Wiki source code of SDMX 2.1 Standards. Section. 5. Registry Specification – Logical Interfaces

Version 3.3 by Helena on 2025/05/21 15:27

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1.1	1	{{box title="Contents"}}
	2	{{toc/}}
	3	{{/box}}
	4
	5	Revision History
	6
	7	\|Revision\|Date\|Contents
	8	\| \|April 2011\|Initial release
	9	\|1.0\|July 2011\|Rectification of problems of the specifications dated April 2011
	10	\|2.0\|July 2020\|Addition of VTL (Validation and Transformation Language) package, maintainable artefacts, nameable artefacts to 5.2.3, 6.2.2, 6.2.3, 6.2.4, 7.1.1
	11
	12	Corrigendum
	13
	14	The following problems with the specification dated April 2011 have been rectified as described below.
	15
	16	1. Problem
	17
	18	Figure 17 - Logical Class Diagram of Registration of Data and Metadata – shows the Provision Agreement as it was identified in version 2.0, and not as it is identified in version 2.1.
	19
	20	Rectification
	21
	22	Provision Agreement is a Maintainable Artefact at version 2.1 and so the relationship is shown directly to the Provision Agreement class and not indirectly to the Provision Agreement via a ProvisionAgreementRef class.
	23
	24	~1. Problem
	25
	26	Figure 17 - Logical Class Diagram of Registration of Data and Metadata – shows the Registration class without the indexAttributes attribute.
	27
	28	Rectification
	29
	30	The attribute indexAttribute attribute is added to the Registration class and a description is of its purpose is given in the table at line 916.
	31
	32	2. Problem
	33
	34	Lines 437 and 648 of the April 2011 document mention that the fixed id for an AgencyScheme is AGENCY_SCHEME whereas it should be AGENCIES. Rectification
	35
	36	The reference to AGENCY_SCHEME is changed to AGENCIES.
	37
	38	Adoption of the Validation and Transformation Language in 2020
	39
	40	The SDMX specifications dated July 2011 envisaged the adoption of a language aimed at defining algorithms for the derivation of the data and presented a basic framework requiring however further elaboration for its actual use.
	41
	42	Following the adoption of the Validation and Transformation Language (VTL) version 2.0 and its application to SDMX 2.1, this section of the SDMX specifications has been integrated by introducing the VTL package, maintainable artefacts, nameable artefacts to the sections 5.2.3, 6.2.2, 6.2.3, 6.2.4 and 7.1.1.
	43
	44	= 1 Introduction =
	45
	46	The business vision for SDMX envisages the promotion of a “data sharing” model to facilitate low-cost, high-quality statistical data and metadata exchange. Data sharing reduces the reporting burden of organisations by allowing them to publish data once, and let their counterparties “pull” data and related metadata as required. The scenario is based on:
	47
	48	* the availability of an abstract information model capable of supporting timeseries and cross-sectional data, structural metadata, and reference metadata (SDMX-IM)
	49	* standardised XML schemas derived from the model (SDMX-ML)
	50	* the use of web-services technology (XML, XSD, WSDL, WADL)
	51
	52	Such an architecture needs to be well organised, and the SDMX Registry/Repository (SDMX-RR) is tasked with providing structure, organisation, and maintenance and query interfaces for most of the SDMX components required to support the datasharing vision.
	53
	54	However, it is important to emphasis that the SDMX-RR provides support for the submission and retrieval of all SDMX structural metadata and provisioning metadata. Therefore, the Registry not only supports the data sharing scenario, but this metadata is also vital in order to provide support for data and metadata reporting/collection, and dissemination scenarios.
	55
	56	Standard formats for the exchange of aggregated statistical data and metadata as prescribed in SDMX v2.1 are envisaged to bring benefits to the statistical community because data reporting and dissemination processes can be made more efficient.
	57
	58	As organisations migrate to SDMX enabled systems, many XML (and conventional) artefacts will be produced (e.g. Data Structure, Metadata Structure, Code List and Concept definitions (often collectively called structural metadata), XML schemas generated from data and metadata structure definitions, XSLT style-sheets for transformation and display of data and metadata, terminology references, etc.). The SDMX model supports interoperability, and it is important to be able to discover and share these artefacts between parties in a controlled and organized way.
	59
	60	This is the role of the registry.
	61
	62	With the fundamental SDMX standards in place, a set of architectural standards are needed to address some of the processes involved in statistical data and metadata exchange, with an emphasis on maintenance, retrieval and sharing of the structural metadata. In addition, the architectural standards support the registration and discovery of data and referential metadata.
	63
	64	These architectural standards address the ‘how’ rather than the ‘what’, and are aimed at enabling existing SDMX standards to achieve their mission. The architectural standards address registry services which initially comprise:
	65
	66	* structural metadata repository
	67	* data and metadata registration
	68	* query
	69
	70	The registry services outlined in this specification are designed to help the SDMX community manage the proliferation of SDMX assets and to support data sharing for reporting and dissemination.
	71
	72	= 2 Scope and Normative Status =
	73
	74	The scope of this document is to specify the logical interfaces for the SDMX registry in terms of the functions required and the data that may be present in the function call, and the behaviour expected of the registry.
	75
	76	In this document, functions and behaviours of the Registry Interfaces are described in four ways:
	77
	78	* in text
	79	* with tables
	80	* with UML diagrams excerpted from the SDMX Information Model (SDMX-IM)
	81	* with UML diagrams that are not a part of the SDMX-IM but are included here for clarity and to aid implementations (these diagram are clearly marked as “Logical Class Diagram ...”)
	82
	83	Whilst the introductory section contains some information on the role of the registry, it is assumed that the reader is familiar with the uses of a registry in providing shared metadata across a community of counterparties.
	84
	85	Note that sections 5 and 6 contain normative rules regarding the Registry Interface and the identification of registry objects. Further, the minimum standard for access to the registry is via a REST interface (HTTP or HTTPS), as described in the appropriate sections. The notification mechanism must support e-mail and HTTP/HTTPS protocols as described. Normative registry interfaces are specified in the SDMX-ML specification (Part 03 of the SDMX Standard). All other sections of this document are informative.
	86
	87	Note that although the term “authorised user” is used in this document, the SDMX standards do not define an access control mechanism. Such a mechanism, if required, must be chosen and implemented by the registry software provider.
	88
	89	= 3 Scope of the SDMX Registry/Repository =
	90
	91	== 3.1 Objective ==
	92
	93	The objective of the SDMX registry/repository is, in broad terms, to allow organisations to publish statistical data and reference metadata in known formats such that interested third parties can discover these data and interpret them accurately and correctly. The mechanism for doing this is twofold:
	94
	95	1. To maintain and publish structural metadata that describes the structure and valid content of data and reference metadata sources such as databases, metadata repositories, data sets, metadata sets. This structural metadata enables software applications to understand and to interpret the data and reference metadata in these sources.
	96	1. To enable applications, organisations, and individuals to share and to discover data and reference metadata. This facilitates data and reference metadata dissemination by implementing the data sharing vision of SDMX.
	97
	98	== 3.2 Structural Metadata ==
	99
	100	Setting up structural metadata and the exchange context (referred to as “data provisioning”) involves the following steps for maintenance agencies:
	101
	102	* agreeing and creating a specification of the structure of the data (called a Data Structure Definition or DSD in this document but also known as “key family”) which defines the dimensions, measures and attributes of a dataset and their valid value set
	103	* if required, defining a subset or view of a DSD which allows some restriction of content called a “dataflow definition”
	104	* agreeing and creating a specification of the structure of reference metadata (Metadata Structure Definition) which defines the attributes and presentational arrangement of a Metadataset and their valid values and content
	105	* if required, defining a subset or view of a MSD which allows some restriction of content called a “metadataflow definition”
	106	* defining which subject matter domains (specified as a Category Scheme) are related to the Dataflow and Metadataflow Definitions to enable browsing
	107	* defining one or more lists of Data Providers (which includes metadata providers)
	108	* defining which Data Providers have agreed to publish a given Dataflow and/or Metadataflow Definition - this is called a Provision Agreement
	109
	110	[[image:1747824122996-812.jpeg]]
	111
	112	Figure 1: Schematic of the Basic Structural Artifacts in the SDMX-IM
	113
	114	== 3.3 Registration ==
	115
	116	Publishing the data and reference metadata involves the following steps for a Data Provider:
	117
	118	* making the reference metadata and data available in SDMX-ML conformant data files or databases (which respond to an SDMX-ML query with SDMX-ML data). The data and reference metadata files or databases must be webaccessible, and must conform to an agreed Dataflow or Metadataflow Definition (Data Structure Definition or Metadata Structure Definition subset)
	119	* registering the existence of published reference metadata and data files or databases with one or more SDMX registries
	120
	121	[[image:1747824123003-199.jpeg]]
	122
	123	Figure 2: Schematic of Registered Data and Metadata Sources in the SDMX-IM
	124
	125	== 3.4 Notification ==
	126
	127	Notifying interested parties of newly published or re-published data, reference metadata or changes in structural metadata involves:
	128
	129	* registry support of a subscription-based notification service which sends an email or notifies an HTTP address announcing all published data that meets the criteria contained in the subscription request
	130
	131	== 3.5 Discovery ==
	132
	133	Discovering published data and reference metadata involves interaction with the registry to fulfil the following logical steps that would be carried out by a user interacting with a service that itself interacts with the registry and an SDMX-enabled data or reference metadata resource:
	134
	135	* optionally browsing a subject matter domain category scheme to find Dataflow Definitions (and hence Data Structure Definitions) and Metadataflows which structure the type of data and/or reference metadata being sought
	136	* build a query, in terms of the selected Data Structure Definition or Metadata Structure Definition, which specifies what data are required and submitting this to a service that can query an SDMX registry which will return a list of (URLs of) data and reference metadata files and databases which satisfy the query
	137	* processing the query result set and retrieving data and/or reference metadata from the supplied URLs
	138
	139	[[image:1747824123006-476.jpeg]]
	140
	141	Figure 3: Schematic of Data and Metadata Discovery and Query in the SDMX-IM
	142
	143	= 4 SDMX Registry/Repository Architecture =
	144
	145	== 4.1 Architectural Schematic ==
	146
	147	The architecture of the SDMX registry/repository is derived from the objectives stated above. It is a layered architecture that is founded by a structural metadata repository which supports a provisioning metadata repository which supports the registry services. These are all supported by the SDMX-ML schemas. Applications can be built on top of these services which support the reporting, storage, retrieval, and dissemination aspects of the statistical lifecycle as well as the maintenance of the structural metadata required to drive these applications.
	148
	149	[[image:1747824123008-995.jpeg]]
	150
	151	Figure 4: Schematic of the Registry Content and Services
	152
	153	== 4.2 Structural Metadata Repository ==
	154
	155	The basic layer is that of a structural metadata service which supports the lifecycle of SDMX structural metadata artefacts such as Maintenance Agencies, Data Structure Definitions, Metadata Structure Definitions, Provision Agreements, Processes etc. This layer is supported by the Structure Submission and Query Service.
	156
	157	Note that the SDMX-ML Submit Structure Request message supports all of the SDMX structural artefacts. The only structural artefacts that are not supported by the SDMX-ML Submit Structure Request are::
	158
	159	* Registration of data and metadata sources
	160	* Subscription and Notification
	161
	162	Separate registry-based messages are defined to support these artefacts.
	163
	164	== 4.3 Provisioning Metadata Repository ==
	165
	166	The function of this repository is to support the definition of the structural metadata that describes the various types of data-store which model SDMX-conformant databases or files, and to link to these data sources. These links can be specified for a data provider, for a specific data or metadata flow. In the SDMX model this is called the Provision Agreement.
	167
	168	This layer is supported by the Data and Metadata Registration Service.
	169
	170	= 5 Registry Interfaces and Services =
	171
	172	== 5.1 Registry Interfaces ==
	173
	174	The Registry Interfaces are:
	175
	176	* Notify Registry Event
	177	* Submit Subscription Request
	178	* Submit Subscription Response
	179	* Submit Registration Request
	180	* Submit Registration Response
	181	* Query Registration Request
	182	* Query Registration Response
	183	* Query Subscription Request
	184	* Query Subscription Response
	185	* Submit Structure Request
	186	* Submit Structure Response
	187
	188	The registry interfaces are invoked in one of two ways:
	189
	190	1. The interface is the name of the root node of the SDMX-ML document
	191	1. The interface is invoked as a child element of the RegistryInterface message where the RegistryInterface is the root node of the SDMX-ML document.
	192
	193	In addition to these interfaces the registry must support a mechanism for querying for structural metadata. This is detailed in 5.2.2.
	194
1.2	195	All these interactions with the Registry – with the exception of Notify Registry Event – are designed in pairs. The first document – the one which invokes the SDMX-RR interface, is a “Request” document. The message returned by the interface is a “Response” document.
1.1	196
	197	It should be noted that all interactions are assumed to be synchronous, with the exception of Notify Registry Event. This document is sent by the SDMX-RR to all subscribers whenever an even occurs to which any users have subscribed. Thus, it does not conform to the request-response pattern, because it is inherently asynchronous.
	198
	199	== 5.2 Registry Services ==
	200
	201	=== 5.2.1 Introduction ===
	202
	203	The services described in this section do not imply that each is implemented as a discrete web service.
	204
	205	=== 5.2.2 Structure Submission and Query Service ===
	206
	207	This service must implement the following SDMX-ML Interfaces:
	208
	209	* SubmitStructureRequest
	210	* SubmitStructureResponse
	211
	212	These interfaces allow structural definitions to be created, modified, and removed in a controlled fashion. It also allows the structural metadata artefacts to be queried and retrieved either in part or as a whole. In order for the architecture to be scalable, the finest-grained piece of structural metadata that can be processed by the SDMX-RR is a MaintainableArtefact (see next section on the SDMX Information Model).
	213
	214	=== 5.2.3 Structure Query Service ===
	215
	216	The registry must support a mechanism for querying for structural metadata. This mechanism can be one or both of the SDMX-ML Query message and the SDMX REST interface for structural metadata (this is defined in Part 7 of the SDMX standards). The registry response to both of these query mechanisms is the SDMX Structure message which has as its root node
	217
	218	* Structure
	219
	220	The SDMX structural artefacts that may be queried are:
	221
	222	* dataflows and metadataflows
	223	* data structure definitions and metadata structure definitions
	224	* codelists
	225	* concept schemes
	226	* reporting taxonomies
	227	* provision agreements
	228	* structure sets
	229	* processes
	230	* hierarchical code lists
	231	* constraints
	232	* category schemes
	233	* categorisations and categorised objects (examples are categorised dataflows and metadatflows, data structure definitions, metadata structure definitions, provision agreements registered data sources and metadata sources)
	234	* organisation schemes (agency scheme, data provider scheme, data consumer scheme, organisation unit scheme)
	235
	236	Due to the VTL implementation the other structural artefact that may be queried are:
	237
	238	* transformation schemes
	239	* custom type schemes
	240	* name personalisation schemes
	241	* vtl mapping schemes
	242	* ruleset schemes
	243	* user defined operator schemes
	244
	245	The SDMX query messages that are a part of the SDMX-ML Query message are:
	246
	247	* StructuresQuery
	248	* DataflowQuery
	249	* MetadataflowQuery
	250	* DataStructureQuery
	251	* MetadataStructureQuery
	252	* CategorySchemeQuery
	253	* ConceptScheneQuery
	254	* CodelistQuery
	255	* HierarchicalCodelistQuery
	256	* OrganisationSchemeQuery
	257	* ReportingTaxonomyQuery
	258	* StructureSetQuery
	259	* ProcessQuery
	260	* CategorisationQuery
	261	* ProvisionAgreementQuery
	262	* ConstraintQuery
	263
	264	Due to the VTL implementation the other query messages that became a part of the SDMX-ML Query message are:
	265
	266	* TransformationSchemeQuery
	267	* CustomTypeSchemeQuery
	268	* VtlMappingSchemeQuery
	269	* NamePersonalisationSchemeQuery
	270	* RulesetSchemeQuery
	271	* UserDefinedOperatorSchemeQuery
	272
	273	=== 5.2.4 Data and Reference Metadata Registration Service ===
	274
	275	This service must implement the following SDMX-ML Interfaces:
	276
	277	* SubmitRegistrationRequest
	278	* SubmitRegistrationResponse
	279	* QueryRegistrationRequest
	280	* QueryRegistrationResponse
	281
	282	The Data and Metadata Registration Service allows SDMX conformant XML files and web-accessible databases containing published data and reference metadata to be registered in the SDMX Registry. The registration process MAY validate the content of the data-sets or metadata-sets, and MAY extract a concise representation of the contents in terms of concept values (e.g. values of the data attribute, dimension, metadata attribute), or entire keys, and storing this as a record in the registry to enable discovery of the original data-set or metadata-set. These are called Constraints in the SDMX-IM.
	283
	284	The Data and Metadata Registration Service MAY validate the following, subject to the access control mechanism implemented in the Registry:
	285
	286	* that the data provider is allowed to register the data-set or metadata-set
	287	* that the content of the data set or metadata set meets the validation constraints. This is dependent upon such constraints being defined in the structural repository and which reference the relevant Dataflow, Metadataflow, Data Provider, Data Structure Definition, Metadata Structure Definition, Provision Agreement
	288	* that a queryable data source exists - this would necessitate the registration service querying the service to determine its existence
	289	* that a simple data source exists (i.e. a file accessible at a URL)
	290	* that the correct Data Structure Definition or Metadata Structure Definition is used by the registered data that the components (Dimensions, Attributes, Measures, Identifier Components etc.) are consistent with the Data Structure Definition or Metadata Structure Definition
3.3	291	* that the valid representations of the concepts to which these components correspond conform to the definition in the Data Structure Definition or Metadata Structure Definition
1.1	292
	293	3The Registration has an action attribute which takes one of the following values:
	294
3.3	295	(% style="margin-left:auto; margin-right:auto" %)
	296	\|(% style="width:200px" %)(((
1.3	297	Action Attribute Value
3.3	298	)))\|(% style="width:1672px" %)Behaviour
	299	\|(% style="width:200px" %)Append\|(% style="width:1672px" %)Add this registration to the registry
	300	\|(% style="width:200px" %)Replace\|(% style="width:1672px" %)Replace the existing Registration with this Registration identified by the id in the Registration of the Submit Registration Request
	301	\|(% style="width:200px" %)Delete\|(% style="width:1672px" %)Delete the existing Registration identified by the id in the Registration of the Submit Registration Request
1.1	302	The Registration has three Boolean attributes which may be present to determine how an SDMX compliant Dataset or Metadata Set indexing application must index the Datasets or Metadata Set upon registration. The indexing application behaviour is as follows:
3.3	303	\|(% style="width:200px" %)Boolean Attribute\|(% style="width:1672px" %)Behaviour if Value is “true”
	304	\|(% style="width:200px" %)indexTimeSeries\|(% style="width:1672px" %)A compliant indexing application must index all the time series keys (for a Dataset registration) or metadata target values (for a Metadata Set registration)
	305	\|(% style="width:200px" %)indexDataSet\|(% style="width:1672px" %)(((
1.1	306	A compliant indexing application must index the range of actual (present) values for each dimension of the Dataset (for a Dataset registration) or the range of actual (present) values for each Metadata Attribute which takes an enumerated value.
	307	Note that for data this requires much less storage than full key indexing, but this method cannot guarantee that a specific combination of Dimension values (the Key) is actually present in the Dataset
	308	)))
3.3	309	\|(% style="width:200px" %)indexReportingPeriod\|(% style="width:1672px" %)A compliant indexing application must index the time period range(s) for which data are present in the Dataset or Metadata Set
1.1	310
	311	=== 5.2.5 Data and Reference Metadata Discovery ===
	312
	313	The Data and Metadata Discovery Service implements the following Registry Interfaces:
	314
1.3	315	* QueryRegistrationRequest
	316	* QueryRegistrationResponse
1.1	317
	318	=== 5.2.6 Subscription and Notification ===
	319
	320	The Subscription and Notification Service implements the following Registry Interfaces:
	321
	322	* SubmitSubscriptionRequest
	323	* SubmitSubscriptionResponse
	324	* NotifyRegistryEvent
	325
	326	The data sharing paradigm relies upon the consumers of data and metadata being able to pull information from data providers’ dissemination systems. For this to work efficiently, a data consumer needs to know when to pull data, i.e. when something has changed in the registry (e.g. a dataset has been updated and re-registered). Additionally, SDMX systems may also want to know if a new Data Structure Definition, Code List or Metadata Structure Definition has been added. The Subscription and Notification Service comprises two parts: subscription management, and notification.
	327
	328	Subscription management involves a user submitting a subscription request which contains:
	329
	330	* a query or constraint expression in terms of a filter which defines the events for which the user is interested (e.g. new data for a specific dataflow, or for a domain category, or changes to a Data Structure Definition).
	331	* a list of URIs or end-points to which an XML notification message can be sent. Supported end-point types will be email (mailto~:) and HTTP POST (a normal http:~/~/ address)
	332	* request for a list of submitted subscriptions
	333	* deletion of a subscription
	334
	335	Notification requires that the structural metadata repository and the provisioning metadata repository monitor any event which is of interest to a user (the object of a subscription request query), and to issue an SDMX-ML notification document to the end-points specified in the relevant subscriptions.
	336
	337	=== 5.2.7 Registry Behaviour ===
	338
	339	The following table defines the behaviour of the SDMX Registry for the various Registry Interface messages.
	340
3.3	341	\|(% style="width:227px" %)Interface\|(% style="width:1644px" %)Behaviour
	342	\|(% style="width:227px" %)All\|(% style="width:1644px" %)(((
1.1	343	1) If the action is set to “replace” then the entire contents of the existing maintainable object in the Registry MUST be replaced by the object submitted, unless the final attribute is set to “true” in which case the only changes that are allowed are to the following constructs:
	344
	345	* Name – this applies to the Maintainable object and its contained elements, such a Code in a Code list.
	346	* Description - this applies to the Maintainable object and its contained elements, such a Code in a Code list.
	347	* Annotation - this applies to the Maintainable object and its contained elements, such a Code in a Code list.
	348	* validTo
	349	* validFrom
	350	* structureURL
	351	* serviceURL
	352	* uri
	353	* isExternalReference
	354
1.4	355	2) Cross referenced structures MUST exist in either the submitted document (in Structures or Structure Location) or in the registry to which the request is submitted.
	356	3) If the action is set to “delete” then the Registry MUST verify that the object can deleted. In order to qualify for deletion the object must:
1.1	357
1.4	358	а) Not have the final attribute set to “true”
	359	b) Not be referenced from any other object in the Registry.
1.1	360
1.4	361	4) The version rules in the SDMX Schema documentation MUST be obeyed.
	362	5) The specific rules for the elements and attributes documented in the SDMX Schema MUST be obeyed.
1.1	363	)))
3.3	364	\|(% style="width:227px" %)SubmitStructureRequest\|(% style="width:1644px" %)Structures are submitted at the level of the Maintainable Artefact and the behaviour in “All” above is therefore at the level of the Maintainable Artefact.
	365	\|(% style="width:227px" %)SubmitProvisioningRequest\|(% style="width:1644px" %)No additional behaviour.
	366	\|(% style="width:227px" %)Submit Registration Request\|(% style="width:1644px" %)(((
1.1	367	If the datasource is a file (simple datasource) then the file MAY be retrieved and indexed according to the Boolean attributes set in the Registration.
	368	For a queryable datasource the Registry MAY validate that the source exists and can accept an SDMX-ML data query.
	369	)))
	370
	371	= 6 Identification of SDMX Objects =
	372
	373	== 6.1 Identification, Versioning, and Maintenance ==
	374
	375	All major classes of the SDMX Information model inherit from one of:
	376
	377	* IdentifiableArtefact - this gives an object the ability to be uniquely identified (see following section on identification), to have a user-defined URI, and to have multi-lingual annotations.
	378	* NamableArtefact - this has all of the features of IdentifiableArtefact plus the ability to have a multi-lingual name and description,
	379	* VersionableArtefact – this has all of the above features plus a version number and a validity period.
	380	* MaintainableArtefact – this has all of the above features, and indication as to whether the object is “final” and cannot be changed or deleted, registry and structure URIs, plus an association to the maintenance agency of the object.
	381
	382	=== 6.1.1 Identification, Naming, Versioning, and Maintenance Model ===
	383
1.6	384	[[image:1747824504225-229.png]]
	385
1.1	386	Figure 5: Class diagram of fundamental artefacts in the SDMX-IM
	387
	388	The table below shows the identification and related data attributes to be stored in a registry for objects that are one of:
	389
	390	* Annotable
	391	* Identifiable
	392	* Nameable
	393	* Versionable
	394	* Maintainable
	395
1.6	396	(% style="width:935.294px" %)
	397	\|Object Type\|(% style="width:244px" %)Data Attributes\|(% style="width:99px" %)Status\|Data type\|(% style="width:389px" %)Notes
	398	\|Annotable\|(% style="width:244px" %)AnnotationTitle\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)
	399	\| \|(% style="width:244px" %)AnnotationType\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)
	400	\| \|(% style="width:244px" %)AnnotationURN\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)
	401	\| \|(% style="width:244px" %)(((
	402	AnnotationText in the form of International String
	403	)))\|(% style="width:99px" %)C\| \|(% style="width:389px" %)This can have languagespecific variants.
	404	\|Identifiable\|(% style="width:244px" %)all content as for Annotable plus\|(% style="width:99px" %) \| \|(% style="width:389px" %)
	405	\| \|(% style="width:244px" %)id\|(% style="width:99px" %)M\|string\|(% style="width:389px" %)
	406	\| \|(% style="width:244px" %)uri\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)
	407	\| \|(% style="width:244px" %)urn\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)Although the urn is computable and therefore may not be submitted or stored physically, the Registry must return the urn for each object, and must be able to service a query on an object referenced solely by its urn.
	408	\|Nameable\|(% style="width:244px" %)all content as for Identifiable plus\|(% style="width:99px" %) \| \|(% style="width:389px" %)
	409	\| \|(% style="width:244px" %)Name in the form of International String\|(% style="width:99px" %)M\|string\|(% style="width:389px" %)This can have languagespecific variants.
	410	\| \|(% style="width:244px" %)(((
	411	Description in the form of International String
	412	)))\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)This can have languagespecific variants.
	413	\|Versionable\|(% style="width:244px" %)All content as for Identifiable plus\|(% style="width:99px" %) \| \|(% style="width:389px" %)
	414	\| \|(% style="width:244px" %)version\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)This is the version number. If not present the default is 1.0
	415	\| \|(% style="width:244px" %)validFrom\|(% style="width:99px" %)C\|Date/time\|(% style="width:389px" %)
	416	\| \|(% style="width:244px" %)validTo\|(% style="width:99px" %)C\|Date/time\|(% style="width:389px" %)
	417	\|Maintainable\|(% style="width:244px" %)All content as for Versionable plus\|(% style="width:99px" %) \| \|(% style="width:389px" %)
	418	\| \|(% style="width:244px" %)final\|(% style="width:99px" %) \|boolean\|(% style="width:389px" %)Value of “true” indicates that this is a final specification and it cannot be changed except as a new version. Note that providing a “final’ object is not referenced from another object then it may be deleted.
	419	\| \|(% style="width:244px" %)isExternalReference\|(% style="width:99px" %)C\|boolean\|(% style="width:389px" %)Value of “true” indicates that the actual resource is held outside of this registry. The actual reference is given in the registry URI or the structureURI, each of which must return a valid SDMX-ML file.
	420	\| \|(% style="width:244px" %)serviceURL\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)The url of the service that can be queried for this resource
	421	\| \|(% style="width:244px" %)structureURL\|(% style="width:99px" %)C\|string\|(% style="width:389px" %)The url of the resource.
	422	\| \|(% style="width:244px" %)(Maintenance) agencyId\|(% style="width:99px" %)M\|string\|(% style="width:389px" %)The object must be linked to a maintenance agency.
1.1	423
	424	Table 1: Common Attributes of Object Types
	425
	426	== 6.2 Unique identification of SDMX objects ==
	427
	428	=== 6.2.1 Agencies ===
	429
	430	The Maintenance Agency in SDMX is maintained in an Agency Scheme which itself is a sub class of Organisation Scheme – this is shown in the class diagram below.
	431
	432	Figure 6: Agency Scheme Model
	433
	434	The Agency in SDMX is extremely important. The Agency Id system used in SDMX is an n-level structure. The top level of this structure is maintained by SDMX. Any Agency in this top level can declare sub agencies and any sub agency can also declare sub agencies. The Agency Scheme has a fixed id and version and is never declared explicitly in the SDMX object identification mechanism.
	435
	436	In order to achieve this SDMX adopts the following rules:
	437
	438	1. Agencies are maintained in an Agency Scheme (which is a sub class of Organisation Scheme)
	439	1. The agency of the Agency Scheme must also be declared in a (different) Agency Scheme.
	440	1. The “top-level” agency is SDMX and maintains the “top-level” Agency Scheme.
	441	1. Agencies registered in the top-level scheme can themselves maintain a single Agency Scheme. Agencies in these second-tier schemes can themselves maintain a single Agency Scheme and so on.
	442	1. The AgencyScheme cannot be versioned and so take a default version number of 1.0 and cannot be made “final”.
	443	1. There can be only one AgencyScheme maintained by any one Agency. It has a fixed Id of AGENCIES.
	444	1. The /hierarchy of Organisation is not inherited by Maintenance Agency – thus each Agency Scheme is a flat list of Maintenance Agencies.
	445	1. The format of the agency identifier is agencyID.agencyID etc. The toplevel agency in this identification mechanism is the agency registered in the SDMX agency scheme. In other words, SDMX is not a part of the hierarchical ID structure for agencies. However SDMX is, itself, a maintenance agency and is contained in the top-level Agency Scheme.
	446
	447	This supports a hierarchical structure of agencyID.
	448
	449	An example is shown below.
	450
	451	[[image:1747824123012-527.jpeg]]
	452
	453	==== Figure 7: Example of Hierarchic Structure of Agencies ====
	454
	455	The following organizations maintain an Agency Scheme.
	456
	457	* SDMX – contains Agencies AA, BB
	458	* AA – contains Agencies CC, DD
	459	* BB – contains Agencies CC, DD
	460	* DD – Contains Agency EE
	461
	462	Each agency is identified by its full hierarchy excluding SDMX.
	463
	464	e.g. the id of EE as an agencyID is AA.DD.EE
	465
	466	An example of this is shown in the XML snippet below.
	467
2.1	468	[[image:1747824123013-196.jpeg\|\|height="309" width="446"]]
1.1	469
2.1	470	(% class="wikigeneratedid" id="HFigure8:ExampleShowingUseofAgencyIdentifiers" %)
	471	Figure 8: Example Showing Use of Agency Identifiers
1.1	472
	473	Each of these maintenance agencies has an identical Code list with the Id CL_BOP. However, each is uniquely identified by means of the hierarchic agency structure.
	474
	475	=== 6.2.2 Universal Resource Name (URN) ===
	476
	477	==== 6.2.2.1 Introduction ====
	478
	479	To provide interoperability between SDMX Registry/Repositories in a distributed network environment, it is important to have a scheme for uniquely identifying (and thus accessing) all first-class (Identifiable) SDMX-IM objects. Most of these unique identifiers are composite (containing maintenance agency, or parent object identifiers), and there is a need to be able to construct a unique reference as a single string. This is achieved by having a globally unique identifier called a universal resource name (URN) which is generated from the actual identification components in the SDMX-RR APIs. In other words, the URN for any Identifiable Artefact is constructed from its component identifiers (agency, Id, version etc.).
	480
	481	==== 6.2.2.2 URN Structure ====
	482
	483	===== //Case Rules for URN// =====
	484
	485	For the URN, all parts of the string are case sensitive. The Id of any object must be UPPER CASE. Therefore, CRED_ext_Debt is invalid and it should be CRED_EXT_DEBT.
	486
	487	The generic structure of the URN is as follows:
	488
3.3	489	>SDMXprefix.SDMX-IM-package-name.class-name=agencyid:maintainedobject-id(maintainedobject-version).*containerobject-id.object-id
1.1	490
	491	~* this can repeat and may not be present (see explanation below)
	492
	493	Note that in the SDMX Information Model there are no concrete Versionable Artefacts that are not a Maintainable Artefact. For this reason the only version information that is allowed is for the maintainable object.
	494
	495	The Maintenance agency identifier is separated from the maintainable artefact identifier by a colon ‘:’. All other identifiers in the SDMX URN syntax are separated by a period(.).
	496
	497	==== 6.2.2.3 Explanation of the generic structure ====
	498
	499	In the explanation below the actual object that is the target of the URN is called the //actual object//.
	500
3.2	501	SDMXPrefix: urn:sdmx:org.
1.1	502
	503	SDMX-IM package name: sdmx.infomodel.package=
	504
	505	[[image:1747824123016-678.png]]
	506
	507	maintainable-object-id is the identifier of the maintainable object. This will always be present as all identifiable objects are either a maintainable object or contained in a maintainable object.
	508
	509	(maintainable-object-version) is the version of the maintainable object and is enclosed in round brackets (). It will always be present.
	510
2.2	511	container-object-id is the identifier of an intermediary object that contains the actual object which the URN is identifying. It is not mandatory as many actual objects do not have an intermediary container object. For instance, a Code is in a maintained object (Code List) and has no intermediary container object, whereas a Metadata Attribute has an intermediary container object (Report Structure) and may have an intermediary container object which is its parent Metadata Attribute. For this reason the container object id may repeat, with each repetition identifying the object at the next-lower level in its hierarchy. Note that if there is only a single containing object in the model then it is NOT included in the URN structure. This applies to Attribute Descriptor, Dimension Descriptor, and Measure Descriptor where there can be only one such object and this object has a fixed id. Therefore, whilst each of these has a URN, the id of the Attribute Descriptor, Dimension Descriptor, and Measure Descriptor is not included when the actual object is a Data Attribute or a Dimension/Measure Dimension/ Time Dimension, or a Measure.
1.1	512
	513	Note that although a Code can have a parent Code and a Concept can have a parent Concept these are maintained in a flat structure and therefore do not have a container-object-id.
	514
	515	For example the sequence is agency:DSDid(version).DimensionId and not agency:DSDid(version).DimensionDescriptorId.DimensionId.
	516
	517	object-id is the identifier of the actual object unless the actual object is a maintainable object. If present it is always the last id and is not followed by any other character.
	518
2.2	519	===== __//Generic Examples of the URN Structure//__ =====
1.1	520
2.2	521	__Actual object is a maintainable__
1.1	522
2.5	523	> SDMXPrefix.SDMX-IM package name.classname=agency id:maintained-object-id(version)
1.1	524
2.2	525	__Actual object is contained in a maintained object with no intermediate containing object__
1.1	526
2.5	527	> SDMXPrefix.SDMX-IM package name.classname=agency id:maintained-object-id(version).object-id
1.1	528
2.2	529	__Actual object is contained in a maintained object with an intermediate containing object__
1.1	530
2.5	531	> SDMXPrefix.SDMX-IM package name.classname=agency
1.1	532
	533	id:maintained-object-id(version).contained-object-id.object-id
	534
2.2	535	__Actual object is contained in a maintained object with no intermediate containing object but the object type itself is hierarchical__
1.1	536
	537	In this case the object id may not be unique in itself but only within the context of the hierarchy. In the general syntax of the URN all intermediary objects in the structure (with the exception, of course, of the maintained object) are shown as a contained object. An example here would be a Category in a Category Scheme. The Category is hierarchical and all intermediate Categories are shown as a contained object. The example below shows the generic structure for Category Scheme/Category/Category
	538
2.5	539	> SDMXPrefix.SDMX-IM package name.classname=agency id:maintained-object-id(version).contained-object-id.object-id
1.1	540
2.3	541	__Actual object is contained in a maintained object with an intermediate containing object and the object type itself is hierarchical__
1.1	542
	543	In this case the generic syntax is the same as for the example above as the parent object is regarded as a containing object, even if it is of the same type. An example here is a Metadata Attribute where the contained objects are Report Structure (first contained object id) and Metadata Attribute (subsequent contained object Ids). The example below shows the generic structure for MSD/Report Structure/Metadata Attribute/Metadata Attribute
	544
2.5	545	> SDMXPrefix.SDMX-IM package name.classname=agency id:maintained-object-id(version).contained-object-id. contained-object-id contained-object-id.object-id
1.1	546
2.4	547	===== __//Concrete Examples of the URN Structure//__ =====
1.1	548
	549	The Data Structure Definition CRED_EXT_DEBT version 1.0 maintained by the top level Agency TFFS would have the URN:
	550
2.5	551	> urn:sdmx:org.sdmx.infomodel.datastructure.DataStucture=TFFS:CRED_EXT_ DEBT(1.0)
1.1	552
	553	The URN for a code for Argentina maintained by ISO in the code list CL_3166A2 version 1.0 would be:
	554
2.5	555	> urn:sdmx:org.sdmx.infomodel.codelist.Code=ISO:CL_3166A2(1.0).AR
1.1	556
	557	The URN for a category (id of 1) which has parent category (id of 2) maintained by SDMX in the category scheme SUBJECT_MATTER_DOMAINS version 1.0 would be:
	558
2.5	559	> urn:sdmx:org.sdmx.infomodel.categoryscheme.Category=SDMX:SUBJE CT_MATTER_DOMAINS(1.0).1.2
1.1	560
	561	The URN for a Metadata Attribute maintained by SDMX in the MSD CONTACT_METADATA version 1.0 in the Report Structure CONTACT_REPORT where the hierarchy of the Metadata Attribute is
	562
	563	CONTACT_DETAILS/CONTACT_NAME would be:
	564
2.5	565	> urn:sdmx:org.sdmx.infomodel.metadatastructure.MetadataAttribut e=SDMX:CONTACT_METADATA(1.0).CONTACT_REPORT.CONTACT_DETAILS.CO NTACT_NAME
1.1	566
	567	The TFFS defines ABC as a sub Agency of TFFS then the URN of a Dataflow maintained by ABC and identified as EXTERNAL_DEBT version 1.0 would be:
	568
2.5	569	> urn:sdmx:org.sdmx.infomodel.datastructure.Dataflow=TFFS.ABC:EX
1.1	570
	571	TERNAL_DEBT(1.0)
	572
	573	The SDMX-RR MUST support this globally unique identification scheme. The SDMXRR MUST be able to create the URN from the individual identification attributes submitted and to transform the URN to these identification attributes. The identification attributes are:
	574
	575	* Identifiable and Nameable Artefacts: id (in some cases this id may be hierarchic)
	576	* Maintainable Artefacts: id, version, agencyId,
	577
	578	The SDMX-RR MUST be able to resolve the unique identifier of an SDMX artefact and to produce an SDMX-ML rendering of that artefact if it is located in the Registry.
	579
	580	=== 6.2.3 Table of SDMX-IM Packages and Classes ===
	581
	582	The table below lists all of the packages in the SDMX-IM together with the concrete classes that are in these packages and whose objects have a URN.
	583
2.6	584	\|(% style="width:127px" %)Package\|(% style="width:1745px" %)(((
	585	URN Classname (model classname where this is different)
1.1	586	)))
2.6	587	\|(% style="width:127px" %)base\|(% style="width:45px" %)Agency
	588	\|(% style="width:127px" %) \|(% style="width:45px" %)OrganisationUnitScheme
	589	\|(% style="width:127px" %) \|(% style="width:45px" %)AgencyScheme
	590	\|(% style="width:127px" %) \|(% style="width:45px" %)DataProviderScheme
	591	\|(% style="width:127px" %) \|(% style="width:45px" %)DataConsumerScheme
	592	\|(% style="width:127px" %) \|(% style="width:45px" %)OrganisationUnit
	593	\|(% style="width:127px" %) \|(% style="width:45px" %)DataProvider
	594	\|(% style="width:127px" %) \|(% style="width:45px" %)DataConsumer
	595	\|(% style="width:127px" %)datastructure\|(% style="width:45px" %)DataStructure (DataStructureDefinition)
	596	\|(% style="width:127px" %) \|(% style="width:45px" %)AttributeDescriptor
	597	\|(% style="width:127px" %) \|(% style="width:45px" %)DataAttribute
	598	\|(% style="width:127px" %) \|(% style="width:45px" %)GroupDimensionDescriptor
	599	\|(% style="width:127px" %) \|(% style="width:45px" %)DimensionDescriptor
	600	\|(% style="width:127px" %) \|(% style="width:45px" %)Dimension
	601	\|(% style="width:127px" %) \|(% style="width:45px" %)MeasureDimension
	602	\|(% style="width:127px" %) \|(% style="width:45px" %)TimeDimension
	603	\|(% style="width:127px" %) \|(% style="width:45px" %)MeasureDescriptor
	604	\|(% style="width:127px" %) \|(% style="width:45px" %)PrimaryMeasure
	605	\|(% style="width:127px" %) \|(% style="width:45px" %)Dataflow (DataflowDefinition)
	606	\|(% style="width:127px" %)metadatastructure\|(% style="width:45px" %)MetadataTarget
	607	\|(% style="width:127px" %) \|(% style="width:45px" %)DimensionDescriptorValueTarget
	608	\|(% style="width:127px" %) \|(% style="width:45px" %)IdentifiableObjectTarget
	609	\|(% style="width:127px" %) \|(% style="width:45px" %)ReportPeriodTarget
	610	\|(% style="width:127px" %) \|(% style="width:45px" %)DataSetTarget
	611	\|(% style="width:127px" %) \|(% style="width:45px" %)ReportStructure
	612	\|(% style="width:127px" %) \|(% style="width:45px" %)MetadataAttribute
	613	\|(% style="width:127px" %) \|(% style="width:45px" %)(((
1.1	614	MetadataStructure
	615
	616	(MetadataStructureDefinition)
	617	)))
2.6	618	\|(% style="width:127px" %) \|(% style="width:45px" %)Metadataflow (MetadataflowDefinition)
	619	\|(% style="width:127px" %)process\|(% style="width:45px" %)Process
	620	\|(% style="width:127px" %) \|(% style="width:45px" %)ProcessStep
	621	\|(% style="width:127px" %) \|(% style="width:45px" %)Transition
	622	\|(% style="width:127px" %)registry\|(% style="width:45px" %)ProvisionAgreement
	623	\|(% style="width:127px" %) \|(% style="width:45px" %)AttachmentConstraint
	624	\|(% style="width:127px" %) \|(% style="width:45px" %)ContentConstraint
	625	\|(% style="width:127px" %) \|(% style="width:45px" %)Subscription
	626	\|(% style="width:127px" %)mapping\|(% style="width:45px" %)StructureMap
	627	\|(% style="width:127px" %) \|(% style="width:45px" %)StructureSet
	628	\|(% style="width:127px" %) \|(% style="width:45px" %)ComponentMap
	629	\|(% style="width:127px" %) \|(% style="width:1745px" %)ConceptSchemeMap
	630	\|(% style="width:127px" %) \|(% style="width:1745px" %)OrganisationSchemeMap
	631	\|(% style="width:127px" %) \|(% style="width:1745px" %)CodelistMap
	632	\|(% style="width:127px" %) \|(% style="width:1745px" %)CategorySchemeMap
	633	\|(% style="width:127px" %) \|(% style="width:1745px" %)ReportingTaxonomyMap
	634	\|(% style="width:127px" %) \|(% style="width:1745px" %)ConceptMap
	635	\|(% style="width:127px" %) \|(% style="width:1745px" %)OrganisationMap
	636	\|(% style="width:127px" %) \|(% style="width:1745px" %)CodeMap
	637	\|(% style="width:127px" %) \|(% style="width:1745px" %)HybridCodelistMap
	638	\|(% style="width:127px" %) \|(% style="width:1745px" %)CategoryMap
	639	\|(% style="width:127px" %) \|(% style="width:1745px" %)HybridCodeMap
	640	\|(% style="width:127px" %) \|(% style="width:1745px" %)ReportingCategoryMap
	641	\|(% style="width:127px" %)codelist\|(% style="width:1745px" %)Codelist
	642	\|(% style="width:127px" %) \|(% style="width:1745px" %)HierarchicalCodelist
	643	\|(% style="width:127px" %) \|(% style="width:1745px" %)Hierarchy
	644	\|(% style="width:127px" %) \|(% style="width:1745px" %)Hierarchy
	645	\|(% style="width:127px" %) \|(% style="width:1745px" %)Code
	646	\|(% style="width:127px" %) \|(% style="width:1745px" %)HierarchicalCode
	647	\|(% style="width:127px" %) \|(% style="width:1745px" %)Level
	648	\|(% style="width:127px" %)categoryscheme\|(% style="width:1745px" %)CategoryScheme
	649	\|(% style="width:127px" %) \|(% style="width:1745px" %)Category
	650	\|(% style="width:127px" %) \|(% style="width:1745px" %)Categorisation
	651	\|(% style="width:127px" %) \|(% style="width:1745px" %)ReportingTaxonomy
	652	\|(% style="width:127px" %) \|(% style="width:1745px" %)ReportingCategory
	653	\|(% style="width:127px" %)conceptscheme\|(% style="width:1745px" %)ConceptScheme
	654	\|(% style="width:127px" %) \|(% style="width:1745px" %)Concept
	655	\|(% style="width:127px" %)transformation\|(% style="width:1745px" %)TransformationScheme
	656	\|(% style="width:127px" %) \|(% style="width:1745px" %)Transformation
	657	\|(% style="width:127px" %) \|(% style="width:1745px" %)CustomTypeScheme
	658	\|(% style="width:127px" %) \|(% style="width:1745px" %)CustomType
	659	\|(% style="width:127px" %) \|(% style="width:1745px" %)NamePersonalisationScheme
	660	\|(% style="width:127px" %) \|(% style="width:1745px" %)NamePersonalisation
	661	\|(% style="width:127px" %) \|(% style="width:1745px" %)VtlCodelistMapping
	662	\|(% style="width:127px" %) \|(% style="width:1745px" %)VtlConceptMapping
	663	\|(% style="width:127px" %) \|(% style="width:1745px" %)VtlDataflowMapping
	664	\|(% style="width:127px" %) \|(% style="width:1745px" %)VtlConceptSchemeMapping
	665	\|(% style="width:127px" %) \|(% style="width:1745px" %)RulesetScheme
	666	\|(% style="width:127px" %) \|(% style="width:1745px" %)Ruleset
	667	\|(% style="width:127px" %) \|(% style="width:1745px" %)UserDefinedOperatorScheme
	668	\|(% style="width:127px" %) \|(% style="width:1745px" %)UserDefinedOperator
1.1	669
	670	Table 2: SDMX-IM Packages and Contained Classes
	671
	672	=== 6.2.4 URN Identification components of SDMX objects ===
	673
	674	The table below describes the identification components for all SDMX object types that have identification. Note the actual attributes are all Id, but have been prefixed by their class name or multiple class names to show navigation, e.g. conceptSchemeAgencyId is really the Id attribute of the Agency class that is associated to the ConceptScheme.
	675
	676	~* indicates that the object is maintainable.
	677
	678	Note that for brevity the URN examples omit the prefix. All URNs have the prefix
	679
2.7	680	> urn:sdmx.org.sdmx.infomodel.{package}.{classname}=
1.1	681
2.10	682	(% style="width:1091.29px" %)
	683	\|(% style="width:250px" %)SDMX Class\|(% style="width:444px" %)Key attribute(s)\|(% style="width:396px" %)Example of URN
	684	\|(% style="width:250px" %)Agency\|(% style="width:444px" %)The URN for an Agency is shown later in this table. The identification of an Agency in the URN structure for the maintainable object is by means of the agencyId. The AgencyScheme is not identified as SDMX has a mechanism for identifying an Agency uniquely by its Id. Note that this Id may be hierarchical.\|(% style="width:396px" %)(((
1.1	685	IMF
2.9	686	Sub agency in the IMF AGENCIES
1.1	687	IMF.SubAgency1
	688	)))
2.10	689	\|(% style="width:250px" %)*ConceptScheme\|(% style="width:444px" %)conceptSchemeAgencyId:conceptSchemeId(ve rsion)\|(% style="width:396px" %)SDMX:CROSS_DOMAIN_CONCEPTS(1.0)
	690	\|(% style="width:250px" %)Concept\|(% style="width:444px" %)conceptSchemeAgencyId:
	691	conceptSchemeId(version).conceptId\|(% style="width:396px" %)SDMX:CROSS_DOMAIN_CONCEPTS(1.0).FREQ
	692	\|(% style="width:250px" %)*Codelist\|(% style="width:444px" %)codeListAgencyId:codeListId(version)\|(% style="width:396px" %)SDMX:CL_FREQ(1.0)
	693	\|(% style="width:250px" %)Code\|(% style="width:444px" %)codeListAgencyId:codelistId(version).codeId\|(% style="width:396px" %)SDMX:CL_FREQ(1.0).Q
	694	\|(% style="width:250px" %)(((
2.8	695	*Hierarchical Codelist
2.10	696	)))\|(% style="width:444px" %)hierachicalCodelistAgencyId: hierarchicalCodelistId(version)\|(% style="width:396px" %)(((
2.8	697	UNESCO:CL_EXP_SOURCE(1.0(% style="background-color:transparent" %))
1.1	698	)))
2.10	699	\|(% style="width:250px" %)Hierarchy\|(% style="width:444px" %)(((
1.1	700	hierachicalcodeListAgencyId:
	701	hierarchicalcodelistId(version).Hierarchy
2.10	702	)))\|(% style="width:396px" %)UNESCO:CL_EXP_SOURCE(1.0).
2.9	703	H-C-GOV
2.10	704	\|(% style="width:250px" %)Level\|(% style="width:444px" %)(((
1.1	705	hierachicalcodeListAgencyId:
	706	hierarchicalcodelistId(version).Hierarchy.Level
2.10	707	)))\|(% style="width:396px" %)(((
1.1	708	ESTAT:HCL_REGION(1.0).H_1.COUNTRY
	709
	710
	711	)))
2.10	712	\|(% style="width:250px" %)HierarchicalCode\|(% style="width:444px" %)hierachicalCodeListAgencyId: hierarchicalcodelistId(version).hierarchy.hierarc hicalCode\|(% style="width:396px" %)UNESCO:CL_EXP_SOURCE(1.0). H-C-GOV.GOV_CODE1
	713	\|(% style="width:250px" %)*DataStructure\|(% style="width:444px" %)dataStructureDefintitionAgencyId: dataStructureDefintitionId(version)\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0)
	714	\|(% style="width:250px" %)(((
1.1	715	Dimension
	716	Descriptor
	717	Measure
	718	Descriptor
	719	Attribute
	720	Descriptor
2.10	721	)))\|(% style="width:444px" %)(((
1.1	722	dataStructureDefinitionAgencyId: dataStructureDefinitionId(version).
	723	componentListId
	724	where the componentListId is the name of the class (there is only one occurrence of each in the Data Structure Definition)
2.10	725	)))\|(% style="width:396px" %)(((
1.1	726	TFFS:EXT_DEBT(1.0).DimensionDescriptor
	727
	728	TFFS:EXT_DEBT(1.0).MeasureDescriptor
	729
	730	TFFS:EXT_DEBT(1.0).AttributeDescriptor
	731	)))
2.10	732	\|(% style="width:250px" %)(((
1.1	733	GroupDimension
	734	Descriptor
2.10	735	)))\|(% style="width:444px" %)(((
1.1	736	dataStructureDefinitionAgencyId: dataStructureDefinitionId(version).
	737	groupDimensionDescriptorId
2.10	738	)))\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0).SIBLING
	739	\|(% style="width:250px" %)Dimension\|(% style="width:444px" %)(((
1.1	740	dataStructureDefinitionAgencyId: dataStructureDefinition (version).
	741	dimensionId
2.10	742	)))\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0).FREQ
	743	\|(% style="width:250px" %)TimeDimension\|(% style="width:444px" %)(((
1.1	744	dataStructureDefinitionAgencyId: dataStructureDefinition (version).
	745	timeDimensionId
2.10	746	)))\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0).TIME_PERIOD
	747	\|(% style="width:250px" %)Measure Dimension\|(% style="width:444px" %)dataStructureDefinitionAgencyId: dataStructureDefinition (version).
	748	measureDimensionId\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0).STOCK_FLOW
	749	\|(% style="width:250px" %)DataAttrribute\|(% style="width:444px" %)dataStructureDefinitionAgencyId: dataStructureDefinition (version). dataAttributeId\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0).OBS_STATUS
	750	\|(% style="width:250px" %)PrimaryMeasure\|(% style="width:444px" %)(((
1.1	751	dataStructureDefinitionAgencyId: dataStructureDefinition (version).
	752	primaryMeasureId
2.10	753	)))\|(% style="width:396px" %)TFFS:EXT_DEBT(1.0).OBS_VALUE
	754	\|(% style="width:250px" %)(((
2.9	755	*Category Scheme
2.10	756	)))\|(% style="width:444px" %)categorySchemeAgencyId:
	757	categorySchemeId(version)\|(% style="width:396px" %)IMF:SDDS(1.0)
	758	\|(% style="width:250px" %)Category\|(% style="width:444px" %)categorySchemeAgencyId:
2.9	759	categorySchemeId(version).
2.10	760	categoryId.categoryId categoryId.categoryId etc.\|(% style="width:396px" %)(((
1.1	761	IMF:SDDS(1.0):
	762	level_1_category.level_2_category …
	763	)))
2.10	764	\|(% style="width:250px" %)(((
2.9	765	*Reporting Taxonomy
2.10	766	)))\|(% style="width:444px" %)reportingTaxonomyAgencyId: reportingTaxonomyId(version)\|(% style="width:396px" %) IMF:REP_1(1.0)
	767	\|(% style="width:250px" %)ReportingCategory\|(% style="width:444px" %)reportingTaxonomyAgencyId: reportingTaxonomyId(version) reportingcategoryId.reportingcategoryId\|(% style="width:396px" %)(((
1.1	768	IMF:REP_1(1.0):
	769	level_1_repcategory.level_2_repcategory …
	770	)))
2.10	771	\|(% style="width:250px" %)*Categorisation\|(% style="width:444px" %)categorisationAgencyId: categorisationId(version)\|(% style="width:396px" %)IMF:cat001(1.0)
	772	\|(% style="width:250px" %)(((
2.9	773	*Organisation Unit Scheme
2.10	774	)))\|(% style="width:444px" %)organisationUnitSchemeAgencyId: organisationUnitSchemeId(version)\|(% style="width:396px" %)ECB:ORGANISATIONS(1.0)
	775	\|(% style="width:250px" %)Organisation Unit\|(% style="width:444px" %)organisationUnitSchemeAgencyId: organisationUnitSchemeId(version). organisationUnitId\|(% style="width:396px" %)ECB:ORGANISATIONS(1.0).1F
	776	\|(% style="width:250px" %)*AgencyScheme\|(% style="width:444px" %)agencySchemeAgencyId: agencySchemeId(version)\|(% style="width:396px" %)ECB:AGENCIES(1.0)
1.1	777
2.10	778	\|(% style="width:262px" %)Agency\|(% style="width:369px" %)agencySchemeAgencyId: agencySchemeId(version). agencyId\|(% style="width:1262px" %)ECB:AGENCY(1.0).AA
	779	\|(% style="width:262px" %)(((
	780	*DataProvider Scheme
	781	)))\|(% style="width:369px" %)dataProviderSchemeAgencyId: dataProviderSchemeId(version)\|(% style="width:1262px" %)SDMX:DATA_PROVIDERS(1.0)
	782	\|(% style="width:262px" %)DataProvider\|(% style="width:369px" %)dataProviderSchemeAgencyId: dataProviderSchemeId(version) dataProviderId\|(% style="width:1262px" %)SDMX:DATA_PROVIDERS(1.0).PROVIDER_1
	783	\|(% style="width:262px" %)(((
	784	*DataConsumer Scheme
	785	)))\|(% style="width:369px" %)dataConsumerSchemeAgencyId: dataConsumerSchemeId(version)\|(% style="width:1262px" %)SDMX:DATA_CONSUMERS(1.0)
	786	\|(% style="width:262px" %)Data Consumer\|(% style="width:369px" %)dataConsumerSchemeAgencyId: dataConsumerSchemeId(version) dataConsumerId\|(% style="width:1262px" %)SDMX:DATA_CONSUMERS(1.0).CONSUMER_1
	787	\|(% style="width:262px" %)(((
	788	*Metadata Structure
	789	)))\|(% style="width:369px" %)MSDAgencyId:MSDId(version)\|(% style="width:1262px" %)IMF:SDDS_MSD(1.0)
	790	\|(% style="width:262px" %)MetadataTarget\|(% style="width:369px" %)(((
1.1	791	MSDAgencyId:
	792	MSDId(version).metadataTargetId
2.10	793	)))\|(% style="width:1262px" %)IMF:SDDS_MSD(1.0).AGENCY
	794	\|(% style="width:262px" %)(((
1.1	795	Dimension
	796	DescriptorValues
	797	Target
2.10	798	)))\|(% style="width:369px" %)(((
1.1	799	MSDAgencyId: MSDId(version).
	800	metadataTargetId.keyDescriptorValueTargetId
2.10	801	)))\|(% style="width:1262px" %)IMF:SDDS_MSD(1.0).AGENCY.KEY
	802	\|(% style="width:262px" %)Identifiable Object Target\|(% style="width:369px" %)(((
	803	MSDAgencyId: MSDId(version).metadataTargetId.identifiableObjectTargetId
	804	)))\|(% style="width:1262px" %)IMF:SDDS_MSD(1.0).AGENCY.STR-OBJECT
	805	\|(% style="width:262px" %)DataSetTarget\|(% style="width:369px" %)(((
1.1	806	MSDAgencyId:
2.10	807	MSDId(version).metadataTargetId.dataSetTargetId
	808	)))\|(% style="width:1262px" %)IMF:SDDS_MSD(1.0).AGENCY.D1101
	809	\|(% style="width:262px" %)PeportPeriod Target\|(% style="width:369px" %)(((
	810	MSDAgencyId: MSDId(version).metadataTargetId.reportPeriodTargetId
	811	)))\|(% style="width:1262px" %)IMF:SDDS_MSD(1.0).AGENCY.REP_PER
1.1	812
2.10	813	\|(% style="width:251px" %)(((
1.1	814	ReportStructure
	815
	816
2.10	817	)))\|(% style="width:442px" %)(((
	818	MSDAgencyId: MSDId(version).reportStructureId
	819	)))\|(% style="width:1178px" %)IMF:SDDS_MSD(1.0).AGENCY_REPORT
	820	\|(% style="width:251px" %)(((
1.1	821	Metadata
	822
	823	Attribute
2.10	824	)))\|(% style="width:442px" %)(((
	825	MSDAgencyId: MSDId(version).reportStructureId.metadataattri buteID
	826	)))\|(% style="width:1178px" %)IMF:SDDS_MSD(1.0).AGENCY_REPORT.COMPILATION
	827	\|(% style="width:251px" %)*Dataflow\|(% style="width:442px" %)dataflowAgencyId: dataflowId(version)\|(% style="width:1178px" %)TFFS:CRED_EXT_DEBT(1.0)
	828	\|(% style="width:251px" %)*Provision Agreement\|(% style="width:442px" %)(((
1.1	829	provisionAgreementAgencyId:provisionAgreem entId(version)
2.10	830	)))\|(% style="width:1178px" %)(((
1.1	831	TFFS:CRED_EXT_DEBT_AB(1.0)
	832	)))
2.10	833	\|(% style="width:251px" %)(((
1.1	834	*Content
	835
	836	Constraint
2.10	837	)))\|(% style="width:442px" %)constraintAgencyId:ContentConstraintId(versio n)\|(% style="width:1178px" %)TFFS:CREDITOR_DATA_CONTENT(1.0)
	838	\|(% style="width:251px" %)(((
1.1	839	*Attachment
	840
	841	Constraint
2.10	842	)))\|(% style="width:442px" %)(((
1.1	843	constraintAgencyId:
	844
	845	attachmentConstraintId(version)
2.10	846	)))\|(% style="width:1178px" %)TFFS:CREDITOR_DATA_ATTACHMENT_CONSTRAINT_ONE(1.0)
	847	\|(% style="width:251px" %)*Metadataflow\|(% style="width:442px" %)metadataflowAgencyId: metadataflowId(version)\|(% style="width:1178px" %)IMF:SDDS_FLOW(1.0)
	848	\|(% style="width:251px" %)*StructureSet\|(% style="width:442px" %)structureSetAgencyId: structureSetId(version)\|(% style="width:1178px" %)SDMX:BOP_STRUCTURES(1.0)
	849	\|(% style="width:251px" %)StructureMap\|(% style="width:442px" %)structureSetAgencyId: structureSetId(version). structureMapId\|(% style="width:1178px" %)SDMX:BOP_STRUCTURES(1.0).TABLE1_TABLE2
	850	\|(% style="width:251px" %)Component Map\|(% style="width:442px" %)(((
1.1	851	structureSetAgencyId: structureSetId(version).
	852
	853	structureMapId. componentMapId
2.10	854	)))\|(% style="width:1178px" %)SDMX:BOP_STRUCTURES(1.0).TABLE1_TABLE2. REFAREA_REPCOUNTRY
	855	\|(% style="width:251px" %)CodelistMap\|(% style="width:442px" %)structureSetAgencyId: structureSetId(version). codelistMapId\|(% style="width:1178px" %)SDMX:BOP_STRUCTURES(1.0).CLREFAREA_CLREPCOUNTRY
	856	\|(% style="width:251px" %)CodeMap\|(% style="width:442px" %)structureSetAgencyId: structureSetId(version).\|(% style="width:1178px" %)SDMX:BOP_STRUCTURES(1.0).CLREFAREA_CLREPCOUNTRY. DE_GER
1.1	857
	858	\| \|(((
	859	codeListMapId.
	860
	861	codeMapId
	862	)))\|
	863	\|(((
	864	Category
	865
	866	SchemeMap
	867	)))\|structureSetAgencyId: structureSetId(version). categorySchemeMapId\|SDMX:BOP_STRUCTURES(1.0).SDMX_EUROSTAT
	868	\|CategoryMap\|structureSetAgencyId: structureSetId(version). categorySchemeMapId. categoryMapId\|SDMX:BOP_STRUCTURES(1.0).SDMX_EUROSTAT.TOURISM_M AP
	869	\|Organisation SchemeMap\|structureSetAgencyId: structureSetId(version). organisationSchemeMapId\|SDMX:BOP_STRUCTURES(1.0).DATA_PROVIDER_MAP
	870	\|Organisation Map\|structureSetAgencyId: structureSetId(version). organisationSchemeMapId. organisationMapId\|SDMX:BOP_STRUCTURES(1.0).DATA_PROVIDER_MAP.IMF_1C0
	871	\|(((
	872	Concept
	873
	874	SchemeMap
	875	)))\|structureSetAgencyId: structureSetId(version). conceptSchemeMapId\|SDMX:BOP_STRUCTURES(1.0).SDMX_OECD
	876	\|ConceptMap\|(((
	877	structureSetAgencyId: structureSetId(version). conceptSchemeMapId.
	878
	879	conceptMapId
	880
	881
	882	)))\|SDMX:BOP_STRUCTURES(1.0).SDMX_OECD.COVERAGE_AVAI LABILITY
	883	\|(((
	884	Reporting
	885
	886	TaxonomyMap
	887	)))\|structureSetAgencyId: structureSetId(version). reportingTaxonomyMapId\|SDMX:BOP_STRUCTURES(1.0).TAXMAP
	888	\|(((
	889	Reporting
	890
	891	CategoryMap
	892	)))\|(((
	893	structureSetAgencyId: structureSetId(version).
	894
	895	reportngCategoryId
	896	)))\|SDMX:BOP_STRUCTURES(1.0).TAXMAP.TOPCAT
	897
	898
	899
	900	\|(((
	901	HybridCodelist
	902
	903	Map
	904	)))\|structureSetAgencyId: structureSetId(version). hybridCodelistMapId.\|SDMX:BOP_STRUCTURES(1.0).COUNTRY_HIERARCHYMAP
	905	\|HybridCodeMap\|structureSetAgencyId: structureSetId(version). hybridCodelistMapId. hybridCodeMapId\|SDMX:BOP_STRUCTURES(1.0).COUNTRY_HIERARCHYMAP.CO DEMAP1
	906	\|*Process\|processAgencyId: processId{version]\|BIS:PROCESS1(1.0)
	907	\|ProcessStep\|(((
	908	processAgencyId: processId(version).
	909
	910	processStepId
	911	)))\|BIS:PROCESS1(1.0).STEP1
	912	\|Transition\|(((
	913	processAgencyId: processId(version).
	914
	915	processStepId transitionId
	916	)))\|BIS:PROCESS1(1.0).STEP1.TRANSITION1
	917	\|Subscription\|The Subscription is not itself an Identifiable Artefact and therefore it does not follow the rules for URN structure, The name of the URN is registryURN There is no pre-determined format.\|This cannot be generated by a common mechanism as subscriptions, although maintainable in the sense that they can be submitted and deleted, are not mandated to be created by a maintenance agency, and have no versioning mechanism. It is therefore the responsibility of the target registry to generate a unique Id for the Subscription, and for the application creating the subscription to store the registryURN that is returned from the registry in the subscription response message.
	918	\|(((
	919	*Transformation
	920
	921	Scheme
	922	)))\|transformationSchemeAgencyId transformationSchemeId(version)\|ECB: TRANSFORMATION_SCHEME(1.0)
	923	\|Transformation\|(((
	924	transformationSchemeAgencyId transformationSchemeId(version)
	925
	926	transformationId
	927	)))\|ECB:TRANSFORMATION_SCHEME(1.0).TRANS_1
	928	\|CustomType Scheme\|customTypeSchemeAgencyId customTypeSchemeId(version)\|ECB:CUSTOM_TYPE_SCHEME(1.0)
	929
	930
	931
	932	\|CustomType\|customTypeSchemeAgencyId customTypeSchemeId(version) customTypeId\|ECB: CUSTOM_TYPE_SCHEME(1.0).CUSTOM_TYPE_1
	933	\|(((
	934	Name
	935
	936	Personalisation
	937
	938	Scheme
	939	)))\|namePersonalisationSchemeAgencyId namePersonalisationSchemeId(version)\|ECB:PSN_SCHEME(1.0)
	940	\|(((
	941	Name
	942
	943	Personalisation
	944	)))\|namePersonalisationSchemeAgencyId namePersonalisationSchemeId(version) namePersonalisationId\|ECB:PSN_SCHEME(1.0).PSN1234
	945	\|VtlMapping Scheme\|vtlMappingSchemeAgencyId VtlMappingSchemeId(version)\|ECB:CLIST_MP(2.0)
	946	\|VtlCodelist Mapping\|vtlMappingSchemeAgencyId vtlMappingSchemeId(version) vtlCodelistMappingId\|ECB:CLIST_MP(2.0).ABZ
	947	\|VtlConcept Mapping\|vtlMappingSchemeAgencyId vtlMappingSchemeId(version) vtlConceptMappingId\|ECB:CLIST_MP(1.0).XYA
	948	\|VtlDataflow Mapping\|vtlMappingSchemeAgencyId vtlMappingSchemeId(version) vtlDataflowMappingId\|ECB:CLIST_MP(1.0).MOQ
	949	\|(((
	950	VtlConcept
	951
	952	SchemeMapping
	953	)))\|vtlMappingSchemeAgencyId vtlMappingSchemeId(version) vtlConceptSchemeId\|ECB:CLIST_MP(1.0).Z11
	954	\|RulesetScheme\|rulesetSchemeAgencyId rulesetSchemeId(version)\|ECB:RULESET_23(1.0)
	955	\|Ruleset\|rulesetSchemeAgencyId rulesetSchemeId(version) rulesetId\|ECB:RULESET_23(1.0).SET111
	956	\|(((
	957	UserDefined
	958
	959	OperatorScheme
	960	)))\|userDefinedOperatorSchemeAgencyId userDefinedOperatorSchemeId(version)\|ECB:OS_CALC(1.2)
	961	\|UserDefined Operator\|userDefinedOperatorSchemeAgencyId userDefinedOperatorSchemeId(version) usserDefinedOperatorId\|ECB:OS_CALC(1.2).OS267
	962
	963	7Table 3: Table of identification components for SDMX Identifiable Artefacts
	964
	965	= 7 Implementation Notes =
	966
	967	== 7.1 Structural Definition Metadata ==
	968
	969	=== 7.1.1 Introduction ===
	970
	971	The SDMX Registry must have the ability to support agencies in their role of defining and disseminating structural metadata artefacts. These artefacts include data structure definitions, code lists, concepts etc. and are fully defined in the SDMX-IM. An authenticated agency may submit valid structural metadata definitions which must be stored in the registry. Note that the term “structural metadata” refers as a general term to all structural components (Data structure Definitions, Metadata Structure Definitions, Code lists, Concept Schemes, etc.)
	972
	973	At a minimum, structural metadata definitions may be submitted to and queried from the registry via an HTTP/HTTPS POST in the form of one of the SDMX-ML registry messages for structural metadata and the SDMX Query message for structure queries. The use of SOAP is also recommended, as described in the SDMX Web Services Guidelines. The message may contain all structural metadata items for the whole registry, structural metadata items for one maintenance agency, or individual structural metadata items.
	974
	975	Structural metadata items
	976
	977	* may only be modified by the maintenance agency which created them
	978	* may only be deleted by the agency which created them
	979	* may not be deleted if they are referenced from other constructs in the Registry
	980
	981	The level of granularity for the maintenance of SDMX Structural Metadata objects in the registry is the Maintainable Artefact. In other words, any function such as add, modify, delete is at the level of the Maintainable Artefact. For instance, if a Code is added to a Code List, or the Name of a Code is changed, the Registry must replace the existing Code List with the submitted Code List of the same Maintenance Agency, Code List, Id and Version.
	982
	983	The following table lists the Maintainable Artefacts.
	984
2.10	985	(% style="width:640.294px" %)
	986	\|(% colspan="2" rowspan="1" style="width:186px" %)Maintainable Artefacts\|(% style="width:206px" %)Content
	987	\|(% style="width:171px" %)Abstract Class\|(% style="width:232px" %)Concrete Class\|(% style="width:206px" %)
	988	\|(% style="width:171px" %)Item Scheme\|(% style="width:232px" %)Codelist\|(% style="width:206px" %)Code
	989	\|(% style="width:171px" %) \|(% style="width:232px" %)Concept Scheme\|(% style="width:206px" %)Concept
	990	\|(% style="width:171px" %) \|(% style="width:232px" %)Category Scheme\|(% style="width:206px" %)Category
	991	\|(% style="width:171px" %) \|(% style="width:232px" %)Organisation Unit Scheme\|(% style="width:206px" %)Organisation Unit
	992	\|(% style="width:171px" %) \|(% style="width:232px" %)Agency Scheme\|(% style="width:206px" %)Agency
	993	\|(% style="width:171px" %) \|(% style="width:232px" %)Data Provider Scheme\|(% style="width:206px" %)Data Provider
	994	\|(% style="width:171px" %) \|(% style="width:232px" %)Data Consumer Scheme\|(% style="width:206px" %)Data Consumer
	995	\|(% style="width:171px" %) \|(% style="width:232px" %)Reporting Taxonomy\|(% style="width:206px" %)Reporting Category
	996	\|(% style="width:171px" %) \|(% style="width:232px" %)Transformation Scheme\|(% style="width:206px" %)Transformation
	997	\|(% style="width:171px" %) \|(% style="width:232px" %)Custom Type Scheme\|(% style="width:206px" %)Custom Type
	998	\|(% style="width:171px" %) \|(% style="width:232px" %)Name Personalisation Scheme\|(% style="width:206px" %)Name Personalisation
	999	\|(% style="width:171px" %) \|(% style="width:232px" %)Vtl Mapping Scheme\|(% style="width:206px" %)Vtl Codelist Mapping
	1000	\|(% style="width:171px" %) \|(% style="width:232px" %) \|(% style="width:206px" %)Vtl Dataflow Mapping
	1001	\|(% style="width:171px" %) \|(% style="width:232px" %) \|(% style="width:206px" %)Vtl Concept Scheme Mapping
	1002	\|(% style="width:171px" %) \|(% style="width:232px" %)Ruleset Scheme\|(% style="width:206px" %)Ruleset
	1003	\|(% style="width:171px" %) \|(% style="width:232px" %)User Defined Operator Scheme\|(% style="width:206px" %)User Defined Operator
	1004	\|(% style="width:171px" %) \|(% style="width:232px" %) \|(% style="width:206px" %)User Defined Operator
	1005	\|(% style="width:171px" %)Structure\|(% style="width:232px" %)Data Structure Definition\|(% style="width:206px" %)(((
1.1	1006	Dimension Descriptor
	1007	Group Dimension
	1008	Descriptor
	1009	Dimension
	1010	Measure Dimension
	1011	Time Dimension
	1012	Attribute Descriptor
	1013	Data Attribute
	1014	Measure Descriptor
	1015	Primary Measure
	1016	)))
2.10	1017	\|(% style="width:171px" %) \|(% style="width:232px" %)Metadata Structure Definition\|(% style="width:206px" %)(((
	1018	Metadata Target, Dimension Descriptor
1.1	1019	Values Target Identifiable
	1020	Object Target
	1021	Report Period Target
	1022	Data SetTarget
	1023	Report Structure
	1024	Metadata Attribute
	1025	)))
2.11	1026	\|(% style="width:171px" %)Structure Usage\|(% style="width:232px" %)Dataflow Definition\|(% style="width:206px" %)
	1027	\|(% style="width:171px" %) \|(% style="width:232px" %)Metadataflow Definition\|(% style="width:206px" %)
	1028	\|(% style="width:171px" %)None\|(% style="width:232px" %)Process\|(% style="width:206px" %)Process Step
	1029	\|(% style="width:171px" %)None\|(% style="width:232px" %)Structure Set\|(% style="width:206px" %)(((
1.1	1030	Component Map
	1031	Concept Scheme Map
	1032	Codelist Map
	1033	Category Scheme Map
	1034	Reporting Taxonomy Map
	1035	Organisation Scheme Map
	1036	Concept Map
	1037	Code Map
	1038	Category Map
	1039	Organisation Map
	1040	Reporting Category Map
	1041	Hybrid Codelist Map
	1042	Hybrid Code Map
	1043	)))
2.11	1044	\|(% style="width:171px" %)None\|(% style="width:232px" %)Provision Agreement\|(% style="width:206px" %)
	1045	\|(% style="width:171px" %)None\|(% style="width:232px" %)Hierarchical Codelist\|(% style="width:206px" %)(((
1.1	1046	Hierarchy
	1047	Hierarchical Code
	1048	)))
	1049
2.11	1050	able 4: Table of Maintainable Artefacts for Structural Definition Metadata
1.1	1051
	1052	=== 7.1.2 Item Scheme, Structure ===
	1053
	1054	The artefacts included in the structural definitions are:
	1055
	1056	* All types of Item Scheme (Codelist, Concept Scheme, Category Scheme, Organisation Scheme - Agency Scheme, Data Provider Scheme, Data Consumer Scheme, Organisation Unit Scheme)
2.11	1057	* All types of Structure (Data Structure Definition, Metadata Structure Definition)
1.1	1058	* All types of Structure Usage (Dataflow Definition, Metadataflow Definition)
	1059
	1060	=== 7.1.3 Structure Usage ===
	1061
	1062	==== 7.1.3.1 Structure Usage: Basic Concepts ====
	1063
	1064	The Structure Usage defines, in its concrete classes of Dataflow Definition and
	1065
	1066	Metadataflow Definition, which flows of data and metadata use which specific Structure, and importantly for the support of data and metadata discovery, the Structure Usage can be linked to one or more Category in one or more Category Scheme using the Categorisation mechanism. This gives the ability for an application to discover data and metadata by “drilling down” the Category Schemes.
	1067
	1068	==== 7.1.3.2 Structure Usage Schematic ====
	1069
	1070	[[image:1747824123018-658.jpeg]]
	1071
	1072	Figure 9: Schematic of Linking the Data and Metadata Flows to Categories and Structure Definitions
	1073
	1074	==== 7.1.3.3 Structure Usage Model ====
	1075
2.12	1076	[[image:1747829078194-749.png]]
	1077
1.1	1078	Figure 10: SDMX-IM of links from Structure Usage to Category
	1079
	1080	In addition to the maintenance of the Dataflow Definition and the Metadataflow Definition the following links must be maintained in the registry:
	1081
	1082	* Dataflow Definition to Data Structure Definition
	1083	* Metadataflow Definition to Metadata Structure Definition
	1084
	1085	The following links may be created by means of a Categorisation
	1086
	1087	* Categorisation to Dataflow Definition and Category
	1088	* Categorisation to Metadataflow Definition and Category
	1089
	1090	== 7.2 Data and Metadata Provisioning ==
	1091
	1092	=== 7.2.1 Provisioning Agreement: Basic concepts ===
	1093
	1094	Data provisioning defines a framework in which the provision of different types of statistical data and metadata by various data providers can be specified and controlled. This framework is the basis on which the existence of data can be made known to the SDMX-enabled community and hence the basis on which data can subsequently be discovered. Such a framework can be used to regulate the data content to facilitate the building of intelligent applications. It can also be used to facilitate the processing implied by service level agreements, or other provisioning agreements in those scenarios that are based on legal directives. Additionally, quality and timeliness metadata can be supported by this framework which makes it practical to implement information supply chain monitoring.
	1095
	1096	Note that in the SDMX-IM the class “Data Provider” encompasses both data and metadata and the term “data provisioning” here includes both the provisioning of data and metadata.
	1097
	1098	Although the Provision Agreement directly supports the data-sharing “pull” model, it is also useful in “push” exchanges (bilateral and gateway scenarios), or in a dissemination environment. It should be noted, too, that in any exchange scenario, the registry functions as a repository of structural metadata.
	1099
	1100	=== 7.2.2 Provisioning Agreement Model – pull use case ===
	1101
	1102	An organisation which publishes statistical data or reference metadata and wishes to make it available to an SDMX enabled community is called a Data Provider. In terms of the SDMX Information Model, the Data Provider is maintained in a Data Provider Scheme.
	1103
2.13	1104	[[image:1747829109466-595.png]]
1.1	1105
	1106	Figure 11: SDMX-IM of the Data Provider
	1107
	1108	Note that the Data Provider does not inherit the hierarchy association. The diagram below shows a logical schematic of the data model classes required to maintain provision agreements
	1109
	1110	[[image:1747824123019-181.jpeg]]
	1111
	1112	Figure 12: Schematic of the Provision Agreement
	1113
	1114	The diagram below is a logical representation of the data required in order to maintain Provision Agreements.
	1115
2.13	1116	[[image:1747829139951-378.png]]
1.1	1117
2.13	1118	(% class="wikigeneratedid" id="HFigure13:LogicalclassdiagramoftheinformationcontainedintheProvisionAgreement" %)
	1119	Figure 13: Logical class diagram of the information contained in the Provision Agreement
1.1	1120
	1121	A Provision Agreement is structural metadata. Each Provision Agreement must reference a Data Provider and a Dataflow or Metadataflow Definition. The Data Provider and the Dataflow/Metadataflow Definition must exist already in order to set up a Provision Agreement.
	1122
	1123	== 7.3 Data and Metadata Constraints ==
	1124
	1125	=== 7.3.1 Data and Metadata Constraints: Basic Concepts ===
	1126
	1127	Constraints are, effectively, lists of the valid or actual content of data and metadata. Constraints can be used to specify a sub set of the theoretical content of data set or metadata set which can be derived from the specification of the DSD or MSD. A Constraint can comprise a list of keys or a list of content (usually code values) of a specific component such as a dimension or attribute.
	1128
	1129	Constraints comprise the specification of subsets of key or target values or attribute values that are contained in a Datasource, or is to be provided for a Dataflow or Metadataflow Definition, or directly attached to a Data Structure Definition or Metadata Structure Definition. This is important metadata because, for example, the full range of possibilities which is implied by the Data Structure Definition (e.g. the complete set of valid keys is the Cartesian product of all the values in the code lists for each of the Dimensions) is often more than is actually present in any specific Datasource, or more than is intended to be supplied according to a specific Dataflow Definition.
	1130
	1131	Often a Data Provider will not be able to provide data for all key combinations, either because the combination itself is not meaningful, or simply because the provider does not have the data for that combination. In this case the Data Provider could constrain the Datasource (at the level of the Provision Agreement or the Data Provider) by supplying metadata that defines the key combinations or cube regions that are available. This is done by means of a Constraint. The Content Constraint is also used to define a code list sub set which is used to populate a Partial Code List.
	1132
	1133	Furthermore, it is often useful to define subsets or views of the Data Structure Definition which restrict values in some code lists, especially where many such subsets restrict the same Data Structure Definition. Such a view is called a Dataflow Definition, and there can be one or more defined for any Data Structure Definition.
	1134
	1135	Whenever data is published or made available by a Data Provider, it must conform to a Dataflow Definition (and hence to a Data Structure Definition). The Dataflow Definition is thus a means of enabling content based processing.
	1136
	1137	In addition, Constraints can be extremely useful in a data visualisation system, such as dissemination of statistics on a website. In such a system a Cube Region can be used to specify the Dimension codes that actually exist in a datasource (these can be used to build relevant selection tables), and the Key Set can be used to specify the keys that exist in a datasource (these can be used to guide the user to select only those Dimension code values that will return data based on the Dimension values already selected).
	1138
	1139	=== 7.3.2 Data and Metadata Constraints: Schematic ===
	1140
	1141	[[image:1747824123021-978.jpeg]]
	1142
	1143	Figure 14: Schematic of the Constraint and the Artefacts that can be Constrained
	1144
	1145	=== 7.3.3 Data and Metadata Constraints: Model ===
	1146
2.13	1147	[[image:1747829204737-370.png]]
1.1	1148
2.13	1149	Figure 15: Logical class diagram showing inheritance between and reference to constrainable artifacts
1.1	1150
2.13	1151	The class diagram above shows that DataProvider, DataflowDefinition, MetadataflowDefinition, ProvisionAgreement, DataStructureDefinition, MetadataStructureDefinition, SimpleDatasource and QueryDatasource are all concrete sub-classes of ConstrainableArtefact and can therefore have Constraints specified. Note that the actual Constraint as submitted is associated to the reference classes which inherit from ConstrainableRef: these are used to refer to the classes to which the Constraint applies.
1.1	1152
	1153	The content of the Constraint can be found in the SDMX Information Model document.
	1154
	1155	== 7.4 Data and Metadata Registration ==
	1156
	1157	=== 7.4.1 Basic Concepts ===
	1158
	1159	A Data Provider has published a new dataset conforming to an existing Dataflow Definition (and hence Data Structure Definition). This is implemented as either a web-accessible SDMX-ML file, or in a database which has a web-services interface capable of responding to an SDMX-ML Query or RESTful query with an SDMX-ML data stream.
	1160
	1161	The Data Provider wishes to make this new data available to one or more data collectors in a “pull” scenario, or to make the data available to data consumers. To do this, the Data Provider registers the new dataset with one or more SDMX conformant registries that have been configured with structural and provisioning metadata. In other words, the registry “knows” the Data Provider and “knows” what data flows the data provider has agreed to make available.
	1162
	1163	The same mechanism can be used to report or make available a metadata set.
	1164
	1165	SDMX-RR supports dataset and metadata set registration via the Registration Request, which can be created by the Data Provider (giving the Data Provider maximum control). The registry responds to the registration request with a registration response which indicates if the registration was successful. In the event of an error, the error messages are returned as a registry exception within the response.
	1166
	1167	=== 7.4.2 The Registration Request ===
	1168
	1169	==== 7.4.2.1 Registration Request Schematic ====
	1170
	1171	[[image:1747824123025-411.jpeg]]
	1172
3.3	1173	Figure 16: Schematic of the Objects Concerned with Registration
1.1	1174
	1175	==== 7.4.2.2 Registration Request Model ====
	1176
	1177	The following UML diagram shows the composition of the registration request. Each request is made up of one or more Registrations, one per dataset or metadata set to be registered. The Registration can optionally have information which has been extracted from the Registration:
	1178
	1179	* validFrom
	1180	* validTo
	1181	* lastUpdated
	1182
	1183	The last updated date is useful during the discovery process to make sure the client knows which data is freshest.
	1184
	1185	The Registration has an action attribute which takes one of the following values:
	1186
2.14	1187	(% style="width:970.294px" %)
	1188	\|(% style="width:212px" %)Action Attribute Value\|(% style="width:756px" %)Behaviour
	1189	\|(% style="width:212px" %)Append\|(% style="width:756px" %)Add this Registration to the registry
	1190	\|(% style="width:212px" %)Replace\|(% style="width:756px" %)Replace the existing Registration with identified by the id in the Registration of the Submit Registration Request
	1191	\|(% style="width:212px" %)Delete\|(% style="width:756px" %)Delete the existing Registration identified by the id in the Registration of the Submit Registration Request
1.1	1192
2.15	1193	[[image:1747829290890-122.png]]
	1194
1.1	1195	Figure 17: Logical Class Diagram of Registration of Data and Metadata
	1196
	1197	The Query Datasource is an abstract class that represents a data source which can understand an SDMX-ML query (SOAPDatasource) or RESTful query
	1198
	1199	(RESTDatasource) and respond appropriately. Each of these different Datasources inherit the dataURL from Datasource, and the QueryDatasource has an additional URL to locate a WSDL or WADL document to describe how to access it. All other supported protocols are assumed to use the Simple Datasource URL.
	1200
	1201	A Simple Datasource is used to reference a physical SDMX-ML file that is available at a URL.
	1202
	1203	The Registration Request has an action attribute which defines whether this is a new (append) or updated (replace) Registration, or that the Registration is to be deleted (delete). The id is only provided for the replace and delete actions, as the Registry will allocate the unique id of the (new) Registration.
	1204
	1205	The Registration includes attributes that state how a Simple Datasource is to be indexed when registered. The Registry registration process must act as follows.
	1206
	1207	Information in the data or metadata set is extracted and placed in one or more Content Constraints (see the Constraints model in the SDMX Information Model – Section 2 of the SDMX Standards). The information to be extracted is indicated by the Boolean values set on the Provision Agreement as shown in the table below.
	1208
2.16	1209	\|(% style="width:185px" %)Indexing Required\|(% style="width:1686px" %)Registration Process Activity
	1210	\|(% style="width:185px" %)indexTimeSeries\|(% style="width:1686px" %)Extract all the series keys and create a KeySet(s) Constraint.
	1211	\|(% style="width:185px" %)indexDataSet\|(% style="width:1686px" %)(((
	1212	Extract all the codes and other content of the Key value of the Series Key in a Data Set and create one or more Cube Regions containing Member Selections of Dimension Components of the Constraints model in the SDMX-IM, and the associated Selection Value.
1.1	1213	)))
2.16	1214	\|(% style="width:185px" %)indexReportingPeriod\|(% style="width:1686px" %)(((
1.1	1215	This applies only to a registered dataset.
	1216	Extract the Reporting Begin and Reporting End from the Header of the Message containing the data set, and create a Reference Period constraint.
	1217	)))
2.16	1218	\|(% style="width:185px" %)indexAttributes\|(% style="width:1686px" %)(((
1.1	1219	Data Set
	1220	Extract the content of the Attribute Values in a Data Set and create one or more Cube Regions containing Member Selections of Data Attribute Components of the Constraints model in the SDMXIM, and the associated Selection Value
	1221	Metadata Set
	1222	Indicate the presence of a Reported Attribute by creating one or more Cube Regions containing Member Selections of Metadata Attribute Components of the Constraints model in the SDMX-IM. Note that the content is not stored in the Selection Value.
	1223	)))
	1224
	1225	Constraints that specify the contents of a Query Datasource are submitted to the Registry in a Submit Structure Request.
	1226
	1227	The Registration must reference the Provision Agreement to which it relates.
	1228
	1229	=== 7.4.3 Registration Response ===
	1230
2.16	1231	After a registration request has been submitted to the registry, a response is returned to the submitter indicating success or failure. Given that a registration request can hold many Registrations, then there must be a registration status for each Registration. The Submit Registration class has a status field which is either set to “Success”, “Warning” or “Failure”.
1.1	1232
	1233	If the registration has succeeded, a Registration will be returned - this holds the Registry-allocated Id of the newly registered Datasource plus a Datasource holding the URL to access the dataset, metadataset, or query service.
	1234
	1235	The Registration Response returns set of registration status (one for each registration submitted) in terms of a Status Message (this is common to all Registry Responses) that indicates success or failure. In the event of registration failure, a set of Message Text are returned, giving the error messages that occurred during registration. It is entirely possible when registering a batch of datasets, that the response will contain some successful and some failed statuses. The logical model for the Registration Response is shown below:
	1236
2.16	1237	[[image:1747829477882-750.png]]
1.1	1238
	1239	Figure 18: Logical class diagram showing the registration response
	1240
	1241	== 7.5 Subscription and Notification Service ==
	1242
	1243	The contents of the SDMX Registry/Repository will change regularly: new code lists and key families will be published, new datasets and metadata-sets will be registered. To obviate the need for users to repeatedly query the registry to see when new information is available, a mechanism is provided to allow users to be notified when these events happen.
	1244
	1245	A user can submit a subscription in the registry that defines which events are of interest, and either an email and/or an HTTP address to which a notification of qualifying events will be delivered. The subscription will be identified in the registry by a URN which is returned to the user when the subscription is created. If the user wants to delete the subscription at a later point, the subscription URN is used as identification. Subscriptions have a validity period expressed as a date range (startDate, endDate) and the registry may delete any expired subscriptions, and will notify the subscriber on expiry.
	1246
2.17	1247	When a registry/repository artefact is modified, any subscriptions which are observing the object are activated, and either an email or HTTP POST is instigated to report details of the changes to the user specified in the subscription. This is called a “notification”.
1.1	1248
3.2	1249	=== 7.5.1Subscription Logical Class Diagram ===
1.1	1250
2.17	1251	[[image:1747829554603-150.png]]
1.1	1252
	1253	Figure 19: Logical Class Diagram of the Subscription
	1254
	1255	=== 7.5.2 Subscription Information ===
	1256
	1257	Regardless of the type of registry/repository events being observed, a subscription always contains:
	1258
2.17	1259	1. A set of URIs describing the end-points to which notifications must be sent if the subscription is activated. The URIs can be either mailto~: or http: protocol. In the former case an email notification is sent; in the latter an HTTP POST notification is sent.
	1260	1. A user-defined identifier which is returned in the response to the subscription request. This helps with asynchronous processing and is NOT stored in the Registry.
	1261	1. A validity period which defines both when the subscription becomes active and expires. The subscriber may be sent a notification on expiration of the subscription.
	1262	1. A selector which specifies which type of events are of interest. The set of event types is:
1.1	1263
2.17	1264	\|(% style="width:327px" %)Event Type\|(% style="width:1545px" %)Comment
	1265	\|(% style="width:327px" %)STRUCTURAL_REPOSITORY_EVENTS\|(% style="width:1545px" %)Life-cycle changes to Maintainable Artefacts in the structural metadata repository.
	1266	\|(% style="width:327px" %)DATA_REGISTRATION_EVENTS\|(% style="width:1545px" %)Whenever a published dataset is registered. This can be either a SDMXML data file or an SDMX conformant database.
	1267	\|(% style="width:327px" %)METADATA_REGISTRATION_EVENTS\|(% style="width:1545px" %)Whenever a published metadataset is registered. This can be either a SDMXML reference metadata file or an SDMX conformant database.
	1268	\|(% style="width:327px" %)ALL_EVENTS\|(% style="width:1545px" %)All events of the specified EventType
1.1	1269
	1270	=== 7.5.3 Wildcard Facility ===
	1271
	1272	Subscription notification supports wildcarded identifier components URNs, which are identiiers which have some or all of their component parts replaced by the wildcard character `%`. Identifier components comprise:
	1273
2.17	1274	* agencyID
	1275	* id
	1276	* version
1.1	1277
	1278	Examples of wildcarded identifier components for an identified object type of Codelist are shown below.
	1279
2.18	1280	//AgencyID = %
1.1	1281	Id = %
2.18	1282	Version = %//
1.1	1283
	1284	This subscribes to all Codelists of all versions for all agencies.
	1285
2.18	1286	//AgencyID = AGENCY1
1.1	1287	Id = CODELIST1
2.18	1288	Version = %//
1.1	1289
	1290	This subscribes to all versions of Codelist CODELIST1 maintained by the agency
	1291
2.18	1292	//AGENCY1
1.1	1293	AgencyID = AGENCY1
	1294	Id = %
2.18	1295	Version = %//
1.1	1296
	1297	This subscribes to all versions of all Codelist objects maintained by the agency
	1298
2.18	1299	//AGENCY1
1.1	1300	AgencyID = %
	1301	Id = CODELIST1
2.18	1302	Version = %//
1.1	1303
	1304	This subscribes to all versions of Codelist CODELIST1 maintained by the agency
	1305
2.18	1306	//AGENCY1//
1.1	1307
	1308	Note that if the subscription is to the latest version then this can be achieved by the * character
	1309
2.18	1310	//i.e. Version = *//
1.1	1311
	1312	Note that a subscription using the URN mechanism cannot use wildcard characters.
	1313
	1314	=== 7.5.4 Structural Repository Events ===
	1315
	1316	Whenever a maintainable artefact (data structure definition, concept scheme, codelist, metadata structure definition, category scheme, etc.) is added to, deleted from, or modified in the structural metadata repository, a structural metadata event is triggered. Subscriptions may be set up to monitor all such events, or focus on specific artefacts such as a Data Structure Definition.
	1317
	1318	=== 7.5.5 Registration Events ===
	1319
	1320	Whenever a dataset or metadata-set is registered a registration event is created. A subscription may be observing all data or metadata registrations, or it may focus on specific registrations as shown in the table below:
	1321
3.1	1322	\|(% style="width:405px" %)Selector\|(% style="width:1467px" %)Comment
	1323	\|(% style="width:405px" %)DataProvider\|(% style="width:1467px" %)Any datasets or metadata sets registered by the specified data provider will activate the notification.
	1324	\|(% style="width:405px" %)ProvisionAgreement\|(% style="width:1467px" %)Any datasets or metadata sets registered for the provision agreement will activate the notification.
	1325	\|(% style="width:405px" %)Dataflow (&Metadataflow)\|(% style="width:1467px" %)Any datasets or metadata sets registered for the specified dataflow (or metadataflow) will activate the notification.
	1326	\|(% style="width:405px" %)DataStructureDefinition & MetadataStructureDefinition\|(% style="width:1467px" %)Any datasets or metadata sets registered for those dataflows (or metadataflows) that are based on the specified Data Structure Definition will
	1327	\|(% style="width:405px" %)Selector\|(% style="width:1467px" %)Comment
	1328	\|(% style="width:405px" %) \|(% style="width:1467px" %)activate the notification.
	1329	\|(% style="width:405px" %)Category\|(% style="width:1467px" %)Any datasets or metadata sets registered for those dataflows, metadataflows, provision agreements that are categorised by the category.
1.1	1330
	1331	The event will also capture the semantic of the registration: deletion or replacement of an existing registration or a new registration.
	1332
	1333	== 7.6 Notification ==
	1334
	1335	=== 7.6.1 Logical Class Diagram ===
	1336
3.1	1337	[[image:1747829675568-610.png]]
1.1	1338
3.1	1339	(% class="wikigeneratedid" id="HFigure20:LogicalClassDiagramoftheNotification" %)
	1340	Figure 20: Logical Class Diagram of the Notification
1.1	1341
	1342	A notification is an XML document that is sent to a user via email or http POST whenever a subscription is activated. It is an asynchronous one-way message.
	1343
	1344	Regardless of the registry component that caused the event to be triggered, the following common information is in the message:
	1345
	1346	* Date and time that the event occurred
	1347	* The URN of the artefact that caused the event
	1348	* The URN of the Subscription that produced the notification
	1349	* Event Action: Add, Replace, or Delete.
	1350
	1351	Additionally, supplementary information may be contained in the notification as detailed below.
	1352
	1353	=== 7.6.2 Structural Event Component ===
	1354
	1355	The notification will contain the MaintainableArtefact that triggered the event in a form similar to the SDMX-ML structural message (using elements from that namespace).
	1356
	1357	=== 7.6.3 Registration Event Component ===
	1358
	1359	The notification will contain the Registration.