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Hashing in Computer Science: Fifty Years of Slicing and Dicing / Edition 1

Hashing in Computer Science: Fifty Years of Slicing and Dicing / Edition 1

by Alan G. Konheim
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Product Details

ISBN-13: 9780470344736
Publisher: Wiley
Publication date: 07/06/2010
Pages: 408
Product dimensions: 7.20(w) x 10.10(h) x 1.10(d)

About the Author

Alan G. Konheim, PhD, is Professor Emeritus of Computer Science at the University of Californa, Santa Barbara. Dr. Konheim’s early work at IBM led to the Data Encryption Standard (DES), which was evaluated by his Yorktown Probability and Cryptography Group. DES was certified as a national standard in the 1970s. Dr. Konheim continues to consult the government in the area of cryptanalysis.

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Table of Contents



1. Counting.

1.1: The Sum and Product Rules.

1.2: Mathematical Induction.

1.3: Factorial.

1.4: Binomial Coefficients.

1.5: Multinomial Coefficients.

1.6: Permutations.

1.7: Combinations.

1.8: The Principle of Inclusion-Exclusion.

1.9: Partitions.

1.10: Relations.

1.11: Inverse Relations.

Appendix 1: Summations Involving Binomial Coefficients.

2. Recurrence and Generating Functions.

2.1: Recursions.

2.2: Generating Functions.

2.3: Linear Constant Coefficient Recursions.

2.4: Solving Homogeneous LCCRs Using Generating Functions.

2.5: The Catalan Recursion.

2.6: The Umbral Calculus.

2.7: Exponential Generating Functions.

2.8: Partitions of a Set: The Bell and Stirling Numbers.

2.9: Rouché’s Theorem and the Lagrange’sInversion Formula.

3. Asymptotic Analysis.

3.1: Growth Notation for Sequences.

3.2: Asymptotic Sequences and Expansions.

3.3: Saddle Points.

3.4: Laplace’s Method.

3.5: The Saddle Point Method.

3.6: When Will the Saddle Point Method Work?

3.7: The Saddle Point Bounds.

3.8: Examples of Saddle Point Analysis.

4. Discrete Probability Theory.

4.1: The Origins of Probability Theory.

4.2: Chance Experiments, Sample Points, Spaces, and Events.

4.3: Random Variables.

4.4: Moments—Expectation and Variance.

4.5: The Birthday Paradox.

4.6: Conditional Probability and Independence.

4.7: The Law of Large Numbers (LLN).

4.8: The Central Limit Theorem (CLT).

4.9: Random Processes and Markov Chains.

5. Number Theory and Modern Algebra.

5.1: Prime Numbers.

5.2: Modular Arithmetic and the Euclidean Algorithm.

5.3: Modular Multiplication.

5.4: The Theorems of Fermat and Euler.

5.5: Fields and Extension Fields.

5.6: Factorization of Integers.

5.7: Testing Primality.

6. Basic Concepts of Cryptography.

6.1: The Lexicon of Cryptography.

6.2: Stream Ciphers.

6.3: Block Ciphers.

6.4: Secrecy Systems and Cryptanalysis.

6.5: Symmetric and Two-Key Cryptographic Systems.

6.6: The Appearance of Public Key Cryptographic systems.

6.7: A Multitude of Keys.

6.8: The RSA Cryptosystem.

6.9: Does PKC Solve the Problem of Key Distribution?

6.10: Elliptic Groups Over the Reals.

6.11: Elliptic Groups Over the Field Zm,2.

6.12: Elliptic Group Cryptosystems.

6.13: The Menezes-Vanstone Elliptic Curve Cryptosystem.

6.14: Super-Singular Elliptic Curves.


7. Basic Concepts.

7.1: Overview of the Records Management Problem.

7.2: A Simple Storage Management Protocol: Plain VanillaChaining.

7.3: Record-Management with Sorted Keys.

8. Hash Functions.

8.1: The Origin of Hashing.

8.2: Hash Tables.

8.3: A Statistical Model for Hashing.

8.4: The Likelihood of Collisions.

9. Hashing Functions: Examples and Evaluation.

9.1: Overview: The Tradeoff of Randomization VersusComputational Simplicity.

9.2: Some Examples of Hashing Functions.

9.3: Performance of Hash Functions: Formulation.

9.4: The X2-Test.

9.5: Testing a Hash Function.

9.6: The McKenzie et al. Results.

10. Record Chaining with Hash Tables.

10.1: Separate Chaining of Records.

10.2: Analysis of Separate Chaining Hashing Sequences and theChains They Create.

10.3: A Combinatorial Analysis of Separate Chaining.

10.4: Coalesced Chaining.

10.5: The Pittel-Yu Analysis of EICH Coalesced Chaining.

10.6: To Separate or to Coalesce; and Which Version? That Is theQuestion.

11. Perfect Hashing.

11.1: Overview.

11.2: Chichelli’s Construction.

12. The Uniform Hashing Model.

12.1: An Idealized Hashing Model.

12.2: The Asymptotics of Uniform Hashing.

12.3: Collision-Free Hashing.

13. Hashing with Linear Probing.

13.1: Formulation and Preliminaries.

13.2: Performance Measures for LP Hashing.

13.3: All Cells Other than HTn-1 in theHash-Table of n Cells are Occupied.

13.4: m-Keys Hashed into a Hash Table of n CellsLeaving Cell HTn-1 Unoccupied.

13.5: The Probability Distribution for the Length of aSearch.

13.6: Asymptotics.

13.7: Hashing with Linear Open Addressing: Coda.

13.8: A Possible Improvement to Linear Probing.

14. Double Hashing.

14.1: Formulation of Double Hashing.

14.2: Progressions and Strides.

14.3: The Number of Progressions Which Fill a Hash-TableCell.

14.3.1: Progression Graphs.

14.4: Dominance.

14.5: Insertion-Cost Bounds Relating Uniform and DoubleHashing.

14.6: UsuallyDoubleHash.

14.7: The UDH Chance Experiment and the Cost to Insert the NextKey by Double Hashing.

14.8: Proof of Equation (14.12a).

14.9: UsuallyDoubleHash.

14.10: Proof of Equation (14.12b).

15. Optimum Hashing.

15.1: The Ullman–Yao Framework.

15.1.1: The Ullman–Yao Hashing Functions.

15.1.2: Ullman–Yao INSERT(k) and SEARCH(k).

15.1.3: The Ullman–Yao Statistical Model.

15.2: The Rates at Which a Cell is Probed and Occupied.

15.3: Partitions of (i)Scenarios,(i)Subscenarios, and Their Skeletons.

15.3.1: (i)Subscenarios.

15.3.2: Skeletons.

15.4: Randomly Generated m-Scenarios.

15.5: Bounds on Random Sums.

15.6: Completing the Proof of Theorem 15.1.


16. Karp-Rabin String Searching.

16.1: Overview.

16.2: The Basic Karp-Rabin Hash-Fingerprint Algorithm.

16.3: The Plain Vanilla Karp-Rabin Fingerprint Algorithm.

16.4: Some Estimates on Prime Numbers.

16.5: The Cost of False Matches in the Plain Vanilla Karp-RabinFingerprint Algorithm.

16.6: Variations on the Plain Vanilla Karp-Rabin FingerprintAlgorithm.

16.7: A Nonhashing Karp-Rabin Fingerprint.

17. Hashing Rock and Roll.

17.1: Overview of Audio Fingerprinting .

17.2: The Basics of Fingerprinting Music.

17.3: Haar Wavelet Coding.

17.4: Min-Hash.

17.5: Some Commercial Fingerprinting Products.

18. Hashing in E-Commerce.

18.1: The Varied Applications of Cryptography.

18.2: Authentication.

18.3: The Need for Certificates.

18.4: Cryptographic Hash Functions.

18.5: X.509 Certificates and CCIT Standardization.

18.6: The Secure Socket Layer (SSL).

18.7: Trust on the Web ... Trust No One Over 40!

18.8: MD5.

18.9: Criticism of MD5.

18.10: The Wang-Yu Collision Attack.

18.11: Steven’s Improvement to the Wang-Yu CollisionAttack.

18.12: The Chosen-Prefix Attack on MD5.

18.13: The Rogue CA Attack Scenario.

18.14: The Secure Hash Algorithms.

18.15: Criticism of SHA-1.

18.16: SHA-2.

18.17: What Now?

Appendix 18: Sketch of the Steven’s Chosen PrefixAttack.

19. Hashing and the Secure Distribution of DigitalMedia.

19.1: Overview.

19.2: Intellectual Property (Copyrights and Patents).

19.3: Steganography.

19.4: Boil, Boil, Toil ... and But First, Carefully Mix.

19.5: Software Distribution Systems.

19.6: Watermarks.

19.7: An Image-Processing Technique for Watermarking.

19.8: Using Geometric Hashing to Watermark Images.

19.9: Biometrics and Hashing.

19.10: The Dongle.

Appendix 19: Reed-Solomon and Hadamard Coding.

Exercises and Solutions.


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"Graduate students and researchers in mathematics, cryptography, and security will benefit from this overview of hashing and the complicated mathematics that it requires." (Forums Digital Media Net, 27 October 2010)

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