OpenSIPS and SIP PATH Extension

.

Introduction

RFC 3327 (SIP Path Extension) specifies a way to discover and record the sequence of proxies between the UA and the registrar. The constructed routing path will be stored in the database of the registrar along with the corresponding contact address. Each intermediate proxy (NOT terminating routing point) that wants to stay in the routing path, inserts its URI as a new “Path” header field (or as value in the “Path” header field). This mechanism is applied only to requests that are transiting or originating in the home domain. The constructed routing path will be carried as pre-loaded Route set in the upcoming initial requests. This mechanism is similar to the operation of Record-Route mechanism in dialog-initiating requests (In-dialog/Sequential requests) and it can be combined with it (Example – Invite Transaction).

In this article i will talk about SIP Path extension in OpenSIPS context.

Example

Assume we have this scenario:

UA1 – – – – P1 (Outbound Proxy) – – – – P2 – – – – Registrar/Home-Proxy (OpenSIPS) – – – – UA2

The outgoing proxy is the first hop after client’s NAT . The home proxy is a terminal point for SIP routing. The requested path starts by the outgoing proxy and ends at the registrar/home proxy. It is not common that the UA adds a “Path” header field in the request.

OpenSIPS As Registrar/Home-Proxy

OpenSIPS “Registrar” module has “Path” support. When OpenSIPS receives a SIP Register request, it calls the function save(..), among others. Upon calling this function, the values of the Path header(s) along with the contact address will be stored in the database (User Location Table). The contact address will be stored in the column “contact” and the values of Path header(s) will be stored in the column “path”.

In our scenario, if the proxies P1 and P2 receive a Register request and want to be in the path vector, each one adds its own SIP address as a top most value in the “Path” header field and forward the request. When the request reached the registrar, the path vector will be: Path: <sip:P2.testdomain.com;lr>,<sip:P1.testdomain.com;lr>.

The function save(…) takes some flags as a single string parameter. Among others, we have these flags that are related to the “Path” support:

  • p0‘ (OFF Mode): The path vector will be saved in the user location table but it will not be included in the reply of the Register request.
  • p1‘ (Lazy Mode): The path vector will be saved in the user location table and it will be included in the reply only if the UA indicated path support in the request (add the tag “path” as a value in the “Supported” header field of the request: “Supported: path”).
  • p2‘ (Strict Mode): The path vector will be saved in the user location table only if the the UA indicated path support in the registration request (add the tag “path” as a value in the “Supported” header field of the request). If it is not indicated, the request is rejected with “420 – Bad Extension” and the header “Unsupported: path” will be included in the reply along with the received path vector.

The flags above enable “path” support in “registrar” module and specify the mode of this support as well.

According to all above and if the path vector {p2,p1} is sent in the response, the UA can use the path (as preloaded Route set) in the future requests if that is allowed by the policy. In addition to this, any request reached the home proxy can be routed based on that path {p2,p1} which is stored in the database of the registrar.

According to RFC 3327:

The intermediate proxies (not terminating points) should not add a “Path” header field to a request unless the UA add the tag “path” as a value in the “Supported” header field in that request. Here we say the UA indicated support for PATH extension. If the UA indicated path support and the intermediate proxy requires path support in the registrar, then the proxy adds the tag “path” as a value in the “Requires” header field in that request. If the UA has not indicated support for path and the proxy requires support for it in the registrar, the proxy should reject the request with 421 response. This nearly corresponds to using the flag ‘p2’ in the “save” function: save(“location”,”p2″).

The “save(…)” function has also flag ‘v‘ (path received). If this flag is set, the “received” parameter of the first Path URI of a registration {p1} is set as received-uri and the NAT branch flag is set for this contact. This will be explained further down.

To use multiple flags in the “save(…)” function, mix them as one string. Example: save(“location”,”p2v”).

The routing script will have these lines, among others:

….

if (method == “REGISTER”) {

save(“location”, “p2v”);
}

Registrar’s Lookup Operation

When for example UA2 wants to call UA1 (Send Invite request). When the request reached OpenSIPS that operates as a registrar/home proxy, it looks up (Call the function lookup(..)) the AOR of UA1 (UA1@testdomain.com) and returns:

  • Contact = <sip:UA1@192.18.8.10>

  • Path vector= <sip:P2.testdomain.com;lr>,<sip:P1.testdomain.com;lr>

The Request-URI is overwritten by the registered contact address and the Path vector {p2,p1} is inserted as Route set in the same order {p2,p1} in the outgoing Invite request. The topmost Route header field (proxy: p2) is used for routing decision (next hop) in conjunction with the local policy. Calling this function, also sets the destination URI to the first Path URI (outbound proxy: p1).

OpenSIPS As Outbound Proxy with NAT Detection

OpenSIPS has a module named “path” which is designed to be used at intermediate SIP proxies (e.g. outgoing proxy, load balancer,..etc.). Assume we have this scenario:

UA1 – – – NAT – – – P1 (Outbound Proxy -OpenSIPS) – – – P2 – – – Registrar/Home-Proxy

P1 is OpenSIPS that operates as outgoing proxy with NAT detection. To use “path” module, it must be configured in the routing script to be loaded at startup (loadmodule “path.so”). The module “rr” must be loaded before so it must be configured to be loaded before. To insert a path header into Register message, two functions are exported by this module:

  • The function “add_path(…)” which adds a path header in this form “Path: <sip:1.2.3.4;lr>” .The IP address is the IP address of the proxy’s outgoing interface. A port is only added if it is not the default (5060). If it is called with username as parameter, then the username will be added to the URI “Path: <sip:username@1.2.3.4;lr>“.
  • The function “add_path_received(…)” which adds a path header in this form:

Path: <sip:1.2.3.4;received=sip:2.3.4.5:1234;lr>

In our scenario, the outbound proxy p1 will call the function “add_path_received” upon receiving a Register message. The received parameter of its Path URI contains the address where the request has been received (NAT’ed address). This is used to pass the NAT’ed address to the registrar through the next proxy if exists. If it is called with username then the username is added to the URI: “Path: <sip:username@1.2.3.4;received=sip:2.3.4.5:1234;lr>“. Then the proxy will forward the message further to next hop on a way to the registrar.

If the parameter “use_received” exported from “path” module is set to 1 by the outgoing proxy (modparam(“path”, “use_received”, 1), then when the proxy receives a request, the “received” parameter of the its Route URI  (first Route URI ) is evaluated and used as destination URI(route the request to this address).

This behaviour of outbound proxy is considered as complement to registrar behaviour (SIP Path Extension-aware behaviour of Save(…) and Lookup(…)). So Keep the outbound proxy in the constructed path.

The routing script will have these lines, among others:

loadmodule “path.so”

modparam(“path”, “use_received”, 1)

if (method == “REGISTER”) {
if (!add_path_received(“Outbound”))
sl_send_reply(“503”, “Internal Path Error”);

}


Notes

  • SIP “Path” extension is very useful for SIP loadbalancers that are in front of registrars and proxies. As it helps in drawing SIP routing paths.
  • If you like to manipulate the “received” parameter of the Path URI by yourself in the script (not recommended), you can use the script core variables: $Ri which is the IP address of the interface where the request has been received and $Rp which is the port number. Informations like these are detected by the transport of OpenSIPS (under the SIP layer).
  • If you do not understand the structure of the SIP URI. Go Here.

 More Information


Advertisements

Strict and Loose Routing of SIP Sequential Requests

.

Strict Routing of SIP Sequential Requests

Sequential requests within a dialog (like ACK, BYE, reINVITE) must take the path determined by record-routing and represented by Route set. In other words strict routing exactly follows the path represented by the Route set. Each strict router on the routing path, will route the SIP message as following: Rewrite the Request-URI with the topmost Route header field value and forward the message to the new Request URI. The Request-URI always contains the URI of the next hop. The next hop can be another SIP router or destination user agent. Strict Routing is legacy approach.

Loose Routing of SIP Sequential Requests

Sequential requests within a dialog should take the path determined by record-routing and represented by Route set. Loose routing of the sequential requests leaves the Request-URI and does not change it.

  • The sequential request has “To-tag” (i.e. belongs to a dialog) whereas the initial request does not have “To-tag” (does not belong to any dialog). The initial request (Method: INVITE, or SUBSCRIBE) creates the dialog.
  • The Request-URI of the sequential request contains the URI of the destination user agent (username@FQDN/IP) whereas the initial request has AOR (username@proxyDomain).
  • Taking a simple case where all routers on the routing path are loose routers and the user agents support loose routing (i.e. The user agent will not insert its URI (user@FQDN) in a Record-Route). According to this, we can say:

The Request-URI of the sequential request will not be changed by any proxy at all because the one who is responsible for the resource associated with this Request-URI is the destination user agent. Whereas the Request-URI of the initial request will be changed once by the proxy which is responsible for the domain in the Request-URI.

The last Route header field value will be for the last proxy in the routing path.

Upon this, the routing procedure will look like following:

The Pre-loaded Route header field values (Route Set in an initial SIP Request) should not be allowed for security reasons.

Note: Transition from strict routing to loose routing would break the compatibility with the older user agents. Avoiding this problem adds lot of overhead and causes problems.

Routing Path (Route Set) in SIP Message

Assume a set of loose proxies {P1 -> P2 -> P3}.

The Route set which will be included in the SIP sequential requests , will look like this:

Route: <sip:p1.domain.com;lr>,<sip:p2.domain.com;lr>,<sip:p3.domain.com;lr>

lr parameter is added to indicate that the router is a loose router. If the SIP router is strict, then the URI will not have the lr parameter.

In the strict routing,the Request-URI is overwritten so we keep the destination user agent (the contact address) in an additional Route header field value.

OpenSIPS Route Processing

In OpenSIPS, I would like to mention two important functions in “rr” module:

  • The function loose_route() which used in routing SIP requests that contain Route Set. For example to route the sequential requests we call this function as following:

if (has_totag()){

loose_route()

 # route it out to whatever destination was set by loose_route()
# in $du (destination URI).
route(relay);

}

If Route set is not empty the loose_route() returns TRUE and the destination uri ($du) is set to the first Route header field value.

  • The function record_route() which used for building the routing path by adding Record-Route header field value upon passing each proxy in a way the initial request follows to reach the destination user agent.

More Information