From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc9205.txt | 1533 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1533 insertions(+) create mode 100644 doc/rfc/rfc9205.txt (limited to 'doc/rfc/rfc9205.txt') diff --git a/doc/rfc/rfc9205.txt b/doc/rfc/rfc9205.txt new file mode 100644 index 0000000..eecff53 --- /dev/null +++ b/doc/rfc/rfc9205.txt @@ -0,0 +1,1533 @@ + + + + +Internet Engineering Task Force (IETF) M. Nottingham +Request for Comments: 9205 June 2022 +BCP: 56 +Obsoletes: 3205 +Category: Best Current Practice +ISSN: 2070-1721 + + + Building Protocols with HTTP + +Abstract + + Applications often use HTTP as a substrate to create HTTP-based APIs. + This document specifies best practices for writing specifications + that use HTTP to define new application protocols. It is written + primarily to guide IETF efforts to define application protocols using + HTTP for deployment on the Internet but might be applicable in other + situations. + + This document obsoletes RFC 3205. + +Status of This Memo + + This memo documents an Internet Best Current Practice. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Further information on + BCPs is available in Section 2 of RFC 7841. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + https://www.rfc-editor.org/info/rfc9205. + +Copyright Notice + + Copyright (c) 2022 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (https://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. Code Components extracted from this document must + include Revised BSD License text as described in Section 4.e of the + Trust Legal Provisions and are provided without warranty as described + in the Revised BSD License. + +Table of Contents + + 1. Introduction + 1.1. Notational Conventions + 2. Is HTTP Being Used? + 2.1. Non-HTTP Protocols + 3. What's Important About HTTP + 3.1. Generic Semantics + 3.2. Links + 3.3. Rich Functionality + 4. Best Practices for Specifying the Use of HTTP + 4.1. Specifying the Use of HTTP + 4.2. Specifying Server Behaviour + 4.3. Specifying Client Behaviour + 4.4. Specifying URLs + 4.4.1. Discovering an Application's URLs + 4.4.2. Considering URI Schemes + 4.4.3. Choosing Transport Ports + 4.5. Using HTTP Methods + 4.5.1. GET + 4.5.2. OPTIONS + 4.6. Using HTTP Status Codes + 4.6.1. Redirection + 4.7. Specifying HTTP Header Fields + 4.8. Defining Message Content + 4.9. Leveraging HTTP Caching + 4.9.1. Freshness + 4.9.2. Stale Responses + 4.9.3. Caching and Application Semantics + 4.9.4. Varying Content Based Upon the Request + 4.10. Handling Application State + 4.11. Making Multiple Requests + 4.12. Client Authentication + 4.13. Coexisting with Web Browsing + 4.14. Maintaining Application Boundaries + 4.15. Using Server Push + 4.16. Allowing Versioning and Evolution + 5. IANA Considerations + 6. Security Considerations + 6.1. Privacy Considerations + 7. References + 7.1. Normative References + 7.2. Informative References + Appendix A. Changes from RFC 3205 + Author's Address + +1. Introduction + + Applications other than Web browsing often use HTTP [HTTP] as a + substrate, a practice sometimes referred to as creating "HTTP-based + APIs", "REST APIs", or just "HTTP APIs". This is done for a variety + of reasons, including: + + * familiarity by implementers, specifiers, administrators, + developers, and users; + + * availability of a variety of client, server, and proxy + implementations; + + * ease of use; + + * availability of Web browsers; + + * reuse of existing mechanisms like authentication and encryption; + + * presence of HTTP servers and clients in target deployments; and + + * its ability to traverse firewalls. + + These protocols are often ad hoc, intended for only deployment by one + or a few servers and consumption by a limited set of clients. As a + result, a body of practices and tools has arisen around defining + HTTP-based APIs that favour these conditions. + + However, when such an application has multiple, separate + implementations, is deployed on multiple uncoordinated servers, and + is consumed by diverse clients (as is often the case for HTTP APIs + defined by standards efforts), tools and practices intended for + limited deployment can become unsuitable. + + This mismatch is largely because the API's clients and servers will + implement and evolve at different paces, leading to a need for + deployments with different features and versions to coexist. As a + result, the designers of HTTP-based APIs intended for such + deployments need to more carefully consider how extensibility of the + service will be handled and how different deployment requirements + will be accommodated. + + More generally, an application protocol using HTTP faces a number of + design decisions, including: + + * Should it define a new URI scheme? Use new ports? + + * Should it use standard HTTP methods and status codes or define new + ones? + + * How can the maximum value be extracted from the use of HTTP? + + * How does it coexist with other uses of HTTP -- especially Web + browsing? + + * How can interoperability problems and "protocol dead ends" be + avoided? + + Section 2 defines when this document applies, Section 3 surveys the + properties of HTTP that are important to preserve, and Section 4 + contains best practices for the specification of applications that + use HTTP. + + It is written primarily to guide IETF efforts to define application + protocols using HTTP for deployment on the Internet but might be + applicable in other situations. Note that the requirements herein do + not necessarily apply to the development of generic HTTP extensions. + + This document obsoletes [RFC3205] to reflect the experience and + developments regarding HTTP in the intervening time. + +1.1. Notational Conventions + + 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. + +2. Is HTTP Being Used? + + Different applications have different goals when using HTTP. The + recommendations in this document apply when a specification defines + an application that: + + * uses the transport port 80 or 443, or + + * uses the URI scheme "http" or "https", or + + * uses an ALPN protocol ID [RFC7301] that generically identifies + HTTP (e.g., "http/1.1", "h2", "h3"), or + + * makes registrations in or overall modifications to the IANA + registries defined for HTTP. + + Additionally, when a specification is using HTTP, all of the + requirements of the HTTP protocol suite are in force ([HTTP] in + particular but also other specifications such as the specific version + of HTTP in use and any extensions in use). + + Note that this document is intended to apply to applications, not + generic extensions to HTTP. Furthermore, while it is intended for + IETF-specified applications, other standards organisations are + encouraged to adhere to its requirements. + +2.1. Non-HTTP Protocols + + An application can rely upon HTTP without meeting the criteria for + using it as defined above. For example, an application might wish to + avoid re-specifying parts of the message format but might change + other aspects of the protocol's operation, or it might want to use + application-specific methods. + + Doing so permits more freedom to modify protocol operations, but at + least a portion of the benefits outlined in Section 3 are lost as + most HTTP implementations won't be easily adaptable to these changes. + The benefit of mindshare will also be lost. + + Such specifications MUST NOT use HTTP's URI schemes, transport ports, + ALPN protocol IDs, or IANA registries; rather, they are encouraged to + establish their own. + +3. What's Important About HTTP + + This section examines the characteristics of HTTP that are important + to consider when using HTTP to define an application protocol. + +3.1. Generic Semantics + + Much of the value of HTTP is in its generic semantics -- that is, the + protocol elements defined by HTTP are potentially applicable to every + resource and are not specific to a particular context. Application- + specific semantics are best expressed in message content and header + fields, not status codes or methods (although status codes and + methods do have generic semantics that relate to application state). + + This split between generic and application-specific semantics allows + an HTTP message to be handled by common software (e.g., HTTP servers, + intermediaries, client implementations, and caches) without requiring + those implementations to understand the application in use. It also + allows people to leverage their knowledge of HTTP semantics without + needing specialised knowledge of a particular application. + + Therefore, applications that use HTTP MUST NOT redefine, refine, or + overlay the semantics of generic protocol elements such as methods, + status codes, or existing header fields. Instead, they should focus + their specifications on protocol elements that are specific to that + application -- namely, their HTTP resources. + + When writing a specification, it's often tempting to specify exactly + how HTTP is to be implemented, supported, and used. However, this + can easily lead to an unintended profile of HTTP behaviour. For + example, it's common to see specifications with language like this: + + | A POST request MUST result in a 201 (Created) response. + + This forms an expectation in the client that the response will always + be 201 (Created) when in fact there are a number of reasons why the + status code might differ in a real deployment; for example, there + might be a proxy that requires authentication, or a server-side + error, or a redirection. If the client does not anticipate this, the + application's deployment is brittle. + + See Section 4.2 for more details. + +3.2. Links + + Another common practice is assuming that the HTTP server's namespace + (or a portion thereof) is exclusively for the use of a single + application. This effectively overlays special, application-specific + semantics onto that space and precludes other applications from using + it. + + As explained in [BCP190], such "squatting" on a part of the URL space + by a standard usurps the server's authority over its own resources, + can cause deployment issues, and is therefore bad practice in + standards. + + Instead of statically defining URI components like paths, it is + RECOMMENDED that applications using HTTP define and use links + [WEB-LINKING] to allow flexibility in deployment. + + Using runtime links in this fashion has a number of other benefits -- + especially when an application is to have multiple implementations + and/or deployments (as is often the case for those that are + standardised). + + For example, navigating with a link allows a request to be routed to + a different server without the overhead of a redirection, thereby + supporting deployment across machines well. + + By using links, it also becomes possible to "mix and match" different + applications on the same server. The use of links also offers a + natural mechanism for extensibility, versioning, and capability + management because the document containing the links can also contain + information about their targets. + + Using links also offers a form of cache invalidation that's seen on + the Web; when a resource's state changes, the application can change + the affected links so that a fresh copy is always fetched. + + See Section 4.4 for more details. + +3.3. Rich Functionality + + HTTP offers a number of features to applications, such as: + + * Message framing + + * Multiplexing (in HTTP/2 [HTTP/2] and HTTP/3 [HTTP/3]) + + * Integration with TLS + + * Support for intermediaries (proxies, gateways, content delivery + networks (CDNs)) + + * Client authentication + + * Content negotiation for format, language, and other features + + * Caching for server scalability, latency and bandwidth reduction, + and reliability + + * Granularity of access control (through use of a rich space of + URLs) + + * Partial content to selectively request part of a response + + * The ability to interact with the application easily using a Web + browser + + An application that uses HTTP is encouraged to utilise the various + features that the protocol offers so that its users receive the + maximum benefit from those features and so that the application can + be deployed in a variety of situations. This document does not + require specific features to be used since the appropriate design + trade-offs are highly specific to a given situation. However, + following the practices in Section 4 is a good starting point. + +4. Best Practices for Specifying the Use of HTTP + + This section contains best practices for specifying the use of HTTP + by applications, including practices for specific HTTP protocol + elements. + +4.1. Specifying the Use of HTTP + + Specifications should use [HTTP] as the primary reference for HTTP; + it is not necessary to reference all of the specifications in the + HTTP suite unless there are specific reasons to do so (e.g., a + particular feature is called out). + + Because HTTP is a hop-by-hop protocol, a connection can be handled by + implementations that are not controlled by the application; for + example, proxies, CDNs, firewalls, and so on. Requiring a particular + version of HTTP makes it difficult to use in these situations and + harms interoperability. Therefore, it is NOT RECOMMENDED that + applications using HTTP specify a minimum version of HTTP to be used. + + However, if an application's deployment benefits from the use of a + particular version of HTTP (for example, HTTP/2's multiplexing), this + ought be noted. + + Applications using HTTP MUST NOT specify a maximum version, to + preserve the protocol's ability to evolve. + + When specifying examples of protocol interactions, applications + should document both the request and response messages with complete + header sections, preferably in HTTP/1.1 format [HTTP/1.1]. For + example: + + GET /thing HTTP/1.1 + Host: example.com + Accept: application/things+json + User-Agent: Foo/1.0 + + HTTP/1.1 200 OK + Content-Type: application/things+json + Content-Length: 500 + Server: Bar/2.2 + + [content here] + +4.2. Specifying Server Behaviour + + The server-side behaviours of an application are most effectively + specified by defining the following protocol elements: + + * Media types [RFC6838], often based upon a format convention such + as JSON [JSON]; + + * HTTP header fields, per Section 4.7; and + + * The behaviour of resources, as identified by link relations + [WEB-LINKING]. + + An application can define its operation by composing these protocol + elements to define a set of resources that are identified by link + relations and that implement specified behaviours, including: + + * retrieval of resource state using GET in one or more formats + identified by media type; + + * resource creation or update using POST or PUT, with an + appropriately identified request content format; + + * data processing using POST and identified request and response + content format(s); and + + * Resource deletion using DELETE. + + For example, an application might specify: + + | Resources linked to with the "example-widget" link relation type + | are Widgets. The state of a Widget can be fetched in the + | "application/example-widget+json" format, and can be updated by + | PUT to the same link. Widget resources can be deleted. + | + | The Example-Count response header field on Widget representations + | indicates how many Widgets are held by the sender. + | + | The "application/example-widget+json" format is a JSON [RFC8259] + | format representing the state of a Widget. It contains links to + | related information in the link indicated by the Link header field + | value with the "example-other-info" link relation type. + + Applications can also specify the use of URI Templates [URI-TEMPLATE] + to allow clients to generate URLs based upon runtime data. + +4.3. Specifying Client Behaviour + + An application's expectations for client behaviour ought to be + closely aligned with those of Web browsers to avoid interoperability + issues when they are used. + + One way to do this is to define it in terms of [FETCH] since that is + the abstraction that browsers use for HTTP. + + Some client behaviours (e.g., automatic redirect handling) and + extensions (e.g., cookies) are not required by HTTP but nevertheless + have become very common. If their use is not explicitly specified by + applications using HTTP, there may be confusion and interoperability + problems. In particular: + + Redirect handling: Applications need to specify how redirects are + expected to be handled; see Section 4.6.1. + + Cookies: Applications using HTTP should explicitly reference the + Cookie specification [COOKIES] if they are required. + + Certificates: Applications using HTTP should specify that TLS + certificates are to be checked according to Section 4.3.4 of + [HTTP] when HTTPS is used. + + Applications using HTTP should not require that clients statically + support HTTP features that are usually negotiated. For example, + requiring that clients support responses with a certain content + coding ([HTTP], Section 8.4.1) instead of negotiating for it ([HTTP], + Section 12.5.3) means that otherwise conformant clients cannot + interoperate with the application. Applications can encourage the + implementation of such features, though. + +4.4. Specifying URLs + + In HTTP, the resources that clients interact with are identified with + URLs [URL]. As [BCP190] explains, parts of the URL are designed to + be under the control of the owner (also known as the "authority") of + that server to give them the flexibility in deployment. + + This means that in most cases, specifications for applications that + use HTTP won't contain fixed application URLs or paths; while it is + common practice for a specification of a single-deployment API to + specify the path prefix "/app/v1" (for example), doing so in an IETF + specification is inappropriate. + + Therefore, the specification writer needs some mechanism to allow + clients to discover an application's URLs. Additionally, they need + to specify which URL scheme(s) the application should be used with + and whether to use a dedicated port or to reuse HTTP's port(s). + +4.4.1. Discovering an Application's URLs + + Generally, a client will begin interacting with a given application + server by requesting an initial document that contains information + about that particular deployment, potentially including links to + other relevant resources. Doing so ensures that the deployment is as + flexible as possible (potentially spanning multiple servers), allows + evolution, and also gives the application the opportunity to tailor + the "discovery document" to the client. + + There are a few common patterns for discovering that initial URL. + + The most straightforward mechanism for URL discovery is to configure + the client with (or otherwise convey to it) a full URL. This might + be done in a configuration document or through another discovery + mechanism. + + However, if the client only knows the server's hostname and the + identity of the application, there needs to be some way to derive the + initial URL from that information. + + An application cannot define a fixed prefix for its URL paths; see + [BCP190]. Instead, a specification for such an application can use + one of the following strategies: + + * Register a well-known URI [WELL-KNOWN-URI] as an entry point for + that application. This provides a fixed path on every potential + server that will not collide with other applications. + + * Enable the server authority to convey a URI Template + [URI-TEMPLATE] or similar mechanism for generating a URL for an + entry point. For example, this might be done in a configuration + document or other artefact. + + Once the discovery document is located, it can be fetched, cached for + later reuse (if allowed by its metadata), and used to locate other + resources that are relevant to the application using full URIs or URL + Templates. + + In some cases, an application may not wish to use such a discovery + document -- for example, when communication is very brief or when the + latency concerns of doing so preclude the use of a discovery + document. These situations can be addressed by placing all of the + application's resources under a well-known location. + +4.4.2. Considering URI Schemes + + Applications that use HTTP will typically employ the "http" and/or + "https" URI schemes. "https" is RECOMMENDED to provide + authentication, integrity, and confidentiality, as well as to + mitigate pervasive monitoring attacks [RFC7258]. + + However, application-specific schemes can also be defined. When + defining a URI scheme for an application using HTTP, there are a + number of trade-offs and caveats to keep in mind: + + * Unmodified Web browsers will not support the new scheme. While it + is possible to register new URI schemes with Web browsers (e.g., + registerProtocolHandler() in [HTML], as well as several + proprietary approaches), support for these mechanisms is not + shared by all browsers, and their capabilities vary. + + * Existing non-browser clients, intermediaries, servers, and + associated software will not recognise the new scheme. For + example, a client library might fail to dispatch the request, a + cache might refuse to store the response, and a proxy might fail + to forward the request. + + * Because URLs commonly occur in HTTP artefacts and are often + generated automatically (e.g., in the Location response header + field), it can be difficult to ensure that the new scheme is used + consistently. + + * The resources identified by the new scheme will still be available + using "http" and/or "https" URLs. Those URLs can "leak" into use, + which can present security and operability issues. For example, + using a new scheme to ensure that requests don't get sent to a + "normal" Web site is likely to fail. + + * Features that rely upon the URL's origin [RFC6454], such as the + Web's same-origin policy, will be impacted by a change of scheme. + + * HTTP-specific features such as cookies [COOKIES], authentication + [HTTP], caching [HTTP-CACHING], HTTP Strict Transport Security + (HSTS) [RFC6797], and Cross-Origin Resource Sharing (CORS) [FETCH] + might or might not work correctly, depending on how they are + defined and implemented. Generally, they are designed and + implemented with an assumption that the URL will always be "http" + or "https". + + * Web features that require a secure context [SECCTXT] will likely + treat a new scheme as insecure. + + See [RFC7595] for more information about minting new URI schemes. + +4.4.3. Choosing Transport Ports + + Applications can use the applicable default port (80 for HTTP, 443 + for HTTPS), or they can be deployed upon other ports. This decision + can be made at deployment time or might be encouraged by the + application's specification (e.g., by registering a port for that + application). + + If a non-default port is used, it needs to be reflected in the + authority of all URLs for that resource; the only mechanism for + changing a default port is changing the URI scheme (see + Section 4.4.2). + + Using a port other than the default has privacy implications (i.e., + the protocol can now be distinguished from other traffic), as well as + operability concerns (as some networks might block or otherwise + interfere with it). Privacy implications (including those stemming + from this distinguishability) should be documented in Security + Considerations. + + See [RFC7605] for further guidance. + +4.5. Using HTTP Methods + + Applications that use HTTP MUST confine themselves to using + registered HTTP methods such as GET, POST, PUT, DELETE, and PATCH. + + New HTTP methods are rare; they are required to be registered in the + "HTTP Method Registry" with IETF Review (see [HTTP]) and are also + required to be generic. That means that they need to be potentially + applicable to all resources, not just those of one application. + + While historically some applications (e.g., [RFC4791]) have defined + application-specific methods, [HTTP] now forbids this. + + When authors believe that a new method is required, they are + encouraged to engage with the HTTP community early (e.g., on the + mailing list) and document their + proposal as a separate HTTP extension rather than as part of an + application's specification. + +4.5.1. GET + + GET is the most common and useful HTTP method; its retrieval + semantics allow caching and side-effect free linking and underlie + many of the benefits of using HTTP. + + Queries can be performed with GET, often using the query component of + the URL; this is a familiar pattern from Web browsing, and the + results can be cached, improving the efficiency of an often expensive + process. In some cases, however, GET might be unwieldy for + expressing queries because of the limited syntax of the URI; in + particular, if binary data forms part of the query terms, it needs to + be encoded to conform to the URI syntax. + + While this is not an issue for short queries, it can become one for + larger query terms or those that need to sustain a high rate of + requests. Additionally, some HTTP implementations limit the size of + URLs they support, although modern HTTP software has much more + generous limits than previously (typically, considerably more than + 8000 octets, as required by [HTTP]). + + In these cases, an application using HTTP might consider using POST + to express queries in the request's content; doing so avoids encoding + overhead and URL length limits in implementations. However, in doing + so, it should be noted that the benefits of GET such as caching and + linking to query results are lost. Therefore, applications using + HTTP that require support for POST queries ought to consider allowing + both methods. + + Processing of GET requests should not change the application's state + or have other side effects that might be significant to the client + since implementations can and do retry HTTP GET requests that fail. + Furthermore, some GET requests protected by TLS early data might be + vulnerable to replay attacks (see [RFC8470]). Note that this does + not include logging and similar functions; see [HTTP], Section 9.2.1. + + Finally, note that while the generic HTTP syntax allows a GET request + message to contain content, the purpose is to allow message parsers + to be generic; per [HTTP], Section 9.3.1, content in a GET is not + recommended, has no meaning, and will be either ignored or rejected + by generic HTTP software (such as intermediaries, caches, servers, + and client libraries). + +4.5.2. OPTIONS + + The OPTIONS method was defined for metadata retrieval and is used + both by Web Distributed Authoring and Versioning (WebDAV) [RFC4918] + and CORS [FETCH]. Because HTTP-based APIs often need to retrieve + metadata about resources, it is often considered for their use. + + However, OPTIONS does have significant limitations: + + * It isn't possible to link to the metadata with a simple URL + because OPTIONS is not the default method. + + * OPTIONS responses are not cacheable because HTTP caches operate on + representations of the resource (i.e., GET and HEAD). If OPTIONS + responses are cached separately, their interactions with the HTTP + cache expiry, secondary keys, and other mechanisms need to be + considered. + + * OPTIONS is "chatty" -- requesting metadata separately increases + the number of requests needed to interact with the application. + + * Implementation support for OPTIONS is not universal; some servers + do not expose the ability to respond to OPTIONS requests without + significant effort. + + Instead of OPTIONS, one of these alternative approaches might be more + appropriate: + + * For server-wide metadata, create a well-known URI [WELL-KNOWN-URI] + or use an already existing one if appropriate (e.g., host-meta + [RFC6415]). + + * For metadata about a specific resource, create a separate resource + and link to it using a Link response header field or a link + serialised into the response's content. See [WEB-LINKING]. Note + that the Link header field is available on HEAD responses, which + is useful if the client wants to discover a resource's + capabilities before they interact with it. + +4.6. Using HTTP Status Codes + + HTTP status codes convey semantics both for the benefit of generic + HTTP components -- such as caches, intermediaries, and clients -- and + applications themselves. However, applications can encounter a + number of pitfalls in their use. + + First, status codes are often generated by components other than the + application itself. This can happen, for example, when network + errors are encountered; when a captive portal, proxy, or content + delivery network is present; or when a server is overloaded or thinks + it is under attack. They can even be generated by generic client + software when certain error conditions are encountered. As a result, + if an application assigns specific semantics to one of these status + codes, a client can be misled about its state because the status code + was generated by a generic component, not the application itself. + + Furthermore, mapping application errors to individual HTTP status + codes one-to-one often leads to a situation where the finite space of + applicable HTTP status codes is exhausted. This, in turn, leads to a + number of bad practices -- including minting new, application- + specific status codes or using existing status codes even though the + link between their semantics and the application's is tenuous at + best. + + Instead, applications using HTTP should define their errors to use + the most applicable status code, making generous use of the general + status codes (200, 400, and 500) when in doubt. Importantly, they + should not specify a one-to-one relationship between status codes and + application errors, thereby avoiding the exhaustion issue outlined + above. + + To distinguish between multiple error conditions that are mapped to + the same status code and to avoid the misattribution issue outlined + above, applications using HTTP should convey finer-grained error + information in the response's message content and/or header fields. + [PROBLEM-DETAILS] provides one way to do so. + + Because the set of registered HTTP status codes can expand, + applications using HTTP should explicitly point out that clients + ought to be able to handle all applicable status codes gracefully + (i.e., falling back to the generic n00 semantics of a given status + code; e.g., 499 can be safely handled as 400 (Bad Request) by clients + that don't recognise it). This is preferable to creating a "laundry + list" of potential status codes since such a list won't be complete + in the foreseeable future. + + Applications using HTTP MUST NOT re-specify the semantics of HTTP + status codes, even if it is only by copying their definition. It is + NOT RECOMMENDED they require specific reason phrases to be used; the + reason phrase has no function in HTTP, is not guaranteed to be + preserved by implementations, and is not carried at all in the HTTP/2 + [HTTP/2] message format. + + Applications MUST only use registered HTTP status codes. As with + methods, new HTTP status codes are rare and required (by [HTTP]) to + be registered with IETF Review. Similarly, HTTP status codes are + generic; they are required (by [HTTP]) to be potentially applicable + to all resources, not just to those of one application. + + When authors believe that a new status code is required, they are + encouraged to engage with the HTTP community early (e.g., on the + mailing list) and document their + proposal as a separate HTTP extension, rather than as part of an + application's specification. + +4.6.1. Redirection + + The 3xx series of status codes specified in Section 15.4 of [HTTP] + directs the user agent to another resource to satisfy the request. + The most common of these are 301, 302, 307, and 308, all of which use + the Location response header field to indicate where the client + should resend the request. + + There are two ways that the members of this group of status codes + differ: + + * Whether they are permanent or temporary. Permanent redirects can + be used to update links stored in the client (e.g., bookmarks), + whereas temporary ones cannot. Note that this has no effect on + HTTP caching; it is completely separate. + + * Whether they allow the redirected request to change the request + method from POST to GET. Web browsers generally do change POST to + GET for 301 and 302; therefore, 308 and 307 were created to allow + redirection without changing the method. + + This table summarises their relationships: + + +==============================+===========+===========+ + | | Permanent | Temporary | + +==============================+===========+===========+ + | Allows change of the request | 301 | 302 | + | method from POST to GET | | | + +------------------------------+-----------+-----------+ + | Does not allow change of the | 308 | 307 | + | request method | | | + +------------------------------+-----------+-----------+ + + Table 1 + + The 303 (See Other) status code can be used to inform the client that + the result of an operation is available at a different location using + GET. + + As noted in [HTTP], a user agent is allowed to automatically follow a + 3xx redirect that has a Location response header field, even if they + don't understand the semantics of the specific status code. However, + they aren't required to do so; therefore, if an application using + HTTP desires redirects to be automatically followed, it needs to + explicitly specify the circumstances when this is required. + + Redirects can be cached (when appropriate cache directives are + present), but beyond that, they are not "sticky" -- i.e., redirection + of a URI will not result in the client assuming that similar URIs + (e.g., with different query parameters) will also be redirected. + + Applications using HTTP are encouraged to specify that 301 and 302 + responses change the subsequent request method from POST (but no + other method) to GET to be compatible with browsers. Generally, when + a redirected request is made, its header fields are copied from the + original request. However, they can be modified by various + mechanisms; e.g., sent Authorization ([HTTP], Section 11) and Cookie + ([COOKIES]) header fields will change if the origin (and sometimes + path) of the request changes. An application using HTTP should + specify if any request header fields that it defines need to be + modified or removed upon a redirect; however, this behaviour cannot + be relied upon since a generic client (like a browser) will be + unaware of such requirements. + +4.7. Specifying HTTP Header Fields + + Applications often define new HTTP header fields. Typically, using + HTTP header fields is appropriate in a few different situations: + + * The field is useful to intermediaries (who often wish to avoid + parsing message content), and/or + + * The field is useful to generic HTTP software (e.g., clients, + servers), and/or + + * It is not possible to include their values in the message content + (usually because a format does not allow it). + + When the conditions above are not met, it is usually better to convey + application-specific information in other places -- e.g., the message + content or the URL query string. + + New header fields MUST be registered, per Section 16.3 of [HTTP]. + + See Section 16.3.2 of [HTTP] for guidelines to consider when minting + new header fields. [STRUCTURED-FIELDS] provides a common structure + for new header fields and avoids many issues in their parsing and + handling; it is RECOMMENDED that new header fields use it. + + It is RECOMMENDED that header field names be short (even when field + compression is used, there is an overhead) but appropriately + specific. In particular, if a header field is specific to an + application, an identifier for that application can form a prefix to + the header field name, separated by a hyphen. + + For example, if the "example" application needs to create three + header fields, they might be called "example-foo", "example-bar", and + "example-baz". Note that the primary motivation here is to avoid + consuming more generic field names, not to reserve a portion of the + namespace for the application; see [RFC6648] for related + considerations. + + The semantics of existing HTTP header fields MUST NOT be redefined + without updating their registration or defining an extension to them + (if allowed). For example, an application using HTTP cannot specify + that the Location header field has a special meaning in a certain + context. + + See Section 4.9 for the interaction between header fields and HTTP + caching; in particular, request header fields that are used to choose + (per Section 4.1 of [HTTP-CACHING]) a response have impact there and + need to be carefully considered. + + See Section 4.10 for considerations regarding header fields that + carry application state (e.g., Cookie). + +4.8. Defining Message Content + + Common syntactic conventions for message contents include JSON + [JSON], XML [XML], and Concise Binary Object Representation (CBOR) + [RFC8949]. Best practices for their use are out of scope for this + document. + + Applications should register distinct media types for each format + they define; this makes it possible to identify them unambiguously + and negotiate for their use. See [RFC6838] for more information. + +4.9. Leveraging HTTP Caching + + HTTP caching [HTTP-CACHING] is one of the primary benefits of using + HTTP for applications; it provides scalability, reduces latency, and + improves reliability. Furthermore, HTTP caches are readily available + in browsers and other clients, networks as forward and reverse + proxies, content delivery networks, and as part of server software. + + Even when an application using HTTP isn't designed to take advantage + of caching, it needs to consider how caches will handle its responses + to preserve correct behaviour when one is interposed (whether in the + network, server, client, or intervening infrastructure). + +4.9.1. Freshness + + Assigning even a short freshness lifetime ([HTTP-CACHING], + Section 4.2) -- e.g., 5 seconds -- allows a response to be reused to + satisfy multiple clients and/or a single client making the same + request repeatedly. In general, if it is safe to reuse something, + consider assigning a freshness lifetime. + + The most common method for specifying freshness is the max-age + response directive ([HTTP-CACHING], Section 5.2.2.1). The Expires + header field ([HTTP-CACHING], Section 5.3) can also be used, but it + is not necessary; all modern cache implementations support the Cache- + Control header field, and specifying freshness as a delta is usually + more convenient and less error-prone. + + It is not necessary to add the public response directive + ([HTTP-CACHING], Section 5.2.2.9) to cache most responses; it is only + necessary when it's desirable to store an authenticated response, or + when the status code isn't understood by the cache and there isn't + explicit freshness information available. + + In some situations, responses without explicit cache freshness + directives will be stored and served using a heuristic freshness + lifetime; see [HTTP-CACHING], Section 4.2.2. As the heuristic is not + under the control of the application, it is generally preferable to + set an explicit freshness lifetime or make the response explicitly + uncacheable. + + If caching of a response is not desired, the appropriate cache + response directive is no-store. Other directives are not necessary, + and no-store only needs to be sent in situations where the response + might be cached; see [HTTP-CACHING], Section 3. Note that the no- + cache directive allows a response to be stored, just not reused by a + cache without validation; it does not prevent caching (despite its + name). + + For example, this response cannot be stored or reused by a cache: + + HTTP/1.1 200 OK + Content-Type: application/example+xml + Cache-Control: no-store + + [content] + +4.9.2. Stale Responses + + Authors should understand that stale responses (e.g., with Cache- + Control: max-age=0) can be reused by caches when disconnected from + the origin server; this can be useful for handling network issues. + + If doing so is not suitable for a given response, the origin should + send the must-revalidate cache directive. See Section 4.2.4 of + [HTTP-CACHING] and also [RFC5861] for additional controls over stale + content. + + Stale responses can be refreshed by assigning a validator, saving + both transfer bandwidth and latency for large responses; see + Section 13 of [HTTP]. + +4.9.3. Caching and Application Semantics + + When an application has a need to express a lifetime that's separate + from the freshness lifetime, this should be conveyed separately, + either in the response's content or in a separate header field. When + this happens, the relationship between HTTP caching and that lifetime + needs to be carefully considered since the response will be used as + long as it is considered fresh. + + In particular, application authors need to consider how responses + that are not freshly obtained from the origin server should be + handled; if they have a concept like a validity period, this will + need to be calculated considering the age of the response (see + [HTTP-CACHING], Section 4.2.3). + + One way to address this is to explicitly specify that responses need + to be fresh upon use. + +4.9.4. Varying Content Based Upon the Request + + If an application uses a request header field to change the + response's header fields or content, authors should point out that + this has implications for caching; in general, such resources need to + either make their responses uncacheable (e.g., with the no-store + cache directive defined in [HTTP-CACHING], Section 5.2.2.5) or send + the Vary response header field ([HTTP], Section 12.5.5) on all + responses from that resource (including the "default" response). + + For example, this response: + + HTTP/1.1 200 OK + Content-Type: application/example+xml + Cache-Control: max-age=60 + ETag: "sa0f8wf20fs0f" + Vary: Accept-Encoding + + [content] + + can be stored for 60 seconds by both private and shared caches, can + be revalidated with If-None-Match, and varies on the Accept-Encoding + request header field. + +4.10. Handling Application State + + Applications can use stateful cookies [COOKIES] to identify a client + and/or store client-specific data to contextualise requests. + + When used, it is important to carefully specify the scoping and use + of cookies; if the application exposes sensitive data or capabilities + (e.g., by acting as an ambient authority), exploits are possible. + Mitigations include using a request-specific token to ensure the + intent of the client. + +4.11. Making Multiple Requests + + Clients often need to send multiple requests to perform a task. + + In HTTP/1 [HTTP/1.1], parallel requests are most often supported by + opening multiple connections. Application performance can be + impacted when too many simultaneous connections are used because + connections' congestion control will not be coordinated. + Furthermore, it can be difficult for applications to decide when to + issue and which connection to use for a given request, further + impacting performance. + + HTTP/2 [HTTP/2] and HTTP/3 [HTTP/3] offer multiplexing to + applications, removing the need to use multiple connections. + However, application performance can still be significantly affected + by how the server chooses to prioritize responses. Depending on the + application, it might be best for the server to determine the + priority of responses or for the client to hint its priorities to the + server (see, e.g., [HTTP-PRIORITY]). + + In all versions of HTTP, requests are made independently -- you can't + rely on the relative order of two requests to guarantee their + processing order. This is because they might be sent over a + multiplexed protocol by an intermediary or sent to different origin + servers, or the server might even perform processing in a different + order. If two requests need strict ordering, the only reliable way + to ensure the outcome is to issue the second request when the final + response to the first has begun. + + Applications MUST NOT make assumptions about the relationship between + separate requests on a single transport connection; doing so breaks + many of the assumptions of HTTP as a stateless protocol and will + cause problems in interoperability, security, operability, and + evolution. + +4.12. Client Authentication + + Applications can use HTTP authentication (Section 11 of [HTTP]) to + identify clients. Per [RFC7617], the Basic authentication scheme is + not suitable for protecting sensitive or valuable information unless + the channel is secure (e.g., using the "https" URI scheme). + Likewise, [RFC7616] requires the Digest authentication scheme to be + used over a secure channel. + + With HTTPS, clients might also be authenticated using certificates + [RFC8446], but note that such authentication is intrinsically scoped + to the underlying transport connection. As a result, a client has no + way of knowing whether the authenticated status was used in preparing + the response (though Vary: * and/or the private cache directive can + provide a partial indication), and the only way to obtain a + specifically unauthenticated response is to open a new connection. + + When used, it is important to carefully specify the scoping and use + of authentication; if the application exposes sensitive data or + capabilities (e.g., by acting as an ambient authority; see + Section 8.3 of [RFC6454]), exploits are possible. Mitigations + include using a request-specific token to ensure the intent of the + client. + +4.13. Coexisting with Web Browsing + + Even if there is not an intent for an application to be used with a + Web browser, its resources will remain available to browsers and + other HTTP clients. This means that all such applications that use + HTTP need to consider how browsers will interact with them, + particularly regarding security. + + For example, if an application's state can be changed using a POST + request, a Web browser can easily be coaxed into cross-site request + forgery (CSRF) from arbitrary Web sites. + + Or, if an attacker gains control of content returned from the + application's resources (for example, part of the request is + reflected in the response, or the response contains external + information that the attacker can change), they can inject code into + the browser and access data and capabilities as if they were the + origin -- a technique known as a cross-site scripting (XSS) attack. + + This is only a small sample of the kinds of issues that applications + using HTTP must consider. Generally, the best approach is to + actually consider the application as a Web application, and to follow + best practices for their secure development. + + A complete enumeration of such practices is out of scope for this + document, but some considerations include: + + * Using an application-specific media type in the Content-Type + header field, and requiring clients to fail if it is not used. + + * Using X-Content-Type-Options: nosniff [FETCH] to ensure that + content under attacker control can't be coaxed into a form that is + interpreted as active content by a Web browser. + + * Using Content-Security-Policy [CSP] to constrain the capabilities + of active content (i.e., that which can execute scripts, such as + HTML [HTML] and PDF), thereby mitigating XSS attacks. + + * Using Referrer-Policy [REFERRER-POLICY] to prevent sensitive data + in URLs from being leaked in the Referer request header field. + + * Using the 'HttpOnly' flag on Cookies to ensure that cookies are + not exposed to browser scripting languages [COOKIES]. + + * Avoiding use of compression on any sensitive information (e.g., + authentication tokens, passwords), as the scripting environment + offered by Web browsers allows an attacker to repeatedly probe the + compression space; if the attacker has access to the network path + of the communication, they can use this capability to recover that + information. + + Depending on how they are intended to be deployed, specifications for + applications using HTTP might require the use of these mechanisms in + specific ways or might merely point them out in Security + Considerations. + + An example of an HTTP response from an application that does not + intend for its content to be treated as active by browsers might look + like this: + + HTTP/1.1 200 OK + Content-Type: application/example+json + X-Content-Type-Options: nosniff + Content-Security-Policy: default-src 'none' + Cache-Control: max-age=3600 + Referrer-Policy: no-referrer + + [content] + + If an application has browser compatibility as a goal, client + interaction ought to be defined in terms of [FETCH] since that is the + abstraction that browsers use for HTTP; it enforces many of these + best practices. + +4.14. Maintaining Application Boundaries + + Because many HTTP capabilities are scoped to the origin [RFC6454], + applications also need to consider how deployments might interact + with other applications (including Web browsing) that use the same + origin server. + + For example, if cookies [COOKIES] are used to carry application + state, they will be sent with all requests to the origin by default + (unless scoped by path), and the application might receive cookies + from other applications on the origin server. This can lead to + security issues as well as collision in cookie names. + + One solution to these issues is to require a dedicated hostname for + the application so that it has a unique origin. However, it is often + desirable to allow multiple applications to be deployed on a single + hostname; doing so provides the most deployment flexibility and + enables them to be "mixed" together (see [BCP190] for details). + + Therefore, applications using HTTP should strive to allow multiple + applications on an origin. Specifically, when specifying the use of + cookies, HTTP authentication realms [HTTP], or other origin-wide HTTP + mechanisms, applications using HTTP should not mandate the use of a + particular name but instead let deployments configure them. + Consideration should be given to scoping them to part of the origin, + using their specified mechanisms for doing so. + + Modern Web browsers constrain the ability of content from one origin + to access resources from another to avoid leaking private + information. As a result, applications that wish to expose cross- + origin data to browsers will need to implement the CORS protocol; see + [FETCH]. + +4.15. Using Server Push + + HTTP/2 added the ability for servers to "push" request/response pairs + to clients in [HTTP/2], Section 8.4. While server push seems like a + natural fit for many common application semantics (e.g., "fanout" and + publish/subscribe), a few caveats should be noted: + + * Server push is hop by hop; that is, it is not automatically + forwarded by intermediaries. As a result, it might not work + easily (or at all) with proxies, reverse proxies, and content + delivery networks. + + * Server push can have a negative performance impact on HTTP when + used incorrectly, particularly if there is contention with + resources that have actually been requested by the client. + + * Server push is implemented differently in different clients, + especially regarding interaction with HTTP caching, and + capabilities might vary. + + * APIs for server push are currently unavailable in some + implementations and vary widely in others. In particular, there + is no current browser API for it. + + * Server push is not supported in HTTP/1.1 or HTTP/1.0. + + * Server push does not form part of the "core" semantics of HTTP and + therefore might not be supported by future versions of the + protocol. + + Applications wishing to optimise cases where the client can perform + work related to requests before the full response is available (e.g., + fetching links for things likely to be contained within) might + benefit from using the 103 (Early Hints) status code; see [RFC8297]. + + Applications using server push directly need to enforce the + requirements regarding authority in [HTTP/2], Section 8.4 to avoid + cross-origin push attacks. + +4.16. Allowing Versioning and Evolution + + It's often necessary to introduce new features into application + protocols and change existing ones. + + In HTTP, backwards-incompatible changes can be made using mechanisms + such as: + + * Using a distinct link relation type [WEB-LINKING] to identify a + URL for a resource that implements the new functionality. + + * Using a distinct media type [RFC6838] to identify formats that + enable the new functionality. + + * Using a distinct HTTP header field to implement new functionality + outside the message content. + +5. IANA Considerations + + This document has no IANA actions. + +6. Security Considerations + + Applications using HTTP are subject to the security considerations of + HTTP itself and any extensions used; [HTTP], [HTTP-CACHING], and + [WEB-LINKING] are often relevant, amongst others. + + Section 4.4.2 recommends support for "https" URLs and discourages the + use of "http" URLs to provide authentication, integrity, and + confidentiality, as well as to mitigate pervasive monitoring attacks. + Many applications using HTTP perform authentication and authorization + with bearer tokens (e.g., in session cookies). If the transport is + unencrypted, an attacker that can eavesdrop upon or modify HTTP + communications can often escalate their privilege to perform + operations on resources. + + Section 4.9.3 highlights the potential for mismatch between HTTP + caching and application-specific storage of responses or information + therein. + + Section 4.10 discusses the impact of using stateful mechanisms in the + protocol as ambient authority and suggests a mitigation. + + Section 4.13 highlights the implications of Web browsers' + capabilities on applications that use HTTP. + + Section 4.14 discusses the issues that arise when applications are + deployed on the same origin as websites (and other applications). + + Section 4.15 highlights risks of using HTTP/2 server push in a manner + other than that specified. + + Applications that use HTTP in a manner that involves modification of + implementations -- for example, requiring support for a new URI + scheme or a non-standard method -- risk having those implementations + "fork" from their parent HTTP implementations, with the possible + result that they do not benefit from patches and other security + improvements incorporated upstream. + +6.1. Privacy Considerations + + HTTP clients can expose a variety of information to servers. Besides + information that's explicitly sent as part of an application's + operation (for example, names and other user-entered data) and "on + the wire" (which is one of the reasons "https" is recommended in + Section 4.4.2), other information can be gathered through less + obvious means -- often by connecting activities of a user over time. + + This includes session information, tracking the client through + fingerprinting, and code execution. + + Session information includes things like the IP address of the + client, TLS session tickets, Cookies, ETags stored in the client's + cache, and other stateful mechanisms. Applications are advised to + avoid using session mechanisms unless they are unavoidable or + necessary for operation, in which case these risks need to be + documented. When they are used, implementations should be encouraged + to allow clearing such state. + + Fingerprinting uses unique aspects of a client's messages and + behaviours to connect disparate requests and connections. For + example, the User-Agent request header field conveys specific + information about the implementation; the Accept-Language request + header field conveys the users' preferred language. In combination, + a number of these markers can be used to uniquely identify a client, + impacting its control over its data. As a result, applications are + advised to specify that clients should only emit the information they + need to function in requests. + + Finally, if an application exposes the ability to execute code, great + care needs to be taken since any ability to observe its environment + can be used as an opportunity to both fingerprint the client and to + obtain and manipulate private data (including session information). + For example, access to high-resolution timers (even indirectly) can + be used to profile the underlying hardware, creating a unique + identifier for the system. Applications are advised to avoid + allowing the use of mobile code where possible; when it cannot be + avoided, the resulting system's security properties need be carefully + scrutinised. + +7. References + +7.1. Normative References + + [BCP190] Nottingham, M., "URI Design and Ownership", BCP 190, + RFC 8820, DOI 10.17487/RFC8820, June 2020, + . + + [HTTP] Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, + Ed., "HTTP Semantics", STD 97, RFC 9110, + DOI 10.17487/RFC9110, June 2022, + . + + [HTTP-CACHING] + Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, + Ed., "HTTP Caching", STD 98, RFC 9111, + DOI 10.17487/RFC9111, June 2022, + . + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, + DOI 10.17487/RFC2119, March 1997, + . + + [RFC6454] Barth, A., "The Web Origin Concept", RFC 6454, + DOI 10.17487/RFC6454, December 2011, + . + + [RFC6648] Saint-Andre, P., Crocker, D., and M. Nottingham, + "Deprecating the "X-" Prefix and Similar Constructs in + Application Protocols", BCP 178, RFC 6648, + DOI 10.17487/RFC6648, June 2012, + . + + [RFC6838] Freed, N., Klensin, J., and T. Hansen, "Media Type + Specifications and Registration Procedures", BCP 13, + RFC 6838, DOI 10.17487/RFC6838, January 2013, + . + + [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC + 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, + May 2017, . + + [STRUCTURED-FIELDS] + Nottingham, M. and P-H. Kamp, "Structured Field Values for + HTTP", RFC 8941, DOI 10.17487/RFC8941, February 2021, + . + + [URL] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform + Resource Identifier (URI): Generic Syntax", STD 66, + RFC 3986, DOI 10.17487/RFC3986, January 2005, + . + + [WEB-LINKING] + Nottingham, M., "Web Linking", RFC 8288, + DOI 10.17487/RFC8288, October 2017, + . + + [WELL-KNOWN-URI] + Nottingham, M., "Well-Known Uniform Resource Identifiers + (URIs)", RFC 8615, DOI 10.17487/RFC8615, May 2019, + . + +7.2. Informative References + + [COOKIES] Barth, A., "HTTP State Management Mechanism", RFC 6265, + DOI 10.17487/RFC6265, April 2011, + . + + [CSP] West, M., "Content Security Policy Level 3", W3C Working + Draft, June 2021, + . + + [FETCH] WHATWG, "Fetch - Living Standard", + . + + [HTML] WHATWG, "HTML - Living Standard", + . + + [HTTP-PRIORITY] + 奥 一穂 (Oku, K.) and L. Pardue, "Extensible Prioritization + Scheme for HTTP", RFC 9218, DOI 10.17487/RFC9218, June + 2022, . + + [HTTP/1.1] Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, + Ed., "HTTP/1.1", STD 99, RFC 9112, DOI 10.17487/RFC9112, + June 2022, . + + [HTTP/2] Thomson, M., Ed. and C. Benfield, Ed., "HTTP/2", RFC 9113, + DOI 10.17487/RFC9113, June 2022, + . + + [HTTP/3] Bishop, M., Ed., "HTTP/3", RFC 9114, DOI 10.17487/RFC9114, + June 2022, . + + [JSON] Bray, T., Ed., "The JavaScript Object Notation (JSON) Data + Interchange Format", STD 90, RFC 8259, + DOI 10.17487/RFC8259, December 2017, + . + + [PROBLEM-DETAILS] + Nottingham, M. and E. Wilde, "Problem Details for HTTP + APIs", RFC 7807, DOI 10.17487/RFC7807, March 2016, + . + + [REFERRER-POLICY] + Eisinger, J. and E. Stark, "Referrer Policy", W3C + Candidate Recommendation CR-referrer-policy-20170126, + January 2017, + . + + [RFC3205] Moore, K., "On the use of HTTP as a Substrate", BCP 56, + RFC 3205, DOI 10.17487/RFC3205, February 2002, + . + + [RFC4791] Daboo, C., Desruisseaux, B., and L. Dusseault, + "Calendaring Extensions to WebDAV (CalDAV)", RFC 4791, + DOI 10.17487/RFC4791, March 2007, + . + + [RFC4918] Dusseault, L., Ed., "HTTP Extensions for Web Distributed + Authoring and Versioning (WebDAV)", RFC 4918, + DOI 10.17487/RFC4918, June 2007, + . + + [RFC5861] Nottingham, M., "HTTP Cache-Control Extensions for Stale + Content", RFC 5861, DOI 10.17487/RFC5861, May 2010, + . + + [RFC6415] Hammer-Lahav, E., Ed. and B. Cook, "Web Host Metadata", + RFC 6415, DOI 10.17487/RFC6415, October 2011, + . + + [RFC6797] Hodges, J., Jackson, C., and A. Barth, "HTTP Strict + Transport Security (HSTS)", RFC 6797, + DOI 10.17487/RFC6797, November 2012, + . + + [RFC7258] Farrell, S. and H. Tschofenig, "Pervasive Monitoring Is an + Attack", BCP 188, RFC 7258, DOI 10.17487/RFC7258, May + 2014, . + + [RFC7301] Friedl, S., Popov, A., Langley, A., and E. Stephan, + "Transport Layer Security (TLS) Application-Layer Protocol + Negotiation Extension", RFC 7301, DOI 10.17487/RFC7301, + July 2014, . + + [RFC7595] Thaler, D., Ed., Hansen, T., and T. Hardie, "Guidelines + and Registration Procedures for URI Schemes", BCP 35, + RFC 7595, DOI 10.17487/RFC7595, June 2015, + . + + [RFC7605] Touch, J., "Recommendations on Using Assigned Transport + Port Numbers", BCP 165, RFC 7605, DOI 10.17487/RFC7605, + August 2015, . + + [RFC7616] Shekh-Yusef, R., Ed., Ahrens, D., and S. Bremer, "HTTP + Digest Access Authentication", RFC 7616, + DOI 10.17487/RFC7616, September 2015, + . + + [RFC7617] Reschke, J., "The 'Basic' HTTP Authentication Scheme", + RFC 7617, DOI 10.17487/RFC7617, September 2015, + . + + [RFC8297] Oku, K., "An HTTP Status Code for Indicating Hints", + RFC 8297, DOI 10.17487/RFC8297, December 2017, + . + + [RFC8446] Rescorla, E., "The Transport Layer Security (TLS) Protocol + Version 1.3", RFC 8446, DOI 10.17487/RFC8446, August 2018, + . + + [RFC8470] Thomson, M., Nottingham, M., and W. Tarreau, "Using Early + Data in HTTP", RFC 8470, DOI 10.17487/RFC8470, September + 2018, . + + [RFC8949] Bormann, C. and P. Hoffman, "Concise Binary Object + Representation (CBOR)", STD 94, RFC 8949, + DOI 10.17487/RFC8949, December 2020, + . + + [SECCTXT] West, M., "Secure Contexts", W3C Candidate Recommendation, + September 2021, + . + + [URI-TEMPLATE] + Gregorio, J., Fielding, R., Hadley, M., Nottingham, M., + and D. Orchard, "URI Template", RFC 6570, + DOI 10.17487/RFC6570, March 2012, + . + + [XML] Bray, T., Paoli, J., Sperberg-McQueen, M., Maler, E., and + F. Yergeau, "Extensible Markup Language (XML) 1.0 (Fifth + Edition)", W3C Recommendation REC-xml-20081126, November + 2008, . + +Appendix A. Changes from RFC 3205 + + [RFC3205] captured the Best Current Practice in the early 2000s based + on the concerns facing protocol designers at the time. Use of HTTP + has changed considerably since then; as a result, this document is + substantially different. Consequently, the changes are too numerous + to list individually. + +Author's Address + + Mark Nottingham + Prahran + Australia + Email: mnot@mnot.net + URI: https://www.mnot.net/ -- cgit v1.2.3