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== Literature ==
== Literature ==
* {{cite book |doi=10.1007/978-3-540-24654-1_9 |chapter=A New Meet-in-the-Middle Attack on the IDEA Block Cipher |title=Selected Areas in Cryptography |series=Lecture Notes in Computer Science |year=2004 |last1=Demirci |first1=Hüseyin |last2=Selçuk |first2=Ali Aydin |last3=Türe |first3=Erkan |volume=3006 |pages=117–129 |isbn=978-3-540-21370-3 }}
* Hüseyin Demirci, Erkan Türe, Ali Aydin Selçuk, A New Meet in the Middle Attack on The IDEA Block Cipher, 10th Annual Workshop on [[Selected Areas in Cryptography]], 2004.
* Xuejia Lai and James L. Massey, [http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.14.3451 A Proposal for a New Block Encryption Standard], [[EUROCRYPT]] 1990, pp. 389–404
* {{cite book |doi=10.1007/3-540-46877-3_35 |citeseerx=10.1.1.14.3451 |chapter=A Proposal for a New Block Encryption Standard |title=Advances in Cryptology — EUROCRYPT '90 |series=Lecture Notes in Computer Science |year=1991 |last1=Lai |first1=Xuejia |last2=Massey |first2=James L. |volume=473 |pages=389–404 |isbn=978-3-540-53587-4 }}
* {{cite book |doi=10.1007/3-540-46416-6_2 |chapter=Markov Ciphers and Differential Cryptanalysis |title=Advances in Cryptology — EUROCRYPT '91 |series=Lecture Notes in Computer Science |year=1991 |last1=Lai |first1=Xuejia |last2=Massey |first2=James L. |last3=Murphy |first3=Sean |volume=547 |pages=17–38 |isbn=978-3-540-54620-7 }}
* Xuejia Lai and James L. Massey and S. Murphy, Markov ciphers and differential cryptanalysis, ''Advances in Cryptology — Eurocrypt '91'', Springer-Verlag (1992), pp. 17–38.


==References==
==References==

Revision as of 03:25, 7 July 2023

IDEA
An encryption round of IDEA
General
DesignersXuejia Lai and James Massey
Derived fromPES
SuccessorsMMB, MESH, Akelarre,
IDEA NXT (FOX)
Cipher detail
Key sizes128 bits
Block sizes64 bits
StructureLai–Massey scheme
Rounds8.5
Best public cryptanalysis
The key can be recovered with a computational complexity of 2126.1 using narrow bicliques. This attack is computationally faster than a full brute-force attack, though not, as of 2013, computationally feasible.[1]

In cryptography, the International Data Encryption Algorithm (IDEA), originally called Improved Proposed Encryption Standard (IPES), is a symmetric-key block cipher designed by James Massey of ETH Zurich and Xuejia Lai and was first described in 1991. The algorithm was intended as a replacement for the Data Encryption Standard (DES). IDEA is a minor revision of an earlier cipher Proposed Encryption Standard (PES).

The cipher was designed under a research contract with the Hasler Foundation, which became part of Ascom-Tech AG. The cipher was patented in a number of countries but was freely available for non-commercial use. The name "IDEA" is also a trademark. The last patents expired in 2012, and IDEA is now patent-free and thus completely free for all uses.[2]

IDEA was used in Pretty Good Privacy (PGP) v2.0 and was incorporated after the original cipher used in v1.0, BassOmatic, was found to be insecure.[3] IDEA is an optional algorithm in the OpenPGP standard.

Operation

IDEA operates on 64-bit blocks using a 128-bit key and consists of a series of 8 identical transformations (a round, see the illustration) and an output transformation (the half-round). The processes for encryption and decryption are similar. IDEA derives much of its security by interleaving operations from different groupsmodular addition and multiplication, and bitwise eXclusive OR (XOR) — which are algebraically "incompatible" in some sense. In more detail, these operators, which all deal with 16-bit quantities, are:

  • Bitwise XOR (exclusive OR) (denoted with a blue circled plus ).
  • Addition modulo 216 (denoted with a green boxed plus ).
  • Multiplication modulo 216 + 1, where the all-zero word (0x0000) in inputs is interpreted as 216, and 216 in output is interpreted as the all-zero word (0x0000) (denoted by a red circled dot ).

After the 8 rounds comes a final “half-round”, the output transformation illustrated below (the swap of the middle two values cancels out the swap at the end of the last round, so that there is no net swap):

Structure

The overall structure of IDEA follows the Lai–Massey scheme. XOR is used for both subtraction and addition. IDEA uses a key-dependent half-round function. To work with 16-bit words (meaning 4 inputs instead of 2 for the 64-bit block size), IDEA uses the Lai–Massey scheme twice in parallel, with the two parallel round functions being interwoven with each other. To ensure sufficient diffusion, two of the sub-blocks are swapped after each round.

Key schedule

Each round uses 6 16-bit sub-keys, while the half-round uses 4, a total of 52 for 8.5 rounds. The first 8 sub-keys are extracted directly from the key, with K1 from the first round being the lower 16 bits; further groups of 8 keys are created by rotating the main key left 25 bits between each group of 8. This means that it is rotated less than once per round, on average, for a total of 6 rotations.

Decryption

Decryption works like encryption, but the order of the round keys is inverted, and the subkeys for the odd rounds are inversed. For instance, the values of subkeys K1–K4 are replaced by the inverse of K49–K52 for the respective group operation, K5 and K6 of each group should be replaced by K47 and K48 for decryption.

Security

The designers analysed IDEA to measure its strength against differential cryptanalysis and concluded that it is immune under certain assumptions. No successful linear or algebraic weaknesses have been reported. As of 2007, the best attack applied to all keys could break IDEA reduced to 6 rounds (the full IDEA cipher uses 8.5 rounds).[4] Note that a "break" is any attack that requires less than 2128 operations; the 6-round attack requires 264 known plaintexts and 2126.8 operations.

Bruce Schneier thought highly of IDEA in 1996, writing: "In my opinion, it is the best and most secure block algorithm available to the public at this time." (Applied Cryptography, 2nd ed.) However, by 1999 he was no longer recommending IDEA due to the availability of faster algorithms, some progress in its cryptanalysis, and the issue of patents.[5]

In 2011 full 8.5-round IDEA was broken using a meet-in-the-middle attack.[6] Independently in 2012, full 8.5-round IDEA was broken using a narrow-bicliques attack, with a reduction of cryptographic strength of about 2 bits, similar to the effect of the previous bicliques attack on AES; however, this attack does not threaten the security of IDEA in practice.[7]

Weak keys

The very simple key schedule makes IDEA subject to a class of weak keys; some keys containing a large number of 0 bits produce weak encryption.[8] These are of little concern in practice, being sufficiently rare that they are unnecessary to avoid explicitly when generating keys randomly. A simple fix was proposed: XORing each subkey with a 16-bit constant, such as 0x0DAE.[8][9]

Larger classes of weak keys were found in 2002.[10]

This is still of negligible probability to be a concern to a randomly chosen key, and some of the problems are fixed by the constant XOR proposed earlier, but the paper is not certain if all of them are. A more comprehensive redesign of the IDEA key schedule may be desirable.[10]

Availability

A patent application for IDEA was first filed in Switzerland (CH A 1690/90) on May 18, 1990, then an international patent application was filed under the Patent Cooperation Treaty on May 16, 1991. Patents were eventually granted in Austria, France, Germany, Italy, the Netherlands, Spain, Sweden, Switzerland, the United Kingdom, (European Patent Register entry for European patent no. 0482154, filed May 16, 1991, issued June 22, 1994 and expired May 16, 2011), the United States (U.S. patent 5,214,703, issued May 25, 1993 and expired January 7, 2012) and Japan (JP 3225440, expired May 16, 2011).[11]

MediaCrypt AG is now offering a successor to IDEA and focuses on its new cipher (official release in May 2005) IDEA NXT, which was previously called FOX.

Literature

  • Demirci, Hüseyin; Selçuk, Ali Aydin; Türe, Erkan (2004). "A New Meet-in-the-Middle Attack on the IDEA Block Cipher". Selected Areas in Cryptography. Lecture Notes in Computer Science. Vol. 3006. pp. 117–129. doi:10.1007/978-3-540-24654-1_9. ISBN 978-3-540-21370-3.
  • Lai, Xuejia; Massey, James L. (1991). "A Proposal for a New Block Encryption Standard". Advances in Cryptology — EUROCRYPT '90. Lecture Notes in Computer Science. Vol. 473. pp. 389–404. CiteSeerX 10.1.1.14.3451. doi:10.1007/3-540-46877-3_35. ISBN 978-3-540-53587-4.
  • Lai, Xuejia; Massey, James L.; Murphy, Sean (1991). "Markov Ciphers and Differential Cryptanalysis". Advances in Cryptology — EUROCRYPT '91. Lecture Notes in Computer Science. Vol. 547. pp. 17–38. doi:10.1007/3-540-46416-6_2. ISBN 978-3-540-54620-7.

References

  1. ^ "Narrow-Bicliques: Cryptanalysis of Full IDEA" (PDF). www.cs.bris.ac.uk.
  2. ^ "Espacenet - Bibliografische Daten" (in German). Worldwide.espacenet.com. Retrieved 2013-06-15.
  3. ^ Garfinkel, Simson (December 1, 1994), PGP: Pretty Good Privacy, O'Reilly Media, pp. 101–102, ISBN 978-1-56592-098-9.
  4. ^ Biham, E.; Dunkelman, O.; Keller, N. "A New Attack on 6-Round IDEA". Proceedings of Fast Software Encryption, 2007, Lecture Notes in Computer Science. Springer-Verlag.
  5. ^ "Slashdot: Crypto Guru Bruce Schneier Answers". slashdot.org. Retrieved 2010-08-15.
  6. ^ Biham, Eli; Dunkelman, Orr; Keller, Nathan; Shamir, Adi (2011-08-22). "New Attacks on IDEA with at Least 6 Rounds". Journal of Cryptology. 28 (2): 209–239. doi:10.1007/s00145-013-9162-9. ISSN 0933-2790.
  7. ^ Khovratovich, Dmitry; Leurent, Gaëtan; Rechberger, Christian (2012). "Narrow-Bicliques: Cryptanalysis of Full IDEA". Advances in Cryptology – EUROCRYPT 2012. Lecture Notes in Computer Science. Vol. 7237. pp. 392–410. doi:10.1007/978-3-642-29011-4_24. ISBN 978-3-642-29010-7.
  8. ^ a b Daemen, Joan; Govaerts, Rene; Vandewalle, Joos (1994). "Weak Keys for IDEA". Advances in Cryptology — CRYPTO' 93. Lecture Notes in Computer Science. Vol. 773. pp. 224–231. CiteSeerX 10.1.1.51.9466. doi:10.1007/3-540-48329-2_20. ISBN 978-3-540-57766-9.
  9. ^ Nakahara, Jorge Jr.; Preneel, Bart; Vandewalle, Joos (2002), A note on Weak Keys of PES, IDEA and some Extended Variants, CiteSeerX 10.1.1.20.1681
  10. ^ a b Biryukov, Alex; Nakahara, Jorge Jr.; Preneel, Bart; Vandewalle, Joos, "New Weak-Key Classes of IDEA" (PDF), Information and Communications Security, 4th International Conference, ICICS 2002, Lecture Notes in Computer Science 2513: 315–326, While the zero-one weak keys problem of IDEA can be corrected just by XORing a fixed constant to all the keys (one such constant may be 0DAEx as suggested in [4]) the problem with the runs of ones may still remain and will require complete redesign of the IDEA key schedule.
  11. ^ "GnuPG 1.4.13 released". Werner Koch. 21 December 2012. Retrieved 2013-10-06.