(* *)
(**************************************************************************)
-set "baseuri" "cic:/matita/RELATIONAL/NLE/inv".
-include "NPlus/inv.ma".
+
include "NLE/defs.ma".
theorem nle_inv_succ_1: \forall x,y. x < y \to
- \exists z. y = succ z \land x <= z.
- intros. elim H.
- lapply linear nplus_gen_succ_2 to H1.
- decompose. subst. auto depth = 4.
+ \exists z. y = succ z \land x <= z.
+ intros. inversion H; clear H; intros; destruct. autobatch.
qed.
theorem nle_inv_succ_succ: \forall x,y. x < succ y \to x <= y.
- intros.
- lapply linear nle_inv_succ_1 to H. decompose.
- destruct H1. clear H1. subst.
- auto.
+ intros. inversion H; clear H; intros; destruct. autobatch.
qed.
theorem nle_inv_succ_zero: \forall x. x < zero \to False.
- intros.
- lapply linear nle_inv_succ_1 to H. decompose.
- destruct H1.
+ intros. inversion H; clear H; intros; destruct.
qed.
theorem nle_inv_zero_2: \forall x. x <= zero \to x = zero.
- intros 1. elim x; clear x; intros;
- [ auto
- | lapply linear nle_inv_succ_zero to H1. decompose.
- ].
+ intros. inversion H; clear H; intros; destruct. autobatch.
qed.
theorem nle_inv_succ_2: \forall y,x. x <= succ y \to
x = zero \lor \exists z. x = succ z \land z <= y.
- intros 2; elim x; clear x; intros;
- [ auto
- | lapply linear nle_inv_succ_succ to H1.
- auto depth = 4.
- ].
+ intros. inversion H; clear H; intros; destruct;
+ autobatch depth = 4.
qed.