The English version of this specification is the only normative version. Nonnormative translations may also be available.
Copyright © 20132017 FIDO Alliance All Rights Reserved.
The FIDO Basic Attestation scheme uses attestation "group" keys shared across a set of authenticators with identical characteristics in order to preserve privacy by avoiding the introduction of global correlation handles. If such an attestation key is extracted from one single authenticator, it is possible to create a "fake" authenticator using the same key and hence indistinguishable from the original authenticators by the relying party. Removing trust for registering new authenticators with the related key would affect the entire set of authenticators sharing the same "group" key. Depending on the number of authenticators, this risk might be unacceptable high.
This is especially relevant when the attestation key is primarily protected against malware attacks as opposed to targeted physical attacks.
An alternative approach to "group" keys is the use of individual keys combined with a PrivacyCA [TPMv12Part1]. Translated to FIDO, this approach would require one PrivacyCA interaction for each Uauth key. This means relatively high load and high availability requirements for the PrivacyCA. Additionally the PrivacyCA aggregates sensitive information (i.e. knowing the relying parties the user interacts with). This might make the PrivacyCA an interesting attack target.
Another alternative is the Direct Anonymous Attestation [BriCamChe2004DAA]. Direct Anonymous Attestation is a cryptographic scheme combining privacy with security. It uses the authenticator specific secret once to communicate with a single DAA Issuer and uses the resulting DAA credential in the DAASign protocol with each relying party. The DAA scheme has been adopted by the Trusted Computing Group for TPM v1.2 [TPMv12Part1].
In this document, we specify the use of an improved DAA scheme based on elliptic curves and bilinear pairings largely compatible with [CheLi2013ECDAA] called ECDAA. This scheme provides significantly improved performance compared with the original DAA and basic building blocks for its implementation are part of the TPMv2 specification [TPMv2Part1].
Our improvements over [CheLi2013ECDAA] mainly consist of security fixes (see [ANZ2013] and [XYZF2014]) when splitting the sign operation into two parts.
This section describes the status of this document at the time of its publication. Other documents may supersede this document. A list of current FIDO Alliance publications and the latest revision of this technical report can be found in the FIDO Alliance specifications index at https://www.fidoalliance.org/specifications/.
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This document has been reviewed by FIDO Aliance Members and is endorsed as a Proposed Standard. It is a stable document and may be used as reference material or cited from another document. FIDO Alliance's role in making the Recommendation is to draw attention to the specification and to promote its widespread deployment.
Type names, attribute names and element names are written as code
.
String literals are enclosed in “”, e.g. “ED256”.
In formulas we use “” to denote byte wise concatenation operations.
$X = P^x$ denotes scalar multiplication (with scalar x) of a (elliptic) curve point P.
RAND(x) denotes generation of a random number between 0 and x1.
RAND(G) denotes generation of a random number belonging to Group G.
Specific terminology used in this document is defined in [FIDOGlossary].
The type BigNumber
denotes an arbitrary length integer value.
The type ECPoint
denotes an elliptic curve point with its affine coordinates x and y.
The type ECPoint2
denotes a point on the sextic twist of a BN elliptic curve over $F(q^2)$.
The ECPoint2 has two affine coordinates each having two components of type BigNumber
As well as sections marked as nonnormative, all authoring guidelines, diagrams, examples, and notes in this specification are nonnormative. Everything else in this specification is normative.
The key words MUST, MUST NOT, REQUIRED, SHOULD, SHOULD NOT, RECOMMENDED, MAY, and OPTIONAL in this specification are to be interpreted as described in [RFC2119].
This section is nonnormative.
FIDO uses the concept of attestation to provide a cryptographic proof of the authenticator [FIDOGlossary] model to the relying party. When the authenticator is registered to the relying party (RP), it generates a new authentication key pair and includes the public key in the attestation message (also known as key registration data object, KRD). When using the ECDAA algorithm, the KRD object is signed using 3.5 ECDAASign.
For privacy reasons, the authentication key pair is dedicated to one RP (to an application identifier AppID [FIDOGlossary] to be more specific). Consequently the attestation method needs to provide the same level of unlinkability. This is the reason why the FIDO ECDAA Algorithm doesn't use a basename (bsn) often found in other direct anonymous attestation algorithms, e.g. [BriCamChe2004DAA] or [BFGSW2011].
The authenticator encapsulates all user verification operations and cryptographic functions. An authenticator specific module (ASM) [FIDOGlossary] is used to provide a standardized communication interface for authenticators. The authenticator might be implemented in separate hardware or trusted execution environments. The ASM is assumed to run in the normal operating system (e.g. Android, Windows, ...).
This document describes the FIDO ECDAA attestation algorithm in detail.
The technical implementation details of the ECDAAJoin step are outofscope for FIDO. In this document we normatively specify the general algorithm to the extent required for interoperability and we outline examples of some possible implementations for this step.
The ECDAASign and ECDAAVerify steps and the encoding of the related ECDAA Signature are normatively specified in this document. The generation and encoding of the KRD object is defined in other FIDO specifications.
The algorithm and terminology are inspired by [BFGSW2011]. The algorithm was modified in order to fix security weaknesses (e.g. as mentioned by [ANZ2013] and [XYZF2014]). Our algorithm proposes an improved task split for the sign operation while still being compatible to TPMv2 (without fixing the TPMv2 weaknesses in such case).
This section is normative.
We need to convert BigNumber
and ECPoint
objects to
byte strings using the following encoding functions:
BigNumber
values as byte strings (BigNumberToB)n
will be copied rightaligned into the buffer area b
.
The unused bytes will be set to 0. Negative values will not occur due to the construction of the algorithms.
b0 b1 b2 b3 b4 b5 b6 b7 0 0 n0 n1 n2 n3 n4 n5
ByteArray BigNumberToB( BigNumber inVal, // IN: number to convert int size // IN: size of the output. ) { ByteArray buffer = new ByteArray(size); int oversize = size  inVal.length; if (oversize < 0) return null; for (int i=overvize; i > 0; i) buffer[i] = 0; ByteCopy( inVal.bytes, &buffer[oversize], inVal.length); return buffer; }
ECPoint
values as byte strings (ECPointToB)(x, y) = ECPointGetAffineCoordinates(P) len = G1.byteLength byte string = 0x04  BigIntegerToB(x,len)  BigIntegerToB(y,len)
ECPoint2
values as byte strings (ECPoint2ToB)
The type ECPoint2
denotes a point on the sextic twist of a BN elliptic curve over $F(q^2)$,
see section 4.1 Supported Curves for ECDAA.
Each ECPoint2
is represented by a pair (a, b)
of elements of $F(q)$.
We always assume normalized (nonzero) ECPoint2 values (i.e. cz = 1) before encoding them.
Nonzero values are encoded using the expanded format (i.e. 0x04 for expanded)
followed by the cx followed by the cy value.
This leads to the concatenation of 0x04 followed by the first element (cx.a
) and
second element (cx.b
) of the pair of cx followed by the
first element (cy.a
) and second element (cy.b
) of the pair of cy.
All individual numbers are padded to the same length
(i.e. the maximum byte length of all relevant 4 numbers).
(cx, cy) = ECPointGetAffineCoordinates(P2) len = G2.byteLength byte string = 0x04  BigIntegerToB(cx.a,len)  BigIntegerToB(cx.b,len)  BigIntegerToB(cy.a,len)  BigIntegerToB(cy.b,len)
Definition of $G_1, G_2, G_T$, Pairings and hash function $H$
See section 4.1 Supported Curves for ECDAA.$H(P_2^{s_x} \cdot X^{c}  P_2^{s_y} \cdot Y^{c}  P_2  X  Y) \stackrel{?}{=} c$
$P_2^{s_x} \cdot X^{c} = P_2^{r_x + c x} \cdot P_2^{c x} = P_2^{r_x} = U_x$
$P_2^{s_y} \cdot Y^{c} = P_2^{r_y + c y} \cdot P_2^{c y} = P_2^{r_y} = U_y$
The ECDAAIssuer public key ipk MUST be dedicated to a single authenticator model.
One ECDAAJoin operation is required once in the lifetime of an authenticator prior to the first registration of a credential.
In order to use ECDAA, the authenticator must first receive ECDAA credentials from an ECDAAIssuer. This is done by the ECDAAJoin operation. This operation needs to be performed a single time (before the first credential registration can take place). After the ECDAAJoin, the authenticator will use the ECDAASign operation as part of each FIDO Registration. The ECDAAIssuer is not involved in this step. ECDAA plays no role in FIDO Authentication / Transaction Confirmation operations.
In order to use ECDAA, (at least) one ECDAAIssuer is needed. The approach specified in this document easily scales to multiple ECDAAIssuers, e.g. one per authenticator vendor. FIDO lets the authenticator vendor choose any ECDAAIssuer (similar to his current freedom for selecting any PKI infrastructure/service provider to issuing attestation certificates required for FIDO Basic Attestation).
There are two different implementation options relevant for the authenticator Vendors (the authenticator vendor can freely choose them):
In the first case, physical proximity is used to locally establish the trust between the ECDAAIssuer and the authenticator (e.g. using a key provisioning station in a production line). There is no requirement for the ECDAAIssuer to operate an online web service.
In the second case, some credential is required to remotely establish the trust between the ECDAAIssuer and the authenticator. As this operation is performed once and only with a single ECDAAIssuer, privacy is preserved and an authenticator specific credential can and should be used.
Not all ECDAA authenticators might be able to add their authenticator model IDs (e.g. AAGUID) to the registration assertion (e.g. TPMs). In all cases, the ECDAAIssuer will be able to derive the exact the authenticator model from either the credential or the physically proximiate authenticator. So the ECDAAIssuer root key MUST be dedicated to a single authenticator model.
This section is normative.
If this join is not infactory, the value Q must be authenticated by the authenticator. Upon receiving this value, the issuer must verify that this authenticator did not join before.
$P_1^{s_1} \cdot Q^{c_1} = P_1^{r_1 + c_1 sk} \cdot Q^{c_1} = P_1^{r_1 + c_1 sk} \cdot P_1^{c_1 sk} = P_1^{r_1} = U_1$
$P_1^{s_2} \cdot B^{c_2} = P_1^{r_2} \cdot P_1^{c_2 \cdot l_J \cdot y} \cdot B^{c_2} = U_2 \cdot B^{c_2} \cdot B^{c_2} = U_2$
$Q^{s_2} \cdot D^{c_2} = Q^{r_2} \cdot Q^{c_2 \cdot l_J \cdot y} \cdot D^{c_2} = V_2 \cdot D^{c_2} \cdot D^{c_2} = V_2$
$e(A, Y) = e(P_1^{l_J}, P_2^y)$; $e(B, P_2) = e(A^y, P_2) = e(P_1^{y l_J}, P_2)$
$e(C, P_2) = e(A^x \cdot Q^{x y l_J}, P_2)$; $e(A \cdot D, X) = e(A \cdot Q^{y l_J}, P_2^x)$
This section is nonnormative.
If this join is not infactory, the value Q must be authenticated by the authenticator. Upon receiving this value, the issuer must verify that this authenticator did not join before.
These values belong to the ECDAA secret key $sk$. They should persist even in the case of a factory reset.
This section is nonnormative.
The Endorsement key credential (EKC) and TPM2_ActivateCredentials are used for supporting the remote Join.
This description is based on the principles described in [TPMv2Part1] section 24 and [ArthurChallener2015], page 109 ("Activating a Credential").
TPMT_PUBLIC
[TPMv2Part2]
(including the public key $Q$ in field unique
) to the ASM.
TPMT_PUBLIC
(including $Q$ in field unique
), $c_1, s_1$
to the ECDAA Issuer.objectAttributes
in TPMT_PUBLIC
[TPMv2Part2]
matches the following flags:
fixedTPM
= 1; fixedParent
= 1; sensitiveDataOrigin
= 1;
encryptedDuplication
= 0;
restricted
= 1; decrypt
= 0; sign
= 1.
The parameter name in KDFa is derived from
TPMT_PUBLIC
, see [TPMv2Part1], section 16.
One ECDAASign operation is required for the clientside environment whenever a new credential is being registered at a relying party.
This section is normative.
(signature, KRD) = EcdaaSign(String AppID)Parameters
Algorithm outline
This section is nonnormative.
This split requires both the authenticator and ASM to be honest to achieve anonymity. Only the authenticator must be trusted for unforgeability. The communication between ASM and authenticator must be secure.
Algorithm outline
This section is nonnormative.
This algorithm is for the special case of a TPMv2 as authenticator. This case requires both the TPM and ASM to be honest for anonymity and unforgeability (see [XYZF2014]).
Algorithm outline
This section is normative.
One ECDAAVerify operation is required for the FIDO Server as part of each FIDO Registration.
Parameters
Algorithm outline
$B = A^y = P_1^{l y}$
$D = Q^{l_J y} = P_1^{sk l_J y} = B^{sk}$
$S = B^l$ and $W = D^l$
$U = S^r$
$S^s \cdot W^{c} = S^{r + c sk} \cdot W^{c} = U \cdot S^{c sk} \cdot W^{c}$
$= U \cdot B^{l c sk} \cdot D^{l c} = U \cdot B^{l c sk} \cdot B^{l c sk} = U$
$e(R, Y) = e(A^l, P_2^y); e(S, P_2) = e(B^l, P_2) = e(A^{l y}, P_2)$
$e(T, P_2) = e(C^l, P_2) = e(A^{x l} \cdot Q^{x l y l_J}, P_2); e(A^l \cdot D^l, X) = e(A^l \cdot Q^{l y l_J}, P_2^x)$
TPMS_ATTEST
object. In this case the
verifier must check whether the TPMS_ATTEST
object starts
with TPM_GENERATED
magic number and whether its field
objectAttributes
contains the flag fixedTPM
=1
(indicating that the key was generated by the TPM).
This section is normative.
Definition of G1
G1 is an elliptic curve group E : $y^2 = x^3 + ax + b$ over $F(q)$ with $a=0$.Definition of G2
G2 is the ptorsion subgroup of $E'(F_{q^2})$ where E' is a sextic twist of E. With E' : $y'^2 = x'^3 + b'$.An element of $F(q^2)$ is represented by a pair (a,b) where a + bX is an element of $F(q)[X] / <X^2+1>$. We use angle brackets $<Y>$ to signify the ideal generated by the enclosed value.
In the literature the pair (a,b) is sometimes also written as a complex number $a+b*i$.
Definition of GT
GT is an orderp subgroup of $F_{q^{12}}$.Pairings
We propose the use of Ate pairings as they are efficient (more efficient than Tate pairings) on BarretoNaehrig curves [DevScoDah2007].Supported BN curves
We use pairingfriendly BarretoNaehrig [BarNae2006] [ISO159465] elliptic curves.
The curves TPM_ECC_BN_P256
and
TPM_ECC_BN_P638
curves are defined in [TPMv2Part4].
BN curves have a Modulus $q = 36 \cdot u^4 + 36 \cdot u^3 + 24 \cdot u^2 + 6 \cdot u + 1$ [ISO159465] and a related order of the group $p = 36 \cdot u^4 + 36 \cdot u^3 + 18 \cdot u^2 + 6 \cdot u + 1$ [ISO159465].
TPM_ECC_BN_P256
is a curve of form E(F(q)), where q is the field modulus
[TPMv2Part4] [BarNae2006]. This curve is identical to the P256 curve defined in [ISO159465] section C.3.5.
TPM_ECC_BN_P638
[TPMv2Part4] uses
ECC_BN_DSD_P256
[DevScoDah2007] section 3 uses
ECC_BN_ISOP512
[ISO159465] section C.3.7 uses
Spaces are used inside numbers to improve readability.
Hash Algorithms
Depending on the curve, we use H(x) = SHA256(x) mod p
or
H(x) = SHA512(x) mod p
as hash algorithm H:$\{0, 1\}^* \rightarrow Z_p$.
The argument of the hash function must always be converted to a byte string using the appropriate
encoding function specific in section 3.1 Object Encodings, e.g. according to section
3.1.3 Encoding ECPoint2 values as byte strings (ECPoint2ToB) in the case of ECPoint2
points.
We don't use IEEE P1363.3 section 6.1.1 IHF1SHA with security parameter t (e.g. t=128 or 256) as it is more complex and not supported by TPMv2.
TPM_ECC_BN_P256
curve, using SHA256 as hash algorithm H.ECC_BN_DSD_P256
curve, using SHA256 as hash algorithm H.ECC_BN_ISOP512
curve, using SHA512 as hash algorithm H.TPM_ECC_BN_P638
curve, using SHA512 as hash algorithm H.The fields c and s both have length N. The fields R, S, T, W have equal length (2*N+1 each).
In the case of BN_P256 curve (with key length N=32 bytes), the fields R, S, T, W have length 2*32+1=65 bytes. The fields c and s have length N=32 each.
The ecdaaSignature object is a binary object generated as the concatenation of the binary fields in the order described below (total length of 324 bytes for 256bit curves):
Value  Length (in Bytes)  Description 

UINT8[] ECDAA_Signature_c  N  The c value, c=H(U  S  W  KRD  AppID) as returned by AuthnrEcdaaSign encoded
as byte string according to BigNumberToB.
Where

UINT8[] ECDAA_Signature_s  N  The s value, s=r + c * sk (mod p), as returned by AuthnrEcdaaSign encoded
as byte string according to BigNumberToB.
Where

UINT8[] ECDAA_Signature_R  2*N+1  $R = A^l$; computed by the ASM or the
authenticator at FIDO registration; encoded
as byte string according to ECPointToB. Where

UINT8[] ECDAA_Signature_S  2*N+1  $S = B^l$; computed by the ASM or the authenticator at
FIDO registration encoded as byte string according to ECPointToB.
Where B has been provided by the ECDAAIssuer on Join: $B = A^{y}$, see 3.4.1 ECDAAJoin Algorithm. 
UINT8[] ECDAA_Signature_T  2*N+1  $T = C^l$; computed by the ASM or the authenticator
at FIDO registration encoded as byte string according to ECPointToB.
Where

UINT8[] ECDAA_Signature_W  2*N+1  $W = D^l$; computed by the ASM or the authenticator at
FIDO registration encoded as byte string according to ECPointToB.
Where $D = Q^{l_J y}$ is computed by the ECDAAIssuer at Join (see 3.4.1 ECDAAJoin Algorithm). 
This section is nonnormative.
A detailed security analysis of this algorithm can be found in [FIDODAASecurityProof].The proposed algorithms and key sizes are chosen such that compatibility to TPMv2 is possible.
Some authenticators (e.g. TPMv2) do not have the ability to include their model (i.e. vendor ID and model name) in attested messages (i.e. the tobesigned part of the registration assertion). The TPM's endorsement key certificate typically contains that information directly or at least it allows the model to be derived from the endorsement key certificate.
In FIDO, the relying party expects the ability to cryptographically verify the authenticator model.
We require the ECDAAIssuers public key (ipk=(X,Y,c,sx,sy)) to be dedicated to one single authenticator model (e.g. as identified by AAID or AAGUID).
If the private ECDAA attestation key $sk$ of an authenticator has been leaked, it can be revoked by adding its value to a RogueList.
The ECDAAVerifier (i.e. FIDO Server) check for such revocations. See section 3.6 ECDAAVerify Operation.
The ECDAAIssuer is expected to check revocation by other means:
The pairing algorithm e
needs to be used by the ASM as part of the Join process and by the
verifier (i.e. FIDO relying party) as part of the verification (i.e. FIDO registration) process.
The result of such a pairing operation is only compared to the result of another pairing operation computed by the same entity. As a consequence, it doesn't matter whether the ASM and the verifier use the exact same pairings or not (as long as they both use valid pairings).
For performance reasons the calculation of Sig2=($R, S, T, W$) may be performed by the ASM running on the FIDO user device (as opposed to inside the authenticator). See section 3.5.2 ECDAASign Split between Authenticator and ASM.
The cryptographic computations to be performed inside the authenticator are limited to G1. The ECDAAIssuer has to perform two G2 point multiplications for computing the public key. The Verifier (i.e. FIDO relying party) has to perform G1 operations and two pairing operations.
We use a simple bytewise concatenation function for the different parameters, i.e. H(a,b) = H(a  b).
This approach is as secure as the underlying hash algorithm since the authenticator controls the length of the (fixedlength) values (e.g. U, S, W). The AppID is provided externally and has unverified structure and length. However, it is only followed by a fixed length entry  the (system defined) hash of KRD. As a consequence, no parts of the AppID would ever be confused with the fixed length value.
Algorithm Name  "ED256" 
Algorithm Description  FIDO ECDAA algorithm based on TPM_ECC_BN_P256 [TPMv2Part4] curve using SHA256 hash algorithm. 
Algorithm Usage Location(s)  "alg", i.e. used with JWS. 
JOSE Implementation Requirements  Optional 
Change Controller  FIDO Alliance, Contact Us 
Specification Documents  Sections 3. FIDO ECDAA Attestation and 4. FIDO ECDAA Object Formats and Algorithm Details of [FIDOEcdaaAlgorithm]. 
Algorithm Analysis Document(s)  [FIDODAASecurityProof] 
Algorithm Name  "ED512" 
Algorithm Description  ECDAA algorithm based on ECC_BN_ISOP512 [ISO159465] curve using SHA512 algorithm. 
Algorithm Usage Location(s)  "alg", i.e. used with JWS. 
JOSE Implementation Requirements  Optional 
Change Controller  FIDO Alliance, Contact Us 
Specification Documents  Sections 3. FIDO ECDAA Attestation and 4. FIDO ECDAA Object Formats and Algorithm Details of [FIDOEcdaaAlgorithm]. 
Algorithm Analysis Document(s)  [FIDODAASecurityProof] 
Algorithm Name  "ED638" 
Algorithm Description  ECDAA algorithm based on TPM_ECC_BN_P638 [TPMv2Part4] curve using SHA512 algorithm. 
Algorithm Usage Location(s)  "alg", i.e. used with JWS. 
JOSE Implementation Requirements  Optional 
Change Controller  FIDO Alliance, Contact Us 
Specification Documents  Sections 3. FIDO ECDAA Attestation and 4. FIDO ECDAA Object Formats and Algorithm Details of [FIDOEcdaaAlgorithm]. 
Algorithm Analysis Document(s)  [FIDODAASecurityProof] 