Network Working Group Groves
Internet Draft CESG
Intended Status: Informational February 28, 2011
Expires: September 01, 2011
Elliptic Curve-based Certificate-less Signatures for Identifier Based
Encryption (ECCSI)
draft-groves-eccsi-01
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Abstract
Many signature schemes currently in use rely on certificates for
authentication of identity. In Identifier based cryptography, this
adds unnecessary overhead and administration. The ECCSI signature
scheme described in this document is certificate-less. This scheme
has the additional advantages of low bandwidth and low computational
requirements.
Table of Contents
1. Introduction.....................................................2
1.1. Requirements Terminology....................................3
2. Architecture.....................................................3
3. Notation.........................................................5
3.1. Arithmetic..................................................5
3.2. Representations.............................................5
3.3. Format of material..........................................6
4. Parameters.......................................................6
4.1. Static Parameters...........................................7
4.2. Community Parameters........................................8
5. Algorithms.......................................................8
5.1. User Key Material...........................................8
5.1.1. Algorithm for constructing (SSK,PVT) pair..............8
5.1.2. Algorithm for validating a received SSK................9
5.2. Signatures..................................................9
5.2.1. Algorithm for signing..................................9
5.2.2. Algorithm for verifying...............................10
6. Security Considerations.........................................11
7. IANA Considerations.............................................12
8. References......................................................12
8.1. Normative References.......................................12
8.2. Informative References.....................................13
Appendix A. Test data..............................................13
1. Introduction
Digital signatures provide authentication services across a wide
range of applications. A chain of trust for such signatures is
usually provided by certificates. However, in low bandwidth or other
resource constrained environments, the use of certificates might be
undesirable. This document describes an efficient scheme, ECCSI, for
elliptic curve-based certificate-less signatures, primarily intended
for use with Identifier Based Encryption (IBE) schemes such as
[SAKKE]. As certificates are not needed, the need to transmit or
store them to authenticate each communication is obviated. The
algorithm has been developed by drawing on ideas set out by Arazi
[BA] and is originally based upon [ECDSA], one of the most commonly
used signature algorithms.
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The algorithm is for use in the following context:
where there are two parties, a Signer and a Verifier;
where short unambiguous Identifier strings are naturally
associated to each of these parties;
where a message is to be signed and then verified (e.g., for
authenticating the initiating party during an Identifier-based key
establishment);
where a common Key Management Server (KMS) provides a root of
trust for both parties.
The scheme does not rely on any web of trust between users.
Authentication is provided in a single simplex transmission without
per-session reference to any third party. Thus the scheme is
particularly suitable in situations where the receiving party need
not be active (or even enrolled) when the message to be authenticated
is sent, or in which the number of transmissions is to be minimized
for efficiency.
Instead of having a certificate, the Signer has an Identifier, to
which his Secret Signing Key (see Section 2) will have been
cryptographically bound by means of a Public Validation Token (see
Section 2) by the KMS. Unlike a traditional public key, this Public
Validation Token requires no further explicit certification.
The verification primitive within this scheme can be implemented
using projective representation of elliptic curve points, without
arithmetic field divisions, and without explicitly using the size of
the underlying cryptographic group.
1.1. Requirements Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119].
2. Architecture
A Key Management Server (KMS) provisions key material for a set of
communicating devices (a "user community"). Each device within the
user community MUST have an Identifier (ID) which can be formed by
its peers. These Identifiers MUST be unique to devices (or users),
and MAY change over time. As such, all applications of this
signature scheme MUST define an unambiguous format for Identifiers.
We consider the situation where one device (the Signer) wishes to
sign a message that it is sending to another (the Verifier). Only
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the Signer's Identifier is used in the signature scheme.
In advance, the KMS chooses its KMS Secret Authentication Key (KSAK),
which is the root of trust for all other key material in the scheme.
From this, the KMS derives the KMS Public Authentication Key (KPAK),
which all devices will require in order to verify Signatures. This
will be the root of trust for verification.
Before verification of any Signatures, members of the user community
are supplied with the KPAK. The supply of the KPAK MUST be
authenticated by the KMS and this authentication MUST be verified by
each member of the user community. Confidentiality protection MAY
also be applied.
In the description of the algorithms in this document, it is assumed
that there is one KMS, one user community, and hence one KPAK.
Applications MAY support multiple KPAKs, and some KPAKs could in fact
be "private" to certain communities in certain circumstances. The
method for determining which KPAK to use (when more than one is
available) is out of scope.
The KMS generates and provisions key material for each device. It
MUST supply a Secret Signing Key (SSK) along with a Public Validation
Token (PVT) to all devices that are to send signed messages. The
mechanism by which these SSKs are provided MUST be secure, as the
security of the authentication provided by ECCSI Signatures is no
stronger than the security of this supply channel.
Before using the supplied key material (SSK,KPAK) to form Signatures,
the Sender MUST verify the key material (SSK) against the root of
trust (KPAK) and against its own Identifier (ID) and its Public
Validation Token (PVT) using the algorithm defined in Section 5.1.2.
During the signing protocol, once the Signer has formed its message,
it signs the message using its SSK. It transmits the Signature
(including the PVT), and MAY also transmit the message (in cases
where the message is not known to the Verifier). The Verifier MUST
then use the message, Signature, and Sender ID in verification
against the KPAK.
This document specifies
an algorithm for creating a KPAK from a KSAK, for a given elliptic
curve;
a format for transporting a KPAK;
an algorithm for creating an SSK and a PVT from a Signer's ID,
using the KSAK;
an algorithm for verifying an SSK and a PVT against a Signer's ID
and KPAK;
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an algorithm for creating a Signature from a message, using a
Signer's ID with a matching SSK and PVT;
a format for transporting a Signature;
an algorithm for verifying a Signature for a message, using a
Signer's ID with the matching KPAK.
This document does not specify (but comments on)
how to choose a valid and secure elliptic curve;
which hash function to use;
how to format a Signer's ID;
how to format a message for signing;
how to manage and install a KPAK;
how to transport or install an SSK.
As used in [MIKEY-SAKKE], the elliptic curve and hash function are
specified in Section 2.1.1 of [MIKEY-SAKKE], the format of
Identifiers is specified in Section 3.2 of [MIKEY-SAKKE] and messages
for signing are formatted as specified in [RFC3830].
3. Notation
3.1. Arithmetic
ECCSI relies on elliptic curve arithmetic. If P and Q are two
elliptic curve points, their addition is denoted P + Q. Moreover,
the addition of P with itself k times is denoted [k]P.
F_p denotes the finite field of p elements, where p is prime. All
elliptic curve points will be defined over F_p.
The curve is defined by the equation y^2 = x^3 - 3*x + B modulo p,
where B is an element of F_p. Elliptic curve points, other than the
group identity (0), are represented in the format P = (Px,Py), where
Px and Py are the affine coordinates in F_p satisfying the above
equation. In particular, a point P = (Px,Py) is said to lie on an
elliptic curve if Py^2 - Px^3 + 3*Px - B = 0 modulo p. The identity
point 0 will require no representation.
3.2. Representations
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This section provides canonical representations of values which MUST
be used to ensure interoperability of implementations. The following
representations MUST be used for input into hash functions and for
transmission. In this document concatenation of octet strings s and
t is denoted s || t. The logarithm base 2 of a real number a is
denoted lg(a).
Integers Integers MUST be represented as an octet string,
with bit length a multiple of 8. To achieve this,
the integer is represented most significant bit
first, and padded with zero bits on the left until
an octet string of the necessary length is
obtained. This is the Octet String representation
described in Section 6 of [RFC6090]. There will
be no need to represent negative integers. When
transmitted or hashed, such octet strings MUST
have length N = Ceiling(lg(p)/8).
F_p elements Elements of F_p MUST be represented as integers in
the range 0 to p-1 using the octet string
representation defined above. For use in ECCSI
such octet strings MUST have length N =
Ceiling(lg(p)/8).
Points on E Elliptic Curve Points MUST be represented in
Uncompressed representation ("affine coordinates")
as defined in Section 2.2 of [RFC5480]. For an
elliptic curve point (x,y) with x and y in F_p,
this representation is given by 0x04 || x' || y' ,
where x' is the N-octet string representing x and
y' is the N-octet string representing y.
3.3. Format of material
This section describes the subfields of the different objects used
within the protocol.
Signature = r || s || PVT where r and s are octet strings of length
N = Ceiling(lg(p)/8) representing
integers, and PVT is an octet string of
length 2N+1 representing an elliptic
curve point, yielding a total signature
length of 4N+1 octets. (Note that r and
s represent integers rather than elements
of F_p, and therefore it is possible that
either or both of them could equal or
exceed p.)
4. Parameters
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4.1. Static Parameters
The following static parameters are fixed for each implementation.
They are not intended to change frequently, and MUST be specified for
each user community. Note that these parameters MAY be shared across
multiple KMSs.
n A security parameter, the size in bits of the
prime p over which elliptic curve cryptography
is to be performed.
N = Ceiling(n/8) The number of octets used to represent
fields r and s in a Signature. Also the
number of octets output by the Hash Function
(see below).
p A prime number of size n bits. The finite
field with p elements is denoted F_p.
E An elliptic curve defined over F_p, having a
subgroup of prime order q.
B An element of F_p, where E is defined by the
formula y^2 = x^3 - 3*x + B modulo p.
G A point on the elliptic curve E which generates
the subgroup of order q.
q The prime q is defined to be the order of G in
E over F_p.
Hash A cryptographic hash function mapping arbitrary
strings to strings of N octets. If a, b, c,
... are strings, then hash( a || b || c ||
...) denotes the result obtained by hashing the
concatenation of these strings.
Identifiers The method for deriving user Identifiers. The
format of Identifiers MUST be specified by each
implementation. It MUST be possible for each
device to derive the Identifier for every
device with which it needs to communicate. In
this document, ID will denote the correctly
formatted Identifier string of the Signer.
ECCSI makes use of the Signer Identifier only,
though an implementation MAY make use of other
Identifiers when constructing the message to be
signed. Identifier formats MAY include a
timestamp to allow for automatic expiration of
key material.
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It is RECOMMENDED that p, E, and G are chosen to be standardized
values. In particular, it is RECOMMENDED to use the curves and
base-points defined in [FIPS186-3].
4.2. Community Parameters
The following community parameter MUST be supplied to devices each
time the root of trust is changed.
KPAK The KMS Public Authentication Key (KPAK) is the root of trust
for authentication. It is derived from the KSAK in the KMS.
This value MUST be provisioned in a trusted fashion, such
that each device that receives it has assurance that it is
the genuine KPAK belonging to its KMS. Before use, each
device MUST check that the supplied KPAK lies on the elliptic
curve E.
The KMS MUST fix the KPAK to be KPAK = [KSAK]G, where KSAK MUST be
chosen to be a random secret non-zero integer modulo q. The value
KSAK MUST be kept secret to the KMS.
5. Algorithms
5.1. User Key Material
To create Signatures, each Signer requires a Secret Signing Key (SSK)
and a Public Validation Token (PVT). The SSK is an integer and the
PVT is an elliptic curve point. The SSK MUST be kept secret (to the
Signer and KMS), but the PVT need not be kept secret. A different
(SSK,PVT) pair will be needed for each Signer ID.
5.1.1. Algorithm for constructing (SSK,PVT) pair
The KMS constructs a (SSK,PVT) pair from the Signer's ID (ID), the
KMS secret (KSAK), and the root of trust (KPAK). To do this, the KMS
MUST perform the following procedure:
* Choose v, a random (ephemeral) non-zero element of F_q;
* Compute PVT = [v]G (this MUST be represented canonically - see
Section 3.2);
* Compute HS = hash( G || KPAK || ID || PVT ), an N-octet integer;
* Compute SSK = ( KSAK + HS * v ) modulo q;
* If either SSK or HS is zero modulo q, the KMS MUST erase SSK and
abort or restart the procedure with a fresh value of v;
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* Output the pair ( SSK, PVT ). The KMS MUST then erase the value
v.
The method for transporting the SSK to the legitimate Signer device
is out of scope of this document, but the SSK MUST be provisioned by
the KMS using a method that protects its confidentiality.
If necessary, the KMS MAY create multiple (SSK,PVT) pairs for the
same Identifier.
5.1.2. Algorithm for validating a received SSK
Every SSK MUST be validated before being installed as a signing key.
The Signer uses its ID and the KPAK to validate a received (SSK,PVT)
pair. To do this validation, the Signer MUST perform the following
procedure, passing all checks:
* Validate that PVT lies on the elliptic curve E;
* Compute HS = hash( G || KPAK || ID || PVT ), an N-octet
integer. The integer HS SHOULD be stored with the SSK for later
use;
* Validate that KPAK = [SSK]G - [HS]PVT.
5.2. Signatures
5.2.1. Algorithm for signing
To sign a message M, the Signer requires:
the KMS Public Authentication Key, KPAK;
the Signer's own Identifier, ID;
its Secret Signing Key, SSK;
its Public Validation Token, PVT = ( PVTx, PVTy ).
These values, with the exception of ID, MUST have been provided by
the KMS. The value of ID is derived by the Signer using the
community defined method for formatting Identifiers.
The following procedure MUST be used by the Signer to compute the
signature:
1) Choose a random (ephemeral) non-zero value j in F_q;
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2) Compute J = [j]G (this MUST be represented canonically).
Viewing J in affine coordinates J = (Jx,Jy), assign to r the
N-octet integer representing Jx;
3) Recall (or recompute) HS, and use it to compute HE = hash( HS
|| r || M );
4) Verify that HE + r * SSK is non-zero modulo q; if this check
fails, the Signer MUST abort or restart this procedure with a
fresh value of j;
5) Compute s' = ( (( HE + r * SSK )^-1) * j ) modulo q; the Signer
MUST then erase the value j;
6) If s' is too big to fit within an N-octet integer, then set the
N-octet integer s = q - s'; otherwise set the N-octet integer s
= s' (note that, since p is less than 2^n, by Hasse's theorem
on elliptic curves, q < 2^n + 2^(n/2 + 1) + 1. Therefore, if
s' > 2^n, we have q - s' < 2(n/2 + 1) + 1. Thus s is
guaranteed to fit within an N-octet integer);
7) Output the signature as Signature = ( r || s || PVT ).
Note that the reason that step 6) is necessary is that it is possible
for q (and hence for elements of F_q) to be too big to fit within N
octets. The Signer MAY instead elect to set s to be the least
integer of s' and q - s', represented in N octets.
5.2.2. Algorithm for verifying
The algorithm provided assumes that the Verifier computes points on
elliptic curves using affine coordinates. However, the Verifier MAY
perform elliptic curve operations using any appropriate
representation of points which achieves the equivalent operations.
To verify a Signature ( r || s || PVT ) against a Signer's Identifier
ID, a message M, and a pre-installed root of trust KPAK, the Verifier
MUST perform a procedure equivalent to the following:
1) The Verifier MUST check that PVT lies on the elliptic curve E;
2) Compute HS = hash( G || KPAK || ID || PVT );
3) Compute HE = hash( HS || r || M );
4) Y = [HS]PVT + KPAK.
5) Compute J = [s]( [HE]G + [r]Y ).
6) Viewing J in affine coordinates (Jx,Jy), the Verifier MUST
check that Jx = r modulo p, and that Jx modulo p is non-zero,
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before accepting the Signature as valid.
It is anticipated that the Identifier (ID), message (M), and KPAK,
will be implicitly understood due to context, but any of these values
MAY also be included in signaling.
Note that the parameter q is not needed during verification.
6. Security Considerations
The ECCSI cryptographic algorithm is based upon [ECDSA]. In fact,
step '5' in the verification algorithm above is the same as the
verification stage in ECDSA. The only difference between ECDSA and
ECCSI is that in ECCSI the 'public key', Y, is derived from the
Signer ID by the verifier (whereas in ECDSA the public key is
fixed). It is therefore assumed that the security of ECCSI depends
entirely on the secrecy of the secret keys. In addition, to recover
secret keys one will need to perform computationally intensive
cryptanalytic attacks.
The KMS Secret Authentication Key (KSAK) provides the security for
each device provisioned by the KMS. It MUST NOT be revealed to any
entity other than the KMS which holds it. Each user's Secret Signing
Key (SSK) authenticates the user as being associated with the
Identifier (ID) to which the Secret Signing Key is assigned by the
KMS. This key MUST NOT be revealed to any entity other than the KMS
and the authorized user.
The order of the base point G used in ECCSI MUST be a large prime q.
If k bits of symmetric security are needed, Ceiling(lg(q)) MUST be at
least 2*k.
It is RECOMMENDED that the curves and base-points defined in
[FIPS186-3] are used since these curves are suitable for
cryptographic use. However, if other curves are used, the security
of the curves MUST be assessed.
In order to ensure that the Secret Signing Key is only received by an
authorized device, it MUST be provided through a secure channel. The
strength of the authentication offered by this signature scheme is no
greater than the security provided by this delivery channel.
Identifiers MUST be defined unambiguously by each application of
ECCSI. Note that it is not necessary to use a hash function to
compose an Identifier string. In this way, any weaknesses that might
otherwise be caused by collisions in hash functions can be avoided
without reliance on the structure of the Identifier format.
Applications of ECCSI MAY include a time/date component in their
Identifier format to ensure that Identifiers (and hence Secret
Signing Keys) are only valid for a fixed period of time.
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The use of the ephemeral value r in the hash HE significantly reduces
the scope for offline attacks, improving the overall security, as
compared to [ECDSA]. Furthermore, if Identifiers are specified to
contain date-stamps, then all Identifiers, secret signing keys,
signatures, and hash values will become deprecated periodically
automatically, reducing the need for revocation and other additional
management methods.
The randomness of values stipulated to be selected at random as
described in this document is essential to the security provided by
ECCSI. If the value of KSAK (the KMS Secret Authentication Key) can
be predicted, then any signatures can be forged. Similarly, if the
value of v used by the KMS to create a user's Secret Signing Key can
be predicted, then the value of KSAK could be recovered, which would
allow signatures to be forged. If the value of j used by a user is
predictable, then the value of his Secret Signing Key could be
recovered. This would allow that user's signatures to be forged.
Guidance on the generation of random values for security can be found
in [RFC4086].
Note that in most instances the value s in the Signature can be
replaced by q - s. Thus the malleability of ECCSI signatures is
similar to that in [ECDSA]; malleability is available but yet also
very limited.
7. IANA Considerations
This document has no IANA actions.
8. References
8.1. Normative References
[ECDSA] X9.62-2005, "Public Key Cryptography for the
Financial Services Industry: The Elliptic Curve
Digital Signature Standard (ECDSA)", November,
2005.
[FIPS186-3] Federal Information Processing Standards Publication
(FIPS PUB) 186-3, Digital Signature Standard (DSS),
June 2009.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC5480] Turner, S., Brown, D., Yiu, K., Housley, R. and
T. Polk, "Elliptic Curve Cryptography Subject
Public Key Information", RFC 5480, March 2009.
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[RFC6090] McGrew, D., Igoe, K. and M. Salter, "Fundamental
Elliptic Curve Cryptography Algorithms", RFC 6090,
February 2011.
8.2. Informative References
[BA] Arazi, Benjamin, paper submitted to P1363 meeting,
August 1998, http://grouper.ieee.org/groups/1363/
StudyGroup/contributions/arazi.doc.
[FIPS180-3] Federal Information Processing Standards Publication
(FIPS PUB) 180-3, Secure Hash Standard (SHS),
October 2008.
[MIKEY-SAKKE] Groves, M., "MIKEY-SAKKE: Sakai-Kasahara Key
Exchange in Multimedia Internet KEYing (MIKEY)",
draft-groves-mikey-sakke-01 [work in progress],
February 2011.
[RFC3830] Arkko, J., Carrara, E., Lindholm, F., Naslund, M.,
and K. Norrman, "MIKEY: Multimedia Internet
KEYing", RFC 3830, August 2004.
[RFC4086] Eastlake, D., Schiller, J., and S. Crocker,
"Randomness Requirements for Security", BCP 106,
RFC 4086, June 2005.
[SAKKE] Groves M., "Sakai-Kasahara Key Establishment
(SAKKE)", draft-groves-sakke-01 [work in progress],
February 2011.
Appendix A. Test data
This test data is built from the NIST P256 curve and base-point.
SHA-256 (as defined in [FIPS180-3]) is used as the hash function.
The keys and ephemerals KSAK, v, j, are arbitrary and for
illustration only.
// --------------------------------------------------------
// Global parameters
n := 256;
N := 32;
p := 0x FFFFFFFF 00000001 00000000 00000000
00000000 FFFFFFFF FFFFFFFF FFFFFFFF;
Hash := SHA-256;
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// --------------------------------------------------------
// Community parameters
B := 0x 5AC635D8 AA3A93E7 B3EBBD55 769886BC
651D06B0 CC53B0F6 3BCE3C3E 27D2604B;
q := 0x FFFFFFFF 00000000 FFFFFFFF FFFFFFFF
BCE6FAAD A7179E84 F3B9CAC2 FC632551;
G := 0x 04
6B17D1F2 E12C4247 F8BCE6E5 63A440F2
77037D81 2DEB33A0 F4A13945 D898C296
4FE342E2 FE1A7F9B 8EE7EB4A 7C0F9E16
2BCE3357 6B315ECE CBB64068 37BF51F5;
KSAK := 0x 12345;
KPAK := 0x 04
50D4670B DE75244F 28D2838A 0D25558A
7A72686D 4522D4C8 273FB644 2AEBFA93
DBDD3755 1AFD263B 5DFD617F 3960C65A
8C298850 FF99F203 66DCE7D4 367217F4;
// --------------------------------------------------------
// Signer ID
ID := "2011-02\0tel:+447700900123\0",
= 0x 3230 31312D30 32007465 6C3A2B34
34373730 30393030 31323300;
// --------------------------------------------------------
// Creating SSK and PVT
v := 0x 23456;
PVT := 0x 04
758A1427 79BE89E8 29E71984 CB40EF75
8CC4AD77 5FC5B9A3 E1C8ED52 F6FA36D9
A79D2476 92F4EDA3 A6BDAB77 D6AA6474
A464AE49 34663C52 65BA7018 BA091F79;
HS := hash( 0x 04
6B17D1F2 E12C4247 F8BCE6E5 63A440F2
77037D81 2DEB33A0 F4A13945 D898C296
4FE342E2 FE1A7F9B 8EE7EB4A 7C0F9E16
2BCE3357 6B315ECE CBB64068 37BF51F5
04
50D4670B DE75244F 28D2838A 0D25558A
7A72686D 4522D4C8 273FB644 2AEBFA93
DBDD3755 1AFD263B 5DFD617F 3960C65A
8C298850 FF99F203 66DCE7D4 367217F4
32303131 2D303200 74656C3A 2B343437
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37303039 30303132 3300
04
758A1427 79BE89E8 29E71984 CB40EF75
8CC4AD77 5FC5B9A3 E1C8ED52 F6FA36D9
A79D2476 92F4EDA3 A6BDAB77 D6AA6474
A464AE49 34663C52 65BA7018 BA091F79 ),
= 0x 490F3FEB BC1C902F 6289723D 7F8CBF79
DB889308 49D19F38 F0295B5C 276C14D1;
SSK := 0x 23F374AE 1F4033F3 E9DBDDAA EF20F4CF
0B86BBD5 A138A5AE 9E7E006B 34489A0D;
// --------------------------------------------------------
// Creating a Signature
M := "message\0",
= 0x 6D657373 61676500;
j := 0x 34567;
J := 0x 04
269D4C8F DEB66A74 E4EF8C0D 5DCC597D
DFE6029C 2AFFC493 6008CD2C C1045D81
6DDA6A13 10F4B067 BD5DABDA D741B7CE
F36457E1 96B1BFA9 7FD5F8FB B3926ADB;
r := 0x 269D4C8F DEB66A74 E4EF8C0D 5DCC597D
DFE6029C 2AFFC493 6008CD2C C1045D81;
HE := hash( 0x
490F3FEB BC1C902F 6289723D 7F8CBF79
DB889308 49D19F38 F0295B5C 276C14D1
269D4C8F DEB66A74 E4EF8C0D 5DCC597D
DFE6029C 2AFFC493 6008CD2C C1045D81
6D657373 61676500 ),
= 0x 111F90EA E8271C96 DF9B3D67 26768D9E
E9B18145 D7EC152C FA9C23D1 C4F02285;
s' := 0x E09B528D 0EF8D6DF 1AA3ECBF 80110CFC
EC9FC682 52CEBB67 9F413484 6940CCFD;
s := 0x E09B528D 0EF8D6DF 1AA3ECBF 80110CFC
EC9FC682 52CEBB67 9F413484 6940CCFD;
Sig := 0x 269D4C8F DEB66A74 E4EF8C0D 5DCC597D
DFE6029C 2AFFC493 6008CD2C C1045D81
E09B528D 0EF8D6DF 1AA3ECBF 80110CFC
EC9FC682 52CEBB67 9F413484 6940CCFD
04
Groves Informational [Page 15]
Internet Draft draft-groves-eccsi-01 Feb 28, 2011
758A1427 79BE89E8 29E71984 CB40EF75
8CC4AD77 5FC5B9A3 E1C8ED52 F6FA36D9
A79D2476 92F4EDA3 A6BDAB77 D6AA6474
A464AE49 34663C52 65BA7018 BA091F79;
// --------------------------------------------------------
// Verifying a Signature
Y := 0x 04
833898D9 39C0013B B0502728 6F95CCE0
37C11BD2 5799423C 76E48362 A4959978
95D0473A 1CD6186E E9F0C104 B472499E
1A24D6CE 3D85173F 02EBBD94 5C25F604;
J := 0x 04
269D4C8F DEB66A74 E4EF8C0D 5DCC597D
DFE6029C 2AFFC493 6008CD2C C1045D81
6DDA6A13 10F4B067 BD5DABDA D741B7CE
F36457E1 96B1BFA9 7FD5F8FB B3926ADB;
Jx := 0x 269D4C8F DEB66A74 E4EF8C0D 5DCC597D
DFE6029C 2AFFC493 6008CD2C C1045D81;
Jx = r modulo p.
// --------------------------------------------------------
Author's Address
Michael Groves
CESG
Hubble Road
Cheltenham
GL51 8HJ
UK
Email: Michael.Groves@cesg.gsi.gov.uk
Acknowledgement
Funding for the RFC Editor function is provided by the IETF
Administrative Support Activity (IASA).
Groves Informational [Page 16]