Weak key

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In cryptography, a weak key is a key which when used with a specific cipher, makes the cipher behave in some undesirable way. Weak keys usually represent a very small fraction of the overall keyspace, which usually means that if one generates a random key to encrypt a message weak keys are very unlikely to give rise to a security problem. Nevertheless, it is considered desirable for a cipher to have no weak keys. A cipher with no weak keys is said to have a flat, or linear, key space.

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[edit] Weak keys in DES

The block cipher DES has a few specific keys termed "weak keys" and "semi-weak keys". These are keys which cause the encryption mode of DES to act identically to the decryption mode of DES (albeit potentially that of a different key).

In operation, the secret 56-bit key is broken up into 16 subkeys according to the DES key schedule; one subkey is used in each of the sixteen DES rounds. The weak keys of DES are those which produce sixteen identical subkeys. This occurs when the key bits are:[1]

  • Alternating ones + zeros (0x0101010101010101)
  • Alternating 'F' + 'E' (0xFEFEFEFEFEFEFEFE)
  • '0xE0E0E0E0F1F1F1F1'
  • '0x1F1F1F1F0E0E0E0E'

If an implementation does not consider the parity bits, the corresponding keys with the inverted parity bits may also work as weak keys:

  • all zeros (0x0000000000000000)
  • all ones (0xFFFFFFFFFFFFFFFF)
  • '0xE1E1E1E1F0F0F0F0'
  • '0x1E1E1E1E0F0F0F0F'

Using weak keys, the outcome of the Permuted Choice 1 (PC1) in the DES key schedule leads to round keys being either all zeros, all ones or alternating zero-one patterns.

Since all the subkeys are identical, and DES is a Feistel network, the encryption function is self-inverting; that is, encrypting twice produces the original plaintext.

DES also has semi-weak keys, which only produce two different subkeys, each used eight times in the algorithm: This means they come in pairs K1 and K2, and they have the property that:

E_{K_1}(E_{K_2}(M))=M

where EK(M) is the encryption algorithm encrypting message M with key K. There are six semiweak key pairs:

  • 0x011F011F010E010E and 0x1F011F010E010E01
  • 0x01E001E001F101F1 and 0xE001E001F101F101
  • 0x01FE01FE01FE01FE and 0xFE01FE01FE01FE01
  • 0x1FE01FE00EF10EF1 and 0xE01FE01FF10EF10E
  • 0x1FFE1FFE0EFE0EFE and 0xFE1FFE1FFE0EFE0E
  • 0xE0FEE0FEF1FEF1FE and 0xFEE0FEE0FEF1FEF1

There are also 48 possibly weak keys that produce only four distinct subkeys (instead of 16). They can be found in [2]

These weak and semiweak keys are not considered "fatal flaws" of DES. There are 256 (7.21 × 1016, about 72 quadrillion) possible keys for DES, of which four are weak and twelve are semiweak. This is such a tiny fraction of the possible keyspace that users do not need to worry. If they so desire, they can check for weak or semiweak keys when the keys are generated. They are very few, and easy to recognize. Note, however, that DES is not recommended for general use since all keys can be brute-forced in about a day for a one-time hardware cost on the order of some new cars.

[edit] List of algorithms with weak keys

  • RC4. RC4's weak initialization vectors allow an attacker to mount a known-plaintext attack and have been widely used to compromise the security of WEP.[3]
  • IDEA. IDEA's weak keys are identifiable in a chosen-plaintext attack. They make the relationship between the XOR sum of plaintext bits and ciphertext bits predictable. There is no list of these keys, but they can be identified by their "structure".
  • Blowfish. Blowfish's weak keys produce bad S-boxes, since Blowfish's S-boxes are key-dependent. There is a chosen plaintext attack against a reduced-round variant of Blowfish that is made easier by the use of weak keys. This is not a concern for full 16-round Blowfish.

[edit] No weak keys as a design goal

The goal of having a 'flat' keyspace (ie, all keys equally strong) is always a cipher design goal. As in the case of DES, sometimes a small number of weak keys is acceptable, provided that they are all identified or identifiable. An algorithm that has weak keys which are unknown does not inspire much trust.

The two main countermeasures against inadvertently using a weak key:

  • Checking generated keys against a list of known weak keys, or building rejection of weak keys into the key scheduling.
  • When the number of weak keys is known to be very small (in comparison to the size of the keyspace), generating a key uniformly at random ensures that the probability of it being weak is a (known) very small number.

A large number of weak keys is a serious flaw in any cipher design, since there will then be a (perhaps too) large chance that a randomly generated one will be a weak one, compromising the security of messages encrypted under it. It will also take longer to check randomly generated keys for weakness in such cases, which will tempt shortcuts in interest of 'efficiency'.

However, weak keys are much more often a problem where the adversary has some control over what keys are used, such as when a block cipher is used in a mode of operation intended to construct a secure cryptographic hash function (eg Davies-Meyer).

[edit] See also

[edit] References

  1. ^ FIPS, GUIDELINES FOR IMPLEMENTING AND USING THE NBS DATA ENCRYPTION STANDARD, FIPS-PUB 74, http://www.itl.nist.gov/fipspubs/fip74.htm
  2. ^ NIST, Recommendation for the Triple Data Encryption Algorithm (TDEA) Block Cipher, Special Publication 800-67, page 14
  3. ^ FLUHRER, S., MANTIN, I., AND SHAMIR, A. Weaknesses in the key scheduling algorithm of RC4. Eighth Annual Workshop on Selected Areas in Cryptography (August 2001), http://citeseer.ist.psu.edu/fluhrer01weaknesses.html