wip on preservation proof
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2 changed files with 404 additions and 50 deletions
399
coq/soundness.v
399
coq/soundness.v
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@ -16,40 +16,405 @@ Include Typing.
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Module Soundness.
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Module Soundness.
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Lemma typing_weakening : forall Γ e τ x σ,
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(Γ |- e \is τ) ->
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((ctx_assign x σ Γ) |- e \is τ)
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.
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Proof.
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intros.
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induction H.
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apply T_Var.
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apply C_shuffle.
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apply H.
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apply T_Let with (σ:=σ0).
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apply IHexpr_type1.
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admit.
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Admitted.
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Lemma morphism_path_solves_type : forall Γ τ τ' m,
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(translate_morphism_path Γ τ τ' m) ->
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Γ |- m \is (type_morph τ τ')
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.
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Proof.
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intros.
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induction H.
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(* Sub *)
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apply T_MorphAbs.
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apply T_DescendImplicit with (τ:=τ).
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apply T_Var.
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apply C_take.
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apply H.
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(* Lift *)
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apply T_MorphAbs.
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apply T_Ascend with (τ:=τ').
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apply T_App with (σ':=τ) (σ:=τ).
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apply T_MorphFun.
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apply typing_weakening.
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apply IHtranslate_morphism_path.
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apply T_Descend with (τ:=(type_ladder σ τ)).
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apply T_Var.
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apply C_take.
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apply TSubRepr_Ladder, TSubRepr_Refl, TEq_Refl.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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apply TSubRepr_Ladder, TSubRepr_Refl, TEq_Refl.
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(* Single *)
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apply T_Var.
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apply H.
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(* Chain *)
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apply T_MorphAbs.
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apply T_App with (σ':=τ') (σ:=τ') (τ:=τ'').
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apply T_MorphFun.
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apply typing_weakening.
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apply IHtranslate_morphism_path2.
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apply T_App with (σ':=τ) (σ:=τ) (τ:=τ').
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apply T_MorphFun.
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apply typing_weakening.
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apply IHtranslate_morphism_path1.
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apply T_Var.
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apply C_take.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* Map Sequence *)
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apply T_MorphAbs.
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apply T_App with (σ':=(type_spec (type_id "Seq") τ)) (σ:=(type_spec (type_id "Seq") τ)).
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apply T_App with (σ':=(type_fun τ τ')) (σ:=(type_fun τ τ')).
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admit.
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apply T_MorphFun.
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apply typing_weakening.
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apply IHtranslate_morphism_path.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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apply T_Var.
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apply C_take.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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Admitted.
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(* reduction step preserves well-typedness *)
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Lemma preservation : forall Γ e e' τ,
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~(is_value e) ->
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(Γ |- e \is τ) ->
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(e -->β e') ->
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(Γ |- e' \is τ)
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.
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Proof.
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intros.
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induction e.
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(* `e` is Variable *)
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contradict H.
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apply V_Abs, VAbs_Var.
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(* `e` is Type-Abstraction *)
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contradict H.
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apply V_Abs, VAbs_TypAbs.
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(* `e` is Type-Application *)
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admit.
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(* `e` is Abstraction *)
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contradict H.
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apply V_Abs, VAbs_Abs.
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(* `e` is morphism *)
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contradict H.
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apply V_Abs, VAbs_Morph.
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(* `e` is Application *)
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admit.
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(* `e` is Let-Binding *)
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admit.
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(* `e` is Ascension *)
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admit.
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(* `e` is Descension *)
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admit.
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Admitted.
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(* translation of expression preserves typing *)
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Lemma translation_preservation : forall Γ e e' τ,
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(Γ |- e \is τ) ->
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(translate_typing Γ e τ e') ->
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(Γ |- e' \is τ)
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.
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Proof.
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intros.
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induction H0.
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(* e is Variable *)
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apply H.
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(* e is Let-Binding *)
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apply T_Let with (τ:=τ) (σ:=σ).
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apply IHtranslate_typing1.
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apply H0.
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apply IHtranslate_typing2.
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apply H1.
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(* e is Type-Abstraction *)
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apply T_TypeAbs.
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apply IHtranslate_typing.
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apply H0.
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(* e is Type-Application *)
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admit.
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(* e is Abstraction *)
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apply T_Abs.
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apply IHtranslate_typing.
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apply H0.
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(* e is Morphism-Abstraction *)
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apply T_MorphAbs.
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apply IHtranslate_typing.
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apply H0.
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(* e is Application *)
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apply T_App with (σ':=σ) (σ:=σ) (τ:=τ).
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apply IHtranslate_typing1.
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apply H0.
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induction H3.
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(* Repr-Subtype *)
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apply T_App with (σ':=τ0) (σ:=τ0) (τ:=τ').
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apply T_MorphFun.
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apply T_MorphAbs.
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apply T_DescendImplicit with (τ:=τ0).
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apply T_Var.
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apply C_take.
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apply H3.
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apply T_DescendImplicit with (τ:=τ0).
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apply IHtranslate_typing2.
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apply H1.
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apply TSubRepr_Refl, TEq_Refl.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* Lifted Morphism *)
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apply T_App with (σ':=(type_ladder σ τ0)) (σ:=(type_ladder σ τ0)) (τ:=(type_ladder σ τ')).
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apply T_MorphFun.
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apply T_MorphAbs.
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apply T_Ascend with (τ:=τ').
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apply T_App with (σ':=τ0) (σ:=τ0) (τ:=τ').
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apply T_MorphFun.
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apply typing_weakening.
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apply morphism_path_solves_type.
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apply H4.
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apply T_Descend with (τ:=(type_ladder σ τ0)).
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apply T_Var.
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apply C_take.
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apply TSubRepr_Ladder, TSubRepr_Refl, TEq_Refl.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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apply TSubRepr_Ladder, TSubRepr_Refl, TEq_Refl.
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apply IHtranslate_typing2.
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apply H1.
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* argument coecrion is single function variable *)
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apply T_App with (σ':= τ0) (σ:=τ0).
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apply T_MorphFun.
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apply T_Var.
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apply H3.
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apply IHtranslate_typing2.
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apply H1.
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(* lemma: every context implies identity morphism *)
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* argument coecrion is chain of coercions *)
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apply T_App with (σ':=τ0) (σ:=τ0).
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apply T_MorphFun.
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apply T_MorphAbs.
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apply T_App with (σ':=τ') (σ:=τ').
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apply T_MorphFun.
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apply typing_weakening.
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apply morphism_path_solves_type.
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apply H3_0.
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apply T_App with (σ':=τ0) (σ:=τ0).
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apply T_MorphFun.
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apply typing_weakening.
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apply morphism_path_solves_type.
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apply H3_.
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apply T_Var.
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apply C_take.
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(* lemma: every context implies identity morphism *)
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* lemma: every context implies identity morphism *)
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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apply IHtranslate_typing2.
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apply H1.
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(* lemma: every context implies identity morphism *)
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* argument coercion is is map *)
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(*
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apply T_App with (σ':=(type_spec (type_id "Seq") τ0)) (σ:=(type_spec (type_id "Seq") τ0)).
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apply T_MorphFun.
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apply T_MorphAbs.
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apply T_App with (σ':=(type_spec (type_id "Seq") τ0)) (σ:=(type_spec (type_id "Seq") τ0)).
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apply T_App with (σ':=(type_fun τ0 τ')) (σ:=(type_fun τ0 τ')).
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apply T_TypeApp with
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(α:="T2"%string)
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(e:=(expr_ty_app (expr_var "map") τ0))
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(τ:=(type_fun
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(type_fun τ0 τ')
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(type_fun
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(type_spec (type_id "Seq") τ0)
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(type_spec (type_id "Seq") τ')))).
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apply T_TypeApp with
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(α:="T1"%string)
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(e:=(expr_var "map"))
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(τ:=(type_univ "T2"
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(type_fun
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(type_fun τ0 τ')
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(type_fun
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(type_spec (type_id "Seq") (type_var "T1"))
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(type_spec (type_id "Seq") (type_var "T2")))))).
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apply T_Var.
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admit.
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apply TSubst_VarReplace.
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apply TSubst_UnivReplace.
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*)
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admit.
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(* argument coercion *)
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apply M_Sub, TSubRepr_Refl, TEq_Refl.
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(* end case `e application` *)
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(* e is Morphism *)
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apply T_MorphFun.
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apply IHtranslate_typing.
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apply H0.
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(* e is Ascension *)
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apply T_Ascend with (τ:=τ).
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apply IHtranslate_typing.
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apply H0.
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apply H1.
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(* e is Desecension *)
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apply T_DescendImplicit with (τ:=τ).
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apply IHtranslate_typing.
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apply H0.
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apply H1.
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Admitted.
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(* e is stuck when it is neither a value, nor can it be reduced *)
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(* e is stuck when it is neither a value, nor can it be reduced *)
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Definition is_stuck (e:expr_term) : Prop :=
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Definition is_stuck (e:expr_term) : Prop :=
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~(is_value e) ->
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~(is_value e) ->
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~(exists e', e -->β e')
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~(exists e', e -->β e')
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.
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.
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(* every well typed term is not stuck *)
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(* the translation any well typed term is not stuck *)
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Lemma progress :
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Lemma progress :
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forall (e:expr_term),
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forall Γ e τ e',
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(is_well_typed e) -> ~(is_stuck e)
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(Γ |- e \is τ) ->
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(translate_typing Γ e τ e') ->
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~(is_stuck e')
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.
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.
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Proof.
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Proof.
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Admitted.
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Admitted.
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(* reduction step preserves well-typedness *)
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(* every well-typed expression is translated,
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Lemma preservation :
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* such that it be reduced to a value
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*)
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Theorem soundness :
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forall Γ e e' τ,
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forall Γ e e' τ,
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(Γ |- e \is τ) ->
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(Γ |- e \is τ) ->
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(e -->β e') ->
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(translate_typing Γ e τ e') ->
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(Γ |- e' \is τ)
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(exists v, (e' -->β* v) /\ (is_value v) /\ (Γ |- v \is τ))
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.
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Proof.
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Admitted.
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(* every well-typed expression can be reduced to a value *)
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Theorem soundness :
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forall (e:expr_term),
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(is_well_typed e) ->
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(exists e', e -->β* e' /\ (is_value e'))
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.
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.
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Proof.
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Proof.
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intros.
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intros.
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(* `e` is Variable *)
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induction H0.
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exists (expr_var x).
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split. apply Multi_Refl.
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split. apply V_Abs,VAbs_Var.
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apply H.
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(* `e` is Let-Binding *)
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exists (expr_subst x e' t').
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split.
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apply Multi_Step with (y:=(expr_subst x e' t')).
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apply E_Let with (x:=x) (a:=e') (e:=t').
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apply Multi_Refl.
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(*
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split.
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unfold expr_subst.
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induction t'.
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exists (expr_subst x e' (expr_var s)).
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split.
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unfold expr_subst.
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apply E_Let.
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*)
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admit.
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(* `e` is Type-Abstraction *)
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exists (expr_ty_abs α e').
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split.
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apply Multi_Refl.
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split.
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apply V_Abs, VAbs_TypAbs.
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apply T_TypeAbs.
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apply translation_preservation with (e:=e).
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apply H0.
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apply H1.
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(* `e` is Type-Application *)
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admit.
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(* `e`is Abstraction *)
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exists (expr_abs x σ e').
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split. apply Multi_Refl.
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split. apply V_Abs, VAbs_Abs.
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apply T_Abs.
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apply translation_preservation with (e:=e).
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apply H0.
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apply H2.
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(* `e` is Morphism Abstraction *)
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exists (expr_morph x σ e').
|
||||||
|
split. apply Multi_Refl.
|
||||||
|
split. apply V_Abs, VAbs_Morph.
|
||||||
|
apply T_MorphAbs.
|
||||||
|
apply translation_preservation with (e:=e).
|
||||||
|
apply H0.
|
||||||
|
apply H2.
|
||||||
|
|
||||||
|
(* `e` is Application *)
|
||||||
|
admit.
|
||||||
|
admit.
|
||||||
|
|
||||||
|
(* `e` is Ascension *)
|
||||||
|
admit.
|
||||||
|
|
||||||
|
(* `e` is Descension *)
|
||||||
|
admit.
|
||||||
Admitted.
|
Admitted.
|
||||||
|
|
||||||
End Soundness.
|
End Soundness.
|
||||||
|
|
55
coq/terms.v
55
coq/terms.v
|
@ -30,45 +30,34 @@ Inductive expr_term : Type :=
|
||||||
| expr_descend : type_term -> expr_term -> expr_term
|
| expr_descend : type_term -> expr_term -> expr_term
|
||||||
.
|
.
|
||||||
|
|
||||||
(* TODO
|
|
||||||
|
|
||||||
Inductive type_DeBruijn : Type :=
|
|
||||||
| id : nat -> type_DeBruijn
|
|
||||||
| var : nat -> type_DeBruijn
|
|
||||||
| fun : type_DeBruijn -> type_DeBruijn -> type_DeBruijn
|
|
||||||
| univ : type_DeBruijn -> type_DeBruijn
|
|
||||||
| spec : type_DeBruijn -> type_DeBruijn -> type_DeBruijn
|
|
||||||
| morph : type_DeBruijn -> type_DeBruijn -> type_DeBruijn
|
|
||||||
| ladder : type_DeBruijn -> type_DeBruijn -> type_DeBruijn
|
|
||||||
|
|
||||||
Inductive expr_DeBruijn : Type :=
|
|
||||||
| var : nat -> expr_DeBruijn
|
|
||||||
| ty_abs : expr_DeBruijn -> expr_DeBruijn
|
|
||||||
| ty_app : expr_DeBruijn -> type_DeBruijn -> expr_Debruijn
|
|
||||||
| abs : type_DeBruijn -> expr_DeBruijn -> expr_DeBruijn
|
|
||||||
| morph : type_DeBruijn -> expr_DeBruijn -> expr_Debruijn
|
|
||||||
| app : expr_DeBruijn -> expr_DeBruijn -> expr_Debruijn
|
|
||||||
| let : type_DeBruijn -> expr_DeBruijn -> expr_Debruijn -> expr_Debruijn
|
|
||||||
| ascend : type_DeBruijn -> expr_DeBruijn -> expr_DeBruijn
|
|
||||||
| descend : type_DeBruijn -> expr_DeBruijn -> expr_DeBruijn
|
|
||||||
.
|
|
||||||
*)
|
|
||||||
|
|
||||||
|
|
||||||
|
|
||||||
(* values *)
|
(* values *)
|
||||||
Inductive is_value : expr_term -> Prop :=
|
Inductive is_abs_value : expr_term -> Prop :=
|
||||||
| V_Abs : forall x τ e,
|
| VAbs_Var : forall x,
|
||||||
(is_value (expr_abs x τ e))
|
(is_abs_value (expr_var x))
|
||||||
|
|
||||||
| V_TypAbs : forall τ e,
|
| VAbs_Abs : forall x τ e,
|
||||||
(is_value (expr_ty_abs τ e))
|
(is_abs_value (expr_abs x τ e))
|
||||||
|
|
||||||
|
| VAbs_Morph : forall x τ e,
|
||||||
|
(is_abs_value (expr_morph x τ e))
|
||||||
|
|
||||||
|
| VAbs_TypAbs : forall τ e,
|
||||||
|
(is_abs_value (expr_ty_abs τ e))
|
||||||
|
.
|
||||||
|
|
||||||
|
Inductive is_value : expr_term -> Prop :=
|
||||||
|
| V_Abs : forall e,
|
||||||
|
(is_abs_value e) ->
|
||||||
|
(is_value e)
|
||||||
|
|
||||||
| V_Ascend : forall τ e,
|
| V_Ascend : forall τ e,
|
||||||
(is_value e) ->
|
(is_abs_value e) ->
|
||||||
(is_value (expr_ascend τ e))
|
(is_value (expr_ascend τ e))
|
||||||
.
|
|
||||||
|
|
||||||
|
| V_Descend : forall τ e,
|
||||||
|
(is_abs_value e) ->
|
||||||
|
(is_value (expr_descend τ e))
|
||||||
|
.
|
||||||
|
|
||||||
Declare Scope ladder_type_scope.
|
Declare Scope ladder_type_scope.
|
||||||
Declare Scope ladder_expr_scope.
|
Declare Scope ladder_expr_scope.
|
||||||
|
|
Loading…
Reference in a new issue