }.
-
+*)
Implicit Arguments ND [ Judgment ].