ECRIT B. Rosen
Internet-Draft
Intended status: Standards Track H. Schulzrinne
Expires: July 31, 2020 Columbia U.
H. Tschofenig
ARM Limited
R. Gellens
Core Technology Consulting
January 28, 2020

Non-Interactive Emergency Calls
draft-ietf-ecrit-data-only-ea-19

Abstract

RFC 6443 'Framework for Emergency Calling Using Internet Multimedia' describes how devices use the Internet to place emergency calls and how Public Safety Answering Points (PSAPs) handle Internet multimedia emergency calls natively. The exchange of multimedia traffic for emergency services involves a Session Initiation Protocol (SIP) session establishment starting with a SIP INVITE that negotiates various parameters for that session. These calls involve a person, who uses the interactive media to communicate with the PSAP.

In some cases, however, the transmission of application data is all that is needed, and no interactive media channel is established. Examples of such environments include alerts issued by a temperature sensor, burglar alarm, or chemical spill sensor. Often these alerts are conveyed as one-shot data transmissions. These type of interactions are called 'non-interactive emergency calls'. This document describes use of a SIP MESSAGE transaction containing a container for the data based on the Common Alerting Protocol (CAP). MESSAGE does not establish a session, which differentiates this type of emergency request from a SIP INVITE, which would. Any device that needs to initiate a request for emergency services where no interactive media channel will be established would use the mechanisms in this document.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on July 31, 2020.

Copyright Notice

Copyright (c) 2020 IETF Trust and the persons identified as the document authors. All rights reserved.

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Table of Contents

1. Introduction

[RFC6443] describes how devices use the Internet to place emergency calls and how Public Safety Answering Points (PSAPs) handle Internet multimedia emergency calls natively. The exchange of multimedia traffic for emergency services involves a SIP session establishment starting with a SIP INVITE that negotiates various parameters for that session.

In some cases, however, there is only application data to be conveyed from the end devices to a PSAP or an intermediary. Examples of such environments includes sensors issuing alerts, or certain types of medical monitors. These messages may be one-shot alerts to emergency authorities and do not require establishment of a session. These type of interactions are called 'non-interactive emergency calls'. In this document, we use the term "call" so that similarities between non-interactive alerts and sessions with interactive media are more obvious.

Non-Interactive emergency calls are similar to regular emergency calls in the sense that they require the emergency indications, emergency call routing functionality and may even have the same location requirements. However, the communication interaction will not lead to the exchange of interactive media, that is, Real-Time Protocol packets, such as voice, video data or real-time text.

The Common Alerting Protocol (CAP) [cap] is a format for exchanging emergency alerts and public warnings. CAP is mainly used for conveying alerts and warnings between authorities and from authorities to citizens/individuals. This document is concerned with citizen to authority "alerts", where the alert is a call without any interactive media.

This document describes a method of including a CAP message in a SIP transaction by defining it as a block of "additional data" as defined in [RFC7852]. The CAP message is included either by value (the CAP message is in the body of the message, using a CID) or by reference (a URI is included in the message, which when dereferenced returns the CAP message). The additional data mechanism is also used to send alert specific data beyond that available in the CAP message. This document also describes how a SIP MESSAGE [RFC3428] transaction can be used to send a non-interactive call.

2. Terminology

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].

SIP is the Session Initiation Protocol [RFC3261]

PIDF-LO is Presence Information Data Format - Location Object, a data structure for carrying location [RFC4119]

LoST is the Location To Service Translation protocol [RFC5222]

CID is Content InDirection [RFC2392]

CAP is the Common Alerting Protocol [cap]

PSAP is a Public Safety Answering Point, the call center for emergency calls.

ESRP is an Emergency Services Routing Proxy, a type of SIP Proxy Server used in some emergency services networks

3. Architectural Overview

This section illustrates two envisioned usage modes: targeted and location-based emergency alert routing.

  1. Emergency alerts containing only data are targeted to an intermediary recipient responsible for evaluating the next steps. These steps could include:
    1. Sending a non-interactive call containing only data towards a Public Safety Answering Point (PSAP);
    2. Establishing a third-party initiated emergency call towards a PSAP that could include audio, video, and data.

  2. Emergency alerts may be targeted to a Service URN used for IP-based emergency calls where the recipient is not known to the originator. In this scenario, the alert may contain only data (e.g., a CAP, Geolocation header field and one or more Call-Info header fields containing Additional Data [RFC7852] in a SIP MESSAGE).

Figure 1 shows a deployment variant where a sensor is pre-configured (using techniques outside the scope of this document) to issue an alert to an aggregator that processes these messages and performs whatever steps are necessary to appropriately react to the alert. For example, a security firm may use different sensor inputs to dispatch their security staff to a building they protect or to initiate a third-party emergency call.

          
 +------------+              +------------+
 | Sensor     |              | Aggregator |
 |            |              |            | 
 +---+--------+              +------+-----+
     |                              |
  Sensors                           |
  trigger                           |
  emergency                         |
  alert                             |
     |    SIP MESSAGE with CAP      |
     |----------------------------->|
     |                              |
     |                           Aggregator
     |                           processes
     |                           emergency
     |                           alert
     |      SIP 200 (OK)            |
     |<-----------------------------|
     |                              |
     |                              |
          

Figure 1: Targeted Emergency Alert Routing

In Figure 2 a scenario is shown whereby the alert is routed using location information and a Service URN. An emergency services routing proxy (ESRP) may use LoST (a protocol defined by [RFC5222] which translates a location to a URI used to route an emergency call) to determine the next hop proxy to route the alert message to. A possible receiver is a PSAP and the recipient of the alert may be a call taker. In the generic case, there is very likely no prior relationship between the originator and the receiver, e.g., a PSAP. A PSAP, for example, is likely to receive and accept alerts from entities it has no previous relationship with. This scenario corresponds to the classic emergency services use case and the description in [RFC6881] is applicable. In this use case, the only difference between an emergency call and an emergency non-interactive call is that the former uses INVITE, creates a session, and negotiates one or more media streams, while the latter uses MESSAGE, does not create a session, and does not have interactive media.

          
   +----------+         +----------+                  +-----------+
   |Sensor or |         |  ESRP    |                  |   PSAP    |
   |Aggregator|         |          |                  |           |
   +----+-----+         +---+------+                  +----+------+
        |                   |                              |
     Sensors                |                              |
     trigger                |                              |
     emergency              |                              |
     alert                  |                              |
        |                   |                              |
        |                   |                              |
        | SIP MESSAGE w/CAP |                              |
        | (including Service URN,                          |
        | such as urn:service:sos)                         |
        |-------------------|                              |
        |                   |                              |
        |              ESRP performs                       |
        |              emergency alert                     |
        |              routing                             |
        |                   |  MESSAGE with CAP            |
        |                   |  (including identity info)   | 
        |                   |----------------------------->|
        |                   |                              |
        |                   |                           PSAP
        |                   |                           processes
        |                   |                           emergency
        |                   |                           alert
        |                   |      SIP 200 (OK)            |
        |                   |<-----------------------------|
        |                   |                              |
        |  SIP 200 (OK)     |                              |
        |<------------------|                              |
        |                   |                              |
        |                   |                              |

Figure 2: Location-Based Emergency Alert Routing

4. Protocol Specification

4.1. CAP Transport

A CAP message may be sent in the initial message of any SIP transaction. However, this document only addresses sending a CAP message in a SIP MESSAGE transaction for a one-shot, non-interactive emergency call. Behavior with other transactions is not defined.

The CAP message is included in a SIP message as an additional-data block [RFC7852]. Accordingly, it is introduced to the SIP message with a Call-Info header field with a purpose of "EmergencyCallData.cap". The header field may contain a URI that is used by the recipient (or in some cases, an intermediary) to obtain the CAP message. Alternative, the Call-Info header field may contain a Content Indirect url [RFC2392] and the CAP message included in the body of the message. In the latter case, the CAP message is located in a MIME block of the type 'application/emergencyCallData.cap+xml'.

If the SIP server does not support the functionality required to fulfill the request then a 501 Not Implemented MUST be returned as specified in [RFC3261]. This is the appropriate response when a User Agent Server (UAS) does not recognize the request method and is not capable of supporting it for any user.

The 415 Unsupported Media Type error MUST be returned as specified in [RFC3261] if the SIP server is refusing to service the request because the message body of the request is in a format not supported by the server for the requested method. The server MUST return a list of acceptable formats using the Accept, Accept-Encoding, or Accept-Language header fields, depending on the specific problem with the content.

4.2. Profiling of the CAP Document Content

The usage of CAP MUST conform to the specification provided with [cap]. For usage with SIP the following additional requirements are imposed:

sender:
The following restrictions and conditions apply to setting the value of the <sender> element:
incidents:
The <incidents> element MUST be present. This incident identifier MUST be chosen in such a way that it is unique for a given <sender, expires, incidents> combination. Note that the <expires> element is optional and may not be present.

scope:
The value of the <scope> element MAY be set to "Private" if the alert is not meant for public consumption. The <addresses> element is, however, not used by this specification since the message routing is performed by SIP and the respective address information is already available in other SIP header fields. Populating information twice into different parts of the message may lead to inconsistency.

parameter:
The <parameter> element MAY contain additional information specific to the sender, conforming to the CAP message syntax.

area:
It is RECOMMENDED to omit this element when constructing a message. If the CAP message already contains an <area> element, then the specified location information SHOULD be copied into a PIDF-LO structure (the data format for location used by emergency calls on the Internet) referenced by the SIP 'Geolocation' header field. If there is a need to copy the PIDF-LO structure referenced by 'geolocation' to <area>, implementers must be aware that <area> is limited to a circle or polygon, and conversion of other shapes will be required. Points SHOULD be converted to a circle with a radius equal to the uncertainty of the point. Arc-bands and ellipses SHOULD be converted to an equivalent polygon. 3D locations SHOULD be converted to their equivalent 2D forms.

4.3. Sending a non-interactive Emergency Call

A non-interactive emergency call is sent using a SIP MESSAGE transaction with a CAP URI or body part as described above in a manner similar to how an emergency call with interactive media is sent, as described in [RFC6881]. The MESSAGE transaction does not create a session nor establish interactive media streams, but otherwise, the header content of the transaction, routing, and processing of non-interactive calls are the same as those of other emergency calls.

5. Error Handling

This section defines a new error response code and a header field for additional information.

5.1. 425 (Bad Alert Message) Response Code

This SIP extension creates a new location-specific response code, defined as follows:

The 425 response code is a rejection of the request due to its included alert content, indicating that it was malformed or not satisfactory for the recipient's purpose.

A SIP intermediary can also reject an alert it receives from a User Agent (UA) when it detects that the provided alert is malformed.

Section 5.2 describes an AlertMsg-Error header field with more details about what was wrong with the alert message in the request. This header field MUST be included in the 425 response.

It is only appropriate to generate a 425 response when the responding entity has no other information in the request that is usable by the responder.

A 425 response code MUST NOT be sent in response to a request that lacks an alert message, as the user agent in that case may not support this extension.

A 425 response is a final response within a transaction, and MUST NOT terminate an existing dialog.

5.2. The AlertMsg-Error Header Field

The AlertMsg-Error header field provides additional information about what was wrong with the original request. In some cases the provided information will be used for debugging purposes.

The AlertMsg-Error header field has the following ABNF [RFC5234]:

              
   message-header   /= AlertMsg-Error
                           ; (message-header from 3261)
   AlertMsg-Error   = "AlertMsg-Error" HCOLON
                           ErrorValue
   ErrorValue       =  error-code
                            *(SEMI error-params)
   error-code       = 1*3DIGIT
   error-params     = error-code-text
                            / generic-param ; from RFC3261
   error-code-text  = "code" EQUAL quoted-string ; from RFC3261

HCOLON, SEMI, and EQUAL are defined in [RFC3261]. DIGIT is defined in [RFC5234].

The AlertMsg-Error header field MUST contain only one ErrorValue to indicate what was wrong with the alert payload the recipient determined was bad.

The ErrorValue contains a 3-digit error code indicating what was wrong with the alert in the request. This error code has a corresponding quoted error text string that is human readable. The text string is OPTIONAL, but RECOMMENDED for human readability, similar to the string phrase used for SIP response codes. That said, the strings are complete enough for rendering to the user, if so desired. The strings in this document are recommendations, and are not standardized -- meaning an operator can change the strings -- but MUST NOT change the meaning of the error code. Similar to how RFC 3261 specifies, there MUST NOT be more than one string per error code.

The AlertMsg-Error header field MAY be included in any response if an alert message was in the request part of the same transaction. For example, a UA includes an alert in a MESSAGE to a PSAP. The PSAP can accept this MESSAGE, thus creating a dialog, even though its UA determined that the alert message contained in the MESSAGE was bad. The PSAP merely includes an AlertMsg-Error header field value in the 200 OK to the MESSAGE, thus informing the UA that the MESSAGE was accepted but the alert provided was bad.

If, on the other hand, the PSAP cannot accept the transaction without a suitable alert message, a 425 response is sent.

A SIP intermediary that requires the UA's alert message in order to properly process the transaction may also sends a 425 with an AlertMsg-Error code.

This document defines an initial list of AlertMsg-Error values for any SIP response, including provisional responses (other than 100 Trying) and the new 425 response. There MUST be no more than one AlertMsg-Error code in a SIP response.

AlertMsg-Error: 100 ; code="Cannot Process the Alert Payload"

AlertMsg-Error: 101 ; code="Alert Payload was not present or could not be found"

AlertMsg-Error: 102 ; code="Not enough information to determine the purpose of the alert"

AlertMsg-Error: 103 ; code="Alert Payload was corrupted"

Additionally, if an entity cannot or chooses not to process the alert message from a SIP request, a 500 (Server Internal Error) SHOULD be used with or without a configurable Retry-After header field.

6. Call Backs

This document does not describe any method for the recipient to call back the sender of a non-interactive call. Usually, these alerts are sent by automata, which do not have a mechanism to receive calls of any kind. The identifier in the 'From' header field may be useful to obtain more information, but any such mechanism is not defined in this document. The CAP message may contain related contact information for the sender.

7. Handling Large Amounts of Data

It is not atypical for sensors to have large quantities of data that they may wish to send. Including large amounts of data (tens of kilobytes) in a MESSAGE is not advisable, because SIP entities are usually not equipped to handle very large messages. In such cases, the sender SHOULD make use of the by-reference mechanisms defined in [RFC7852], which involves making the data available via HTTPS (either at the originator or at another entity), placing a URI to the data in the 'Call-Info' header field, and the recipient uses HTTPS to retrieve the data. The CAP message itself can be sent by-reference using this mechanism, as well as any or all of the Additional Data blocks that may contain sensor-specific data.

8. Example

The following example shows a CAP document indicating a BURGLARY alert issued by a sensor called 'sensor1@example.com'. The location of the sensor can be obtained from the attached location information provided via the 'geolocation' header field contained in the SIP MESSAGE structure. Additionally, the sensor provided some data along with the alert message, using proprietary information elements intended only to be processed by the receiver, a SIP entity acting as an aggregator.

                  
   MESSAGE sip:aggregator@example.com SIP/2.0
   Via: SIP/2.0/TCP sensor1.example.com;branch=z9hG4bK776sgdkse
   Max-Forwards: 70
   From: sip:sensor1@example.com;tag=49583
   To: sip:aggregator@example.com
   Call-ID: asd88asd77a@2001:DB8:0:0FF
   Geolocation: <cid:abcdef@example.com>
     ;routing-allowed=yes
   Supported: geolocation
   Accept: application/pidf+xml,application/EmergencyCallData.cap+xml
   CSeq: 1 MESSAGE
   Call-Info: cid:abcdef2@example.com;purpose=EmergencyCallData.cap
   Content-Type: multipart/mixed; boundary=boundary1
   Content-Length: ...

   --boundary1

   Content-Type: application/EmergencyCallData.cap+xml
   Content-ID: <abcdef2@example.com>
   Content-Disposition: by-reference;handling=optional
  <?xml version="1.0" encoding="UTF-8"?>

  <alert xmlns="urn:oasis:names:tc:emergency:cap:1.1">
    <identifier>S-1</identifier>
    <sender>sip:sensor1@example.com</sender>
    <sent>2008-11-19T14:57:00-07:00</sent>
    <status>Actual</status>
    <msgType>Alert</msgType>
    <scope>Private</scope>
    <incidents>abc1234</incidents>
    <info>
        <category>Security</category>
        <event>BURGLARY</event>
        <urgency>Expected</urgency>
        <certainty>Likely</certainty>
        <severity>Moderate</severity>
        <senderName>SENSOR 1</senderName>
        <parameter>
          <valueName>SENSOR-DATA-NAMESPACE1</valueName>
          <value>123</value>
        </parameter>
        <parameter>
          <valueName>SENSOR-DATA-NAMESPACE2</valueName>
          <value>TRUE</value>
        </parameter>  
    </info>
   </alert>

   --boundary1

   Content-Type: application/pidf+xml
   Content-ID: <abcdef2@example.com>
   Content-Disposition: by-reference;handling=optional
   <?xml version="1.0" encoding="UTF-8"?>
       <presence
          xmlns="urn:ietf:params:xml:ns:pidf"
          xmlns:gp="urn:ietf:params:xml:ns:pidf:geopriv10"
          xmlns:gbp=
                 "urn:ietf:params:xml:ns:pidf:geopriv10:basicPolicy"
          xmlns:cl="urn:ietf:params:xml:ns:pidf:geopriv10:civicAddr"
          xmlns:gml="http://www.opengis.net/gml"
          xmlns:dm="urn:ietf:params:xml:ns:pidf:data-model"
          entity="pres:alice@atlanta.example.com">
        <dm:device id="sensor">
          <gp:geopriv>
            <gp:location-info>
              <gml:location>
                <gml:Point srsName="urn:ogc:def:crs:EPSG::4326">
                  <gml:pos>32.86726 -97.16054</gml:pos>
                </gml:Point>
             </gml:location>
            </gp:location-info>
            <gp:usage-rules>
              <gbp:retransmission-allowed>false
              </gbp:retransmission-allowed>
              <gbp:retention-expiry>2010-11-14T20:00:00Z
              </gbp:retention-expiry>
            </gp:usage-rules>
            <gp:method>802.11</gp:method>
          </gp:geopriv>
          <dm:timestamp>2010-11-04T20:57:29Z</dm:timestamp>
        </dm:device>
      </presence>
   --boundary1--
          

Figure 3: Example Message conveying an Alert to an aggregator

The following shows the same CAP document sent as a non-interactive emergency call towards a PSAP.

                  
   MESSAGE urn:service:sos SIP/2.0
   Via: SIP/2.0/TCP sip:aggreg.1.example.com;branch=z9hG4bK776abssa
   Max-Forwards: 70
   From: sip:aggregator@example.com;tag=32336
   To: 112
   Call-ID: asdf33443a@example.com
   Route: sip:psap1.example.gov
   Geolocation: <cid:abcdef@example.com>
     ;routing-allowed=yes
   Supported: geolocation
   Accept: application/pidf+xml,application/EmergencyCallData.cap+xml
   Call-info: cid:abcdef2@example.com;purpose=EmergencyCallData.cap
   CSeq: 1 MESSAGE
   Content-Type: multipart/mixed; boundary=boundary1
   Content-Length: ...

   --boundary1

   Content-Type: application/EmergencyCallData.cap+xml
   Content-ID: <abcdef2@example.com>
  <?xml version="1.0" encoding="UTF-8"?>

  <alert xmlns="urn:oasis:names:tc:emergency:cap:1.1">
    <identifier>S-1</identifier>
    <sender>sip:sensor1@example.com</sender>
    <sent>2008-11-19T14:57:00-07:00</sent>
    <status>Actual</status>
    <msgType>Alert</msgType>
    <scope>Private</scope>
    <incidents>abc1234</incidents>
    <info>
        <category>Security</category>
        <event>BURGLARY</event>
        <urgency>Expected</urgency>
        <certainty>Likely</certainty>
        <severity>Moderate</severity>
        <senderName>SENSOR 1</senderName>
        <parameter>
          <valueName>SENSOR-DATA-NAMESPACE1</valueName>
          <value>123</value>
        </parameter>
        <parameter>
          <valueName>SENSOR-DATA-NAMESPACE2</valueName>
          <value>TRUE</value>
        </parameter>  
    </info>
   </alert>

   --boundary1

   Content-Type: application/pidf+xml
   Content-ID: <abcdef2@example.com>
   <?xml version="1.0" encoding="UTF-8"?>
       <presence
          xmlns="urn:ietf:params:xml:ns:pidf"
          xmlns:gp="urn:ietf:params:xml:ns:pidf:geopriv10"
          xmlns:gbp=
                 "urn:ietf:params:xml:ns:pidf:geopriv10:basicPolicy"
          xmlns:cl="urn:ietf:params:xml:ns:pidf:geopriv10:civicAddr"
          xmlns:gml="http://www.opengis.net/gml"
          xmlns:dm="urn:ietf:params:xml:ns:pidf:data-model"
          entity="pres:alice@atlanta.example.com">
        <dm:device id="sensor">
          <gp:geopriv>
            <gp:location-info>
              <gml:location>
                <gml:Point srsName="urn:ogc:def:crs:EPSG::4326">
                  <gml:pos>32.86726 -97.16054</gml:pos>
                </gml:Point>
             </gml:location>
            </gp:location-info>
            <gp:usage-rules>
              <gbp:retransmission-allowed>false
              </gbp:retransmission-allowed>
              <gbp:retention-expiry>2010-11-14T20:00:00Z
              </gbp:retention-expiry>
            </gp:usage-rules>
            <gp:method>802.11</gp:method>
          </gp:geopriv>
          <dm:timestamp>2010-11-04T20:57:29Z</dm:timestamp>
        </dm:device>
      </presence>
   --boundary1--
          

Figure 4: Example Message conveying an Alert to a PSAP

9. Security Considerations

This section discusses security considerations when SIP user agents issue emergency alerts utilizing MESSAGE and CAP. Location specific threats are not unique to this document and are discussed in [RFC7378] and [RFC6442].

The ECRIT emergency services architecture [RFC6443] considers classic individual-to-authority emergency calling where the identity of the emergency caller does not play a role at the time of the call establishment itself, i.e., a response to the emergency call does not depend on the identity of the caller. In the case of emergency alerts generated by devices such as sensors, the processing may be different in order to reduce the number of falsely generated emergency alerts. Alerts could get triggered based on certain sensor input that might have been caused by factors other than the actual occurrence of an alert-relevant event. For example, a sensor may simply be malfunctioning. For this reason, not all alert messages are directly sent to a PSAP, but rather may be pre-processed by a separate entity, potentially under supervision by a human, to filter alerts and potentially correlate received alerts with others to obtain a larger picture of the ongoing situation.

In any case, for alerts initiated by sensors, the identity could play an important role in deciding whether to accept or ignore an incoming alert message. With the scenario shown in Figure 1 it is very likely that only authorized sensor input will be processed. For this reason, it needs to be possible to refuse to accept alert messages from an unknown origin. Two types of information elements can be used for this purpose:

  1. SIP itself provides security mechanisms that allow the verification of the originator's identity. These mechanisms can be re-used, such as P-Asserted-Identity [RFC3325] or SIP Identity [RFC8224]. The latter provides a cryptographic assurance while the former relies on a chain of trust model.
  2. CAP provides additional security mechanisms and the ability to carry further information about the sender's identity. Section 3.3.4.1 of [cap] specifies the signing algorithms of CAP documents.

In addition to the desire to perform identity-based access control, the classic communication security threats need to be considered, including integrity protection to prevent forgery or replay of alert messages in transit. To deal with replay of alerts, a CAP document contains the mandatory <identifier>, <sender>, <sent> elements and an optional <expire> element. Together, these elements make the CAP document unique for a specific sender and provide time restrictions. An entity that has already received a CAP message within the indicated timeframe is able to detect a replayed message and, if the content of that message is unchanged, then no additional security vulnerability is created. Additionally, it is RECOMMENDED to make use of SIP security mechanisms, such as SIP Identity [RFC8224], to tie the CAP message to the SIP message. To provide protection of the entire SIP message exchange between neighboring SIP entities, the usage of TLS is REQUIRED.

Note that none of the security mechanism in this document protect against a compromised sensor sending crafted alerts. Privacy provided for any emergency calls, including non-interactive messages, is subject to local regulations.

10. IANA Considerations

10.1. Registration of the 'application/EmergencyCallData.cap+xml' MIME type

To:
ietf-types@iana.org

Subject:
Registration of MIME media type application/ EmergencyCallData.cap+xml

MIME media type name:
application

MIME subtype name:
cap+xml

Required parameters:
(none)

Optional parameters:
charset; Indicates the character encoding of enclosed XML. Default is UTF-8 [RFC3629].

Encoding considerations:
Uses XML, which can employ 8-bit characters, depending on the character encoding used. See [RFC7303], Section 3.2.

Security considerations:
This content type is designed to carry payloads of the Common Alerting Protocol (CAP). RFC XXX [Replace by the RFC number of this specification] discusses security considerations for this.

Interoperability considerations:
This content type provides a way to convey CAP payloads.

Published specification:
RFC XXX [Replace by the RFC number of this specification].

Applications which use this media type:
Applications that convey alerts and warnings according to the CAP standard.

Additional information:
OASIS has published the Common Alerting Protocol at http://www.oasis-open.org/committees/documents.php&wg_abbrev=emergency

Person and email address to contact for further information:
Hannes Tschofenig, hannes.tschofenig@gmx.net

Intended usage:
Limited use

Author/Change controller:
IETF ECRIT working group

Other information:
This media type is a specialization of application/xml [RFC7303], and many of the considerations described there also apply to application/cap+xml.

10.2. IANA Registration of 'cap' Additional Data Block

This document registers a new block type in the sub-registry called 'Emergency Call Data Types' of the Emergency Call Additional Data Registry defined in [RFC7852]. The token is "cap", the Data About is "The Call" and the reference is this document.

10.3. IANA Registration for 425 Response Code

In the SIP Response Codes registry, the following is added

Reference: RFC-XXXX (i.e., this document)

Response code: 425 (recommended number to assign)

Default reason phrase: Bad Alert Message

            
   Registry:
     Response Code                               Reference
     ------------------------------------------  ---------
     Request Failure 4xx
       425 Bad Alert Message                   [this doc]
          

This SIP Response code is defined in Section 5.

10.4. IANA Registration of New AlertMsg-Error Header Field

            
   Registry:
     Header Name        compact    Reference
     -----------------  -------    ---------
     AlertMsg-Error             [this doc]
          
            
                                            Predefined
   Header Field        Parameter Name       Values      Reference
   -----------------   -------------------  ----------  ---------
   AlertMsg-Error      code                 yes         [this doc]
          

The SIP AlertMsg-error header field is created by this document, with its definition and rules in Section 5, to be added to the IANA Session Initiation Protocol (SIP) Parameters registry with two actions:

  1. Update the Header Fields registry with

  2. In the portion titled "Header Field Parameters and Parameter Values", add

10.5. IANA Registration for the SIP AlertMsg-Error Codes

This document creates a new registry for SIP, called "AlertMsg-Error Codes". AlertMsg-Error codes provide reasons for an error discovered by a recipient, categorized by the action to be taken by the error recipient. The initial values for this registry are shown below.

Registry Name: AlertMsg-Error Codes

Reference: [this doc]

Registration Procedures: Specification Required

            
Code Default Reason Phrase                                 Reference
---- ---------------------------------------------------   ---------
100  "Cannot Process the Alert Payload"                    [this doc]

101  "Alert Payload was not present or could not be found" [this doc]

102  "Not enough information to determine
      the purpose of the alert"                            [this doc]

103  "Alert Payload was corrupted"                         [this doc]
          

Details of these error codes are in Section 5.

11. Acknowledgments

The authors would like to thank the participants of the Early Warning adhoc meeting at IETF#69 for their feedback. Additionally, we would like to thank the members of the NENA Long Term Direction Working Group for their feedback.

Additionally, we would like to thank Martin Thomson, James Winterbottom, Shida Schubert, Bernard Aboba, Marc Linsner, Christer Holmberg and Ivo Sedlacek for their review comments.

12. References

12.1. Normative References

[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", March 1997.
[cap] Jones, E. and A. Botterell, "Common Alerting Protocol v. 1.2", October 2005.
[RFC2392] Levinson, E., "Content-ID and Message-ID Uniform Resource Locators", RFC 2392, DOI 10.17487/RFC2392, August 1998.
[RFC3261] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A., Peterson, J., Sparks, R., Handley, M. and E. Schooler, "SIP: Session Initiation Protocol", RFC 3261, DOI 10.17487/RFC3261, June 2002.
[RFC3428] Campbell, B., Rosenberg, J., Schulzrinne, H., Huitema, C. and D. Gurle, "Session Initiation Protocol (SIP) Extension for Instant Messaging", RFC 3428, DOI 10.17487/RFC3428, December 2002.
[RFC4119] Peterson, J., "A Presence-based GEOPRIV Location Object Format", RFC 4119, DOI 10.17487/RFC4119, December 2005.
[RFC5222] Hardie, T., Newton, A., Schulzrinne, H. and H. Tschofenig, "LoST: A Location-to-Service Translation Protocol", RFC 5222, DOI 10.17487/RFC5222, August 2008.
[RFC5234] Crocker, D. and P. Overell, "Augmented BNF for Syntax Specifications: ABNF", STD 68, RFC 5234, DOI 10.17487/RFC5234, January 2008.
[RFC7303] Thompson, H. and C. Lilley, "XML Media Types", RFC 7303, DOI 10.17487/RFC7303, July 2014.
[RFC3629] Yergeau, F., "UTF-8, a transformation format of ISO 10646", STD 63, RFC 3629, DOI 10.17487/RFC3629, November 2003.
[RFC6442] Polk, J., Rosen, B. and J. Peterson, "Location Conveyance for the Session Initiation Protocol", RFC 6442, DOI 10.17487/RFC6442, December 2011.
[RFC6881] Rosen, B. and J. Polk, "Best Current Practice for Communications Services in Support of Emergency Calling", BCP 181, RFC 6881, DOI 10.17487/RFC6881, March 2013.
[RFC7852] Gellens, R., Rosen, B., Tschofenig, H., Marshall, R. and J. Winterbottom, "Additional Data Related to an Emergency Call", RFC 7852, DOI 10.17487/RFC7852, July 2016.

12.2. Informative References

[RFC7378] Tschofenig, H., Schulzrinne, H. and B. Aboba, "Trustworthy Location", RFC 7378, DOI 10.17487/RFC7378, December 2014.
[RFC8224] Peterson, J., Jennings, C., Rescorla, E. and C. Wendt, "Authenticated Identity Management in the Session Initiation Protocol (SIP)", RFC 8224, DOI 10.17487/RFC8224, February 2018.
[RFC3325] Jennings, C., Peterson, J. and M. Watson, "Private Extensions to the Session Initiation Protocol (SIP) for Asserted Identity within Trusted Networks", RFC 3325, DOI 10.17487/RFC3325, November 2002.
[RFC6443] Rosen, B., Schulzrinne, H., Polk, J. and A. Newton, "Framework for Emergency Calling Using Internet Multimedia", RFC 6443, DOI 10.17487/RFC6443, December 2011.

Authors' Addresses

Brian Rosen 470 Conrad Dr Mars, PA 16046 US EMail: br@brianrosen.net
Henning Schulzrinne Columbia University Department of Computer Science 450 Computer Science Building New York, NY 10027 US Phone: +1 212 939 7004 EMail: hgs+ecrit@cs.columbia.edu URI: http://www.cs.columbia.edu
Hannes Tschofenig ARM Limited Austria EMail: Hannes.Tschofenig@gmx.net URI: http://www.tschofenig.priv.at
Randall Gellens Core Technology Consulting EMail: rg+ietf@coretechnologyconsulting.com URI: http://www.coretechnologyconsulting.com