(* Title: HOL/wf.ML
ID: $Id$
Author: Tobias Nipkow
Copyright 1992 University of Cambridge
For wf.thy. Well-founded Recursion
*)
open WF;
val H_cong = read_instantiate [("f","H::[?'a, ?'a=>?'b]=>?'b")]
(standard(refl RS cong RS cong));
val H_cong1 = refl RS H_cong;
(*Restriction to domain A. If r is well-founded over A then wf(r)*)
val [prem1,prem2] = goalw WF.thy [wf_def]
"[| r <= Sigma A (%u.A); \
\ !!x P. [| ! x. (! y. <y,x> : r --> P(y)) --> P(x); x:A |] ==> P(x) |] \
\ ==> wf(r)";
by (strip_tac 1);
by (rtac allE 1);
by (assume_tac 1);
by (best_tac (HOL_cs addSEs [prem1 RS subsetD RS SigmaE2] addIs [prem2]) 1);
qed "wfI";
val major::prems = goalw WF.thy [wf_def]
"[| wf(r); \
\ !!x.[| ! y. <y,x>: r --> P(y) |] ==> P(x) \
\ |] ==> P(a)";
by (rtac (major RS spec RS mp RS spec) 1);
by (fast_tac (HOL_cs addEs prems) 1);
qed "wf_induct";
(*Perform induction on i, then prove the wf(r) subgoal using prems. *)
fun wf_ind_tac a prems i =
EVERY [res_inst_tac [("a",a)] wf_induct i,
rename_last_tac a ["1"] (i+1),
ares_tac prems i];
val prems = goal WF.thy "[| wf(r); <a,x>:r; <x,a>:r |] ==> P";
by (subgoal_tac "! x. <a,x>:r --> <x,a>:r --> P" 1);
by (fast_tac (HOL_cs addIs prems) 1);
by (wf_ind_tac "a" prems 1);
by (fast_tac set_cs 1);
qed "wf_asym";
val prems = goal WF.thy "[| wf(r); <a,a>: r |] ==> P";
by (rtac wf_asym 1);
by (REPEAT (resolve_tac prems 1));
qed "wf_anti_refl";
(*transitive closure of a WF relation is WF!*)
val [prem] = goal WF.thy "wf(r) ==> wf(r^+)";
by (rewtac wf_def);
by (strip_tac 1);
(*must retain the universal formula for later use!*)
by (rtac allE 1 THEN assume_tac 1);
by (etac mp 1);
by (res_inst_tac [("a","x")] (prem RS wf_induct) 1);
by (rtac (impI RS allI) 1);
by (etac tranclE 1);
by (fast_tac HOL_cs 1);
by (fast_tac HOL_cs 1);
qed "wf_trancl";
(** cut **)
(*This rewrite rule works upon formulae; thus it requires explicit use of
H_cong to expose the equality*)
goalw WF.thy [cut_def]
"(cut f r x = cut g r x) = (!y. <y,x>:r --> f(y)=g(y))";
by(simp_tac (HOL_ss addsimps [expand_fun_eq]
setloop (split_tac [expand_if])) 1);
qed "cut_cut_eq";
goalw WF.thy [cut_def] "!!x. <x,a>:r ==> (cut f r a)(x) = f(x)";
by(asm_simp_tac HOL_ss 1);
qed "cut_apply";
(*** is_recfun ***)
goalw WF.thy [is_recfun_def,cut_def]
"!!f. [| is_recfun r a H f; ~<b,a>:r |] ==> f(b) = (@z.True)";
by (etac ssubst 1);
by(asm_simp_tac HOL_ss 1);
qed "is_recfun_undef";
(*eresolve_tac transD solves <a,b>:r using transitivity AT MOST ONCE
mp amd allE instantiate induction hypotheses*)
fun indhyp_tac hyps =
ares_tac (TrueI::hyps) ORELSE'
(cut_facts_tac hyps THEN'
DEPTH_SOLVE_1 o (ares_tac [TrueI] ORELSE'
eresolve_tac [transD, mp, allE]));
(*** NOTE! some simplifications need a different finish_tac!! ***)
fun indhyp_tac hyps =
resolve_tac (TrueI::refl::hyps) ORELSE'
(cut_facts_tac hyps THEN'
DEPTH_SOLVE_1 o (ares_tac [TrueI] ORELSE'
eresolve_tac [transD, mp, allE]));
val wf_super_ss = HOL_ss setsolver indhyp_tac;
val prems = goalw WF.thy [is_recfun_def,cut_def]
"[| wf(r); trans(r); is_recfun r a H f; is_recfun r b H g |] ==> \
\ <x,a>:r --> <x,b>:r --> f(x)=g(x)";
by (cut_facts_tac prems 1);
by (etac wf_induct 1);
by (REPEAT (rtac impI 1 ORELSE etac ssubst 1));
by (asm_simp_tac (wf_super_ss addcongs [if_cong]) 1);
qed "is_recfun_equal_lemma";
bind_thm ("is_recfun_equal", (is_recfun_equal_lemma RS mp RS mp));
val prems as [wfr,transr,recfa,recgb,_] = goalw WF.thy [cut_def]
"[| wf(r); trans(r); \
\ is_recfun r a H f; is_recfun r b H g; <b,a>:r |] ==> \
\ cut f r b = g";
val gundef = recgb RS is_recfun_undef
and fisg = recgb RS (recfa RS (transr RS (wfr RS is_recfun_equal)));
by (cut_facts_tac prems 1);
by (rtac ext 1);
by (asm_simp_tac (wf_super_ss addsimps [gundef,fisg]
setloop (split_tac [expand_if])) 1);
qed "is_recfun_cut";
(*** Main Existence Lemma -- Basic Properties of the_recfun ***)
val prems = goalw WF.thy [the_recfun_def]
"is_recfun r a H f ==> is_recfun r a H (the_recfun r a H)";
by (res_inst_tac [("P", "is_recfun r a H")] selectI 1);
by (resolve_tac prems 1);
qed "is_the_recfun";
val prems = goal WF.thy
"[| wf(r); trans(r) |] ==> is_recfun r a H (the_recfun r a H)";
by (cut_facts_tac prems 1);
by (wf_ind_tac "a" prems 1);
by (res_inst_tac [("f", "cut (%y. wftrec r y H) r a1")] is_the_recfun 1);
by (rewrite_goals_tac [is_recfun_def, wftrec_def]);
by (rtac (cut_cut_eq RS ssubst) 1);
(*Applying the substitution: must keep the quantified assumption!!*)
by (EVERY1 [strip_tac, rtac H_cong1, rtac allE, atac,
etac (mp RS ssubst), atac]);
by (fold_tac [is_recfun_def]);
by (asm_simp_tac (wf_super_ss addsimps[cut_apply,is_recfun_cut,cut_cut_eq]) 1);
qed "unfold_the_recfun";
(*Beware incompleteness of unification!*)
val prems = goal WF.thy
"[| wf(r); trans(r); <c,a>:r; <c,b>:r |] \
\ ==> the_recfun r a H c = the_recfun r b H c";
by (DEPTH_SOLVE (ares_tac (prems@[is_recfun_equal,unfold_the_recfun]) 1));
qed "the_recfun_equal";
val prems = goal WF.thy
"[| wf(r); trans(r); <b,a>:r |] \
\ ==> cut (the_recfun r a H) r b = the_recfun r b H";
by (REPEAT (ares_tac (prems@[is_recfun_cut,unfold_the_recfun]) 1));
qed "the_recfun_cut";
(*** Unfolding wftrec ***)
goalw WF.thy [wftrec_def]
"!!r. [| wf(r); trans(r) |] ==> \
\ wftrec r a H = H a (cut (%x.wftrec r x H) r a)";
by (EVERY1 [stac (rewrite_rule [is_recfun_def] unfold_the_recfun),
REPEAT o atac, rtac H_cong1]);
by (asm_simp_tac (HOL_ss addsimps [cut_cut_eq,the_recfun_cut]) 1);
qed "wftrec";
(*Unused but perhaps interesting*)
val prems = goal WF.thy
"[| wf(r); trans(r); !!f x. H x (cut f r x) = H x f |] ==> \
\ wftrec r a H = H a (%x.wftrec r x H)";
by (rtac (wftrec RS trans) 1);
by (REPEAT (resolve_tac prems 1));
qed "wftrec2";
(** Removal of the premise trans(r) **)
goalw WF.thy [wfrec_def]
"!!r. wf(r) ==> wfrec r a H = H a (cut (%x.wfrec r x H) r a)";
by (etac (wf_trancl RS wftrec RS ssubst) 1);
by (rtac trans_trancl 1);
by (rtac (refl RS H_cong) 1); (*expose the equality of cuts*)
by (simp_tac (HOL_ss addsimps [cut_cut_eq, cut_apply, r_into_trancl]) 1);
qed "wfrec";
(*This form avoids giant explosions in proofs. NOTE USE OF == *)
val rew::prems = goal WF.thy
"[| !!x. f(x)==wfrec r x H; wf(r) |] ==> f(a) = H a (cut (%x.f(x)) r a)";
by (rewtac rew);
by (REPEAT (resolve_tac (prems@[wfrec]) 1));
qed "def_wfrec";