| author | nipkow |
| Thu, 26 Jun 1997 10:42:50 +0200 | |
| changeset 3460 | 5d71eed16fbe |
| parent 3326 | 930c9bed5a09 |
| child 3652 | 4c484f03079c |
| permissions | -rw-r--r-- |
| 2640 | 1 |
(* Title: HOLCF/Fix.ML |
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ID: $Id$ |
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Author: Franz Regensburger |
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Copyright 1993 Technische Universitaet Muenchen |
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Lemmas for Fix.thy |
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*) |
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open Fix; |
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(* ------------------------------------------------------------------------ *) |
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(* derive inductive properties of iterate from primitive recursion *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goal "iterate_0" thy "iterate 0 F x = x" |
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(fn prems => |
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[ |
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(resolve_tac (nat_recs iterate_def) 1) |
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]); |
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qed_goal "iterate_Suc" thy "iterate (Suc n) F x = F`(iterate n F x)" |
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(fn prems => |
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[ |
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(resolve_tac (nat_recs iterate_def) 1) |
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]); |
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Addsimps [iterate_0, iterate_Suc]; |
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qed_goal "iterate_Suc2" thy "iterate (Suc n) F x = iterate n F (F`x)" |
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(fn prems => |
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[ |
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(nat_ind_tac "n" 1), |
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(Simp_tac 1), |
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(stac iterate_Suc 1), |
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(stac iterate_Suc 1), |
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(etac ssubst 1), |
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(rtac refl 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* the sequence of function itertaions is a chain *) |
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(* This property is essential since monotonicity of iterate makes no sense *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goalw "is_chain_iterate2" thy [is_chain] |
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" x << F`x ==> is_chain (%i.iterate i F x)" |
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(fn prems => |
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[ |
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(cut_facts_tac prems 1), |
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(strip_tac 1), |
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(Simp_tac 1), |
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(nat_ind_tac "i" 1), |
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(Asm_simp_tac 1), |
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(Asm_simp_tac 1), |
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(etac monofun_cfun_arg 1) |
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]); |
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qed_goal "is_chain_iterate" thy |
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"is_chain (%i.iterate i F UU)" |
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(fn prems => |
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[ |
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(rtac is_chain_iterate2 1), |
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(rtac minimal 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* Kleene's fixed point theorems for continuous functions in pointed *) |
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(* omega cpo's *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goalw "Ifix_eq" thy [Ifix_def] "Ifix F =F`(Ifix F)" |
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(fn prems => |
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[ |
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(stac contlub_cfun_arg 1), |
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(rtac is_chain_iterate 1), |
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(rtac antisym_less 1), |
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(rtac lub_mono 1), |
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(rtac is_chain_iterate 1), |
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(rtac ch2ch_fappR 1), |
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(rtac is_chain_iterate 1), |
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(rtac allI 1), |
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(rtac (iterate_Suc RS subst) 1), |
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(rtac (is_chain_iterate RS is_chainE RS spec) 1), |
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(rtac is_lub_thelub 1), |
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(rtac ch2ch_fappR 1), |
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(rtac is_chain_iterate 1), |
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(rtac ub_rangeI 1), |
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(rtac allI 1), |
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(rtac (iterate_Suc RS subst) 1), |
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(rtac is_ub_thelub 1), |
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(rtac is_chain_iterate 1) |
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]); |
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qed_goalw "Ifix_least" thy [Ifix_def] "F`x=x ==> Ifix(F) << x" |
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(fn prems => |
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[ |
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(cut_facts_tac prems 1), |
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(rtac is_lub_thelub 1), |
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(rtac is_chain_iterate 1), |
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(rtac ub_rangeI 1), |
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(strip_tac 1), |
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(nat_ind_tac "i" 1), |
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(Asm_simp_tac 1), |
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(Asm_simp_tac 1), |
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(res_inst_tac [("t","x")] subst 1),
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(atac 1), |
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(etac monofun_cfun_arg 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* monotonicity and continuity of iterate *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goalw "monofun_iterate" thy [monofun] "monofun(iterate(i))" |
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(fn prems => |
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[ |
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(strip_tac 1), |
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(nat_ind_tac "i" 1), |
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(Asm_simp_tac 1), |
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(Asm_simp_tac 1), |
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(rtac (less_fun RS iffD2) 1), |
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(rtac allI 1), |
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(rtac monofun_cfun 1), |
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(atac 1), |
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(rtac (less_fun RS iffD1 RS spec) 1), |
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(atac 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* the following lemma uses contlub_cfun which itself is based on a *) |
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(* diagonalisation lemma for continuous functions with two arguments. *) |
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(* In this special case it is the application function fapp *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goalw "contlub_iterate" thy [contlub] "contlub(iterate(i))" |
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(fn prems => |
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[ |
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(strip_tac 1), |
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(nat_ind_tac "i" 1), |
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(Asm_simp_tac 1), |
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(rtac (lub_const RS thelubI RS sym) 1), |
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(Asm_simp_tac 1), |
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(rtac ext 1), |
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(stac thelub_fun 1), |
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(rtac is_chainI 1), |
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(rtac allI 1), |
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(rtac (less_fun RS iffD2) 1), |
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(rtac allI 1), |
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(rtac (is_chainE RS spec) 1), |
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(rtac (monofun_fapp1 RS ch2ch_MF2LR) 1), |
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(rtac allI 1), |
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(rtac monofun_fapp2 1), |
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(atac 1), |
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(rtac ch2ch_fun 1), |
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(rtac (monofun_iterate RS ch2ch_monofun) 1), |
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(atac 1), |
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(stac thelub_fun 1), |
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(rtac (monofun_iterate RS ch2ch_monofun) 1), |
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(atac 1), |
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(rtac contlub_cfun 1), |
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(atac 1), |
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(etac (monofun_iterate RS ch2ch_monofun RS ch2ch_fun) 1) |
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]); |
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qed_goal "cont_iterate" thy "cont(iterate(i))" |
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(fn prems => |
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[ |
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(rtac monocontlub2cont 1), |
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(rtac monofun_iterate 1), |
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(rtac contlub_iterate 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* a lemma about continuity of iterate in its third argument *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goal "monofun_iterate2" thy "monofun(iterate n F)" |
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(fn prems => |
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[ |
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(rtac monofunI 1), |
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(strip_tac 1), |
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(nat_ind_tac "n" 1), |
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(Asm_simp_tac 1), |
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(Asm_simp_tac 1), |
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(etac monofun_cfun_arg 1) |
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]); |
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qed_goal "contlub_iterate2" thy "contlub(iterate n F)" |
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(fn prems => |
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[ |
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(rtac contlubI 1), |
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(strip_tac 1), |
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(nat_ind_tac "n" 1), |
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(Simp_tac 1), |
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(Simp_tac 1), |
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(res_inst_tac [("t","iterate n F (lub(range(%u. Y u)))"),
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("s","lub(range(%i. iterate n F (Y i)))")] ssubst 1),
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(atac 1), |
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(rtac contlub_cfun_arg 1), |
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(etac (monofun_iterate2 RS ch2ch_monofun) 1) |
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]); |
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qed_goal "cont_iterate2" thy "cont (iterate n F)" |
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(fn prems => |
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[ |
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(rtac monocontlub2cont 1), |
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(rtac monofun_iterate2 1), |
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(rtac contlub_iterate2 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* monotonicity and continuity of Ifix *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goalw "monofun_Ifix" thy [monofun,Ifix_def] "monofun(Ifix)" |
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(fn prems => |
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[ |
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(strip_tac 1), |
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(rtac lub_mono 1), |
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(rtac is_chain_iterate 1), |
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(rtac is_chain_iterate 1), |
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(rtac allI 1), |
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(rtac (less_fun RS iffD1 RS spec) 1), |
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(etac (monofun_iterate RS monofunE RS spec RS spec RS mp) 1) |
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]); |
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(* ------------------------------------------------------------------------ *) |
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(* since iterate is not monotone in its first argument, special lemmas must *) |
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(* be derived for lubs in this argument *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goal "is_chain_iterate_lub" thy |
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"is_chain(Y) ==> is_chain(%i. lub(range(%ia. iterate ia (Y i) UU)))" |
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(fn prems => |
| 1461 | 241 |
[ |
242 |
(cut_facts_tac prems 1), |
|
243 |
(rtac is_chainI 1), |
|
244 |
(strip_tac 1), |
|
245 |
(rtac lub_mono 1), |
|
246 |
(rtac is_chain_iterate 1), |
|
247 |
(rtac is_chain_iterate 1), |
|
248 |
(strip_tac 1), |
|
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(etac (monofun_iterate RS ch2ch_monofun RS ch2ch_fun RS is_chainE |
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RS spec) 1) |
| 1461 | 251 |
]); |
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|
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(* ------------------------------------------------------------------------ *) |
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(* this exchange lemma is analog to the one for monotone functions *) |
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(* observe that monotonicity is not really needed. The propagation of *) |
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(* chains is the essential argument which is usually derived from monot. *) |
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(* ------------------------------------------------------------------------ *) |
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qed_goal "contlub_Ifix_lemma1" thy |
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"is_chain(Y) ==>iterate n (lub(range Y)) y = lub(range(%i. iterate n (Y i) y))" |
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(fn prems => |
| 1461 | 262 |
[ |
263 |
(cut_facts_tac prems 1), |
|
264 |
(rtac (thelub_fun RS subst) 1), |
|
265 |
(rtac (monofun_iterate RS ch2ch_monofun) 1), |
|
266 |
(atac 1), |
|
267 |
(rtac fun_cong 1), |
|
| 2033 | 268 |
(stac (contlub_iterate RS contlubE RS spec RS mp) 1), |
| 1461 | 269 |
(atac 1), |
270 |
(rtac refl 1) |
|
271 |
]); |
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|
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273 |
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qed_goal "ex_lub_iterate" thy "is_chain(Y) ==>\ |
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\ lub(range(%i. lub(range(%ia. iterate i (Y ia) UU)))) =\ |
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\ lub(range(%i. lub(range(%ia. iterate ia (Y i) UU))))" |
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(fn prems => |
| 1461 | 278 |
[ |
279 |
(cut_facts_tac prems 1), |
|
280 |
(rtac antisym_less 1), |
|
281 |
(rtac is_lub_thelub 1), |
|
282 |
(rtac (contlub_Ifix_lemma1 RS ext RS subst) 1), |
|
283 |
(atac 1), |
|
284 |
(rtac is_chain_iterate 1), |
|
285 |
(rtac ub_rangeI 1), |
|
286 |
(strip_tac 1), |
|
287 |
(rtac lub_mono 1), |
|
288 |
(etac (monofun_iterate RS ch2ch_monofun RS ch2ch_fun) 1), |
|
289 |
(etac is_chain_iterate_lub 1), |
|
290 |
(strip_tac 1), |
|
291 |
(rtac is_ub_thelub 1), |
|
292 |
(rtac is_chain_iterate 1), |
|
293 |
(rtac is_lub_thelub 1), |
|
294 |
(etac is_chain_iterate_lub 1), |
|
295 |
(rtac ub_rangeI 1), |
|
296 |
(strip_tac 1), |
|
297 |
(rtac lub_mono 1), |
|
298 |
(rtac is_chain_iterate 1), |
|
299 |
(rtac (contlub_Ifix_lemma1 RS ext RS subst) 1), |
|
300 |
(atac 1), |
|
301 |
(rtac is_chain_iterate 1), |
|
302 |
(strip_tac 1), |
|
303 |
(rtac is_ub_thelub 1), |
|
304 |
(etac (monofun_iterate RS ch2ch_monofun RS ch2ch_fun) 1) |
|
305 |
]); |
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|
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qed_goalw "contlub_Ifix" thy [contlub,Ifix_def] "contlub(Ifix)" |
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(fn prems => |
| 1461 | 310 |
[ |
311 |
(strip_tac 1), |
|
| 2033 | 312 |
(stac (contlub_Ifix_lemma1 RS ext) 1), |
| 1461 | 313 |
(atac 1), |
314 |
(etac ex_lub_iterate 1) |
|
315 |
]); |
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316 |
|
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317 |
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qed_goal "cont_Ifix" thy "cont(Ifix)" |
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(fn prems => |
| 1461 | 320 |
[ |
321 |
(rtac monocontlub2cont 1), |
|
322 |
(rtac monofun_Ifix 1), |
|
323 |
(rtac contlub_Ifix 1) |
|
324 |
]); |
|
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|
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(* ------------------------------------------------------------------------ *) |
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327 |
(* propagate properties of Ifix to its continuous counterpart *) |
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328 |
(* ------------------------------------------------------------------------ *) |
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|
329 |
|
| 2640 | 330 |
qed_goalw "fix_eq" thy [fix_def] "fix`F = F`(fix`F)" |
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331 |
(fn prems => |
| 1461 | 332 |
[ |
333 |
(asm_simp_tac (!simpset addsimps [cont_Ifix]) 1), |
|
334 |
(rtac Ifix_eq 1) |
|
335 |
]); |
|
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336 |
|
| 2640 | 337 |
qed_goalw "fix_least" thy [fix_def] "F`x = x ==> fix`F << x" |
|
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338 |
(fn prems => |
| 1461 | 339 |
[ |
340 |
(cut_facts_tac prems 1), |
|
341 |
(asm_simp_tac (!simpset addsimps [cont_Ifix]) 1), |
|
342 |
(etac Ifix_least 1) |
|
343 |
]); |
|
|
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344 |
|
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|
345 |
|
| 2640 | 346 |
qed_goal "fix_eqI" thy |
| 1274 | 347 |
"[| F`x = x; !z. F`z = z --> x << z |] ==> x = fix`F" |
348 |
(fn prems => |
|
| 1461 | 349 |
[ |
350 |
(cut_facts_tac prems 1), |
|
351 |
(rtac antisym_less 1), |
|
352 |
(etac allE 1), |
|
353 |
(etac mp 1), |
|
354 |
(rtac (fix_eq RS sym) 1), |
|
355 |
(etac fix_least 1) |
|
356 |
]); |
|
| 1274 | 357 |
|
358 |
||
| 2640 | 359 |
qed_goal "fix_eq2" thy "f == fix`F ==> f = F`f" |
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|
360 |
(fn prems => |
| 1461 | 361 |
[ |
362 |
(rewrite_goals_tac prems), |
|
363 |
(rtac fix_eq 1) |
|
364 |
]); |
|
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|
365 |
|
| 2640 | 366 |
qed_goal "fix_eq3" thy "f == fix`F ==> f`x = F`f`x" |
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|
367 |
(fn prems => |
| 1461 | 368 |
[ |
369 |
(rtac trans 1), |
|
370 |
(rtac ((hd prems) RS fix_eq2 RS cfun_fun_cong) 1), |
|
371 |
(rtac refl 1) |
|
372 |
]); |
|
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373 |
|
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|
374 |
fun fix_tac3 thm i = ((rtac trans i) THEN (rtac (thm RS fix_eq3) i)); |
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|
375 |
|
| 2640 | 376 |
qed_goal "fix_eq4" thy "f = fix`F ==> f = F`f" |
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|
377 |
(fn prems => |
| 1461 | 378 |
[ |
379 |
(cut_facts_tac prems 1), |
|
380 |
(hyp_subst_tac 1), |
|
381 |
(rtac fix_eq 1) |
|
382 |
]); |
|
|
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|
383 |
|
| 2640 | 384 |
qed_goal "fix_eq5" thy "f = fix`F ==> f`x = F`f`x" |
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|
385 |
(fn prems => |
| 1461 | 386 |
[ |
387 |
(rtac trans 1), |
|
388 |
(rtac ((hd prems) RS fix_eq4 RS cfun_fun_cong) 1), |
|
389 |
(rtac refl 1) |
|
390 |
]); |
|
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|
391 |
|
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|
392 |
fun fix_tac5 thm i = ((rtac trans i) THEN (rtac (thm RS fix_eq5) i)); |
|
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|
393 |
|
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|
394 |
fun fix_prover thy fixdef thm = prove_goal thy thm |
|
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|
395 |
(fn prems => |
|
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|
396 |
[ |
|
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|
397 |
(rtac trans 1), |
|
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|
398 |
(rtac (fixdef RS fix_eq4) 1), |
|
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|
399 |
(rtac trans 1), |
|
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|
400 |
(rtac beta_cfun 1), |
| 2566 | 401 |
(Simp_tac 1) |
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|
402 |
]); |
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|
403 |
|
|
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|
404 |
(* use this one for definitions! *) |
| 297 | 405 |
|
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changeset
|
406 |
fun fix_prover2 thy fixdef thm = prove_goal thy thm |
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parents:
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changeset
|
407 |
(fn prems => |
| 1461 | 408 |
[ |
409 |
(rtac trans 1), |
|
410 |
(rtac (fix_eq2) 1), |
|
411 |
(rtac fixdef 1), |
|
412 |
(rtac beta_cfun 1), |
|
| 2566 | 413 |
(Simp_tac 1) |
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|
414 |
]); |
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|
415 |
|
|
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|
416 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
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|
417 |
(* better access to definitions *) |
|
c22b85994e17
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|
418 |
(* ------------------------------------------------------------------------ *) |
|
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|
419 |
|
|
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|
420 |
|
| 2640 | 421 |
qed_goal "Ifix_def2" thy "Ifix=(%x. lub(range(%i. iterate i x UU)))" |
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|
422 |
(fn prems => |
| 1461 | 423 |
[ |
424 |
(rtac ext 1), |
|
425 |
(rewtac Ifix_def), |
|
426 |
(rtac refl 1) |
|
427 |
]); |
|
|
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|
428 |
|
|
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|
429 |
(* ------------------------------------------------------------------------ *) |
|
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|
430 |
(* direct connection between fix and iteration without Ifix *) |
|
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|
431 |
(* ------------------------------------------------------------------------ *) |
|
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|
432 |
|
| 2640 | 433 |
qed_goalw "fix_def2" thy [fix_def] |
|
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|
434 |
"fix`F = lub(range(%i. iterate i F UU))" |
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|
435 |
(fn prems => |
| 1461 | 436 |
[ |
437 |
(fold_goals_tac [Ifix_def]), |
|
438 |
(asm_simp_tac (!simpset addsimps [cont_Ifix]) 1) |
|
439 |
]); |
|
|
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|
440 |
|
|
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|
441 |
|
|
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|
442 |
(* ------------------------------------------------------------------------ *) |
|
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|
443 |
(* Lemmas about admissibility and fixed point induction *) |
|
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|
444 |
(* ------------------------------------------------------------------------ *) |
|
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|
445 |
|
|
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|
446 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
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|
447 |
(* access to definitions *) |
|
c22b85994e17
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|
448 |
(* ------------------------------------------------------------------------ *) |
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|
449 |
|
| 3460 | 450 |
qed_goalw "admI" thy [adm_def] |
451 |
"(!!Y. [| is_chain(Y); !i.P(Y(i)) |] ==> P(lub(range(Y)))) ==> adm(P)" |
|
452 |
(fn prems => [fast_tac (HOL_cs addIs prems) 1]); |
|
453 |
||
454 |
qed_goalw "admD" thy [adm_def] |
|
455 |
"!!P. [| adm(P); is_chain(Y); !i.P(Y(i)) |] ==> P(lub(range(Y)))" |
|
456 |
(fn prems => [fast_tac HOL_cs 1]); |
|
|
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|
457 |
|
| 2640 | 458 |
qed_goalw "admw_def2" thy [admw_def] |
| 1461 | 459 |
"admw(P) = (!F.(!n.P(iterate n F UU)) -->\ |
460 |
\ P (lub(range(%i.iterate i F UU))))" |
|
|
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|
461 |
(fn prems => |
| 1461 | 462 |
[ |
463 |
(rtac refl 1) |
|
464 |
]); |
|
|
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|
465 |
|
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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|
466 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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|
467 |
(* an admissible formula is also weak admissible *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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diff
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|
468 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
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diff
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|
469 |
|
| 3460 | 470 |
qed_goalw "adm_impl_admw" thy [admw_def] "!!P. adm(P)==>admw(P)" |
|
243
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|
471 |
(fn prems => |
| 1461 | 472 |
[ |
473 |
(strip_tac 1), |
|
| 3460 | 474 |
(etac admD 1), |
| 1461 | 475 |
(rtac is_chain_iterate 1), |
476 |
(atac 1) |
|
477 |
]); |
|
|
243
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|
478 |
|
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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parents:
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|
479 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
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|
480 |
(* fixed point induction *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
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|
481 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
482 |
|
| 2640 | 483 |
qed_goal "fix_ind" thy |
|
1168
74be52691d62
The curried version of HOLCF is now just called HOLCF. The old
regensbu
parents:
892
diff
changeset
|
484 |
"[| adm(P);P(UU);!!x. P(x) ==> P(F`x)|] ==> P(fix`F)" |
|
243
c22b85994e17
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|
485 |
(fn prems => |
| 1461 | 486 |
[ |
487 |
(cut_facts_tac prems 1), |
|
| 2033 | 488 |
(stac fix_def2 1), |
| 3460 | 489 |
(etac admD 1), |
| 1461 | 490 |
(rtac is_chain_iterate 1), |
491 |
(rtac allI 1), |
|
492 |
(nat_ind_tac "i" 1), |
|
| 2033 | 493 |
(stac iterate_0 1), |
| 1461 | 494 |
(atac 1), |
| 2033 | 495 |
(stac iterate_Suc 1), |
| 1461 | 496 |
(resolve_tac prems 1), |
497 |
(atac 1) |
|
498 |
]); |
|
|
243
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|
499 |
|
| 2640 | 500 |
qed_goal "def_fix_ind" thy "[| f == fix`F; adm(P); \ |
| 2568 | 501 |
\ P(UU);!!x. P(x) ==> P(F`x)|] ==> P f" (fn prems => [ |
502 |
(cut_facts_tac prems 1), |
|
503 |
(asm_simp_tac HOL_ss 1), |
|
504 |
(etac fix_ind 1), |
|
505 |
(atac 1), |
|
506 |
(eresolve_tac prems 1)]); |
|
507 |
||
|
243
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|
508 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
509 |
(* computational induction for weak admissible formulae *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
510 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
511 |
|
| 2640 | 512 |
qed_goal "wfix_ind" thy |
|
1168
74be52691d62
The curried version of HOLCF is now just called HOLCF. The old
regensbu
parents:
892
diff
changeset
|
513 |
"[| admw(P); !n. P(iterate n F UU)|] ==> P(fix`F)" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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parents:
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changeset
|
514 |
(fn prems => |
| 1461 | 515 |
[ |
516 |
(cut_facts_tac prems 1), |
|
| 2033 | 517 |
(stac fix_def2 1), |
| 1461 | 518 |
(rtac (admw_def2 RS iffD1 RS spec RS mp) 1), |
519 |
(atac 1), |
|
520 |
(rtac allI 1), |
|
521 |
(etac spec 1) |
|
522 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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changeset
|
523 |
|
| 2640 | 524 |
qed_goal "def_wfix_ind" thy "[| f == fix`F; admw(P); \ |
| 2568 | 525 |
\ !n. P(iterate n F UU) |] ==> P f" (fn prems => [ |
526 |
(cut_facts_tac prems 1), |
|
527 |
(asm_simp_tac HOL_ss 1), |
|
528 |
(etac wfix_ind 1), |
|
529 |
(atac 1)]); |
|
530 |
||
|
243
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|
531 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
532 |
(* for chain-finite (easy) types every formula is admissible *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
533 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
534 |
|
| 2640 | 535 |
qed_goalw "adm_max_in_chain" thy [adm_def] |
|
1168
74be52691d62
The curried version of HOLCF is now just called HOLCF. The old
regensbu
parents:
892
diff
changeset
|
536 |
"!Y. is_chain(Y::nat=>'a) --> (? n.max_in_chain n Y) ==> adm(P::'a=>bool)" |
|
243
c22b85994e17
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nipkow
parents:
diff
changeset
|
537 |
(fn prems => |
| 1461 | 538 |
[ |
539 |
(cut_facts_tac prems 1), |
|
540 |
(strip_tac 1), |
|
541 |
(rtac exE 1), |
|
542 |
(rtac mp 1), |
|
543 |
(etac spec 1), |
|
544 |
(atac 1), |
|
| 2033 | 545 |
(stac (lub_finch1 RS thelubI) 1), |
| 1461 | 546 |
(atac 1), |
547 |
(atac 1), |
|
548 |
(etac spec 1) |
|
549 |
]); |
|
|
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|
550 |
|
| 3324 | 551 |
bind_thm ("adm_chain_finite" ,chfin RS adm_max_in_chain);
|
|
243
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Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
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|
552 |
|
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
553 |
(* ------------------------------------------------------------------------ *) |
| 2354 | 554 |
(* some lemmata for functions with flat/chain_finite domain/range types *) |
555 |
(* ------------------------------------------------------------------------ *) |
|
556 |
||
| 3324 | 557 |
qed_goalw "adm_chfindom" thy [adm_def] "adm (%(u::'a::cpo->'b::chfin). P(u`s))" |
558 |
(fn _ => [ |
|
| 2354 | 559 |
strip_tac 1, |
560 |
dtac chfin_fappR 1, |
|
561 |
eres_inst_tac [("x","s")] allE 1,
|
|
| 3324 | 562 |
fast_tac (HOL_cs addss (!simpset addsimps [chfin])) 1]); |
| 2354 | 563 |
|
| 3324 | 564 |
(* adm_flat not needed any more, since it is a special case of adm_chfindom *) |
| 2354 | 565 |
|
| 1992 | 566 |
(* ------------------------------------------------------------------------ *) |
| 3326 | 567 |
(* improved admisibility introduction *) |
| 1992 | 568 |
(* ------------------------------------------------------------------------ *) |
569 |
||
| 3460 | 570 |
qed_goalw "admI2" thy [adm_def] |
| 1992 | 571 |
"(!!Y. [| is_chain Y; !i. P (Y i); !i. ? j. i < j & Y i ~= Y j & Y i << Y j |]\ |
572 |
\ ==> P(lub (range Y))) ==> adm P" |
|
573 |
(fn prems => [ |
|
| 2033 | 574 |
strip_tac 1, |
575 |
etac increasing_chain_adm_lemma 1, atac 1, |
|
576 |
eresolve_tac prems 1, atac 1, atac 1]); |
|
| 1992 | 577 |
|
578 |
||
|
243
c22b85994e17
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parents:
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|
579 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
580 |
(* admissibility of special formulae and propagation *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
581 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
582 |
|
| 2640 | 583 |
qed_goalw "adm_less" thy [adm_def] |
| 1461 | 584 |
"[|cont u;cont v|]==> adm(%x.u x << v x)" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
585 |
(fn prems => |
| 1461 | 586 |
[ |
587 |
(cut_facts_tac prems 1), |
|
588 |
(strip_tac 1), |
|
589 |
(etac (cont2contlub RS contlubE RS spec RS mp RS ssubst) 1), |
|
590 |
(atac 1), |
|
591 |
(etac (cont2contlub RS contlubE RS spec RS mp RS ssubst) 1), |
|
592 |
(atac 1), |
|
593 |
(rtac lub_mono 1), |
|
594 |
(cut_facts_tac prems 1), |
|
595 |
(etac (cont2mono RS ch2ch_monofun) 1), |
|
596 |
(atac 1), |
|
597 |
(cut_facts_tac prems 1), |
|
598 |
(etac (cont2mono RS ch2ch_monofun) 1), |
|
599 |
(atac 1), |
|
600 |
(atac 1) |
|
601 |
]); |
|
| 3460 | 602 |
Addsimps [adm_less]; |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
603 |
|
| 2640 | 604 |
qed_goal "adm_conj" thy |
| 3460 | 605 |
"!!P. [| adm P; adm Q |] ==> adm(%x. P x & Q x)" |
606 |
(fn prems => [fast_tac (HOL_cs addEs [admD] addIs [admI]) 1]); |
|
607 |
Addsimps [adm_conj]; |
|
608 |
||
609 |
qed_goalw "adm_not_free" thy [adm_def] "adm(%x.t)" |
|
610 |
(fn prems => [fast_tac HOL_cs 1]); |
|
611 |
Addsimps [adm_not_free]; |
|
612 |
||
613 |
qed_goalw "adm_not_less" thy [adm_def] |
|
614 |
"!!t. cont t ==> adm(%x.~ (t x) << u)" |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
615 |
(fn prems => |
| 1461 | 616 |
[ |
617 |
(strip_tac 1), |
|
618 |
(rtac contrapos 1), |
|
619 |
(etac spec 1), |
|
620 |
(rtac trans_less 1), |
|
621 |
(atac 2), |
|
622 |
(etac (cont2mono RS monofun_fun_arg) 1), |
|
623 |
(rtac is_ub_thelub 1), |
|
624 |
(atac 1) |
|
625 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
626 |
|
| 3460 | 627 |
qed_goal "adm_all" thy |
628 |
"!!P. !y.adm(P y) ==> adm(%x.!y.P y x)" |
|
629 |
(fn prems => [fast_tac (HOL_cs addIs [admI] addEs [admD]) 1]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
630 |
|
| 1779 | 631 |
bind_thm ("adm_all2", allI RS adm_all);
|
| 625 | 632 |
|
| 2640 | 633 |
qed_goal "adm_subst" thy |
| 3460 | 634 |
"!!P. [|cont t; adm P|] ==> adm(%x. P (t x))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
635 |
(fn prems => |
| 1461 | 636 |
[ |
| 3460 | 637 |
(rtac admI 1), |
| 2033 | 638 |
(stac (cont2contlub RS contlubE RS spec RS mp) 1), |
| 1461 | 639 |
(atac 1), |
640 |
(atac 1), |
|
| 3460 | 641 |
(etac admD 1), |
642 |
(etac (cont2mono RS ch2ch_monofun) 1), |
|
| 1461 | 643 |
(atac 1), |
644 |
(atac 1) |
|
645 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
646 |
|
| 2640 | 647 |
qed_goal "adm_UU_not_less" thy "adm(%x.~ UU << t(x))" |
| 3460 | 648 |
(fn prems => [Simp_tac 1]); |
649 |
||
650 |
qed_goalw "adm_not_UU" thy [adm_def] |
|
651 |
"!!t. cont(t)==> adm(%x.~ (t x) = UU)" |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
652 |
(fn prems => |
| 1461 | 653 |
[ |
654 |
(strip_tac 1), |
|
655 |
(rtac contrapos 1), |
|
656 |
(etac spec 1), |
|
657 |
(rtac (chain_UU_I RS spec) 1), |
|
658 |
(rtac (cont2mono RS ch2ch_monofun) 1), |
|
659 |
(atac 1), |
|
660 |
(atac 1), |
|
661 |
(rtac (cont2contlub RS contlubE RS spec RS mp RS subst) 1), |
|
662 |
(atac 1), |
|
663 |
(atac 1), |
|
664 |
(atac 1) |
|
665 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
666 |
|
| 2640 | 667 |
qed_goal "adm_eq" thy |
| 3460 | 668 |
"!!u. [|cont u ; cont v|]==> adm(%x. u x = v x)" |
669 |
(fn prems => [asm_simp_tac (!simpset addsimps [po_eq_conv]) 1]); |
|
670 |
||
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
671 |
|
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
672 |
|
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
673 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
674 |
(* admissibility for disjunction is hard to prove. It takes 10 Lemmas *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
675 |
(* ------------------------------------------------------------------------ *) |
|
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
676 |
|
| 1992 | 677 |
local |
678 |
||
| 2619 | 679 |
val adm_disj_lemma1 = prove_goal HOL.thy |
680 |
"!n.P(Y n)|Q(Y n) ==> (? i.!j.R i j --> Q(Y(j))) | (!i.? j.R i j & P(Y(j)))" |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
681 |
(fn prems => |
| 1461 | 682 |
[ |
683 |
(cut_facts_tac prems 1), |
|
684 |
(fast_tac HOL_cs 1) |
|
685 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
686 |
|
| 2640 | 687 |
val adm_disj_lemma2 = prove_goal thy |
| 2619 | 688 |
"!!Q. [| adm(Q); ? X.is_chain(X) & (!n.Q(X(n))) &\ |
| 1992 | 689 |
\ lub(range(Y))=lub(range(X))|] ==> Q(lub(range(Y)))" |
| 3460 | 690 |
(fn _ => [fast_tac (!claset addEs [admD] addss !simpset) 1]); |
| 2619 | 691 |
|
| 2640 | 692 |
val adm_disj_lemma3 = prove_goalw thy [is_chain] |
| 2619 | 693 |
"!!Q. is_chain(Y) ==> is_chain(%m. if m < Suc i then Y(Suc i) else Y m)" |
694 |
(fn _ => |
|
| 1461 | 695 |
[ |
| 2619 | 696 |
asm_simp_tac (!simpset setloop (split_tac[expand_if])) 1, |
697 |
safe_tac HOL_cs, |
|
698 |
subgoal_tac "ia = i" 1, |
|
699 |
Asm_simp_tac 1, |
|
700 |
trans_tac 1 |
|
| 1461 | 701 |
]); |
|
243
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Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
702 |
|
| 2619 | 703 |
val adm_disj_lemma4 = prove_goal Nat.thy |
704 |
"!!Q. !j. i < j --> Q(Y(j)) ==> !n. Q( if n < Suc i then Y(Suc i) else Y n)" |
|
705 |
(fn _ => |
|
| 1461 | 706 |
[ |
| 2619 | 707 |
asm_simp_tac (!simpset setloop (split_tac[expand_if])) 1, |
708 |
strip_tac 1, |
|
709 |
etac allE 1, |
|
710 |
etac mp 1, |
|
711 |
trans_tac 1 |
|
| 1461 | 712 |
]); |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
713 |
|
| 2640 | 714 |
val adm_disj_lemma5 = prove_goal thy |
|
2841
c2508f4ab739
Added "discrete" CPOs and modified IMP to use those rather than "lift"
nipkow
parents:
2764
diff
changeset
|
715 |
"!!Y::nat=>'a::cpo. [| is_chain(Y); ! j. i < j --> Q(Y(j)) |] ==>\ |
| 1992 | 716 |
\ lub(range(Y)) = lub(range(%m. if m< Suc(i) then Y(Suc(i)) else Y m))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
717 |
(fn prems => |
| 1461 | 718 |
[ |
| 2619 | 719 |
safe_tac (HOL_cs addSIs [lub_equal2,adm_disj_lemma3]), |
| 2764 | 720 |
atac 2, |
| 2619 | 721 |
asm_simp_tac (!simpset setloop (split_tac[expand_if])) 1, |
722 |
res_inst_tac [("x","i")] exI 1,
|
|
723 |
strip_tac 1, |
|
724 |
trans_tac 1 |
|
| 1461 | 725 |
]); |
|
243
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Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
726 |
|
| 2640 | 727 |
val adm_disj_lemma6 = prove_goal thy |
|
2841
c2508f4ab739
Added "discrete" CPOs and modified IMP to use those rather than "lift"
nipkow
parents:
2764
diff
changeset
|
728 |
"[| is_chain(Y::nat=>'a::cpo); ? i. ! j. i < j --> Q(Y(j)) |] ==>\ |
| 1992 | 729 |
\ ? X. is_chain(X) & (! n. Q(X(n))) & lub(range(Y)) = lub(range(X))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
730 |
(fn prems => |
| 1461 | 731 |
[ |
732 |
(cut_facts_tac prems 1), |
|
733 |
(etac exE 1), |
|
734 |
(res_inst_tac [("x","%m.if m<Suc(i) then Y(Suc(i)) else Y m")] exI 1),
|
|
735 |
(rtac conjI 1), |
|
736 |
(rtac adm_disj_lemma3 1), |
|
737 |
(atac 1), |
|
738 |
(rtac conjI 1), |
|
739 |
(rtac adm_disj_lemma4 1), |
|
740 |
(atac 1), |
|
741 |
(rtac adm_disj_lemma5 1), |
|
742 |
(atac 1), |
|
743 |
(atac 1) |
|
744 |
]); |
|
|
243
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nipkow
parents:
diff
changeset
|
745 |
|
| 2640 | 746 |
val adm_disj_lemma7 = prove_goal thy |
|
2841
c2508f4ab739
Added "discrete" CPOs and modified IMP to use those rather than "lift"
nipkow
parents:
2764
diff
changeset
|
747 |
"[| is_chain(Y::nat=>'a::cpo); ! i. ? j. i < j & P(Y(j)) |] ==>\ |
| 1992 | 748 |
\ is_chain(%m. Y(Least(%j. m<j & P(Y(j)))))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
749 |
(fn prems => |
| 1461 | 750 |
[ |
751 |
(cut_facts_tac prems 1), |
|
752 |
(rtac is_chainI 1), |
|
753 |
(rtac allI 1), |
|
754 |
(rtac chain_mono3 1), |
|
755 |
(atac 1), |
|
| 1675 | 756 |
(rtac Least_le 1), |
| 1461 | 757 |
(rtac conjI 1), |
758 |
(rtac Suc_lessD 1), |
|
759 |
(etac allE 1), |
|
760 |
(etac exE 1), |
|
| 1675 | 761 |
(rtac (LeastI RS conjunct1) 1), |
| 1461 | 762 |
(atac 1), |
763 |
(etac allE 1), |
|
764 |
(etac exE 1), |
|
| 1675 | 765 |
(rtac (LeastI RS conjunct2) 1), |
| 1461 | 766 |
(atac 1) |
767 |
]); |
|
|
243
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Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
768 |
|
| 2640 | 769 |
val adm_disj_lemma8 = prove_goal thy |
| 2619 | 770 |
"[| ! i. ? j. i < j & P(Y(j)) |] ==> ! m. P(Y(LEAST j::nat. m<j & P(Y(j))))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
771 |
(fn prems => |
| 1461 | 772 |
[ |
773 |
(cut_facts_tac prems 1), |
|
774 |
(strip_tac 1), |
|
775 |
(etac allE 1), |
|
776 |
(etac exE 1), |
|
| 1675 | 777 |
(etac (LeastI RS conjunct2) 1) |
| 1461 | 778 |
]); |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
779 |
|
| 2640 | 780 |
val adm_disj_lemma9 = prove_goal thy |
|
2841
c2508f4ab739
Added "discrete" CPOs and modified IMP to use those rather than "lift"
nipkow
parents:
2764
diff
changeset
|
781 |
"[| is_chain(Y::nat=>'a::cpo); ! i. ? j. i < j & P(Y(j)) |] ==>\ |
| 1992 | 782 |
\ lub(range(Y)) = lub(range(%m. Y(Least(%j. m<j & P(Y(j))))))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
783 |
(fn prems => |
| 1461 | 784 |
[ |
785 |
(cut_facts_tac prems 1), |
|
786 |
(rtac antisym_less 1), |
|
787 |
(rtac lub_mono 1), |
|
788 |
(atac 1), |
|
789 |
(rtac adm_disj_lemma7 1), |
|
790 |
(atac 1), |
|
791 |
(atac 1), |
|
792 |
(strip_tac 1), |
|
793 |
(rtac (chain_mono RS mp) 1), |
|
794 |
(atac 1), |
|
795 |
(etac allE 1), |
|
796 |
(etac exE 1), |
|
| 1675 | 797 |
(rtac (LeastI RS conjunct1) 1), |
| 1461 | 798 |
(atac 1), |
799 |
(rtac lub_mono3 1), |
|
800 |
(rtac adm_disj_lemma7 1), |
|
801 |
(atac 1), |
|
802 |
(atac 1), |
|
803 |
(atac 1), |
|
804 |
(strip_tac 1), |
|
805 |
(rtac exI 1), |
|
806 |
(rtac (chain_mono RS mp) 1), |
|
807 |
(atac 1), |
|
808 |
(rtac lessI 1) |
|
809 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
810 |
|
| 2640 | 811 |
val adm_disj_lemma10 = prove_goal thy |
|
2841
c2508f4ab739
Added "discrete" CPOs and modified IMP to use those rather than "lift"
nipkow
parents:
2764
diff
changeset
|
812 |
"[| is_chain(Y::nat=>'a::cpo); ! i. ? j. i < j & P(Y(j)) |] ==>\ |
| 1992 | 813 |
\ ? X. is_chain(X) & (! n. P(X(n))) & lub(range(Y)) = lub(range(X))" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
814 |
(fn prems => |
| 1461 | 815 |
[ |
816 |
(cut_facts_tac prems 1), |
|
| 1675 | 817 |
(res_inst_tac [("x","%m. Y(Least(%j. m<j & P(Y(j))))")] exI 1),
|
| 1461 | 818 |
(rtac conjI 1), |
819 |
(rtac adm_disj_lemma7 1), |
|
820 |
(atac 1), |
|
821 |
(atac 1), |
|
822 |
(rtac conjI 1), |
|
823 |
(rtac adm_disj_lemma8 1), |
|
824 |
(atac 1), |
|
825 |
(rtac adm_disj_lemma9 1), |
|
826 |
(atac 1), |
|
827 |
(atac 1) |
|
828 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
829 |
|
| 2640 | 830 |
val adm_disj_lemma12 = prove_goal thy |
| 1992 | 831 |
"[| adm(P); is_chain(Y);? i. ! j. i < j --> P(Y(j))|]==>P(lub(range(Y)))" |
832 |
(fn prems => |
|
833 |
[ |
|
834 |
(cut_facts_tac prems 1), |
|
835 |
(etac adm_disj_lemma2 1), |
|
836 |
(etac adm_disj_lemma6 1), |
|
837 |
(atac 1) |
|
838 |
]); |
|
| 430 | 839 |
|
| 1992 | 840 |
in |
841 |
||
| 2640 | 842 |
val adm_lemma11 = prove_goal thy |
| 430 | 843 |
"[| adm(P); is_chain(Y); ! i. ? j. i < j & P(Y(j)) |]==>P(lub(range(Y)))" |
844 |
(fn prems => |
|
| 1461 | 845 |
[ |
846 |
(cut_facts_tac prems 1), |
|
847 |
(etac adm_disj_lemma2 1), |
|
848 |
(etac adm_disj_lemma10 1), |
|
849 |
(atac 1) |
|
850 |
]); |
|
| 430 | 851 |
|
| 2640 | 852 |
val adm_disj = prove_goal thy |
| 3460 | 853 |
"!!P. [| adm P; adm Q |] ==> adm(%x.P x | Q x)" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
854 |
(fn prems => |
| 1461 | 855 |
[ |
| 3460 | 856 |
(rtac admI 1), |
| 1461 | 857 |
(rtac (adm_disj_lemma1 RS disjE) 1), |
858 |
(atac 1), |
|
859 |
(rtac disjI2 1), |
|
860 |
(etac adm_disj_lemma12 1), |
|
861 |
(atac 1), |
|
862 |
(atac 1), |
|
863 |
(rtac disjI1 1), |
|
| 1992 | 864 |
(etac adm_lemma11 1), |
| 1461 | 865 |
(atac 1), |
866 |
(atac 1) |
|
867 |
]); |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
868 |
|
| 1992 | 869 |
end; |
870 |
||
871 |
bind_thm("adm_lemma11",adm_lemma11);
|
|
872 |
bind_thm("adm_disj",adm_disj);
|
|
| 430 | 873 |
|
| 2640 | 874 |
qed_goal "adm_imp" thy |
| 3460 | 875 |
"!!P. [| adm(%x.~(P x)); adm Q |] ==> adm(%x.P x --> Q x)" |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
876 |
(fn prems => |
| 1461 | 877 |
[ |
| 3460 | 878 |
subgoal_tac "(%x.P x --> Q x) = (%x. ~P x | Q x)" 1, |
879 |
(Asm_simp_tac 1), |
|
880 |
(etac adm_disj 1), |
|
| 1461 | 881 |
(atac 1), |
| 3460 | 882 |
(rtac ext 1), |
883 |
(fast_tac HOL_cs 1) |
|
| 1461 | 884 |
]); |
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
885 |
|
| 3460 | 886 |
goal Fix.thy "!! P. [| adm (%x. P x --> Q x); adm (%x.Q x --> P x) |] \ |
887 |
\ ==> adm (%x. P x = Q x)"; |
|
888 |
by(subgoal_tac "(%x.P x = Q x) = (%x. (P x --> Q x) & (Q x --> P x))" 1); |
|
889 |
by (Asm_simp_tac 1); |
|
890 |
by (rtac ext 1); |
|
891 |
by (fast_tac HOL_cs 1); |
|
892 |
qed"adm_iff"; |
|
893 |
||
894 |
||
| 2640 | 895 |
qed_goal "adm_not_conj" thy |
| 1681 | 896 |
"[| adm (%x. ~ P x); adm (%x. ~ Q x) |] ==> adm (%x. ~ (P x & Q x))"(fn prems=>[ |
| 2033 | 897 |
cut_facts_tac prems 1, |
898 |
subgoal_tac |
|
899 |
"(%x. ~ (P x & Q x)) = (%x. ~ P x | ~ Q x)" 1, |
|
900 |
rtac ext 2, |
|
901 |
fast_tac HOL_cs 2, |
|
902 |
etac ssubst 1, |
|
903 |
etac adm_disj 1, |
|
904 |
atac 1]); |
|
| 1675 | 905 |
|
| 2566 | 906 |
val adm_lemmas = [adm_imp,adm_disj,adm_eq,adm_not_UU,adm_UU_not_less, |
| 3460 | 907 |
adm_all2,adm_not_less,adm_not_free,adm_not_conj,adm_conj,adm_less, |
908 |
adm_iff]; |
|
|
243
c22b85994e17
Franz Regensburger's Higher-Order Logic of Computable Functions embedding LCF
nipkow
parents:
diff
changeset
|
909 |
|
| 2566 | 910 |
Addsimps adm_lemmas; |