Mercurial > dropbear
view libtomcrypt/notes/tech0006.txt @ 1855:35d504d59c05
Implement server-side support for sk-ecdsa U2F-backed keys (#142)
* Implement server-side support for sk-ecdsa U2F-backed keys
* Fix out-of-bounds read on normal ecdsa-sha2-[identifier] keys
* Fix one more potential out-of-bounds read
* Check if nistp256 curve is used in sk-ecdsa-sha2- key
It's the only allowed curve per PROTOCOL.u2f specification
* Implement server-side support for sk-ed25519 FIDO2-backed keys
* Keys with type sk-* make no sense as host keys, so they should be
disabled
* fix typo
* Make sk-ecdsa call buf_ecdsa_verify
This reduces code duplication, the SK code just handles the
different message format.
* Reduce sk specific code
The application id can be stored in signkey, then we don't need
to call sk-specific functions from svr-authpubkey
* Remove debugging output, which causes compilation errors with DEBUG_TRACE disabled
* Proper cleanup of sk_app
Co-authored-by: Matt Johnston <[email protected]>
| author | egor-duda <egor-duda@users.noreply.github.com> |
|---|---|
| date | Sat, 22 Jan 2022 16:53:04 +0300 |
| parents | 1b9e69c058d2 |
| children |
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Tech Note 0006 PK Standards Compliance Tom St Denis RSA ---- PKCS #1 compliance. Key Format: RSAPublicKey and RSAPrivateKey as per PKCS #1 v2.1 Encryption: OAEP as per PKCS #1 Signature : PSS as per PKCS #1 DSA ---- The NIST DSA algorithm Key Format: HomeBrew [see below] Signature : ANSI X9.62 format [see below]. Keys are stored as DSAPublicKey ::= SEQUENCE { publicFlags BIT STRING(1), -- must be 0 g INTEGER , -- base generator, check that g^q mod p == 1 -- and that 1 < g < p - 1 p INTEGER , -- prime modulus q INTEGER , -- order of sub-group (must be prime) y INTEGER , -- public key, specifically, g^x mod p, -- check that y^q mod p == 1 -- and that 1 < y < p - 1 } DSAPrivateKey ::= SEQUENCE { publicFlags BIT STRING(1), -- must be 1 g INTEGER , -- base generator, check that g^q mod p == 1 -- and that 1 < g < p - 1 p INTEGER , -- prime modulus q INTEGER , -- order of sub-group (must be prime) y INTEGER , -- public key, specifically, g^x mod p, -- check that y^q mod p == 1 -- and that 1 < y < p - 1 x INTEGER -- private key } Signatures are stored as DSASignature ::= SEQUENCE { r, s INTEGER -- signature parameters } ECC ---- The ANSI X9.62 and X9.63 algorithms [partial]. Supports all NIST GF(p) curves. Key Format : Homebrew [see below, only GF(p) NIST curves supported] Signature : X9.62 compliant Encryption : Homebrew [based on X9.63, differs in that the public point is stored as an ECCPublicKey] Shared Secret: X9.63 compliant ECCPublicKey ::= SEQUENCE { flags BIT STRING(1), -- public/private flag (always zero), keySize INTEGER, -- Curve size (in bits) divided by eight -- and rounded down, e.g. 521 => 65 pubkey.x INTEGER, -- The X co-ordinate of the public key point pubkey.y INTEGER, -- The Y co-ordinate of the public key point } ECCPrivateKey ::= SEQUENCE { flags BIT STRING(1), -- public/private flag (always one), keySize INTEGER, -- Curve size (in bits) divided by eight -- and rounded down, e.g. 521 => 65 pubkey.x INTEGER, -- The X co-ordinate of the public key point pubkey.y INTEGER, -- The Y co-ordinate of the public key point secret.k INTEGER, -- The secret key scalar } The encryption works by finding the X9.63 shared secret and hashing it. The hash is then simply XOR'ed against the message [which must be at most the size of the hash digest]. The format of the encrypted text is as follows ECCEncrypted ::= SEQUENCE { hashOID OBJECT IDENTIFIER, -- The OID of the hash used pubkey OCTET STRING , -- Encapsulation of a random ECCPublicKey skey OCTET STRING -- The encrypted text (which the hash was XOR'ed against) } % $Source: /cvs/libtom/libtomcrypt/notes/tech0006.txt,v $ % $Revision: 1.2 $ % $Date: 2005/06/18 02:26:27 $