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SIP Security Mechanisms

SIP Security Mechanisms. Through a secure Software Engineering approach Prajwalan Karanjit pkaranji@cc.hut.fi. Agenda. Introduction Security Issues during phases of SDLC Requirements Engineering System Design Implementation Testing Open Issues. Introduction.

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SIP Security Mechanisms

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  1. SIP Security Mechanisms Through a secure Software Engineering approach Prajwalan Karanjit pkaranji@cc.hut.fi

  2. Agenda • Introduction • Security Issues during phases of SDLC • Requirements Engineering • System Design • Implementation • Testing • Open Issues

  3. Introduction • SIP  Session Management Protocol, Signalling/Call Control Protocol • Many Applications: • VoIP, Distributed Classroom, Virtual Meeting, Shared Whiteboard, Publish/Subscribe based applications etc... • Vulnerable to several attacks • Attacks on confidentiality/secrecy (sniffing, traffic analysis) • Attacks on integrity (message tampering, hijack REGISTER) • Attacks on authenticity (spoofing) • Attacks on availability (message fabrication, replay, false proxy ) • Countermeasures • TLS/SSL, S/MIME, Digest Authentication, IPSec, and many others ...

  4. Introduction • But, is just considering countermeasures enough ? • No, Not at all • A systematic and disciplined approach of development • Security aspects need to considered in all phases of Software Development Life Cycle (SDLC) • SQUARE (Security Quality Requirements Engineering) • UMLSec • Safety critical systems require Spiral Model R. Anderson. Security Engineering: A Guide to Building Dependable Distributed Systems. Wiley, 2001. • What about other models ? • Waterfall, Agile Development Methods, eXtreme Programming • Software • Engineering

  5. System Design Requirements Engineering Implementation (Coding) System Testing and Customer Review Boehm Spiral Model

  6. Requirements Engineering • What could an end user expect ? • Call should be established with right callee • Media will remain confidential throughout the path • Third party should not be able to see who is calling whom • Caller is charged correctly • It is possible to make calls when caller wants • Security goals • Maintain confidentiality (Encryption) • Integrity protection ( MAC ) • DoS protection ( Deal with replay, ... ) • Entities involved are authenticated ( Both caller and callee )

  7. Requirements Engineering • Attacks and their impact  Risk

  8. Requirements Engineering • Prioritize the Requirements

  9. System Design • Several security mechanisms  Which one to go for ? • Its important to analyze the tradeoffs associated with each countermeasure • Lets analyze now abc.com xyz.com Trudy sip:alice@xyz.com sip:bob@abc.com

  10. Digest Authentication • Authenticating Client • No Encryption  No confidentiality • No guarantee of successful client authenticity  Use Identity Header(RFC 4474) UA and Proxy Authentication Digest Authentication * Source of Picture: Sawda, S., Urien, P.: SIP Security Attacks and Solutions: A state-of-the-art review. IEEE Network, (2006)

  11. Identity Header • First Step : Digest Authentication • Second Step : From To Call ID Date Cseq Contact INVITE sip:bob@abc.com SIP 2.0 From: ... To: ... Call-ID : ... Cseq: ... Contact: ... Date: ... Identity: ”IUSY89KJ%)(HASD=” Identity-Info: <https://somesite.com/xyz.cer>;alg=rsa-sha1 Content-Type: .... Private Key of Proxy SHA - 1 RSA Signature Base 64 Identity

  12. TLS/DTLS • Provides confidentiality as well as integrity • Integrated key management • Hop by Hop  Intermediate proxies must be trusted • If all the links do not use TLS/DTLS then security may be compromised • ”sips:” URI is used to indicate that TLS must be used. • TLS  TCP, DTLS  UDP • If signalling is also done over UDP  Only DTLS may be sufficient • Using DTLS (without RTP) for media may result into high network overhead • PKI Problem

  13. S/MIME • Encrypt the MIME body with public key of receiver • Provides both confidentiality and integrity • Entity authentication • Public key of receiver  Obtained through X.509 certificate (signed by trusted CA ) • Additional overhead due to PKI • All the headers cannot be encrypted  Request URI, Via, Record-Route, To, From, Cseq, Call ID • OR, encrypt all the headers along with body and their hash over header and body + attach unencrypted header • End to End

  14. IPSec • Network layer security, so protects both TCP and UDP • Confidentiality, Integrity, Entity Authentication • Integrated Key Management • Transparent to application • But it is also based on PKI  • Deployment challenges • SAD, Administrative Rights, Support by all OS • Hop by Hop • It seems like application will have to depend on the platform Chang, C., Lu, Y.F., Pang, A.C., Kuo, T.W..: Design and Implementation of SIP Security. LNCS, vol. 3391, pp. 669--678. Springer, Heidelberg (2005)

  15. Secure RTP • Basically RTP based media protection • Confidentiality  AES in key stream mode • Integrity  HMAC-SHA-1 • Replay based DoS  Sequence Numbers • Low network overhead • Key Management Issue • Have to depend on additional SIP signal + TLS or S/MIME • ZRTP  key agreement protocol which performs Diffie-Hellman key exchange for SRTP, No need of PKI, SAS (Short Authentication String) • What if media is not RTP ?

  16. So Which one to go with ? • Digest + Identity  ... • S/MIME  PKI problem • IPSec  Deployment issues + PKI problem • TLS  Trusted Proxies and all intermediate proxis must support it • SRTP Key Distribution issues and supports only RTP • DTLS  TLS problems + network overhead if RTP is not used.

  17. Implementation • Configuration of different servers such as DNS, Proxies etc... • Developing custom proxies, UAs • JAIN SIP + JAIN SDP from Sun Microsystems and NIST • SIP Servlet • SIP API for J2ME from Sun Microsystems and Nokia • As per recent documentation, none provides API support for above security mechanisms  Different API needed • Open SSL  Strictly C based with Unix libraries • Java and .NET based API • Visual C++ (Win 32 and MFC) • Write Responsible codes

  18. SIP Security Testing • Should at least focus on security requirements identified in Requirements Engineering phase • Should be performed by sending malformed SIP requests, • Sending a lot of authenticated and unauthenticated requests • Check of TLS or S/MIME or DTLS or SRTP support • Check if deprecated technologies are used • RTP or media tampering • Buffer overflow and SQL Injection  ???

  19. SIP Security Testing • Tools: • SIPp: A free Open Source test tool / traffic generator for the SIP protocol. • PROTOS SIP Fuzzer: - Tool that sends a set of malformed SIP messages. • SiVuS: A SIP Vulnerability Scanner that scans for SIP targets and attacks them • SIPNess: A basic tool to construct, send or receive SIP messages • SIPBomber: A sip-protocol [RFC3261] testing tool • SFTF: A SIP Forum test framework to evaluate and report the security and robustness of a SIP user agent

  20. Open Issues • Denial of Service Attacks • Against UA, Proxies • Flooding  Set threshold for each user in the proxy • How to know that proxy is authorized for a particular domain • Attribute Certificate • Existing X.509 fields ?? • Will the method described in this paper really result into a secure SIP based product ?

  21. Summary • SIP is highly vulnerable to several attacks • Security Mechanims are there, but each of them have their own tradeoffs • Mainly implementation issues and practical problems • Security should be considered through all the phases of SDLC • From Requirements Engineering to Testing

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