Public-Key Cryptography

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Public-Key Cryptography Archived NIST Technical Series Publication The attached publication has been archived (withdrawn), and is provided solely for historical purposes. It may have been superseded by another publication (indicated below). Archived Publication Series/Number: NIST Special Publication 800-2 Title: Public Key Cryptography Publication Date(s): April 1991 Withdrawal Date: Withdrawal Note: Superseding Publication(s) The attached publication has been superseded by the following publication(s): Series/Number: Title: Author(s): Publication Date(s): URL/DOI: Additional Information (if applicable) Contact: Computer Security Division (Information Technology Lab) Latest revision of the attached publication: Related information: http://csrc.nist.gov/projects/crypto.html Withdrawal announcement (link): Date updated: June Ϯϯ, 2015 NIST Special Publication 800-2 Pllblic-KeV Cryptography u s. department of COMMERCE National Institute of Standards , and Technology James Nechvatal NATL INST. OF STAND & TECH R.I.C. A111D3 551M7M NIST PUBLICATIONS COMPUTER SECURITY QC 100 U57 800-2 1991 C.2 NATIONAL INSTITUTE OF STANDARDS & TECHNOLOGY Research Informatkai Center Gakhersburg, MD 20899 mm NIST Special Publication 800-2 Public-Key Cryptography James Nechvatal COMPUTER SECURITY Computer Systems Laboratory National Institute of Standards and Technology Gaithersburg, MD 20899 April 1991 U.S. DEPARTMENT OF COMMERCE Robert A. Mosbacher, Secretary NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY John W. Lyons, Director Reports on Computer Systems Technology The National Institute of Standards and Technology (NIST) has a unique responsibility for computer systems technology within the Federal Government. NIST's Computer Systems Laboratory (CSL) devel- ops standards and guidelines, provides technical assistance, and conducts research for computers and related telecommunications systems to achieve more effective utilization of Federal information technol- ogy resources. CSL's responsibilities include development of technical, management, physical, and ad- ministrative standards and guidelines for the cost-effective security and privacy of sensitive unclassified information processed in Federal computers. CSL assists agencies in developing security plans and in improving computer security awareness training. This Special Publication 800 series reports CSL re- search and guidelines to Federal agencies as well as to organizations in industry, government, and academia. National Institute of Standards and Technology Special Publication 800-2 Natl. Inst. Stand. Technol. Spec. Publ. 800-2, 158 pages (Apr. 1991) CODEN: NSPUE2 U.S. GOVERNMENT PRINTING OFFICE WASHINGTON: 1991 For sale by the Superintendent of Documents, U.S. Government Printing Office, Washington, DC 20402 . PREFACE This publication presents a state-of-the-art survey of public- key cryptography circa 1988 - 1990. In doing so, it covers a number of different topics including: 1. The theory of public-key cryptography. 2. Comparisons to conventional (secret-key) cryptography. 3. A largely self-contained summary of relevant mathematics. 4. A survey of major existing public-key systems. 5. An exploration of digital -signatures and hash functions. 6. A survey of public-key implementations in networks. 7. An introduction to zero-knowledge protocols and probabilistic encryption. 8. An exploration of security issues and key sizes. The treatment of public-key cryptography in this publication includes both theory and practice. Much of the existing published work, including those documents listed in the references, treats either the theory or specific systems/implementations, but not both. The viewpoint here is that the theory and practice are inseparable Any mention of commercial products is for purposes of explanation and illustration only. Also, the selection of cryptosystems and hash functions mentioned in this publication serve only to provide examples. Such identification does not imply recommendation or endorsement by the National Institute of Standards and Technology, nor does it imply that systems or functions identified are necessarily the best available for the purpose The focus is on issues such as criteria for systems and protocols for usage. These are presumably long-term, in contrast, to the set of existing public-key systems which is more volatile. Thus we provide information which will hopefully be of use to implementors of systems, but the frameworks we develop are versatile enough to be relevant in a variety of settings. The latter may include, for example, both electronic mail systems and electronic fund transfer systems. The core of this exposition is sections 1 to 5. Sections 1 to 3 iii cover the fundamentals of public-key cryptography and the related topics of hash functions and digital signatures. Extensive coverage of key management is also included, with a focus on certificate- based management. Section 4 gives some examples of public-key systems and hash functions. Section 5 gives some examples of actual or proposed implementations of public-key cryptography. The major example is the International Organization for Standardization (ISO) authentication framework. Section 6 gives a sample proposal for a local-area network implementation of public-key cryptography. It draws heavily on the work of ISO. A variety of topics are covered in the appendices, including a summary of relevant mathematics and algorithms. Also included is a brief introduction to zero-knowledge protocols, probabilistic encryption and identity-based public-key systems. In the following, letters refer to appendices; e.g. lemma G.2.1 refers to a lemma appearing in section 2 of appendix G. The author wishes to thank Dr. Ronald L. Rivest, Dr. Gustavus Simmons, and Dr. Dennis Branstad for providing many comments and suggestions, and Dr. Burton S. Kaliski Jr. for providing information on implementations of the RSA public-key system. The paper was edited by Miles Smid. This paper was supported in part by the United States Department of Computer-Aided Logistics Supports, Department of Defense. iv CONTENTS 1. Cryptosystems and cryptanalysis 1 1.1 Requirements for secrecy 2 1.2 Requirements for authenticity and integrity 4 1 . 3 Conventional systems 5 1.4 Example of a conventional cipher: DES 5 1.5 Another conventional cipher: exponentiation 6 1 . 6 Public-key cryptosystems 7 1.6.1 Secrecy and authenticity 8 1.6.2 Applicability and limitations 10 2 . Key management 12 2 . 1 Secret-key management 12 2.2 Public distribution of secret keys 13 2.3 Management of public components in a public-key system... 15 2.3.1 Use of certificates 16 2.3.2 Generation and storage of component pairs 17 2.3.3 Hardware support for key management 18 2.4 Using public-key systems for secret key distribution 19 2.4.1 A protocol for key exchange 20 2.5 Protocols for certificate-based key management 22 2.5.1 Certificate management by a central authority 22 2.5.2 Decentralized management 23 2.5.3 A phone-book approach to certificates. 24 3. Digital signatures and hash functions 25 3.1 Public-key implementation of signatures 27 3.1.1 Signing messages 27 3.1.2 The issue of nonrepudiat ion 29 3.1.3 The issue of proof of delivery 30 3.2 Hash functions and message digests 31 3.2.1 Usage of hash functions 33 3.2.2 Relation to one-way functions 33 3.2.3 Weak and strong hash functions 34 3.3 Digital signatures and certificate-based systems 35 4. Examples of public-key systems and hash functions 37 4.1 The RSA public-key scheme 39 4.1.1 Choice of p and q 41 v 4.1.2 Further notes on implementation 42 4.1.3 Security of RSA 43 4.1.3.1 Restrictions on p and q 43 4.1.3.2 Notes on factoring 44 4.1.4 Low-exponent versions of RSA 45 4.2 Other public-key systems 46 4.2.1 Knapsack systems 47 4.2.2 The ElGamal signature scheme 4 9 4.3 Examples of hash functions 53 4.3.1 Merkle' s meta-method 53 4.3.2 Coppersmith's attack on Rabin-type functions 56 4.3.3 Quadratic congruential hash functions 57 4.4 Hardware and software support 58 4.4.1 Design considerations for RSA chips 58 4.4.2 Proposed designs for RSA chips 59 5. Implementations of public-key cryptography 61 5 . 1 MITRENET 61 5.2 ISDN 62 5.2.1 Keys 62 5.2.2 Calling 63 5.3 ISO Authentication Framework 64 5.3.1 Use of certificates 64 5.3.2 Certification paths 65 5.3.3 Expiration and revocation of certificates 66 5.3.4 Authentication protocols 67 5.3.5 Further notes 71 5.4 DARPA- Internet 71 6. A sample proposal for a LAN implementation 73 6.1 Integration into a network 73 6 . 2 Security threats 74 6 . 3 Security services 74 6 . 4 Security mechanisms 75 6.5 Criteria for cryptosystems 76 6.5.1 Security 77 6.5.2 Numerical criteria 77 6.5.3 Other criteria 78 6.6 Criteria for hash functions 78 6.7 Example of a LAN security framework 78 6.7.1 Key management 79 6.7.2 Component generation and storage k 7 9 6.7.3 Secret -key generation 79 6.7.4 Issuance and distribution of certificates 80 6.7.5 Compromised or invalidated certificates 80 6.7.6 Authentication 81 vi Appendix A. Mathematical and computational aspects 83 A.l Computational complexity and cryptocomplexity 83 A. 2 Classical complexity theory 84 A. 3 Public-key systems and cryptocomplexity 84 A. 4 Probabilistic algorithms 85 A. 5 Status of some relevant problems 86 Appendix B. Algorithms and architectures 8 9 B. 1 Technology 8 9 B . 2 Computing modes 90 B.3 Some relevant algorithms and implementation ..92 B.3.1 Quadratic sieve factoring algorithm 92 B.3. 2 Computations in finite fields 93 B . 3 . 3 Other algorithms 94 B . 4 Application-specific architectures 94 B.4.1 Systolic and wavefront arrays 94 B.4.2 Proposal for a quadratic sieve machine 95 B.4.3 Massively parallel machines 95 Appendix C.
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