(* Title: HOL/IOA/NTP/Impl.thy
ID: $Id$
Author: Tobias Nipkow & Konrad Slind
*)
header {* The implementation *}
theory Impl
imports Sender Receiver Abschannel
begin
types 'm impl_state
= "'m sender_state * 'm receiver_state * 'm packet multiset * bool multiset"
(* sender_state * receiver_state * srch_state * rsch_state *)
consts
impl_ioa :: "('m action, 'm impl_state)ioa"
sen :: "'m impl_state => 'm sender_state"
rec :: "'m impl_state => 'm receiver_state"
srch :: "'m impl_state => 'm packet multiset"
rsch :: "'m impl_state => bool multiset"
inv1 :: "'m impl_state => bool"
inv2 :: "'m impl_state => bool"
inv3 :: "'m impl_state => bool"
inv4 :: "'m impl_state => bool"
hdr_sum :: "'m packet multiset => bool => nat"
defs
impl_def:
"impl_ioa == (sender_ioa || receiver_ioa || srch_ioa || rsch_ioa)"
sen_def: "sen == fst"
rec_def: "rec == fst o snd"
srch_def: "srch == fst o snd o snd"
rsch_def: "rsch == snd o snd o snd"
hdr_sum_def:
"hdr_sum M b == countm M (%pkt. hdr(pkt) = b)"
(* Lemma 5.1 *)
inv1_def:
"inv1(s) ==
(!b. count (rsent(rec s)) b = count (srcvd(sen s)) b + count (rsch s) b)
& (!b. count (ssent(sen s)) b
= hdr_sum (rrcvd(rec s)) b + hdr_sum (srch s) b)"
(* Lemma 5.2 *)
inv2_def: "inv2(s) ==
(rbit(rec(s)) = sbit(sen(s)) &
ssending(sen(s)) &
count (rsent(rec s)) (~sbit(sen s)) <= count (ssent(sen s)) (~sbit(sen s)) &
count (ssent(sen s)) (~sbit(sen s)) <= count (rsent(rec s)) (sbit(sen s)))
|
(rbit(rec(s)) = (~sbit(sen(s))) &
rsending(rec(s)) &
count (ssent(sen s)) (~sbit(sen s)) <= count (rsent(rec s)) (sbit(sen s)) &
count (rsent(rec s)) (sbit(sen s)) <= count (ssent(sen s)) (sbit(sen s)))"
(* Lemma 5.3 *)
inv3_def: "inv3(s) ==
rbit(rec(s)) = sbit(sen(s))
--> (!m. sq(sen(s))=[] | m ~= hd(sq(sen(s)))
--> count (rrcvd(rec s)) (sbit(sen(s)),m)
+ count (srch s) (sbit(sen(s)),m)
<= count (rsent(rec s)) (~sbit(sen s)))"
(* Lemma 5.4 *)
inv4_def: "inv4(s) == rbit(rec(s)) = (~sbit(sen(s))) --> sq(sen(s)) ~= []"
subsection {* Invariants *}
declare Let_def [simp] le_SucI [simp]
lemmas impl_ioas =
impl_def sender_ioa_def receiver_ioa_def srch_ioa_thm [THEN eq_reflection]
rsch_ioa_thm [THEN eq_reflection]
lemmas "transitions" =
sender_trans_def receiver_trans_def srch_trans_def rsch_trans_def
lemmas [simp] =
ioa_triple_proj starts_of_par trans_of_par4 in_sender_asig
in_receiver_asig in_srch_asig in_rsch_asig
declare let_weak_cong [cong]
lemma [simp]:
"fst(x) = sen(x)"
"fst(snd(x)) = rec(x)"
"fst(snd(snd(x))) = srch(x)"
"snd(snd(snd(x))) = rsch(x)"
by (simp_all add: sen_def rec_def srch_def rsch_def)
lemma [simp]:
"a:actions(sender_asig)
| a:actions(receiver_asig)
| a:actions(srch_asig)
| a:actions(rsch_asig)"
by (induct a) simp_all
declare split_paired_All [simp del]
(* Three Simp_sets in different sizes
----------------------------------------------
1) simpset() does not unfold the transition relations
2) ss unfolds transition relations
3) renname_ss unfolds transitions and the abstract channel *)
ML {*
val ss = @{simpset} addsimps @{thms transitions};
val rename_ss = ss addsimps @{thms unfold_renaming};
val tac = asm_simp_tac (ss addcongs [@{thm conj_cong}] addsplits [@{thm split_if}])
val tac_ren = asm_simp_tac (rename_ss addcongs [@{thm conj_cong}] addsplits [@{thm split_if}])
*}
subsubsection {* Invariant 1 *}
lemma raw_inv1: "invariant impl_ioa inv1"
apply (unfold impl_ioas)
apply (rule invariantI)
apply (simp add: inv1_def hdr_sum_def srcvd_def ssent_def rsent_def rrcvd_def)
apply (simp (no_asm) del: trans_of_par4 add: imp_conjR inv1_def)
txt {* Split proof in two *}
apply (rule conjI)
(* First half *)
apply (simp add: Impl.inv1_def split del: split_if)
apply (induct_tac a)
apply (tactic "EVERY1[tac, tac, tac, tac]")
apply (tactic "tac 1")
apply (tactic "tac_ren 1")
txt {* 5 + 1 *}
apply (tactic "tac 1")
apply (tactic "tac_ren 1")
txt {* 4 + 1 *}
apply (tactic {* EVERY1[tac, tac, tac, tac] *})
txt {* Now the other half *}
apply (simp add: Impl.inv1_def split del: split_if)
apply (induct_tac a)
apply (tactic "EVERY1 [tac, tac]")
txt {* detour 1 *}
apply (tactic "tac 1")
apply (tactic "tac_ren 1")
apply (rule impI)
apply (erule conjE)+
apply (simp (no_asm_simp) add: hdr_sum_def Multiset.count_def Multiset.countm_nonempty_def
split add: split_if)
txt {* detour 2 *}
apply (tactic "tac 1")
apply (tactic "tac_ren 1")
apply (rule impI)
apply (erule conjE)+
apply (simp add: Impl.hdr_sum_def Multiset.count_def Multiset.countm_nonempty_def
Multiset.delm_nonempty_def split add: split_if)
apply (rule allI)
apply (rule conjI)
apply (rule impI)
apply hypsubst
apply (rule pred_suc [THEN iffD1])
apply (drule less_le_trans)
apply (cut_tac eq_packet_imp_eq_hdr [unfolded Packet.hdr_def, THEN countm_props])
apply assumption
apply assumption
apply (rule countm_done_delm [THEN mp, symmetric])
apply (rule refl)
apply (simp (no_asm_simp) add: Multiset.count_def)
apply (rule impI)
apply (simp add: neg_flip)
apply hypsubst
apply (rule countm_spurious_delm)
apply (simp (no_asm))
apply (tactic "EVERY1 [tac, tac, tac, tac, tac, tac]")
done
subsubsection {* INVARIANT 2 *}
lemma raw_inv2: "invariant impl_ioa inv2"
apply (rule invariantI1)
txt {* Base case *}
apply (simp add: inv2_def receiver_projections sender_projections impl_ioas)
apply (simp (no_asm_simp) add: impl_ioas split del: split_if)
apply (induct_tac "a")
txt {* 10 cases. First 4 are simple, since state doesn't change *}
ML {* val tac2 = asm_full_simp_tac (ss addsimps [@{thm inv2_def}]) *}
txt {* 10 - 7 *}
apply (tactic "EVERY1 [tac2,tac2,tac2,tac2]")
txt {* 6 *}
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv1_def}]
(@{thm raw_inv1} RS @{thm invariantE}) RS conjunct1] 1 *})
txt {* 6 - 5 *}
apply (tactic "EVERY1 [tac2,tac2]")
txt {* 4 *}
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv1_def}]
(@{thm raw_inv1} RS @{thm invariantE}) RS conjunct1] 1 *})
apply (tactic "tac2 1")
txt {* 3 *}
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv1_def}]
(@{thm raw_inv1} RS @{thm invariantE})] 1 *})
apply (tactic "tac2 1")
apply (tactic {* fold_tac [rewrite_rule [@{thm Packet.hdr_def}] (@{thm Impl.hdr_sum_def})] *})
apply arith
txt {* 2 *}
apply (tactic "tac2 1")
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv1_def}]
(@{thm raw_inv1} RS @{thm invariantE}) RS conjunct1] 1 *})
apply (intro strip)
apply (erule conjE)+
apply simp
txt {* 1 *}
apply (tactic "tac2 1")
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv1_def}]
(@{thm raw_inv1} RS @{thm invariantE}) RS conjunct2] 1 *})
apply (intro strip)
apply (erule conjE)+
apply (tactic {* fold_tac [rewrite_rule [@{thm Packet.hdr_def}] (@{thm Impl.hdr_sum_def})] *})
apply simp
done
subsubsection {* INVARIANT 3 *}
lemma raw_inv3: "invariant impl_ioa inv3"
apply (rule invariantI)
txt {* Base case *}
apply (simp add: Impl.inv3_def receiver_projections sender_projections impl_ioas)
apply (simp (no_asm_simp) add: impl_ioas split del: split_if)
apply (induct_tac "a")
ML {* val tac3 = asm_full_simp_tac (ss addsimps [@{thm inv3_def}]) *}
txt {* 10 - 8 *}
apply (tactic "EVERY1[tac3,tac3,tac3]")
apply (tactic "tac_ren 1")
apply (intro strip, (erule conjE)+)
apply hypsubst
apply (erule exE)
apply simp
txt {* 7 *}
apply (tactic "tac3 1")
apply (tactic "tac_ren 1")
apply force
txt {* 6 - 3 *}
apply (tactic "EVERY1[tac3,tac3,tac3,tac3]")
txt {* 2 *}
apply (tactic "asm_full_simp_tac ss 1")
apply (simp (no_asm) add: inv3_def)
apply (intro strip, (erule conjE)+)
apply (rule imp_disjL [THEN iffD1])
apply (rule impI)
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv2_def}]
(@{thm raw_inv2} RS @{thm invariantE})] 1 *})
apply simp
apply (erule conjE)+
apply (rule_tac j = "count (ssent (sen s)) (~sbit (sen s))" and
k = "count (rsent (rec s)) (sbit (sen s))" in le_trans)
apply (tactic {* forward_tac [rewrite_rule [@{thm inv1_def}]
(@{thm raw_inv1} RS @{thm invariantE}) RS conjunct2] 1 *})
apply (simp add: hdr_sum_def Multiset.count_def)
apply (rule add_le_mono)
apply (rule countm_props)
apply (simp (no_asm))
apply (rule countm_props)
apply (simp (no_asm))
apply assumption
txt {* 1 *}
apply (tactic "tac3 1")
apply (intro strip, (erule conjE)+)
apply (rule imp_disjL [THEN iffD1])
apply (rule impI)
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv2_def}]
(@{thm raw_inv2} RS @{thm invariantE})] 1 *})
apply simp
done
subsubsection {* INVARIANT 4 *}
lemma raw_inv4: "invariant impl_ioa inv4"
apply (rule invariantI)
txt {* Base case *}
apply (simp add: Impl.inv4_def receiver_projections sender_projections impl_ioas)
apply (simp (no_asm_simp) add: impl_ioas split del: split_if)
apply (induct_tac "a")
ML {* val tac4 = asm_full_simp_tac (ss addsimps [@{thm inv4_def}]) *}
txt {* 10 - 2 *}
apply (tactic "EVERY1[tac4,tac4,tac4,tac4,tac4,tac4,tac4,tac4,tac4]")
txt {* 2 b *}
apply (intro strip, (erule conjE)+)
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv2_def}]
(@{thm raw_inv2} RS @{thm invariantE})] 1 *})
apply simp
txt {* 1 *}
apply (tactic "tac4 1")
apply (intro strip, (erule conjE)+)
apply (rule ccontr)
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv2_def}]
(@{thm raw_inv2} RS @{thm invariantE})] 1 *})
apply (tactic {* forward_tac [rewrite_rule [@{thm Impl.inv3_def}]
(@{thm raw_inv3} RS @{thm invariantE})] 1 *})
apply simp
apply (erule_tac x = "m" in allE)
apply simp
done
text {* rebind them *}
lemmas inv1 = raw_inv1 [THEN invariantE, unfolded inv1_def]
and inv2 = raw_inv2 [THEN invariantE, unfolded inv2_def]
and inv3 = raw_inv3 [THEN invariantE, unfolded inv3_def]
and inv4 = raw_inv4 [THEN invariantE, unfolded inv4_def]
end