Format-preserving encryption
In cryptography, format-preserving encryption, refers to encrypting in such a way that the output is in the same format as the input. The meaning of "format" varies. Typically only finite domains are discussed, for example:
- To encrypt a 16-digit credit card number so that the ciphertext is another 16-digit number.
- To encrypt an English word so that the ciphertext is another English word.
- To encrypt an n-bit number so that the ciphertext is another n-bit number.
Motivation
Restricted field lengths or formats
One motivation for using FPE comes from the problems associated with integrating encryption into existing applications, with well-defined data models. A typical example would be a credit card number, such as1234567812345670
.Adding encryption to such applications might be challenging if data models are to be changed, as it usually involves changing field length limits or data types. For example, output from a typical block cipher would turn credit card number into a hexadecimal or Base64 value, which will break any existing applications expecting the credit card number to be a 16-digit number.
Apart from simple formatting problems, using AES-128-CBC, this credit card number might get encrypted to the hexadecimal value
0xde015724b081ea7003de4593d792fd8b695b39e095c98f3a220ff43522a2df02
. In addition to the problems caused by creating invalid characters and increasing the size of the data, data encrypted using the CBC mode of an encryption algorithm also changes its value when it is decrypted and encrypted again. This happens because the random seed value that is used to initialize the encryption algorithm and is included as part of the encrypted value is different for each encryption operation. Because of this, it is impossible to use data that has been encrypted with the CBC mode as a unique key to identify a row in a database.FPE attempts to simplify the transition process by preserving the formatting and length of the original data, allowing a drop-in replacement of plaintext values with their ciphertexts in legacy applications.
Comparison to truly random permutations
Although a truly random permutation is the ideal FPE cipher, for large domains it is infeasible to pre-generate and remember a truly random permutation. So the problem of FPE is to generate a pseudorandom permutation from a secret key, in such a way that the computation time for a single value is small.Comparison to block ciphers
An n-bit block cipher technically is a FPE on the set. If an FPE is needed on one of these standard sized sets a block cipher of the right size can be used.However, in typical usage, a block cipher is used in a mode of operation that allows it to encrypt arbitrarily long messages, and with an initialization vector as discussed above. In this mode, a block cipher is not an FPE.
Definition of security
In cryptographic literature, the measure of a "good" FPE is whether an attacker can distinguish the FPE from a truly random permutation. Various types of attackers are postulated, depending on whether they have access to oracles or known ciphertext/plaintext pairs.Algorithms
In most of the approaches listed here, a well-understood block cipher is used as a primitive to take the place of an ideal random function. This has the advantage that incorporation of a secret key into the algorithm is easy. Where AES is mentioned in the following discussion, any other good block cipher would work as well.The FPE constructions of Black and Rogaway
Implementing FPE with security provably related to that of the underlying block cipher was first undertaken in a paper by cryptographers John Black and Phillip Rogaway, which described three ways to do this. They proved that each of these techniques is as secure as the block cipher that is used to construct it. This means that if the AES algorithm is used to create an FPE algorithm, then the resulting FPE algorithm is as secure as AES because an adversary capable of defeating the FPE algorithm can also defeat the AES algorithm. Therefore, if AES is secure, then the FPE algorithms constructed from it are also secure. In all of the following, E denotes the AES encryption operation that is used to construct an FPE algorithm and F denotes the FPE encryption operation.FPE from a prefix cipher
One simple way to create an FPE algorithm on is to assign a pseudorandom weight to each integer, then sort by weight. The weights are defined by applying an existing block cipher to each integer. Black and Rogaway call this technique a "prefix cipher" and showed it was provably as good as the block cipher used.Thus, to create a FPE on the domain, given a key K apply AES to each integer, giving, for example,
weight = 0x56c644080098fc5570f2b329323dbf62
weight = 0x08ee98c0d05e3dad3eb3d6236f23e7b7
weight = 0x47d2e1bf72264fa01fb274465e56ba20
weight = 0x077de40941c93774857961a8a772650d
Sorting by weight gives , so the cipher is
F = 3
F = 1
F = 2
F = 0
This method is only useful for small values of N. For larger values, the size of the lookup table and the required number of encryptions to initialize the table gets too big to be practical.
FPE from cycle walking
If there is a set M of allowed values within the domain of a pseudorandom permutation P, an FPE algorithm can be created from the block cipher by repeatedly applying the block cipher until the result is one of the allowed values.CycleWalkingFPE
The recursion is guaranteed to terminate.
This has the advantage that the elements of M do not have to be mapped to a consecutive sequence of integers. It has the disadvantage, when M is much smaller than P's domain, that too many iterations might be required for each operation. If P is a block cipher of a fixed size, such as AES, this is a severe restriction on the sizes of M for which this method is efficient.
For example, an application may want to encrypt 100-bit values with AES in a way that creates another 100-bit value. With this technique, AES-128-ECB encryption can be applied until it reaches a value which has all of its 28 highest bits set to 0, which will take an average of 228 iterations to happen.
FPE from a Feistel network
It is also possible to make a FPE algorithm using a Feistel network. A Feistel network needs a source of pseudo-random values for the sub-keys for each round, and the output of the AES algorithm can be used as these pseudo-random values. When this is done, the resulting Feistel construction is good if enough rounds are used.One way to implement an FPE algorithm using AES and a Feistel network is to use as many bits of AES output as are needed to equal the length of the left or right halves of the Feistel network. If a 24-bit value is needed as a sub-key, for example, it is possible to use the lowest 24 bits of the output of AES for this value.
This may not result in the output of the Feistel network preserving the format of the input, but it is possible to iterate the Feistel network in the same way that the cycle-walking technique does to ensure that format can be preserved. Because it is possible to adjust the size of the inputs to a Feistel network, it is possible to make it very likely that this iteration ends very quickly on average. In the case of credit card numbers, for example, there are 1016 possible 16-digit credit card numbers, and because the 1016 = 253.1, using a 54-bit wide Feistel network along with cycle walking will create an FPE algorithm that encrypts fairly quickly on average.
The Thorp shuffle
A Thorp shuffle is like an idealized card-shuffle, or equivalently a maximally-unbalanced Feistel cipher where one side is a single bit. It is easier to prove security for unbalanced Feistel ciphers than for balanced ones.VIL mode
For domain sizes that are a power of two, and an existing block cipher with a smaller block size, a new cipher may be created using VIL mode as described by Bellare, Rogaway.Hasty Pudding Cipher
The Hasty Pudding Cipher uses custom constructions to encrypt arbitrary finite small domains.The FFSEM/FFX mode of AES
The FFSEM mode of AES that has been accepted for consideration by NIST uses the Feistel network construction of Black and Rogaway described above, with AES for the round function, with one slight modification: a single key is used and is tweaked slightly for each round.As of February 2010, FFSEM has been superseded by the FFX mode written by Mihir Bellare, Phillip Rogaway, and Terence Spies..
FPE for JPEG 2000 encryption
In JPEG 2000 standard, the marker codes should not appear in the plaintext and ciphertext. The simple modular-0xFF90 technique cannot be applied to solve the JPEG 2000 encryption problem. For example, the ciphertext words 0x23FF and 0x9832 are valid, but their combination 0x23FF9832 becomes invalid since it introduces the marker code 0xFF98. Similarly, the simple cycle-walking technique cannot be applied to solve the JPEG2000 encryption problem since two valid ciphertext blocks may give invalid ciphertext when they get combined. For example, if the first ciphertext block ends with bytes "...30FF" and the second ciphertext block starts with bytes "9832...", then the marker code "0xFF98" would appear in the ciphertext.Two mechanisms for format-preserving encryption of JPEG 2000 were given in the paper "Efficient and Secure Encryption Schemes for JPEG2000" by Hongjun Wu and Di Ma. To perform format-preserving encryption of JPEG 2000, the technique is to exclude the byte "0xFF" in the encryption and decryption. Then a JPEG 2000 encryption mechanism performs modulo-n addition with stream cipher; another JPEG 2000 encryption mechanism performs the cycle-walking technique with block cipher.
Other FPE constructions
Several FPE constructs are based on adding the output of a standard cipher, modulo n, to the data to be encrypted, with various methods of unbiasing the result. The modulo-n addition shared by many of the constructs is the immediately obvious solution to the FPE problem, with the main differences being the unbiasing mechanisms used.Section 8 of the FIPS 74, Federal Information Processing Standards Publication 1981 Guidelines for Implementing and Using the NBS Data Encryption Standard, describes a way to use the DES encryption algorithm in a manner that preserves the format of the data via modulo-n addition followed by an unbiasing operation. This standard was withdrawn on May 19, 2005, so the technique should be considered obsolete in terms of being a formal standard.
Another early mechanism for format-preserving encryption was Peter Gutmann's "Encrypting data with a restricted range of values" which again performs modulo-n addition on any cipher with some adjustments to make the result uniform, with the resulting encryption being as strong as the underlying encryption algorithm on which it is based.
The paper "Using Datatype-Preserving Encryption to Enhance Data Warehouse Security" by Michael Brightwell and Harry Smith describes a way to use the DES encryption algorithm in a way that preserves the format of the plaintext. This technique doesn't appear to apply an unbiasing step as do the other modulo-n techniques referenced here.
The paper "Format-Preserving Encryption" by Mihir Bellare and Thomas Ristenpart describes using "nearly balanced" Feistel networks to create secure FPE algorithms.
The paper "Format Controlling Encryption Using Datatype Preserving Encryption" by Ulf Mattsson describes other ways to create FPE algorithms.
An example of FPE algorithm is FNR.
Acceptance of FPE algorithms by standards authorities
NIST Special Publication 800-38G, "Recommendation for Block Cipher Modes of Operation: Methods for Format-Preserving Encryption" specifies two methods: FF1 and FF3. Details on the proposals submitted for each can be found at the NIST Block Cipher Modes Development site, including patent and test vector information. Sample values are available for both FF1 and FF3.- FF1 is FFX "Format-preserving Feistel-based Encryption Mode" which is also in standards processes under ANSI X9 as X9.119 and X9.124. It was submitted to NIST by Mihir Bellare of University of California, San Diego, Phillip Rogaway of University of California, Davis, and Terence Spies of Voltage Security Inc. Test vectors are supplied and parts of it are patented. requires the minimum domain size of the data being encrypted to be 1 million.
- FF3 is BPS named after the authors. It was submitted to NIST by Eric Brier, Thomas Peyrin and Jacques Stern of Ingenico, France. Authors declared to NIST that their algorithm is not patented. The company although claims to own patents also for BPS mode. On 12 April 2017, NIST concluded that FF3 is "no longer suitable as a general-purpose FPE method" because researchers found a vulnerability.
- FF3-1 replaces FF3 and requires the minimum domain size of the data being encrypted to be 1 million.
- FF2 is VAES3 scheme for FFX: An addendum to "The FFX Mode of Operation for Preserving Encryption": A parameter collection for encipher strings of arbitrary radix with subkey operation to lengthen life of the enciphering key. It was submitted to NIST by Joachim Vance of VeriFone Systems Inc. Test vectors are not supplied separately from FF1 and parts of it are patented. Authors have submitted a modified algorithm as DFF which is under active consideration by NIST.