X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=helm%2Fsoftware%2Fmatita%2Ftests%2Fdestruct_bb.ma;h=382620e34f23fa458a31029354c79039fca61833;hb=2dd6e8f11fa3ac2995f326ecb742d9b4e8948fce;hp=494d5805a286f72977ac220c98b2eeb28cb721e6;hpb=c6c248e635ef35e9515ed981374ce2a0cef30e62;p=helm.git diff --git a/helm/software/matita/tests/destruct_bb.ma b/helm/software/matita/tests/destruct_bb.ma index 494d5805a..382620e34 100644 --- a/helm/software/matita/tests/destruct_bb.ma +++ b/helm/software/matita/tests/destruct_bb.ma @@ -79,7 +79,7 @@ definition R2 : ∀b1: T1 b0 e0. ∀e1:R1 ??? a1 ? e0 = b1. T2 b0 e0 b1 e1. -intros 9;intro e1; +intros (T0 a0 T1 a1 T2 a2); apply (eq_rect' ????? e1); apply (R1 ?? ? ?? e0); simplify;assumption; @@ -94,14 +94,15 @@ definition R3 : ∀a2:T2 a0 (refl_eq ? a0) a1 (refl_eq ? a1). ∀T3:∀x0:T0. ∀p0:a0=x0. ∀x1:T1 x0 p0.∀p1:R1 ??? a1 ? p0 = x1. ∀x2:T2 x0 p0 x1 p1.R2 T0 a0 T1 a1 T2 a2 ? p0 ? p1 = x2→ Type. + ∀a3:T3 a0 (refl_eq ? a0) a1 (refl_eq ? a1) a2 (refl_eq ? a2). ∀b0:T0. ∀e0:a0 = b0. ∀b1: T1 b0 e0. ∀e1:R1 ??? a1 ? e0 = b1. ∀b2: T2 b0 e0 b1 e1. ∀e2:R2 T0 a0 T1 a1 T2 a2 ? e0 ? e1 = b2. - ∀a3:T3 a0 (refl_eq ? a0) a1 (refl_eq ? a1) a2 (refl_eq ? a2).T3 b0 e0 b1 e1 b2 e2. -intros 12;intros 2 (e2 H); + T3 b0 e0 b1 e1 b2 e2. +intros (T0 a0 T1 a1 T2 a2 T3 a3); apply (eq_rect' ????? e2); apply (R2 ?? ? ???? e0 ? e1); simplify;assumption; @@ -194,16 +195,91 @@ inductive I2 : ∀n:nat.I1 n → Type ≝ inductive I3 : Type ≝ | kI3 : ∀x1:nat.∀x2:I1 x1.∀x3:I2 x1 x2.I3. -definition I3d: I3 → I3 → Type ≝ -λx,y.match x with +(* lemma idfof : (∀t1,t2,t3,u1,u2,u3.((λy1:ℕ.λp1:t1=y1.λy2:I1 y1.λp2:R1 ℕ t1 (λy1:ℕ.λp1:t1=y1.I1 y1) t2 y1 p1 =y2. + λy3:I2 y1 y2.λp3:R2 ℕ t1 (λy1:ℕ.λp1:t1=y1.I1 y1) t2 (λy1:ℕ.λp1:t1=y1.λy2:I1 y1.λp2:R1 ℕ t1 (λy1:ℕ.λp1:t1 =y1.I1 y1) t2 y1 p1 =y2.I2 y1 y2) t3 y1 p1 y2 p2 =y3. + kI3 y1 y2 y3 =kI3 u1 u2 u3) +t1 (refl_eq ℕ t1) t2 (refl_eq ((λy1:ℕ.λp1:t1=y1.I1 y1) t1 (refl_eq ℕ t1)) t2) + t3 (refl_eq ((λy1:ℕ.λp1:t1=y1.λy2:I1 y1.λp2:R1 ℕ t1 (λy1:ℕ.λp1:t1=y1.I1 y1) t2 y1 p1 =y2.I2 y1 y2) t1 (refl_eq ℕ t1) t2 (refl_eq ((λy1:ℕ.λp1:t1=y1.I1 y1) t1 (refl_eq ℕ t1)) t2)) t3) + ) + → True). +simplify; *) + +definition I3d : ∀x,y:I3.x = y → Type ≝ +λx,y.match x return (λx:I3.x = y → Type) with +[ kI3 x1 x2 x3 ⇒ match y return (λy:I3.kI3 x1 x2 x3 = y → Type) with + [ kI3 y1 y2 y3 ⇒ + λe:kI3 x1 x2 x3 = kI3 y1 y2 y3. + ∀P:Prop.(∀e1: x1 = y1. + ∀e2: R1 ?? (λz1,p1.I1 z1) ?? e1 = y2. + ∀e3: R2 ???? (λz1,p1,z2,p2.I2 z1 z2) x3 ? e1 ? e2 = y3. + R3 ?????? + (λz1,p1,z2,p2,z3,p3. + eq ? (kI3 z1 z2 z3) (kI3 y1 y2 y3)) e y1 e1 y2 e2 y3 e3 + = refl_eq ? (kI3 y1 y2 y3) + → P) → P]]. + +definition I3d : ∀x,y:I3.x=y → Type. +intros 2;cases x;cases y;intro; +apply (∀P:Prop.(∀e1: x1 = x3. + ∀e2: R1 ?? (λy1,p1.I1 y1) ?? e1 = x4. + ∀e3: R2 ???? (λy1,p1,y2,p2.I2 y1 y2) i ? e1 ? e2 = i1. + R3 ?????? + (λy1,p1,y2,p2,y3,p3. + eq ? (kI3 y1 y2 y3) (kI3 x3 x4 i1)) H x3 e1 x4 e2 i1 e3 + = refl_eq ? (kI3 x3 x4 i1) + → P) → P); +qed. + +(* definition I3d : ∀x,y:nat. x = y → Type ≝ +λx,y. +match x + return (λx.x = y → Type) + with +[ O ⇒ match y return (λy.O = y → Type) with + [ O ⇒ λe:O = O.∀P.P → P + | S q ⇒ λe: O = S q. ∀P.P] +| S p ⇒ match y return (λy.S p = y → Type) with + [ O ⇒ λe:S p = O.∀P.P + | S q ⇒ λe: S p = S q. ∀P.(p = q → P) → P]]. + +definition I3d: + ∀x,y:I3. x = y → Type + ≝ +λx,y. +match x with +[ kI3 t1 t2 (t3:I2 t1 t2) ⇒ match y with + [ kI3 u1 u2 u3 ⇒ λe:kI3 t1 t2 t3 = kI3 u1 u2 u3.∀P:Type. + (∀e1: t1 = u1. + ∀e2: R1 nat t1 (λy1:nat.λp1:y1 = u1.I1 y1) t2 ? e1 = u2. + ∀e3: R2 nat t1 (λy1,p1.I1 y1) t2 (λy1,p1,y2,p2.I2 y1 y2) t3 ? e1 ? e2 = u3. + (* ∀e: kI3 t1 t2 t3 = kI3 u1 u2 u3.*) + R3 nat t1 (λy1,p1.I1 y1) t2 (λy1,p1,y2,p2.I2 y1 y2) t3 + (λy1,p1,y2,p2,y3,p3.eq I3 (kI3 y1 y2 y3) (kI3 u1 u2 u3)) e u1 e1 u2 e2 u3 e3 = refl_eq I3 (kI3 u1 u2 u3) + → P) + → P]]. + +definition I3d: + ∀x,y:I3. + (∀x,y.match x with [ kI3 t1 t2 t3 ⇒ + match y with [ kI3 u1 u2 u3 ⇒ kI3 t1 t2 t3 = kI3 u1 u2 u3]]) → Type + ≝ +λx,y.λe: + (∀x,y.match x with [ kI3 t1 t2 t3 ⇒ + match y with [ kI3 u1 u2 u3 ⇒ kI3 t1 t2 t3 = kI3 u1 u2 u3]]). +match x with [ kI3 t1 t2 (t3:I2 t1 t2) ⇒ match y with [ kI3 u1 u2 u3 ⇒ ∀P:Type. (∀e1: t1 = u1. ∀e2: R1 ?? (λy1,p1.I1 y1) ?? e1 = u2. - ∀e3: R2 ???? (λy1,p1,y2,p2.I2 y1 y2) ? e1 ? e2 t3 = u3.P) → P]]. - -lemma I3nc : ∀a,b.a = b → I3d a b. -intros;rewrite > H;elim b;simplify;intros;apply f;reflexivity; + ∀e3: R2 ???? (λy1,p1,y2,p2.I2 y1 y2) t3 ? e1 ? e2 = u3. + (* ∀e: kI3 t1 t2 t3 = kI3 u1 u2 u3.*) + R3 nat t1 (λy1,p1.I1 y1) t2 (λy1,p1,y2,p2.I2 y1 y2) t3 + (λy1,p1,y2,p2,y3,p3.eq I3 (kI3 y1 y2 y3) (kI3 u1 u2 u3)) (e (kI3 t1 t2 t3) (kI3 u1 u2 u3)) u1 e1 u2 e2 u3 e3 = refl_eq ? (kI3 u1 u2 u3) + → P) + → P]].*) + +lemma I3nc : ∀a,b.∀e:a = b. I3d a b e. +intros;apply (R1 ????? e);elim a;whd;intros;apply H;reflexivity; qed. (*lemma R1_r : ΠA:Type.Πx:A.ΠP:Πy:A.y=x→Type.P x (refl_eq A x)→Πy:A.Πp:y=x.P y p. @@ -231,17 +307,25 @@ apply (R1_r ?? ? ?? e0); simplify;assumption; qed.*) -definition I3prova : ∀a,b,c,d,e,f.kI3 a b c = kI3 d e f → ∃P.P d e f. -intros;apply (I3nc ?? H);clear H; +definition I3prova : ∀a,b,c,d,e,f.∀Heq:kI3 a b c = kI3 d e f. + ∀P:? → ? → ? → ? → Prop. + P d e f Heq → + P a b c (refl_eq ??). +intros;apply (I3nc ?? Heq); simplify;intro; +generalize in match H as H;generalize in match Heq as Heq; generalize in match f as f;generalize in match e as e; -generalize in match c as c;generalize in match b as b; -clear f e c b; +clear H Heq f e; apply (R1 ????? e1);intros 5;simplify in e2; -generalize in match f as f;generalize in match c as c; -clear f c; -apply (R1 ????? e2);intros;simplify in H; -elim daemon; +generalize in match H as H;generalize in match Heq as Heq; +generalize in match f as f; +clear H Heq f; +apply (R1 ????? e2);intros 4;simplify in e3; +generalize in match H as H;generalize in match Heq as Heq; +clear H Heq; +apply (R1 ????? e3);intros;simplify in H1; +apply (R1 ????? H1); +assumption; qed.