(* Title: HOL/BCV/Kildall.thy
ID: $Id$
Author: Tobias Nipkow
Copyright 2000 TUM
Kildall's algorithm
*)
header "Kildall's Algorithm"
theory Kildall = Typing_Framework + While_Combinator:
constdefs
pres_type :: "(nat => 's => 's) => nat => 's set => bool"
"pres_type step n A == !s:A. !p<n. step p s : A"
mono :: "'s ord => (nat => 's => 's) => nat => 's set => bool"
"mono r step n A ==
!s p t. s : A & p < n & s <=_r t --> step p s <=_r step p t"
consts
iter :: "'s binop \<Rightarrow> (nat \<Rightarrow> 's \<Rightarrow> 's) \<Rightarrow> (nat \<Rightarrow> nat list) \<Rightarrow>
's list \<Rightarrow> nat set \<Rightarrow> 's list \<times> nat set"
propa :: "'s binop => nat list => 's => 's list => nat set => 's list * nat set"
primrec
"propa f [] t ss w = (ss,w)"
"propa f (q#qs) t ss w = (let u = t +_f ss!q;
w' = (if u = ss!q then w else insert q w)
in propa f qs t (ss[q := u]) w')"
defs iter_def:
"iter f step succs ss w ==
while (%(ss,w). w \<noteq> {})
(%(ss,w). let p = SOME p. p : w
in propa f (succs p) (step p (ss!p)) ss (w-{p}))
(ss,w)"
constdefs
unstables ::
"'s ord => (nat => 's => 's) => (nat => nat list) => 's list => nat set"
"unstables r step succs ss ==
{p. p < size ss & ~stable r step succs ss p}"
kildall :: "'s ord => 's binop => (nat => 's => 's) => (nat => nat list)
=> 's list => 's list"
"kildall r f step succs ss == fst(iter f step succs ss (unstables r step succs ss))"
consts merges :: "'s binop => 's => nat list => 's list => 's list"
primrec
"merges f s [] ss = ss"
"merges f s (p#ps) ss = merges f s ps (ss[p := s +_f ss!p])"
lemmas [simp] = Let_def le_iff_plus_unchanged [symmetric]
lemma pres_typeD:
"[| pres_type step n A; s:A; p<n |] ==> step p s : A"
by (unfold pres_type_def, blast)
lemma boundedD:
"[| bounded succs n; p < n; q : set(succs p) |] ==> q < n"
by (unfold bounded_def, blast)
lemma monoD:
"[| mono r step n A; p < n; s:A; s <=_r t |] ==> step p s <=_r step p t"
by (unfold mono_def, blast)
(** merges **)
lemma length_merges [rule_format, simp]:
"!ss. size(merges f t ps ss) = size ss"
by (induct_tac ps, auto)
lemma merges_preserves_type [rule_format, simp]:
"[| semilat(A,r,f) |] ==>
!xs. xs : list n A --> x : A --> (!p : set ps. p<n)
--> merges f x ps xs : list n A"
apply (frule semilatDclosedI)
apply (unfold closed_def)
apply (induct_tac ps)
apply auto
done
lemma merges_incr [rule_format]:
"[| semilat(A,r,f) |] ==>
!xs. xs : list n A --> x : A --> (!p:set ps. p<size xs) --> xs <=[r] merges f x ps xs"
apply (induct_tac ps)
apply simp
apply simp
apply clarify
apply (rule order_trans)
apply simp
apply (erule list_update_incr)
apply assumption
apply simp
apply simp
apply (blast intro!: listE_set intro: closedD listE_length [THEN nth_in])
done
lemma merges_same_conv [rule_format]:
"[| semilat(A,r,f) |] ==>
(!xs. xs : list n A --> x:A --> (!p:set ps. p<size xs) -->
(merges f x ps xs = xs) = (!p:set ps. x <=_r xs!p))"
apply (induct_tac ps)
apply simp
apply clarsimp
apply (rename_tac p ps xs)
apply (rule iffI)
apply (rule context_conjI)
apply (subgoal_tac "xs[p := x +_f xs!p] <=[r] xs")
apply (force dest!: le_listD simp add: nth_list_update)
apply (erule subst, rule merges_incr)
apply assumption
apply (blast intro!: listE_set intro: closedD listE_length [THEN nth_in])
apply assumption
apply simp
apply clarify
apply (rotate_tac -2)
apply (erule allE)
apply (erule impE)
apply assumption
apply (erule impE)
apply assumption
apply (drule bspec)
apply assumption
apply (simp add: le_iff_plus_unchanged [THEN iffD1] list_update_same_conv [THEN iffD2])
apply clarify
apply (simp add: le_iff_plus_unchanged [THEN iffD1] list_update_same_conv [THEN iffD2])
done
lemma list_update_le_listI [rule_format]:
"set xs <= A --> set ys <= A --> xs <=[r] ys --> p < size xs -->
x <=_r ys!p --> semilat(A,r,f) --> x:A -->
xs[p := x +_f xs!p] <=[r] ys"
apply (unfold Listn.le_def lesub_def semilat_def)
apply (simp add: list_all2_conv_all_nth nth_list_update)
done
lemma merges_pres_le_ub:
"[| semilat(A,r,f); t:A; set ts <= A; set ss <= A;
!p. p:set ps --> t <=_r ts!p;
!p. p:set ps --> p<size ts;
ss <=[r] ts |]
==> merges f t ps ss <=[r] ts"
proof -
{ fix A r f t ts ps
have
"!!qs. [| semilat(A,r,f); set ts <= A; t:A;
!p. p:set ps --> t <=_r ts!p;
!p. p:set ps --> p<size ts |] ==>
set qs <= set ps -->
(!ss. set ss <= A --> ss <=[r] ts --> merges f t qs ss <=[r] ts)"
apply (induct_tac qs)
apply simp
apply (simp (no_asm_simp))
apply clarify
apply (rotate_tac -2)
apply simp
apply (erule allE, erule impE, erule_tac [2] mp)
apply (simp (no_asm_simp) add: closedD)
apply (simp add: list_update_le_listI)
done
} note this [dest]
case antecedent
thus ?thesis by blast
qed
lemma nth_merges [rule_format]:
"[| semilat (A, r, f); t:A; p < n |] ==> !ss. ss : list n A -->
(!p:set ps. p<n) -->
(merges f t ps ss)!p = (if p : set ps then t +_f ss!p else ss!p)"
apply (induct_tac "ps")
apply simp
apply (simp add: nth_list_update closedD listE_nth_in)
done
(** propa **)
lemma decomp_propa [rule_format]:
"!ss w. (!q:set qs. q < size ss) -->
propa f qs t ss w =
(merges f t qs ss, {q. q:set qs & t +_f ss!q ~= ss!q} Un w)"
apply (induct_tac qs)
apply simp
apply (simp (no_asm))
apply clarify
apply (rule conjI)
apply (simp add: nth_list_update)
apply blast
apply (simp add: nth_list_update)
apply blast
done
(** iter **)
lemma stable_pres_lemma:
"[| semilat (A,r,f); pres_type step n A; bounded succs n;
ss : list n A; p : w; ! q:w. q < n;
! q. q < n --> q ~: w --> stable r step succs ss q; q < n;
q : set (succs p) --> step p (ss ! p) +_f ss ! q = ss ! q;
q ~: w | q = p |]
==> stable r step succs (merges f (step p (ss!p)) (succs p) ss) q"
apply (unfold stable_def)
apply (subgoal_tac "step p (ss!p) : A")
defer
apply (blast intro: listE_nth_in pres_typeD)
apply simp
apply clarify
apply (subst nth_merges)
apply assumption
apply assumption
prefer 2
apply assumption
apply (blast dest: boundedD)
apply (blast dest: boundedD)
apply (subst nth_merges)
apply assumption
apply assumption
prefer 2
apply assumption
apply (blast dest: boundedD)
apply (blast dest: boundedD)
apply simp
apply (rule conjI)
apply clarify
apply (blast intro!: semilat_ub1 semilat_ub2 listE_nth_in
intro: order_trans dest: boundedD)
apply (blast intro!: semilat_ub1 semilat_ub2 listE_nth_in
intro: order_trans dest: boundedD)
done
lemma merges_bounded_lemma [rule_format]:
"[| semilat (A,r,f); mono r step n A; bounded succs n;
step p (ss!p) : A; ss : list n A; ts : list n A; p < n;
ss <=[r] ts; ! p. p < n --> stable r step succs ts p |]
==> merges f (step p (ss!p)) (succs p) ss <=[r] ts"
apply (unfold stable_def)
apply (blast intro!: listE_set monoD listE_nth_in le_listD less_lengthI
intro: merges_pres_le_ub order_trans
dest: pres_typeD boundedD)
done
lemma termination_lemma:
"[| semilat(A,r,f); ss : list n A; t:A; ! q:set qs. q < n; p:w |] ==>
ss <[r] merges f t qs ss |
merges f t qs ss = ss & {q. q:set qs & t +_f ss!q ~= ss!q} Un (w-{p}) < w"
apply (unfold lesssub_def)
apply (simp (no_asm_simp) add: merges_incr)
apply (rule impI)
apply (rule merges_same_conv [THEN iffD1, elim_format])
apply assumption+
defer
apply (rule sym, assumption)
apply (simp cong add: conj_cong add: le_iff_plus_unchanged [symmetric])
apply (blast intro!: psubsetI elim: equalityE)
apply simp
done
lemma iter_properties[rule_format]:
"\<lbrakk> semilat(A,r,f); acc r ; pres_type step n A; mono r step n A;
bounded succs n; \<forall>p\<in>w0. p < n; ss0 \<in> list n A;
\<forall>p<n. p \<notin> w0 \<longrightarrow> stable r step succs ss0 p \<rbrakk> \<Longrightarrow>
iter f step succs ss0 w0 = (ss',w')
\<longrightarrow>
ss' \<in> list n A \<and> stables r step succs ss' \<and> ss0 <=[r] ss' \<and>
(\<forall>ts\<in>list n A. ss0 <=[r] ts \<and> stables r step succs ts \<longrightarrow> ss' <=[r] ts)"
apply (unfold iter_def stables_def)
apply (rule_tac P = "%(ss,w).
ss \<in> list n A \<and> (\<forall>p<n. p \<notin> w \<longrightarrow> stable r step succs ss p) \<and> ss0 <=[r] ss \<and>
(\<forall>ts\<in>list n A. ss0 <=[r] ts \<and> stables r step succs ts \<longrightarrow> ss <=[r] ts) \<and>
(\<forall>p\<in>w. p < n)" and
r = "{(ss',ss) . ss <[r] ss'} <*lex*> finite_psubset"
in while_rule)
(* Invariant holds initially: *)
apply (simp add:stables_def)
(* Invariant is preserved: *)
apply(simp add: stables_def split_paired_all)
apply(rename_tac ss w)
apply(subgoal_tac "(SOME p. p \<in> w) \<in> w")
prefer 2; apply (fast intro: someI)
apply(subgoal_tac "step (SOME p. p \<in> w) (ss ! (SOME p. p \<in> w)) \<in> A")
prefer 2; apply (blast intro: pres_typeD listE_nth_in dest: boundedD);
apply (subgoal_tac "\<forall>q\<in>set(succs (SOME p. p \<in> w)). q < size ss")
prefer 2; apply(clarsimp, blast dest!: boundedD)
apply (subst decomp_propa)
apply blast
apply simp
apply (rule conjI)
apply (blast intro: merges_preserves_type dest: boundedD);
apply (rule conjI)
apply (blast intro!: stable_pres_lemma)
apply (rule conjI)
apply (blast intro!: merges_incr intro: le_list_trans)
apply (rule conjI)
apply clarsimp
apply (best intro!: merges_bounded_lemma)
apply (blast dest!: boundedD)
(* Postcondition holds upon termination: *)
apply(clarsimp simp add: stables_def split_paired_all)
(* Well-foundedness of the termination relation: *)
apply (rule wf_lex_prod)
apply (drule (1) semilatDorderI [THEN acc_le_listI])
apply (simp only: acc_def lesssub_def)
apply (rule wf_finite_psubset)
(* Loop decreases along termination relation: *)
apply(simp add: stables_def split_paired_all)
apply(rename_tac ss w)
apply(subgoal_tac "(SOME p. p \<in> w) \<in> w")
prefer 2; apply (fast intro: someI)
apply(subgoal_tac "step (SOME p. p \<in> w) (ss ! (SOME p. p \<in> w)) \<in> A")
prefer 2; apply (blast intro: pres_typeD listE_nth_in dest: boundedD);
apply (subgoal_tac "\<forall>q\<in>set(succs (SOME p. p \<in> w)). q < n")
prefer 2; apply(clarsimp, blast dest!: boundedD)
apply (subst decomp_propa)
apply clarsimp
apply clarify
apply (simp del: listE_length
add: lex_prod_def finite_psubset_def decomp_propa termination_lemma
bounded_nat_set_is_finite)
done
lemma kildall_properties:
"\<lbrakk> semilat(A,r,f); acc r; pres_type step n A; mono r step n A;
bounded succs n; ss0 \<in> list n A \<rbrakk> \<Longrightarrow>
kildall r f step succs ss0 : list n A \<and>
stables r step succs (kildall r f step succs ss0) \<and>
ss0 <=[r] kildall r f step succs ss0 \<and>
(\<forall>ts\<in>list n A. ss0 <=[r] ts \<and> stables r step succs ts \<longrightarrow>
kildall r f step succs ss0 <=[r] ts)";
apply (unfold kildall_def)
apply(case_tac "iter f step succs ss0 (unstables r step succs ss0)")
apply(simp)
apply (rule iter_properties)
apply (simp_all add: unstables_def stable_def)
done
lemma is_bcv_kildall:
"[| semilat(A,r,f); acc r; top r T;
pres_type step n A; bounded succs n;
mono r step n A |]
==> is_bcv r T step succs n A (kildall r f step succs)"
apply(unfold is_bcv_def wt_step_def)
apply(insert kildall_properties[of A])
apply(simp add:stables_def)
apply clarify
apply(subgoal_tac "kildall r f step succs ss : list n A")
prefer 2 apply (simp(no_asm_simp))
apply (rule iffI)
apply (rule_tac x = "kildall r f step succs ss" in bexI)
apply (rule conjI)
apply blast
apply (simp (no_asm_simp))
apply assumption
apply clarify
apply(subgoal_tac "kildall r f step succs ss!p <=_r ts!p")
apply simp
apply (blast intro!: le_listD less_lengthI)
done
end