The HTTP Transport Binding for CloudEvents defines how events are mapped to HTTP 1.1 request and response messages.
This document is a working draft.
- 1.1. Conformance
- 1.2. Relation to HTTP
- 1.3. Content Modes
- 1.4. Event Formats
- 1.5. Security
- 2.1. contentType Attribute
- 2.2. data Attribute
- 3.2. Binary Content Mode
- 3.1. Structured Content Mode
CloudEvents is a standardized and transport-neutral definition of the structure and metadata description of events. This specification defines how the elements defined in the CloudEvents specification are to be used in HTTP 1.1 requests and response messages.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC2119.
This specification does not prescribe rules constraining the use or handling of specific HTTP methods, and it also does not constrain the HTTP target resource that is used for transferring or soliciting events.
Events can be transferred with all standard or application-defined HTTP request methods that support payload body transfers. Events can be also be transferred in HTTP responses and with all HTTP status codes that permit payload body transfers.
All examples herein that show HTTP methods, HTTP target URIs, and HTTP status codes are non-normative illustrations.
This specification also applies equivalently to HTTP/2 (RFC7540), which is compatible with HTTP 1.1 semantics.
This specification defines two content modes for transferring events: structured and binary. Every compliant implementation SHOULD support both modes.
In the structured content mode, event metadata attributes and event data are placed into the HTTP request or response body using an event format.
In the binary content mode, the value of the event data attribute is placed
into the HTTP request or response body as-is, with the contentType attribute
value declaring its media type; all other event attributes are mapped to HTTP
headers.
Event formats, used with the stuctured content mode, define how an event is expressed in a particular data format. All implementations of this specification MUST support the JSON event format, but MAY support any additional, including proprietary, formats.
This specification does not introduce any new security features for HTTP, or mandate specific existing features to be used. This specification applies identically to HTTP over TLS.
This specification does not further define any of the CloudEvents event attributes.
Two of the event attributes, contentType and data are handled specially
and mapped onto HTTP constructs, all other attributes are transferred as
metadata without further interpretation.
This mapping is intentionally robust against changes, including the addition
and removal of event attributes, and also accommodates vendor extensions to the
event metadata. Any mention of event attributes other than contentType and
data is exemplary.
The contentType attribute is assumed to contain a RFC2046
compliant media-type expression.
The data attribute is assumed to contain opaque application data that is
encoded as declared by the contentType attribute.
An application is free to hold the information in any in-memory representation
of its choosing, but as the value is transposed into HTTP as defined in this
specification, the assumption is that the data attribute value is made
available as a sequence of bytes.
For instance, if the declared contentType is
application/json;charset=utf-8, the expectation is that the data attribute
value is made available as UTF-8 encoded JSON text to HTTP.
The event binding is identical for both HTTP request and response messages.
The content mode is chosen by the sender of the event, which is either the requesting or the responding party. Gestures that might allow solicitation of events using a particular mode might be defined by an application, but are not defined here.
The receiver of the event can distinguish between the two modes by inspecting
the Content-Type header value. If the value is prefixed with the CloudEvents
media type application/cloudevents, indicating the use of a known event
format, the receiver uses structured mode, otherwise it
defaults to binary mode.
If a receiver detects the CloudEvents media type, but with an event format that
it cannot handle, for instance application/cloudevents+avro, it MAY still
treat the event as binary and forward it to another party as-is.
The binary content mode accommodates any shape of event data, and allows for efficient transfer and without transcoding effort.
For the binary mode, the HTTP Content-Type value maps directly to the
CloudEvents contentType attribute.
The data attribute byte-sequence is used as the HTTP
message body.
All CloudEvents attributes with exception of contentType and data
are individually mapped to and from distinct HTTP message headers.
The naming convention for the HTTP header mapping of attributes is:
* Each attribute name MUST be prefixed with "CE-"
* Each attribute name's first character MUST be capitalized
Examples:
* `eventTime` maps to `CE-EventTime`
* `eventID` maps to `CE-EventID`
* `cloudEventsVersion` maps to `CE-CloudEventsVersion`
For the extensions attribute, each entry of the extensions map
is mapped to a separate HTTP header. The extensions attribute itself is
not mapped to a header.
The naming convention for the extensions header mapping of attributes is:
* Each map entry name MUST be prefixed with "CE-X-"
* Each map entry name's first character MUST be capitalized
Examples:
* `example` maps to `CE-X-Example`
* `testExtension` maps to `CE-X-TestExtension`
The value for each HTTP header is constructed from the respective attribute's JSON value representation, compliant with the JSON event format specification.
Some CloudEvents metadata attributes can contain arbitrary UTF-8 string content, and per RFC7230 Section 3, HTTP headers MUST only use printable characters from the US-ASCII character set, and are terminated by a CRLF sequence.
Therefore, and analog to the encoding rules for Universal character set host names in URIs RFC3986 3.2.2, the JSON value MUST be encoded as follows:
Non-printable ASCII characters and non-ASCII characters MUST first be encoded according to UTF-8, and then each octet of the corresponding UTF-8 sequence MUST be percent-encoded to be represented as HTTP header characters, in compliance with RFC7230, sections 3, 3.2, 3.2.6. The rules for encoding of the percent character ('%') apply as defined in RFC 3986 Section 2.4..
JSON objects and arrays are NOT surrounded with single or double quotes.
This example shows the binary mode mapping of an event with an HTTP POST request:
POST /someresource HTTP/1.1
Host: webhook.example.com
CE-CloudEventsVersion: "0.1"
CE-EventType: "com.example.someevent"
CE-EventTime: "2018-04-05T03:56:24Z"
CE-EventID: "1234-1234-1234"
CE-Source: "/mycontext/subcontext"
.... further attributes ...
Content-Type: application/json; charset=utf-8
Content-Length: nnnn
{
... application data ...
}
This example shows a response containing an event:
HTTP/1.1 200 OK
CE-CloudEventsVersion: "0.1"
CE-EventType: "com.example.someevent"
CE-EventTime: "2018-04-05T03:56:24Z"
CE-EventID: "1234-1234-1234"
CE-Source: "/mycontext/subcontext"
.... further attributes ...
Content-Type: application/json; charset=utf-8
Content-Length: nnnn
{
... application data ...
}
The structured content mode keeps event metadata and data together in the payload, allowing simple forwarding of the same event across multiple routing hops, and across multiple transports.
The HTTP Content-Type header MUST be set to the media type of
an event format.
Example for the JSON format:
Content-Type: application/cloudevents+json; charset=UTF-8
The chosen event format defines how all attributes,
including the data attribute, are represented.
The event metadata and data is then rendered in accordance with the event format specification and the resulting data becomes the HTTP message body.
Implementations MAY include the same HTTP headers as defined for the binary mode.
All CloudEvents metadata attributes MUST be mapped into the payload, even if they are also mapped into HTTP headers.
This example shows a JSON event format encoded event, sent with a PUT request:
PUT /myresource HTTP/1.1
Host: webhook.example.com
Content-Type: application/cloudevents+json; charset=utf-8
Content-Length: nnnn
{
"cloudEventsVersion" : "0.1",
"eventType" : "com.example.someevent",
... further attributes omitted ...
"data" : {
... application data ...
}
}
This example shows a JSON encoded event retuned in a response:
HTTP/1.1 200 OK
Content-Type: application/cloudevents+json; charset=utf-8
Content-Length: nnnn
{
"cloudEventsVersion" : "0.1",
"eventType" : "com.example.someevent",
... further attributes omitted ...
"data" : {
... application data ...
}
}
- RFC2046 Multipurpose Internet Mail Extensions (MIME) Part Two: Media Types
- RFC2119 Key words for use in RFCs to Indicate Requirement Levels
- RFC2818 HTTP over TLS
- RFC3629 UTF-8, a transformation format of ISO 10646
- RFC3986 Uniform Resource Identifier (URI): Generic Syntax
- RFC4627 The application/json Media Type for JavaScript Object Notation (JSON)
- RFC4648 The Base16, Base32, and Base64 Data Encodings
- RFC6839 Additional Media Type Structured Syntax Suffixes
- RFC7159 The JavaScript Object Notation (JSON) Data Interchange Format
- RFC7230 Hypertext Transfer Protocol (HTTP/1.1): Message Syntax and Routing
- RFC7231 Hypertext Transfer Protocol (HTTP/1.1): Semantics and Content
- RFC7540 Hypertext Transfer Protocol Version 2 (HTTP/2)