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Info

The instructions, commands and references in this document apply to the

Spacevars
0series4
(
Spacevars
0series
,
Spacevars
0series2
,
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0model5
, and
Spacevars
0series3
Spacevars
0company
Session Border Controllers).

This document does not apply to SBC Edge (SBC 1000 and 2000 systems).

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1. Introduction

This document provides configuration and provisioning guidance to enable SIP transparency on

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0series4
systems. In addition to the configuration examples on the
Spacevars
0product
(Session Border Controller), this document provides an introduction to key topics related to SIP headers and bodies on the
Spacevars
0series4
.

1.1 Audience

This document is intended for design engineers, system engineers and operations staff for the purpose of deploying SIP on a 

Spacevars
0series4
system. Although this document provides some background on the concepts involved, the reader is expected to have a basic understanding of SIP.

Spacevars
0company
Technical Support can be obtained through the following:

1.2 Requirements

This document describes configuration procedures related to version 4.2 of the 

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0series4
software.

Note
This document does not apply to SBC Edge (SBC 1000 and 2000 systems).
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1.3 References

2. SIP Transparency

For some SIP elements, transparency is a frequently-debated topic. When transparency for a SIP header or body is desired, the user may often compare the element against a SIP Proxy which is a typical benchmark for significant transparency. Considered a popular comparison, this topic needs to addressed up front when discussing SIP transparency.

2.1 SIP Proxy vs. SIP B2BUA

The SIP devices that connect most peers and endpoints are typically a SIP Proxy or Back-to-Back User Agent (B2BUA). The most transparent device is the SIP Proxy; its behaviors are primarily specified in RFC 3261 and are very basic in its message processing capabilities. The required transparency of a Proxy is one of its few strengths when compared to a B2BUA.

Caption
0Figure
1SIP Transparency Spectrum

Although an

Spacevars
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is not defined in any IETF standard, it is most closely associated functionally with a SIP B2BUA (RFC 5853, 7092). Unless otherwise specified, this document will use B2BUA and 
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terms interchangeably.

While RFC 3261 goes into detail describing the required behavior of a SIP Proxy, its description for a B2BUA could be considered somewhat terse: "Since it is a concatenation of a UAC [User Agent Client] and UAS [User Agent Server], no explicit definitions are needed for its behavior." This statement notwithstanding, debate and research into the transparency behavior of a B2BUA continued, but seemingly without consensus. An often referenced IETF draft (draft-marjou-sipping-01) submitted to the SIPPING WG was not accepted as a working group document.

Admittedly, complete SIP transparency is not achievable due to the needs and requirements of changing some headers. Even a SIP Proxy is not completely transparent. In many scenarios the ability to control and even minimize transparency is a strength of a B2BUA/

Spacevars
0product
. Some key selling points of an
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0product
highlight its ability to not be transparent:

  • SIP Normalization (including arbitrary SIP Message Manipulation)
  • Topology Hiding
  • Protocol Translation
  • Codec Transcoding (allowing a non-transparent SDP)

Fundamentally, the 

Spacevars
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Spacevars
0product
behaves as a SIP Back-to-Back User Agent (B2BUA) and not as a SIP Proxy. (If SIP Proxy behavior is actually needed then use of the 
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0company
PSX Policy Server should be considered as it can be deployed specifically as a SIP Proxy or Redirector.) Unlike a standard SIP Proxy, the
Spacevars
0company
Spacevars
0product
can provide a wide spectrum of SIP message transparency, from fairly transparent to almost completely non-transparent.

This document describes the

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SIP transparency controls, how they behave, and how they interact. Some configuration examples using these transparency controls is also provided.

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3. 
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SIP Transparency and Control Mechanisms

Since its inception, the 

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includes two related types of control flags: Relay Flags and Transparency Flags. Relay Flags primarily control SIP at the Request and Response level and are discussed later in a separate section. Transparency Flags control SIP headers and bodies that are generally not modified when received in a SIP message. While these controls are related, there is no direct overlap or precedence between them.

3.1 Existing 
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Transparency Mechanisms

Prior to release 4.0, SIP header and body transparency was controlled primarily by the use of individual Transparency Flags, mostly within the IP Signaling Profile (IPSP; ipSignalingProfile > commonIpAttributes > transparencyFlags) and apply on the egress leg of a session (egress relative to the SIP message).

Caption
0Table
1IP Signaling Profile Transparency Flags

acceptContactHeader

pVisitedNetworkIDHeader

acceptHeader

qsigBody

acceptLanguageHeader

reasonHeader

alertInformationHeader

referredByHeader

authcodeHeaders

requestURI

callInfoHeader

resourceListBody

contactHeader

resourcePriorityOptionTag

errorInfo

rlmiBody

externalBody

routeHeader

fromHeader

serverHeader

geolocation

serviceRouteHeader

geolocationError

simpleFilterBody

geolocationRouting

sipBody

historyInfo

sipfragBody

maxForwardsHeader

toHeader

mwiBody

toneBody

pAccessNetworkInfoHeader

unknownBody

passCompleteContactHeader

unknownHeader

pathHeader

userAgentHeader

pCalledPartyID

userToUserHeader

pChargingVectorHeader

viaHeader

pEarlyMedia

warningHeader

pidfBody

watcherInfoBody

pidfDiffBody

 

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 If a header or body did not have a specific flag on the

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, it was treated as unknown, which meant it, along with any other
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-unknown header, was controlled by the single unknownHeader flag (or unknownBody).

When a transparency flag was added for a header, it meant that the header was now known and that the unknownHeader flag no longer controlled it.

This methodology was problematic as headers transitioned from unknown to known on the

Spacevars
0product
. It also meant that the unknownHeader flag was a very coarse control as it would allow any header that was unknown to the 
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.

Starting in version 4.0, the 

Spacevars
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introduced a more robust future-proofing mechanism called the Transparency Profile. 
Spacevars
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Spacevars
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version 4.2 extends the Transparency Profile with similar support for SIP message bodies and the flexible ability to explicitly exclude some headers and/or methods.

3.2 Transparency Profile

A Transparency Profile is a user-configurable profile allowing the user to transparently pass almost any SIP header/body through the

Spacevars
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. It is no longer necessary for a user to request 
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to create a specific Transparency Flag for the desired header/body.

Both already-known and previously-unknown SIP headers and bodies can be configured in a Transparency Profile. By default, no headers or message bodies are present in a Transparency Profile. Up to 256 unique Transparency Profiles can be created on the 

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and Transparency Profiles are applied on a SIP Trunk Group basis.

When a header or body is specified in a Transparency Profile, the profile will take precedence over any applicable Transparency Flag. For headers not specified in a transparency profile, the setting of existing Transparency Flags will continue to determine the transparency of that header. In this way, a Transparency Profile can either override or augment existing Transparency Flag settings. This document will describe some usage scenarios where both mechanisms may be used together.

When configuring a Transparency Profile for specific SIP headers,

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recommends that the unknownHeader flag be disabled (similarly, when configuring a Transparency Profile for specific SIP message bodies, 
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recommends that the unknownBody flag be disabled).

Info
For additional details, see https://doc.rbbn.com/display/SBXDOC42/Transparency+Profile.
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3.2.1 SIP Message Header

Starting in version 4.0, the 

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introduced the Transparency Profile, where one or more SIP headers can be configured in a single profile to be passed transparently through. Version 4.2 extended the abilities of the Transparency Profile further. It now supported transparency for out-of-dialog messages, the ability to exclude specific headers from transparency and the ability to configure transparency on a per-method basis (e.g. INVITE, REGISTER, SUBSCRIBE, REFER, etc...), where specific methods can be excluded from transparency for that header. If no methods are specified to be excluded, then the configured header will be transparent for all methods.

Code Block
languagenone
set profiles services transparencyProfile <profile> sipHeader <SIP Header>

where <SIP Header> is case insensitive, supports up to 31 characters, and supports an "all" entry to match all headers (see section 3.3 for exceptions).

The ability to exclude specific headers from transparency is primarily intended for use in conjunction with the "all" header option.

SIP headers are also configurable using compact form. When configuring specific headers in a Transparency Profile,

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  recommends the configuration of both compact and long forms.

Info
See IANA for the SIP header fields and their compact forms at: +http://www.iana.org/assignments/sip-parameters/sip-parameters.xhtml+

Compact form can be received by the

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, but the 
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Spacevars
0product
never generates the Compact form of any headers.

The 

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Spacevars
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does not send multiple header instances as a comma separated list; they are always sent as separate headers.

The following SIP headers are not controlled by the Transparency Profile (or any Transparency Flags), and are ignored if configured in a profile:

  • Allow
  • Call-ID
  • CSeq
  • Max-Forwards
  • Require
  • RSeq
  • Supported

If Contact Header is specified in a Transparency Profile, then it is treated as full Contact transparency and it will take precedence over other Contact related flags (such as useZoneLevelDomainNameInContact).

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3.2.2 SIP Message Body

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Spacevars
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version 4.2 extends the Transparency Profile with similar support for SIP message bodies. In addition, both message header and body transparency is configurable on a per-method basis (e.g. INVITE, REGISTER, SUBSCRIBE, REFER, etc...), where specific methods can be excluded from transparency for that body. If no methods are specified to be excluded, then the configured body is transparent for all methods.

Code Block
languagenone
set profiles services transparencyProfile <profile> sipMessageBody <Content-Type> 

where <Content-Type> is case insensitive, supports up to 127 characters, and supports an "all" entry to match all message bodies except those described in the below list.

The following Content-Types are not controlled by the Transparency Profile and are ignored if configured in a profile:

  • application/sdp
  • application/dtmf
  • application/dtmf-relay
  • application/sonus-media
  • application/broadsoft
  • application/isup
  • multipart/mixed
  • multipart/related

Multipart/mixed and multipart/related are ignored because the 

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automatically matches each component message body contained within a multipart message independently. For example, if "application/qsig" is configured in a profile, the 
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will match it even if it is contained within a multipart/mixed message with no additional configuration needed.

A Transparency Profile cannot control the SDP (application/sdp). The SDP and its controls will be discussed later in this document.

The other exceptions are due to existing Relay Flags (see table below) elsewhere within the 

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.

Caption
0Table
1Relay Flags That Control SIP Message Bodies

Relay Flag

Configuration Location

Content Applicability

dtmfBody

IP Signaling Profile

application/dtmf and application/dtmf-relay

sonusMediaBody

IP Signaling Profile

application/sonus-media

thirdPartyBodies

IP Signaling Profile

application/broadsoft

isupMimeBodyRelay

SIP Trunk Group

application/isup

See RelayFlags below for details.

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3.3 SIP Header Transparency Behaviors

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 transparency mechanisms control the initial INVITE, its responses, and other requests/responses within the INVITE dialog, as well as REGISTER, BYE, UPDATE, REFER, INFO, PUBLISH, MESSAGE, OPTIONS, SUBSCRIBE, NOTIFY requests and their responses (this assumes that the request method has been allowed by the applicable Relay Flag: INFO, MESSAGE, etc…).
There are some exceptions to the transparency mechanisms. Some SIP Methods and some SIP headers are not affected by any configurable transparency mechanism, while other headers may not be affected by transparency controls in some scenarios (in-dialog vs. out-of-dialog).

3.3.1 
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Non-Transparent Methods and Scenarios

The following SIP methods are not supported by a Transparency Profile (or any Transparency Flags):

  • ACK (even if the endToEndAck flag is enabled)
  • CANCEL
  • PRACK

3.3.2 
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Non-Transparent Headers

The following SIP headers are not supported by a Transparency Profile (or any Transparency Flags):

  • Allow

  • Call-ID

  • CSeq

  • Max-Forwards

  • Require

  • RSeq

  • Supported

These SIP headers are entirely added and/or modified by the 

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itself and cannot be transparently passed.

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3.3.3 In-Dialog vs. Out-of-Dialog

Some header behaviors vary depending on whether they are received in or out of an existing dialog. While the Transparency Profile has been extended in 4.2 to apply to out-of-dialog messages, there are some specific headers whose behavior is not under the control of a Transparency Profile (or Transparency Flags) when received in out-of-dialog messages.

A Dialog "represents a peer-to-peer SIP relationship between two user agents that persists for some time. The dialog facilitates sequencing of messages between the user agents and proper routing of requests between both of them. The dialog represents a context in which to interpret SIP messages." (reference: RFC 3261)

The 

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can receive messages within a dialog or outside of a dialog, and treats them differently based upon that relationship (or lack thereof).

Out-of-Dialog header behavior irrespective of the Transparency Profile or Flags:

Caption
0Table
1Out-of-Dialog SIP Header Behavior

SIP Header

Out-of-Dialog Behavior

Accept-Language

Sent

Alert-Info

Sent

Also

Dropped

Anonymity

Dropped

Authorization

Sent

Content-Length

Sent

Diversion

Dropped

Error-Info

Sent

Event

Sent

Expires

Sent

Min-Expires

Sent

Min-SE

Sent

P-Charge-Info

Dropped

P-DCS-Billing-Info

Dropped

P-K-Cfl

Dropped

P-K-Cfo

Dropped

P-Preferred-Identity

Dropped

P-Sig-Info

Dropped

Path

Dropped

Proxy-Authenticate

Sent

Proxy-Authorization

Sent

Proxy-Require

Sent

RAck

Sent

Reason

Sent

Record-Route

Dropped

Refer-Sub

Sent

Remote-Party-ID

Dropped

Reply-To

Dropped

Requested-By

Dropped

Resource-Priority

Sent

Retry-After

Sent

RSeq

Sent

Service-Route

Dropped

Session-Expires

Sent

Subscription-State

Sent

Warning

Sent

WWW-Authenticate

Sent

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3.4 SDP

The

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supports anchoring the following media types:

  1. Audio
  2. Video Main
  3. Video Extended (for Content Share)
  4. Binary Floor Control Protocol (UDP and TCP)
  5. Far End Camera Control (FECC)
  6. Message Session Relay Protocol ( MSRP)

For all the above mentioned media types (with the exception of Audio), the 

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0product
consumes (hence does not transparently relay) the following attributes that are required to anchor the media:

  • C line
  • RTCP attributes
  • Media direction (a= sendrecv/sendonly/inactive/recvonly)
  • Spacevars
    0product
    supports Secure Real-Time Transport Protocol (SRTP) media pass-through for SRTP and Secure Real-Time Transport Control Protocol (SRTCP) media streams.

For Audio, the 

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0product
does not transparently relay the following attributes in addition to the above mentioned attributes:

You must enable Video (assign a valid video bandwidth) and Audio transparency to achieve the above described behavior using the below CLI syntax.

Note

Associate the following configuration with both Trunk Groups.

Code Block
languagenone
% set profiles media packetServiceProfile <packetServiceProfileName> packetToPacketControl transcode transcoderFreeTransparency
% set addressContext <addressContextName> zone <zoneName> sipTrunkGroup <trunkGroupName> media sdpAttributesSelectiveRelay enabled
% set addressContext <addressContextName> zone <zoneName> sipTrunkGroup <trunkGroupName> media lateMediaSupport passthru 
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3.4.1 SRTP Pass-through

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supports SRTP media pass-through for SRTP and SRTCP media streams. SBC does not terminate the SDP security description or SRTP media streams and passes them through without authenticating, decrypting, and encrypting. In this pass-through mode of operation, SBC treats SRTP media as plain text RTP pass-through media.

The following diagram illustrates the media flow for an SRTP pass-through call.

Caption
0Figure
1SRTP Packet to Packet Media Call Flow

Note
  • Secure RTP and Secure RTCP pass-through flows are supported for end-to-end security-associated peers.
  • This feature does not support media transcoding, DTMF interworking, and Lawful Intercept (LI).

To control this SRTP media pass-through, a new allowPassthru flag is introduced to the secureRtpRtcp of PSP. When allowPassthru flag is enabled along with the security enableSrtp flag, it allows SBC topass-through SRTPmedia without authenticating, decrypting, and encrypting it internally. When selected, this flag prioritizes SRTP pass-through media over terminated SRTP media. When disabled, this flag terminates all SRTP and SRTCP media for authentication, encryption, or decryption. This flag is disabled by default.

3.4.2 SDP Transparency Flag

Make note that the sdpTransparencyState signaling object within the SIP Trunk Group should not be considered a general use parameter.  It is specific to some functionality (mainly ICE) and environments; however, this flag does not apply to all types of call flows.

Note
Do not enable the sdpTransparencyState flag unless specifically directed to do so by 
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Design or Support engineers.

Anchor
RelayFlags
RelayFlags
3.5 Relay Flags

Relay Flags exist mostly within the IP Signaling Profile (IPSP; ipSignalingProfile > commonIpAttributes > relayFlags) and apply on the ingress leg of a session (ingress relative to the SIP message).
Relay Flags are intended mainly for SIP Methods (Requests) and Responses (and some SIP message bodies) that normally get consumed or modified by the 

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when received in the incoming SIP message.

Albeit imprecise, a good method to contrast Relay Flags and Transparency Flags/Profiles is to consider that Relay controls whether a SIP request/response is sent through the

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, while the Transparency controls whether a header/body in a SIP request/response is sent through the
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.

Caption
0Table
1Configuration Locations of Relay Flags

Relay Flags

Configuration Location

conferenceEventPackage

IP Signaling Profile > Common IP Attributes

dialogEventPackage

IP Signaling Profile > Common IP Attributes

dtmfBody

IP Signaling Profile > Common IP Attributes

force503to500Relay

IP Signaling Profile > Common IP Attributes

info

IP Signaling Profile > Common IP Attributes

message

IP Signaling Profile > Common IP Attributes

notify

IP Signaling Profile > Common IP Attributes

options

IP Signaling Profile > Common IP Attributes

publish

IP Signaling Profile > Common IP Attributes

refer

IP Signaling Profile > Common IP Attributes

referToHeaderRelay

IP Signaling Profile > Common IP Attributes

regEventPackage

IP Signaling Profile > Common IP Attributes

sonusMediaBody

IP Signaling Profile > Common IP Attributes

statusCode3xx

IP Signaling Profile > Common IP Attributes

statusCode4xx6xx

IP Signaling Profile > Common IP Attributes

thirdPartyBodies

IP Signaling Profile > Common IP Attributes

updateWithoutSdp

IP Signaling Profile > Common IP Attributes

isupMimeBodyRelay

SIP Trunk Group > Signaling

relayUpdatewithSdp

SIP Trunk Group > Signaling

3.6 Relaying REFER Request

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is enhanced to relay REFER request, even though the refer relay flag is disabled. To support this enhancement, a new  Conditional Relay Matching criteria is introduced. Using this criteria, 
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decides whether to relay and process the REFER request message or not.

If the refer relay flag is disabled, the Call Control (CC) mechanism forwards the REFER request to Digital Signaling (DS). DS exchanges information with the PSX to check the match criteria set in Conditional Relay Matching. 

The matched criteria includes call parameters such as Username, Directory Number (DN), or Fully Qualified Domain Name (FQDN).

  • If the call parameters received with the REFER request match the call routing criteria, 
    Spacevars
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    relays the REFER request to Egress SIPSG.
  • If the call parameters received with the REFER request do not match the call routing criteria, the REFER request is processed locally by
    Spacevars
    0company
    . The REFER request acts as the transferor and the call is forwarded to the Egress SIPSG, resulting in call bridging. In this scenario, 
    Spacevars
    0company
    sends back a 202 response and proceeds for local processing.
Note

If a REFER request is sent after a switchover and:

  • If the refer relay flag is enabled, 
    Spacevars
    0company
    relays REFER request.
  • If the refer relay flag is disabled and DN/username/FQDN match, 
    Spacevars
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    relays the REFER request.
  • If the refer relay flag is disabled and no DN/username/FQDN match, the REFER request is rejected. 
    Spacevars
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    cannot locally process the REFER request.
Note

This feature is supported only for Blind/Unattended Transfer calls and not for Attended Transfer (refer with replaces) calls.

Caption
0Figure
1The following figure shows the enhanced REFER request processing call flow:

3.6.1 Configuring 
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For Enhanced Refer Processing

To configure this feature, perform the following steps:

  1. Configure 
    Spacevars
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    for regular REFER call Blind Transfer.
  2. Create SIP_MSG_TYPE_REFER call parameter filter profile (CPFP) in the PSX. Execute the following command to view the CPFP SIP_MSG_TYPE_REFER. This profile is already present in ERE.

    Info

    For more information on creating CPFP, refer to PSX documentation.

    Code Block
    > show table profiles callParameterFilterProfile
    Description:
    Profile used for routing based on SIP message type.
    
    Possible completions:
      SIP_MSG_TYPE_INFO      - SIP Message Type is Info
      SIP_MSG_TYPE_MESSAGE   - SIP Message Type is Message
      SIP_MSG_TYPE_NOTIFY    - SIP Message Type is Notify
      SIP_MSG_TYPE_REFER     - SIP Message Type is Refer
      SIP_MSG_TYPE_REGISTER  - SIP Message Type is Register
      SIP_MSG_TYPE_SUBSCRIBE - SIP Message Type is Subscribe
      none                   - seed data for provisioning support
    
    

    All > Profiles > Call Parameter Filter Profile

    Caption
    0Figure
    1Call Parameter Filter Profile List showing SIP_MSG_TYPE_REFER profile

    Note

    A new script SONS_SIP_REFER_RELAY is seeded in both ERE and PSX.

  3. Disable the Refer relay flag in IPSP.

    Code Block
    % set profiles signaling ipSignalingProfile DEFAULT_SIP commonIpAttributes relayFlags refer disable
  4. Enable the Notify relay in Egress side on IPSP to relay REFER for DN/Username/FQDN match.

    Code Block
    % set profiles signaling ipSignalingProfile DEFAULT_SIP commonIpAttributes relayFlags notify enable

    All > Profiles > Signaling > Ip Signaling Profile > Common Ip Attributes > Relay Flags

    Caption
    0Figure
    1Notify and Refer relay flags

  5. Create a new routing label with the script SONS_SIP_REFER_RELAY to trigger process refer request feature.

    Note

    The routing label action must be set as script.

    Code Block
    % set global callRouting routingLabel <routing_label> script SONS_SIP_REFER_RELAY action script

    All > Global > Call Routing > Routing Label

    Caption
    0Figure
    1Creating a Routing Label

    Caption
    0Figure
    1 Routing Label screen

  6. Configure a DN criteria in the standard route and attach the SIP_MSG_TYPE_REFER profile to the standard route by executing the following command:

    Code Block
    % set global callRouting route none Sonus_NULL Sonus_NULL standard  <Matched_DN or FQDN> 1 all ALL SIP_MSG_TYPE_REFER Sonus_NULL routingLabel <routing_label>

    For DN (Directory Number) or username

    Code Block
    % set global callRouting route none Sonus_NULL Sonus_NULL standard <Matched_DN or Username> 1 all ALL SIP_MSG_TYPE_REFER Sonus_NULL  routingLabel <routing_label>

    For FQDN with DN or username

    Note

    The corresponding Sip domain group must be configured in

    Spacevars
    0company
    .

    Code Block
    % set global sipDomain <Matched_domain_name >
     
    % set global callRouting route none Sonus_NULL Sonus_NULL standard <Matched_DN or Username> 1 all ALL SIP_MSG_TYPE_REFER  <Matched_domain_name> routingLabel <routing_label>
    
    

    All > Global > Call Routing > Route

    Caption
    0Figure
    1Creating a Route

    Caption
    0Figure
    1Route screen

  7. Execute the following commands to view the call detail status and call media status.

    Code Block
    > show status global callDetailStatus 
    or
    > show status global callMediaStatus 
    
    
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3.7 Transparency Profile Usage

As discussed previously, the Transparency Profile does not deprecate any existing Transparency Flag. Those flags continue to function as designed. When a header/body is specified in a Transparency Profile, then the profile takes precedence over any applicable Transparency Flag. For headers/bodies not specified in a transparency profile, the setting of existing Transparency Flags continues to determine the transparency of that header.

When configuring a Transparency Profile for specific SIP headers,

Spacevars
0company
recommends disabling the unknownHeader flag (similarly, when configuring a Transparency Profile for specific SIP message bodies, 
Spacevars
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recommends disabling the unknownBody flag).

3.7.1 Maximum Transparency using the Transparency Profile

Complete or maximum transparency is occasionally desired, especially during initial integration testing to determine if specific headers are required for the success of certain call flows.

Code Block
languagenone
set profiles services transparencyProfile MAX_TRANSPARENCY sipHeader all
set profiles services transparencyProfile MAX_TRANSPARENCY sipMessageBody all
set profiles services transparencyProfile MAX_TRANSPARENCY state enabled
commit
set addressContext <AC> zone <ZONE> sipTrunkGroup <TG> services transparencyProfile MAX_TRANSPARENCY
commit 

Additional Relay Flags also need to be enabled to maximize the transparency of the Trunk Group for testing. See Relay Flags above.

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3.7.2 Transparency Profile, All Headers, with Exceptions

The ignoreTransparency header option within the Transparency Profile is primarily used for excluding one or more specific headers when paired with the "all" header option. In the example below, the user wishes to pass all SIP headers except for the History-Info header.

Code Block
languagenone
set profiles services transparencyProfile ALMOST_ALL_HDRS sipHeader all
set profiles services transparencyProfile ALMOST_ALL_HDRS sipHeader History-Info ignoreTransparency yes
set profiles services transparencyProfile ALMOST_ALL_HDRS state enabled
commit
set addressContext <AC> zone <ZONE> sipTrunkGroup <TG> services transparencyProfile ALMOST_ALL_HDRS
commit

3.7.3 Existing Deployment Augmented with a Transparency Profile

Existing deployments will likely utilize Transparency Flags, and those that must pass proprietary or otherwise 

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unsupported SIP headers will most likely make use of the unknownHeader transparency flag in an IP Signaling Profile.

While a Transparency Profile can be configured to completely overlap with any existing Transparency Flags settings, it is not required. A Transparency Profile can be configured to simply augment existing Transparency Flags settings with a more surgical configuration and allowing unknownHeader to be disabled.

For example, a user may wish to have the 

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transparently pass RFC 4474 identity headers. Prior to the introduction of the Transparency Profile, the user would have had to enable the unknownHeader transparency flag.

Rather than continue to allow all unknown headers through the

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, the user can configure a Transparency Profile that only allows the RFC 4474 identity headers (configured in standard and compact forms) and disable the unknownHeader transparency flag.

Code Block
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set profiles services transparencyProfile IDENTITY_HDRS sipHeader Identity
set profiles services transparencyProfile IDENTITY_HDRS sipHeader y
set profiles services transparencyProfile IDENTITY_HDRS sipHeader Identity-Info
set profiles services transparencyProfile IDENTITY_HDRS sipHeader n
set profiles services transparencyProfile IDENTITY_HDRS state enabled
commit
set addressContext <AC> zone <ZONE> sipTrunkGroup <TG> services transparencyProfile IDENTITY_HDRS
commit
set profiles signaling ipSignalingProfile <IPSP> commonIpAttributes transparencyFlags unknownHeader disable
commit
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3.8 Audio Transparency

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for the audio m line allows relaying unknown attributes. 
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allows transparency for subset of attributes like rtpmap, fmtp, and T38 fax. Audio transparency functionality is used to manage bandwidth for audio stream in the pass-through calls. By enabling this feature, audio codecs that are unknown to the system are available to establish audio calls or streams.

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supports audio transparency for known attributes by relaying attributes and codecs transparently in pass-through scenarios for SIP-SIP calls only. However, the following exceptions require system handling:

  • recvonly/sendonly/sendrecv/inactive
  • crypto
  • X-dmi
  • rtcp
  • fingerprint
  • OMR
Note

This feature does not support H323-H323 and GW-GW calls.

Audio Transparency Feature is controlled by two flags:

  • Enable Transcoder-Free-Transparency for the session (enable on either of the PSPs).
  • Enable Selective-SDP-Transparency on both ingress and egress Trunk Groups that receive the relayed SDP.

Bandwidth (b) lines are transparently relayed and do not play any role in calculating the unknown audio codec bandwidth. The following PSP configuration bits for Audio Transparency feature are included for Unknown audio bandwidth reservation to calculate the Unknown audio bandwidth:

  • unknownCodecBitRate
  • unknownCodecPacketSize

Note

If the bandwidth is not configured, the default settings (Packet Size—10 ms and Bit Rate—124 KB/s) are used for a pass-through call.

3.8.1 Audio Transparency and Reserve Bandwidth for Preferred Common Codec

By default for pass-through calls, 

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reserves the worst case common audio codec bandwidth on Trunk Groups and IP interfaces, and polices for the same bandwidth. To facilitate pass-through calls scenarios/cases, where media uses the preferred common codec the flag reserveBwForPreferredAudioCommonCodec is added to reserve the bandwidth associated with the preferred common codec (instead of the worst case common codec) on the Trunk Groups and IP interfaces. When this flag is enabled, bandwidth of the first common codec from Answer (SIP) is used for reservation and bandwidth of the heaviest common codec is used for policer.

Note

This flag can be used independently or in conjunction with Audio Transparency feature and/or policeOnHeaviestAudioCodec flag. This functionality is currently supported for SIP-SIP  call scenarios only. In the event that policeOnHeaviestAudioCodec and reserveBwForPreferredAudioCommonCodecare both configured, the following behavior applies:

  • reserveBwForPreferredAudioCommonCodec impacts the bandwidth reservation policy. That is, first common codec from Answer (SIP) and,
  • policeOnHeaviestAudioCodec impacts the policer configuration. That is, heaviest codec in the offer or answer.
Note

The flag reserveBwForPreferredAudioCommonCodec is active for a call when both the PSPs have this flag enabled. If this flag is disabled in any of the PSPs, the flag is not applied.

3.8.2 Media Policer Reservation For Worst Case Codec

By default, for pass-through calls the

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reserves the worst case common audio codec bandwidth on trunk groups and IP interfaces, and polices for the same bandwidth. To facilitate asymmetric pass-through calls scenarios/cases and to police on the heaviest codec in the offer or answer, a new flag policeOnHeaviestAudioCodec is introduced in PSP.

Note

This flag can be used independent of or in conjunction with Audio transparency feature and/or reserveBwForPreferredAudioCommonCodec flag. This functionality is currently supported for SIP-SIP  call scenarios only.

3.8.3 Configuring Audio Transparency

Configuring the basic audio transparency feature contains:

Anchor
Enabling the sdpAttributesSelectiveRelay Parameter on Both Ingress and Egress Trunk Groups
Enabling the sdpAttributesSelectiveRelay Parameter on Both Ingress and Egress Trunk Groups
Enabling the sdpAttributesSelectiveRelay Parameter on Both Ingress and Egress Trunk Groups

Code Block
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% set addressContext default zone ZONE1 sipTrunkGroup TG_SBX_INT media sdpAttributesSelectiveRelay enabled
% set addressContext default zone ZONE2 sipTrunkGroup TG_SBX_EXT media sdpAttributesSelectiveRelay enabled

Anchor
Configuring the transcoderFreeTransparency Parameter on Packet Service Profile
Configuring the transcoderFreeTransparency Parameter on Packet Service Profile
Configuring the transcoderFreeTransparency Parameter on Packet Service Profile

Code Block
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% set profiles media packetServiceProfile PSP_INT packetToPacketControl transcode transcoderFreeTransparency 
% set profiles media packetServiceProfile PSP_EXT packetToPacketControl transcode transcoderFreeTransparency

Anchor
Configuring audioTransparecy Parameter on Packet Service Profile
Configuring audioTransparecy Parameter on Packet Service Profile
Configuring audioTransparecy Parameter on Packet Service Profile

Code Block
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% set profiles media packetServiceProfile PSP_INT audioTransparency unknownCodecBitRate 124
% set profiles media packetServiceProfile PSP_EXT audioTransparency unknownCodecBitRate 124

% set profiles media packetServiceProfile PSP_INT audioTransparency unknownCodecPacketSize 10
% set profiles media packetServiceProfile PSP_EXT audioTransparency unknownCodecPacketSize 10

% set profiles media packetServiceProfile PSP_INT flags reserveBwForPreferredAudioCommonCodec enable
% set profiles media packetServiceProfile PSP_EXT flags reserveBwForPreferredAudioCommonCodec enable
Note

For configuring Bit Rate (kbps), Packet Size (ms) and Reserve BW For Preferred Audio Common Codec for pass-through calls flags on PSX, see PSX Documentation.

3.9 SIP Param Filter Profile

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is enhanced to support SIP Param Filter Profile to allow the operator to create a profile defining a set of SIP header tags and methods to transparently pass or block, and then assign that profile to a trunk group. The SIP headers configured in this profile for pass-through are transparently passed to the Egress trunk group if received in the Ingress SIP message. 

The SIP Param Filter Profile includes the following characteristics:

  • This profile takes precedence over existing mechanism/flags when transparently passing Allow/Supported/Require headers, but does not impact corresponding configurations established by the operator. It is operators responsibility to ensure the system is configured properly so that transparently-passed values do not conflict with existing configurations. For example, do not configure 100rel as pass-through if 100rel support fro SIP Trunk Group Signaling is disabled.
  • The settings of SIP Param Filter Profiles for both ingress and egress legs dictate the actual pass-through results (see SIP Param Filter Profile Behavior table below for details.)
  • Pass-through of individual header values is configurable.
  • SIP tags are provided for unknown SIP parameter transparency only. Known SIP parameter transparency is still determined using existing SBC application logic (from Ingress leg to Egress leg) and configurations.
Info
The SBC supports configuring up to 32 SIP Param Filter Profiles. Each profile can be configured using any/all of the SIP headers Allow/Supported/Require.

The following table explains the SIP Param Filter Profile behavior when using the Allow, Supported and Require headers.

Caption
0Table
1SIP Param Filter Profile Behavior
3SIP Param Filter Profile Behavior
HeaderSIP Param Filter Profile Processing
Allow

Ingress leg:

The Allow header in the received message is processed after Ingress SIP Message Manipulation (SMM) processing but before any other SBC processing occurs.

  • Pass-through <method list> –  Any methods present in the Allow header but not included in the method list are removed.
  • Pass-through "all" – All methods present in the Allow header are left intact.
  • Block <method list> – Methods specified in the <method list> which exist in the Allow header are removed.
  • Block "all" – All methods present in the Allow header are removed.

Egress leg:

The Allow header in the message to be egressed by SBC is processed after all SBC processing but before Egress SMM processing is performed.

  • Pass-through <method list> – Any methods present in the Allow header to be egressed but not specified in the <method list> are removed.
  • Pass-through "all" – All methods present in the Allow header are left intact.
  • Block <method list> – Any methods present in the <method list> are removed if they exist in the Allow header.
  • Block "all" – All methods present in the Allow header are removed.

Require/Supported

Ingress leg:

The Require/Supported header in the received message is processed after Ingress SMM processing but before any other SBC processing occurs.

  • Pass-through <option tag list> – Any Option tags present in the Require/Supported header but not specified in the <option tag list> are removed.
  • Pass-through "all" – All Option tags present in the Require/Supported header are left intact.
  • Block <option tag list> – Any Option tags present in the <option tag list> are removed if they exist in the Require/Supported header.
  • Block "all" – All Option tags present in the Require/Supported header are removed.

Egress leg:

The Require/Supported header in the message to be egressed by SBC is processed after all SBC processing but before Egress SMM processing occurs.

  • Pass-through <option tag list> – Any Option tags present in the Require/Supported header to be egressed but not in the <option tag list> are removed.

  • Pass-through "all" –All Option tags present in the Require/Supported header are left intact.

  • Block <option tag list> – Any Option tags present in the <option tag list> are removed if they exist in the Require/Supported header.
  • Block "all" – All Option tags present in the Require/Supported header are removed.

If an option tag present in the received Ingress request is dropped due to Require transparency settings, and if rejectRequest is configured, the request is rejected with a new internal cause code. This internal cause code is mapped to 420 "Bad Extension" by default. Option tags added to Require header due to SBC processing (e.g. path) are not rejected even if they are eventually dropped by the Require transparency functionality.

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