Quelle Guard_Shared.thy

Sprache: Isabelle

(*  Title:      HOL/Auth/Guard/Guard_Shared.thy
    Author:     Frederic Blanqui, University of Cambridge Computer Laboratory
    Copyright   2002  University of Cambridge
*)

section‹lemmas on guarded messages for protocols with symmetric keys›

theory Guard_Shared imports Guard GuardK "../Shared" begin

subsection‹Extensions to Theory ‹Shared››

declare initState.simps [simp del]

subsubsection‹a little abbreviation›

abbreviation
  Ciph :: "agent => msg => msg" where
  "Ciph A X == Crypt (shrK A) X"

subsubsection‹agent associated to a key›

definition agt :: "key => agent" where
"agt K == SOME A. K = shrK A"

lemma agt_shrK [simp]: "agt (shrK A) = A"
by (simp add: agt_def)

subsubsection‹basic facts about term‹initState››

lemma no_Crypt_in_parts_init [simp]: "Crypt K X ∉ parts (initState A)"
by (cases A, auto simp: initState.simps)

lemma no_Crypt_in_analz_init [simp]: "Crypt K X ∉ analz (initState A)"
by auto

lemma no_shrK_in_analz_init [simp]: "A ∉ bad
\<Longrightarrow> Key (shrK A) ∉ analz (initState Spy)"
by (auto simp: initState.simps)

lemma shrK_notin_initState_Friend [simp]: "A ≠ Friend C
\<Longrightarrow> Key (shrK A) ∉ parts (initState (Friend C))"
by (auto simp: initState.simps)

lemma keyset_init [iff]: "keyset (initState A)"
by (cases A, auto simp: keyset_def initState.simps)

subsubsection‹sets of symmetric keys›

definition shrK_set :: "key set => bool" where
"shrK_set Ks ≡ ∀K. K ∈ Ks ⟶ (∃A. K = shrK A)"

lemma in_shrK_set: "[shrK_set Ks; K ∈ Ks] ==> ∃A. K = shrK A"
by (simp add: shrK_set_def)

lemma shrK_set1 [iff]: "shrK_set {shrK A}"
by (simp add: shrK_set_def)

lemma shrK_set2 [iff]: "shrK_set {shrK A, shrK B}"
by (simp add: shrK_set_def)

subsubsection‹sets of good keys›

definition good :: "key set ==> bool" where
"good Ks ≡ ∀K. K ∈ Ks ⟶ agt K ∉ bad"

lemma in_good: "[good Ks; K ∈ Ks] ==> agt K ∉ bad"
by (simp add: good_def)

lemma good1 [simp]: "A ∉ bad ==> good {shrK A}"
by (simp add: good_def)

lemma good2 [simp]: "[A ∉ bad; B ∉ bad] ==> good {shrK A, shrK B}"
by (simp add: good_def)

subsection‹Proofs About Guarded Messages›

subsubsection‹small hack›

lemma shrK_is_invKey_shrK: "shrK A = invKey (shrK A)"
by simp

lemmas shrK_is_invKey_shrK_substI = shrK_is_invKey_shrK [THEN ssubst]

lemmas invKey_invKey_substI = invKey [THEN ssubst]

lemma "Nonce n ∈ parts {X} ==> Crypt (shrK A) X ∈ guard n {shrK A}"
apply (rule shrK_is_invKey_shrK_substI, rule invKey_invKey_substI)
by (rule Guard_Nonce, simp+)

subsubsection‹guardedness results on nonces›

lemma guard_ciph [simp]: "shrK A ∈ Ks ==> Ciph A X ∈ guard n Ks"
by (rule Guard_Nonce, simp)

lemma guardK_ciph [simp]: "shrK A ∈ Ks ==> Ciph A X ∈ guardK n Ks"
by (rule Guard_Key, simp)

lemma Guard_init [iff]: "Guard n Ks (initState B)"
by (induct B, auto simp: Guard_def initState.simps)

lemma Guard_knows_max': "Guard n Ks (knows_max' C evs)
\<Longrightarrow> Guard n Ks (knows_max C evs)"
by (simp add: knows_max_def)

lemma Nonce_not_used_Guard_spies [dest]: "Nonce n ∉ used evs
\<Longrightarrow> Guard n Ks (spies evs)"
by (auto simp: Guard_def dest: not_used_not_known parts_sub)

lemma Nonce_not_used_Guard [dest]: "[evs ∈ p; Nonce n ∉ used evs;
Gets_correct p; one_step p] ==> Guard n Ks (knows (Friend C) evs)"
by (auto simp: Guard_def dest: known_used parts_trans)

lemma Nonce_not_used_Guard_max [dest]: "[evs ∈ p; Nonce n ∉ used evs;
Gets_correct p; one_step p] ==> Guard n Ks (knows_max (Friend C) evs)"
by (auto simp: Guard_def dest: known_max_used parts_trans)

lemma Nonce_not_used_Guard_max' [dest]: "[evs ∈ p; Nonce n ∉ used evs;
Gets_correct p; one_step p] ==> Guard n Ks (knows_max' (Friend C) evs)"
apply (rule_tac H="knows_max (Friend C) evs" in Guard_mono)
by (auto simp: knows_max_def)

subsubsection‹guardedness results on keys›

lemma GuardK_init [simp]: "n ∉ range shrK ==> GuardK n Ks (initState B)"
by (induct B, auto simp: GuardK_def initState.simps)

lemma GuardK_knows_max': "[GuardK n A (knows_max' C evs); n ∉ range shrK]
\<Longrightarrow> GuardK n A (knows_max C evs)"
by (simp add: knows_max_def)

lemma Key_not_used_GuardK_spies [dest]: "Key n ∉ used evs
\<Longrightarrow> GuardK n A (spies evs)"
by (auto simp: GuardK_def dest: not_used_not_known parts_sub)

lemma Key_not_used_GuardK [dest]: "[evs ∈ p; Key n ∉ used evs;
Gets_correct p; one_step p] ==> GuardK n A (knows (Friend C) evs)"
by (auto simp: GuardK_def dest: known_used parts_trans)

lemma Key_not_used_GuardK_max [dest]: "[evs ∈ p; Key n ∉ used evs;
Gets_correct p; one_step p] ==> GuardK n A (knows_max (Friend C) evs)"
by (auto simp: GuardK_def dest: known_max_used parts_trans)

lemma Key_not_used_GuardK_max' [dest]: "[evs ∈ p; Key n ∉ used evs;
Gets_correct p; one_step p] ==> GuardK n A (knows_max' (Friend C) evs)"
apply (rule_tac H="knows_max (Friend C) evs" in GuardK_mono)
by (auto simp: knows_max_def)

subsubsection‹regular protocols›

definition regular :: "event list set => bool" where
"regular p ≡ ∀evs A. evs ∈ p ⟶ (Key (shrK A) ∈ parts (spies evs)) = (A ∈ bad)"

lemma shrK_parts_iff_bad [simp]: "[evs ∈ p; regular p] ==>
(Key (shrK A) ∈ parts (spies evs)) = (A ∈ bad)"
by (auto simp: regular_def)

lemma shrK_analz_iff_bad [simp]: "[evs ∈ p; regular p] ==>
(Key (shrK A) ∈ analz (spies evs)) = (A ∈ bad)"
by auto

lemma Guard_Nonce_analz: "[Guard n Ks (spies evs); evs ∈ p;
shrK_set Ks; good Ks; regular p] ==> Nonce n ∉ analz (spies evs)"
apply (clarify, simp only: knows_decomp)
apply (drule Guard_invKey_keyset, simp+, safe)
apply (drule in_good, simp)
apply (drule in_shrK_set, simp+, clarify)
apply (frule_tac A=A in shrK_analz_iff_bad)
by (simp add: knows_decomp)+

lemma GuardK_Key_analz:
  assumes "GuardK n Ks (spies evs)" "evs ∈ p" "shrK_set Ks"
    "good Ks" "regular p" "n ∉ range shrK"
  shows "Key n ∉ analz (spies evs)"
proof (rule ccontr)
  assume "¬ Key n ∉ analz (knows Spy evs)"
  then have *: "Key n ∈ analz (spies' evs ∪ initState Spy)"
    by (simp add: knows_decomp)
  from ‹GuardK n Ks (spies evs)›
  have "GuardK n Ks (spies' evs ∪ initState Spy)"
    by (simp add: knows_decomp)
  then have "GuardK n Ks (spies' evs)"
    and "finite (spies' evs)" "keyset (initState Spy)"
    by simp_all
  moreover have "Key n ∉ initState Spy"
    using ‹n ∉ range shrK› by (simp add: image_iff initState_Spy)
  ultimately obtain K
    where "K ∈ Ks" and **: "Key K ∈ analz (spies' evs ∪ initState Spy)"
    using * by (auto dest: GuardK_invKey_keyset)
  from ‹K ∈ Ks› and ‹good Ks› have "agt K ∉ bad"
    by (auto dest: in_good)
  from ‹K ∈ Ks› ‹shrK_set Ks› obtain A
    where "K = shrK A"
    by (auto dest: in_shrK_set)
  then have "agt K ∈ bad"
    using ** ‹evs ∈ p› ‹regular p› shrK_analz_iff_bad [of evs p "agt K"]
    by (simp add: knows_decomp)
  with ‹agt K ∉ bad› show False by simp
qed

end

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