The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 RFC2119 RFC8174 when, and only when, they appear in all capitals, as shown here.
This document is licensed under The Apache License, Version 2.0.
The OpenAPI Specification (OAS) defines a standard, language-agnostic interface to HTTP APIs which allows both humans and computers to discover and understand the capabilities of the service without access to source code, documentation, or through network traffic inspection. When properly defined, a consumer can understand and interact with the remote service with a minimal amount of implementation logic.
An OpenAPI Description can then be used by documentation generation tools to display the API, code generation tools to generate servers and clients in various programming languages, testing tools, and many other use cases.
For examples of OpenAPI usage and additional documentation, please visit [[?OpenAPI-Learn]].
For extension registries and other specifications published by the OpenAPI Initiative, as well as the authoritative rendering of this specification, please visit spec.openapis.org.
An OpenAPI Description (OAD) formally describes the surface of an API and its semantics. It is composed of an entry document, which must be an OpenAPI Document, and any/all of its referenced documents. An OAD uses and conforms to the OpenAPI Specification, and MUST contain at least one paths field, components field, or webhooks field.
An OpenAPI Document is a single JSON or YAML document that conforms to the OpenAPI Specification. An OpenAPI Document compatible with OAS 3.*.* contains a required openapi
field which designates the version of the OAS that it uses.
A "schema" is a formal description of syntax and structure. This document serves as the schema for the OpenAPI Specification format; a non-authoritative JSON Schema based on this document is also provided on spec.openapis.org for informational purposes. This specification also uses schemas in the form of the Schema Object.
When capitalized, the word "Object" refers to any of the Objects that are named by section headings in this document.
Path templating refers to the usage of template expressions, delimited by curly braces ({}
), to mark a section of a URL path as replaceable using path parameters.
Each template expression in the path MUST correspond to a path parameter that is included in the Path Item itself and/or in each of the Path Item's Operations. An exception is if the path item is empty, for example due to ACL constraints, matching path parameters are not required.
The value for these path parameters MUST NOT contain any unescaped "generic syntax" characters described by RFC3986: forward slashes (/
), question marks (?
), or hashes (#
).
Media type definitions are spread across several resources. The media type definitions SHOULD be in compliance with RFC6838.
Some examples of possible media type definitions:
text/plain; charset=utf-8
application/json
application/vnd.github+json
application/vnd.github.v3+json
application/vnd.github.v3.raw+json
application/vnd.github.v3.text+json
application/vnd.github.v3.html+json
application/vnd.github.v3.full+json
application/vnd.github.v3.diff
application/vnd.github.v3.patch
The HTTP Status Codes are used to indicate the status of the executed operation. Status codes SHOULD be selected from the available status codes registered in the IANA Status Code Registry.
As most field names and values in the OpenAPI Specification are case-sensitive, this document endeavors to call out any case-insensitive names and values. However, the case sensitivity of field names and values that map directly to HTTP concepts follow the case sensitivity rules of HTTP, even if this document does not make a note of every concept.
This specification deems certain situations to have either undefined or implementation-defined behavior.
Behavior described as undefined is likely, at least in some circumstances, to result in outcomes that contradict the specification. This description is used when detecting the contradiction is impossible or impractical. Implementations MAY support undefined scenarios for historical reasons, including ambiguous text in prior versions of the specification. This support might produce correct outcomes in many cases, but relying on it is NOT RECOMMENDED as there is no guarantee that it will work across all tools or with future specification versions, even if those versions are otherwise strictly compatible with this one.
Behavior described as implementation-defined allows implementations to choose which of several different-but-compliant approaches to a requirement to implement. This documents ambiguous requirements that API description authors are RECOMMENDED to avoid in order to maximize interoperability. Unlike undefined behavior, it is safe to rely on implementation-defined behavior if and only if it can be guaranteed that all relevant tools support the same behavior.
The OpenAPI Specification is versioned using a major
.minor
.patch
versioning scheme. The major
.minor
portion of the version string (for example 3.1
) SHALL designate the OAS feature set. .patch
versions address errors in, or provide clarifications to, this document, not the feature set. Tooling which supports OAS 3.1 SHOULD be compatible with all OAS 3.1.* versions. The patch version SHOULD NOT be considered by tooling, making no distinction between 3.1.0
and 3.1.1
for example.
Occasionally, non-backwards compatible changes may be made in minor
versions of the OAS where impact is believed to be low relative to the benefit provided.
An OpenAPI Document that conforms to the OpenAPI Specification is itself a JSON object, which may be represented either in JSON or YAML format.
For example, if a field has an array value, the JSON array representation will be used:
{
"field": [1, 2, 3]
}
All field names in the specification are case sensitive. This includes all fields that are used as keys in a map, except where explicitly noted that keys are case insensitive.
The schema exposes two types of fields: fixed fields, which have a declared name, and patterned fields, which have a declared pattern for the field name.
Patterned fields MUST have unique names within the containing object.
In order to preserve the ability to round-trip between YAML and JSON formats, YAML version 1.2 is RECOMMENDED along with some additional constraints:
- Tags MUST be limited to those allowed by YAML's JSON schema ruleset, which defines a subset of the YAML syntax and is unrelated to [[JSON-Schema-2020-12|JSON Schema]].
- Keys used in YAML maps MUST be limited to a scalar string, as defined by the YAML Failsafe schema ruleset.
Note: While APIs may be described by OpenAPI Descriptions in either YAML or JSON format, the API request and response bodies and other content are not required to be JSON or YAML.
An OpenAPI Description (OAD) MAY be made up of a single JSON or YAML document or be divided into multiple, connected parts at the discretion of the author. In the latter case, Reference Object, Path Item Object and Schema Object $ref
fields, as well as the Link Object operationRef
field, and the URI form of the Discriminator Object mapping
field, are used to identify the referenced elements.
In a multi-document OAD, the document containing the OpenAPI Object where parsing begins is known as that OAD's entry document.
It is RECOMMENDED that the entry document of an OAD be named: openapi.json
or openapi.yaml
.
In order to properly handle Schema Objects, OAS 3.1 inherits the parsing requirements of JSON Schema Specification Draft 2020-12, with appropriate modifications regarding base URIs as specified in Relative References In URIs.
This includes a requirement to parse complete documents before deeming a Schema Object reference to be unresolvable, in order to detect keywords that might provide the reference target or impact the determination of the appropriate base URI.
Implementations MAY support complete-document parsing in any of the following ways:
- Detecting OpenAPI or JSON Schema documents using media types
- Detecting OpenAPI documents through the root
openapi
field - Detecting JSON Schema documents through detecting keywords or otherwise successfully parsing the document in accordance with the JSON Schema specification
- Detecting a document containing a referenceable Object at its root based on the expected type of the reference
- Allowing users to configure the type of documents that might be loaded due to a reference to a non-root Object
Implementations that parse referenced fragments of OpenAPI content without regard for the content of the rest of the containing document will miss keywords that change the meaning and behavior of the reference target. In particular, failing to take into account keywords that change the base URI introduces security risks by causing references to resolve to unintended URIs, with unpredictable results. While some implementations support this sort of parsing due to the requirements of past versions of this specification, in version 3.1, the result of parsing fragments in isolation is undefined and likely to contradict the requirements of this specification.
While it is possible to structure certain OpenAPI Descriptions to ensure that they will behave correctly when references are parsed as isolated fragments, depending on this is NOT RECOMMENDED. This specification does not explicitly enumerate the conditions under which such behavior is safe and provides no guarantee for continued safety in any future versions of the OAS.
A special case of parsing fragments of OAS content would be if such fragments are embedded in another format, referred to as an embedding format with respect to the OAS. Note that the OAS itself is an embedding format with respect to JSON Schema, which is embedded as Schema Objects. It is the responsibility of an embedding format to define how to parse embedded content, and OAS implementations that do not document support for an embedding format cannot be expected to parse embedded OAS content correctly.
JSON or YAML objects within an OAD are interpreted as specific Objects (such as Operation Objects, Response Objects, Reference Objects, etc.) based on their context. Depending on how references are arranged, a given JSON or YAML object can be interpreted in multiple different contexts:
- As the root object of the entry document, which is always interpreted as an OpenAPI Object
- As the Object type implied by its parent Object within the document
- As a reference target, with the Object type matching the reference source's context
If the same JSON/YAML object is parsed multiple times and the respective contexts require it to be parsed as different Object types, the resulting behavior is implementation defined, and MAY be treated as an error if detected. An example would be referencing an empty Schema Object under #/components/schemas
where a Path Item Object is expected, as an empty object is valid for both types. For maximum interoperability, it is RECOMMENDED that OpenAPI Description authors avoid such scenarios.
Several features of this specification require resolution of non-URI-based connections to some other part of the OpenAPI Description (OAD).
These connections are unambiguously resolved in single-document OADs, but the resolution process in multi-document OADs is implementation-defined, within the constraints described in this section. In some cases, an unambiguous URI-based alternative is available, and OAD authors are RECOMMENDED to always use the alternative:
Source | Target | Alternative |
---|---|---|
Security Requirement Object {name} |
Security Scheme Object name under the Components Object | n/a |
Discriminator Object mapping (implicit, or explicit name syntax) |
Schema Object name under the Components Object | mapping (explicit URI syntax) |
Operation Object tags |
Tag Object name (in the OpenAPI Object's tags array) |
n/a |
Link Object operationId |
Path Item Object operationId |
operationRef |
A fifth implicit connection involves appending the templated URL paths of the Paths Object to the appropriate Server Object's url
field.
This is unambiguous because only the entry document's Paths Object contributes URLs to the described API.
It is RECOMMENDED to consider all Operation Objects from all parsed documents when resolving any Link Object operationId
.
This requires parsing all referenced documents prior to determining an operationId
to be unresolvable.
The implicit connections in the Security Requirement Object and Discriminator Object rely on the component name, which is the name of the property holding the component in the appropriately typed sub-object of the Components Object.
For example, the component name of the Schema Object at #/components/schemas/Foo
is Foo
.
The implicit connection of tags
in the Operation Object uses the name
field of Tag Objects, which (like the Components Object) are found under the root OpenAPI Object.
This means resolving component names and tag names both depend on starting from the correct OpenAPI Object.
For resolving component and tag name connections from a referenced (non-entry) document, it is RECOMMENDED that tools resolve from the entry document, rather than the current document. This allows Security Scheme Objects and Tag Objects to be defined next to the API's deployment information (the top-level array of Server Objects), and treated as an interface for referenced documents to access.
The interface approach can also work for Discriminator Objects and Schema Objects, but it is also possible to keep the Discriminator Object's behavior within a single document using the relative URI-reference syntax of mapping
.
There are no URI-based alternatives for the Security Requirement Object or for the Operation Object's tags
field.
These limitations are expected to be addressed in a future release.
See Appendix F: Resolving Security Requirements in a Referenced Document for an example of the possible resolutions, including which one is recommended by this section.
The behavior for Discrimator Object non-URI mappings and for the Operation Object's tags
field operate on the same principles.
Note that no aspect of implicit connection resolution changes how URIs are resolved, or restricts their possible targets.
Data types in the OAS are based on the types defined by the JSON Schema Validation Specification Draft 2020-12: "null", "boolean", "object", "array", "number", "string", or "integer". Models are defined using the Schema Object, which is a superset of the JSON Schema Specification Draft 2020-12.
JSON Schema keywords and format
values operate on JSON "instances" which may be one of the six JSON data types, "null", "boolean", "object", "array", "number", or "string", with certain keywords and formats only applying to a specific type. For example, the pattern
keyword and the date-time
format only apply to strings, and treat any instance of the other five types as automatically valid. This means JSON Schema keywords and formats do NOT implicitly require the expected type. Use the type
keyword to explicitly constrain the type.
Note that the type
keyword allows "integer"
as a value for convenience, but keyword and format applicability does not recognize integers as being of a distinct JSON type from other numbers because [[RFC7159|JSON]] itself does not make that distinction. Since there is no distinct JSON integer type, JSON Schema defines integers mathematically. This means that both 1
and 1.0
are equivalent, and are both considered to be integers.
As defined by the JSON Schema Validation specification, data types can have an optional modifier keyword: format
. As described in that specification, format
is treated as a non-validating annotation by default; the ability to validate format
varies across implementations.
The OpenAPI Initiative also hosts a Format Registry for formats defined by OAS users and other specifications. Support for any registered format is strictly OPTIONAL, and support for one registered format does not imply support for any others.
Types that are not accompanied by a format
keyword follow the type definition in the JSON Schema. Tools that do not recognize a specific format
MAY default back to the type
alone, as if the format
is not specified.
For the purpose of JSON Schema validation, each format should specify the set of JSON data types for which it applies. In this registry, these types are shown in the "JSON Data Type" column.
The formats defined by the OAS are:
format |
JSON Data Type | Comments |
---|---|---|
int32 |
number | signed 32 bits |
int64 |
number | signed 64 bits (a.k.a long) |
float |
number | |
double |
number | |
password |
string | A hint to obscure the value. |
As noted under Data Type, both type: number
and type: integer
are considered to be numbers in the data model.
The OAS can describe either raw or encoded binary data.
- raw binary is used where unencoded binary data is allowed, such as when sending a binary payload as the entire HTTP message body, or as part of a
multipart/*
payload that allows binary parts - encoded binary is used where binary data is embedded in a text-only format such as
application/json
orapplication/x-www-form-urlencoded
(either as a message body or in the URL query string).
In the following table showing how to use Schema Object keywords for binary data, we use image/png
as an example binary media type. Any binary media type, including application/octet-stream
, is sufficient to indicate binary content.
Keyword | Raw | Encoded | Comments |
---|---|---|---|
type |
omit | string |
raw binary is outside of type |
contentMediaType |
image/png |
image/png |
can sometimes be omitted if redundant (see below) |
contentEncoding |
omit | base64 or base64url |
other encodings are allowed |
Note that the encoding indicated by contentEncoding
, which inflates the size of data in order to represent it as 7-bit ASCII text, is unrelated to HTTP's Content-Encoding
header, which indicates whether and how a message body has been compressed and is applied after all content serialization described in this section has occurred. Since HTTP allows unencoded binary message bodies, there is no standardized HTTP header for indicating base64 or similar encoding of an entire message body.
Using a contentEncoding
of base64url
ensures that URL encoding (as required in the query string and in message bodies of type application/x-www-form-urlencoded
) does not need to further encode any part of the already-encoded binary data.
The contentMediaType
keyword is redundant if the media type is already set:
- as the key for a MediaType Object
- in the
contentType
field of an Encoding Object
If the Schema Object will be processed by a non-OAS-aware JSON Schema implementation, it may be useful to include contentMediaType
even if it is redundant. However, if contentMediaType
contradicts a relevant Media Type Object or Encoding Object, then contentMediaType
SHALL be ignored.
The maxLength
keyword MAY be used to set an expected upper bound on the length of a streaming payload. The keyword can be applied to either string data, including encoded binary data, or to unencoded binary data. For unencoded binary, the length is the number of octets.
The following table shows how to migrate from OAS 3.0 binary data descriptions, continuing to use image/png
as the example binary media type:
OAS < 3.1 | OAS 3.1 | Comments |
---|---|---|
type: string format: binary |
contentMediaType: image/png |
if redundant, can be omitted, often resulting in an empty Schema Object |
type: string format: byte |
type: string contentMediaType: image/png contentEncoding: base64 |
note that base64url can be used to avoid re-encoding the base64 string to be URL-safe |
Throughout the specification description
fields are noted as supporting CommonMark markdown formatting.
Where OpenAPI tooling renders rich text it MUST support, at a minimum, markdown syntax as described by CommonMark 0.27. Tooling MAY choose to ignore some CommonMark or extension features to address security concerns.
While the framing of CommonMark 0.27 as a minimum requirement means that tooling MAY choose to implement extensions on top of it, note that any such extensions are by definition implementation-defined and will not be interoperable. OpenAPI Description authors SHOULD consider how text using such extensions will be rendered by tools that offer only the minimum support.
URIs used as references within an OpenAPI Description, or to external documentation or other supplementary information such as a license, are resolved as identifiers, and described by this specification as URIs. As noted under Parsing Documents, this specification inherits JSON Schema Specification Draft 2020-12's requirements for loading documents and associating them with their expected URIs, which might not match their current location. This feature is used both for working in development or test environments without having to change the URIs, and for working within restrictive network configurations or security policies.
Note that some URI fields are named url
for historical reasons, but the descriptive text for those fields uses the correct "URI" terminology.
Unless specified otherwise, all fields that are URIs MAY be relative references as defined by RFC3986.
Relative references in Schema Objects, including any that appear as $id
values, use the nearest parent $id
as a Base URI, as described by JSON Schema Specification Draft 2020-12.
Relative URI references in other Objects, and in Schema Objects where no parent schema contains an $id
, MUST be resolved using the referring document's base URI, which is determined in accordance with [[RFC3986]] Section 5.1.2 – 5.1.4.
In practice, this is usually the retrieval URI of the document, which MAY be determined based on either its current actual location or a user-supplied expected location.
If a URI contains a fragment identifier, then the fragment should be resolved per the fragment resolution mechanism of the referenced document. If the representation of the referenced document is JSON or YAML, then the fragment identifier SHOULD be interpreted as a JSON-Pointer as per RFC6901.
Relative references in CommonMark hyperlinks are resolved in their rendered context, which might differ from the context of the API description.
API endpoints are by definition accessed as locations, and are described by this specification as URLs.
Unless specified otherwise, all fields that are URLs MAY be relative references as defined by RFC3986. Unless specified otherwise, relative references are resolved using the URLs defined in the Server Object as a Base URL. Note that these themselves MAY be relative to the referring document.
This section describes the structure of the OpenAPI Description format. This text is the only normative description of the format. A JSON Schema is hosted on spec.openapis.org for informational purposes. If the JSON Schema differs from this section, then this section MUST be considered authoritative.
In the following description, if a field is not explicitly REQUIRED or described with a MUST or SHALL, it can be considered OPTIONAL.
This is the root object of the OpenAPI Description.
Field Name | Type | Description |
---|---|---|
openapi | string |
REQUIRED. This string MUST be the version number of the OpenAPI Specification that the OpenAPI Document uses. The openapi field SHOULD be used by tooling to interpret the OpenAPI Document. This is not related to the API info.version string. |
info | Info Object | REQUIRED. Provides metadata about the API. The metadata MAY be used by tooling as required. |
jsonSchemaDialect | string |
The default value for the $schema keyword within Schema Objects contained within this OAS document. This MUST be in the form of a URI. |
servers | [Server Object] | An array of Server Objects, which provide connectivity information to a target server. If the servers field is not provided, or is an empty array, the default value would be a Server Object with a url value of / . |
paths | Paths Object | The available paths and operations for the API. |
webhooks | Map[string , Path Item Object] |
The incoming webhooks that MAY be received as part of this API and that the API consumer MAY choose to implement. Closely related to the callbacks feature, this section describes requests initiated other than by an API call, for example by an out of band registration. The key name is a unique string to refer to each webhook, while the (optionally referenced) Path Item Object describes a request that may be initiated by the API provider and the expected responses. An example is available. |
components | Components Object | An element to hold various Objects for the OpenAPI Description. |
security | [Security Requirement Object] | A declaration of which security mechanisms can be used across the API. The list of values includes alternative Security Requirement Objects that can be used. Only one of the Security Requirement Objects need to be satisfied to authorize a request. Individual operations can override this definition. The list can be incomplete, up to being empty or absent. To make security explicitly optional, an empty security requirement ({} ) can be included in the array. |
tags | [Tag Object] | A list of tags used by the OpenAPI Description with additional metadata. The order of the tags can be used to reflect on their order by the parsing tools. Not all tags that are used by the Operation Object must be declared. The tags that are not declared MAY be organized randomly or based on the tools' logic. Each tag name in the list MUST be unique. |
externalDocs | External Documentation Object | Additional external documentation. |
This object MAY be extended with Specification Extensions.
The object provides metadata about the API. The metadata MAY be used by the clients if needed, and MAY be presented in editing or documentation generation tools for convenience.
Field Name | Type | Description |
---|---|---|
title | string |
REQUIRED. The title of the API. |
summary | string |
A short summary of the API. |
description | string |
A description of the API. CommonMark syntax MAY be used for rich text representation. |
termsOfService | string |
A URI for the Terms of Service for the API. This MUST be in the form of a URI. |
contact | Contact Object | The contact information for the exposed API. |
license | License Object | The license information for the exposed API. |
version | string |
REQUIRED. The version of the OpenAPI Document (which is distinct from the OpenAPI Specification version or the version of the API being described or the version of the OpenAPI Description). |
This object MAY be extended with Specification Extensions.
{
"title": "Example Pet Store App",
"summary": "A pet store manager.",
"description": "This is an example server for a pet store.",
"termsOfService": "https://example.com/terms/",
"contact": {
"name": "API Support",
"url": "https://www.example.com/support",
"email": "[email protected]"
},
"license": {
"name": "Apache 2.0",
"url": "https://www.apache.org/licenses/LICENSE-2.0.html"
},
"version": "1.0.1"
}
title: Example Pet Store App
summary: A pet store manager.
description: This is an example server for a pet store.
termsOfService: https://example.com/terms/
contact:
name: API Support
url: https://www.example.com/support
email: [email protected]
license:
name: Apache 2.0
url: https://www.apache.org/licenses/LICENSE-2.0.html
version: 1.0.1
Contact information for the exposed API.
This object MAY be extended with Specification Extensions.
{
"name": "API Support",
"url": "https://www.example.com/support",
"email": "[email protected]"
}
name: API Support
url: https://www.example.com/support
email: [email protected]
License information for the exposed API.
Field Name | Type | Description |
---|---|---|
name | string |
REQUIRED. The license name used for the API. |
identifier | string |
An SPDX license expression for the API. The identifier field is mutually exclusive of the url field. |
url | string |
A URI for the license used for the API. This MUST be in the form of a URI. The url field is mutually exclusive of the identifier field. |
This object MAY be extended with Specification Extensions.
{
"name": "Apache 2.0",
"identifier": "Apache-2.0"
}
name: Apache 2.0
identifier: Apache-2.0
An object representing a Server.
Field Name | Type | Description |
---|---|---|
url | string |
REQUIRED. A URL to the target host. This URL supports Server Variables and MAY be relative, to indicate that the host location is relative to the location where the document containing the Server Object is being served. Variable substitutions will be made when a variable is named in { braces} . |
description | string |
An optional string describing the host designated by the URL. CommonMark syntax MAY be used for rich text representation. |
variables | Map[string , Server Variable Object] |
A map between a variable name and its value. The value is used for substitution in the server's URL template. |
This object MAY be extended with Specification Extensions.
A single server would be described as:
{
"url": "https://development.gigantic-server.com/v1",
"description": "Development server"
}
url: https://development.gigantic-server.com/v1
description: Development server
The following shows how multiple servers can be described, for example, at the OpenAPI Object's servers
:
{
"servers": [
{
"url": "https://development.gigantic-server.com/v1",
"description": "Development server"
},
{
"url": "https://staging.gigantic-server.com/v1",
"description": "Staging server"
},
{
"url": "https://api.gigantic-server.com/v1",
"description": "Production server"
}
]
}
servers:
- url: https://development.gigantic-server.com/v1
description: Development server
- url: https://staging.gigantic-server.com/v1
description: Staging server
- url: https://api.gigantic-server.com/v1
description: Production server
The following shows how variables can be used for a server configuration:
{
"servers": [
{
"url": "https://{username}.gigantic-server.com:{port}/{basePath}",
"description": "The production API server",
"variables": {
"username": {
"default": "demo",
"description": "A user-specific subdomain. Use `demo` for a free sandbox environment."
},
"port": {
"enum": ["8443", "443"],
"default": "8443"
},
"basePath": {
"default": "v2"
}
}
}
]
}
servers:
- url: https://{username}.gigantic-server.com:{port}/{basePath}
description: The production API server
variables:
username:
# note! no enum here means it is an open value
default: demo
description: A user-specific subdomain. Use `demo` for a free sandbox environment.
port:
enum:
- '8443'
- '443'
default: '8443'
basePath:
# open meaning there is the opportunity to use special base paths as assigned by the provider, default is `v2`
default: v2
An object representing a Server Variable for server URL template substitution.
Field Name | Type | Description |
---|---|---|
enum | [string ] |
An enumeration of string values to be used if the substitution options are from a limited set. The array MUST NOT be empty. |
default | string |
REQUIRED. The default value to use for substitution, which SHALL be sent if an alternate value is not supplied. If the enum is defined, the value MUST exist in the enum's values. Note that this behavior is different from the Schema Object's default keyword, which documents the receiver's behavior rather than inserting the value into the data. |
description | string |
An optional description for the server variable. CommonMark syntax MAY be used for rich text representation. |
This object MAY be extended with Specification Extensions.
Holds a set of reusable objects for different aspects of the OAS. All objects defined within the Components Object will have no effect on the API unless they are explicitly referenced from outside the Components Object.
Field Name | Type | Description |
---|---|---|
schemas | Map[string , Schema Object] |
An object to hold reusable Schema Objects. |
responses | Map[string , Response Object | Reference Object] |
An object to hold reusable Response Objects. |
parameters | Map[string , Parameter Object | Reference Object] |
An object to hold reusable Parameter Objects. |
examples | Map[string , Example Object | Reference Object] |
An object to hold reusable Example Objects. |
requestBodies | Map[string , Request Body Object | Reference Object] |
An object to hold reusable Request Body Objects. |
headers | Map[string , Header Object | Reference Object] |
An object to hold reusable Header Objects. |
securitySchemes | Map[string , Security Scheme Object | Reference Object] |
An object to hold reusable Security Scheme Objects. |
links | Map[string , Link Object | Reference Object] |
An object to hold reusable Link Objects. |
callbacks | Map[string , Callback Object | Reference Object] |
An object to hold reusable Callback Objects. |
pathItems | Map[string , Path Item Object] |
An object to hold reusable Path Item Objects. |
This object MAY be extended with Specification Extensions.
All the fixed fields declared above are objects that MUST use keys that match the regular expression: ^[a-zA-Z0-9\.\-_]+$
.
Field Name Examples:
User
User_1
User_Name
user-name
my.org.User
"components": {
"schemas": {
"GeneralError": {
"type": "object",
"properties": {
"code": {
"type": "integer",
"format": "int32"
},
"message": {
"type": "string"
}
}
},
"Category": {
"type": "object",
"properties": {
"id": {
"type": "integer",
"format": "int64"
},
"name": {
"type": "string"
}
}
},
"Tag": {
"type": "object",
"properties": {
"id": {
"type": "integer",
"format": "int64"
},
"name": {
"type": "string"
}
}
}
},
"parameters": {
"skipParam": {
"name": "skip",
"in": "query",
"description": "number of items to skip",
"required": true,
"schema": {
"type": "integer",
"format": "int32"
}
},
"limitParam": {
"name": "limit",
"in": "query",
"description": "max records to return",
"required": true,
"schema" : {
"type": "integer",
"format": "int32"
}
}
},
"responses": {
"NotFound": {
"description": "Entity not found."
},
"IllegalInput": {
"description": "Illegal input for operation."
},
"GeneralError": {
"description": "General Error",
"content": {
"application/json": {
"schema": {
"$ref": "#/components/schemas/GeneralError"
}
}
}
}
},
"securitySchemes": {
"api_key": {
"type": "apiKey",
"name": "api-key",
"in": "header"
},
"petstore_auth": {
"type": "oauth2",
"flows": {
"implicit": {
"authorizationUrl": "https://example.org/api/oauth/dialog",
"scopes": {
"write:pets": "modify pets in your account",
"read:pets": "read your pets"
}
}
}
}
}
}
components:
schemas:
GeneralError:
type: object
properties:
code:
type: integer
format: int32
message:
type: string
Category:
type: object
properties:
id:
type: integer
format: int64
name:
type: string
Tag:
type: object
properties:
id:
type: integer
format: int64
name:
type: string
parameters:
skipParam:
name: skip
in: query
description: number of items to skip
required: true
schema:
type: integer
format: int32
limitParam:
name: limit
in: query
description: max records to return
required: true
schema:
type: integer
format: int32
responses:
NotFound:
description: Entity not found.
IllegalInput:
description: Illegal input for operation.
GeneralError:
description: General Error
content:
application/json:
schema:
$ref: '#/components/schemas/GeneralError'
securitySchemes:
api_key:
type: apiKey
name: api-key
in: header
petstore_auth:
type: oauth2
flows:
implicit:
authorizationUrl: https://example.org/api/oauth/dialog
scopes:
write:pets: modify pets in your account
read:pets: read your pets
Holds the relative paths to the individual endpoints and their operations. The path is appended to the URL from the Server Object in order to construct the full URL. The Paths Object MAY be empty, due to Access Control List (ACL) constraints.
Field Pattern | Type | Description |
---|---|---|
/{path} | Path Item Object | A relative path to an individual endpoint. The field name MUST begin with a forward slash (/ ). The path is appended (no relative URL resolution) to the expanded URL from the Server Object's url field in order to construct the full URL. Path templating is allowed. When matching URLs, concrete (non-templated) paths would be matched before their templated counterparts. Templated paths with the same hierarchy but different templated names MUST NOT exist as they are identical. In case of ambiguous matching, it's up to the tooling to decide which one to use. |
This object MAY be extended with Specification Extensions.
Assuming the following paths, the concrete definition, /pets/mine
, will be matched first if used:
/pets/{petId}
/pets/mine
The following paths are considered identical and invalid:
/pets/{petId}
/pets/{name}
The following may lead to ambiguous resolution:
/{entity}/me
/books/{id}
{
"/pets": {
"get": {
"description": "Returns all pets from the system that the user has access to",
"responses": {
"200": {
"description": "A list of pets.",
"content": {
"application/json": {
"schema": {
"type": "array",
"items": {
"$ref": "#/components/schemas/pet"
}
}
}
}
}
}
}
}
}
/pets:
get:
description: Returns all pets from the system that the user has access to
responses:
'200':
description: A list of pets.
content:
application/json:
schema:
type: array
items:
$ref: '#/components/schemas/pet'
Describes the operations available on a single path. A Path Item MAY be empty, due to ACL constraints. The path itself is still exposed to the documentation viewer but they will not know which operations and parameters are available.
Field Name | Type | Description |
---|---|---|
$ref | string |
Allows for a referenced definition of this path item. The value MUST be in the form of a URI, and the referenced structure MUST be in the form of a Path Item Object. In case a Path Item Object field appears both in the defined object and the referenced object, the behavior is undefined. See the rules for resolving Relative References. Note: The behavior of $ref with adjacent properties is likely to change in future versions of this specification to bring it into closer alignment with the behavior of the Reference Object. |
summary | string |
An optional string summary, intended to apply to all operations in this path. |
description | string |
An optional string description, intended to apply to all operations in this path. CommonMark syntax MAY be used for rich text representation. |
get | Operation Object | A definition of a GET operation on this path. |
put | Operation Object | A definition of a PUT operation on this path. |
post | Operation Object | A definition of a POST operation on this path. |
delete | Operation Object | A definition of a DELETE operation on this path. |
options | Operation Object | A definition of a OPTIONS operation on this path. |
head | Operation Object | A definition of a HEAD operation on this path. |
patch | Operation Object | A definition of a PATCH operation on this path. |
trace | Operation Object | A definition of a TRACE operation on this path. |
servers | [Server Object] | An alternative servers array to service all operations in this path. If a servers array is specified at the OpenAPI Object level, it will be overridden by this value. |
parameters | [Parameter Object | Reference Object] | A list of parameters that are applicable for all the operations described under this path. These parameters can be overridden at the operation level, but cannot be removed there. The list MUST NOT include duplicated parameters. A unique parameter is defined by a combination of a name and location. The list can use the Reference Object to link to parameters that are defined in the OpenAPI Object's components.parameters . |
This object MAY be extended with Specification Extensions.
{
"get": {
"description": "Returns pets based on ID",
"summary": "Find pets by ID",
"operationId": "getPetsById",
"responses": {
"200": {
"description": "pet response",
"content": {
"*/*": {
"schema": {
"type": "array",
"items": {
"$ref": "#/components/schemas/Pet"
}
}
}
}
},
"default": {
"description": "error payload",
"content": {
"text/html": {
"schema": {
"$ref": "#/components/schemas/ErrorModel"
}
}
}
}
}
},
"parameters": [
{
"name": "id",
"in": "path",
"description": "ID of pet to use",
"required": true,
"schema": {
"type": "array",
"items": {
"type": "string"
}
},
"style": "simple"
}
]
}
get:
description: Returns pets based on ID
summary: Find pets by ID
operationId: getPetsById
responses:
'200':
description: pet response
content:
'*/*':
schema:
type: array
items:
$ref: '#/components/schemas/Pet'
default:
description: error payload
content:
text/html:
schema:
$ref: '#/components/schemas/ErrorModel'
parameters:
- name: id
in: path
description: ID of pet to use
required: true
schema:
type: array
items:
type: string
style: simple
Describes a single API operation on a path.
Field Name | Type | Description |
---|---|---|
tags | [string ] |
A list of tags for API documentation control. Tags can be used for logical grouping of operations by resources or any other qualifier. |
summary | string |
A short summary of what the operation does. |
description | string |
A verbose explanation of the operation behavior. CommonMark syntax MAY be used for rich text representation. |
externalDocs | External Documentation Object | Additional external documentation for this operation. |
operationId | string |
Unique string used to identify the operation. The id MUST be unique among all operations described in the API. The operationId value is case-sensitive. Tools and libraries MAY use the operationId to uniquely identify an operation, therefore, it is RECOMMENDED to follow common programming naming conventions. |
parameters | [Parameter Object | Reference Object] | A list of parameters that are applicable for this operation. If a parameter is already defined at the Path Item, the new definition will override it but can never remove it. The list MUST NOT include duplicated parameters. A unique parameter is defined by a combination of a name and location. The list can use the Reference Object to link to parameters that are defined in the OpenAPI Object's components.parameters . |
requestBody | Request Body Object | Reference Object | The request body applicable for this operation. The requestBody is fully supported in HTTP methods where the HTTP 1.1 specification RFC7231 has explicitly defined semantics for request bodies. In other cases where the HTTP spec is vague (such as GET, HEAD and DELETE), requestBody is permitted but does not have well-defined semantics and SHOULD be avoided if possible. |
responses | Responses Object | The list of possible responses as they are returned from executing this operation. |
callbacks | Map[string , Callback Object | Reference Object] |
A map of possible out-of band callbacks related to the parent operation. The key is a unique identifier for the Callback Object. Each value in the map is a Callback Object that describes a request that may be initiated by the API provider and the expected responses. |
deprecated | boolean |
Declares this operation to be deprecated. Consumers SHOULD refrain from usage of the declared operation. Default value is false . |
security | [Security Requirement Object] | A declaration of which security mechanisms can be used for this operation. The list of values includes alternative Security Requirement Objects that can be used. Only one of the Security Requirement Objects need to be satisfied to authorize a request. To make security optional, an empty security requirement ({} ) can be included in the array. This definition overrides any declared top-level security . To remove a top-level security declaration, an empty array can be used. |
servers | [Server Object] | An alternative servers array to service this operation. If a servers array is specified at the Path Item Object or OpenAPI Object level, it will be overridden by this value. |
This object MAY be extended with Specification Extensions.
{
"tags": ["pet"],
"summary": "Updates a pet in the store with form data",
"operationId": "updatePetWithForm",
"parameters": [
{
"name": "petId",
"in": "path",
"description": "ID of pet that needs to be updated",
"required": true,
"schema": {
"type": "string"
}
}
],
"requestBody": {
"content": {
"application/x-www-form-urlencoded": {
"schema": {
"type": "object",
"properties": {
"name": {
"description": "Updated name of the pet",
"type": "string"
},
"status": {
"description": "Updated status of the pet",
"type": "string"
}
},
"required": ["status"]
}
}
}
},
"responses": {
"200": {
"description": "Pet updated.",
"content": {
"application/json": {},
"application/xml": {}
}
},
"405": {
"description": "Method Not Allowed",
"content": {
"application/json": {},
"application/xml": {}
}
}
},
"security": [
{
"petstore_auth": ["write:pets", "read:pets"]
}
]
}
tags:
- pet
summary: Updates a pet in the store with form data
operationId: updatePetWithForm
parameters:
- name: petId
in: path
description: ID of pet that needs to be updated
required: true
schema:
type: string
requestBody:
content:
application/x-www-form-urlencoded:
schema:
type: object
properties:
name:
description: Updated name of the pet
type: string
status:
description: Updated status of the pet
type: string
required:
- status
responses:
'200':
description: Pet updated.
content:
application/json: {}
application/xml: {}
'405':
description: Method Not Allowed
content:
application/json: {}
application/xml: {}
security:
- petstore_auth:
- write:pets
- read:pets
Allows referencing an external resource for extended documentation.
Field Name | Type | Description |
---|---|---|
description | string |
A description of the target documentation. CommonMark syntax MAY be used for rich text representation. |
url | string |
REQUIRED. The URI for the target documentation. This MUST be in the form of a URI. |
This object MAY be extended with Specification Extensions.
{
"description": "Find more info here",
"url": "https://example.com"
}
description: Find more info here
url: https://example.com
Describes a single operation parameter.
A unique parameter is defined by a combination of a name and location.
See Appendix E for a detailed examination of percent-encoding concerns, including interactions with the application/x-www-form-urlencoded
query string format.
There are four possible parameter locations specified by the in
field:
- path - Used together with Path Templating, where the parameter value is actually part of the operation's URL. This does not include the host or base path of the API. For example, in
/items/{itemId}
, the path parameter isitemId
. - query - Parameters that are appended to the URL. For example, in
/items?id=###
, the query parameter isid
. - header - Custom headers that are expected as part of the request. Note that RFC7230 states header names are case insensitive.
- cookie - Used to pass a specific cookie value to the API.
The rules for serialization of the parameter are specified in one of two ways.
Parameter Objects MUST include either a content
field or a schema
field, but not both.
See Appendix B for a discussion of converting values of various types to string representations.
These fields MAY be used with either content
or schema
.
Field Name | Type | Description |
---|---|---|
name | string |
REQUIRED. The name of the parameter. Parameter names are case sensitive.
|
in | string |
REQUIRED. The location of the parameter. Possible values are "query" , "header" , "path" or "cookie" . |
description | string |
A brief description of the parameter. This could contain examples of use. CommonMark syntax MAY be used for rich text representation. |
required | boolean |
Determines whether this parameter is mandatory. If the parameter location is "path" , this field is REQUIRED and its value MUST be true . Otherwise, the field MAY be included and its default value is false . |
deprecated | boolean |
Specifies that a parameter is deprecated and SHOULD be transitioned out of usage. Default value is false . |
allowEmptyValue | boolean |
If true , clients MAY pass a zero-length string value in place of parameters that would otherwise be omitted entirely, which the server SHOULD interpret as the parameter being unused. Default value is false . If style is used, and if behavior is n/a (cannot be serialized), the value of allowEmptyValue SHALL be ignored. Interactions between this field and the parameter's Schema Object are implementation-defined. This field is valid only for query parameters. Use of this field is NOT RECOMMENDED, and it is likely to be removed in a later revision. |
This object MAY be extended with Specification Extensions.
Note that while "Cookie"
as a name
is not forbidden if in
is "header"
, the effect of defining a cookie parameter that way is undefined; use in: "cookie"
instead.
For simpler scenarios, a schema
and style
can describe the structure and syntax of the parameter.
When example
or examples
are provided in conjunction with the schema
field, the example SHOULD match the specified schema and follow the prescribed serialization strategy for the parameter.
The example
and examples
fields are mutually exclusive, and if either is present it SHALL override any example
in the schema.
Serializing with schema
is NOT RECOMMENDED for in: "cookie"
parameters, in: "header"
parameters that use HTTP header parameters (name=value pairs following a ;
) in their values, or in: "header"
parameters where values might have non-URL-safe characters; see Appendix D for details.
Field Name | Type | Description |
---|---|---|
style | string |
Describes how the parameter value will be serialized depending on the type of the parameter value. Default values (based on value of in ): for "query" - "form" ; for "path" - "simple" ; for "header" - "simple" ; for "cookie" - "form" . |
explode | boolean |
When this is true, parameter values of type array or object generate separate parameters for each value of the array or key-value pair of the map. For other types of parameters this field has no effect. When style is "form" , the default value is true . For all other styles, the default value is false . Note that despite false being the default for deepObject , the combination of false with deepObject is undefined. |
allowReserved | boolean |
When this is true, parameter values are serialized using reserved expansion, as defined by RFC6570, which allows RFC3986's reserved character set, as well as percent-encoded triples, to pass through unchanged, while still percent-encoding all other disallowed characters (including % outside of percent-encoded triples). Applications are still responsible for percent-encoding reserved characters that are not allowed in the query string ([ , ] , # ), or have a special meaning in application/x-www-form-urlencoded (- , & , + ); see Appendices C and E for details. This field only applies to parameters with an in value of query . The default value is false . |
schema | Schema Object | The schema defining the type used for the parameter. |
example | Any | Example of the parameter's potential value; see Working With Examples. |
examples | Map[ string , Example Object | Reference Object] |
Examples of the parameter's potential value; see Working With Examples. |
See also Appendix C: Using RFC6570-Based Serialization for additional guidance.
For more complex scenarios, the content
field can define the media type and schema of the parameter, as well as give examples of its use.
Using content
with a text/plain
media type is RECOMMENDED for in: "header"
and in: "cookie"
parameters where the schema
strategy is not appropriate.
Field Name | Type | Description |
---|---|---|
content | Map[string , Media Type Object] |
A map containing the representations for the parameter. The key is the media type and the value describes it. The map MUST only contain one entry. |
In order to support common ways of serializing simple parameters, a set of style
values are defined.
style |
type |
in |
Comments |
---|---|---|---|
matrix | primitive , array , object |
path |
Path-style parameters defined by RFC6570 |
label | primitive , array , object |
path |
Label style parameters defined by RFC6570 |
simple | primitive , array , object |
path , header |
Simple style parameters defined by RFC6570. This option replaces collectionFormat with a csv value from OpenAPI 2.0. |
form | primitive , array , object |
query , cookie |
Form style parameters defined by RFC6570. This option replaces collectionFormat with a csv (when explode is false) or multi (when explode is true) value from OpenAPI 2.0. |
spaceDelimited | array , object |
query |
Space separated array values or object properties and values. This option replaces collectionFormat equal to ssv from OpenAPI 2.0. |
pipeDelimited | array , object |
query |
Pipe separated array values or object properties and values. This option replaces collectionFormat equal to pipes from OpenAPI 2.0. |
deepObject | object |
query |
Allows objects with scalar properties to be represented using form parameters. The representation of array or object properties is not defined. |
See Appendix E for a discussion of percent-encoding, including when delimiters need to be percent-encoded and options for handling collisions with percent-encoded data.
Assume a parameter named color
has one of the following values:
string -> "blue"
array -> ["blue", "black", "brown"]
object -> { "R": 100, "G": 200, "B": 150 }
The following table shows examples, as would be shown with the example
or examples
keywords, of the different serializations for each value.
- The value empty denotes the empty string, and is unrelated to the
allowEmptyValue
field - The behavior of combinations marked n/a is undefined
- The
undefined
column replaces theempty
column in previous versions of this specification in order to better align with RFC6570 terminology, which describes certain values including but not limited tonull
as "undefined" values with special handling; notably, the empty string is not undefined - For
form
and the non-RFC6570 query string stylesspaceDelimited
,pipeDelimited
, anddeepObject
, each example is shown prefixed with?
as if it were the only query parameter; see Appendix C for more information on constructing query strings from multiple parameters, and Appendix D for warnings regardingform
and cookie parameters - Note that the
?
prefix is not appropriate for serializingapplication/x-www-form-urlencoded
HTTP message bodies, and MUST be stripped or (if constructing the string manually) not added when used in that context; see the Encoding Object for more information - The examples are percent-encoded as required by RFC6570 and RFC3986; see Appendix E for a thorough discussion of percent-encoding concerns, including why unencoded
|
(%7C
),[
(%5B
), and]
(%5D
) seem to work in some environments despite not being compliant.
style |
explode |
undefined |
string |
array |
object |
---|---|---|---|---|---|
matrix | false | ;color | ;color=blue | ;color=blue,black,brown | ;color=R,100,G,200,B,150 |
matrix | true | ;color | ;color=blue | ;color=blue;color=black;color=brown | ;R=100;G=200;B=150 |
label | false | . | .blue | .blue,black,brown | .R,100,G,200,B,150 |
label | true | . | .blue | .blue.black.brown | .R=100.G=200.B=150 |
simple | false | empty | blue | blue,black,brown | R,100,G,200,B,150 |
simple | true | empty | blue | blue,black,brown | R=100,G=200,B=150 |
form | false | ?color= | ?color=blue | ?color=blue,black,brown | ?color=R,100,G,200,B,150 |
form | true | ?color= | ?color=blue | ?color=blue&color=black&color=brown | ?R=100&G=200&B=150 |
spaceDelimited | false | n/a | n/a | ?color=blue%20black%20brown | ?color=R%20100%20G%20200%20B%20150 |
spaceDelimited | true | n/a | n/a | n/a | n/a |
pipeDelimited | false | n/a | n/a | ?color=blue%7Cblack%7Cbrown | ?color=R%7C100%7CG%7C200%7CB%7C150 |
pipeDelimited | true | n/a | n/a | n/a | n/a |
deepObject | false | n/a | n/a | n/a | n/a |
deepObject | true | n/a | n/a | n/a | ?color%5BR%5D=100&color%5BG%5D=200&color%5BB%5D=150 |
A header parameter with an array of 64-bit integer numbers:
{
"name": "token",
"in": "header",
"description": "token to be passed as a header",
"required": true,
"schema": {
"type": "array",
"items": {
"type": "integer",
"format": "int64"
}
},
"style": "simple"
}
name: token
in: header
description: token to be passed as a header
required: true
schema:
type: array
items:
type: integer
format: int64
style: simple
A path parameter of a string value:
{
"name": "username",
"in": "path",
"description": "username to fetch",
"required": true,
"schema": {
"type": "string"
}
}
name: username
in: path
description: username to fetch
required: true
schema:
type: string
An optional query parameter of a string value, allowing multiple values by repeating the query parameter:
{
"name": "id",
"in": "query",
"description": "ID of the object to fetch",
"required": false,
"schema": {
"type": "array",
"items": {
"type": "string"
}
},
"style": "form",
"explode": true
}
name: id
in: query
description: ID of the object to fetch
required: false
schema:
type: array
items:
type: string
style: form
explode: true
A free-form query parameter, allowing undefined parameters of a specific type:
{
"in": "query",
"name": "freeForm",
"schema": {
"type": "object",
"additionalProperties": {
"type": "integer"
}
},
"style": "form"
}
in: query
name: freeForm
schema:
type: object
additionalProperties:
type: integer
style: form
A complex parameter using content
to define serialization:
{
"in": "query",
"name": "coordinates",
"content": {
"application/json": {
"schema": {
"type": "object",
"required": ["lat", "long"],
"properties": {
"lat": {
"type": "number"
},
"long": {
"type": "number"
}
}
}
}
}
}
in: query
name: coordinates
content:
application/json:
schema:
type: object
required:
- lat
- long
properties:
lat:
type: number
long:
type: number
Describes a single request body.
Field Name | Type | Description |
---|---|---|
description | string |
A brief description of the request body. This could contain examples of use. CommonMark syntax MAY be used for rich text representation. |
content | Map[string , Media Type Object] |
REQUIRED. The content of the request body. The key is a media type or media type range and the value describes it. For requests that match multiple keys, only the most specific key is applicable. e.g. "text/plain" overrides "text/*" |
required | boolean |
Determines if the request body is required in the request. Defaults to false . |
This object MAY be extended with Specification Extensions.
A request body with a referenced schema definition.
{
"description": "user to add to the system",
"content": {
"application/json": {
"schema": {
"$ref": "#/components/schemas/User"
},
"examples": {
"user": {
"summary": "User Example",
"externalValue": "https://foo.bar/examples/user-example.json"
}
}
},
"application/xml": {
"schema": {
"$ref": "#/components/schemas/User"
},
"examples": {
"user": {
"summary": "User example in XML",
"externalValue": "https://foo.bar/examples/user-example.xml"
}
}
},
"text/plain": {
"examples": {
"user": {
"summary": "User example in Plain text",
"externalValue": "https://foo.bar/examples/user-example.txt"
}
}
},
"*/*": {
"examples": {
"user": {
"summary": "User example in other format",
"externalValue": "https://foo.bar/examples/user-example.whatever"
}
}
}
}
}
description: user to add to the system
content:
application/json:
schema:
$ref: '#/components/schemas/User'
examples:
user:
summary: User example
externalValue: https://foo.bar/examples/user-example.json
application/xml:
schema:
$ref: '#/components/schemas/User'
examples:
user:
summary: User example in XML
externalValue: https://foo.bar/examples/user-example.xml
text/plain:
examples:
user:
summary: User example in plain text
externalValue: https://foo.bar/examples/user-example.txt
'*/*':
examples:
user:
summary: User example in other format
externalValue: https://foo.bar/examples/user-example.whatever
Each Media Type Object provides schema and examples for the media type identified by its key.
When example
or examples
are provided, the example SHOULD match the specified schema and be in the correct format as specified by the media type and its encoding.
The example
and examples
fields are mutually exclusive, and if either is present it SHALL override any example
in the schema.
See Working With Examples for further guidance regarding the different ways of specifying examples, including non-JSON/YAML values.
Field Name | Type | Description |
---|---|---|
schema | Schema Object | The schema defining the content of the request, response, parameter, or header. |
example | Any | Example of the media type; see Working With Examples. |
examples | Map[ string , Example Object | Reference Object] |
Examples of the media type; see Working With Examples. |
encoding | Map[string , Encoding Object] |
A map between a property name and its encoding information. The key, being the property name, MUST exist in the schema as a property. The encoding field SHALL only apply to Request Body Objects, and only when the media type is multipart or application/x-www-form-urlencoded . If no Encoding Object is provided for a property, the behavior is determined by the default values documented for the Encoding Object. |
This object MAY be extended with Specification Extensions.
{
"application/json": {
"schema": {
"$ref": "#/components/schemas/Pet"
},
"examples": {
"cat": {
"summary": "An example of a cat",
"value": {
"name": "Fluffy",
"petType": "Cat",
"color": "White",
"gender": "male",
"breed": "Persian"
}
},
"dog": {
"summary": "An example of a dog with a cat's name",
"value": {
"name": "Puma",
"petType": "Dog",
"color": "Black",
"gender": "Female",
"breed": "Mixed"
}
},
"frog": {
"$ref": "#/components/examples/frog-example"
}
}
}
}
application/json:
schema:
$ref: '#/components/schemas/Pet'
examples:
cat:
summary: An example of a cat
value:
name: Fluffy
petType: Cat
color: White
gender: male
breed: Persian
dog:
summary: An example of a dog with a cat's name
value:
name: Puma
petType: Dog
color: Black
gender: Female
breed: Mixed
frog:
$ref: '#/components/examples/frog-example'
In contrast to OpenAPI 2.0, file
input/output content in OAS 3.x is described with the same semantics as any other schema type.
In contrast to OAS 3.0, the format
keyword has no effect on the content-encoding of the schema in OAS 3.1. Instead, JSON Schema's contentEncoding
and contentMediaType
keywords are used. See Working With Binary Data for how to model various scenarios with these keywords, and how to migrate from the previous format
usage.
Examples:
Content transferred in binary (octet-stream) MAY omit schema
:
# a PNG image as a binary file:
content:
image/png: {}
# an arbitrary binary file:
content:
application/octet-stream: {}
# arbitrary JSON without constraints beyond being syntactically valid:
content:
application/json: {}
These examples apply to either input payloads of file uploads or response payloads.
A requestBody
for submitting a file in a POST
operation may look like the following example:
requestBody:
content:
application/octet-stream: {}
In addition, specific media types MAY be specified:
# multiple, specific media types may be specified:
requestBody:
content:
# a binary file of type png or jpeg
image/jpeg: {}
image/png: {}
To upload multiple files, a multipart
media type MUST be used as shown under Example: Multipart Form with Multiple Files.
See Encoding the x-www-form-urlencoded
Media Type for guidance and examples, both with and without the encoding
field.
See Encoding multipart
Media Types for further guidance and examples, both with and without the encoding
field.
A single encoding definition applied to a single schema property. See Appendix B for a discussion of converting values of various types to string representations.
Properties are correlated with multipart
parts using the name
parameter of Content-Disposition: form-data
, and with application/x-www-form-urlencoded
using the query string parameter names.
In both cases, their order is implementation-defined.
See Appendix E for a detailed examination of percent-encoding concerns for form media types.
These fields MAY be used either with or without the RFC6570-style serialization fields defined in the next section below.
Field Name | Type | Description |
---|---|---|
contentType | string |
The Content-Type for encoding a specific property. The value is a comma-separated list, each element of which is either a specific media type (e.g. image/png ) or a wildcard media type (e.g. image/* ). Default value depends on the property type as shown in the table below. |
headers | Map[string , Header Object | Reference Object] |
A map allowing additional information to be provided as headers. Content-Type is described separately and SHALL be ignored in this section. This field SHALL be ignored if the request body media type is not a multipart . |
This object MAY be extended with Specification Extensions.
The default values for contentType
are as follows, where an n/a in the contentEncoding
column means that the presence or value of contentEncoding
is irrelevant:
type |
contentEncoding |
Default contentType |
---|---|---|
absent | n/a | application/octet-stream |
string |
present | application/octet-stream |
string |
absent | text/plain |
number , integer , or boolean |
n/a | text/plain |
object |
n/a | application/json |
array |
n/a | according to the type of the items schema |
Determining how to handle a type
value of null
depends on how null
values are being serialized.
If null
values are entirely omitted, then the contentType
is irrelevant.
See Appendix B for a discussion of data type conversion options.
Field Name | Type | Description |
---|---|---|
style | string |
Describes how a specific property value will be serialized depending on its type. See Parameter Object for details on the style field. The behavior follows the same values as query parameters, including default values. Note that the initial ? used in query strings is not used in application/x-www-form-urlencoded message bodies, and MUST be removed (if using an RFC6570 implementation) or simply not added (if constructing the string manually). This field SHALL be ignored if the request body media type is not application/x-www-form-urlencoded or multipart/form-data . If a value is explicitly defined, then the value of contentType (implicit or explicit) SHALL be ignored. |
explode | boolean |
When this is true, property values of type array or object generate separate parameters for each value of the array, or key-value-pair of the map. For other types of properties this field has no effect. When style is "form" , the default value is true . For all other styles, the default value is false . Note that despite false being the default for deepObject , the combination of false with deepObject is undefined. This field SHALL be ignored if the request body media type is not application/x-www-form-urlencoded or multipart/form-data . If a value is explicitly defined, then the value of contentType (implicit or explicit) SHALL be ignored. |
allowReserved | boolean |
When this is true, parameter values are serialized using reserved expansion, as defined by RFC6570, which allows RFC3986's reserved character set, as well as percent-encoded triples, to pass through unchanged, while still percent-encoding all other disallowed characters (including % outside of percent-encoded triples). Applications are still responsible for percent-encoding reserved characters that are not allowed in the query string ([ , ] , # ), or have a special meaning in application/x-www-form-urlencoded (- , & , + ); see Appendices C and E for details. The default value is false . This field SHALL be ignored if the request body media type is not application/x-www-form-urlencoded or multipart/form-data . If a value is explicitly defined, then the value of contentType (implicit or explicit) SHALL be ignored. |
See also Appendix C: Using RFC6570 Implementations for additional guidance, including on difficulties caused by the interaction between RFC6570's percent-encoding rules and the multipart/form-data
media type.
Note that the presence of at least one of style
, explode
, or allowReserved
with an explicit value is equivalent to using schema
with in: "query"
Parameter Objects.
The absence of all three of those fields is the equivalent of using content
, but with the media type specified in contentType
rather than through a Media Type Object.
To submit content using form url encoding via RFC1866, use the application/x-www-form-urlencoded
media type in the Media Type Object under the Request Body Object.
This configuration means that the request body MUST be encoded per RFC1866 when passed to the server, after any complex objects have been serialized to a string representation.
See Appendix E for a detailed examination of percent-encoding concerns for form media types.
When there is no encoding
field, the serialization strategy is based on the Encoding Object's default values:
requestBody:
content:
application/x-www-form-urlencoded:
schema:
type: object
properties:
id:
type: string
format: uuid
address:
# complex types are stringified to support RFC 1866
type: object
properties: {}
With this example, consider an id
of f81d4fae-7dec-11d0-a765-00a0c91e6bf6
and a US-style address (with ZIP+4) as follows:
{
"streetAddress": "123 Example Dr.",
"city": "Somewhere",
"state": "CA",
"zip": "99999+1234"
}
Assuming the most compact representation of the JSON value (with unnecessary whitespace removed), we would expect to see the following request body, where space characters have been replaced with +
and +
, "
, {
, and }
have been percent-encoded to %2B
, %22
, %7B
, and %7D
, respectively:
id=f81d4fae-7dec-11d0-a765-00a0c91e6bf6&address=%7B%22streetAddress%22:%22123+Example+Dr.%22,%22city%22:%22Somewhere%22,%22state%22:%22CA%22,%22zip%22:%2299999%2B1234%22%7D
Note that the id
keyword is treated as text/plain
per the Encoding Object's default behavior, and is serialized as-is.
If it were treated as application/json
, then the serialized value would be a JSON string including quotation marks, which would be percent-encoded as %22
.
Here is the id
parameter (without address
) serialized as application/json
instead of text/plain
, and then encoded per RFC1866:
id=%22f81d4fae-7dec-11d0-a765-00a0c91e6bf6%22
Note that application/x-www-form-urlencoded
is a text format, which requires base64-encoding any binary data:
requestBody:
content:
application/x-www-form-urlencoded:
schema:
type: object
properties:
name:
type: string
icon:
# The default with "contentEncoding" is application/octet-stream,
# so we need to set image media type(s) in the Encoding Object.
type: string
contentEncoding: base64url
encoding:
icon:
contentType: image/png, image/jpeg
Given a name of example
and a solid red 2x2-pixel PNG for icon
, this
would produce a request body of:
name=example&icon=iVBORw0KGgoAAAANSUhEUgAAAAIAAAACCAIAAAD91JpzAAAABGdBTUEAALGPC_xhBQAAADhlWElmTU0AKgAAAAgAAYdpAAQAAAABAAAAGgAAAAAAAqACAAQAAAABAAAAAqADAAQAAAABAAAAAgAAAADO0J6QAAAAEElEQVQIHWP8zwACTGCSAQANHQEDqtPptQAAAABJRU5ErkJggg%3D%3D
Note that the =
padding characters at the end need to be percent-encoded, even with the "URL safe" contentEncoding: base64url
.
Some base64-decoding implementations may be able to use the string without the padding per RFC4648.
However, this is not guaranteed, so it may be more interoperable to keep the padding and rely on percent-decoding.
It is common to use multipart/form-data
as a Content-Type
when transferring forms as request bodies. In contrast to OpenAPI 2.0, a schema
is REQUIRED to define the input parameters to the operation when using multipart
content. This supports complex structures as well as supporting mechanisms for multiple file uploads.
The form-data
disposition and its name
parameter are mandatory for multipart/form-data
(RFC7578).
Array properties are handled by applying the same name
to multiple parts, as is recommended by RFC7578 for supplying multiple values per form field.
See RFC7578 for guidance regarding non-ASCII part names.
Various other multipart
types, most notable multipart/mixed
(RFC2046) neither require nor forbid specific Content-Disposition
values, which means care must be taken to ensure that any values used are supported by all relevant software.
It is not currently possible to correlate schema properties with unnamed, ordered parts in media types such as multipart/mixed
, but implementations MAY choose to support such types when Content-Disposition: form-data
is used with a name
parameter.
Note that there are significant restrictions on what headers can be used with multipart
media types in general (RFC2046) and multi-part/form-data
in particular (RFC7578).
Note also that Content-Transfer-Encoding
is deprecated for multipart/form-data
(RFC7578) where binary data is supported, as it is in HTTP.
+Using contentEncoding
for a multipart field is equivalent to specifying an Encoding Object with a headers
field containing Content-Transfer-Encoding
with a schema that requires the value used in contentEncoding
.
+If contentEncoding
is used for a multipart field that has an Encoding Object with a headers
field containing Content-Transfer-Encoding
with a schema that disallows the value from contentEncoding
, the result is undefined for serialization and parsing.
Note that as stated in Working with Binary Data, if the Encoding Object's contentType
, whether set explicitly or implicitly through its default value rules, disagrees with the contentMediaType
in a Schema Object, the contentMediaType
SHALL be ignored.
Because of this, and because the Encoding Object's contentType
defaulting rules do not take the Schema Object'scontentMediaType
into account, the use of contentMediaType
with an Encoding Object is NOT RECOMMENDED.
See Appendix E for a detailed examination of percent-encoding concerns for form media types.
When the encoding
field is not used, the encoding is determined by the Encoding Object's defaults:
requestBody:
content:
multipart/form-data:
schema:
type: object
properties:
id:
# default for primitives without a special format is text/plain
type: string
format: uuid
profileImage:
# default for string with binary format is `application/octet-stream`
type: string
format: binary
addresses:
# default for arrays is based on the type in the `items`
# subschema, which is an object, so `application/json`
type: array
items:
$ref: '#/components/schemas/Address'
Using encoding
, we can set more specific types for binary data, or non-JSON formats for complex values.
We can also describe headers for each part:
requestBody:
content:
multipart/form-data:
schema:
type: object
properties:
id:
# default is `text/plain`
type: string
format: uuid
addresses:
# default based on the `items` subschema would be
# `application/json`, but we want these address objects
# serialized as `application/xml` instead
description: addresses in XML format
type: array
items:
$ref: '#/components/schemas/Address'
profileImage:
# default is application/octet-stream, but we can declare
# a more specific image type or types
type: string
format: binary
encoding:
addresses:
# require XML Content-Type in utf-8 encoding
# This is applied to each address part corresponding
# to each address in he array
contentType: application/xml; charset=utf-8
profileImage:
# only accept png or jpeg
contentType: image/png, image/jpeg
headers:
X-Rate-Limit-Limit:
description: The number of allowed requests in the current period
schema:
type: integer
In accordance with RFC7578, multiple files for a single form field are uploaded using the same name (file
in this example) for each file's part:
requestBody:
content:
multipart/form-data:
schema:
properties:
# The property name 'file' will be used for all files.
file:
type: array
items: {}
As seen in the Encoding Object's contentType
field documentation, the empty schema for items
indicates a media type of application/octet-stream
.
A container for the expected responses of an operation. The container maps a HTTP response code to the expected response.
The documentation is not necessarily expected to cover all possible HTTP response codes because they may not be known in advance. However, documentation is expected to cover a successful operation response and any known errors.
The default
MAY be used as a default Response Object for all HTTP codes
that are not covered individually by the Responses Object.
The Responses Object MUST contain at least one response code, and if only one response code is provided it SHOULD be the response for a successful operation call.
Field Name | Type | Description |
---|---|---|
default | Response Object | Reference Object | The documentation of responses other than the ones declared for specific HTTP response codes. Use this field to cover undeclared responses. |
Field Pattern | Type | Description |
---|---|---|
HTTP Status Code | Response Object | Reference Object | Any HTTP status code can be used as the property name, but only one property per code, to describe the expected response for that HTTP status code. This field MUST be enclosed in quotation marks (for example, "200") for compatibility between JSON and YAML. To define a range of response codes, this field MAY contain the uppercase wildcard character X . For example, 2XX represents all response codes between 200 and 299 . Only the following range definitions are allowed: 1XX , 2XX , 3XX , 4XX , and 5XX . If a response is defined using an explicit code, the explicit code definition takes precedence over the range definition for that code. |
This object MAY be extended with Specification Extensions.
A 200 response for a successful operation and a default response for others (implying an error):
{
"200": {
"description": "a pet to be returned",
"content": {
"application/json": {
"schema": {
"$ref": "#/components/schemas/Pet"
}
}
}
},
"default": {
"description": "Unexpected error",
"content": {
"application/json": {
"schema": {
"$ref": "#/components/schemas/ErrorModel"
}
}
}
}
}
'200':
description: a pet to be returned
content:
application/json:
schema:
$ref: '#/components/schemas/Pet'
default:
description: Unexpected error
content:
application/json:
schema:
$ref: '#/components/schemas/ErrorModel'
Describes a single response from an API operation, including design-time, static
links
to operations based on the response.
Field Name | Type | Description |
---|---|---|
description | string |
REQUIRED. A description of the response. CommonMark syntax MAY be used for rich text representation. |
headers | Map[string , Header Object | Reference Object] |
Maps a header name to its definition. RFC7230 states header names are case insensitive. If a response header is defined with the name "Content-Type" , it SHALL be ignored. |
content | Map[string , Media Type Object] |
A map containing descriptions of potential response payloads. The key is a media type or media type range and the value describes it. For responses that match multiple keys, only the most specific key is applicable. e.g. "text/plain" overrides "text/*" |
links | Map[string , Link Object | Reference Object] |
A map of operations links that can be followed from the response. The key of the map is a short name for the link, following the naming constraints of the names for Component Objects. |
This object MAY be extended with Specification Extensions.
Response of an array of a complex type:
{
"description": "A complex object array response",
"content": {
"application/json": {
"schema": {
"type": "array",
"items": {
"$ref": "#/components/schemas/VeryComplexType"
}
}
}
}
}
description: A complex object array response
content:
application/json:
schema:
type: array
items:
$ref: '#/components/schemas/VeryComplexType'
Response with a string type:
{
"description": "A simple string response",
"content": {
"text/plain": {
"schema": {
"type": "string"
}
}
}
}
description: A simple string response
content:
text/plain:
schema:
type: string
Plain text response with headers:
{
"description": "A simple string response",
"content": {
"text/plain": {
"schema": {
"type": "string"
},
"example": "whoa!"
}
},
"headers": {
"X-Rate-Limit-Limit": {
"description": "The number of allowed requests in the current period",
"schema": {
"type": "integer"
}
},
"X-Rate-Limit-Remaining": {
"description": "The number of remaining requests in the current period",
"schema": {
"type": "integer"
}
},
"X-Rate-Limit-Reset": {
"description": "The number of seconds left in the current period",
"schema": {
"type": "integer"
}
}
}
}
description: A simple string response
content:
text/plain:
schema:
type: string
example: 'whoa!'
headers:
X-Rate-Limit-Limit:
description: The number of allowed requests in the current period
schema:
type: integer
X-Rate-Limit-Remaining:
description: The number of remaining requests in the current period
schema:
type: integer
X-Rate-Limit-Reset:
description: The number of seconds left in the current period
schema:
type: integer
Response with no return value:
{
"description": "object created"
}
description: object created
A map of possible out-of band callbacks related to the parent operation. Each value in the map is a Path Item Object that describes a set of requests that may be initiated by the API provider and the expected responses. The key value used to identify the Path Item Object is an expression, evaluated at runtime, that identifies a URL to use for the callback operation.
To describe incoming requests from the API provider independent from another API call, use the webhooks
field.
Field Pattern | Type | Description |
---|---|---|
{expression} | Path Item Object | A Path Item Object used to define a callback request and expected responses. A complete example is available. |
This object MAY be extended with Specification Extensions.
The key that identifies the Path Item Object is a runtime expression that can be evaluated in the context of a runtime HTTP request/response to identify the URL to be used for the callback request.
A simple example might be $request.body#/url
.
However, using a runtime expression the complete HTTP message can be accessed.
This includes accessing any part of a body that a JSON Pointer RFC6901 can reference.
For example, given the following HTTP request:
POST /subscribe/myevent?queryUrl=https://clientdomain.com/stillrunning HTTP/1.1
Host: example.org
Content-Type: application/json
Content-Length: 188
{
"failedUrl": "https://clientdomain.com/failed",
"successUrls": [
"https://clientdomain.com/fast",
"https://clientdomain.com/medium",
"https://clientdomain.com/slow"
]
}
resulting in:
201 Created
Location: https://example.org/subscription/1
The following examples show how the various expressions evaluate, assuming the callback operation has a path parameter named eventType
and a query parameter named queryUrl
.
Expression | Value |
---|---|
$url | https://example.org/subscribe/myevent?queryUrl=https://clientdomain.com/stillrunning |
$method | POST |
$request.path.eventType | myevent |
$request.query.queryUrl | https://clientdomain.com/stillrunning |
$request.header.content-type | application/json |
$request.body#/failedUrl | https://clientdomain.com/failed |
$request.body#/successUrls/1 | https://clientdomain.com/medium |
$response.header.Location | https://example.org/subscription/1 |
The following example uses the user provided queryUrl
query string parameter to define the callback URL. This is similar to a webhook, but differs in that the callback only occurs because of the initial request that sent the queryUrl
.
myCallback:
'{$request.query.queryUrl}':
post:
requestBody:
description: Callback payload
content:
application/json:
schema:
$ref: '#/components/schemas/SomePayload'
responses:
'200':
description: callback successfully processed
The following example shows a callback where the server is hard-coded, but the query string parameters are populated from the id
and email
property in the request body.
transactionCallback:
'http://notificationServer.com?transactionId={$request.body#/id}&email={$request.body#/email}':
post:
requestBody:
description: Callback payload
content:
application/json:
schema:
$ref: '#/components/schemas/SomePayload'
responses:
'200':
description: callback successfully processed
An object grouping an internal or external example value with basic summary
and description
metadata.
This object is typically used in fields named examples
(plural), and is a referenceable alternative to older example
(singular) fields that do not support referencing or metadata.
Examples allow demonstration of the usage of properties, parameters and objects within OpenAPI.
Field Name | Type | Description |
---|---|---|
summary | string |
Short description for the example. |
description | string |
Long description for the example. CommonMark syntax MAY be used for rich text representation. |
value | Any | Embedded literal example. The value field and externalValue field are mutually exclusive. To represent examples of media types that cannot naturally represented in JSON or YAML, use a string value to contain the example, escaping where necessary. |
externalValue | string |
A URI that identifies the literal example. This provides the capability to reference examples that cannot easily be included in JSON or YAML documents. The value field and externalValue field are mutually exclusive. See the rules for resolving Relative References. |
This object MAY be extended with Specification Extensions.
In all cases, the example value SHOULD be compatible with the schema of its associated value. Tooling implementations MAY choose to validate compatibility automatically, and reject the example value(s) if incompatible.
Example Objects can be used in both Parameter Objects and Media Type Objects.
In both Objects, this is done through the examples
(plural) field.
However, there are several other ways to provide examples: The example
(singular) field that is mutually exclusive with examples
in both Objects, and two keywords (the deprecated singular example
and the current plural examples
, which takes an array of examples) in the Schema Object that appears in the schema
field of both Objects.
Each of these fields has slightly different considerations.
The Schema Object's fields are used to show example values without regard to how they might be formatted as parameters or within media type representations.
The examples
array is part of JSON Schema and is the preferred way to include examples in the Schema Object, while example
is retained purely for compatibility with older versions of the OpenAPI Specification.
The mutually exclusive fields in the Parameter or Media Type Objects are used to show example values which SHOULD both match the schema and be formatted as they would appear as a serialized parameter or within a media type representation.
The exact serialization and encoding is determined by various fields in the Parameter Object, or in the Media Type Object's Encoding Object.
Because examples using these fields represent the final serialized form of the data, they SHALL override any example
in the corresponding Schema Object.
The singular example
field in the Parameter or Media Type Object is concise and convenient for simple examples, but does not offer any other advantages over using Example Objects under examples
.
Some examples cannot be represented directly in JSON or YAML.
For all three ways of providing examples, these can be shown as string values with any escaping necessary to make the string valid in the JSON or YAML format of documents that comprise the OpenAPI Description.
With the Example Object, such values can alternatively be handled through the externalValue
field.
In a request body:
requestBody:
content:
'application/json':
schema:
$ref: '#/components/schemas/Address'
examples:
foo:
summary: A foo example
value:
foo: bar
bar:
summary: A bar example
value:
bar: baz
application/xml:
examples:
xmlExample:
summary: This is an example in XML
externalValue: https://example.org/examples/address-example.xml
text/plain:
examples:
textExample:
summary: This is a text example
externalValue: https://foo.bar/examples/address-example.txt
In a parameter:
parameters:
- name: zipCode
in: query
schema:
type: string
format: zip-code
examples:
zip-example:
$ref: '#/components/examples/zip-example'
In a response:
responses:
'200':
description: your car appointment has been booked
content:
application/json:
schema:
$ref: '#/components/schemas/SuccessResponse'
examples:
confirmation-success:
$ref: '#/components/examples/confirmation-success'
Two different uses of JSON strings:
First, a request or response body that is just a JSON string (not an object containing a string):
"application/json": {
"schema": {
"type": "string"
},
"examples": {
"jsonBody": {
"description": "A body of just the JSON string \"json\"",
"value": "json"
}
}
}
application/json:
schema:
type: string
examples:
jsonBody:
description: 'A body of just the JSON string "json"'
value: json
In the above example, we can just show the JSON string (or any JSON value) as-is, rather than stuffing a serialized JSON value into a JSON string, which would have looked like "\"json\""
.
In contrast, a JSON string encoded inside of a URL-style form body:
"application/x-www-form-urlencoded": {
"schema": {
"type": "object",
"properties": {
"jsonValue": {
"type": "string"
}
}
},
"encoding": {
"jsonValue": {
"contentType": "application/json"
}
},
"examples": {
"jsonFormValue": {
"description": "The JSON string \"json\" as a form value",
"value": "jsonValue=%22json%22"
}
}
}
application/x-www-form-urlencoded:
schema:
type: object
properties:
jsonValue:
type: string
encoding:
jsonValue:
contentType: application/json
examples:
jsonFormValue:
description: 'The JSON string "json" as a form value'
value: jsonValue=%22json%22
In this example, the JSON string had to be serialized before encoding it into the URL form value, so the example includes the quotation marks that are part of the JSON serialization, which are then URL percent-encoded.
The Link Object represents a possible design-time link for a response. The presence of a link does not guarantee the caller's ability to successfully invoke it, rather it provides a known relationship and traversal mechanism between responses and other operations.
Unlike dynamic links (i.e. links provided in the response payload), the OAS linking mechanism does not require link information in the runtime response.
For computing links and providing instructions to execute them, a runtime expression is used for accessing values in an operation and using them as parameters while invoking the linked operation.
Field Name | Type | Description |
---|---|---|
operationRef | string |
A URI reference to an OAS operation. This field is mutually exclusive of the operationId field, and MUST point to an Operation Object. Relative operationRef values MAY be used to locate an existing Operation Object in the OpenAPI Description. |
operationId | string |
The name of an existing, resolvable OAS operation, as defined with a unique operationId . This field is mutually exclusive of the operationRef field. |
parameters | Map[string , Any | {expression}] |
A map representing parameters to pass to an operation as specified with operationId or identified via operationRef . The key is the parameter name to be used (optionally qualified with the parameter location, e.g. path.id for an id parameter in the path), whereas the value can be a constant or an expression to be evaluated and passed to the linked operation. |
requestBody | Any | {expression} | A literal value or {expression} to use as a request body when calling the target operation. |
description | string |
A description of the link. CommonMark syntax MAY be used for rich text representation. |
server | Server Object | A server object to be used by the target operation. |
This object MAY be extended with Specification Extensions.
A linked operation MUST be identified using either an operationRef
or operationId
.
The identified or reference operation MUST be unique, and in the case of an operationId
, it MUST be resolved within the scope of the OpenAPI Description (OAD).
Because of the potential for name clashes, the operationRef
syntax is preferred for multi-document OADs.
However, because use of an operation depends on its URL path template in the Paths Object, operations from any Path Item Object that is referenced multiple times within the OAD cannot be resolved unambiguously.
In such ambiguous cases, the resulting behavior is implementation-defined and MAY result in an error.
Note that it is not possible to provide a constant value to parameters
that matches the syntax of a runtime expression.
It is possible to have ambiguous parameter names, e.g. name: "id", in: "path"
and name: "path.id", in: "query"
; this is NOT RECOMMENDED and the behavior is implementation-defined, however implementations SHOULD prefer the qualified interpretation (path.id
as a path parameter), as the names can always be qualified to disambiguate them (e.g. using query.path.id
for the query parameter).
Computing a link from a request operation where the $request.path.id
is used to pass a request parameter to the linked operation.
paths:
/users/{id}:
parameters:
- name: id
in: path
required: true
description: the user identifier, as userId
schema:
type: string
get:
responses:
'200':
description: the user being returned
content:
application/json:
schema:
type: object
properties:
uuid: # the unique user id
type: string
format: uuid
links:
address:
# the target link operationId
operationId: getUserAddress
parameters:
# get the `id` field from the request path parameter named `id`
userid: $request.path.id
# the path item of the linked operation
/users/{userid}/address:
parameters:
- name: userid
in: path
required: true
description: the user identifier, as userId
schema:
type: string
# linked operation
get:
operationId: getUserAddress
responses:
'200':
description: the user's address
When a runtime expression fails to evaluate, no parameter value is passed to the target operation.
Values from the response body can be used to drive a linked operation.
links:
address:
operationId: getUserAddressByUUID
parameters:
# get the `uuid` field from the `uuid` field in the response body
userUuid: $response.body#/uuid
Clients follow all links at their discretion. Neither permissions nor the capability to make a successful call to that link is guaranteed solely by the existence of a relationship.
As references to operationId
MAY NOT be possible (the operationId
is an optional
field in an Operation Object), references MAY also be made through a relative operationRef
:
links:
UserRepositories:
# returns array of '#/components/schemas/repository'
operationRef: '#/paths/~12.0~1repositories~1%7Busername%7D/get'
parameters:
username: $response.body#/username
or a URI operationRef
:
links:
UserRepositories:
# returns array of '#/components/schemas/repository'
operationRef: https://na2.gigantic-server.com/#/paths/~12.0~1repositories~1%7Busername%7D/get
parameters:
username: $response.body#/username
Note that in the use of operationRef
the escaped forward-slash is necessary when
using JSON Pointer, and it is necessary to URL-encode {
and }
as %7B
and %7D
, respectively, when using JSON Pointer as URI fragments.
Runtime expressions allow defining values based on information that will only be available within the HTTP message in an actual API call. This mechanism is used by Link Objects and Callback Objects.
The runtime expression is defined by the following ABNF syntax
expression = "$url" / "$method" / "$statusCode" / "$request." source / "$response." source
source = header-reference / query-reference / path-reference / body-reference
header-reference = "header." token
query-reference = "query." name
path-reference = "path." name
body-reference = "body" ["#" json-pointer ]
json-pointer = *( "/" reference-token )
reference-token = *( unescaped / escaped )
unescaped = %x00-2E / %x30-7D / %x7F-10FFFF
; %x2F ('/') and %x7E ('~') are excluded from 'unescaped'
escaped = "~" ( "0" / "1" )
; representing '~' and '/', respectively
name = *( CHAR )
token = 1*tchar
tchar = "!" / "#" / "$" / "%" / "&" / "'" / "*" / "+" / "-" / "."
/ "^" / "_" / "`" / "|" / "~" / DIGIT / ALPHA
Here, json-pointer
is taken from RFC6901, char
from RFC7159 and token
from RFC7230.
The name
identifier is case-sensitive, whereas token
is not.
The table below provides examples of runtime expressions and examples of their use in a value:
Source Location | example expression | notes |
---|---|---|
HTTP Method | $method |
The allowable values for the $method will be those for the HTTP operation. |
Requested media type | $request.header.accept |
|
Request parameter | $request.path.id |
Request parameters MUST be declared in the parameters section of the parent operation or they cannot be evaluated. This includes request headers. |
Request body property | $request.body#/user/uuid |
In operations which accept payloads, references may be made to portions of the requestBody or the entire body. |
Request URL | $url |
|
Response value | $response.body#/status |
In operations which return payloads, references may be made to portions of the response body or the entire body. |
Response header | $response.header.Server |
Single header values only are available |
Runtime expressions preserve the type of the referenced value.
Expressions can be embedded into string values by surrounding the expression with {}
curly braces.
Describes a single header for HTTP responses and for individual parts in multipart
representations; see the relevant Response Object and Encoding Object documentation for restrictions on which headers can be described.
The Header Object follows the structure of the Parameter Object, including determining its serialization strategy based on whether schema
or content
is present, with the following changes:
name
MUST NOT be specified, it is given in the correspondingheaders
map.in
MUST NOT be specified, it is implicitly inheader
.- All traits that are affected by the location MUST be applicable to a location of
header
(for example,style
). This means thatallowEmptyValue
andallowReserved
MUST NOT be used, andstyle
, if used, MUST be limited to"simple"
.
These fields MAY be used with either content
or schema
.
Field Name | Type | Description |
---|---|---|
description | string |
A brief description of the header. This could contain examples of use. CommonMark syntax MAY be used for rich text representation. |
required | boolean |
Determines whether this header is mandatory. The default value is false . |
deprecated | boolean |
Specifies that the header is deprecated and SHOULD be transitioned out of usage. Default value is false . |
This object MAY be extended with Specification Extensions.
For simpler scenarios, a schema
and style
can describe the structure and syntax of the header.
When example
or examples
are provided in conjunction with the schema
field, the example MUST follow the prescribed serialization strategy for the header.
Serializing with schema
is NOT RECOMMENDED for headers with parameters (name=value pairs following a ;
) in their values, or where values might have non-URL-safe characters; see Appendix D for details.
When example
or examples
are provided in conjunction with the schema
field, the example SHOULD match the specified schema and follow the prescribed serialization strategy for the header.
The example
and examples
fields are mutually exclusive, and if either is present it SHALL override any example
in the schema.
Field Name | Type | Description |
---|---|---|
style | string |
Describes how the header value will be serialized. The default (and only legal value for headers) is "simple" . |
explode | boolean |
When this is true, header values of type array or object generate a single header whose value is a comma-separated list of the array items or key-value pairs of the map, see Style Examples. For other data types this field has no effect. The default value is false . |
schema | Schema Object | Reference Object | The schema defining the type used for the header. |
example | Any | Example of the header's potential value; see Working With Examples. |
examples | Map[ string , Example Object | Reference Object] |
Examples of the header's potential value; see Working With Examples. |
See also Appendix C: Using RFC6570-Based Serialization for additional guidance.
For more complex scenarios, the content
field can define the media type and schema of the header, as well as give examples of its use.
Using content
with a text/plain
media type is RECOMMENDED for headers where the schema
strategy is not appropriate.
Field Name | Type | Description |
---|---|---|
content | Map[string , Media Type Object] |
A map containing the representations for the header. The key is the media type and the value describes it. The map MUST only contain one entry. |
A simple header of type integer
:
"X-Rate-Limit-Limit": {
"description": "The number of allowed requests in the current period",
"schema": {
"type": "integer"
}
}
X-Rate-Limit-Limit:
description: The number of allowed requests in the current period
schema:
type: integer
Requiring that a strong ETag
header (with a value starting with "
rather than W/
) is present. Note the use of content
, because using schema
and style
would require the "
to be percent-encoded as %22
:
"ETag": {
"required": true,
"content": {
"text/plain": {
"schema": {
"type": "string",
"pattern": "^\""
}
}
}
}
ETag:
required: true
content:
text/plain:
schema:
type: string
pattern: ^"
Adds metadata to a single tag that is used by the Operation Object. It is not mandatory to have a Tag Object per tag defined in the Operation Object instances.
Field Name | Type | Description |
---|---|---|
name | string |
REQUIRED. The name of the tag. |
description | string |
A description for the tag. CommonMark syntax MAY be used for rich text representation. |
externalDocs | External Documentation Object | Additional external documentation for this tag. |
This object MAY be extended with Specification Extensions.
{
"name": "pet",
"description": "Pets operations"
}
name: pet
description: Pets operations
A simple object to allow referencing other components in the OpenAPI Description, internally and externally.
The $ref
string value contains a URI RFC3986, which identifies the value being referenced.
See the rules for resolving Relative References.
Field Name | Type | Description |
---|---|---|
$ref | string |
REQUIRED. The reference identifier. This MUST be in the form of a URI. |
summary | string |
A short summary which by default SHOULD override that of the referenced component. If the referenced object-type does not allow a summary field, then this field has no effect. |
description | string |
A description which by default SHOULD override that of the referenced component. CommonMark syntax MAY be used for rich text representation. If the referenced object-type does not allow a description field, then this field has no effect. |
This object cannot be extended with additional properties, and any properties added SHALL be ignored.
Note that this restriction on additional properties is a difference between Reference Objects and Schema Objects that contain a $ref
keyword.
{
"$ref": "#/components/schemas/Pet"
}
$ref: '#/components/schemas/Pet'
{
"$ref": "Pet.json"
}
$ref: Pet.yaml
{
"$ref": "definitions.json#/Pet"
}
$ref: definitions.yaml#/Pet
The Schema Object allows the definition of input and output data types.
These types can be objects, but also primitives and arrays. This object is a superset of the JSON Schema Specification Draft 2020-12. The empty schema (which allows any instance to validate) MAY be represented by the boolean value true
and a schema which allows no instance to validate MAY be represented by the boolean value false
.
For more information about the keywords, see JSON Schema Core and JSON Schema Validation.
Unless stated otherwise, the keyword definitions follow those of JSON Schema and do not add any additional semantics; this includes keywords such as $schema
, $id
, $ref
, and $dynamicRef
being URIs rather than URLs.
Where JSON Schema indicates that behavior is defined by the application (e.g. for annotations), OAS also defers the definition of semantics to the application consuming the OpenAPI document.
The OpenAPI Schema Object dialect is defined as requiring the OAS base vocabulary, in addition to the vocabularies as specified in the JSON Schema Specification Draft 2020-12 general purpose meta-schema.
The OpenAPI Schema Object dialect for this version of the specification is identified by the URI https://spec.openapis.org/oas/3.1/dialect/base
(the "OAS dialect schema id").
The following keywords are taken from the JSON Schema specification but their definitions have been extended by the OAS:
- description - CommonMark syntax MAY be used for rich text representation.
- format - See Data Type Formats for further details. While relying on JSON Schema's defined formats, the OAS offers a few additional predefined formats.
In addition to the JSON Schema keywords comprising the OAS dialect, the Schema Object supports keywords from any other vocabularies, or entirely arbitrary properties.
JSON Schema implementations MAY choose to treat keywords defined by the OpenAPI Specification's base vocabulary as unknown keywords, due to its inclusion in the OAS dialect with a $vocabulary
value of false
.
The OAS base vocabulary is comprised of the following keywords:
Field Name | Type | Description |
---|---|---|
discriminator | Discriminator Object | Adds support for polymorphism. The discriminator is used to determine which of a set of schemas a payload is expected to satisfy. See Composition and Inheritance for more details. |
xml | XML Object | This MAY be used only on property schemas. It has no effect on root schemas. Adds additional metadata to describe the XML representation of this property. |
externalDocs | External Documentation Object | Additional external documentation for this schema. |
example | Any | A free-form field to include an example of an instance for this schema. To represent examples that cannot be naturally represented in JSON or YAML, a string value can be used to contain the example with escaping where necessary. Deprecated: The example field has been deprecated in favor of the JSON Schema examples keyword. Use of example is discouraged, and later versions of this specification may remove it. |
This object MAY be extended with Specification Extensions, though as noted, additional properties MAY omit the x-
prefix within this object.
JSON Schema Draft 2020-12 supports collecting annotations, including treating unrecognized keywords as annotations.
OAS implementations MAY use such annotations, including extensions not recognized as part of a declared JSON Schema vocabulary, as the basis for further validation.
Note that JSON Schema Draft 2020-12 does not require an x-
prefix for extensions.
The format
keyword (when using default format-annotation vocabulary) and the contentMediaType
, contentEncoding
, and contentSchema
keywords define constraints on the data, but are treated as annotations instead of being validated directly.
Extended validation is one way that these constraints MAY be enforced.
The readOnly
and writeOnly
keywords are annotations, as JSON Schema is not aware of how the data it is validating is being used.
Validation of these keywords MAY be done by checking the annotation, the read or write direction, and (if relevant) the current value of the field.
JSON Schema Validation Draft 2020-12 §9.4 defines the expectations of these keywords, including that a resource (described as the "owning authority") MAY either ignore a readOnly
field or treat it as an error.
Fields that are both required and read-only are an example of when it is beneficial to ignore a readOnly: true
constraint in a PUT, particularly if the value has not been changed.
This allows correctly requiring the field on a GET and still using the same representation and schema with PUT.
Even when read-only fields are not required, stripping them is burdensome for clients, particularly when the JSON data is complex or deeply nested.
Note that the behavior of readOnly
in particular differs from that specified by version 3.0 of this specification.
The OpenAPI Specification allows combining and extending model definitions using the allOf
keyword of JSON Schema, in effect offering model composition.
allOf
takes an array of object definitions that are validated independently but together compose a single object.
While composition offers model extensibility, it does not imply a hierarchy between the models.
To support polymorphism, the OpenAPI Specification adds the discriminator
field.
When used, the discriminator
indicates the name of the property that hints which schema definition is expected to validate the structure of the model.
As such, the discriminator
field MUST be a required field.
There are two ways to define the value of a discriminator for an inheriting instance.
- Use the schema name.
- Override the schema name by overriding the property with a new value. If a new value exists, this takes precedence over the schema name.
Implementations MAY support defining generic or template data structures using JSON Schema's dynamic referencing feature:
$dynamicAnchor
identifies a set of possible schemas (including a default placeholder schema) to which a$dynamicRef
can resolve$dynamicRef
resolves to the first matching$dynamicAnchor
encountered on its path from the schema entry point to the reference, as described in the JSON Schema specification
An example is included in the "Schema Object Examples" section below, and further information can be found on the Learn OpenAPI site's "Dynamic References" page.
The Schema Object's enum
keyword does not allow associating descriptions or other information with individual values.
Implementations MAY support recognizing a oneOf
or anyOf
where each subschema in the keyword's array consists of a const
keyword and annotations such as title
or description
as an enumerated type with additional information. The exact behavior of this pattern beyond what is required by JSON Schema is implementation-defined.
The xml field allows extra definitions when translating the JSON definition to XML. The XML Object contains additional information about the available options.
It is important for tooling to be able to determine which dialect or meta-schema any given resource wishes to be processed with: JSON Schema Core, JSON Schema Validation, OpenAPI Schema dialect, or some custom meta-schema.
The $schema
keyword MAY be present in any Schema Object that is a schema resource root, and if present MUST be used to determine which dialect should be used when processing the schema. This allows use of Schema Objects which comply with other drafts of JSON Schema than the default Draft 2020-12 support. Tooling MUST support the OAS dialect schema id, and MAY support additional values of $schema
.
To allow use of a different default $schema
value for all Schema Objects contained within an OAS document, a jsonSchemaDialect
value may be set within the OpenAPI Object. If this default is not set, then the OAS dialect schema id MUST be used for these Schema Objects. The value of $schema
within a resource root Schema Object always overrides any default.
For standalone JSON Schema documents that do not set $schema
, or for Schema Objects in OpenAPI description documents that are not complete documents, the dialect SHOULD be assumed to be the OAS dialect.
However, for maximum interoperability, it is RECOMMENDED that OpenAPI description authors explicitly set the dialect through $schema
in such documents.
{
"type": "string",
"format": "email"
}
type: string
format: email
{
"type": "object",
"required": ["name"],
"properties": {
"name": {
"type": "string"
},
"address": {
"$ref": "#/components/schemas/Address"
},
"age": {
"type": "integer",
"format": "int32",
"minimum": 0
}
}
}
type: object
required:
- name
properties:
name:
type: string
address:
$ref: '#/components/schemas/Address'
age:
type: integer
format: int32
minimum: 0
For a simple string to string mapping:
{
"type": "object",
"additionalProperties": {
"type": "string"
}
}
type: object
additionalProperties:
type: string
For a string to model mapping:
{
"type": "object",
"additionalProperties": {
"$ref": "#/components/schemas/ComplexModel"
}
}
type: object
additionalProperties:
$ref: '#/components/schemas/ComplexModel'
{
"oneOf": [
{
"const": "RGB",
"title": "Red, Green, Blue",
"description": "Specify colors with the red, green, and blue additive color model"
},
{
"const": "CMYK",
"title": "Cyan, Magenta, Yellow, Black",
"description": "Specify colors with the cyan, magenta, yellow, and black subtractive color model"
}
]
}
oneOf:
- const: RGB
title: Red, Green, Blue
description: Specify colors with the red, green, and blue additive color model
- const: CMYK
title: Cyan, Magenta, Yellow, Black
description: Specify colors with the cyan, magenta, yellow, and black subtractive color model
{
"type": "object",
"properties": {
"id": {
"type": "integer",
"format": "int64"
},
"name": {
"type": "string"
}
},
"required": ["name"],
"examples": [
{
"name": "Puma",
"id": 1
}
]
}
type: object
properties:
id:
type: integer
format: int64
name:
type: string
required:
- name
examples:
- name: Puma
id: 1
{
"components": {
"schemas": {
"ErrorModel": {
"type": "object",
"required": ["message", "code"],
"properties": {
"message": {
"type": "string"
},
"code": {
"type": "integer",
"minimum": 100,
"maximum": 600
}
}
},
"ExtendedErrorModel": {
"allOf": [
{
"$ref": "#/components/schemas/ErrorModel"
},
{
"type": "object",
"required": ["rootCause"],
"properties": {
"rootCause": {
"type": "string"
}
}
}
]
}
}
}
}
components:
schemas:
ErrorModel:
type: object
required:
- message
- code
properties:
message:
type: string
code:
type: integer
minimum: 100
maximum: 600
ExtendedErrorModel:
allOf:
- $ref: '#/components/schemas/ErrorModel'
- type: object
required:
- rootCause
properties:
rootCause:
type: string
{
"components": {
"schemas": {
"Pet": {
"type": "object",
"discriminator": {
"propertyName": "petType"
},
"properties": {
"name": {
"type": "string"
},
"petType": {
"type": "string"
}
},
"required": ["name", "petType"]
},
"Cat": {
"description": "A representation of a cat. Note that `Cat` will be used as the discriminating value.",
"allOf": [
{
"$ref": "#/components/schemas/Pet"
},
{
"type": "object",
"properties": {
"huntingSkill": {
"type": "string",
"description": "The measured skill for hunting",
"default": "lazy",
"enum": ["clueless", "lazy", "adventurous", "aggressive"]
}
},
"required": ["huntingSkill"]
}
]
},
"Dog": {
"description": "A representation of a dog. Note that `Dog` will be used as the discriminating value.",
"allOf": [
{
"$ref": "#/components/schemas/Pet"
},
{
"type": "object",
"properties": {
"packSize": {
"type": "integer",
"format": "int32",
"description": "the size of the pack the dog is from",
"default": 0,
"minimum": 0
}
},
"required": ["packSize"]
}
]
}
}
}
}
components:
schemas:
Pet:
type: object
discriminator:
propertyName: petType
properties:
name:
type: string
petType:
type: string
required:
- name
- petType
Cat: # "Cat" will be used as the discriminating value
description: A representation of a cat
allOf:
- $ref: '#/components/schemas/Pet'
- type: object
properties:
huntingSkill:
type: string
description: The measured skill for hunting
enum:
- clueless
- lazy
- adventurous
- aggressive
required:
- huntingSkill
Dog: # "Dog" will be used as the discriminating value
description: A representation of a dog
allOf:
- $ref: '#/components/schemas/Pet'
- type: object
properties:
packSize:
type: integer
format: int32
description: the size of the pack the dog is from
default: 0
minimum: 0
required:
- packSize
{
"components": {
"schemas": {
"genericArrayComponent": {
"$id": "fully_generic_array",
"type": "array",
"items": {
"$dynamicRef": "#generic-array"
},
"$defs": {
"allowAll": {
"$dynamicAnchor": "generic-array"
}
}
},
"numberArray": {
"$id": "array_of_numbers",
"$ref": "fully_generic_array",
"$defs": {
"numbersOnly": {
"$dynamicAnchor": "generic-array",
"type": "number"
}
}
},
"stringArray": {
"$id": "array_of_strings",
"$ref": "fully_generic_array",
"$defs": {
"stringsOnly": {
"$dynamicAnchor": "generic-array",
"type": "string"
}
}
},
"objWithTypedArray": {
"$id": "obj_with_typed_array",
"type": "object",
"required": ["dataType", "data"],
"properties": {
"dataType": {
"enum": ["string", "number"]
}
},
"oneOf": [{
"properties": {
"dataType": {"const": "string"},
"data": {"$ref": "array_of_strings"}
}
}, {
"properties": {
"dataType": {"const": "number"},
"data": {"$ref": "array_of_numbers"}
}
}]
}
}
}
}
components:
schemas:
genericArrayComponent:
$id: fully_generic_array
type: array
items:
$dynamicRef: '#generic-array'
$defs:
allowAll:
$dynamicAnchor: generic-array
numberArray:
$id: array_of_numbers
$ref: fully_generic_array
$defs:
numbersOnly:
$dynamicAnchor: generic-array
type: number
stringArray:
$id: array_of_strings
$ref: fully_generic_array
$defs:
stringsOnly:
$dynamicAnchor: generic-array
type: string
objWithTypedArray:
$id: obj_with_typed_array
type: object
required:
- dataType
- data
properties:
dataType:
enum:
- string
- number
oneOf:
- properties:
dataType:
const: string
data:
$ref: array_of_strings
- properties:
dataType:
const: number
data:
$ref: array_of_numbers
When request bodies or response payloads may be one of a number of different schemas, a Discriminator Object gives a hint about the expected schema of the document. This hint can be used to aid in serialization, deserialization, and validation. The Discriminator Object does this by implicitly or explicitly associating the possible values of a named property with alternative schemas.
Note that discriminator
MUST NOT change the validation outcome of the schema.
This object MAY be extended with Specification Extensions.
The Discriminator Object is legal only when using one of the composite keywords oneOf
, anyOf
, allOf
.
In both the oneOf
and anyOf
use cases, where those keywords are adjacent to discriminator
, all possible schemas MUST be listed explicitly.
To avoid redundancy, the discriminator MAY be added to a parent schema definition, and all schemas building on the parent schema via an allOf
construct may be used as an alternate schema.
The allOf
form of discriminator
is only useful for non-validation use cases; validation with the parent schema with this form of discriminator
does not perform a search for child schemas or use them in validation in any way.
This is because discriminator
cannot change the validation outcome, and no standard JSON Schema keyword connects the parent schema to the child schemas.
The behavior of any configuration of oneOf
, anyOf
, allOf
and discriminator
that is not described above is undefined.
The value of the property named in propertyName
is used as the name of the associated schema under the Components Object, unless a mapping
is present for that value.
The mapping
entry maps a specific property value to either a different schema component name, or to a schema identified by a URI.
When using implicit or explicit schema component names, inline oneOf
or anyOf
subschemas are not considered.
The behavior of a mapping
value that is both a valid schema name and a valid relative URI reference is implementation-defined, but it is RECOMMENDED that it be treated as a schema name.
To ensure that an ambiguous value (e.g. "foo"
) is treated as a relative URI reference by all implementations, authors MUST prefix it with the "."
path segment (e.g. "./foo"
).
Mapping keys MUST be string values, but tooling MAY convert response values to strings for comparison. However, the exact nature of such conversions are implementation-defined.
For these examples, assume all schemas are in the entry document of the OAD; for handling of discriminator
in referenced documents see Resolving Implicit Connections.
In OAS 3.x, a response payload MAY be described to be exactly one of any number of types:
MyResponseType:
oneOf:
- $ref: '#/components/schemas/Cat'
- $ref: '#/components/schemas/Dog'
- $ref: '#/components/schemas/Lizard'
which means the payload MUST, by validation, match exactly one of the schemas described by Cat
, Dog
, or Lizard
. Deserialization of a oneOf
can be a costly operation, as it requires determining which schema matches the payload and thus should be used in deserialization. This problem also exists for anyOf
schemas. A discriminator
MAY be used as a "hint" to improve the efficiency of selection of the matching schema. The discriminator
field cannot change the validation result of the oneOf
, it can only help make the deserialization more efficient and provide better error messaging. We can specify the exact field that tells us which schema is expected to match the instance:
MyResponseType:
oneOf:
- $ref: '#/components/schemas/Cat'
- $ref: '#/components/schemas/Dog'
- $ref: '#/components/schemas/Lizard'
discriminator:
propertyName: petType
The expectation now is that a property with name petType
MUST be present in the response payload, and the value will correspond to the name of a schema defined in the OpenAPI Description. Thus the response payload:
{
"id": 12345,
"petType": "Cat"
}
will indicate that the Cat
schema is expected to match this payload.
In scenarios where the value of the discriminator
field does not match the schema name or implicit mapping is not possible, an optional mapping
definition MAY be used:
MyResponseType:
oneOf:
- $ref: '#/components/schemas/Cat'
- $ref: '#/components/schemas/Dog'
- $ref: '#/components/schemas/Lizard'
- $ref: https://gigantic-server.com/schemas/Monster/schema.json
discriminator:
propertyName: petType
mapping:
dog: '#/components/schemas/Dog'
monster: https://gigantic-server.com/schemas/Monster/schema.json
Here the discriminating value of dog
will map to the schema #/components/schemas/Dog
, rather than the default (implicit) value of #/components/schemas/dog
. If the discriminating value does not match an implicit or explicit mapping, no schema can be determined and validation SHOULD fail.
When used in conjunction with the anyOf
construct, the use of the discriminator can avoid ambiguity for serializers/deserializers where multiple schemas may satisfy a single payload.
This example shows the allOf
usage, which avoids needing to reference all child schemas in the parent:
components:
schemas:
Pet:
type: object
required:
- petType
properties:
petType:
type: string
discriminator:
propertyName: petType
mapping:
dog: Dog
Cat:
allOf:
- $ref: '#/components/schemas/Pet'
- type: object
# all other properties specific to a `Cat`
properties:
name:
type: string
Dog:
allOf:
- $ref: '#/components/schemas/Pet'
- type: object
# all other properties specific to a `Dog`
properties:
bark:
type: string
Lizard:
allOf:
- $ref: '#/components/schemas/Pet'
- type: object
# all other properties specific to a `Lizard`
properties:
lovesRocks:
type: boolean
Validated against the Pet
schema, a payload like this:
{
"petType": "Cat",
"name": "Misty"
}
will indicate that the #/components/schemas/Cat
schema is expected to match. Likewise this payload:
{
"petType": "dog",
"bark": "soft"
}
will map to #/components/schemas/Dog
because the dog
entry in the mapping
element maps to Dog
which is the schema name for #/components/schemas/Dog
.
A metadata object that allows for more fine-tuned XML model definitions.
When using arrays, XML element names are not inferred (for singular/plural forms) and the name
field SHOULD be used to add that information.
See examples for expected behavior.
Field Name | Type | Description |
---|---|---|
name | string |
Replaces the name of the element/attribute used for the described schema property. When defined within items , it will affect the name of the individual XML elements within the list. When defined alongside type being "array" (outside the items ), it will affect the wrapping element if and only if wrapped is true . If wrapped is false , it will be ignored. |
namespace | string |
The URI of the namespace definition. Value MUST be in the form of a non-relative URI. |
prefix | string |
The prefix to be used for the name. |
attribute | boolean |
Declares whether the property definition translates to an attribute instead of an element. Default value is false . |
wrapped | boolean |
MAY be used only for an array definition. Signifies whether the array is wrapped (for example, <books><book/><book/></books> ) or unwrapped (<book/><book/> ). Default value is false . The definition takes effect only when defined alongside type being "array" (outside the items ). |
This object MAY be extended with Specification Extensions.
The namespace
field is intended to match the syntax of XML namespaces, although there are a few caveats:
- Versions 3.1.0, 3.0.3, and earlier of this specification erroneously used the term "absolute URI" instead of "non-relative URI", so authors using namespaces that include a fragment should check tooling support carefully.
- XML allows but discourages relative URI-references, while this specification outright forbids them.
- XML 1.1 allows IRIs (RFC3987) as namespaces, and specifies that namespaces are compared without any encoding or decoding, which means that IRIs encoded to meet this specification's URI syntax requirement cannot be compared to IRIs as-is.
Each of the following examples represent the value of the properties
keyword in a Schema Object that is omitted for brevity.
The JSON and YAML representations of the properties
value are followed by an example XML representation produced for the single property shown.
Basic string property:
{
"animals": {
"type": "string"
}
}
animals:
type: string
<animals>...</animals>
Basic string array property (wrapped
is false
by default):
{
"animals": {
"type": "array",
"items": {
"type": "string"
}
}
}
animals:
type: array
items:
type: string
<animals>...</animals>
<animals>...</animals>
<animals>...</animals>
{
"animals": {
"type": "string",
"xml": {
"name": "animal"
}
}
}
animals:
type: string
xml:
name: animal
<animal>...</animal>
In this example, a full model definition is shown.
{
"Person": {
"type": "object",
"properties": {
"id": {
"type": "integer",
"format": "int32",
"xml": {
"attribute": true
}
},
"name": {
"type": "string",
"xml": {
"namespace": "https://example.com/schema/sample",
"prefix": "sample"
}
}
}
}
}
Person:
type: object
properties:
id:
type: integer
format: int32
xml:
attribute: true
name:
type: string
xml:
namespace: https://example.com/schema/sample
prefix: sample
<Person id="123">
<sample:name xmlns:sample="https://example.com/schema/sample">example</sample:name>
</Person>
Changing the element names:
{
"animals": {
"type": "array",
"items": {
"type": "string",
"xml": {
"name": "animal"
}
}
}
}
animals:
type: array
items:
type: string
xml:
name: animal
<animal>value</animal>
<animal>value</animal>
The external name
field has no effect on the XML:
{
"animals": {
"type": "array",
"items": {
"type": "string",
"xml": {
"name": "animal"
}
},
"xml": {
"name": "aliens"
}
}
}
animals:
type: array
items:
type: string
xml:
name: animal
xml:
name: aliens
<animal>value</animal>
<animal>value</animal>
Even when the array is wrapped, if a name is not explicitly defined, the same name will be used both internally and externally:
{
"animals": {
"type": "array",
"items": {
"type": "string"
},
"xml": {
"wrapped": true
}
}
}
animals:
type: array
items:
type: string
xml:
wrapped: true
<animals>
<animals>value</animals>
<animals>value</animals>
</animals>
To overcome the naming problem in the example above, the following definition can be used:
{
"animals": {
"type": "array",
"items": {
"type": "string",
"xml": {
"name": "animal"
}
},
"xml": {
"wrapped": true
}
}
}
animals:
type: array
items:
type: string
xml:
name: animal
xml:
wrapped: true
<animals>
<animal>value</animal>
<animal>value</animal>
</animals>
Affecting both internal and external names:
{
"animals": {
"type": "array",
"items": {
"type": "string",
"xml": {
"name": "animal"
}
},
"xml": {
"name": "aliens",
"wrapped": true
}
}
}
animals:
type: array
items:
type: string
xml:
name: animal
xml:
name: aliens
wrapped: true
<aliens>
<animal>value</animal>
<animal>value</animal>
</aliens>
If we change the external element but not the internal ones:
{
"animals": {
"type": "array",
"items": {
"type": "string"
},
"xml": {
"name": "aliens",
"wrapped": true
}
}
}
animals:
type: array
items:
type: string
xml:
name: aliens
wrapped: true
<aliens>
<aliens>value</aliens>
<aliens>value</aliens>
</aliens>
Defines a security scheme that can be used by the operations.
Supported schemes are HTTP authentication, an API key (either as a header, a cookie parameter or as a query parameter), mutual TLS (use of a client certificate), OAuth2's common flows (implicit, password, client credentials and authorization code) as defined in RFC6749, and [[OpenID-Connect-Core]]. Please note that as of 2020, the implicit flow is about to be deprecated by OAuth 2.0 Security Best Current Practice. Recommended for most use cases is Authorization Code Grant flow with PKCE.
Field Name | Type | Applies To | Description |
---|---|---|---|
type | string |
Any | REQUIRED. The type of the security scheme. Valid values are "apiKey" , "http" , "mutualTLS" , "oauth2" , "openIdConnect" . |
description | string |
Any | A description for security scheme. CommonMark syntax MAY be used for rich text representation. |
name | string |
apiKey |
REQUIRED. The name of the header, query or cookie parameter to be used. |
in | string |
apiKey |
REQUIRED. The location of the API key. Valid values are "query" , "header" , or "cookie" . |
scheme | string |
http |
REQUIRED. The name of the HTTP Authentication scheme to be used in the Authorization header as defined in RFC7235. The values used SHOULD be registered in the IANA Authentication Scheme registry. The value is case-insensitive, as defined in RFC7235. |
bearerFormat | string |
http ("bearer" ) |
A hint to the client to identify how the bearer token is formatted. Bearer tokens are usually generated by an authorization server, so this information is primarily for documentation purposes. |
flows | OAuth Flows Object | oauth2 |
REQUIRED. An object containing configuration information for the flow types supported. |
openIdConnectUrl | string |
openIdConnect |
REQUIRED. Well-known URL to discover the [[OpenID-Connect-Discovery]] provider metadata. |
This object MAY be extended with Specification Extensions.
{
"type": "http",
"scheme": "basic"
}
type: http
scheme: basic
{
"type": "apiKey",
"name": "api-key",
"in": "header"
}
type: apiKey
name: api-key
in: header
{
"type": "http",
"scheme": "bearer",
"bearerFormat": "JWT"
}
type: http
scheme: bearer
bearerFormat: JWT
{
"type": "mutualTLS",
"description": "Cert must be signed by example.com CA"
}
type: mutualTLS
description: Cert must be signed by example.com CA
{
"type": "oauth2",
"flows": {
"implicit": {
"authorizationUrl": "https://example.com/api/oauth/dialog",
"scopes": {
"write:pets": "modify pets in your account",
"read:pets": "read your pets"
}
}
}
}
type: oauth2
flows:
implicit:
authorizationUrl: https://example.com/api/oauth/dialog
scopes:
write:pets: modify pets in your account
read:pets: read your pets
Allows configuration of the supported OAuth Flows.
Field Name | Type | Description |
---|---|---|
implicit | OAuth Flow Object | Configuration for the OAuth Implicit flow |
password | OAuth Flow Object | Configuration for the OAuth Resource Owner Password flow |
clientCredentials | OAuth Flow Object | Configuration for the OAuth Client Credentials flow. Previously called application in OpenAPI 2.0. |
authorizationCode | OAuth Flow Object | Configuration for the OAuth Authorization Code flow. Previously called accessCode in OpenAPI 2.0. |
This object MAY be extended with Specification Extensions.
Configuration details for a supported OAuth Flow
This object MAY be extended with Specification Extensions.
{
"type": "oauth2",
"flows": {
"implicit": {
"authorizationUrl": "https://example.com/api/oauth/dialog",
"scopes": {
"write:pets": "modify pets in your account",
"read:pets": "read your pets"
}
},
"authorizationCode": {
"authorizationUrl": "https://example.com/api/oauth/dialog",
"tokenUrl": "https://example.com/api/oauth/token",
"scopes": {
"write:pets": "modify pets in your account",
"read:pets": "read your pets"
}
}
}
}
type: oauth2
flows:
implicit:
authorizationUrl: https://example.com/api/oauth/dialog
scopes:
write:pets: modify pets in your account
read:pets: read your pets
authorizationCode:
authorizationUrl: https://example.com/api/oauth/dialog
tokenUrl: https://example.com/api/oauth/token
scopes:
write:pets: modify pets in your account
read:pets: read your pets
Lists the required security schemes to execute this operation. The name used for each property MUST correspond to a security scheme declared in the Security Schemes under the Components Object.
A Security Requirement Object MAY refer to multiple security schemes in which case all schemes MUST be satisfied for a request to be authorized. This enables support for scenarios where multiple query parameters or HTTP headers are required to convey security information.
When the security
field is defined on the OpenAPI Object or Operation Object and contains multiple Security Requirement Objects, only one of the entries in the list needs to be satisfied to authorize the request.
This enables support for scenarios where the API allows multiple, independent security schemes.
An empty Security Requirement Object ({}
) indicates anonymous access is supported.
Field Pattern | Type | Description |
---|---|---|
{name} | [string ] |
Each name MUST correspond to a security scheme which is declared in the Security Schemes under the Components Object. If the security scheme is of type "oauth2" or "openIdConnect" , then the value is a list of scope names required for the execution, and the list MAY be empty if authorization does not require a specified scope. For other security scheme types, the array MAY contain a list of role names which are required for the execution, but are not otherwise defined or exchanged in-band. |
See also Appendix F: Resolving Security Requirements in a Referenced Document for an example using Security Requirement Objects in multi-document OpenAPI Descriptions.
{
"api_key": []
}
api_key: []
{
"petstore_auth": ["write:pets", "read:pets"]
}
petstore_auth:
- write:pets
- read:pets
Optional OAuth2 security as would be defined in an OpenAPI Object or an Operation Object:
{
"security": [
{},
{
"petstore_auth": ["write:pets", "read:pets"]
}
]
}
security:
- {}
- petstore_auth:
- write:pets
- read:pets
While the OpenAPI Specification tries to accommodate most use cases, additional data can be added to extend the specification at certain points.
The extensions properties are implemented as patterned fields that are always prefixed by x-
.
Field Pattern | Type | Description |
---|---|---|
^x- | Any | Allows extensions to the OpenAPI Schema. The field name MUST begin with x- , for example, x-internal-id . Field names beginning x-oai- and x-oas- are reserved for uses defined by the OpenAPI Initiative. The value can be any valid JSON value (null , a primitive, an array, or an object.) |
The OpenAPI Initiative maintains several [[OpenAPI-Registry|extension registries]], including registries for individual extension keywords and extension keyword namespaces.
Extensions are one of the best ways to prove the viability of proposed additions to the specification. It is therefore RECOMMENDED that implementations be designed for extensibility to support community experimentation.
Support for any one extension is OPTIONAL, and support for one extension does not imply support for others.
Some objects in the OpenAPI Specification MAY be declared and remain empty, or be completely removed, even though they are inherently the core of the API documentation.
The reasoning is to allow an additional layer of access control over the documentation. While not part of the specification itself, certain libraries MAY choose to allow access to parts of the documentation based on some form of authentication/authorization.
Two examples of this:
- The Paths Object MAY be present but empty. It may be counterintuitive, but this may tell the viewer that they got to the right place, but can't access any documentation. They would still have access to at least the Info Object which may contain additional information regarding authentication.
- The Path Item Object MAY be empty. In this case, the viewer will be aware that the path exists, but will not be able to see any of its operations or parameters. This is different from hiding the path itself from the Paths Object, because the user will be aware of its existence. This allows the documentation provider to finely control what the viewer can see.
OpenAPI Descriptions use a combination of JSON, YAML, and JSON Schema, and therefore share their security considerations:
In addition, OpenAPI Descriptions are processed by a wide variety of tooling for numerous different purposes, such as client code generation, documentation generation, server side routing, and API testing. OpenAPI Description authors must consider the risks of the scenarios where the OpenAPI Description may be used.
An OpenAPI Description describes the security schemes used to protect the resources it defines. The security schemes available offer varying degrees of protection. Factors such as the sensitivity of the data and the potential impact of a security breach should guide the selection of security schemes for the API resources. Some security schemes, such as basic auth and OAuth Implicit flow, are supported for compatibility with existing APIs. However, their inclusion in OpenAPI does not constitute an endorsement of their use, particularly for highly sensitive data or operations.
OpenAPI Descriptions may contain references to external resources that may be dereferenced automatically by consuming tools. External resources may be hosted on different domains that may be untrusted.
References in an OpenAPI Description may cause a cycle. Tooling must detect and handle cycles to prevent resource exhaustion.
Certain fields allow the use of Markdown which can contain HTML including script. It is the responsibility of tooling to appropriately sanitize the Markdown.
Version | Date | Notes |
---|---|---|
3.1.1 | 2024-10-24 | Patch release of the OpenAPI Specification 3.1.1 |
3.1.0 | 2021-02-15 | Release of the OpenAPI Specification 3.1.0 |
3.1.0-rc1 | 2020-10-08 | rc1 of the 3.1 specification |
3.1.0-rc0 | 2020-06-18 | rc0 of the 3.1 specification |
3.0.4 | 2024-10-24 | Patch release of the OpenAPI Specification 3.0.4 |
3.0.3 | 2020-02-20 | Patch release of the OpenAPI Specification 3.0.3 |
3.0.2 | 2018-10-08 | Patch release of the OpenAPI Specification 3.0.2 |
3.0.1 | 2017-12-06 | Patch release of the OpenAPI Specification 3.0.1 |
3.0.0 | 2017-07-26 | Release of the OpenAPI Specification 3.0.0 |
3.0.0-rc2 | 2017-06-16 | rc2 of the 3.0 specification |
3.0.0-rc1 | 2017-04-27 | rc1 of the 3.0 specification |
3.0.0-rc0 | 2017-02-28 | Implementer's Draft of the 3.0 specification |
2.0 | 2015-12-31 | Donation of Swagger 2.0 to the OpenAPI Initiative |
2.0 | 2014-09-08 | Release of Swagger 2.0 |
1.2 | 2014-03-14 | Initial release of the formal document. |
1.1 | 2012-08-22 | Release of Swagger 1.1 |
1.0 | 2011-08-10 | First release of the Swagger Specification |
Serializing typed data to plain text, which can occur in text/plain
message bodies or multipart
parts, as well as in the application/x-www-form-urlencoded
format in either URL query strings or message bodies, involves significant implementation- or application-defined behavior.
Schema Objects validate data based on the JSON Schema data model, which only recognizes four primitive data types: strings (which are only broadly interoperable as UTF-8), numbers, booleans, and null
.
Notably, integers are not a distinct type from other numbers, with type: "integer"
being a convenience defined mathematically, rather than based on the presence or absence of a decimal point in any string representation.
The Parameter Object, Header Object, and Encoding Object offer features to control how to arrange values from array or object types. They can also be used to control how strings are further encoded to avoid reserved or illegal characters. However, there is no general-purpose specification for converting schema-validated non-UTF-8 primitive data types (or entire arrays or objects) to strings.
Two cases do offer standards-based guidance:
- RFC3987 provides guidance for converting non-Unicode strings to UTF-8, particularly in the context of URIs (and by extension, the form media types which use the same encoding rules)
- RFC6570 specifies which values, including but not limited to
null
, are considered undefined and therefore treated specially in the expansion process when serializing based on that specification
Implementations of RFC6570 often have their own conventions for converting non-string values, but these are implementation-specific and not defined by the RFC itself. This is one reason for the OpenAPI Specification to leave these conversions as implementation-defined: It allows using RFC6570 implementations regardless of how they choose to perform the conversions.
To control the serialization of numbers, booleans, and null
(or other values RFC6570 deems to be undefined) more precisely, schemas can be defined as type: "string"
and constrained using pattern
, enum
, format
, and other keywords to communicate how applications must pre-convert their data prior to schema validation.
The resulting strings would not require any further type conversion.
The format
keyword can assist in serialization.
Some formats (such as date-time
) are unambiguous, while others (such as decimal
in the Format Registry) are less clear.
However, care must be taken with format
to ensure that the specific formats are supported by all relevant tools as unrecognized formats are ignored.
Requiring input as pre-formatted, schema-validated strings also improves round-trip interoperability as not all programming languages and environments support the same data types.
Serialization is defined in terms of RFC6570 URI Templates in three scenarios:
Object | Condition |
---|---|
Parameter Object | When schema is present |
Header Object | When schema is present |
Encoding Object | When encoding for application/x-www-form-urlencoded and any of style , explode , or allowReserved are used |
Implementations of this specification MAY use an implementation of RFC6570 to perform variable expansion, however, some caveats apply.
Note that when using style: "form"
RFC6570 expansion to produce an application/x-www-form-urlencoded
HTTP message body, it is necessary to remove the ?
prefix that is produced to satisfy the URI query string syntax.
When using style
and similar keywords to produce a multipart/form-data
body, the query string names are placed in the name
parameter of the Content-Disposition
part header, and the values are placed in the corresponding part body; the ?
, =
, and &
characters are not used.
Note that while RFC7578 allows using [[RFC3986]] percent-encoding in "file names", it does not otherwise address the use of percent-encoding within the format.
RFC7578 discusses character set and encoding issues for multipart/form-data
in detail, and it is RECOMMENDED that OpenAPI Description authors read this guidance carefully before deciding to use RFC6570-based serialization with this media type.
Note also that not all RFC6570 implementations support all four levels of operators, all of which are needed to fully support the OpenAPI Specification's usage. Using an implementation with a lower level of support will require additional manual construction of URI Templates to work around the limitations.
Certain field values translate to RFC6570 operators (or lack thereof):
field | value | equivalent |
---|---|---|
style | "simple" |
n/a |
style | "matrix" |
; prefix operator |
style | "label" |
. prefix operator |
style | "form" |
? prefix operator |
allowReserved | false |
n/a |
allowReserved | true |
+ prefix operator |
explode | false |
n/a |
explode | true |
* modifier suffix |
Multiple style: "form"
parameters are equivalent to a single RFC6570 variable list using the ?
prefix operator:
parameters:
- name: foo
in: query
schema:
type: object
explode: true
- name: bar
in: query
schema:
type: string
This example is equivalent to RFC6570's {?foo*,bar}
, and NOT {?foo*}{&bar}
. The latter is problematic because if foo
is not defined, the result will be an invalid URI.
The &
prefix operator has no equivalent in the Parameter Object.
Note that RFC6570 does not specify behavior for compound values beyond the single level addressed by explode
. The result of using objects or arrays where no behavior is clearly specified for them is implementation-defined.
Delimiters used by RFC6570 expansion, such as the ,
used to join arrays or object values with style: "simple"
, are all automatically percent-encoded as long as allowReserved
is false
.
Note that since RFC6570 does not define a way to parse variables based on a URI Template, users must take care to first split values by delimiter before percent-decoding values that might contain the delimiter character.
When allowReserved
is true
, both percent-encoding (prior to joining values with a delimiter) and percent-decoding (after splitting on the delimiter) must be done manually at the correct time.
See Appendix E for additional guidance on handling delimiters for style
values with no RFC6570 equivalent that already need to be percent-encoded when used as delimiters.
Configurations with no direct RFC6570 equivalent SHOULD also be handled according to RFC6570.
Implementations MAY create a properly delimited URI Template with variables for individual names and values using RFC6570 regular or reserved expansion (based on allowReserved
).
This includes:
- the styles
pipeDelimited
,spaceDelimited
, anddeepObject
, which have no equivalents at all - the combination of the style
form
withallowReserved: true
, which is not allowed because only one prefix operator can be used at a time - any parameter name that is not a legal RFC6570 variable name
The Parameter Object's name
field has a much more permissive syntax than RFC6570 variable name syntax.
A parameter name that includes characters outside of the allowed RFC6570 variable character set MUST be percent-encoded before it can be used in a URI Template.
Let's say we want to use the following data in a form query string, where formulas
is exploded, and words
is not:
formulas:
a: x+y
b: x/y
c: x^y
words:
- math
- is
- fun
This array of Parameter Objects uses regular style: "form"
expansion, fully supported by RFC6570:
parameters:
- name: formulas
in: query
schema:
type: object
additionalProperties:
type: string
explode: true
- name: words
in: query
schema:
type: array
items:
type: string
This translates to the following URI Template:
{?formulas*,words}
when expanded with the data given earlier, we get:
?a=x%2By&b=x%2Fy&c=x%5Ey&words=math,is,fun
But now let's say that (for some reason), we really want that /
in the b
formula to show up as-is in the query string, and we want our words to be space-separated like in a written phrase.
To do that, we'll add allowReserved: true
to formulas
, and change to style: "spaceDelimited"
for words
:
parameters:
- name: formulas
in: query
schema:
type: object
additionalProperties:
type: string
explode: true
allowReserved: true
- name: words
in: query
style: spaceDelimited
explode: false
schema:
type: array
items:
type: string
We can't combine the ?
and +
RFC6570 prefixes, and there's no way with RFC6570 to replace the ,
separator with a space character.
So we need to restructure the data to fit a manually constructed URI Template that passes all of the pieces through the right sort of expansion.
Here is one such template, using a made-up convention of words.0
for the first entry in the words value, words.1
for the second, and words.2
for the third:
?a={+a}&b={+b}&c={+c}&words={words.0} {words.1} {words.2}
RFC6570 mentions the use of .
"to indicate name hierarchy in substructures," but does not define any specific naming convention or behavior for it.
Since the .
usage is not automatic, we'll need to construct an appropriate input structure for this new template.
We'll also need to pre-process the values for formulas
because while /
and most other reserved characters are allowed in the query string by RFC3986, [
, ]
, and #
are not, and &
, =
, and +
all have special behavior in the application/x-www-form-urlencoded
format, which is what we are using in the query string.
Setting allowReserved: true
does not make reserved characters that are not allowed in URIs allowed, it just allows them to be passed through expansion unchanged.
Therefore, any tooling still needs to percent-encode those characters because reserved expansion will not do it, but it will leave the percent-encoded triples unchanged.
See also Appendix E for further guidance on percent-encoding and form media types, including guidance on handling the delimiter characters for spaceDelimited
, pipeDelimited
, and deepObject
in parameter names and values.
So here is our data structure that arranges the names and values to suit the template above, where values for formulas
have []#&=+
pre-percent encoded (although only +
appears in this example):
a: x%2By
b: x/y
c: x^y
words.0: math
words.1: is
words.2: fun
Expanding our manually assembled template with our restructured data yields the following query string:
?a=x%2By&b=x/y&c=x%5Ey&words=math%20is%20fun
The /
and the pre-percent-encoded %2B
have been left alone, but the disallowed ^
character (inside a value) and space characters (in the template but outside of the expanded variables) were percent-encoded.
Care must be taken when manually constructing templates to handle the values that RFC6570 considers to be undefined correctly:
formulas: {}
words:
- hello
- world
Using this data with our original RFC6570-friendly URI Template, {?formulas*,words}
, produces the following:
?words=hello,world
This means that the manually constructed URI Template and restructured data need to leave out the formulas
object entirely so that the words
parameter is the first and only parameter in the query string.
Restructured data:
words.0: hello
words.1: world
Manually constructed URI Template:
?words={words.0} {words.1}
Result:
?words=hello%20world
In this example, the heart emoji is not legal in URI Template names (or URIs):
parameters:
- name: ❤️
in: query
schema:
type: string
We can't just pass ❤️: "love!"
to an RFC6570 implementation.
Instead, we have to pre-percent-encode the name (which is a six-octet UTF-8 sequence) in both the data and the URI Template:
"%E2%9D%A4%EF%B8%8F": love!
{?%E2%9D%A4%EF%B8%8F}
This will expand to the result:
?%E2%9D%A4%EF%B8%8F=love%21
RFC6570's percent-encoding behavior is not always appropriate for in: "header"
and in: "cookie"
parameters.
In many cases, it is more appropriate to use content
with a media type such as text/plain
and require the application to assemble the correct string.
For both RFC6265 cookies and HTTP headers using the RFC8941 structured fields syntax, non-ASCII content is handled using base64 encoding (contentEncoding: "base64"
).
Note that the standard base64-encoding alphabet includes non-URL-safe characters that are percent-encoded by RFC6570 expansion; serializing values through both encodings is NOT RECOMMENDED.
While contentEncoding
also supports the base64url
encoding, which is URL-safe, the header and cookie RFCs do not mention this encoding.
Most HTTP headers predate the structured field syntax, and a comprehensive assessment of their syntax and encoding rules is well beyond the scope of this specification.
While RFC8187 recommends percent-encoding HTTP (header or trailer) field parameters, these parameters appear after a ;
character.
With style: "simple"
, that delimiter would itself be percent-encoded, violating the general HTTP field syntax.
Using style: "form"
with in: "cookie"
is ambiguous for a single value, and incorrect for multiple values.
This is true whether the multiple values are the result of using explode: true
or not.
This style is specified to be equivalent to RFC6570 form expansion which includes the ?
character (see Appendix C for more details), which is not part of the cookie syntax.
However, examples of this style in past versions of this specification have not included the ?
prefix, suggesting that the comparison is not exact.
Because implementations that rely on an RFC6570 implementation and those that perform custom serialization based on the style example will produce different results, it is implementation-defined as to which of the two results is correct.
For multiple values, style: "form"
is always incorrect as name=value pairs in cookies are delimited by ;
(a semicolon followed by a space character) rather than &
.
NOTE: In this section, the application/x-www-form-urlencoded
and multipart/form-data
media types are abbreviated as form-urlencoded
and form-data
, respectively, for readability.
Percent-encoding is used in URIs and media types that derive their syntax from URIs. This process is concerned with three sets of characters, the names of which vary among specifications but are defined as follows for the purposes of this section:
- unreserved characters do not need to be percent-encoded; while it is safe to percent-encode them, doing so produces a URI that is not normalized
- reserved characters either have special behavior in the URI syntax (such as delimiting components) or are reserved for other specifications that need to define special behavior (e.g.
form-urlencoded
defines special behavior for=
,&
, and+
) - unsafe characters are known to cause problems when parsing URIs in certain environments
Unless otherwise specified, this section uses RFC3986's definition of reserved and unreserved, and defines the unsafe set as all characters not included in either of those sets.
Each URI component (such as the query string) considers some of the reserved characters to be unsafe, either because they serve as delimiters between the components (e.g. #
), or (in the case of [
and ]
) were historically considered globally unsafe but were later given reserved status for limited purposes.
Reserved characters with no special meaning defined within a component can be left un-percent encoded. However, other specifications can define special meanings, requiring percent-encoding for those characters outside of the additional special meanings.
The form-urlencoded
media type defines special meanings for =
and &
as delimiters, and +
as the replacement for the space character (instead of its percent-encoded form of %20
).
This means that while these three characters are reserved-but-allowed in query strings by RFC3986, they must be percent-encoded in form-urlencoded
query strings except when used for their form-urlencoded
purposes; see Appendix C for an example of handling +
in form values.
RFC7578 suggests RFC3986-based percent-encoding as a mechanism to keep text-based per-part header data such as file names within the ASCII character set.
This suggestion was not part of older (pre-2015) specifications for form-data
, so care must be taken to ensure interoperability.
The form-data
media type allows arbitrary text or binary data in its parts, so percent-encoding is not needed and is likely to cause interoperability problems unless the Content-Type
of the part is defined to require it.
URI percent encoding and the form-urlencoded
media type have complex specification histories spanning multiple revisions and, in some cases, conflicting claims of ownership by different standards bodies.
Unfortunately, these specifications each define slightly different percent-encoding rules, which need to be taken into account if the URIs or form-urlencoded
message bodies will be subject to strict validation.
(Note that many URI parsers do not perform validation by default.)
This specification normatively cites the following relevant standards:
Specification | Date | OAS Usage | Percent-Encoding | Notes |
---|---|---|---|---|
RFC3986 | 01/2005 | URI/URL syntax | [[RFC3986]] | obsoletes [[RFC1738]], [[RFC2396]] |
RFC6570 | 03/2012 | style-based serialization | [[RFC3986]] | does not use + for form‑urlencoded |
RFC1866 | 11/1995 | content-based serialization | [[RFC1738]] | obsoleted by [[HTML401]] Section 17.13.4.1, [[URL]] Section 5 |
Style-based serialization is used in the Parameter Object when schema
is present, and in the Encoding Object when at least one of style
, explode
, or allowReserved
is present.
See Appendix C for more details of RFC6570's two different approaches to percent-encoding, including an example involving +
.
Content-based serialization is defined by the Media Type Object, and used with the Parameter Object when the content
field is present, and with the Encoding Object based on the contentType
field when the fields style
, explode
, and allowReserved
are absent.
Each part is encoded based on the media type (e.g. text/plain
or application/json
), and must then be percent-encoded for use in a form-urlencoded
string.
Note that content-based serialization for form-data
does not expect or require percent-encoding in the data, only in per-part header values.
In most cases, generating query strings in strict compliance with [[RFC3986]] is sufficient to pass validation (including JSON Schema's format: "uri"
and format: "uri-reference"
), but some form-urlencoded
implementations still expect the slightly more restrictive [[RFC1738]] rules to be used.
Since all RFC1738-compliant URIs are compliant with RFC3986, applications needing to ensure historical interoperability SHOULD use RFC1738's rules.
WHATWG is a web browser-oriented standards group that has defined a "URL Living Standard" for parsing and serializing URLs in a browser context, including parsing and serializing form-urlencoded
data.
WHATWG's percent-encoding rules for query strings are different depending on whether the query string is being treated as form-urlencoded
(where it requires more percent-encoding than [[RFC1738]]) or as part of the generic syntax, where it allows characters that [[RFC3986]] forbids.
Implementations needing maximum compatibility with web browsers SHOULD use WHATWG's form-urlencoded
percent-encoding rules.
However, they SHOULD NOT rely on WHATWG's less stringent generic query string rules, as the resulting URLs would fail RFC3986 validation, including JSON Schema's format: uri
and format: uri-reference
.
The percent-decoding algorithm does not care which characters were or were not percent-decoded, which means that URIs percent-encoded according to any specification will be decoded correctly.
Similarly, all form-urlencoded
decoding algorithms simply add +
-for-space handling to the percent-decoding algorithm, and will work regardless of the encoding specification used.
However, care must be taken to use form-urlencoded
decoding if +
represents a space, and to use regular percent-decoding if +
represents itself as a literal value.
The [
, ]
, |
, and space characters, which are used as delimiters for the deepObject
, pipeDelimited
, and spaceDelimited
styles, respectively, all MUST be percent-encoded to comply with [[RFC3986]].
This requires users to pre-encode the character(s) in some other way in parameter names and values to distinguish them from the delimiter usage when using one of these styles.
The space character is always illegal and encoded in some way by all implementations of all versions of the relevant standards.
While one could use the form-urlencoded
convention of +
to distinguish spaces in parameter names and values from spaceDelimited
delimiters encoded as %20
, the specifications define the decoding as a single pass, making it impossible to distinguish the different usages in the decoded result.
Some environments use [
, ]
, and possibly |
unencoded in query strings without apparent difficulties, and WHATWG's generic query string rules do not require percent-encoding them.
Code that relies on leaving these delimiters unencoded, while using regular percent-encoding for them within names and values, is not guaranteed to be interoperable across all implementations.
For maximum interoperability, it is RECOMMENDED to either define and document an additional escape convention while percent-encoding the delimiters for these styles, or to avoid these styles entirely. The exact method of additional encoding/escaping is left to the API designer, and is expected to be performed before serialization and encoding described in this specification, and reversed after this specification's encoding and serialization steps are reversed. This keeps it outside of the processes governed by this specification.
This appendix shows how to retrieve an HTTP-accessible multi-document OpenAPI Description (OAD) and resolve a Security Requirement Object in the referenced (non-entry) document. See Resolving Implicit Connections for more information.
First, the entry document is where parsing begins. It defines the MySecurity
security scheme to be JWT-based, and it defines a Path Item as a reference to a component in another document:
GET /api/description/openapi HTTP/1.1
Host: www.example.com
Accept: application/openapi+json
"components": {
"securitySchemes": {
"MySecurity": {
"type": "http",
"scheme": "bearer",
"bearerFormat": "JWT"
}
}
},
"paths": {
"/foo": {
"$ref": "other#/components/pathItems/Foo"
}
}
GET /api/description/openapi HTTP/1.1
Host: www.example.com
Accept: application/openapi+yaml
components:
securitySchemes:
MySecurity:
type: http
scheme: bearer
bearerFormat: JWT
paths:
/foo:
$ref: 'other#/components/pathItems/Foo'
This entry document references another document, other
, without using a file extension. This gives the client the flexibility to choose an acceptable format on a resource-by-resource basis, assuming both representations are available:
GET /api/description/other HTTP/1.1
Host: www.example.com
Accept: application/openapi+json
"components": {
"securitySchemes": {
"MySecurity": {
"type": "http",
"scheme": "basic"
}
},
"pathItems": {
"Foo": {
"get": {
"security": [
"MySecurity": []
]
}
}
}
}
GET /api/description/other HTTP/1.1
Host: www.example.com
Accept: application/openapi+yaml
components:
securitySchemes:
MySecurity:
type: http
scheme: basic
pathItems:
Foo:
get:
security:
- MySecurity: []
In the other
document, the referenced path item has a Security Requirement for a Security Scheme, MySecurity
. The same Security Scheme exists in the original entry document. As outlined in Resolving Implicit Connections, MySecurity
is resolved with an implementation-defined behavior. However, documented in that section, it is RECOMMENDED that tools resolve component names from the entry document. As with all implementation-defined behavior, it is important to check tool documentation to determine which behavior is supported.