Network Working Group M.P.H. Petit-Huguenin
Internet-Draft (Unaffiliated)
Intended status: Standards Track October 31, 2011
Expires: May 03, 2012

Configuration of Access Control Policy in REsource LOcation And Discovery (RELOAD) Base Protocol
draft-petithuguenin-p2psip-access-control-04

Abstract

This document describes an extension to the REsource LOcation And Discovery (RELOAD) base protocol to distribute the code of new Access Control Policies without having to upgrade the RELOAD implementations in an overlay.

Status of this Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at http://datatracker.ietf.org/drafts/current/.

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This Internet-Draft will expire on May 03, 2012.

Copyright Notice

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Table of Contents

1. Introduction

The RELOAD base protocol specifies an Access Control Policy as "defin[ing] whether a request from a given node to operate on a given value should succeed or fail." The paragraph continues saying that "[i]t is anticipated that only a small number of generic access control policies are required", but there is indications that this assumption will not hold. On all the RELOAD Usages defined in other documents than the RELOAD base protocol, roughly 50% defines a new Access Control Policy.

The problem with a new Access Control Policy is that, because it is executed when a Store request is processed, it needs to be implemented by all the peers and so requires an upgrade of the software. This is something that is probably not possible in large overlays or on overlays using different implementations. For this reason, this document proposes an extension to the RELOAD configuration document that permits to transport the code of a new Access Control Policy to each peer.

This extension defines a new element <access-control-code> that can be optionally added to a <configuration> element in the configuration document. The <access-control-code> element contains ECMAScript [ECMA-262] code that will be called for each StoredData object that use this access control policy. The code receives four parameters, corresponding to the Resource-ID, Signature, Kind and StoredDataValue of the value to store. The code returns true or false to signal to the implementation if the request should succeed or fail.

For example the USER-MATCH Access Control Policy defined in the base protocol could be redefined by inserting the following code in an <access-control-code> element:

return resource.equalsHash(signer.user_name.bytes());

The <kind> parameters are also passed to the code, so the NODE-MULTIPLE Access Control Policy could be implemented like this:

for (var i = 0; i < kind.max_node_multiple; i++) {
    if (resource.equalsHash(signer.node_id, i.width(4))) {
        return true;
    }
}
return false;

2. Terminology

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].

"SHOULD", "SHOULD NOT", "RECOMMENDED", and "NOT RECOMMENDED" are appropriate when valid exceptions to a general requirement are known to exist or appear to exist, and it is infeasible or impractical to enumerate all of them. However, they should not be interpreted as permitting implementors to fail to implement the general requirement when such failure would result in interoperability failure.

3. Processing

A peer receiving a configuration document containing one or more <access-control-code> elements, either by retrieving it from the configuration server or in a ConfigUpdateReq message, MUST reject this configuration if is not is not signed or if the signature verification fails.

The Compact Relax NG Grammar for this element is:

namespace acp = "http://implementers.org/access-control"

parameter &= element acp:access-control-code {
  attribute name { xsd:string },
  xsd:base64Binary
}?
				

The "name" attribute defines the access control policy and can then be used in a <kind> element as if it was defined by IANA.

If the <access-control-code> element is present in the namespace allocated to this specification, and the Access Control Policy is not natively implemented, then the code inside the element MUST be called for each DataValue found in a received StoreReq for a Kind that is defined with this access control policy. The content of the <access-control-code> element MUST be decoded using the base64 [RFC4648] encoding, uncompressed using gzip [RFC1952] then converted to characters using UTF-8. <access-control-code> elements that are not encoded using UTF-8, compressed with gzip or finally converted to the base64 format MUST be ignored. For each call to the code, the following ECMAScript objects, properties and functions MUST be available:

configuration.instance_name:
The name of the overlay, as a String object.
configuration.topology_plugin:
The overlay algorithm, as a String object.
configuration.node_id_length:
The length of a NodeId in bytes, as a Number object.
configuration.kinds:
An array of kinds (with the same definition than the kind object), indexed by id and eventually by name.
configuration.evaluate(String, String, String):
A function that evaluates the first parameter as an XPath expression against the configuration element, and returns the result as a String object. The second parameter must contain a namespace prefix and the third parameter must contain a namespace.
kind.id:
The id of the Kind associated with the entry, as a Number object.
kind.name:
If the Kind associated with the entry is registered by IANA, contains the name as a String object. If not, this property is undefined.
kind.data_model:
The name of the Data Model associated with the entry, as a String object.
kind.access_control:
The name of the Access Control Policy associated with the entry, as a String object.
kind.max_count:
The value of the max-count element in the configuration file, as a Number object.
kind.max_size:
The value of the max-size element in the configuration file as a Number object.
kind.max_node_multiple:
If the Access Control is MULTIPLE-NODE, contains the value of the max-node-multiple element in the configuration file, as a Number object. If not, this property is undefined.
kind.evaluate(String, String, String):
A function that evaluates the first parameter as an XPath expression against the kind element, and returns the result as a String object. The second parameter must contain a namespace prefix and the third parameter must contain a namespace.
resource:
An opaque object representing the Resource-ID, as an array of bytes.
resource.entries:
An array of arrays of entry objects, with the first array level indexed by Kind-Id and kind names, and the second level indexed by index, key or nothing, depending on the data model of the kind. This permits to retrieve all the values of all Kinds stored at the same Resource-ID than the entry currently processed.
resource.equalsHash(Object...):
A function that returns true if hashing the concatenation of the arguments according to the mapping function of the overlay algorithm is equal to the Resource-ID. Each argument is an array of bytes.
entry.index:
If the Data Model is ARRAY, contains the index of the entry, as a Number object. If not, this property is undefined.
entry.key:
If the Data Model is DICTIONARY, contains the key of the entry, as an array of bytes. If not, this property is undefined.
entry.storage_time:
The date and time used to store the entry, as a Date object.
entry.lifetime:
The validity for the entry in seconds, as a Number object.
entry.exists:
Indicates if the entry value exists, as Boolean object.
entry.value:
This property contains an opaque object that represents the whole data, as an array of bytes.
entry.signer.user_name:
The rfc822Name stored in the certificate that was used to sign the request, as a String object.
entry.signer.node_id:
The Node-ID stored in the certificate that was used to sign the request, as an array of bytes.

The properties SHOULD NOT be modifiable or deletable and if they are, modifying or deleting them MUST NOT modify or delete the equivalent internal values (in other words, the code cannot be used to modify the elements that will be stored).

The value returned by the code is evaluated to true or false, according to the ECMAScript rules. If the return value of one of the call to the code is evaluated to false, then the StoreReq fails, the state MUST be rolled back and an Error_Forbidden MUST be returned.

4. Security Considerations

Because the configuration document containing the ECMAScript code is under the responsability of the same entity that will sign it, using a scripting language does not introduce any additional risk if the RELOAD implementers follow the rules in this document (no side effect when modifying the parameters, only base classes of ECMAScript implemented, etc...). It is even possible to deal with less than perfect implementations as long as they do not accept a configuration file that is not signed correctly. One way for the signer to enforce this would be to deliberately send in a ConfigUpdate an incorrectly signed version of the configuration file and blacklist all the nodes that accepted it in a newly issued configuration file.

By permitting multiple overlay implementations to interoperate inside one overlay, RELOAD helps build overlays that are not only resistant to hardware or communication failures, but also to programmer errors. Distributing the access control policy code inside the configuration document reintroduces this single point of failure. To mitigate this problem, new access control policies should be implemented natively as soon as possible, but if all implementations uses the script as a blueprint for the native code, an hidden bug can be duplicated. This is why developers should implement new access control policies from the normative text instead of using the code. That is anyway probably not legal under most copyright laws but to help developers do the right thing the code in the configuration is obfuscated by compressing and encoding it as a base64 character string.

5. IANA Considerations

If this document is accepted as a standard track document this section will request an URN in the "XML Namespaces" class of the "IETF XML Registry" from IANA. Until this is done, implementions should use the following URN:

http://implementers.org/access-control

6. Acknowledgements

This document was written with the xml2rfc tool described in [RFC2629].

7. References

7.1. Normative References

[RFC1952] Deutsch, P., Gailly, J-L., Adler, M., Deutsch, L.P. and G. Randers-Pehrson, "GZIP file format specification version 4.3", RFC 1952, May 1996.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data Encodings", RFC 4648, October 2006.
[I-D.ietf-p2psip-base] Jennings, C, Lowekamp, B, Rescorla, E, Baset, S and H Schulzrinne, "REsource LOcation And Discovery (RELOAD) Base Protocol", Internet-Draft draft-ietf-p2psip-base-19, October 2011.
[ECMA-262] Ecma, , "ECMAScript Language Specification 3rd Edition", December 2009.

7.2. Informative References

[RFC2629] Rose, M.T., "Writing I-Ds and RFCs using XML", RFC 2629, June 1999.
[I-D.ietf-p2psip-service-discovery] Maenpaa, J and G Camarillo, "Service Discovery Usage for REsource LOcation And Discovery (RELOAD)", Internet-Draft draft-ietf-p2psip-service-discovery-03, July 2011.
[I-D.petithuguenin-vipr-reload-usage] Rosenberg, J, Jennings, C and M Petit-Huguenin, "A Usage of Resource Location and Discovery (RELOAD) for Public Switched Telephone Network (PSTN) Verification", Internet-Draft draft-petithuguenin-vipr-reload-usage-02, July 2011.
[I-D.knauf-p2psip-share] Knauf, A, Hege, G, Schmidt, T and M Waehlisch, "A Usage for Shared Resources in RELOAD (ShaRe)", Internet-Draft draft-knauf-p2psip-share-02, October 2011.

Appendix A. Examples

Appendix A.1. Standard Access Control Policies

This section shows the ECMAScript code that could be used to implement the standard Access Control Policies defined in [I-D.ietf-p2psip-base].

Appendix A.1.1. USER-MATCH

String.prototype['bytes'] = function() {
    var bytes = [];
    for (var i = 0; i < this.length; i++) {
        bytes[i] = this.charCodeAt(i);
    }
    return bytes;
};

return resource.equalsHash(entry.signer.user_name.bytes());

Appendix A.1.2. NODE-MATCH

return resource.equalsHash(entry.signer.node_id);

Appendix A.1.3. USER-NODE-MATCH

String.prototype['bytes'] = function() {
    var bytes = [];
    for (var i = 0; i < this.length; i++) {
        bytes[i] = this.charCodeAt(i);
    }
    return bytes;
};

var equals = function(a, b) {
    if (a.length !== b.length) return false;
    for (var i = 0; i < a.length; i++) {
        if (a[i] !== b[i]) return false;
    }
    return true;
};

return resource.equalsHash(entry.signer.user_name.bytes())
  && equals(entry.key, entry.signer.node_id);

Appendix A.1.4. NODE-MULTIPLE

Number.prototype['width'] = function(w) {
    var bytes = [];
    for (var i = 0; i < w; i++) {
        bytes[i] = (this >>> ((w - i - 1) * 8)) & 255;
    }
    return bytes;
};

for (var i = 0; i < kind.max_node_multiple; i++) {
    if (resource.equalsHash(entry.signer.node_id, i.width(4))) {
        return true;
    }
}
return false;

[[Note that base-15 still does not state exactly the length of i when concatenated in the hash input]]

Appendix A.2. Service Discovery Access Control Policy NODE-ID-MATCH

[I-D.ietf-p2psip-service-discovery] defines a specific Access Control Policy (NODE-ID-MATCH) that need to access the content of the entry to be written. If implemented as specified by this document, the ECMAScript code would look something like this:

/* Insert here the code from
   http://jsfromhell.com/classes/bignumber
 */

var toBigNumber = function(node_id) {
   var bignum = new BigNumber(0);
   for (var i = 0; i < node_id.length; i++) {
       bignum = bignum.multiply(256).add(node_id[i]);
   }
   return bignum;
};

var checkIntervals = function(node_id, level, node, factor) {
   var size = new BigNumber(2).pow(128);
   var node = toBigNumber(node_id);
   for (var f = 0; f < factor; f++) {
       var temp = size.multiply(new BigNumber(f)
         .pow(new BigNumber(level).negate()));
       var min = temp.multiply(node.add(new BigNumber(f)
         .divide(factor)));
       var max = temp.multiply(node.add(new BigNumber(f + 1)
         .divide(factor)));
       if (node.compare(min) === -1 || node.compare(max) == 1
         || node.compare(max) == 0) return false;
   }
   return true;
};

var equals = function(a, b) {
   if (a.length !== b.length) return false;
   for (var i = 0; i < a.length; i++) {
       if (a[i] !== b[i]) return false;
   }
   return true;
};

var level = function(value) {
   var length = value[16] * 256 + value[17];
   return value[18 + length] * 256 + value[18 + length + 1];
};

var node = function(value) {
   var length = value[16] * 256 + value[17];
   return value[18 + length + 2] * 256
     + value[18 + length + 3];
};

var namespace = function(value) {
   var length = value[16] * 256 + value[17];
   return String.fromCharCode.apply(null,
     value.slice(18, length + 18));
};

var branching_factor =
  kind.evaluate('/branching-factor',
  'redir', 'urn:ietf:params:xml:ns:p2p:redir');
return equals(entry.key, entry.signer.node_id)
 && (!entry.exists || checkIntervals(entry.key,
   level(entry.value), node(entry.value),
   branching_factor))
 && (!entry.exists
   || resource.equalsHash(namespace(entry.value),
     level(entry.value), node(entry.value)));

Note that the code for the BigNumber object was removed from this example, as the licensing terms are unclear. The code is available at http://jsfromhell.com/classes/bignumber.

Appendix A.3. VIPR Access Control Policy

[I-D.petithuguenin-vipr-reload-usage] defines a specific Access Control Policy. If implemented as specified by this document, the ECMAScript code would look something like this:

var equals = function(a, b) {
  if (a.length !== b.length) return false;
  for (var i = 0; i < a.length; i++) {
    if (a[i] !== b[i]) return false;
  }
  return true;
};
var length = configuration.node_id_length;
return equals(entry.key.slice(0, length),
  entry.value.slice(4, length + 4))
  && equals(entry.key.slice(0, length), entry.signer.node_id);

Appendix A.4. ShaRe Access Control Policy USER-CHAIN-ACL

[I-D.knauf-p2psip-share] defines a new Access Control Policies, USER-CHAIN-ACL. If implemented as specified by this document, the ECMAScript code would look something like this:

var pattern = kind.evaluate('/share:pattern',
  'share', 'urn:ietf:params:xml:ns:p2p:config-share');
var username = entry.signer.user_name.match(/^([^@]+)@(.+)$/);
var new_pattern = new RegExp(
  pattern.replace('$USER', username[1])
    .replace('$DOMAIN', username[2]));
var length =  entry.value[0] * 256 + entry.value[1];
var resource_name = String.fromCharCode.apply(null,
  entry.value.slice(2, length + 2));
return new_pattern.test(resource_name);\n"));

[[Note: the code is incomplete]]

Appendix B. Release notes

This section must be removed before publication as an RFC.

Appendix B.1. Modifications between -04 and -03

Appendix B.2. Modifications between -03 and -02

Appendix B.3. Modifications between -02 and -01

Appendix B.4. Modifications between -01 and -00

Appendix B.5. Running Code Considerations

Appendix B.6. TODO List

Author's Address

Marc Petit-Huguenin (Unaffiliated) EMail: petithug@acm.org