(* Title: HOL/Library/Old_Recdef.thy
Author: Konrad Slind and Markus Wenzel, TU Muenchen
*)
section \TFL: recursive function definitions\
theory Old_Recdef
imports Main
keywords
"recdef" :: thy_decl and
"permissive" "congs" "hints"
begin
subsection \Lemmas for TFL\
lemma tfl_wf_induct: "ALL R. wf R -->
(ALL P. (ALL x. (ALL y. (y,x):R --> P y) --> P x) --> (ALL x. P x))"
apply clarify
apply (rule_tac r = R and P = P and a = x in wf_induct, assumption, blast)
done
lemma tfl_cut_def: "cut f r x \ (\y. if (y,x) \ r then f y else undefined)"
unfolding cut_def .
lemma tfl_cut_apply: "ALL f R. (x,a):R --> (cut f R a)(x) = f(x)"
apply clarify
apply (rule cut_apply, assumption)
done
lemma tfl_wfrec:
"ALL M R f. (f=wfrec R M) --> wf R --> (ALL x. f x = M (cut f R x) x)"
apply clarify
apply (erule wfrec)
done
lemma tfl_eq_True: "(x = True) --> x"
by blast
lemma tfl_rev_eq_mp: "(x = y) --> y --> x"
by blast
lemma tfl_simp_thm: "(x --> y) --> (x = x') --> (x' --> y)"
by blast
lemma tfl_P_imp_P_iff_True: "P ==> P = True"
by blast
lemma tfl_imp_trans: "(A --> B) ==> (B --> C) ==> (A --> C)"
by blast
lemma tfl_disj_assoc: "(a \ b) \ c == a \ (b \ c)"
by simp
lemma tfl_disjE: "P \ Q ==> P --> R ==> Q --> R ==> R"
by blast
lemma tfl_exE: "\x. P x ==> \x. P x --> Q ==> Q"
by blast
ML_file "old_recdef.ML"
subsection \Rule setup\
lemmas [recdef_simp] =
inv_image_def
measure_def
lex_prod_def
same_fst_def
less_Suc_eq [THEN iffD2]
lemmas [recdef_cong] =
if_cong let_cong image_cong INF_cong SUP_cong bex_cong ball_cong imp_cong
map_cong filter_cong takeWhile_cong dropWhile_cong foldl_cong foldr_cong
lemmas [recdef_wf] =
wf_trancl
wf_less_than
wf_lex_prod
wf_inv_image
wf_measure
wf_measures
wf_pred_nat
wf_same_fst
wf_empty
end