(* Title: HOL/UNITY/Extend.thy
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1998 University of Cambridge
Extending of state setsExtending of state sets
function f (forget) maps the extended state to the original state
function g (forgotten) maps the extended state to the "extending part"
*)
header{*Extending State Sets*}
theory Extend imports Guar begin
constdefs
(*MOVE to Relation.thy?*)
Restrict :: "[ 'a set, ('a*'b) set] => ('a*'b) set"
"Restrict A r == r \<inter> (A <*> UNIV)"
good_map :: "['a*'b => 'c] => bool"
"good_map h == surj h & (\<forall>x y. fst (inv h (h (x,y))) = x)"
(*Using the locale constant "f", this is f (h (x,y))) = x*)
extend_set :: "['a*'b => 'c, 'a set] => 'c set"
"extend_set h A == h ` (A <*> UNIV)"
project_set :: "['a*'b => 'c, 'c set] => 'a set"
"project_set h C == {x. \<exists>y. h(x,y) \<in> C}"
extend_act :: "['a*'b => 'c, ('a*'a) set] => ('c*'c) set"
"extend_act h == %act. \<Union>(s,s') \<in> act. \<Union>y. {(h(s,y), h(s',y))}"
project_act :: "['a*'b => 'c, ('c*'c) set] => ('a*'a) set"
"project_act h act == {(x,x'). \<exists>y y'. (h(x,y), h(x',y')) \<in> act}"
extend :: "['a*'b => 'c, 'a program] => 'c program"
"extend h F == mk_program (extend_set h (Init F),
extend_act h ` Acts F,
project_act h -` AllowedActs F)"
(*Argument C allows weak safety laws to be projected*)
project :: "['a*'b => 'c, 'c set, 'c program] => 'a program"
"project h C F ==
mk_program (project_set h (Init F),
project_act h ` Restrict C ` Acts F,
{act. Restrict (project_set h C) act :
project_act h ` Restrict C ` AllowedActs F})"
locale Extend =
fixes f :: "'c => 'a"
and g :: "'c => 'b"
and h :: "'a*'b => 'c" (*isomorphism between 'a * 'b and 'c *)
and slice :: "['c set, 'b] => 'a set"
assumes
good_h: "good_map h"
defines f_def: "f z == fst (inv h z)"
and g_def: "g z == snd (inv h z)"
and slice_def: "slice Z y == {x. h(x,y) \<in> Z}"
(** These we prove OUTSIDE the locale. **)
subsection{*Restrict*}
(*MOVE to Relation.thy?*)
lemma Restrict_iff [iff]: "((x,y): Restrict A r) = ((x,y): r & x \<in> A)"
by (unfold Restrict_def, blast)
lemma Restrict_UNIV [simp]: "Restrict UNIV = id"
apply (rule ext)
apply (auto simp add: Restrict_def)
done
lemma Restrict_empty [simp]: "Restrict {} r = {}"
by (auto simp add: Restrict_def)
lemma Restrict_Int [simp]: "Restrict A (Restrict B r) = Restrict (A \<inter> B) r"
by (unfold Restrict_def, blast)
lemma Restrict_triv: "Domain r \<subseteq> A ==> Restrict A r = r"
by (unfold Restrict_def, auto)
lemma Restrict_subset: "Restrict A r \<subseteq> r"
by (unfold Restrict_def, auto)
lemma Restrict_eq_mono:
"[| A \<subseteq> B; Restrict B r = Restrict B s |]
==> Restrict A r = Restrict A s"
by (unfold Restrict_def, blast)
lemma Restrict_imageI:
"[| s \<in> RR; Restrict A r = Restrict A s |]
==> Restrict A r \<in> Restrict A ` RR"
by (unfold Restrict_def image_def, auto)
lemma Domain_Restrict [simp]: "Domain (Restrict A r) = A \<inter> Domain r"
by blast
lemma Image_Restrict [simp]: "(Restrict A r) `` B = r `` (A \<inter> B)"
by blast
(*Possibly easier than reasoning about "inv h"*)
lemma good_mapI:
assumes surj_h: "surj h"
and prem: "!! x x' y y'. h(x,y) = h(x',y') ==> x=x'"
shows "good_map h"
apply (simp add: good_map_def)
apply (safe intro!: surj_h)
apply (rule prem)
apply (subst surjective_pairing [symmetric])
apply (subst surj_h [THEN surj_f_inv_f])
apply (rule refl)
done
lemma good_map_is_surj: "good_map h ==> surj h"
by (unfold good_map_def, auto)
(*A convenient way of finding a closed form for inv h*)
lemma fst_inv_equalityI:
assumes surj_h: "surj h"
and prem: "!! x y. g (h(x,y)) = x"
shows "fst (inv h z) = g z"
by (metis UNIV_I f_inv_into_f pair_collapse prem surj_h surj_range)
subsection{*Trivial properties of f, g, h*}
lemma (in Extend) f_h_eq [simp]: "f(h(x,y)) = x"
by (simp add: f_def good_h [unfolded good_map_def, THEN conjunct2])
lemma (in Extend) h_inject1 [dest]: "h(x,y) = h(x',y') ==> x=x'"
apply (drule_tac f = f in arg_cong)
apply (simp add: f_def good_h [unfolded good_map_def, THEN conjunct2])
done
lemma (in Extend) h_f_g_equiv: "h(f z, g z) == z"
by (simp add: f_def g_def
good_h [unfolded good_map_def, THEN conjunct1, THEN surj_f_inv_f])
lemma (in Extend) h_f_g_eq: "h(f z, g z) = z"
by (simp add: h_f_g_equiv)
lemma (in Extend) split_extended_all:
"(!!z. PROP P z) == (!!u y. PROP P (h (u, y)))"
proof
assume allP: "\<And>z. PROP P z"
fix u y
show "PROP P (h (u, y))" by (rule allP)
next
assume allPh: "\<And>u y. PROP P (h(u,y))"
fix z
have Phfgz: "PROP P (h (f z, g z))" by (rule allPh)
show "PROP P z" by (rule Phfgz [unfolded h_f_g_equiv])
qed
subsection{*@{term extend_set}: basic properties*}
lemma project_set_iff [iff]:
"(x \<in> project_set h C) = (\<exists>y. h(x,y) \<in> C)"
by (simp add: project_set_def)
lemma extend_set_mono: "A \<subseteq> B ==> extend_set h A \<subseteq> extend_set h B"
by (unfold extend_set_def, blast)
lemma (in Extend) mem_extend_set_iff [iff]: "z \<in> extend_set h A = (f z \<in> A)"
apply (unfold extend_set_def)
apply (force intro: h_f_g_eq [symmetric])
done
lemma (in Extend) extend_set_strict_mono [iff]:
"(extend_set h A \<subseteq> extend_set h B) = (A \<subseteq> B)"
by (unfold extend_set_def, force)
lemma extend_set_empty [simp]: "extend_set h {} = {}"
by (unfold extend_set_def, auto)
lemma (in Extend) extend_set_eq_Collect: "extend_set h {s. P s} = {s. P(f s)}"
by auto
lemma (in Extend) extend_set_sing: "extend_set h {x} = {s. f s = x}"
by auto
lemma (in Extend) extend_set_inverse [simp]:
"project_set h (extend_set h C) = C"
by (unfold extend_set_def, auto)
lemma (in Extend) extend_set_project_set:
"C \<subseteq> extend_set h (project_set h C)"
apply (unfold extend_set_def)
apply (auto simp add: split_extended_all, blast)
done
lemma (in Extend) inj_extend_set: "inj (extend_set h)"
apply (rule inj_on_inverseI)
apply (rule extend_set_inverse)
done
lemma (in Extend) extend_set_UNIV_eq [simp]: "extend_set h UNIV = UNIV"
apply (unfold extend_set_def)
apply (auto simp add: split_extended_all)
done
subsection{*@{term project_set}: basic properties*}
(*project_set is simply image!*)
lemma (in Extend) project_set_eq: "project_set h C = f ` C"
by (auto intro: f_h_eq [symmetric] simp add: split_extended_all)
(*Converse appears to fail*)
lemma (in Extend) project_set_I: "!!z. z \<in> C ==> f z \<in> project_set h C"
by (auto simp add: split_extended_all)
subsection{*More laws*}
(*Because A and B could differ on the "other" part of the state,
cannot generalize to
project_set h (A \<inter> B) = project_set h A \<inter> project_set h B
*)
lemma (in Extend) project_set_extend_set_Int:
"project_set h ((extend_set h A) \<inter> B) = A \<inter> (project_set h B)"
by auto
(*Unused, but interesting?*)
lemma (in Extend) project_set_extend_set_Un:
"project_set h ((extend_set h A) \<union> B) = A \<union> (project_set h B)"
by auto
lemma project_set_Int_subset:
"project_set h (A \<inter> B) \<subseteq> (project_set h A) \<inter> (project_set h B)"
by auto
lemma (in Extend) extend_set_Un_distrib:
"extend_set h (A \<union> B) = extend_set h A \<union> extend_set h B"
by auto
lemma (in Extend) extend_set_Int_distrib:
"extend_set h (A \<inter> B) = extend_set h A \<inter> extend_set h B"
by auto
lemma (in Extend) extend_set_INT_distrib:
"extend_set h (INTER A B) = (\<Inter>x \<in> A. extend_set h (B x))"
by auto
lemma (in Extend) extend_set_Diff_distrib:
"extend_set h (A - B) = extend_set h A - extend_set h B"
by auto
lemma (in Extend) extend_set_Union:
"extend_set h (Union A) = (\<Union>X \<in> A. extend_set h X)"
by blast
lemma (in Extend) extend_set_subset_Compl_eq:
"(extend_set h A \<subseteq> - extend_set h B) = (A \<subseteq> - B)"
by (unfold extend_set_def, auto)
subsection{*@{term extend_act}*}
(*Can't strengthen it to
((h(s,y), h(s',y')) \<in> extend_act h act) = ((s, s') \<in> act & y=y')
because h doesn't have to be injective in the 2nd argument*)
lemma (in Extend) mem_extend_act_iff [iff]:
"((h(s,y), h(s',y)) \<in> extend_act h act) = ((s, s') \<in> act)"
by (unfold extend_act_def, auto)
(*Converse fails: (z,z') would include actions that changed the g-part*)
lemma (in Extend) extend_act_D:
"(z, z') \<in> extend_act h act ==> (f z, f z') \<in> act"
by (unfold extend_act_def, auto)
lemma (in Extend) extend_act_inverse [simp]:
"project_act h (extend_act h act) = act"
by (unfold extend_act_def project_act_def, blast)
lemma (in Extend) project_act_extend_act_restrict [simp]:
"project_act h (Restrict C (extend_act h act)) =
Restrict (project_set h C) act"
by (unfold extend_act_def project_act_def, blast)
lemma (in Extend) subset_extend_act_D:
"act' \<subseteq> extend_act h act ==> project_act h act' \<subseteq> act"
by (unfold extend_act_def project_act_def, force)
lemma (in Extend) inj_extend_act: "inj (extend_act h)"
apply (rule inj_on_inverseI)
apply (rule extend_act_inverse)
done
lemma (in Extend) extend_act_Image [simp]:
"extend_act h act `` (extend_set h A) = extend_set h (act `` A)"
by (unfold extend_set_def extend_act_def, force)
lemma (in Extend) extend_act_strict_mono [iff]:
"(extend_act h act' \<subseteq> extend_act h act) = (act'<=act)"
by (unfold extend_act_def, auto)
declare (in Extend) inj_extend_act [THEN inj_eq, iff]
(*This theorem is (extend_act h act' = extend_act h act) = (act'=act) *)
lemma Domain_extend_act:
"Domain (extend_act h act) = extend_set h (Domain act)"
by (unfold extend_set_def extend_act_def, force)
lemma (in Extend) extend_act_Id [simp]:
"extend_act h Id = Id"
apply (unfold extend_act_def)
apply (force intro: h_f_g_eq [symmetric])
done
lemma (in Extend) project_act_I:
"!!z z'. (z, z') \<in> act ==> (f z, f z') \<in> project_act h act"
apply (unfold project_act_def)
apply (force simp add: split_extended_all)
done
lemma (in Extend) project_act_Id [simp]: "project_act h Id = Id"
by (unfold project_act_def, force)
lemma (in Extend) Domain_project_act:
"Domain (project_act h act) = project_set h (Domain act)"
apply (unfold project_act_def)
apply (force simp add: split_extended_all)
done
subsection{*extend*}
text{*Basic properties*}
lemma Init_extend [simp]:
"Init (extend h F) = extend_set h (Init F)"
by (unfold extend_def, auto)
lemma Init_project [simp]:
"Init (project h C F) = project_set h (Init F)"
by (unfold project_def, auto)
lemma (in Extend) Acts_extend [simp]:
"Acts (extend h F) = (extend_act h ` Acts F)"
by (simp add: extend_def insert_Id_image_Acts)
lemma (in Extend) AllowedActs_extend [simp]:
"AllowedActs (extend h F) = project_act h -` AllowedActs F"
by (simp add: extend_def insert_absorb)
lemma Acts_project [simp]:
"Acts(project h C F) = insert Id (project_act h ` Restrict C ` Acts F)"
by (auto simp add: project_def image_iff)
lemma (in Extend) AllowedActs_project [simp]:
"AllowedActs(project h C F) =
{act. Restrict (project_set h C) act
\<in> project_act h ` Restrict C ` AllowedActs F}"
apply (simp (no_asm) add: project_def image_iff)
apply (subst insert_absorb)
apply (auto intro!: bexI [of _ Id] simp add: project_act_def)
done
lemma (in Extend) Allowed_extend:
"Allowed (extend h F) = project h UNIV -` Allowed F"
apply (simp (no_asm) add: AllowedActs_extend Allowed_def)
apply blast
done
lemma (in Extend) extend_SKIP [simp]: "extend h SKIP = SKIP"
apply (unfold SKIP_def)
apply (rule program_equalityI, auto)
done
lemma project_set_UNIV [simp]: "project_set h UNIV = UNIV"
by auto
lemma project_set_Union:
"project_set h (Union A) = (\<Union>X \<in> A. project_set h X)"
by blast
(*Converse FAILS: the extended state contributing to project_set h C
may not coincide with the one contributing to project_act h act*)
lemma (in Extend) project_act_Restrict_subset:
"project_act h (Restrict C act) \<subseteq>
Restrict (project_set h C) (project_act h act)"
by (auto simp add: project_act_def)
lemma (in Extend) project_act_Restrict_Id_eq:
"project_act h (Restrict C Id) = Restrict (project_set h C) Id"
by (auto simp add: project_act_def)
lemma (in Extend) project_extend_eq:
"project h C (extend h F) =
mk_program (Init F, Restrict (project_set h C) ` Acts F,
{act. Restrict (project_set h C) act
\<in> project_act h ` Restrict C `
(project_act h -` AllowedActs F)})"
apply (rule program_equalityI)
apply simp
apply (simp add: image_eq_UN)
apply (simp add: project_def)
done
lemma (in Extend) extend_inverse [simp]:
"project h UNIV (extend h F) = F"
apply (simp (no_asm_simp) add: project_extend_eq image_eq_UN
subset_UNIV [THEN subset_trans, THEN Restrict_triv])
apply (rule program_equalityI)
apply (simp_all (no_asm))
apply (subst insert_absorb)
apply (simp (no_asm) add: bexI [of _ Id])
apply auto
apply (rename_tac "act")
apply (rule_tac x = "extend_act h act" in bexI, auto)
done
lemma (in Extend) inj_extend: "inj (extend h)"
apply (rule inj_on_inverseI)
apply (rule extend_inverse)
done
lemma (in Extend) extend_Join [simp]:
"extend h (F\<squnion>G) = extend h F\<squnion>extend h G"
apply (rule program_equalityI)
apply (simp (no_asm) add: extend_set_Int_distrib)
apply (simp add: image_Un, auto)
done
lemma (in Extend) extend_JN [simp]:
"extend h (JOIN I F) = (\<Squnion>i \<in> I. extend h (F i))"
apply (rule program_equalityI)
apply (simp (no_asm) add: extend_set_INT_distrib)
apply (simp add: image_UN, auto)
done
(** These monotonicity results look natural but are UNUSED **)
lemma (in Extend) extend_mono: "F \<le> G ==> extend h F \<le> extend h G"
by (force simp add: component_eq_subset)
lemma (in Extend) project_mono: "F \<le> G ==> project h C F \<le> project h C G"
by (simp add: component_eq_subset, blast)
lemma (in Extend) all_total_extend: "all_total F ==> all_total (extend h F)"
by (simp add: all_total_def Domain_extend_act)
subsection{*Safety: co, stable*}
lemma (in Extend) extend_constrains:
"(extend h F \<in> (extend_set h A) co (extend_set h B)) =
(F \<in> A co B)"
by (simp add: constrains_def)
lemma (in Extend) extend_stable:
"(extend h F \<in> stable (extend_set h A)) = (F \<in> stable A)"
by (simp add: stable_def extend_constrains)
lemma (in Extend) extend_invariant:
"(extend h F \<in> invariant (extend_set h A)) = (F \<in> invariant A)"
by (simp add: invariant_def extend_stable)
(*Projects the state predicates in the property satisfied by extend h F.
Converse fails: A and B may differ in their extra variables*)
lemma (in Extend) extend_constrains_project_set:
"extend h F \<in> A co B ==> F \<in> (project_set h A) co (project_set h B)"
by (auto simp add: constrains_def, force)
lemma (in Extend) extend_stable_project_set:
"extend h F \<in> stable A ==> F \<in> stable (project_set h A)"
by (simp add: stable_def extend_constrains_project_set)
subsection{*Weak safety primitives: Co, Stable*}
lemma (in Extend) reachable_extend_f:
"p \<in> reachable (extend h F) ==> f p \<in> reachable F"
apply (erule reachable.induct)
apply (auto intro: reachable.intros simp add: extend_act_def image_iff)
done
lemma (in Extend) h_reachable_extend:
"h(s,y) \<in> reachable (extend h F) ==> s \<in> reachable F"
by (force dest!: reachable_extend_f)
lemma (in Extend) reachable_extend_eq:
"reachable (extend h F) = extend_set h (reachable F)"
apply (unfold extend_set_def)
apply (rule equalityI)
apply (force intro: h_f_g_eq [symmetric] dest!: reachable_extend_f, clarify)
apply (erule reachable.induct)
apply (force intro: reachable.intros)+
done
lemma (in Extend) extend_Constrains:
"(extend h F \<in> (extend_set h A) Co (extend_set h B)) =
(F \<in> A Co B)"
by (simp add: Constrains_def reachable_extend_eq extend_constrains
extend_set_Int_distrib [symmetric])
lemma (in Extend) extend_Stable:
"(extend h F \<in> Stable (extend_set h A)) = (F \<in> Stable A)"
by (simp add: Stable_def extend_Constrains)
lemma (in Extend) extend_Always:
"(extend h F \<in> Always (extend_set h A)) = (F \<in> Always A)"
by (simp (no_asm_simp) add: Always_def extend_Stable)
(** Safety and "project" **)
(** projection: monotonicity for safety **)
lemma project_act_mono:
"D \<subseteq> C ==>
project_act h (Restrict D act) \<subseteq> project_act h (Restrict C act)"
by (auto simp add: project_act_def)
lemma (in Extend) project_constrains_mono:
"[| D \<subseteq> C; project h C F \<in> A co B |] ==> project h D F \<in> A co B"
apply (auto simp add: constrains_def)
apply (drule project_act_mono, blast)
done
lemma (in Extend) project_stable_mono:
"[| D \<subseteq> C; project h C F \<in> stable A |] ==> project h D F \<in> stable A"
by (simp add: stable_def project_constrains_mono)
(*Key lemma used in several proofs about project and co*)
lemma (in Extend) project_constrains:
"(project h C F \<in> A co B) =
(F \<in> (C \<inter> extend_set h A) co (extend_set h B) & A \<subseteq> B)"
apply (unfold constrains_def)
apply (auto intro!: project_act_I simp add: ball_Un)
apply (force intro!: project_act_I dest!: subsetD)
(*the <== direction*)
apply (unfold project_act_def)
apply (force dest!: subsetD)
done
lemma (in Extend) project_stable:
"(project h UNIV F \<in> stable A) = (F \<in> stable (extend_set h A))"
apply (unfold stable_def)
apply (simp (no_asm) add: project_constrains)
done
lemma (in Extend) project_stable_I:
"F \<in> stable (extend_set h A) ==> project h C F \<in> stable A"
apply (drule project_stable [THEN iffD2])
apply (blast intro: project_stable_mono)
done
lemma (in Extend) Int_extend_set_lemma:
"A \<inter> extend_set h ((project_set h A) \<inter> B) = A \<inter> extend_set h B"
by (auto simp add: split_extended_all)
(*Strange (look at occurrences of C) but used in leadsETo proofs*)
lemma project_constrains_project_set:
"G \<in> C co B ==> project h C G \<in> project_set h C co project_set h B"
by (simp add: constrains_def project_def project_act_def, blast)
lemma project_stable_project_set:
"G \<in> stable C ==> project h C G \<in> stable (project_set h C)"
by (simp add: stable_def project_constrains_project_set)
subsection{*Progress: transient, ensures*}
lemma (in Extend) extend_transient:
"(extend h F \<in> transient (extend_set h A)) = (F \<in> transient A)"
by (auto simp add: transient_def extend_set_subset_Compl_eq Domain_extend_act)
lemma (in Extend) extend_ensures:
"(extend h F \<in> (extend_set h A) ensures (extend_set h B)) =
(F \<in> A ensures B)"
by (simp add: ensures_def extend_constrains extend_transient
extend_set_Un_distrib [symmetric] extend_set_Diff_distrib [symmetric])
lemma (in Extend) leadsTo_imp_extend_leadsTo:
"F \<in> A leadsTo B
==> extend h F \<in> (extend_set h A) leadsTo (extend_set h B)"
apply (erule leadsTo_induct)
apply (simp add: leadsTo_Basis extend_ensures)
apply (blast intro: leadsTo_Trans)
apply (simp add: leadsTo_UN extend_set_Union)
done
subsection{*Proving the converse takes some doing!*}
lemma (in Extend) slice_iff [iff]: "(x \<in> slice C y) = (h(x,y) \<in> C)"
by (simp (no_asm) add: slice_def)
lemma (in Extend) slice_Union: "slice (Union S) y = (\<Union>x \<in> S. slice x y)"
by auto
lemma (in Extend) slice_extend_set: "slice (extend_set h A) y = A"
by auto
lemma (in Extend) project_set_is_UN_slice:
"project_set h A = (\<Union>y. slice A y)"
by auto
lemma (in Extend) extend_transient_slice:
"extend h F \<in> transient A ==> F \<in> transient (slice A y)"
by (unfold transient_def, auto)
(*Converse?*)
lemma (in Extend) extend_constrains_slice:
"extend h F \<in> A co B ==> F \<in> (slice A y) co (slice B y)"
by (auto simp add: constrains_def)
lemma (in Extend) extend_ensures_slice:
"extend h F \<in> A ensures B ==> F \<in> (slice A y) ensures (project_set h B)"
apply (auto simp add: ensures_def extend_constrains extend_transient)
apply (erule_tac [2] extend_transient_slice [THEN transient_strengthen])
apply (erule extend_constrains_slice [THEN constrains_weaken], auto)
done
lemma (in Extend) leadsTo_slice_project_set:
"\<forall>y. F \<in> (slice B y) leadsTo CU ==> F \<in> (project_set h B) leadsTo CU"
apply (simp (no_asm) add: project_set_is_UN_slice)
apply (blast intro: leadsTo_UN)
done
lemma (in Extend) extend_leadsTo_slice [rule_format]:
"extend h F \<in> AU leadsTo BU
==> \<forall>y. F \<in> (slice AU y) leadsTo (project_set h BU)"
apply (erule leadsTo_induct)
apply (blast intro: extend_ensures_slice leadsTo_Basis)
apply (blast intro: leadsTo_slice_project_set leadsTo_Trans)
apply (simp add: leadsTo_UN slice_Union)
done
lemma (in Extend) extend_leadsTo:
"(extend h F \<in> (extend_set h A) leadsTo (extend_set h B)) =
(F \<in> A leadsTo B)"
apply safe
apply (erule_tac [2] leadsTo_imp_extend_leadsTo)
apply (drule extend_leadsTo_slice)
apply (simp add: slice_extend_set)
done
lemma (in Extend) extend_LeadsTo:
"(extend h F \<in> (extend_set h A) LeadsTo (extend_set h B)) =
(F \<in> A LeadsTo B)"
by (simp add: LeadsTo_def reachable_extend_eq extend_leadsTo
extend_set_Int_distrib [symmetric])
subsection{*preserves*}
lemma (in Extend) project_preserves_I:
"G \<in> preserves (v o f) ==> project h C G \<in> preserves v"
by (auto simp add: preserves_def project_stable_I extend_set_eq_Collect)
(*to preserve f is to preserve the whole original state*)
lemma (in Extend) project_preserves_id_I:
"G \<in> preserves f ==> project h C G \<in> preserves id"
by (simp add: project_preserves_I)
lemma (in Extend) extend_preserves:
"(extend h G \<in> preserves (v o f)) = (G \<in> preserves v)"
by (auto simp add: preserves_def extend_stable [symmetric]
extend_set_eq_Collect)
lemma (in Extend) inj_extend_preserves: "inj h ==> (extend h G \<in> preserves g)"
by (auto simp add: preserves_def extend_def extend_act_def stable_def
constrains_def g_def)
subsection{*Guarantees*}
lemma (in Extend) project_extend_Join:
"project h UNIV ((extend h F)\<squnion>G) = F\<squnion>(project h UNIV G)"
apply (rule program_equalityI)
apply (simp add: project_set_extend_set_Int)
apply (simp add: image_eq_UN UN_Un, auto)
done
lemma (in Extend) extend_Join_eq_extend_D:
"(extend h F)\<squnion>G = extend h H ==> H = F\<squnion>(project h UNIV G)"
apply (drule_tac f = "project h UNIV" in arg_cong)
apply (simp add: project_extend_Join)
done
(** Strong precondition and postcondition; only useful when
the old and new state sets are in bijection **)
lemma (in Extend) ok_extend_imp_ok_project:
"extend h F ok G ==> F ok project h UNIV G"
apply (auto simp add: ok_def)
apply (drule subsetD)
apply (auto intro!: rev_image_eqI)
done
lemma (in Extend) ok_extend_iff: "(extend h F ok extend h G) = (F ok G)"
apply (simp add: ok_def, safe)
apply (force+)
done
lemma (in Extend) OK_extend_iff: "OK I (%i. extend h (F i)) = (OK I F)"
apply (unfold OK_def, safe)
apply (drule_tac x = i in bspec)
apply (drule_tac [2] x = j in bspec)
apply (force+)
done
lemma (in Extend) guarantees_imp_extend_guarantees:
"F \<in> X guarantees Y ==>
extend h F \<in> (extend h ` X) guarantees (extend h ` Y)"
apply (rule guaranteesI, clarify)
apply (blast dest: ok_extend_imp_ok_project extend_Join_eq_extend_D
guaranteesD)
done
lemma (in Extend) extend_guarantees_imp_guarantees:
"extend h F \<in> (extend h ` X) guarantees (extend h ` Y)
==> F \<in> X guarantees Y"
apply (auto simp add: guar_def)
apply (drule_tac x = "extend h G" in spec)
apply (simp del: extend_Join
add: extend_Join [symmetric] ok_extend_iff
inj_extend [THEN inj_image_mem_iff])
done
lemma (in Extend) extend_guarantees_eq:
"(extend h F \<in> (extend h ` X) guarantees (extend h ` Y)) =
(F \<in> X guarantees Y)"
by (blast intro: guarantees_imp_extend_guarantees
extend_guarantees_imp_guarantees)
end