When a Session Initiation Protocol (SIP) [1] server receives a
request, there are a number of decisions it can make regarding the
processing of the request. These include:
o whether to proxy or redirect the request
o which URIs to proxy or redirect to
o whether to fork or not
o whether to search recursively or not
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o whether to search in parallel or sequentially
The server can base these decisions on any local policy. This policy
can be statically configured, or can be based on execution of a
program or database access.
However, the administrator of the server is the not the only entity
with an interest in request processing. There are at least three
parties which have an interest: (1) the administrator of the server,
(2) the user that sent the request, and (3) the user to whom the
request is directed. The directives of the administrator are
embedded in the policy of the server. The preferences of the user to
whom the request is directed (referred to as the callee, even though
the request method may not be INVITE) can be expressed most easily
through a script written in some type of scripting language, such as
the Call Processing Language (CPL) [11]. However, no mechanism
exists to incorporate the preferences of the user that sent the
request (also referred to as the caller, even though the request
method may not be INVITE). For example, the caller might want to
speak to a specific user, but wants to reach them only at work,
because the call is a business call. As another example, the caller
might want to reach a user, but not their voicemail, since it is
important that the caller talk to the called party. In both of these
examples, the caller's preference amounts to having a proxy make a
particular routing choice based on the preferences of the caller.
This extension allows the caller to have these preferences met. It
does so by specifying mechanisms by which a caller can provide
preferences on processing of a request. There are two types of
preferences. One of them, called request handling preferences, are
encapsulated in the Request-Disposition header field. They provide
specific request handling directives for a server. The other, called
feature preferences, is present in the Accept-Contact and Reject-
Contact header fields. They allow the caller to provide a feature
set [2] that expresses its preferences on the characteristics of the
UA that is to be reached. These are matched with a feature set
provided by a UA to its registrar [3]. The extension is very general
purpose, and not tied to a particular service. Rather, it is a tool
that can be used in the development of many services.
One example of a service enabled by caller preferences is a "one
number" service. A user can have a single identity (their SIP URI)
for all of their devices - their cell phone, PDA, work phone, home
phone, and so on. If the caller wants to reach the user at their
business phone, they simply select "business phone" from a pull-down
menu of options when calling that URI. Users would no longer need to
maintain and distribute separate identities for each device.
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In this document, the key words "MUST", "MUST NOT", "REQUIRED",
"SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY",
and "OPTIONAL" are to be interpreted as described in BCP 14, RFC 2119
[4] and indicate requirement levels for compliant implementations.
Much of the terminology used in this specification is presented in
[3]. This specification defines the following additional terms:
Caller: Within the context of this specification, a caller refers to
the user on whose behalf a UAC is operating. It is not limited to
a user whose UAC sends an INVITE request.
Feature Preferences: Caller preferences that describe desired
properties of a UA to which the request is to be routed. Feature
preferences can be made explicit with the Accept-Contact and
Reject-Contact header fields.
Request Handling Preferences: Caller preferences that describe
desired request treatment at a server. These preferences are
carried in the Request-Disposition header field.
Target Set: A target set is a set of candidate URIs to which a proxy
or redirect server can send or redirect a request. Frequently,
target sets are obtained from a registration, but they need not
be.
Explicit Preference: A caller preference indicated explicitly in the
Accept-Contact or Reject-Contact header fields.
Implicit Preference: A caller preference that is implied through the
presence of other aspects of a request. For example, if the
request method is INVITE, it represents an implicit caller
preference to route the request to a UA that supports the INVITE
method.
When a caller sends a request, it can optionally include new header
fields which request certain handling at a server. These preferences
fall into two categories. The first category, called request
handling preferences, is carried in the Request-Disposition header
field. It describes specific behavior that is desired at a server.
Request handling preferences include whether the caller wishes the
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server to proxy or redirect, and whether sequential or parallel
search is desired. These preferences can be applied at every proxy
or redirect server on the call signaling path.
The second category of preferences, called feature preferences, is
carried in the Accept-Contact and Reject-Contact header fields.
These header fields contain feature sets, represented by the same
feature parameters that are used to indicate capabilities [3]. Here,
the feature parameters represent the caller's preferences. The
Accept-Contact header field contains feature sets that describe UAs
that the caller would like to reach. The Reject-Contact header field
contains feature sets which, if matched by a UA, imply that the
request should not be routed to that UA.
Proxies use the information in the Accept-Contact and Reject-Contact
header fields to select amongst contacts in their target set. When
neither of those header fields are present, the proxy computes
implicit preferences from the request. These are caller preferences
that are not explicitly placed into the request, but can be inferred
from the presence of other message components. As an example, if the
request method is INVITE, this is an implicit preference to route the
call to a UA that supports the INVITE method.
Both request handling and feature preferences can appear in any
request, not just INVITE. However, they are only useful in requests
where proxies need to determine a request target. If the domain in
the request URI is not owned by any proxies along the request path,
those proxies will never access a location service, and therefore,
never have the opportunity to apply the caller preferences. This
makes sense because typically, the request URI will identify a UAS
for mid-dialog requests. In those cases, the routing decisions were
already made on the initial request, and it makes no sense to redo
them for subsequent requests in the dialog.
A caller wishing to express preferences for a request includes
Accept-Contact, Reject-Contact, or Request-Disposition header fields
in the request, depending on their particular preferences. No
additional behavior is required after the request is sent.
The Accept-Contact, Reject-Contact, and Request-Disposition header
fields in an ACK for a non-2xx final response, or in a CANCEL
request, MUST be equal to the values in the original request being
acknowledged or cancelled. This is to ensure proper operation
through stateless proxies.
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If the UAC wants to determine whether servers along the path
understand the header fields described in this specification, it
includes a Proxy-Require header field with a value of "pref" [3] in
its request. If the request should fail with a 420 response code,
the UAC knows that the extension is not supported. In that case, it
SHOULD retry, and may decide whether or not to use caller
preferences. A UA should only use Proxy-Require if knowledge about
support is essential for handling of the request. Note that, in any
case, caller preferences can only be considered preferences - there
is no guarantee that the requested service will be executed. As
such, inclusion of a Proxy-Require header field does not mean that
the preferences will be executed, just that the caller preferences
extension is understood by the proxies.
The Request-Disposition header field specifies caller preferences for
how a server should process a request. Its value is a list of
tokens, each of which specifies a particular processing directive.
The syntax of the header field can be found in Section 10, and the
semantics of the directives are described in Section 9.1.
A UAC can indicate caller preferences for the capabilities of a UA
that should be reached or not reached as a result of sending a SIP
request. To do that, it adds one or more Accept-Contact and Reject-
Contact header field values. Each header field value contains a set
of feature parameters that define a feature set. The syntax of the
header field can be found in Section 10, and a discussion of their
usage in Section 9.2.
Each feature set is constructed as described in Section 5 of [3].
The feature sets placed into these header fields MAY overlap; that
is, a UA MAY indicate preferences for feature sets that match
according to the matching algorithm of RFC 2533 [2].
A UAC can express explicit preferences for the methods and event
packages supported by a UA. It is RECOMMENDED that a UA include a
term in an Accept-Contact feature set with the "sip.methods" feature
tag (note, however, that even though the name of this feature tag is
sip.methods, it would be encoded into the Accept-Contact header field
as just "methods"), whose value includes the method of the request.
When a UA sends a SUBSCRIBE request, it is RECOMMENDED that a UA
include a term in an Accept-Contact feature set with the "sip.events"
feature tag, whose value includes the event package of the request.
Whether these terms are placed into a new feature set, or whether
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they are included in each feature set, is at the discretion of the
implementor. In most cases, the right effect is achieved by
including a term in each feature set.
As an example, the following Accept-Contact header field expresses a
desire to route a call to a mobile device, using feature parameters
taken from [3]:
Accept-Contact: *;mobility="mobile";methods="INVITE"
The Reject-Contact header field allows the UAC to specify that a UA
should not be contacted if it matches any of the values of the header
field. Each value of the Reject-Contact header field contains a "*",
purely to align the syntax with guidelines for SIP extensions [12],
and is parameterized by a set of feature parameters. Any UA whose
capabilities match the feature set described by the feature
parameters matches the value.
The Accept-Contact header field allows the UAC to specify that a UA
should be contacted if it matches some or all of the values of the
header field. Each value of the Accept-Contact header field contains
a "*", and is parameterized by a set of feature parameters. Any UA
whose capabilities match the feature set described by the feature
parameters matches the value. The precise behavior depends heavily
on whether the "require" and "explicit" parameters are present. When
both of them are present, a proxy will only forward the request to
contacts which have explicitly indicated that they support the
desired feature set. Any others are discarded. As such, a UAC
should only use "require" and "explicit" together when it wishes the
call to fail unless a contact definitively matches. It's possible
that a UA supports a desired feature, but did not indicate it in its
registration. When a UAC uses both "explicit" and "require", such a
contact would not be reached. As a result, this combination is often
not the one a UAC will want.
When only "require" is present, it means that a contact will not be
used if it doesn't match. If it does match, or if it's not known
whether it's a complete match, the contact is still used. A UAC
would use "require" alone when a non-matching contact is useless.
This is common for services where the request simply can't be
serviced without the necessary features. An example is support for
specific methods or event packages. When only "require" is present,
the proxy will also preferentially route the request to the UA which
represents the "best" match. Here, "best" means that the UA has
explicitly indicated it supports more of the desired features than
any other. Note, however, that this preferential routing will never
override an ordering provided by the called party. The preferential
routing will only choose amongst contacts of equal q-value.
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When only "explicit" is present, it means that all contacts provided
by the callee will be used. However, if the contact isn't an
explicit match, it is tried last amongst all other contacts with the
same q-value. The principle difference, therefore, between this
configuration and the usage of both "require" and "explicit" is the
fallback behavior for contacts that don't match explicitly. Here,
they are tried as a last resort. If "require" is also present, they
are never tried.
Finally, if neither "require" nor "explicit" are present, it means
that all contacts provided by the callee will be used. However, if
the contact doesn't match, it is tried last amongst all other
contacts with the same q-value. If it does match, the request is
routed preferentially to the "best" match. This is a common
configuration for preferences that, if not honored, will still allow
for a successful call, and the greater the match, the better.
When a UAS compliant to this specification receives a request whose
request-URI corresponds to one of its registered contacts, it SHOULD
apply the behavior described in Section 7.2 as if it were a proxy for
the domain in the request-URI. The UAS acts as if its location
database contains a single request target for the request-URI. That
target is associated with a feature set. The feature set is the same
as the one placed in the registration of the URI in the request-URI.
If a UA had registered against multiple separate addresses-of-record,
and the contacts registered for each had different capabilities, it
will have used a different URI in each registration, so it can
determine which feature set to use.
This processing occurs after the client authenticates and authorizes
the request, but before the remainder of the general UAS processing
described in Section 8.2.1 of RFC 3261.
If, after performing this processing, there are no URI left in the
target set, the UA SHOULD reject the request with a 480 response. If
there is a URI remaining (there was only one to begin with), the UA
proceeds with request processing as per RFC 3261.
Having a UAS perform the matching operations as if it were a proxy
allows certain caller preferences to be honored, even if the proxy
doesn't support the extension.
A UAS SHOULD process any queue directive present in a Request-
Disposition header field in the request. All other directives MUST
be ignored.
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Proxy behavior consists of two orthogonal sets of rules - one for
processing the Request-Disposition header field, and one for
processing the URI and feature set preferences in the Accept-Contact
and Reject-Contact header fields.
In addition to processing these headers, a proxy MAY add one if not
present, or add a value to an existing header field, as if it were a
UAC. This is useful for a proxy to request processing in downstream
proxies in the implementation of a feature. However, a proxy MUST
NOT modify or remove an existing header field value. This is
particularly important when S/MIME is used. The message signature
could include the caller preferences header fields, allowing the UAS
to verify that, even though proxies may have added header fields, the
original caller preferences were still present.
If the request contains a Request-Disposition header field and it is
the owner of the domain in the Request URI, the server SHOULD execute
the directives as described in Section 9.1, unless it has local
policy configured to direct it otherwise.
A proxy compliant to this specification MUST NOT apply the
preferences matching operation described here to a request unless it
is the owner of the domain in the request URI, and accessing a
location service that has capabilities associated with request
targets. However, if it is the owner of the domain, and accessing a
location service that has capabilities associated with request
targets, it SHOULD apply the processing described in this section.
Typically, this is a proxy that is using a registration database to
determine the request targets. However, if a proxy knows about
capabilities through some other means, it SHOULD apply the processing
defined here as well. If it does perform the processing, it MUST do
so as described below.
The processing is described through a conversion from the syntax
described in this specification to RFC 2533 [2] syntax, followed by a
matching operation and a sorting of resulting contact values. The
usage of RFC 2533 syntax as an intermediate step is not required; it
only serves as a useful tool to describe the behavior required of the
proxy. A proxy can use any steps it likes, so long as the results
are identical to the ones that would be achieved with the processing
described here.
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The first step in proxy processing is to extract explicit
preferences. To do that, it looks for the Accept-Contact and
Reject-Contact header fields.
For each value of those header fields, it extracts the feature
parameters. These are the header field parameters whose name is
"audio", "automata", "class", "duplex", "data", "control",
"mobility", "description", "events", "priority", "methods",
"extensions", "schemes", "application", "video", "language", "type",
"isfocus", "actor", or "text", or whose name begins with a plus (+)
[3]. The proxy converts all of those parameters to the syntax of RFC
2533, based on the rules in Section 8.
The result will be a set of feature set predicates in conjunctive
normal form, each of which is associated with one of the two
preference header fields. If there was a req-parameter associated
with a header field value in the Accept-Contact header field, the
feature set predicate derived from that header field value is said to
have its require flag set. Similarly, if there was an explicit-param
associated with a header field value in the Accept-Contact header
field, the feature set predicate derived from that header field value
is said to have its explicit flag set.
If, and only if, the proxy did not find any explicit preferences in
the request (because there was no Accept-Contact or Reject-Contact
header field), the proxy extracts implicit preferences. These
preferences are ones implied by the presence of other information in
the request.
First, the proxy creates a conjunction with no terms. This
conjunction represents a feature set that will be associated with the
Accept-Contact header field, as if it were included there. Note that
there is no modification of the message implied - only an association
for the purposes of processing. Furthermore, this feature set has
its require flag set, but not its explicit flag.
The proxy then adds terms to the conjunction for the two implicit
preference types below.
One implicit preference is the method. When a UAC sends a request
with a specific method, it is an implicit preference to have the
request routed only to UAs that support that method. To support this
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implicit preference, the proxy adds a term to the conjunction of the
following form:
(sip.methods=[method of request])
For requests that establish a subscription [5], the Event header
field is another expression of an implicit preference. It expresses
a desire for the request to be routed only to a server that supports
the given event package. To support this implicit preference, the
proxy adds a term to the conjunction of the following form:
(sip.events=[value of the Event header field])
The proxy then takes each URI in the target set (the set of URI it is
going to proxy or redirect to), and obtains its capabilities as an
RFC 2533 formatted feature set predicate. This is called a contact
predicate. If the target URI was obtained through a registration,
the proxy computes the contact predicate by extracting the feature
parameters from the Contact header field [3] and then converting them
to a feature predicate. To extract the feature parameters, the proxy
follows these steps:
1. Create an initial, empty list of feature parameters.
2. If the Contact URI parameters included the "audio", "automata",
"class", "duplex", "data", "control", "mobility", "description",
"events", "priority", "methods", "schemes", "application",
"video", "actor", "language", "isfocus", "type", "extensions", or
"text" parameters, those are copied into the list.
3. If any Contact URI parameter name begins with a "+", it is copied
into the list if the list does not already contain that name with
the plus removed. In other words, if the "video" feature
parameter is in the list, the "+video" parameter would not be
placed into the list. This conflict should never arise if the
client were compliant to [3], since it is illegal to use the +
form for encoding of a feature tag in the base set.
If the URI in the target set had no feature parameters, it is said to
be immune to caller preference processing. This means that the URI
is removed from the target set temporarily, the caller preferences
processing described below is executed, and then the URI is added
back in.
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Assuming the URI has feature parameters, they are converted to RFC
2533 syntax using the rules of Section 8.
The resulting predicate is associated with a q-value. If the contact
predicate was learned through a REGISTER request, the q-value is
equal to the q-value in the Contact header field parameter, else
"1.0" if not specified.
As an example, consider the following registered Contact header
field:
Contact: <sip:user@example.com>;audio;video;mobility="fixed";
+sip.message="TRUE";other-param=66372;
methods="INVITE,OPTIONS,BYE,CANCEL,ACK";schemes="sip,http"
This would be converted into the following predicate:
(& (sip.audio=TRUE)
(sip.video=TRUE)
(sip.mobility=fixed)
(sip.message=TRUE)
(| (sip.methods=INVITE) (sip.methods=OPTIONS) (sip.methods=BYE)
(sip.methods=CANCEL) (sip.methods=ACK))
(| (sip.schemes=sip) (sip.schemes=http)))
Note that "other-param" was not considered a feature parameter, since
it is neither a base tag nor did it begin with a leading +.
It is important to note that the proxy does not have to know anything
about the meaning of the feature tags that it is comparing in order
to perform the matching operation. The rules for performing the
comparison depend on syntactic hints present in the values of each
feature tag. For example, a predicate such as:
(foo>=4)
implies that the feature tag "foo" is a numeric value. The matching
rules in RFC 2533 only require an implementation to know whether the
feature tag is a numeric, token, or quoted string (booleans can be
treated as tokens). Quoted strings are always matched using a case-
sensitive matching operation. Tokens are matched using case-
insensitive matching. These two cases are differentiated by the
presence of angle brackets around the feature tag value. When these
brackets are present (i.e., ;+sip.foo="<value>"), it implies case
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sensitive string comparison. When they are not present, (i.e.,
(;+sip.bar="val"), it implies case insensitivity. Numerics are
matched using normal mathematical comparisons.
First, the proxy applies the predicates associated with the Reject-
Contact header field.
For each contact predicate, each Reject-Contact predicate (that is,
each predicate associated with the Reject-Contact header field) is
examined. If that Reject-Contact predicate contains a filter for a
feature tag, and that feature tag is not present anywhere in the
contact predicate, that Reject-Contact predicate is discarded for the
processing of that contact predicate. If the Reject-Contact
predicate is not discarded, it is matched with the contact predicate
using the matching operation of RFC 2533 [2]. If the result is a
match, the URI corresponding to that contact predicate is discarded
from the target set.
The result is that Reject-Contact will only discard URIs where the UA
has explicitly indicated support for the features that are not
wanted.
Next, the proxy applies the predicates associated with the Accept-
Contact header field. For each contact that remains in the target
set, the proxy constructs a matching set, Ms. Initially, this set
contains all of the Accept-Contact predicates. Each of those
predicates is examined. It is matched with the contact predicate
using the matching operation of RFC 2533 [2]. If the result is not a
match, and the Accept-Contact predicate had its require flag set, the
URI corresponding to that contact predicate is discarded from the
target set. If the result is not a match, but the Accept-Contact
predicate did not have its require flag set, that contact URI is not
discarded from the target set, however, the Accept-Contact predicate
is removed from the matching set for that contact.
For each contact that remains in the target set, the proxy computes a
score for that contact against each predicate in the contact's
matching set. Let the number of terms in the Accept-Contact
predicate conjunction be equal to N. Each term in that predicate
contains a single feature tag. If the contact predicate has a term
containing that same feature tag, the score is incremented by 1/N.
If the feature tag was not present in the contact predicate, the
score remains unchanged. Based on these rules, the score can range
between zero and one.
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T
+----------> DROP Contact
|
|
/ \
/ \
T / \ F
+---->/require\------> Set score=0
| \ /
| \ /
/ \ \ /
/ \ \/
score<1 / \
+-------> /explicit----> Score unchanged
| \ / F
| \ /
/ \ \ /
/ \ \/
+--------+ / \
-->|Compute |--> /Score \ --------> Score unchanged
| Score | \ / score=1
+--------+ \ /
\ /
\/
Figure 1: Applying the Score
The require and explicit tags are then applied, resulting in
potential modification of the score and the target set. This process
is summarized in Figure 1. If the score for the contact predicate
against that Accept-Contact predicate was less than one, the Accept-
Contact predicate had an explicit tag, and if the predicate also had
a require tag, the Contact URI corresponding to that contact
predicate is dropped. If, however, the predicate did not have a
require tag, the score is set to zero. If there was no explicit tag,
the score is unchanged.
The next step is to combine the scores and the q-values associated
with the predicates in the matching set, to arrive at an overall
caller preference, Qa. For those URIs in the target set which
remain, there will be a score which indicates its match against each
Accept-Contact predicate in the matching set. If there are M
Accept-Contact predicates in the matching set, there will be M scores
S1 through SM, for each contact. The overall caller preference, Qa,
is the arithmetic average of S1 through SM.
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At this point, any URIs that were removed from the target set because
they were immune from caller preferences are added back in, and Qa
for that URI is set to 1.0.
The purpose of the caller preference Qa is to provide an ordering for
any contacts remaining in the target set, if the callee has not
provided an ordering. To do this, the contacts remaining in the
target set are sorted by the q-value provided by the callee. Once
sorted, they are grouped into equivalence classes, such that all
contacts with the same q-value are in the same equivalence class.
Within each equivalence class, the contacts are then ordered based on
their values of Qa. The result is an ordered list of contacts that
is used by the proxy.
If there were no URIs in the target set after the application of the
processing in this section, and the caller preferences were based on
implicit preferences (Section 7.2.2), the processing in this section
is discarded, and the original target set, ordered by their original
q-values, is used.
This handles the case where implicit preferences for the method or
event packages resulted in the elimination of all potential
targets. By going back to the original target set, those URIs
will be tried, and result in the generation of a 405 or 489
response. The UAC can then use this information to try again, or
report the error to the user. Without reverting to the original
target set, the UAC would see a 480 response, and have no
knowledge of why their request failed. Of course, the target set
can also be empty after the application of explicit preferences.
This will result in the generation of a 480 by the proxy. This
behavior is acceptable, and indeed, desirable in the case of
explicit preferences. When the caller makes an explicit
preference, it is agreeing that its request might fail because of
a preference mismatch. One might try to return an error
indicating the capabilities of the callee, so that the caller
could perhaps try again. However, doing so results in the leaking
of potentially sensitive information to the caller without
authorization from the callee, and therefore this specification
does not provide a means for it.
If a proxy server is recursing, it adds the Contact header fields
returned in the redirect responses to the target set, and re-applies
the caller preferences algorithm.
If the server is redirecting, it returns all entries in the target
set. It assigns q-values to those entries so that the ordering is
identical to the ordering determined by the processing above.
However, it MUST NOT include the feature parameters for the entries
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in the target set. If it did, the upstream proxy server would apply
the same caller preferences once more, resulting in a double
application of those preferences. If the redirect server does wish
to include the feature parameters in the Contact header field, it
MUST redirect using the original target set and original q-values,
before the application of caller preferences.
Consider the following example, which is contrived but illustrative
of the various components of the matching process. There are five
registered Contacts for sip:user@example.com. They are:
Contact: sip:u1@h.example.com;audio;video;methods="INVITE,BYE";q=0.2
Contact: sip:u2@h.example.com;audio="FALSE";
methods="INVITE";actor="msg-taker";q=0.2
Contact: sip:u3@h.example.com;audio;actor="msg-taker";
methods="INVITE";video;q=0.3
Contact: sip:u4@h.example.com;audio;methods="INVITE,OPTIONS";q=0.2
Contact: sip:u5@h.example.com;q=0.5
An INVITE sent to sip:user@example.com contained the following caller
preferences header fields:
Reject-Contact: *;actor="msg-taker";video
Accept-Contact: *;audio;require
Accept-Contact: *;video;explicit
Accept-Contact: *;methods="BYE";class="business";q=1.0
There are no implicit preferences in this example, because explicit
preferences are provided.
The proxy first removes u5 from the target set, since it is immune
from caller preferences processing.
Next, the proxy processes the Reject-Contact header field. It is a
match for all four remaining contacts, but only an explicit match for
u3. That is because u3 is the only one that explicitly indicated
support for video, and explicitly indicated it is a message taker.
So, u3 gets discarded, and the others remain.
Next, each of the remaining three contacts is compared against each
of the three Accept-Contact predicates. u1 is a match to all three,
earning a score of 1.0 for the first two predicates, and 0.5 for the
third (the methods feature tag was present in the contact predicate,
but the class tag was not). u2 doesn't match the first predicate.
Because that predicate has a require tag, u2 is discarded. u4
matches the first predicate, earning a score of 1.0. u4 matches the
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second predicate, but since the match is not explicit (the score is
0.0, in fact), the score is set to zero (it was already zero, so
nothing changes). u4 does not match the third predicate.
At this point, u1 and u4 remain. u1 matched all three Accept-Contact
predicates, so its matching set contains all three, with scores of 1,
1, and 0.5. u4 matches the first two predicates, with scores of 1.0
and 0.0. Qa for u1 is 0.83 and Qa for u4 is 0.5. u5 is added back
in with a Qa of 1.0.
Next, the remaining contacts in the target set are sorted by q-value.
u5 has a value of 0.5, u1 has a q-value of 0.2 and so does u4. There
are two equivalence classes. The first has a q-value of 0.5, and
consists of just u5. Since there is only one member of the class,
sorting within the class has no impact. The second equivalence class
has a q-value of 0.2. Within that class, the two contacts, u1 and
u4, are ordered based on their values of Qa. u1 has a Qa of 0.83,
and u4, a Qa of 0.5. Thus, u1 comes first, followed by u4. The
resulting overall ordered set of contacts in the target set is u5,
u1, and then u4.
Mapping between feature parameters and a feature set predicate,
formatted according to the syntax of RFC 2533 [2], is trivial. It is
just the opposite of the process described in Section 5 of [3].
Starting from a set of feature-param, the procedure is as follows.
Construct a conjunction. Each term in the conjunction derives from
one feature-param. If the feature-param has no value, it is
equivalent, in terms of the processing which follows, as if it had a
value of "TRUE".
If the feature-param value is a tag-value-list, the element of the
conjunction is a disjunction. There is one term in the disjunction
for each tag-value in the tag-value-list.
Consider now the construction of a filter from a tag-value. If the
tag-value starts with an exclamation mark (!), the filter is of the
form:
(! <filter from remainder>)
where "<filter from remainder>" refers to the filter that would be
constructed from the tag-value if the exclamation mark had not been
present.
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If the tag-value starts with an octothorpe (#), the filter is a
numeric comparison. The comparator is either =, >=, <=, or a range
based on the next characters in the phrase. If the next characters
are =, >=, or <=, the filter is of the form:
(name comparator compare-value)
where name is the name of the feature parameter after it has been
decoded (see below), and the comparator is either =, >=, or <=
depending of the initial characters in the phrase. If the remainder
of the text in the tag-value after the equal contains a decimal point
(implying a rational number), the decimal point is shifted right N
times until it is an integer, I. Compare-value above is then set to
"I / 10**N", where 10**N is the result of computing the number 10 to
the Nth power.
If the value after the octothorpe is a number, the filter is a range.
The format of the filter is:
(name=<remainder>)
where "name" is the feature-tag after it has been decoded (see
below), and "<remainder>" is the remainder of the text in the tag-
value after the #, with any decimal numbers converted to a rational
form, and the colon replaced by a double dot (..).
If the tag-value does not begin with an octothorpe (it is a token-
nobang or boolean), the filter is of the form:
(name=tag-value)
where name is the feature-tag after it has been decoded (see below).
If the feature-param contains a string-value (based on the fact that
it begins with a left angle bracket ("<") and ends with a right angle
bracket (">")), the filter is of the form:
(name="qdtext")
Note the explicit usage of quotes around the qdtext, which indicate
that the value is a string. In RFC 2533, strings are compared using
case sensitive rules, and tokens are compared using case insensitive
rules.
Feature tags, as specified in RFC 2506 [13], cannot be directly
represented as header field parameters in the Contact, Accept-
Contact, and Reject-Contact header fields. This is due to an
inconsistency in the grammars, and in the need to differentiate
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feature parameters from parameters used by other extensions. As
such, feature tag values are encoded from RFC 2506 format to yield an
enc-feature-tag, and then are decoded into RFC 2506 format. The
decoding process is simple. If there is a leading plus (+) sign, it
is removed. Any exclamation point (!) is converted to a colon (:)
and any single quote (') is converted to a forward slash (/). If
there was no leading plus sign, and the remainder of the encoded name
was "audio", "automata", "class", "duplex", "data", "control",
"mobility", "description", "events", "priority", "methods",
"schemes", "application", "video", "actor", "isfocus", "extensions"
or "text", the prefix "sip." is added to the remainder of the encoded
name to compute the feature tag name.
As an example, the Accept-Contact header field:
Accept-Contact:*;mobility="fixed"
;events="!presence,message-summary"
;language="en,de";description="<PC>";+sip.newparam
;+rangeparam="#-4:+5.125"
would be converted to the following feature predicate:
(& (sip.mobility=fixed)
(| (! (sip.events=presence)) (sip.events=message-summary))
(| (language=en) (language=de))
(sip.description="PC")
(sip.newparam=TRUE)
(rangeparam=-4..5125/1000))
This specification defines three new header fields - Accept-Contact,
Reject-Contact, and Request-Disposition.
Figure 2 and Figure 3 are an extension of Tables 2 and 3 in RFC 3261
[1] for the Accept-Contact, Reject-Contact, and Request-Disposition
header fields. The column "INF" is for the INFO method [6], "PRA" is
for the PRACK method [7], "UPD" is for the UPDATE method [8], "SUB"
is for the SUBSCRIBE method [5], "NOT" is for the NOTIFY method [5],
"MSG" is for the MESSAGE method [9], and "REF" is for the REFER
method [10].
Rosenberg, et al. Standards Track [Page 19]
RFC 3841 Caller Preferences for SIP August 2004
Header field where proxy ACK BYE CAN INV OPT REG
Accept-Contact R ar o o o o o -
Reject-Contact R ar o o o o o -
Request-Disposition R ar o o o o o o
Figure 2: Accept-Contact, Reject-Contact, and Request-Disposition
header fields
Header field where proxy PRA UPD SUB NOT INF MSG REF
Accept-Contact R ar o o o o o o o
Reject-Contact R ar o o o o o o o
Request-Disposition R ar o o o o o o o
Figure 3: Accept-Contact, Reject-Contact, and Request-Disposition
header fields
The Request-Disposition header field specifies caller preferences for
how a server should process a request. Its value is a list of
tokens, each of which specifies a particular directive. Its syntax
is specified in Section 10. Note that a compact form, using the
letter d, has been defined. The directives are grouped into types.
There can only be one directive of each type per request (e.g., you
cannot have both "proxy" and "redirect" in the same Request-
Disposition header field).
When the caller specifies a directive, the server SHOULD honor that
directive.
The following types of directives are defined:
proxy-directive: This type of directive indicates whether the caller
would like each server to proxy ("proxy") or redirect
("redirect").
cancel-directive: This type of directive indicates whether the caller
would like each proxy server to send a CANCEL request downstream
("cancel") in response to a 200 OK from the downstream server
(which is the normal mode of operation, making it redundant), or
whether this function should be left to the caller ("no-cancel").
If a proxy receives a request with this parameter set to "no-
cancel", it SHOULD NOT CANCEL any outstanding branches upon
receipt of a 2xx. However, it would still send CANCEL on any
outstanding branches upon receipt of a 6xx.
Rosenberg, et al. Standards Track [Page 20]
RFC 3841 Caller Preferences for SIP August 2004
fork-directive: This type of directive indicates whether a proxy
should fork a request ("fork"), or proxy to only a single address
("no-fork"). If the server is requested not to fork, the server
SHOULD proxy the request to the "best" address (generally the one
with the highest q-value). If there are multiple addresses with
the highest q-value, the server chooses one based on its local
policy. The directive is ignored if "redirect" has been
requested.
recurse-directive: This type of directive indicates whether a proxy
server receiving a 3xx response should send requests to the
addresses listed in the response ("recurse"), or forward the list
of addresses upstream towards the caller ("no-recurse"). The
directive is ignored if "redirect" has been requested.
parallel-directive: For a forking proxy server, this type of
directive indicates whether the caller would like the proxy server
to proxy the request to all known addresses at once ("parallel"),
or go through them sequentially, contacting the next address only
after it has received a non-2xx or non-6xx final response for the
previous one ("sequential"). The directive is ignored if
"redirect" has been requested.
queue-directive: If the called party is temporarily unreachable,
e.g., because it is in another call, the caller can indicate that
it wants to have its call queued ("queue") or rejected immediately
("no-queue"). If the call is queued, the server returns "182
Queued". A queued call can be terminated as described in [1].
Example:
Request-Disposition: proxy, recurse, parallel
The set of request disposition directives is not extensible on
purpose. This is to avoid a proliferation of new extensions to SIP
that are "tunneled" through this header field.
The syntax for these header fields is described in Section 10. A
compact form, with the letter a, has been defined for the Accept-
Contact header field, and with the letter j for the Reject-Contact
header field.
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RFC 3841 Caller Preferences for SIP August 2004
The BNF for the Request-Disposition header field is:
Request-Disposition = ( "Request-Disposition" / "d" ) HCOLON
directive *(COMMA directive)
directive = proxy-directive / cancel-directive /
fork-directive / recurse-directive /
parallel-directive / queue-directive
proxy-directive = "proxy" / "redirect"
cancel-directive = "cancel" / "no-cancel"
fork-directive = "fork" / "no-fork"
recurse-directive = "recurse" / "no-recurse"
parallel-directive = "parallel" / "sequential"
queue-directive = "queue" / "no-queue"
The BNF for the Accept-Contact and Reject-Contact header fields is:
Accept-Contact = ("Accept-Contact" / "a") HCOLON ac-value
*(COMMA ac-value)
Reject-Contact = ("Reject-Contact" / "j") HCOLON rc-value
*(COMMA rc-value)
ac-value = "*" *(SEMI ac-params)
rc-value = "*" *(SEMI rc-params)
ac-params = feature-param / req-param
/ explicit-param / generic-param
;;feature param from RFC 3840
;;generic-param from RFC 3261
rc-params = feature-param / generic-param
req-param = "require"
explicit-param = "explicit"
Despite the BNF, there MUST NOT be more than one req-param or
explicit-param in an ac-params. Furthermore, there can only be one
instance of any feature tag in feature-param.
The presence of caller preferences in a request has an effect on the
ways in which the request is handled at a server. As a result,
requests with caller preferences SHOULD be integrity-protected with
the sips mechanism specified in RFC 3261, Section 26.
Processing of caller preferences requires set operations and searches
which can require some amount of computation. This enables a DOS
attack whereby a user can send requests with substantial numbers of
Rosenberg, et al. Standards Track [Page 22]
RFC 3841 Caller Preferences for SIP August 2004
caller preferences, in the hopes of overloading the server. To
counter this, servers SHOULD reject requests with too many rules. A
reasonable number is around 20.
This specification registers three new SIP header fields, according
to the process of RFC 3261 [1].
The following is the registration for the Accept-Contact header
field:
RFC Number: RFC 3841
Header Field Name: Accept-Contact
Compact Form: a
The following is the registration for the Reject-Contact header
field:
RFC Number: RFC 3841
Header Field Name: Reject-Contact
Compact Form: j
The following is the registration for the Request-Disposition header
field:
RFC Number: RFC 3841
Header Field Name: Request-Disposition
Compact Form: d
The initial set of media feature tags used by this specification were
influenced by Scott Petrack's CMA design. Jonathan Lennox, Bob
Penfield, Ben Campbell, Mary Barnes, Rohan Mahy, and John Hearty
provided helpful comments. Graham Klyne provided assistance on the
usage of RFC 2533.
Rosenberg, et al. Standards Track [Page 23]
RFC 3841 Caller Preferences for SIP August 2004
[1] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A.,
Peterson, J., Sparks, R., Handley, M., and E. Schooler, "SIP:
Session Initiation Protocol", RFC 3261, June 2002.
[2] Klyne, G., "A Syntax for Describing Media Feature Sets", RFC
2533, March 1999.
[3] Rosenberg, J., Schulzrinne, J., and P. Kyzivat, "Indicating
User Agent Capabilities in the Session Initiation Protocol
(SIP)", RFC 3840, August 2004.
[4] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
[5] Roach, A.B., "Session Initiation Protocol (SIP)-Specific Event
Notification", RFC 3265, June 2002.
[6] Donovan, S., "The SIP INFO Method", RFC 2976, October 2000.
[7] Rosenberg, J. and H. Schulzrinne, "Reliability of Provisional
Responses in Session Initiation Protocol (SIP)", RFC 3262, June
2002.
[8] Rosenberg, J., "The Session Initiation Protocol (SIP) UPDATE
Method", RFC 3311, October 2002.
[9] Campbell, B., Ed., Rosenberg, J., Schulzrinne, H., Huitema, C.,
and D. Gurle, "Session Initiation Protocol (SIP) Extension for
Instant Messaging", RFC 3428, December 2002.
[10] Sparks, R., "The Session Initiation Protocol (SIP) Refer
Method", RFC 3515, April 2003.
[11] Lennox, J. and H. Schulzrinne, "Call Processing Language
Framework and Requirements", RFC 2824, May 2000.
[12] Rosenberg, J., "Guidelines for Authors of Extensions to the
Session Initiation Protocol (SIP)", Work in Progress, November
2002.
[13] Holtman, K., Muntz, A., and T. Hardie, "Media Feature Tag
Registration Procedure", BCP 31, RFC 2506, March 1999.
Rosenberg, et al. Standards Track [Page 24]
RFC 3841 Caller Preferences for SIP August 2004
Jonathan Rosenberg
dynamicsoft
600 Lanidex Plaza
Parsippany, NJ 07054
US
Phone: +1 973 952-5000
EMail: jdrosen@dynamicsoft.com
URI: http://www.jdrosen.net
Henning Schulzrinne
Columbia University
M/S 0401
1214 Amsterdam Ave.
New York, NY 10027
US
EMail: schulzrinne@cs.columbia.edu
URI: http://www.cs.columbia.edu/~hgs
Paul Kyzivat
Cisco Systems
1414 Massachusetts Avenue
BXB500 C2-2
Boxboro, MA 01719
US
EMail: pkyzivat@cisco.com
Rosenberg, et al. Standards Track [Page 25]
RFC 3841 Caller Preferences for SIP August 2004
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Rosenberg, et al. Standards Track [Page 26]