removed the infernal States, eqStates, compatible, etc.
(* Title: HOL/UNITY/Constrains
ID: $Id$
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1998 University of Cambridge
Safety relations: restricted to the set of reachable states.
*)
(*** Constrains ***)
overload_1st_set "Constrains.Constrains";
(*F : constrains B B'
==> F : constrains (reachable F Int B) (reachable F Int B')*)
bind_thm ("constrains_reachable_Int",
subset_refl RS
rewrite_rule [stable_def] stable_reachable RS
constrains_Int);
Goalw [Constrains_def] "F : constrains A A' ==> F : Constrains A A'";
by (blast_tac (claset() addIs [constrains_reachable_Int]) 1);
qed "constrains_imp_Constrains";
Goalw [stable_def, Stable_def] "F : stable A ==> F : Stable A";
by (etac constrains_imp_Constrains 1);
qed "stable_imp_Stable";
val prems = Goal
"(!!act s s'. [| act: Acts F; (s,s') : act; s: A |] ==> s': A') \
\ ==> F : Constrains A A'";
by (rtac constrains_imp_Constrains 1);
by (blast_tac (claset() addIs (constrainsI::prems)) 1);
qed "ConstrainsI";
Goalw [Constrains_def, constrains_def] "F : Constrains {} B";
by (Blast_tac 1);
qed "Constrains_empty";
Goal "F : Constrains A UNIV";
by (blast_tac (claset() addIs [ConstrainsI]) 1);
qed "Constrains_UNIV";
AddIffs [Constrains_empty, Constrains_UNIV];
Goalw [Constrains_def]
"[| F : Constrains A A'; A'<=B' |] ==> F : Constrains A B'";
by (blast_tac (claset() addIs [constrains_weaken_R]) 1);
qed "Constrains_weaken_R";
Goalw [Constrains_def]
"[| F : Constrains A A'; B<=A |] ==> F : Constrains B A'";
by (blast_tac (claset() addIs [constrains_weaken_L]) 1);
qed "Constrains_weaken_L";
Goalw [Constrains_def]
"[| F : Constrains A A'; B<=A; A'<=B' |] ==> F : Constrains B B'";
by (blast_tac (claset() addIs [constrains_weaken]) 1);
qed "Constrains_weaken";
(** Union **)
Goalw [Constrains_def]
"[| F : Constrains A A'; F : Constrains B B' |] \
\ ==> F : Constrains (A Un B) (A' Un B')";
by (blast_tac (claset() addIs [constrains_Un RS constrains_weaken]) 1);
qed "Constrains_Un";
Goal "ALL i:I. F : Constrains (A i) (A' i) \
\ ==> F : Constrains (UN i:I. A i) (UN i:I. A' i)";
by (asm_full_simp_tac (simpset() addsimps [Constrains_def]) 1);
by (dtac ball_constrains_UN 1);
by (blast_tac (claset() addIs [constrains_weaken]) 1);
qed "ball_Constrains_UN";
(** Intersection **)
Goalw [Constrains_def]
"[| F : Constrains A A'; F : Constrains B B' |] \
\ ==> F : Constrains (A Int B) (A' Int B')";
by (blast_tac (claset() addIs [constrains_Int RS constrains_weaken]) 1);
qed "Constrains_Int";
Goal "ALL i:I. F : Constrains (A i) (A' i) \
\ ==> F : Constrains (INT i:I. A i) (INT i:I. A' i)";
by (asm_full_simp_tac (simpset() addsimps [Constrains_def]) 1);
by (dtac ball_constrains_INT 1);
by (dtac constrains_reachable_Int 1);
by (blast_tac (claset() addIs [constrains_weaken]) 1);
qed "ball_Constrains_INT";
Goal "F : Constrains A A' ==> reachable F Int A <= A'";
by (asm_full_simp_tac (simpset() addsimps [Constrains_def]) 1);
by (dtac constrains_imp_subset 1);
by (ALLGOALS
(full_simp_tac (simpset() addsimps [Int_subset_iff, Int_lower1])));
qed "Constrains_imp_subset";
Goalw [Constrains_def]
"[| F : Constrains A B; F : Constrains B C |] \
\ ==> F : Constrains A C";
by (blast_tac (claset() addIs [constrains_trans, constrains_weaken]) 1);
qed "Constrains_trans";
Goalw [Constrains_def, constrains_def]
"[| F : Constrains A (A' Un B); F : Constrains B B' |] \
\ ==> F : Constrains A (A' Un B')";
by (Clarify_tac 1);
by (Blast_tac 1);
qed "Constrains_cancel";
(*** Stable ***)
Goal "(F : Stable A) = (F : stable (reachable F Int A))";
by (simp_tac (simpset() addsimps [Stable_def, Constrains_def, stable_def]) 1);
qed "Stable_eq_stable";
Goalw [Stable_def] "F : Constrains A A ==> F : Stable A";
by (assume_tac 1);
qed "StableI";
Goalw [Stable_def] "F : Stable A ==> F : Constrains A A";
by (assume_tac 1);
qed "StableD";
Goalw [Stable_def]
"[| F : Stable A; F : Stable A' |] ==> F : Stable (A Un A')";
by (blast_tac (claset() addIs [Constrains_Un]) 1);
qed "Stable_Un";
Goalw [Stable_def]
"[| F : Stable A; F : Stable A' |] ==> F : Stable (A Int A')";
by (blast_tac (claset() addIs [Constrains_Int]) 1);
qed "Stable_Int";
Goalw [Stable_def]
"[| F : Stable C; F : Constrains A (C Un A') |] \
\ ==> F : Constrains (C Un A) (C Un A')";
by (blast_tac (claset() addIs [Constrains_Un RS Constrains_weaken]) 1);
qed "Stable_Constrains_Un";
Goalw [Stable_def]
"[| F : Stable C; F : Constrains (C Int A) A' |] \
\ ==> F : Constrains (C Int A) (C Int A')";
by (blast_tac (claset() addIs [Constrains_Int RS Constrains_weaken]) 1);
qed "Stable_Constrains_Int";
Goalw [Stable_def]
"(ALL i:I. F : Stable (A i)) ==> F : Stable (UN i:I. A i)";
by (etac ball_Constrains_UN 1);
qed "ball_Stable_UN";
Goalw [Stable_def]
"(ALL i:I. F : Stable (A i)) ==> F : Stable (INT i:I. A i)";
by (etac ball_Constrains_INT 1);
qed "ball_Stable_INT";
Goal "F : Stable (reachable F)";
by (simp_tac (simpset() addsimps [Stable_eq_stable, stable_reachable]) 1);
qed "Stable_reachable";
(*** Increasing ***)
Goalw [Increasing_def, Stable_def, Constrains_def, stable_def, constrains_def]
"Increasing f <= Increasing (length o f)";
by Auto_tac;
by (blast_tac (claset() addIs [prefix_length_le, le_trans]) 1);
qed "Increasing_size";
Goalw [Increasing_def]
"Increasing f <= {F. ALL z::nat. F: Stable {s. z < f s}}";
by (simp_tac (simpset() addsimps [Suc_le_eq RS sym]) 1);
by (Blast_tac 1);
qed "Increasing_Stable_less";
Goalw [increasing_def, Increasing_def]
"F : increasing f ==> F : Increasing f";
by (blast_tac (claset() addIs [stable_imp_Stable]) 1);
qed "increasing_imp_Increasing";
(*** The Elimination Theorem. The "free" m has become universally quantified!
Should the premise be !!m instead of ALL m ? Would make it harder to use
in forward proof. ***)
Goalw [Constrains_def, constrains_def]
"[| ALL m. F : Constrains {s. s x = m} (B m) |] \
\ ==> F : Constrains {s. s x : M} (UN m:M. B m)";
by (Blast_tac 1);
qed "Elimination";
(*As above, but for the trivial case of a one-variable state, in which the
state is identified with its one variable.*)
Goalw [Constrains_def, constrains_def]
"(ALL m. F : Constrains {m} (B m)) ==> F : Constrains M (UN m:M. B m)";
by (Blast_tac 1);
qed "Elimination_sing";
(*** Specialized laws for handling Invariants ***)
(** Natural deduction rules for "Invariant F A" **)
Goal "[| Init F<=A; F : Stable A |] ==> F : Invariant A";
by (asm_simp_tac (simpset() addsimps [Invariant_def]) 1);
qed "InvariantI";
Goal "F : Invariant A ==> Init F<=A & F : Stable A";
by (asm_full_simp_tac (simpset() addsimps [Invariant_def]) 1);
qed "InvariantD";
bind_thm ("InvariantE", InvariantD RS conjE);
(*The set of all reachable states is the strongest Invariant*)
Goal "F : Invariant A ==> reachable F <= A";
by (full_simp_tac
(simpset() addsimps [Stable_def, Constrains_def, constrains_def,
Invariant_def]) 1);
by (rtac subsetI 1);
by (etac reachable.induct 1);
by (REPEAT (blast_tac (claset() addIs reachable.intrs) 1));
qed "Invariant_includes_reachable";
Goalw [Invariant_def, invariant_def, Stable_def, Constrains_def, stable_def]
"F : invariant A ==> F : Invariant A";
by (blast_tac (claset() addIs [constrains_reachable_Int]) 1);
qed "invariant_imp_Invariant";
Goalw [Invariant_def, invariant_def, Stable_def, Constrains_def, stable_def]
"Invariant A = {F. F : invariant (reachable F Int A)}";
by (blast_tac (claset() addIs reachable.intrs) 1);
qed "Invariant_eq_invariant_reachable";
(*Invariant is the "always" notion*)
Goal "Invariant A = {F. reachable F <= A}";
by (auto_tac (claset() addDs [invariant_includes_reachable],
simpset() addsimps [Int_absorb2, invariant_reachable,
Invariant_eq_invariant_reachable]));
qed "Invariant_eq_always";
Goal "Invariant A = (UN I: Pow A. invariant I)";
by (simp_tac (simpset() addsimps [Invariant_eq_always]) 1);
by (blast_tac (claset() addIs [invariantI, impOfSubs Init_subset_reachable,
stable_reachable,
impOfSubs invariant_includes_reachable]) 1);
qed "Invariant_eq_UN_invariant";
(*** "Constrains" rules involving Invariant ***)
Goal "[| F : Invariant INV; F : Constrains (INV Int A) A' |] \
\ ==> F : Constrains A A'";
by (asm_full_simp_tac
(simpset() addsimps [Invariant_includes_reachable RS Int_absorb2,
Constrains_def, Int_assoc RS sym]) 1);
qed "Invariant_ConstrainsI";
(* [| F : Invariant INV; F : Constrains (INV Int A) A |]
==> F : Stable A *)
bind_thm ("Invariant_StableI", Invariant_ConstrainsI RS StableI);
Goal "[| F : Invariant INV; F : Constrains A A' |] \
\ ==> F : Constrains A (INV Int A')";
by (asm_full_simp_tac
(simpset() addsimps [Invariant_includes_reachable RS Int_absorb2,
Constrains_def, Int_assoc RS sym]) 1);
qed "Invariant_ConstrainsD";
bind_thm ("Invariant_StableD", StableD RSN (2,Invariant_ConstrainsD));
(** Conjoining Invariants **)
Goal "[| F : Invariant A; F : Invariant B |] ==> F : Invariant (A Int B)";
by (auto_tac (claset(), simpset() addsimps [Invariant_eq_always]));
qed "Invariant_Int";
(*Delete the nearest invariance assumption (which will be the second one
used by Invariant_Int) *)
val Invariant_thin =
read_instantiate_sg (sign_of thy)
[("V", "?F : Invariant ?A")] thin_rl;
(*Combines two invariance ASSUMPTIONS into one. USEFUL??*)
val Invariant_Int_tac = dtac Invariant_Int THEN'
assume_tac THEN'
etac Invariant_thin;
(*Combines a list of invariance THEOREMS into one.*)
val Invariant_Int_rule = foldr1 (fn (th1,th2) => [th1,th2] MRS Invariant_Int);
(*To allow expansion of the program's definition when appropriate*)
val program_defs_ref = ref ([] : thm list);
(*proves "constrains" properties when the program is specified*)
fun constrains_tac i =
SELECT_GOAL
(EVERY [simp_tac (simpset() addsimps !program_defs_ref) 1,
REPEAT (resolve_tac [StableI, stableI,
constrains_imp_Constrains] 1),
rtac constrainsI 1,
Full_simp_tac 1,
REPEAT (FIRSTGOAL (etac disjE)),
ALLGOALS Clarify_tac,
ALLGOALS Asm_full_simp_tac]) i;