Key Wrap

Key Wrap constructions are a class of algorithms designed to (encrypt) cryptographic key material. The Key Wrap algorithms are intended for applications such as protecting keys while in untrusted storage or transmitting keys over untrusted communications networks. The constructions are typically built from standard primitives such as and cryptographic hash functions.

Key Wrap may be considered as a form of algorithm, although it should not be confused with the more commonly known asymmetric (public-key) algorithms (e.g., ). Key Wrap algorithms can be used in a similar application: to securely transport a session key by encrypting it under a long-term encryption key.

Background

In the late 1990s, the (NIST) posed the “Key Wrap” problem: to develop secure and efficient cipher-based key encryption algorithms. The resulting algorithms would be formally evaluated by NIST, and eventually approved for use in NIST-certified cryptographic modules. NIST did not precisely define the security goals of the resulting algorithm, and left further refinement to the algorithm developers. Based on the resulting algorithms, the design requirements appear to be (1) confidentiality, (2) integrity protection (authentication), (3) efficiency, (4) use of standard (approved) underlying primitives such as the Advanced Encryption Standard (AES) and the Secure Hash Algorithm (SHA-1), and (5) consideration of additional circumstances (e.g., resilience to operator error, low-quality random number generators). Goals (3) and (5) are particularly important, given that many widely deployed algorithms (e.g., AES-CCM) are already sufficient to accomplish the remaining goals.

NIST AES Key Wrap Specification

Several constructions have been proposed. These include:

Each of the proposed algorithms can be considered as a form of algorithm providing confidentiality for highly messages such as cryptographic keys. The AES Key Wrap Specification, AESKW, TDKW, and AKW1 are intended to maintain confidentiality under , while the AKW2 algorithm is designed to be secure only under known-plaintext (or weaker) attacks. (The stated goal of AKW2 is for use in legacy systems and computationally limited devices where use of the other algorithms would be impractical.) AESKW, TDKW and AKW2 also provide the ability to authenticate cleartext “header”, an associated block of data that is not encrypted.

and Shrimpton evaluated the design of the ANSX9.102 algorithms with respect to the stated security goals. Among their general findings, they noted the lack of clearly stated design goals for the algorithms, and the absence of security proofs for all constructions.

In their paper, and Shrimpton proposed a provable key-wrapping algorithm (SIV—the Synthetic Initialization Vector mode) that authenticates and encrypts an arbitrary string and authenticates, but does not encrypt, additional data which can be bound into the wrapped key. This has been standardized as a new AES mode in RFC 5297.

See Also on BitcoinWiki

Source

http://wikipedia.org/