(cic:/matita/logic/connectives/Not.con (cic:/matita/nat/primes/divides.ind#xpointer(1/1) n m)).
theorem reflexive_divides : reflexive nat divides.
-simplify.
+unfold reflexive.
intros.
-exact witness x x (S O) (times_n_SO x).
+exact (witness x x (S O) (times_n_SO x)).
qed.
theorem divides_to_div_mod_spec :
\forall n,m. O < n \to n \divides m \to div_mod_spec m n (m / n) O.
intros.elim H1.rewrite > H2.
constructor 1.assumption.
-apply lt_O_n_elim n H.intros.
+apply (lt_O_n_elim n H).intros.
rewrite < plus_n_O.
rewrite > div_times.apply sym_times.
qed.
theorem div_mod_spec_to_divides :
\forall n,m,p. div_mod_spec m n p O \to n \divides m.
intros.elim H.
-apply witness n m p.
+apply (witness n m p).
rewrite < sym_times.
-rewrite > plus_n_O (p*n).assumption.
+rewrite > (plus_n_O (p*n)).assumption.
qed.
theorem divides_to_mod_O:
\forall n,m. O < n \to n \divides m \to (m \mod n) = O.
-intros.apply div_mod_spec_to_eq2 m n (m / n) (m \mod n) (m / n) O.
+intros.apply (div_mod_spec_to_eq2 m n (m / n) (m \mod n) (m / n) O).
apply div_mod_spec_div_mod.assumption.
apply divides_to_div_mod_spec.assumption.assumption.
qed.
theorem mod_O_to_divides:
\forall n,m. O< n \to (m \mod n) = O \to n \divides m.
intros.
-apply witness n m (m / n).
-rewrite > plus_n_O (n * (m / n)).
+apply (witness n m (m / n)).
+rewrite > (plus_n_O (n * (m / n))).
rewrite < H1.
rewrite < sym_times.
(* Andrea: perche' hint non lo trova ?*)
qed.
theorem divides_n_O: \forall n:nat. n \divides O.
-intro. apply witness n O O.apply times_n_O.
+intro. apply (witness n O O).apply times_n_O.
+qed.
+
+theorem divides_n_n: \forall n:nat. n \divides n.
+intro. apply (witness n n (S O)).apply times_n_SO.
qed.
theorem divides_SO_n: \forall n:nat. (S O) \divides n.
-intro. apply witness (S O) n n. simplify.apply plus_n_O.
+intro. apply (witness (S O) n n). simplify.apply plus_n_O.
qed.
theorem divides_plus: \forall n,p,q:nat.
n \divides p \to n \divides q \to n \divides p+q.
intros.
-elim H.elim H1. apply witness n (p+q) (n2+n1).
+elim H.elim H1. apply (witness n (p+q) (n2+n1)).
rewrite > H2.rewrite > H3.apply sym_eq.apply distr_times_plus.
qed.
theorem divides_minus: \forall n,p,q:nat.
divides n p \to divides n q \to divides n (p-q).
intros.
-elim H.elim H1. apply witness n (p-q) (n2-n1).
+elim H.elim H1. apply (witness n (p-q) (n2-n1)).
rewrite > H2.rewrite > H3.apply sym_eq.apply distr_times_minus.
qed.
theorem divides_times: \forall n,m,p,q:nat.
n \divides p \to m \divides q \to n*m \divides p*q.
intros.
-elim H.elim H1. apply witness (n*m) (p*q) (n2*n1).
+elim H.elim H1. apply (witness (n*m) (p*q) (n2*n1)).
rewrite > H2.rewrite > H3.
-apply trans_eq nat ? (n*(m*(n2*n1))).
-apply trans_eq nat ? (n*(n2*(m*n1))).
+apply (trans_eq nat ? (n*(m*(n2*n1)))).
+apply (trans_eq nat ? (n*(n2*(m*n1)))).
apply assoc_times.
apply eq_f.
-apply trans_eq nat ? ((n2*m)*n1).
+apply (trans_eq nat ? ((n2*m)*n1)).
apply sym_eq. apply assoc_times.
-rewrite > sym_times n2 m.apply assoc_times.
+rewrite > (sym_times n2 m).apply assoc_times.
apply sym_eq. apply assoc_times.
qed.
theorem transitive_divides: transitive ? divides.
unfold.
intros.
-elim H.elim H1. apply witness x z (n2*n).
+elim H.elim H1. apply (witness x z (n2*n)).
rewrite > H3.rewrite > H2.
apply assoc_times.
qed.
theorem eq_mod_to_divides:\forall n,m,p. O< p \to
mod n p = mod m p \to divides p (n-m).
intros.
-cut n \le m \or \not n \le m.
+cut (n \le m \or \not n \le m).
elim Hcut.
-cut n-m=O.
+cut (n-m=O).
rewrite > Hcut1.
-apply witness p O O.
+apply (witness p O O).
apply times_n_O.
apply eq_minus_n_m_O.
assumption.
-apply witness p (n-m) ((div n p)-(div m p)).
+apply (witness p (n-m) ((div n p)-(div m p))).
rewrite > distr_times_minus.
rewrite > sym_times.
-rewrite > sym_times p.
-cut (div n p)*p = n - (mod n p).
+rewrite > (sym_times p).
+cut ((div n p)*p = n - (mod n p)).
rewrite > Hcut1.
rewrite > eq_minus_minus_minus_plus.
rewrite > sym_plus.
rewrite > sym_plus.
apply div_mod.
assumption.
-apply decidable_le n m.
+apply (decidable_le n m).
+qed.
+
+theorem antisymmetric_divides: antisymmetric nat divides.
+unfold antisymmetric.intros.elim H. elim H1.
+apply (nat_case1 n2).intro.
+rewrite > H3.rewrite > H2.rewrite > H4.
+rewrite < times_n_O.reflexivity.
+intros.
+apply (nat_case1 n).intro.
+rewrite > H2.rewrite > H3.rewrite > H5.
+rewrite < times_n_O.reflexivity.
+intros.
+apply antisymmetric_le.
+rewrite > H2.rewrite > times_n_SO in \vdash (? % ?).
+apply le_times_r.rewrite > H4.apply le_S_S.apply le_O_n.
+rewrite > H3.rewrite > times_n_SO in \vdash (? % ?).
+apply le_times_r.rewrite > H5.apply le_S_S.apply le_O_n.
qed.
(* divides le *)
theorem divides_to_le : \forall n,m. O < m \to n \divides m \to n \le m.
-intros. elim H1.rewrite > H2.cut O < n2.
-apply lt_O_n_elim n2 Hcut.intro.rewrite < sym_times.
+intros. elim H1.rewrite > H2.cut (O < n2).
+apply (lt_O_n_elim n2 Hcut).intro.rewrite < sym_times.
simplify.rewrite < sym_plus.
apply le_plus_n.
-elim le_to_or_lt_eq O n2.
+elim (le_to_or_lt_eq O n2).
assumption.
-absurd O<m.assumption.
+absurd (O<m).assumption.
rewrite > H2.rewrite < H3.rewrite < times_n_O.
-apply not_le_Sn_n O.
+apply (not_le_Sn_n O).
apply le_O_n.
qed.
theorem divides_to_lt_O : \forall n,m. O < m \to n \divides m \to O < n.
intros.elim H1.
-elim le_to_or_lt_eq O n (le_O_n n).
+elim (le_to_or_lt_eq O n (le_O_n n)).
assumption.
-rewrite < H3.absurd O < m.assumption.
+rewrite < H3.absurd (O < m).assumption.
rewrite > H2.rewrite < H3.
-simplify.exact not_le_Sn_n O.
+simplify.exact (not_le_Sn_n O).
qed.
(* boolean divides *)
| false \Rightarrow n \ndivides m].
apply eqb_elim.
intro.simplify.apply mod_O_to_divides.assumption.assumption.
-intro.simplify.intro.apply H1.apply divides_to_mod_O.assumption.assumption.
+intro.simplify.unfold Not.intro.apply H1.apply divides_to_mod_O.assumption.assumption.
qed.
theorem divides_b_true_to_divides :
theorem decidable_divides: \forall n,m:nat.O < n \to
decidable (n \divides m).
-intros.change with (n \divides m) \lor n \ndivides m.
+intros.change with ((n \divides m) \lor n \ndivides m).
cut
-match divides_b n m with
+(match divides_b n m with
[ true \Rightarrow n \divides m
-| false \Rightarrow n \ndivides m] \to n \divides m \lor n \ndivides m.
+| false \Rightarrow n \ndivides m] \to n \divides m \lor n \ndivides m).
apply Hcut.apply divides_b_to_Prop.assumption.
elim (divides_b n m).left.apply H1.right.apply H1.
qed.
theorem divides_to_divides_b_true : \forall n,m:nat. O < n \to
n \divides m \to divides_b n m = true.
intros.
-cut match (divides_b n m) with
+cut (match (divides_b n m) with
[ true \Rightarrow n \divides m
-| false \Rightarrow n \ndivides m] \to ((divides_b n m) = true).
+| false \Rightarrow n \ndivides m] \to ((divides_b n m) = true)).
apply Hcut.apply divides_b_to_Prop.assumption.
-elim divides_b n m.reflexivity.
+elim (divides_b n m).reflexivity.
absurd (n \divides m).assumption.assumption.
qed.
theorem not_divides_to_divides_b_false: \forall n,m:nat. O < n \to
\lnot(n \divides m) \to (divides_b n m) = false.
intros.
-cut match (divides_b n m) with
+cut (match (divides_b n m) with
[ true \Rightarrow n \divides m
-| false \Rightarrow n \ndivides m] \to ((divides_b n m) = false).
+| false \Rightarrow n \ndivides m] \to ((divides_b n m) = false)).
apply Hcut.apply divides_b_to_Prop.assumption.
-elim divides_b n m.
+elim (divides_b n m).
absurd (n \divides m).assumption.assumption.
reflexivity.
qed.
(* divides and pi *)
-theorem divides_f_pi_f : \forall f:nat \to nat.\forall n,i:nat.
-i < n \to f i \divides pi n f.
-intros 3.elim n.apply False_ind.apply not_le_Sn_O i H.
+theorem divides_f_pi_f : \forall f:nat \to nat.\forall n,m,i:nat.
+m \le i \to i \le n+m \to f i \divides pi n f m.
+intros 5.elim n.simplify.
+cut (i = m).rewrite < Hcut.apply divides_n_n.
+apply antisymmetric_le.assumption.assumption.
simplify.
-apply le_n_Sm_elim (S i) n1 H1.
-intro.
-apply transitive_divides ? (pi n1 f).
-apply H.simplify.apply le_S_S_to_le. assumption.
-apply witness ? ? (f n1).apply sym_times.
-intro.cut i = n1.
-rewrite > Hcut.
-apply witness ? ? (pi n1 f).reflexivity.
-apply inj_S.assumption.
+cut (i < S n1+m \lor i = S n1 + m).
+elim Hcut.
+apply (transitive_divides ? (pi n1 f m)).
+apply H1.apply le_S_S_to_le. assumption.
+apply (witness ? ? (f (S n1+m))).apply sym_times.
+rewrite > H3.
+apply (witness ? ? (pi n1 f m)).reflexivity.
+apply le_to_or_lt_eq.assumption.
qed.
+(*
theorem mod_S_pi: \forall f:nat \to nat.\forall n,i:nat.
i < n \to (S O) < (f i) \to (S (pi n f)) \mod (f i) = (S O).
intros.cut (pi n f) \mod (f i) = O.
apply divides_to_mod_O.apply trans_lt O (S O).apply le_n (S O).assumption.
apply divides_f_pi_f.assumption.
qed.
+*)
(* divides and fact *)
theorem divides_fact : \forall n,i:nat.
O < i \to i \le n \to i \divides n!.
-intros 3.elim n.absurd O<i.assumption.apply le_n_O_elim i H1.
-apply not_le_Sn_O O.
-change with i \divides (S n1)*n1!.
-apply le_n_Sm_elim i n1 H2.
+intros 3.elim n.absurd (O<i).assumption.apply (le_n_O_elim i H1).
+apply (not_le_Sn_O O).
+change with (i \divides (S n1)*n1!).
+apply (le_n_Sm_elim i n1 H2).
intro.
-apply transitive_divides ? n1!.
+apply (transitive_divides ? n1!).
apply H1.apply le_S_S_to_le. assumption.
-apply witness ? ? (S n1).apply sym_times.
+apply (witness ? ? (S n1)).apply sym_times.
intro.
rewrite > H3.
-apply witness ? ? n1!.reflexivity.
+apply (witness ? ? n1!).reflexivity.
qed.
theorem mod_S_fact: \forall n,i:nat.
(S O) < i \to i \le n \to (S n!) \mod i = (S O).
-intros.cut n! \mod i = O.
+intros.cut (n! \mod i = O).
rewrite < Hcut.
-apply mod_S.apply trans_lt O (S O).apply le_n (S O).assumption.
+apply mod_S.apply (trans_lt O (S O)).apply (le_n (S O)).assumption.
rewrite > Hcut.assumption.
-apply divides_to_mod_O.apply trans_lt O (S O).apply le_n (S O).assumption.
-apply divides_fact.apply trans_lt O (S O).apply le_n (S O).assumption.
+apply divides_to_mod_O.apply (trans_lt O (S O)).apply (le_n (S O)).assumption.
+apply divides_fact.apply (trans_lt O (S O)).apply (le_n (S O)).assumption.
assumption.
qed.
(S O) < i \to i \le n \to i \ndivides S n!.
intros.
apply divides_b_false_to_not_divides.
-apply trans_lt O (S O).apply le_n (S O).assumption.
-change with (eqb ((S n!) \mod i) O) = false.
+apply (trans_lt O (S O)).apply (le_n (S O)).assumption.
+change with ((eqb ((S n!) \mod i) O) = false).
rewrite > mod_S_fact.simplify.reflexivity.
assumption.assumption.
qed.
(\forall m:nat. m \divides n \to (S O) < m \to m = n).
theorem not_prime_O: \lnot (prime O).
-simplify.intro.elim H.apply not_le_Sn_O (S O) H1.
+unfold Not.unfold prime.intro.elim H.apply (not_le_Sn_O (S O) H1).
qed.
theorem not_prime_SO: \lnot (prime (S O)).
-simplify.intro.elim H.apply not_le_Sn_n (S O) H1.
+unfold Not.unfold prime.intro.elim H.apply (not_le_Sn_n (S O) H1).
qed.
(* smallest factor *)
theorem lt_SO_smallest_factor:
\forall n:nat. (S O) < n \to (S O) < (smallest_factor n).
intro.
-apply nat_case n.intro.apply False_ind.apply not_le_Sn_O (S O) H.
-intro.apply nat_case m.intro. apply False_ind.apply not_le_Sn_n (S O) H.
+apply (nat_case n).intro.apply False_ind.apply (not_le_Sn_O (S O) H).
+intro.apply (nat_case m).intro. apply False_ind.apply (not_le_Sn_n (S O) H).
intros.
change with
-S O < min_aux m1 (S(S m1)) (\lambda m.(eqb ((S(S m1)) \mod m) O)).
-apply lt_to_le_to_lt ? (S (S O)).
-apply le_n (S(S O)).
-cut (S(S O)) = (S(S m1)) - m1.
+(S O < min_aux m1 (S(S m1)) (\lambda m.(eqb ((S(S m1)) \mod m) O))).
+apply (lt_to_le_to_lt ? (S (S O))).
+apply (le_n (S(S O))).
+cut ((S(S O)) = (S(S m1)) - m1).
rewrite > Hcut.
apply le_min_aux.
apply sym_eq.apply plus_to_minus.
theorem lt_O_smallest_factor: \forall n:nat. O < n \to O < (smallest_factor n).
intro.
-apply nat_case n.intro.apply False_ind.apply not_le_Sn_n O H.
-intro.apply nat_case m.intro.
-simplify.apply le_n.
-intros.apply trans_lt ? (S O).
-simplify. apply le_n.
-apply lt_SO_smallest_factor.simplify. apply le_S_S.
+apply (nat_case n).intro.apply False_ind.apply (not_le_Sn_n O H).
+intro.apply (nat_case m).intro.
+simplify.unfold lt.apply le_n.
+intros.apply (trans_lt ? (S O)).
+unfold lt.apply le_n.
+apply lt_SO_smallest_factor.unfold lt. apply le_S_S.
apply le_S_S.apply le_O_n.
qed.
theorem divides_smallest_factor_n :
\forall n:nat. O < n \to smallest_factor n \divides n.
intro.
-apply nat_case n.intro.apply False_ind.apply not_le_Sn_O O H.
-intro.apply nat_case m.intro. simplify.
-apply witness ? ? (S O). simplify.reflexivity.
+apply (nat_case n).intro.apply False_ind.apply (not_le_Sn_O O H).
+intro.apply (nat_case m).intro. simplify.
+apply (witness ? ? (S O)). simplify.reflexivity.
intros.
apply divides_b_true_to_divides.
-apply lt_O_smallest_factor ? H.
+apply (lt_O_smallest_factor ? H).
change with
-eqb ((S(S m1)) \mod (min_aux m1 (S(S m1))
- (\lambda m.(eqb ((S(S m1)) \mod m) O)))) O = true.
+(eqb ((S(S m1)) \mod (min_aux m1 (S(S m1))
+ (\lambda m.(eqb ((S(S m1)) \mod m) O)))) O = true).
apply f_min_aux_true.
-apply ex_intro nat ? (S(S m1)).
+apply (ex_intro nat ? (S(S m1))).
split.split.
apply le_minus_m.apply le_n.
rewrite > mod_n_n.reflexivity.
-apply trans_lt ? (S O).apply le_n (S O).simplify.
+apply (trans_lt ? (S O)).apply (le_n (S O)).unfold lt.
apply le_S_S.apply le_S_S.apply le_O_n.
qed.
theorem le_smallest_factor_n :
\forall n:nat. smallest_factor n \le n.
-intro.apply nat_case n.simplify.reflexivity.
-intro.apply nat_case m.simplify.reflexivity.
+intro.apply (nat_case n).simplify.reflexivity.
+intro.apply (nat_case m).simplify.reflexivity.
intro.apply divides_to_le.
-simplify.apply le_S_S.apply le_O_n.
+unfold lt.apply le_S_S.apply le_O_n.
apply divides_smallest_factor_n.
-simplify.apply le_S_S.apply le_O_n.
+unfold lt.apply le_S_S.apply le_O_n.
qed.
theorem lt_smallest_factor_to_not_divides: \forall n,i:nat.
(S O) < n \to (S O) < i \to i < (smallest_factor n) \to i \ndivides n.
intros 2.
-apply nat_case n.intro.apply False_ind.apply not_le_Sn_O (S O) H.
-intro.apply nat_case m.intro. apply False_ind.apply not_le_Sn_n (S O) H.
+apply (nat_case n).intro.apply False_ind.apply (not_le_Sn_O (S O) H).
+intro.apply (nat_case m).intro. apply False_ind.apply (not_le_Sn_n (S O) H).
intros.
apply divides_b_false_to_not_divides.
-apply trans_lt O (S O).apply le_n (S O).assumption.
-change with (eqb ((S(S m1)) \mod i) O) = false.
-apply lt_min_aux_to_false
-(\lambda i:nat.eqb ((S(S m1)) \mod i) O) (S(S m1)) m1 i.
-cut (S(S O)) = (S(S m1)-m1).
+apply (trans_lt O (S O)).apply (le_n (S O)).assumption.
+change with ((eqb ((S(S m1)) \mod i) O) = false).
+apply (lt_min_aux_to_false
+(\lambda i:nat.eqb ((S(S m1)) \mod i) O) (S(S m1)) m1 i).
+cut ((S(S O)) = (S(S m1)-m1)).
rewrite < Hcut.exact H1.
apply sym_eq. apply plus_to_minus.
rewrite < sym_plus.simplify.reflexivity.
theorem prime_smallest_factor_n :
\forall n:nat. (S O) < n \to prime (smallest_factor n).
-intro. change with (S(S O)) \le n \to (S O) < (smallest_factor n) \land
-(\forall m:nat. m \divides smallest_factor n \to (S O) < m \to m = (smallest_factor n)).
+intro. change with ((S(S O)) \le n \to (S O) < (smallest_factor n) \land
+(\forall m:nat. m \divides smallest_factor n \to (S O) < m \to m = (smallest_factor n))).
intro.split.
apply lt_SO_smallest_factor.assumption.
intros.
-cut le m (smallest_factor n).
-elim le_to_or_lt_eq m (smallest_factor n) Hcut.
-absurd m \divides n.
-apply transitive_divides m (smallest_factor n).
+cut (le m (smallest_factor n)).
+elim (le_to_or_lt_eq m (smallest_factor n) Hcut).
+absurd (m \divides n).
+apply (transitive_divides m (smallest_factor n)).
assumption.
apply divides_smallest_factor_n.
-apply trans_lt ? (S O). simplify. apply le_n. exact H.
+apply (trans_lt ? (S O)). unfold lt. apply le_n. exact H.
apply lt_smallest_factor_to_not_divides.
exact H.assumption.assumption.assumption.
apply divides_to_le.
-apply trans_lt O (S O).
-apply le_n (S O).
+apply (trans_lt O (S O)).
+apply (le_n (S O)).
apply lt_SO_smallest_factor.
exact H.
assumption.
theorem prime_to_smallest_factor: \forall n. prime n \to
smallest_factor n = n.
-intro.apply nat_case n.intro.apply False_ind.apply not_prime_O H.
-intro.apply nat_case m.intro.apply False_ind.apply not_prime_SO H.
+intro.apply (nat_case n).intro.apply False_ind.apply (not_prime_O H).
+intro.apply (nat_case m).intro.apply False_ind.apply (not_prime_SO H).
intro.
change with
-(S O) < (S(S m1)) \land
+((S O) < (S(S m1)) \land
(\forall m:nat. m \divides S(S m1) \to (S O) < m \to m = (S(S m1))) \to
-smallest_factor (S(S m1)) = (S(S m1)).
+smallest_factor (S(S m1)) = (S(S m1))).
intro.elim H.apply H2.
apply divides_smallest_factor_n.
-apply trans_lt ? (S O).simplify. apply le_n.assumption.
+apply (trans_lt ? (S O)).unfold lt. apply le_n.assumption.
apply lt_SO_smallest_factor.
assumption.
qed.
[ true \Rightarrow prime n
| false \Rightarrow \lnot (prime n)].
intro.
-apply nat_case n.simplify.intro.elim H.apply not_le_Sn_O (S O) H1.
-intro.apply nat_case m.simplify.intro.elim H.apply not_le_Sn_n (S O) H1.
+apply (nat_case n).simplify.unfold Not.unfold prime.intro.elim H.apply (not_le_Sn_O (S O) H1).
+intro.apply (nat_case m).simplify.unfold Not.unfold prime.intro.elim H.apply (not_le_Sn_n (S O) H1).
intro.
change with
match eqb (smallest_factor (S(S m1))) (S(S m1)) with
[ true \Rightarrow prime (S(S m1))
| false \Rightarrow \lnot (prime (S(S m1)))].
-apply eqb_elim (smallest_factor (S(S m1))) (S(S m1)).
-intro.change with prime (S(S m1)).
+apply (eqb_elim (smallest_factor (S(S m1))) (S(S m1))).
+intro.change with (prime (S(S m1))).
rewrite < H.
apply prime_smallest_factor_n.
-simplify.apply le_S_S.apply le_S_S.apply le_O_n.
-intro.change with \lnot (prime (S(S m1))).
-change with prime (S(S m1)) \to False.
+unfold lt.apply le_S_S.apply le_S_S.apply le_O_n.
+intro.change with (\lnot (prime (S(S m1)))).
+change with (prime (S(S m1)) \to False).
intro.apply H.
apply prime_to_smallest_factor.
assumption.
qed.
theorem decidable_prime : \forall n:nat.decidable (prime n).
-intro.change with (prime n) \lor \lnot (prime n).
+intro.change with ((prime n) \lor \lnot (prime n)).
cut
-match primeb n with
+(match primeb n with
[ true \Rightarrow prime n
-| false \Rightarrow \lnot (prime n)] \to (prime n) \lor \lnot (prime n).
+| false \Rightarrow \lnot (prime n)] \to (prime n) \lor \lnot (prime n)).
apply Hcut.apply primeb_to_Prop.
elim (primeb n).left.apply H.right.apply H.
qed.
theorem prime_to_primeb_true: \forall n:nat.
prime n \to primeb n = true.
intros.
-cut match (primeb n) with
+cut (match (primeb n) with
[ true \Rightarrow prime n
-| false \Rightarrow \lnot (prime n)] \to ((primeb n) = true).
+| false \Rightarrow \lnot (prime n)] \to ((primeb n) = true)).
apply Hcut.apply primeb_to_Prop.
-elim primeb n.reflexivity.
+elim (primeb n).reflexivity.
absurd (prime n).assumption.assumption.
qed.
theorem not_prime_to_primeb_false: \forall n:nat.
\lnot(prime n) \to primeb n = false.
intros.
-cut match (primeb n) with
+cut (match (primeb n) with
[ true \Rightarrow prime n
-| false \Rightarrow \lnot (prime n)] \to ((primeb n) = false).
+| false \Rightarrow \lnot (prime n)] \to ((primeb n) = false)).
apply Hcut.apply primeb_to_Prop.
-elim primeb n.
+elim (primeb n).
absurd (prime n).assumption.assumption.
reflexivity.
qed.