X-Git-Url: http://matita.cs.unibo.it/gitweb/?p=helm.git;a=blobdiff_plain;f=matita%2Fmatita%2Fcontribs%2Flambdadelta%2Fstatic_2%2Fstatic%2Frdeq_rdeq.ma;h=30069162df6bb1575ab1056b90558ec858b7eb37;hp=316438d662241b1c5a9325fa866db8ff9ff78d34;hb=4173283e148199871d787c53c0301891deb90713;hpb=a67fc50ccfda64377e2c94c18c3a0d9265f651db diff --git a/matita/matita/contribs/lambdadelta/static_2/static/rdeq_rdeq.ma b/matita/matita/contribs/lambdadelta/static_2/static/rdeq_rdeq.ma index 316438d66..30069162d 100644 --- a/matita/matita/contribs/lambdadelta/static_2/static/rdeq_rdeq.ma +++ b/matita/matita/contribs/lambdadelta/static_2/static/rdeq_rdeq.ma @@ -16,85 +16,84 @@ include "static_2/syntax/ext2_ext2.ma". include "static_2/syntax/tdeq_tdeq.ma". include "static_2/static/rdeq_length.ma". -(* DEGREE-BASED EQUIVALENCE FOR LOCAL ENVIRONMENTS ON REFERRED ENTRIES ******) +(* SORT-IRRELEVANT EQUIVALENCE FOR LOCAL ENVIRONMENTS ON REFERRED ENTRIES ***) (* Advanced properties ******************************************************) (* Basic_2A1: uses: lleq_sym *) -lemma rdeq_sym: ∀h,o,T. symmetric … (rdeq h o T). +lemma rdeq_sym: ∀T. symmetric … (rdeq T). /3 width=3 by rdeq_fsge_comp, rex_sym, tdeq_sym/ qed-. (* Basic_2A1: uses: lleq_dec *) -lemma rdeq_dec: ∀h,o,L1,L2. ∀T:term. Decidable (L1 ≛[h, o, T] L2). +lemma rdeq_dec: ∀L1,L2. ∀T:term. Decidable (L1 ≛[T] L2). /3 width=1 by rex_dec, tdeq_dec/ qed-. (* Main properties **********************************************************) (* Basic_2A1: uses: lleq_bind lleq_bind_O *) -theorem rdeq_bind: ∀h,o,p,I,L1,L2,V1,V2,T. - L1 ≛[h, o, V1] L2 → L1.ⓑ{I}V1 ≛[h, o, T] L2.ⓑ{I}V2 → - L1 ≛[h, o, ⓑ{p,I}V1.T] L2. +theorem rdeq_bind: ∀p,I,L1,L2,V1,V2,T. + L1 ≛[V1] L2 → L1.ⓑ{I}V1 ≛[T] L2.ⓑ{I}V2 → + L1 ≛[ⓑ{p,I}V1.T] L2. /2 width=2 by rex_bind/ qed. (* Basic_2A1: uses: lleq_flat *) -theorem rdeq_flat: ∀h,o,I,L1,L2,V,T. L1 ≛[h, o, V] L2 → L1 ≛[h, o, T] L2 → - L1 ≛[h, o, ⓕ{I}V.T] L2. +theorem rdeq_flat: ∀I,L1,L2,V,T. + L1 ≛[V] L2 → L1 ≛[T] L2 → L1 ≛[ⓕ{I}V.T] L2. /2 width=1 by rex_flat/ qed. -theorem rdeq_bind_void: ∀h,o,p,I,L1,L2,V,T. - L1 ≛[h, o, V] L2 → L1.ⓧ ≛[h, o, T] L2.ⓧ → - L1 ≛[h, o, ⓑ{p,I}V.T] L2. +theorem rdeq_bind_void: ∀p,I,L1,L2,V,T. + L1 ≛[V] L2 → L1.ⓧ ≛[T] L2.ⓧ → L1 ≛[ⓑ{p,I}V.T] L2. /2 width=1 by rex_bind_void/ qed. (* Basic_2A1: uses: lleq_trans *) -theorem rdeq_trans: ∀h,o,T. Transitive … (rdeq h o T). -#h #o #T #L1 #L * #f1 #Hf1 #HL1 #L2 * #f2 #Hf2 #HL2 +theorem rdeq_trans: ∀T. Transitive … (rdeq T). +#T #L1 #L * #f1 #Hf1 #HL1 #L2 * #f2 #Hf2 #HL2 lapply (frees_tdeq_conf_rdeq … Hf1 T … HL1) // #H0 lapply (frees_mono … Hf2 … H0) -Hf2 -H0 /5 width=7 by sex_trans, sex_eq_repl_back, tdeq_trans, ext2_trans, ex2_intro/ qed-. (* Basic_2A1: uses: lleq_canc_sn *) -theorem rdeq_canc_sn: ∀h,o,T. left_cancellable … (rdeq h o T). +theorem rdeq_canc_sn: ∀T. left_cancellable … (rdeq T). /3 width=3 by rdeq_trans, rdeq_sym/ qed-. (* Basic_2A1: uses: lleq_canc_dx *) -theorem rdeq_canc_dx: ∀h,o,T. right_cancellable … (rdeq h o T). +theorem rdeq_canc_dx: ∀T. right_cancellable … (rdeq T). /3 width=3 by rdeq_trans, rdeq_sym/ qed-. -theorem rdeq_repl: ∀h,o,L1,L2. ∀T:term. L1 ≛[h, o, T] L2 → - ∀K1. L1 ≛[h, o, T] K1 → ∀K2. L2 ≛[h, o, T] K2 → K1 ≛[h, o, T] K2. +theorem rdeq_repl: ∀L1,L2. ∀T:term. L1 ≛[T] L2 → + ∀K1. L1 ≛[T] K1 → ∀K2. L2 ≛[T] K2 → K1 ≛[T] K2. /3 width=3 by rdeq_canc_sn, rdeq_trans/ qed-. (* Negated properties *******************************************************) (* Note: auto works with /4 width=8/ so rdeq_canc_sn is preferred **********) (* Basic_2A1: uses: lleq_nlleq_trans *) -lemma rdeq_rdneq_trans: ∀h,o.∀T:term.∀L1,L. L1 ≛[h, o, T] L → - ∀L2. (L ≛[h, o, T] L2 → ⊥) → (L1 ≛[h, o, T] L2 → ⊥). +lemma rdeq_rdneq_trans: ∀T:term.∀L1,L. L1 ≛[T] L → + ∀L2. (L ≛[T] L2 → ⊥) → (L1 ≛[T] L2 → ⊥). /3 width=3 by rdeq_canc_sn/ qed-. (* Basic_2A1: uses: nlleq_lleq_div *) -lemma rdneq_rdeq_div: ∀h,o.∀T:term.∀L2,L. L2 ≛[h, o, T] L → - ∀L1. (L1 ≛[h, o, T] L → ⊥) → (L1 ≛[h, o, T] L2 → ⊥). +lemma rdneq_rdeq_div: ∀T:term.∀L2,L. L2 ≛[T] L → + ∀L1. (L1 ≛[T] L → ⊥) → (L1 ≛[T] L2 → ⊥). /3 width=3 by rdeq_trans/ qed-. -theorem rdneq_rdeq_canc_dx: ∀h,o,L1,L. ∀T:term. (L1 ≛[h, o, T] L → ⊥) → - ∀L2. L2 ≛[h, o, T] L → L1 ≛[h, o, T] L2 → ⊥. +theorem rdneq_rdeq_canc_dx: ∀L1,L. ∀T:term. (L1 ≛[T] L → ⊥) → + ∀L2. L2 ≛[T] L → L1 ≛[T] L2 → ⊥. /3 width=3 by rdeq_trans/ qed-. (* Negated inversion lemmas *************************************************) (* Basic_2A1: uses: nlleq_inv_bind nlleq_inv_bind_O *) -lemma rdneq_inv_bind: ∀h,o,p,I,L1,L2,V,T. (L1 ≛[h, o, ⓑ{p,I}V.T] L2 → ⊥) → - (L1 ≛[h, o, V] L2 → ⊥) ∨ (L1.ⓑ{I}V ≛[h, o, T] L2.ⓑ{I}V → ⊥). +lemma rdneq_inv_bind: ∀p,I,L1,L2,V,T. (L1 ≛[ⓑ{p,I}V.T] L2 → ⊥) → + (L1 ≛[V] L2 → ⊥) ∨ (L1.ⓑ{I}V ≛[T] L2.ⓑ{I}V → ⊥). /3 width=2 by rnex_inv_bind, tdeq_dec/ qed-. (* Basic_2A1: uses: nlleq_inv_flat *) -lemma rdneq_inv_flat: ∀h,o,I,L1,L2,V,T. (L1 ≛[h, o, ⓕ{I}V.T] L2 → ⊥) → - (L1 ≛[h, o, V] L2 → ⊥) ∨ (L1 ≛[h, o, T] L2 → ⊥). +lemma rdneq_inv_flat: ∀I,L1,L2,V,T. (L1 ≛[ⓕ{I}V.T] L2 → ⊥) → + (L1 ≛[V] L2 → ⊥) ∨ (L1 ≛[T] L2 → ⊥). /3 width=2 by rnex_inv_flat, tdeq_dec/ qed-. -lemma rdneq_inv_bind_void: ∀h,o,p,I,L1,L2,V,T. (L1 ≛[h, o, ⓑ{p,I}V.T] L2 → ⊥) → - (L1 ≛[h, o, V] L2 → ⊥) ∨ (L1.ⓧ ≛[h, o, T] L2.ⓧ → ⊥). +lemma rdneq_inv_bind_void: ∀p,I,L1,L2,V,T. (L1 ≛[ⓑ{p,I}V.T] L2 → ⊥) → + (L1 ≛[V] L2 → ⊥) ∨ (L1.ⓧ ≛[T] L2.ⓧ → ⊥). /3 width=3 by rnex_inv_bind_void, tdeq_dec/ qed-.