Library
Module
Module type
Parameter
Class
Class type
DSA digital signature algorithm.
type priv = private {
p : Z.t;
Modulus
*)q : Z.t;
Subgroup order
*)gg : Z.t;
Group Generator
*)x : Z.t;
Private key proper
*)y : Z.t;
Public component
*)}
Private key. p
, q
and gg
comprise domain parameters.
Sexplib
convertible.
val priv :
?fips:bool ->
p:Z.t ->
q:Z.t ->
gg:Z.t ->
x:Z.t ->
y:Z.t ->
unit ->
(priv, [> `Msg of string ]) Stdlib.result
priv ~fips ~p ~q ~gg ~x ~y ()
constructs a private DSA key from the given numbers. Will result in an error if parameters are ill-formed: same as pub
, and additionally 0 < x < q
and y = g ^ x mod p
. Note that no time masking is done on the modular exponentiation.
Public key, a subset of private key.
Sexplib
convertible.
val pub :
?fips:bool ->
p:Z.t ->
q:Z.t ->
gg:Z.t ->
y:Z.t ->
unit ->
(pub, [> `Msg of string ]) Stdlib.result
pub ~fips ~p ~q ~gg ~y ()
constructs a public DSA key from the given numbers. Will result in an error if the parameters are not well-formed: one < gg < p
, q
probabilistically a prime, p
probabilistically prime and odd, 0 < y < p
, q < p
, and p - 1 mod q = 0
. If fips
is specified and true
(defaults to false
), only FIPS-specified bit length for p
and q
are accepted.
Key size request. Three Fips variants refer to FIPS-standardized L-values (p
size) and imply the corresponding N (q
size); The last variants specifies L and N directly.
Masking (cryptographic blinding) option.
val generate : ?g:Mirage_crypto_rng.g -> keysize -> priv
generate g size
is a fresh private key. The domain parameters are derived using a modified FIPS.186-4 probabilistic process, but the derivation can not be validated. Note that no time masking is done for the modular exponentiations.
Note The process might diverge if it is impossible to find parameters with the given bit sizes. This happens when n
gets too big for l
, if the size
was given as `Exactly (l, n)
.
sign ~mask ~k ~key digest
is the signature, a pair of Cstruct.t
s representing r
and s
in big-endian.
digest
is the full digest of the actual message.
k
, the random component, can either be provided, or is deterministically derived as per RFC6979, using SHA256.
val verify : key:pub -> (Cstruct.t * Cstruct.t) -> Cstruct.t -> bool
verify ~key (r, s) digest
verifies that the pair (r, s)
is the signature of digest
, the message digest, under the private counterpart to key
.
val massage : key:pub -> Cstruct.t -> Cstruct.t
massage key digest
is the numeric value of digest
taken modulo q
and represented in the leftmost bits(q)
bits of the result.
Both FIPS.186-4 and RFC6979 specify that only the leftmost bits(q)
bits of digest
are to be taken into account, but some implementations consider the entire digest
. In cases where sign and verify seem incompatible with a given implementation (esp. if sign produces signatures with the s
component different from the other implementation's), it might help to pre-process digest
using this function (e.g. sign ~key (massage ~key:(pub_of_priv key) digest)
).
module K_gen (H : Mirage_crypto.Hash.S) : sig ... end
K_gen
can be instantiated over a hashing module to obtain an RFC6979 compliant k
-generator for that hash.