X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;ds=sidebyside;f=helm%2Fsoftware%2Fmatita%2Ftests%2Fcoercions_russell.ma;h=48639b3cb54afdad3c89def91c1b04be77f3e83b;hb=b367de0252e88d6b0476648d5ceac7e4aeffca27;hp=50bf81dfd44647c6970923381b708c168175d3ef;hpb=aa654b256f9deca4ed5bb2b13b87e1d69377f17d;p=helm.git diff --git a/helm/software/matita/tests/coercions_russell.ma b/helm/software/matita/tests/coercions_russell.ma index 50bf81dfd..48639b3cb 100644 --- a/helm/software/matita/tests/coercions_russell.ma +++ b/helm/software/matita/tests/coercions_russell.ma @@ -12,42 +12,120 @@ (* *) (**************************************************************************) -set "baseuri" "cic:/matita/test/russell/". + include "nat/orders.ma". include "list/list.ma". +include "datatypes/constructors.ma". inductive sigma (A:Type) (P:A → Prop) : Type ≝ sig_intro: ∀a:A. P a → sigma A P. interpretation "sigma" 'exists \eta.x = - (cic:/matita/test/russell/sigma.ind#xpointer(1/1) _ x). + (cic:/matita/tests/coercions_russell/sigma.ind#xpointer(1/1) _ x). definition inject ≝ λP.λa:list nat.λp:P a. sig_intro ? P ? p. -coercion cic:/matita/test/russell/inject.con 0 1. +coercion cic:/matita/tests/coercions_russell/inject.con 0 1. definition eject ≝ λP.λc: ∃n:list nat.P n. match c with [ sig_intro w _ ⇒ w]. -coercion cic:/matita/test/russell/eject.con. +coercion cic:/matita/tests/coercions_russell/eject.con. alias symbol "exists" (instance 2) = "exists". lemma tl : ∀l:list nat. l ≠ [] → ∃l1.∃a.a :: l1 = l. -letin program ≝ - (λl:list nat. λH:l ≠ [].match l with [ nil ⇒ λH.[] | cons x l1 ⇒ λH.l1] H); -letin program_spec ≝ (program : ∀l:list nat. l ≠ [] → ∃l1.∃a.a :: l1 = l); - [ generalize in match H; cases l; [intros (h1); cases (h1 ?); reflexivity] - intros; apply (ex_intro ? ? n); apply eq_f; reflexivity; ] -exact program_spec; + apply rule (λl:list nat. λ_.match l with [ nil ⇒ [] | cons x l1 ⇒ l1]); + [ exists; [2: reflexivity | skip] + | destruct; elim H; reflexivity] qed. alias symbol "exists" (instance 3) = "exists". lemma tl2 : ∀l:∃l:list nat. l ≠ []. ∃l1.∃a.a :: l1 = l. -letin program ≝ - (λl:list nat. match l with [ nil ⇒ [] | cons x l1 ⇒ l1]); -letin program_spec ≝ - (program : ∀l:∃l:list nat. l ≠ []. ∃l1.∃a.a :: l1 = l); - [ autobatch; | generalize in match H; clear H; cases s; simplify; - intros; cases (H H1); ] -exact program_spec. +apply rule (λl:list nat. match l with [ nil ⇒ [] | cons x l1 ⇒ l1]); +[ autobatch; +| cases s in H; simplify; intros; cases (H H1); ] +qed. + +definition nat_return := λn:nat. Some ? n. + +coercion cic:/matita/tests/coercions_russell/nat_return.con. + +definition raise_exn := None nat. + +definition try_with := + λx,e. match x with [ None => e | Some (x : nat) => x]. + +lemma hd : list nat → option nat := + λl.match l with [ nil ⇒ raise_exn | cons x _ ⇒ nat_return x ]. + +axiom f : nat -> nat. + +definition bind ≝ λf:nat->nat.λx. + match x with [None ⇒ raise_exn| Some x ⇒ nat_return(f x)]. + +include "datatypes/bool.ma". +include "list/sort.ma". +include "nat/compare.ma". + +definition inject_opt ≝ λP.λa:option nat.λp:P a. sig_intro ? P ? p. + +coercion cic:/matita/tests/coercions_russell/inject_opt.con 0 1. + +definition eject_opt ≝ λP.λc: ∃n:option nat.P n. match c with [ sig_intro w _ ⇒ w]. + +coercion cic:/matita/tests/coercions_russell/eject_opt.con. + +(* we may define mem as in the following lemma and get rid of it *) +definition find_spec ≝ + λl,p.λres:option nat. + match res with + [ None ⇒ ∀y. mem ? eqb y l = true → p y = false + | Some x ⇒ mem ? eqb x l = true ∧ + p x = true ∧ + ∀y.mem ? eqb y l = true → p y = true → x ≠ y → + ∃l1,l2,l3.l = l1 @ [x] @ l2 @ [y] @ l3]. + +lemma mem_x_to_ex_l1_l2 : ∀l,x.mem ? eqb x l = true → ∃l1,l2.l = l1 @ [x] @ l2. +intros 2; elim l (H hd tl IH H); [simplify in H; destruct H] +generalize in match H; clear H; +simplify; apply (eqb_elim x hd); simplify; intros; +[1:clear IH; rewrite < H; apply (ex_intro ? ? []); +|2:lapply(IH H1); clear H1 IH; decompose; rewrite > H2; clear H2] +simplify; autobatch; qed. + +notation > "'If' b 'Then' t 'Else' f" non associative +with precedence 90 for @{ match $b with [ true ⇒ $t | _ ⇒ $f ] }. + +alias symbol "exists" = "sigma". +definition sigma_find_spec : ∀p,l. ∃res.find_spec l p res. +apply rule (λp. + let rec aux l ≝ + match l with + [ nil ⇒ raise_exn + | cons x l ⇒ If p x Then nat_return x Else aux l] + in aux); +(* l = x::tl ∧ p x = false *) +[1: cases (aux l1); clear aux; + cases a in H2; simplify; + [1: intros 2; apply (eqb_elim y n); intros (Eyn); autobatch; + |2: intros; decompose; repeat split; [2: assumption]; intros; + [1: cases (eqb n1 n); simplify; autobatch; + |2: generalize in match (refl_eq ? (eqb y n)); + generalize in ⊢ (? ? ? %→?); + intro; cases b; clear b; intro Eyn; rewrite > Eyn in H3; simplify in H3; + [1: rewrite > (eqb_true_to_eq ? ? Eyn) in H6; rewrite > H1 in H6; destruct H6; + |2: lapply H4; try assumption; decompose; clear H4; rewrite > H8; + simplify; autobatch depth = 4;]]] +(* l = x::tl ∧ p x = true *) +|2: unfold find_spec; unfold nat_return; simplify; repeat split; [2: assumption] + [1: rewrite > eqb_n_n; reflexivity + |2: intro; generalize in match (refl_eq ? (eqb y n)); generalize in ⊢ (? ? ? %→?); + intro; cases b; clear b; intro Eyn; rewrite > Eyn; + [1: rewrite > (eqb_true_to_eq ? ? Eyn);] clear Eyn; simplify; intros; + [1: cases H4; reflexivity + |2: lapply (mem_x_to_ex_l1_l2 ? ? H2); decompose; rewrite > H6; + apply (ex_intro ? ? []); simplify; autobatch;]] +(* l = [] *) +|3: unfold raise_exn; simplify; intros; destruct H1;] +qed. \ No newline at end of file