WDIFF

draft-mraihi-oath-hmac-otp-04.txt --> rfc4226.txt

Internet Draft

Network Working Group D. M'Raihi
Request for Comments: 4226 VeriSign
Category: Informational VeriSign
Document: draft-mraihi-oath-hmac-otp-04.txt M. Bellare
Expires: April 2005
UCSD
F. Hoornaert
Vasco
D. Naccache
Gemplus
O. Ranen
Aladdin
October 2004
December 2005

HOTP: An HMAC-based One Time HMAC-Based One-Time Password Algorithm

Status of this This Memo

By submitting this Internet-Draft, each author represents that any
applicable patent or other IPR claims of which he or she is aware
have been or will be disclosed, and any of which he or she becomes
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Copyright (C) The list of Internet-Draft Shadow Directories can be accessed at
http://www.ietf.org/shadow.html Internet Society (2005).

Abstract

This document describes an algorithm to generate one-time password
values, based on HMAC [BCK1]. Hashed Message Authentication Code (HMAC). A
security analysis of the algorithm is presented, and important
parameters related to the secure deployment of the algorithm are
discussed. The proposed algorithm can be used across a wide range of
network applications ranging from remote VPN Virtual Private Network
(VPN) access, Wi-Fi network logon to transaction-oriented Web
applications.

This work is a joint effort by the OATH (Open AuTHentication)
membership to specify an algorithm that can be freely distributed to
the technical community. The authors believe that a common and
shared algorithm will facilitate adoption of two-factor
authentication on the Internet by enabling interoperability across
commercial and open-source implementations.

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RFC 4226 HOTP Algorithm December 2005

Table of Contents

1. Overview...................................................3 Overview ........................................................3
2. Introduction...............................................3 Introduction ....................................................3
3. Requirements Terminology...................................4 Terminology ........................................4
4. Algorithm Requirements.....................................4 Requirements ..........................................4
5. HOTP Algorithm.............................................5
5.1 Algorithm ..................................................5
5.1. Notation and Symbols.......................................5
5.2 Description................................................5
5.3 Symbols .......................................5
5.2. Description ................................................6
5.3. Generating an HOTP value...................................6
5.4 Value ...................................6
5.4. Example of HOTP computation Computation for Digit = 6..................7 6 ..................7
6. Security Considerations....................................7
6.1 Considerations .........................................8
7. Security Requirements ...........................................9
7.1. Authentication Protocol Requirements.......................8
6.2 Requirements .......................9
7.2. Validation of HOTP values..................................8
6.3 Bi-directional Authentication..............................9
6.4 Values .................................10
7.3. Throttling at the server...................................9
6.5 Server ..................................10
7.4. Resynchronization of the counter...........................9
6.6 Counter ..........................11
7.5. Management of Shared Secrets..............................10
7. HOTP Algorithm Security: Overview.........................12 Secrets ..............................11
8. Composite Shared Secrets..................................13 Secrets .......................................14
9. IANA Considerations.......................................13 Bi-Directional Authentication ..................................14
10. Conclusion................................................13 Conclusion ....................................................15
11. Acknowledgements..........................................13 Acknowledgements ..............................................15
12. Contributors..............................................13 Contributors ..................................................15
13. References................................................14
12.1 Normative...............................................14
12.2 Informative.............................................14
14. Authors' Addresses........................................15
15. Full Copyright Statement...................................15
16. Intellectual Property......................................16 References ....................................................15
13.1. Normative References .....................................15
13.2. Informative References ...................................16
Appendix A - HOTP Algorithm Security: Detailed Analysis........16
A.1 Analysis ...........17
A.1. Definitions and Notations..................................16
A.2 Notations .................................17
A.2. The idealized algorithm: HOTP-IDEAL........................17
A.3 Idealized Algorithm: HOTP-IDEAL .......................17
A.3. Model of Security..........................................17
A.4 Security .........................................18
A.4. Security of the ideal authentication algorithm.............19
A.4.1 Ideal Authentication Algorithm ............19
A.4.1. From bits Bits to digits......................................19
A.4.2 Digits ................................19
A.4.2. Brute force attacks......................................20
A.4.3 Force Attacks ................................21
A.4.3. Brute force attacks are the best possible attacks........21
A.5 attacks ..22
A.5. Security Analysis of HOTP..................................22 HOTP .................................23
Appendix B - SHA-1 Attacks.....................................23
B.1 Attacks ........................................25
B.1. SHA-1 status...............................................23
B.2 Status ..............................................25
B.2. HMAC-SHA-1 status..........................................24
B.3 Status .........................................26
B.3. HOTP status................................................25 Status ...............................................26
Appendix C - HOTP Algorithm: Reference Implementation..........25 Implementation .............27
Appendix D - HOTP Algorithm: Test Values.......................29 Values ..........................32
Appendix E - Extensions........................................29
E.1 Extensions ...........................................33
E.1. Number of Digits..........................................30
E.2 Alpha-numeric Values......................................30
E.3 Digits ..........................................33
E.2. Alphanumeric Values .......................................33
E.3. Sequence of HOTP values...................................30
E.4 values ...................................34
E.4. A Counter-based Re-Synchronization Method.................31
E.5 Counter-Based Resynchronization Method ..................34
E.5. Data Field................................................31 Field ................................................35

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1. Overview

The document introduces first the context around an algorithm that
generates one-time password values based on HMAC [BCK1] and, thus, is
named the HOTP HMAC-Based One-Time Password (HOTP) algorithm. In section Section
4, the algorithm requirements are listed and in section Section 5, the HOTP
algorithm is described. Sections 6 and 7 focus on the algorithm
security. Section 8 proposes some extensions and improvements, and
Section 9 10 concludes this document. The In Appendix A, the interested
reader will find in the Appendix a detailed, full-fledge full-fledged analysis of the algorithm
security: an idealized version of the algorithm is evaluated, and
then the HOTP algorithm security is analyzed.

2. Introduction

Today, deployment of two-factor authentication remains extremely
limited in scope and scale. Despite increasingly higher levels of
threats and attacks, most Internet applications still rely on weak
authentication schemes for policing user access. The lack of
interoperability among hardware and software technology vendors has
been a limiting factor in the adoption of two-factor authentication
technology. In particular, the absence of open specifications has
led to solutions where hardware and software components are tightly
coupled through proprietary technology, resulting in high cost high-cost
solutions, poor adoption adoption, and limited innovation.

In the last two years, the rapid rise of network threats has exposed
the inadequacies of static passwords as the primary mean of
authentication on the Internet. At the same time, the current
approach that requires an end-user end user to carry an expensive,
single-function single-
function device that is only used to authenticate to the network is
clearly not the right answer. For two factor two-factor authentication to
propagate on the Internet, it will have to be embedded in more
flexible devices that can work across a wide range of applications.

The ability to embed this base technology while ensuring broad
interoperability require requires that it be made freely available to the
broad technical community of hardware and software developers. Only
an open system open-system approach will ensure that basic two-factor
authentication primitives can be built into the next-generation next generation of
consumer devices such as USB mass storage devices, IP phones, and
personal digital assistants).

One Time assistants.

One-Time Password is certainly one of the simplest and most popular
forms of two-factor authentication for securing network access. For
example, in large enterprises, Virtual Private Network access often
requires the use of One Time One-Time Password tokens for remote user
authentication. One Time One-Time Passwords are often preferred to stronger

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forms of authentication such as PKI Public-Key Infrastructure (PKI) or
biometrics because an air-gap device does not require the
installation of any client desktop software on the user machine,
therefore allowing them to roam across multiple machines including
home computers, kiosks kiosks, and personal digital assistants.

This draft document proposes a simple One Time One-Time Password algorithm that can
be implemented by any hardware manufacturer or software developer to
create interoperable authentication devices and software agents. The
algorithm is event-based so that it can be embedded in high
volume high-volume
devices such as Java smart cards, USB dongles dongles, and GSM SIM cards.
The presented algorithm is made freely available to the developer
community under the terms and conditions of the IETF Intellectual
Property Rights [RFC3668]. [RFC3979].

The authors of this document are members of the Open AuTHentication
initiative [OATH]. The initiative was created in 2004 to facilitate
collaboration among strong authentication technology providers.

3. 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 RFC 2119. [RFC2119].

4. Algorithm Requirements

This section presents the main requirements that drove this algorithm
design. A lot of emphasis was placed on end-consumer usability as
well as the ability for the algorithm to be implemented by low cost low-cost
hardware that may provide minimal user interface capabilities. In
particular, the ability to embed the algorithm into high volume high-volume SIM
and Java cards was a fundamental
pre-requisite. prerequisite.

R1 - The algorithm MUST be sequence sequence- or counter-based: One one of the
goals is to have the HOTP algorithm embedded in high volume high-volume devices
such as Java smart cards, USB dongles dongles, and GSM SIM cards.

R2 - The algorithm SHOULD be economical to implement in hardware by
minimizing requirements on battery, number of buttons, computational
horsepower, and size of LCD display.

R3 - The algorithm MUST work with tokens that do not supports support any
numeric input, but MAY also be used with more sophisticated devices
such as secure PIN-pads.

R4 - The value displayed on the token MUST be easily read and entered
by the user: This requires the HOTP value to be of reasonable length.

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The HOTP value must be at least a 6-digit value. It is also
desirable that the HOTP value be 'numeric only' so that it can be
easily entered on restricted devices such as phones.

R5 - There MUST be user-friendly mechanisms available to
resynchronize the counter. The sections 6.4 Section 7.4 and 8.4 detail Appendix E.4 details the
resynchronization mechanism proposed in this draft. document

R6 - The algorithm MUST use a strong shared secret. The length of
the shared secret MUST be at least 128 bits. This draft document
RECOMMENDs a shared secret length of 160 bits.

5. HOTP Algorithm

In this section, we introduce the notation and describe the HOTP
algorithm basic blocks - -- the base function to compute an HMAC-SHA-1
value and the truncation method to extract an HOTP value.

5.1

5.1. Notation and Symbols

A string always means a binary string, meaning a sequence of zeros
and ones.

If s is a string string, then |s| denotes its length.

If n is a number number, then |n| denotes its absolute value.

If s is a string string, then s[i] denotes its i-th bit. We start numbering
the bits at 0, so s = s[0]s[1]..s[n-1] s[0]s[1]...s[n-1] where n = |s| is the length
of s.

Let StToNum (String to Number) denote the function which that as input a
string s returns the number whose binary representation is s. (For example
example, StToNum(110) = 6). 6.)

Here is a list of symbols used in this document.

Symbol Represents
-------------------------------------------------------------------
C 8-byte counter value, the moving factor. This counter
MUST be synchronized between the HOTP generator (client)
and the HOTP validator (server); (server).

K shared secret between client and server; each HOTP
generator has a different and unique secret K; K.

T throttling parameter: the server will refuse connections
from a user after T unsuccessful authentication attempts; attempts.

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s resynchronization parameter: the server will attempt to
verify a received authenticator across s consecutive
counter values; values.

Digit number of digits in an HOTP value; system parameter.

5.2

5.2. Description

The HOTP algorithm is based on an increasing counter value and a
static symmetric key known only to the token and the validation
service. In order to create the HOTP value, we will use the

HMAC-SHA-1 HMAC-
SHA-1 algorithm, as defined in RFC 2104 [BCK2].

As the output of the HMAC-SHA1 HMAC-SHA-1 calculation is 160 bits, we must
truncate this value to something that can be easily entered by a
user.

HOTP(K,C) = Truncate(HMAC-SHA-1(K,C))

Where:

- Truncate represents the function that converts an HMAC-SHA-1
value into an HOTP value as defined in Section 5.3.

The Key (K), the Counter (C) (C), and Data values are hashed high-order
byte first.

The HOTP values generated by the HOTP generator are treated as big
endian.

5.3

5.3. Generating an HOTP value Value

We can describe the operations in 3 distinct steps:

Step 1: Generate an HMAC-SHA-1 value Let HS = HMAC-SHA-1(K,C) // HS
is a 20 byte 20-byte string

Step 2: Generate a 4-byte string (Dynamic Truncation)
Let Sbits = DT(HS) // DT, defined in Section 6.3.1 below,
// returns a 31 bit 31-bit string

Step 3: Compute an HOTP value
Let Snum = StToNum(S) StToNum(Sbits) // Convert S to a number in
0...2^{31}-1
Return D = Snum mod 10^Digit // D is a number in the range
0...10^{Digit}-1

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The Truncate function performs Step 2 and Step 3, i.e. i.e., the dynamic
truncation and then the reduction modulo 10^Digit. The purpose of
the dynamic offset truncation technique is to extract a 4-byte
dynamic binary code from a 160-bit (20-byte) HMAC-SHA1 HMAC-SHA-1 result.

DT(String) // String = String[0]...String[19]
Let OffsetBits be the low order four low-order 4 bits of String[19]
Offset = StToNum(OffSetBits) StToNum(OffsetBits) // 0 <= OffSet <= 15
Let P = String[OffSet]...String[OffSet+3]
Return the Last 31 bits of P

The reason for masking the most significant bit of P is to avoid
confusion about signed vs. unsigned modulo computations. Different
processors perform these operations differently, and masking out the
signed bit removes all ambiguity.

Implementations MUST extract a 6-digit code at a minimum and possibly
7 and 8-digit code. Depending on security requirements, Digit = 7 or
more SHOULD be considered in order to extract a longer HOTP value.

The following paragraph is an example of using this technique for
Digit = 6, i.e. i.e., that a 6-digit HOTP value is calculated from the
HMAC value.

5.4

5.4. Example of HOTP computation Computation for Digit = 6

The following code example describes the extraction of a dynamic
binary code given that hmac_result is a byte array with the
HMAC-SHA1 HMAC-
SHA-1 result:

int offset = hmac_result[19] & 0xf ;
int bin_code = (hmac_result[offset] & 0x7f) << 24
| (hmac_result[offset+1] & 0xff) << 16
| (hmac_result[offset+2] & 0xff) << 8
| (hmac_result[offset+3] & 0xff) ;

SHA-1 HMAC Bytes (Example)

-------------------------------------------------------------
| Byte Number |
-------------------------------------------------------------
|00|01|02|03|04|05|06|07|08|09|10|11|12|13|14|15|16|17|18|19|
-------------------------------------------------------------
| Byte Value |
-------------------------------------------------------------
|1f|86|98|69|0e|02|ca|16|61|85|50|ef|7f|19|da|8e|94|5b|55|5a|
-------------------------------***********----------------++|

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* The last byte (byte 19) has the hex value 0x5a.
* The value of the lower four 4 bits is 0xa (the offset value).
* The offset value is byte 10 (0xa).
* The value of the 4 bytes starting at byte 10 is 0x50ef7f19,
which is the dynamic binary code DBC1 DBC1.
* The MSB of DBC1 is 0x50 so DBC2 = DBC1 = 0x50ef7f19 .
* HOTP = DBC2 modulo 10^6 = 872921.

We treat the dynamic binary code as a 31-bit, unsigned, big-endian
integer; the first byte is masked with a 0x7f.

We then take this number modulo 1,000,000 (10^6) to generate the
6-digit 6-
digit HOTP value 872921 decimal.

6. Security Considerations

Any One-Time Password algorithm is only as secure as

The conclusion of the
application and security analysis detailed in the authentication protocols that implement it.

Therefore, this section discusses Appendix is
that, for all practical purposes, the critical security
requirements that our choice outputs of algorithm imposes on the
authentication protocol Dynamic
Truncation (DT) on distinct counter inputs are uniformly and validation software.
independently distributed 31-bit strings.

The parameters T and s discussed in this section have a significant
impact on the security - further analysis then details in Section 7 elaborate on the relations between these parameters and their impact on of the
system security.

It is also important conversion from
a string to remark that an integer and the HOTP algorithm final reduction modulo 10^Digit, where
Digit is not the number of digits in an HOTP value.

The analysis demonstrates that these final steps introduce a
substitute for encryption and
negligible bias, which does not provide for impact the privacy security of
data transmission. Other mechanisms should be used to defeat

6.1 Authentication Protocol Requirements

We introduce the HOTP
algorithm, in this section some requirements for a protocol P
implementing the sense that the best possible attack against the
HOTP as function is the brute force attack.

Assuming an adversary is able to observe numerous protocol exchanges
and collect sequences of successful authentication method between values. This
adversary, trying to build a prover and function F to generate HOTP values based
on his observations, will not have a verifier.

RP1 - P MUST be two-factor, i.e. something you know (secret code
such as significant advantage over a Password, Pass phrase, PIN code, etc.) and something you
have (token).
random guess.

The secret code logical conclusion is known only to the user and usually
entered with simply that the one-time password value for authentication purpose
(two-factor authentication).

RP2 - P SHOULD NOT best strategy will once
again be vulnerable to perform a brute force attacks. This
implies that a throttling/lockout scheme is RECOMMENDED on the
validation server side.

RP3 - P SHOULD be implemented with respect attack to enumerate and try all the state of
possible values.

Considering the art
in terms of security, security analysis in order to avoid the usual attacks and risks
associated with the transmission Appendix of sensitive data over a public
network (privacy, replay attacks, etc.)

6.2 Validation this document,
without loss of HOTP values

The HOTP client (hardware or software token) increments its counter
and then calculates the next HOTP value HOTP-client. If the value
received by generality, we can approximate closely the authentication server matches security
of the value calculated HOTP algorithm by the client, then the following formula:

Sec = sv/10^Digit

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Where:
- Sec is validated. In this case, the
server increments probability of success of the counter value by one.

If the value received by the server does not match the value
calculated by the client, the server initiate the resynch protocol
(look-ahead window) before it requests another pass.

If adversary;
- s is the resynch fails, look-ahead synchronization window size;
- v is the server asks then for another
authentication pass number of verification attempts;
- Digit is the protocol to take place, until the
maximum number of authorized attempts is reached.

If and when digits in HOTP values.

Obviously, we can play with s, T (the Throttling parameter that would
limit the maximum number of authorized attempts is reached,
the server SHOULD lock out the account by an attacker), and initiate Digit until
achieving a procedure to
inform certain level of security, still preserving the user.

6.3 Bi-directional Authentication

Interestingly enough, system
usability.

7. Security Requirements

Any One-Time Password algorithm is only as secure as the HOTP client could also be used to
authenticate application
and the validation server, claiming authentication protocols that it is a genuine
entity knowing implement it. Therefore, this
section discusses the shared secret.

Since critical security requirements that our choice
of algorithm imposes on the HOTP client authentication protocol and the server are synchronized validation
software.

The parameters T and share the
same secret (or a method to recompute it) s discussed in this section have a simple 3-pass protocol
could be put significant
impact on the security -- further details in place:
1- The end user enter Section 6 elaborate on
the TokenID relations between these parameters and their impact on the system
security.

It is also important to remark that the HOTP algorithm is not a first OTP value OTP1;
2- The server checks OTP1 and if correct, sends back OTP2;
3- The end user checks OTP2 using his HOTP device
substitute for encryption and if correct,
uses does not provide for the web site.

Obviously, privacy of
data transmission. Other mechanisms should be used to defeat attacks
aimed at breaking confidentiality and privacy of transactions.

7.1. Authentication Protocol Requirements

We introduce in this section some requirements for a protocol P
implementing HOTP as indicated previously, all the OTP communications authentication method between a prover and a
verifier.

RP1 - P MUST support two-factor authentication, i.e., the
communication and verification of something you know (secret code
such as a Password, Pass phrase, PIN code, etc.) and something you
have (token). The secret code is known only to take place over secure https (SSL) connections.

6.4 Throttling at the server

Truncating user and usually
entered with the HMAC-SHA1 value to a shorter One-Time Password value makes a brute
force attack possible. Therefore, the for authentication server needs purpose
(two-factor authentication).

RP2 - P SHOULD NOT be vulnerable to detect and stop brute force attacks.

We RECOMMEND setting This
implies that a throttling parameter T, which defines throttling/lockout scheme is RECOMMENDED on the
maximum number of possible attempts for One-Time-Password
validation. The
validation server manages individual counters per
HOTP device side.

RP3 - P SHOULD be implemented over a secure channel in order to take note
protect users' privacy and avoid replay attacks.

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7.2. Validation of any failed attempt. We
RECOMMEND T not to be too large, particularly if HOTP Values

The HOTP client (hardware or software token) increments its counter
and then calculates the
resynchronization method used on next HOTP value HOTP client. If the value
received by the authentication server is window-based, and matches the window size is large. value calculated by
the client, then the HOTP value is validated. In this case, the
server increments the counter value by one.

If the value received by the server does not match the value
calculated by the client, the server initiate the resynch protocol
(look-ahead window) before it requests another pass.

If the resynch fails, the server asks then for another
authentication pass of the protocol to take place, until the
maximum number of authorized attempts is reached.

If and when the maximum number of authorized attempts is reached, the
server SHOULD lock out the account and initiate a procedure to inform
the user.

7.3. Throttling at the Server

Truncating the HMAC-SHA-1 value to a shorter value makes a brute
force attack possible. Therefore, the authentication server needs to
detect and stop brute force attacks.

We RECOMMEND setting a throttling parameter T, which defines the
maximum number of possible attempts for One-Time Password validation.
The validation server manages individual counters per HOTP device in
order to take note of any failed attempt. We RECOMMEND T not to be
too large, particularly if the resynchronization method used on the
server is window-based, and the window size is large. T SHOULD be
set as low as possible, while still ensuring that usability is not
significantly impacted.

Another option would be to implement a delay scheme to avoid a brute
force attack. After each failed attempt A, the authentication server
would wait for an increased T*A number of seconds, e.g. e.g., say T = 5,
then after 1 attempt, the server waits for 5 seconds, at the second
failed attempt, it waits for 5*2 = 10 seconds, etc.

The delay or lockout schemes MUST be across login sessions to prevent
attacks based on multiple parallel guessing techniques.

6.5

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7.4. Resynchronization of the counter Counter

Although the server's counter value is only incremented after a
successful HOTP authentication, the counter on the token is
incremented every time a new HOTP is requested by the user. Because
of this, the counter values on the server and on the token might be
out of synchronization.

We RECOMMEND setting a look-ahead parameter s on the server, which
defines the size of the look-ahead window. In a nutshell, the server
can recalculate the next s HOTP-server values, and check them against
the received HOTP-client. HOTP client.

Synchronization of counters in this scenario simply requires the
server to calculate the next HOTP values and determine if there is a
match. Optionally, the system MAY require the user to send a
sequence of (say (say, 2, 3) HOTP values for resynchronization purpose,
since forging a sequence of consecutive HOTP values is even more
difficult than guessing a single HOTP value.

The upper bound set by the parameter s ensures the server does not go
on checking HOTP values forever (causing a DoS denial-of-service attack)
and also restricts the space of possible solutions for an attacker
trying to manufacture HOTP values. s SHOULD be set as low as
possible, while still ensuring that usability is not impacted.

6.6

7.5. Management of Shared Secrets

The operations dealing with the shared secrets used to generate and
verify OTP values must be performed securely, in order to mitigate
risks of any leakage of sensitive information. We describe in this
section different modes of operations and techniquest techniques to perform these
different operations with respect of to the state of the art in
terms of data
security.

We can consider two different avenues for generating and storing
(securely) shared secrets in the Validation system:

* Deterministic Generation: secrets are derived from a master
seed, both at provisioning and verification stages and generated
on-the-fly whenever it is required; required.
* Random Generation: secrets are generated randomly at
provisioning stage, stage and must be stored immediately and kept
secure during their life cycle.

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Deterministic Generation
------------------------

A possible strategy is to derive the shared secrets from a master
secret. The master secret will be stored at the server only. A
tamper resistant
tamper-resistant device MUST be used to store the master key and
derive the shared secrets from the master key and some public
information. The main benefit would be to avoid the exposure of the
shared secrets at any time and also avoid specific requirements on
storage, since the shared secrets could be generated on-demand when
needed at provisioning and validation time.

We distinguish two different cases:

- A single master key MK is used to derive the shared secrets;
each HOTP device has a different secret, K_i = SHA-1 (MK,i)
where i stands for a public piece of information that identifies
uniquely the HOTP device such as a serial number, a token ID, etc.; obviously,
etc. Obviously, this is in the context of an application or
service - -- different application or service providers will have
different secrets and settings; settings.
- Several master keys MK_i are used and each HOTP device stores a
set of different derived secrets, {K_i,j = SHA-1(MK_i,j)} where
j stands for a public piece of information identifying the
device. The idea would be to store ONLY the active master key
at the validation server, in the HSM, Hardware Security Module (HSM),
and keep in a safe place, using secret sharing methods such as
[Shamir] for instance. In this case, if a master secret MK_i is
compromised, then it is possible to switch to another secret
without replacing all the devices.

The drawback in the deterministic case is that the exposure of the
master secret would obviously enable an attacker to rebuild any
shared secret based on correct public information. The revocation of
all secrets would be required, or switching to a new set of secrets
in the case of multiple master keys.

On the other hand, the device used to store the master key(s) and
generate the shared secrets MUST be tamper resistant. Furthermore,
the HSM will not be exposed outside the security perimeter of the
validation system, therefore reducing the risk of leakage.

M'Raihi, et al. Informational [Page 12]

RFC 4226 HOTP Algorithm December 2005

Random Generation
-----------------

The shared secrets are randomly generated. We RECOMMEND to follow following
the recommendations in [RFC1750] [RFC4086] and to select selecting a good and secure
random source for generating these secrets. A (true) random
generator requires a naturally occurring source of randomness.
Practically, there are two possible avenues to consider for the
generation of the shared secrets:

* Hardware-based generators: they exploit the randomness which that
occurs in physical phenomena. A nice implementation can be based on
oscillators,
oscillators and built in such ways that active attacks are more
difficult to perform.

* Software-based generators: designing a good software random
generator is not an easy task. A simple, but efficient,
implementation should be based on various sources, sources and apply to the
sampled sequence a one-way function such as SHA-1.

We RECOMMEND to select selecting proven products, being hardware or software
generators
generators, for the computation of shared secrets.

We also RECOMMEND storing the shared secrets securely, and more
specifically encrypting the shared secrets when stored using
tamper-resistant tamper-
resistant hardware encryption, encryption and exposing them only when required: e.g.
for example, the shared secret is decrypted when needed to verify an
HOTP value, and re-encrypted immediately to limit exposure in the RAM
for a short period of time. The data store holding the shared
secrets MUST be in a secure area, to avoid as much as possible direct
attack on the validation system and secrets database.

Particularly, access to the shared secrets should be limited to
programs and processes required by the validation system only. We
will not elaborate on the different security mechanisms to put in
place, but obviously, the protection of shared secrets is of the
uttermost importance.

M'Raihi, et al. Informational [Page 13]

RFC 4226 HOTP Algorithm Security: Overview

The conclusion of the security analysis detailed in the Appendix
section is that, for all practical purposes, December 2005

8. Composite Shared Secrets

It may be desirable to include additional authentication factors in
the outputs shared secret K. These additional factors can consist of any
data known at the
dynamic truncation (DT) on distinct counter inputs are uniformly
and independently distributed 31-bit strings.

The security analysis then details the impact token but not easily obtained by others. Examples
of such data include:

* PIN or Password obtained as user input at the conversion
from a string to an integer and token
* Phone number
* Any unique identifier programmatically available at the final reduction modulo
10^Digit, where Digit token

In this scenario, the composite shared secret K is constructed during
the number of digits provisioning process from a random seed value combined with one
or more additional authentication factors. The server could either
build on-demand or store composite secrets -- in an HOTP any case, depending
on implementation choice, the token only stores the seed value. When
the token performs the HOTP calculation, it computes K from the seed
value and the locally derived or input values of the other
authentication factors.

The analysis demonstrates that these final steps introduce a
negligible bias, which does not impact use of composite shared secrets can strengthen HOTP-based
authentication systems through the security inclusion of additional
authentication factors at the HOTP
algorithm, in token. To the sense extent that the best possible attack against the
HOTP function token is
a trusted device, this approach has the brute force attack.

Assuming an adversary is able to observe numerous protocol
exchanges and collect sequences further benefit of successful not
requiring exposure of the authentication
values. This adversary, trying factors (such as the user
input PIN) to build a function F other devices.

9. Bi-Directional Authentication

Interestingly enough, the HOTP client could also be used to generate
authenticate the validation server, claiming that it is a genuine
entity knowing the shared secret.

Since the HOTP values based on his observations, will not have client and the server are synchronized and share the
same secret (or a significant
advantage over method to recompute it), a random guess.

The logical conclusion is simply that is best strategy will once
again simple 3-pass protocol
could be to perform put in place:
1- The end user enter the TokenID and a brute force attack to enumerate first OTP value OTP1;
2- The server checks OTP1 and try all if correct, sends back OTP2;
3- The end user checks OTP2 using his HOTP device and if correct,
uses the possible values.

Considering web site.

Obviously, as indicated previously, all the security analysis in OTP communications have
to take place over a secure channel, e.g., SSL/TLS, IPsec
connections.

M'Raihi, et al. Informational [Page 14]

RFC 4226 HOTP Algorithm December 2005

10. Conclusion

This document describes HOTP, a HMAC-based One-Time Password
algorithm. It also recommends the Appendix section of this
document, without loss preferred implementation and
related modes of generality, we can approximate closely operations for deploying the security algorithm.

The document also exhibits elements of security and demonstrates that
the HOTP algorithm by the following formula:

Sec = sv/10^Digit

Where:
- Sec is practical and sound, the probability of success best possible attack
being a brute force attack that can be prevented by careful
implementation of countermeasures in the adversary
- s stands for the look-ahead synchronization window size;
- v stands for the number of verification attempts;
- Digit stands for the number of digits validation server.

Eventually, several enhancements have been proposed, in HOTP values.

Obviously, we can play with s, T (the Throttling parameter that order to
improve security if needed for specific applications.

11. Acknowledgements

The authors would limit like to thank Siddharth Bajaj, Alex Deacon, Loren
Hart, and Nico Popp for their help during the number of attempts by an attacker) conception and Digit until
achieving a certain level
redaction of security, still preserving the system
usability.

8. Composite Shared Secrets

It may be desirable to include additional authentication factors in
the shared secret K. These additional factors can consist this document.

12. Contributors

The authors of any
data known at this document would like to emphasize the token but not easily obtained by others. Examples role of such data include:
* PIN or Password obtained as user input at the token
* Phone number
* Any unique identifier programmatically available at the token

In
three persons who have made a key contribution to this scenario the composite shared secret K document:

- Laszlo Elteto is constructed
during the provisioning process from a random seed value combined system architect with one or more additional authentication factors. The server
could either build on-demand or store composite secrets SafeNet, Inc.

- in any
case, depending on implementation choice, the token only stores the
seed value. When the token performs the HOTP calculation it
computes K from the seed value and the locally derived or input
values of the other authentication factors.

The use of composite shared secrets can strengthen HOTP based
authentication systems through the inclusion of additional
authentication factors at the token. To the extent that the token
is a trusted device this approach has the further benefit of not
requiring exposure of the authentication factors (such as the user
input PIN) to other devices.

9. IANA Considerations

This document has no actions for IANA.

10. Conclusion

This draft describes HOTP, a HMAC-based One-Time Password
algorithm. It also recommends the preferred implementation and
related modes of operations for deploying the algorithm.

The draft also exhibits elements of security and demonstrates that
the HOTP algorithm is practical and sound, the best possible attack
being a brute force attack that can be prevented by careful
implementation of countermeasures in the validation server.

Eventually, several enhancements have been proposed, in order to
improve security if needed for specific applications.

11. Acknowledgements

The authors would like to thank Siddharth Bajaj, Alex Deacon, Loren
Hart and Nico Popp for their help during the conception and
redaction of this document.

12. Contributors

The authors of this draft would like to emphasize the role of three
persons who have made a key contribution to this document:

- Laszlo Elteto is system architect with SafeNet, Inc.

- Ernesto Frutos is director Ernesto Frutos is director of Engineering with Authenex, Inc.

- Fred McClain is Founder and CTO with Boojum Mobile, Inc.

Without their advice and valuable inputs, this draft would not be
the same.

13. References

12.1 Normative

[BCK1] M. Bellare, R. Canetti and H. Krawczyk, "Keyed Hash
Functions and Message Authentication", Proceedings of
Crypto'96, LNCS Vol. 1109, pp. 1-15.

[BCK2] M. Bellare, R. Canetti and H. Krawczyk, "HMAC:
Keyed-Hashing for Message Authentication", IETF Network
Working Group, RFC 2104, February 1997.

[RFC1750] D. Eastlake, 3rd., S. Crocker and J. Schiller,
"Randomness Recommendantions for Security", IETF
Network Working Group, RFC 1750, December 2004.

[RFC2119] S. Bradner, "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.

[RFC3668] S. Bradner, "Intellectual Propery Rights in IETF
Technology", BCP 79, RFC 3668, February 2004.

12.2 Informative

[OATH] Initiative for Open AuTHentication
http://www.openauthentication.org

[PrOo] B. Preneel and P. van Oorschot, "MD-x MAC and building
fast MACs from hash functions", Advances in Cryptology
CRYPTO '95, Lecture Notes in Computer Science Vol. 963,
D. Coppersmith ed., Springer-Verlag, 1995.

[Crack] Crack in SHA-1 code 'stuns' security gurus
http://www.eetimes.com/showArticle.jhtml?articleID=60402150

[Sha1] Bruce Schneier. SHA-1 broken. February 15, 2005.
http://www.schneier.com/blog/archives/2005/02/sha1_broken.html

[Res] Researchers: Digital encryption standard flawed
http://news.com.com/Researchers+Digital+encryption+standard+flawed/
2100-1002-5579881.html?part=dht&tag=ntop&tag=nl.e703

[Shamir] How to Share a Secret, by Adi Shamir. In Communications
of the ACM, Vol. 22, No. 11, pp. 612-613, November, 1979.

14. Authors' Addresses

Primary point of contact (for sending comments and question):

David M'Raihi
VeriSign, Inc.
685 E. Middlefield Road Phone: 1-650-426-3832
Mountain View, CA 94043 USA Email: dmraihi@verisign.com

Other Authors' contact information:

Mihir Bellare
Dept of Computer Science and Engineering, Mail Code 0114
University of California at San Diego
9500 Gilman Drive
La Jolla, CA 92093, USA Email: mihir@cs.ucsd.edu

Frank Hoornaert
VASCO Data Security, Inc.
Koningin Astridlaan 164
1780 Wemmel, Belgium Email: frh@vasco.com

David Naccache
Gemplus Innovation
34 rue Guynemer, 92447,
Issy les Moulineaux, France Email: david.naccache@gemplus.com
and
Information Security Group,
Royal Holloway,
University of London, Egham,
Surrey TW20 0EX, UK Email: david.naccache@rhul.ac.uk

Ohad Ranen
Aladdin Knowledge Systems Ltd.
15 Beit Oved Street
Tel Aviv, Israel 61110 Email: Ohad.Ranen@ealaddin.com

15. Full Copyright Statement

This document is subject to the rights, licenses and restrictions
contained in BCP 78, and except as set forth therein, the authors
retain all their rights.

This document and the information contained herein are provided on
an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE
REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND
THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES,
EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT
THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR
ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A
PARTICULAR PURPOSE.

16. Intellectual Property

The IETF takes no position regarding the validity or scope of any
Intellectual Property Rights or other rights that might be claimed
to pertain to the implementation or use of the technology described
in their advice and valuable inputs, this document or the extent to which any license under such
rights might or might would not be available; nor does it represent that
it has made any independent effort to identify any such rights.
Information on
the procedures with respect to rights same.

13. References

13.1. Normative References

[BCK1] M. Bellare, R. Canetti and H. Krawczyk, "Keyed Hash
Functions and Message Authentication", Proceedings of
Crypto'96, LNCS Vol. 1109, pp. 1-15.

[BCK2] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
Hashing for Message Authentication", RFC 2104, February
1997.

[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC
documents can be found 2119, March 1997.

M'Raihi, et al. Informational [Page 15]

RFC 4226 HOTP Algorithm December 2005

[RFC3979] Bradner, S., "Intellectual Property Rights in IETF
Technology", BCP 78 79, RFC 3979, March 2005.

[RFC4086] Eastlake, D., 3rd, Schiller, J., and S. Crocker,
"Randomness Requirements for Security", BCP 79.

Copies of IPR disclosures made to the IETF Secretariat and any
assurances of licenses to be made available, or the result of an
attempt made to obtain a general license or permission 106, RFC 4086,
June 2005.

13.2. Informative References

[OATH] Initiative for the use
of such proprietary rights by implementers or users of this
specification can be obtained Open AuTHentication
http://www.openauthentication.org

[PrOo] B. Preneel and P. van Oorschot, "MD-x MAC and building
fast MACs from the IETF on-line IPR repository
at http://www.ietf.org/ipr.

The IETF invites any interested party to bring to its attention any
copyrights, patents or patent applications, or other proprietary
rights that may cover technology that may be required to implement
this standard. Please address the information hash functions", Advances in Cryptology
CRYPTO '95, Lecture Notes in Computer Science Vol. 963, D.
Coppersmith ed., Springer-Verlag, 1995.

[Crack] Crack in SHA-1 code 'stuns' security gurus
http://www.eetimes.com/showArticle.jhtml?
articleID=60402150

[Sha1] Bruce Schneier. SHA-1 broken. February 15, 2005.
http://www.schneier.com/blog/archives/2005/02/
sha1_broken.html

[Res] Researchers: Digital encryption standard flawed
http://news.com.com/
Researchers+Digital+encryption+standard+flawed/
2100-1002-5579881.html?part=dht&tag=ntop&tag=nl.e703

[Shamir] How to Share a Secret, by Adi Shamir. In Communications
of the IETF at ietf-
ipr@ietf.org. ACM, Vol. 22, No. 11, pp. 612-613, November, 1979.

M'Raihi, et al. Informational [Page 16]

RFC 4226 HOTP Algorithm December 2005

Appendix A - HOTP Algorithm Security: Detailed Analysis

The security analysis of the HOTP algorithm is summarized in this
section. We first detail the best attack strategies, and then
elaborate on the security under various assumptions, assumptions and the impact of
the truncation and make some recommendations regarding the number of
digits.

We focus this analysis on the case where Digit = 6, i.e. i.e., an HOTP
function that produces 6-digit values, which is the bare minimum
recommended in this draft.

A.1 document.

A.1. Definitions and Notations

We denote by {0,1}^l the set of all strings of length l.

Let Z_{n} = {0,.., n - 1}.

Let IntDiv(a,b) denote the integer division algorithm that takes
input integers a, b where a >= b >= 1 and returns integers (q,r)

the quotient and remainder, respectively, of the division of a by b. (Thus
(Thus, a = bq + r and 0 <= r < b.)

Let H: {0,1}^k x {0,1}^c --> {0,1}^n be the base function that takes
a k-bit key K and c-bit counter C and returns an n-bit output H(K,C).
(In the case of HOTP, H is HMAC-SHA-1; we use this formal definition
for generalizing our proof of security)

A.2 security.)

A.2. The idealized algorithm: Idealized Algorithm: HOTP-IDEAL

We now define an idealized counterpart of the HOTP algorithm. In
this algorithm, the role of H is played by a random function that
forms the key.

To be more precise, let Maps(c,n) denote the set of all functions
mapping from {0,1}^c to {0,1}^n. The idealized algorithm has key
space Maps(c,n), so that a "key" for such an algorithm is a function
h from {0,1}^c to {0,1}^n. We imagine this key (function) to be
drawn at random. It is not feasible to implement this idealized
algorithm, since the key, being a function from {0,1}^c to {0,1}^n,
is way too large to even store. So why consider it?

Our security analysis will show that as long as H satisfies a certain
well-accepted assumption, the security of the actual and idealized
algorithms is for all practical purposes the same. The task that
really faces us, then, is to assess the security of the idealized
algorithm.

M'Raihi, et al. Informational [Page 17]

RFC 4226 HOTP Algorithm December 2005

In analyzing the idealized algorithm, we are concentrating on
assessing the quality of the design of the algorithm itself,
independently of HMAC-SHA-1. This is in fact the important issue.

A.3

A.3. Model of Security

The model exhibits the type of threats or attacks that are being
considered and enables one to asses assess the security of HOTP and
HOTP-IDEAL. HOTP-
IDEAL. We denote ALG as either HOTP or HOTP-IDEAL for the purpose of
this security analysis.

The scenario we are considering is that a user and server share a key
K for ALG. Both maintain a counter C, initially zero, and the user
authenticates itself by sending ALG(K,C) to the server. The latter
accepts if this value is correct.

In order to protect against accidental increment of the user counter,
the server, upon receiving a value z, will accept as long as z equals
ALG(K,i) for some i in the range C,...,C + s-1, where s is the
resynchronization parameter and C is the server counter. If it
accepts with some value of i, it then increments its counter to
i+ 1. i+1.
If it does not accept, it does not change its counter value.

The model we specify captures what an adversary can do and what it
needs to achieve in order to "win." "win". First, the adversary is assumed
to be able to eavesdrop, meaning meaning, to see the authenticator
transmitted by the user. Second, the adversary wins if it can get
the server to accept an authenticator relative to a counter value for
which the user has never transmitted an authenticator.

The formal adversary, which we denote by B, starts out knowing which
algorithm ALG is being used, knowing the system design design, and knowing
all system parameters. The one and only thing it is not given a
priori is the key K shared between the user and the server.

The model gives B full control of the scheduling of events. It has
access to an authenticator oracle representing the user. By calling
this oracle, the adversary can ask the user to authenticate itself
and get back the authenticator in return. It can call this oracle as
often as it wants and when it wants, using the authenticators it
accumulates to perhaps "learn" how to make authenticators itself. At
any time, it may also call a verification oracle, supplying the
latter with a candidate authenticator of its choice. It wins if the
server accepts this accumulator.

Consider the following game involving an adversary B that is
attempting to compromise the security of an authentication algorithm
ALG: K x {0,1}^c --> R.

M'Raihi, et al. Informational [Page 18]

RFC 4226 HOTP Algorithm December 2005

Initializations - A key K is selected at random from K, a counter C
is initialized to 0, and the Boolean value win is set to false.

Game execution - Adversary B is provided with the two following
oracles:

Oracle AuthO()
--------------
A = ALG(K,C)
C = C + 1
Return O to B

Oracle VerO(A)
--------------
i = C
While (i <= C + s - 1 and Win == FALSE) do
If A == ALG(K,i) then Win = TRUE; C = i + 1
Else i = i + 1
Return Win to B

AuthO() is the authenticator oracle and VerO(A) is the verification
oracle.

Upon execution, B queries the two oracles at will. Let Adv(B) be the
probability that win gets set to true in the above game. This is the
probability that the adversary successfully impersonates the user.

Our goal is to assess how large this value can be as a function of
the number v of verification queries made by B, the number a of
authenticator oracle queries made by B, and the running time t of B.
This will tell us how to set the throttle, which effectively upper
bounds v.

A.4

A.4. Security of the ideal authentication algorithm Ideal Authentication Algorithm

This section summarizes the security analysis of HOTP-IDEAL, starting
with the impact of the conversion modulo 10^Digit and
then, then focusing
on the different possible attacks.

A.4.1

A.4.1. From bits Bits to digits Digits

The dynamic offset truncation of a random n-bit string yields a
random 31-bit string. What happens to the distribution when it is
taken modulo m = 10^Digit, as done in HOTP?

M'Raihi, et al. Informational [Page 19]

RFC 4226 HOTP Algorithm December 2005

The following lemma estimates the biases in the outputs in this case.

Lemma 1
-------
Let N >= m >= 1 be integers, and let (q,r) = IntDiv(N,m). For z in
Z_{m} let:

P_{N,m}(z) = Pr [x mod m = z : x randomly pick in Z_{n}]

Then for any z in Z_{m}

P_{N,m}(z) = (q + 1) / N if 0 <= z < r
q / N if r <= z < m

Proof of Lemma 1
----------------
Let the random variable X be uniformly distributed over Z_{N}. Then:

P_{N,m}(z) = Pr [X mod m = z]

= Pr [X < mq] * Pr [X mod m = z| X < mq]
+ Pr [mq <= X < N] * Pr [X mod m = z| mq <= X < N]

= mq/N * 1/m +
(N - mq)/N * 1 / (N - mq) if 0 <= z < N - mq
0 if N - mq <= z <= m

= q/N +
r/N * 1 / r if 0 <= z < N - mq
0 if r <= z <= m

Simplifying yields the claimed equation.

Let N = 2^31, d = 6 6, and m = 10^d. If x is chosen at random from
Z_{N} (meaning, is a random 31-bit string), then reducing it to a
6-digit 6-
digit number by taking x mod m does not yield a random 6-digit
number.

Rather, x mod m is distributed as shown in the following table:

Values Probability that each appears as output
----------------------------------------------------------------
0,1,...,483647 2148/2^31 roughly equals to 1.00024045/10^6
483648,...,999999 2147/2^31 roughly equals to 0.99977478/10^6

If X is uniformly distributed over Z_{2^31} (meaning (meaning, is a random
31-bit string) string), then the above shows the probabilities for different
outputs of X mod 10^6. The first set of values appear appears with

M'Raihi, et al. Informational [Page 20]

RFC 4226 HOTP Algorithm December 2005

probability slightly greater than 10^-6, the rest with probability
slightly less, meaning that the distribution is slightly non-uniform.

However, as the Figure table above indicates, the bias is small small, and as we
will see later, negligible: the probabilities are very close to
10^-6.

A.4.2

A.4.2. Brute force attacks Force Attacks

If the authenticator consisted of d random digits, then a brute force
attack using v verification attempts would succeed with probability
sv/10^Digit.

However, an adversary can exploit the bias in the outputs of HOTP-
IDEAL,
HOTP-IDEAL, predicted by Lemma 1, to mount a slightly better attack.

Namely, it makes authentication attempts with authenticators which that are
the most likely values, meaning the ones in the range 0,...,r - 1,
where (q,r) = IntDiv(2^31,10^Digit).

The following specifies an adversary in our model of security that
mounts the attack. It estimates the success probability as a
function of the number of verification queries.

For simplicity, we assume that the number of verification queries is
at most r. With N = 2^31 and m = 10^6 10^6, we have r = 483,648, and the
throttle value is certainly less than this, so this assumption is not
much of a restriction.

Proposition 1
-------------

Suppose m = 10^Digit < 2^31, and let (q,r) = IntDiv(2^31,m). Assume
s <= m. The brute-force attack brute-force-attack adversary B-bf attacks HOTP using v
<= r verification oracle queries. This adversary makes no
authenticator oracle queries, and succeeds with probability

Adv(B-bf) = 1 - (1 - v(q+1)/2^31)^s

which is roughly equals equal to

sv * (q+1)/2^31

With m = 10^6 we get q = 2,147. In that case, the brute force attack
using v verification attempts succeeds with probability

Adv(B-bf) roughly = sv * 2148/2^31 = sv * 1.00024045/10^6

M'Raihi, et al. Informational [Page 21]

RFC 4226 HOTP Algorithm December 2005

As this equation shows, the resynchronization parameter s has a
significant impact in that the adversary's success probability is
proportional to s. This means that s cannot be made too large
without compromising security.

A.4.3

A.4.3. Brute force attacks are the best possible attacks attacks.

A central question is whether there are attacks any better than the
brute force one. In particular, the brute force attack did not
attempt to collect authenticators sent by the user and try to
cryptanalyze them in an attempt to learn how to better construct
authenticators. Would doing this help? Is there some way to "learn"
how to build authenticators that result in a higher success rate than
given by the brute-force attack?

The following says the answer to these questions is no. No matter
what strategy the adversary uses, and even if it sees, and tries to
exploit, the authenticators from authentication attempts of the user,
its success probability will not be above that of the brute force
attack - -- this is true as long as the number of authentications it
observes is not incredibly large. This is valuable information
regarding the security of the scheme.

Proposition 2 ------------- Suppose m = 10^Digit < 2^31, and let
(q,r) = IntDiv(2^31,m). Let B be any adversary attacking HOTP-IDEAL
using v verification oracle queries and a <= 2^c - s authenticator
oracle queries. Then

Adv(B) < = sv * (q+1)/ 2^31

Note: This result is conditional on the adversary not seeing more
than 2^c - s authentications performed by the user, which is hardly
restrictive as long as c is large enough.

With m = 10^6 10^6, we get q = 2,147. In that case, Proposition 2 says
that any adversary B attacking HOTP-IDEAL and making v verification
attempts succeeds with probability at most

Equation 1
----------
sv * 2148/2^31 roughly = sv * 1.00024045/10^6

Meaning, B's success rate is not more than that achieved by the brute
force attack.

A.5

M'Raihi, et al. Informational [Page 22]

RFC 4226 HOTP Algorithm December 2005

A.5. Security Analysis of HOTP

We have analyzed analyzed, in the previous sections, the security of the
idealized counterparts HOTP-IDEAL of the actual authentication
algorithm HOTP. We now show that, under appropriate and
well-believed well-
believed assumption on H, the security of the actual algorithms is
essentially the same as that of its idealized counterpart.

The assumption in question is that H is a secure pseudorandom
function, or PRF, meaning that its input-output values are
indistinguishable from those of a random function in practice.

Consider an adversary A that is given an oracle for a function f:
{0,1}^c --> {0, 1}^n and eventually outputs a bit. We denote Adv(A)
as the prf-advantage of A, which represents how well the adversary
does at distinguishing the case where its oracle is H(K,.) from the
case where its oracle is a random function of {0,1}^c to {0,1}^n.

One possible attack is based on exhaustive search for the key K. If
A runs for t steps and T denotes the time to perform one computation
of H, its prf-advantage from this attack turns out to be (t/T)2^-k . (t/T)2^-k.
Another possible attack is a birthday one [PrOo], whereby A can
attain advantage p^2/2^n in p oracle queries and running time about
pT.

Our assumption is that these are the best possible attacks. This
translates into the following.

Assumption 1
------------

Let T denotes the time to perform one computation of H. Then if A is
any adversary with running time at most t and making at most p oracle
queries,

Adv(A) <= (t/T)/2^k + p^2/2^n

In practice practice, this assumption means that H is very secure as PRF. For
example, given that k = n = 160, an attacker with running time 2^60
and making 2^40 oracle queries has advantage at most (about) 2^-80.

Theorem 1
---------

Suppose m = 10^Digit < 2^31, and let (q,r) = IntDiv(2^31,m). Let B
be any adversary attacking HOTP using v verification oracle queries,

M'Raihi, et al. Informational [Page 23]

RFC 4226 HOTP Algorithm December 2005

a <= 2^c - s authenticator oracle queries, and running time t. Let T
denote the time to perform one computation of H. If Assumption 1 is true
true, then

Adv(B) <= sv * (q + 1)/2^31 + (t/T)/2^k + ((sv + a)^2)/2^n

In practice, the (t/T)2^-k + ((sv + a)^2)2^-n term is much smaller
than the sv(q + 1)/2^n term, so that the above says that for all
practical purposes the success rate of an adversary attacking HOTP is
sv(q + 1)/2^n, just as for HOTP-IDEAL, meaning the HOTP algorithm is
in practice essentially as good as its idealized counterpart.

In the case m = 10^6 of a 6-digit output output, this means that an
adversary making v authentication attempts will have a success rate
that is at most that of Equation 1.

For example, consider an adversary with running time at most 2^60
that sees at most 2^40 authentication attempts of the user. Both
these choices are very generous to the adversary, who will typically
not have these resources, but we are saying that even such a powerful
adversary will not have more success than indicated by Equation 1.

We can safely assume sv <= 2^40 due to the throttling and bounds on
s. So:

(t/T)/2^k + ((sv + a)^2)/2^n <= 2^60/2^160 + (2^41)^2/2^160
roughly <= 2^-78

which is much smaller than the success probability of Equation 1 and
negligible compared to it.

M'Raihi, et al. Informational [Page 24]

RFC 4226 HOTP Algorithm December 2005

Appendix B - SHA-1 Attacks

This sections addresses the impact of the recent attacks on SHA-1 on
the security of the HMAC-SHA-1 based HMAC-SHA-1-based HOTP. We begin with some
discussion of the situation of SHA-1 and then discuss the relevance
to HMAC-SHA-1 and HOTP. Cited references are at the bottom of the
document.

B.1 in Section 13.

B.1. SHA-1 status Status

A collision for a hash function h means a pair x,y of different
inputs such that h(x)=h(y). Since SHA-1 outputs 160 bits, a birthday
attack finds a collision in 2^{80} trials. (A trial means one
computation of the function.) This was thought to be the best
possible until Wang, Yin Yin, and Yu announced on February 15, 2005 2005, that
they had an attack finding collisions in 2^{69} trials.

Is SHA-1 broken? For most practical purposes purposes, we would say probably
not, since the resources needed to mount the attack are huge. Here
is one way to get a sense of it: we can estimate it is about the same
as the time we would need to factor a 760-bit RSA modulus, and this
is currently considered out of reach.

Burr of NIST is quoted in [Crack] as saying ``Large "Large national
intelligence agencies could do this in a reasonable amount of time
with a few million dollars in computer time.'' time". However, the
computation may be out of reach of all but such well-funded agencies.

One should also ask what impact finding SHA-1 collisions actually has
on security of real applications such as signatures. To exploit a
collision x,y to forge signatures, you need to somehow obtain a
signature of x and then you can forge a signature of y. How damaging
this is depends on the content of y: the y created by the attack may
not be meaningful in the application context. Also, one needs a
chosen-message attack to get the signature of x. This seems possible
in some contexts, but not others. Overall, it is not clear that the
impact on the security of signatures is significant.

Indeed, one can read in the press that SHA-1 is ``broken,'' [Sha1], "broken" [Sha1] and
that encryption and SSL are ``broken'' [Res], in the press. "broken" [Res]. The media have a
tendency to magnify events: it would hardly be interesting to
announce in the news that a team of cryptanalysts did very
interesting theoretical work in attacking SHA-1.

Cryptographers are excited too. But mainly because this is an
important theoretical breakthrough. Attacks can only get beter better with
time: it is therefore important to monitor any progress in hash
functions cryptanalysis and be prepared for any really practical
break with a sound migration plan for the future.

B.2

M'Raihi, et al. Informational [Page 25]

RFC 4226 HOTP Algorithm December 2005

B.2. HMAC-SHA-1 status Status

The new attacks on SHA-1 have no impact on the security of HMAC-
SHA-1.
HMAC-SHA-1. The best attack on the latter remains one needing a
sender to authenticate 2^{80} messages before an adversary can create
a forgery. Why?

HMAC is not a hash function. It is a message authentication code
(MAC) that uses a hash function internally. A MAC depends on a
secret key, while hash functions don't. What one needs to worry
about with a MAC is forgery, not collisions. HMAC was designed so
that collisions in the hash function (here SHA-1) do not yield
forgeries for HMAC.

Recall that HMAC-SHA-1(K,x) = SHA-1(K_o,SHA-1(K_i,x)) where the keys
K_o,K_i are derived from K. Suppose the attacker finds a pair x,y
such that SHA-1(K_i,x)=SHA-1(K_i,y). SHA-1(K_i,x) = SHA-1(K_i,y). (Call this a hidden-key
collision.) Then if it can obtain the MAC of x (itself a tall
order), it can forge the MAC of y. (These values are the same.) But
finding hidden-key collisions is harder than finding collisions,
because the attacker does not know the hidden key K_i. All it may
have is some outputs of HMAC-SHA-1 with key K. To date date, there are no
claims or evidence that the recent attacks on SHA-1 extend to find
hidden-key collisions.

Historically, the HMAC design has already proven itself in this
regard. MD5 is considered broken in that collisions in this hash
function can be found relatively easily. But there is still no
attack on HMAC-MD5 better than the trivial 2^{64} time birthday one.
(MD5 outputs 128 bits, not 160.) We are seeing this strength of HMAC
coming into play again in the SHA-1 context.

B.3

B.3. HOTP status Status

Since no new weakness has surfaced in HMAC-SHA-1, there is no impact
on HOTP. The best attacks on HOTP remain those described in the
document, namely namely, to try to guess output values.

The security proof of HOTP requires that HMAC-SHA-1 behave like a
pseudorandom function. The quality of HMAC-SHA-1 as a pseudorandom
function is not impacted by the new attacks on SHA-1, and so neither
is this proven guarantee.

M'Raihi, et al. Informational [Page 26]

RFC 4226 HOTP Algorithm December 2005

Appendix C - HOTP Algorithm: Reference Implementation

/*
* OneTimePasswordAlgorithm.java
* OATH Initiative,
* HOTP one-time password algorithm
*
*/

/* Copyright (C) 2004, OATH. All rights reserved.
*
* License to copy and use this software is granted provided that it
* is identified as the "OATH HOTP Algorithm" in all material
* mentioning or referencing this software or this function.
*
* License is also granted to make and use derivative works provided
* that such works are identified as
* "derived from OATH HOTP algorithm"
* in all material mentioning or referencing the derived work.
*
* OATH (Open AuTHentication) and its members make no
* representations concerning either the merchantability of this
* software or the suitability of this software for any particular
* purpose.
*
* It is provided "as is" without express or implied warranty
* of any kind and OATH AND ITS MEMBERS EXPRESSELY EXPRESSaLY DISCLAIMS
* ANY WARRANTY OR LIABILITY OF ANY KIND relating to this software.
*
* These notices must be retained in any copies of any part of this
* documentation and/or software.
*/

package org.openauthentication.otp;

import java.io.IOException;
import java.io.File;
import java.io.DataInputStream;
import java.io.FileInputStream ;
import java.lang.reflect.UndeclaredThrowableException;

import java.security.GeneralSecurityException;
import java.security.NoSuchAlgorithmException;
import java.security.InvalidKeyException;

import javax.crypto.Mac;
import javax.crypto.spec.SecretKeySpec;

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RFC 4226 HOTP Algorithm December 2005

/**
* This class contains static methods that are used to calculate the
* One-Time Password (OTP) using
* JCE to provide the HMAC-SHA1. HMAC-SHA-1.
*
* @author Loren Hart
* @version 1.0
*/
public class OneTimePasswordAlgorithm {
private OneTimePasswordAlgorithm() {}

// These are used to calculate the check-sum digits.
// 0 1 2 3 4 5 6 7 8 9
private static final int[] doubleDigits =
{ 0, 2, 4, 6, 8, 1, 3, 5, 7, 9 };

/**
* Calculates the checksum using the credit card algorithm.
* This algorithm has the advantage that it detects any single
* mistyped digit and any single transposition of
* adjacent digits.
*
* @param num the number to calculate the checksum for
* @param digits number of significant places in the number
*
* @return the checksum of num
*/
public static int calcChecksum(long num, int digits) {
boolean doubleDigit = true;
int total = 0;
while (0 < digits--) {
int digit = (int) (num % 10);
num /= 10;
if (doubleDigit) {
digit = doubleDigits[digit];
}
total += digit;
doubleDigit = !doubleDigit;
}
int result = total % 10;
if (result > 0) {
result = 10 - result;
}
return result;
}

/**
* This method uses the JCE to provide the HMAC-SHA1 HMAC-SHA-1

M'Raihi, et al. Informational [Page 28]

RFC 4226 HOTP Algorithm December 2005

* algorithm.
* HMAC computes a Hashed Message Authentication Code and
* in this case SHA1 is the hash algorithm used.
*
* @param keyBytes the bytes to use for the HMAC-SHA1 HMAC-SHA-1 key
* @param text the message or text to be authenticated.
*
* @throws NoSuchAlgorithmException if no provider makes
* either HmacSHA1 or HMAC-SHA1 HMAC-SHA-1
* digest algorithms available.
* @throws InvalidKeyException
* The secret provided was not a valid HMAC-SHA1 HMAC-SHA-1 key.
*
*/

public static byte[] hmac_sha1(byte[] keyBytes, byte[] text)
throws NoSuchAlgorithmException, InvalidKeyException
{
// try {
Mac hmacSha1;
try {
hmacSha1 = Mac.getInstance("HmacSHA1");
} catch (NoSuchAlgorithmException nsae) {
hmacSha1 = Mac.getInstance("HMAC-SHA1"); Mac.getInstance("HMAC-SHA-1");
}
SecretKeySpec macKey =
new SecretKeySpec(keyBytes, "RAW");
hmacSha1.init(macKey);
return hmacSha1.doFinal(text);
// } catch (GeneralSecurityException gse) {
// throw new UndeclaredThrowableException(gse);
// }
}

private static final int[] DIGITS_POWER
// 0 1 2 3 4 5 6 7 8
= {1,10,100,1000,10000,100000,1000000,10000000,100000000};

/**
* This method generates an OTP value for the given
* set of parameters.
*
* @param secret the shared secret
* @param movingFactor the counter, time, or other value that
* changes on a per use basis.
* @param codeDigits the number of digits in the OTP, not
* including the checksum, if any.
* @param addChecksum a flag that indicates if a checksum digit

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RFC 4226 HOTP Algorithm December 2005

* should be appended to the OTP.
* @param truncationOffset the offset into the MAC result to
* begin truncation. If this value is out of
* the range of 0 ... 15, then dynamic
* truncation will be used.
* Dynamic truncation is when the last 4
* bits of the last byte of the MAC are
* used to determine the start offset.
* @throws NoSuchAlgorithmException if no provider makes
* either HmacSHA1 or HMAC-SHA1 HMAC-SHA-1
* digest algorithms available.
* @throws InvalidKeyException
* The secret provided was not
* a valid HMAC-SHA1 HMAC-SHA-1 key.
*
* @return A numeric String in base 10 that includes
* {@link codeDigits} digits plus the optional checksum
* digit if requested.
*/
static public String generateOTP(byte[] secret,
long movingFactor,
int codeDigits,
boolean addChecksum,
int truncationOffset)
throws NoSuchAlgorithmException, InvalidKeyException
{
// put movingFactor value into text byte array
String result = null;
int digits = addChecksum ? (codeDigits + 1) : codeDigits;
byte[] text = new byte[8];
for (int i = text.length - 1; i >= 0; i--) {
text[i] = (byte) (movingFactor & 0xff);
movingFactor >>= 8;
}

// compute hmac hash
byte[] hash = hmac_sha1(secret, text);

// put selected bytes into result int
int offset = hash[hash.length - 1] & 0xf;
if ( (0<=truncationOffset) &&
(truncationOffset<(hash.length-4)) ) {
offset = truncationOffset;
}
int binary =
((hash[offset] & 0x7f) << 24)
| ((hash[offset + 1] & 0xff) << 16)
| ((hash[offset + 2] & 0xff) << 8)

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RFC 4226 HOTP Algorithm December 2005

| (hash[offset + 3] & 0xff);

int otp = binary % DIGITS_POWER[codeDigits];
if (addChecksum) {
otp = (otp * 10) + calcChecksum(otp, codeDigits);
}
result = Integer.toString(otp);
while (result.length() < digits) {
result = "0" + result;
}
return result;
}
}

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RFC 4226 HOTP Algorithm December 2005

Appendix D - HOTP Algorithm: Test Values

The following test data uses the ASCII string
"123456787901234567890"
"12345678901234567890" for the secret:

Secret = 0x3132333435363738393031323334353637383930

Table 1 details for each count, the intermediate hmac HMAC value.

Count Hexadecimal HMAC-SHA1(secret, HMAC-SHA-1(secret, count)
0 cc93cf18508d94934c64b65d8ba7667fb7cde4b0
1 75a48a19d4cbe100644e8ac1397eea747a2d33ab
2 0bacb7fa082fef30782211938bc1c5e70416ff44
3 66c28227d03a2d5529262ff016a1e6ef76557ece
4 a904c900a64b35909874b33e61c5938a8e15ed1c
5 a37e783d7b7233c083d4f62926c7a25f238d0316
6 bc9cd28561042c83f219324d3c607256c03272ae
7 a4fb960c0bc06e1eabb804e5b397cdc4b45596fa
8 1b3c89f65e6c9e883012052823443f048b4332db
9 1637409809a679dc698207310c8c7fc07290d9e5

Table 2 details for each count the truncated values (both in
hexadecimal and decimal) and then the HOTP value.

Truncated
Count Hexadecimal Decimal HOTP
0 4c93cf18 1284755224 755224
1 41397eea 1094287082 287082
2 82fef30 137359152 359152
3 66ef7655 1726969429 969429
4 61c5938a 1640338314 338314
5 33c083d4 868254676 254676
6 7256c032 1918287922 287922
7 4e5b397 82162583 162583
8 2823443f 673399871 399871
9 2679dc69 645520489 520489

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RFC 4226 HOTP Algorithm December 2005

Appendix E - Extensions

We introduce in this section several enhancements to the HOTP
algorithm. These are not recommended extensions or part of the
standard algorithm, but merely variations that could be used for
customized implementations.

E.1

E.1. Number of Digits

A simple enhancement in terms of security would be to extract more
digits from the HMAC-SHA1 HMAC-SHA-1 value.

For instance, calculating the HOTP value modulo 10^8 to build an
8-digit 8-
digit HOTP value would reduce the probability of success of the
adversary from sv/10^6 to sv/10^8.

This could give the opportunity to improve usability, e.g. e.g., by
increasing T and/or s, while still achieving a better security
overall. For instance, s = 10 and 10v/10^8 = v/10^7 < v/10^6 which
is the theoretical optimum for 6-digit code when s = 1.

E.2 Alpha-numeric

E.2. Alphanumeric Values

Another option is to use A-Z and 0-9 values; or rather a subset of 32
symbols taken from the alphanumerical alphabet in order to avoid any
confusion between characters: 0, O O, and Q as well as l, 1 1, and I are
very similar, and can look the same on a small display.

The immediate consequence is that the security is now in the order of
sv/32^6 for a 6-digit HOTP value and sv/32^8 for an 8-digit HOTP
value.

32^6 > 10^9 so the security of a 6-alphanumeric HOTP code is slightly
better than a 9-digit HOTP value, which is the maximum length of an
HOTP code supported by the proposed algorithm.

32^8 > 10^12 so the security of an 8-alphanumeric HOTP code is
significantly better than a 9-digit HOTP value.

Depending on the application and token/interface used for displaying
and entering the HOTP value, the choice of alphanumeric values could
be a simple and efficient way to improve security at a reduced cost
and impact on users.

E.3

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RFC 4226 HOTP Algorithm December 2005

E.3. Sequence of HOTP values Values

As we suggested for the resynchronization to enter the resynchronization to enter a short sequence
(say, 2 or 3) of HOTP values, we could generalize the concept to the
protocol, and add a parameter L that would define the length of the
HOTP sequence to enter.

Per default, the value L SHOULD be set to 1, but if security needs to
be increased, users might be asked (possibly for a short period of
time, or a specific operation) to enter L HOTP values.

This is another way, without increasing the HOTP length or using
alphanumeric values to tighten security.

Note: The system MAY also be programmed to request synchronization on
a regular basis (e.g., every night, twice a week, etc.) and to
achieve this purpose, ask for a sequence of L HOTP values.

E.4. A Counter-Based Resynchronization Method

In this case, we assume that the client can access and send not only
the HOTP value but also other information, more specifically, the
counter value.

A more efficient and secure method for resynchronization is possible
in this case. The client application will not send the HOTP-client
value only, but the HOTP-client and the related C-client counter
value, the HOTP value acting as a message authentication code of the
counter.

Resynchronization Counter-based Protocol (RCP)
----------------------------------------------

The server accepts if the following are all true, where C-server is
its own current counter value:

1) C-client >= C-server
2) C-client - C-server <= s
3) Check that HOTP client is valid HOTP(K,C-Client)
4) If true, the server sets C to C-client + 1 and client is
authenticated

In this case, there is no need for managing a short sequence
(say 2 or 3) look-ahead window
anymore. The probability of success of HOTP values, we could generalize the concept adversary is only v/10^6
or roughly v in one million. A side benefit is obviously to the
protocol, be able
to increase s "infinitely" and add a parameter L that would define therefore improve the length of system usability
without impacting the security.

M'Raihi, et al. Informational [Page 34]

RFC 4226 HOTP sequence to enter.

Per default, the value L Algorithm December 2005

This resynchronization protocol SHOULD be set to 1, but if security needs
to be increased, users might be asked (possibly for a short period used whenever the related
impact on the client and server applications is deemed acceptable.

E.5. Data Field

Another interesting option is the introduction of time, or a specific operation) to enter L Data field, which
would be used for generating the One-Time Password values: HOTP values.

This (K,
C, [Data]) where Data is another way, without increasing an optional field that can be the HOTP length or using
alphanumeric values to tighten security.

Note: The system MAY
concatenation of various pieces of identity-related information,
e.g., Data = Address | PIN.

We could also be programmed to request synchronization
on use a regular basis (e.g. every night, Timer, either as the only moving factor or twice a week, in
combination with the Counter -- in this case, e.g., Data = Timer,
where Timer could be the UNIX-time (GMT seconds since 1/1/1970)
divided by some factor (8, 16, 32, etc.) and in order to
achieve this purpose, ask give a specific
time step. The time window for a sequence of L HOTP values.

E.4 A Counter-based Re-Synchronization Method

In this case, we assume that the client can access and send not
only One-Time Password is then equal
to the HOTP value but also other information, more specifically time step multiplied by the counter value.

A more efficient resynchronization parameter as
defined before. For example, if we take 64 seconds as the time step
and secure method 7 for the resynchronization is
possible parameter, we obtain an acceptance
window of +/- 3 minutes.

Using a Data field opens for more flexibility in this case. The client application will not send the
HOTP-client value only, but the HOTP-client and the related
C-client counter value, algorithm
implementation, provided that the Data field is clearly specified.

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RFC 4226 HOTP value acting as a message
authentication code Algorithm December 2005

Authors' Addresses

David M'Raihi (primary contact for sending comments and questions)
VeriSign, Inc.
685 E. Middlefield Road
Mountain View, CA 94043 USA

Phone: 1-650-426-3832
EMail: dmraihi@verisign.com

Mihir Bellare
Dept of the counter.

Resynchronization Counter-based Protocol (RCP)
---------------------------------------------- Computer Science and Engineering, Mail Code 0114
University of California at San Diego
9500 Gilman Drive
La Jolla, CA 92093, USA

EMail: mihir@cs.ucsd.edu

Frank Hoornaert
VASCO Data Security, Inc.
Koningin Astridlaan 164
1780 Wemmel, Belgium

EMail: frh@vasco.com

David Naccache
Gemplus Innovation
34 rue Guynemer, 92447,
Issy les Moulineaux, France
and
Information Security Group,
Royal Holloway,
University of London, Egham,
Surrey TW20 0EX, UK

EMail: david.naccache@gemplus.com, david.naccache@rhul.ac.uk

Ohad Ranen
Aladdin Knowledge Systems Ltd.
15 Beit Oved Street
Tel Aviv, Israel 61110

EMail: Ohad.Ranen@ealaddin.com

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RFC 4226 HOTP Algorithm December 2005

Full Copyright Statement

This document is subject to the following are rights, licenses and restrictions
contained in BCP 78, and except as set forth therein, the authors
retain all true, where C-server is
its own current counter value:

1) C-client >= C-server
2) C-client - C-server <= s
3) Check that HOTP-client is valid HOTP(K,C-Client)
4) If true, their rights.

This document and the server sets C to C-client + 1 information contained herein are provided on an
"AS IS" basis and client is
authenticated

In this case, there is no need for managing a look-ahead window
anymore. THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET
ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED,
INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE
INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.

Intellectual Property

The probability of success of IETF takes no position regarding the adversary is only v/10^6 validity or roughly v in one million. A side benefit is obviously to scope of any
Intellectual Property Rights or other rights that might be able claimed to
pertain to increase s "infinitely" and therefore improve the system
usability without impacting the security.

This resynchronization protocol SHOULD be implementation or use whenever the related
impact on of the client and server applications is deemed acceptable.

E.5 Data Field

Another interesting option is technology described in
this document or the introduction of a Data field, extent to which any license under such rights
might or might not be available; nor does it represent that would be used for generating it has
made any independent effort to identify any such rights. Information
on the One-Time password values:
HOTP (K, C, [Data]) where Data is an optional field that procedures with respect to rights in RFC documents can be
found in BCP 78 and BCP 79.

Copies of IPR disclosures made to the
concatenation IETF Secretariat and any
assurances of various pieces licenses to be made available, or the result of identity-related information -
e.g. Data = Address | PIN.

We could also use an
attempt made to obtain a Timer, either as the only moving factor general license or in
combination with permission for the Counter - in use of
such proprietary rights by implementers or users of this case, e.g. Data = Timer,
where Timer could
specification can be obtained from the UNIX-time (GMT seconds since 1/1/1970)
divided by some factor (8, 16, 32, etc.) in order to give a
specific time step. IETF on-line IPR repository at
http://www.ietf.org/ipr.

The time window for the One-Time Password is

then equal IETF invites any interested party to bring to its attention any
copyrights, patents or patent applications, or other proprietary
rights that may cover technology that may be required to implement
this standard. Please address the time step multiplied by the resynchronization
parameter as defined before - e.g. if we take 64 seconds as the
time step and 7 for information to the resynchronization parameter, we obtain an
acceptance window of +/- 3 minutes.

Using a Data field opens IETF at ietf-
ipr@ietf.org.

Acknowledgement

Funding for more flexibility in the algorithm
implementation, RFC Editor function is currently provided that by the Data field is clearly specified.
Internet Society.

M'Raihi, et al. Informational [Page 37]

----