(n+1)sec

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(n+1)sec

Abstract

In this document we present the first public draft of (n+1)sec - a secure multi-party communication protocol developed by eQualit.ie with support from the Open Technology Fund and Cryptocat. We include the design rationale, choice of security features, adversarial models, schematic and high level specification of sub-protocols. A subsequent document will present security proofs and implementation details.

I. INTRODUCTION

The (n+1)sec project was inspired by Off-The-Record messaging protocol and subsequent efforts to explore a multiparty use-case for OTR in [GUVGC09]. (n+1)sec is currently developed for Cryptocat - a browser based XMPP chat platform and assumes its use-cases. Most importantly, (n+1)sec allows for secure multi-party key exchange and end-to-end encrypted communications without extensive computational requirements from the client. You can follow and contribute to the implementation of np1sec on our Github pages. Future protocol iterations will consider a variety of other real-world use cases and be platform independent. Please use the Discussion page to ask questions and leave comments.

In the following section we summarise relevant publications and describe their influence on this protocol. In Section III, we describe our approach and choice of security features. In Section IV, we review the security properties within this protocol. In Section V we give basic mathematical definition needed to model the chat session and security proofs for various security aspects of the protocol. Section VI provides formal definitions and references to the adversarial models for each property. In Section VII we describe various parts of the protocol and present choices for each sub protocol. In Section VIII, we present each of the (n+1)sec protocol steps at various stages in schematic and algorithmic format. We present our choice of primitives in Section IX. Finally, we define the work that remains to be done on this protocol and acknowledge the good people who have helped us get here.

II. History and literature review

Two-party Off The Record messaging (OTR) was introduced in [BGB04] as an alternative to PGP for secure casual Internet chat by providing necessary forward secrecy and deniable transcript features. The paper proposes the use of symmetric encryption and message authentication in OTR for confidentiality and integrity, and the Diffie-Hellman key exchange for authenticating the other party in the chat. Since publication in 2004, it has defined the standard for secure Internet chat attracting a lot of academic attention and security analysis. The OTR protocol is now at Version 3 and the libotr software libraries are continuously updated. Our research and literature review focused on the protocol presented in [BGB04] and the subsequent proposal for a multiparty use-case in [GUVGC09].

In [RGK05], researchers point out that OTR’s approach to authenticate renewed ephemeral session keys is provided by the property of confidentiality and is therefore dependent on the secrecy of the conversation. Hence, breaking the secrecy of the conversation (e.g. by leaking the session key) will lead to false authentication as well. They offer two authenticated deniable key exchange protocols, which also provide forward secrecy, as a replacement for OTR’s original key exchange. Furthermore, they argue that forgeability and malleability do not have any mathematical consequence in improving deniability if the parties have been authenticated by a deniable key exchange scheme. They argue that as these properties pose potential security threats, it is desirable to omit them from the protocol entirely.

An alternative appears in [BS07], using the Schnorr zero-knowledge proof and signature algorithm, to introduce a 4-round challenge-based authentication scheme that grants deniability to the two-round authenticated protocol described in [BVS05].

[ACMP10] offers a more efficient protocol than [BS07] in the sense that ephemeral Diffie-Hellman elements are reusable to regenerate keys when some of the participants change. As such, it offers a one-round protocol to generate a key for a subgroup of the original conversation.

An unauthenticated exchange of the OTR version identifier can pose a threat to authenticity as shown in [BM]: the adversary can force clients to downgrade to an older, (potentially insecure) version of the protocol. They also note the Diffie-Hellman key exchange failure in delivering authentication in the presence of an active adversary. Furthermore, they show that the early publication of MAC keys for the purpose of forgeability can easily enable the active adversary to forge messages during the conversation (instead of the intended forgeability after the conversation has ended). Finally, they argue that in an environment where the adversary is controlling the whole network, she can effectively disarm the protocol of its forgeability property.

Various attempts have been made to construct an efficient multiparty (known as group) authenticated key exchange protocol. OTR authors proposed a generalisation of two-party OTR to a multiparty use-case in [GUVGC09]. However, they did not specify the cryptographic primitives, neither did they give a formal definition of the adversaries nor the proof of the algorithm’s security (reduction). Although a more robust key exchange is proposed, some primary performance analysis of the implementation of the key agreement protocol has been shown to be impractically slow, especially on mobile devices [Gun13a][Git11].

[LVH13] proposes GOTR as an alternative to [GUVGC09] with a goal of improving on some of its security properties. A notable change is the use of p2p private channels to send message digest so as to establish transcript consistency and implicit message origin authenticity between users. GOTR also strives to improve on repudiability by considering deniability against an 'online judge' as well as forgeability for the entire transcript by a single party (this is possible in [GUVGC09] as long as a deniable AKE is being used). The idea of online repudiabilty relies on the judge controlling up to N-2 parties while the two remaining "honest" parties are allowed to collude. This is slightly unusual for both repudiability and honesty. [LVH13] also proposes an involved contributory BD based key agreement scheme, which disregard room consistency and turns GOTR into a broadcast scheme (c.f. Appendix B).

III. Design rationale

Our approach for (n+1)sec design was based on the following requirements, in order of importance:

  1. A protocol that is provably secure in a sufficiently strong adversarial model that addresses confidentiality, authenticity and forward secrecy
  2. Applicable to the Cryptocat XMPP use-case
  3. Providing some degree of deniability when it does not negatively impact usability or our security goals
  4. Addressing security flaws in [BGB04] and [GUVGC09]

We designate the protocol suggested in [GUVGC09] as our starting point and apply various modifications to reach a desirable protocol satisfying the above stated goals.

A significant portion of our research suggested a better performing, more secure alternative to the key exchange protocol suggested in [GUVGC09]. Based on conclusions in [BM] and [RGK05], we are making the following design changes:

  • Using a more secure deniable key exchange algorithm, instead of naive Diffie-Hellman

In designing (n+1)sec’s deniable authentication and key agreement protocol, we have followed [ACMP10] by choosing a provably secure authenticated key exchange method and replacing the signature-based authentication with a deniable one. We have chosen the protocol introduced in [ACMP10] instead of [BS07], due to its superior efficiency. We abstract out the method where parties communicate their secret for additional flexibility.

  • Using a more practical algorithm, rather than the peer-to-peer signature key exchange

We have chosen the two round SKEME-based Triple Diffie-Hellman deniable key authentication instead of the Schnorr signature scheme suggested in [BS07] because it saves us two critical rounds for authentication (even though it offers a slightly weaker form of deniability). We have also modified the protocol to represent the chat condition where participants sequentially join and leave the chat.

  • Omitting forgeability and malleability from the protocol and refraining from broadcasting the expired ephemeral authentication keys.

Following conclusions in [RGK05] we have dropped forgeability (mandatory publication of ephemeral signature/MAC keys) and malleability from our requirements since protocol deniability is based on a deniable key exchange. This significantly improves protocol efficiency, a primary focus for (n+1)sec. The deniability of the authentication scheme prevents users not present in a chat session from forging a part of the transcript, however it allows them to forge a whole session with false participants and a complete transcript.

Another major departure from the suggested protocol in [GUVGC09] is in-session transcript authentication, which happens every time a participant receives or sends a message. Transcript authentication (referred to as transcript consistency check from here on) is an optimistic approach based on the assumption that the chat server is mandated to provides a reliable and orderly message delivery, as it is in the case of XMPP protocol. We can ensure transcript consistency whenever the underlying transport layer guarantees the reliable delivery of the messages in the same order for all participants. If however, the underlying protocol does not guarantee reliability either in delivery or order, we report the discrepancy in user's transcript compared to their peers but we do not attempt to correct the transport protocol's action (we offer detection but not recovery).

We also equip (n+1)sec with heartbeat to ensure in-session forward secrecy, periodical consistency check and freshness.

We propose the possibility of using block-based, rather than stream-based, encryption for the symmetric encryption primitives.

Finally, other protocol design possibilities considered and the rationale for not pursuing them further is discussed in Appendix B: Other design possibilities

IV. Security Properties

Following from the design rationales proposed in SectionIII, we give an informal description of the properties which (n+1)sec aims to secure in a multi-party chat session:

  • Participant deniable authenticity based on their long term persistent identity: While a participant in a chat can be sure of another participant’s authenticity, they cannot prove their confidence to anybody else who has not actively participated in the chat session or who has not interacted with the authenticator prior to the session.
  • Message origin authenticity against both outsider intrusion and the impersonation of existing participants by other malicious participants in the session. This means that the user can be assured of the authenticity of the sender of each original message even if other participants in the room try to impersonate the sender and send messages on their behalf.
  • Confidentiality of the conversation so its content is not accessible or readable by an outsider.
  • Forward secrecy of the conversation, so its content remains inaccessible in the event that the long term private key of a participant (which represents their long term identity) is compromised after session key establishment. In addition in-session forward secrecy means that compromise of the ephemeral keys of a participant, or the session key during chat session which is live for long time, would reveal only a fraction of the transcript.
  • Room consistency, where all participants are confident that they have been participating in the same room; they are confident that everybody in the room believes that everybody else sees the same participant list as they do.
  • Transcript consistency, where all participants are confident that they have been participating in the same conversation; as the conversation continues, they are confident that they have been seeing the same sequence of messages.

For each of these requirements, it is necessary to formalize the above mentioned properties against an adversarial model which addresses the requirements stated in Section III. The next section will introduce formal definitions covering these elements.

V. Chat Session Model

In modelling the chat session, in terms of the adversarial models and protocol specifications, the notation of [ACMP10] is followed. This notation is common to other publication on group key exchange such as [GBNM11], and is adherred to for consistency.

Definition V.1 Multi-party chat session: Let {\mathcal  {U}}=\{U_{1},...,U_{m}\} be the set of possible participants. A multi-party chat session is an ordered pair S:=({\mathcal  {S}},sid) in which {\mathcal  {S}}\subset {\mathcal  {U}} and sid is the unique session id. Without loss of generality we assume {\mathcal  {S}}=\{U_{1},...,U_{n}\} and we interchangeably refer to party U_{i} by index i. Furthermore, it is assumed that party U_{i} is presented and identified verifiably by a long-term persistence key pair (LPK_{{U_{i}}},LSK_{{U_{i}}}).

Definition V.2 sub session After session S is established, A subset of participants {\mathcal  {T}}\subset {\mathcal  {S}} might want to start a session in which parties in {\mathcal  {T}}\backslash {\mathcal  {S}} are excluded (for example when those parties leave the chatroom). In such a setting we say T:=({\mathcal  {T}},sid^{T}) is a subsession of S. When there is no need to specify the subsession of choice, we use spid to refer to sid^{T}.

Definition V.3 An authenticated group key exchange (AGKE) is Algorithm \Pi which each honest party will execute in order to communicate (by means of sending, receiving or computing) a cryptographic secret - namely a key - among the other parties of a session. By \Pi _{i}^{S} (or \Pi _{i} when the underlying session is understood) we are referring to an instance of \Pi which the party U_{i} executes to achieve the collective goal. Further more we define:

  • Session id as seen by U_{i}: Session id sid will be derived during the execution of the protocol. The session id is computed by \Pi _{i}^{S} (the instance of the protocol run by U_{i} for session S) and is indicated by sid_{i}^{S}, or sid_{i} when there is no concern of confusion
  • Participant list: plist_{i}^{S} is the list of participants which U_{i} believes are participating in the chat session S. When there is no ambiguity in the underlying session, we simply use plist_{i} notation.
  • 'key id is the serial number given to the P2P keys generated during the process of key exchange, is computed as Hash(U_{i}|y_{i}|U_{j}|y_{j}).
  • Ephemeral key list: klist_{i}^{S} is the list of ephemeral public key y_{j}=g^{{x_{j}}}'s of all participants which U_{i} believes they are using in the chat session S. When there is no ambiguity in the underlying session, we simply use klist_{i} notation instead. We use the notaion of plist_{i}|klist_{i} to represent ordered concatenation of U_{i}|y_{i} pairs as in U_{1}|y_{1}|\dots |U_{n}|y_{n}. The order is assumed to be computable by all participants (lexicographically ordered using long term public key of participants, for example).
  • Session key of \Pi _{j}^{S} as seen by U_{i}: sk_{i}^{S} (or sk_{i}) is the session key of session S as computed by \Pi _{i}. It represents the cryptographic secret computed by AGKE, it can be a set of secrets. The essential defining factor is that it should become common knowledge for the session participants at the end of AGKE execution. Similarly we define subk_{i} to represent the subsession key
  • Accepted state: A party enters the accepted state if it has computed sk_{i}^{S} and has detected no errors in the protocol.
  • Partnered instances: Two instances \Pi _{i}^{S} and \Pi _{j}^{S} are considered partnered if and only if both instances have accepted sid_{i}=sid_{j} and plist_{i}=plist_{j}.
  • A correct AKGE algorithm is an AKGE which, when all \Pi _{i}^{S} instances of AKE algorithm are initiated with access to a network which correctly forwards all messages without modification, all participants ultimately are partnered and all compute equal sk_{i}^{S}’s.

When underlying session are not considered we may omit the super script \_^{S} from all above notations.

VI. Threat Models and Adversarial Goals

Adversarial models are explained as a game, in which the adversary's possibilitiy of winning the game should be considered in terms of their ability to break the cryptographic primitives.

Accordingly to the requirements discussed in Section IV, it is necessary to examine the algorithm in terms of following threat cases:

  1. Deniable Authenticated key exchange (including a forward secrecy adversary)
  2. Message origin authenticity
  3. Confidentiality
  4. Transcript consistency

The following sections will define adversarial scenarios which represent the above threats.

Deniable Authenticated Key Exchange Adversary

Following the approach in [BoSt06] the model is divided into two adversaries: Authenticated Group Key Exchange and the Deniability Adversary.

As deniability is not our primary focus, we wil consider a weaker deniability adversarial model, which limits possible input similarly to the limitations considered by [GKR06]. This provision would disallow an input from the 'judge' and therefore saves an extra round of communication within the protocol.

Because he t(n+1)sec protocol runs a peer-to-peer key exchange and establishes parallel deniable authentication, we use the adversarial model from [ACMP10] for authenticated group key exchange. This ensures the security of both group and peer-to-peer keys independently. The protocol also takes advantage of "single round computation of a subgroup key". Meaning that when a participant leaves the session remaining participants can re-establish a (sub)session with only one round of communication. In this circumstance, the model must also consider an adversary's attack against the subgroup key.

We do not attempt to model resistance against internal key compromise impersonation (KCI) as defined [GBNM11].

Authenticated Key Exchange Adversary

Adversarial power

The following set of functions model the AKE adversarial threats. The adversary for the authenticated key exchange can mount an attack through a sequence of call to the functions, outlined below. The limitation on the order and condition of calling these functions is defined per adversary. We will re-use these definitions to demonstrate similar routes for other adversaries considered by the threat models in later sections.

  • Execute(plist): asks all parties in the plist to run (a new) AGKE protocol and {\mathcal  {A}} will receive the execution transcript, i.e.{\mathcal  {A}} can eavesdrop.
  • Send(\Pi _{i}^{S},m)/(U_{i},m) sends a message m to the instance \Pi _{i}^{S}. We assume that m contains information to identify the sender U_{j}. {\mathcal  {A}} will receive the execution transcript. Specifically, by sending plist messages it forces U_{i} to initiate \Pi _{i}^{S}.
  • SKE(\Pi _{i}^{S},spid_{i}): asks \Pi _{i}^{S} to compute the subgroup key for the spid_{i} subsession. In response, \Pi _{i}^{S} will either send a message or compute the subgroup key k_{{spid_{i}}} depending on the state of \Pi _{i}^{S}. This can be invoked only once per input.
  • RevealGK(\Pi _{i}^{S}): \Pi _{i}^{S} gives sk_{i} to {\mathcal  {A}}_{a} if it has accepted (as defined in Definition III.3).
  • RevealSK(\Pi _{i}^{S},T): \Pi _{i}^{S} gives the subk_{i}^{T} to {\mathcal  {A}}_{a} if it has been computed for subsession T.
  • Corrupt(U_{i}): U_{i} gives its long term secret key to {\mathcal  {A}}_{a} (but not the session key).

Adversary's challenges

The following set of functions model the adversary's challenges. These reveal either a random value or a key. The adversary's advantage in distinguishing the cases should be translatable into an attack against the GDH primitive for the protocol to be considered secure.

  • TestGK(\Pi _{i}^{S}): To the ultimate goal of challenging the confidentially of sk_{i}, {\mathcal  {A}} can run TestGK(\Pi _{i}^{S}) against U. As a the result a random bit b is chosen, if b=1 then {\mathcal  {A}}_{a} is given sk_{i} the session key, otherwise a random value from the same probability distribution is given to {\mathcal  {A}}. Obviously, this can only be invoked once and only on accepted participants.
  • TestSK(\Pi _{i}^{S}): To the ultimate goal of challenging the confidentially of subk_{i}^{T}, {\mathcal  {A}} can run TestSK(\Pi _{i}^{S}) against U. The result depends on a a random chosen bit b, if b=1 then {\mathcal  {A}} is given subk_{i}^{{T}} the subsession key, otherwise a random value from the same probability distribution is given to {\mathcal  {A}}.

Definition of Adversaries and their advantages

The following terminology is useful in simplifying the elimination of trivial adversarial threats.

Definition VI.1 Accepted \Pi _{i}^{S} is fresh if none of the following is true:

  • RevealGK(\Pi _{j}^{s}) for U_{j}\in plist.
  • Corrupt(U_{j}) invoked for any U_{j}\in plist before any Send(\Pi _{i}^{S},.).

Definition VI.2 A pair of \Pi _{i}^{S},spid_{i}^{S} is fresh, if \Pi _{i}^{S} is accepted and if none of the following is true:

  • RevealSK(\Pi _{j}^{s},spid_{i}^{S}) for U_{j}\in plist.
  • Corrupt(U_{j}) invoked for any U_{j}\in plist before any Send(\Pi _{i}^{S},.).

Definition VI.3 An AKE Adversary for the join key agreement {\mathcal  {A}}_{{join}} is a probabilistic polynomial time algorithm (ppt) which can invoke all the functions given above with a condition that the TestGK is invoked at least once against a fresh instance \Pi _{i}^{S} which stays fresh until the end of the game. The game ends when {\mathcal  {A}}_{{join}} outputs its guess for b. We say a key exchange protocol is secure if the following function is negligible:

max_{{\forall {\mathcal  {A}}_{{join}}}}|2Pr(Output({\mathcal  {A}}_{{join}})=b)-1|

Similarly we define {\mathcal  {A}}_{{leave}} the Adversary leaving the session:

Definition VI.4 An AKE Adversary for the leave key agreement {\mathcal  {A}}_{{leave}} is a ppt which can invoke all the functions given above with the condition that one of the invocations of TestSK is invoked against a fresh instance (\Pi _{i}^{S},spid_{i}) which stays fresh till the the end of the game. The game ends when {\mathcal  {A}}_{{join}} outputs its guess for b for that invocation. We say a key exchange protocol is secure if the following function is negilgible:

max_{{\forall {\mathcal  {A}}_{{leave}}}}|2Pr(Output({\mathcal  {A}}_{{leave}})=b)-1|

Forward Secrecy Adversary

We do not define an independent forward secrecy adversary. Forward secrecy can be derived by resistance against the confidentiality adversary as well incorporating a forward secure key exchange as described in [GBN10]. The adversaries of Definition VI.3 and VI.4, are able to Corrupt users after the communication of DH secrets. Therefore they can trivially break an AKE without forward secrecy. In this sense, the resistance against forward secrecy adversary is included in AKE adversarial model.

Deniability Adversary

We use the deniability adversary of [BoSt06], however following the path of [GRK06], we limit the security input of the deniability adversary in order to prevent the adversary from receiving input from the judge.

'Definition VI.5 A Deniability Adversary {\mathcal  {A}}_{{deny}} with bound q_{c} and security input Aux is a ppt algorithm which can invoke Send and Reveal as desired and Corrupt as many as q_{c} times. At the end, {\mathcal  {A}}_{{deny}} will output a transcript T_{{{\mathcal  {A}}_{{deny}}}}(Aux).

Definition VI.6 For each {\mathcal  {A}}_{{deny}}, we define a simulator {\mathcal  {S}}_{{deny}}, is a ppt algorithm which receives the same input as {\mathcal  {A}}_{{deny}}. It can invoke Corrupt q_{c} times in addition to Send and Reveal but only against corrupted instances. It terminates by outputting a transcript T_{{{\mathcal  {S}}_{{deny}}(Aux)}}.

Definition VI.7 A deniability judge {\mathcal  {J}} with security input Aux is a ppt algorithm which can invoke arbitrary number of deniability adversaries {\mathcal  {A}}_{{deny}} with security input Aux. On each execution of {\mathcal  {A}}_{{deny}} a corresponding {\mathcal  {S}}_{{deny}} runs with the same input. At the end a confidential random bit b is generated, and either T_{{{\mathcal  {A}}_{{deny}}}}(Aux) or T_{{{\mathcal  {S}}_{{deny}}}}(Aux) is presented to {\mathcal  {J}} based on whether b=1 or 0 respectively.

Definition VI.8 We call a Group AKE deniable with respect to input set Aux, if the following advantage is negligible: max_{{\forall {\mathcal  {J}}}}|2Pr(Output({\mathcal  {J}},Aux)=b)-1|

Similar to [GRK06], we claim that the AKE presented in this paper is deniable when Aux is equal to the set of valid messages eavesdropped by {\mathcal  {A}}_{{deny}} during other sessions. This, in particular, excludes a transcript computed by {\mathcal  {J}} such as a group element whose discrete logarithm is only known to {\mathcal  {J}} (This means {\mathcal  {A}}_{{deny}} is given g^{a} but is unaware of a).

Secure Multiparty Channel Adversary

The desirable way to define an adversary for a multiparty chat session is a secure channel model similar to the two-party secure channels described in [CaKr01] and [KPW13]. However, defining such a model is outside of our current scope. It is desirable to later improve the security of the protocol bu considering such a model at a later stage. At present, we use a per message model for confidentiality and origin authenticity.

Message Origin Authentication Adversary

As each participant executes a sign and encrypt function before sending their authenticated ephemeral signing key, the message origin adversary model is based on a typical adversary for a signature scheme such as the one presented in [PVY00].

Adversarial power

In addition to adversarial functions defined in section 1.1.1. we must define the following function to allow for the adversary using the chosen-message attack.

  • MakeSend(\Pi _{i}^{S},\Pi _{j}^{S},m) causes the \Pi _{i}^{S} to sign and send a valid message m to instance \Pi _{j}^{S}. {\mathcal  {A}} will receive the transcript including the signature.

Definition of Adversary

Definition VI.9: Message Origin Authentication Adversary {\mathcal  {A}} is a polynomial time algorithm which has access to the Corrupt, Send, Reveal and MakeSend functions. The output of the algorithm should be a message m sent to instance \Pi _{j}^{S}. The scheme is secure against Message Origin Adversary if the probability in which \Pi _{j}^{S} believes that m has originated from an uncorrupted participant U_{i} is negligible.

Message Confidentiality Adversary

The goal of adversary {\mathcal  {A}}_{{conf}} is to read, at least, part of the communications transcript during the session.

Adversary's challenges

The following set of functions model the confidentiality adversary's challenges. These reveal either a random value or an encrypted message. The adversary's advantage in distinguishing the cases should be translatable into an attack against the block cipher, AES in this case.

  • TestM(\Pi _{i}^{S},m): To the ultimate goal of challenging the indistinguishibility of E(m)>, {\mathcal  {A}}_{{conf}} can execute TestM(\Pi _{i}^{S},m) against U_{i}. As a result a random bit b is chosen, if b=1 then {\mathcal  {A}}_{{conf}} is given E_{{s_{k}}}(m)<math>,theencryptedmessage,otherwisearandomvaluefromthesameprobabilitydistributionisgivento<math>{\mathcal  {A}}_{{conf}}.

Definition of Adversaries and their advantages

Definition 1 A Confidentiality Adversary {\mathcal  {A}}_{{conf}} is a ppt which can invoke all the functions given in sections IV.1.1.1 and IV.1.1.3 with the condition that one of the invocations of TestM is invoked against an instance \Pi _{i}^{S} where all instances in session s are fresh and stay fresh till the end of the game. The game ends when {\mathcal  {A}}_{{conf}} outputs its guess for b for that invocation. We say that the protocol is secure if the following function is negligible:

max_{{\forall {A}_{{conf}}}}|2Pr(Output({\mathcal  {A}}_{{conf}})=b)-1|

Consistency Adversary

In (n+1)sec protocol, we attempt to ensure the consistency among participants all along the session incrementally, i.e. assuring consistency after receiving each message in a timely manner. However, we do not model the incremental aspect of consistency into the adversarial model, for the sake of simplicity.

Definition 1 Transcript Consistency Adversary {\mathcal  {A}}_{{cons}} is given the ability to invoke all functions in sections IV.1.1.1 and IV.1.1.3. We say the protocol is secure against Consensus Adversary if at least two uncorrupted accepted instances \Pi _{i}^{S},\Pi _{j}^{S} possess the transcripts chain TransChain_{{\Pi _{i}^{S}}}(l)\neq TransChain_{{\Pi _{j}^{S}}}(l) and they believe they have the TransChain_{{\Pi _{i}^{S}}}(l)=TransChain_{{Pi_{j}^{S}}}(l)withnon-negligibleprobability.Fordefinitionof<math>TransChain_{{\Pi _{i}^{S}}}(l) see Section VII.4.1.

VII. Protocol High Level Design

To achieve the security properties listed in Section IV, we break the protocol into the following sub-protocols:

  1. Deniable authenticated signature key and session key exchange, where participants deniably authenticate each other and agree on session key(s), while also exchanging ephemeral signing keys
  2. Communication, where parties send authenticated confidential messages
  3. Transcript consistency verification, where parties verify that all have received and seen an identical transcript in the same order, since the start of the chat session after receiving each messages.

Our choice of sub-protocols for (n+1)sec followed suggestions made in [BGB04] and [GUVGC09], except where there has been a practical or security-related reason to deviate from those recommendations.

In the following section we briefly describe our choice of the sub-protocols for each of the required tasks for a multi-party chat session.

VII.1 Design of Deniable Authenticated Signature Key Exchange

We have chosen our deniable signature key exchange protocol following the conclusions in [Gun13b] - by identifying a secure key exchange protocol that satisfies our needs. We then apply the triple Diffie-Hellman authenticated exchange to grant it properties of deniability [Ma13]. Subsequently, one can apply the same approach presented in [Gun13b] to communicate ephemeral signature keys during the key establishment process. However, for efficiency, we use the same ephemeral Diffie-Hellman private and public values used to deniably authenticate users and generate secret shares to produce ephemeral signatures.

For the choice of the base authenticated key exchange protocol, we suggest a variant based on [ACMP10]. The rationale for the choice is laid out as follows:

  • The base design of the protocol in [ACMP10] is the same as the base for [BVS05] (recommended by [Gun13a]). However, the protocol presented in [ACMP10] is simpler.
  • [ACMP10] offers a peer-to-peer key exchange with no extra rounds, if needed.
  • [BVS05] and [ACMP10] are superior to the widely studied [BCPQ01] and its dynamic variation [BCP01] both in security and performance (O(1) rounds).
  • [BVS05] has been suggested by [Gun13b] for the reason described in [Gun13a]. We believe that the new deniable authentication approach, as it is similar to the SKEME protocol, satisfies the properties of deniability which [BVS05] considered crucial aside from the cooperating judge.
  • Security analysis of [GBNM11] and [BCGNP08] has found that [BVS05] is provably secure against all attacks (including the insider attacks) that the papers consider.
  • It is a two-round protocol and hence offers competitive efficiency considering the security property that it provides.
  • [ACMP10] only needs one round of key re-agreement in the case of a participant leaving the chat, while [BVS05] enforces re-computation of Diffie-Hellman ephemeral keys and hence needs a minimum of two rounds plus overhead of re-authenticating the new ephemeral keys. This can significantly improve the efficiency of casual chat sessions where participants frequently enter and exit the chat.
  • Although the Schnorr based algorithm suggested in [BVS05] satisfies a more comprehensible deniable model, triple Diffie-Hellman authenticated key exchange only needs two rounds of communication and can be done alongside the key agreement steps, while the Schnorr based algorithm of [BVS05] needs four rounds.
  • Although key exchange algorithms based on the standard model are considered theoretically more secure than those based on the random oracle model, there has been no proposal for a 2-round protocol in the standard model that promises forward secrecy. Therefore, due to the importance of usability and efficiency in our approach, we opted to for a ROM based protocol such as described by [BVS05] and [ACMP10].

VII.1a Sharing a secret among the group

All AGKE descriptions take the necessary steps to share a common secret confidentially among the group members along side other operations such as authentication and insuring partnership. To insure forward secrecy these methods mostly rely upon a P2P Deffie-Hellman key exchange. Most AGKE descriptions rely on sharing an equation and solving a specific linear system described in IX.4.

We abstract this step as GroupEnc/GroupDec primitive, to allow for alternative designs which do not interact with the rest of the protocol and might offer other benefits. For example the "Naive peer-to-peer" primitive IX.4 trades simplicity and generalizability (to a broadcast scheme c.f. Section VII.2) for bandwidth consumption.

VII.3 Message Authentication

As message authentication needs to be resistant to malicious insiders, following the outline of [GUVGC09], (n+1)sec signs each message using a public key signature scheme. The messages are signed with the ephemeral key of the sender. The authenticity of the origin can be verified by the public ephemeral key of the party distributed during the key exchange period.

VII.4 Transcript Ordering and Consistency

Since each message sent by any one participant is signed by the ephemeral private key generated for that specific session, it is not possible for the internal or external adversary to forge a message on behalf of an uncorrupted participant.

However, if the adversary is controlling the network structure, denial or delay of service is always possible. The consistency of the transcript (i.e. all participants see the same transcript in the same order) relies on the means of transport guaranteeing reliable delivery, with a single order, to every participant. In other words, we are verifying the reception of the message by the intended recipients.

By assuring transcript consistency, we also preventing U_{i} from sending different messages to U_{j}, U_{k} while they believe they are seeing the same conversation. In absence of transcript consistency, when a central server is managing the chatroom, this attack requires U_{i} to conspire with server, which is permeable in (n+1)sec threat model in accordance with the definition of transcript consistency in [GUVGC09].

The protocol offered in this document examines the transcript for such consistency. In the case that the underlying transport fails to provide this level of consistency, clearly the consistency test will fail. In this sense, failure of consistency does not distinguish between malicious activities or the absence of a reliable transport.

(n+1)sec performs transcript authentication whenever a message is received. This is to guarantee consistency and protect the protocol against the transcript consistency attack. The procedure is similar to the procedure described in [GUVGC09], with two major differences:

  • We require additionally that message order be preserved for the following reasons:
  1. XMPP, as the main protocol considered for this design, delivers messages to all clients in the same order.
  2. The (n+1)sec protocol detects if the adversary has manipulated the order of the messages rather than only dropping undesirable messages
  3. It is simpler to authenticate an ordered transcript compared to an unordered transcript.
  • We also require that each participant updates all other participants about their view of the session transcript every time they send a message, along with requiring heartbeat, this ensures that participants are aware whether or not they are all seeing the same transcript during the session.

There are some cases where XMPP can fail our reliability assumption. In such cases, our consistency checks will fail. More advanced end-to-end recovery techniques are able to rescue such a scenario. We do not specify such techniques currently, though later versions of the protocol may rectify this.

Definitions and assumptions

Transport assumption: We assume the central server reliably delivers messages to everyone, including the original sender, in the same order.

Definition Each message M (sent after session S has been established) has an implicit server-sequence-number seqnum(M), a receive-parent: parent(M) (or recv-parent) the seqnum of last message the sender has received before sending M and a sender-sequence-number own-seqnum(M). We interchangeable use m when refering to both a message and its seqnum.

Once a message M with seqnum m is received by instance \Pi _{i}^{S} from the server (including participants own messages sent), a TranscriptChain_{i}^{S}[m] may be calculated recursively as follows:

TrascriptChain_{i}^{S}[m]:=(M,Hash(TranscriptChain_{i}^{S}[m-1]))

(we define TrascriptChain[0] = (sk^S_i, sid_i))

A new message M contains p the seqnum of recv-parent of m, Hash(TranscriptChain_{i}^{S}[p]) and own-seqnum(M).

  • We say instance \Pi _{i}^{S} has accepted message m if it has been received by \Pi _{i}^{S}, then decrypted-verified.
  • We say instances \Pi _{i}^{S} and \Pi _{j}^{S} have reached mutual consistency for message m if both accepted message m and have calculated the same hash of TranscriptChain(m) and verified H_{j}(TranscriptChain_{i}^{S}[m]))==H_{i}(TranscriptChain_{i}^{S}[m]).
  • We say session S has reached consistency on message m, if all instances \Pi _{i}^{S},\Pi _{j}^{S}\in plist^{S}, \Pi _{i}^{S} and \Pi _{j}^{S} have reached mutual consistency.

Server order

All clients see the same message order from the server. All messages are sent to all users. Aside from the presence messages (messages which indicate a user is joining or leaving a chatroom or if they have been inactive for a long time) sent by the server, messages are sent by users.

All messages in a room have a unique sequence number (0, 1, ...). We assume that the server is unaware of sequence numbers (e.g. XMPP MUC); clients must allocate them implicitly when receiving messages.

VIII. (n+1)sec Protocol: Step by Step

In this section we present the (n+1)sec protocol in algorithmic format. All user IDs should be considered the modulo number of participants in the room.

Deniable authentication is derived from the Triple Diffie-Hellman algorithm presented in [Sys14]. Joining the room is a variation of the two-round mBD+P protocol presented in [ACMP10] where the authentication step has been made deniable. Leaving the room is the one-round mBD+S from [ACMP10].

VIII.1 Schematic view of the key exchange

The protocol computes a unified session key for all participants. This imposes, in particular, the necessity that all plist_{i}' is identical for all participants.However, as consistent view is part of (n+1)sec security model, it does not impose extra limitation on the protocol. For more information please see Appendix B: Participatory vs individually independent computation of group keys.

For simplicity, group operation is written multiplicatively (even though it is actually an elliptic curve point operation traditionally represented by addition).

Whenever our design deviates from [ACMP10], it is marked in yellow. We have abstracted out the steps mentioned in [ACMP10] as an independent primitive in pink, however the resulting computation is identical with the one in [ACMP10] protocol:

Algorithm 1

Round Step Description Pseudo-code Type
1 1 Generate ephemeral DH private key x_{i}\leftarrow [0,order(g)] Computation
2 Generate DH key for BD, Triple DH and Signature y_{i}\leftarrow g^{{x_{i}}} Computation
3 Broadcast User identity and the DH key (U_{i},y_{i}) Broadcast
2 4 Compute Session Id sid_{i}\leftarrow (U_{1}|y_{1}|\dots |U_{n}|y_{n}) Receive
5 Generate Triple Diffie-Hellman P2P keys k_{{i,j}}\leftarrow H({y_{j}}^{{LSK_{{U_{i}}}}},LPK_{{U_{j}}}^{{x_{i}}},y_{j}^{{x_{i}}})\;\forall j\neq i Computation
6 Generate key confirmations kc_i \leftarrow (H(k_{i,1}, U_1),\dots,H(k_{i,n}, U_n)) Computation
7 Generate secret shares z'_{i}\leftarrow (H(k_{{i,j}},sid_{i})forj\in \{1,\dots ,n\}) Computation
8 Encrypt shares z_{i}\leftarrow GroupEnc(k_{{i,j}}forj\in \{1,\dots ,n\},z'_{i}) Computation
9 Sign identity, shares \sigma _{i}\leftarrow Sign_{{x_{i}}}(U_{i},z_{i},sid) Computation
10 Broadcast encrypted shares and confirmation (U_{i},z_{i},\sigma _{i},kc_{i}) Broadcast
- 11 Check validity of key confirmation H(k_{{j,i}},U_{i}){\stackrel  {?}{=}}kc_{j}[U_{i}]\;\forall j\neq k Receive
12 Check signatures Verify_{{y_{i}}}(\sigma _{j})\;\forall j\neq i Computation
13 Check Session Ids sid_{j}{\stackrel  {?}{=}}sid_{i}\;\forall j\neq i Computation
14 Generate session key sk_{{i}}\leftarrow H(GroupDec(k_{{i,l}}\forall l,z_{j})\forall j,sid_{i})=H(z'_{1},\dots ,z'_{n},sid_{i}) Computation

Triple Diffie-Hellman authentication

(n+1)sec uses a varient of Triple Diffie-Hellman (TDH) protocol also employed in Textsecure protocol [Mo13] to carry on mutual deniable authentication as well as peer-to-peer secret key exchange. It can be seen as a variation of [SoKi00] key exchange, however, unlike SoKi00], as it does not multiply all three DH secrets and therefore is not suspticble to attacks mentioned in [BoMa10].

By using TDH secret both in p2p key as well as in key confirmation step, (n+1)sec both implicitly and explicitly authenticate the peers.

In Algorithm 1, TDH and the original group key exchange from [ACMP10] has been combined to provide a deniable authenticated group key exchange. Here, we single out TDH Algorithm 1.1 for better presentation of the protocol for the reader.

Algorithm 1.1 Triple Diffie-Hellman between U_{i} and U_{j}

Round Step Description Pseudo-code Type
1 1 Generate ephemeral DH private key x_{i}\leftarrow [0,order(g)] Computation
2 Generate ephemeral DH public key y_{i}\leftarrow g^{{x_{i}}} Computation
3 Broadcast User identity and the DH key (U_{i},y_{i}) Broadcast
2 4 Receive other party id and ephemeral DH public key (U_{j}|y_{j}) Receive
5 Generate Triple Diffie-Hellman P2P keys k_{{i,j}}\leftarrow H({y_{j}}^{{LSK_{{U_{i}}}}},LPK_{{U_{j}}}^{{x_{i}}},y_{j}^{{x_{i}}})\;\forall j\neq i}} Computation
6 Send key confirmation to other party kc_{i}\leftarrow H(k_{{i,j}},U_{j}) Broadcast
- 7 Receive and Check validity of key confirmation kc_{j}{\stackrel  {?}{=}}H(k_{{j,i}},U_{i}) Receive

GroupEnc and GroupDec functions

For the high level design of the protocol we do not specify the primitives for GroupEnc and GroupDec used in steps 8 and 14 of Alogrithm 1 as a part of the protocol, as we do not specifies the Hash function and the block cipher. We explain their property here. We choose a candidate in section IX.4.

The GroupEnc and GroupDec functions are primitives which are called collectively by all instances involved in the session and are supposed to satisfies the following goal:

Definition: Let {\mathcal  {S}}:=\{U_{1},...,U_{n}\} and for each i,j, let k_{{i,j}} be a secret shared between and only between U_{i} and U_{j}. The goal of group {\mathcal  {S}} is that:

  1. Each member of group U_{i} to generate and share a secret z'_{i} among the member of group G using public channel {\mathcal  {C}}.
  2. z'_{i} remains unknown for any {\mathcal  {A}}\not \in G eavesdropping the channel {\mathcal  {C}}.

To this end each member U_{i} compute z_{i}:=GroupEnc(k_{{i,j}}forj\in \{1,...,n\},z'_{i}) and broadcast z_{i} on {\mathcal  {C}}. Later on when U_{i} receives all z_{j}. It recovers all secrets z'_{i} by computing GroupDec(k_{{i,j}}forj\in \{1,...,n\},z_{i}).

(n+1)sec key exchange vs original Flexible Group Key Exchange of [ACMP10]

Although in higher level view of (n+1)sec we generalized the process of key exchange using GroupEnc/GroupDec abstraction, at lower level our choice of primitive for this functions make the group key computation processes of (n+1)sec and the original key exchange algorithm the same. Hence, the steps marked pink in Algorithm 1, only differ in from [ACMP10] but not in result.

(n+1)run a deniable mutual authentication protocol along side with the key exchange protocol, this results in communicating extra key confirmation data along side of other data exchanged during the course of running the protocol. As we will show in the proof, these data has effect on the usual run of the algorithm.

The only step that (n+1)sec runs differently compare to the original algorithm (beside generating extra data), is computation of mutual secret, between U_{i} and U_{j}. In original, algorithm it is simply g^{{x_{i}}}{x_{j}}. In (n+1)sec, it is the triple DH secret H({y_{j}}^{{LSK_{{U_{i}}}}},LPK_{{U_{j}}}^{{x_{i}}},y_{j}^{{x_{i}}}). We will prove that this change does not compromise any of the protocol proprieties.

The main difference between the two key exchange algorithms is in the key used for signature. In original algorithm, parties use their long term private key to sign their contribution, while in (n+1)sec they use their ephemeral keys. However, because the ephemeral keys has been authenticated before used for verification, we prove that the authenticity of signatures in both algorithms are equivalent under CDH assumption.

VIII.2 Chatroom Setup

In almost any practical case, participants join the chat sequentially. It is assumed that multiple participants cannot join simultaneously. For the sake of efficiency one can adjust the implementation to have a threshold time to wait and thus start a chat with more participants. However, this makes the implementation significantly more complicated without any evident efficiency benefit.

Therefore, our assumption is that a secure chat is always set up when a participant starts the chat room. Additional participants would be added sequentially using Algorithm VIII.3, as they enter the chat. Algorithm 1 describes the chat room setup protocol.

Algorithm 2

Description Pseudo-code Type
Generate ephemeral DH private key of the room initiator x_{i}\leftarrow [0,order(g)] Computation
Generate DH key for BD, Triple DH and Signature y_{i}\leftarrow g^{{x_{i}}} Computation
Set participant list plist\leftarrow [U_{i}] Computation

VIII.3 Join

Joining a chat involves two different procedures: the Join procedure, described in Algorithm 2, which runs on the new participant’s instance, and an Accept New Participant Procedure, described in Algorithm 3, which runs on the clients of participants that are already in the chat.

When a new participant U_{{n+1}} joins the chat, current participants can still use their established authenticated ephemeral public key (to derive the sessionKey_{{new}} and as their signature verification key). Confidentiality of sessionKey_{{old}} is guarded against the new participant by Diffie-Hellman key shares hashed alongside the session id (which is dependent on the list of participants). The new participant cannot combine the old and new shares to recover sessionKey_{{old}}. The fact that old participants do not need to compute new ephemeral keys (and re-verify their ephemeral identities) decreases the computational complexity of the protocol.

The new participant needs to authenticate everybody already in the room and hand them their ephemeral key. All the parties already in the room only need to authenticate the new participant and need to send to them their ephemeral DH key. These procedures are described in Algorithm 3 and 4. After initial authentication step, all parties follow the same procedure to initiate a new session following Algorithm 5.

Authentication Step for new Joining party

Algorithm 3

Description Pseudo-code Type
Generate ephemeral DH private key x_{i}\leftarrow [0,order(g)] Computation
Generate DH key for BD, Triple DH and Signature y_{i}\leftarrow g^{{x_{i}}} Computation
Broadcast User identity and the DH key (U_{i},y_{i}) Broadcast
Receive other users' id/key plist_{i}|klist_{i}\leftarrow (U_{1}|y_{1}|\dots |U_{n}|y_{n})\cup (U_{i},y_{i}) Receive
Generate Triple Diffie-Hellman P2P keys k_{{i,j}}\leftarrow H({y_{j}}^{{LSK_{{U_{i}}}}},LPK{U_{j}}^{{x_{i}}},y_{j}^{{x_{i}}}) Computation
Generate key confirmations kc_{i}\leftarrow ((U_{1},H(k_{{i,1}},U_{1})),\dots ,(U_{n},H(k_{{i,n}},U_{n}))) Computation

After this step joining user will proceed to "initiate new session" by Algorithm 5.

Authentication Step for parties in the room

For other participants to a accept a new participant only, the authentication step is different. After current participants authenticate the new user, they proceed to update session.

Algorithm 4

Description Pseudo-code Type
broadcast all user's identities (U_{1}|y_{1}|\dots |U_{n}|y_{n}) Broadcast
Receive other users' id/key and update participant list (plist_{i}|klist_{i})\cup (U_{j}|y_{j}) Receive
Generate Triple Diffie-Hellman P2P key for the new participant k_{{i,j}}\leftarrow H({y_{j}}^{{LSK_{{U_{i}}}}},LP_{{U_{j}}}^{{x_{i}}},y_{j}^{{x_{i}}}) Computation
Generate key confirmations kc_{{i,j}}\leftarrow (U_{i},H(k_{{i,j}},U_{i})) Computation

After this step users will proceed to "initiate new session" using Algorithm 5.

Initiate new session

Algorithm 5

Description Pseudo-code Type
Compute Session Id sid_{i}\leftarrow H(U_{1}|y_{1}|\dots |U_{n}|y_{n}) Computation
Cancel any pending request for establishing a session with the same Id AxeNewSessionRequestTimer(sid_{i}) Computation
Generate secret shares z'_{i}\leftarrow (H(k_{{i,j}},sid_{i})forj\in \{1,\dots ,n\}) Computation
Encrypt shares z_{i}\leftarrow GroupEnc(k_{{i,j}}forj\in \{1,\dots ,n\},z') Computation
Sign identity, shares \sigma _{i}\leftarrow Sign_{{x_{i}}}(U_{i},z_{i},sid) Computation
Broadcast key shares and confirmation (if any) (U_{i},z_{i},\sigma _{i},kc_{i}) Broadcast
Receive other user(s)' key shares and confirmation of unauthenticated users or Time out Wait to Receive (U_{j}|z_{j},\sigma _{1},kc_{{ji}}) for U_{j} unauthenticated or Timeout by(2\times BROADCAST_LATENCY+INTERACTION_GRACE_INTERVAL, Drop inactive users, queue a new session request) Receive
Check validity of key confirmation of unauthenticated users kc_{j}[U_{i}]{\stackrel  {?}{=}}H(k_{{i,j}},U_{i}) for unauthenticated U_{j} Computation
Check signatures Verify_{{y_{i}}}(\sigma _{j}) for j in {1,...,n} Computation
Check Session Ids sid_{j}{\stackrel  {?}{=}}sid_{i}\;\forall j\neq i Computation
Generate session key sk_{{i}}\leftarrow H(GroupDec(k_{{i,l}}\forall l,z_{j})\forall j,sid_{i})=H(z'_{1},\dots ,z'_{n},sid_{i}) Computation
Initiate the TranscriptChain TrascriptChain_{i}^{S}[0]\leftarrow (sk_{i}^{S},sid_{i}) Computation
Initiate the last_sender_seq_num array last\_sender\_seq\_num\leftarrow (0,...,0) Computation
Initiate the own_seq_num to 0 own\_seq\_num\leftarrow 0 Computation

Sending and receiving messages while joining is in progress

In situations where a prolonged joining process (due to connection problems or malicious activities) has an adverse effect on the user experience, it might be desirable to enable that joining users can communicate with the parties in the room, while maintaining minimum assurances of authenticity, confidentiality, forward secrecy, as well as consistency only among participants.

Consistency aspects of (n+1)sec, both for the room view (plist) and for the transcript, are reached through group agreement. However, there are times when group agreement may be hard or impossible to reach either due to latency in a single participant's connection or due to a single participant broadcasting incorrect confirmation data (such as wrong plist, sid, key share, etc).

We offer an extension to the (n+1)sec protocol to tackle this problem during the joining process. When a new participant joins the room, they send their DH key shares to the other participants. The other participants send their ephemeral key in return. They then send their key confirmation and key share. If this extension is to be considered, as soon as each user receives a key confirmation from another user, who is not currently part of the session, (n+1)sec displays a message highlighting the fact that although the user is not part of the session part of the conversation (from users' who confirmed the new user's identity) is being shared with them (through P2P encryption using the key derived from DH Key). The protocol, however, does not honour their input in the consistency check until a new session including the new user is set up. Each client can decide whether to disable this option.

The user remains in the list of those not part of the current session, but receives the session messages until a new session is set up. Similarly, when a user receives a message from a user who is not part of the session, (n+1)sec will decrypt the message and display it with a disclaimer that the user is not yet part of the session and that some participants may not receive the same message.

This is less secure model in which a room is a forwardly secure authenticated communication channel while a session is a subset of the room, which additionally offers a consistent view of the room and consistent messages among participants. The detail of the process is depicted in Secthoin VIII.5

VIII.4 Leave

Leaving a chatroom involves a message from a leaving party indicating its intention to leave which, as with all other messages, contains the hash of TranscriptChain and one procedure for those who are staying in the chatroom (Procedure Farewell) which is described in Table ''(n+1)sec''#Leave.

Farewell

Run by exiting user.

Algorithm 6

Description Pseudo-code Type
Send farewell message Send("Leaving!") Broadcast
Wait to receive hashes of TranscriptChain or Timeout Wait to Receive() or Timeout by((2 \times BROADCAST_LATENCY)+INTERACTION_GRACE_INTERVAL) Receive

Shrink

When the remaining participants receive the farewell message they need to reply with the Hash of TranscriptChain of the last message seen by the leaving user. They also need to re-run the one round key update algorithm. However, they only need a notice from the server that the user is leaving to initiate a subsession excluding the leaving user.

Additionally, failure to receive a heartbeat from a user will result in executing Algorithm ''(n+1)sec''#Shrink excluding users who did not update their key.

Algorithm 7

Description Pseudo-code Type
Send Hash of TranscriptChain of last message seen by leaving user Send(H(TranscriptChain_{i}^{S}[Parent(m_{{farewell}})])) Broadcast
Remove leaving user's id/key and update participant list (plist_{i}|klist_{i})\backslash (U_{j}|y_{j}) Computation

Users will proceed to "initiate new session" steps.

VIII.5 Secure Send and Receive

After the session key is established, participants will use Algorithms 5 and 6 to communicate securely.

On Send, the protocol checks the status of the new ephemeral Diffie-Hellman and key share using messages it receives from participants. It (re)sends any missing pieces. It also informs other participants which part of the key share has been received by the participant. This information is needed in order to enforce in-session forward secrecy. The metadata flag indicates if the message being sent only contains meta data (e.g. heartbeat) or actual user communication.

On Receive, the protocol updates who has seen which pieces of the key shares. The protocol also generates a new group key if the new key shares have been received from all participants. Those who have not updated their key shares eventually time out via their heartbeat interval.

VIII.5.1 (n+1)sec Message Structure

Every (n+1)sec message sent after establishment of a session has the following format:

   np1sec:3Base64EnocodedMessage:3

The Base64EncodedMessage is decoded as:

   sid, Encrypted part of the message

Encrypted message can be decrypted by the session key and has the following structure

   Signed message, Signature corresponding to the signed message

Signed Message consists of following parts

   sid, sender ID, User message, meta message, hash of TranscriptChain of the message, naunce

The "session ID" and the "sender ID" are prepended in part to address concerns of [Da01]. The nuance is a random 128 bit value, appended to prevent any possibility of replay or brute force attack.

User message is the plain text typed by user and handled to (n+1)sec by the chat client.

meta message contains a message has the following format

   meta_only  , ustate_1, ..., ustate_n, current_load

If meta_only flag is true then User message is ignored and client is informed not display anything

ustate_{i} flag = {0: sender has no key update from U_{i}, 1: sender has received a new ephemeral key from U_{i}, 2: user has received secret share from U_{i}}

   current_load = (load_flag, load)
   load_flag = 0 no load
   load_flag = 1 load contains new ephemeral public key from sender
   load_flag = 2 load contains new secret share from the sender

The message also include "hash of TranscriptChain" of parent of the message as "additional authenticated data".

H(TransciptChain[parent(m)])

Note that we send the entry in the chain indexed by parent(m) rather than m. This is because a hash may only be calculated once the subject is actually received back from the server (i.e. gets a sequence number). This differs from some other concepts of "message ID" that may be calculated locally.

(n+1)sec P2P Message Structure

Every (n+1)sec message sent after establishment of a session has the following format:

   np1sec:3Base64EnocodedMessage:3

The Base64EncodedMessage is decoded as:

   keyid, Encrypted part of the message

Encrypted message can be decrypted by the session key and has the following structure

   Signed message, Signature corresponding to the signed message

Signed Message consists of following parts

   keyid, sender ID, User message, naunce

The "Key ID" and the "sender ID" are prepended in part to address concerns of [Da02]. The nuance is a random 128 bit value, appended to prevent any possibility of replay or brute force attack.

User message is the plain text typed by user and handled to (n+1)sec by the chat client.

Send

Algorithm 8

Description Pseudo-code Type
prepend session id and sender id m\leftarrow (sid,U_{i},m) Computation
Generate new DH Key or new secret share if needed and append m\leftarrow (m,s) Computation
Increment own sequence number own\_seq\_num\leftarrow own\_seq\_num+1 Computation
Append the hash of the TranscriptChain, up to the parent of the message being sent m\leftarrow (m, H(H(parent(m)),H(TransciptChain_{i}^{S}[parent(m)-1])), parent\_id(m), own\_seq\_num) Computation
Generate a random nuance and append to the message m\leftarrow (m,rand(128bit)) Computation
Sign the message and append the signature m\leftarrow (m,Sign_{{x_{i}}}(m)) Computation
Encrypt e\leftarrow Enc_{{k_{{sid}}}}(m) Computation
Broadcast the message (sid_{i},e) Broadcast
Reset Heartbeat timeout timer ResetHeartbeatTimer() Computation
Set ACK timeout timer if the message has user content meta\_only{\stackrel  {?}=} False then ResetHeartbeatTimer() Computation

Receive

Algorithm 9

Description Pseudo-code Type
Decrypt message sid_{{rec}},sender\_id,m,s,h,parent\_id,sender\_seq\_num,sigma\leftarrow Dec_{k}(m) Computation
Check signature Verify_{{sender\_id}}(m,\sigma ) Computation
Compute message sequence number seqnum(m)\leftarrow ComputeSeqNum(m) Computation
Verify session id and transcript consistency and sender sequence number, issue a warning in case of failure sid_{i}{\stackrel  {?}{=}}sid_{{rec}}\; and \;h{\stackrel  {?}{=}}H(H(parent(m)),H(TranscriptChain_{i}^{S}[parent(m)-1])) and sender\_seq\_num{\stackrel  {?}{>}}last\_own\_seq\_nums[sender\_id] Computation
Update TranscriptChain if possible TranscriptChain_{i}^{S}[seqnum(m)]=(H(m),H(TranscriptChain_{i}^{S}[seqnum(m)-1])) Computation
Update sender sequence number record last\_own\_seq\_nums[sender\_id]\leftarrow sender\_seq\_num Computation
Update sender's ephemeral key or share secret y_{j}\leftarrow s\;{\textrm  {or}}\;z_{{j}}\leftarrow s Computation
If all users' share are received, generate session key sk_{{i}}\leftarrow H(GroupDec(k_{{i,j}},z_{j}\;\forall j),sid_{i},U_{j})\;\forall j\neq i Computation
Update ack timeout timer AxeAckTimeoutTimer(parent(m),sender_{i}) Computation
Update rekey timeout timer ResetRekeyTimeOut(sender_{i}) Computation
If the message has content set up ACK timer meta\_only{\stackrel  {?}=}True then SetACKTimer(m) Computation
return m If meta\_only{\stackrel  {?}{=}}False then return m Computation

Out of Session Send and Receive

Due to nature of the key exchange algorithm, (n+1)sec support confidential P2P communication. This in particular enables the user to share the conversation with joining user(s) who confirmed their identity to the user but have not established a session yet. It is worth mentioning that every session keeps a list future sessions to transition to this is equivalent to the list of confirmed but yet to join users. If the extension discussed in section VIII.3 is enabled it will make use of this list to implement the following changes:

  • When a user send a message Extended Send is invoked instead, it sends the message to the session using Send but also to the prospective participants, using P2P Send.
  • When a message is received, Extended Receive is called which check if the user has the correct key to decrypt the message. If the message is encrypted by session key and user has the session key then it calls the normal receive. If the message is encrypted by a p2p key that the user share, it calls P2P Receive. Otherwise, it simply ignores the message.

Algorithm 9.1 Extended Send

Description Pseudo-code Type
If we are part of a session id in the room call Send Send Broadcast
For all confirmed users not in session call P2P Send P2P Send Broadcast

Algorithm 9.2 Extended Receive

Description Pseudo-code Type
If m has session id call Receive if m has sid then Receive Computation
If m has key id, call P2P Receive P2P Send Computation

Algorithm 9.3 P2P Send

Description Pseudo-code Type
Prepend key id and sender id m\leftarrow (key\_id,U_{i},m) Computation
Generate a random nuance and append to the message m\leftarrow (m,rand(128bit)) Computation
Sign the message and append the signature m\leftarrow (m,Sign_{{x_{i}}}(m)) Computation
Encrypt e\leftarrow Enc_{{k_{{key\_id}}}}(m) Computation
Broadcast the message (key\_id,e) Broadcast

Algorithm 9.4 P2P Receive

Description Pseudo-code Type
Decrypt message key_{{id}},sender\_id,m,sigma\leftarrow Dec_{{k_{{key\_id}}}}(m) Computation
Check signature Verify_{{sender\_id}}(m,\sigma ) Computation
return m return m Computation

VIII.6 Reaching Consistency

The protocol provisions two procedures to reach consistency in different cases: (a) reaching consistency for arbitrary messages during the course of a conversation, and (b) reaching consistency when an instance \Pi _{i}^{S} leaves. Case (b) may be viewed as a special instance of case (a) plus the additional premise that \Pi _{i}^{S} must reach consistency as soon as possible (because they want to leave), and that they don't care about reaching consistency for any subsequent messages that they might receive after their final "farewell" message.

Reaching consistency for arbitrary messages during the course of a conversation:

Algorithm 10

Description Pseudo-code Type
Receive m with parent p from \Pi _{j}^{S} m\leftarrow seqnum(M),p\leftarrow parentnum(m) Computation
Compare hash of TranscriptChain_j[p] with own value of it, issue a warning if it fails. H(TranscriptChain_{j}^{S}[p]){\stackrel  {?}{=}}H(TranscriptChain_{i}^{S}[p]) Computation
Compute TranscriptChain^S_i[m] plist\leftarrow [U_{i}] Computation

Case (b): when an instance \Pi _{i}^{S} wants to part, they send a "farewell" message m which contains Hash(TranscriptChain_{i}^{S}[p]).

  • Everyone should include Hash(TranscriptChain_{j}[p]) in their re-key message
  • When \Pi _{i}^{S} reaches mutual consistency for p may leave or otherwise (if received hashes and their owns are non-matching) shows a warning.
    • \Pi _{i}^{S} won't have a chance to reach consistency for the messages receives after p

VIII.7 In-session Forward Secrecy

To ensure forward secrecy in long living chat sessions, (n+1)sec provides a session key update throughout the session. Each message sent to the session by each participant contains meta data described in #VIII.5.1 (n+1)sec Message Structure. Prior to sending any message, (n+1)sec determines the content of meta data, and piggy backs to that message according to the following algorithm:

Algorithm 10.1 Compute meta data

Description Pseudo-code Type
Initiate meta data with current state of knowledge of new ephemeral keys and secret shares meta\_data\leftarrow ustate_{i}[j] for all j in {1,...n} Computation
Include the new ephemeral key if participant U_{j} has not receive it If ustate_{i}[j]{\stackrel  {?}{=}}0 meta_data \leftarrow y_{{i_{{new}}}} Computation
If (all) participants have sent their ephemeral keys compute the shared secret If ustate_{{j}}[i]{\stackrel  {?}{=}}1 for all j

in {1,...n}, then meta\_data\leftarrow (meta\_data,GroupEnc(k_{{i_{j}}}forj\in \{1,\dots ,n\},z'))

Computation
Return meta data return meta_data Computation

VIII.8 Heartbeat and Timeout

Heartbeat is an empty message which contains only meta data. The meta data consists of information used to compute a new key and the most updated hash of transcript chain.

The protocol sends a heart beat only if the user has not sent any messages for a specific period of time.

The heartbeat is necessary to ensure three properties:

- Periodic transcript consistency check. - In session forward secrecy. - Freshness

To achieve these goals three time out periods are defined when heart beat sending is required. Additionally, we define an interval to model the latency in the underlying transport. These should be defined to cover common cases (e.g. 95th-percentile):

  • ACK_GRACE_INTERVAL: When \Pi _{i}^{S} a receives a non-empty message it needs to inform the group about the transcript update no later than ACK_GRACE_INTERVAL time. Therefore if \Pi _{i}^{S} f U_{i} does not send a message ACK_GRACE_INTERVAL seconds after receiving a non empty message,\Pi _{i}^{S} will send a heartbeat.
  • REKEY_GRACE_INTERVAL, to ensure in session forward secrecy, the protocol requires that each U_{i} updates their DH ephemeral key as well as group key. After a session is established or it was rekeyed, each \Pi _{i}^{S} needs to send its new DH ephemeral key no later than REKEY_GRACE_INTERVAL. Therefore if \Pi _{i}^{S} has not sent any message by that

period of time, it issues an empty message. Similarly after receiving all ephemeral keys from all participants, \Pi _{i}^{S} needs to send its secret for computation of new key no later than REKEY_GRACE_INTERVAL.

  • INTERACTION_GRACE_INTERVAL, to ensure establishment of a session in timely manner, when immediate contribution of participants is required (for example sending key confirmation, contribution to the session secret), this values indicate that how long an active participants should wait till it decide to drop the non-contributing inactive participants from the participant list.
  • BROADCAST_LATENCY: Modelling the amount of time which a message takes to reach the server and broadcast to the other clients. It should be based on the transport considered.

Failure to heartbeat and inactivity timers

Whenever, a message m is received a timer of (2*BROADCAST_LATENCY)+ACK_GRACE_INTERVAL) period is set. If the H(Transcript_{j}[m']) for a m'\geq m is received from all participants, the timer is cancelled. Otherwise at the time out, the protocol issues a local UI warning and cancel the warning if/when such a hash is received and is consistence among participants.

When a new session key is computed as well as when \Pi _{i}^{S} receives new ephemeral DH values from all users, a timer of (2*BROADCAST_LATENCY)+REKEY_GRACE_INTERVAL period is set. It is cancelled when all user contributions are received (ephemeral keys or session key secrets). Otherwise, the \Pi _{i}^{S} excludes users who failed to contribute from the plist exclude those users from the plist and call initiate new session. This measure is taken to ensure that users do not block in-session forward secrecy due to loss of connection or being under attack.

Timing out during an interactive session

(n+1)sec by design assumes the participants are trusted in being commited to the goal fo creating a secure chatroom. In this sense, (n+1)sec provide little defens against party which trying to sabotage a room by mounting various denial of service approaches. However, there are situation where a party is genuinely affected (by external adversary) or by connection problem. Under such assumption, situations we expect that all other parties, reach a consensus, that a participant has connectivity problem and agree on leave them out of the room.

Timeout sub protocol is designed to deal with such a situation. When a new session is requested (for join, leave, etc) each participant wait for (2*BROADCAST_LATENCY)+INTERACTION_GRACE_INTERVAL, they omit non-participating participants from the plist, and wait for PLIST_UPDATE_GRACE_INTERVAL. so other participants also reach to the same conclusion and updates their plists, then they initiate a new session.

Drop inactive users, queue a new session request

Algorithm 10.XX

Description Pseudo-code Type
Drop inactive users plist_{i}\leftarrow plist_{i}\backslash inactive\_participant\_list Computation
Recompute Session Id sid_{i}\leftarrow H(U_{1}|y_{1}|\dots |U_{{n_{{active}}}}|y_{{n_{{active}}}}) Computation
Set up timer to request a new session SetTimer(PLIST_UPDATE_GRACE_INTERVAL, initiate new session) Computation

When a participant receives a request for initiating new session, it checks their most current view of participant list (the one with eliminated timed out users) and if it matched then they go ahead with initiating the session, otherwise decline halt the request.

IX Cryptographic Primitives

IX.1 Hash Function

SHA256 is being used as the hash function and the random oracle. SHA256 provides a sufficiently secure hash primitive for the level of security provided by (n+1)sec and is widely implemented.

IX.2 Message Origin Authentication

ED25519 has been chosen as the signature primitive due to its efficiency and more secure implementability over other elliptic-curve digital signature algorithms. [Be11]

IX.3 Message Encryption

We are using AES-256 in Galois/Counter Mode (GCM) with a shared group key for message encryption, we are following the suggestion by the original OTR protocol of using counter mode. However, unlike OTR, (n+1)sec does not support per message forgeability (although the whole transcript is forgeable), it is not prohibitive to use the same key for encryption and authentication.

The added authentication, spares P@P send and receive routines from using digital signature.

With GCM mode, the authenticated encryption is generically secure by the result (and assumptions) of [Kr00].

IX.4 GroupEnc and GroupDec Functions

The GroupEnc and GroupDec functions defined in Section VIII.1, facilitate the collective generation of a secret(s) shared by the group. Here we mention two examples of such functions, and specify the functions for (n+1)sec' protocol:

  • Naive peer-to-peer GroupEnc/Dec:

The simplest path to design such primitives is to encrypt z'_{i} using the p2p encryption secret between each pair of participants:

GroupEnc((k_{{i,1}},...,k_{{i,n}}),z'_{i}):=(E_{{k_{{i,1}}}}(z'_{i}),...,E_{{k_{{i,n}}}}(z'_{i}))GroupDec((k_{{i,1}},...,k_{{i,n}}),(z_{1},...,z_{n})):=(D_{{k_{{i,1}}}}(z_{1}[i]),...,D_{{k_{{i,n}}}}(z_{n}[i]))

  • Linear System based GroupEnc/Dec:

Another possibility is that each user generates k linear equations of l variables such if the system of k.n equations has m independent equations then m < l. The remaining equations should be generated using the mutual secrets k_{{i,j}}.

An example of such a system is used by [BuDe95]. In which k=1,l=n+1,m=n as follows:

Each user U_i generate equations (k_{i,i-1}+k_{i,i+1}=a_i) so the system for n equation n+1 variable will be:

Failed to parse (unknown function '\matrix'): \matrix{ x_1 + x_2 = a_1 \\ x_2+x_3= a_2 \\ \vdots \\ x_n + x_{n-1} = a_n \\}


Then each participant adds the equation of x_{i}=k_{{i,i+1}} to the system and solves the derived system of n+1-equation n+1-unknown to recover the secrets.

in such a system:

z'_{i}:=k_{{i,i-1}}=k{i-1,i}GroupEnc((k_{{i,1}},...,k_{{i,n}}),z'_{i},z'_{{i+1}}):=z'_{{i}}\oplus z'_{{i+1}}

(n+1)sec uses the modification of the primitive suggested in [ACMP10] to guard the confidentiality of the p2p and the subgroup keys:

z'_{i}:=H(k_{{i,i-1}},sid_{i})

While the naive peer to peer primitive is easier to understand and analyse, the second system gives the flexibility for the implementor to decide the trade off between the amount of data (number of equations) vs. the redundancy in the system (if some equations are not delivered the user can still compute a subset of secrets).

X. Next Steps

This document is the first public draft of the (n+1)sec protocol. We are genuinely hoping to receive a lot of feedback and review on this work and have chosen the wiki format to support Discussion. Ongoing tasks for the team include mathematical proofs of resistance to the adversarial model presented herein as well as technical implementation details. This is currently scheduled for the end of December, 2014. The np1sec software library will be initially implemented in Cryptocat and (with your help) further developed to suit a variety of use-cases in the near future.

XI. Acknowledgements

The eQualit.ie team would like to give special thanks and note to the effort and dedication offered by Trevor Perrin and Ximin Luo to this project. They have been actively involved throughout the year and the result would not have been the same without their contribution. The team would also like to express thanks to Joseph Bonneau for his constructive comment and critisim to improve the protocol and its presentation. George Kadianakis for helping with the security proof and pointing out flaws and attack; Arlo Breault for his work on implementation of the protocol in the np1sec software library; David Goulet for valuable advice as well as continued assistance and support offered to the project; Prof. Payman Mohassel for his help and advice on the security model and the proof; Prof. Jermey Clark, Prof. Matthew Green and Frederic Jacobs for their constructive participation in the design debates; Prof. Mark Manulis for suggesting the GKA. eQualit.ie expresses gratitude to Nadim Kobeissi, Cryptocat founder and developer who initiated the project and for sharing his experience and giving advice on secure browser based chat. Last but not least we would like to thank the Open Technology Fund for supporting the project.

XII. References


[ACMP10] ^ 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Michel Abdalla, Céline Chevalier, Mark Manulis, and David Pointcheval. “Flexible Group Key Exchange with on-Demand Computation of Subgroup Keys.” In Third African International Conference on Cryptology (AfricaCrypt ’10), edited by Dan Bernstein and Tanja Lange, 6055:351–368. LNCS. Stellenbosch, South Africa, 2010: Springer.

[Be11] ^ Bernstein, Daniel J.; Duif, Niels; Lange, Tanja; Schwabe, Peter; Yang, Bo-Yin. "High-Speed High-Security Signatures.","CHES","978-3-642-23950-2","http://dblp.uni-trier.de/db/conf/ches/ches2011.html#BernsteinDLSY11". 2011. pages: 124-142","6917","Lecture Notes in Computer Science","Springer".

[BS07] ^ 1 2 3 4 Bohli, Jens-Matthias, and Rainer Steinwandt. 2007. “Deniable Group Key Agreement.” In VIETCRYPT, edited by Phong Q. Nguyen, 4341:298–311. Lecture Notes in Computer Science. Springer. http://dblp.uni-trier.de/db/conf/vietcrypt/vietcrypt2006.html#BohliS06.

[BVS05] ^ 1 2 3 4 5 6 7 8 9 10 Bohli, Jens-Matthias, Maria Isabel Gonzalez Vasco, and Rainer Steinwandt. 2005. “Secure Group Key Establishment Revisited.” IACR Cryptology ePrint Archive 2005: 395. http://dblp.uni-trier.de/db/journals/iacr/iacr2005.html#BohliVS05a.

[BM] ^ 1 2 Bonneau, Joseph, and Andrew Morrison. “Finite-State Security Analysis of OTR Version 2.” http://www.jbonneau.com/doc/BM06-OTR_v2_analysis.pdf

[BGB04] ^ 1 2 3 4 Borisov, Nikita, Ian Goldberg, and Eric Brewer. 2004. “Off-the-Record Communication, or, Why Not to Use PGP.” In Proceedings of the 2004 ACM Workshop on Privacy in the Electronic Society, 77–84. WPES ’04. New York, NY, USA

[BCGNP08] ^ Colin Boyd, Yvonne Cliff, Juan Gonzalez Nieto, and KennethG. Paterson. 2008. “Efficient One-Round Key Exchange in the Standard Model.” In Information Security and Privacy, edited by Yi Mu, Willy Susilo, and Jennifer Seberry, 5107:69–83. Lecture Notes in Computer Science. Springer Berlin Heidelberg.

[BoMa10] ^ Boyd, Colin; Mathuria, Anish. "Protocols for Authentication and Key Establishment","3642077161, 9783642077166",2010, Springer Publishing Company, Incorporated, 1st edition

[BCP01] ^ Emmanuel Bresson, Olivier Chevassut, and David Pointcheval. 2001. “Provably Authenticated Group Diffie-Hellman Key Exchange - the Dynamic Case.” In Advances in Cryptology - Proceedings of ASIACRYPT ’01, edited by Colin Boyd, 2248:290–309. LNCS. Gold Coast, Australia: Springer.

[BCPQ01] ^ Emmanuel Bresson, Olivier Chevassut, David Pointcheval, and Jean-Jacques Quisquater. 2001. “Provably Authenticated Group Diffie-Hellman Key Exchange.” In Proceedings of the 8th ACM Conference on Computer and Communications Security (CCS ’01), edited by Mike Reiter, 255–264. Philadelphia, Pennsylvania.

[CaKr01] ^ Ran Canetti, Hugo Krawczyk. 2001. “Analysis of Key-Exchange Protocols and Their Use for Building Secure Channels” “EUROCRYPT Conference. Lecture Notes in Computer Science”. Edited by Birgit Pfitzmann.

[Da14] ^ George Danezis, Should Group Key Agreement be Symmetric and Contributory, http://conspicuouschatter.wordpress.com/2014/06/28/should-group-key-agreement-be-symmetric-and-contributory/

[Da02] ^ Davis, Don,"Defective Sign & Encrypt in S/MIME, PKCS#7, MOSS, PEM, PGP, and XML.","USENIX Annual Technical Conference, General Track","1-880446-09-X","http://dblp.uni-trier.de/db/conf/usenix/usenix2001g.html#Davis01","2002-09-022001", page 65-78

[GUVGC09] ^ 1 2 3 4 5 6 7 8 9 10 11 12 13 Ian Goldberg, Berkant Ustao\uglu, Matthew D. Van Gundy, and Hao Chen. 2009. “Multi-Party Off-the-Record Messaging.” In Proceedings of the 16th ACM Conference on Computer and Communications Security, 358–368. CCS ’09. New York, NY, USA: ACM.

[GBN10] ^ M. Choudary Gorantla, Colin Boyd, and Juan Manuel González Nieto. 2010. One Round Group Key Exchange with Forward Security in the Standard Model. http://eprint.iacr.org/2010/083.pdf

[GBNM11] ^ 1 2 3 M. Choudary Gorantla, Colin Boyd, Juan Manuel González Nieto, and Mark Manulis. 2011. “Modeling Key Compromise Impersonation Attacks on Group Key Exchange Protocols.” 'ACM Trans. Inf. Syst. Secur.

[Gun13a] ^ 1 2 3 Matthew Van Gundy. April 2013. “[OTR-dev] Improved Deniable Signature Key Exchange for mpOTR.” http://matt.singlethink.net/projects/mpotr/improved-dske.pdf

[Gun13b] ^ 1 2 3 Matthew Van Gundy March 2013. “[OTR-dev] Improved Deniable Signature Key Exchange for mpOTR.” http://lists.cypherpunks.ca/pipermail/otr-dev/2013-March/001676.html.

[Kr00] ^, "Krawczyk, Hugo","The order of encryption and authentication for protecting communications (Or: how secure is SSL?), 2001, Published: Cryptology ePrint Archive, Report 2001/045 http://eprint.iacr.org/

[KPW13] ^ Hugo Krawczyk and Kenneth G. Paterson, Hoeteck Wee. 2013. “On the Security of the TLS Protocol: A Systematic Analysis” in IACR Cryptology ePrint Archive.

[LVH13] ^ 1 2 3 Liu, Hong; Vasserman, Eugene Y.; Hopper, Nicholas. "Improved Group Off-the-record Messaging" from the Proceedings of the 12th ACM Workshop on Workshop on Privacy in the Electronic Society, 978-1-4503-2485-4, 'ACM', New York, NY, USA. 2013

[Mo13] ^ Marlinspike, Moxie,"Simplifying OTR deniability" blogpost, Open Whispersystems, https://whispersystems.org/blog/simplifying-otr-deniability/

[Sys14] ^ Marlinspike, Moxie et al. Whisper Systems. 2014. “TextSecure ProtocolV2.” Accessed March 2. https://github.com/WhisperSystems/TextSecure/wiki/ProtocolV2.

[RGK05] ^ 1 2 3 Mario Di Raimondo, Rosario Gennaro, and Hugo Krawczyk. 2005. “Secure Off-the-Record Messaging.” In WPES, 81–89. Alexandria, VA, USA. http://dl.acm.org/citation.cfm?doid=1102199.1102216

[KiSo00] Song, Boyeon; Kim, Kwangjo, "Two-Pass Authenticated Key Agreement Protocol with Key Confirmation","Progress in Cryptology —INDOCRYPT 2000","978-3-540-41452-0","http://dx.doi.org/10.1007/3-540-44495-5_21","2000"; "237-249",1977 "Lecture Notes in Computer Science",Springer Berlin Heidelber.

[Git11] ^ https://github.com/hellais/cryptocat


Appendices

Appendix A: Asynchronous communication and Forward Secrecy

The protocol is primarily targeted to synchronous cases, however, with some modification it can be used for asynchronous cases.

Provided that the participants are not concerned with authenticating the list of participants (it is OK if Eve impersonates Bob as long as she is unable to read Bob’s messages). Participants can communicate using their pairwise exchanged ephemeral Diffie-Hellman keys until all participants finish the second round of authentication.

As soon as a deniable handshake has been established among a set of participants any subset of them can communicate and authenticate their messages using the “session key” and their ephemeral signature key.

The protocol does not enforce explicitly a time limit on renewing the session key shares and can be used for an asynchronous high latency transport after the key establishment state.

The downside of using a session key for a long time is that a compromised session key will reveal all past communication during that session. This does not pose an imminent threat when the life span of a chat is short. However, in the context of asynchronous high latency transport, it is a more serious concern.

The protocol requires the participants to pre-emptively update their ephemeral signature/shares and propagate them as part of the messages they are already sending. Subsequently, they also update their key share with their neighbours as soon as the neighbours also propagate their new ephemeral signature keys.

As the assumption of having a continuous heartbeat might not be realistic in various asynchronous cases, implementations can assume specific deadlines for dropping users who did not communicate their new keys or shares.

Appendix B: Other design possibilities

During the process of designing (n+1)sec we have considered and debated other design possibilities which we will describe in this section along side our arguments in favour of the choices made.

Group Key Scheme vs Broadcast Scheme

We say a group key scheme (as defined in Section V) is correct if all accepted instances of \Pi _{i}^{S} end up with the same participant lists plist_{i} and compute the same session id.

By contrast, a broadcast scheme refers to a scheme in which each participant is broadcasting a message to a set of participants of their choice from a set of potential participants. Each participant will have its own different plist_{i} which is able to broadcast as well. See GOTR by [LVH13] For an example of such scheme where each participant chooses there own circle of audiances.

Therefore, in the context of a chat room, broadcasting scheme participants do not have the same view of the room and consequently we cannot compute a unified session id sid based on the list of the participants (as opposed to the group key scheme). In a group key scheme, it is the name of the chat room plus a set of ephemeral keys and the set of ephemeral public keys which uniquely identifies the session. There are advantages and disadvantages to each of these schemes, which we enumerate here:

  1. Chat room simulation: A group scheme simulates a normal chat room in the absence of an authentication adversary, where the participants all have the same view of who is in the chat room when they start talking. This is not the case in a broadcasting scheme as participants keep different participant lists. This is in conflict with the security assumptions of the authentication properties from the original proposal for (n+1)sec.
  2. Consistency: In a group key exchange, the consistency of the participant list (and session id) is provided by the group key exchange protocol. In such a protocol, extra measures need to be taken only to assure the transcript's consistency, i.e. verification of the consistency of delivery and order of messages exchanged between participants. In a broadcast scheme, a new notion needs to be defined and enforced so that a minimum consistency of a conversation can be simulated. For example, as broadcasting to a subset of potential participants is allowed, the notion needs to deal with a situation in which A receives the DH public key of B but wants to send a message to the "room" before it receives the DH key of C.
  3. Delayed join and leave: In a group scheme, until all participants confirm their identical view of a new participant list (due to a member joining or leaving the room), they need to assume the status quo. This might delay a new participant from joining a chat or, if no further measure is taken, enable a participant to deny join/leave for the whole group. While various mitigation methods are possible against such attacks (all summarized under the umbrella term "Denial of Service" ) they are not included in threat model considered in (n+1)sec protocol.

Based on the above differences, we selected a group key scheme for the proposed protocol. This is primarily because room consistency is one of the main security properties desired. However, when it is critical, the sub-protocol described by Section VIII.2 Sending and receiving messages while joining is in progress allows for communication with users while they are waiting for the join procedure to complete.

Participatory vs individually independent computation of group key(s)

Most AKGE offer some degree of contributiveness in computing the group secret. This roughly means that (at least in the absence of an insider) the group secret is derived using contribution from all members of the group. There has been criticism of the importance of this property such as in [Da14]. In this section we consider briefly the arguments for each side and describe the rational for our choice.

Last modified on 4 February 2015, at 23:21