Content-Type Processing Model
Univeristy of California, Berkeley
abarth@eecs.berkeley.eduhttp://www.adambarth.com/
Google, Inc.
ian@hixie.chhttp://ln.hixie.ch/Working GroupInternet-DraftMany Web servers supply incorrect Content-Type headers with their
HTTP responses. In order to be compatible with these Web servers, Web
browsers must consider the content of HTTP responses as well as the
Content-Type header when determining the effective mime type of the
response. This document describes an algorithm for determining the
effective mime type of HTTP responses that balances security and
compatibility considerations.The HTTP Content-Type header indicates the mime type of an HTTP
responses. However, many HTTP servers supply a Content-Type that does
not match the actual contents of the response. Historically, Web
browsers have been tolerated these servers by examining the content of
HTTP responses in addition to the Content-Type header to determine the
effective mime type of the response.Without a clear specification of how to "sniff" the mime type, each
browser vendor was forced to reverse engineer the behavior of the
other borwsers and to developed their own algorithm. These divergent
algorithms have lead to a lack of interoperability between browsers
and to security issues when the site intends an HTTP response to be
interpreted as one mime type but the browser interpretes the responses
as another mime type.These security issues are must severe when a Web site lets users
upload files and then serves the contents of those files with a
low-privilege mime type (such as text/plain or image/jpeg). In the
absense of mime sniffing, this user-generated content will not be able
to run JavaScript, but if the browser treats the response as
text/html, then the user can mount a cross-site scripting attack by
including JavaScript code in the uploaded file.This document describes a mime sniffing algorithm that carefully
balances the compatibility needs of browser vendors with the security
constraints. The algorithm has been constructed with reference to
mime sniffing algorithms present in popular Web browsers, an extensive
database of Web content, and metrics collected from implementations
deployed to a sizable number of Web users.Warning! It is imperative that the algorithm in this document be
followed exactly. When a user agent uses different heuristics for
content type detection than the server expects, security problems can
occur. For example, if a server believes that the client will treat a
contributed file as an image (and thus treat it as benign), but a Web
browser believes the content to be HTML (and thus execute any scripts
contained therein), the end user can be exposed to malicious content,
making the user vulnerable to cookie theft attacks and other
cross-site scripting attacks.What explicit Content-Type metadata is associated with the resource
(the resource's type information) depends on the protocol that was
used to fetch the resource.For HTTP resources, only the first Content-Type HTTP header, if
any, contributes any type information; the explicit type of the
resource is then the value of that header, interpreted as described by
the HTTP specifications. If the Content-Type HTTP header is present
but the value of the first such header cannot be interpreted as
described by the HTTP specifications (e.g. because its value doesn't
contain a U+002F SOLIDUS ('/') character), then the resource has no
type information (even if there are multiple Content-Type HTTP headers
and one of the other ones is syntactically correct). [HTTP]For resources fetched from the file system, user agents should use
platform-specific conventions, e.g. operating system extension/type
mappings.Extensions must not be used for determining resource types for
resources fetched over HTTP.For resources fetched over most other protocols, e.g. FTP, there is
no type information.The algorithm for extracting an encoding from a Content-Type, given
a string s, is as follows. It either returns an encoding or nothing.
Find the first seven characters in s that are an ASCII
case-insensitive match for the word "charset". If no such match is
found, return nothing.Skip any U+0009, U+000A, U+000C, U+000D, or U+0020 characters
that immediately follow the word 'charset' (there might not be
any).If the next character is not a U+003D EQUALS SIGN ('='), return
nothing.Skip any U+0009, U+000A, U+000C, U+000D, or U+0020 characters
that immediately follow the equals sign (there might not be
any).Process the next character as follows:
If it is a U+0022 QUOTATION MARK ('"') and there is a later
U+0022 QUOTATION MARK ('"') in s, orIf it is a U+0027 APOSTROPHE ("'") and there is a later U+0027
APOSTROPHE ("'") in s
Return the string between this character and the next
earliest occurrence of this character.If it is an unmatched U+0022 QUOTATION MARK ('"'),If it is an unmatched U+0027 APOSTROPHE ("'"), orIf there is no next character
Return nothing.Otherwise
Return the string from this character to the first U+0009,
U+000A, U+000C, U+000D, U+0020, or U+003B character or the end
of s, whichever comes first.Note: The above algorithm is a willful violation of the HTTP
specification. [RFC2616]The sniffed type of a resource must be found as follows:
If the user agent is configured to strictly obey Content-Type
headers for this resource, then jump to the last step in this set of
steps.If the resource was fetched over an HTTP protocol and there is an
HTTP Content-Type header and the value of the first such header has
bytes that exactly match one of the following lines:
Let official type be the type given by the Content-Type metadata
for the resource, ignoring parameters. If there is no such type,
jump to the unknown type step below. Comparisons with this type, as
defined by MIME specifications, are done in an ASCII
case-insensitive manner. [RFC2046]If official type is "unknown/unknown" or "application/unknown",
jump to the unknown type step below.If official type ends in "+xml", or if it is either "text/xml" or
"application/xml", then the sniffed type of the resource is official
type; return that and abort these steps.If official type is an image type supported by the user agent
(e.g. "image/png", "image/gif", "image/jpeg", etc), then jump to
the "images" section below, passing it the official type.If official type is "text/html", then jump to the feed or HTML
section below.The sniffed type of the resource is official type.The user agent may wait for 512 or more bytes of the resource to
be available.Let n be the smaller of either 512 or the number of bytes already
available.If n is 4 or more, and the first bytes of the resource match one
of the following byte sets:
If none of the first n bytes of the resource are binary data
bytes then the sniffed type of the resource is "text/plain". Abort
these steps.
If the first bytes of the resource match one of the byte
sequences in the "pattern" column of the table in the unknown type
section below, ignoring any rows whose cell in the "security" column
says "scriptable" (or "n/a"), then the sniffed type of the resource
is the type given in the corresponding cell in the "sniffed type"
column on that row; abort these steps.
Warning! It is critical that this step not ever return a
scriptable type (e.g. text/html), as otherwise that would allow a
privilege escalation attack.Otherwise, the sniffed type of the resource is
"application/octet-stream".The user agent may wait for 512 or more bytes of the resource to
be available.Let stream length be the smaller of either 512 or the number of
bytes already available.For each row in the table below:
If the row has no "WS" bytes:
Let pattern length be the length of the pattern (number of
bytes described by the cell in the second column of the
row).If stream length is smaller than pattern length then skip
this row.Apply the "and" operator to the first pattern length bytes of
the resource and the given mask (the bytes in the cell of first
column of that row), and let the result be the data.If the bytes of the data matches the given pattern bytes
exactly, then the sniffed type of the resource is the type given
in the cell of the third column in that row; abort these
steps.If the row has a "WS" byte:
Let index_pattern be an index into the mask and pattern byte
strings of the row.Let index_stream be an index into the byte stream being
examined.Loop: If indexstream points beyond the end of the byte
stream, then this row doesn't match, skip this row.Examine the indexstreamth byte of the byte stream as
follows:
If the index_patternth byte of the pattern is a normal
hexadecimal byte and not a "WS" byte:
If the "and" operator, applied to the index_streamth byte
of the stream and the index_patternth byte of the mask,
yield a value different that the index_patternth byte of the
pattern, then skip this row.Otherwise, increment index_pattern to the next byte in
the mask and pattern and index_stream to the next byte in
the byte stream.Otherwise, if the indexpatternth byte of the pattern is a
"WS" byte:
"WS" means "whitespace", and allows insignificant
whitespace to be skipped when sniffing for a type
signature.If the index_streamth byte of the stream is one of 0x09
(ASCII TAB), 0x0A (ASCII LF), 0x0C (ASCII FF), 0x0D (ASCII
CR), or 0x20 (ASCII space), then increment only the
index_stream to the next byte in the byte stream.Otherwise, increment only the index_pattern to the next
byte in the mask and pattern.If index_pattern does not point beyond the end of the mask
and pattern byte strings, then jump back to the loop step in
this algorithm.Otherwise, the sniffed type of the resource is the type given
in the cell of the third column in that row; abort these
steps.If none of the first n bytes of the resource are binary data
bytes then the sniffed type of the resource is "text/plain". Abort
these steps.Otherwise, the sniffed type of the resource is
"application/octet-stream".The table used by the above algorithm is:
User agents may support further types if desired, by implicitly
adding to the above table. However, user agents should not use any
other patterns for types already mentioned in the table above, as this
could then be used for privilege escalation (where, e.g., a server
uses the above table to determine that content is not HTML and thus
safe from XSS attacks, but then a user agent detects it as HTML anyway
and allows script to execute).The column marked "security" is used by the algorithm in the "text
or binary" section, to avoid sniffing text/plain content as a type
that can be used for a privilege escalation attack.If the resource's official type is "image/svg+xml", then the
sniffed type of the resource is its official type (an XML type).Otherwise, if the first bytes of the resource match one of the byte
sequences in the first column of the following table, then the sniffed
type of the resource is the type given in the corresponding cell in
the second column on the same row:
Otherwise, the sniffed type of the resource is the same as its
official type.The user agent may wait for 512 or more bytes of the resource to
be available.Let s be the stream of bytes, and let s[i] represent the byte in
s with position i, treating s as zero-indexed (so the first byte is
at i=0).If at any point this algorithm requires the user agent to
determine the value of a byte in s which is not yet available, or
which is past the first 512 bytes of the resource, or which is
beyond the end of the resource, the user agent must stop this
algorithm, and assume that the sniffed type of the resource is
"text/html".
Note: User agents are allowed, by the first step of this
algorithm, to wait until the first 512 bytes of the resource are
available.Initialize pos to 0.If s[0] is 0xEF, s[1] is 0xBB, and s[2] is 0xBF, then set pos to
3. (This skips over a leading UTF-8 BOM, if any.)Loop start: Examine s[pos].
If it is 0x09 (ASCII tab), 0x20 (ASCII space), 0x0A (ASCII LF),
or 0x0D (ASCII CR)
Increase pos by 1 and repeat this step.If it is 0x3C (ASCII "<")
Increase pos by 1 and go to the next step.If it is anything else
The sniffed type of the resource is "text/html". Abort these
steps.If the bytes with positions pos to pos+2 in s are exactly equal
to 0x21, 0x2D, 0x2D respectively (ASCII for "!--"), then:
Increase pos by 3.If the bytes with positions pos to pos+2 in s are exactly equal
to 0x2D, 0x2D, 0x3E respectively (ASCII for "-->"), then increase
pos by 3 and jump back to the previous step (the step labeled loop
start) in the overall algorithm in this section.Otherwise, increase pos by 1.Return to step 2 in these substeps.If s[pos] is 0x21 (ASCII "!"):
Increase pos by 1.If s[pos] equal 0x3E, then increase pos by 1 and jump back to
the step labeled loop start in the overall algorithm in this
section.Otherwise, return to step 1 in these substeps.If s[pos] is 0x3F (ASCII "?"):
Increase pos by 1.If s[pos] and s[pos+1] equal 0x3F and 0x3E respectively, then
increase pos by 1 and jump back to the step labeled loop start in
the overall algorithm in this section.Otherwise, return to step 1 in these substeps.Otherwise, if the bytes in s starting at pos match any of the
sequences of bytes in the first column of the following table, then
the user agent must follow the steps given in the corresponding cell
in the second column of the same row.
???? If, before the next ">", you find two xmlns* attributes
with http://www.w3.org/1999/02/22-rdf-syntax-ns# and
http://purl.org/rss/1.0/ as the namespaces, then the sniffed type of
the resource is "application/rss+xml", abort these steps. (maybe we
only need to check for http://purl.org/rss/1.0/ actually) ????Otherwise, the sniffed type of the resource is "text/html".For efficiency reasons, implementations may wish to implement this
algorithm and the algorithm for detecting the character encoding of
HTML documents in parallel.