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Topic 14: Secure Communication1 Information Security CS 526 Topic 14: Key Distribution & Agreement, Secure Communication.

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Presentation on theme: "Topic 14: Secure Communication1 Information Security CS 526 Topic 14: Key Distribution & Agreement, Secure Communication."— Presentation transcript:

1 Topic 14: Secure Communication1 Information Security CS 526 Topic 14: Key Distribution & Agreement, Secure Communication

2 Topic 14: Secure Communication2 Readings for This Lecture On Wikipedia Needham-Schroeder protocol (only the symmetric key part)Needham-Schroeder protocol Public Key Certificates HTTP Secure

3 Outline and Objectives Key distribution among multiple parties Kerberos Distribution of public keys, with public key certificates Diffie-Hellman Protocol TLS/SSL/HTTPS Topic 14: Secure Communication3

4 Symmetric Key Agreement among Multiple Parties For a group of N parties, every pair needs to share a different symmetric key –What is the number of keys? –What secure channel to use to establish the keys? How to establish such keys –Symmetric Encryption - Use a central authority, a.k.a. (TTP). –Asymmetric Encryption – PKI. Topic 14: Secure Communication4

5 5 Needham-Schroeder Shared-Key Protocol Parties: A, B, and trusted server T Setup: A and T share K AT, B and T share K BT Goal: –Security: Mutual entity authentication between A and B; key establishment, Secure against active attacker & replay –Efficiency: Minimize the involvement of T; T can be stateless Messages: A  T: A, B, N A (1) A  T: E[K AT ] (N A, B, k, E[K BT ](k,A))(2) A  B: E[K BT ] (k, A) (3) A  B: E[k] (N B ) (4) A  B: E[k] (N B -1)(5) What bad things can happen if there is no N A ? Another subtle flaw in Step 3.

6 Topic 14: Secure Communication6 Kerberos Implements the idea of Needham- Schroeder protocol Kerberos is a network authentication protocol Provides authentication and secure communication Relies entirely on symmetric cryptography Developed at MIT: http://web.mit.edu/kerberos/www http://web.mit.edu/kerberos/www Used in many systems, e.g., Windows 2000 and later as default authentication protocol

7 Topic 14: Secure Communication7 Kerberos Overview One issue of Needham-Schroeder – Needs [K AT ] to talk to any new service. –Think about a login session with K AT derived from a password; either the password needs to be stored, or user needs to enter it every time Kerberos solution: Separates TTP into an AS and a TGS. The client authenticates to AS using a long-term shared secret and receives a TGT [SSO]. Use this TGT to get additional tickets from TGS without resorting to using the shared secret. AS = Authentication Server SS = Service Server TGS = Ticket Granting Server TGT = Ticket Granting Ticket

8 Kerberos Protocol - 1 Topic 14: Secure Communication8 C (client) SS (server) AS (authentication server) TGS (ticket-granting server) 1 2 3 4 5 6

9 Kerberos Protocol – 2 (Simplified) Topic 14: Secure Communication9 1. C  AS: TGS || N C 2. AS  C: { K C,TGS || C} K AS,TGS || {K C,TGS || N C || TGS} K AS,C (Note that the first part of message 2 is the ticket granting ticket (TGT) for the TGS) 3. C  TGS: SS || N’ C || {K C,TGS || C} K AS,TGS || {C||T 1 } K C,TGS 4. TGS  C: {K C,SS || C} K TGS,SS || {K C,SS || N’ C || SS} K C,TGS (Note that the first part in message 4 is the ticket for the server S). 5. C  SS: {K C,SS || C} K TGS,SS || {C || T 2 } K C,SS 6. SS  C: {T 3 } K C,SS

10 Topic 14: Secure Communication10 Kerberos Drawback Highly trusted TTP: KS –Malicious KS can silently eavesdrop in any communication Single point of failure: Security partially depends on tight clock synchronization. Useful primarily inside an organization –Does it scale to Internet? What is the main difficulty?

11 Topic 14: Secure Communication11 Public Keys and Trust Public Key: P A Secret key: S A Public Key: P B Secret key: S B How are public keys stored? How to obtain the public key? How does Bob know or ‘trusts’ that P A is Alice’s public key?

12 Topic 14: Secure Communication12 Distribution of Public Keys Public announcement : users distribute public keys to recipients or broadcast to community at large. Publicly available directory : can obtain greater security by registering keys with a public directory. Both approaches have problems, and are vulnerable to forgeries

13 Topic 14: Secure Communication13 Public-Key Certificates A certificate binds identity (or other information) to public key Contents digitally signed by a trusted Public-Key or Certificate Authority (CA) –Can be verified by anyone who knows the public-key authority’s public-key. For Alice to send an encrypted message to Bob, obtains a certificate of Bob’s public key

14 Public Key Certificates Topic 14: Secure Communication14

15 Topic 14: Secure Communication15 X.509 Certificates Part of X.500 directory service standards. –Started in 1988 Defines framework for authentication services: –Defines that public keys stored as certificates in a public directory. –Certificates are issued and signed by an entity called certification authority (CA). Used by numerous applications: SSL, IPSec, SET Example: see certificates accepted by your browser

16 Topic 14: Secure Communication16 How to Obtain a Certificate? Define your own CA (use openssl or Java Keytool) –Certificates unlikely to be accepted by others Obtain certificates from one of the vendors: VeriSign, Thawte, and many others

17 Topic 14: Secure Communication17 CAs and Trust Certificates are trusted if signature of CA verifies Chain of CA’s can be formed, head CA is called root CA In order to verify the signature, the public key of the root CA should be obtain. TRUST is centralized (to root CA’s) and hierarchical What bad things can happen if the root CA system is compromised? How does this compare with the TTP in Needham/Schroeder protocol?

18 Topic 14: Secure Communication18 Key Agreement: Diffie-Hellman Protocol Key agreement protocol, both A and B contribute to the key Setup: p prime and g generator of Z p *, p and g public. K = (g b mod p) a = g ab mod p g a mod p g b mod p K = (g a mod p) b = g ab mod p Pick random, secret (a) Compute and send g a mod p Pick random, secret (b) Compute and send g b mod p

19 Topic 14: Secure Communication19 Authenticated Diffie-Hellman g a mod n g b mod n g c mod n Alice computes g ac mod n and Bob computes g bc mod n !!! Is C Alice Alice’s certificate? C Alice, g a mod n, Sign Alice (g a mod n) C Bob, g b mod n, Sign Bob (g b mod n) Is C Bob Bob’s certificate?

20 Forward Secrecy Compromise of long-term keys does not compromise past session keys. –I.e., a session that is secure now remains secure in future –Violated in secret-key based protocols such as Needham- Schroeder and used in Kerberos Can be satisfied by ephemeral Diffie-Hellman –Do not store secrets such as a, b after computing g ab. –Long-term secret (digital signature signing keys) used only for authenticity Stealing a key cannot compromise authenticity of past sessions Topic 14: Secure Communication20

21 Secure communication 21Topic 14: Secure Communication

22 22 Transport Layer Security (TLS) Predecessors: Secure socket layer (SSL): Versions 1.0, 2.0, 3.0 TLS 1.0 (SSL 3.1); Jan 1999 TLS 1.1 (SSL 3.2); Apr 2006 TLS 1.2 (SSL 3.3); Aug 2008 Standard for Internet security –Originally designed by Netscape –Goal: “... provide privacy and reliability between two communicating applications” Two main parts –Handshake Protocol Establish shared secret key using public-key cryptography Signed certificates for authentication –Record Layer Transmit data using negotiated key, encryption function

23 Usage of SSL/TLS Applied on top of transport layer (typically TCP) Used to secure HTTP (HTTPS), SMTP, etc. One or both ends can be authenticated using public key and certificates –Typically only the server is authenticated Client & server negotiate a cipher suite, which includes –A key exchange algorithm, e.g., RSA, Diffie-Hellman, SRP, etc. –An encryption algorithm, e.g., RC4, Triple DES, AES, etc. –A MAC algorithm, e.g., HMAC-MD5, HMC-SHA1, etc. Topic 14: Secure Communication23

24 What Goes Wrong in Real World? Heartbleed software bug in OpenSSL –Improper input validation (missing bounds check) –Buffer over-read: Exploitation is able to read data in memory, including private key, etc. SSL Certificate validation errors Non-random private keys in RSA n=pq (the same primes are occasionally generated) Pre-computation can be used to break Diffie-Hellman used in TLS –(Optional) See “Imperfect Forward Secrecy: How Diffie-Hellman Fails in Practice” in CCS 2015 Topic 14: Secure Communication24

25 Viewing HTTPS web sites Browser needs to communicate to the user the fact that HTTPS is used –E.g., a golden lock indicator on the bottom or on the address bar –Check some common websites –When users correctly process this information, can defeat phishing attacks –Security problems exist People don’t know about the security indicator People forgot to check the indicator Browser vulnerabilities enable incorrect indicator to be shown Use confusing URLs, e.g., –https:// homebanking.purdueefcu.com@host.evil.com/homebanking.purdueefcu.com@host.evil.com/ Stored certificate authority info may be changed Topic 14: Secure Communication25

26 Topic 14: Secure Communication26 Coming Attractions … Malware Defense & Intrusion Detection

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