Theory Message
section‹Theory of Agents and Messages for Security Protocols›
theory Message
imports Main
begin
lemma [simp] : "A ∪ (B ∪ A) = B ∪ A"
by blast
type_synonym
key = nat
consts
all_symmetric :: bool
invKey :: "key⇒key"
specification (invKey)
invKey [simp]: "invKey (invKey K) = K"
invKey_symmetric: "all_symmetric ⟶ invKey = id"
by (rule exI [of _ id], auto)
text‹The inverse of a symmetric key is itself; that of a public key
is the private key and vice versa›
definition symKeys :: "key set" where
"symKeys == {K. invKey K = K}"
datatype
agent = Server | Friend nat | Spy
datatype
msg = Agent agent
| Number nat
| Nonce nat
| Key key
| Hash msg
| MPair msg msg
| Crypt key msg
text‹Concrete syntax: messages appear as ‹⦃A,B,NA⦄›, etc...›
syntax
"_MTuple" :: "['a, args] ⇒ 'a * 'b" ("(2⦃_,/ _⦄)")
translations
"⦃x, y, z⦄" ⇌ "⦃x, ⦃y, z⦄⦄"
"⦃x, y⦄" ⇌ "CONST MPair x y"
definition HPair :: "[msg,msg] ⇒ msg" ("(4Hash[_] /_)" [0, 1000]) where
"Hash[X] Y == ⦃Hash⦃X,Y⦄, Y⦄"
definition keysFor :: "msg set ⇒ key set" where
"keysFor H == invKey ` {K. ∃X. Crypt K X ∈ H}"
subsubsection‹Inductive Definition of All Parts" of a Message›
inductive_set
parts :: "msg set ⇒ msg set"
for H :: "msg set"
where
Inj [intro]: "X ∈ H ==> X ∈ parts H"
| Fst: "⦃X,Y⦄ ∈ parts H ==> X ∈ parts H"
| Snd: "⦃X,Y⦄ ∈ parts H ==> Y ∈ parts H"
| Body: "Crypt K X ∈ parts H ==> X ∈ parts H"
text‹Monotonicity›
lemma parts_mono: "G ⊆ H ==> parts(G) ⊆ parts(H)"
apply auto
apply (erule parts.induct)
apply (blast dest: parts.Fst parts.Snd parts.Body)+
done
text‹Equations hold because constructors are injective.›
lemma Friend_image_eq [simp]: "(Friend x ∈ Friend`A) = (x∈A)"
by auto
lemma Key_image_eq [simp]: "(Key x ∈ Key`A) = (x∈A)"
by auto
lemma Nonce_Key_image_eq [simp]: "(Nonce x ∉ Key`A)"
by auto
subsubsection‹Inverse of keys›
lemma invKey_eq [simp]: "(invKey K = invKey K') = (K=K')"
by (metis invKey)
subsection‹keysFor operator›
lemma keysFor_empty [simp]: "keysFor {} = {}"
by (unfold keysFor_def, blast)
lemma keysFor_Un [simp]: "keysFor (H ∪ H') = keysFor H ∪ keysFor H'"
by (unfold keysFor_def, blast)
lemma keysFor_UN [simp]: "keysFor (⋃i∈A. H i) = (⋃i∈A. keysFor (H i))"
by (unfold keysFor_def, blast)
text‹Monotonicity›
lemma keysFor_mono: "G ⊆ H ==> keysFor(G) ⊆ keysFor(H)"
by (unfold keysFor_def, blast)
lemma keysFor_insert_Agent [simp]: "keysFor (insert (Agent A) H) = keysFor H"
by (unfold keysFor_def, auto)
lemma keysFor_insert_Nonce [simp]: "keysFor (insert (Nonce N) H) = keysFor H"
by (unfold keysFor_def, auto)
lemma keysFor_insert_Number [simp]: "keysFor (insert (Number N) H) = keysFor H"
by (unfold keysFor_def, auto)
lemma keysFor_insert_Key [simp]: "keysFor (insert (Key K) H) = keysFor H"
by (unfold keysFor_def, auto)
lemma keysFor_insert_Hash [simp]: "keysFor (insert (Hash X) H) = keysFor H"
by (unfold keysFor_def, auto)
lemma keysFor_insert_MPair [simp]: "keysFor (insert ⦃X,Y⦄ H) = keysFor H"
by (unfold keysFor_def, auto)
lemma keysFor_insert_Crypt [simp]:
"keysFor (insert (Crypt K X) H) = insert (invKey K) (keysFor H)"
by (unfold keysFor_def, auto)
lemma keysFor_image_Key [simp]: "keysFor (Key`E) = {}"
by (unfold keysFor_def, auto)
lemma Crypt_imp_invKey_keysFor: "Crypt K X ∈ H ==> invKey K ∈ keysFor H"
by (unfold keysFor_def, blast)
subsection‹Inductive relation "parts"›
lemma MPair_parts:
"[| ⦃X,Y⦄ ∈ parts H;
[| X ∈ parts H; Y ∈ parts H |] ==> P |] ==> P"
by (blast dest: parts.Fst parts.Snd)
declare MPair_parts [elim!] parts.Body [dest!]
text‹NB These two rules are UNSAFE in the formal sense, as they discard the
compound message. They work well on THIS FILE.
‹MPair_parts› is left as SAFE because it speeds up proofs.
The Crypt rule is normally kept UNSAFE to avoid breaking up certificates.›
lemma parts_increasing: "H ⊆ parts(H)"
by blast
lemmas parts_insertI = subset_insertI [THEN parts_mono, THEN subsetD]
lemma parts_empty [simp]: "parts{} = {}"
apply safe
apply (erule parts.induct, blast+)
done
lemma parts_emptyE [elim!]: "X∈ parts{} ==> P"
by simp
text‹WARNING: loops if H = {Y}, therefore must not be repeated!›
lemma parts_singleton: "X∈ parts H ==> ∃Y∈H. X∈ parts {Y}"
by (erule parts.induct, fast+)
subsubsection‹Unions›
lemma parts_Un_subset1: "parts(G) ∪ parts(H) ⊆ parts(G ∪ H)"
by (intro Un_least parts_mono Un_upper1 Un_upper2)
lemma parts_Un_subset2: "parts(G ∪ H) ⊆ parts(G) ∪ parts(H)"
apply (rule subsetI)
apply (erule parts.induct, blast+)
done
lemma parts_Un [simp]: "parts(G ∪ H) = parts(G) ∪ parts(H)"
by (intro equalityI parts_Un_subset1 parts_Un_subset2)
lemma parts_insert: "parts (insert X H) = parts {X} ∪ parts H"
by (metis insert_is_Un parts_Un)
text‹TWO inserts to avoid looping. This rewrite is better than nothing.
But its behaviour can be strange.›
lemma parts_insert2:
"parts (insert X (insert Y H)) = parts {X} ∪ parts {Y} ∪ parts H"
by (metis Un_commute Un_empty_right Un_insert_right insert_is_Un parts_Un)
lemma parts_UN_subset1: "(⋃x∈A. parts(H x)) ⊆ parts(⋃x∈A. H x)"
by (intro UN_least parts_mono UN_upper)
lemma parts_UN_subset2: "parts(⋃x∈A. H x) ⊆ (⋃x∈A. parts(H x))"
apply (rule subsetI)
apply (erule parts.induct, blast+)
done
lemma parts_UN [simp]:
"parts (⋃x∈A. H x) = (⋃x∈A. parts (H x))"
by (intro equalityI parts_UN_subset1 parts_UN_subset2)
lemma parts_image [simp]:
"parts (f ` A) = (⋃x∈A. parts {f x})"
apply auto
apply (metis (mono_tags, hide_lams) image_iff parts_singleton)
apply (metis empty_subsetI image_eqI insert_absorb insert_subset parts_mono)
done
text‹Added to simplify arguments to parts, analz and synth.
NOTE: the UN versions are no longer used!›
text‹This allows ‹blast› to simplify occurrences of
\<^term>‹parts(G∪H)› in the assumption.›
lemmas in_parts_UnE = parts_Un [THEN equalityD1, THEN subsetD, THEN UnE]
declare in_parts_UnE [elim!]
lemma parts_insert_subset: "insert X (parts H) ⊆ parts(insert X H)"
by (blast intro: parts_mono [THEN [2] rev_subsetD])
subsubsection‹Idempotence and transitivity›
lemma parts_partsD [dest!]: "X∈ parts (parts H) ==> X∈ parts H"
by (erule parts.induct, blast+)
lemma parts_idem [simp]: "parts (parts H) = parts H"
by blast
lemma parts_subset_iff [simp]: "(parts G ⊆ parts H) = (G ⊆ parts H)"
by (metis parts_idem parts_increasing parts_mono subset_trans)
lemma parts_trans: "[| X∈ parts G; G ⊆ parts H |] ==> X∈ parts H"
by (metis parts_subset_iff subsetD)
text‹Cut›
lemma parts_cut:
"[| Y∈ parts (insert X G); X∈ parts H |] ==> Y∈ parts (G ∪ H)"
by (blast intro: parts_trans)
lemma parts_cut_eq [simp]: "X∈ parts H ==> parts (insert X H) = parts H"
by (metis insert_absorb parts_idem parts_insert)
subsubsection‹Rewrite rules for pulling out atomic messages›
lemmas parts_insert_eq_I = equalityI [OF subsetI parts_insert_subset]
lemma parts_insert_Agent [simp]:
"parts (insert (Agent agt) H) = insert (Agent agt) (parts H)"
apply (rule parts_insert_eq_I)
apply (erule parts.induct, auto)
done
lemma parts_insert_Nonce [simp]:
"parts (insert (Nonce N) H) = insert (Nonce N) (parts H)"
apply (rule parts_insert_eq_I)
apply (erule parts.induct, auto)
done
lemma parts_insert_Number [simp]:
"parts (insert (Number N) H) = insert (Number N) (parts H)"
apply (rule parts_insert_eq_I)
apply (erule parts.induct, auto)
done
lemma parts_insert_Key [simp]:
"parts (insert (Key K) H) = insert (Key K) (parts H)"
apply (rule parts_insert_eq_I)
apply (erule parts.induct, auto)
done
lemma parts_insert_Hash [simp]:
"parts (insert (Hash X) H) = insert (Hash X) (parts H)"
apply (rule parts_insert_eq_I)
apply (erule parts.induct, auto)
done
lemma parts_insert_Crypt [simp]:
"parts (insert (Crypt K X) H) = insert (Crypt K X) (parts (insert X H))"
apply (rule equalityI)
apply (rule subsetI)
apply (erule parts.induct, auto)
apply (blast intro: parts.Body)
done
lemma parts_insert_MPair [simp]:
"parts (insert ⦃X,Y⦄ H) =
insert ⦃X,Y⦄ (parts (insert X (insert Y H)))"
apply (rule equalityI)
apply (rule subsetI)
apply (erule parts.induct, auto)
apply (blast intro: parts.Fst parts.Snd)+
done
lemma parts_image_Key [simp]: "parts (Key`N) = Key`N"
by auto
text‹In any message, there is an upper bound N on its greatest nonce.›
lemma msg_Nonce_supply: "∃N. ∀n. N≤n ⟶ Nonce n ∉ parts {msg}"
proof (induct msg)
case (Nonce n)
show ?case
by simp (metis Suc_n_not_le_n)
next
case (MPair X Y)
then show ?case
by (simp add: parts_insert2) (metis le_trans nat_le_linear)
qed auto
subsection‹Inductive relation "analz"›
text‹Inductive definition of "analz" -- what can be broken down from a set of
messages, including keys. A form of downward closure. Pairs can
be taken apart; messages decrypted with known keys.›
inductive_set
analz :: "msg set ⇒ msg set"
for H :: "msg set"
where
Inj [intro,simp]: "X ∈ H ==> X ∈ analz H"
| Fst: "⦃X,Y⦄ ∈ analz H ==> X ∈ analz H"
| Snd: "⦃X,Y⦄ ∈ analz H ==> Y ∈ analz H"
| Decrypt [dest]:
"⟦Crypt K X ∈ analz H; Key(invKey K) ∈ analz H⟧ ⟹ X ∈ analz H"
text‹Monotonicity; Lemma 1 of Lowe's paper›
lemma analz_mono: "G⊆H ==> analz(G) ⊆ analz(H)"
apply auto
apply (erule analz.induct)
apply (auto dest: analz.Fst analz.Snd)
done
text‹Making it safe speeds up proofs›
lemma MPair_analz [elim!]:
"[| ⦃X,Y⦄ ∈ analz H;
[| X ∈ analz H; Y ∈ analz H |] ==> P
|] ==> P"
by (blast dest: analz.Fst analz.Snd)
lemma analz_increasing: "H ⊆ analz(H)"
by blast
lemma analz_subset_parts: "analz H ⊆ parts H"
apply (rule subsetI)
apply (erule analz.induct, blast+)
done
lemmas analz_into_parts = analz_subset_parts [THEN subsetD]
lemmas not_parts_not_analz = analz_subset_parts [THEN contra_subsetD]
lemma parts_analz [simp]: "parts (analz H) = parts H"
by (metis analz_increasing analz_subset_parts equalityI parts_mono parts_subset_iff)
lemma analz_parts [simp]: "analz (parts H) = parts H"
apply auto
apply (erule analz.induct, auto)
done
lemmas analz_insertI = subset_insertI [THEN analz_mono, THEN [2] rev_subsetD]
subsubsection‹General equational properties›
lemma analz_empty [simp]: "analz{} = {}"
apply safe
apply (erule analz.induct, blast+)
done
text‹Converse fails: we can analz more from the union than from the
separate parts, as a key in one might decrypt a message in the other›
lemma analz_Un: "analz(G) ∪ analz(H) ⊆ analz(G ∪ H)"
by (intro Un_least analz_mono Un_upper1 Un_upper2)
lemma analz_insert: "insert X (analz H) ⊆ analz(insert X H)"
by (blast intro: analz_mono [THEN [2] rev_subsetD])
subsubsection‹Rewrite rules for pulling out atomic messages›
lemmas analz_insert_eq_I = equalityI [OF subsetI analz_insert]
lemma analz_insert_Agent [simp]:
"analz (insert (Agent agt) H) = insert (Agent agt) (analz H)"
apply (rule analz_insert_eq_I)
apply (erule analz.induct, auto)
done
lemma analz_insert_Nonce [simp]:
"analz (insert (Nonce N) H) = insert (Nonce N) (analz H)"
apply (rule analz_insert_eq_I)
apply (erule analz.induct, auto)
done
lemma analz_insert_Number [simp]:
"analz (insert (Number N) H) = insert (Number N) (analz H)"
apply (rule analz_insert_eq_I)
apply (erule analz.induct, auto)
done
lemma analz_insert_Hash [simp]:
"analz (insert (Hash X) H) = insert (Hash X) (analz H)"
apply (rule analz_insert_eq_I)
apply (erule analz.induct, auto)
done
text‹Can only pull out Keys if they are not needed to decrypt the rest›
lemma analz_insert_Key [simp]:
"K ∉ keysFor (analz H) ==>
analz (insert (Key K) H) = insert (Key K) (analz H)"
apply (unfold keysFor_def)
apply (rule analz_insert_eq_I)
apply (erule analz.induct, auto)
done
lemma analz_insert_MPair [simp]:
"analz (insert ⦃X,Y⦄ H) =
insert ⦃X,Y⦄ (analz (insert X (insert Y H)))"
apply (rule equalityI)
apply (rule subsetI)
apply (erule analz.induct, auto)
apply (erule analz.induct)
apply (blast intro: analz.Fst analz.Snd)+
done
text‹Can pull out enCrypted message if the Key is not known›
lemma analz_insert_Crypt:
"Key (invKey K) ∉ analz H
==> analz (insert (Crypt K X) H) = insert (Crypt K X) (analz H)"
apply (rule analz_insert_eq_I)
apply (erule analz.induct, auto)
done
lemma lemma1: "Key (invKey K) ∈ analz H ==>
analz (insert (Crypt K X) H) ⊆
insert (Crypt K X) (analz (insert X H))"
apply (rule subsetI)
apply (erule_tac x = x in analz.induct, auto)
done
lemma lemma2: "Key (invKey K) ∈ analz H ==>
insert (Crypt K X) (analz (insert X H)) ⊆
analz (insert (Crypt K X) H)"
apply auto
apply (erule_tac x = x in analz.induct, auto)
apply (blast intro: analz_insertI analz.Decrypt)
done
lemma analz_insert_Decrypt:
"Key (invKey K) ∈ analz H ==>
analz (insert (Crypt K X) H) =
insert (Crypt K X) (analz (insert X H))"
by (intro equalityI lemma1 lemma2)
text‹Case analysis: either the message is secure, or it is not! Effective,
but can cause subgoals to blow up! Use with ‹if_split›; apparently
‹split_tac› does not cope with patterns such as \<^term>‹analz (insert
(Crypt K X) H)››
lemma analz_Crypt_if [simp]:
"analz (insert (Crypt K X) H) =
(if (Key (invKey K) ∈ analz H)
then insert (Crypt K X) (analz (insert X H))
else insert (Crypt K X) (analz H))"
by (simp add: analz_insert_Crypt analz_insert_Decrypt)
text‹This rule supposes "for the sake of argument" that we have the key.›
lemma analz_insert_Crypt_subset:
"analz (insert (Crypt K X) H) ⊆
insert (Crypt K X) (analz (insert X H))"
apply (rule subsetI)
apply (erule analz.induct, auto)
done
lemma analz_image_Key [simp]: "analz (Key`N) = Key`N"
apply auto
apply (erule analz.induct, auto)
done
subsubsection‹Idempotence and transitivity›
lemma analz_analzD [dest!]: "X∈ analz (analz H) ==> X∈ analz H"
by (erule analz.induct, blast+)
lemma analz_idem [simp]: "analz (analz H) = analz H"
by blast
lemma analz_subset_iff [simp]: "(analz G ⊆ analz H) = (G ⊆ analz H)"
by (metis analz_idem analz_increasing analz_mono subset_trans)
lemma analz_trans: "[| X∈ analz G; G ⊆ analz H |] ==> X∈ analz H"
by (drule analz_mono, blast)
text‹Cut; Lemma 2 of Lowe›
lemma analz_cut: "[| Y∈ analz (insert X H); X∈ analz H |] ==> Y∈ analz H"
by (erule analz_trans, blast)
text‹This rewrite rule helps in the simplification of messages that involve
the forwarding of unknown components (X). Without it, removing occurrences
of X can be very complicated.›
lemma analz_insert_eq: "X∈ analz H ==> analz (insert X H) = analz H"
by (metis analz_cut analz_insert_eq_I insert_absorb)
text‹A congruence rule for "analz"›
lemma analz_subset_cong:
"[| analz G ⊆ analz G'; analz H ⊆ analz H' |]
==> analz (G ∪ H) ⊆ analz (G' ∪ H')"
by (metis Un_mono analz_Un analz_subset_iff subset_trans)
lemma analz_cong:
"[| analz G = analz G'; analz H = analz H' |]
==> analz (G ∪ H) = analz (G' ∪ H')"
by (intro equalityI analz_subset_cong, simp_all)
lemma analz_insert_cong:
"analz H = analz H' ==> analz(insert X H) = analz(insert X H')"
by (force simp only: insert_def intro!: analz_cong)
text‹If there are no pairs or encryptions then analz does nothing›
lemma analz_trivial:
"[| ∀X Y. ⦃X,Y⦄ ∉ H; ∀X K. Crypt K X ∉ H |] ==> analz H = H"
apply safe
apply (erule analz.induct, blast+)
done
text‹These two are obsolete (with a single Spy) but cost little to prove...›
lemma analz_UN_analz_lemma:
"X∈ analz (⋃i∈A. analz (H i)) ==> X∈ analz (⋃i∈A. H i)"
apply (erule analz.induct)
apply (blast intro: analz_mono [THEN [2] rev_subsetD])+
done
lemma analz_UN_analz [simp]: "analz (⋃i∈A. analz (H i)) = analz (⋃i∈A. H i)"
by (blast intro: analz_UN_analz_lemma analz_mono [THEN [2] rev_subsetD])
subsection‹Inductive relation "synth"›
text‹Inductive definition of "synth" -- what can be built up from a set of
messages. A form of upward closure. Pairs can be built, messages
encrypted with known keys. Agent names are public domain.
Numbers can be guessed, but Nonces cannot be.›
inductive_set
synth :: "msg set => msg set"
for H :: "msg set"
where
Inj [intro]: "X ∈ H ==> X ∈ synth H"
| Agent [intro]: "Agent agt ∈ synth H"
| Number [intro]: "Number n ∈ synth H"
| Hash [intro]: "X ∈ synth H ==> Hash X ∈ synth H"
| MPair [intro]: "[|X ∈ synth H; Y ∈ synth H|] ==> ⦃X,Y⦄ ∈ synth H"
| Crypt [intro]: "[|X ∈ synth H; Key(K) ∈ H|] ==> Crypt K X ∈ synth H"
text‹Monotonicity›
lemma synth_mono: "G⊆H ==> synth(G) ⊆ synth(H)"
by (auto, erule synth.induct, auto)
text‹NO ‹Agent_synth›, as any Agent name can be synthesized.
The same holds for \<^term>‹Number››
inductive_simps synth_simps [iff]:
"Nonce n ∈ synth H"
"Key K ∈ synth H"
"Hash X ∈ synth H"
"⦃X,Y⦄ ∈ synth H"
"Crypt K X ∈ synth H"
lemma synth_increasing: "H ⊆ synth(H)"
by blast
subsubsection‹Unions›
text‹Converse fails: we can synth more from the union than from the
separate parts, building a compound message using elements of each.›
lemma synth_Un: "synth(G) ∪ synth(H) ⊆ synth(G ∪ H)"
by (intro Un_least synth_mono Un_upper1 Un_upper2)
lemma synth_insert: "insert X (synth H) ⊆ synth(insert X H)"
by (blast intro: synth_mono [THEN [2] rev_subsetD])
subsubsection‹Idempotence and transitivity›
lemma synth_synthD [dest!]: "X∈ synth (synth H) ==> X∈ synth H"
by (erule synth.induct, auto)
lemma synth_idem: "synth (synth H) = synth H"
by blast
lemma synth_subset_iff [simp]: "(synth G ⊆ synth H) = (G ⊆ synth H)"
by (metis subset_trans synth_idem synth_increasing synth_mono)
lemma synth_trans: "[| X∈ synth G; G ⊆ synth H |] ==> X∈ synth H"
by (drule synth_mono, blast)
text‹Cut; Lemma 2 of Lowe›
lemma synth_cut: "[| Y∈ synth (insert X H); X∈ synth H |] ==> Y∈ synth H"
by (erule synth_trans, blast)
lemma Crypt_synth_eq [simp]:
"Key K ∉ H ==> (Crypt K X ∈ synth H) = (Crypt K X ∈ H)"
by blast
lemma keysFor_synth [simp]:
"keysFor (synth H) = keysFor H ∪ invKey`{K. Key K ∈ H}"
by (unfold keysFor_def, blast)
subsubsection‹Combinations of parts, analz and synth›
lemma parts_synth [simp]: "parts (synth H) = parts H ∪ synth H"
apply (rule equalityI)
apply (rule subsetI)
apply (erule parts.induct)
apply (blast intro: synth_increasing [THEN parts_mono, THEN subsetD]
parts.Fst parts.Snd parts.Body)+
done
lemma analz_analz_Un [simp]: "analz (analz G ∪ H) = analz (G ∪ H)"
apply (intro equalityI analz_subset_cong)+
apply simp_all
done
lemma analz_synth_Un [simp]: "analz (synth G ∪ H) = analz (G ∪ H) ∪ synth G"
apply (rule equalityI)
apply (rule subsetI)
apply (erule analz.induct)
prefer 5 apply (blast intro: analz_mono [THEN [2] rev_subsetD])
apply (blast intro: analz.Fst analz.Snd analz.Decrypt)+
done
lemma analz_synth [simp]: "analz (synth H) = analz H ∪ synth H"
by (metis Un_empty_right analz_synth_Un)
subsubsection‹For reasoning about the Fake rule in traces›
lemma parts_insert_subset_Un: "X∈ G ==> parts(insert X H) ⊆ parts G ∪ parts H"
by (metis UnCI Un_upper2 insert_subset parts_Un parts_mono)
text‹More specifically for Fake. See also ‹Fake_parts_sing› below›
lemma Fake_parts_insert:
"X ∈ synth (analz H) ==>
parts (insert X H) ⊆ synth (analz H) ∪ parts H"
by (metis Un_commute analz_increasing insert_subset parts_analz parts_mono
parts_synth synth_mono synth_subset_iff)
lemma Fake_parts_insert_in_Un:
"⟦Z ∈ parts (insert X H); X ∈ synth (analz H)⟧
⟹ Z ∈ synth (analz H) ∪ parts H"
by (metis Fake_parts_insert subsetD)
text‹\<^term>‹H› is sometimes \<^term>‹Key ` KK ∪ spies evs›, so can't put
\<^term>‹G=H›.›
lemma Fake_analz_insert:
"X∈ synth (analz G) ==>
analz (insert X H) ⊆ synth (analz G) ∪ analz (G ∪ H)"
apply (rule subsetI)
apply (subgoal_tac "x ∈ analz (synth (analz G) ∪ H)", force)
apply (blast intro: analz_mono [THEN [2] rev_subsetD] analz_mono [THEN synth_mono, THEN [2] rev_subsetD])
done
lemma analz_conj_parts [simp]:
"(X ∈ analz H ∧ X ∈ parts H) = (X ∈ analz H)"
by (blast intro: analz_subset_parts [THEN subsetD])
lemma analz_disj_parts [simp]:
"(X ∈ analz H | X ∈ parts H) = (X ∈ parts H)"
by (blast intro: analz_subset_parts [THEN subsetD])
text‹Without this equation, other rules for synth and analz would yield
redundant cases›
lemma MPair_synth_analz [iff]:
"(⦃X,Y⦄ ∈ synth (analz H)) =
(X ∈ synth (analz H) ∧ Y ∈ synth (analz H))"
by blast
lemma Crypt_synth_analz:
"[| Key K ∈ analz H; Key (invKey K) ∈ analz H |]
==> (Crypt K X ∈ synth (analz H)) = (X ∈ synth (analz H))"
by blast
lemma Hash_synth_analz [simp]:
"X ∉ synth (analz H)
==> (Hash⦃X,Y⦄ ∈ synth (analz H)) = (Hash⦃X,Y⦄ ∈ analz H)"
by blast
subsection‹HPair: a combination of Hash and MPair›
subsubsection‹Freeness›
lemma Agent_neq_HPair: "Agent A ≠ Hash[X] Y"
unfolding HPair_def by simp
lemma Nonce_neq_HPair: "Nonce N ≠ Hash[X] Y"
unfolding HPair_def by simp
lemma Number_neq_HPair: "Number N ≠ Hash[X] Y"
unfolding HPair_def by simp
lemma Key_neq_HPair: "Key K ≠ Hash[X] Y"
unfolding HPair_def by simp
lemma Hash_neq_HPair: "Hash Z ≠ Hash[X] Y"
unfolding HPair_def by simp
lemma Crypt_neq_HPair: "Crypt K X' ≠ Hash[X] Y"
unfolding HPair_def by simp
lemmas HPair_neqs = Agent_neq_HPair Nonce_neq_HPair Number_neq_HPair
Key_neq_HPair Hash_neq_HPair Crypt_neq_HPair
declare HPair_neqs [iff]
declare HPair_neqs [symmetric, iff]
lemma HPair_eq [iff]: "(Hash[X'] Y' = Hash[X] Y) = (X' = X ∧ Y'=Y)"
by (simp add: HPair_def)
lemma MPair_eq_HPair [iff]:
"(⦃X',Y'⦄ = Hash[X] Y) = (X' = Hash⦃X,Y⦄ ∧ Y'=Y)"
by (simp add: HPair_def)
lemma HPair_eq_MPair [iff]:
"(Hash[X] Y = ⦃X',Y'⦄) = (X' = Hash⦃X,Y⦄ ∧ Y'=Y)"
by (auto simp add: HPair_def)
subsubsection‹Specialized laws, proved in terms of those for Hash and MPair›
lemma keysFor_insert_HPair [simp]: "keysFor (insert (Hash[X] Y) H) = keysFor H"
by (simp add: HPair_def)
lemma parts_insert_HPair [simp]:
"parts (insert (Hash[X] Y) H) =
insert (Hash[X] Y) (insert (Hash⦃X,Y⦄) (parts (insert Y H)))"
by (simp add: HPair_def)
lemma analz_insert_HPair [simp]:
"analz (insert (Hash[X] Y) H) =
insert (Hash[X] Y) (insert (Hash⦃X,Y⦄) (analz (insert Y H)))"
by (simp add: HPair_def)
lemma HPair_synth_analz [simp]:
"X ∉ synth (analz H)
==> (Hash[X] Y ∈ synth (analz H)) =
(Hash ⦃X, Y⦄ ∈ analz H ∧ Y ∈ synth (analz H))"
by (auto simp add: HPair_def)
text‹We do NOT want Crypt... messages broken up in protocols!!›
declare parts.Body [rule del]
text‹Rewrites to push in Key and Crypt messages, so that other messages can
be pulled out using the ‹analz_insert› rules›
lemmas pushKeys =
insert_commute [of "Key K" "Agent C"]
insert_commute [of "Key K" "Nonce N"]
insert_commute [of "Key K" "Number N"]
insert_commute [of "Key K" "Hash X"]
insert_commute [of "Key K" "MPair X Y"]
insert_commute [of "Key K" "Crypt X K'"]
for K C N X Y K'
lemmas pushCrypts =
insert_commute [of "Crypt X K" "Agent C"]
insert_commute [of "Crypt X K" "Agent C"]
insert_commute [of "Crypt X K" "Nonce N"]
insert_commute [of "Crypt X K" "Number N"]
insert_commute [of "Crypt X K" "Hash X'"]
insert_commute [of "Crypt X K" "MPair X' Y"]
for X K C N X' Y
text‹Cannot be added with ‹[simp]› -- messages should not always be
re-ordered.›
lemmas pushes = pushKeys pushCrypts
subsection‹The set of key-free messages›
inductive_set
keyfree :: "msg set"
where
Agent: "Agent A ∈ keyfree"
| Number: "Number N ∈ keyfree"
| Nonce: "Nonce N ∈ keyfree"
| Hash: "Hash X ∈ keyfree"
| MPair: "[|X ∈ keyfree; Y ∈ keyfree|] ==> ⦃X,Y⦄ ∈ keyfree"
| Crypt: "[|X ∈ keyfree|] ==> Crypt K X ∈ keyfree"
declare keyfree.intros [intro]
inductive_cases keyfree_KeyE: "Key K ∈ keyfree"
inductive_cases keyfree_MPairE: "⦃X,Y⦄ ∈ keyfree"
inductive_cases keyfree_CryptE: "Crypt K X ∈ keyfree"
lemma parts_keyfree: "parts (keyfree) ⊆ keyfree"
by (clarify, erule parts.induct, auto elim!: keyfree_KeyE keyfree_MPairE keyfree_CryptE)
lemma analz_keyfree_into_Un: "⟦X ∈ analz (G ∪ H); G ⊆ keyfree⟧ ⟹ X ∈ parts G ∪ analz H"
apply (erule analz.induct, auto dest: parts.Body)
apply (metis Un_absorb2 keyfree_KeyE parts_Un parts_keyfree UnI2)
done
subsection‹Tactics useful for many protocol proofs›
ML
‹
fun impOfSubs th = th RSN (2, @{thm rev_subsetD})
fun Fake_insert_tac ctxt =
dresolve_tac ctxt [impOfSubs @{thm Fake_analz_insert},
impOfSubs @{thm Fake_parts_insert}] THEN'
eresolve_tac ctxt [asm_rl, @{thm synth.Inj}];
fun Fake_insert_simp_tac ctxt i =
REPEAT (Fake_insert_tac ctxt i) THEN asm_full_simp_tac ctxt i;
fun atomic_spy_analz_tac ctxt =
SELECT_GOAL
(Fake_insert_simp_tac ctxt 1 THEN
IF_UNSOLVED
(Blast.depth_tac
(ctxt addIs [@{thm analz_insertI}, impOfSubs @{thm analz_subset_parts}]) 4 1));
fun spy_analz_tac ctxt i =
DETERM
(SELECT_GOAL
(EVERY
[
(REPEAT o CHANGED)
(Rule_Insts.res_inst_tac ctxt [((("x", 1), Position.none), "X")] []
(insert_commute RS ssubst) 1),
simp_tac ctxt 1,
REPEAT (FIRSTGOAL (resolve_tac ctxt [allI,impI,notI,conjI,iffI])),
DEPTH_SOLVE (atomic_spy_analz_tac ctxt 1)]) i);
›
text‹By default only ‹o_apply› is built-in. But in the presence of
eta-expansion this means that some terms displayed as \<^term>‹f o g› will be
rewritten, and others will not!›
declare o_def [simp]
lemma Crypt_notin_image_Key [simp]: "Crypt K X ∉ Key ` A"
by auto
lemma Hash_notin_image_Key [simp] :"Hash X ∉ Key ` A"
by auto
lemma synth_analz_mono: "G⊆H ==> synth (analz(G)) ⊆ synth (analz(H))"
by (iprover intro: synth_mono analz_mono)
lemma Fake_analz_eq [simp]:
"X ∈ synth(analz H) ==> synth (analz (insert X H)) = synth (analz H)"
by (metis Fake_analz_insert Un_absorb Un_absorb1 Un_commute
subset_insertI synth_analz_mono synth_increasing synth_subset_iff)
text‹Two generalizations of ‹analz_insert_eq››
lemma gen_analz_insert_eq [rule_format]:
"X ∈ analz H ⟹ ∀G. H ⊆ G ⟶ analz (insert X G) = analz G"
by (blast intro: analz_cut analz_insertI analz_mono [THEN [2] rev_subsetD])
lemma synth_analz_insert_eq [rule_format]:
"X ∈ synth (analz H)
⟹ ∀G. H ⊆ G ⟶ (Key K ∈ analz (insert X G)) = (Key K ∈ analz G)"
apply (erule synth.induct)
apply (simp_all add: gen_analz_insert_eq subset_trans [OF _ subset_insertI])
done
lemma Fake_parts_sing:
"X ∈ synth (analz H) ==> parts{X} ⊆ synth (analz H) ∪ parts H"
by (metis Fake_parts_insert empty_subsetI insert_mono parts_mono subset_trans)
lemmas Fake_parts_sing_imp_Un = Fake_parts_sing [THEN [2] rev_subsetD]
method_setup spy_analz = ‹
Scan.succeed (SIMPLE_METHOD' o spy_analz_tac)›
"for proving the Fake case when analz is involved"
method_setup atomic_spy_analz = ‹
Scan.succeed (SIMPLE_METHOD' o atomic_spy_analz_tac)›
"for debugging spy_analz"
method_setup Fake_insert_simp = ‹
Scan.succeed (SIMPLE_METHOD' o Fake_insert_simp_tac)›
"for debugging spy_analz"
end