2 ||M|| This file is part of HELM, an Hypertextual, Electronic
3 ||A|| Library of Mathematics, developed at the Computer Science
4 ||T|| Department of the University of Bologna, Italy.
7 ||A|| This file is distributed under the terms of the
8 \ / GNU General Public License Version 2
10 V_______________________________________________________________ *)
12 include "lambda/subst.ma".
14 inductive subterm : T → T → Prop ≝
15 | appl : ∀M,N. subterm M (App M N)
16 | appr : ∀M,N. subterm N (App M N)
17 | lambdal : ∀M,N. subterm M (Lambda M N)
18 | lambdar : ∀M,N. subterm N (Lambda M N)
19 | prodl : ∀M,N. subterm M (Prod M N)
20 | prodr : ∀M,N. subterm N (Prod M N)
21 | sub_b : ∀M. subterm M (D M)
22 | sub_trans : ∀M,N,P. subterm M N → subterm N P → subterm M P.
24 inverter subterm_myinv for subterm (?%).
26 lemma subapp: ∀S,M,N. subterm S (App M N) →
27 S = M ∨ S = N ∨ subterm S M ∨ subterm S N.
28 #S #M #N #subH (@(subterm_myinv … subH))
29 [#M1 #N1 #eqapp destruct /4/
30 |#M1 #N1 #eqapp destruct /4/
31 |3,4,5,6: #M1 #N1 #eqapp destruct
33 |#M1 #N1 #P #sub1 #sub2 #H1 #H2 #eqapp
35 [* [* /3/ | #subN1 %1 %2 /2/ ]
41 lemma sublam: ∀S,M,N. subterm S (Lambda M N) →
42 S = M ∨ S = N ∨ subterm S M ∨ subterm S N.
43 #S #M #N #subH (@(subterm_myinv … subH))
44 [1,2,5,6: #M1 #N1 #eqH destruct
45 |3,4:#M1 #N1 #eqH destruct /4/
47 |#M1 #N1 #P #sub1 #sub2 #H1 #H2 #eqH
49 [* [* /3/ | #subN1 %1 %2 /2/ ]
55 lemma subprod: ∀S,M,N. subterm S (Prod M N) →
56 S = M ∨ S = N ∨ subterm S M ∨ subterm S N.
57 #S #M #N #subH (@(subterm_myinv … subH))
58 [1,2,3,4: #M1 #N1 #eqH destruct
59 |5,6:#M1 #N1 #eqH destruct /4/
61 |#M1 #N1 #P #sub1 #sub2 #H1 #H2 #eqH
63 [* [* /3/ | #subN1 %1 %2 /2/ ]
69 lemma subd: ∀S,M. subterm S (D M) →
71 #S #M #subH (@(subterm_myinv … subH))
72 [1,2,3,4,5,6: #M1 #N1 #eqH destruct
73 |#M1 #eqH destruct /2/
74 |#M1 #N1 #P #sub1 #sub2 #_ #H #eqH
80 lemma subsort: ∀S,n. ¬ subterm S (Sort n).
81 #S #n % #subH (@(subterm_myinv … subH))
82 [1,2,3,4,5,6: #M1 #N1 #eqH destruct
88 lemma subrel: ∀S,n. ¬ subterm S (Rel n).
89 #S #n % #subH (@(subterm_myinv … subH))
90 [1,2,3,4,5,6: #M1 #N1 #eqH destruct
96 theorem Telim: ∀P: T → Prop. (∀M. (∀N. subterm N M → P N) → P M) →
98 #P #H #M (cut (P M ∧ (∀N. subterm N M → P N)))
102 [@H #N1 #subN1 @False_ind /2/
103 |#N #subN1 @False_ind /2/
106 [@H #N1 #subN1 @False_ind /2/
107 |#N #subN1 @False_ind /2/
109 |#M1 #M2 * #PM1 #Hind1 * #PM2 #Hind2
110 (cut (∀N.subterm N (App M1 M2) → P N))
111 [#N1 #subN1 (cases (subapp … subN1))
112 [* [* // | @Hind1 ] | @Hind2 ]]
114 |#M1 #M2 * #PM1 #Hind1 * #PM2 #Hind2
115 (cut (∀N.subterm N (Lambda M1 M2) → P N))
116 [#N1 #subN1 (cases (sublam … subN1))
117 [* [* // | @Hind1 ] | @Hind2 ]]
119 |#M1 #M2 * #PM1 #Hind1 * #PM2 #Hind2
120 (cut (∀N.subterm N (Prod M1 M2) → P N))
121 [#N1 #subN1 (cases (subprod … subN1))
122 [* [* // | @Hind1 ] | @Hind2 ]]
125 (cut (∀N.subterm N (D M1) → P N))
126 [#N1 #subN1 (cases (subd … subN1)) /2/]
135 |App P Q ⇒ size P + size Q + 1
136 |Lambda P Q ⇒ size P + size Q + 1
137 |Prod P Q ⇒ size P + size Q + 1
142 axiom pos_size: ∀M. 1 ≤ size M.
144 theorem Telim_size: ∀P: T → Prop.
145 (∀M. (∀N. size N < size M → P N) → P M) → ∀M. P M.
146 #P #H #M (cut (∀p,N. size N = p → P N))
148 #p @(nat_elim1 p) #m #H1 #N #sizeN @H #N0 #Hlt @(H1 (size N0)) //