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CloudEvents Subscriptions API - Version 0.1-wip

Abstract

This specification defines mechanisms, including an API definition, for CNCF CloudEvents event consumers to subscribe to events originating from event producers on behalf of event sources. The software entity handling these subscriptions and responsible for distributing events is abstractly referred to as a "subscription manager".

1. Introduction

A subscription manager responsible for a specific set of events can reside immediately at or near the event producer or it can reside in some middleware infrastructure. This document does not formalize the relationship between the original event producer and the subscription manager, and how the subscription manager obtains the events it distributes to subscribers.

This document also does not formalize the relationship between a specific set of events and the subscription manager. An event producer that produces multiple different types of events can offer one subscription manager for all events or a subscription manager for each type of event, or any other combination. An event producer can also offer up the same set of events for subscription at multiple concurrent subscription managers. Regardless of relationship between the event producer(s) and the subscription manager(s), the advertisement of the subscription offers are published in a CloudEvents Discovery service.

As with the core CloudEvents specification, the goal of this specification is to reuse mechanisms based on existing standards and conventions where such exist and only introduce new mechanisms where needed.

Therefore, this specification not only defines a new subscription management API for certain use-cases, but also refers to existing mechanisms available in the specifications of transport protocols for which CloudEvents bindings exist.

For instance, introducing and mandating a CloudEvents-specific subscription mechanism for MQTT would only complicate implementations while not providing any obvious advantage. Using any of the referred native subscription mechanisms of the respective transport protocols is therefore within the scope and in compliance with this specification.

2. Notations and Terminology

Notational Conventions

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119.

Terminology

This specification uses the following terms:

Source

An event source is a logical entity in a system on behalf of which events are produced based on occurrences.

Producer

The entity producing the event. The event might reflect an occurrence on a source elsewhere in the system. The producer is the concrete entity that creates and sends the event related to an occurrence.

Intermediary

An "intermediary" (also referred to as middleware) receives an event for the purpose of forwarding it to the next receiver, which might be another intermediary or a consumer. A typical task for an intermediary is to route the event to receivers based on the information in the event context.

Consumer

An entity receiving and processing events. Consumers might receive events from producers directly or via intermediaries. A consumer might listen and wait for events to be delivered to it or it might actively solicit them from the producer or intermediary.

Subscription

A relationship established between a consumer and a producer or an intermediary. The subscription reflects the consumer's interest in receiving events and describes the method for how to deliver those events.

Subscription Manager

An entity, defined in this specification, that manages the lifecycle of a subscription on behalf of an event consumer and that distributes events to registered consumers.

3. Event Subscriptions

This specification defines mechanisms for CNCF CloudEvents event consumers to subscribe to events originating from producers on behalf of event sources. The software entity handling these subscriptions and responsible for distributing events is abstractly referred to as a "subscription manager".

A compliant CloudEvents subscription manager MUST support at least one of the transport protocols referenced in this specification and it MUST implement the subscription mechanism referred to or defined in this specification.

In some cases, the event producer MAY delegate the role of the subscription manager to some intermediary, in which case produced events are made available to the intermediary, and the intermediary's subscription manager determines who receives copies of the published events. In other cases, the event producer MAY take on the subscription manager role by itself.

In this specification, we distinguish two styles of relationships between an event consumer and a subscription manager, whereby the key differentiator is how the event delivery channel to the consumer is initiated:

  • Subscriptions with consumer-solicited delivery ("pull"-style) are configured on the subscription manager for delivering events through a communication channel (like an AMQP link or a MQTT connection) initiated by the consumer and connecting to the subscription manager. These kinds of subscriptions are typically offered by messaging or eventing middleware and their lifetime might be bounded by the lifetime of the communication channel.

  • Subscriptions with subscription-manager-initiated delivery ("push"-style) are configured on the subscription manager for delivering events through a communication channel that the subscription manager initiates when events are available for delivery on the subscription. The configuration of such a subscription MUST contain all information needed for the subscription manager to select a transport protocol, establish the desired communication channel, and deliver the event(s).

An end-to-end solution using CloudEvents might use only one of these styles or a combination of those.

For instance, the solution might use an MQTT broker to handle delivery of events into connected devices that connect into the broker and subscribe on a particular MQTT topic, which acts as the subscription manager in the sense of this specification ("pull"-style). The events that ought to be shared with the connected devices might however originate elsewhere in the overall solution, and some event router middleware's subscription manager might therefore be configured to initiate delivery of events ("push"-style) into the given MQTT broker topic whenever such events are available.

3.1 Native Subscription Management Mechanisms

MQTT, AMQP, NATS, and Apache Kafka are protocols with a formal CloudEvents binding that have native mechanisms filling the role of a subscription manager.

Using any of these subscription management mechanisms ought to allow an application to claim conformance with this specification. More specifically, an application that uses an MQTT or AMQP message broker as its middleware component ought be able to use the native capabilities of those protocols to subscribe to CloudEvents event streams without requiring CloudEvents Subscription API-specific mechanisms or extensions. The conformance section in this document formally enumerates the requirements.

The descriptions of the protocol subscription mechanisms in this section are non-normative. Please refer to the protocol specifications or documentation for normative definitions.

3.1.1. MQTT 3.x/5.x

The MQTT 3.x/5.x protocol has a native "SUBSCRIBE" (and matching "UNSUBSCRIBE") operation, which allows a consumer to solicit messages matching a pattern against the MQTT broker's topic path hierarchy.

Once an MQTT consumer has issued one or multiple SUBSCRIBE requests, matching events for any of the MQTT session's active subscription are delivered by the broker to the consumer without requiring further interactions. Depending on the quality-of-service (QoS) level of the subscription, individual deliveries might have to be acknowledged by the consumer.

The lifetime of a subscription is bounded by lifetime of the MQTT session.

Events are published using the "PUBLISH" operation on a path into the topic hierarchy, and all current subscriptions whose topic filters match the path receive a message.

The operations are normatively defined in the MQTT 3.1.1 and MQTT 5.0 specifications.

3.1.2. AMQP 1.0

The AMQP 1.0 protocol has a built-in subscription mechanism.

When an AMQP container establishes a receive-role link to another container, it can specify a "distribution-mode" on the link source in the other container. If the distribution mode is "copy", each such established link receives a copy of the message stream available at the distribution node. If the distribution mode is "move", messages are exclusively owned by the link and are removed from the source when the transfer is settled successfully.

Supporting the "copy" mode, is OPTIONAL for the underlying implementation of the broker

The link source can also be configured with filters. The AMQP core specification does not define concrete filter types, but the AMQP Filter Expressions 1.0 extension specification and the Apache Qpid project's filter definitions do.

3.1.3. NATS

The NATS protocol has a native subscribe operation "SUB" (and matching "UNSUB"), which allows a client to solicit a stream of messages that match a given subject or a wildcard.

Events are published using the "PUB" operation with a subject name that is then matched against the existing subscriptions.

3.1.4. Apache Kafka

Apache Kafka allows consumers to fetch events stored in topic partitions once or multiple times.

While Apache Kafka does not have a server-side subscribe operation and also does not provide filtering capabilities, it allows the fetching client to fully control from which offset in the partition's log store events are being read from. This allows multiple parties to retrieve the same set of events from the stream.

The management of the subscription and selecting which events are being fetched and dispatched into the application lies completely with the consumer in the Apache Kafka case.

3.1.5. HTTP

HTTP does not have a built-in subscription mechanism that allows for establishing a flow of events similar to the aforementioned protocols. HTTP allows for modeling pull-style retrieval of events from a store and, with HTTP/2 "server push", even for continuous delivery an event stream triggered by a initial request, but for event delivery scenarios, these techniques are applications of HTTP rather than inherent features of HTTP per-se.

3.2. Subscription Manager API

The subscription manager API defines a subscription object and a protocol for creating, updating and deleting subscriptions on a subscription manager.

The subscription object describes the consumer's interest in events and defines the delivery method. The protocol allows to configure subscriptions on the subscription manager. Especially in case of subscription manager initiated ("push"-style) delivery, the protocol is used to express the consumer's interest to the subscription manager before the subscription manager can initiate delivery.

The protocol used to configure the subscription manager is decoupled from the delivery protocol, meaning that an application can configure a push delivery into an AMQP destination using an API call initiated over HTTP.

A subscription manager that natively exists in a middleware implementation might also have a separate CloudEvents subscription manager API endpoint implementation. If such a separate API endpoint exists and creating subscriptions is not feasible on such a separate API endpoint, the respective operation might not be available. For instance, creating an MQTT subscription is not feasible from outside an MQTT connection, but an existing subscription might be enumerable through a subscription collection and deleting the subscription from the collection might terminate it.

3.2.1. Subscription Object

A subscription manager manages a collection of subscriptions. The upper limit on how many subscriptions are supported is implementation specific.

To help explain the subscription resource, the following non-normative pseudo json shows its basic structure:

(* means zero or more, + means one or more, ? means OPTIONAL)

Subscription:

{
  "id": "[a subscription manager scoped unique string]",
  "source": "[...]", ?
  "types": "[ "[ce-type values]" + ]", ?
  "config": { ?
    "[key]": [subscription manager specific value], *
  },

  "filters": [ ?
    { "[dialect name]": [dialect specific object] } +
  ],

  "sink": "[URI to where events are delivered]",
  "protocol": "[delivery protocol]",
  "protocolsettings": { ?
    "[key]": "[type]", *
  }
}

Each subscription is represented by an object that has the following properties:

id
  • Type: String

  • Description: The unique identifier of the subscription in the scope of the subscription manager. This value MUST be unique within the scope of the subscription manager and MUST be immutable.

  • Constraints:

    • REQUIRED when retrieving the object
    • if present on the input to a subscribe operation then it MUST be ignored
  • Examples:

    • f1d15fd0-6893-11eb-9439-0242ac130002
    • bigco-subscription-1234
source
  • Type: URI-reference - a CloudEvents source value

  • Description: Indicates the source to which the subscription is related. When present on a subscribe request, all events generated due to this subscription MUST have a CloudEvents source property that matches this value. If this property is not present on a subscribe request then there are no constraints placed on the CloudEvents source property for the events generated.

    TODO: add something to discovery to indicate if manager supports this

  • Constraints:

    • OPTIONAL
    • If present, MUST be a non-empty URI
  • Examples:

    • /sensors/tn-1234567/alerts
types
  • Type: Array of Strings - array of CloudEvents type values

  • Description: Indicates which types of events the subscriber is interested in receiving. When present on a subscribe request, all events generated due to this subscription MUST have a CloudEvents type property that matches one of these values.

  • Constraints:

    • OPTIONAL
    • If present, any value present MUST a non-empty string
  • Examples:

    • com.github.pull_request.opened
    • com.example.object.deleted
config
  • Type: Map of subscription manager defined types

  • Description: A set of key/value pairs that modify the configuration of of the subscription related to the event generation process. While this specification places no constraints on the data type of the map values. When there is a Discovery Endpoint Service definition defined for the subscription manager, then the key MUST be one of the subscriptionconfig keys specified in the Discovery Endpoint Service definition. The value MUST conform to the data type specified by the value in the subscriptionconfig entry for the key

  • Constraints:

    • OPTIONAL
    • If present, any "key" used in the map MUST be a non-empty string
  • Examples:

    • { "interval": 5 }
filters
  • Type: Array of Objects

  • Description: An array of filter expressions that evaluates to true or false. If any filter expression in the array evaluates to false, the event MUST NOT be sent to the sink. If all the filter expressions in the array evaluates to true, the event MUST be attempted to be delivered. Absence of a filter or empty array implies a value of true.

    Each filter dialect MUST have a name that is unique within the scope of the subscription manager. Each dialect will define the semantics and syntax of the filter expression language. See the Filters section for more information.

    If a subscription manager does not support filters, or the filter dialect specified in a subscription request, then it MUST generate an error and reject the subscription create or update request.

  • Constraints:

    • OPTIONAL for both subscription managers and subscribers to support
  • Examples:

    • [ {"prefix": { "type": "com.github.issue" } } ]
sink
  • Type: URI

  • Description: The address to which events MUST be sent. The format of the address MUST be valid for the protocol specified in the protocol property, or one of the protocol's own transport bindings (e.g. AMQP over WebSockets).

  • Constraints:

    • REQUIRED
  • Examples:

    • https://example.com/event-processor
sinkCredential
  • Type: Map of attributes

  • Description: A set of settings carrying credential information that is enabling the entity delivering events to the subscription target to be authorized for delivery at the sink endpoint. The well-known attribute values are defined in section 3.2.3.

    Implementations SHOULD NOT include secrets contained in this map when the subscription object is enumerated or retrieved. Secrets SHOULD be write-only. Tokens, passphrases, and passwords are such secrets and account identifiers might be considered secrets as well.

  • Constraints:

    • OPTIONAL
protocol
  • Type: String

  • Description: Identifier of a delivery protocol. Because of WebSocket tunneling options for AMQP, MQTT and other protocols, the URI scheme is not sufficient to identify the protocol. The protocols with existing CloudEvents bindings are identified as AMQP, MQTT3, MQTT5, HTTP, KAFKA, and NATS. An implementation MAY add support for further protocols.

  • Constraints:

    • REQUIRED
    • Value comparisons MUST be case sensitive.
  • Examples:

    • HTTP
protocolsettings
  • Type: Map of protocol specific attributes

  • Description: A set of settings specific to the selected delivery protocol provider. Options for these settings are listed in the following subsection. An subscription manager MAY offer more options. See the Protocol Settings section for future details.

  • Constraints:

    • OPTIONAL
  • Examples:

    • Credentials
    • Retry policies
    • QoS modes

In general the intent of this specification is to consider the processing of events to have 3 conceptual phases:

  • event generation. This phase creates the events and is typically controlled by the config, source and types properties. This might include settings that influence how often events are generated, or the scope of the event sources being monitored.
  • event filtering. This phase, as the name implies, will "filter" the stream of events generated from the previous phase. The filters property will be used to specify how this filtering will be done. Whether this is done separately from the event generation phase, or as part of it, is an implementation choice. It is also possible for Subscription Managers to control this aspect of the event stream via the config property if they so choose.
  • event transmission. This phase controls how the events are sent to the sink. Typically, by this step in the processing the set of events to be sent are already known and the only variable is the exact mechanism that will be used to send them. The protocol and protocolsettings properties will control this phase.

Additionally, it might be possible for one Subscription property to have influence over multiple phases of the event processing. Regardless of which aspect of the Subscription is controlled by which of the above phases/properties, the Service description specified by the Discovery specification SHOULD contain enough information for a consumer to know which properties to use when creating a Subscription to get the desired results.

Below is an example JSON serialization of a subscription resource:

{
  "id": "sub-193-18365",

  "config": {
    "data": "hello",
    "interval": 5
  },

  "filters": [
    { "prefix": { "type": "com.example." } }
  ],

  "protocol": "HTTP",
  "protocolsettings": {
    "method": "POST"
  },
  "sink": "http://example.com/event-processor"
}

3.2.2 Protocol Settings

This section enumerates protocol-specific delivery options for the protocol-settings map, including default values where necessary.

3.2.2.1. HTTP

For HTTP, the following settings properties SHOULD be supported by all implementations.

headers
  • Type: Map
  • Description: A set of key/value pairs that is copied into the HTTP request as custom headers.
  • Constraints:
    • OPTIONAL
method
  • Type: String
  • Description: The HTTP method to use for sending the message. This defaults to POST if not set.
  • Constraints:
    • OPTIONAL
3.2.2.2. MQTT

All implementations that support MQTT MUST support the topicname settings. All other settings SHOULD be supported.

  • topicname (string) – REQUIRED. The name of the MQTT topic to publish to.
topicname
  • Type: String
  • Description: The name of the MQTT topic to publish to.
  • Constraints:
    • REQUIRED
qos
  • Type: Integer
  • Description: MQTT quality of service (QoS) level: 0 (at most once), 1 (at least once), or 2 (exactly once). This defaults to 1 if not set.
  • Constraints:
    • OPTIONAL
retain
  • Type: Boolean
  • Description: MQTT retain flag: true/false. This defaults to false if not set.
  • Constraints:
    • OPTIONAL
expiry
  • Type: Integer
  • Description: MQTT expiry interval, in seconds. This value has no default value and the message will not expire if the setting is absent. This setting only applies to MQTT 5.0.
  • Constraints:
    • OPTIONAL
userproperties
  • Type: Map
  • Description: A set of key/value pairs that are copied into the MQTT PUBLISH packet's user property section. This setting only applies to MQTT 5.0.
  • Constraints:
    • OPTIONAL
3.2.2.3. AMQP

For AMQP, the address property MUST be supported by all implementations and other settings properties SHOULD be supported by all implementations.

address
  • Type: String
  • Description: The link target node in the AMQP container identified by the sink URI, if not expressed in the sink URI's path portion.
  • Constraints:
    • OPTIONAL
linkname
  • Type: String
  • Description: Name to use for the AMQP link. If not set, a random link name is used.
  • Constraints:
    • OPTIONAL
sendersettlementmode
  • Type: String
  • Description: Allows to control the sender's settlement mode, which determines whether transfers are performed "settled" (without acknowledgement) or "unsettled" (with acknowledgement). Default value is unsettled.
  • Constraints:
    • OPTIONAL
linkproperties
  • Type: Map
  • Description: A set of key/value pairs that are copied into link properties for the send link.
  • Constraints:
    • OPTIONAL
3.2.2.4. Apache Kafka

All implementations that support Apache Kafka MUST support the topicname settings. All other settings SHOULD be supported.

topicname
  • Type: String
  • Description: The name of the Kafka topic to publish to.
  • Constraints:
    • OPTIONAL
partitionkeyextractor
  • Type: String
  • Description: A partition key extractor expression per the CloudEvents Kafka transport binding specification.
  • Constraints:
    • OPTIONAL
clientid
  • Type: String
  • Description:
  • Constraints:
    • OPTIONAL
acks
  • Type: String
  • Description:
  • Constraints:
    • OPTIONAL
3.2.2.5. NATS
subject
  • Type: String
  • Description: The name of the NATS subject to publish to.
  • Constraints:
    • REQUIRED

3.2.3 Sink Credentials

A sink credential provides authentication or authorization information necessary to enable delivery of events to a target.

credentialType
  • Type: String

  • Description: Identifier of a credential type. The predefined types are "PLAIN", "ACCESSTOKEN", and "REFRESHTOKEN", with attributes enumerated below providing credential information. Applications MAY implement further credential types.

  • Constraints:

    • REQUIRED
  • Examples:

    • PLAIN
identifier
  • Type: String

  • Description: The identifier of a plain credential might be an account or username.

  • Constraints:

    • REQUIRED for credentialType="PLAIN"
secret
  • Type: String

  • Description: The secret of a plain credential might be a password or passphrase or key.

  • Constraints:

    • REQUIRED for credentialType="PLAIN"
    • SHOULD NOT be returned during enumeration or retrieval
accessToken
  • Type: String

  • Description: An access token is a previously acquired token granting access to the target resource.

  • Constraints:

    • REQUIRED for credentialType="ACCESSTOKEN" and credentialType="REFRESHTOKEN"
    • SHOULD NOT be returned during enumeration or retrieval
accessTokenExpiresUtc
  • Type: Timestamp

  • Description: An absolute UTC instant at which the token SHALL be considered expired.

  • Constraints:

    • REQUIRED for credentialType="ACCESSTOKEN" and credentialType="REFRESHTOKEN"
accessTokenType
  • Type: String

  • Description: Type of the access token (See OAuth 2.0).

  • Constraints:

    • REQUIRED for credentialType="ACCESSTOKEN" and credentialType="REFRESHTOKEN"
refreshToken
  • Type: String

  • Description: A refresh token credential used to acquire access tokens.

  • Constraints:

    • REQUIRED for credentialType="REFRESHTOKEN"
refreshTokenEndpoint
  • Type: String

  • Description: A URL at which the refresh token can be traded for an access token.

    Not that in some setups, accessing the refresh token endpoint uses an extra security layer, whereby the requestor passing the refresh token to the endpoint MUST be authorized. The credentials for this authorization relationship, which exists between the delivery service managed by the subscription API and the refresh endpoint, are out of scope for this specification. The sinkCredentials represent the authorization relationship between the subscriber and the delivery target it points the subscription to.

3.2.4 Filters

Filters allow for subscriptions to specify that only a subset of events are to be delivered to the sink based on a set of criteria. The filter property in a subscription is a set of filter expressions, where each expression evaluates to either true or false for each event generated.

If any of the filter expressions in the set evaluate to false, the event MUST NOT be sent to the sink. If all the filter expressions in the set evaluate to true, the event MUST be attempted to be delivered.

Each filter expression includes the specification of a dialect that defines the type of filter and the set of additional properties that are allowed within the filter expression. If a filter dialect is specified in a subscription that is unsupported by the subscription manager, creation or update of the subscription MUST be rejected with an error.

3.2.4.1 Filter Dialects

The filter expression language supported by an event producer is indicated by its dialect. This is intended to allow for flexibility, extensibility and to allow for a variety of filter dialects without enumerating them all in this specification or predicting what filtering needs every system will have in the future.

Filter dialects are identified by a unique URI-Reference.

When encoded in JSON, a filter is encoded as follows:

{ "dialect URI-Reference" : { <dialect-specific-properties> } }

This specification defines the following 7 filter dialects that all implementations MUST support:

exact filter dialect

The keys are the names of the CloudEvents attributes to be matched, and their values are the String values to use in the comparison. To evaluate to true the values of the matching CloudEvents attributes MUST all exactly match with the associated value String specified (case sensitive).

The attribute name and value specified in the filter expression MUST NOT be empty strings.

For example:

{ "exact": { "type": "com.github.push", "subject": "https://github.com/cloudevents/spec" } }
prefix filter dialect

The keys are the names of the CloudEvents attributes to be matched, and their values are the String values to use in the comparison. To evaluate to true the values of the matching CloudEvents attributes MUST all start with the associated value String specified (case sensitive).

The attribute name and value specified in the filter expression MUST NOT be empty strings.

For example:

{ "prefix": { "type": "com.github.", "subject": "https://github.com/cloudevents" } }
suffix filter dialect

The keys are the names of the CloudEvents attributes to be matched, and their values are the String values to use in the comparison. To evaluate to true the values of the matching CloudEvents attributes MUST all end with the associated value String specified (case sensitive).

The attribute name and value specified in the filter expression MUST NOT be empty strings.

For example:

{ "suffix": { "type": ".created", "subject": "/cloudevents/spec" } }
all filter dialect

Use of this MUST include a nested array of filter expressions, where all nested filter expressions MUST evaluate to true in order for the all filter expression to be true.

Note: there MUST be at least one filter expression in the array.

For example:

{
  "all": [
    { "exact": { "type": "com.github.push" } },
    { "exact": { "subject": "https://github.com/cloudevents/spec" } }
  ]
}
any filter dialect

Use of this MUST include one nested array of filter expressions, where at least one nested filter expressions MUST evaluate to true in order for the any filter expression to be true.

Note: there MUST be at least one filter expression in the array.

For example:

{
  "any": [
    { "exact": { "type": "com.github.push" } },
    { "exact": { "subject": "https://github.com/cloudevents/spec" } }
  ]
}
not filter dialect

Use of this MUST include one nested filter expression, where the result of this filter expression is the inverse of the result of the nested expression. In other words, if the nested expression evaluated to true, then the not filter expression's result is false.

For example:

{
  "not": { "exact": { "type": "com.github.push" } }
}
sql filter dialect

Use of this MUST have a string value, representing a CloudEvents SQL Expression. The filter result MUST be true if the result value of the expression, coerced to boolean, equals to the TRUE boolean value, otherwise MUST be false if an error occurred while evaluating the expression or if the result value, coerced to boolean, equals to the FALSE boolean value.

Implementations SHOULD reject subscriptions with invalid CloudEvents SQL expressions.

For example:

{ "sql": "source LIKE '%cloudevents%'" }

3.2.5. API Operations

This section enumerates the abstract operations that are defined for subscription managers. The following sections define bindings of these abstract operations to concrete protocols.

The operations are Create, Retrieve, Query, Update, and Delete. Of those, only the Retrieve operation is REQUIRED for conformance. The Create and Delete operations SHOULD be implemented. Query and Update are OPTIONAL.

Protocol bindings SHOULD provide a discovery mechanism for which operations are supported.

3.2.5.1. Creating a subscription

The Create operation SHOULD be supported by compliant Event Producers. It creates a new Subscription. The client proposes a subscription object which MUST contain all REQUIRED properties with the exception of the ID property, which will be defined by the subscription manager. The subscription manager then realizes the subscription and returns a subscription object that also contains all OPTIONAL properties for which default values have been applied.

Parameters:

  • subscription (subscription) - REQUIRED. Proposed subscription object.

Result:

  • subscription (subscription) - REQUIRED. Realized subscription object.

Errors:

  • ok - the operation succeeded
  • conflict - a subscription with the given id already exists
  • invalid - the proposed subscription object contains invalid information

Protocol bindings MAY map the Create operation such that the proposed id is ignored and the subscription manager assigns one instead.

3.2.5.2. Retrieving a Subscription

The Retrieve operation MUST be supported by compliant Event Producers. It returns the specification of the identified subscription.

Parameters:

  • id (string) - REQUIRED. Identifier of the subscription.

Result:

  • subscription (subscription) - REQUIRED. Subscription object.

Errors:

  • ok - the operation succeeded
  • notfound - a subscription with the given id already exists

3.2.5.3. Querying for a list of Subscriptions

The Query operation SHOULD be supported by compliant Event Producers. It allows to query the list of subscriptions on the subscription manager associated with or otherwise visible to the party making the request. If supported, it MUST be supported at the same endpoint as the Create subscription operation.

Parameters:

  • none

Result:

  • subscription (list of subscription) - REQUIRED. List of subscription objects

Errors:

  • ok - the operation succeeded and returned results
  • nocontent - the operation succeeded and returned no results

Protocol bindings and implementations of such bindings MAY add custom filter constraints and pagination arguments as parameters. A request without filtering constraints SHOULD return all available subscriptions associated with or otherwise visible to the party making the request.

3.2.5.4. Updating a Subscription

The Update operation MAY be supported by compliant Event Producers. To request the update of a Subscription, the client submits a proposed subscription object whose id MUST match an existing subscription. All other properties MAY differ from the original subscription. The subscription manager then updates the subscription and returns a subscription object that also contains all OPTIONAL properties for which default values have been applied.

Parameters:

  • subscription (subscription) - REQUIRED. Proposed subscription object.

Result:

  • subscription (subscription) - REQUIRED. Realized subscription object.

Protocol bindings MAY map the Update and the Create operation into a composite "upsert" operation that creates a new subscription if one with the given id does not exist. In this case, the operation is *Create and follows that operation's rules.

3.2.5.5. Deleting a Subscription

The Delete operation SHOULD be supported by compliant Event Producers. It returns the specification of the identified subscription.

Parameters:

  • id (string) - REQUIRED. Identifier of the subscription.

Result:

  • subscription (subscription) - REQUIRED. Subscription object.

Errors:

  • ok - the operation succeeded
  • notfound - a subscription with the given id already exists

3.3. HTTP Binding for the Subscription API

(TBD) This will be a straightforward mapping of the described API to a basic HTTP CRUD API using PUT, POST, GET, DELETE, and OPTIONS.

Placeholders:

Create:
POST /subscriptions
Content-Type: application/json

{
  "config": { ... }
  "filter": { ... },
  "protocol": "...",
  "protocolsettings": { ... },
  "sink": "..."
}

Note: no ID in the request

Retrieve:
GET /subscriptions/{id}

Delete:
DELETE /subscriptions/{id}

Update:
PUT /subscriptions/{id}
Content-Type: application/json

{
  "id": "...",
  "config": { ... }
  "filter": { ... },
  "protocol": "...",
  "protocolsettings": { ... },
  "sink": "..."
}

3.4. AMQP Binding for the Subscription API

(TBD) This will be a set of bi-directional exchanges for the respective operations.

4. Conformance

(TBD) Conformance clauses.