logrelnew #1
1 changed files with 93 additions and 8 deletions
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@ -13,7 +13,7 @@ Definition ProdSpace {n} (PA : PTm n -> Prop)
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Definition SumSpace {n} (PA : PTm n -> Prop)
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(PF : PTm n -> (PTm n -> Prop) -> Prop) t : Prop :=
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SNe t \/ exists a b, rtc TRedSN t (PPair a b) /\ PA a /\ (forall PB, PF a PB -> PB b).
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(exists v, rtc TRedSN t v /\ SNe v) \/ exists a b, rtc TRedSN t (PPair a b) /\ PA a /\ (forall PB, PF a PB -> PB b).
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Definition BindSpace {n} p := if p is PPi then @ProdSpace n else SumSpace.
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@ -22,7 +22,7 @@ Reserved Notation "⟦ A ⟧ i ;; I ↘ S" (at level 70).
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Inductive InterpExt {n} i (I : nat -> PTm n -> Prop) : PTm n -> (PTm n -> Prop) -> Prop :=
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| InterpExt_Ne A :
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SNe A ->
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⟦ A ⟧ i ;; I ↘ SNe
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⟦ A ⟧ i ;; I ↘ (fun a => exists v, rtc TRedSN a v /\ SNe v)
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| InterpExt_Bind p A B PA PF :
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⟦ A ⟧ i ;; I ↘ PA ->
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(forall a, PA a -> exists PB, PF a PB) ->
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@ -95,6 +95,25 @@ Qed.
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#[export]Hint Rewrite @InterpUnivN_nolt : InterpUniv.
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Lemma InterpUniv_ind
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: forall (n i : nat) (P : PTm n -> (PTm n -> Prop) -> Prop),
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(forall A : PTm n, SNe A -> P A (fun a : PTm n => exists v : PTm n, rtc TRedSN a v /\ SNe v)) ->
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(forall (p : BTag) (A : PTm n) (B : PTm (S n)) (PA : PTm n -> Prop)
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(PF : PTm n -> (PTm n -> Prop) -> Prop),
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⟦ A ⟧ i ↘ PA ->
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P A PA ->
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(forall a : PTm n, PA a -> exists PB : PTm n -> Prop, PF a PB) ->
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(forall (a : PTm n) (PB : PTm n -> Prop), PF a PB -> ⟦ subst_PTm (scons a VarPTm) B ⟧ i ↘ PB) ->
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(forall (a : PTm n) (PB : PTm n -> Prop), PF a PB -> P (subst_PTm (scons a VarPTm) B) PB) ->
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P (PBind p A B) (BindSpace p PA PF)) ->
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(forall j : nat, j < i -> P (PUniv j) (fun A => exists PA, ⟦ A ⟧ j ↘ PA)) ->
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(forall (A A0 : PTm n) (PA : PTm n -> Prop), TRedSN A A0 -> ⟦ A0 ⟧ i ↘ PA -> P A0 PA -> P A PA) ->
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forall (p : PTm n) (P0 : PTm n -> Prop), ⟦ p ⟧ i ↘ P0 -> P p P0.
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Proof.
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elim /Wf_nat.lt_wf_ind => n ih i . simp InterpUniv.
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apply InterpExt_ind.
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Qed.
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Derive Dependent Inversion iinv with (forall n i I (A : PTm n) PA, InterpExt i I A PA) Sort Prop.
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Lemma InterpExt_cumulative n i j I (A : PTm n) PA :
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@ -133,7 +152,7 @@ Lemma adequacy_ext i n I A PA
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CR PA /\ SN A.
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Proof.
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elim : A PA / h.
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- hauto lq:on ctrs:SN unfold:CR.
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- hauto l:on use:N_Exps ctrs:SN,SNe.
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- move => p A B PA PF hPA [ihA0 ihA1] hTot hRes ihPF.
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have hb : PA PBot by hauto q:on ctrs:SNe.
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have hb' : SN PBot by hauto q:on ctrs:SN, SNe.
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@ -142,16 +161,13 @@ Proof.
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+ case : p =>//=.
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* rewrite /ProdSpace.
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qauto use:SN_AppInv unfold:CR.
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* rewrite /SumSpace => a []; first by apply N_SNe.
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move => [q0][q1]*.
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have : SN q0 /\ SN q1 by hauto q:on.
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hauto lq:on use:N_Pair,N_Exps.
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* hauto q:on unfold:SumSpace use:N_SNe, N_Pair,N_Exps.
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+ move => a ha.
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case : p=>/=.
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* rewrite /ProdSpace => a0 *.
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suff : SNe (PApp a a0) by sfirstorder.
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hauto q:on use:N_App.
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* rewrite /SumSpace. tauto.
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* sfirstorder.
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+ apply N_Bind=>//=.
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have : SN (PApp (PAbs B) PBot).
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apply : N_Exp; eauto using N_β.
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@ -160,3 +176,72 @@ Proof.
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- sfirstorder.
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- hauto l:on ctrs:SN unfold:CR.
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Qed.
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Lemma InterpExt_Steps i n I A A0 PA :
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rtc TRedSN A A0 ->
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⟦ A0 : PTm n ⟧ i ;; I ↘ PA ->
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⟦ A ⟧ i ;; I ↘ PA.
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Proof. induction 1; eauto using InterpExt_Step. Qed.
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Lemma InterpUniv_Steps i n A A0 PA :
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rtc TRedSN A A0 ->
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⟦ A0 : PTm n ⟧ i ↘ PA ->
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⟦ A ⟧ i ↘ PA.
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Proof. hauto l:on use:InterpExt_Steps rew:db:InterpUniv. Qed.
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Lemma adequacy i n A PA
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(h : ⟦ A : PTm n ⟧ i ↘ PA) :
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CR PA /\ SN A.
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Proof.
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move : i A PA h.
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elim /Wf_nat.lt_wf_ind => i ih A PA.
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simp InterpUniv.
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apply adequacy_ext.
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hauto lq:on ctrs:rtc use:InterpUniv_Steps.
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hauto l:on use:InterpExt_Ne rew:db:InterpUniv.
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Qed.
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Lemma InterpExt_back_clos n i I (A : PTm n) PA
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(hI1 : forall j, j < i -> CR (I j))
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(hI : forall j, j < i -> forall a b, TRedSN a b -> I j b -> I j a) :
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⟦ A ⟧ i ;; I ↘ PA ->
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forall a b, TRedSN a b ->
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PA b -> PA a.
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Proof.
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move => h.
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elim : A PA /h; eauto.
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hauto q:on ctrs:rtc.
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move => p A B PA PF hPA ihPA hTot hRes ihPF a b hr.
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case : p => //=.
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- rewrite /ProdSpace.
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move => hba a0 PB ha hPB.
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suff : TRedSN (PApp a a0) (PApp b a0) by hauto lq:on.
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apply N_AppL => //=.
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hauto q:on use:adequacy_ext.
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- hauto lq:on ctrs:rtc unfold:SumSpace.
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Qed.
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Lemma InterpUniv_back_clos n i (A : PTm n) PA :
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⟦ A ⟧ i ↘ PA ->
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forall a b, TRedSN a b ->
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PA b -> PA a.
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Proof.
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simp InterpUniv. apply InterpExt_back_clos;
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hauto l:on use:adequacy unfold:CR ctrs:InterpExt rew:db:InterpUniv.
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Qed.
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Lemma InterpUniv_back_closs n i (A : PTm n) PA :
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⟦ A ⟧ i ↘ PA ->
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forall a b, rtc TRedSN a b ->
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PA b -> PA a.
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Proof.
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induction 2; hauto lq:on ctrs:rtc use:InterpUniv_back_clos.
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Qed.
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Lemma InterpExt_Join n i I (A B : PTm n) PA PB :
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⟦ A ⟧ i ;; I ↘ PA ->
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⟦ B ⟧ i ;; I ↘ PB ->
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DJoin.R A B ->
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PA = PB.
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Proof.
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