blob: a9e4a8434a04dc08dc22f9b925f2426fec61de68 (
plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
|
Axiom magic:False.
(* Submitted by Dachuan Yu (bug #220) *)
Fixpoint T[n:nat] : Type :=
Cases n of
| O => (nat -> Prop)
| (S n') => (T n')
end.
Inductive R : (n:nat)(T n) -> nat -> Prop :=
| RO : (Psi:(T O); l:nat)
(Psi l) -> (R O Psi l)
| RS : (n:nat; Psi:(T (S n)); l:nat)
(R n Psi l) -> (R (S n) Psi l).
Definition Psi00 : (nat -> Prop) := [n:nat] False.
Definition Psi0 : (T O) := Psi00.
Lemma Inversion_RO : (l:nat)(R O Psi0 l) -> (Psi00 l).
Inversion 1.
Abort.
(* Submitted by Pierre Casteran (bug #540) *)
Set Implicit Arguments.
Parameter rule: Set -> Type.
Inductive extension [I:Set]:Type :=
NL : (extension I)
|add_rule : (rule I) -> (extension I) -> (extension I).
Inductive in_extension [I :Set;r: (rule I)] : (extension I) -> Type :=
in_first : (e:?)(in_extension r (add_rule r e))
|in_rest : (e,r':?)(in_extension r e) -> (in_extension r (add_rule r' e)).
Implicits NL [1].
Inductive super_extension [I:Set;e :(extension I)] : (extension I) -> Type :=
super_NL : (super_extension e NL)
| super_add : (r:?)(e': (extension I))
(in_extension r e) ->
(super_extension e e') ->
(super_extension e (add_rule r e')).
Lemma super_def : (I :Set)(e1, e2: (extension I))
(super_extension e2 e1) ->
(ru:?)
(in_extension ru e1) ->
(in_extension ru e2).
Proof.
Induction 1.
Inversion 1; Auto.
Elim magic.
Qed.
(* Example from Norbert Schirmer on Coq-Club, Sep 2000 *)
Unset Implicit Arguments.
Definition Q[n,m:nat;prf:(le n m)]:=True.
Goal (n,m:nat;H:(le (S n) m))(Q (S n) m H)==True.
Intros.
Dependent Inversion_clear H.
Elim magic.
Elim magic.
Qed.
(* Submitted by Boris Yakobowski (bug #529) *)
(* Check that Inversion does not fail due to unnormalized evars *)
Set Implicit Arguments.
Require Import Bvector.
Inductive I : nat -> Set :=
| C1 : (I (S O))
| C2 : (k,i:nat)(vector (I i) k) -> (I i).
Inductive SI : (k:nat)(I k) -> (vector nat k) -> nat -> Prop :=
| SC2 : (k,i,vf:nat) (v:(vector (I i) k))(xi:(vector nat i))(SI (C2 v) xi vf).
Theorem SUnique : (k:nat)(f:(I k))(c:(vector nat k))
(v,v':?) (SI f c v) -> (SI f c v') -> v=v'.
Proof.
NewInduction 1.
Intros H ; Inversion H.
Admitted.
|