Internet Engineering Task Force IDWG Internet Draft Gupta draft-ietf-idwg-iap-01.txt Hewlett-Packard March 31, 2000 Expires: September, 2000 Intrusion Alert Protocol - IAP STATUS OF THIS MEMO This document is an Internet-Draft and is in full conformance with all provisions of Section 10 of RFC2026. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet- Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress". The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Abstract Intrusion Alert Protocol (IAP) is an application-level protocol for exchanging intrusion alert data between intrusion detection elements, notably sensor/analyzers and managers across IP networks. The protocol's design is compatible with the design goals for the HyperText Transfer Protocol (HTTP). The specification of alerts carried using this protocol is described in companion documents of the intrusion detection working group of the IETF. 1 Introduction 1.1 Purpose The Intrusion Alert Protocol (IAP) is application-level protocol for exchanging intrusion alert data. The protocol is designed to provide the necessary transport and security properties to allow sensitive alert data to be sent across IP networks. In addition, the protocol is designed so that future extensions may use the application layer for configuring intrusion detection Gupta [Page 1] Internet Draft IAP March 23, 2000 sensor/analyzers or sending responses. 1.2 Transport layer protocol IAP uses the transmission control protocol (TCP) [1] as its underlying transport layer mechanism. This protocol is used for a wide variety of IP services. It has a number of features such as congestion avoidance, slow start, etc. that enable it to work over large networks with a wide variety of latency, bandwidth and congestion characteristics. TCP provides reliable and sequenced delivery of data between IP peers. 1.3 Terminology Terminology is borrowed from [2]. 1.4 Overall operation IAP is primarily oriented towards supporting the transmission of alert data from an intrusion detection sensor/analyser that detects a potential intrusion, to a manager that displays it to a human, logs it to a database or takes appropriate action. In the simplest case, a sensor/analyser (SA) sends alerts to a manager(M). SA -------------------> M In a more complex situation, there are more than one intermediaries in the communication path. Two common forms of intermediary are: Proxy A proxy is a forwarding agent which MAY do some rewriting of the content, and forward the message. Gateway A gateway is used to translate messages from/to some native format (such as SNMPv3 UDP wire protocol). A proxy may be used to relay two connections when the communication needs to pass through an intermediary such as a firewall. SA ----> P -----> G ----> M Gupta [Page 2] Internet Draft IAP March 23, 2000 Here, IDEF data is generated by SA and passed to a proxy P. P connects to a gateway G, which translates alerts into a native format to be consumed by the manager M. In this exchange, the connections between SA and P, and P and G use IAP. The connection between G and M uses the native protocol supported by M. IAP communication takes place over an IP network using the transport control protocol (TCP). To connect with other networks, gateways should be used to transform protocol data into the native representation. It is expected that the IANA will allocate a designated TCP port for IAP communications. 1.5 Augmented BNF We use the augmented BNF definitions of [3]. 1.6 Protocol parameters IAP uses a . numbering scheme to indicate versions of the protocol. The minor number is changed when updates to the protocol add features that do not change the parsing algorithm. The major number is changed when the parsing algorithm is modified. This document describes version 0.3 of IAP. The version string for this is iap-version: IAP/0.3. 1.7 Media Types IAP uses Internet Media Types [4] to denote the type of alert data. Media types are used to define the encapsulation of data, in a manner that can be extended without requiring changes to the application protocol. The only media type used by IAP/0.3 is application/x-idef-alert. It is expected that the IANA will allocate a registered media type for the IDEF alert format. IAP entities MUST accept data sent in this format. 2 IAP Communication Model IAP communications occur on top of the transport control protocol (TCP). The TCP connection carries request-response pairs much like the payload of the HyperText Transfer Protocol (http). The TCP connection MAY be initiated by the analyzer SA or the manager M. This is to accommodate security perimeter configurations that proscribe certain kinds of connections - for instance, if the manager resides in an outsourcer's environment whereas the analyzer is inside a protected network, perimeter security needs of the protected network Gupta [Page 3] Internet Draft IAP March 23, 2000 may be better served if the analyzer initiates the connection. Response codes are borrowed from the hypertext transfer protocol [3]. In order to accommodate this variation, the roles of IAP entities are not determined by who initiates the TCP connection. This is in contrast to the hypertext transfer protocol (HTTP) where the client (user agent) always initiates the TCP connection. 2.1 Why not HTTP? HTTP/1.1 satisfies a number of needs of the application, but has a few assumptions that make it hard to use in-toto as the application layer. The first is the assumption that the TCP connection initiator is the HTTP client or requester in the request-response scheme - this precludes running the protocol "in reverse". A second issue is the inability to give the proxy enough hints about the connection if the protocol is being run over a TLS session, although there is ongoing work in that direction. This draft uses the recommendations of this work, in particular the Upgrade: keyword and the CONNECT method as outlined in [5]. 2.2 Request-Response A configured IAP sensor/analyzer - manager pair MAY have two types of active connections for analyzer-initiated and manager-initiated flows. Payload where the analyzer sends requests such as alerts is carried over one TCP connection. Should the manager wish to send commands to the analyzer, it MUST be carried over a separate TCP connection. An IAP entity MAY close a connection if it finds unexpected data from its peer. An analyzer MUST support connections in which it sends the requests. It MAY choose to support connections in which it responds to requests from a manager. 2.3 Phases The protocol is divided into two major phases. The first (setup) phase is a request-response protocol where requests are sent by the peer that initiated the TCP connection. This establishes roles for the peers and the two parties agree whether the connection will be used for request-response pairs where the analyzer acts as the sender, or vice versa. The second (data) phase is also a request-response session in which the sender of requests may be reversed, based on the negotiations in the first phase. If the connection is used for carrying payload Gupta [Page 4] Internet Draft IAP March 23, 2000 initiated by the analyzer, such as alerts, the requests will be from the analyzer. Otherwise, they will be from the manager. 2.3.1 Proxies An IDEF entity in a proxy role does not have an IAP identity. It acts as a relay of messages without understanding their content. It MAY do some rewriting of the content, but in a manner that does not impact the security properties of alerts. 3 IAP Setup Phase This is the first phase after a TCP connection is in the established state. In this phase, the two parties set up the transport parameters of the protocol. An IAP entity in a proxy role MAY rewrite content to set up the protocol in this phase. This phase uses a request-response form, with the TCP connection initiator as requestor. The phase is divided into three subphases, where the TCP connection, security and channel parameters are agreed upon by the peers. 3.1 TCP Setup The TCP connection initiator issues an iap-connect-request command. A corresponding peer MAY choose to accept this connection, and respond using an iap-response command, with the status code set to 200 to denote success. The pair can then proceed to the security setup section. Alternatively, the entity MAY reject the connection request by setting the status code to 4xx to denote failure. In particular, the 403 Forbidden command MAY be used by the responder. An intermediate entity in a proxy role MAY, upon receiving the request, rewrite the iap-connect-request command. A proxy MAY append a iap-proxy-via line to the connection request before passing it on to the receiving entity. A proxy SHOULD relay the server's response back to the client after appending a iap-proxy-via line. A proxy MUST verify that existing proxy-via headers in the request don't match its own identity in order to limit the damage from misconfigured proxies. Otherwise, it MUST send a bad gateway (502) response to the peer that requested the connection. Any entities in a proxy role MUST forward data transparently once the upgrade phase is reached. End entities detect any attempts to manipulate or inject messages into the communications channel. Gupta [Page 5] Internet Draft IAP March 23, 2000 3.2 Security Setup A single request-response pair is used to upgrade the security of a connected transport. The initiator of the TCP connection upon receiving an iap-response command without any errors, issues a iap- upgrade-request command. A server should expect the iap-upgrade-request command after sending an iap-response reply indicating acceptance of the connection. The server SHOULD terminate if the request is not received, or some other request is received. Upon receiving the request, it SHOULD send an iap-response reply with the status code set to 101 to indicate acceptance of the upgrade. It MAY also send a 500 to denote server configuration error, if for instance, it is not yet configured and does not have a certificate. Once the TCP connection initiator receives an iap-response message indicating success of its request to upgrade the security of the connection, the parties initiate the TLS 1.0 handshake protocol [6]. This step negotiates the protocol version, cryptographic algorithms, mutual authentication and generates shared secrets for the next phase. The analyzer will initiate this step regardless of who initiated the TCP session, because it assumes the TLS client role. The analyzer sends the TLS client-hello message to initiate the handshake. If the parties complete the TLS handshake protocol successfully, they enter exchange final setup request-response pairs, using the TLS record protocol. These pairs are exchanged after a successful handshake and is used by the parties to verify connection parameters. Once the TLS handshake is completed successfully, the TCP connection initiator sends the channel setup request. 3.3 Channel Setup Data in the channel setup phase is send using the TLS record layer, and is thus impervious to passive and active attacks. The purpose of this phase is to verify the IAP version information and decide on the kind of payload the connection will carry for data. The TCP connection initiator sends the iap-channel-setup-request message. The recipient then: + Verifies the version information against what it received during the protocol setup phase; Gupta [Page 6] Internet Draft IAP March 23, 2000 + Checks that it is able to either accept requests from, or send requests to the peer It then issues a iap-response reply to indicate its agreement with the parameters specified by the TCP connection initiator. The protocol, security and channel setup phases are now complete, and the channel is ready to communicate data. The directionality of this phase is dependent on the parameters agreed upon during channel setup. 3.4 Secured data transport This is the main phase of the protocol. In this phase, encoded IDEF alerts are sent by the client (sensor/analyzer) to the server (manager) over the TLS record layer. In addition to data in the form x-idef-alert, compatible clients and servers MAY send other data using this transport. A peer, upon receipt of data that it is unable to decode (unknown IAP content type), SHOULD reject the data. It MAY choose not to terminate the connection. This allows clients (analyzers) supporting richer content types to communicate with legacy servers (managers). 3.5 Termination Termination can be initiated by either peer by sending a TLS close- notify alert (section 7.2.1). The recipient, on receipt of this alert, should in turn respond with a close-notify alert and the parties can close the connection gracefully. 3.6 Example In this example, an analyzer A is configured to connect to proxy P. P connects to a manager M to deliver the alerts. The following diagram depicts the abstract message flow for the case where there are no errors, and a connection is set up to deliver alerts from A to M. A P M [Setup Phase] ---------------> iap-connect-request ---------------> iap-connect-request Gupta [Page 7] Internet Draft IAP March 23, 2000 <--------------- iap-response <--------------- iap-response [proxy is now a transparent forwarding agent] ---------------> iap-upgrade-request <--------------- iap-response (TLS handshake negotiation) [TLS handshake completed: data sent using the TLS record layer] ---------------> iap-channel-setup-request <--------------- iap-response [Data Phase] ---------------> iap-content <--------------- iap-response 4 IAP Wire Protocol IAP uses a subset of the HTTP/1.1 syntax to send IDEF alerts. The request-response protocol is modeled on HTTP, with the exception that the each request and response must be prefixed with the IAP version number during the setup phase. All requests must be responded to using an iap-response message indicating whether the recipient was able to successfully interpret (and act on) the request. Response codes are borrowed from HTTP/1.1. 4.1 Alert content Gupta [Page 8] Internet Draft IAP March 23, 2000 Alert content payload must be preceded by a header specifying the content length. 4.2 Syntax In the wire protocol, requests and responses are terminated by a pair of CRLF sequences, following HTTP/1.1. The following definitions from [3] are used. + hostThis + DIGIT + Chunked-Body + SPC + CRLF An IAP message is denoted by iap-message. iap-message = ( iap-connect-request | iap-upgrade-request | iap-channel-setup-request | iap-content | iap-response ) CRLF The version of the protocol is denoted by iap-t-version iap-t-version = "IAP/0.3" The role of the TCP connection initiator is specified by sender- receiver: sender-receiver = "Sender" | "Receiver" By choosing the appropriate string, it signals whether it wants to send requests to the peer or receive them from the peer. 4.3 Protocol messages 4.3.1 Responses Gupta [Page 9] Internet Draft IAP March 23, 2000 An iap-response denotes the status code returned by an IAP entity in response to a request. iap-response = iap-t-version SP 3DIGIT CRLF 4.3.2 Connection Request A iap-connect-request denotes a request message sent by an IAP client to establish an IAP protocol connection. iap-connect-request = iap-t-connect-request ( iap-t-via )* iap-t-connect-request = iap-t-version SP "CONNECT" SP host CRLF iap-t-via = iap-t-version SP "Via:" SP host CRLF 4.3.3 Upgrade Request An iap-upgrade-request contains a notification from the client that it wishes to upgrade the security of the connection. iap-upgrade-request = iap-t-version SP "Upgrade: TLS/1.0" CRLF 4.3.4 Channel Setup An iap-channel-setup request contains a notification requesting that the peer verify the version of IAP being used. iap-channel-setup-request = iap-t-version SP "IAP-Version: 0.3" CRLF "IAP-Role:" SP sender-receiver CRLF Gupta [Page 10] Internet Draft IAP March 23, 2000 4.3.5 Alert Content The iap-content message is an encoded alert sent using IAP. iap-content = iap-t-content-header CRLF iap-t-content-body CRLF iap-t-content-header = iap-content-type iap-transfer-encoding iap-content-type = "Content-Type:" SP "application/x-idef-alert" CRLF iap-transfer-encoding = "Content-Length: " SP +DIGIT CRLF 4.4 Example Here is a transcript of a scenario in which an IDEF sensor/analyzer A wishes to send alerts to manager M. The proxy P mediates this connection. After the connection has been set up, A sends an IDEF alert 64 octets in length with each octet set to 0xFF. A P M iap-connect-request ---------------> IAP/0.3 CONNECT M.DOM.ORG CRLF CRLF iap-connect-request ---------------> IAP/0.3 CONNECT M.DOM.ORG CRLF IAP/0.3 Via: P.DOM.ORG CRLF CRLF iap-response <--------------- IAP/0.3 200 CRLF CRLF iap-response Gupta [Page 11] Internet Draft IAP March 23, 2000 <--------------- IAP/0.3 200 CRLF IAP/0.3 Via: P.DOM.ORG CRLF CRLF [proxy is now a transparent forwarding agent] iap-upgrade-request ---------------> IAP/0.3 Upgrade: TLS/1.0 CRLF CRLF iap-response <--------------- IAP/0.3 101 CRLF CRLF (TLS handshake negotiation) [TLS handshake completed: data sent using the TLS record layer] iap-version-verify ---------------> IAP/0.3 IAP-Version: 0.3 CRLF IAP/0.3 IAP-Role: Sender CRLF CRLF iap-response <--------------- IAP/0.3 200 CRLF CRLF iap-version-verify iap-content ---------------> Content-Type: application/x-idef-alert CRLF Content-Length: 64 CRLF 64 * 0xFF octet (IDEF alert data) CRLF CRLF iap-response <--------------- IAP/0.3 200 CRLF CRLF 5 Scenarios Gupta [Page 12] Internet Draft IAP March 23, 2000 5.1 Simple analyzer A simple analyzer can only initiate connections, and only be able to connect with a single manager at a time. In this case, the analyzer's configuration is expected to include the manager's IP address and a specification of the manager's certificate (such as the signer's public key and patterns in the common name or organizational unit). The analyzer would initiate the TCP session. As a result, any firewalls in the path MUST be configured to let through traffic initiated by the analyzer(s) with the manager's IP address and IAP destination port as the other endpoint of the session. 5.2 Simple analyzer with proxy If perimeter security demands that a proxy be deployed, the analyzer should be configured with the proxy's IP address. The proxy would then establish a connection to the manager, and forward traffic between the two connections. The proxy's configuration would include the manager's address. Note that the proxy does not participate in the TLS handshake and does not need TLS related configuration parameters. 5.3 Manager design considerations The protocol is oriented to allow lightweight implementation of sensor/analyzers. A manager MUST accept TCP connections from multiple sensor/analyzers by listening on the IAP port. 6 Implementation Considerations 6.1 TCP connection initiation The entity that initiates a TCP connection will be variable, and dependent on the exact deployment model. One scenario is that of sensor/analyzers outside a security perimeter, with the manager inside. In such configurations, the manager MAY initiate the connection in line with perimeter security requirements. Another scenario is that of remote sensor/analyzers being managed by a service provider. In this case, the sensor/analyzer MAY contact a proxy on the perimeter, which in turn connects to the remote manager in a service provider's network. The communications protocol should allow chained proxies to carry IAP data across multiple security perimeters. 6.2 Urgent data Gupta [Page 13] Internet Draft IAP March 23, 2000 Urgent data at the TCP layer MUST NOT be used by an entity using IAP. Endpoints SHOULD terminate a connection upon receipt of urgent data. 6.3 TLS/1.0 protocol The TLS 1.0 protocol MUST be used. An IDEF entity MUST not allow older protocol HELLO messages, and reject attempts to negotiate an older version of the protocol. The following TLS ciphersuite MUST be supported in line with recommendations from the tls working group: + TLS_DHE_DSS_WITH_3DES_EDE_CBC_SHA The recommendations in sections 2.1 and 2.2 of [7] must be followed by IAP client and server implementations. 6.4 Mandatory client certificates In line with the requirement for strong mutual authentication, client certificates (for sensor/analyzers acting in an IAP client role) are mandatory, and the entity should verify the certificate's content during the TLS handshake. 6.5 Certificate conventions One or more of the following extended key usage extensions MUST be specified in X.509v3 certificates issued to an IAP client or server entity: + IAP_ALERT_GENERATOR + IAP_ALERT_CONSUMER + IAP_IDEF_CONFIGURATOR The object identifiers (OIDs) for these extensions will be specified in a companion document. The presence of the extension means that the signer believes that the holder of the certificate is allowed to function in the corresponding IAP role. An entity in a IAP server role MUST have the IAP_ALERT_CONSUMER extension in its certificate. Similarly, an entity in a IAP client role MUST have the IAP_ALERT_GENERATOR extension in its certificate. 6.6 Verification of peer identity As the peer identity is initially sent in the clear, it is essential that the IAP client and server entities verify the identity of their peer using criteria based on their public key certificates. Gupta [Page 14] Internet Draft IAP March 23, 2000 Implementors SHOULD adopt prudent security practice and reject certificates that are not in accordance with the installation's configuration. For instance, they may wish to verify subfields of the peer's identity, such as the Organizational Unit, in addition to verifying the correctness of the signature and the signer's identity. The version of the protocol MUST be verified during the channel setup phase to stop protocol downgrade attacks. The mechanism specified in section 2.4 of [7] for verifying peer certificates must be followed. 6.7 TLS session resumption The entities MUST be configured to support TLS session resumption. Because of the possibility of external entities maliciously terminating IAP sessions, clients and servers MAY attempt to resume a session even if the TLS close-notify alert was not received before the transport closed. 7 Security Considerations As IAP is intended to be used for carrying security-sensitive data, we will list a number of security considerations. 7.1 Reliable and sequenced delivery Although reliable and sequenced delivery can be built on top of UDP, this usually reimplements some of the protocol features of TCP. Certain deployment scenarios may prefer fast unreliable delivery with the manager doing a "best effort" attempt to keep up with the flow of alerts. This proposal does not address such a scenario. One potential alternative for this scenario is to use the SNMP trap as a means to represent the alert. We remark that the above scenario is at odds with a number of items in section 6 of the requirements document of the working group. In addition, the use of UDP-based protocols is likely to result in unresponsive or aggressive flows which further exacerbate the congestion problem in the internet. 7.2 TCP handshake TCP uses a three-message handshake mechanism to set up connections. This opens the protocol up to certain well-known denial of service attacks. This protocol does not address this vulnerability. The effect of such attacks can be mitigated by a number of techniques, including: + restricting the set of peer IP addresses allowed to connect to the node. Gupta [Page 15] Internet Draft IAP March 23, 2000 + having the node only accept connections when it is not already connected to known peers. 7.3 Key Management For a public-key based communications model to be useful, good key management principles must be used for the lifecycle of public key certificates. The pkix working group of the IETF is defining mechanisms that can be used for this purpose. 7.4 Message length Traffic analysis may allow an observer to induce the type of alert from the size of the message. If this is a threat, IDEF entities SHOULD pad their data so that it observes some known distribution (such as the uniform distribution) over time. 7.5 Proxy considerations As the proxy transparently forwards encrypted traffic after connections are established, it is prudent to deploy the proxy in a manner that it can't be used to violate the perimeter security policy. For instance, a proxy may only accept requests from connections on its inside interface, to known locations outside the perimeter. 8 Acknowledgements This document makes heavy use of prior work in the IETF on HTTP, MIME and TLS. Their effort is gratefully acknowledged. Members of the IETF's intrusion detection working group (idwg) have made extensive comments that are reflected in the draft. 9 Bibliography [1] J. Postel, "Transmission control protocol," Request for Comments (Standard) 793, Internet Engineering Task Force, Sept. 1981. [2] M. Wood, "Intrusion detection exchange format requirements," internet draft (work in progress), Internet Engineering Task Force, June 1999. [3] R. Fielding, J. Gettys, J. Mogul, H. Frystyk, L. Masinter, P. Leach, and T. Berners-Lee, "Hypertext transfer protocol - HTTP/1.1," Request for Comments (Draft Standard) 2616, Internet Engineering Task Force, June 1999. [4] N. Borenstein and N. Freed, "MIME (multipurpose internet mail Gupta [Page 16] Internet Draft IAP March 23, 2000 extensions): Mechanisms for specifying and describing the format of internet message bodies," Request for Comments (Proposed Standard) 1341, Internet Engineering Task Force, June 1992. [5] R. Khare and S. Lawrence, "Upgrading to TLS within HTTP/1.1", internet draft (work in progress), Internet Engineering Task Force, Jan 2000. [6] T. Dierks and C. Allen, "The TLS protocol version 1.0," Request for Comments (Proposed Standard) 2246, Internet Engineering Task Force, Jan. 1999. [7] C. Newman, "Using TLS with IMAP, POP3 and ACAP," Request for Comments (Proposed Standard) 2595, Internet Engineering Task Force, June 1999. A Author's Address Dipankar Gupta Hewlett-Packard 690 E Middlefield Road, MS 31R Mountain View, CA 94043, USA Fax: +1(650)919-8066 Email: dg@mayfield.hp.com B Full Copyright Statement Copyright (C) The Internet Society (1999). All Rights Reserved. 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Table of Contents 1 Introduction ........................................ 1 1.1 Purpose ............................................. 1 1.2 Transport layer protocol ............................ 2 1.3 Terminology ......................................... 2 1.4 Overall operation ................................... 2 1.5 Augmented BNF ....................................... 3 1.6 Protocol parameters ................................. 3 1.7 Media Types ......................................... 3 2 IAP Communication Model ............................. 3 2.1 Why not HTTP? ...................................... 4 2.2 Request-Response .................................... 4 2.3 Phases .............................................. 4 2.3.1 Proxies ............................................. 5 3 IAP Setup Phase ..................................... 5 3.1 TCP Setup ........................................... 5 3.2 Security Setup ...................................... 6 3.3 Channel Setup ....................................... 6 3.4 Secured data transport .............................. 7 Gupta [Page 18] Internet Draft IAP March 23, 2000 3.5 Termination ......................................... 7 3.6 Example ............................................. 7 4 IAP Wire Protocol ................................... 8 4.1 Alert content ....................................... 8 4.2 Syntax .............................................. 9 4.3 Protocol messages ................................... 9 4.3.1 Responses ........................................... 9 4.3.2 Connection Request .................................. 10 4.3.3 Upgrade Request ..................................... 10 4.3.4 Channel Setup ....................................... 10 4.3.5 Alert Content ....................................... 11 4.4 Example ............................................. 11 5 Scenarios ........................................... 12 5.1 Simple analyzer ..................................... 13 5.2 Simple analyzer with proxy .......................... 13 5.3 Manager design considerations ....................... 13 6 Implementation Considerations ....................... 13 6.1 TCP connection initiation ........................... 13 6.2 Urgent data ......................................... 13 6.3 TLS/1.0 protocol .................................... 14 6.4 Mandatory client certificates ....................... 14 6.5 Certificate conventions ............................. 14 6.6 Verification of peer identity ....................... 14 6.7 TLS session resumption .............................. 15 Gupta [Page 19] Internet Draft IAP March 23, 2000 7 Security Considerations ............................. 15 7.1 Reliable and sequenced delivery ..................... 15 7.2 TCP handshake ....................................... 15 7.3 Key Management ...................................... 16 7.4 Message length ...................................... 16 7.5 Proxy considerations ................................ 16 8 Acknowledgements .................................... 16 9 Bibliography ........................................ 16 A Author's Address .................................... 17 B Full Copyright Statement ............................ 17 Gupta [Page 20]