RFC 2705 - Media Gateway Control Protocol (MGCP) Version 1.0
(Formats: TXT)
Network Working Group M. Arango
Request for Comments: 2705 RSL COM
Category: Informational A. Dugan
I. Elliott
Level3 Communications
C. Huitema
Telcordia
S. Pickett
Vertical Networks
October 1999
|
Media Gateway Control Protocol (MGCP)
Version 1.0
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (1999). All Rights Reserved.
IESG NOTE:
This document is being published for the information of the
community. It describes a protocol that is currently being deployed
in a number of products. Implementers should be aware of
developments in the IETF Megaco Working Group and ITF-T SG16 who are
currently working on a potential successor to this protocol.
Abstract
This document describes an application programming interface and a
corresponding protocol (MGCP) for controlling Voice over IP (VoIP)
Gateways from external call control elements. MGCP assumes a call
control architecture where the call control "intelligence" is outside
the gateways and handled by external call control elements.
The document is structured in 6 main sections:
* The introduction presents the basic assumptions and the relation
to other protocols such as H.323, RTSP, SAP or SIP.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
* The interface section presents a conceptual overview of the MGCP,
presenting the naming conventions, the usage of the session
description protocol SDP, and the procedures that compose MGCP:
Notifications Request, Notification, Create Connection, Modify
Connection, Delete Connection, AuditEndpoint, AuditConnection and
RestartInProgress.
* The protocol description section presents the MGCP encodings,
which are based on simple text formats, and the transmission
procedure over UDP.
* The security section presents the security requirement of MGCP,
and its usage of IP security services (IPSEC).
* The event packages section provides an initial definition of
packages and event names.
* The description of the changes made in combining SGCP 1.1 and IPDC
to create MGCP 1.0.
Table of Contents
1. Introduction .............................................. 5
1.1. Relation with the H.323 standards .................... 7
1.2. Relation with the IETF standards ..................... 8
1.3. Definitions .......................................... 9
2. Media Gateway Control Interface ........................... 9
2.1. Model and naming conventions. ........................ 10
2.1.1. Types of endpoints .............................. 10
2.1.1.1. Digital channel (DS0) ...................... 11
2.1.1.2. Analog line ................................ 11
2.1.1.3. Annoucement server access point ............ 12
2.1.1.4. Interactive Voice Response access point .... 12
2.1.1.5. Conference bridge access point ............. 13
2.1.1.6. Packet relay ............................... 13
2.1.1.7. Wiretap access point ....................... 14
2.1.1.8. ATM "trunk side" interface. ................ 14
2.1.2. Endpoint identifiers ............................ 15
2.1.3. Calls and connections ........................... 17
2.1.3.1. Names of calls ............................. 20
2.1.3.2. Names of connections ....................... 20
2.1.3.3. Management of resources, attributes of ..... 20
2.1.3.4. Special case of local connections .......... 23
2.1.4. Names of Call Agents and other entities ......... 23
2.1.5. Digit maps ...................................... 24
2.1.6. Names of events ................................. 26
2.2. Usage of SDP ......................................... 29
2.3. Gateway Control Commands ............................. 30
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
2.3.1. EndpointConfiguration ........................... 32
2.3.2. NotificationRequest ............................. 33
2.3.3. CreateConnection ................................ 38
2.3.4. ModifyConnection ................................ 44
2.3.5. DeleteConnection (from the Call Agent) .......... 46
2.3.6. DeleteConnection (from the VoIP gateway) ........ 51
2.3.7. DeleteConnection (multiple connections, from the 51
2.3.8. Audit Endpoint .................................. 52
2.3.9. Audit Connection ................................ 55
2.3.10. Restart in progress ............................ 56
2.4. Return codes and error codes. ........................ 58
2.5. Reason Codes ......................................... 61
3. Media Gateway Control Protocol ............................ 61
3.1. General description .................................. 62
3.2. Command Header ....................................... 62
3.2.1. Command line .................................... 62
3.2.1.1. Coding of the requested verb ............... 63
3.2.1.2. Transaction Identifiers .................... 63
3.2.1.3. Coding of the endpoint identifiers and ..... 64
3.2.1.4. Coding of the protocol version ............. 65
3.2.2. Parameter lines ................................. 65
3.2.2.1. Response Acknowledgement ................... 68
3.2.2.2. Local connection options ................... 68
3.2.2.3. Capabilities ............................... 70
3.2.2.4. Connection parameters ...................... 71
3.2.2.5. Reason Codes ............................... 72
3.2.2.6. Connection mode ............................ 73
3.2.2.7. Coding of event names ...................... 73
3.2.2.8. RequestedEvents ............................ 74
3.2.2.9. SignalRequests ............................. 76
3.2.2.10. ObservedEvent ............................. 76
3.2.2.11. RequestedInfo ............................. 76
3.2.2.12. QuarantineHandling ........................ 77
3.2.2.13. DetectEvents .............................. 77
3.2.2.14. EventStates ............................... 77
3.2.2.15. RestartMethod ............................. 78
3.2.2.16. Bearer Information ........................ 78
3.3. Format of response headers ........................... 78
3.4. Formal syntax description of the protocol ............ 81
3.5. Encoding of the session description .................. 86
3.5.1. Usage of SDP for an audio service ............... 86
3.5.2. Usage of SDP in a network access service ........ 87
3.5.3. Usage of SDP for ATM connections ................ 90
3.5.4. Usage of SDP for local connections .............. 91
3.6. Transmission over UDP ................................ 91
3.6.1. Providing the At-Most-Once functionality ........ 91
3.6.2. Transaction identifiers and three ways handshake. 92
3.6.3. Computing retransmission timers ................. 93
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3.6.4. Piggy backing ................................... 94
3.6.5. Provisional responses ........................... 94
4. States, failover and race conditions. ..................... 95
4.1. Basic Asumptions ..................................... 95
4.2. Security, Retransmission, and Detection of Lost ...... 96
4.3. Race conditions ...................................... 99
4.3.1. Quarantine list ................................. 99
4.3.2. Explicit detection ..............................103
4.3.3. Ordering of commands, and treatment of disorder .104
4.3.4. Fighting the restart avalanche ..................105
4.3.5. Disconnected Endpoints ..........................107
1. A "disconnected" timer is initialized to a random value, .107
2. The gateway then waits for either the end of this timer, .107
3. When the "disconnected" timer elapses, when a command is .107
4. If the "disconnected" procedure still left the endpoint ..107
5. Security requirements .....................................108
5.1. Protection of media connections ......................109
6. Event packages and end point types ........................109
6.1. Basic packages .......................................110
6.1.1. Generic Media Package ...........................110
6.1.2. DTMF package ....................................112
6.1.3. MF Package ......................................113
6.1.4. Trunk Package ...................................114
6.1.5. Line Package ....................................116
6.1.6. Handset emulation package .......................119
6.1.7. RTP Package .....................................120
6.1.8. Network Access Server Package ...................121
6.1.9. Announcement Server Package .....................122
6.1.10. Script Package .................................122
6.2. Basic endpoint types and profiles ....................123
7. Versions and compatibility ................................124
7.1. Differences between version 1.0 and draft 0.5 ........124
7.2. Differences between draft-04 and draft-05 ............125
7.3. Differences between draft-03 and draft-04 ............125
7.4. Differences between draft-02 and draft-03 ............125
7.5. Differences between draft-01 and draft-02 ............126
7.6. The making of MGCP from IPDC and SGCP ................126
7.7. Changes between MGCP and initial versions of SGCP ....126
8. Security Considerations ...................................128
9. Acknowledgements ..........................................128
10. References ................................................129
11. Authors' Addresses ........................................130
12. Appendix A: Proposed "MoveConnection" command .............132
12.1. Proposed syntax modification ........................133
13. Full Copyright Statement ..................................134
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
1. Introduction
This document describes an abstract application programming interface
and a corresponding protocol (MGCP) for controlling Telephony
Gateways from external call control elements called media gateway
controllers or call agents. A telephony gateway is a network element
that provides conversion between the audio signals carried on
telephone circuits and data packets carried over the Internet or over
other packet networks. Example of gateways are:
* Trunking gateways, that interface between the telephone network
and a Voice over IP network. Such gateways typically manage a
large number of digital circuits.
* Voice over ATM gateways, which operate much the same way as voice
over IP trunking gateways, except that they interface to an ATM
network.
* Residential gateways, that provide a traditional analog (RJ11)
interface to a Voice over IP network. Examples of residential
gateways include cable modem/cable set-top boxes, xDSL devices,
broad-band wireless devices
* Access gateways, that provide a traditional analog (RJ11) or
digital PBX interface to a Voice over IP network. Examples of
access gateways include small-scale voice over IP gateways.
* Business gateways, that provide a traditional digital PBX
interface or an integrated "soft PBX" interface to a Voice over IP
network.
* Network Access Servers, that can attach a "modem" to a telephone
circuit and provide data access to the Internet. We expect that,
in the future, the same gateways will combine Voice over IP
services and Network Access services.
* Circuit switches, or packet switches, which can offer a control
interface to an external call control element.
MGCP assumes a call control architecture where the call control
"intelligence" is outside the gateways and handled by external call
control elements. The MGCP assumes that these call control elements,
or Call Agents, will synchronize with each other to send coherent
commands to the gateways under their control. MGCP does not define a
mechanism for synchronizing Call Agents. MGCP is, in essence, a
master/slave protocol, where the gateways are expected to execute
commands sent by the Call Agents. In consequence, this document
specifies in great detail the expected behavior of the gateways, but
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only specify those parts of a call agent implementation, such as
timer management, that are mandated for proper operation of the
protocol.
MGCP assumes a connection model where the basic constructs are
endpoints and connections. Endpoints are sources or sinks of data and
could be physical or virtual. Examples of physical endpoints are:
* An interface on a gateway that terminates a trunk connected to a
PSTN switch (e.g., Class 5, Class 4, etc.). A gateway that
terminates trunks is called a trunk gateway.
* An interface on a gateway that terminates an analog POTS
connection to a phone, key system, PBX, etc. A gateway that
terminates residential POTS lines (to phones) is called a
residential gateway.
An example of a virtual endpoint is an audio source in an audio-
content server. Creation of physical endpoints requires hardware
installation, while creation of virtual endpoints can be done by
software.
Connections may be either point to point or multipoint. A point to
point connection is an association between two endpoints with the
purpose of transmitting data between these endpoints. Once this
association is established for both endpoints, data transfer between
these endpoints can take place. A multipoint connection is
established by connecting the endpoint to a multipoint session.
Connections can be established over several types of bearer networks:
* Transmission of audio packets using RTP and UDP over a TCP/IP
network.
* Transmission of audio packets using AAL2, or another adaptation
layer, over an ATM network.
* Transmission of packets over an internal connection, for example
the TDM backplane or the interconnection bus of a gateway. This is
used, in particular, for "hairpin" connections, connections that
terminate in a gateway but are immediately rerouted over the
telephone network.
For point-to-point connections the endpoints of a connection could be
in separate gateways or in the same gateway.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
1.1. Relation with the H.323 standards
MGCP is designed as an internal protocol within a distributed system
that appears to the outside as a single VoIP gateway. This system is
composed of a Call Agent, that may or may not be distributed over
several computer platforms, and of a set of gateways, including at
least one "media gateway" that perform the conversion of media
signals between circuits and packets, and at least one "signalling
gateway" when connecting to an SS7 controlled network. In a typical
configuration, this distributed gateway system will interface on one
side with one or more telephony (i.e. circuit) switches, and on the
other side with H.323 conformant systems, as indicated in the
following table:
___________________________________________________________________
| Functional| Phone | Terminating | H.323 conformant |
| Plane | switch | Entity | systems |
|___________|____________|_________________|_______________________|
| Signaling | Signaling | Call agent | Signaling exchanges |
| Plane | exchanges | | with the call agent |
| | through | | through H.225/RAS and|
| | SS7/ISUP | | H.225/Q.931. |
|___________|____________|_________________|_______________________|
| | | | Possible negotiation |
| | | | of logical channels |
| | | | and transmission |
| | | | parameters through |
| | | | H.245 with the call |
| | | | agent. |
|___________|____________|_________________|_______________________|
| | | Internal | |
| | | synchronization| |
| | | through MGCP | |
|___________|____________|_________________|_______________________|
| Bearer | Connection| Telephony | Transmission of VOIP |
| Data | through | gateways | data using RTP |
| Transport | high speed| | directly between the |
| Plane | trunk | | H.323 station and the|
| | groups | | gateway. |
|___________|____________|_________________|_______________________|
In the MGCP model, the gateways focus on the audio signal translation
function, while the Call Agent handles the signaling and call
processing functions. As a consequence, the Call Agent implements the
"signaling" layers of the H.323 standard, and presents itself as an
"H.323 Gatekeeper" or as one or more "H.323 Endpoints" to the H.323
systems.
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1.2. Relation with the IETF standards
While H.323 is the recognized standard for VoIP terminals, the IETF
has also produced specifications for other types of multi-media
applications. These other specifications include:
* the Session Description Protocol (SDP), RFC 2327,
* the Session Announcement Protocol (SAP),
* the Session Initiation Protocol (SIP),
* the Real Time Streaming Protocol (RTSP), RFC 2326.
The latter three specifications are in fact alternative signaling
standards that allow for the transmission of a session description to
an interested party. SAP is used by multicast session managers to
distribute a multicast session description to a large group of
recipients, SIP is used to invite an individual user to take part in
a point-to-point or unicast session, RTSP is used to interface a
server that provides real time data. In all three cases, the session
description is described according to SDP; when audio is transmitted,
it is transmitted through the Real-time Transport Protocol, RTP.
The distributed gateway systems and MGCP will enable PSTN telephony
users to access sessions set up using SAP, SIP or RTSP. The Call
Agent provides for signaling conversion, according to the following
table:
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
_____________________________________________________________________
| Functional| Phone | Terminating | IETF conforming systems|
| Plane | switch | Entity | |
|___________|____________|_________________|_________________________|
| Signaling | Signaling | Call agent | Signaling exchanges |
| Plane | exchanges | | with the call agent |
| | through | | through SAP, SIP or |
| | SS7/ISUP | | RTSP. |
|___________|____________|_________________|_________________________|
| | | | Negotiation of session |
| | | | description parameters |
| | | | through SDP (telephony |
| | | | gateway terminated but |
| | | | passed via the call |
| | | | agent to and from the |
| | | | IETF conforming system)|
|___________|____________|_________________|_________________________|
| | | Internal | |
| | | synchronization| |
| | | through MGCP | |
|___________|____________|_________________|_________________________|
| Bearer | Connection| Telephony | Transmission of VoIP |
| Data | through | gateways | data using RTP, |
| Transport | high speed| | directly between the |
| Plane | trunk | | remote IP end system |
| | groups | | and the gateway. |
|___________|____________|_________________|_________________________|
The SDP standard has a pivotal status in this architecture. We will
see in the following description that we also use it to carry session
descriptions in MGCP.
1.3. Definitions
Trunk: A communication channel between two switching systems. E.g., a
DS0 on a T1 or E1 line.
2. Media Gateway Control Interface
The interface functions provide for connection control and endpoint
control. Both use the same system model and the same naming
conventions.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
2.1. Model and naming conventions
The MGCP assumes a connection model where the basic constructs are
endpoints and connections. Connections are grouped in calls. One or
more connections can belong to one call. Connections and calls are
set up at the initiative of one or several Call Agents.
2.1.1. Types of endpoints
In the introduction, we presented several classes of gateways. Such
classifications, however, can be misleading. Manufacturers can
arbitrarily decide to provide several types of services in a single
packaging. A single product could well, for example, provide some
trunk connections to telephony switches, some primary rate
connections and some analog line interfaces, thus sharing the
characteristics of what we described in the introduction as
"trunking", "access" and "residential" gateways. MGCP does not make
assumptions about such groupings. We simply assume that media
gateways support collections of endpoints. The type of the endpoint
determines its functionalities. Our analysis, so far, has led us to
isolate the following basic endpoint types:
* Digital channel (DS0),
* Analog line,
* Annoucement server access point,
* Interactive Voice Response access point,
* Conference bridge access point,
* Packet relay,
* Wiretap access point,
* ATM "trunk side" interface.
In this section, we will develop the expected behavior of such end
points.
This list is not limitative. There may be other types of endpoints
defined in the future, for example test endpoint that could be used
to check network quality, or frame-relay endpoints that could be used
to managed audio channels multiplexed over a frame-relay virtual
circuit.
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2.1.1.1. Digital channel (DS0)
Digital channels provide an 8Khz*8bit service. Such channels are
found in trunk and ISDN interfaces. They are typically part of
digital multiplexes, such as T1, E1, T3 or E3 interfaces. Media
gateways that support such channels are capable of translating the
digital signals received on the channel, which may be encoded
according to A or mu-law, using either the complete set of 8 bits or
only 7 of these bits, into audio packets. When the media gateway
also supports a NAS service, the gateway shall be capable of
receiving either audio-encoded data (modem connection) or binary data
(ISDN connection) and convert them into data packets.
+-------
+------------+|
(channel) ===|DS0 endpoint| -------- Connections
+------------+|
+-------
Media gateways should be able to establish several connections
between the endpoint and the packet networks, or between the endpoint
and other endpoints in the same gateway. The signals originating
from these connections shall be mixed according to the connection
"mode", as specified later in this document. The precise number of
connections that an endpoint support is a characteristic of the
gateway, and may in fact vary according with the allocation of
resource within the gateway.
In some cases, digital channels are used to carry signalling. This
is the case for example of SS7 "F" links, or ISDN "D" channels.
Media gateways that support these signalling functions shall be able
to send and receive the signalling packets to and from a call agent,
using the "back haul" procedures defined by the SIGTRAN working group
of the IETF. Digital channels are sometimes used in conjunction with
channel associated signalling, such as "MF R2". Media gateways that
support these signalling functions shall be able to detect and
produce the corresponding signals, such as for example "wink" or "A",
according to the event signalling and reporting procedures defined in
MGCP.
2.1.1.2. Analog line
Analog lines can be used either as a "client" interface, providing
service to a classic telephone unit, or as a "service" interface,
allowing the gateway to send and receive analog calls. When the
media gateway also supports a NAS service, the gateway shall be
capable of receiving audio-encoded data (modem connection) and
convert them into data packets.
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+-------
+---------------+|
(line) ===|analog endpoint| -------- Connections
+---------------+|
+-------
Media gateways should be able to establish several connections
between the endpoint and the packet networks, or between the endpoint
and other endpoints in the same gateway. The audio signals
originating from these connections shall be mixed according to the
connection "mode", as specified later in this document. The precise
number of connections that an endpoint support is a characteristic of
the gateway, and may in fact vary according with the allocation of
resource within the gateway. A typical gateway should however be
able to support two or three connections per endpoint, in order to
provide services such as "call waiting" or "three ways calling".
2.1.1.3. Annoucement server access point
An announcement server endpoint provides acces to an announcement
service. Under requests from the call agent, the announcement server
will "play" a specified announcement. The requests from the call
agent will follow the event signalling and reporting procedures
defined in MGCP.
+----------------------+
| Announcement endpoint| -------- Connection
+----------------------+
A given announcement endpoint is not supposed to support more than
one connection at a time. If several connections were established to
the same endpoint, then the same announcements would be played
simultaneously over all the connections.
Connections to an announcement server are typically oneway, or "half
duplex" -- the announcement server is not expected to listen the
audio signals from the connection.
2.1.1.4. Interactive Voice Response access point
An Interactive Voice Response (IVR) endpoint provides acces to an IVR
service. Under requests from the call agent, the IVR server will
"play" announcements and tones, and will "listen" to responses from
the user. The requests from the call agent will follow the event
signalling and reporting procedures defined in MGCP.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
+-------------+
| IVR endpoint| -------- Connection
+-------------+
A given IVR endpoint is not supposed to support more than one
connection at a time. If several connections were established to the
same endpoint, then the same tones and announcements would be played
simultaneously over all the connections.
2.1.1.5. Conference bridge access point
A conference bridge endpoint is used to provide access to a specific
conference.
+-------
+--------------------------+|
|Conference bridge endpoint| -------- Connections
+--------------------------+|
+-------
Media gateways should be able to establish several connections
between the endpoint and the packet networks, or between the endpoint
and other endpoints in the same gateway. The signals originating
from these connections shall be mixed according to the connection
"mode", as specified later in this document. The precise number of
connections that an endpoint support is a characteristic of the
gateway, and may in fact vary according with the allocation of
resource within the gateway.
2.1.1.6. Packet relay
A packet relay endpoint is a specific form of conference bridge, that
typically only supports two connections. Packets relays can be found
in firewalls between a protected and an open network, or in
transcoding servers used to provide interoperation between
incompatible gateways, for example gateways that do not support
compatible compression algorithms, or gateways that operate over
different transmission networks such as IP and ATM.
+-------
+---------------------+ |
|Packet relay endpoint| 2 connections
+---------------------+ |
+-------
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
2.1.1.7. Wiretap access point
A wiretap access point provides access to a wiretap service,
providing either a recording or a life playback of a connection.
+-----------------+
| Wiretap endpoint| -------- Connection
+-----------------+
A given wiretap endpoint is not supposed to support more than one
connection at a time. If several connections were established to the
same endpoint, then the recording or playback would mix the audio
signals received on this connections.
Connections to an wiretap endpoint are typically oneway, or "half
duplex" -- the wiretap server is not expected to signal its presence
in a call.
2.1.1.8. ATM "trunk side" interface.
ATM "trunk side" endpoints are typically found when one or several
ATM permanent virtual circuits are used as a replacement for the
classic "TDM" trunks linking switches. When ATM/AAL2 is used,
several trunks or channels are multiplexed on a single virtual
circuit; each of these trunks correspond to a single endpoint.
+-------
+------------------+|
(channel) = |ATM trunk endpoint| -------- Connections
+------------------+|
+-------
Media gateways should be able to establish several connections
between the endpoint and the packet networks, or between the endpoint
and other endpoints in the same gateway. The signals originating
from these connections shall be mixed according to the connection
"mode", as specified later in this document. The precise number of
connections that an endpoint support is a characteristic of the
gateway, and may in fact vary according with the allocation of
resource within the gateway.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
2.1.2. Endpoint identifiers
Endpoints identifiers have two components that both are case
insensitive:
* the domain name of the gateway that is managing the endpoint,
* a local name within that gateway,
The syntax of the local name depends on the type of endpoint being
named. However, the local name for each of these types is naturally
hierarchical, beginning with a term which identifies the physical
gateway containing the given endpoint and ending in a term which
specifies the individual endpoint concerned. With this in mind, the
following rules for construction and interpretation of the Entity
Name field for these entity types MUST be supported:
1) The individual terms of the naming path MUST be separated by a
single slash ("/", ASCII 2F hex).
2) The individual terms are character strings composed of letters,
digits or other printable characters, with the exception of
characters used as delimitors ("/", "@"), characters used for
wildcarding ("*", "$") and white spaces.
3) Wild-carding is represented either by an asterisk ("*") or a
dollar sign ("$") for the terms of the naming path which are to be
wild-carded. Thus, if the full naming path looks like
term1/term2/term3
then the Entity Name field looks like this depending on which
terms are wild-carded:
*/term2/term3 if term1 is wild-carded
term1/*/term3 if term2 is wild-carded
term1/term2/* if term3 is wild-carded
term1/*/* if term2 and term3 are wild-carded,
etc.
In each of these examples a dollar sign could have appeared
instead of an asterisk.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
4) A term represented by an asterisk is to be interpreted as: "use
ALL values of this term known within the scope of the Media
Gateway". A term represented by a dollar sign is to be
interpreted as: "use ANY ONE value of this term known within the
scope of the Media Gateway". The description of a specific
command may add further criteria for selection within the general
rules given here.
If the Media Gateway controls multiple physical gateways, the first
term of the naming MUST identify the physical gateway containing the
desired entity. If the Media Gateway controls only a single physical
gateway, the first term of the naming string MAY identify that
physical gateway, depending on local practice. A local name that is
composed of only a wildcard character refers to either all (*) or any
($) endpoints within the media gateway.
In the case of trunking gateways, endpoints are trunk circuits
linking a gateway to a telephone switch. These circuits are typically
grouped into a digital multiplex, that is connected to the gateway by
a physical interface. Such circuits are named in three contexts:
* In the ISUP protocol, trunks are grouped into trunk groups,
identified by the SS7 point codes of the switches that the group
connects. Circuits within a trunk group are identified by a
circuit number (CIC in ISUP).
* In the gateway configuration files, physical interfaces are
typically identified by the name of the interface, an arbitrary
text string. When the interface multiplexes several circuits,
individual circuits are typically identified by a circuit number.
* In MGCP, the endpoints are identified by an endpoint identifier.
The Call Agents use configuration databases to map ranges of circuit
numbers within an ISUP trunk group to corresponding ranges of
circuits in a multiplex connected to a gateway through a physical
interface. The gateway will be identified, in MGCP, by a domain name.
The local name will be structured to encode both the name of the
physical interface, for example X35V3+A4, and the circuit number
within the multiplex connected to the interface, for example 13. The
circuit number will be separated from the name of the interface by a
fraction bar, as in:
X35V3+A4/13
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Other types of endpoints will use different conventions. For example,
in gateways were physical interfaces by construction only control one
circuit, the circuit number will be omitted. The exact syntax of such
names should be specified in the corresponding server specification.
2.1.3. Calls and connections
Connections are created on the call agent on each endpoint that will
be involved in the "call." In the classic example of a connection
between two "DS0" endpoints (EP1 and EP2), the call agents
controlling the end points will establish two connections (C1 and
C2):
+---+ +---+
(channel1) ===|EP1|--(C1)--... ...(C2)--|EP2|===(channel2)
+---+ +---+
Each connection will be designated locally by a connection
identifier, and will be characterized by connection attributes.
When the two endpoints are located on gateways that are managed by
the same call agent, the creation is done via the three following
steps:
1) The call agent asks the first gateway to "create a connection" on
the first endpoint. The gateway allocates resources to that
connection, and respond to the command by providing a "session
description." The session description contains the information
necessary for a third party to send packets towards the newly
created connection, such as for example IP address, UDP port, and
packetization parameters.
2) The call agent then asks the second gateway to "create a
connection" on the second endpoint. The command carries the
"session description" provided by the first gateway. The gateway
allocates resources to that connection, and respond to the command
by providing its own "session description."
3) The call agent uses a "modify connection" command to provide this
second "session description" to the first endpoint. Once this is
done, communication can proceed in both directions.
When the two endpoints are located on gateways that are managed by
the different call agents, these two call agents shall exchange
information through a call-agent to call-agent signalling protocol,
in order to synchronize the creation of the connection on the two
endpoints.
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Once established, the connection parameters can be modified at any
time by a "modify connection" command. The call agent may for
example instruct the gateway to change the compression algorithm used
on a connection, or to modify the IP address and UDP port to which
data should be sent, if a connection is "redirected."
The call agent removes a connection by sending to the gateway a
"delete connection" command. The gateway may also, under some
circumstances, inform a gateway that a connection could not be
sustained.
The following diagram provides a view of the states of a connection,
as seen from the gateway:
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
Create connection
received
|
V
+-------------------+
|resource allocation|-(failed)-+
+-------------------+ |
| (connection refused)
(successful)
|
v
+----------->+
| |
| +-------------------+
| | remote session |
| | description |----------(yes)--------+
| | available ? | |
| +-------------------+ |
| | |
| (no) |
| | |
| +-----------+ +------+
| +--->| half open |------> Delete <-------| open |<----------+
| | | (wait) | Connection |(wait)| |
| | +-----------+ received +------+ |
| | | | | |
| | Modify Connection | Modify Connection |
| | received | received |
| | | | | |
| | +--------------------+ | +--------------------+ |
| | |assess modification | | |assess modification | |
| | +--------------------+ | +--------------------+ |
| | | | | | | |
| |(failed) (successful) | (failed) (successful) |
| | | | | | | |
| +<---+ | | +-------------+-------+
| | |
+<-------------------+ |
|
+-----------------+
| Free connection |
| resources. |
| Report. |
+-----------------+
|
V
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2.1.3.1. Names of calls
One of the attributes of each connection is the "call identifier."
Calls are identified by unique identifiers, independent of the
underlying platforms or agents. These identifiers are created by the
Call Agent. They are treated in MGCP as unstructured octet strings.
Call identifiers are expected to be unique within the system, or at a
minimum, unique within the collection of Call Agents that control the
same gateways. When a Call Agent builds several connections that
pertain to the same call, either on the same gateway or in different
gateways, these connections that belong to the same call share the
same call-id. This identifier can then be used by accounting or
management procedures, which are outside the scope of MGCP.
2.1.3.2. Names of connections
Connection identifiers are created by the gateway when it is
requested to create a connection. They identify the connection within
the context of an endpoint. They are treated in MGCP as unstructured
octet strings. The gateway should make sure that a proper waiting
period, at least 3 minutes, elapses between the end of a connection
that used this identifier and its use in a new connection for the
same endpoint. (Gateways may decide to use identifiers that are
unique within the context of the gateway.)
2.1.3.3. Management of resources, attributes of connections
Many types of resources will be associated to a connection, such as
specific signal processing functions or packetization functions.
Generally, these resources fall in two categories:
1) Externally visible resources, that affect the format of "the bits
on the network" and must be communicated to the second endpoint
involved in the connection.
2) Internal resources, that determine which signal is being sent over
the connection and how the received signals are processed by the
endpoint.
The resources allocated to a connection, and more generally the
handling of the connection, are chosen by the gateway under
instructions from the call agent. The call agent will provide these
instructions by sending two set of parameters to the gateway:
1) The local directives instruct the gateway on the choice of
resources that should be used for a connection,
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2) When available, the "session description" provided by the other
end of the connection.
The local directives specify such parameters as the mode of the
connection (e.g. send only, send-receive), preferred coding or
packetization methods, usage of echo cancellation or silence
suppression. (A detailed list can be found in the specification of
the LocalConnectionOptions parameter of the CreateConnection
command.) For each of these parameters, the call agent can either
specify a value, a range of value, or no value at all. This allow
various implementations to implement various level of control, from a
very tight control where the call agent specifies minute details of
the connection handling to a very loose control where the call agent
only specifies broad guidelines, such as the maximum bandwidth, and
let the gateway choose the detailed values.
Based on the value of the local directives, the gateway will
determine the resources allocated to the connection. When this is
possible, the gateway will choose values that are in line with the
remote session description - but there is no absolute requirement
that the parameters be exactly the same.
Once the resource have been allocated, the gateway will compose a
"session description" that describes the way it intends to receive
packets. Note that the session description may in some cases present
a range of values. For example, if the gateway is ready to accept
one of several compression algorithm, it can provide a list of these
accepted algorithms.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
Local Directives
(from call agent 1)
|
V
+-------------+
| resources |
| allocation |
| (gateway 1) |
+-------------+
| |
V |
Local |
Parameters V
| Session
| Description Local Directives
| | (from call agent 2)
| +---> Transmission----+ |
| (CA to CA) | |
| V V
| +-------------+
| | resources |
| | allocation |
| | (gateway 2) |
| +-------------+
| | |
| | V
| | Local
| | Parameters
| Session
| Description
| +---- Transmission<---+
| | (CA to CA)
V V
+-------------+
| modification|
| (gateway 1) |
+-------------+
|
V
Local
Parameters
-- Information flow: local directives & session descriptions --
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
2.1.3.4. Special case of local connections
Large gateways include a large number of endpoints which are often of
different types. In some networks, we may often have to set-up
connections between endpoints that are located within the same
gateway. Examples of such connections may be:
* Connecting a trunk line to a wiretap device,
* Connecting a call to an Interactive Voice-Response unit,
* Connecting a call to a Conferencing unit,
* Routing a call from on endpoint to another, something often
described as a "hairpin" connection.
Local connections are much simpler to establish than network
connections. In most cases, the connection will be established
through some local interconnecting device, such as for example a TDM
bus.
When two endpoints are managed by the same gateway, it is possible to
specify the connection in a single command that conveys the name of
the two endpoints that will be connected. The command is essentially
a "Create Connection" command which includes the name of the second
endpoint in lieu of the "remote session description."
2.1.4. Names of Call Agents and other entities
The media gateway control protocol has been designed to allow the
implementation of redundant Call Agents, for enhanced network
reliability. This means that there is no fixed binding between
entities and hardware platforms or network interfaces.
Reliability can be improved by the following precautions:
* Entities such as endpoints or Call Agents are identified by their
domain name, not their network addresses. Several addresses can be
associated with a domain name. If a command or a response cannot
be forwarded to one of the network addresses, implementations
should retry the transmission using another address.
* Entities may move to another platform. The association between a
logical name (domain name) and the actual platform are kept in the
domain name service. Call Agents and Gateways should keep track of
the time-to-live of the record they read from the DNS. They should
query the DNS to refresh the information if the time to live has
expired.
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In addition to the indirection provided by the use of domain names
and the DNS, the concept of "notified entity" is central to
reliability and fail-over in MGCP. The "notified entity" for an
endpoint is the Call Agent currently controlling that endpoint. At
any point in time, an endpoint has one, and only one, "notified
entity" associated with it, and when the endpoint needs to send a
command to the Call Agent, it MUST send the command to the current
"notified entity" for which endpoint(s) the command pertains. Upon
startup, the "notified entity" MUST be set to a provisioned value.
Most commands sent by the Call Agent include the ability to
explicitly name the "notified entity" through the use of a
"NotifiedEntity" parameter. The "notified entity" will stay the same
until either a new "NotifiedEntity" parameter is received or the
endpoint reboots. If the "notified entity" for an endpoint is empty
or has not been set explicitly, the "notified entity" will then
default to the source address of the last connection handling command
or notification request received for the endpoint. Auditing will thus
not change the "notified entity."
2.1.5. Digit maps
The Call Agent can ask the gateway to collect digits dialed by the
user. This facility is intended to be used with residential gateways
to collect the numbers that a user dials; it may also be used with
trunking gateways and access gateways alike, to collect the access
codes, credit card numbers and other numbers requested by call
control services.
An alternative procedure is for the gateway to notify the Call Agent
of the dialed digits, as soon as they are dialed. However, such a
procedure generates a large number of interactions. It is preferable
to accumulate the dialed numbers in a buffer, and to transmit them in
a single message.
The problem with this accumulation approach, however, is that it is
hard for the gateway to predict how many numbers it needs to
accumulate before transmission. For example, using the phone on our
desk, we can dial the following numbers:
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
_______________________________________________________
| 0 | Local operator |
| 00 | Long distance operator |
| xxxx | Local extension number |
| 8xxxxxxx | Local number |
| #xxxxxxx | Shortcut to local number at|
| | other corporate sites |
| *xx | Star services |
| 91xxxxxxxxxx | Long distance number |
| 9011 + up to 15 digits| International number |
|________________________|_____________________________|
The solution to this problem is to load the gateway with a digit map
that correspond to the dial plan. This digit map is expressed using a
syntax derived from the Unix system command, egrep. For example, the
dial plan described above results in the following digit map:
(0T| 00T|[1-7]xxx|8xxxxxxx|#xxxxxxx|*xx|91xxxxxxxxxx|9011x.T)
The formal syntax of the digit map is described by the DigitMap rule
in the formal syntax description of the protocol (section 3.4). A
Digit-Map, according to this syntax, is defined either by a "string"
or by a list of strings. Each string in the list is an alternative
numbering scheme, specified either as a set of digits or timers, or
as regular expression. A gateway that detects digits, letters or
timers will:
1) Add the event parameter code as a token to the end of an internal
state variable called the "current dial string"
2) Apply the current dial string to the digit map table, attempting a
match to each regular expression in the Digit Map in lexical order
3) If the result is under-qualified (partially matches at least one
entry in the digit map), do nothing further.
If the result matches, or is over-qualified (i.e. no further digits
could possibly produce a match), send the current digit string to the
Call Agent. A match, in this specification, can be either a "perfect
match," exactly matching one of the specified alternatives, or an
impossible match, which occur when the dial string does not match any
of the alternative. Unexpected timers, for example, can cause
"impossible matches." Both perfect matches and impossible matches
trigger notification of the accumulated digits.
Digit maps are provided to the gateway by the Call Agent, whenever
the Call Agent instructs the gateway to listen for digits.
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2.1.6. Names of events
The concept of events and signals is central to MGCP. A Call Agent
may ask to be notified about certain events occurring in an endpoint,
e.g. off-hook events, and a call agent may request certain signals
to be applied to an endpoint, e.g. dial-tone.
Events and signals are grouped in packages within which they share
the same namespace which we will refer to as event names in the
following. Packages are groupings of the events and signals
supported by a particular type of endpoint. For instance, one package
may support a certain group of events and signals for analog access
lines, and another package may support another group of events and
signals for video lines. One or more packages may exist for a given
endpoint-type.
Event names are case insensitive and are composed of two logical
parts, a package name and an event name. Both names are strings of
letters, hyphens and digits, with the restriction that hyphens shall
never be the first or last characters in a name. Package or event
names are not case sensitive - values such as "hu", "Hu", "HU" or
"hU" should be considered equal.
Examples of package names are "D" (DTMF), "M" (MF), "T" (Trunk) or
"L" (Line). Examples of event names can be "hu" (off hook or "hang-
up" transition), "hf" (flash hook) or "0" (the digit zero).
In textual representations, the package name, when present, is
separated from the event name by a slash ("/"). The package name is
in fact optional. Each endpoint-type has a default package associated
with it, and if the package name is excluded from the event name, the
default package name for that endpoint-type is assumed. For example,
for an analog access line, the following two event names are equal:
l/dl dial-tone in the line package for an analog access line.
dl dial-tone in the line package (default) for an analog access
line.
This document defines a basic set of package names and event names.
Additional package names and event names can be registered with the
IANA. A package definition shall define the name of the package, and
the definition of each event belonging to the package. The event
definition shall include the precise name of the event (i.e., the
code used in MGCP), a plain text definition of the event, and, when
appropriate, the precise definition of the corresponding signals, for
example the exact frequencies of audio signal such as dial tones or
DTMF tones.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
In addition, implementers can gain experience by using experimental
packages. The names of experimental packages must start with the two
characters "x-"; the IANA shall not register package names that start
with these characters.
Digits, or letters, are supported in many packages, notably "DTMF"
and "MF". Digits and letters are defined by the rules "Digit" and
"Letter" in the definition of digit maps. This definition refers to
the digits (0 to 9), to the asterisk or star ("*") and orthotrope,
number or pound sign ("#"), and to the letters "A", "B", "C" and "D",
as well as the timer indication "T". These letters can be combined in
"digit string" that represent the keys that a user punched on a dial.
In addition, the letter "X" can be used to represent all digits, and
the sign "$" can be used in wildcard notations. The need to easily
express the digit strings has a consequence on the form of event
names:
An event name that does not denote a digit should always contain at
least one character that is neither a digit, nor one of the letters
A, B, C, D, T or X. (Such names should not contain the special
signs "*", "#", "/" or "$".)
A Call Agent may often have to ask a gateway to detect a group of
events. Two conventions can be used to denote such groups:
* The wildcard convention can be used to detect any event belonging
to a package, or a given event in many packages, or event any
event in any package supported by the gateway.
* The regular expression Range notation can be used to detect a
range of digits.
The star sign (*) can be used as a wildcard instead of a package
name, and the keyword "all" can be used as a wildcard instead of an
event name:
A name such as "foo/all" denotes all events in package "foo"
A name such as "*/bar" denotes the event "bar" in any package
supported by the gateway
The names "*" or "*/all" denote all events supported by the
gate way.
The call agent can ask a gateway to detect a set of digits or letters
either by individually describing those letters, or by using the
"range" notation defined in the syntax of digit strings. For example,
the call agent can:
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
Use the letter "x" to denote "any letter or digit."
Use the notation "[0-9#]" to denote the digits 0 to 9 and the pound
sign.
In some cases, Call Agents will request the gateway to generate or
detect events on connections rather than on the end point itself.
For example, gateways may be asked to provide a ringback tone on a
connection. When an event shall be applied on a connection, the name
of the connection is added to the name of the event, using an "at"
sign (@) as a delimiter, as in:
G/rt@0A3F58
The wildcard character "*" (star) can be used to denote "all
connections". When this convention is used, the gateway will generate
or detect the event on all the connections that are connected to the
endpoint. An example of this convention could be:
R/qa@*
The wildcard character "$" can be used to denote "the current
connection." It should only be used by the call agent, when the event
notification request is "encapsulated" within a command creation or
modification command. When this convention is used, the gateway will
generate or detect the event on the connection that is currently
being created or modified. An example of this convention is:
G/rt@$
The connection id, or a wildcard replacement, can be used in
conjunction with the "all packages" and "all events" conventions.
For example, the notation:
*/all@*
can be used to designate all events on all connections.
Events and signals are described in packages. The package description
must provide, for each events, the following informations:
* The description of the event and its purpose, which should mean
the actual signal that is generated by the client (i.e., xx ms FSK
tone) as well as the resulting user observed result (i.e., MW
light on/off).
* The detailed characteristics of the event, such as for example
frequencies and amplitude of audio signals, modulations and
repetitions,
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
* The typical and maximum duration of the event.
Signals are divided into different types depending on their behavior:
* On/off (OO) Once applied, these signals last forever until they
are turned off. This may happen either as the result of an event
or a new SignalRequests (see later).
* Time-out (TO) Once applied, these signals last until they are
either turned off (by an event or SignalRequests) or a signal
specific period of time has elapsed. Depending on package
specifications, a signal that times out may generate an "operation
complete" event.
* Brief (BR) The duration of these signals is so short, that they
stop on their own. If an event occurs the signal will not stop,
however if a new SignalRequests is applied, the signal will stop.
(Note: this point should be debated. One could make a case that
events such as strings of DTMF digits should in fact be allowed to
complete.)
TO signals are normally used to alert the endpoints' users, to
signal them that they are expected to perform a specific action,
such as hang down the phone (ringing). Transmission of these
signals should typically be interrupted as soon as the first of
the requested events has been produced.
Package descriptions should describe, for all signals, their type
(OO, TO, BR). They should also describe the maximum duration of
the TO signals.
2.2. Usage of SDP
The Call Agent uses the MGCP to provision the gateways with the
description of connection parameters such as IP addresses, UDP port
and RTP profiles. These descriptions will follow the conventions
delineated in the Session Description Protocol which is now an IETF
proposed standard, documented in RFC 2327.
SDP allows for description of multimedia conferences. This version
limits SDP usage to the setting of audio circuits and data access
circuits. The initial session descriptions contain the description
of exactly one media, of type "audio" for audio connections, "nas"
for data access.
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
2.3. Gateway Control Commands
This section describes the commands of the MGCP. The service consists
of connection handling and endpoint handling commands. There are nine
commands in the protocol:
* The Call Agent can issue an EndpointConfiguration command to a
gateway, instructing the gateway about the coding characteristics
expected by the "line-side" of the endpoint.
* The Call Agent can issue a NotificationRequest command to a
gateway, instructing the gateway to watch for specific events such
as hook actions or DTMF tones on a specified endpoint .
* The gateway will then use the Notify command to inform the Call
Agent when the requested events occur.
* The Call Agent can use the CreateConnection command to create a
connection that terminates in an "endpoint" inside the gateway.
* The Call Agent can use the ModifyConnection command to change the
parameters associated to a previously established connection.
* The Call Agent can use the DeleteConnection command to delete an
existing connection. The DeleteConnection command may also be used
by a gateway to indicate that a connection can no longer be
sustained.
* The Call Agent can use the AuditEndpoint and AuditConnection
commands to audit the status of an "endpoint" and any connections
associated with it. Network management beyond the capabilities
provided by these commands are generally desirable, e.g.
information about the status of the gateway. Such capabilities are
expected to be supported by the use of the Simple Network
Management Protocol (SNMP) and definition of a MIB which is
outside the scope of this specification.
* The Gateway can use the RestartInProgress command to notify the
Call Agent that the gateway, or a group of endpoints managed by
the gateway, is being taken out of service or is being placed back
in service.
These services allow a controller (normally, the Call Agent) to
instruct a gateway on the creation of connections that terminate in
an "endpoint" attached to the gateway, and to be informed about
events occurring at the endpoint. An endpoint may be for example:
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RFC 2705 Media Gateway Control Protocol (MGCP) October 1999
* A specific trunk circuit, within a trunk group terminating in a
gateway,
* A specific announcement handled by an announcement server.
Connections are grouped into "calls". Several connections, that may
or may not belong to the same call, can terminate in the same
endpoint . Each connection is qualified by a "mode" parameter, which
can be set to "send only" (sendonly), "receive only" (recvonly),
"send/receive" (sendrecv), "conference" (confrnce), "data",
"inactive" (inactive), "loopback", "continuity test" (conttest),
"network loop back" (netwloop) or "network continuity test"
(netwtest).
The handling of the audio signals received on these connections is
determined by the mode parameters:
* Audio signals received in data packets through connections in
"receive", "conference" or "send/receive" mode are mixed and sent
to the endpoint.
* Audio signals originating from the endpoint are transmitted over
all the connections whose mode is "send", "conference" or
"send/receive."
* In addition to being sent to the endpoint, audio signals received
in data packets through connections in "conference" mode are
replicated to all the other connections whose mode is
"conference."
The "loopback" and "continuity test" modes are used during
maintenance and continuity test operations. There are two flavors of
continuity test, one specified by ITU and one used in the US. In the
first case, the test is a loopback test. The originating switch will
send a tone (the go tone) on the bearer circuit and expect the
terminating switch to loopback the circuit. If the originating switch
sees the same tone returned (the return tone), the COT has passed. If
not, the COT has failed. In the second case, the go and return tones
are different. The originating switch sends a certain go tone. The
terminating switch detects the go tone, it asserts a different return
tone in the backwards direction. When the originating switch detects
the return tone, the COT is passed. If the originating switch never
detects the return tone, the COT has failed.
If the mode is set to "loopback", the gateway is expected to return
the incoming signal from the endpoint back into that same endpoint.
This procedure will be used, typically, for testing the continuity of
trunk circuits according to the ITU specifications.
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If the mode is set to "continuity test", the gateway is informed that
the other end of the circuit has initiated a continuity test
procedure according to the GR specification. The gateway will place
the circuit in the transponder mode required for dual-tone continuity
tests.
If the mode is set to "network loopback", the audio signals received
from the connection will be echoed back on the same connection.
If the mode is set to "network continuity test", the gateway will
process the packets received from the connection according to the
transponder mode required for dual-tone continuity test, and send the
processed signal back on the connection.
2.3.1. EndpointConfiguration
The EndpointConfiguration commands are used to specify the encoding
of the signals that will be received by the endpoint. For example,
in certain international telephony configurations, some calls will
carry mu-law encoded audio signals, while other will use A-law. The
Call Agent will use the EndpointConfiguration command to pass this
information to the gateway. The configuration may vary on a call by
call basis, but can also be used in the absence of any connection.
ReturnCode
<-- EndpointConfiguration( EndpointId,
BearerInformation)
EndpointId is the name for the endpoint in the gateway where
EndpointConfiguration executes, as defined in section 2.1.1. The
"any of" wildcard convention shall not be used. If the "all of"
wildcard convention is used, the command applies to all the endpoint
whose name matches the wildcard.
BearerInformation is a parameter defining the coding of the data
received from the line side. These information is encoded as a list
of sub-parameters. The only sub-parameter defined in this version of
the specification is the encoding method, whose values can be set to
"A-law" and "mu-law".
ReturnCode is a parameter returned by the gateway. It indicates the
outcome of the command and consists of an integer number optionally
followed by commentary.
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2.3.2. NotificationRequest
The NotificationRequest commands are used to request the gateway to
send notifications upon the occurrence of specified events in an
endpoint. For example, a notification may be requested for when a
gateway detects that an endpoint is receiving tones associated with
fax communication. The entity receiving this notification may decide
to use a different type of encoding method in the connections bound
to this endpoint.
ReturnCode
<-- NotificationRequest( EndpointId,
[NotifiedEntity,]
[RequestedEvents,]
RequestIdentifier,
[DigitMap,]
[SignalRequests,]
[QuarantineHandling,]
[DetectEvents,]
[encapsulated EndpointConfiguration])
EndpointId is the name for the endpoint in the gateway where
NotificationRequest executes, as defined in section 2.1.1.
NotifiedEntity is an optional parameter that specifies where the
notifications should be sent. When this parameter is absent, the
notifications should be sent to the originator of the
NotificationRequest.
RequestIdentifier is used to correlate this request with the
notifications that it triggers.
RequestedEvents is a list of events that the gateway is requested to
detect and report. Such events include, for example, fax tones,
continuity tones, or on-hook transition. To each event is associated
an action, which can be:
* Notify the event immediately, together with the accumulated list
of observed events,
* Swap audio,
* Accumulate the event in an event buffer, but don't notify yet,
* Accumulate according to Digit Map,
* Keep Signal(s) active,
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* process the Embedded Notification Request,
* Ignore the event.
Some actions can be combined. In particular:
* The "swap audio" action can be combined with "Notify",
"Accumulate" and "Ignore."
* The "keep signal active" action can be combined with "Notify",
"Accumulate", "Accumulate according to Digit Map", "Ignore" and
"Embedded Notification Request."
* The "Embedded Notification Request" can be combined with
"Accumulate" and with "Keep signals active." It can also be
combined with Notify, if the gateway is allowed to issue several
Notify commands in response to a single Notification request.
In addition to the requestedEvents parameter specified in the
command, some profiles of MGCP have introduced the concept of
"persistent events." According to such profiles, the persistent event
list is configured in the endpoint, by means outside the scope of
MGCP. The basic MGCP specification does not specify any persistent
event.
If a persistent event is not included in the list of RequestedEvents,
and the event occurs, the event will be detected anyway, and
processed like all other events, as if the persistent event had been
requested with a Notify action. Thus, informally, persistent events
can be viewed as always being implicitly included in the list of
RequestedEvents with an action to Notify, although no glare
detection, etc., will be performed.
Non-persistent events are those events explicitly included in the
RequestedEvents list. The (possibly empty) list of requested events
completely replaces the previous list of requested events. In
addition to the persistent events, only the events specified in the
requested events list will be detected by the endpoint. If a
persistent event is included in the RequestedEvents list, the action
specified will then replace the default action associated with the
event for the life of the RequestedEvents list, after which the
default action is restored. For example, if "Ignore off-hook" was
specified, and a new request without any off-hook instructions were
received, the default "Notify off-hook" operation then would be
restored. A given event MUST NOT appear more than once in a
RequestedEvents.
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The gateway will detect the union of the persistent events and the
requested events. If an event is not specified in either list, it
will be ignored.
The Swap Audio action can be used when a gateway handles more than
one active connection on an endpoint. This will be the case for
three-way calling, call waiting, and possibly other feature
scenarios. In order to avoid the round-trip to the Call Agent when
just changing which connection is attached to the audio functions of
the endpoint, the NotificationRequest can map an event (usually hook
flash, but could be some other event) to a local function swap audio,
which selects the "next" connection in a round robin fashion. If
there is only one connection, this action is effectively a no-op.
If signal(s) are desired to start when an event being looked for
occurs, the "Embedded NotificationRequest" action can be used. The
embedded NotificationRequest may include a new list of
RequestedEvents, SignalRequests and a new digit map as well. The
semantics of the embedded NotificationRequest is as if a new
NotificationRequest was just received with the same NotifiedEntity,
and RequestIdentifier. When the "Embedded NotificationRequest" is
activated, the "current dial string" will be cleared; the list of
observed events and the quarantine buffer will be unaffected.
MGCP implementations shall be able to support at least one level of
embedding. An embedded NotificationRequest that respects this
limitation shall not contain another Embedded NotificationRequest.
DigitMap is an optional parameter that allows the Call Agent to
provision the gateways with a digit map according to which digits
will be accumulated. If this optional parameter is absent, the
previously defined value is retained. This parameter must be defined,
either explicitly or through a previous command, if the
RequestedEvent parameters contain an request to "accumulate according
to the digit map." The collection of these digits will result in a
digit string. The digit string is initialized to a null string upon
reception of the NotificationRequest, so that a subsequent
notification only returns the digits that were collected after this
request. Digits that were accumulated according to the digit map are
reported as any other accumulated event, in the order in which they
occur. It is therefore possible that other events be accumulated may
be found in between the list of digits.
SignalRequests is a parameter that contains the set of signals that
the gateway is asked to apply to the endpoint, such as, for example
ringing, or continuity tones. Signals are identified by their name,
which is an event name, and may be qualified by parameters.
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The action triggered by the SignalRequests is synchronized with the
collection of events specified in the RequestedEvents parameter. For
example, if the NotificationRequest mandates "ringing" and the event
request ask to look for an "off-hook" event, the ringing shall stop
as soon as the gateway detect an off hook event. The formal
definition is that the generation of all "Time Out" signals shall
stop as soon as one of the requested events is detected, unless the
"Keep signals active" action is associated to the specified event.
The specific definition of actions that are requested via these
SignalRequests, such as the duration of and frequency of a DTMF
digit, is out side the scope of MGCP. This definition may vary from
location to location and hence from gateway to gateway.
The RequestedEvents and SignalRequests refer to the same event
definitions. In one case, the gateway is asked to detect the
occurrence of the event, and in the other case it is asked to
generate it. The specific events and signals that a given endpoint
can detect or perform are determined by the list of event packages
that are supported by that end point. Each package specifies a list
of events and actions that can be detected or performed. A gateway
that is requested to detect or perform an event belonging to a
package that is not supported by the specified endpoint shall return
an error. When the event name is not qualified by a package name, the
default package name for the end point is assumed. If the event name
is not registered in this default package, the gateway shall return
an error.
The Call Agent can send a NotificationRequest whose requested signal
list is empty. It will do so for example when tone generation should
stop.
The optional QuarantineHandling parameter specifies the handling of
"quarantine" events, i.e. events that have been detected by the
gateway before the arrival of this NotificationRequest command, but
have not yet been notified to the Call Agent. The parameter provides
a set of handling options:
* whether the quarantined events should be processed or discarded
(the default is to process them.)
* whether the gateway is expected to generate at most one
notification (step by step), or multiple notifications (loop), in
response to this request (the default is exactly one.)
When the parameter is absent, the default value is assumed.
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We should note that the quarantine-handling parameter also governs
the handling of events that were detected but not yet notified when
the command is received.
DetectEvents is an optional parameter that specifies a list of events
that the gateway is requested to detect during the quarantine period.
When this parameter is absent, the events that should be detected in
the quarantine period are those listed in the last received
DetectEvents list. In addition, the gateway should also detect the
events specified in the request list, including those for which the
"ignore" action is specified.
Some events and signals, such as the in-line ringback or the quality
alert, are performed or detected on connections terminating in the
end point rather than on the endpoint itself. The structure of the
event names allow the Call Agent to specify the connection (or
connections) on which the events should be performed or detected.
The command may carry an encapsulated EndpointConfiguration command,
that will apply to the same endpoint. When this command is present,
the parameters of the EndpointConfiguration command are inserted
after the normal parameters of the NotificationRequest, with the
exception of the EndpointId, which is not replicated.
The encapsulated EndpointConfiguration command shares the fate of the
NotificationRequest command. If the NotificationRequest is rejected,
the EndpointConfiguration is not executed.
ReturnCode is a parameter returned by the gateway. It indicates the
outcome of the command and consists of an integer number optionally
followed by commentary. .NH 3 Notifications
Notifications are sent via the Notify command and are sent by the
gateway when the observed events occur.
ReturnCode
<-- Notify( EndpointId,
[NotifiedEntity,]
RequestIdentifier,
ObservedEvents)
EndpointId is the name for the endpoint in the gateway which is
issuing the Notify command, as defined in section 2.1.1. The
identifier should be a fully qualified endpoint identifier, including
the domain name of the gateway. The local part of the name shall not
use the wildcard convention.
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NotifiedEntity is an optional parameter that identifies the entity to
which the notifications is sent. This parameter is equal to the last
received value of the NotifiedEntity parameter. The parameter is
absent if there was no such parameter in the triggering request. The
notification is sent to the "current notified entity" or, if no such
entity was ever specified, to the address from which the request was
received.
RequestIdentifier is parameter that repeats the RequestIdentifier
parameter of the NotificationRequest that triggered this
notification. It is used to correlate this notification with the
request that triggered it.
ObservedEvents is a list of events that the gateway detected. A
single notification may report a list of events that will be reported
in the order in which they were detected. The list may only contain
the identification of events that were requested in the
RequestedEvents parameter of the triggering NotificationRequest. It
will contain the events that were either accumulated (but not
notified) or treated according to digit map (but no match yet), and
the final event that triggered the detection or provided a final
match in the digit map.
ReturnCode is a parameter returned by the call agent. It indicates
the outcome of the command and consists of an integer number
optionally followed by commentary.
2.3.3. CreateConnection
This command is used to create a connection between two endpoints.
ReturnCode,
ConnectionId,
[SpecificEndPointId,]
[LocalConnectionDescriptor,]
[SecondEndPointId,]
[SecondConnectionId]
<--- CreateConnection(CallId,
EndpointId,
[NotifiedEntity,]
[LocalConnectionOptions,]
Mode,
[{RemoteConnectionDescriptor |
SecondEndpointId}, ]
[Encapsulated NotificationRequest,]
[Encapsulated EndpointConfiguration])
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A connection is defined by its endpoints. The input parameters in
CreateConnection provide the data necessary to build a gateway's
"view" of a connection.
CallId is a globally unique parameter that identifies the call (or
session) to which this connection belongs. Connections that belong to
the same call share the same call-id. The call-id can be used to
identify calls for reporting and accounting purposes. It does not
affect the handling of connections by the gateway.
EndpointId is the identifier for the connection endpoint in the
gateway where CreateConnection executes. The EndpointId can be
fully-specified by assigning a value to the parameter EndpointId in
the function call or it may be under-specified by using the "anyone"
wildcard convention. If the endpoint is underspecified, the endpoint
identifier will be assigned by the gateway and its complete value
returned in the SpecificEndPointId parameter of the response.
The NotifiedEntity is an optional parameter that specifies where the
Notify or DeleteConnection commands should be sent. If the parameter
is absent, the Notify or DeleteConnection commands should be sent to
the last received Notified Entity, or to originator of the
CreateConnection command if no Notified Entity was ever received for
the end point.
LocalConnectionOptions is a parameter used by the Call Agent to
direct the handling of the connection by the gateway. The fields
contained in LocalConnectionOptions are the following:
* Encoding Method,
* Packetization period,
* Bandwidth,
* Type of Service,
* Usage of echo cancellation,
* Usage of silence suppression or voice activity detection,
* Usage of signal level adaptation and noise level reduction, or
"gain control."
* Usage of reservation service,
* Usage of RTP security,
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* Type of network used to carry the connection.
This set of field can be completed by vendor specific optional or
mandatory extensions. The encoding of the first three fields, when
they are present, will be compatible with the SDP and RTP profiles:
* The encoding method shall be specified by using one or several
valid encoding names, as defined in the RTP AV Profile or
registered with the IANA.
* The packetization period is encoded as either the length of time
in milliseconds represented by the media in a packet, as specified
in the "ptime" parameter of SDP, or as a range value, specifying
both the minimum and maximum acceptable packetization periods.
* The bandwidth is encoded as either a single value or a range,
expressed as an integer number of kilobit per seconds.
For each of the first three fields, the Call Agent has three options:
* It may state exactly one value, which the gateway will then use
for the connection,
* It may provide a loose specification, such as a list of allowed
encoding methods or a range of packetization periods,
* It may simply provide a bandwidth indication, leaving the choice
of encoding method and packetization period to the gateway.
The bandwidth specification shall not contradict the specification of
encoding methods and packetization period. If an encoding method is
specified, then the gateway is authorized to use it, even if it
results in the usage of a larger bandwidth than specified.
The LocalConnectionOptions parameter may be absent in the case of a
data call.
The Type of Service specifies the class of service that will be used
for the connection. When the connection is transmitted over an IP
network, the parameters encodes the 8-bit type of service value
parameter of the IP header. When the Type of Service is not
specified, the gateway shall use a default or configured value.
The gateways can be instructed to perform a reservation, for example
using RSVP, on a given connection. When a reservation is needed, the
call agent will specify the reservation profile that should be used,
which is either "controlled load" or "guaranteed service." The
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absence of reservation can be indicated by asking for the "best
effort" service, which is the default value of this parameter. When
reservation has been asked on a connection, the gateway will:
* start emitting RSVP "PATH" messages if the connection is in
"send-only", "send-receive", "conference", "network loop back" or
"network continuity test" mode (if a remote connection descriptor
has been received,)
* start emitting RSVP "RESV" messages as soon as it receives "PATH"
messages if the connection is in "receive-only", "send-receive",
"conference", "network loop back" or "network continuity test"
mode.
The RSVP filters will be deduced from the characteristics of the
connection. The RSVP resource profiles will be deduced from the
connection's bandwidth and packetization period.
By default, the telephony gateways always perform echo cancellation.
However, it is necessary, for some calls, to turn off these
operations. The echo cancellation parameter can have two values,
"on" (when the echo cancellation is requested) and "off" (when it is
turned off.)
The telephony gateways may perform gain control, in order to adapt
the level of the signal. However, it is necessary, for example for
modem calls, to turn off this function. The gain control parameter
may either be specified as "automatic", or as an explicit number of
decibels of gain. The default is to not perform gain control, which
is equivalent to specifying a gain of 0 decibels.
The telephony gateways may perform voice activity detection, and
avoid sending packets during periods of silence. However, it is
necessary, for example for modem calls, to turn off this detection.
The silence suppression parameter can have two values, "on" (when the
detection is requested) and "off" (when it is turned off.) The
default is "off."
The Call agent can request the gateway to enable encryption of the
audio Packets. It does so by providing an key specification, as
specified in RFC 2327. By default, encryption is not used.
The Call Agent may instruct the gateway to prepare the connection on
a specified type of network. The type of network is encoded as in
the "connection-field" parameter of the SDP standard. Possible
values are IN (Internet), ATM and LOCAL. The parameter is optional;
if absent, the network is determined by the type of gateway.
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RemoteConnectionDescriptor is the connection descriptor for the
remote side of a connection, on the other side of the IP network. It
includes the same fields as in the LocalConnectionDescriptor, i.e.
the fields that describe a session according to the SDP standard.
This parameter may have a null value when the information for the
remote end is not known yet. This occurs because the entity that
builds a connection starts by sending a CreateConnection to one of
the two gateways involved in it. For the first CreateConnection
issued, there is no information available about the other side of the
connection. This information may be provided later via a
ModifyConnection call. In the case of data connections (mode=data),
this parameter describes the characteristics of the data connection.
The SecondEndpointId can be used instead of the
RemoteConnectionDescriptor to establish a connection between two
endpoints located on the same gateway. The connection is by
definition a local connection. The SecondEndpointId can be fully-
specified by assigning a value to the parameter SecondEndpointId in
the function call or it may be under-specified by using the "anyone"
wildcard convention. If the secondendpoint is underspecified, the
second endpoint identifier will be assigned by the gateway and its
complete value returned in the SecondEndPointId parameter of the
response.
Mode indicates the mode of operation for this side of the connection.
The mode are "send", "receive", "send/receive", "conference", "data",
"inactive", "loopback", "continuity test", "network loop back" or
"network continuity test." The expected handling of these modes is
specified in the introduction of the "Gateway Handling Function"
section. Some end points may not be capable of supporting all modes.
If the command specifies a mode that the endpoint cannot support, and
error shall be returned.
The gateway returns a ConnectionId, that uniquely identifies the
connection within one endpoint, and a LocalConnectionDescriptor,
which is a session description that contains information about
addresses and RTP ports, as defined in SDP. The
LocalConnectionDescriptor is not returned in the case of data
connections. The SpecificEndPointId is an optional parameter that
identifies the responding endpoint. It can be used when the
EndpointId argument referred to a "any of" wildcard name. When a
SpecificEndPointId is returned, the Call Agent should use it as the
EndpointId value is successive commands referring to this call.
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When a SecondEndpointId is specified, the command really creates two
connections that can be manipulated separately through
ModifyConnection and DeleteConnection commands. The response to the
creation provides a SecondConnectionId parameter that identifies the
second connection.
After receiving a "CreateConnection" request that did not include a
RemoteConnectionDescriptor parameter, a gateway is in an ambiguous
situation. Because it has exported a LocalConnectionDescriptor
parameter, it can potentially receive packets. Because it has not yet
received the RemoteConnectionDescriptor parameter of the other
gateway, it does not know whether the packets that it receives have
been authorized by the Call Agent. It must thus navigate between two
risks, i.e. clipping some important announcements or listening to
insane data. The behavior of the gateway is determined by the value
of the Mode parameter:
* If the mode was set to ReceiveOnly, the gateway should accept the
voice signals and transmit them through the endpoint.
* If the mode was set to Inactive, Loopback, Continuity Test, the
gateway should refuse the voice signals.
* If the mode was set to Network Loopback or Network Continuity
Test, the gateway should perform the expected echo or Response.
Note that the mode values SendReceive, Conference, Data and SendOnly
don't make sense in this situation. They should be treated as errors,
and the command should be rejected (Error code 517).
The command may optionally contain an encapsulated Notification
Request command, in which case a RequestIdentifier parameter will be
present, as well as, optionally, the RequestedEvents DigitMap,
SignalRequests, QuarantineHandling and DetectEvents parameters. The
encapsulated NotificationRequest is executed simultaneously with the
creation of the connection. For example, when the Call Agent wants to
initiate a call to an residential gateway, it should:
* ask the residential gateway to prepare a connection, in order to
be sure that the user can start speaking as soon as the phone goes
off hook,
* ask the residential gateway to start ringing,
* ask the residential gateway to notify the Call Agent when the
phone goes off-hook.
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This can be accomplished in a single CreateConnection command, by
also transmitting the RequestedEvent parameters for the off hook
event, and the SignalRequest parameter for the ringing signal.
When these parameters are present, the creation and the
NotificationRequests should be synchronized, which means that
bothshould be accepted, or both refused. In our example, the
CreateConnection may be refused if the gateway does not have
sufficient resources, or cannot get adequate resources from the local
network access, and the off-hook Notification-Request can be refused
in the glare condition, if the user is already off-hook. In this
example, the phone should not ring if the connection cannot be
established, and the connection should not be established if the user
is already off hook.
The NotifiedEntity parameter, if present, applies to both the
CreateConnection and the NotificationRequest command. It defines the
new "notified entity" for the endpoint.
The command may carry an encapsulated EndpointConfiguration command,
that will apply to the same endpoint. When this command is present,
the parameters of the EndpointConfiguration command are inserted
after the normal parameters of the CreateConnection with the
exception of the EndpointId, which is not replicated. The
EndpointConfiguration command may be encapsulated together with an
encapsulated NotificationRequest command.
The encapsulated EndpointConfiguration command shares the fate of the
CreateConnection command. If the CreateConnection is rejected, the
EndpointConfiguration is not executed.
ReturnCode is a parameter returned by the gateway. It indicates the
outcome of the command and consists of an integer number optionally
followed by commentary.
2.3.4. ModifyConnection
This command is used to modify the characteristics of a gateway's
"view" of a connection. This "view" of the call includes both the
local connection descriptors as well as the remote connection
descriptor.
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ReturnCode,
[LocalConnectionDescriptor]
<--- ModifyConnection(CallId,
EndpointId,
ConnectionId,
[NotifiedEntity,]
[LocalConnectionOptions,]
[Mode,]
[RemoteConnectionDescriptor,]
[Encapsulated NotificationRequest,]
[Encapsulated EndpointConfiguration])
The parameters used are the same as in the CreateConnection command,
with the addition of a ConnectionId that identifies the connection
within the endpoint. This parameter is returned by the
CreateConnection function, as part of the local connection
descriptor. It uniquely identifies the connection within the context
of the endpoint.
The EndpointId should be a fully qualified endpoint identifier. The
local name shall not use the wildcard convention.
The ModifyConnection command can be used to affect parameters of a
connection in the following ways:
* Provide information about the other end of the connection, through
the RemoteConnectionDescriptor.
* Activate or deactivate the connection, by changing the value of
the Mode parameter. This can occur at any time during the
connection, with arbitrary parameter values.
* Change the sending parameters of the connection, for example by
switching to a different coding scheme, changing the packetization
period, or modifying the handling of echo cancellation.
Connections can only be activated if the RemoteConnectionDescriptor
has been provided to the gateway. The receive only mode, however, can
be activated without the provision of this descriptor.
The command will only return a LocalConnectionDescriptor if the local
connection parameters, such as RTP ports, were modified. (Usage of
this feature is actually for further study.)
The command may optionally contain an encapsulated Notification
Request command, in which case a RequestIdentifier parameter will be
present, as well as, optionnally, the RequestedEvents DigitMap,
SignalRequests, QuarantineHandling and DetectEvents parameters. The
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encapsulated NotificationRequest is executed simultaneously with the
modification of the connection. For example, when a connection is
accepted, the calling gateway should be instructed to place the
circuit in send-receive mode and to stop providing ringing tones.
This can be accomplished in a single ModifyConnection command, by
also transmitting the RequestedEvent parameters, for the on hook
event, and an empty SignalRequest parameter, to stop the provision of
ringing tones.
When these parameters are present, the modification and the
NotificationRequests should be synchronized, which means that both
should be accepted, or both refused. The NotifiedEntity parameter,
if present, applies to both the ModifyConnection and the
NotificationRequest command.
The command may carry an encapsulated EndpointConfiguration command,
that will apply to the same endpoint. When this command is present,
the parameters of the EndpointConfiguration command are inserted
after the normal parameters of the ModifyConnection with the
exception of the EndpointId, which is not replicated. The
EndpointConfiguration command may be encapsulated together with an
encapsulated NotificationRequest command.
The encapsulated EndpointConfiguration command shares the fate of the
ModifyConnection command. If the ModifyConnection is rejected, the
EndpointConfiguration is not executed.
ReturnCode is a parameter returned by the gateway. It indicates the
outcome of the command and consists of an integer number optionally
followed by commentary.
2.3.5. DeleteConnection (from the Call Agent)
This command is used to terminate a connection. As a side effect, it
collects statistics on the execution of the connection.
ReturnCode,
Connection-parameters
<-- DeleteConnection(CallId,
EndpointId,
ConnectionId,
[Encapsulated NotificationRequest,]
[Encapsulated EndpointConfiguration])
The endpoint identifier, in this form of the DeleteConnection
command, shall be fully qualified. Wildcard conventions shall not be
used.
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In the general case where a connection has two ends, this command has
to be sent to both gateways involved in the connection. Some
connections, however, may use IP multicast. In this case, they can be
deleted individually.
After the connection has been deleted, any loopback that has been
requested for the connection should be cancelled. When all
connections to an endpoint have been deleted, that endpoint should be
placed in inactive mode.
In response to the DeleteConnection command, the gateway returns a
list of parameters that describe the status of the connection. These
parameters are:
Number of packets sent:
The total number of RTP data packets transmitted by the sender since
starting transmission on this connection. The count is not reset if
the sender changes its synchronization source identifier (SSRC, as
defined in RTP), for example as a result of a Modify command. The
value is zero if the connection was set in "receive only" mode.
Number of octets sent:
The total number of payload octets (i.e., not including header or
padding) transmitted in RTP data packets by the sender since starting
transmission on this connection. The count is not reset if the sender
changes its SSRC identifier, for example as a result of a
ModifyConnection command. The value is zero if the connection was set
in "receive only" mode.
Number of packets received:
The total number of RTP data packets received by the sender since
starting reception on this connection. The count includes packets
received from different SSRC, if the sender used several values. The
value is zero if the connection was set in "send only" mode.
Number of octets received:
The total number of payload octets (i.e., not including header or
padding) transmitted in RTP data packets by the sender since starting
transmission on this connection. The count includes packets received
from different SSRC, if the sender used several values. The value is
zero if the connection was set in "send only" mode.
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Number of packets lost:
The total number of RTP data packets that have been lost since the
beginning of reception. This number is defined to be the number of
packets expected less the number of packets actually received, where
the number of packets received includes any which are late or
duplicates. The count includes packets received from different SSRC,
if the sender used several values. Thus packets that arrive late are
not counted as lost, and the loss may be negative if there are
duplicates. The count includes packets received from different SSRC,
if the sender used several values. The number of packets expected is
defined to be the extended last sequence number received, as defined
next, less the initial sequence number received. The count includes
packets received from different SSRC, if the sender used several
values. The value is zero if the connection was set in "send only"
mode. This parameter is omitted if the connection was set in "data"
mode.
Interarrival jitter:
An estimate of the statistical variance of the RTP data packet
interarrival time measured in milliseconds and expressed as an
unsigned integer. The interarrival jitter J is defined to be the mean
deviation (smoothed absolute value) of the difference D in packet
spacing at the receiver compared to the sender for a pair of packets.
Detailed computation algorithms are found in RFC 1889. The count
includes packets received from different SSRC, if the sender used
several values. The value is zero if the connection was set in "send
only" mode. This parameter is omitted if the connection was set in
"data" mode.
Average transmission delay:
An estimate of the network latency, expressed in milliseconds. This
is the average value of the difference between the NTP timestamp
indicated by the senders of the RTCP messages and the NTP timestamp
of the receivers, measured when this messages are received. The
average is obtained by summing all the estimates, then dividing by
the number of RTCP messages that have been received. This parameter
is omitted if the connection was set in "data" mode.
When the gateway's clock is not synchronized by NTP, the latency
value can be computed as one half of the round trip delay, as
measured through RTCP.
When the gateway cannot compute the one way delay or the round trip
delay, the parameter conveys a null value.
For a detailed definition of these variables, refer to RFC 1889.
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When the connection was set up over an ATM network, the meaning of
these parameters may change:
Number of packets sent: The total number of ATM cells transmitted
since starting transmission on this connection.
Number of octets sent:
The total number of payload octets transmitted in ATM cells.
Number of packets received:
The total number of ATM cells received since starting reception on
this connection.
Number of octets received:
The total number of payload octets received in ATM cells.
Number of packets lost:
Should be determined as the number of cell losts, or set to zero
if the adaptation layer does not enable the gateway to assess
losses.
Interarrival jitter:
Should be understood as the interarrival jitter between ATM cells.
Average transmission delay:
The gateway may not be able to assess this parameter over an ATM
network. It could simply report a null value.
When the connection was set up over an LOCAL interconnect, the
meaning of these parameters is defined as follows:
Number of packets sent:
Not significant.
Number of octets sent:
The total number of payload octets transmitted over the local
connection.
Number of packets received:
Not significant.
Number of octets received:
The total number of payload octets received over the connection.
Number of packets lost:
Not significant. A value of zero is assumed.
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Interarrival jitter:
Not significant. A value of zero is assumed.
Average transmission delay:
Not significant. A value of zero is assumed.
The standard set of connection parameters can be extended by the
creation of extension parameters.
The command may optionally contain an encapsulated Notification
Request command, in which case a RequestIdentifier parameter will be
present, as well as, optionnally, the RequestedEvents DigitMap,
SignalRequests, QuarantineHandling and DetectEvents parameters. The
encapsulated NotificationRequest is executed simultaneously with the
deletion of the connection. For example, when a user hang-up is
notified, the gateway should be instructed to delete the connection
and to start looking for an off hook event.
This can be accomplished in a single DeleteConnection command, by
also transmitting the RequestedEvent parameters, for the off hook
event, and an empty SignalRequest parameter.
When these parameters are present, the DeleteConnection and the
NotificationRequests should be synchronized, which means that both
should be accepted, or both refused.
The command may carry an encapsulated EndpointConfiguration command,
that will apply to the same endpoint. When this command is present,
the parameters of the EndpointConfiguration command are inserted
after the normal parameters of the DeleteConnection with the
exception of the EndpointId, which is not replicated. The
EndpointConfiguration command may be encapsulated together with an
encapsulated NotificationRequest command.
The encapsulated EndpointConfiguration command shares the fate of the
DeleteConnection command. If the Delet |
