Internet Engineering Task Force (IETF) K. Cartwright
Request for Comments: 7878 V. Bhatia
Category: Standards Track TNS
ISSN: 2070-1721 J-F. Mule
Apple Inc.
A. Mayrhofer
nic.at GmbH
August 2016
Session Peering Provisioning (SPP) Protocol over SOAP
Abstract
The Session Peering Provisioning Framework (SPPF) specifies the data
model and the overall structure to provision Session Establishment
Data (SED) into Session Data Registries and SIP Service Provider data
stores. To utilize this framework, one needs a substrate protocol.
Given that the Simple Object Access Protocol (SOAP) is currently
widely used for messaging between elements of such provisioning
systems, this document specifies the usage of SOAP (via HTTPS) as the
substrate protocol for SPPF. The benefits include leveraging
prevalent expertise and a higher probability that existing
provisioning systems will be able to easily migrate to using an SPPF-
based protocol.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in Section 2 of RFC 7841.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc7878.
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Copyright Notice
Copyright (c) 2016 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
SPPF, defined in [RFC7877], is best supported by a transport and
messaging infrastructure that is connection oriented, is request-
response oriented, is easily secured, supports propagation through
firewalls in a standard fashion, and is easily integrated into back-
office systems. This is due to the fact that the client side of SPPF
is likely to be integrated with organizations' operational support
systems that facilitate transactional provisioning of user addresses
and their associated SED. The server side of SPPF is likely to
reside in a separate organization's network, resulting in the SPPF
provisioning transactions traversing the Internet as they are
propagated from the SPPF client to the SPPF server. Given the
current state of industry practice and technologies, SOAP and HTTP(S)
are well suited for this type of environment. This document
describes the specification for transporting SPPF XML structures,
using SOAP and HTTP(S) as substrates.
The specification in this document for transporting SPPF XML
structures over SOAP and HTTP(S) is primarily comprised of five
subjects: (1) a description of any applicable SOAP features, (2) any
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applicable HTTP features, (3) security considerations, (4) (perhaps
most importantly) the Web Services Description Language (WSDL)
definition for the SPP Protocol over SOAP, and (5) XML Schema
Definition (XSD) types that are "substrate" specific.
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].
3. SOAP Features and Protocol Layering
The list of SOAP features that are explicitly used and required for
SPPP over SOAP are limited. Most SOAP features are not necessary for
SPPF. SPPP over SOAP primarily uses SOAP simply as a standard
message-envelope technology. The SOAP message envelope is comprised
of the SOAP header and body. As described in the SOAP specification
[SOAPREF], the SOAP header can contain optional, application-
specific, information about the message. The SOAP body contains the
SPPF message itself, whose structure is defined by the combination of
one of the WSDL operations defined in this document and the SPPF XML
data structures defined in this document and the SPPF document. SPPF
does not rely on any data elements in the SOAP header. All relevant
data elements are defined in the SPPF XML Schema described in
[RFC7877] and the SPPF WSDL types specification described in
Section 9 of this document.
WSDL is a widely standardized and adopted technology for defining the
top-level structures of the messages that are transported within the
body of a SOAP message. The WSDL definition for the SPPF SOAP
messages is defined later in this document, which imports by
reference the XML data types contained in the SPPF schema. The IANA
registry where the SPPF schema resides is described in "The IETF XML
Registry" [RFC3688].
There are multiple structural styles that WSDL allows. The best
practice for this type of application is what is sometimes referred
to as the "document/literal wrapped style". This style is generally
regarded as an optimal approach that enhances maintainability,
comprehension, portability, and, to a certain extent, performance.
It is characterized by setting the soapAction binding style as
"document", the soapAction encoding style as "literal", and then
defining the SOAP messages to simply contain a single data element
that "wraps" a data structure containing all the required input or
output data elements. The figure below illustrates this high-level
technical structure as conceptual layers 3 through 6.
Figure 1: Layering and Technical Structure of SPPP over SOAP Messages
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The operations supported by SPPP over SOAP are normatively defined
later in this document. Each SOAP operation defines a request/input
message and a response/output message. Each such request and
response message then contains a single object that wraps the SPPF
XML data types that comprise the inputs and the outputs,
respectively, of the SOAP operation.
SOAP faults are not used by the SPPP over SOAP. All success and
error responses are specified in Section 7.3 of this document.
However, if a SOAP fault were to occur, perhaps due to failures in
the SOAP message handling layer of a SOAP library, the client
application should capture and handle the fault. Specifics on how to
handle such SOAP faults, if they should occur, will be specific to
the chosen SOAP implementation.
Implementations MUST use SOAP 1.2 [SOAPREF] or higher and MUST
support SOAP 1.2. Implementations SHOULD use WSDL 1.1 [WSDLREF] and
MUST NOT use earlier versions. Use of WSDL versions greater than 1.1
may introduce interoperability problems with implementations that use
1.1.
SPPF is a request/reply framework that allows a client application to
submit provisioning data and query requests to a server. The SPPF
data structures are designed to be protocol agnostic. Concerns
regarding encryption, non-repudiation, and authentication are beyond
the scope of this document. For more details, please refer to
Section 4 ("Transport Substrate Protocol Requirements") of [RFC7877].
As illustrated in the previous diagram, SPPF can be viewed as a set
of layers that collectively define the structure of an SPPF request
and response. Layers 1 and 2 represent the transport, envelope, and
authentication technologies. This document defines layers 3, 4, 5,
and 6 for SPPP over SOAP.
1. Layer 1: The transport protocol layer represents the
communication mechanism between the client and server. SPPF can
be layered over any substrate protocol that provides a set of
basic requirements defined in Section 4 of [RFC7877].
2. Layer 2: The message-envelope layer is optional but can provide
features that are above the transport technology layer but below
the application messaging layer. Technologies such as HTTP and
SOAP are examples of message-envelope technologies.
3. Layers 3, 4, 5, and 6: The operation and message layers provide
an envelope-independent and substrate-independent wrapper for the
SPPF data model objects that are being acted on (created,
modified, and queried).
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4. HTTP(S) Features and SPPP over SOAP
While SOAP is not tied to HTTP(S), for reasons described in the
Introduction, HTTP(S) is a good choice as the substrate protocol for
the SPP Protocol SOAP messages. HTTP 1.1 includes the "persistent
connection" feature, which allows multiple HTTP request/response
pairs to be transported across a single HTTP connection. This is an
important performance optimization feature, particularly when the
connection is an HTTPS connection where the relatively time-consuming
TLS handshake has occurred.
Implementations compliant with this document MUST use HTTP 1.1
[RFC7230] or higher. Also, implementations SHOULD use persistent
connections.
5. Authentication, Integrity, and Confidentiality
To accomplish authentication, conforming SPPP over SOAP clients and
servers MUST use HTTP Digest Authentication as defined in [RFC7235].
To achieve integrity and privacy, conforming SPPP over SOAP clients
and servers MUST support TLS as defined in [RFC5246] as the secure
transport mechanism. Use of TLS MUST follow the recommendations
contained in [RFC7525]
6. Language Identification
Section 9 of [RFC7877] requires protocols to provide a mechanism to
transmit language tags together with human-readable messages. When
conforming SPPP SOAP servers use such tagging, the XML "lang"
attribute ([W3C.REC-xml-20081126], Section 2.12) MUST be used.
Clients MAY use the HTTP "Accept-Language" header field (see
Section 5.3.5 of [RFC7231]) in order to indicate their language
preference.
7. SPPP SOAP Data Structures
SPPP over SOAP uses a set of XML-based data structures for all the
supported operations and any parameters to which those operations are
applied. As also mentioned earlier in this document, these XML
structures are envelope independent and substrate independent. Refer
to "Protocol Operations" (Section 8) of this document for a
description of all the operations that MUST be supported.
The following sections describe the definitions of all the XML data
structures.
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7.1. Concrete Object Key Types
Certain operations in SPPF require an object key that uniquely
identifies the object(s) on which a given operation needs to be
performed. SPPF defines the XML structure of any such object key in
an abstract manner and delegates the concrete representation to any
conforming substrate protocol. The following subsections define the
various types of concrete object key types used in various operations
in SPPP over SOAP.
7.1.1. Generic Object Key
Most objects in SPPP over SOAP are uniquely identified by the
attributes in the generic object key (Refer to "Generic Object Key
Type", Section 5.2.1 of [RFC7877], for details). The concrete XML
representation of ObjKeyType is as below:
The ObjKeyType has the data elements as described below:
o rant: The identifier of the Registrant organization that owns the
object.
o name: The character string that contains the name of the object.
o type: The enumeration value that represents the type of SPPF
object. For example, both a Destination Group and a SED Group can
have the same name "TestObj" and be associated with the same
Registrant ID. Hence, to uniquely identify the object that
represents a Destination Group with the name "TestObj", the type
"DestGrp" must be specified when using this concrete ObjKeyType
structure to identify the Destination Group "TestObj".
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The object types in SPPP over SOAP MUST adhere to the above
definition of generic object key and are defined as an enumeration in
the XML data structure as follows:
Public Identifier type objects can further be of various sub-types
like a Telephone Number (TN), Routing Number (RN), TN Prefix, URI, or
TN Range and cannot be cleanly identified with the attributes in the
generic ObjKeyType. The definition of PubIdKeyType is as below:
The PubIdKeyType has data elements, as described below:
o rant: The identifier of the Registrant organization that owns the
object.
o number: An element of type NumberType (refer to Section 12 of
[RFC7877]) that contains the value and type of a number.
o range: An element of type NumberRangeType (refer to Section 12 of
[RFC7877]) that contains a range of numbers.
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o uri: A value that represents a Public Identifier.
Any instance of PubIdKeyType MUST contain exactly one element from
the following set of elements: "number", "range", "uri".
7.1.3. SED Group Offer Key
In addition to the attributes in the generic ObjKeyType, a SED Group
Offer object is uniquely identified by the organization ID of the
organization to whom a SED Group has been offered. The definition of
SedGrpOfferKeyType is as below:
The SedGrpOfferKeyType has the data elements as described below:
o sedGrpKey: Identifies the SED Group that was offered.
o offeredTo: The organization ID of the organization that was
offered the SED Group object identified by the sedGrpKey.
7.2. Operation Request and Response Structures
An SPPF client interacts with an SPPF server by sending one or more
requests to the server and by receiving corresponding responses from
the server. The basic set of operations that an SPPF client can
submit to an SPPF server and the semantics of those operations are
defined in "Framework Operations", Section 7 of [RFC7877]. The
following subsections describe the XML data structures that are used
for each of those types of operations for an SPPP over SOAP
implementation.
7.2.1. Add Operation Structure
In order to add (or modify) an object in the Registry, an authorized
entity can send the spppAddRequest to the Registry.
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An SPPP over SOAP Add request is wrapped within the <spppAddRequest>
element while an SPPP over SOAP Add response is wrapped within an
<spppAddResponse> element. The following sub-sections describe the
<spppAddRequest> and <spppAddResponse> elements. Refer to Section 10
for an example of an Add operation on each type of SPPF object.
7.2.1.1. Add Request
An SPPP over SOAP Add request definition is contained within the
generic <spppAddRequest> element.
The data elements within the <spppAddRequest> element are described
as follows:
o clientTransId: Zero or one client-generated transaction ID that,
within the context of the SPPF client, identifies this request.
This value can be used at the discretion of the SPPF client to
track, log, or correlate requests and their responses. The SPPF
server MUST echo back this value to the client in the
corresponding response to the incoming request. The SPPF server
will not check this value for uniqueness.
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o obj: One or more elements of abstract type BasicObjType (defined
in [RFC7877]). Each element contains all the attributes of an
SPPF object that the client is requesting the SPPF server to add.
Refer to Section 3.1 of [RFC7877] for the XML structure of all
concrete types, for various SPPF objects, that extend from
abstract BasicObjType and hence are eligible to be passed into
this element. The elements are processed by the SPPF server in
the order in which they are included in the request. With respect
to the handling of error conditions, conforming SPPP SOAP servers
MUST stop processing BasicObjType elements in the request at the
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first error and roll back any BasicObjType elements that had
already been processed for that add request ("stop and roll
back").
7.2.1.2. Add Response
An SPPP over SOAP add response object is contained within the generic
<spppAddResponse> element. This response structure is used for all
types of SPPF objects that are provisioned by the SPPF client.
An <spppAddResponse> contains the elements necessary for the SPPF
client to precisely determine the overall result of the request, and
if an error occurs, it provides information about the specific
object(s) that caused the error.
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The data elements within the SPPP over SOAP Add response are
described as follows:
o clientTransId: Zero or one client transaction ID. This value is
simply an echo of the client transaction ID that the SPPF client
passed into the SPPF update request. When included in the
request, the SPPF server MUST return it in the corresponding
response message.
o serverTransId: Exactly one server transaction ID that identifies
this request for tracking purposes. This value MUST be unique for
a given SPPF server.
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o detailResult: An optional response code, response message, and
BasicObjType (as defined in [RFC7877]) triplet. This element will
be present only if an object-level error has occurred. It
indicates the error condition and the exact request object that
contributed to the error. The response code will reflect the
exact error. See Section 7.3 for further details.
7.2.2. Delete Operation Structure
In order to remove an object from the Registry, an authorized entity
can send the spppDelRequest into the Registry. An SPPP over SOAP
Delete request is wrapped within the <spppDelRequest> element while
an SPPP over SOAP Delete response is wrapped within the generic
<spppDelResponse> element. The following subsections describe the
<spppDelRequest> and <spppDelResponse> elements. Refer to Section 10
for an example of the Delete operation on each type of SPPF object.
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7.2.2.1. Delete Request
An SPPP over SOAP Delete request definition is contained within the
generic <spppDelRequest> element.
The data elements within the <spppDelRequest> element are described
as follows:
o clientTransId: Zero or one client-generated transaction ID that,
within the context of the SPPF client, identifies this request.
This value can be used at the discretion of the SPPF client to
track, log, or correlate requests and their responses. The SPPF
server MUST echo back this value to the client in the
corresponding response to the incoming request. SPPF server will
not check this value for uniqueness.
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o objKey: One or more elements of abstract type ObjKeyType (as
defined in [RFC7877]). Each element contains attributes that
uniquely identify the object that the client is requesting the
server to delete. Refer to Section 7.1 for a description of all
concrete object key types, for various SPPF objects, which are
eligible to be passed into this element. The elements are
processed by the SPPF server in the order in which they are
included in the request. With respect to the handling of error
conditions, conforming SPPP SOAP servers MUST stop processing
ObjKeyType elements in the request at the first error and roll
back any ObjKeyType elements that had already been processed for
that Delete request ("stop and roll back").
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7.2.2.2. Delete Response
An SPPP over SOAP delete response object is contained within the
generic <sppDeleteResponse> element. This response structure is used
for a Delete request on all types of SPPF objects that are
provisioned by the SPPF client.
An <spppDelResponse> contains the elements necessary for the SPPF
client to precisely determine the overall result of the request, and
if an error occurs, it provides information about the specific object
key(s) that caused the error.
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The data elements within the SPPP over SOAP Delete response are
described as follows:
o clientTransId: Zero or one client transaction ID. This value is
simply an echo of the client transaction ID that the SPPF client
passed into the SPPF update request. When included in the
request, the SPPF server MUST return it in the corresponding
response message.
o serverTransId: Exactly one server transaction ID that identifies
this request for tracking purposes. This value MUST be unique for
a given SPPF server.
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o detailResult: An optional response code, response message, and
ObjKeyType (as defined in [RFC7877]) triplet. This element will
be present only if a specific object key level error has occurred.
It indicates the error condition and the exact request object key
that contributed to the error. The response code will reflect the
exact error. See Section 7.3 for further details.
7.2.3. Accept Operation Structure
In SPPF, a SED Group Offer can be accepted or rejected by, or on
behalf of, the Registrant to whom the SED Group has been offered
(refer to Section 3.1 of [RFC7877] for a description of the SED Group
Offer object). The Accept operation is used to accept such SED Group
Offers by, or on behalf of, the Registrant. The request structure
for an SPPP over SOAP Accept operation is wrapped within the
<spppAcceptRequest> element while an SPPP over SOAP Accept response
is wrapped within the generic <spppAcceptResponse> element. The
following subsections describe the <spppAcceptRequest> and
<spppAcceptResponse> elements. Refer to Section 10 for an example of
the Accept operation on a SED Group Offer.
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7.2.3.1. Accept Request Structure
An SPPP over SOAP Accept request definition is contained within the
generic <sppAcceptRequest> element.
The data elements within the <spppAcceptRequest> element are
described as follows:
o clientTransId: Zero or one client-generated transaction ID that,
within the context of the SPPF client, identifies this request.
This value can be used at the discretion of the SPPF client to
track, log, or correlate requests and their responses. The SPPF
server MUST echo back this value to the client in the
corresponding response to the incoming request. The SPPF server
will not check this value for uniqueness.
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o sedGrpOfferKey: One or more elements of type SedGrpOfferKeyType
(as defined in this document). Each element contains attributes
that uniquely identify a SED Group Offer that the client is
requesting the server to accept. The elements are processed by
the SPPF server in the order in which they are included in the
request. With respect to the handling of error conditions,
conforming SPPP SOAP servers MUST stop processing
SedGrpOfferKeyType elements in the request at the first error and
roll back any SedGrpOfferKeyType elements that had already been
processed for that Accept request ("stop and roll back").
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7.2.3.2. Accept Response
An SPPP over SOAP accept response structure is contained within the
generic <sppAcceptResponse> element. This response structure is used
for an Accept request on a SED Group Offer.
An <spppAcceptResponse> contains the elements necessary for the SPPF
client to precisely determine the overall result of the request, and
if an error occurs, it provides information about the specific SED
Group Offer key(s) that caused the error.
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The data elements within the SPPP over SOAP Accept response are
described as follows:
o clientTransId: Zero or one client transaction ID. This value is
simply an echo of the client transaction ID that the SPPF client
passed into the SPPF update request. When included in the
request, the SPPF server MUST return it in the corresponding
response message.
o serverTransId: Exactly one server transaction ID that identifies
this request for tracking purposes. This value MUST be unique for
a given SPPF server.
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o detailResult: An optional response code, response message, and
SedGrpOfferKeyType (as defined in this document) triplet. This
element will be present only if any specific SED Group Offer key
level error has occurred. It indicates the error condition and
the exact request SED Group Offer key that contributed to the
error. The response code will reflect the exact error. See
Section 7.3 for further details.
7.2.4. Reject Operation Structure
In SPPF, a SED Group Offer can be accepted or rejected by, or on
behalf of, the Registrant to whom the SED Group has been offered
(refer to "Framework Data Model Objects", Section 6 of [RFC7877] for
a description of the SED Group Offer object). The Reject operation
is used to reject such SED Group Offers by, or on behalf of, the
Registrant. The request structure for an SPPP over SOAP Reject
operation is wrapped within the <spppRejectRequest> element while an
SPPP over SOAP Reject response is wrapped within the generic
<spppRejecResponse> element. The following subsections describe the
<spppRejectRequest> and <spppRejecResponse> elements. Refer to
Section 10 for an example of the Reject operation on a SED Group
Offer.
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7.2.4.1. Reject Request
An SPPP over SOAP Reject request definition is contained within the
generic <spppRejectRequest> element.
The data elements within the <spppRejectRequest> element are
described as follows:
o clientTransId: Zero or one client-generated transaction ID that,
within the context of the SPPF client, identifies this request.
This value can be used at the discretion of the SPPF client to
track, log, or correlate requests and their responses. The SPPF
server MUST echo back this value to the client in the
corresponding response to the incoming request. The SPPF server
will not check this value for uniqueness.
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o sedGrpOfferKey: One or more elements of type SedGrpOfferKeyType
(as defined in this document). Each element contains attributes
that uniquely identify a SED Group Offer that the client is
requesting the server to reject. The elements are processed by
the SPPF server in the order in which they are included in the
request. With respect to the handling of error conditions,
conforming SPPF servers MUST stop processing SedGrpOfferKeyType
elements in the request at the first error and roll back any
SedGrpOfferKeyType elements that had already been processed for
that Reject request ("stop and roll back").
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7.2.4.2. Reject Response
An SPPP over SOAP reject response structure is contained within the
generic <sppRejectResponse> element. This response structure is used
for a Reject request on a SED Group Offer.
An <spppRejectResponse> contains the elements necessary for the SPPF
client to precisely determine the overall result of the request, and
if an error occurs, it provides information about the specific SED
Group Offer key(s) that caused the error.
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The data elements within the SPPP over SOAP Reject response are
described as follows:
o clientTransId: Zero or one client transaction ID. This value is
simply an echo of the client transaction ID that the SPPF client
passed into the SPPF update request. When included in the
request, the SPPF server MUST return it in the corresponding
response message.
o serverTransId: Exactly one server transaction ID that identifies
this request for tracking purposes. This value MUST be unique for
a given SPPF server.
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o detailResult: An optional response code, response message, and
SedGrpOfferKeyType (as defined in this document) triplet. This
element will be present only if any specific SED Group Offer key
level error has occurred. It indicates the error condition and
the exact request SED Group Offer key that contributed to the
error. The response code will reflect the exact error. See
Section 7.3 for further details.
7.2.5. Batch Operation Structure
An SPPP over SOAP Batch request XML structure allows the SPPF client
to send any of the Add, Del, Accept, or Reject operations together in
one single request. This gives an SPPF client the flexibility to use
one single request structure to perform more than operations (verbs).
The batch request structure is wrapped within the <spppBatchRequest>
element while an SPPF Batch response is wrapped within the
<spppBatchResponse> element. The following subsections describe the
<spppBatchRequest> and <spppBatchResponse> elements. Refer to
Section 10 for an example of a Batch operation.
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7.2.5.1. Batch Request Structure
An SPPP over SOAP Batch request definition is contained within the
generic <spppBatchRequest> element.
The data elements within the <sppBatchRequest> element are described
as follows:
o clientTransId: Zero or one client-generated transaction ID that,
within the context of the SPPF client, identifies this request.
This value can be used at the discretion of the SPPF client to
track, log, or correlate requests and their responses. The SPPF
server MUST echo back this value to the client in the
corresponding response to the incoming request. The SPPF server
will not check this value for uniqueness.
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o addObj: One or more elements of abstract type BasicObjType where
each element identifies an object that needs to be added.
o delObj: One or more elements of abstract type ObjKeyType where
each element identifies a key for the object that needs to be
deleted .
o acceptSedGrpOffer: One or more elements of type SedGrpOfferKeyType
where each element identifies a SED Group Offer that needs to be
accepted.
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o rejectSedGrpOffer: One or more elements of type SedGrpOfferKeyType
where each element identifies a SED Group Offer that needs to be
rejected.
With respect to the handling of error conditions, conforming SPPP
SOAP servers MUST stop processing elements in the request at the
first error and roll back any elements that had already been
processed for that Batch request ("stop and roll back").
7.2.5.2. Batch Response
An SPPP over SOAP batch response structure is contained within the
generic <sppBatchResponse> element. This response structure is used
for a Batch request that contains many different types of SPPF
operations.
An <spppBatchResponse> contains the elements necessary for an SPPF
client to precisely determine the overall result of various
operations in the request, and if an error occurs, it provides
information about the specific objects or keys in the request that
caused the error.
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The data elements within the SPPP over SOAP Batch response are
described as follows:
o clientTransId: Zero or one client transaction ID. This value is
simply an echo of the client transaction ID that the SPPF client
passed into the SPPF update request. When included in the
request, the SPPF server MUST return it in the corresponding
response message.
o serverTransId: Exactly one server transaction ID that identifies
this request for tracking purposes. This value MUST be unique for
a given SPPF server.
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o addResult: One or more elements of type ObjResultCodeType where
each element identifies the result code, result message, and the
specific object to which the result relates.
o delResult: One or more elements of type ObjKeyResultCodeType where
each element identifies the result code, result message, and the
specific object key to which the result relates.
o acceptResult: One or more elements of type
SedGrpOfferKeyResultCodeType where each element identifies the
result code, result message, and the specific SED Group Offer key
to which the result relates.
o rejectResult: One or more elements of type
SedGrpOfferKeyResultCodeType where each element identifies the
result code, result message, and the specific SED Group Offer key
to which the result relates.
7.2.6. Get Operation Structure
In order to query the details of an object from the Registry, an
authorized entity can send the spppGetRequest to the Registry with a
GetRqstType XML data structure containing one or more object keys
that uniquely identify the object whose details are being queried.
The following subsections describe the <spppGetRequest> and
<spppGetResponse> elements. Refer to Section 10 for an example of
the SPPP over SOAP Get operation on each type of SPPF object.
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7.2.6.1. Get Request
The request structure for an SPPP over SOAP Get operation is
contained within the generic <spppGetRequest> element:
The data elements within the <spppGetRequest> element are described
as follows:
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o objKey: One or more elements of abstract type ObjKeyType (as
defined in [RFC7877]). Each element contains attributes that
uniquely identify the object that the client is requesting the
server to query. Refer to Section 7.1 of this document for a
description of all concrete object key types, for various SPPF
objects, which are eligible to be passed into this element.
7.2.6.2. Get Response
The SPPP over SOAP Get response is wrapped within the generic
<spppGetResponse> element, as described in Section 7.2.8.
7.2.7. Get SED Group Offers Operation Structure
In addition to the ability to query the details of one or more SED
Group Offers using a SED Group Offer key in the spppGetRequest, this
operation also provides an additional, more flexible, structure to
query for SED Group Offer objects. This additional structure is
contained within the <getSedGrpOffersRequest> element while the
response is wrapped within the generic <spppGetResponse> element.
The following subsections describe the <getSedGrpOffersRequest> and
<spppGetResponse> elements.
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7.2.7.1. Get SED Group Offers Request
Using the details passed into this structure, the server will attempt
to find SED Group Offer objects that satisfy all the criteria passed
into the request. If no criteria are passed in, then the SPPF server
will return the list of SED Group Offer objects that belong to the
Registrant. If there are no matching SED Group Offers found, then an
empty result set will be returned.
The data elements within the <getSedGrpOffersRequest> element are
described as follows:
o minorVer: Zero or one minor version identifier, as defined in
Section 7.4.
o offeredBy: Zero or more organization IDs. Only offers that are
offered to the organization IDs in this list should be included in
the result set. The result set is also subject to other query
criteria in the request.
o offeredTo: Zero or more organization IDs. Only offers that are
offered by the organization IDs in this list should be included in
the result set. The result set is also subject to other query
criteria in the request.
o status: The status of the offer, offered or accepted. Only offers
in the specified status should be included in the result set. If
this element is not present, then the status of the offer should
not be considered in the query. The result set is also subject to
other query criteria in the request.
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o sedGrpOfferKey: Zero or more SED Group Offer keys. Only offers
having one of these keys should be included in the result set.
The result set is also subject to other query criteria in the
request.
7.2.7.2. Get SED Group Offers Response
The spppGetResponse element is described in Section 7.2.8.
7.2.8. Generic Query Response
An SPPP over SOAP query response object is contained within the
generic <spppGetResponse> element.
An <spppGetResponse> contains the elements necessary for the SPPF
client to precisely determine the overall result of the query and
details of any SPPF objects that matched the criteria in the request.
The data elements within the SPPP over SOAP query response are
described as follows:
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o resultObj: The set of zero or more objects that matched the query
criteria. If no objects matched the query criteria, then the
result object(s) MUST be empty and the overallResult value MUST
indicate success (if no matches are found for the query criteria,
the response is considered a success).
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7.2.9. Get Server Details Operation Structure
In order to query certain details of the SPPF server, such as the
SPPF server's status and the major/minor version supported by the
server, the Server Details operation structure SHOULD be used. This
structure is contained within the <spppServerStatusRequest> element
whereas an SPPF server status response is wrapped within the
<spppServerStatusResponse> element. The following subsections
describe the <spppServerStatusRequest> and <spppServerStatusResponse>
elements.
7.2.9.1. Get Server Details Request
An SPPP over SOAP server details request structure is represented in
the <spppServerStatusRequest> element as follows:
The data elements within the <spppServerStatusResponse> element are
described as follows:
o overallResult: Exactly one response code and message pair that
explicitly identifies the result of the request. See Section 7.3
for further details.
o svcMenu: Exactly one element of type SvcMenuType that, in turn,
contains the elements to return the server status, the major and
minor versions of SPPP over SOAP supported by the SPPF server
(refer to Section 12 of [RFC7877] for the definition of
SvcMenuType).
7.3. Response Codes and Messages
This section contains the listing of response codes and their
corresponding human-readable text. These response codes are in
conformance with the response types defined in Section 5.3 of
[RFC7877].
The response code numbering scheme generally adheres to the theory
formalized in Section 4.2.1 of [RFC5321]:
o The first digit of the response code can only be 1 or 2: 1 = a
positive result, and 2 = a negative result.
o The second digit of the response code indicates the category: 0 =
Protocol Syntax, 1 = Implementation Specific Business Rule, 2 =
Security, and 3 = Server System.
o The third and fourth digits of the response code indicate the
individual message event within the category defined by the first
two digits.
The response codes are also categorized as to whether they are
overall response codes that may only be returned in the overallResult
data element in SPPF responses or object-level response codes that
may only be returned in the detailResult element of the SPPF
responses.
Table 1: Response Code Numbering Scheme and Messages
The response message for response code 2001 is "parameterized" with
the following parameter: "[Maximum requests supported]". When the
request is too large, this parameter MUST be used to indicate the
maximum number of requests supported by the server in a single
protocol operation.
Response code 2000 SHOULD be used when the XML Schema validation of
requests fails.
Each of the object-level response messages are "parameterized" with
the following parameters: "AttributeName" and "AttributeValue".
For example, if an SPPF client sends a request to delete a
Destination Group with a name "TestDG", and it does not already
exist, then the error message returned should be: "Attribute value
invalid. AttrName:dgName AttrVal:TestDG".
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The use of these parameters MUST adhere to the rules defined in
Section 5.3 of [RFC7877].
7.4. Minor Version Identifier
The minor version identifier element is defined as follows:
o minorVer: Zero or one minor version identifier, indicating the
minor version of the SPPP over SOAP API that the client is
attempting to use. This is used in conjunction with the major
version identifier in the XML Namespace to identify the version of
SPPP over SOAP that the client is using. If the element is not
present, the server assumes that the client is using the latest
minor version of SPPP over SOAP supported by the SPPF server for
the given major version. The versions of SPPP over SOAP supported
by a given SPPF server can be retrieved by the client using this
same spppServerStatusRequest without passing in the minorVer
element.
8. Protocol Operations
Refer to Section 7 of [RFC7877] for a description of all SPPF
operations and any necessary semantics that MUST be adhered to in
order to conform with SPPF.
9. SPPP over SOAP WSDL Definition
The SPPP over SOAP WSDL and data types are defined below. The WSDL
design approach is commonly referred to as "Generic WSDL". It is
generic in the sense that there is not a specific WSDL operation
defined for each object type that is supported by the SPPF protocol.
There is a single WSDL structure for each type of SPPF operation.
Each such WSDL structure contains exactly one input structure and one
output structure that wraps any data elements that are part of the
incoming request and the outgoing response, respectively. The
spppSOAPBinding in the WSDL defines the binding style as "document"
and the encoding as "literal". It is this combination of "wrapped"
input and output data structures, "document" binding style, and
"literal" encoding that characterize the Document Literal Wrapped
style of WSDL specifications.
Notes: The following WSDL has been formatted (e.g., tabs, spaces) to
meet IETF requirements. Deployments MUST replace
"REPLACE_WITH_ACTUAL_URL" in the WSDL below with the URI of the SPPF
server instance.
This section shows an XML message exchange between two SIP Service
Providers (SSPs) and a Registry. The messages in this section are
valid XML instances that conform to the SPPP over SOAP schema version
within this document. This section also relies on the XML data
structures defined in the SPPF specification [RFC7877], which should
also be referenced to understand XML object types embedded in these
example messages.
In this sample use-case scenario, SSP1 and SSP2 provision resource
data in the Registry and use SPPF constructs to selectively share the
SED Groups. In the figure below, SSP2 has two ingress Signaling Path
Border Element (SBE) instances that are associated with the Public
Identities with which SSP2 has the retail relationship. Also, the
two SBE instances for SSP1 are used to show how to use SPPF to
associate route preferences for the destination Ingress Routes and
exercise greater control on outbound traffic to the peer's ingress
SBEs.
SSP2 adds a Destination Group to the Registry for later use. The
SSP2 SPPF client sets a unique transaction identifier "txn_1479" for
tracking purposes. The name of the Destination Group is set to
DEST_GRP_SSP2_1.
The Registry processes the request and returns a favorable response
confirming successful creation of the named Destination Group. In
addition to returning a unique server transaction identifier, the
Registry returns the matching client transaction identifier from the
request message back to the SPPF client.
SSP2 creates the grouping of SED Records (e.g., Ingress Routes) and
chooses a higher precedence for SED_SSP2_SBE2 by setting a lower
number for the "priority" attribute, a protocol agnostic precedence
indicator.
10.5. Add Public Identifier -- Successful COR Claim
SSP2 activates a TN Public Identifier by associating it with a valid
Destination Group. Further, SSP2 puts forth a claim that it is the
carrier-of-record (COR) for the TN.
Assuming that the Registry has access to TN authority data and it
performs the required checks to verify that SSP2 is in fact the SP of
record for the given TN, the request is processed successfully. In
the response message, the Registry sets the value of <cor> to "true"
in order to confirm the SSP2 claim as the carrier-of-record, and the
<corDate> reflects the time when the carrier-of-record claim is
processed.
If another entity that SSP2 shares SED (e.g., routes) with has access
to Number Portability data, it may choose to perform route lookups by
RN. Therefore, SSP2 associates an RN to a Destination Group in order
to facilitate Ingress Route discovery.
In order for SSP1 to complete session establishment for a destination
TN where the target subscriber has a retail relationship with SSP2,
it first requires an asynchronous bidirectional handshake to show
mutual consent. To start the process, SSP2 initiates the peering
handshake by offering SSP1 access to its SED Group.
The Registry completes the request successfully and confirms that the
SSP1 will now have the opportunity to weigh in on the offer and
either accept or reject it. The Registry may employ out-of-band
notification mechanisms for quicker updates to SSP1 so they can act
faster, though this topic is beyond the scope of this document.
The Registry confirms that the request has been processed
successfully. From this point forward, if SSP1 looks up a Public
Identifier through the query resolution server, where the Public
Identifier is part of the Destination Group by way of
"SED_GRP_SSP2_1" SED association, SSP2 ingress SBE information will
be shared with SSP1.
SSP1 wants to prioritize all outbound traffic to the Ingress Route
associated with the "SED_GRP_SSP2_1" SED Group record, through
"sbe1.ssp1.example.com".
Earlier, SSP1 had accepted having visibility to SSP2 SED. SSP1 now
decides to no longer maintain this visibility; hence, it rejects the
SED Group Offer.
The Registry confirms that the request has been processed
successfully. From this point forward, if SSP1 looks up a Public
Identifier through the query resolution server, where the Public
Identifier is part of the Destination Group by way of
"SED_GRP_SSP2_1" SED association, SSP2 ingress SBE information will
not be shared with SSP1; hence, an SSP2 ingress SBE will not be
returned in the query response.
The Registry completes the request successfully and returns a
favorable response. Restoring this resource sharing will require a
new SED Group Offer from SSP2 to SSP1 followed by a successful SED
Group Accept request from SSP1.
Following is an example of how some of the operations mentioned in
previous sections MAY be performed by an SPPF client as a batch in
one single SPPP over SOAP request.
In the sample request below, SSP1 wants to accept a SED Group Offer
from SSP3, add a Destination Group, add a Naming Authority Pointer
(NAPTR) SED Record, add a SED Group, add a SED Group Offer, delete a
previously provisioned TN type Public Identifier, delete a previously
provisioned SED Group, and reject a SED Group Offer from SSP4.
The base security considerations of SPPP outlined in Section 9 of
[RFC7877] also apply to SPPP over SOAP implementations.
Additionally, the following must be considered:
SPPP over SOAP is used to query and update session peering data and
addresses, so the ability to access this protocol should be limited
to users and systems that are authorized to query and update this
data. Because this data is sent in both directions, it may not be
sufficient for just the client or user to be authenticated with the
server. The identity of the server should also be authenticated by
the client, which is often accomplished using the TLS certificate
exchange and validation described in [RFC2818].
11.1. Vulnerabilities
Section 5 describes the use of HTTP and TLS as the underlying
substrate protocols for SPPP over SOAP. These underlying protocols
may have various vulnerabilities, and these may be inherited by SPPP
over SOAP. SPPP over SOAP itself may have vulnerabilities because an
authorization model is not explicitly specified in this document.
During a TLS handshake, TLS servers can optionally request a
certificate from a TLS client; that option is not a requirement for
this protocol. This presents a denial-of-service risk in which
unauthenticated clients can consume server CPU resources by creating
TLS sessions. The risk is increased if the server supports client-
initiated renegotiation. This risk can be mitigated by disabling
client-initiated renegotiation on the server and by ensuring that
other means (such as firewall access control lists) are used to
restrict unauthenticated client access to servers.
In conjunction with the above, it is important that SPPP over SOAP
implementations implement an authorization model that considers the
source of each query or update request and determines whether it is
reasonable to authorize that source to perform that specific query or
update.
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12. IANA Considerations
This document uses URNs to describe XML Namespaces and XML Schemas.
According to [RFC3688], IANA has performed the following URN
assignment:
URN: urn:ietf:params:xml:ns:sppf:soap:1
Registrant Contact: IESG
XML: See Section 9 of [RFC7878]
13. References
13.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<http://www.rfc-editor.org/info/rfc2119>.
[RFC5246] Dierks, T. and E. Rescorla, "The Transport Layer Security
(TLS) Protocol Version 1.2", RFC 5246,
DOI 10.17487/RFC5246, August 2008,
<http://www.rfc-editor.org/info/rfc5246>.
[RFC7230] Fielding, R., Ed. and J. Reschke, Ed., "Hypertext Transfer
Protocol (HTTP/1.1): Message Syntax and Routing",
RFC 7230, DOI 10.17487/RFC7230, June 2014,
<http://www.rfc-editor.org/info/rfc7230>.
[RFC7231] Fielding, R., Ed. and J. Reschke, Ed., "Hypertext Transfer
Protocol (HTTP/1.1): Semantics and Content", RFC 7231,
DOI 10.17487/RFC7231, June 2014,
<http://www.rfc-editor.org/info/rfc7231>.
[RFC7235] Fielding, R., Ed. and J. Reschke, Ed., "Hypertext Transfer
Protocol (HTTP/1.1): Authentication", RFC 7235,
DOI 10.17487/RFC7235, June 2014,
<http://www.rfc-editor.org/info/rfc7235>.
Cartwright, et al. Standards Track [Page 81]
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[RFC7525] Sheffer, Y., Holz, R., and P. Saint-Andre,
"Recommendations for Secure Use of Transport Layer
Security (TLS) and Datagram Transport Layer Security
(DTLS)", BCP 195, RFC 7525, DOI 10.17487/RFC7525, May
2015, <http://www.rfc-editor.org/info/rfc7525>.
[RFC7877] Cartwright, K., Bhatia, V., Ali, S., and D. Schwartz,
"Session Peering Provisioning Framework (SPPF)", RFC 7877,
DOI 10.17487/RFC7877, August 2016,
<http://www.rfc-editor.org/info/rfc7877>.
[SOAPREF] Gudgin, M., Hadley, M., Moreau, J., and H. Nielsen, "SOAP
Version 1.2 Part 1: Messaging Framework (Second Edition)",
W3C Recommendation REC-SOAP12-part1-20070427, April 2007,
<http://www.w3.org/TR/soap12-part1/>.
[W3C.REC-xml-20081126]
Sperberg-McQueen, C., Yergeau, F., Bray, T., Maler, E.,
and J. Paoli, "Extensible Markup Language (XML) 1.0 (Fifth
Edition)", W3C Recommendation REC-xml-20081126, November
2008, <http://www.w3.org/TR/2008/REC-xml-20081126>.
[WSDLREF] Christensen, E., Curbera, F., Meredith, G., and S.
Weerawarana, "Web Services Description Language (WSDL)
1.1", W3C Note NOTE-wsdl-20010315, March 2001,
<http://www.w3.org/TR/2001/NOTE-wsdl-20010315>.
Acknowledgements
This document is a result of various discussions held with the IETF
DRINKS working group, specifically the protocol design team, with
contributions from the following individuals, in alphabetical order:
Syed Ali, Vikas Bhatia, Kenneth Cartwright, Sumanth Channabasappa,
Lisa Dusseault, Deborah A. Guyton, Scott Hollenbeck, Otmar Lendl,
Manjul Maharishi, Mickael Marrache, Alexander Mayrhofer, Samuel
Melloul, Jean-Francois Mule, Peter Saint-Andre, David Schwartz, and
Richard Shockey.
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Authors' Addresses
Kenneth Cartwright
TNS
10740 Parkridge Boulevard
Reston, VA 20191
United States
