You're reading from TLS Cryptography In-Depth

Product type Book

Published in Jan 2024

Publisher Packt

ISBN-13 9781804611951

Pages 712 pages

Edition 1st Edition

Languages

Concepts

Cryptography

Authors (2):

Dr. Paul Duplys

Dr. Roland Schmitz

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Table of Contents (30) Chapters

Preface

1. Part I Getting Started

2. Chapter 1: The Role of Cryptography in the Connected World

3. Chapter 2: Secure Channel and the CIA Triad

4. Chapter 3: A Secret to Share

5. Chapter 4: Encryption and Decryption

6. Chapter 5: Entity Authentication

7. Chapter 6: Transport Layer Security at a Glance

8. Part II Shaking Hands

9. Chapter 7: Public-Key Cryptography

10. Chapter 8: Elliptic Curves

11. Chapter 9: Digital Signatures

12. Chapter 10: Digital Certificates and Certification Authorities

13. Chapter 11: Hash Functions and Message Authentication Codes

14. Chapter 12: Secrets and Keys in TLS 1.3

15. Chapter 13: TLS Handshake Protocol Revisited

16. Part III Off the Record

17. Chapter 14: Block Ciphers and Their Modes of Operation

18. Chapter 15: Authenticated Encryption

19. Chapter 16: The Galois Counter Mode

20. Chapter 17: TLS Record Protocol Revisited

21. Chapter 18: TLS Cipher Suites

22. Part IV Bleeding Hearts and Biting Poodles

23. Chapter 19: Attacks on Cryptography

24. Chapter 20: Attacks on the TLS Handshake Protocol

25. Chapter 21: Attacks on the TLS Record Protocol

26. Chapter 22: Attacks on TLS Implementations

27. Bibliography

28. Index

29. Other Books You Might Enjoy

9.3 Digital signatures based on discrete logarithms

Other than for RSA signatures, we cannot create a signature based on discrete logarithms simply by encrypting the message m with a private key. This is because in the Diffie-Hellman protocol, we only agree on a shared secret between Alice and Bob. In the ElGamal scheme, Alice uses this shared secret, but not her private key for encryption. Moreover, Alice needs Bob’s public key to compute the shared secret. A digital signature scheme should work without knowing any other public keys than the signer’s, however.

The solution is to compute a number that depends on the private key α and to add this number to the hash value of the message to be signed. This number is masked with another secret parameter k so that the private key cannot be computed from the signature. The basic scheme can be found in the paper by ElGamal [62] from 1985. However, today, ElGamal signatures are not widely used because in 1990, Schnorr...

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Table of Contents (30) Chapters

9.3 Digital signatures based on discrete logarithms

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