(* Title: HOL/Auth/NS_Shared ID: $Id: NS_Shared.thy,v 1.34 2005/06/17 14:13:06 haftmann Exp $ Author: Lawrence C Paulson, Cambridge University Computer Laboratory Copyright 1996 University of Cambridge *) header{*The Needham-Schroeder Shared-Key Protocol*} theory NS_Shared imports Public begin text{* From page 247 of Burrows, Abadi and Needham (1989). A Logic of Authentication. Proc. Royal Soc. 426 *} consts ns_shared :: "event list set" inductive "ns_shared" intros (*Initial trace is empty*) Nil: "[] ∈ ns_shared" (*The spy MAY say anything he CAN say. We do not expect him to invent new nonces here, but he can also use NS1. Common to all similar protocols.*) Fake: "[|evsf ∈ ns_shared; X ∈ synth (analz (spies evsf))|] ==> Says Spy B X # evsf ∈ ns_shared" (*Alice initiates a protocol run, requesting to talk to any B*) NS1: "[|evs1 ∈ ns_shared; Nonce NA ∉ used evs1|] ==> Says A Server \<lbrace>Agent A, Agent B, Nonce NA\<rbrace> # evs1 ∈ ns_shared" (*Server's response to Alice's message. !! It may respond more than once to A's request !! Server doesn't know who the true sender is, hence the A' in the sender field.*) NS2: "[|evs2 ∈ ns_shared; Key KAB ∉ used evs2; KAB ∈ symKeys; Says A' Server \<lbrace>Agent A, Agent B, Nonce NA\<rbrace> ∈ set evs2|] ==> Says Server A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key KAB, (Crypt (shrK B) \<lbrace>Key KAB, Agent A\<rbrace>)\<rbrace>) # evs2 ∈ ns_shared" (*We can't assume S=Server. Agent A "remembers" her nonce. Need A ≠ Server because we allow messages to self.*) NS3: "[|evs3 ∈ ns_shared; A ≠ Server; Says S A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key K, X\<rbrace>) ∈ set evs3; Says A Server \<lbrace>Agent A, Agent B, Nonce NA\<rbrace> ∈ set evs3|] ==> Says A B X # evs3 ∈ ns_shared" (*Bob's nonce exchange. He does not know who the message came from, but responds to A because she is mentioned inside.*) NS4: "[|evs4 ∈ ns_shared; Nonce NB ∉ used evs4; K ∈ symKeys; Says A' B (Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>) ∈ set evs4|] ==> Says B A (Crypt K (Nonce NB)) # evs4 ∈ ns_shared" (*Alice responds with Nonce NB if she has seen the key before. Maybe should somehow check Nonce NA again. We do NOT send NB-1 or similar as the Spy cannot spoof such things. Letting the Spy add or subtract 1 lets him send all nonces. Instead we distinguish the messages by sending the nonce twice.*) NS5: "[|evs5 ∈ ns_shared; K ∈ symKeys; Says B' A (Crypt K (Nonce NB)) ∈ set evs5; Says S A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key K, X\<rbrace>) ∈ set evs5|] ==> Says A B (Crypt K \<lbrace>Nonce NB, Nonce NB\<rbrace>) # evs5 ∈ ns_shared" (*This message models possible leaks of session keys. The two Nonces identify the protocol run: the rule insists upon the true senders in order to make them accurate.*) Oops: "[|evso ∈ ns_shared; Says B A (Crypt K (Nonce NB)) ∈ set evso; Says Server A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key K, X\<rbrace>) ∈ set evso|] ==> Notes Spy \<lbrace>Nonce NA, Nonce NB, Key K\<rbrace> # evso ∈ ns_shared" declare Says_imp_knows_Spy [THEN parts.Inj, dest] declare parts.Body [dest] declare Fake_parts_insert_in_Un [dest] declare analz_into_parts [dest] declare image_eq_UN [simp] (*accelerates proofs involving nested images*) text{*A "possibility property": there are traces that reach the end*} lemma "[| A ≠ Server; Key K ∉ used []; K ∈ symKeys |] ==> ∃N. ∃evs ∈ ns_shared. Says A B (Crypt K \<lbrace>Nonce N, Nonce N\<rbrace>) ∈ set evs" apply (intro exI bexI) apply (rule_tac [2] ns_shared.Nil [THEN ns_shared.NS1, THEN ns_shared.NS2, THEN ns_shared.NS3, THEN ns_shared.NS4, THEN ns_shared.NS5]) apply (possibility, simp add: used_Cons) done (*This version is similar, while instantiating ?K and ?N to epsilon-terms lemma "A ≠ Server ==> ∃evs ∈ ns_shared. Says A B (Crypt ?K \<lbrace>Nonce ?N, Nonce ?N\<rbrace>) ∈ set evs" *) subsection{*Inductive proofs about @{term ns_shared}*} subsubsection{*Forwarding lemmas, to aid simplification*} text{*For reasoning about the encrypted portion of message NS3*} lemma NS3_msg_in_parts_spies: "Says S A (Crypt KA \<lbrace>N, B, K, X\<rbrace>) ∈ set evs ==> X ∈ parts (spies evs)" by blast text{*For reasoning about the Oops message*} lemma Oops_parts_spies: "Says Server A (Crypt (shrK A) \<lbrace>NA, B, K, X\<rbrace>) ∈ set evs ==> K ∈ parts (spies evs)" by blast text{*Theorems of the form @{term "X ∉ parts (spies evs)"} imply that NOBODY sends messages containing @{term X}*} text{*Spy never sees another agent's shared key! (unless it's bad at start)*} lemma Spy_see_shrK [simp]: "evs ∈ ns_shared ==> (Key (shrK A) ∈ parts (spies evs)) = (A ∈ bad)" apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, simp_all, blast+) done lemma Spy_analz_shrK [simp]: "evs ∈ ns_shared ==> (Key (shrK A) ∈ analz (spies evs)) = (A ∈ bad)" by auto text{*Nobody can have used non-existent keys!*} lemma new_keys_not_used [simp]: "[|Key K ∉ used evs; K ∈ symKeys; evs ∈ ns_shared|] ==> K ∉ keysFor (parts (spies evs))" apply (erule rev_mp) apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, simp_all) txt{*Fake, NS2, NS4, NS5*} apply (force dest!: keysFor_parts_insert, blast+) done subsubsection{*Lemmas concerning the form of items passed in messages*} text{*Describes the form of K, X and K' when the Server sends this message.*} lemma Says_Server_message_form: "[|Says Server A (Crypt K' \<lbrace>N, Agent B, Key K, X\<rbrace>) ∈ set evs; evs ∈ ns_shared|] ==> K ∉ range shrK ∧ X = (Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>) ∧ K' = shrK A" by (erule rev_mp, erule ns_shared.induct, auto) text{*If the encrypted message appears then it originated with the Server*} lemma A_trusts_NS2: "[|Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace> ∈ parts (spies evs); A ∉ bad; evs ∈ ns_shared|] ==> Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace>) ∈ set evs" apply (erule rev_mp) apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, auto) done lemma cert_A_form: "[|Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace> ∈ parts (spies evs); A ∉ bad; evs ∈ ns_shared|] ==> K ∉ range shrK ∧ X = (Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>)" by (blast dest!: A_trusts_NS2 Says_Server_message_form) text{*EITHER describes the form of X when the following message is sent, OR reduces it to the Fake case. Use @{text Says_Server_message_form} if applicable.*} lemma Says_S_message_form: "[|Says S A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key K, X\<rbrace>) ∈ set evs; evs ∈ ns_shared|] ==> (K ∉ range shrK ∧ X = (Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>)) ∨ X ∈ analz (spies evs)" by (blast dest: Says_imp_knows_Spy analz_shrK_Decrypt cert_A_form analz.Inj) (*Alternative version also provable lemma Says_S_message_form2: "[|Says S A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key K, X\<rbrace>) ∈ set evs; evs ∈ ns_shared|] ==> Says Server A (Crypt (shrK A) \<lbrace>Nonce NA, Agent B, Key K, X\<rbrace>) ∈ set evs ∨ X ∈ analz (spies evs)" apply (case_tac "A ∈ bad") apply (force dest!: Says_imp_knows_Spy [THEN analz.Inj]) by (blast dest!: A_trusts_NS2 Says_Server_message_form) *) (**** SESSION KEY COMPROMISE THEOREM. To prove theorems of the form Key K ∈ analz (insert (Key KAB) (spies evs)) ==> Key K ∈ analz (spies evs) A more general formula must be proved inductively. ****) text{*NOT useful in this form, but it says that session keys are not used to encrypt messages containing other keys, in the actual protocol. We require that agents should behave like this subsequently also.*} lemma "[|evs ∈ ns_shared; Kab ∉ range shrK|] ==> (Crypt KAB X) ∈ parts (spies evs) ∧ Key K ∈ parts {X} --> Key K ∈ parts (spies evs)" apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, simp_all) txt{*Fake*} apply (blast dest: parts_insert_subset_Un) txt{*Base, NS4 and NS5*} apply auto done subsubsection{*Session keys are not used to encrypt other session keys*} text{*The equality makes the induction hypothesis easier to apply*} lemma analz_image_freshK [rule_format]: "evs ∈ ns_shared ==> ∀K KK. KK ⊆ - (range shrK) --> (Key K ∈ analz (Key`KK ∪ (spies evs))) = (K ∈ KK ∨ Key K ∈ analz (spies evs))" apply (erule ns_shared.induct) apply (drule_tac [8] Says_Server_message_form) apply (erule_tac [5] Says_S_message_form [THEN disjE], analz_freshK, spy_analz) txt{*NS2, NS3*} apply blast+; done lemma analz_insert_freshK: "[|evs ∈ ns_shared; KAB ∉ range shrK|] ==> (Key K ∈ analz (insert (Key KAB) (spies evs))) = (K = KAB ∨ Key K ∈ analz (spies evs))" by (simp only: analz_image_freshK analz_image_freshK_simps) subsubsection{*The session key K uniquely identifies the message*} text{*In messages of this form, the session key uniquely identifies the rest*} lemma unique_session_keys: "[|Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace>) ∈ set evs; Says Server A' (Crypt (shrK A') \<lbrace>NA', Agent B', Key K, X'\<rbrace>) ∈ set evs; evs ∈ ns_shared|] ==> A=A' ∧ NA=NA' ∧ B=B' ∧ X = X'" apply (erule rev_mp, erule rev_mp, erule ns_shared.induct, simp_all, blast+) done subsubsection{*Crucial secrecy property: Spy does not see the keys sent in msg NS2*} text{*Beware of @{text "[rule_format]"} and the universal quantifier!*} lemma secrecy_lemma: "[|Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>\<rbrace>) ∈ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared|] ==> (∀NB. Notes Spy \<lbrace>NA, NB, Key K\<rbrace> ∉ set evs) --> Key K ∉ analz (spies evs)" apply (erule rev_mp) apply (erule ns_shared.induct, force) apply (frule_tac [7] Says_Server_message_form) apply (frule_tac [4] Says_S_message_form) apply (erule_tac [5] disjE) apply (simp_all add: analz_insert_eq analz_insert_freshK pushes split_ifs, spy_analz) txt{*NS2*} apply blast txt{*NS3, Server sub-case*} apply (blast dest!: Crypt_Spy_analz_bad A_trusts_NS2 dest: Says_imp_knows_Spy analz.Inj unique_session_keys) txt{*NS3, Spy sub-case; also Oops*} apply (blast dest: unique_session_keys)+ done text{*Final version: Server's message in the most abstract form*} lemma Spy_not_see_encrypted_key: "[|Says Server A (Crypt K' \<lbrace>NA, Agent B, Key K, X\<rbrace>) ∈ set evs; ∀NB. Notes Spy \<lbrace>NA, NB, Key K\<rbrace> ∉ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared|] ==> Key K ∉ analz (spies evs)" by (blast dest: Says_Server_message_form secrecy_lemma) subsection{*Guarantees available at various stages of protocol*} text{*If the encrypted message appears then it originated with the Server*} lemma B_trusts_NS3: "[|Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace> ∈ parts (spies evs); B ∉ bad; evs ∈ ns_shared|] ==> ∃NA. Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>\<rbrace>) ∈ set evs" apply (erule rev_mp) apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, auto) done lemma A_trusts_NS4_lemma [rule_format]: "evs ∈ ns_shared ==> Key K ∉ analz (spies evs) --> Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace>) ∈ set evs --> Crypt K (Nonce NB) ∈ parts (spies evs) --> Says B A (Crypt K (Nonce NB)) ∈ set evs" apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies) apply (analz_mono_contra, simp_all, blast) txt{*NS2: contradiction from the assumptions @{term "Key K ∉ used evs2"} and @{term "Crypt K (Nonce NB) ∈ parts (spies evs2)"} *} apply (force dest!: Crypt_imp_keysFor) txt{*NS3*} apply blast txt{*NS4*} apply (blast dest: B_trusts_NS3 Says_imp_knows_Spy [THEN analz.Inj] Crypt_Spy_analz_bad unique_session_keys) done text{*This version no longer assumes that K is secure*} lemma A_trusts_NS4: "[|Crypt K (Nonce NB) ∈ parts (spies evs); Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace> ∈ parts (spies evs); ∀NB. Notes Spy \<lbrace>NA, NB, Key K\<rbrace> ∉ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared|] ==> Says B A (Crypt K (Nonce NB)) ∈ set evs" by (blast intro: A_trusts_NS4_lemma dest: A_trusts_NS2 Spy_not_see_encrypted_key) text{*If the session key has been used in NS4 then somebody has forwarded component X in some instance of NS4. Perhaps an interesting property, but not needed (after all) for the proofs below.*} theorem NS4_implies_NS3 [rule_format]: "evs ∈ ns_shared ==> Key K ∉ analz (spies evs) --> Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, X\<rbrace>) ∈ set evs --> Crypt K (Nonce NB) ∈ parts (spies evs) --> (∃A'. Says A' B X ∈ set evs)" apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, analz_mono_contra) apply (simp_all add: ex_disj_distrib, blast) txt{*NS2*} apply (blast dest!: new_keys_not_used Crypt_imp_keysFor) txt{*NS3*} apply blast txt{*NS4*} apply (blast dest: B_trusts_NS3 dest: Says_imp_knows_Spy [THEN analz.Inj] unique_session_keys Crypt_Spy_analz_bad) done lemma B_trusts_NS5_lemma [rule_format]: "[|B ∉ bad; evs ∈ ns_shared|] ==> Key K ∉ analz (spies evs) --> Says Server A (Crypt (shrK A) \<lbrace>NA, Agent B, Key K, Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace>\<rbrace>) ∈ set evs --> Crypt K \<lbrace>Nonce NB, Nonce NB\<rbrace> ∈ parts (spies evs) --> Says A B (Crypt K \<lbrace>Nonce NB, Nonce NB\<rbrace>) ∈ set evs" apply (erule ns_shared.induct, force, drule_tac [4] NS3_msg_in_parts_spies, analz_mono_contra, simp_all, blast) txt{*NS2*} apply (blast dest!: new_keys_not_used Crypt_imp_keysFor) txt{*NS3*} apply (blast dest!: cert_A_form) txt{*NS5*} apply (blast dest!: A_trusts_NS2 dest: Says_imp_knows_Spy [THEN analz.Inj] unique_session_keys Crypt_Spy_analz_bad) done text{*Very strong Oops condition reveals protocol's weakness*} lemma B_trusts_NS5: "[|Crypt K \<lbrace>Nonce NB, Nonce NB\<rbrace> ∈ parts (spies evs); Crypt (shrK B) \<lbrace>Key K, Agent A\<rbrace> ∈ parts (spies evs); ∀NA NB. Notes Spy \<lbrace>NA, NB, Key K\<rbrace> ∉ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared|] ==> Says A B (Crypt K \<lbrace>Nonce NB, Nonce NB\<rbrace>) ∈ set evs" by (blast intro: B_trusts_NS5_lemma dest: B_trusts_NS3 Spy_not_see_encrypted_key) end
lemma
[| A ≠ Server; Key K ∉ used []; K ∈ symKeys |] ==> ∃N. ∃evs∈ns_shared. Says A B (Crypt K {|Nonce N, Nonce N|}) ∈ set evs
lemma NS3_msg_in_parts_spies:
Says S A (Crypt KA {|N, B, K, X|}) ∈ set evs ==> X ∈ parts (knows Spy evs)
lemma Oops_parts_spies:
Says Server A (Crypt (shrK A) {|NA, B, K, X|}) ∈ set evs ==> K ∈ parts (knows Spy evs)
lemma Spy_see_shrK:
evs ∈ ns_shared ==> (Key (shrK A) ∈ parts (knows Spy evs)) = (A ∈ bad)
lemma Spy_analz_shrK:
evs ∈ ns_shared ==> (Key (shrK A) ∈ analz (knows Spy evs)) = (A ∈ bad)
lemma new_keys_not_used:
[| Key K ∉ used evs; K ∈ symKeys; evs ∈ ns_shared |] ==> K ∉ keysFor (parts (knows Spy evs))
lemma Says_Server_message_form:
[| Says Server A (Crypt K' {|N, Agent B, Key K, X|}) ∈ set evs; evs ∈ ns_shared |] ==> K ∉ range shrK ∧ X = Crypt (shrK B) {|Key K, Agent A|} ∧ K' = shrK A
lemma A_trusts_NS2:
[| Crypt (shrK A) {|NA, Agent B, Key K, X|} ∈ parts (knows Spy evs); A ∉ bad; evs ∈ ns_shared |] ==> Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, X|}) ∈ set evs
lemma cert_A_form:
[| Crypt (shrK A) {|NA, Agent B, Key K, X|} ∈ parts (knows Spy evs); A ∉ bad; evs ∈ ns_shared |] ==> K ∉ range shrK ∧ X = Crypt (shrK B) {|Key K, Agent A|}
lemma Says_S_message_form:
[| Says S A (Crypt (shrK A) {|Nonce NA, Agent B, Key K, X|}) ∈ set evs; evs ∈ ns_shared |] ==> K ∉ range shrK ∧ X = Crypt (shrK B) {|Key K, Agent A|} ∨ X ∈ analz (knows Spy evs)
lemma
[| evs ∈ ns_shared; Kab ∉ range shrK |] ==> Crypt KAB X ∈ parts (knows Spy evs) ∧ Key K ∈ parts {X} --> Key K ∈ parts (knows Spy evs)
lemma analz_image_freshK:
[| evs ∈ ns_shared; KK ⊆ - range shrK |] ==> (Key K ∈ analz (Key ` KK ∪ knows Spy evs)) = (K ∈ KK ∨ Key K ∈ analz (knows Spy evs))
lemma analz_insert_freshK:
[| evs ∈ ns_shared; KAB ∉ range shrK |] ==> (Key K ∈ analz (insert (Key KAB) (knows Spy evs))) = (K = KAB ∨ Key K ∈ analz (knows Spy evs))
lemma unique_session_keys:
[| Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, X|}) ∈ set evs; Says Server A' (Crypt (shrK A') {|NA', Agent B', Key K, X'|}) ∈ set evs; evs ∈ ns_shared |] ==> A = A' ∧ NA = NA' ∧ B = B' ∧ X = X'
lemma secrecy_lemma:
[| Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, Crypt (shrK B) {|Key K, Agent A|}|}) ∈ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared |] ==> (∀NB. Notes Spy {|NA, NB, Key K|} ∉ set evs) --> Key K ∉ analz (knows Spy evs)
lemma Spy_not_see_encrypted_key:
[| Says Server A (Crypt K' {|NA, Agent B, Key K, X|}) ∈ set evs; ∀NB. Notes Spy {|NA, NB, Key K|} ∉ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared |] ==> Key K ∉ analz (knows Spy evs)
lemma B_trusts_NS3:
[| Crypt (shrK B) {|Key K, Agent A|} ∈ parts (knows Spy evs); B ∉ bad; evs ∈ ns_shared |] ==> ∃NA. Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, Crypt (shrK B) {|Key K, Agent A|}|}) ∈ set evs
lemma A_trusts_NS4_lemma:
[| evs ∈ ns_shared; Key K ∉ analz (knows Spy evs); Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, X|}) ∈ set evs; Crypt K (Nonce NB) ∈ parts (knows Spy evs) |] ==> Says B A (Crypt K (Nonce NB)) ∈ set evs
lemma A_trusts_NS4:
[| Crypt K (Nonce NB) ∈ parts (knows Spy evs); Crypt (shrK A) {|NA, Agent B, Key K, X|} ∈ parts (knows Spy evs); ∀NB. Notes Spy {|NA, NB, Key K|} ∉ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared |] ==> Says B A (Crypt K (Nonce NB)) ∈ set evs
theorem NS4_implies_NS3:
[| evs ∈ ns_shared; Key K ∉ analz (knows Spy evs); Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, X|}) ∈ set evs; Crypt K (Nonce NB) ∈ parts (knows Spy evs) |] ==> ∃A'. Says A' B X ∈ set evs
lemma B_trusts_NS5_lemma:
[| B ∉ bad; evs ∈ ns_shared; Key K ∉ analz (knows Spy evs); Says Server A (Crypt (shrK A) {|NA, Agent B, Key K, Crypt (shrK B) {|Key K, Agent A|}|}) ∈ set evs; Crypt K {|Nonce NB, Nonce NB|} ∈ parts (knows Spy evs) |] ==> Says A B (Crypt K {|Nonce NB, Nonce NB|}) ∈ set evs
lemma B_trusts_NS5:
[| Crypt K {|Nonce NB, Nonce NB|} ∈ parts (knows Spy evs); Crypt (shrK B) {|Key K, Agent A|} ∈ parts (knows Spy evs); ∀NA NB. Notes Spy {|NA, NB, Key K|} ∉ set evs; A ∉ bad; B ∉ bad; evs ∈ ns_shared |] ==> Says A B (Crypt K {|Nonce NB, Nonce NB|}) ∈ set evs