1. Introduction
This section is not normative.
This document defines Content Security Policy, a mechanism web applications can use to mitigate a broad class of content injection vulnerabilities, such as cross-site scripting (XSS). Content Security Policy is a declarative policy that lets the authors (or server administrators) of a web application inform the client about the sources from which the application expects to load resources.
To mitigate XSS attacks, for example, a web application can declare that it only expects to load script from specific, trusted sources. This declaration allows the client to detect and block malicious scripts injected into the application by an attacker.
Content Security Policy (CSP) is not intended as a first line of defense against content injection vulnerabilities. Instead, CSP is best used as defense-in-depth, to reduce the harm caused by content injection attacks. As a first line of defense against content injection, server operators should validate their input and encode their output.
There is often a non-trivial amount of work required to apply CSP to an existing web application. To reap the greatest benefit, authors will need to move all inline script and style out-of-line, for example into external scripts, because the user agent cannot determine whether an inline script was injected by an attacker.
To take advantage of CSP, a web application opts into using CSP by supplying a Content-Security-Policy
HTTP header. Such policies apply to the
current resource representation only. To supply a policy for an entire site,
the server needs to supply a policy with each resource representation.
1.1. Changes from Level 2
This document describes an evolution of the Content Security Policy specification. Level 3 makes the following changes from Level 2:
-
The following directives are brand new in this revision:
-
manifest-src
controls the protected resource’s ability to load application manifests [MANIFEST]. -
reflected-xss
controls the user agent’s built-in heuristics to actively protect against XSS. It is meant to supplant theX-XSS-Protection
HTTP request header.
-
1.2. Changes from Level 1
Level 2 made two breaking changes from Level 1, and added support for a number of new directives and capabilities which are summarized below:
-
The following changes are backwards incompatible with the majority of
user agent’s implementations of Level 1:
-
The path component of a source expression is now ignored if the
resource being loaded is the result of a redirect, as described in §4.2.2.3 Paths and Redirects.
Note: Paths are technically new in Level 2, but they were already implemented in many user agents before this revision of CSP was completed, so noting the change here seems reasonable.
- A protected resource’s ability to load Workers [WORKERS] is now controlled via
child-src
rather thanscript-src
. - Workers now have their own policy, separate from the protected resource which loaded them. This is described in §5.1 Workers.
-
The path component of a source expression is now ignored if the
resource being loaded is the result of a redirect, as described in §4.2.2.3 Paths and Redirects.
-
The following directives are brand new in this revision:
-
base-uri
controls the protected resource’s ability to specify the document base URL. -
child-src
deprecates and replacesframe-src
, controlling the protected resource’s ability to embed frames, and to load Workers. -
form-action
controls the protected resource’s ability to submit forms. -
frame-ancestors
controls the protected resource’s ability be embedded in other documents. It is meant to supplant theX-Frame-Options
HTTP request header. [RFC7034] -
plugin-types
controls the protected resource’s ability to load specific types of plugins.
-
- Individual inline scripts and stylesheets may be whitelisted via nonces (as described in §4.2.4 Valid Nonces) and hashes (as described in §4.2.5 Valid Hashes).
- A
CSP
request header is now sent with relevant requests, as described in §3.4 The CSP HTTP Request Header. - A
SecurityPolicyViolationEvent
is fired upon violations, as described in §6.4 Firing Violation Events. - A number of new fields were added to violation reports (both those POSTED
via
report-uri
, and those handed to the DOM viaSecurityPolicyViolationEvent
events. These includeeffectiveDirective
,statusCode
,sourceFile
,lineNumber
, andcolumnNumber
. - Certain flags present in the
sandbox
directive now affect Worker creation, as described in §7.16.1 Sandboxing and Workers.
2. Key Concepts and Terminology
The Augmented Backus-Naur Form (ABNF) notation used in this document is
specified in RFC5234 [ABNF]. We use the #rule
extension
defined in [RFC7230].
- security policy
- security policy directive
- security policy directive name
- security policy directive value
- security policy directive
-
A security policy refers to both a set of security
preferences for restrictions within which content can operate, and
to a fragment of text that codifies or transmits these preferences.
For example, the following string is a policy which restricts script
and object content:
script-src 'self'; object-src 'none'
Security policies contain a set of security policy directives (
script-src
andobject-src
in the example above), each responsible for declaring the restrictions for a particular resource type, or manipulating a specific aspect of the policy’s restrictions. The list of directives defined by this specification can be found in §7 Directives.Each directive has a name and value; value may be optional for some directives. A detailed grammar can be found in §4 Syntax and Algorithms.
- protected resource
- A security policy is applied by a user agent to a specific resource representation, known as the protected resource. See §3 Policy Delivery for details regarding the mechanisms by which policies may be applied to a protected resource.
3. Policy Delivery
The server delivers a policy to the user agent via an HTTP response
header (defined in §3.1 Content-Security-Policy Header Field and §3.2 Content-Security-Policy-Report-Only Header Field) or an HTML meta
element (defined in §3.3 HTML meta Element).
Servers are informed that requests are coming from a protected resource via an HTTP request header (defined in §3.4 The CSP HTTP Request Header).
3.1. Content-Security-Policy
Header Field
The Content-Security-Policy
header field is
the preferred mechanism for delivering a policy. The grammar is as follows:
"Content-Security-Policy:" 1#policy-token
For example, a response might include the following header field:
Content-Security-Policy: script-src 'self'
A server MUST NOT send more than one HTTP header field named Content-Security-Policy
with a given resource
representation.
A server MAY send different Content-Security-Policy
header field values with different representations of the same
resource or with different resources.
Upon receiving an HTTP response containing at least one Content-Security-Policy
header field, the user agent
MUST enforce each of the policies contained in each such
header field.
3.2. Content-Security-Policy-Report-Only
Header Field
The Content-Security-Policy-Report-Only
header field lets servers experiment with policies by monitoring (rather
than enforcing) a policy. The grammar is as follows:
"Content-Security-Policy-Report-Only:" 1#policy-token
For example, server operators might wish to develop their security policy iteratively. The operators can deploy a report-only policy based on their best estimate of how their site behaves:
Content-Security-Policy-Report-Only: script-src 'self'; report-uri /csp-report-endpoint/
If their site violates this policy the user agent will send violation
reports to the URL specified in the policy’s report-uri directive, but allow the violating resources to load regardless. Once a site
has confidence that the policy is appropriate, they can start enforcing the
policy using the Content-Security-Policy
header field.
A server MUST NOT send more than one HTTP header field named Content-Security-Policy-Report-Only
with a given resource representation.
A server MAY send different Content-Security-Policy-Report-Only
header field values
with different representations of the same resource or with different
resources.
Upon receiving an HTTP response containing at least one Content-Security-Policy-Report-Only
header field, the
user agent MUST monitor each of the policies
contained in each such header field.
Note: The Content-Security-Policy-Report-Only
header is not supported inside a meta
element.
3.3. HTML meta
Element
The server MAY supply policy via one or more HTML meta
elements
with http-equiv
attributes that are an ASCII case-insensitive
match for the string "Content-Security-Policy
". For
example:
<meta http-equiv="Content-Security-Policy" content="script-src 'self'">
Add the following entry to the pragma directives for the meta
element:
- Content security policy
(
http-equiv="content-security-policy"
) -
- If the Document’s
head
element is not an ancestor of themeta
element, abort these steps. - If the
meta
element lacks acontent
attribute, abort these steps. - Let policy be the value of the
content
attribute of themeta
element. - Let directive-set be the result of parsing policy.
-
Remove all occurrences of
reflected-xss
,report-uri
,frame-ancestors
, andsandbox
directives from directive-set.Note: User agents are encouraged to issue a warning to developers if one or more of these directives are included in a policy delivered via
meta
. - Enforce each of the directives in directive-set, as defined for each directive type.
- If the Document’s
Authors are strongly encouraged to place meta
elements as early
in the document as possible, because policies in meta
elements are not
applied to content which preceds them. In particular, note that resources
fetched or prefetched using the Link
HTTP response header
field, and resources fetched or prefetched using link
and script
elements which precede a meta
-delivered policy will not be blocked.
Note: A policy specified via a meta
element will be enforced
along with any other policies active for the protected resource, regardless
of where they’re specified. The general impact of enforcing multiple
policies is described in §3.5 Enforcing multiple policies.
Note: Modifications to the content
attribute of a meta
element
after the element has been parsed will be ignored.
Note: The Content-Security-Policy-Report-Only
header is not supported inside a meta
element.
3.4. The CSP
HTTP Request Header
The CSP
header field indicates that a particular
request is subject to a policy, and its value is defined by the
following ABNF grammar:
"CSP:" 1#csp-header-value csp-header-value = *WSP "active" *WSP
If the user agent is monitoring or enforcing a policy that includes directives whose value is a source list, then the user
agent MUST send a header field named CSP
along with requests
for resources whose origin does not match the protected
resource’s origin. The value of this header MUST be active
.
The user agent MAY choose to send this header only if the request is for a
resource type which the active policy would effect. That is, given a policy
of img-src example.com
, the user agent would send CSP:
active
along with requests for images, but might choose not to send
the header with requests for script.
Note: The central reason for including this header is that it hints to a
server that information about redirects might be leaked as a side-effect
of a page’s active policy. If this header is present, a server might decline
to redirect a logged-out user from example.com
to accounts.example.com
, for example, as a malicious embedder
might otherwise be able to determine the user’s logged-in status.
3.5. Enforcing multiple policies
This section is not normative.
The above sections note that when multiple policies are present,
each must be enforced or reported, according to its type. An example
will help clarify how that ought to work in practice. The behavior of
an XMLHttpRequest
might seem unclear given a site
that, for whatever reason, delivered the following HTTP headers:
Content-Security-Policy: default-src 'self' https://example.com https://example.net; connect-src 'none'; Content-Security-Policy: connect-src https://example.com/; script-src https://example.com/
Is a connection to example.com
allowed or not? The
short answer is that the connection is not allowed. Enforcing both
policies means that a potential connection would have to pass through
both unscathed. Even though the second policy would allow this
connection, the first policy contains connect-src 'none'
, so its enforcement blocks the connection. The impact is
that adding additional policies to the list of policies to enforce can
only further restrict the capabilities of the protected resource.
To demonstrate that further, consider a script tag on this page.
The first policy would lock scripts down to 'self'
, https://example.com
and https://example.net
via the default-src
directive. The second, however,
would only allow script from https://example.com/
. Script
will only load if it meets both policy’s criteria: in this case, the only
origin that can match is https://example.com
, as both
policies allow it.
3.6. Policy applicability
This section is not normative.
Policies are associated with an protected resource, and enforced or monitored for that resource. If a resource does not create a new execution context (for example, when including a script, image, or stylesheet into a document), then any policies delivered with that resource are discarded without effect. Its execution is subject to the policy or policies of the including context. The following table outlines examples of these relationships:
Resource Type | What policy applies? | |
---|---|---|
Top-level Contexts | HTML as a new, top-level browsing context | The policy delivered with the resource applies. |
SVG, as a top-level document | The policy delivered with the resource applies. | |
Embedded Contexts | Any resource included via iframe , object , or embed
| Unless the embedded resource is a globally unique identifier (or a srcdoc iframe), the embedded resource is controlled by the policy delivered with the resource. If the embedded resource is a globally unique identifier or srcdoc iframe, it inherits the policy of the context creating it. (The frame-src and child-src directives of the embedding context only control what resources are eligible for embedding in that context, not the behavior of the resource once embedded.) |
SVG, as an embedded document | Unless the resource is a globally unique identifier, it is controlled by the policy delivered with the resource. If a globally unique identifier, it inherits the policy of the context creating it. | |
JavaScript, as a Worker, Shared Worker, or Service Worker | Unless the resource is a globally unique identifier, it is controlled by the policy delivered with the resource. If a globally unique identifier, it inherits the policy of the context creating it. | |
Subresources | SVG, inlined via svg
| The policy of the including context applies. |
SVG, as a resource document | The policy of the including context applies. | |
HTML via XMLHttpRequest | The policy of the context that performed the fetch applies. | |
Image via img element
| The policy of the including context applies. | |
JavaScript via a script element
| The policy of the including context applies. | |
SVG, via img
| No policy applies; this should be just as safe as JPG. | |
SVG, as a WebFont | No policy applies; this should be just as safe as WOFF. |
4. Syntax and Algorithms
4.1. Policy Syntax
A Content Security Policy consists of a U+003B SEMICOLON
(;
) delimited list of directives. Each directive consists of a directive name and (optionally) a directive value, defined by the following ABNF:
policy-token = [ directive-token *( ";" [ directive-token ] ) ] directive-token = *WSP [ directive-name [ WSP directive-value ] ] directive-name = 1*( ALPHA / DIGIT / "-" ) directive-value = *( WSP / <VCHAR except ";" and ","> )
4.1.1. Parsing Policies
To parse the policy policy, the user agent MUST use an algorithm equivalent to the following:
- Let the set of directives be the empty set.
-
For each non-empty token returned by strictly splitting the string policy on the character U+003B SEMICOLON
(
;
):- Skip whitespace.
- Collect a sequence of characters that are not space characters. The collected characters are the directive name.
- If there are characters remaining in token, skip ahead exactly one character (which must be a space character).
- The remaining characters in token (if any) are the directive value.
- If the set of directives already contains a directive whose name is a case insensitive match for directive name, ignore this instance of the directive and continue to the next token.
- Add a directive to the set of directives with name directive name and value directive value.
- Return the set of directives.
4.2. Source List Syntax
Many CSP directives use a value consisting of a source list, defined in the ABNF grammar below.
Each source expression in the source list represents a
location from which content of the specified type can be retrieved.
For example, the source expression 'none'
represents
the empty set of URLs, and the source expression 'unsafe-inline'
represents content supplied inline in the
resource itself.
source-list = *WSP [ source-expression *( 1*WSP source-expression ) *WSP ] / *WSP "'none'" *WSP source-expression = scheme-source / host-source / keyword-source / nonce-source / hash-source scheme-source = scheme-part ":" host-source = [ scheme-part "://" ] host-part [ port-part ] [ path-part ] keyword-source = "'self'" / "'unsafe-inline'" / "'unsafe-eval'" base64-value = 1*( ALPHA / DIGIT / "+" / "/" )*2( "=" ) nonce-value = base64-value hash-value = base64-value nonce-source = "'nonce-" nonce-value "'" hash-algo = "sha256" / "sha384" / "sha512" hash-source = "'" hash-algo "-" hash-value "'" scheme-part = <scheme production from RFC 3986, section 3.1> host-part = "*" / [ "*." ] 1*host-char *( "." 1*host-char ) host-char = ALPHA / DIGIT / "-" path-part = <path production from RFC 3986, section 3.3> port-part = ":" ( 1*DIGIT / "*" )
If the policy contains a nonce-source
expression, the
server MUST generate a fresh value for the nonce-value
directive at random and independently each time it transmits a policy.
The generated value SHOULD be at least 128 bits long (before encoding),
and generated via a cryptographically secure random number generator.
This requirement ensures that the nonce-value
is
difficult for an attacker to predict.
Note: Using a nonce to whitelist inline script or style is less secure than
not using a nonce, as nonces override the restrictions in the directive in
which they are present. An attacker who can gain access to the nonce can
execute whatever script they like, whenever they like. That said, nonces
provide a substantial improvement over 'unsafe-inline'
when
layering a content security policy on top of old code. When considering 'unsafe-inline'
, authors are encouraged to consider nonces (or
hashes) instead.
The host-char
production intentionally contains only
ASCII characters; internationalized domain names cannot be entered
directly into a policy string, but instead MUST be Punycode-encoded [RFC3492]. For example, the domain üüüüüü.de
would be
encoded as xn--tdaaaaaa.de
.
NOTE: Though IP addresses do match the grammar above, only 127.0.0.1
will actually match a URL when used in a source
expression (see §4.2.2 Matching Source Expressions for details). The security
properties of IP addresses are suspect, and authors ought to prefer
hostnames to IP addresses whenever possible.
4.2.1. Parsing Source Lists
To parse a source list source list, the user agent MUST use an algorithm equivalent to the following:
- Strip leading and trailing whitespace from source list.
- If source list is an ASCII case-insensitive match for the string
'none'
(including the quotation marks), return the empty set. - Let set of source expressions be the empty set.
- For each token returned by splitting source
list on spaces, if the token matches the grammar for
source-expression
, add the token to the set of source expressions. - Return the set of source expressions.
Note: Characters like U+003B SEMICOLON (;
) and
U+002C COMMA (,
) cannot appear in source expressions
directly: if you’d like to include these characters in a source
expression, they must be percent
encoded as %3B
and %2C
respectively.
4.2.2. Matching Source Expressions
A URL url is said to match a source expression for a protected resource if the following algorithm returns does match:
- Let url be the result of processing the URL through the URL parser.
- If the source expression a consists of a single U+002A ASTERISK
character (
*
), and url’s scheme is not one ofblob
,data
,filesystem
, then return does match. -
If the source expression matches the grammar for
scheme-source
:- If url’s scheme is an ASCII case-insensitive
match for the source expression’s
scheme-part
, return does match. - Otherwise, return does not match.
- If url’s scheme is an ASCII case-insensitive
match for the source expression’s
-
If the source expression matches the grammar for
host-source
:- If url’s host is
null
, return does not match. -
Let url-scheme, url-host, and url-port be the scheme, host, and port of url’s origin, respectively.
Note: If url doesn’t specify a port, then its origin’s port will be the default port for url’s scheme.
- Let url-path-list be the path of url.
- If the source expression has a
scheme-part
that is not a case insensitive match for url-scheme, then return does not match. -
If the source expression does not have a
scheme, return does not match if any of the following
are true:
- The scheme of the protected resource’s URL is a case
insensitive match for
HTTP
, and url-scheme is not a case insensitive match for eitherHTTP
orHTTPS
. - The scheme of the protected resource’s URL is not a case insensitive match for
HTTP
, and url-scheme is not a case insensitive match for the scheme of the protected resource’s URL.
- The scheme of the protected resource’s URL is a case
insensitive match for
- If the first character of the source expression’s
host-part
is an U+002A ASTERISK character (*
) and the remaining characters, including the leading U+002E FULL STOP character (.
), are not a case insensitive match for the rightmost characters of url-host, then return does not match. - If the first character of the source expression’s
host-part
is not an U+002A ASTERISK character (*
) and url-host is not a case insensitive match for the source expression’shost-part
, then return does not match. -
If the source expression’s
host-part
matches theIPv4address
production from [RFC3986], and is not127.0.0.1
, or is an IPv6 address, return does not match.Note: A future version of this specification may allow literal IPv6 and IPv4 addresses, depending on usage and demand. Given the weak security properties of IP addresses in relation to named hosts, however, authors are encouraged to prefer the latter whenever possible.
- If the source expression does not contain
a
port-part
and url-port is not the default port for url-scheme, then return does not match. -
If the source expression does contain a
port-part
, then return does not match if both of the following are true: -
If the source expression contains a non-empty
path-part
, and the URL is not the result of a redirect, then:- Let exact-match be
true
if the final character of path-part is not the U+002F SOLIDUS character (/
), andfalse
otherwise. - Let source-expression-path-list be the result of
splitting path-part on the U+002F SOLIDUS character
(
/
). - If source-expression-path-list’s length is greater than url-path-list’s length, return does not match.
-
For each entry in source-expression-path-list:
- Percent decode entry.
- Percent decode the first item in url-path-list.
- If entry is not an ASCII case-insensitive match for the first item in url-path-list, return does not match.
- Pop the first item in url-path-list off the list.
- If exact-match is
true
, and url-path-list is not empty, return does not match.
- Let exact-match be
- Otherwise, return does match.
- If url’s host is
-
If the source expression is a case insensitive match for
'self'
(including the quotation marks), then:-
Return does match if the
origin of url matches the origin of protected
resource’s URL.
Note: This includes IP addresses. That is, a document at
https://111.111.111.111/
with a policy ofimg-src 'self'
can load the imagehttps://111.111.111.111/image.png
, as the origins match.
-
Return does match if the
origin of url matches the origin of protected
resource’s URL.
- Otherwise, return does not match.
Note: This algorithm treats the URLs https://example.com/
and https://example.com./
as non-matching. This
is consistent with browser behavior which treats documents served from
these URLs as existing in distinct origins.
A URL url is said to match a source list for protected resource if at least one source expression in the set of source expressions obtained by parsing the source list matches url for protected resource.
Note: No URLs match an empty set of source expressions, such as the set
obtained by parsing the source list 'none'
.
4.2.2.1. Security Considerations for GUID URL schemes
This section is not normative.
As defined above, special URL schemes that refer to specific pieces of
unique content, such as "data:", "blob:" and "filesystem:" are
excluded from matching a policy of *
and must be
explicitly listed. Policy authors should note that the content of
such URLs is often derived from a response body or execution in a
Document context, which may be unsafe. Especially for the default-src
and script-src
directives, policy authors should be aware that allowing "data:" URLs
is equivalent to unsafe-inline
and allowing "blob:" or
"filesystem:" URLs is equivalent to unsafe-eval
.
4.2.2.2. Path Matching
This section is not normative.
The rules for matching source expressions that contain paths
are simpler than they look: paths that end with the '/'
character match all files in a directory and its subdirectories. Paths
that do not end with the '/'
character match only one
specific file. A few examples should make this clear:
- The source expression
example.com
has no path, and therefore matches any file served from that host. - The source expression
example.com/scripts/
matches any file in thescripts
directory ofexample.com
, and any of its subdirectories. For example, bothhttps://example.com/scripts/file.js
andhttps://example.com/scripts/js/file.js
would match. - The source expression
example.com/scripts/file.js
matches only the file namedfile.js
in thescripts
directory ofexample.com
. - Likewise, the source expression
example.com/js
matches only the file namedjs
. In particular, note that it would not match files inside a directory namedjs
. Files likeexample.com/js/file.js
would be matched only if the source expression ended with a trailing "/", as inexample.com/js/
.
Note: Query strings have no impact on matching: the source
expression example.com/file
matches each of https://example.com/file
, https://example.com/file?key=value
, https://example.com/file?key=notvalue
, and https://example.com/file?notkey=notvalue
.
4.2.2.3. Paths and Redirects
To avoid leaking path information cross-origin (as discussed
in Egor Homakov’s Using Content-Security-Policy for Evil),
the matching algorithm ignores the path component of a source
expression if the resource being loaded is the result of a
redirect. For example, given a page with an active policy of img-src example.com not-example.com/path
:
- Directly loading
https://not-example.com/not-path
would fail, as it doesn’t match the policy. - Directly loading
https://example.com/redirector
would pass, as it matchesexample.com
. - Assuming that
https://example.com/redirector
delivered a redirect response pointing tohttps://not-example.com/not-path
, the load would succeed, as the initial URL matchesexample.com
, and the redirect target matchesnot-example.com/path
if we ignore its path component.
This restriction reduces the granularity of a document’s policy when redirects are in play, a necessary compromise to avoid brute-forced information leaks of this type.
The relatively long thread "Remove paths from CSP?" from [email protected] has more detailed discussion around alternate proposals.
4.2.3. The nonce
attribute
Nonce sources require a new nonce
attribute to be added to
both script
and style
elements.
partial interface HTMLScriptElement { attribute DOMString nonce; };
- nonce, of type DOMString
- This attribute reflects the value of the
element’s
nonce
content attribute.
partial interface HTMLStyleElement { attribute DOMString nonce; };
- nonce, of type DOMString
- This attribute reflects the value of the
element’s
nonce
content attribute.
4.2.4. Valid Nonces
An element has a valid nonce for a set of source
expressions if the value of the element’s nonce
attribute
after stripping leading
and trailing whitespace is a case-sensitive match for the nonce-value
component of at least one nonce-source
expression in set of source
expressions.
4.2.5. Valid Hashes
An element’s content is the script block’s
source for script
elements, or the value of the element’s textContent
IDL attribute for non-script
elements such as style
.
The digest of element’s content for is the result of applying a hashing algorithm to the element’s content.
To determine whether element has a valid hash for a set of source expressions, execute the following steps:
- Let hashes be a list of all
hash-source
expressions in set of source expressions. -
For each hash in hashes:
-
Let hashing algorithm be:
- SHA-256 if the
hash-algo
component of hash is an ASCII case-insensitive match for the string "sha256". - SHA-384 if the
hash-algo
component of hash is an ASCII case-insensitive match for the string "sha384". - SHA-512 if the
hash-algo
component of hash is an ASCII case-insensitive match for the string "sha512".
- SHA-256 if the
- Let expected be the
hash-value
component of hash. - Let actual be the base64 encoding of the binary digest of element’s content using the hashing algorithm.
- If actual is a case-sensitive match for expected, return true and abort these steps.
-
Let hashing algorithm be:
- Return false.
Note: If an element has an invalid hash, it would be helpful if the user agent reported the failure to the author by adding a warning message containing the actual hash value.
4.3. Media Type List Syntax
The plugin-types
directive uses a value consisting
of a media type list.
Each media type in the media type list represents a specific type of resource that can be retrieved and used to instantiate a plugin in the protected resource.
media-type-list = media-type *( 1*WSP media-type ) media-type = <type from RFC 2045> "/" <subtype from RFC 2045>
4.3.1. Parsing
To parse a media type list media type list, the user agent MUST use an algorithm equivalent to the following:
- Let the set of media types be the empty set.
- For each token returned by splitting media type list on spaces, if the token matches the
grammar for
media-type
, add the token to the set of media types. Otherwise ignore the token. - Return the set of media types.
4.3.2. Matching
A media type matches a media type list if, and only if, the media type is an ASCII case-insensitive match for at least one token in the set of media types obtained by parsing the media type list.
4.4. Reporting
To strip uri for reporting, the user agent MUST use an algorithm equivalent to the following:
- If the origin of uri is a globally unique
identifier (for example, uri has a scheme of
data
,blob
, orfilesystem
), then abort these steps, and return the ASCII serialization of uri’s scheme. - If the origin of uri is not the same as the origin of the protected resource, then abort these steps, and return the ASCII serialization of uri’s origin.
- Return uri, with any fragment component removed.
To generate a violation report object, the user agent MUST use an algorithm equivalent to the following:
-
Prepare a JSON object violation with the
following keys and values:
- blocked-uri
- The originally requested URL of the resource that was prevented from loading, stripped for reporting, or the empty string if the resource has no URL (inline script and inline style, for example).
- document-uri
- The address of the protected resource, stripped for reporting.
- effective-directive
- The name of the policy directive that was violated. This will
contain the directive whose enforcement triggered the
violation (e.g. "
script-src
") even if that directive does not explicitly appear in the policy, but is implicitly activated via thedefault-src
directive. - original-policy
- The original policy, as received by the user agent.
- referrer
- The referrer attribute of the protected resource, or the empty string if the protected resource has no referrer.
- status-code
- The
status-code
of the HTTP response that contained the protected resource, if the protected resource was obtained over HTTP. Otherwise, the number 0. - violated-directive
- The policy directive that was violated, as it appears in the
policy. This will contain the
default-src
directive in the case of violations caused by falling back to the default sources when enforcing a directive.
-
If a specific line or a specific file can be identified as the
cause of the violation (for example, script execution that violates
the
script-src
directive), the user agent MAY add the following keys and values to violation:- source-file
- The URL of the resource where the violation occurred, stripped for reporting.
- line-number
- The line number in
source-file
on which the violation occurred. - column-number
- The column number in
source-file
on which the violation occurred.
- Return violation.
Note: blocked-uri
will not contain the final location of a
resource that was blocked after one or more redirects. It instead will
contain only the location that the protected resource requested, before
any redirects were followed.
To send violation reports, the user agent MUST use an algorithm equivalent to the following:
- Prepare a JSON object report object with a single
key,
csp-report
, whose value is the result of generating a violation report object. - Let report body be the JSON stringification of report object.
-
For each report URL in the set of report URLs:
- If the user agent has already sent a violation report for the protected resource to report URL, and that report contained an entity body that exactly matches report body, the user agent MAY abort these steps and continue to the next report URL.
- Queue a task to fetch report URL from the origin of the protected resource,
with the synchronous flag not set, using HTTP method
POST
, with aContent-Type
header field ofapplication/csp-report
, and an entity body consisting of report body. If the origin of report URL is not the same as the origin of the protected resource, the block cookies flag MUST also be set. The user agent MUST NOT follow redirects when fetching this resource. (Note: The user agent ignores the fetched resource.) The task source for these tasks is the Content Security Policy task source.
To report a violation, the user agent MUST:
- Fire a violation event at the protected resource’s
Document
. - If the set of report URLs is non-empty, send violation reports to each.
Note: This section of the specification should not be interpreted as limiting user agents' ability to apply restrictions to violation reports in order to limit data leakage above and beyond what these algorithms specify. For example, a user agent might offer users the option of disabling reporting entirely.
5. Processing Model
To enforce a policy, the user agent MUST parse the policy and enforce each of the directives contained in the policy, where the specific requirements for enforcing each directive are defined separately for each directive (See §7 Directives, below).
Generally speaking, enforcing a directive prevents the protected resource from performing certain actions, such as loading scripts from URLs other than those indicated in a source list. These restrictions make it more difficult for an attacker to abuse an injection vulnerability in the resource because the attacker will be unable to usurp the resource’s privileges that have been restricted in this way.
Note: User agents may allow users to modify or bypass policy enforcement through user preferences, bookmarklets, third-party additions to the user agent, and other such mechanisms.
To monitor a policy, the user agent MUST parse the policy and monitor each of the directives contained in the policy.
Monitoring a directive does not prevent the protected resource from undertaking any actions. Instead, any actions that would have been prevented by the directives are allowed, but a violation report is generated and reported to the developer of the web application. Monitoring a policy is useful for testing whether enforcing the policy will cause the web application to malfunction.
A server MAY cause user agents to monitor one policy while enforcing
another policy by returning both Content-Security-Policy
and Content-Security-Policy-Report-Only
header fields.
For example, if a server operator may wish to enforce one policy but
experiment with a stricter policy, she can monitor the stricter policy while
enforcing the original policy. Once the server operator is satisfied that
the stricter policy does not break the web application, the server operator
can start enforcing the stricter policy.
If the user agent monitors or enforces a policy that does not contain any directives, the user agent SHOULD report a warning message in the developer console.
If the user agent monitors or enforces a policy that contains an unrecognized directive, the user agent SHOULD report a warning message in the developer console indicating the name of the unrecognized directive.
If the user agent monitors or enforces a policy that contains
a directive that contains a source list, then the user agent MUST set
a CSP
Request Header when requesting cross-origin
resources, as described in §3.4 The CSP HTTP Request Header.
5.1. Workers
Whenever a user agent runs a worker:
-
If the worker’s script’s origin is a globally unique identifier (for example, the worker’s script’s URL has a scheme of
data
,blob
, orfilesystem
), then:- If the user agent is enforcing a CSP policy for the owner document or parent worker, the user agent MUST enforce the CSP policy for the worker.
- If the user agent is monitoring a CSP policy for the owner document or parent worker, the user agent MUST monitor the CSP policy for the worker.
-
Otherwise:
- If the worker’s script is delivered with a
Content-Security-Policy
HTTP header containing the value policy, the user agent MUST enforce policy for the worker. - If the worker’s script is delivered with a
Content-Security-Policy-Report-Only
HTTP header containing the value policy, the user agent MUST monitor policy for the worker.
- If the worker’s script is delivered with a
5.2. srcdoc
iframes
Whenever a user agent creates an iframe
srcdoc
document in a browsing context nested in the
protected resource, if the user agent is enforcing any policies for the protected resource, the user agent MUST enforce those policies on the iframe
srcdoc
document as well.
Whenever a user agent creates an iframe
srcdoc
document in a browsing context nested in the
protected resource, if the user agent is monitoring any policies for the
protected resource, the user agent MUST monitor those policies on
the iframe
srcdoc
document as well.
6. Script Interfaces
6.1. Strawman DOM API
This is a sketch of what an API might look like. It is neither complete nor
finalized; take it as an outline for discussion, nothing more. The general
idea is to model CSP as a set of SecurityPolicy
objects, each
composed of a sequence of directives.
The following is what I think we’ll need for source-list directives (§4.2 Source List Syntax). It’ll need some adjustment to deal well with the other directive types.
[ NoInterfaceObject ] interface SecurityPolicySource { }; [Constructor(DOMString sourceExpression)] interface SecurityPolicySourceURL : SecurityPolicySource { boolean matchesURL(DOMString url); readonly attribute DOMString scheme; readonly attribute DOMString host; readonly attribute DOMString port; readonly attribute DOMString path; readonly attribute boolean hostWildcard; readonly attribute boolean portWildcard; }; enum SecurityPolicyHashAlgorithm { "SHA-256", "SHA-384", "SHA-512" }; [Constructor(DOMString sourceExpression)] interface SecurityPolicySourceHash : SecurityPolicySource { boolean matchesNode(Node node); readonly attribute SecurityPolicyHashAlgorithm algorithm; readonly attribute DOMString hash; }; [Constructor(DOMString sourceExpression)] interface SecurityPolicySourceNonce : SecurityPolicySource { boolean matchesNode(Node node); readonly attribute DOMString nonce; };
[ NoInterfaceObject ] interface SecurityPolicyDirective { }; [Constructor(DOMString directiveName, DOMString directiveValue)] interface SecurityPolicySourceListDirective : SecurityPolicyDirective { boolean matchesURL(DOMString url); boolean matchesNode(Node node); readonly attribute boolean allowRedirects; readonly attribute boolean allowEval; // TODO: Bikeshed doesn’t like `Sequence`? readonly attribute SecurityPolicySource[] sources; readonly attribute DOMString directive; };
enum SecurityPolicyMode { "EnforceMode", "ReportOnlyMode" }; [Constructor(DOMString policy, SecurityPolicyMode mode)] interface SecurityPolicy { // Fetch’s 'Request' object has a URL and a RequestContext, which // should be everything we need here to check outgoing network // requests. It lacks a redirect flag; not sure how to model that // yet. TODO. boolean allowRequest(Request request); // Inline checks can be done on a Node basis; given an HTMLScriptElement, // we’d skim through the `script-src` directive’s sources, checking for // hash and nonce matches. boolean allowNode(Node node); // One-offs. Maybe there’s a good way to fold these in somehow? boolean allowEval(); boolean allowInlineEventHandler(); // TODO: Bikeshed doesn’t like `Sequence`? readonly attribute SecurityPolicyDirective[] directives; readonly attribute SecurityPolicyMode mode; readonly attribute URL reportingEndpoint; };
6.2. SecurityPolicyViolationEvent
Interface
[Constructor(DOMString type, optional SecurityPolicyViolationEventInit eventInitDict)] interface SecurityPolicyViolationEvent : Event { readonly attribute DOMString documentURL; readonly attribute DOMString referrer; readonly attribute DOMString blockedURL; readonly attribute DOMString violatedDirective; readonly attribute DOMString effectiveDirective; readonly attribute DOMString originalPolicy; readonly attribute DOMString sourceFile; readonly attribute DOMString statusCode; readonly attribute long lineNumber; readonly attribute long columnNumber; };
- documentURL, of type DOMString, readonly
- Refer to the
document-uri
property of violation reports for a description of this property. - referrer, of type DOMString, readonly
- Refer to the
referrer
property of violation reports for a description of this property. - blockedURL, of type DOMString, readonly
- Refer to the
blocked-uri
property of violation reports for a description of this property. - violatedDirective, of type DOMString, readonly
- Refer to the
violated-directive
property of violation reports for a description of this property. - effectiveDirective, of type DOMString, readonly
- Refer to the
effective-directive
property of violation reports for a description of this property. - originalPolicy, of type DOMString, readonly
- Refer to the
original-policy
property of violation reports for a description of this property. - statusCode, of type DOMString, readonly
- Refer to the
status-code
property of violation reports for a description of this property. - sourceFile, of type DOMString, readonly
- Refer to the
source-file
property of violation reports for a description of this property. - lineNumber, of type long, readonly
- Refer to the
line-number
property of violation reports for a description of this property. - columnNumber, of type long, readonly
- Refer to the
column-number
property of violation reports for a description of this property.
6.3. SecurityPolicyViolationEventInit
Interface
dictionary SecurityPolicyViolationEventInit : EventInit { DOMString documentURL; DOMString referrer; DOMString blockedURL; DOMString violatedDirective; DOMString effectiveDirective; DOMString originalPolicy; DOMString sourceFile; long lineNumber; long columnNumber; };
- documentURL, of type DOMString
- Refer to the
document-uri
property of violation reports for a description of this property. - referrer, of type DOMString
- Refer to the
referrer
property of violation reports for a description of this property. - blockedURL, of type DOMString
- Refer to the
blocked-uri
property of violation reports for a description of this property. - violatedDirective, of type DOMString
- Refer to the
violated-directive
property of violation reports for a description of this property. - effectiveDirective, of type DOMString
- Refer to the
effective-directive
property of violation reports for a description of this property. - originalPolicy, of type DOMString
- Refer to the
original-policy
property of violation reports for a description of this property. - sourceFile, of type DOMString
- Refer to the
source-file
property of violation reports for a description of this property. - lineNumber, of type long
- Refer to the
line-number
property of violation reports for a description of this property. - columnNumber, of type long
- Refer to the
column-number
property of violation reports for a description of this property.
6.4. Firing Violation Events
To fire a violation event, the user agent MUST use an algorithm equivalent to the following:
- Let report object be the result of generating a violation report object.
-
Queue a task to fire an event named
securitypolicyviolation
using theSecurityPolicyViolationEvent
interface with the following initializations:blockedURL
MUST be initialized to the value of report object’sblocked-uri
key.documentURL
MUST be initialized to the value of report object’sdocument-uri
key.effectiveDirective
MUST be initialized to the value of report object’seffective-directive
key.originalPolicy
MUST be initialized to the value of report object’soriginal-policy
key.referrer
MUST be initialized to the value of report object’sreferrer
key.violatedDirective
MUST be initialized to the value of report object’sviolated-directive
key.sourceFile
MUST be initialized to the value of report object’ssource-file
key.lineNumber
MUST be initialized to the value of report object’sline-number
key.columnNumber
MUST be initialized to the value of report object’scolumn-number
key.
The task source for these tasks is the Content Security Policy task source.
7. Directives
This section describes the content security policy directives introduced in this specification. Directive names are case insensitive.
In order to protect against Cross-Site Scripting (XSS), web application authors SHOULD include:
- both the
script-src
andobject-src
directives, or - include a
default-src
directive, which covers both scripts and plugins.
In either case, authors SHOULD NOT include either 'unsafe-inline'
or data:
as valid sources in
their policies. Both enable XSS attacks by allowing code to be included
directly in the document itself; they are best avoided completely.
7.1. base-uri
The base-uri
directive restricts the URLs that can
be used to specify the document base URL. The syntax for
the name and value of the directive are described by the following ABNF
grammar:
directive-name = "base-uri" directive-value = source-list
The term allowed base URLs refers to the result of parsing the base-uri
directive’s
value as a source list.
Note: base-uri
does not fall back to the default
sources.
Step 4 of the algorithm defined in HTML5 to obtain a document’s base URL (resolution of the href
attribute
of the base
element) MUST be changed to:
- If the previous step was not successful, or the result of the previous step does not match the allowed base URLs for the protected resource, then the document base URL is fallback base URL. Otherwise, it is the result of the previous step.
7.2. child-src
The child-src
directive governs the creation of nested browsing contexts as well as Worker execution
contexts. The syntax for the name and value of the directive are described
by the following ABNF grammar:
directive-name = "child-src" directive-value = source-list
The term allowed child sources refers to the result of parsing the child-src
directive’s value as a source list if a child-src
directive is explicitly specified, and otherwise to the default sources.
7.2.1. Nested Browsing Contexts
To enforce the child-src
directive the user agent MUST
enforce the frame-src
directive.
7.2.2. Workers
Whenever the user agent fetches a URL while processing the Worker
or SharedWorker
constructors [WORKERS], the user agent MUST act as if there was a fatal network
error and no resource was obtained, and report a violation if the URL does not match the allowed child sources for the protected resource.
7.3. connect-src
The connect-src
directive restricts which URLs the
protected resource can load using script interfaces. The syntax for the name
and value of the directive are described by the following ABNF grammar:
directive-name = "connect-src" directive-value = source-list
The term allowed connection targets refers to the result of parsing the connect-src
directive’s value as a source list if the policy contains an
explicit connect-src
directive, or otherwise to the default sources.
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed connection targets for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Processing the
send()
method of anXMLHttpRequest
object. - Processing the
WebSocket
constructor. - Processing the
EventSource
constructor. - Pinging an endpoint during hyperlink auditing.
- Sending a beacon via the
sendBeacon()
method. [BEACON]
7.3.1. Usage
This section is not normative.
JavaScript offers a few mechanisms that directly connect to an
external server to send or receive information. EventSource
maintains an open HTTP connection to a server in order to receive push
notifications, WebSockets
open a bidirectional communication
channel between your browser and a server, and XMLHttpRequest
allows arbitrary HTTP requests. These are powerful APIs that
enable useful functionality, but also provide tempting avenues for data
exfiltration.
The connect-src
directive allows restricting these sorts of
connections to the those matching the source expressions list.
Sending a policy that defines a list of source expressions for this
directive is straightforward. For example, to limit connections to
only example.com
, send the following header:
Content-Security-Policy: connect-src example.com
Each of the following will fail with the preceding directive in place:
new WebSocket("wss://evil.com/");
(new XMLHttpRequest()).open("GET", "https://evil.com/", true);
new EventSource("https://evil.com");
7.4. default-src
The default-src
directive sets a default
source list for a number of directives. The syntax for the name and
value of the directive are described by the following ABNF grammar:
directive-name = "default-src" directive-value = source-list
Let the default sources be the result of parsing the default-src
directive’s value as a source list if a default-src
directive is explicitly specified, and otherwise the U+002A ASTERISK
character (*).
To enforce the default-src
directive, the user agent
MUST enforce the following directives:
If not specified explicitly in the policy, the directives listed above will use the default sources as their source list.
7.4.1. Usage
This section is not normative.
default-src
, as the name implies, serves as a default
source list which the other source list-style directives will use as
a fallback if they’re not otherwise explicitly set. That is, consider
the following policy declaration:
Content-Security-Policy: default-src 'self'
Under this policy, fonts, frames, images, media, objects, scripts, and styles will all only load from the same origin as the protected resource, and connections will only be made to the same origin. Adding a more specific declaration to the policy would completely override the default source list for that resource type.
Content-Security-Policy: default-src 'self'; script-src example.com
Under this new policy, fonts, frames, and etc. continue to be load
from the same origin, but scripts will only load from example.com
. There’s no inheritance; the script-src
directive sets the allowed sources of
script, and the default list is not used for that resource type.
Given this behavior, one good way of building a policy for a site
would be to begin with a default-src
of 'none'
, and to build up a policy from there that contains
only those resource types which are actually in use for the page you’d
like to protect. If you don’t use webfonts, for instance, there’s no
reason to specify a source list for font-src
;
specifying only those resource types a page uses ensures that the
possible attack surface for that page remains as small as possible.
7.5. font-src
The font-src
directive restricts from where the
protected resource can load fonts. The syntax for the name and value
of the directive are described by the following ABNF grammar:
directive-name = "font-src" directive-value = source-list
The term allowed font sources refers to the result of parsing the font-src
directive’s value as a source list if the policy contains an
explicit font-src
, or otherwise to the default sources.
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed font sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Requesting data for display in a font, such as when processing the <<@font-face>> Cascading Style Sheets (CSS) rule.
7.6. form-action
The form-action
restricts which URLs can be used as
the action of HTML form
elements. The syntax for the name and value of
the directive are described by the following ABNF grammar:
directive-name = "form-action" directive-value = source-list
The term allowed form actions refers to the result of parsing the form-action
directive’s value as a source list.
Whenever the user agent fetches a URL in the course of processing
an HTML form
element, if the URL does not match the allowed form actions for
the protected resource, the user agent MUST act as if there was a
fatal network error and no resource was obtained, and report a
violation.
Note: form-action
does not fall back to the default
sources when the directive is not defined. That is, a policy that
defines default-src 'none'
but not form-action
will still allow form submissions to any
target.
7.7. frame-ancestors
The frame-ancestors
directive indicates whether the
user agent should allow embedding the resource using a frame
, iframe
, object
, embed
or applet
element, or equivalent
functionality in non-HTML resources. Resources can use this directive to
avoid many UI Redressing [UIREDRESS] attacks by avoiding being embedded
into potentially hostile contexts.
The syntax for the name and value of the directive are described by the following ABNF grammar:
ancestor-source-list = [ ancestor-source *( 1*WSP ancestor-source ) ] / "'none'" ancestor-source = scheme-source / host-source / "'self'" directive-name = "frame-ancestors" directive-value = ancestor-source-list
The term allowed frame ancestors refers to the result of parsing the frame-ancestors
directive’s value as a source list. If a frame-ancestors
directive is not explicitly included in the policy, then allowed frame
ancestors is "*
".
To enforce the frame-ancestors
directive, whenever the
user agent would load the protected resource into a nested browsing
context, the user agent MUST perform the following steps:
- Let nestedContext be the nested browsing context into which the protected resource is being loaded.
- Let ancestorList be the list of all ancestors of nestedContext.
-
For each ancestorContext in ancestorList:
- Let document be ancestorContext’s active document.
-
If document’s URL does not match the allowed frame
ancestors for the protected resource, the user agent MUST:
- Abort loading the protected resource.
-
Take one of the following actions:
- Act as if it received an empty HTTP 200 response.
- Redirect the user to a friendly error page which provides the option of opening the blocked page in a new top-level browsing context.
- Parse a sandboxing directive using the empty string as the input and the newly created document’s forced sandboxing flag set as the output.
- Report a violation.
- Abort these steps.
Steps 3.2.2 and 3.2.3 ensure that the blocked frame appears to be a normal cross-origin document load. If these steps are ignored, leakage of a document’s policy state is possible.
The frame-ancestors
directive MUST be ignored
when monitoring a policy, and when a contained in a
policy defined via a meta
element.
Note: frame-ancestors
does not fall back to the default sources when the directive is not defined. That is, a policy
that defines default-src 'none'
but not frame-ancestors
will still allow the resource to be framed from
anywhere.
When generating a violation report for a frame-ancestors
violation, the user agent MUST NOT include the value of the embedding
ancestor as a blocked-uri
value unless it is same-origin with
the protected resource, as disclosing the value of cross-origin ancestors
is a violation of the Same-Origin Policy.
7.7.1. Relation to X-Frame-Options
This directive is similar to the X-Frame-Options
header that
several user agents have implemented. The 'none'
source
expression is roughly equivalent to that header’s DENY
, 'self'
to SAMEORIGIN
, and so on. The major
difference is that many user agents implement SAMEORIGIN
such
that it only matches against the top-level document’s location. This
directive checks each ancestor. If any ancestor doesn’t match, the load
is cancelled. [RFC7034]
The frame-ancestors
directive obsoletes the X-Frame-Options
header. If a resource has both policies,
the frame-ancestors
policy SHOULD be enforced and the X-Frame-Options
policy SHOULD be ignored.
7.7.2. Multiple Host Source Values
This section is not normative.
Multiple source-list expressions are allowed in a single policy (in contrast
to X-Frame-Options
, which allows only one) to enable
scenarios involving embedded application components that are multiple levels
below the top-level browsing context.
Many common scenarios for embedding (e.g. embeddable payment,
sharing or social apps) involve potentially many hundreds or thousands of
valid source-list
expressions, but it is strongly recommended
against accommodating such scenarios with a static frame-ancestors
directive listing multiple values. In such
cases it is beneficial to generate this value dynamically, based on an
HTTP Referer header or an explicitly passed-in value, to allow only the
sources necessary for each given embedding of the resource.
Consider a service providing a payments application at https://payments/makeEmbedded
. The service allows this resource
to be embedded by both merchant Alice and merchant Bob, who compete with each
other. Sending:
Content-Security-Policy: frame-ancestors https://alice https://bob
would allow Bob to re-frame Alice’s resource and create fraudulent clicks,
perhaps discrediting Alice with her customers or the payments service. If the
payments service used additional information (e.g. as part of a URL like https://payments/makeEmbedded?merchant=alice
) to send
individually-tailored headers listing only the source-list expressions
needed by each merchant, this attack would be eliminated.
7.8. frame-src
The frame-src
directive is deprecated.
Authors who wish to govern nested browsing contexts SHOULD use the child-src
directive instead.
The frame-src
directive restricts from where the
protected resource can embed frames. The syntax for the name
and value of the directive are described by the following ABNF
grammar:
directive-name = "frame-src" directive-value = source-list
The term allowed frame sources refers to the result of parsing the frame-src
directive’s value as a source list if the policy contains an
explicit frame-src
, or otherwise to the list of allowed child sources.
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed frame sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Requesting data for display in a nested browsing context in the
protected resource created by an
iframe
or aframe
element. - Navigated such a nested browsing context.
7.9. img-src
The img-src
directive restricts from where the
protected resource can load images. The syntax for the name and value
of the directive are described by the following ABNF grammar:
directive-name = "img-src" directive-value = source-list
The term allowed image sources refers to the result of parsing the img-src
directive’s value as a source list if the policy contains an
explicit img-src
, or otherwise to the list of default sources.
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed image sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Requesting data for an image, such as when processing the
src
orsrcset
attributes of animg
element, thesrc
attribute of aninput
element with a type ofimage
, theposter
attribute of avideo
element, the url(), image() or image-set() values on any Cascading Style Sheets (CSS) property that is capable of loading an image [CSS4-IMAGES], or thehref
attribute of alink
element with an image-relatedrel
attribute, such asicon
.
7.10. manifest-src
The manifest-src
directive restricts which
application manifest [MANIFEST] the user agent may apply to the protected
resource. The syntax for the name and value of the directive are described by
the following ABNF grammar:
directive-name = "manifest-src" directive-value = source-list
The term allowed manifest sources refers to the result of parsing the manifest-src
directive’s value as a source list if the policy contains an
explicit manifest-src
, or otherwise to the default sources.
Whenever the user agent fetches a URL that does not match the allowed manifest sources in the course of executing the steps for obtaining a manifest, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation.
7.11. media-src
The media-src
directive restricts from where the
protected resource can load video, audio, and associated text tracks.
The syntax for the name and value of the directive are described by the
following ABNF grammar:
directive-name = "media-src" directive-value = source-list
The term allowed media sources refers to the result of parsing the media-src
directive’s value as a source list if the policy contains an
explicit media-src
, or otherwise to the list of default sources.
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed media sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
7.12. object-src
The object-src
directive restricts from where
the protected resource can load plugins. The syntax for the name and value
of the directive are described by the following ABNF grammar:
directive-name = "object-src" directive-value = source-list
The term allowed object sources refers to the result of parsing the object-src
directive’s value as a source list if the policy contains an
explicit object-src
, or otherwise to the list of default sources.
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed object sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Requesting data for a plugin, such as when processing the
data
attribute of anobject
element, thesrc
attribute of anembed
element, or thecode
orarchive
attributes of anapplet
element. - Requesting data for display in a nested browsing context in the protected resource created by an
object
or anembed
element. - Navigating such a nested browsing context.
It is not required that the consumer of the element’s data be a plugin in order for the object-src
directive to be
enforced. Data for any object
, embed
, or applet
element MUST
match the allowed object sources in order to be fetched. This is true
even when the element data is semantically equivalent to content which would
otherwise be restricted by one of the other §7 Directives, such as an object
element with a text/html
MIME type.
Whenever the user agent would load a plugin without an associated
URL (e.g., because the object
element lacked a data
attribute), if the protected resource’s URL does not match the allowed object sources for the protected resource, the user agent MUST NOT load the plugin.
7.13. plugin-types
The plugin-types
directive restricts the set
of plugins that can be invoked by the protected resource by limiting
the types of resources that can be embedded. The syntax for the name
and value of the directive are described by the following ABNF
grammar:
directive-name = "plugin-types" directive-value = media-type-list
The term allowed plugin media types refers to the result of parsing the plugin-types
directive’s value as a media type list.
Whenever the user agent would instantiate a plugin to handle resource while enforcing the plugin-types
directive, the user agent MUST instead act as though the plugin reported an
error and report a violation if any of the following
conditions hold:
- The plugin is embedded into the protected resource via an
object
orembed
element that does not explicitly declare a MIME type via atype
attribute. - resource’s media type does not match the list of allowed plugin media types.
- The plugin is embedded into the protected resource via an
object
orembed
element, and the media type declared in the element’stype
attribute is not an ASCII case-insensitive match for the resource’s media type. - The plugin is embedded into the protected resource via an
applet
element, and resource’s media type is not an ASCII case-insensitive match forapplication/x-java-applet
.
Note: In any of these cases, acting as though the plugin reported an error will cause the user agent to display the fallback content.
Whenever the user agent creates a plugin document as the active document of a child browsing context of the protected resource, if the user agent is enforcing any plugin-types
directives for the protected resource, the user
agent MUST enforce those plugin-types
directives on the
plugin document as well.
Whenever the user agent creates a plugin document as the active document of a child browsing context of the protected resource, if the user agent is monitoring any plugin-types
directives for the protected resource, the user
agent MUST monitor those plugin-types
directives on the
plugin document as well.
7.13.1. Usage
This section is not normative.
The plugin-types
directive whitelists a certain set
of MIME types that can be embedded in a protected resource. For
example, a site might want to ensure that PDF content loads, but that
no other plugins can be instantiated. The following directive would
satisfy that requirement:
Content-Security-Policy: plugin-types application/pdf
Resources embedded via an embed
or object
element delivered with an application/pdf
content type would be rendered in the
appropriate plugin; resources delivered with some other content type
would be blocked. Multiple types can be specified, in any order. If the
site decided to additionally allow Flash at some point in the future, it
could do so with the following directive:
Content-Security-Policy: plugin-types application/pdf application/x-shockwave-flash
Note: Wildcards are not accepted in the plugin-types
directive. Only the resource types explicitly listed in the directive
will be allowed.
7.13.2. Predeclaration of expected media types
This section is not normative.
Enforcing the plugin-types
directive requires that object
and embed
elements declare the expected media type of the resource they include via
the type
attribute. If an author expects
to load a PDF, she could specify this as follows:
<object data="resource" type="application/pdf"></object>
If resource isn’t actually a PDF file, it won’t load. This prevents certain types of attacks that rely on serving content that unexpectedly invokes a plugin other than that which the author intended.
Note: resource will not load in this scenario even if its media type is otherwise whitelisted: resources will only load when their media type is whitelisted and matches the declared type in their containing element.
7.14. reflected-xss
The reflected-xss
directive instructs a user agent
to activate or deactivate any heuristics used to filter or block
reflected cross-site scripting attacks. The syntax for the name and
value of the directive are described by the following ABNF grammar:
directive-name = "reflected-xss" directive-value = "allow" / "block" / "filter"
A user agent with support for XSS protection MUST enforce this directive as follows:
- If the value of the directive is
allow
, the user agent MUST disable its active protections against reflected cross-site scripting attacks for the protected resource. - If the value of the directive is
filter
, the user agent MUST enable its active protections against reflected cross-site scripting attacks for the protected resource. This might result in filtering script that is believed to be reflected being filtered or selectively blocking script execution. - If the value of the directive is
block
, the user agent MUST stop rendering the protected resource upon detection of reflected script, and instead act as if there was a fatal network error and no resource was obtained, and report a violation:
If the user agent’s active protections against reflected cross-site scripting attacks detect or prevent script execution, the user agent MUST report a violation.
Note: The reflected-xss
directive will be ignored if
contained within a meta
element.
7.14.1. Relationship to X-XSS-Protection
This directive is meant to subsume the functionality provided by
the proprietary X-XSS-Protection
HTTP header which is
supported by a number of user agents. Roughly speaking:
reflected-xss allow
is equivalent toX-XSS-Protection: 0
reflected-xss filter
is equivalent toX-XSS-Protection: 1
reflected-xss block
is equivalent toX-XSS-Protection: 1; mode=block
7.15. report-uri
The report-uri
directive specifies a URL to
which the user agent sends reports about policy violation. The syntax
for the name and value of the directive are described by the following
ABNF grammar:
directive-name = "report-uri" directive-value = uri-reference *( 1*WSP uri-reference ) uri-reference = <URL-reference from RFC 3986>
The set of report URLs is the value of the report-uri
directive, each resolved relative to the
protected resource’s URL.
The process of sending violation reports to the URLs specified in this directive’s value is defined in this document’s §4.4 Reporting section.
Note: The report-uri
directive will be ignored if contained
within a meta
element.
7.16. sandbox
The sandbox
directive specifies an HTML
sandbox policy that the user agent applies to the protected resource.
The syntax for the name and value of the directive are described by
the following ABNF grammar:
directive-name = "sandbox" directive-value = "" / sandbox-token *( 1*WSP sandbox-token ) sandbox-token = <token from RFC 7230>
When enforcing the sandbox
directive, the user agent
MUST parse a sandboxing directive using the directive-value
as the input and protected
resource’s forced sandboxing flag set as the output. [HTML5]
The sandbox
directive will be ignored when monitoring a policy, and when contained in a policy defined via a meta
element.
Moreover, this directive has no effect when monitored, and has no
reporting requirements.
7.16.1. Sandboxing and Workers
When delivered via an HTTP header, a Content Security Policy may indicate
that sandboxing flags ought to be applied to a JavaScript execution
environment that is not a Document
. Of particular interest is the
script content intended for use as a Worker, Shared Worker, or Service
Worker. Many of the sandboxing flags do not apply to such environments, but allow-scripts and allow-same-origin have special
requirements.
When a resource is loaded while executing the runs a Worker
algorithm, the user agent MUST act as if there was
a fatal network error and no resource could be obtained if either of the
following conditions holds:
- The
sandbox
directive delivered with the resource does not contain the allow-scripts flag. - The
sandbox
directive delivered with the resource does not contain the allow-same-origin flag, and the creation of the new execution context requires it to be same-origin with its creating context.
7.16.2. Usage
This section is not normative.
HTML5 defines a sandbox
attribute for iframe
elements, intended to allow web authors
to reduce the risk of including potentially untrusted content by imposing
restrictions on that content’s abilities. When the attribute is set,
the content is forced into a unique origin, prevented from submitting
forms, running script, creating or navigating other browsing contexts,
and prevented from running plugins. These restrictions can be loosened
by setting certain flags as the attribute’s value.
The sandbox
directive allows any resource, framed or
not, to ask for the same sorts of restrictions to be applied to
itself.
For example, a message board or email system might provide
downloads of arbitrary attachments provided by other users. Attacks
that rely on tricking a client into rendering one of these attachments
could be mitigated by requesting that resources only be rendered in a
very restrictive sandbox. Sending the sandbox
directive
with an empty value establishes such an environment:
Content-Security-Policy: sandbox
More trusted resources might be allowed to run in an environment
with fewer restrictions by adding allow-*
flags to the
directive’s value. For example, you can allow a page that you trust
to run script, while ensuring that it isn’t treated as same-origin
with the rest of your site. This can be accomplished by sending the sandbox
directive with the allow-scripts
flag:
Content-Security-Policy: sandbox allow-scripts
The set of flags available to the CSP directive should match those
available to the iframe
attribute.
Currently, those include:
Note: Like the rest of Content Security Policy, the sandbox
directive is meant as a defense-in-depth. Web authors would be well-served
to use it in addition to standard sniffing-mitigation and
privilege-reduction techniques.
7.17. script-src
The script-src
directive restricts which scripts the
protected resource can execute. The directive also controls other resources,
such as XSLT style sheets [XSLT], which can cause the user agent to
execute script. The syntax for the name and value of the directive are
described by the following ABNF grammar:
directive-name = "script-src" directive-value = source-list
The term allowed script sources refers to the result of parsing the script-src
directive’s value as a source list if the policy contains an
explicit script-src
, or otherwise to the default
sources.
If 'unsafe-inline'
is not in the
list of allowed script sources, or if at least one nonce-source
or hash-source
is
present in the list of allowed script sources:
- Whenever the user agent would execute an inline script from a
script
element that lacks a valid nonce and lacks a valid hash for the allowed script sources, instead the user agent MUST NOT execute script, and MUST report a violation. - Whenever the user agent would execute an inline script from an inline event handler, instead the user agent MUST NOT execute script, and MUST report a violation.
- Whenever the user agent would execute script contained in a
javascript
URL, instead the user agent MUST NOT execute the script, and MUST report a violation.
If 'unsafe-eval'
is not in allowed script
sources:
- Instead of evaluating their arguments, both operator
eval
and functioneval
[ECMA-262] MUST throw anEvalError
exception. - When called as a constructor, the function
Function
[ECMA-262] MUST throw anEvalError
exception. - When called with a first argument which returns
false
when passed into IsCallable() (a string, for example), thesetTimeout()
function MUST return zero without creating a timer. - When called with a first argument which returns
false
when passed into IsCallable() (a string, for example), thesetInterval()
function MUST return zero without creating a timer.
Whenever the user agent fetches a URL (including when following redirects) in the course of one of the following activities, if the URL does not match the allowed script sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Requesting a script while processing the
src
attribute of ascript
element that lacks a valid nonce for the allowed script sources. - Requesting a script while invoking the
importScripts
method on a WorkerGlobalScope object. [WORKERS] - Requesting an HTML component, such as
when processing the
href
attribute of alink
element with arel
attribute containing the tokenimport
. [HTML-IMPORTS] - Requesting an Extensible Stylesheet Language Transformations
(XSLT) [XSLT], such as when processing the
<?xml-stylesheet?>
processing directive in an XML document [XML11], thehref
attributes on<xsl:include>
and<xsl:import>
elements.
7.17.1. Nonce usage for script
elements
This section is not normative.
The script-src
directive lets developers specify
exactly which script elements on a page were intentionally included
for execution. Ideally, developers would avoid inline script entirely
and whitelist scripts by URL. However, in some cases, removing inline
scripts can be difficult or impossible. For those cases, developers can
whitelist scripts using a randomly generated nonce.
Usage is straightforward. For each request, the server
generates a unique value at random, and includes it in the Content-Security-Policy
header:
Content-Security-Policy: default-src 'self'; script-src 'self' https://example.com 'nonce-$RANDOM'
This same value is then applied as a nonce
attribute
to each script
element that ought to be
executed. For example, if the server generated the random value Nc3n83cnSAd3wc3Sasdfn939hc3
, the server would send the
following policy:
Content-Security-Policy: default-src 'self'; script-src 'self' https://example.com 'nonce-Nc3n83cnSAd3wc3Sasdfn939hc3'
Script elements can then execute either because their src
URLs
are whitelisted or because they have a valid nonce:
<script> alert("Blocked because the policy doesn’t have 'unsafe-inline'.") </script> <script nonce="EDNnf03nceIOfn39fn3e9h3sdfa"> alert("Still blocked because nonce is wrong.") </script> <script nonce="Nc3n83cnSAd3wc3Sasdfn939hc3"> alert("Allowed because nonce is valid.") </script> <script src="https://example.com/allowed-because-of-src.js"></script> <script nonce="EDNnf03nceIOfn39fn3e9h3sdfa" src="https://elsewhere.com/blocked-because-nonce-is-wrong.js"></script> <script nonce="Nc3n83cnSAd3wc3Sasdfn939hc3" src="https://elsewhere.com/allowed-because-nonce-is-valid.js"></script>
Note that the nonce’s value is not a hash or signature that verifies the contents of the script resources. It’s quite simply a random string that informs the user agent which scripts were intentionally included in the page.
Script elements with the proper nonce execute, regardless of whether they’re inline or external. Script elements without the proper nonce don’t execute unless their URLs are whitelisted. Even if an attacker is able to inject markup into the protected resource, the attack will be blocked by the attacker’s inability to guess the random value.
7.17.2. Hash usage for script
elements
This section is not normative.
The script-src
directive lets developers whitelist a
particular inline script by specifying its hash as an allowed source
of script.
Usage is straightforward. The server computes the hash of a
particular script block’s contents, and includes the base64 encoding
of that value in the Content-Security-Policy
header:
Content-Security-Policy: default-src 'self'; script-src 'self' https://example.com 'sha256-base64 encoded hash'
Each inline script block’s contents are hashed, and compared against
the whitelisted value. If there’s a match, the script is executed. For
example, the SHA-256 digest of alert('Hello, world.');
is qznLcsROx4GACP2dm0UCKCzCG+HiZ1guq6ZZDob/Tng=
.
openssl
program. For example:
echo -n "alert('Hello, world.');" | openssl dgst -sha256 -binary | openssl enc -base64
If the server sent the following header:
Content-Security-Policy: script-src 'sha256-qznLcsROx4GACP2dm0UCKCzCG+HiZ1guq6ZZDob/Tng='
Then the following script tag would result in script execution:
<script>alert('Hello, world.');</script>
Whitespace is significant. The following scripts blocks would not hash to the same value, and would therefore not execute:
<script> alert('Hello, world.');</script> <script>alert('Hello, world.'); </script> <script> alert('Hello, world.'); </script> <script> alert('Hello, world.'); </script>
Note also that the hash applies only to inline script. An
externalized script containing the value alert('Hello, world.');
would not execute if its
origin was not whitelisted as a valid source of script.
7.18. style-src
The style-src
directive restricts which styles the
user agent applies to the protected resource. The syntax for the name and
value of the directive are described by the following ABNF grammar:
directive-name = "style-src" directive-value = source-list
The term allowed style sources refers to the result of parsing the style-src
directive’s value as a source list if the policy contains an
explicit style-src
, or otherwise to the default sources.
If 'unsafe-inline'
is not in the
list of allowed style sources, or if at least one nonce-source
or hash-source
is present in the list of allowed style sources:
- Whenever the user agent would apply style from a
style
element that lacks a valid nonce and lacks a valid hash for the allowed style sources, instead the user agentMUST
ignore the style, and MUST report a violation. - Whenever the user agent would apply style from a
style
attribute, instead the user agentMUST
ignore the style, and MUST report a violation.
Note: These restrictions on inline do not prevent the user agent
from applying style from an external stylesheet (e.g., found via <link rel="stylesheet" ...>
).
If 'unsafe-eval'
is not in allowed style
sources, then:
- Whenever the user agent would invoke the Cascading Style Sheets
Object Model algorithms insert a CSS rule, parse a CSS rule, parse a CSS declaration block, or parse a group of selectors instead the user agent MUST throw a SecurityError exception and terminate the algorithm. This would include,
for example, all invocations of CSSOM’s various
cssText
setters andinsertRule
methods. [CSSOM] [HTML5]
Whenever the user agent fetches a URL in the course of one of the following activities, if the URL does not match the allowed style sources for the protected resource, the user agent MUST act as if there was a fatal network error and no resource was obtained, and report a violation:
- Requesting an external stylesheet when processing the href of a link element
whose rel attribute contains the token
stylesheet
. - Requesting an external stylesheet when processing the <<@import>> directive.
-
Requesting an external stylesheet when processing a
Link
HTTP response header field. [RFC5988]Note: As this stylesheet might be prefetched before a
Document
actually exists, user agents will need to carefully consider how to instantiate a meaningful policy against which to compare this request. See §10.1 Processing Complications for more detail.
Note: The style-src
directive does not restrict the
use of XSLT. XSLT is restricted by the script-src
directive because the security consequences of including an untrusted
XSLT stylesheet are similar to those incurred by including an
untrusted script.
7.18.1. Nonce usage for style
elements
This section is not normative.
See the script-src
nonce usage information for detail; the application of nonces
to style
elements is similar enough to avoid
repetition here.
7.18.2. Hash usage for style
elements
This section is not normative.
See the script-src
hash usage information for detail; the application of hashes
to style
elements is similar enough to avoid
repetition here.
8. Examples
8.1. Sample Policy Definitions
This section provides some sample use cases and supporting policies.
Content-Security-Policy: default-src 'self'
Content-Security-Policy: default-src 'self'; img-src *; object-src media1.example.com media2.example.com *.cdn.example.com; script-src trustedscripts.example.com
Content-Security-Policy: default-src https: 'unsafe-inline' 'unsafe-eval'
This policy allows inline content (such as inline script
elements), use of eval
,
and loading resources over https
. Note: This policy does
not provide any protection from cross-site scripting vulnerabilities.
script
elements
wishes to ensure that script is only executed from its own origin, and those
elements it intentionally inserted inline:
Content-Security-Policy: script-src 'self' 'nonce-$RANDOM';
The inline script
elements would then only
execute if they contained a matching nonce
attribute:
<script nonce="$RANDOM">...</script>
8.2. Sample Violation Report
This section contains an example violation report the user agent might send to a server when the protected resource violates a sample policy.
In the following example, the user agent rendered a representation
of the resource http://example.org/page.html
with the
following policy:
default-src 'self'; report-uri http://example.org/csp-report.cgi
The protected resource loaded an image from http://evil.example.com/image.png
, violating the
policy.
{ "csp-report": { "document-uri": "http://example.org/page.html", "referrer": "http://evil.example.com/haxor.html", "blocked-uri": "http://evil.example.com/image.png", "violated-directive": "default-src 'self'", "effective-directive": "img-src", "original-policy": "default-src 'self'; report-uri http://example.org/csp-report.cgi" } }
9. Security Considerations
9.1. Cascading Style Sheet (CSS) Parsing
The style-src
directive restricts the locations from
which the protected resource can load styles. However, if the user agent uses a
lax CSS parsing algorithm, an attacker might be able to trick the user
agent into accepting malicious "stylesheets" hosted by an otherwise
trustworthy origin.
These attacks are similar to the CSS cross-origin data leakage attack described by Chris Evans in 2009. User agents SHOULD defend against both attacks using the same mechanism: stricter CSS parsing rules for style sheets with improper MIME types.
9.2. Violation Reports
The violation reporting mechanism in this document has been
designed to mitigate the risk that a malicious web site could use
violation reports to probe the behavior of other servers. For example,
consider a malicious web site that white lists https://example.com
as a source of images. If the malicious site attempts to load https://example.com/login
as an image, and the example.com
server redirects to an identity provider (e.g., identityprovider.example.net
), CSP will block the request.
If violation reports contained the full blocked URL, the violation
report might contain sensitive information contained in the redirected URL,
such as session identifiers or purported identities. For this reason, the
user agent includes only the origin of the blocked URL.
10. Implementation Considerations
The Content-Security-Policy
header is an end-to-end
header. It is processed and enforced at the client and, therefore,
SHOULD NOT be modified or removed by proxies or other intermediaries not
in the same administrative domain as the resource.
The originating administrative domain for a resource might wish to
apply a Content-Security-Policy
header outside of the
immediate context of an application. For example, a large organization
might have many resources and applications managed by different
individuals or teams but all subject to a uniform organizational
standard. In such situations, a Content-Security-Policy
header might be added or combined with an existing one at a network-edge
security gateway device or web application firewall. To enforce multiple
policies, the administrator SHOULD combine the policy into a single header.
An administrator might wish to use different combination algorithms
depending on his or her intended semantics.
One sensible policy combination algorithm is to start by allowing a default set of sources and then letting individual upstream resource owners expand the set of allowed sources by including additional origins. In this approach, the resultant policy is the union of all allowed origins in the input policies.
Another sensible policy combination algorithm is to intersect the given policies. This approach enforces that content comes from a certain whitelist of origins, for example, preventing developers from including third-party scripts or content in violation of organizational standards and practices. In this approach, the combination algorithm forms the combined policy by removing disallowed hosts from the policies supplied by upstream resource owners.
Interactions between the default-src
and other directives
SHOULD be given special consideration when combining policies. If none
of the policies contains a default-src
directive, adding new
src directives results in a more restrictive policy. However, if one or
more of the input policies contain a default-src
directive,
adding new src directives might result in a less restrictive policy, for
example, if the more specific directive contains a more permissive set of
allowed origins.
Using a more restrictive policy than the input policy authored by the resource owner might prevent the resource from rendering or operating as intended.
Note: Migration to HTTPS
from HTTP
may require updates to the policy in order to keep things running as
before. Source expressions like http://example.com
do not match HTTPS
resources. For example,
administrators SHOULD carefully examine existing policies before rolling
out HTTP Strict Transport Security headers for an application. [RFC6797]
Content-Security-Policy: frame-ancestors https://example.com/ Content-Security-Policy: default-src https:; report-uri https://example.com/
would send violation reports for http
resources, but would not
send violation reports for frame-ancestors
violations.
Note also that combining them via ',
' into the single header
Content-Security-Policy: frame-ancestors https://example.com/, default-src https:; report-uri https://example.com/
would have the same effect, as the comma splits the header during parsing.
10.1. Processing Complications
Many user agents implement some form of optimistic resource fetching algorithm to speed up page loads. In implementing these features, user agents MUST ensure that these optimizations do not alter the behavior of the page’s security policy.
Here, we’ll note a few potential complications that could cause bugs in implementations:
- The frame-ancestor directive MUST take effect before a document is
loaded into a nested browsing context, and certainly before script
is potentially executed. One way to approach this constraint is to perform
the ancestor check defined in §7.7 frame-ancestors while parsing
the document’s headers. This might mean that no document object is
available at all, which can complicate checks against
'self'
, and scheme- or port-relative source expressions. -
Likewise, the
Link
HTTP response header could generate requests for stylesheet resources before a document is available. User agents MUST ensure that any policy contained in the response headers is parsed and effective before these requests are generated. For example, a response returning the following headers:Content-Security-Policy: style-src 'none' Link: <awesome.css>; rel=stylesheet
MUST have the same behavior as a response returning the following headers:
Link: <awesome.css>; rel=stylesheet Content-Security-Policy: style-src 'none'
namely, both must block requests for the stylesheet. To meet this requirement user agents MUST wait until all headers have been processed before beginning to prefetch resources.
11. IANA Considerations
The permanent message header field registry should be updated with the following registrations: [RFC3864]
11.1. Content-Security-Policy
- Header field name
- Content-Security-Policy
- Applicable protocol
- http
- Status
- standard
- Author/Change controller
- W3C
- Specification document
- This specification (See
Content-Security-Policy
Header Field)
11.2. Content-Security-Policy-Report-Only
- Header field name
- Content-Security-Policy-Report-Only
- Applicable protocol
- http
- Status
- standard
- Author/Change controller
- W3C
- Specification document
- This specification (See
Content-Security-Policy-Report-Only
Header Field)
11.3. CSP
- Header field name
- CSP
- Applicable protocol
- http
- Status
- standard
- Author/Change controller
- W3C
- Specification document
- This specification (See §3.4 The CSP HTTP Request Header)
12. Acknowledgements
In addition to the documents in the W3C Web Application Security working group, the work on this document is also informed by the work of the IETF websec working group, particularly that working group’s requirements document: draft-hodges-websec-framework-reqs.
A portion of the frame-ancestors
directive was
originally developed as X-Frame-Options
. [RFC7034]
Brian Smith, Neil Matatall, Anne van Kesteren, and Sigbjørn Vik provided particularly insightful feedback to keep this specification sane.