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405 lines
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Linux hard disk encryption settings
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This page intends to educate the reader about the existing weaknesses
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of the public-IV on-disk format commonly used with cryptoloop and
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dm-crypt (used in IV-plain mode). This page aims to facilitate risk
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calculation when utilising Linux hard disk encryption. The attacks
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presented on this page may pose a thread to you, but at the same time
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may be totally irrelevant for others. At the end of this document, the
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reader should be able to make a good choice according to his security
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needs.
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A good quote with respect to this topic is ''All security involves
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trade-offs'' from Beyond Fear (Bruce Schneier). You should keep in mind
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that perfect security is unachievable and by all means shouldn't be
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your goal. For instance, when using pass phrase based cryptography, you
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have to trust in that the underlying system is secure, the computer
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system has not been tampered with, and nobody is watching you. The most
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obvious weakness is the last one, but even if you make sure nobody nor
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any camera is around, how about the keyboard you're typing on? Has it
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been manipulated while you have been getting your lunch?
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So security comes for a price, and the price when designing
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cryptography security algorithms is performance. You will be introduced
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to the fastest of all setups available, the "public-IV", which
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sacrifices security properties for speed. After that we will talk about
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ESSIV, the newest of IV modes implemented. It comes for a small price,
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but it can deal with watermarking for a relatively small price. Then
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you'll be introduced to the draft specifications of the Security in
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Storage Working Group ([18]SISWG). Currently SISWG is considering EME
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and LRW for standardisation. EME along with it's cousin CMC seems to
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provide the best security level, but imposes additional encryption
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steps. Plumb-IV is discussed only for reference, because it has the
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same performance penalty as CMC, but in contrast suffers from
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weaknesses of CBC encryption.
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As convention, this document will use the term "blocks", when it
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refers to a single block of plain or cipher text (usually 16 byte),
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and will use the term "sectors", when it refers to a 512-byte wide hard
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disk block.
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CBC Mode: The basic level
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Most hard disk encryption systems utilise CBC to encrypt bulk data.
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Good descriptions on CBC and other common cipher modes are available at
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* [19]Wikipedia
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* [20]Connected: An Internet Encyclopedia
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* [21]NIST: Recommendation for Block Cipher Modes of Operation (CBC
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is at PDF Page 17)
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Please make sure you're familiar with CBC before proceeding.
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Since CBC encryption is a recursive algorithm, the encryption of the
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n-th block requires the encryption of all preceding blocks, 0 till n-1.
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Thus, if we would run the whole hard disk encryption in CBC mode, one
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would have to re-encrypt the whole hard disk, if the first computation
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step changed, this is, when the first plain text block changed. Of
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course, this is an undesired property, therefore the CBC chaining is
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cut every sector and restarted with a new initialisation vector (IV),
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so we can encrypt sectors individually. The choice of the sector as
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smallest unit matches with the smallest unit of hard disks, where a
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sector is also atomic in terms of access.
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For reference, I will give a formal definition of CBC encryption and
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decryption. Note, that decryption is not recursive, in contrast to
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encryption, since it's a function only of C[n-1] and C[n].
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Encryption:
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C[-1] = IV
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C[n] = E(P[n] ⊕ C[n-1])
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Decryption:
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C[-1] = IV
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P[n] = C[n-1] ⊕ D(C[n])
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The next sections will deal with how this IV is chosen.
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The IV Modes
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The "public-IV"
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The IV for sector n is simply the 32-bit version of the number n
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encoded in little-endian padded with zeros to the block-size of the
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cipher used, if necessary. This is the most simple IV mode, but at the
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same the most vulnerable.
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ESSIV
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E(Sector|Salt) IV, short ESSIV, derives the IV from key material via
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encryption of the sector number with a hashed version of the key
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material, the salt. ESSIV does not specify a particular hash algorithm,
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but the digest size of the hash must be an accepted key size for the
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block cipher in use. As the IV depends on a none public piece of
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information, the key, the sequence of IV is not known, and the attacks
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based on this can't be launched.
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plumb IV
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The IV is computed by hashing (or MAC-ing) the plain text from the
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second block till the last. Additionally, the sector number and the key
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are used as input as well. If a byte changes in the plain text of the
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blocks 2 till n, the first block is influenced by the change of the IV.
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As the first encryption effects all subsequent encryption steps due to
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the nature of CBC, the whole sector is changed.
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Decryption is possible because CBC is not recursive for decryption. The
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prerequisites for a successful CBC decryption are two subsequent cipher
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blocks. The former one is decrypted and the first one is XOR-ed into
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the decryption result yielding the original plain text. Therefore
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independent of the IV scheme, decryption is possible from the 2nd to
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the last block. After the recovery of these plain text blocks, the IV
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can be computed, and finally the first block can be decrypted as well.
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The only weakness of this scheme is it's performance. It has to process
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data twice: first for obtaining the IV, and then to produce the CBC
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encryption with this IV. With the same performance penalty CMC is able
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to achieve better security properties (CMC is discussed later), thus
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plumb-IV will remain unimplemented.
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The attack arsenal
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Content leaks
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This attack can be mounted against any system operating in CBC Mode. It
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rests on the property, that in CBC decryption, the preceding cipher
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block's influence is simple, that is, it's XORed into the plain text.
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The preceding cipher block, C[n-1], is readily available on disk (for n
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> 0) or may be deduced from the IV (for n = 0). If an attacker finds
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two blocks with identical cipher text, he knows that both cipher texts
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have been formed according to:
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C[m] = E(P[m] ⊕ C[m-1] )
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C[n] = E(P[n] ⊕ C[n-1] )
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Since he found that C[m] = C[n], it holds
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P[m] ⊕ C[m-1] = P[n] ⊕ C[n-1]
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which can be rewritten as
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C[m-1] ⊕ C[n-1] = P[n] ⊕ P[m]
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The left hand side is known to the attacker by reading the preceding
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cipher text from disk. If one of the blocks is the first block of a
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sector, the IV must be examined instead (when it's available as it is
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in public-IV). The attacker is now able to deduce the difference
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between the plain texts by examining the difference of C[m-1] and
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C[n-1]. If one of the plain text blocks happens to be zero, the
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difference yields the original content of the other related plain text
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block.
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Another information is available to the attacker. Any succeeding
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identical pair of cipher text, that follows the initial identical
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cipher pair, is equal. No information about the content of those pairs
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can be extracted, since the information is extracted from the
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respective preceding cipher blocks, but those are all required to be
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equal.
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Let's have a look at the chance of succeeding with this attack.
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Assuming the output of a cipher forms an uniform distribution, the
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chance, p, of finding an identical block is 2^-blocksize. For instance,
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p = 1/2^128 for a 128-bit cipher. Because the number of possible pairs
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develops as an arithmetic series in n, the number of sectors, the
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chance of not finding two identical blocks is given by
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(1-p)^n(n-1)/2
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As p is very small, but in contrast the power is very big, we apply the
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logarithm to get meaningful answers, that is
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n(n-1)/2 ln (1-p)
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An example: The number of cipher blocks available on 200GB disk with
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known C[n-1] is 200GB × 1024^2 KB/GB × 64/1KB ^1. Or in other words, a
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128-bit block is 16 bytes, so the number of 16-byte blocks in a 200GB
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hard disk is 13.4 billion. Therefore, n = 1.342e10. For a 128-bit
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cipher, p = 2^-128. Hence,
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ln(1-p) = -2.939e-39
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n(n-1)/2 = 9.007e19
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n(n-1)/2 ln (1-p) = -2.647e-19
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1-e^-2.776e-13 = 2.647e-19
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The last term is the chance of finding at least one pair of identical
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cipher blocks. But how does this number grow in n? Obviously
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exponentially. Plotting a few a decimal powers shows that the chance
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for finding at least on identical cipher pair flips to 1 around n =
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10^20 (n = 10^40 for a 256-bit cipher). This inflection point is reached
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for a 146 million TB storage (or a hundred thousand trillion trillions
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TB storage for a 256-bit cipher).
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^1The blocks with available preceding cipher blocks is 62/1KB for all
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non-public IV schemes, i.e. ESSIV/plumb IV
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Data existence leak: The Watermark
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No IV format discussed on this page allows the user to deny the
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existence of encrypted data. Neither cryptoloop nor dm-crypt is an
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implementation of a deniable cryptography system. But the problem is
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more serious with public-IV.
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With public IV and the predicable difference it introduces in the first
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blocks of a sequence of plain text, data can be watermarked, which
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means, the watermarked data is detectable even when the key has not
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been recovered. As shown in the paragraph above, the existence of two
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blocks with identical cipher text is very unlikely and coincidence can
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be excluded, which is relevant when somebody tries to demonstrate
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before the law that certain data is in an encrypted partition.
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As the IV progresses with a foreseeable pattern and is guaranteed to
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change the least significant bit ever step, we can build identical pair
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of cipher text by writing three consecutive sectors each with a flipped
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LSB relative to the previous. (The reason it's three instead of two is,
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that the second least significant bit might change as well.) This
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"public-IV"-driven CBC encryption will output exactly the same cipher
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text for two consecutive sectors. An attacker can search the disk for
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identical consecutive blocks to find the watermark. This can be done in
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a single pass, and is much more feasible than finding to identical
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blocks, that are scattered on the disk, as in the previous attack. A
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few bits of information can be encoded into the watermarks, which might
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serve as tag to prove the existence copyright infringing material.
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A complete description of watermarking can be found in [22]Encrypted
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Watermarks and Linux Laptop Security. The attack can be defeated by
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using ESSIV.
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Data modification leak
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CBC encryption is recursive, so the n-th block depends on all previous
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blocks. But the other way round would also be nice. Why? The weakness
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becomes visible, if storage on a remote computer is used, or more
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likely, the hard disk exhibits good forensic properties. The point is,
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the attacker has to have access to preceding (in time) cipher text of a
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sector, either by recording it from the network, or by using forensic
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methods.
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An attacker can now guess data modification patterns by examining the
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historic data. If a sector is overwritten with a partial changed plain
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text, there is an amount of bytes at the beginning, which are
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unchanged. This point of change^2 is directly reflected in the cipher
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text. So an attacker can deduce the point of the change in plain text
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by finding the point where the cipher text starts to differ.
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This weakness is present in public-IV and ESSIV.
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^2aligned to the cipher block size boundaries
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Malleable plain text
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The decryption structure of CBC is the source of this weakness.
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Malleability (with respect to cryptography) is defined as a
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modification of the cipher text that will resulting in a predictable
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change in plain text. To put it formally, there is a function f(C),
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that, if applied to the cipher text, C' = f(C), will result in a known
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function f', which will predict the resulting plain text, P' = D(C'),
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correctly assuming P is known, that is P' = f'(P).
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As we can see in it's definition, CBC decryption depends on C[n-1]. An
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attacker can flip arbitrary bits in the plain text by flipping bit in
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C[n-1]. More formally^3, if
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P = P[1] || P[2] || ... || P[i] || ... || P[n]
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C = E[CBC](P)
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C = C[1] || C[2] || ... || C[i-1] || ... || C[n]
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the function
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f(C[1] || ... || C[n]) = C[1] || ... || C[i-1] XOR M || ... || C[n]
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follows the function f', which predicts the resulting plain text
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correctly as,
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f'(P[1] || ... || P[n]) = P[1] || ... || P[i] XOR M || ... || P[n]
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The first block of the CBC cipher text stream is not malleable, because
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it depends on the IV, which is not modifiable for an attacker.
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^3The IV parameter for E[CBC] has been intentionally omitted.
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Movable
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On the expense of one block decrypting to garbage, an attacker can move
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around plain text as he likes. CBC decryption depends on two variables,
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C[n-1] and C[n]. Both can be modified at free will. To make meaningful
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modifications, an attacker has to replace the pair C[n-1] and C[n] with
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other cipher text pair from disk. The first block C[n-1] will decrypt
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to garbage, but the second block C[n] will yield a copy of the plain
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text of the copied cipher block. This attack is also known as
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copy&paste attack. This attack is mountable against any CBC setup. The
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only limitation is, the first block, C[0], can't be replaced with
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something meaningful, as C[-1] can't be modified, because it's the IV.
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CMC and EME: Tweakable wide block cipher modes
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CMC is a new chaining mode. It stands for ''CBC-Mask-CBC''. It works by
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processing the data in three steps, first CBC, then masking the cipher
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text, and then another CBC step, but this time backwards. The last step
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introduces a dependency from the last block to the first block. The
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authors of the CMC paper provide a prove for the security of this mode,
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making a secure 128-bit cipher a secure 4096-bit cipher (sector size).
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As in normal CBC, this scheme also takes an IV, but the authors call it
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tweak.
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EME is CMC's cousin. EME has also been authored by Haveli and Rogaway
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as well been authored for the same purpose. The difference to CMC is,
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that EME is parallelizable, that is, all operations of the underlying
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cipher can be evaluated in parallel. To introduce an interdependency
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among the resulting cipher blocks, the encryption happens in two
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stages. Between these stages a mask is computed from all intermediate
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blocks and applied to each intermediate block. This step causes an
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interdependency among the cipher blocks. After applying the mask,
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another encryption step diffuses the mask.
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The interdependency among the resulting blocks allow CMC and EME to be
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nonmovable, nonmalleable, to prevent content leaks and in-sector data
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modification patterns. The tweaks are encrypted by both cipher modes,
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thus both are nonwatermarkable.
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For simplicity, the EME description above omitted the pre- and post-
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whitening steps as well as the multiplications in GF(2^128). An
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in-depth specification can be found at the [23]Cryptology ePrint
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Archive. An applicable draft specification for EME-32-AES can be found
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at [24]SISWG. I have written an EME-32-AES test implementation for
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Linux 2.6. It's available [25]here. The CMC paper is available from the
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[26]Cryptology ePrint Archive as well.
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LRW: A tweakable narrow block cipher mode
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EME as well as CMC are comparatively secure cipher modes, but heavy in
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terms of performance. LRW tries to cope with most of security
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requirements, and at the same time provide a good performance. LRW is a
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narrow block cipher mode, that is, it operates only on one block,
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instead of a whole sector. To make a cipher block tied to a location on
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disk (to make it unmovable), a logical index is included in the
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computation. For LRW you have to provide two keys, one for the cipher
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and one for the cipher mode. The second key is multiplied with a
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logical index under GF(2^128) and used as pre- and post- whitening for
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encryption. With those whitening steps the block is effectively tied to
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a logical index. The logical index is usually the absolute position on
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disk measured with the block size of the cipher algorithm. The
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different choice of the measuring unit is the only different between
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the logical index and the public-IV.
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The LRW draft is available from the [27]SISWG mailing list archive.
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Summarising
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The following table shows a comparison between the security properties
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of different encryption setups and their computational costs. The
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number of cipher calls, XOR operations and additional operations are
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stated in terms of encryption blocks, n.
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IV mode cipher mode content leaks watermarkable malleable movable
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modification detection^5 cipher calls XOR ops additional op.
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public-IV CBC Yes Yes Yes Yes Yes n n None
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ESSIV CBC Yes No Yes Yes Yes n+1 n None
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Plumb-IV1^4 CBC Yes No Yes Yes No 2n-1 2n None
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public-IV CMC No No No No No 2n+1 2n+1 1 LW GF ⊗
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public-IV EME No No No No No 2n+1 5n 3n-1 LW GF ⊗
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public-IV LRW No No No No Yes n 2n n HW GF ⊗
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Legend:
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* LW GF ⊗: light-weight Galois field multiplication, that is, a
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multiplication with a constant x^2^i, which can be computed in
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θ(1).
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* HW GF ⊗: heavy-weight Galois field multiplication, that is, a
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multiplication with an arbitrary constant, which can be computed in
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θ(bits).
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^4plumb-IV1 uses CBC-MAC instead of hashing, so we can make a good
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comparison with other ciphers in terms of cipher/XOR calls.
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^5detectable partial in-sector modification
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__________________________________________________________________
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Clemens Fruhwirth, , also author of LUKS and ESSIV, porter of
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cryptoloop, aes-i586 for 2.6., twofish-i586, and implementor of
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EME-32-AES. This text is an excerpt of my diploma thesis.
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This page has been reviewed by
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Dr. Ernst Molitor
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Arno Wagner
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James Hughes , "Security in Storage Working Group" chair
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Additional thanks to Pascal Brisset, for pointing out an error in the
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Bernoulli estimation in an earlier version of this document, further
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Adam J. Richter for pointing out an error in the KB/GB ratio.
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Content and design, Copyright © 2004-2008 Clemens Fruhwirth, unless
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stated otherwise
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Original design by [28]haran | Additional art by [29]LinuxArt | | Blog
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by [30]NanoBlogger
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References
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||
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||
1. http://clemens.endorphin.org/
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||
2. http://clemens.endorphin.org/credits
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||
3. http://clemens.endorphin.org/aboutme
|
||
4. http://clemens.endorphin.org/cryptography
|
||
5. http://blog.clemens.endorphin.org/
|
||
6. http://clemens.endorphin.org/patches
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||
7. http://clemens.endorphin.org/archive
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||
8. http://clemens.endorphin.org/Cryptoloop_Migration_Guide
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||
9. http://clemens.endorphin.org/LUKS
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||
10. http://clemens.endorphin.org/AFsplitter
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||
11. http://clemens.endorphin.org/lo-tracker
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||
12. http://blog.clemens.endorphin.org/2008/12/luks-on-disk-format-revision-111.html
|
||
13. http://blog.clemens.endorphin.org/2008/11/xmonad-gridselect.html
|
||
14. http://blog.clemens.endorphin.org/2008/11/workaround-for-bittorrent-traffic.html
|
||
15. http://blog.clemens.endorphin.org/2008/09/i-love-lolcat-meme.html
|
||
16. http://blog.clemens.endorphin.org/2008/09/counter-steganography-research.html
|
||
17. http://clemens.endorphin.org/cryptography
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||
18. http://www.siswg.org/
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||
19. http://en.wikipedia.org/wiki/Block_cipher_modes_of_operation
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||
20. http://www.freesoft.org/CIE/Topics/143.htm
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||
21. http://csrc.nist.gov/publications/nistpubs/800-38a/sp800-38a.pdf
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||
22. http://www.tcs.hut.fi/~mjos/doc/wisa2004.pdf
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||
23. http://eprint.iacr.org/2003/147/
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||
24. http://grouper.ieee.org/groups/1619/email/pdf00011.pdf
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||
25. http://article.gmane.org/gmane.linux.kernel.device-mapper.dm-crypt/544
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||
26. http://eprint.iacr.org/2003/148/
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||
27. http://grouper.ieee.org/groups/1619/email/msg00160.html
|
||
28. http://www.oswd.org/user/profile/id/3013
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||
29. http://www.linuxart.com/
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||
30. http://nanoblogger.sourceforge.net/
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