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The Hypertext Transfer Protocol (HTTP) is an application-level protocol for distributed, collaborative, hypertext information systems. HTTP has been in use by the World Wide Web global information initiative since 1990. This document is Part 1 of the seven-part specification that defines the protocol referred to as "HTTP/1.1" and, taken together, obsoletes RFC 2616. Part 1 provides an overview of HTTP and its associated terminology, defines the "http" and "https" Uniform Resource Identifier (URI) schemes, defines the generic message syntax and parsing requirements for HTTP message frames, and describes general security concerns for implementations.
Discussion of this draft should take place on the HTTPBIS working group mailing list (ietf-http-wg@w3.org). The current issues list is at http://tools.ietf.org/wg/httpbis/trac/report/11 and related documents (including fancy diffs) can be found at http://tools.ietf.org/wg/httpbis/.
The changes in this draft are summarized in Appendix D.9 (Since draft-ietf-httpbis-p1-messaging-07).
1.
Introduction
1.1.
Requirements
1.2.
Syntax Notation
1.2.1.
ABNF Extension: #rule
1.2.2.
Basic Rules
1.2.3.
ABNF Rules defined in other Parts of the Specification
2.
HTTP architecture
2.1.
Client/Server Operation
2.2.
Intermediaries
2.3.
Caches
2.4.
Transport Independence
2.5.
HTTP Version
2.6.
Uniform Resource Identifiers
2.6.1.
http URI scheme
2.6.2.
https URI scheme
2.6.3.
http and https URI Normalization and Comparison
3.
HTTP Message
3.1.
Message Parsing Robustness
3.2.
Header Fields
3.3.
Message Body
3.4.
Message Length
3.5.
General Header Fields
4.
Request
4.1.
Request-Line
4.1.1.
Method
4.1.2.
request-target
4.2.
The Resource Identified by a Request
5.
Response
5.1.
Status-Line
5.1.1.
Status Code and Reason Phrase
6.
Protocol Parameters
6.1.
Date/Time Formats: Full Date
6.2.
Transfer Codings
6.2.1.
Chunked Transfer Coding
6.2.2.
Compression Codings
6.2.3.
Transfer Coding Registry
6.3.
Product Tokens
6.4.
Quality Values
7.
Connections
7.1.
Persistent Connections
7.1.1.
Purpose
7.1.2.
Overall Operation
7.1.3.
Proxy Servers
7.1.4.
Practical Considerations
7.2.
Message Transmission Requirements
7.2.1.
Persistent Connections and Flow Control
7.2.2.
Monitoring Connections for Error Status Messages
7.2.3.
Use of the 100 (Continue) Status
7.2.4.
Client Behavior if Server Prematurely Closes Connection
8.
Miscellaneous notes that may disappear
8.1.
Scheme aliases considered harmful
8.2.
Use of HTTP for proxy communication
8.3.
Interception of HTTP for access control
8.4.
Use of HTTP by other protocols
8.5.
Use of HTTP by media type specification
9.
Header Field Definitions
9.1.
Connection
9.2.
Content-Length
9.3.
Date
9.3.1.
Clockless Origin Server Operation
9.4.
Host
9.5.
TE
9.6.
Trailer
9.7.
Transfer-Encoding
9.8.
Upgrade
9.8.1.
Upgrade Token Registry
9.9.
Via
10.
IANA Considerations
10.1.
Message Header Registration
10.2.
URI Scheme Registration
10.3.
Internet Media Type Registrations
10.3.1.
Internet Media Type message/http
10.3.2.
Internet Media Type application/http
10.4.
Transfer Coding Registry
10.5.
Upgrade Token Registration
11.
Security Considerations
11.1.
Personal Information
11.2.
Abuse of Server Log Information
11.3.
Attacks Based On File and Path Names
11.4.
DNS Spoofing
11.5.
Proxies and Caching
11.6.
Denial of Service Attacks on Proxies
12.
Acknowledgments
13.
References
13.1.
Normative References
13.2.
Informative References
Appendix A.
Tolerant Applications
Appendix B.
Compatibility with Previous Versions
B.1.
Changes from HTTP/1.0
B.1.1.
Changes to Simplify Multi-homed Web Servers and Conserve IP Addresses
B.2.
Compatibility with HTTP/1.0 Persistent Connections
B.3.
Changes from RFC 2068
B.4.
Changes from RFC 2616
Appendix C.
Collected ABNF
Appendix D.
Change Log (to be removed by RFC Editor before publication)
D.1.
Since RFC2616
D.2.
Since draft-ietf-httpbis-p1-messaging-00
D.3.
Since draft-ietf-httpbis-p1-messaging-01
D.4.
Since draft-ietf-httpbis-p1-messaging-02
D.5.
Since draft-ietf-httpbis-p1-messaging-03
D.6.
Since draft-ietf-httpbis-p1-messaging-04
D.7.
Since draft-ietf-httpbis-p1-messaging-05
D.8.
Since draft-ietf-httpbis-p1-messaging-06
D.9.
Since draft-ietf-httpbis-p1-messaging-07
§
Index
§
Authors' Addresses
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The Hypertext Transfer Protocol (HTTP) is an application-level request/response protocol that uses extensible semantics and MIME-like message payloads for flexible interaction with network-based hypertext information systems. HTTP relies upon the Uniform Resource Identifier (URI) standard [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.) to indicate request targets and relationships between resources. Messages are passed in a format similar to that used by Internet mail [RFC5322] (Resnick, P., “Internet Message Format,” October 2008.) and the Multipurpose Internet Mail Extensions (MIME) [RFC2045] (Freed, N. and N. Borenstein, “Multipurpose Internet Mail Extensions (MIME) Part One: Format of Internet Message Bodies,” November 1996.) (see Appendix A of [Part3] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 3: Message Payload and Content Negotiation,” October 2009.) for the differences between HTTP and MIME messages).
HTTP is a generic interface protocol for information systems. It is designed to hide the details of how a service is implemented by presenting a uniform interface to clients that is independent of the types of resources provided. Likewise, servers do not need to be aware of each client's purpose: an HTTP request can be considered in isolation rather than being associated with a specific type of client or a predetermined sequence of application steps. The result is a protocol that can be used effectively in many different contexts and for which implementations can evolve independently over time.
HTTP is also designed for use as a generic protocol for translating communication to and from other Internet information systems. HTTP proxies and gateways provide access to alternative information services by translating their diverse protocols into a hypertext format that can be viewed and manipulated by clients in the same way as HTTP services.
One consequence of HTTP flexibility is that the protocol cannot be defined in terms of what occurs behind the interface. Instead, we are limited to defining the syntax of communication, the intent of received communication, and the expected behavior of recipients. If the communication is considered in isolation, then successful actions should be reflected in corresponding changes to the observable interface provided by servers. However, since multiple clients may act in parallel and perhaps at cross-purposes, we cannot require that such changes be observable beyond the scope of a single response.
This document is Part 1 of the seven-part specification of HTTP, defining the protocol referred to as "HTTP/1.1" and obsoleting [RFC2616] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.). Part 1 describes the architectural elements that are used or referred to in HTTP, defines the "http" and "https" URI schemes, describes overall network operation and connection management, and defines HTTP message framing and forwarding requirements. Our goal is to define all of the mechanisms necessary for HTTP message handling that are independent of message semantics, thereby defining the complete set of requirements for message parsers and message-forwarding intermediaries.
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The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” March 1997.).
An implementation is not compliant if it fails to satisfy one or more of the MUST or REQUIRED level requirements for the protocols it implements. An implementation that satisfies all the MUST or REQUIRED level and all the SHOULD level requirements for its protocols is said to be "unconditionally compliant"; one that satisfies all the MUST level requirements but not all the SHOULD level requirements for its protocols is said to be "conditionally compliant."
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This specification uses the Augmented Backus-Naur Form (ABNF) notation of [RFC5234] (Crocker, D., Ed. and P. Overell, “Augmented BNF for Syntax Specifications: ABNF,” January 2008.).
The following core rules are included by reference, as defined in [RFC5234] (Crocker, D., Ed. and P. Overell, “Augmented BNF for Syntax Specifications: ABNF,” January 2008.), Appendix B.1: ALPHA (letters), CR (carriage return), CRLF (CR LF), CTL (controls), DIGIT (decimal 0-9), DQUOTE (double quote), HEXDIG (hexadecimal 0-9/A-F/a-f), LF (line feed), OCTET (any 8-bit sequence of data), SP (space), VCHAR (any visible [USASCII] (American National Standards Institute, “Coded Character Set -- 7-bit American Standard Code for Information Interchange,” 1986.) character), and WSP (whitespace).
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One extension to the ABNF rules of [RFC5234] (Crocker, D., Ed. and P. Overell, “Augmented BNF for Syntax Specifications: ABNF,” January 2008.) is used to improve readability.
A construct "#" is defined, similar to "*", for defining lists of elements. The full form is "<n>#<m>element" indicating at least <n> and at most <m> elements, each separated by a single comma (",") and optional whitespace (OWS).
Thus,
1#element => element *( OWS "," OWS element )
and:
#element => [ 1#element ]
and for n >= 1 and m > 1:
<n>#<m>element => element <n-1>*<m-1>( OWS "," OWS element )
For compatibility with legacy list rules, recipients SHOULD accept empty list elements. In other words, consumers would follow the list productions:
#element => [ ( "," / element ) *( OWS "," [ OWS element ] ) ] 1#element => *( "," OWS ) element *( OWS "," [ OWS element ] )
Appendix C (Collected ABNF) shows the collected ABNF, with the list rules expanded as explained above.
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HTTP/1.1 defines the sequence CR LF as the end-of-line marker for all protocol elements except the entity-body (see Appendix A (Tolerant Applications) for tolerant applications). The end-of-line marker within an entity-body is defined by its associated media type, as described in Section 2.3 of [Part3] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 3: Message Payload and Content Negotiation,” October 2009.).
This specification uses three rules to denote the use of linear whitespace: OWS (optional whitespace), RWS (required whitespace), and BWS ("bad" whitespace).
The OWS rule is used where zero or more linear whitespace characters may appear. OWS SHOULD either not be produced or be produced as a single SP character. Multiple OWS characters that occur within field-content SHOULD be replaced with a single SP before interpreting the field value or forwarding the message downstream.
RWS is used when at least one linear whitespace character is required to separate field tokens. RWS SHOULD be produced as a single SP character. Multiple RWS characters that occur within field-content SHOULD be replaced with a single SP before interpreting the field value or forwarding the message downstream.
BWS is used where the grammar allows optional whitespace for historical reasons but senders SHOULD NOT produce it in messages. HTTP/1.1 recipients MUST accept such bad optional whitespace and remove it before interpreting the field value or forwarding the message downstream.
OWS = *( [ obs-fold ] WSP ) ; "optional" whitespace RWS = 1*( [ obs-fold ] WSP ) ; "required" whitespace BWS = OWS ; "bad" whitespace obs-fold = CRLF ; see Section 3.2
Many HTTP/1.1 header field values consist of words separated by whitespace or special characters. These special characters MUST be in a quoted string to be used within a parameter value (as defined in Section 6.2 (Transfer Codings)).
tchar = "!" / "#" / "$" / "%" / "&" / "'" / "*" / "+" / "-" / "." / "^" / "_" / "`" / "|" / "~" / DIGIT / ALPHA token = 1*tchar
A string of text is parsed as a single word if it is quoted using double-quote marks.
quoted-string = DQUOTE *( qdtext / quoted-pair ) DQUOTE qdtext = OWS / %x21 / %x23-5B / %x5D-7E / obs-text ; OWS / <VCHAR except DQUOTE and "\"> / obs-text obs-text = %x80-FF
The backslash character ("\") can be used as a single-character quoting mechanism within quoted-string constructs:
quoted-pair = "\" ( WSP / VCHAR / obs-text )
Producers SHOULD NOT escape characters that do not require escaping (i.e., other than DQUOTE and the backslash character).
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The ABNF rules below are defined in other parts:
request-header = <request-header, defined in [Part2], Section 3> response-header = <response-header, defined in [Part2], Section 5>
entity-body = <entity-body, defined in [Part3], Section 3.2> entity-header = <entity-header, defined in [Part3], Section 3.1>
Cache-Control = <Cache-Control, defined in [Part6], Section 3.4> Pragma = <Pragma, defined in [Part6], Section 3.4> Warning = <Warning, defined in [Part6], Section 3.6>
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HTTP was created for the World Wide Web architecture and has evolved over time to support the scalability needs of a worldwide hypertext system. Much of that architecture is reflected in the terminology and syntax productions used to define HTTP.
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HTTP is a request/response protocol that operates by exchanging messages across a reliable transport or session-layer connection. An HTTP client is a program that establishes a connection to a server for the purpose of sending one or more HTTP requests. An HTTP server is a program that accepts connections in order to service HTTP requests by sending HTTP responses.
Note that the terms "client" and "server" refer only to the roles that these programs perform for a particular connection. The same program may act as a client on some connections and a server on others. We use the term "user agent" to refer to the program that initiates a request, such as a WWW browser, editor, or spider (web-traversing robot), and the term "origin server" to refer to the program that can originate authoritative responses to a request.
Most HTTP communication consists of a retrieval request (GET) for a representation of some resource identified by a URI. In the simplest case, this may be accomplished via a single connection (v) between the user agent (UA) and the origin server (O).
request chain ------------------------> UA -------------------v------------------- O <----------------------- response chain
A client sends an HTTP request to the server in the form of a request message (Section 4 (Request)), beginning with a method, URI, and protocol version, followed by MIME-like header fields containing request modifiers, client information, and payload metadata, an empty line to indicate the end of the header section, and finally the payload body (if any).
A server responds to the client's request by sending an HTTP response message (Section 5 (Response)), beginning with a status line that includes the protocol version, a success or error code, and textual reason phrase, followed by MIME-like header fields containing server information, resource metadata, and payload metadata, an empty line to indicate the end of the header section, and finally the payload body (if any).
The following example illustrates a typical message exchange for a GET request on the URI "http://www.example.com/hello.txt":
client request:
GET /hello.txt HTTP/1.1 User-Agent: curl/7.16.3 libcurl/7.16.3 OpenSSL/0.9.7l zlib/1.2.3 Host: www.example.com Accept: */*
server response:
HTTP/1.1 200 OK Date: Mon, 27 Jul 2009 12:28:53 GMT Server: Apache Last-Modified: Wed, 22 Jul 2009 19:15:56 GMT ETag: "34aa387-d-1568eb00" Accept-Ranges: bytes Content-Length: 14 Vary: Accept-Encoding Content-Type: text/plain Hello World!
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A more complicated situation occurs when one or more intermediaries are present in the request/response chain. There are three common forms of intermediary: proxy, gateway, and tunnel. In some cases, a single intermediary may act as an origin server, proxy, gateway, or tunnel, switching behavior based on the nature of each request.
request chain --------------------------------------> UA -----v----- A -----v----- B -----v----- C -----v----- O <------------------------------------- response chain
The figure above shows three intermediaries (A, B, and C) between the user agent and origin server. A request or response message that travels the whole chain will pass through four separate connections. Some HTTP communication options may apply only to the connection with the nearest, non-tunnel neighbor, only to the end-points of the chain, or to all connections along the chain. Although the diagram is linear, each participant may be engaged in multiple, simultaneous communications. For example, B may be receiving requests from many clients other than A, and/or forwarding requests to servers other than C, at the same time that it is handling A's request.
We use the terms "upstream" and "downstream" to describe various requirements in relation to the directional flow of a message: all messages flow from upstream to downstream. Likewise, we use the terms "inbound" and "outbound" to refer to directions in relation to the request path: "inbound" means toward the origin server and "outbound" means toward the user agent.
A proxy is a message forwarding agent that is selected by the client, usually via local configuration rules, to receive requests for some type(s) of absolute URI and attempt to satisfy those requests via translation through the HTTP interface. Some translations are minimal, such as for proxy requests for "http" URIs, whereas other requests may require translation to and from entirely different application-layer protocols. Proxies are often used to group an organization's HTTP requests through a common intermediary for the sake of security, annotation services, or shared caching.
A gateway (a.k.a., reverse proxy) is a receiving agent that acts as a layer above some other server(s) and translates the received requests to the underlying server's protocol. Gateways are often used for load balancing or partitioning HTTP services across multiple machines. Unlike a proxy, a gateway receives requests as if it were the origin server for the requested resource; the requesting client will not be aware that it is communicating with a gateway. A gateway communicates with the client as if the gateway is the origin server and thus is subject to all of the requirements on origin servers for that connection. A gateway communicates with inbound servers using any protocol it desires, including private extensions to HTTP that are outside the scope of this specification.
A tunnel acts as a blind relay between two connections without changing the messages. Once active, a tunnel is not considered a party to the HTTP communication, though the tunnel may have been initiated by an HTTP request. A tunnel ceases to exist when both ends of the relayed connection are closed. Tunnels are used to extend a virtual connection through an intermediary, such as when transport-layer security is used to establish private communication through a shared firewall proxy.
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Any party to HTTP communication that is not acting as a tunnel may employ an internal cache for handling requests. A cache is a local store of previous response messages and the subsystem that controls its message storage, retrieval, and deletion. A cache stores cacheable responses in order to reduce the response time and network bandwidth consumption on future, equivalent requests. Any client or server may include a cache, though a cache cannot be used by a server while it is acting as a tunnel.
The effect of a cache is that the request/response chain is shortened if one of the participants along the chain has a cached response applicable to that request. The following illustrates the resulting chain if B has a cached copy of an earlier response from O (via C) for a request which has not been cached by UA or A.
request chain ----------> UA -----v----- A -----v----- B - - - - - - C - - - - - - O <--------- response chain
A response is cacheable if a cache is allowed to store a copy of the response message for use in answering subsequent requests. Even when a response is cacheable, there may be additional constraints placed by the client or by the origin server on when that cached response can be used for a particular request. HTTP requirements for cache behavior and cacheable responses are defined in Section 2 of [Part6] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., Nottingham, M., Ed., and J. Reschke, Ed., “HTTP/1.1, part 6: Caching,” October 2009.).
There are a wide variety of architectures and configurations of caches and proxies deployed across the World Wide Web and inside large organizations. These systems include national hierarchies of proxy caches to save transoceanic bandwidth, systems that broadcast or multicast cache entries, organizations that distribute subsets of cached data via optical media, and so on.
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HTTP systems are used in a wide variety of environments, from corporate intranets with high-bandwidth links to long-distance communication over low-power radio links and intermittent connectivity.
HTTP communication usually takes place over TCP/IP connections. The default port is TCP 80 (http://www.iana.org/assignments/port-numbers), but other ports can be used. This does not preclude HTTP from being implemented on top of any other protocol on the Internet, or on other networks. HTTP only presumes a reliable transport; any protocol that provides such guarantees can be used; the mapping of the HTTP/1.1 request and response structures onto the transport data units of the protocol in question is outside the scope of this specification.
In HTTP/1.0, most implementations used a new connection for each request/response exchange. In HTTP/1.1, a connection may be used for one or more request/response exchanges, although connections may be closed for a variety of reasons (see Section 7.1 (Persistent Connections)).
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HTTP uses a "<major>.<minor>" numbering scheme to indicate versions of the protocol. The protocol versioning policy is intended to allow the sender to indicate the format of a message and its capacity for understanding further HTTP communication, rather than the features obtained via that communication. No change is made to the version number for the addition of message components which do not affect communication behavior or which only add to extensible field values. The <minor> number is incremented when the changes made to the protocol add features which do not change the general message parsing algorithm, but which may add to the message semantics and imply additional capabilities of the sender. The <major> number is incremented when the format of a message within the protocol is changed. See [RFC2145] (Mogul, J., Fielding, R., Gettys, J., and H. Nielsen, “Use and Interpretation of HTTP Version Numbers,” May 1997.) for a fuller explanation.
The version of an HTTP message is indicated by an HTTP-Version field in the first line of the message. HTTP-Version is case-sensitive.
HTTP-Version = HTTP-Prot-Name "/" 1*DIGIT "." 1*DIGIT HTTP-Prot-Name = %x48.54.54.50 ; "HTTP", case-sensitive
Note that the major and minor numbers MUST be treated as separate integers and that each MAY be incremented higher than a single digit. Thus, HTTP/2.4 is a lower version than HTTP/2.13, which in turn is lower than HTTP/12.3. Leading zeros MUST be ignored by recipients and MUST NOT be sent.
An application that sends a request or response message that includes HTTP-Version of "HTTP/1.1" MUST be at least conditionally compliant with this specification. Applications that are at least conditionally compliant with this specification SHOULD use an HTTP-Version of "HTTP/1.1" in their messages, and MUST do so for any message that is not compatible with HTTP/1.0. For more details on when to send specific HTTP-Version values, see [RFC2145] (Mogul, J., Fielding, R., Gettys, J., and H. Nielsen, “Use and Interpretation of HTTP Version Numbers,” May 1997.).
The HTTP version of an application is the highest HTTP version for which the application is at least conditionally compliant.
Proxy and gateway applications need to be careful when forwarding messages in protocol versions different from that of the application. Since the protocol version indicates the protocol capability of the sender, a proxy/gateway MUST NOT send a message with a version indicator which is greater than its actual version. If a higher version request is received, the proxy/gateway MUST either downgrade the request version, or respond with an error, or switch to tunnel behavior.
Due to interoperability problems with HTTP/1.0 proxies discovered since the publication of [RFC2068] (Fielding, R., Gettys, J., Mogul, J., Nielsen, H., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” January 1997.), caching proxies MUST, gateways MAY, and tunnels MUST NOT upgrade the request to the highest version they support. The proxy/gateway's response to that request MUST be in the same major version as the request.
Note: Converting between versions of HTTP may involve modification of header fields required or forbidden by the versions involved.
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Uniform Resource Identifiers (URIs) [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.) are used throughout HTTP as the means for identifying resources. URI references are used to target requests, indicate redirects, and define relationships. HTTP does not limit what a resource may be; it merely defines an interface that can be used to interact with a resource via HTTP. More information on the scope of URIs and resources can be found in [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.).
This specification adopts the definitions of "URI-reference", "absolute-URI", "relative-part", "port", "host", "path-abempty", "path-absolute", "query", and "authority" from [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.). In addition, we define a partial-URI rule for protocol elements that allow a relative URI without a fragment.
URI = <URI, defined in [RFC3986], Section 3> URI-reference = <URI-reference, defined in [RFC3986], Section 4.1> absolute-URI = <absolute-URI, defined in [RFC3986], Section 4.3> relative-part = <relative-part, defined in [RFC3986], Section 4.2> authority = <authority, defined in [RFC3986], Section 3.2> path-abempty = <path-abempty, defined in [RFC3986], Section 3.3> path-absolute = <path-absolute, defined in [RFC3986], Section 3.3> port = <port, defined in [RFC3986], Section 3.2.3> query = <query, defined in [RFC3986], Section 3.4> uri-host = <host, defined in [RFC3986], Section 3.2.2> partial-URI = relative-part [ "?" query ]
Each protocol element in HTTP that allows a URI reference will indicate in its ABNF production whether the element allows only a URI in absolute form (absolute-URI), any relative reference (relative-ref), or some other subset of the URI-reference grammar. Unless otherwise indicated, URI references are parsed relative to the request target (the default base URI for both the request and its corresponding response).
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The "http" URI scheme is hereby defined for the purpose of minting identifiers according to their association with the hierarchical namespace governed by a potential HTTP origin server listening for TCP connections on a given port. The HTTP server is identified via the generic syntax's authority (Uniform Resource Identifiers) component, which includes a host identifier and optional TCP port, and the remainder of the URI is considered to be identifying data corresponding to a resource for which that server might provide an HTTP interface.
http-URI = "http:" "//" authority path-abempty [ "?" query ]
The host identifier within an authority (Uniform Resource Identifiers) component is defined in [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.), Section 3.2.2. If host is provided as an IP literal or IPv4 address, then the HTTP server is any listener on the indicated TCP port at that IP address. If host is a registered name, then that name is considered an indirect identifier and the recipient might use a name resolution service, such as DNS, to find the address of a listener for that host. The host MUST NOT be empty; if an "http" URI is received with an empty host, then it MUST be rejected as invalid. If the port subcomponent is empty or not given, then TCP port 80 is assumed (the default reserved port for WWW services).
Regardless of the form of host identifier, access to that host is not implied by the mere presence of its name or address. The host may or may not exist and, even when it does exist, may or may not be running an HTTP server or listening to the indicated port. The "http" URI scheme makes use of the delegated nature of Internet names and addresses to establish a naming authority (whatever entity has the ability to place an HTTP server at that Internet name or address) and allows that authority to determine which names are valid and how they might be used.
When an "http" URI is used within a context that calls for access to the indicated resource, a client MAY attempt access by resolving the host to an IP address, establishing a TCP connection to that address on the indicated port, and sending an HTTP request message to the server containing the URI's identifying data as described in Section 4 (Request). If the server responds to that request with a non-interim HTTP response message, as described in Section 5 (Response), then that response is considered an authoritative answer to the client's request.
Although HTTP is independent of the transport protocol, the "http" scheme is specific to TCP-based services because the name delegation process depends on TCP for establishing authority. An HTTP service based on some other underlying connection protocol would presumably be identified using a different URI scheme, just as the "https" scheme (below) is used for servers that require an SSL/TLS transport layer on a connection. Other protocols may also be used to provide access to "http" identified resources --- it is only the authoritative interface used for mapping the namespace that is specific to TCP.
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The "https" URI scheme is hereby defined for the purpose of minting identifiers according to their association with the hierarchical namespace governed by a potential HTTP origin server listening for SSL/TLS-secured connections on a given TCP port. The host and port are determined in the same way as for the "http" scheme, except that a default TCP port of 443 is assumed if the port subcomponent is empty or not given.
https-URI = "https:" "//" authority path-abempty [ "?" query ]
The primary difference between the "http" and "https" schemes is that interaction with the latter is required to be secured for privacy through the use of strong encryption. The URI cannot be sent in a request until the connection is secure. Likewise, the default for caching is that each response that would be considered "public" under the "http" scheme is instead treated as "private" and thus not eligible for shared caching.
The process for authoritative access to an "https" identified resource is defined in [RFC2818] (Rescorla, E., “HTTP Over TLS,” May 2000.).
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Since the "http" and "https" schemes conform to the URI generic syntax, such URIs are normalized and compared according to the algorithm defined in [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.), Section 6, using the defaults described above for each scheme.
If the port is equal to the default port for a scheme, the normal form is to elide the port subcomponent. Likewise, an empty path component is equivalent to an absolute path of "/", so the normal form is to provide a path of "/" instead. The scheme and host are case-insensitive and normally provided in lowercase; all other components are compared in a case-sensitive manner. Characters other than those in the "reserved" set are equivalent to their percent-encoded octets (see [RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.), Section 2.1): the normal form is to not encode them.
For example, the following three URIs are equivalent:
http://example.com:80/~smith/home.html http://EXAMPLE.com/%7Esmith/home.html http://EXAMPLE.com:/%7esmith/home.html
[anchor1] ([[This paragraph does not belong here. --Roy]]) If path-abempty is the empty string (i.e., there is no slash "/" path separator following the authority), then the "http" URI MUST be given as "/" when used as a request-target (Section 4.1.2 (request-target)). If a proxy receives a host name which is not a fully qualified domain name, it MAY add its domain to the host name it received. If a proxy receives a fully qualified domain name, the proxy MUST NOT change the host name.
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All HTTP/1.1 messages consist of a start-line followed by a sequence of characters in a format similar to the Internet Message Format [RFC5322] (Resnick, P., “Internet Message Format,” October 2008.): zero or more header fields (collectively referred to as the "headers" or the "header section"), an empty line indicating the end of the header section, and an optional message-body.
An HTTP message can either be a request from client to server or a response from server to client. Syntactically, the two types of message differ only in the start-line, which is either a Request-Line (for requests) or a Status-Line (for responses), and in the algorithm for determining the length of the message-body (Section 3.4 (Message Length)). In theory, a client could receive requests and a server could receive responses, distinguishing them by their different start-line formats, but in practice servers are implemented to only expect a request (a response is interpreted as an unknown or invalid request method) and clients are implemented to only expect a response.
HTTP-message = start-line *( header-field CRLF ) CRLF [ message-body ] start-line = Request-Line / Status-Line
Whitespace (WSP) MUST NOT be sent between the start-line and the first header field. The presence of whitespace might be an attempt to trick a noncompliant implementation of HTTP into ignoring that field or processing the next line as a new request, either of which may result in security issues when implementations within the request chain interpret the same message differently. HTTP/1.1 servers MUST reject such a message with a 400 (Bad Request) response.
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In the interest of robustness, servers SHOULD ignore at least one empty line received where a Request-Line is expected. In other words, if the server is reading the protocol stream at the beginning of a message and receives a CRLF first, it should ignore the CRLF.
Some old HTTP/1.0 client implementations generate an extra CRLF after a POST request as a lame workaround for some early server applications that failed to read message-body content that was not terminated by a line-ending. An HTTP/1.1 client MUST NOT preface or follow a request with an extra CRLF. If terminating the request message-body with a line-ending is desired, then the client MUST include the terminating CRLF octets as part of the message-body length.
The normal procedure for parsing an HTTP message is to read the start-line into a structure, read each header field into a hash table by field name until the empty line, and then use the parsed data to determine if a message-body is expected. If a message-body has been indicated, then it is read as a stream until an amount of OCTETs equal to the message-length is read or the connection is closed. Care must be taken to parse an HTTP message as a sequence of OCTETs in an encoding that is a superset of US-ASCII. Attempting to parse HTTP as a stream of Unicode characters in a character encoding like UTF-16 may introduce security flaws due to the differing ways that such parsers interpret invalid characters.
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Each HTTP header field consists of a case-insensitive field name followed by a colon (":"), optional whitespace, and the field value.
header-field = field-name ":" OWS [ field-value ] OWS field-name = token field-value = *( field-content / OWS ) field-content = *( WSP / VCHAR / obs-text )
No whitespace is allowed between the header field name and colon. For security reasons, any request message received containing such whitespace MUST be rejected with a response code of 400 (Bad Request). A proxy MUST remove any such whitespace from a response message before forwarding the message downstream.
A field value MAY be preceded by optional whitespace (OWS); a single SP is preferred. The field value does not include any leading or trailing white space: OWS occurring before the first non-whitespace character of the field value or after the last non-whitespace character of the field value is ignored and SHOULD be removed without changing the meaning of the header field.
The order in which header fields with differing field names are received is not significant. However, it is "good practice" to send header fields that contain control data first, such as Host on requests and Date on responses, so that implementations can decide when not to handle a message as early as possible. A server MUST wait until the entire header section is received before interpreting a request message, since later header fields might include conditionals, authentication credentials, or deliberately misleading duplicate header fields that would impact request processing.
Multiple header fields with the same field name MUST NOT be sent in a message unless the entire field value for that header field is defined as a comma-separated list [i.e., #(values)]. Multiple header fields with the same field name can be combined into one "field-name: field-value" pair, without changing the semantics of the message, by appending each subsequent field value to the combined field value in order, separated by a comma. The order in which header fields with the same field name are received is therefore significant to the interpretation of the combined field value; a proxy MUST NOT change the order of these field values when forwarding a message.
Note: the "Set-Cookie" header as implemented in practice (as opposed to how it is specified in [RFC2109] (Kristol, D. and L. Montulli, “HTTP State Management Mechanism,” February 1997.)) can occur multiple times, but does not use the list syntax, and thus cannot be combined into a single line. (See Appendix A.2.3 of [Kri2001] (Kristol, D., “HTTP Cookies: Standards, Privacy, and Politics,” November 2001.) for details.) Also note that the Set-Cookie2 header specified in [RFC2965] (Kristol, D. and L. Montulli, “HTTP State Management Mechanism,” October 2000.) does not share this problem.
Historically, HTTP header field values could be extended over multiple lines by preceding each extra line with at least one space or horizontal tab character (line folding). This specification deprecates such line folding except within the message/http media type (Section 10.3.1 (Internet Media Type message/http)). HTTP/1.1 senders MUST NOT produce messages that include line folding (i.e., that contain any field-content that matches the obs-fold rule) unless the message is intended for packaging within the message/http media type. HTTP/1.1 recipients SHOULD accept line folding and replace any embedded obs-fold whitespace with a single SP prior to interpreting the field value or forwarding the message downstream.
Historically, HTTP has allowed field content with text in the ISO-8859-1 [ISO‑8859‑1] (International Organization for Standardization, “Information technology -- 8-bit single-byte coded graphic character sets -- Part 1: Latin alphabet No. 1,” 1998.) character encoding and supported other character sets only through use of [RFC2047] (Moore, K., “MIME (Multipurpose Internet Mail Extensions) Part Three: Message Header Extensions for Non-ASCII Text,” November 1996.) encoding. In practice, most HTTP header field values use only a subset of the US-ASCII character encoding [USASCII] (American National Standards Institute, “Coded Character Set -- 7-bit American Standard Code for Information Interchange,” 1986.). Newly defined header fields SHOULD limit their field values to US-ASCII characters. Recipients SHOULD treat other (obs-text) octets in field content as opaque data.
Comments can be included in some HTTP header fields by surrounding the comment text with parentheses. Comments are only allowed in fields containing "comment" as part of their field value definition.
comment = "(" *( ctext / quoted-cpair / comment ) ")" ctext = OWS / %x21-27 / %x2A-5B / %x5D-7E / obs-text ; OWS / <VCHAR except "(", ")", and "\"> / obs-text
The backslash character ("\") can be used as a single-character quoting mechanism within comment constructs:
quoted-cpair = "\" ( WSP / VCHAR / obs-text )
Producers SHOULD NOT escape characters that do not require escaping (i.e., other than the backslash character "\" and the parentheses "(" and ")").
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The message-body (if any) of an HTTP message is used to carry the entity-body associated with the request or response. The message-body differs from the entity-body only when a transfer-coding has been applied, as indicated by the Transfer-Encoding header field (Section 9.7 (Transfer-Encoding)).
message-body = entity-body / <entity-body encoded as per Transfer-Encoding>
Transfer-Encoding MUST be used to indicate any transfer-codings applied by an application to ensure safe and proper transfer of the message. Transfer-Encoding is a property of the message, not of the entity, and thus MAY be added or removed by any application along the request/response chain. (However, Section 6.2 (Transfer Codings) places restrictions on when certain transfer-codings may be used.)
The rules for when a message-body is allowed in a message differ for requests and responses.
The presence of a message-body in a request is signaled by the inclusion of a Content-Length or Transfer-Encoding header field in the request's header fields. When a request message contains both a message-body of non-zero length and a method that does not define any semantics for that request message-body, then an origin server SHOULD either ignore the message-body or respond with an appropriate error message (e.g., 413). A proxy or gateway, when presented the same request, SHOULD either forward the request inbound with the message-body or ignore the message-body when determining a response.
For response messages, whether or not a message-body is included with a message is dependent on both the request method and the response status code (Section 5.1.1 (Status Code and Reason Phrase)). All responses to the HEAD request method MUST NOT include a message-body, even though the presence of entity-header fields might lead one to believe they do. All 1xx (informational), 204 (No Content), and 304 (Not Modified) responses MUST NOT include a message-body. All other responses do include a message-body, although it MAY be of zero length.
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The transfer-length of a message is the length of the message-body as it appears in the message; that is, after any transfer-codings have been applied. When a message-body is included with a message, the transfer-length of that body is determined by one of the following (in order of precedence):
A range header might be forwarded by a 1.0 proxy that does not understand multipart/byteranges; in this case the server MUST delimit the message using methods defined in items 1, 3 or 5 of this section.
For compatibility with HTTP/1.0 applications, HTTP/1.1 requests containing a message-body MUST include a valid Content-Length header field unless the server is known to be HTTP/1.1 compliant. If a request contains a message-body and a Content-Length is not given, the server SHOULD respond with 400 (Bad Request) if it cannot determine the length of the message, or with 411 (Length Required) if it wishes to insist on receiving a valid Content-Length.
All HTTP/1.1 applications that receive entities MUST accept the "chunked" transfer-coding (Section 6.2 (Transfer Codings)), thus allowing this mechanism to be used for messages when the message length cannot be determined in advance.
Messages MUST NOT include both a Content-Length header field and a transfer-coding. If the message does include a transfer-coding, the Content-Length MUST be ignored.
When a Content-Length is given in a message where a message-body is allowed, its field value MUST exactly match the number of OCTETs in the message-body. HTTP/1.1 user agents MUST notify the user when an invalid length is received and detected.
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There are a few header fields which have general applicability for both request and response messages, but which do not apply to the entity being transferred. These header fields apply only to the message being transmitted.
general-header = Cache-Control ; [Part6], Section 3.2 / Connection ; Section 9.1 / Date ; Section 9.3 / Pragma ; [Part6], Section 3.4 / Trailer ; Section 9.6 / Transfer-Encoding ; Section 9.7 / Upgrade ; Section 9.8 / Via ; Section 9.9 / Warning ; [Part6], Section 3.6
General-header field names can be extended reliably only in combination with a change in the protocol version. However, new or experimental header fields may be given the semantics of general header fields if all parties in the communication recognize them to be general-header fields. Unrecognized header fields are treated as entity-header fields.
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A request message from a client to a server includes, within the first line of that message, the method to be applied to the resource, the identifier of the resource, and the protocol version in use.
Request = Request-Line ; Section 4.1 *(( general-header ; Section 3.5 / request-header ; [Part2], Section 3 / entity-header ) CRLF ) ; [Part3], Section 3.1 CRLF [ message-body ] ; Section 3.3
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The Request-Line begins with a method token, followed by the request-target and the protocol version, and ending with CRLF. The elements are separated by SP characters. No CR or LF is allowed except in the final CRLF sequence.
Request-Line = Method SP request-target SP HTTP-Version CRLF
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The Method token indicates the method to be performed on the resource identified by the request-target. The method is case-sensitive.
Method = token
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The request-target identifies the resource upon which to apply the request.
request-target = "*" / absolute-URI / ( path-absolute [ "?" query ] ) / authority
The four options for request-target are dependent on the nature of the request. The asterisk "*" means that the request does not apply to a particular resource, but to the server itself, and is only allowed when the method used does not necessarily apply to a resource. One example would be
OPTIONS * HTTP/1.1
The absolute-URI form is REQUIRED when the request is being made to a proxy. The proxy is requested to forward the request or service it from a valid cache, and return the response. Note that the proxy MAY forward the request on to another proxy or directly to the server specified by the absolute-URI. In order to avoid request loops, a proxy MUST be able to recognize all of its server names, including any aliases, local variations, and the numeric IP address. An example Request-Line would be:
GET http://www.example.org/pub/WWW/TheProject.html HTTP/1.1
To allow for transition to absolute-URIs in all requests in future versions of HTTP, all HTTP/1.1 servers MUST accept the absolute-URI form in requests, even though HTTP/1.1 clients will only generate them in requests to proxies.
The authority form is only used by the CONNECT method (Section 7.9 of [Part2] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 2: Message Semantics,” October 2009.)).
The most common form of request-target is that used to identify a resource on an origin server or gateway. In this case the absolute path of the URI MUST be transmitted (see Section 2.6.1 (http URI scheme), path-absolute) as the request-target, and the network location of the URI (authority) MUST be transmitted in a Host header field. For example, a client wishing to retrieve the resource above directly from the origin server would create a TCP connection to port 80 of the host "www.example.org" and send the lines:
GET /pub/WWW/TheProject.html HTTP/1.1 Host: www.example.org
followed by the remainder of the Request. Note that the absolute path cannot be empty; if none is present in the original URI, it MUST be given as "/" (the server root).
If a proxy receives a request without any path in the request-target and the method specified is capable of supporting the asterisk form of request-target, then the last proxy on the request chain MUST forward the request with "*" as the final request-target.
For example, the request
OPTIONS http://www.example.org:8001 HTTP/1.1
would be forwarded by the proxy as
OPTIONS * HTTP/1.1 Host: www.example.org:8001
after connecting to port 8001 of host "www.example.org".
The request-target is transmitted in the format specified in Section 2.6.1 (http URI scheme). If the request-target is percent-encoded ([RFC3986] (Berners-Lee, T., Fielding, R., and L. Masinter, “Uniform Resource Identifier (URI): Generic Syntax,” January 2005.), Section 2.1), the origin server MUST decode the request-target in order to properly interpret the request. Servers SHOULD respond to invalid request-targets with an appropriate status code.
A transparent proxy MUST NOT rewrite the "path-absolute" part of the received request-target when forwarding it to the next inbound server, except as noted above to replace a null path-absolute with "/".
Note: The "no rewrite" rule prevents the proxy from changing the meaning of the request when the origin server is improperly using a non-reserved URI character for a reserved purpose. Implementors should be aware that some pre-HTTP/1.1 proxies have been known to rewrite the request-target.
HTTP does not place a pre-defined limit on the length of a request-target. A server MUST be prepared to receive URIs of unbounded length and respond with the 414 (URI Too Long) status if the received request-target would be longer than the server wishes to handle (see Section 8.4.15 of [Part2] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 2: Message Semantics,” October 2009.)).
Various ad-hoc limitations on request-target length are found in practice. It is RECOMMENDED that all HTTP senders and recipients support request-target lengths of 8000 or more OCTETs.
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The exact resource identified by an Internet request is determined by examining both the request-target and the Host header field.
An origin server that does not allow resources to differ by the requested host MAY ignore the Host header field value when determining the resource identified by an HTTP/1.1 request. (But see Appendix B.1.1 (Changes to Simplify Multi-homed Web Servers and Conserve IP Addresses) for other requirements on Host support in HTTP/1.1.)
An origin server that does differentiate resources based on the host requested (sometimes referred to as virtual hosts or vanity host names) MUST use the following rules for determining the requested resource on an HTTP/1.1 request:
Recipients of an HTTP/1.0 request that lacks a Host header field MAY attempt to use heuristics (e.g., examination of the URI path for something unique to a particular host) in order to determine what exact resource is being requested.
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After receiving and interpreting a request message, a server responds with an HTTP response message.
Response = Status-Line ; Section 5.1 *(( general-header ; Section 3.5 / response-header ; [Part2], Section 5 / entity-header ) CRLF ) ; [Part3], Section 3.1 CRLF [ message-body ] ; Section 3.3
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The first line of a Response message is the Status-Line, consisting of the protocol version followed by a numeric status code and its associated textual phrase, with each element separated by SP characters. No CR or LF is allowed except in the final CRLF sequence.
Status-Line = HTTP-Version SP Status-Code SP Reason-Phrase CRLF
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The Status-Code element is a 3-digit integer result code of the attempt to understand and satisfy the request. These codes are fully defined in Section 8 of [Part2] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 2: Message Semantics,” October 2009.). The Reason Phrase exists for the sole purpose of providing a textual description associated with the numeric status code, out of deference to earlier Internet application protocols that were more frequently used with interactive text clients. A client SHOULD ignore the content of the Reason Phrase.
The first digit of the Status-Code defines the class of response. The last two digits do not have any categorization role. There are 5 values for the first digit:
Status-Code = 3DIGIT Reason-Phrase = *( WSP / VCHAR / obs-text )
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HTTP applications have historically allowed three different formats for the representation of date/time stamps:
Sun, 06 Nov 1994 08:49:37 GMT ; RFC 1123 Sunday, 06-Nov-94 08:49:37 GMT ; obsolete RFC 850 format Sun Nov 6 08:49:37 1994 ; ANSI C's asctime() format
The first format is preferred as an Internet standard and represents a fixed-length subset of that defined by [RFC1123] (Braden, R., “Requirements for Internet Hosts - Application and Support,” October 1989.). The other formats are described here only for compatibility with obsolete implementations. HTTP/1.1 clients and servers that parse the date value MUST accept all three formats (for compatibility with HTTP/1.0), though they MUST only generate the RFC 1123 format for representing HTTP-date values in header fields. See Appendix A (Tolerant Applications) for further information.
All HTTP date/time stamps MUST be represented in Greenwich Mean Time (GMT), without exception. For the purposes of HTTP, GMT is exactly equal to UTC (Coordinated Universal Time). This is indicated in the first two formats by the inclusion of "GMT" as the three-letter abbreviation for time zone, and MUST be assumed when reading the asctime format. HTTP-date is case sensitive and MUST NOT include additional whitespace beyond that specifically included as SP in the grammar.
HTTP-date = rfc1123-date / obs-date
Preferred format:
rfc1123-date = day-name "," SP date1 SP time-of-day SP GMT day-name = %x4D.6F.6E ; "Mon", case-sensitive / %x54.75.65 ; "Tue", case-sensitive / %x57.65.64 ; "Wed", case-sensitive / %x54.68.75 ; "Thu", case-sensitive / %x46.72.69 ; "Fri", case-sensitive / %x53.61.74 ; "Sat", case-sensitive / %x53.75.6E ; "Sun", case-sensitive date1 = day SP month SP year ; e.g., 02 Jun 1982 day = 2DIGIT month = %x4A.61.6E ; "Jan", case-sensitive / %x46.65.62 ; "Feb", case-sensitive / %x4D.61.72 ; "Mar", case-sensitive / %x41.70.72 ; "Apr", case-sensitive / %x4D.61.79 ; "May", case-sensitive / %x4A.75.6E ; "Jun", case-sensitive / %x4A.75.6C ; "Jul", case-sensitive / %x41.75.67 ; "Aug", case-sensitive / %x53.65.70 ; "Sep", case-sensitive / %x4F.63.74 ; "Oct", case-sensitive / %x4E.6F.76 ; "Nov", case-sensitive / %x44.65.63 ; "Dec", case-sensitive year = 4DIGIT GMT = %x47.4D.54 ; "GMT", case-sensitive time-of-day = hour ":" minute ":" second ; 00:00:00 - 23:59:59 hour = 2DIGIT minute = 2DIGIT second = 2DIGIT
The semantics of day-name, day, month, year, and time-of-day are the same as those defined for the RFC 5322 constructs with the corresponding name ([RFC5322] (Resnick, P., “Internet Message Format,” October 2008.), Section 3.3).
Obsolete formats:
obs-date = rfc850-date / asctime-date
rfc850-date = day-name-l "," SP date2 SP time-of-day SP GMT date2 = day "-" month "-" 2DIGIT ; day-month-year (e.g., 02-Jun-82) day-name-l = %x4D.6F.6E.64.61.79 ; "Monday", case-sensitive / %x54.75.65.73.64.61.79 ; "Tuesday", case-sensitive / %x57.65.64.6E.65.73.64.61.79 ; "Wednesday", case-sensitive / %x54.68.75.72.73.64.61.79 ; "Thursday", case-sensitive / %x46.72.69.64.61.79 ; "Friday", case-sensitive / %x53.61.74.75.72.64.61.79 ; "Saturday", case-sensitive / %x53.75.6E.64.61.79 ; "Sunday", case-sensitive
asctime-date = day-name SP date3 SP time-of-day SP year date3 = month SP ( 2DIGIT / ( SP 1DIGIT )) ; month day (e.g., Jun 2)
Note: Recipients of date values are encouraged to be robust in accepting date values that may have been sent by non-HTTP applications, as is sometimes the case when retrieving or posting messages via proxies/gateways to SMTP or NNTP.
Note: HTTP requirements for the date/time stamp format apply only to their usage within the protocol stream. Clients and servers are not required to use these formats for user presentation, request logging, etc.
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Transfer-coding values are used to indicate an encoding transformation that has been, can be, or may need to be applied to an entity-body in order to ensure "safe transport" through the network. This differs from a content coding in that the transfer-coding is a property of the message, not of the original entity.
transfer-coding = "chunked" ; Section 6.2.1 / "compress" ; Section 6.2.2.1 / "deflate" ; Section 6.2.2.2 / "gzip" ; Section 6.2.2.3 / transfer-extension transfer-extension = token *( OWS ";" OWS transfer-parameter )
Parameters are in the form of attribute/value pairs.
transfer-parameter = attribute BWS "=" BWS value attribute = token value = token / quoted-string
All transfer-coding values are case-insensitive. HTTP/1.1 uses transfer-coding values in the TE header field (Section 9.5 (TE)) and in the Transfer-Encoding header field (Section 9.7 (Transfer-Encoding)).
Whenever a transfer-coding is applied to a message-body, the set of transfer-codings MUST include "chunked", unless the message indicates it is terminated by closing the connection. When the "chunked" transfer-coding is used, it MUST be the last transfer-coding applied to the message-body. The "chunked" transfer-coding MUST NOT be applied more than once to a message-body. These rules allow the recipient to determine the transfer-length of the message (Section 3.4 (Message Length)).
Transfer-codings are analogous to the Content-Transfer-Encoding values of MIME, which were designed to enable safe transport of binary data over a 7-bit transport service ([RFC2045] (Freed, N. and N. Borenstein, “Multipurpose Internet Mail Extensions (MIME) Part One: Format of Internet Message Bodies,” November 1996.), Section 6). However, safe transport has a different focus for an 8bit-clean transfer protocol. In HTTP, the only unsafe characteristic of message-bodies is the difficulty in determining the exact body length (Section 3.4 (Message Length)), or the desire to encrypt data over a shared transport.
A server which receives an entity-body with a transfer-coding it does not understand SHOULD return 501 (Not Implemented), and close the connection. A server MUST NOT send transfer-codings to an HTTP/1.0 client.
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The chunked encoding modifies the body of a message in order to transfer it as a series of chunks, each with its own size indicator, followed by an OPTIONAL trailer containing entity-header fields. This allows dynamically produced content to be transferred along with the information necessary for the recipient to verify that it has received the full message.
Chunked-Body = *chunk last-chunk trailer-part CRLF chunk = chunk-size *WSP [ chunk-ext ] CRLF chunk-data CRLF chunk-size = 1*HEXDIG last-chunk = 1*("0") *WSP [ chunk-ext ] CRLF chunk-ext = *( ";" *WSP chunk-ext-name [ "=" chunk-ext-val ] *WSP ) chunk-ext-name = token chunk-ext-val = token / quoted-str-nf chunk-data = 1*OCTET ; a sequence of chunk-size octets trailer-part = *( entity-header CRLF ) quoted-str-nf = DQUOTE *( qdtext-nf / quoted-pair ) DQUOTE ; like quoted-string, but disallowing line folding qdtext-nf = WSP / %x21 / %x23-5B / %x5D-7E / obs-text ; WSP / <VCHAR except DQUOTE and "\"> / obs-text
The chunk-size field is a string of hex digits indicating the size of the chunk-data in octets. The chunked encoding is ended by any chunk whose size is zero, followed by the trailer, which is terminated by an empty line.
The trailer allows the sender to include additional HTTP header fields at the end of the message. The Trailer header field can be used to indicate which header fields are included in a trailer (see Section 9.6 (Trailer)).
A server using chunked transfer-coding in a response MUST NOT use the trailer for any header fields unless at least one of the following is true:
This requirement prevents an interoperability failure when the message is being received by an HTTP/1.1 (or later) proxy and forwarded to an HTTP/1.0 recipient. It avoids a situation where compliance with the protocol would have necessitated a possibly infinite buffer on the proxy.
A process for decoding the "chunked" transfer-coding can be represented in pseudo-code as:
length := 0 read chunk-size, chunk-ext (if any) and CRLF while (chunk-size > 0) { read chunk-data and CRLF append chunk-data to entity-body length := length + chunk-size read chunk-size and CRLF } read entity-header while (entity-header not empty) { append entity-header to existing header fields read entity-header } Content-Length := length Remove "chunked" from Transfer-Encoding
All HTTP/1.1 applications MUST be able to receive and decode the "chunked" transfer-coding, and MUST ignore chunk-ext extensions they do not understand.
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The codings defined below can be used to compress the payload of a message.
Note: Use of program names for the identification of encoding formats is not desirable and is discouraged for future encodings. Their use here is representative of historical practice, not good design.
Note: For compatibility with previous implementations of HTTP, applications SHOULD consider "x-gzip" and "x-compress" to be equivalent to "gzip" and "compress" respectively.
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The "compress" format is produced by the common UNIX file compression program "compress". This format is an adaptive Lempel-Ziv-Welch coding (LZW).
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The "zlib" format is defined in [RFC1950] (Deutsch, L. and J-L. Gailly, “ZLIB Compressed Data Format Specification version 3.3,” May 1996.) in combination with the "deflate" compression mechanism described in [RFC1951] (Deutsch, P., “DEFLATE Compressed Data Format Specification version 1.3,” May 1996.).
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The "gzip" format is produced by the file compression program "gzip" (GNU zip), as described in [RFC1952] (Deutsch, P., Gailly, J-L., Adler, M., Deutsch, L., and G. Randers-Pehrson, “GZIP file format specification version 4.3,” May 1996.). This format is a Lempel-Ziv coding (LZ77) with a 32 bit CRC.
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The HTTP Transfer Coding Registry defines the name space for the transfer coding names.
Registrations MUST include the following fields:
Values to be added to this name space require expert review and a specification (see "Expert Review" and "Specification Required" in Section 4.1 of [RFC5226] (Narten, T. and H. Alvestrand, “Guidelines for Writing an IANA Considerations Section in RFCs,” May 2008.)), and MUST conform to the purpose of transfer coding defined in this section.
The registry itself is maintained at http://www.iana.org/assignments/http-parameters.
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Product tokens are used to allow communicating applications to identify themselves by software name and version. Most fields using product tokens also allow sub-products which form a significant part of the application to be listed, separated by whitespace. By convention, the products are listed in order of their significance for identifying the application.
product = token ["/" product-version] product-version = token
Examples:
User-Agent: CERN-LineMode/2.15 libwww/2.17b3 Server: Apache/0.8.4
Product tokens SHOULD be short and to the point. They MUST NOT be used for advertising or other non-essential information. Although any token character MAY appear in a product-version, this token SHOULD only be used for a version identifier (i.e., successive versions of the same product SHOULD only differ in the product-version portion of the product value).
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Both transfer codings (TE request header, Section 9.5 (TE)) and content negotiation (Section 4 of [Part3] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 3: Message Payload and Content Negotiation,” October 2009.)) use short "floating point" numbers to indicate the relative importance ("weight") of various negotiable parameters. A weight is normalized to a real number in the range 0 through 1, where 0 is the minimum and 1 the maximum value. If a parameter has a quality value of 0, then content with this parameter is `not acceptable' for the client. HTTP/1.1 applications MUST NOT generate more than three digits after the decimal point. User configuration of these values SHOULD also be limited in this fashion.
qvalue = ( "0" [ "." 0*3DIGIT ] ) / ( "1" [ "." 0*3("0") ] )
Note: "Quality values" is a misnomer, since these values merely represent relative degradation in desired quality.
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Prior to persistent connections, a separate TCP connection was established to fetch each URL, increasing the load on HTTP servers and causing congestion on the Internet. The use of inline images and other associated data often require a client to make multiple requests of the same server in a short amount of time. Analysis of these performance problems and results from a prototype implementation are available [Pad1995] (Padmanabhan, V. and J. Mogul, “Improving HTTP Latency,” December 1995.) [Spe] (Spero, S., “Analysis of HTTP Performance Problems,” .). Implementation experience and measurements of actual HTTP/1.1 implementations show good results [Nie1997] (Nielsen, H., Gettys, J., Prud'hommeaux, E., Lie, H., and C. Lilley, “Network Performance Effects of HTTP/1.1, CSS1, and PNG,” September 1997.). Alternatives have also been explored, for example, T/TCP [Tou1998] (Touch, J., Heidemann, J., and K. Obraczka, “Analysis of HTTP Performance,” Aug 1998.).
Persistent HTTP connections have a number of advantages:
HTTP implementations SHOULD implement persistent connections.
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A significant difference between HTTP/1.1 and earlier versions of HTTP is that persistent connections are the default behavior of any HTTP connection. That is, unless otherwise indicated, the client SHOULD assume that the server will maintain a persistent connection, even after error responses from the server.
Persistent connections provide a mechanism by which a client and a server can signal the close of a TCP connection. This signaling takes place using the Connection header field (Section 9.1 (Connection)). Once a close has been signaled, the client MUST NOT send any more requests on that connection.
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An HTTP/1.1 server MAY assume that a HTTP/1.1 client intends to maintain a persistent connection unless a Connection header including the connection-token "close" was sent in the request. If the server chooses to close the connection immediately after sending the response, it SHOULD send a Connection header including the connection-token close.
An HTTP/1.1 client MAY expect a connection to remain open, but would decide to keep it open based on whether the response from a server contains a Connection header with the connection-token close. In case the client does not want to maintain a connection for more than that request, it SHOULD send a Connection header including the connection-token close.
If either the client or the server sends the close token in the Connection header, that request becomes the last one for the connection.
Clients and servers SHOULD NOT assume that a persistent connection is maintained for HTTP versions less than 1.1 unless it is explicitly signaled. See Appendix B.2 (Compatibility with HTTP/1.0 Persistent Connections) for more information on backward compatibility with HTTP/1.0 clients.
In order to remain persistent, all messages on the connection MUST have a self-defined message length (i.e., one not defined by closure of the connection), as described in Section 3.4 (Message Length).
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A client that supports persistent connections MAY "pipeline" its requests (i.e., send multiple requests without waiting for each response). A server MUST send its responses to those requests in the same order that the requests were received.
Clients which assume persistent connections and pipeline immediately after connection establishment SHOULD be prepared to retry their connection if the first pipelined attempt fails. If a client does such a retry, it MUST NOT pipeline before it knows the connection is persistent. Clients MUST also be prepared to resend their requests if the server closes the connection before sending all of the corresponding responses.
Clients SHOULD NOT pipeline requests using non-idempotent methods or non-idempotent sequences of methods (see Section 7.1.2 of [Part2] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 2: Message Semantics,” October 2009.)). Otherwise, a premature termination of the transport connection could lead to indeterminate results. A client wishing to send a non-idempotent request SHOULD wait to send that request until it has received the response status for the previous request.
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It is especially important that proxies correctly implement the properties of the Connection header field as specified in Section 9.1 (Connection).
The proxy server MUST signal persistent connections separately with its clients and the origin servers (or other proxy servers) that it connects to. Each persistent connection applies to only one transport link.
A proxy server MUST NOT establish a HTTP/1.1 persistent connection with an HTTP/1.0 client (but see Section 19.7.1 of [RFC2068] (Fielding, R., Gettys, J., Mogul, J., Nielsen, H., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” January 1997.) for information and discussion of the problems with the Keep-Alive header implemented by many HTTP/1.0 clients).
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Servers will usually have some time-out value beyond which they will no longer maintain an inactive connection. Proxy servers might make this a higher value since it is likely that the client will be making more connections through the same server. The use of persistent connections places no requirements on the length (or existence) of this time-out for either the client or the server.
When a client or server wishes to time-out it SHOULD issue a graceful close on the transport connection. Clients and servers SHOULD both constantly watch for the other side of the transport close, and respond to it as appropriate. If a client or server does not detect the other side's close promptly it could cause unnecessary resource drain on the network.
A client, server, or proxy MAY close the transport connection at any time. For example, a client might have started to send a new request at the same time that the server has decided to close the "idle" connection. From the server's point of view, the connection is being closed while it was idle, but from the client's point of view, a request is in progress.
This means that clients, servers, and proxies MUST be able to recover from asynchronous close events. Client software SHOULD reopen the transport connection and retransmit the aborted sequence of requests without user interaction so long as the request sequence is idempotent (see Section 7.1.2 of [Part2] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 2: Message Semantics,” October 2009.)). Non-idempotent methods or sequences MUST NOT be automatically retried, although user agents MAY offer a human operator the choice of retrying the request(s). Confirmation by user-agent software with semantic understanding of the application MAY substitute for user confirmation. The automatic retry SHOULD NOT be repeated if the second sequence of requests fails.
Servers SHOULD always respond to at least one request per connection, if at all possible. Servers SHOULD NOT close a connection in the middle of transmitting a response, unless a network or client failure is suspected.
Clients (including proxies) SHOULD limit the number of simultaneous connections that they maintain to a given server (including proxies).
Previous revisions of HTTP gave a specific number of connections as a ceiling, but this was found to be impractical for many applications. As a result, this specification does not mandate a particular maximum number of connections, but instead encourages clients to be conservative when opening multiple connections.
In particular, while using multiple connections avoids the "head-of-line blocking" problem (whereby a request that takes significant server-side processing and/or has a large payload can block subsequent requests on the same connection), each connection used consumes server resources (sometimes significantly), and furthermore using multiple connections can cause undesirable side effects in congested networks.
Note that servers might reject traffic that they deem abusive, including an excessive number of connections from a client.
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HTTP/1.1 servers SHOULD maintain persistent connections and use TCP's flow control mechanisms to resolve temporary overloads, rather than terminating connections with the expectation that clients will retry. The latter technique can exacerbate network congestion.
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An HTTP/1.1 (or later) client sending a message-body SHOULD monitor the network connection for an error status while it is transmitting the request. If the client sees an error status, it SHOULD immediately cease transmitting the body. If the body is being sent using a "chunked" encoding (Section 6.2 (Transfer Codings)), a zero length chunk and empty trailer MAY be used to prematurely mark the end of the message. If the body was preceded by a Content-Length header, the client MUST close the connection.
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The purpose of the 100 (Continue) status (see Section 8.1.1 of [Part2] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 2: Message Semantics,” October 2009.)) is to allow a client that is sending a request message with a request body to determine if the origin server is willing to accept the request (based on the request headers) before the client sends the request body. In some cases, it might either be inappropriate or highly inefficient for the client to send the body if the server will reject the message without looking at the body.
Requirements for HTTP/1.1 clients:
Because of the presence of older implementations, the protocol allows ambiguous situations in which a client may send "Expect: 100-continue" without receiving either a 417 (Expectation Failed) status or a 100 (Continue) status. Therefore, when a client sends this header field to an origin server (possibly via a proxy) from which it has never seen a 100 (Continue) status, the client SHOULD NOT wait for an indefinite period before sending the request body.
Requirements for HTTP/1.1 origin servers:
Requirements for HTTP/1.1 proxies:
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If an HTTP/1.1 client sends a request which includes a request body, but which does not include an Expect request-header field with the "100-continue" expectation, and if the client is not directly connected to an HTTP/1.1 origin server, and if the client sees the connection close before receiving any status from the server, the client SHOULD retry the request. If the client does retry this request, it MAY use the following "binary exponential backoff" algorithm to be assured of obtaining a reliable response:
If at any point an error status is received, the client
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[anchor2] (TBS: describe why aliases like webcal are harmful.)
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[anchor3] (TBD: Configured to use HTTP to proxy HTTP or other protocols.)
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[anchor4] (TBD: Interception of HTTP traffic for initiating access control.)
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[anchor5] (TBD: Profiles of HTTP defined by other protocol. Extensions of HTTP like WebDAV.)
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[anchor6] (TBD: Instructions on composing HTTP requests via hypertext formats.)
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This section defines the syntax and semantics of HTTP/1.1 header fields related to message framing and transport protocols.
For entity-header fields, both sender and recipient refer to either the client or the server, depending on who sends and who receives the entity.
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The "Connection" general-header field allows the sender to specify options that are desired for that particular connection and MUST NOT be communicated by proxies over further connections.
The Connection header's value has the following grammar:
Connection = "Connection" ":" OWS Connection-v Connection-v = 1#connection-token connection-token = token
HTTP/1.1 proxies MUST parse the Connection header field before a message is forwarded and, for each connection-token in this field, remove any header field(s) from the message with the same name as the connection-token. Connection options are signaled by the presence of a connection-token in the Connection header field, not by any corresponding additional header field(s), since the additional header field may not be sent if there are no parameters associated with that connection option.
Message headers listed in the Connection header MUST NOT include end-to-end headers, such as Cache-Control.
HTTP/1.1 defines the "close" connection option for the sender to signal that the connection will be closed after completion of the response. For example,
Connection: close
in either the request or the response header fields indicates that the connection SHOULD NOT be considered `persistent' (Section 7.1 (Persistent Connections)) after the current request/response is complete.
An HTTP/1.1 client that does not support persistent connections MUST include the "close" connection option in every request message.
An HTTP/1.1 server that does not support persistent connections MUST include the "close" connection option in every response message that does not have a 1xx (informational) status code.
A system receiving an HTTP/1.0 (or lower-version) message that includes a Connection header MUST, for each connection-token in this field, remove and ignore any header field(s) from the message with the same name as the connection-token. This protects against mistaken forwarding of such header fields by pre-HTTP/1.1 proxies. See Appendix B.2 (Compatibility with HTTP/1.0 Persistent Connections).
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The "Content-Length" entity-header field indicates the size of the entity-body, in number of OCTETs. In the case of responses to the HEAD method, it indicates the size of the entity-body that would have been sent had the request been a GET.
Content-Length = "Content-Length" ":" OWS 1*Content-Length-v Content-Length-v = 1*DIGIT
An example is
Content-Length: 3495
Applications SHOULD use this field to indicate the transfer-length of the message-body, unless this is prohibited by the rules in Section 3.4 (Message Length).
Any Content-Length greater than or equal to zero is a valid value. Section 3.4 (Message Length) describes how to determine the length of a message-body if a Content-Length is not given.
Note that the meaning of this field is significantly different from the corresponding definition in MIME, where it is an optional field used within the "message/external-body" content-type. In HTTP, it SHOULD be sent whenever the message's length can be determined prior to being transferred, unless this is prohibited by the rules in Section 3.4 (Message Length).
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The "Date" general-header field represents the date and time at which the message was originated, having the same semantics as orig-date in Section 3.6.1 of [RFC5322] (Resnick, P., “Internet Message Format,” October 2008.). The field value is an HTTP-date, as described in Section 6.1 (Date/Time Formats: Full Date); it MUST be sent in rfc1123-date format.
Date = "Date" ":" OWS Date-v Date-v = HTTP-date
An example is
Date: Tue, 15 Nov 1994 08:12:31 GMT
Origin servers MUST include a Date header field in all responses, except in these cases:
A received message that does not have a Date header field MUST be assigned one by the recipient if the message will be cached by that recipient or gatewayed via a protocol which requires a Date. An HTTP implementation without a clock MUST NOT cache responses without revalidating them on every use. An HTTP cache, especially a shared cache, SHOULD use a mechanism, such as NTP [RFC1305] (Mills, D., “Network Time Protocol (Version 3) Specification, Implementation,” March 1992.), to synchronize its clock with a reliable external standard.
Clients SHOULD only send a Date header field in messages that include an entity-body, as in the case of the PUT and POST requests, and even then it is optional. A client without a clock MUST NOT send a Date header field in a request.
The HTTP-date sent in a Date header SHOULD NOT represent a date and time subsequent to the generation of the message. It SHOULD represent the best available approximation of the date and time of message generation, unless the implementation has no means of generating a reasonably accurate date and time. In theory, the date ought to represent the moment just before the entity is generated. In practice, the date can be generated at any time during the message origination without affecting its semantic value.
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Some origin server implementations might not have a clock available. An origin server without a clock MUST NOT assign Expires or Last-Modified values to a response, unless these values were associated with the resource by a system or user with a reliable clock. It MAY assign an Expires value that is known, at or before server configuration time, to be in the past (this allows "pre-expiration" of responses without storing separate Expires values for each resource).
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The "Host" request-header field specifies the Internet host and port number of the resource being requested, allowing the origin server or gateway to differentiate between internally-ambiguous URLs, such as the root "/" URL of a server for multiple host names on a single IP address.
The Host field value MUST represent the naming authority of the origin server or gateway given by the original URL obtained from the user or referring resource (generally an http URI, as described in Section 2.6.1 (http URI scheme)).
Host = "Host" ":" OWS Host-v Host-v = uri-host [ ":" port ] ; Section 2.6.1
A "host" without any trailing port information implies the default port for the service requested (e.g., "80" for an HTTP URL). For example, a request on the origin server for <http://www.example.org/pub/WWW/> would properly include:
GET /pub/WWW/ HTTP/1.1 Host: www.example.org
A client MUST include a Host header field in all HTTP/1.1 request messages. If the requested URI does not include an Internet host name for the service being requested, then the Host header field MUST be given with an empty value. An HTTP/1.1 proxy MUST ensure that any request message it forwards does contain an appropriate Host header field that identifies the service being requested by the proxy. All Internet-based HTTP/1.1 servers MUST respond with a 400 (Bad Request) status code to any HTTP/1.1 request message which lacks a Host header field.
See Sections 4.2 (The Resource Identified by a Request) and B.1.1 (Changes to Simplify Multi-homed Web Servers and Conserve IP Addresses) for other requirements relating to Host.
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The "TE" request-header field indicates what extension transfer-codings it is willing to accept in the response, and whether or not it is willing to accept trailer fields in a chunked transfer-coding.
Its value may consist of the keyword "trailers" and/or a comma-separated list of extension transfer-coding names with optional accept parameters (as described in Section 6.2 (Transfer Codings)).
TE = "TE" ":" OWS TE-v TE-v = #t-codings t-codings = "trailers" / ( transfer-extension [ te-params ] ) te-params = OWS ";" OWS "q=" qvalue *( te-ext ) te-ext = OWS ";" OWS token [ "=" ( token / quoted-string ) ]
The presence of the keyword "trailers" indicates that the client is willing to accept trailer fields in a chunked transfer-coding, as defined in Section 6.2.1 (Chunked Transfer Coding). This keyword is reserved for use with transfer-coding values even though it does not itself represent a transfer-coding.
Examples of its use are:
TE: deflate TE: TE: trailers, deflate;q=0.5
The TE header field only applies to the immediate connection. Therefore, the keyword MUST be supplied within a Connection header field (Section 9.1 (Connection)) whenever TE is present in an HTTP/1.1 message.
A server tests whether a transfer-coding is acceptable, according to a TE field, using these rules:
If the TE field-value is empty or if no TE field is present, the only transfer-coding is "chunked". A message with no transfer-coding is always acceptable.
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The "Trailer" general-header field indicates that the given set of header fields is present in the trailer of a message encoded with chunked transfer-coding.
Trailer = "Trailer" ":" OWS Trailer-v Trailer-v = 1#field-name
An HTTP/1.1 message SHOULD include a Trailer header field in a message using chunked transfer-coding with a non-empty trailer. Doing so allows the recipient to know which header fields to expect in the trailer.
If no Trailer header field is present, the trailer SHOULD NOT include any header fields. See Section 6.2.1 (Chunked Transfer Coding) for restrictions on the use of trailer fields in a "chunked" transfer-coding.
Message header fields listed in the Trailer header field MUST NOT include the following header fields:
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The "Transfer-Encoding" general-header field indicates what transfer-codings (if any) have been applied to the message body. It differs from Content-Encoding (Section 2.2 of [Part3] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 3: Message Payload and Content Negotiation,” October 2009.)) in that transfer-codings are a property of the message (and therefore are removed by intermediaries), whereas content-codings are not.
Transfer-Encoding = "Transfer-Encoding" ":" OWS Transfer-Encoding-v Transfer-Encoding-v = 1#transfer-coding
Transfer-codings are defined in Section 6.2 (Transfer Codings). An example is:
Transfer-Encoding: chunked
If multiple encodings have been applied to an entity, the transfer-codings MUST be listed in the order in which they were applied. Additional information about the encoding parameters MAY be provided by other entity-header fields not defined by this specification.
Many older HTTP/1.0 applications do not understand the Transfer-Encoding header.
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The "Upgrade" general-header field allows the client to specify what additional communication protocols it would like to use, if the server chooses to switch protocols. Additionally, the server MUST use the Upgrade header field within a 101 (Switching Protocols) response to indicate which protocol(s) are being switched to.
Upgrade = "Upgrade" ":" OWS Upgrade-v Upgrade-v = 1#product
For example,
Upgrade: HTTP/2.0, SHTTP/1.3, IRC/6.9, RTA/x11
The Upgrade header field is intended to provide a simple mechanism for transition from HTTP/1.1 to some other, incompatible protocol. It does so by allowing the client to advertise its desire to use another protocol, such as a later version of HTTP with a higher major version number, even though the current request has been made using HTTP/1.1. This eases the difficult transition between incompatible protocols by allowing the client to initiate a request in the more commonly supported protocol while indicating to the server that it would like to use a "better" protocol if available (where "better" is determined by the server, possibly according to the nature of the method and/or resource being requested).
The Upgrade header field only applies to switching application-layer protocols upon the existing transport-layer connection. Upgrade cannot be used to insist on a protocol change; its acceptance and use by the server is optional. The capabilities and nature of the application-layer communication after the protocol change is entirely dependent upon the new protocol chosen, although the first action after changing the protocol MUST be a response to the initial HTTP request containing the Upgrade header field.
The Upgrade header field only applies to the immediate connection. Therefore, the upgrade keyword MUST be supplied within a Connection header field (Section 9.1 (Connection)) whenever Upgrade is present in an HTTP/1.1 message.
The Upgrade header field cannot be used to indicate a switch to a protocol on a different connection. For that purpose, it is more appropriate to use a 301, 302, 303, or 305 redirection response.
This specification only defines the protocol name "HTTP" for use by the family of Hypertext Transfer Protocols, as defined by the HTTP version rules of Section 2.5 (HTTP Version) and future updates to this specification. Additional tokens can be registered with IANA using the registration procedure defined below.
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The HTTP Upgrade Token Registry defines the name space for product tokens used to identify protocols in the Upgrade header field. Each registered token should be associated with one or a set of specifications, and with contact information.
Registrations should be allowed on a First Come First Served basis as described in Section 4.1 of [RFC5226] (Narten, T. and H. Alvestrand, “Guidelines for Writing an IANA Considerations Section in RFCs,” May 2008.). These specifications need not be IETF documents or be subject to IESG review, but should obey the following rules:
It is not required that specifications for upgrade tokens be made publicly available, but the contact information for the registration should be.
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The "Via" general-header field MUST be used by gateways and proxies to indicate the intermediate protocols and recipients between the user agent and the server on requests, and between the origin server and the client on responses. It is analogous to the "Received" field defined in Section 3.6.7 of [RFC5322] (Resnick, P., “Internet Message Format,” October 2008.) and is intended to be used for tracking message forwards, avoiding request loops, and identifying the protocol capabilities of all senders along the request/response chain.
Via = "Via" ":" OWS Via-v Via-v = 1#( received-protocol RWS received-by [ RWS comment ] ) received-protocol = [ protocol-name "/" ] protocol-version protocol-name = token protocol-version = token received-by = ( uri-host [ ":" port ] ) / pseudonym pseudonym = token
The received-protocol indicates the protocol version of the message received by the server or client along each segment of the request/response chain. The received-protocol version is appended to the Via field value when the message is forwarded so that information about the protocol capabilities of upstream applications remains visible to all recipients.
The protocol-name is optional if and only if it would be "HTTP". The received-by field is normally the host and optional port number of a recipient server or client that subsequently forwarded the message. However, if the real host is considered to be sensitive information, it MAY be replaced by a pseudonym. If the port is not given, it MAY be assumed to be the default port of the received-protocol.
Multiple Via field values represents each proxy or gateway that has forwarded the message. Each recipient MUST append its information such that the end result is ordered according to the sequence of forwarding applications.
Comments MAY be used in the Via header field to identify the software of the recipient proxy or gateway, analogous to the User-Agent and Server header fields. However, all comments in the Via field are optional and MAY be removed by any recipient prior to forwarding the message.
For example, a request message could be sent from an HTTP/1.0 user agent to an internal proxy code-named "fred", which uses HTTP/1.1 to forward the request to a public proxy at p.example.net, which completes the request by forwarding it to the origin server at www.example.com. The request received by www.example.com would then have the following Via header field:
Via: 1.0 fred, 1.1 p.example.net (Apache/1.1)
Proxies and gateways used as a portal through a network firewall SHOULD NOT, by default, forward the names and ports of hosts within the firewall region. This information SHOULD only be propagated if explicitly enabled. If not enabled, the received-by host of any host behind the firewall SHOULD be replaced by an appropriate pseudonym for that host.
For organizations that have strong privacy requirements for hiding internal structures, a proxy MAY combine an ordered subsequence of Via header field entries with identical received-protocol values into a single such entry. For example,
Via: 1.0 ricky, 1.1 ethel, 1.1 fred, 1.0 lucy
could be collapsed to
Via: 1.0 ricky, 1.1 mertz, 1.0 lucy
Applications SHOULD NOT combine multiple entries unless they are all under the same organizational control and the hosts have already been replaced by pseudonyms. Applications MUST NOT combine entries which have different received-protocol values.
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The Message Header Registry located at http://www.iana.org/assignments/message-headers/message-header-index.html should be updated with the permanent registrations below (see [RFC3864] (Klyne, G., Nottingham, M., and J. Mogul, “Registration Procedures for Message Header Fields,” September 2004.)):
Header Field Name | Protocol | Status | Reference |
---|---|---|---|
Connection | http | standard | Section 9.1 (Connection) |
Content-Length | http | standard | Section 9.2 (Content-Length) |
Date | http | standard | Section 9.3 (Date) |
Host | http | standard | Section 9.4 (Host) |
TE | http | standard | Section 9.5 (TE) |
Trailer | http | standard | Section 9.6 (Trailer) |
Transfer-Encoding | http | standard | Section 9.7 (Transfer-Encoding) |
Upgrade | http | standard | Section 9.8 (Upgrade) |
Via | http | standard | Section 9.9 (Via) |
The change controller is: "IETF (iesg@ietf.org) - Internet Engineering Task Force".
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The entries for the "http" and "https" URI Schemes in the registry located at http://www.iana.org/assignments/uri-schemes.html should be updated to point to Sections 2.6.1 (http URI scheme) and 2.6.2 (https URI scheme) of this document (see [RFC4395] (Hansen, T., Hardie, T., and L. Masinter, “Guidelines and Registration Procedures for New URI Schemes,” February 2006.)).
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This document serves as the specification for the Internet media types "message/http" and "application/http". The following is to be registered with IANA (see [RFC4288] (Freed, N. and J. Klensin, “Media Type Specifications and Registration Procedures,” December 2005.)).
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The message/http type can be used to enclose a single HTTP request or response message, provided that it obeys the MIME restrictions for all "message" types regarding line length and encodings.
- Type name:
- message
- Subtype name:
- http
- Required parameters:
- none
- Optional parameters:
- version, msgtype
- version:
- The HTTP-Version number of the enclosed message (e.g., "1.1"). If not present, the version can be determined from the first line of the body.
- msgtype:
- The message type -- "request" or "response". If not present, the type can be determined from the first line of the body.
- Encoding considerations:
- only "7bit", "8bit", or "binary" are permitted
- Security considerations:
- none
- Interoperability considerations:
- none
- Published specification:
- This specification (see Section 10.3.1 (Internet Media Type message/http)).
- Applications that use this media type:
- Additional information:
- Magic number(s):
- none
- File extension(s):
- none
- Macintosh file type code(s):
- none
- Person and email address to contact for further information:
- See Authors Section.
- Intended usage:
- COMMON
- Restrictions on usage:
- none
- Author/Change controller:
- IESG
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The application/http type can be used to enclose a pipeline of one or more HTTP request or response messages (not intermixed).
- Type name:
- application
- Subtype name:
- http
- Required parameters:
- none
- Optional parameters:
- version, msgtype
- version:
- The HTTP-Version number of the enclosed messages (e.g., "1.1"). If not present, the version can be determined from the first line of the body.
- msgtype:
- The message type -- "request" or "response". If not present, the type can be determined from the first line of the body.
- Encoding considerations:
- HTTP messages enclosed by this type are in "binary" format; use of an appropriate Content-Transfer-Encoding is required when transmitted via E-mail.
- Security considerations:
- none
- Interoperability considerations:
- none
- Published specification:
- This specification (see Section 10.3.2 (Internet Media Type application/http)).
- Applications that use this media type:
- Additional information:
- Magic number(s):
- none
- File extension(s):
- none
- Macintosh file type code(s):
- none
- Person and email address to contact for further information:
- See Authors Section.
- Intended usage:
- COMMON
- Restrictions on usage:
- none
- Author/Change controller:
- IESG
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The registration procedure for HTTP Transfer Codings is now defined by Section 6.2.3 (Transfer Coding Registry) of this document.
The HTTP Transfer Codings Registry located at http://www.iana.org/assignments/http-parameters should be updated with the registrations below:
Name | Description | Reference |
---|---|---|
chunked | Transfer in a series of chunks | Section 6.2.1 (Chunked Transfer Coding) |
compress | UNIX "compress" program method | Section 6.2.2.1 (Compress Coding) |
deflate | "zlib" format [RFC1950] (Deutsch, L. and J-L. Gailly, “ZLIB Compressed Data Format Specification version 3.3,” May 1996.) with "deflate" compression | Section 6.2.2.2 (Deflate Coding) |
gzip | Same as GNU zip [RFC1952] (Deutsch, P., Gailly, J-L., Adler, M., Deutsch, L., and G. Randers-Pehrson, “GZIP file format specification version 4.3,” May 1996.) | Section 6.2.2.3 (Gzip Coding) |
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The registration procedure for HTTP Upgrade Tokens -- previously defined in Section 7.2 of [RFC2817] (Khare, R. and S. Lawrence, “Upgrading to TLS Within HTTP/1.1,” May 2000.) -- is now defined by Section 9.8.1 (Upgrade Token Registry) of this document.
The HTTP Status Code Registry located at http://www.iana.org/assignments/http-upgrade-tokens/ should be updated with the registration below:
Value | Description | Reference |
---|---|---|
HTTP | Hypertext Transfer Protocol | Section 2.5 (HTTP Version) of this specification |
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This section is meant to inform application developers, information providers, and users of the security limitations in HTTP/1.1 as described by this document. The discussion does not include definitive solutions to the problems revealed, though it does make some suggestions for reducing security risks.
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HTTP clients are often privy to large amounts of personal information (e.g. the user's name, location, mail address, passwords, encryption keys, etc.), and SHOULD be very careful to prevent unintentional leakage of this information. We very strongly recommend that a convenient interface be provided for the user to control dissemination of such information, and that designers and implementors be particularly careful in this area. History shows that errors in this area often create serious security and/or privacy problems and generate highly adverse publicity for the implementor's company.
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A server is in the position to save personal data about a user's requests which might identify their reading patterns or subjects of interest. This information is clearly confidential in nature and its handling can be constrained by law in certain countries. People using HTTP to provide data are responsible for ensuring that such material is not distributed without the permission of any individuals that are identifiable by the published results.
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Implementations of HTTP origin servers SHOULD be careful to restrict the documents returned by HTTP requests to be only those that were intended by the server administrators. If an HTTP server translates HTTP URIs directly into file system calls, the server MUST take special care not to serve files that were not intended to be delivered to HTTP clients. For example, UNIX, Microsoft Windows, and other operating systems use ".." as a path component to indicate a directory level above the current one. On such a system, an HTTP server MUST disallow any such construct in the request-target if it would otherwise allow access to a resource outside those intended to be accessible via the HTTP server. Similarly, files intended for reference only internally to the server (such as access control files, configuration files, and script code) MUST be protected from inappropriate retrieval, since they might contain sensitive information. Experience has shown that minor bugs in such HTTP server implementations have turned into security risks.
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Clients using HTTP rely heavily on the Domain Name Service, and are thus generally prone to security attacks based on the deliberate mis-association of IP addresses and DNS names. Clients need to be cautious in assuming the continuing validity of an IP number/DNS name association.
In particular, HTTP clients SHOULD rely on their name resolver for confirmation of an IP number/DNS name association, rather than caching the result of previous host name lookups. Many platforms already can cache host name lookups locally when appropriate, and they SHOULD be configured to do so. It is proper for these lookups to be cached, however, only when the TTL (Time To Live) information reported by the name server makes it likely that the cached information will remain useful.
If HTTP clients cache the results of host name lookups in order to achieve a performance improvement, they MUST observe the TTL information reported by DNS.
If HTTP clients do not observe this rule, they could be spoofed when a previously-accessed server's IP address changes. As network renumbering is expected to become increasingly common [RFC1900] (Carpenter, B. and Y. Rekhter, “Renumbering Needs Work,” February 1996.), the possibility of this form of attack will grow. Observing this requirement thus reduces this potential security vulnerability.
This requirement also improves the load-balancing behavior of clients for replicated servers using the same DNS name and reduces the likelihood of a user's experiencing failure in accessing sites which use that strategy.
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By their very nature, HTTP proxies are men-in-the-middle, and represent an opportunity for man-in-the-middle attacks. Compromise of the systems on which the proxies run can result in serious security and privacy problems. Proxies have access to security-related information, personal information about individual users and organizations, and proprietary information belonging to users and content providers. A compromised proxy, or a proxy implemented or configured without regard to security and privacy considerations, might be used in the commission of a wide range of potential attacks.
Proxy operators should protect the systems on which proxies run as they would protect any system that contains or transports sensitive information. In particular, log information gathered at proxies often contains highly sensitive personal information, and/or information about organizations. Log information should be carefully guarded, and appropriate guidelines for use developed and followed. (Section 11.2 (Abuse of Server Log Information)).
Proxy implementors should consider the privacy and security implications of their design and coding decisions, and of the configuration options they provide to proxy operators (especially the default configuration).
Users of a proxy need to be aware that they are no trustworthier than the people who run the proxy; HTTP itself cannot solve this problem.
The judicious use of cryptography, when appropriate, may suffice to protect against a broad range of security and privacy attacks. Such cryptography is beyond the scope of the HTTP/1.1 specification.
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They exist. They are hard to defend against. Research continues. Beware.
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HTTP has evolved considerably over the years. It has benefited from a large and active developer community--the many people who have participated on the www-talk mailing list--and it is that community which has been most responsible for the success of HTTP and of the World-Wide Web in general. Marc Andreessen, Robert Cailliau, Daniel W. Connolly, Bob Denny, John Franks, Jean-Francois Groff, Phillip M. Hallam-Baker, Hakon W. Lie, Ari Luotonen, Rob McCool, Lou Montulli, Dave Raggett, Tony Sanders, and Marc VanHeyningen deserve special recognition for their efforts in defining early aspects of the protocol.
This document has benefited greatly from the comments of all those participating in the HTTP-WG. In addition to those already mentioned, the following individuals have contributed to this specification:
Gary Adams, Harald Tveit Alvestrand, Keith Ball, Brian Behlendorf, Paul Burchard, Maurizio Codogno, Mike Cowlishaw, Roman Czyborra, Michael A. Dolan, Daniel DuBois, David J. Fiander, Alan Freier, Marc Hedlund, Greg Herlihy, Koen Holtman, Alex Hopmann, Bob Jernigan, Shel Kaphan, Rohit Khare, John Klensin, Martijn Koster, Alexei Kosut, David M. Kristol, Daniel LaLiberte, Ben Laurie, Paul J. Leach, Albert Lunde, John C. Mallery, Jean-Philippe Martin-Flatin, Mitra, David Morris, Gavin Nicol, Ross Patterson, Bill Perry, Jeffrey Perry, Scott Powers, Owen Rees, Luigi Rizzo, David Robinson, Marc Salomon, Rich Salz, Allan M. Schiffman, Jim Seidman, Chuck Shotton, Eric W. Sink, Simon E. Spero, Richard N. Taylor, Robert S. Thau, Bill (BearHeart) Weinman, Francois Yergeau, Mary Ellen Zurko, Josh Cohen.
Thanks to the "cave men" of Palo Alto. You know who you are.
Jim Gettys (the editor of [RFC2616] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.)) wishes particularly to thank Roy Fielding, the editor of [RFC2068] (Fielding, R., Gettys, J., Mogul, J., Nielsen, H., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” January 1997.), along with John Klensin, Jeff Mogul, Paul Leach, Dave Kristol, Koen Holtman, John Franks, Josh Cohen, Alex Hopmann, Scott Lawrence, and Larry Masinter for their help. And thanks go particularly to Jeff Mogul and Scott Lawrence for performing the "MUST/MAY/SHOULD" audit.
The Apache Group, Anselm Baird-Smith, author of Jigsaw, and Henrik Frystyk implemented RFC 2068 early, and we wish to thank them for the discovery of many of the problems that this document attempts to rectify.
This specification makes heavy use of the augmented BNF and generic constructs defined by David H. Crocker for [RFC5234] (Crocker, D., Ed. and P. Overell, “Augmented BNF for Syntax Specifications: ABNF,” January 2008.). Similarly, it reuses many of the definitions provided by Nathaniel Borenstein and Ned Freed for MIME [RFC2045] (Freed, N. and N. Borenstein, “Multipurpose Internet Mail Extensions (MIME) Part One: Format of Internet Message Bodies,” November 1996.). We hope that their inclusion in this specification will help reduce past confusion over the relationship between HTTP and Internet mail message formats.
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Although this document specifies the requirements for the generation of HTTP/1.1 messages, not all applications will be correct in their implementation. We therefore recommend that operational applications be tolerant of deviations whenever those deviations can be interpreted unambiguously.
Clients SHOULD be tolerant in parsing the Status-Line and servers tolerant when parsing the Request-Line. In particular, they SHOULD accept any amount of WSP characters between fields, even though only a single SP is required.
The line terminator for header fields is the sequence CRLF. However, we recommend that applications, when parsing such headers, recognize a single LF as a line terminator and ignore the leading CR.
The character set of an entity-body SHOULD be labeled as the lowest common denominator of the character codes used within that body, with the exception that not labeling the entity is preferred over labeling the entity with the labels US-ASCII or ISO-8859-1. See [Part3] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 3: Message Payload and Content Negotiation,” October 2009.).
Additional rules for requirements on parsing and encoding of dates and other potential problems with date encodings include:
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HTTP has been in use by the World-Wide Web global information initiative since 1990. The first version of HTTP, later referred to as HTTP/0.9, was a simple protocol for hypertext data transfer across the Internet with only a single method and no metadata. HTTP/1.0, as defined by [RFC1945] (Berners-Lee, T., Fielding, R., and H. Nielsen, “Hypertext Transfer Protocol -- HTTP/1.0,” May 1996.), added a range of request methods and MIME-like messaging that could include metadata about the data transferred and modifiers on the request/response semantics. However, HTTP/1.0 did not sufficiently take into consideration the effects of hierarchical proxies, caching, the need for persistent connections, or name-based virtual hosts. The proliferation of incompletely-implemented applications calling themselves "HTTP/1.0" further necessitated a protocol version change in order for two communicating applications to determine each other's true capabilities.
HTTP/1.1 remains compatible with HTTP/1.0 by including more stringent requirements that enable reliable implementations, adding only those new features that will either be safely ignored by an HTTP/1.0 recipient or only sent when communicating with a party advertising compliance with HTTP/1.1.
It is beyond the scope of a protocol specification to mandate compliance with previous versions. HTTP/1.1 was deliberately designed, however, to make supporting previous versions easy. It is worth noting that, at the time of composing this specification, we would expect general-purpose HTTP/1.1 servers to:
And we would expect HTTP/1.1 clients to:
For most implementations of HTTP/1.0, each connection is established by the client prior to the request and closed by the server after sending the response. Some implementations implement the Keep-Alive version of persistent connections described in Section 19.7.1 of [RFC2068] (Fielding, R., Gettys, J., Mogul, J., Nielsen, H., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” January 1997.).
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This section summarizes major differences between versions HTTP/1.0 and HTTP/1.1.
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The requirements that clients and servers support the Host request-header, report an error if the Host request-header (Section 9.4 (Host)) is missing from an HTTP/1.1 request, and accept absolute URIs (Section 4.1.2 (request-target)) are among the most important changes defined by this specification.
Older HTTP/1.0 clients assumed a one-to-one relationship of IP addresses and servers; there was no other established mechanism for distinguishing the intended server of a request than the IP address to which that request was directed. The changes outlined above will allow the Internet, once older HTTP clients are no longer common, to support multiple Web sites from a single IP address, greatly simplifying large operational Web servers, where allocation of many IP addresses to a single host has created serious problems. The Internet will also be able to recover the IP addresses that have been allocated for the sole purpose of allowing special-purpose domain names to be used in root-level HTTP URLs. Given the rate of growth of the Web, and the number of servers already deployed, it is extremely important that all implementations of HTTP (including updates to existing HTTP/1.0 applications) correctly implement these requirements:
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Some clients and servers might wish to be compatible with some previous implementations of persistent connections in HTTP/1.0 clients and servers. Persistent connections in HTTP/1.0 are explicitly negotiated as they are not the default behavior. HTTP/1.0 experimental implementations of persistent connections are faulty, and the new facilities in HTTP/1.1 are designed to rectify these problems. The problem was that some existing 1.0 clients may be sending Keep-Alive to a proxy server that doesn't understand Connection, which would then erroneously forward it to the next inbound server, which would establish the Keep-Alive connection and result in a hung HTTP/1.0 proxy waiting for the close on the response. The result is that HTTP/1.0 clients must be prevented from using Keep-Alive when talking to proxies.
However, talking to proxies is the most important use of persistent connections, so that prohibition is clearly unacceptable. Therefore, we need some other mechanism for indicating a persistent connection is desired, which is safe to use even when talking to an old proxy that ignores Connection. Persistent connections are the default for HTTP/1.1 messages; we introduce a new keyword (Connection: close) for declaring non-persistence. See Section 9.1 (Connection).
The original HTTP/1.0 form of persistent connections (the Connection: Keep-Alive and Keep-Alive header) is documented in Section 19.7.1 of [RFC2068] (Fielding, R., Gettys, J., Mogul, J., Nielsen, H., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” January 1997.).
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This specification has been carefully audited to correct and disambiguate key word usage; RFC 2068 had many problems in respect to the conventions laid out in [RFC2119] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” March 1997.).
Transfer-coding and message lengths all interact in ways that required fixing exactly when chunked encoding is used (to allow for transfer encoding that may not be self delimiting); it was important to straighten out exactly how message lengths are computed. (Sections 6.2 (Transfer Codings), 3.4 (Message Length), 9.2 (Content-Length), see also [Part3] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 3: Message Payload and Content Negotiation,” October 2009.), [Part5] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., and J. Reschke, Ed., “HTTP/1.1, part 5: Range Requests and Partial Responses,” October 2009.) and [Part6] (Fielding, R., Ed., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., Berners-Lee, T., Lafon, Y., Ed., Nottingham, M., Ed., and J. Reschke, Ed., “HTTP/1.1, part 6: Caching,” October 2009.))
The use and interpretation of HTTP version numbers has been clarified by [RFC2145] (Mogul, J., Fielding, R., Gettys, J., and H. Nielsen, “Use and Interpretation of HTTP Version Numbers,” May 1997.). Require proxies to upgrade requests to highest protocol version they support to deal with problems discovered in HTTP/1.0 implementations (Section 2.5 (HTTP Version))
Quality Values of zero should indicate that "I don't want something" to allow clients to refuse a representation. (Section 6.4 (Quality Values))
Transfer-coding had significant problems, particularly with interactions with chunked encoding. The solution is that transfer-codings become as full fledged as content-codings. This involves adding an IANA registry for transfer-codings (separate from content codings), a new header field (TE) and enabling trailer headers in the future. Transfer encoding is a major performance benefit, so it was worth fixing [Nie1997] (Nielsen, H., Gettys, J., Prud'hommeaux, E., Lie, H., and C. Lilley, “Network Performance Effects of HTTP/1.1, CSS1, and PNG,” September 1997.). TE also solves another, obscure, downward interoperability problem that could have occurred due to interactions between authentication trailers, chunked encoding and HTTP/1.0 clients.(Section 6.2 (Transfer Codings), 6.2.1 (Chunked Transfer Coding), and 9.5 (TE))
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Empty list elements in list productions have been deprecated. (Section 1.2.1 (ABNF Extension: #rule))
Rules about implicit linear whitespace between certain grammar productions have been removed; now it's only allowed when specifically pointed out in the ABNF. The NUL character is no longer allowed in comment and quoted-string text. The quoted-pair rule no longer allows escaping control characters other than HTAB. Non-ASCII content in header fields and reason phrase has been obsoleted and made opaque (the TEXT rule was removed) (Section 1.2.2 (Basic Rules))
Clarify that HTTP-Version is case sensitive. (Section 2.5 (HTTP Version))
Remove reference to non-existant identity transfer-coding value tokens. (Sections 6.2 (Transfer Codings) and 3.4 (Message Length))
Require that invalid whitespace around field-names be rejected. (Section 3.2 (Header Fields))
Update use of abs_path production from RFC1808 to the path-absolute + query components of RFC3986. (Section 4.1.2 (request-target))
Clarification that the chunk length does not include the count of the octets in the chunk header and trailer. Furthermore disallowed line folding in chunk extensions. (Section 6.2.1 (Chunked Transfer Coding))
Remove hard limit of two connections per server. (Section 7.1.4 (Practical Considerations))
Clarify exactly when close connection options must be sent. (Section 9.1 (Connection))
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BWS = OWS Cache-Control = <Cache-Control, defined in [Part6], Section 3.4> Chunked-Body = *chunk last-chunk trailer-part CRLF Connection = "Connection:" OWS Connection-v Connection-v = *( "," OWS ) connection-token *( OWS "," [ OWS connection-token ] ) Content-Length = "Content-Length:" OWS 1*Content-Length-v Content-Length-v = 1*DIGIT Date = "Date:" OWS Date-v Date-v = HTTP-date GMT = %x47.4D.54 ; GMT HTTP-Prot-Name = %x48.54.54.50 ; HTTP HTTP-Version = HTTP-Prot-Name "/" 1*DIGIT "." 1*DIGIT HTTP-date = rfc1123-date / obs-date HTTP-message = start-line *( header-field CRLF ) CRLF [ message-body ] Host = "Host:" OWS Host-v Host-v = uri-host [ ":" port ] Method = token OWS = *( [ obs-fold ] WSP ) Pragma = <Pragma, defined in [Part6], Section 3.4> RWS = 1*( [ obs-fold ] WSP ) Reason-Phrase = *( WSP / VCHAR / obs-text ) Request = Request-Line *( ( general-header / request-header / entity-header ) CRLF ) CRLF [ message-body ] Request-Line = Method SP request-target SP HTTP-Version CRLF Response = Status-Line *( ( general-header / response-header / entity-header ) CRLF ) CRLF [ message-body ] Status-Code = 3DIGIT Status-Line = HTTP-Version SP Status-Code SP Reason-Phrase CRLF TE = "TE:" OWS TE-v TE-v = [ ( "," / t-codings ) *( OWS "," [ OWS t-codings ] ) ] Trailer = "Trailer:" OWS Trailer-v Trailer-v = *( "," OWS ) field-name *( OWS "," [ OWS field-name ] ) Transfer-Encoding = "Transfer-Encoding:" OWS Transfer-Encoding-v Transfer-Encoding-v = *( "," OWS ) transfer-coding *( OWS "," [ OWS transfer-coding ] ) URI = <URI, defined in [RFC3986], Section 3> URI-reference = <URI-reference, defined in [RFC3986], Section 4.1> Upgrade = "Upgrade:" OWS Upgrade-v Upgrade-v = *( "," OWS ) product *( OWS "," [ OWS product ] ) Via = "Via:" OWS Via-v Via-v = *( "," OWS ) received-protocol RWS received-by [ RWS comment ] *( OWS "," [ OWS received-protocol RWS received-by [ RWS comment ] ] ) Warning = <Warning, defined in [Part6], Section 3.6> absolute-URI = <absolute-URI, defined in [RFC3986], Section 4.3> asctime-date = day-name SP date3 SP time-of-day SP year attribute = token authority = <authority, defined in [RFC3986], Section 3.2> chunk = chunk-size *WSP [ chunk-ext ] CRLF chunk-data CRLF chunk-data = 1*OCTET chunk-ext = *( ";" *WSP chunk-ext-name [ "=" chunk-ext-val ] *WSP ) chunk-ext-name = token chunk-ext-val = token / quoted-str-nf chunk-size = 1*HEXDIG comment = "(" *( ctext / quoted-cpair / comment ) ")" connection-token = token ctext = OWS / %x21-27 ; '!'-''' / %x2A-5B ; '*'-'[' / %x5D-7E ; ']'-'~' / obs-text date1 = day SP month SP year date2 = day "-" month "-" 2DIGIT date3 = month SP ( 2DIGIT / ( SP DIGIT ) ) day = 2DIGIT day-name = %x4D.6F.6E ; Mon / %x54.75.65 ; Tue / %x57.65.64 ; Wed / %x54.68.75 ; Thu / %x46.72.69 ; Fri / %x53.61.74 ; Sat / %x53.75.6E ; Sun day-name-l = %x4D.6F.6E.64.61.79 ; Monday / %x54.75.65.73.64.61.79 ; Tuesday / %x57.65.64.6E.65.73.64.61.79 ; Wednesday / %x54.68.75.72.73.64.61.79 ; Thursday / %x46.72.69.64.61.79 ; Friday / %x53.61.74.75.72.64.61.79 ; Saturday / %x53.75.6E.64.61.79 ; Sunday entity-body = <entity-body, defined in [Part3], Section 3.2> entity-header = <entity-header, defined in [Part3], Section 3.1> field-content = *( WSP / VCHAR / obs-text ) field-name = token field-value = *( field-content / OWS ) general-header = Cache-Control / Connection / Date / Pragma / Trailer / Transfer-Encoding / Upgrade / Via / Warning header-field = field-name ":" OWS [ field-value ] OWS hour = 2DIGIT http-URI = "http://" authority path-abempty [ "?" query ] https-URI = "https://" authority path-abempty [ "?" query ] last-chunk = 1*"0" *WSP [ chunk-ext ] CRLF message-body = entity-body / <entity-body encoded as per Transfer-Encoding> minute = 2DIGIT month = %x4A.61.6E ; Jan / %x46.65.62 ; Feb / %x4D.61.72 ; Mar / %x41.70.72 ; Apr / %x4D.61.79 ; May / %x4A.75.6E ; Jun / %x4A.75.6C ; Jul / %x41.75.67 ; Aug / %x53.65.70 ; Sep / %x4F.63.74 ; Oct / %x4E.6F.76 ; Nov / %x44.65.63 ; Dec obs-date = rfc850-date / asctime-date obs-fold = CRLF obs-text = %x80-FF partial-URI = relative-part [ "?" query ] path-abempty = <path-abempty, defined in [RFC3986], Section 3.3> path-absolute = <path-absolute, defined in [RFC3986], Section 3.3> port = <port, defined in [RFC3986], Section 3.2.3> product = token [ "/" product-version ] product-version = token protocol-name = token protocol-version = token pseudonym = token qdtext = OWS / "!" / %x23-5B ; '#'-'[' / %x5D-7E ; ']'-'~' / obs-text qdtext-nf = WSP / "!" / %x23-5B ; '#'-'[' / %x5D-7E ; ']'-'~' / obs-text query = <query, defined in [RFC3986], Section 3.4> quoted-cpair = "\" ( WSP / VCHAR / obs-text ) quoted-pair = "\" ( WSP / VCHAR / obs-text ) quoted-str-nf = DQUOTE *( qdtext-nf / quoted-pair ) DQUOTE quoted-string = DQUOTE *( qdtext / quoted-pair ) DQUOTE qvalue = ( "0" [ "." *3DIGIT ] ) / ( "1" [ "." *3"0" ] ) received-by = ( uri-host [ ":" port ] ) / pseudonym received-protocol = [ protocol-name "/" ] protocol-version relative-part = <relative-part, defined in [RFC3986], Section 4.2> request-header = <request-header, defined in [Part2], Section 3> request-target = "*" / absolute-URI / ( path-absolute [ "?" query ] ) / authority response-header = <response-header, defined in [Part2], Section 5> rfc1123-date = day-name "," SP date1 SP time-of-day SP GMT rfc850-date = day-name-l "," SP date2 SP time-of-day SP GMT second = 2DIGIT start-line = Request-Line / Status-Line t-codings = "trailers" / ( transfer-extension [ te-params ] ) tchar = "!" / "#" / "$" / "%" / "&" / "'" / "*" / "+" / "-" / "." / "^" / "_" / "`" / "|" / "~" / DIGIT / ALPHA te-ext = OWS ";" OWS token [ "=" ( token / quoted-string ) ] te-params = OWS ";" OWS "q=" qvalue *te-ext time-of-day = hour ":" minute ":" second token = 1*tchar trailer-part = *( entity-header CRLF ) transfer-coding = "chunked" / "compress" / "deflate" / "gzip" / transfer-extension transfer-extension = token *( OWS ";" OWS transfer-parameter ) transfer-parameter = attribute BWS "=" BWS value uri-host = <host, defined in [RFC3986], Section 3.2.2> value = token / quoted-string year = 4DIGIT
ABNF diagnostics:
; Chunked-Body defined but not used ; Content-Length defined but not used ; HTTP-message defined but not used ; Host defined but not used ; Request defined but not used ; Response defined but not used ; TE defined but not used ; URI defined but not used ; URI-reference defined but not used ; http-URI defined but not used ; https-URI defined but not used ; partial-URI defined but not used
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Extracted relevant partitions from [RFC2616] (Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L., Leach, P., and T. Berners-Lee, “Hypertext Transfer Protocol -- HTTP/1.1,” June 1999.).
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Closed issues:
Other changes:
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Closed issues:
Ongoing work on ABNF conversion (http://tools.ietf.org/wg/httpbis/trac/ticket/36):
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Closed issues:
Ongoing work on IANA Message Header Registration (http://tools.ietf.org/wg/httpbis/trac/ticket/40):
Ongoing work on ABNF conversion (http://tools.ietf.org/wg/httpbis/trac/ticket/36):
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Closed issues:
Ongoing work on ABNF conversion (http://tools.ietf.org/wg/httpbis/trac/ticket/36):
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Closed issues:
Ongoing work on ABNF conversion (http://tools.ietf.org/wg/httpbis/trac/ticket/36):
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Closed issues:
Final work on ABNF conversion (http://tools.ietf.org/wg/httpbis/trac/ticket/36):
Other changes:
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Closed issues:
Partly resolved issues:
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Closed issues:
Partly resolved issues:
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Roy T. Fielding (editor) | |
Day Software | |
23 Corporate Plaza DR, Suite 280 | |
Newport Beach, CA 92660 | |
USA | |
Phone: | +1-949-706-5300 |
Fax: | +1-949-706-5305 |
Email: | fielding@gbiv.com |
URI: | http://roy.gbiv.com/ |
Jim Gettys | |
One Laptop per Child | |
21 Oak Knoll Road | |
Carlisle, MA 01741 | |
USA | |
Email: | jg@laptop.org |
URI: | http://www.laptop.org/ |
Jeffrey C. Mogul | |
Hewlett-Packard Company | |
HP Labs, Large Scale Systems Group | |
1501 Page Mill Road, MS 1177 | |
Palo Alto, CA 94304 | |
USA | |
Email: | JeffMogul@acm.org |
Henrik Frystyk Nielsen | |
Microsoft Corporation | |
1 Microsoft Way | |
Redmond, WA 98052 | |
USA | |
Email: | henrikn@microsoft.com |
Larry Masinter | |
Adobe Systems, Incorporated | |
345 Park Ave | |
San Jose, CA 95110 | |
USA | |
Email: | LMM@acm.org |
URI: | http://larry.masinter.net/ |
Paul J. Leach | |
Microsoft Corporation | |
1 Microsoft Way | |
Redmond, WA 98052 | |
Email: | paulle@microsoft.com |
Tim Berners-Lee | |
World Wide Web Consortium | |
MIT Computer Science and Artificial Intelligence Laboratory | |
The Stata Center, Building 32 | |
32 Vassar Street | |
Cambridge, MA 02139 | |
USA | |
Email: | timbl@w3.org |
URI: | http://www.w3.org/People/Berners-Lee/ |
Yves Lafon (editor) | |
World Wide Web Consortium | |
W3C / ERCIM | |
2004, rte des Lucioles | |
Sophia-Antipolis, AM 06902 | |
France | |
Email: | ylafon@w3.org |
URI: | http://www.raubacapeu.net/people/yves/ |
Julian F. Reschke (editor) | |
greenbytes GmbH | |
Hafenweg 16 | |
Muenster, NW 48155 | |
Germany | |
Phone: | +49 251 2807760 |
Fax: | +49 251 2807761 |
Email: | julian.reschke@greenbytes.de |
URI: | http://greenbytes.de/tech/webdav/ |