20 January 1999. Thanks to JF.
Source: http://csrc.nist.gov/fips/dfips46-3.pdf (209K)

See related Federal Register notice: http://jya.com/nist011599.txt and NIST notes at: http://csrc.nist.gov/cryptval

Page numbers as shown on PDF file.



D R A F T
FIPS PUB 46-3

FEDERAL INFORMATION
PROCESSING STANDARDS PUBLICATION

Reaffirmed
<approval date> 1999


U.S. DEPARTMENT OF COMMERCE/National Institute of Standards and Technology



DATA ENCRYPTION STANDARD (DES)

CATEGORY: COMPUTER SECURITY
SUBCATEGORY: CRYPTOGRAPHY

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U.S. DEPARTMENT OF COMMERCE, William M. Daley, Secretary
NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY,
Raymond G. Kammer, Director

Foreword

The Federal Information Processing Standards Publication Series of the National Institute of Standards and Technology (NIST) is the official series of publications relating to standards and guidelines adopted and promulgated under the provisions of Section 5131 of the Information Technology Management Reform Act of 1996 (Public Law 104-106) , and the Computer Security Act of 1987 (Public Law 100-235). These mandates have given the Secretary of Commerce and NIST important responsibilities for improving the utilization and management of computer and related telecommunications systems in the Federal Government. The NIST, through its Information Technology Laboratory, provides leadership, technical guidance, and coordination of Government efforts in the development of standards and guidelines in these areas.

Comments concerning Federal Information Processing Standards Publications are welcomed and should be addressed to the Director, Information Technology Laboratory, National Institute of Standards and Technology, Gaithersburg, MD 20899.

Shukri Wakid, Director
Information Technology Laboratory

Abstract

The selective application of technological and related procedural safeguards is an important responsibility of every Federal organization in providing adequate security to its electronic data systems. This publication specifies two cryptographic algorithms, the Data Encryption Algorithm (DEA) and the Triple Data Encryption Algorithm (TDEA) which may be used by Federal organizations to protect sensitive data. Protection of data during transmission or while in storage may be necessary to maintain the confidentiality and integrity of the information represented by the data. The algorithms uniquely define the mathematical steps required to transform data into a cryptographic cipher and also to transform the cipher back to the original form. The Data Encryption Standard is being made available for use by Federal agencies within the context of a total security program consisting of physical security procedures, good information management practices, and computer system/network access controls. This revision supersedes FIPS 46-2 in its entirety.

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Key words: computer security, data encryption standard, Federal Information Processing Standard (FIPS); security.

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Federal Information
Processing Standards Publication 46-3

1999 <approval date>

Announcing the

DATA ENCRYPTION STANDARD

Federal Information Processing Standards Publications (FIPS PUBS) are issued by the National Institute of Standards and Technology after approval by the Secretary of Commerce pursuant to Section 5131 of the Information Technology Management Reform Act of 1996 (Public Law 104-106), and the Computer Security Act of 1987 (Public Law 100-235).

1. Name of Standard. Data Encryption Standard (DES).

2. Category of Standard. Computer Security, Cryptography.

3. Explanation. The Data Encryption Standard (DES) specifies two FIPS approved cryptographic algorithms as required by FIPS 140-1. When used in conjunction with American National Standards Institute (ANSI) X9.52 standard, this publication provides a complete description of the mathematical algorithms for encrypting (enciphering) and decrypting (deciphering) binary coded information. Encrypting data converts it to an unintelligible form called cipher. Decrypting cipher converts the data back to its original form called plaintext. The algorithms described in this standard specifies both enciphering and deciphering operations which are based on a binary number called a key.

A DEA key consists of 64 binary digits ("0"s or "1"s) of which 56 bits are randomly generated and used directly by the algorithm. The other 8 bits, which are not used by the algorithm, may be used for error detection. The 8 error detecting bits are set to make the parity of each 8-bit byte of the key odd, i.e., there is an odd number of "1"s in each 8-bit byte1. A TDEA key consists of three DEA keys, which is also referred to as a key bundle. Authorized users of encrypted computer data must have the key that was used to encipher the data in order to decrypt it. The encryption algorithms specified in this standard are commonly known among those using the standard. The cryptographic

_________________

1 Sometimes keys are generated in an encrypted form. A random 64-bit number is generated and defined to be the cipher formed by the encryption of a key using a key encrypting key. In this case the parity bits of the encrypted key cannot be set until after the key is decrypted.

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security of the data depends on the security provided for the key used to encipher and decipher the data.

Data can be recovered from cipher only by using exactly the same key used to encipher it. Unauthorized recipients of the cipher who know the algorithm but do not have the correct key cannot derive the original data algorithmically. However, it may be feasible to determine the key by a brute force “exhaustion attack.” Also, anyone who does have the key and the algorithm can easily decipher the cipher and obtain the original data. A standard algorithm based on a secure key thus provides a basis for exchanging encrypted computer data by issuing the key used to encipher it to those authorized to have the data.

Data that is considered sensitive by the responsible authority, data that has a high value, or data that represents a high value should be cryptographicalIy protected if it is vulnerable to unauthorized disclosure or undetected modification during transmission or while in storage. A risk analysis should be performed under the direction of a responsible authority to determine potential threats. The costs of providing cryptographic protection using this standard as well as alternative methods of providing this protection and their respective costs should be projected. A responsible authority then should make a decision, based on these analyses, whether or not to use cryptographic protection and this standard.

4. Approving Authority. Secretary of Commerce.

5. Maintenance Agency. U.S. Department of Commerce, National Institute of Standards and Technology, Information Technology Laboratory.

6. Applicability. This standard may be used by Federal departments and agencies when the following conditions apply:

1. An authorized official or manager responsible for data security or the security of any computer system decides that cryptographic protection is required; and

2. The data is not classified according to the National Security Act of 1947, as amended, or the Atomic Energy Act of 1954, as amended.

Federal agencies or departments which use cryptographic devices for protecting data classified according to either of these acts can use those devices for protecting sensitive data in lieu of the standard.

Other FIPS approved cryptographic algorithms may be used in addition to, or in lieu of, this standard when implemented in accordance with FIPS 140-1.

In addition, this standard may be adopted and used by non-Federal Government organizations. Such use is encouraged when it provides the desired security for commercial and private organizations.

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7. Applications. Data encryption (cryptography) is utilized in various applications and environments. The specific utilization of encryption and the implementation of the DEA and TDEA will be based on many factors particular to the computer system and its associated components. In general, cryptography is used to protect data while it is being communicated between two points or while it is stored in a medium vulnerable to physical theft. Communication security provides protection to data by enciphering it at the transmitting point and deciphering it at the receiving point. DEA forms the basis for TDEA. File security provides protection to data by enciphering it when it is recorded on a storage medium and deciphering it when it is read back from the storage medium. In the first case, the key must be available at the transmitter and receiver simultaneously during communication. In the second case, the key must be maintained and accessible for the duration of the storage period. FIPS 171 provides approved methods for managing the keys used by the algorithms specified in this standard. Public-key based protocols may also be used (e.g., ANSI X9.42).

8. Implementations. Cryptographic modules which implement this standard shall conform to the requirements of FIPS 140-1. The algorithms specified in this standard may be implemented in software, firmware, hardware, or any combination thereof. The specific implementation may depend on several factors such as the application, the environment, the technology used, etc. Implementations which may comply with this standard include electronic devices (e.g., VLSI chip packages), micro-processors using Read Only Memory (ROM), Programmable Read Only Memory (PROM), or Electronically Erasable Read Only Memory (EEROM), and mainframe computers using Random Access Memory (RAM). When an algorithm is implemented in software or firmware, the processor on which the algorithm runs must be specified as part of the validation process. Implementations of an algorithm which are tested and validated by NIST will be considered as complying with the standard. Note that FIPS 140-1 places additional requirements on cryptographic modules for Government use. Information about devices that have been validated and procedures for testing and validating equipment for conformance with this standard and FIPS 140-1 are available from the National Institute of Standards and Technology, Information Technology Laboratory, Gaithersburg, MD 20899.

9. Export Control. Cryptographic devices and technical data regarding them are subject to Federal Government export controls and exports of cryptographic modules implementing this standard and technical data regarding them must comply with these Federal regulations and be licensed by the Bureau of Export Administration of the U.S. Department of Commerce.

10. Patents. Cryptographic devices implementing this standard may be covered by U.S. and foreign patents, including patents issued to the International Business Machines Corporation. However, IBM has granted nonexclusive, royalty-free licenses under the patents to make, use and sell apparatus which complies with the standard. The terms, conditions and scope of the licenses are set out in notices published in the May 13, 1975 and August 31, 1976 issues of the Official Gazette of the United States Patent and Trademark Office (934 O.G. 452 and 949 O.G. 1717).

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11. Alternative Modes of Using the DEA and TDEA. FIPS PUB 81, DES Modes of Operation, describes four different modes for using DEA described in this standard. These four modes are called the Electronic Codebook (ECB) mode, the Cipher Block Chaining (CBC) mode, the Cipher Feedback (CFB) mode, and the Output Feedback (OFB) mode. ECB is a direct application of the DES algorithm to encrypt and decrypt data; CBC is an enhanced mode of ECB which chains together blocks of cipher text; CFB uses previously generated cipher text as input to the DES to generate pseudorandom outputs which are combined with the plaintext to produce cipher, thereby chaining together the resulting cipher; OFB is identical to CFB except that the previous output of the DES is used as input in OFB while the previous cipher is used as input in CFB. OFB does not chain the cipher.

The X9.52 standard, “Triple Data Encryption Algorithm Modes of Operation” describes seven different modes for using TDEA described in this standard. These seven modes are called the TDEA Electronic Codebook Mode of Operation (TECB) mode, the TDEA Cipher Block Chaining Mode of Operation (TCBC), the TDEA Cipher Block Chaining Mode of Operation - Interleaved (TCBC-I), the TDEA Cipher Feedback Mode of Operation (TCFB), the TDEA Cipher Feedback Mode of Operation - Pipelined (TCFB-P), the TDEA Output Feedback Mode of Operation (TOFB), and the TDEA Output Feedback Mode of Operation - Interleaved (TOFB-I). The TECB, TCBC, TCFB and TOBF modes are based upon the ECB, CBC, CFB and OFB modes respectively obtained by substituting the DEA encryption/decryption operation with the TDEA encryption/decryption operation.

12. Implementation of this standard. This standard became effective July 1977. It was reaffirmed in 1983, 1988, 1993, and 1999, if approved. It applies to all Federal agencies, contractors of Federal agencies, or other organizations that process information (using a computer or telecommunications system) on behalf of the Federal Government to accomplish a Federal function. Each Federal agency or department may issue internal directives for the use of this standard by their operating units based on their data security requirement determinations.

With this modification of the FIPS 46-2 standard:

1. Triple DES (i.e., TDEA), as specified in ANSI X9.52 will be recognized as a FIPS approved algorithm.

2. Triple DES will be the FIPS approved symmetric encryption algorithm of choice.

3. Single DES (i.e., DEA) will be permitted for legacy systems only. New procurements to support legacy systems should, where, feasible, use Triple DES products running in the single DES configuration.

4. Government organizations with legacy DES systems are encouraged to transition to Triple DES based on a prudent strategy that matches the strength of the protective measures against the associated risk.

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Note: It is anticipated that triple DES and the Advanced Encryption Standard (AES) will coexist as FIPS approved algorithms allowing for a gradual transition to AES. (The AES is a new symmetric-based encryption standard under development by NIST. AES is intended to provide strong cryptographic security for the protection of sensitive information well into the 21 st century.)

NIST provides technical assistance to Federal agencies in implementing data encryption through the issuance of standards, guidelines and through individual reimbursable projects.

13. Specifications. Federal Information Processing Standard (FIPS) 46-3, Data Encryption Standard (DES) (affixed).

14. Cross Index.

a. FIPS PUB 31, Guidelines to ADP Physical Security and Risk Management.

b. FIPS PUB 39, Glossary for Computer Systems Security.

c. FIPS PUB 73, Guidelines for Security of Computer Applications.

d. FIPS PUB 74, Guidelines for Implementing and Using the NBS Data Encryption Standard.

e. FIPS PUB 81, DES Modes of Operation.

f. FIPS PUB 87, Guidelines for ADP Contingency Planning.

g. FIPS PUB 112, Password Usage.

h. FIPS PUB 113, Computer Data Authentication.

i. FIPS PUB 140-1, Security Requirements for Cryptographic Modules.

j. FIPS PUB 171, Key Management Using ANSI X9.17.

k. ANSI X9.42, Agreement of Symmetric Keys on Using Diffie-Hellman and MQV Algorithms

l. ANSI X9.52, Triple Data Encryption Algorithm Modes of Operation

15. Qualifications.

Both this standard and possible threats reducing the security provided through the use of this standard will undergo review by NIST as appropriate, taking into account newly available technology. In addition, the awareness of any breakthrough in technology or any mathematical weakness of the algorithm will cause NIST to reevaluate this standard and provide necessary revisions.

With regard to the use of single DES, exhaustion of the DES (i.e., breaking a DES encrypted ciphertext by trying all possible keys) has become increasingly more feasible with technology advances. Following a recent hardware based DES key exhaustion attack, NIST can no longer support the use of single DES for many applications. Therefore, Government agencies with legacy single DES systems are encouraged to transition to Triple DES. Agencies are advised to implement Triple DES when building new systems.

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16. Comments. Comments and suggestions regarding this standard and its use are welcomed and should be addressed to the National Institute of Standards and Technology, Attn: Director, Information Technology Laboratory, Gaithersburg, MD 20899.

17. Waiver Procedure. Under certain exceptional circumstances, the heads of Federal departments and agencies may approve waivers to Federal Information Processing Standards (FIPS). The head of such agency may redelegate such authority only to a senior official designated pursuant to section 3506(b) of Title 44, United States Code. Waiver shall be granted only when:

a. Compliance with a standard would adversely affect the accomplishment of the mission of an operator of a Federal computer system; or

b. Compliance with a standard would cause a major adverse financial impact on the operator which is not offset by Government-wide savings.

Agency heads may act upon a written waiver request containing the information detailed above. Agency heads may also act without a written waiver request when they determine that conditions for meeting the standard cannot be met. Agency heads may approve waivers only by a written decision which explains the basis on which the agency head made the required finding(s). A copy of each decision, with procurement sensitive or classified portions clearly identified, shall be sent to: National Institute of Standards and Technology; ATTN: FIPS Waiver Decisions100 Bureau Drive, Stop 8970, Gaithersburg, MD 20899-8970.

In addition, notice of each waiver granted and each delegation of authority to approve waivers shall be sent promptly to the Committee on Government Operations of the House of Representatives and the Committee on Government Affairs of the Senate and shall be published promptly in the Federal Register.

When the determination on a waiver applies to the procurement of equipment and/or services, a notice of the waiver determination must be published in the Commerce Business Daily as a part of the notice of solicitation for offers of an acquisition or, if the waiver determination is made after that notice is published, by amendment to such notice.

A copy of the waiver, any supporting documents, the document approving the waiver and any accompanying documents, with such deletions as the agency is authorized and decides to make under 5 United States Code Section 552(b), shall be part of the procurement documentation and retained by the agency.

18. Special Information. In accordance with the Qualifications Section of this standard, reviews of this standard have been conducted every 5 years since its adoption in 1977. The standard was reaffirmed during each of those reviews. This revision to the text of the standard contains changes which allow software implementations of the algorithm, permit the use of other FIPS approved

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cryptographic algorithms, and designate Triple DES (i.e., TDEA) as a FIPS approved cryptographic algorithm.

19. Where to Obtain Copies of the Standard. Copies of this publication are for sale by the National Technical Information Service, U.S. Department of Commerce, Springfield, VA 22161. When ordering, refer to Federal Information Processing Standards Publication 46-3 (FIPSPUB463), and identify the title. When microfiche is desired, this should be specified. Prices are published by NTIS in current catalogs and other issuances. Payment may be made by check, money order, deposit account or charged to a credit card accepted by NTIS.

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Federal Information
Processing Standards Publication 46-3

1999 <approval date>

SPECIFICATIONS FOR THE

DATA ENCRYPTION STANDARD (DES)

The Data Encryption Standard (DES) shall consist of the following Data Encryption Algorithm (DEA) and Triple Data Encryption Algorithm (TDEA, as described in ANSI X9.52). These devices shall be designed in such a way that they may be used in a computer system or network to provide cryptographic protection to binary coded data. The method of implementation will depend on the application and environment. The devices shall be implemented in such a way that they may be tested and validated as accurately performing the transformations specified in the following algorithms.

DATA ENCRYPTION ALGORITHM

Introduction

The algorithm is designed to encipher and decipher blocks of data consisting of 64 bits under control of a 64-bit key.** Deciphering must be accomplished by using the same key as for enciphering, but with the schedule of addressing the key bits altered so that the deciphering process is the reverse of the enciphering process. A block to be enciphered is subjected to an initial permutation IP, then to a complex key-dependent computation and finally to a permutation which is the inverse of the initial permutation IP-1. The key-dependent computation can be simply defined in terms of a function f, called the cipher function, and a function KS, called the key schedule. A description of the computation is given first, along with details as to how the algorithm is used for encipherment. Next, the use of the algorithm for decipherment is described. Finally, a definition of the cipher function f is given in terms of primitive functions which are called the selection functions Si and the permutation function P. Si, P and KS of the algorithm are contained in the Appendix.

___________________

** Blocks are composed of bits numbered from left to right, i.e., the left most bit of a block is bit one.

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Figure 1

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The following notation is convenient: Given two blocks L and R of bits, LR denotes the block consisting of the bits of L followed by the bits of R. Since concatenation is associative, B1B2...B8, for example, denotes the block consisting of the bits of B1 followed by the bits of B2...followed by the bits of B8.

Enciphering

A sketch of the enciphering computation is given in Figure 1.

The 64 bits of the input block to be enciphered are first subjected to the following permutation, called the initial permutation IP:

IP

58  50  42  34  26  18  10  2
60  52  44  36  28  20  12  4
62  54  46  38  30  22  14  6
64  56  48  40  32  24  16  8
57  49  41  33  25  17   9  1
59  51  43  35  27  19  11  3
61  53  45  37  29  21  13  5
63  55  47  39  31  23  15  7

That is the permuted input has bit 58 of the input as its first bit, bit 50 as its second bit, and so on with bit 7 as its last bit. The permuted input block is then the input to a complex key-dependent computation described below. The output of that computation, called the preoutput, is then subjected to the following permutation which is the inverse of the initial permutation:

IP-1

40  8  48  16  56  24  64  32
39  7  47  15  55  23  63  31
38  6  46  14  54  22  62  30
37  5  45  13  53  21  61  29
36  4  44  12  52  20  60  28
35  3  43  11  51  19  59  27
34  2  42  10  50  18  58  26
33  1  41   9  49  17  57  25

That is, the output of the algorithm has bit 40 of the preoutput block as its first bit, bit 8 as its second bit, and so on, until bit 25 of the preoutput block is the last bit of the output.

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The computation which uses the permuted input block as its input to produce the preoutput block consists, but for a final interchange of blocks, of 16 iterations of a calculation that is described below in terms of the cipher function f which operates on two blocks, one of 32 bits and one of 48 bits, and produces a block of 32 bits.

Let the 64 bits of the input block to an iteration consist of a 32 bit block L followed by a 32 bit block R. Using the notation defined in the introduction, the input block is then LR.

Let K be a block of 48 bits chosen from the 64-bit key. Then the output L'R' of an iteration with input LR is defined by:

(1)

L' = R

R' = L (+) f(R,K)

where (+) denotes bit-by-bit addition modulo 2.

As remarked before, the input of the first iteration of the calculation is the permuted input block. If L'R' is the output of the 16th iteration then R'L' is the preoutput block. At each iteration a different block K of key bits is chosen from the 64-bit key designated by KEY.

With more notation we can describe the iterations of the computation in more detail. Let KS be a function which takes an integer n in the range from 1 to 16 and a 64-bit block KEY as input and yields as output a 48-bit block Kn which is a permuted selection of bits from KEY. That is

(2)

Kn = KS(n,KEY)

with Kn determined by the bits in 48 distinct bit positions of KEY. KS is called the key schedule because the block K used in the n'th iteration of (1) is the block Kn determined by (2).

As before, let the permuted input block be LR. Finally, let L() and R() be respectively L and R and let Ln and Rn be respectively L' and R' of (1) when L and R are respectively Ln-1 and Rn-1 and K is Kn; that is, when n is in the range from 1 to 16,

(3)

Ln = Rn-1

Rn = Ln-1 (+) f(Rn-1,Kn)

The preoutput block is then R16L16.

The key schedule KS of the algorithm is described in detail in the Appendix. The key schedule produces the 16 Kn which are required for the algorithm.

Deciphering

The permutation IP-1 applied to the preoutput block is the inverse of the initial permutation IP applied to the input. Further, from (1) it follows that:

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(4)

R = L'

L = R' (+) f(L',K)

Consequently, to decipher it is only necessary to apply the very same algorithm to an enciphered message block, taking care that at each iteration of the computation the same block of key bits K is used during decipherment as was used during the encipherment of the block. Using the notation of the previous section, this can be expressed by the equations:

(5)

Rn-1 = Ln

Ln-1 = Rn (+) f(Ln,Kn)

where now R16L16 is the permuted input block for the deciphering calculation and L0R0 is the preoutput block. That is, for the decipherment calculation with R16L16 as the permuted input, K16 is used in the first iteration, K15 in the second, and so on, with K1 used in the 16th iteration.

The Cipher Function f

A sketch of the calculation of f(R,K) is given in Figure 2.

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Figure 2

Let E denote a function which takes a block of 32 bits as input and yields a block of 48 bits as output. Let E be such that the 48 bits of its output, written as 8 blocks of 6 bits each, are obtained by selecting the bits in its inputs in order according to the following table:

E BIT-SELECTION TABLE

 32   1   2   3   4   5
  4   5   6   7   8   9
  8   9  10  11  12  13
 12  13  14  15  16  17
 16  17  18  19  20  21
 20  21  22  23  24  25
 24  25  26  27  28  29
 28  29  30  31  32   1

Thus the first three bits of E(R) are the bits in positions 32, 1 and 2 of R while the last 2 bits of E(R) are the bits in positions 32 and 1.

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Each of the unique selection functions S1,S2,...,S8, takes a 6-bit block as input and yields a 4-bit block as output and is illustrated by using a table containing the recommended S1:

S1

                              Column Number
Row
No.   0   1   2   3   4   5   6   7   8   9  10  11  12  13  14  15

  0  14   4  13   1   2  15  11   8   3  10   6  12   5   9   0   7
  1   0  15   7   4  14   2  13   1  10   6  12  11   9   5   3   8
  2   4   1  14   8  13   6   2  11  15  12   9   7   3  10   5   0
  3  15  12   8   2   4   9   1   7   5  11   3  14  10   0   6  13

If S1 is the function defined in this table and B is a block of 6 bits, then S1(B)is determined as follows: The first and last bits of B represent in base 2 a number in the range 0 to 3. Let that number be i. The middle 4 bits of B represent in base 2 a number in the range 0 to 15. Let that number be j. Look up in the table the number in the i'th row and j'th column. It is a number in the range 0 to 15 and is uniquely represented by a 4 bit block. That block is the output S1(B) of S1 for the input B. For example, for input 011011 the row is 01, that is row 1, and the column is determined by 1101, that is column 13. In row 1 column 13 appears 5 so that the output is 0101. Selection functions S1,S2,...,S8 of the algorithm appear in the Appendix.

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The permutation function P yields a 32-bit output from a 32-bit input by permuting the bits of the input block. Such a function is defined by the following table:

P

16   7  20  21
29  12  28  17
 1  15  23  26
 5  18  31  10
 2   8  24  14
32  27   3   9
19  13  30   6
22  11   4  25

The output P(L) for the function P defined by this table is obtained from the input L by taking the 16th bit of L as the first bit of P(L), the 7th bit as the second bit of P(L), and so on until the 25th bit of L is taken as the 32nd bit of P(L). The permutation function P of the algorithm is repeated in the Appendix.

Now let S1,...,S8 be eight distinct selection functions, let P be the permutation function and let E be the function defined above.

To define f(R,K) we first define B1,...,B8 to be blocks of 6 bits each for which

(6)

B1B2...B8 = K (+) E(R)

The block f(R,K) is then defined to be

(7)

P(S1(B1)S2(B2)...S8(B8))

Thus K (+) E(R) is first divided into the 8 blocks as indicated in (6). Then each Bi is taken as an input to Si and the 8 blocks S1(B1),S2(B2)...S8(B8) of 4 bits each are consolidated into a single block of 32 bits which forms the input to P. The output (7) is then the output of the function f for the inputs R and K.

TRIPLE DATA ENCRYPTION ALGORITHM

Let EK(I) and DK(I) represent the DEA encryption and decryption of I using DEA key K respectively. Each TDEA encryption/decryption operation (as specified in ANSI X9.52) is a compound operation of DEA encryption and decryption operations. The following operations are used:

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1. TDEA encryption operation: the transformation of a 64-bit block I into a 64-bit block O that is defined as follows:

O = EK3(DK2(EK1(I))).

2. TDEA decryption operation: the transformation of a 64-bit block I into a 64-bit block O that is defined as follows:

O = DK1(EK2(DK3(I)))

The standard specifies the following keying options for bundle (K1, K2, K3)

1. Keying Option 1: K1, K2, and K3 are independent keys;

2. Keying Option 2: K1 and K2 are independent keys and K3 = K1;

3. Keying Option 3: K1 = K2 = K3.

A TDEA mode of operation is backward compatible with its single DEA counterpart if, with compatible keying options for TDEA operation,

1. an encrypted plaintext computed using a single DEA mode of operation can be decrypted correctly by a corresponding TDEA mode of operation; and

2. an encrypted plaintext computed using a TDEA mode of operation can be decrypted correctly by a corresponding single DEA mode of operation.

When using Keying Option 3 (K1 = K2 = K3), TECB, TCBC, TCFB and TOFB modes are backward compatible with single DEA modes of operation ECB, CBC, CFB, OFB respectively.

The diagram in Appendix 2 illustrates TDEA encryption and TDEA decryption.

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APPENDIX 1

PRIMITIVE FUNCTIONS FOR THE
DATA ENCRYPTION ALGORITHM

The choice of the primitive functions KS, S1,...,S8 and P is critical to the strength of an encipherment resulting from the algorithm. Specified below is the recommended set of functions, describing S1,...,S8 and P in the same way they are described in the algorithm. For the interpretation of the tables describing these functions, see the discussion in the body of the algorithm.

The primitive functions S1,...,S8 are:

[JYA Note: O in tables as written.]

S1

14   4  13   1   2  15  11   8   3  10   6  12   5   9   0   7
 O  15   7   4  14   2  13   1  10   6  12  11   9   5   3   8
 4   1  14   8  13   6   2  11  15  12   9   7   3  10   5   0
15  12   8   2   4   9   1   7   5  11   3  14  10   O   6  13

S2

15   1   8  14   6  11   3   4   9   7   2  13  12   O   5  10
 3  13   4   7  15   2   8  14  12   0   1  10   6   9  11   5
 0  14   7  11  10   4  13   1   5   8  12   6   9   3   2  15
13   8  10   1   3  15   4   2  11   6   7  12   0   5  14   9

S3

10   0   9  14   6   3  15   5   1  13  12   7  11   4   2   8
13   7   O   9   3   4   6  10   2   8   5  14  12  11  15   1
13   6   4   9   8  15   3   0  11   1   2  12   5  10  14   7
 1  10  13   0   6   9   8   7   4  15  14   3  11   5   2  12

S4

 7  13  14   3   0   6   9  10   1   2   8   5  11  12   4  15
13   8  11   5   6  15   O   3   4   7   2  12   1  10  14   9
10   6   9   0  12  11   7  13  15   1   3  14   5   2   8   4
 3  15   O   6  10   1  13   8   9   4   5  11  12   7   2  14

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S5

 2  12   4   1   7  10  11   6   8   5   3  15  13   O  14   9
14  11   2  12   4   7  13   1   5   0  15  10   3   9   8   6
 4   2   1  11  10  13   7   8  15   9  12   5   6   3   O  14
11   8  12   7   1  14   2  13   6  15   O   9  10   4   5   3

S6

12   1  10  15   9   2   6   8   O  13   3   4  14   7   5  11
10  15   4   2   7  12   9   5   6   1  13  14   O  11   3   8
 9  14  15   5   2   8  12   3   7   0   4  10   1  13  11   6
 4   3   2  12   9   5  15  10  11  14   1   7   6   0   8  13

S7

 4  11   2  14  15   0   8  13   3  12   9   7   5  10   6   1
13   0  11   7   4   9   1  10  14   3   5  12   2  15   8   6
 1   4  11  13  12   3   7  14  10  15   6   8   0   5   9   2
 6  11  13   8   1   4  10   7   9   5   0  15  14   2   3  12

S8

13   2   8   4   6  15  11   1  10   9   3  14   5   0  12   7
 1  15  13   8  10   3   7   4  12   5   6  11   0  14   9   2
 7  11   4   1   9  12  14   2   0   6  10  13  15   3   5   8
 2   1  14   7   4  10   8  13  15  12   9   0   3   5   6  11

The primitive function P is:

16   7  20  21
29  12  28  17
 1  15  23  26
 5  18  31  10
 2   8  24  14
32  27   3   9
19  13  30   6
22  11   4  25

Recall that Kn, for 1<n<16, is the block of 48 bits in (2) of the algorithm. Hence, to describe KS, it is sufficient to describe the calculation of Kn from KEY for n = 1, 2,..., 16. That calculation is illustrated in Figure 3. To complete the definition of KS it is therefore sufficient to describe the two

18


permuted choices, as well as the schedule of left shifts. One bit in each 8-bit byte of the  KEY may be utilized for error detection in key generation, distribution and storage. Bits 8, 16,..., 64 are for use in assuring that each byte is of odd parity.

Permuted choice 1 is determined by the following table:

PC-1

57  49  41  33  25  17   9
 1  58  50  42  34  26  18
10   2  59  51  43  35  27
19  11   3  60  52  44  36
63  55  47  39  31  23  15
 7  62  54  46  38  30  22
14   6  61  53  45  37  29
21  13   5  28  20  12   4

The table has been divided into two parts, with the first part determining how the bits of C() are chosen, and the second part determining how the bits of D() are chosen. The bits of KEY are numbered 1 through 64. The bits of C() are respectively bits 57, 49, 41,..., 44 and 36 of KEY, with the bits of D() being bits 63, 55, 47,..., 12 and 4 of KEY.

With C() and D() defined, we now define how the blocks Cn and Dn are obtained from the blocks Cn-1 and Dn-1, respectively, for n = 1, 2,..., 16. That is accomplished by adhering to the following schedule of left shifts of the individual blocks:

19


Figure 3

20


Iteration
Number
   

Number of
Left Shifts

   1
   2
   3
   4
   5
   6
   7
   8
   9
  10
  11
  12
  13
  14
  15
  16

   1
   1
   2
   2
   2
   2
   2
   2
   1
   2
   2
   2
   2
   2
   2
   1

For example, C3 and D3 are obtained from C2 and D2, respectively, by two left shifts, and C16 and D16 are obtained from C15 and D15, respectively, by one left shift. In all cases, by a single left shift is meant a rotation of the bits one place to the left, so that after one left shift the bits in the 28 positions are the bits that were previously in positions 2, 3,..., 28, 1.

Permuted choice 2 is determined by the following table:

PC-2

14  17  11  24   1   5
 3  28  15   6  21  10
23  19  12   4  26   8
16   7  27  20  13   2
41  52  31  37  47  55
30  40  51  45  33  48
44  49  39  56  34  53
46  42  50  36  29  32

Therefore, the first bit of Kn is the 14th bit of CnDn, the second bit the 17th, and so on with the 47th bit the 29th, and the 48th bit the 32nd.

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APPENDIX 2
TRIPLE DEA BLOCK DIAGRAM
(ECB Mode)

TDEA Encryption Operation:

TDEA Decryption Operation:



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[End]

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