title: HTTP State Tokens docname: draft-west-http-state-tokens-latest date: {DATE} category: std ipr: trust200902 area: Applications and Real-Time keyword: Internet-Draft
stand_alone: yes #_ pi: toc: yes tocindent: yes sortrefs: yes symrefs: yes strict: yes compact: yes comments: yes inline: yes tocdepth: 2
ins: M. West
name: Mike West
organization: Google
email: [email protected]
uri: https://www.mikewest.org/
normative: I-D.ietf-httpbis-header-structure: I-D.yasskin-http-origin-signed-responses: RFC2104: RFC2109: RFC2119: RFC4648: Mixed-Content: target: https://w3c.github.io/webappsec-mixed-content/ title: Mixed Content author: - ins: M. West name: Mike West organization: Google Fetch: target: https://fetch.spec.whatwg.org/ title: Fetch author: - ins: A. van Kesteren name: Anne van Kesteren organization: Mozilla
informative: RFC6265: I-D.abarth-cake: I-D.ietf-cbor-cddl:
--- abstract
This document describes a mechanism which allows HTTP servers to maintain stateful sessions with HTTP user agents. It aims to address some of the security and privacy considerations which have been identified in existing state management mechanisms, providing developers with a well-lit path towards our current understanding of best practice.
--- middle
This document defines a state-management mechanism for HTTP that allows clients to create and
persist origin-bound session identifiers that can be delivered to servers in order to enable
stateful interaction. In a nutshell, each user agent will generate a single token per secure
origin, and will deliver it as a Sec-Http-State
structured header along with requests to that
origin (defined in {{sec-http-state}} and {{delivery}}).
Servers can configure this token's characteristics via a Sec-Http-State-Options
response header
(defined in {{sec-http-state-options}} and {{config}}).
That's it.
Cookies {{RFC6265}} are indeed a pervasive HTTP state management mechanism in the status quo, and they enable practically everything interesting on the web today. That said, cookies have some issues: they're hard to use securely, they add substantial weight to users' outgoing requests, and they enable tracking users' activity across the web in potentially surprising ways.
The mechanism proposed in this document aims at a more minimal and opinionated construct which takes inspiration from some of cookies' optional characteristics. In particular:
-
The client controls the token's value, not the server.
-
The token will only be available to the network layer, not to JavaScript (including network-like JavaScript, such as Service Workers).
-
The user agent will generate only one token per origin, and will only expose the token to the origin for which it was generated.
-
Tokens will not be generated for, or delivered to, non-secure origins.
-
By default, token delivery and configuration is constrained to same-site requests.
-
Each token persists for one hour after generation by default. This default expiration time can be overwritten by servers, and tokens can be reset at any time by servers, users, or user agents.
These distinctions might not be appropriate for all use cases, but seem like a reasonable set of
defaults. For folks for whom these defaults aren't good enough, we'll provide developers with a few
control points that can be triggered via a Sec-HTTP-State-Options
HTTP response header, described in
{{sec-http-state-options}}.
We do have cookies. And we've defined a number of extensions to cookies to blunt some of their
sharper edges: the HttpOnly
attribute, the Secure
attribute, SameSite
, prefixes like
__Host-
and __Secure-
, and so on. It's reasonable to suggest that pushing developers towards
these existing flags on our existing state management primitive is the right way forward.
A counterpoint is that we're collectively pretty bad at helping developers understand the risks
that might lead them to adopt The Good Cookie Syntax(tm) above. Adoption of these features has been
quite slow. The Secure
flag, for example, has been around since at least 1997 {{RFC2109}}, and is
hovering around 9% adoption based on data gathered from Chrome's telemetry in March, 2019. In that
dataset, cookies' other properties are set as follows:
- ~6.8% of cookies are set with
HttpOnly
. - ~5.5% are set with
Secure
. - ~3.1% are set with
HttpOnly; Secure
. - ~0.06% are set with
SameSite=*; Secure
. - ~0.05% are set with
SameSite=*
. - ~0.03% are set with
HttpOnly; Secure; SameSite=*
. - ~0.006% are set with
SameSite=*; HttpOnly
. - ~0.005% are set with a
__Secure-
prefix. - ~0.01% are set with a
__Host-
prefix.
In total:
- ~9.9% of cookies are marked as
HttpOnly
. - ~8.8% of cookies are marked as
Secure
. - ~0.1% of cookies are marked as
SameSite
. - ~84.2% of cookies use none of these features.
This document's underlying assumption is that it's going to be easier to teach developers about a
crazy new thing that's secure by default than it would be to convince them to change their
Set-Cookie
headers to be more like __Host-name=value; HttpOnly; Secure; SameSite=Lax; Path=/
. A
new thing resets expectations in a way that vastly exceeds the impact of explanations about the the
four attributes that must be used, the one attribute that must not be used, and the weird naming
convention that ought to be adopted.
User agents can deliver HTTP state tokens to a server in a Sec-Http-State
header. For example,
if a user agent has generated a token bound to https://example.com/
whose base64 encoding is
hB2RfWaGyNk60sjHze5DzGYjSnL7tRF2HWSBx6J1o4k=
({{RFC4648}}, Section 4), then it would generate the
following header when delivering the token along with requests to https://example.com/
:
Sec-Http-State: token=*hB2RfWaGyNk60sjHze5DzGYjSnL7tRF2HWSBx6J1o4k*
{: artwork-align="center"}
The server can control certain aspects of the token's delivery by responding to requests with a
Sec-Http-State-Options
header:
Sec-Http-State-Options: max-age=3600, key=*b7kuUkp...lkRioC2=*
{: artwork-align="center"}
{::boilerplate bcp14}
This document defines two Structured Headers {{!I-D.ietf-httpbis-header-structure}}. In doing so it relies upon the Augmented Backus-Naur Form (ABNF) notation of {{!RFC5234}} and the OWS rule from {{!RFC7230}}.
An HTTP State Token holds a session identifier which allows a user agent to maintain a stateful session with a specific origin, along with associated metadata:
-
creation
is a timestamp representing the point in time when the token was created. -
delivery
specifies the initiating contexts from which the token can be delivered. It is an enum of eithersame-origin
,same-site
, orcross-site
. Unless otherwise specified, its value issame-site
. -
key
is a server-provided key which can be used to sign requests with which the token is delivered. It is either null, or contains up to 256-bits of binary data. Unless otherwise specified, its value is null. -
max-age
is a number representing the token's lifetime in seconds. Unless otherwise specified, its value is3600
(1 hour). -
value
is the token's value (surprising, right?). It contains up to 256-bits of binary data.
An HTTP State Token is said to be "expired" if its creation
timestamp plus max-age
seconds is in
the past.
This document relies upon the definitions of "request" and "response" found in {{Fetch}}.
A request's delivery scope is same-origin
if the request's initiator and target are exactly the
same origin, same-site
if the request's initiator and target are not same-origin but share a
registrable domain (e.g. https://www.example.com/
and https://not-www.example.com/
), and
cross-site
otherwise. The following algorithm spells this relationship out more formally:
-
If the request was generated by the user agent as a response to direct user interaction with the user agent (e.g. the user typed an address into the agent's address bar, clicked a bookmark, or etc.), return
same-origin
. -
Let
request-origin
be the request'sorigin
, andtarget-origin
be the request'sURL
'sorigin
. -
If
request-origin
is same-origin withtarget-origin
, returnsame-origin
. -
If
request-origin
's registrable domain is the same astarget-origin
's registrable domain, returnsame-site
. -
Return
cross-site
.
User agents MUST keep a list of all the unexpired HTTP State Tokens which have been created. For the purposes of this document, we'll assume that user agents keep this list in the form of a map whose keys are origins, and whose values are HTTP State Tokens.
This map exposes three functions:
-
An HTTP State Token can be stored for a given origin. If the origin already exists in the map, the entry's value will be overwritten with the new HTTP State Token.
-
An origin's HTTP State Token can be retrieved. If the origin does not exist in the map,
null
will be returned instead. -
An origin (along with its HTTP State Token) can be deleted from the map.
The map is initially empty.
The user agent MUST generate a new HTTP State Token for an origin using an algorithm equivalent to the following:
-
Delete
origin
from the user agent's token store. -
Let
token
be a newly created HTTP State Token with its properties set as follows:creation
: The current time.delivery
:same-site
key
: nullmax-age
: 3600value
: 256 cryptographically random bits.
-
Store
token
in the user agent's token store fororigin
. -
If the user agent has defined a
NotifyHostHTTPStateReset(origin)
algorithm, call it withorigin
(see {{notify-reset}} for more context on this step). -
Return
token
.
The Sec-Http-State
HTTP header field allows user agents to deliver HTTP state tokens to servers
as part of an HTTP request.
Sec-Http-State
is a Structured Header {{!I-D.ietf-httpbis-header-structure}}. Its value MUST be
a dictionary ({{!I-D.ietf-httpbis-header-structure}}, Section 3.1). Its ABNF is:
Sec-Http-State = sh-dictionary
{: artwork-align="center"}
The dictionary MUST contain:
-
Exactly one member whose key is
token
, and whose value is binary content ({{!I-D.ietf-httpbis-header-structure}}, Section 3.9) that encodes the HTTP state token's value for the origin to which the header is delivered.If the
token
member contains more than 256 bits of binary content, the member MUST be ignored.
The dictionary MAY contain:
-
Exactly one member whose key is
sig
, and whose value is binary content ({{!I-D.ietf-httpbis-header-structure}}, Section 3.9) that encodes a signature over the token and the request which contains it, using a key previously delivered by the server. This mechanism is described in {{sign}}.If the
sig
member contains more than 256 bits of binary content, the member MUST be ignored.
The Sec-Http-State
header is parsed per the algorithm in Section 4.2 of
{{I-D.ietf-httpbis-header-structure}}. Servers MUST ignore the header if parsing fails, or if the
parsed header does not contain a member whose key is token
.
User agents will attach a Sec-Http-State
header to outgoing requests according to the processing
rules described in {{delivery}}.
The Sec-Http-State-Options
HTTP header field allows servers to deliver configuration information
to user agents as part of an HTTP response.
Sec-Http-State-Options
is a Structured Header {{!I-D.ietf-httpbis-header-structure}}. Its value
MUST be a dictionary ({{!I-D.ietf-httpbis-header-structure}}, Section 3.1). Its ABNF is:
Sec-Http-State-Options = sh-dictionary
{: artwork-align="center"}
The Sec-Http-State-Options
header is parsed per the algorithm in Section 4.2 of
{{I-D.ietf-httpbis-header-structure}}. User agents MUST ignore the header if parsing fails.
The dictionary MAY contain:
-
Exactly one member whose key is
key
, and whose value is binary content ({{!I-D.ietf-httpbis-header-structure}}, Section 3.10) that encodes an key which can be used to generate a signature over outgoing requests. -
Exactly one member whose key is
delivery
, and whose value is one of the following tokens ({{!I-D.ietf-httpbis-header-structure}}, Section 3.9):same-origin
,same-site
, orcross-site
.If the
delivery
member contains an unknown identifier, the member MUST be ignored. -
Exactly one member whose key is
max-age
, and whose value is an integer ({{!I-D.ietf-httpbis-header-structure}}, Section 3.6) representing the server's desired lifetime for its HTTP State Token.If the
max-age
member contains anything other than a positive integer, the member MUST be ignored.
User agents will process the Sec-Http-State-Options
header on incoming responses according to the
processing rules described in {{config}}.
Some servers will require access to their tokens from cross-site contexts (perhaps to support
authenticated activity or single-sign on, etc). These servers can request a cross-site
delivery option by delivering the following header:
Sec-Http-State-Options: delivery=cross-site, ...
{: artwork-align="center"}
Other servers might want their sessions to persist for more than an hour. These servers can request a more reasonable token lifetime lifetime by by delivering the following header:
Sec-Http-State-Options: max-age=2592000, ...
{: artwork-align="center"}
Servers may also wish to explicitly trigger the token's expiration (upon signout, for instance).
Setting a max-age
of 0
does the trick:
Sec-Http-State-Options: max-age=0, ...
{: artwork-align="center"}
For some servers, the client-generated token will be enough to maintain state. They can treat it as an opaque session identifier, and bind the user's state to it server-side. Other servers will require additional assurance that they can trust the token's provenance. To that end, servers can generate a unique key, associate it with the session identifier on the server, and deliver it to the client via an HTTP response header:
Sec-Http-State-Options: key=*ZH0GxtBMWA...nJudhZ8dtz*, ...
{: artwork-align="center"}
Clients will store that key, and use it to generate a signature over some set of data that mitigates the risk of token capture:
Sec-HTTP-State:
token=*J6BRKa...MonM*,
sig=*(HMAC-SHA256(key, token+metadata))*
{: artwork-align="center"}
Note: This part in particular is not fully baked, and we need to do some more work to flesh out the threat model (see also Token Binding). Look at it as an area to explore, not a solidly thought-out solution.
User agents deliver HTTP state tokens to servers by appending a Sec-Http-State
header field to
outgoing requests.
This specification provides algorithms which are called at the appropriate points in {{Fetch}} in
order to attach Sec-Http-State
headers to outgoing requests, and to ensure that
Sec-Http-State-Options
headers are correctly processed.
The user agent can attach HTTP State Tokens to a given request using an algorithm equivalent to the
following. This algorithm is intended to execute as the request is being sent out over the network
(after Service Worker processing), perhaps after the Cookie
header is handled in step 5.17.1
of Section 4.5 of {{Fetch}}, describing the "HTTP-network-or-cache fetch" algorithm:
-
If the user agent is configured to suppress explicit identifiers for the request, or if the request's URL is not a priori authenticated {{Mixed-Content}}, then skip the remaining steps in this algorithm, and return without modifying the request.
-
Let
target-origin
be the origin ofrequest
's current URL. -
Let
request-token
be the result of retrieving origin's token from the user agent's token store, ornull
if no such token exists. -
If
request-token
is expired, clear the user agent's token store fortarget-origin
, and setrequest-token
tonull
. -
If
request-token
isnull
, then:-
If
request
's delivery scope iscross-site
, return without modifying the request.Note: As the default
delivery
for HTTP State Tokens issame-site
, we return early rather than generating a token for a cross-site request. -
Set
request-token
to the result of generating an HTTP State Token fortarget-origin
, as defined in {{generate}}.
-
-
Return without modifying the request if either of the following statements are true:
-
request-token
'sdelivery
issame-origin
, andrequest
's delivery scope is notsame-origin
. -
request-token
'sdelivery
issame-site
, andrequest
's delivery scope is neithersame-origin
norsame-site
.
-
-
Let
serialized-value
be the base64 encoding ({{!RFC4648}}, Section 4) ofrequest-token
's value. -
Insert a member into
header-value
whose key istoken
and whose value isserialized-value
. -
If
request-token
'skey
is not null, then insert a member intoheader-value
whose key issig
, and whose value is the result of executing {{sign}} on request,serialized-value
, andrequest-token
'skey
. -
Append a header to
request
's header list whose name isSec-Http-State
, and whose value is the result of serializingheader-value
({{I-D.ietf-httpbis-header-structure}}, Section 4.1).
If the origin server provides a key
, the user agent will use it to sign any outgoing requests
which target that origin and include an HTTP State Token. Note that the signature is produced
before adding the Sec-Http-State
header to the request.
Given a request, a base64-encoded token value, and a key:
-
Let
cbor-request
be the result of building a CBOR representation {{!RFC7409}} of the given request, as specified in the first element of the array described in Section 3.2 of {{I-D.yasskin-http-origin-signed-responses}}. -
Add an item to
cbor-request
which maps the byte string ':token' to the byte string containing the given base64-encoded token value. -
Return the result of computing HMAC-SHA256 {{!RFC2104}} over the canonical CBOR serialization of
cbor-request
(Section 3.4 of {{I-D.yasskin-http-origin-signed-responses}}), using the givenkey
.
The following request:
GET / HTTP/1.1
Host: example.com
Accept: */*
results in the following CBOR representation (represented using the extended diagnostic notation from Appendix G of {{I-D.ietf-cbor-cddl}}):
{
':method': 'GET',
':token': 'hB2RfWaGyNk60sjHze5DzGYjSnL7tRF2HWSBx6J1o4k='
':url': 'https://example.com/',
'accept': '*/*',
}
Servers configure the HTTP State Token representing a given users' state by appending a
Sec-Http-State-Options
header field to outgoing responses.
User agents MUST process this header on a given response as per the following algorithm, which is
intended to be called after the Set-Cookie
header is handled in step 11.4 of Section 4.6 of
{{Fetch}}, which defines the "HTTP-network fetch" algorithm.
-
Let
response-origin
be the origin of response's URL. -
If the response's URL is not a priori authenticated {{Mixed-Content}}, return without altering
response-origin
's HTTP State Token. -
Let
token
be the result of retrievingresponse-origin
's token from the user agent's token store, ornull
if no such token exists. -
If
token
is expired, clear the user agent's token store forresponse-origin
, and settoken
tonull
. -
If
token
isnull
, then:-
If
request
's delivery scope iscross-site
, return without modifying the request.Note: As the default
delivery
for HTTP State Tokens issame-site
, we return early rather than generating a token for a cross-site request. -
Set
token
to the result of generating an HTTP State Token fortarget-origin
, as defined in {{generate}}.
-
-
If the response's header list contains
Sec-Http-State-Options
, then:-
Let
header
be the result of getting response'sSec-Http-State-Options
header, and parsing parsing it per the algorithm in Section 4.2 of {{I-D.ietf-httpbis-header-structure}}. -
Return without altering
response-origin
's HTTP State Token if any of the following conditions hold:- Parsing the header results in failure.
header
has a member namedkey
whose value is not a byte sequence (Section 3.10 of {{I-D.ietf-httpbis-header-structure}})header
has a member nameddelivery
whose value is not one of the following tokens (Section 3.9 of {{I-D.ietf-httpbis-header-structure}}): "same-origin", "same-site", and "cross-site".header
has a member namedmax-age
whose value is not a positive integer (Section 3.6 of {{I-D.ietf-httpbis-header-structure}}).
-
If
header
has a member namedkey
, settoken
'skey
to the member's value. -
If
header
has a member nameddelivery
, settoken
'sdelivery
to the member's value. -
If
header
has a member namedmax-age
:-
If the member's value is
0
, generate a new HTTP State Token forresponse-origin
as defined in {{generate}}.Otherwise, set
token
'smax-age
to the member's value.
Note that
max-age
is processed last, meaning that any other options specified alongsidemax-age=0
will be de facto ignored as a new token is generated, replacing the old. -
-
HTTP State Tokens aim to mitigate some of the security and privacy drawbacks that decades of implementation experience with cookies have laid bare. It would be worthwhile to skim through the privacy considerations (Section 7 of {{RFC6265}}) and security considerations (Section 8 of {{RFC6265}}) of that existing state management mechanism, as it forms a foundation upon which this document builds.
HTTP State Tokens improve upon cookies' weak confidentiality/integrity guarantees (see Sections 8.3, 8.5, 8.6, and 8.7 of {{RFC6265}}) in several ways:
-
User agents MUST require secure channels (such as TLS) for delivery and configuration of HTTP State Tokens. User agents cannot be induced to deliver an origin's tokens across channels visible to (and modifiable by) network attackers, nor can an attack on DNS cause tokens to be revealed (as any server to which the user could be directed will also need to authenticate itself, which is presumably difficult).
-
HTTP State Tokens are mapped to origins, matching developers expectations for client-side data generally. This ensures that tokens are isolated by host and port: code running on
https://bar.example.com/
cannot alter state onhttps://foo.example.com/
without the latter's cooperation, and that the same applies tohttps://example.com:8000/
andhttps://example.com:80/
.Note that this origin binding means that there are no path restrictions for tokens. Servers relying upon these tokens for state management SHOULD NOT run mutually distrusting services on different paths of the same origin.
-
User agents MUST NOT expose HTTP State Tokens to non-HTTP APIs which are web-accessible, thereby reducing the risk of accidental exposure via cross-site scripting attack.
Further, the
Sec-
prefix on bothSec-HTTP-State
andSec-HTTP-State-Options
ensures that both are considered "forbidden header names" by {{Fetch}}. The latter should also be treated as a "forbidden response header".
HTTP State Tokens embrace the session identifier pattern discussed in Section 8.4 of {{RFC6265}} by requiring that the client control the token's value, setting it to a fixed-length, random byte sequence. The client's control mitigates the risk of sensitive information being stored in the token directly, and the token's length makes it unlikely to be easily guessed.
Some servers will be interested in proving the token's provenance over time, which they do today by
storing cookies with signed values. Since storing a signed value directly is impossible in a
client-controlled world, servers can instead store a key
, which is used to sign outgoing requests.
Since this key is never exposed directly to the web, it provides a reasonable guarantee of client
stability over time which a server can rely upon when making risk judgements.
User agents MUST provide users with the ability to control the creation and distribution of HTTP State Tokens, just as they do for cookies today. This certainly means providing controls over first- vs third-party distribution, control over the origins which can store state, control over the state presented to origins, visibility into the state of the user agent's token store, and etc.
Further, this document grants user agents wide latitude to experiment with various distribution
policies and limitations. The capabilities offered by delivery
and max-age
should be considered
upper bounds on distribution, within which user agents are free to roam.
By default, HTTP State Tokens live for an hour, which is a compromise between the reasonable desire of servers to maintain state across a given user's session, and the privacy risks associated with long-lived tokens stored on a user's disk.
Servers that desire a longer session lifetime can explicitly request an extension, which the browser can choose to act on.
HTTP State Tokens, like cookies, provide a form of ambient authority (see Section 8.2 of
{{RFC6265}}). By default, this authority is limited to requests initiated by same-site actors,
which serves as a reasonable mitigation against some classes of attack (e.g. https://evil.com/
making authenticated requests to https://example.com/
).
Servers that desire to interact in an authenticated manner in cross-site contexts are required to
opt-into doing so by delivering an appropriate delivery
value in a Sec-HTTP-State-Options
response header. Servers which choose to do so SHOULD take reasonable precautions, implementing
CSRF tokens for sensitive actions, and taking stock of the context from which a given request is
initiated (by examining incoming Referrer
, Origin
, and Sec-Fetch-Site
headers).
Further, tokens can only be created in same-origin or same-site contexts, which means that cross-site identifier would only be available after the relevant origin was visited in a same-site context, and explicitly declared its tokens as being deliverable cross-site (at which point the user agent is empowered to make some decisions about how to handle that declaration).
Step 4 of the token generation algorithm ({{generate}}) recognizes that user agents may wish to
notify an origin's developers that HTTP state has been reset in order to enable cleanup of state
stored client-side. Embedding environments are encouraged to define an implementation of the
NotifyHostHTTPStateReset(origin)
algorithm that's appropriate for the environment.
For example, HTML may wish to enable developers to respond to token generation by posting a message
to a specially-named BroadcastChannel
for the to enable this kind of work:
let resetChannel = new BroadcastChannel('http-state-reset'));
resetChannel.onmessage = e => { /* Do exciting cleanup here. */ };
{: artwork-align="center"}
This algorithm could take something like the following form:
TODO(mkwst): Write a reasonable implementation of this once I have internet again.
This document registers the Sec-Http-State
and Sec-Http-State-Options
header fields in the
"Permanent Message Header Field Names" registry located at
https://www.iana.org/assignments/message-headers.
Header field name:
: Sec-Http-State
Applicable protocol:
: http
Status:
: experimental
Author/Change controller:
: IETF
Specification document(s):
: This document (see {{sec-http-state}})
Related information:
: (empty)
Header field name:
: Sec-Http-State-Options
Applicable protocol:
: http
Status:
: experimental
Author/Change controller:
: IETF
Specification document(s):
: This document (see {{sec-http-state-options}})
Related information:
: (empty)
--- back
This document owes much to Adam Barth's {{I-D.abarth-cake}} and {{RFC6265}}.
RFC Editor: Please remove this section before publication.
-
-01
- General editorial cleanup.
- Explanation of
NotifyHostHTTPStateReset(origin)
algorithm in {{notify-reset}}.
-
-00
- This document was created.