
 
Technical Committee


ATM Name System 
Specification Version 1.0

af-saa-0069.000

November, 1996

ATM Name System Specification Version 1.0
af-saa-0069.000


 1996 The ATM Forum. All Rights Reserved. No part of this publication may be reproduced in any form or by any 
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Contents
1. INTRODUCTION	1
2. TERMS AND DEFINITIONS	1
3. OVERVIEW OF ANS	1
4. LOGICAL MODELS	2
5. DATABASE ELEMENTS	2
5.1 RESOURCE RECORD DEFINITIONS	2
5.2 ATM SPECIFIC RESOURCE RECORDS	2
5.3 ATM ADDRESS TO DOMAIN NAME MAPPING	3
5.4 EXAMPLE MASTER FILE FORMAT	5
6. DNS PROTOCOL IN ATM ENVIRONMENT	6
6.1 RECURSIVE PROCESSING	7
6.2 CLIENT INITIALIZATION	7
6.3 CONNECTION USAGE	7
7. NATIVE ATM SERVICES INTERFACE	7
8. ATM DIRECTORY SERVICE INTERFACE	9
9. REFERENCES	9
APPENDIX A: REQUIREMENTS	10
A.1 Basing of ANS on DNS	10
A.2 ANS requirements	10
APPENDIX B: API INTERFACE TO ANS	12
B.1 BSD 4.3 CONFORMANT INTERFACE	12
B.1.1 Specifications	12
B.1.2 IPng aligned interface	14
B.1.3 WinSock 2 aligned interface	14



1. Introduction
 ATM applications require various types of directory services.  Directory services 
can be universal, that is, used by more than one application,  or they may be 
application specific.  An example of a universal directory service is finding an 
ATM address corresponding to the name of an ATM end system.  An example of 
an application specific service is finding the  providers of specific types of 
services (for example, Video on Demand servers).  
 
 ATM Name System (ANS) is an extension to the Internet Engineering Task Forces 
(IETF) Domain Name System (DNS).  However, rather than running on top of 
TCP/IP or UDP/IP like most DNS implementations, ANS is a native ATM 
application.  As such, ANS uses an API whose semantics are specified in 
[ATMNAS] to gain access to the ATM network via ATM Forum UNI signaling.  
The ANS record formats and DNS functions are intended to be independent of the 
version of the underlying ATM signaling.  See [ATMNAS] for information on the 
versions of the UNI signaling that are applicable to ANS.
 
 ANS clients use ATM SVCs to communicate to their ANS servers.  ANS version 1.0 
servers use ATM SVCs or UDP to communicate ANS queries and replies to other 
ANS servers.  ANS version 1.0 servers use TCP to communicate reliable zone 
transfer messages.        
 
Basic name services are modeled on the Domain Name System [RFC1034,  
RFC1035].  Some extensions that may be considered for version 2.0 are security 
extensions, dynamic update capability, mechanisms for prompt notification of 
zone changes, and incremental zone transfer capability.

The basic directory services are domain name to ATM address translation and 
ATM address to domain name translation.  The domain name to ATM address 
translation is performed under existing top level domain names.  The ATM 
address to domain name translation is done using a new domain name of 
ATMA.INT.  However, information other than ATM names and addresses may be 
added to the ANS data base.  The ATM Forum (ATMF) supports rapid 
deployment of the essential name services and  provides infrastructure for higher 
level directory services.
 
 This specification is version 1.0 of the ATM Name System (ANS) and includes the basic 
functionality as defined in [RFC1034] and [RFC1035].  Since ANS is based on 
DNS, the SAA/DS group decided to refer to [RFC1034] and [RFC1035] rather 
than repeat information contained in these RFCs in this specification.  
Implementers will need to refer to these documents.
    
2. Terms and Definitions
 
 See [RFC1034] and [RFC1035] for DNS terms and definitions.
 
3. Overview of ANS 
 
 See [RFC1034] and [RFC1035] for an overview of DNS.
 
4. Logical models
 
 See section 2.2 of [RFC1035] for common DNS configurations.
 
5. Database elements 
 
5.1 Resource Record Definitions
 
 ATM specific resource records (RR) conform to the top level RR format and 
semantics as defined in Section 3.2.1 of [RFC1035] and belong to the RR CLASS 
Internet (IN).   
 
5.2 ATM Specific Resource Records
 
 
 This specification defines one ATM specific resource record, ATMA RR, that is 
used to map domain names to ATM addresses.  The ATMA RR is defined with 
the mnemonic ATMA and TYPE code 34 (decimal).  ATM address lookup is 
analogous to IP address lookup.  A query is generated by the resolver requesting 
ATMA RRs for the provided domain name.
 
 

 ATMA RRs have the following RDATA format:
 
 
                                             1  1  1  1  1  1
               0  1  2  3  4  5  6  7  8  9  0  1  2  3  4  5
            +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
            |          FORMAT       |                       |
            +--+--+--+--+--+--+--+--+                       |
            /                    ADDRESS                    /
            |                                               |
            +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
 
 The fields have the following meaning:
  
? FORMAT: One octet that indicates the format of ADDRESS.  The two 
possible values for FORMAT are value 0 indicating ATM End System 
Address (AESA) format and value 1 indicating E.164 format.
 
? ADDRESS: Variable length string of octets containing the ATM address 
of the node to which this RR pertains.  
 
 When the format value is 0, indicating that the address is in AESA format, 
the address is coded as described in ISO 8348/AD 2 using the preferred 
binary encoding of the ISO NSAP format.  When the format value is 1, 
indicating that the address is in E.164 format, the Address/Number Digits 
appear in the order in which they would be entered on a numeric keypad.  
Digits are coded in IA5 characters with the leftmost bit of each digit set to 
0.  This ATM address appears in ATM End System Address Octets field 
(AESA format) or the Address/Number Digits field (E.164 format) of the 
Called party number information element [ATMUNI3.1]. Subaddress 
information is intentionally not included because E.164 subaddress 
information is used for routing.    
 
 ATMA RRs cause no additional section processing.
 
 Other ATM specific resource records can be added in future releases of this 
specification.
 
5.3 ATM Address to Domain Name Mapping
 
 The PTR RR is defined in [RFC1035]. This RR is typically used under the IN-
ADDR.ARPA domain to map from IPv4 addresses to domain names.
 
 Similarly, the PTR RR is used to map from ATM addresses to domain names 
under the ATMA.INT domain. A domain name is generated from the ATM 
address according to the rules described below. A query is sent by the resolver 
requesting a PTR RR for the provided domain name.
 
 A domain name is generated from an AESA formatted ATM address by 
concatenating from left to right the following substrings and separating them by a 
.  character from each other:
 
? the SEL field
 
? the ESI field
 
? the digits of the HO-DSP field in reverse order and separated by a . 
character from each other 
 
? the DCC, ICD, or E.164 field
 
? the AFI field
 
? the top level subdomain AESA.ATMA.INT.
 
 For example, the domain name used in the reverse lookup for the ATM address
 
 39246f000e7c9c03120001000100001234567800
 
 would appear as
 
 00.000012345678.1.0.0.0.1.0.0.0.2.1.3.0.c.9.c.7.e.0.0.0.246f.39.AE
SA.ATMA.INT.
 
 A domain name is generated from an E.164 formatted ATM address by 
concatenating from left to right the following substrings and by separating them 
with a . character.
 
? the digits of the country code national significant numbers in reverse order 
and separated by a . character from each other
 
? the top level subdomain E164.ATMA.INT.

 
 For example, the domain name used in the reverse lookup for the E.164
 number
 
 	3584001234567
 
 would appear as
 
 	7.6.5.4.3.2.1.0.0.4.358.E164.ATMA.INT.
 
 Implementation note: For sanity's sake user interfaces should be designed to allow 
users to enter ATM addresses using their natural order, that is, as they are 
typically written on paper. Also, arbitrary .s should be allowed (and ignored) on 
input.
 
5.4 Example Master File Format

	This section describes an example master file format.  Note that other formats are 
	possible.
 
 	The format of AESA RRs in Master Files conforms to Section 5, "Master 
Files," of [RFC1035]. 
 
 The RDATA section of an A line in a master file is expressed as follows:
 
 AESA formatted ATM address: a string of hexadecimal digits.  A . 
character can be used to separate any two digits for readability.  The string 
is case insensitive.  For example:  
 
 39.246f.00.0e7c9c.0312.0001.0001.000012345678.00
 
 E.164 formatted ATM address: a + character followed by a string of 
decimal digits that form an international E.164 number.  A . character 
can be used to separate any two digits for readability.  For example:
 
 	+358.400.123456


 
 Below are examples of the use of ATMA and PTR RRs in Master Files to support 
name to ATM address and ATM address to name mapping.
 
 
       ;;;;;;
    ;;;;;; Master File for domain data.example.com.
    ;;;;;;
 
    @      IN    SOA    name1.data.example.com.  name4.data.example.com. (
                                      1994041800   ; Serial  - date
                                      1800         ; Refresh - 30 minutes
                                      300          ; Retry   - 5 minutes
                                      604800       ; Expire  - 7 days
                                      3600 )       ; Minimum - 1 hour
           IN    NS     name1.data.example.com.
           IN    NS     ns.example.com.
    ;
    $ORIGIN data.example.com.
    salmon IN    ATMA   39.246f.000e7c9c031200010001.000012345678.00
    char   IN    ATMA   39.246f.000e7c9c031200010001.000023456789.00
 
    ;;;;;;
    ;;;;;; Master File for reverse mapping of ATM addresses under the
    ;;;;;; prefix 39.246f.000e7c9c031200010001
    ;;;;;;
 
    @      IN    SOA    name1.data.example.com.  name4.data.example.com. (
                                      1994041800   ; Serial  - date
                                      1800         ; Refresh - 30 minutes
                                      300          ; Retry   - 5 minutes
                                      604800       ; Expire  - 7 days
                                      3600 )       ; Minimum - 1 hour
           IN    NS     name1.data.example.com.
           IN    NS     ns.example.com.
    ;
    $ORIGIN 1.0.0.0.1.0.0.0.2.1.3.0.c.9.c.7.e.0.0.0.246f.39.AESA.atm.int.
    00.000012345678      IN      PTR     salmon.data.example.com.
    00.000012345679      IN      PTR     char.data.example.com.
 
6. DNS Protocol in ATM Environment
 
 The DNS assumes that protocol messages will be transmitted as datagrams or in a 
byte stream carried by a virtual circuit.  Datagrams are preferred for queries and 
responses due to their lower overhead.  Zone refresh activities (query type AXFR)  
must use reliable virtual connections.
 
 Since ATM networks do not support datagram services, ANS queries and 
responses must be carried over ATM virtual connections established between the 
clients and the servers. In version 1.0, the servers use TCP to reliably 
communicate among themselves. 

 
6.1 Recursive Processing 
 
 By default, ANS clients, when they make queries, request recursive processing of the 
query (by setting the RD bit to 1 in the header of the query).   ANS name servers 
must support recursion.  If the server gives the client a referral, then it can happen 
that the client does not have ATM connectivity to the next server.
 
6.2 Client Initialization
 
 When a client becomes operational, initially it needs to find the ATM addresses of 
one or more ANS servers.  ANS clients use one of two mechanisms to locate the 
ATM address of ANS servers:
 
? Get the ANS server addresses via ILMI.
 
? Use a well-known ANS Address.
 
 Getting ANS server addresses via ILMI is accomplished by defining a new type 
value for the atmfSrvcRegTypes ILMI object that denotes ANS server:
 
 -- ANS Server
 atmfSrvcRegAnsServer    OBJECT IDENTIFIER ::= { atmfSrvcRegTypes 2 }
 
 If an ANS server address cannot be obtained from ILMI or if the client is unable 
to establish a VC to any ILMI supplied server address, then a well-known address 
may be used.  The  well known address is 
02C5007900000000000000000000.00A03E000002.00.
 
6.3 Connection Usage
 
 After learning the ATM address of one or more ANS servers, an ANS client may 
setup a connection to any one of the servers for sending ANS requests and 
receiving ANS responses.  The client sets up and releases the connection 
dynamically using the UNI signaling protocol accessed through an API whose 
semantics are specified by [ATMNAS].  The client should time-out after some 
period of inactivity and release this connection.  The server may release an 
inactive connection so that the server can provide services to other clients.  
Neither the server nor the client shall attribute any special significance to a 
disconnection indication.
7. Native ATM Services Interface

The ANS client and ANS server access the ATM network via an API whose 
semantics are specified by [ATMNAS].  The Native ATM Services connection 
attributes used for communications between an ANS client and an ANS server are 
shown in the table below:

Attribute Name
Attribute Value
AAL_TYPE
AAL type 5
AAL5_FWD_MAX_SDU
512 bytes
AAL5_BAK_MAX_SDU
512 bytes
AAL5_SSCS_TYPE
Null
FWD_PCR_CLP1
line rate in cells per second
BAK_PCR_CLP1
line rate in cells per second
BEST_EFFORT
best effort requested
BEARER_CLASS
class X  (BCOB-X)
TRAFFIC_TYPE
no indication
TIME_REQ
no indication
CLIPPING_IND
not susceptable to clipping
CONNECT_CONFIG
point-to-point connection
APPL_ID_TYPE
vendor-specific application ID
APPL_ID
The OUI (BHLI octets 6-8) is 0x00A03E.
The application ID (BHLI octets 9-12) is 
0x00000001.
CALLED_ADDR_FORMAT
either private or public address format
CALLED_ADDR
ATM address of DNS server
CALLED_SUBADDR_TYPE
private subaddress format, if required
CALLED_SUBADDR
ATM subaddress of DNS server, if required
FWD_QOS_CLASS
QoS class 0
BAK_QOS_CLASS
QoS class 0
SSCS
Null
The following elements form a SAP address for the DNS server:
? ATM address, including the selector byte
? DNS application identification  (carried in the BHLI information element)
Note that both layer-2 protocol identification and layer-3 protocol identification 
are ABSENT.


8. ATM Directory Service Interface

The basic API functions for access to ATM directory services are expected to be 
made through calls to an API that includes a service to obtain a ATM address 
given a domain name and a service to obtain a domain name given an ATM 
address.  An  example of an API that could be used as a starting point is the one 
provided by the UNIX operating system [BSD4.3] and described in informative 
Appendix B.  The example API provides gethostbyname_atmnsap and 
gethostbyname_E164 services that accept  host names as input and returns 
ANS database information about those host names.  The returned information 
includes the host address type, host address length and host address, and may 
include other information such as a list of alias names for that host.  The example 
API also provides a gethostbyaddr service that expects a host address type, 
host address length and host address as input.  This service returns at least the host 
address name and optionally may return other ANS information as well.            

9. References 
 

[ATMNAS]
ATM Forum Technical Committee, Native ATM Services: Semantic 
Description, Version 1.0, af-saa-0048-000, ATM Forum, January, 1996  

[ATMUNI3.1]
ATM Forum Technical Committee, ATM User-Network Interface (UNI) 
Specification, Version 3.1, ISBN 0-13-393828-X, ATM Forum, 1994  

[BSD4.3]  S. J. Leffler, M. K. McKusick, M. Karels,
The Design and Implementation of the 4.3 BSD Unix Operating System, 1989

[RFC1034]
P. Mockapetris, "Domain Names - Concepts and Facilities", RFC 
USC/Information Sciences Institute, November 1987.

[RFC1035]
P. Mockapetris, "Domain Names - Implementation and Specification", RFC 1035, 
USC/Information Sciences Institute, November 1987.

[RFC1700]
J. Reynolds and J. Postel, "Assigned Numbers", RFC 1700, ISI, October 1994.

[RFC1706]
B. Manning and R. Colella, "DNS NSAP Resource Records", RFC 1706, 
ISI/NIST, October 1994.


?????????A? Requirements 

This informative appendix captures the SAA/DS working groups requirements.
??1 Basing of ANS on DNS
 
 The ANS is based on the Domain Name Service (DNS) [RFC1034], 
[RFC1035].  Subsequent versions may include IETF enhancements for  
security, dynamic updates, prompt notification of zone changes and 
incremental zone transfer capability extensions.  There are many reasons 
to use DNS as the basis for ANS.
 
I. DNS is widely implemented in end systems.
II. DNS domain registration procedure has been implemented in most 
countries.
III. DNS domain names are well known by the user community.
IV. DNS can scale well if the name space is properly assigned. This 
satisfies the scalability requirement given in A.2.
V. DNS implementations are efficient in terms of CPU and memory 
usage.  This satisfies the efficiency requirement given in A.2.
VI. DNS is resilient via the secondary server mechanism. This satisfies 
the no single point of failure requirement given in A.2.
VII. DNS has low latency of queries. This satisfies the requirement 
given in 2.1.4.
VIII. DNS extensions for dynamic updates and security are being 
worked on.
IX. DNS can be easily augmented with new database objects for ATM.
X. DNS allows dual hosts to choose between IP and native ATM.
??? ANS requirements  
 
 Several requirements for the directory service function that apply to ANS are:
 
? No single point of failure (resilience)
? efficient implementation including storage efficiency
? Hierarchical naming structure (scalability)
? low latency of queries
? Toleration of temporary inconsistency, that is, that such 
inconsistency does not damage the information in ANS.
? The service may sometimes be transiently unavailability, for 
example, a busy signal 
 
 Other ANS requirements include:
 
? Independence between non-ATM network and transport layer 
protocols 
 
 ANS is to be used by ATM applications.  These applications may 
not necessarily implement non-ATM network or transport 
protocols.  Most current DNS implementations carry DNS protocol 
messages on top of UDP/IP and TCP/IP.  This document specifies 
the operation of DNS protocols using native ATM services  instead 
of TCP/IP. 
 
? Use of an existing naming scheme 
 
 ANS should exploit an already existing naming scheme in the 
same way as ATM addressing utilizes existing addressing 
schemes.  Otherwise the ATM Forum would need to setup a new, 
worldwide name registration service, which would be a difficult 
task to manage and operate.  Examples of existing naming schemes 
are the Internets DNS domain name hierarchy and X.500s 
directory information tree hierarchy.
 
? Dynamic updating of the directory data base
 
 When an ATM end system address changes, it is important that the 
ANS database need not be manually reconfigured.  The end system 
should be able to dynamically check and update its address 
information in the ANS database.  This is especially important 
when the end user does not even necessarily know that an ATM 
address of the end system has changed.  (For example, a manager 
of the switch could change the address prefix without notifying the 
users.) 
? Security of the dynamic updating process
 
 Dynamic updating of the ANS database by end systems usually 
requires that the updates can be authenticated. ANS must therefore 
include an option to sign the ANS database entries with 
cryptographic digital signatures.  It would also be desirable if ANS 
could store authenticated public keys in its database in order to 
make the ANS protocol independent of yet another public key 
management protocol.
 
? Automatic configuration of ANS clients
 
Finally, automatic configuration of ANS clients is an important 
requirement.  In order to use directory services, the clients need to 
know one or more ATM addresses of one or more ANS servers. If 
security is implemented, an ANS client needs a correct public key 
of at least one zone of the hierarchical name space.  A natural 
solution is that ANS clients learn this information dynamically 
from an ATM configuration server.

?????????B? API Interface to ANS

This informative appendix shows an example or a BSD 4.3 compliant application 
program interface for ANS.

??? BSD 4.3 conformant interface
????? Specifications

The interface to ANS can conform to the BSD 4.3 interface used today to resolve IP 
protocol family addresses. It consist then of the following calls (defined here in the most 
common 'C'-syntax)

	extern int h_errno;

	struct hostent *gethostbyname_atmnsap(name)
	char *name;

	struct hostent *gethostbyname_e164(name)
	char *name;

	struct hostent *gethostbyaddr(addr, len, type)
	char *addr; int len, type;

	struct hostent *gethostent()

	sethostent(stayopen)
	int stayopen;

	endhostent()

	herror(string)
	char *string;

where

	struct    hostent 
      {
 	  char  *h_name;		/* official name of host */
	  char **h_aliases;	/* alias list */
	  int    h_addrtype;	/* host address type */
	  int    h_length;	/* length of address */
	  char **h_addr_list;	/* list of addresses from nameserver */
	};

#define h_addr h_addr_list[0] /* address, for backward compatibility */

The members of this structure are:

	h_name	Official name of the host.

	h_aliases	A zero terminated array of alternate names for the host.

	h_addrtype	The type of address being returned

	h_length	The length, in bytes, of the address.

	h_addr_list	A  zero terminated array of network addresses for the host.  Host 	
			addresses are returned in network byte order.

	h_addr	The first address in h_addr_list; this is for backward compatibility.

The sethostent, endhostent, gethostent, and herror calls are not modified. To 
support the remaining two routines the semantics of the structure hostent has to be 
extended by the newly supported address types because the component h_addrtype 
today always carries AF_INET as answer and the type argument of the gethostbyaddr 
function is supposed to be AF_INET in all cases as well. The necessary new specifications 
are two defines:

#define AF_ATMNSAP           3
#define AF_ATME164           8

where the values are usually specified in the file socket.h and should follow [RFC1700] 
as proposed in the definitions above. The call gethostbyname_e164 is supposed to return 
E.164 addresses and gethostbyname_atmnsap ATM-nsap addresses.

The h_length is set to the length of the addresses chained in h_addr_list.

Additionally, if a socket-like form of address conversion from human readable to internal 
forms in the API is supported, some new structures and functions may to be provided as 
existing in today's most BSD 4.3 implementations.

	struct atmnsap_addr
	{
	  char atmnsap[20];
	}
	
	struct atme164_addr
	{
  	  char atme164[20];
	}	

	struct atmnsap_addr *atmnsap_addr(const char *cp);
	char	*atmnsap_ntoa(struct atmnsap_addr in);

	struct atme164_addr *atme164_addr(const char *cp);
	char	*atme164_ntoa(struct atme164_addr in);

The returned and expected human readable strings conform to the form encountered in 
the master file and described in section 5.4. The returned structures must not be freed by 
the application and are not thread-safe.

????? IPng aligned interface

Since introduction of IPv6 included a new addressing scheme, the internet protocol next 
generation (IPNG) work in progress tries to address the issue of a new application 
programmer's interface, specifically of the name-resolving calls beside many others. 
These calls will support address family parameters so functions can be easily 
implemented to support AF_ATMNSAP and AF_ATME164 as well. Extended functions for 
address to ASCII conversions and vice versa translation can also be found in this work.

????? WinSock 2 aligned interface

WinSock 1.1 supported a BSD 4.3 compliant interface for name resolution very much as 
the one described in section B.1.1, so the functions proposed there can be applied as well.  
Version 2 of the specification includes the protocol independent name resolution in the 
current version as an item for further study.




af-saa-0069.000		ATM Name System Specification Version 1.0
ATM Name System Specification Version 1.0	af-saa-0069.000		
Page 16		ATM Forum Technical Committee

ATM Forum Technical Committee		Page  15
