Hardware Cryptographic Coprocessor

1. Hardware Cryptographic Coprocessor Peter R. Wihl Security in Software

2. The Problem • Need for secure computing in an environment where computing is distributed, insecure, and even hostile • More and more, we use computers that belong to others, but we need to know our data is safe.

3. The Goal • Create a trusted computing device that can be added to an untrusted computing system to make it secure. • Isolate your secure processing from the rest of your system.

4. Example 1 - Database • Create a central database system that allows only authorized users to access to only their data on the system. • Exclude even the system administrator from viewing any data in the database.

5. Example 2 – Trusted Boot • You have an untrusted computing system, but you want to ensure that it boots the correct machine code. • Want to make sure that the boot code has not been altered or tampered with

6. Example 3 – Protected Data At Rest(My Favorite!) • You have sensitive data that you can access in a controlled, protected environment but must be protected when not being accessed • Protection of data needed between use of it i.e. during transportation

7. A Secure Coprocessor • A general-purpose computing environment • Withstands physical attacks and logical attacks • Must run the programs that it is supposed to, and must distinguish between the real device and application and a clever impersonator • Must remain secure even if adversaries carry out destructive analysis of one or more devices • Started in the early 1990’s

8. Evaluation Parameters • Physical Protection (tamper resistant) • Reliability (physical or electrical damage) • Computational Ability (Speed bps) • Communications • Portability • Cost

9. Applications • Generalized Access • Generalized Revelation • Autonomous Auditing • Trusted Execution

10. Classes of Solutions • IC Chip Cards (Smart Cards, Your GSM Phone has one) • PCMCIA Tokens (Fortezza) • Other Card Tokens (Secure ID) • Smart Disks (Obsolete) • Bus Cards (IBM 4758) • Your Body (the future is now)

11. FORTEZZA™ CRYPTOCARD

12. Fortezza Features • Data Privacy • User ID Authentication • Data Integrity • Non-Repudiation • Time stamping

13. RSA SecurID • Software tokens support qualified smart cards or USB authenticators • Stores symmetric key and is PIN protected • Stores digital credentials • Only secures the login process

14. The IBM 4758 • Tamper-responding hardware design certified under FIPS PUB 140-1. Suitable for high-security processing and cryptographic operations • Hardware to perform DES, random number generation, and modular math functions for RSA and similar public-key cryptographic algorithms • Secure code loading that enables updating of the functionality while installed in application systems • IBM Common Cryptographic Architecture (CCA) and PKCS #11 as well as custom software options • Provides a secure platform on which developers can build secure applications

15. The 4758 Architecture

16. SafeNet SafeXcel™ 241-PCI Card • Provides industry-leading cryptography throughput for operations such as: • DES and Triple-DES encryption • MD5 and SHA-1 Hashing • Random number generation • Public key computations:- Diffie-Hellman key negotiation- RSA encryption and signatures- DSA signatures

17. SafeXcel™ 241-PCI Architecture