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c1a2114b28
I only recently found out that OpenSSH defined their own protocol IDs for AES-GCM, defined to work the same as the standard ones except that they fixed the semantics for how you select the linked cipher+MAC pair during key exchange. (RFC 5647 defines protocol ids for AES-GCM in both the cipher and MAC namespaces, and requires that you MUST select both or neither - but this contradicts the selection policy set out in the base SSH RFCs, and there's no discussion of how you resolve a conflict between them! OpenSSH's answer is to do it the same way ChaCha20-Poly1305 works, because that will ensure the two suites don't fight.) People do occasionally ask us for this linked cipher/MAC pair, and now I know it's actually feasible, I've implemented it, including a pair of vector implementations for x86 and Arm using their respective architecture extensions for multiplying polynomials over GF(2). Unlike ChaCha20-Poly1305, I've kept the cipher and MAC implementations in separate objects, with an arm's-length link between them that the MAC uses when it needs to encrypt single cipher blocks to use as the inputs to the MAC algorithm. That enables the cipher and the MAC to be independently selected from their hardware-accelerated versions, just in case someone runs on a system that has polynomial multiplication instructions but not AES acceleration, or vice versa. There's a fourth implementation of the GCM MAC, which is a pure software implementation of the same algorithm used in the vectorised versions. It's too slow to use live, but I've kept it in the code for future testing needs, and because it's a convenient place to dump my design comments. The vectorised implementations are fairly crude as far as optimisation goes. I'm sure serious x86 _or_ Arm optimisation engineers would look at them and laugh. But GCM is a fast MAC compared to HMAC-SHA-256 (indeed compared to HMAC-anything-at-all), so it should at least be good enough to use. And we've got a working version with some tests now, so if someone else wants to improve them, they can.
39 lines
1.3 KiB
Python
Executable File
39 lines
1.3 KiB
Python
Executable File
#!/usr/bin/env python3
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# Simple client of the testcrypt system that reports the available
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# variants of each of the crypto primitives that have hardware-
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# accelerated implementations.
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#
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# It will report the set of primitives compiled in to testcrypt, and
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# also report whether each one can be instantiated at run time.
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from testcrypt import *
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def get_implementations(alg):
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return get_implementations_commasep(alg).decode("ASCII").split(",")
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def list_implementations(alg, checkfn):
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print(f"Implementations of {alg}:")
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for impl in get_implementations(alg):
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if impl == alg:
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continue
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if checkfn(impl):
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print(f" {impl:<32s} available")
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else:
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print(f" {impl:<32s} compiled in, but unavailable at run time")
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def list_cipher_implementations(alg):
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list_implementations(alg, lambda impl: ssh_cipher_new(impl) is not None)
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def list_mac_implementations(alg):
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list_implementations(alg, lambda impl: ssh2_mac_new(impl, None) is not None)
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def list_hash_implementations(alg):
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list_implementations(alg, lambda impl: ssh_hash_new(impl) is not None)
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list_cipher_implementations("aes256_cbc")
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list_mac_implementations("aesgcm")
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list_hash_implementations("sha1")
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list_hash_implementations("sha256")
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list_hash_implementations("sha512")
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