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gecko-dev/servo/components/net/mime_classifier.rs

1145 строки
39 KiB
Rust
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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
use hyper::mime::TopLevel;
use net_traits::LoadContext;
use std::borrow::ToOwned;
pub struct MimeClassifier {
image_classifier: GroupedClassifier,
audio_video_classifier: GroupedClassifier,
scriptable_classifier: GroupedClassifier,
plaintext_classifier: GroupedClassifier,
archive_classifier: GroupedClassifier,
binary_or_plaintext: BinaryOrPlaintextClassifier,
feeds_classifier: FeedsClassifier,
font_classifier: GroupedClassifier,
}
pub enum MediaType {
Xml,
Html,
AudioVideo,
Image,
}
pub enum ApacheBugFlag {
On,
Off
}
impl ApacheBugFlag {
/// https://mimesniff.spec.whatwg.org/#supplied-mime-type-detection-algorithm
pub fn from_content_type(last_raw_content_type: &[u8]) -> ApacheBugFlag {
if last_raw_content_type == b"text/plain"
|| last_raw_content_type == b"text/plain; charset=ISO-8859-1"
|| last_raw_content_type == b"text/plain; charset=iso-8859-1"
|| last_raw_content_type == b"text/plain; charset=UTF-8" {
ApacheBugFlag::On
} else {
ApacheBugFlag::Off
}
}
}
#[derive(PartialEq)]
pub enum NoSniffFlag {
On,
Off
}
pub type MimeType = (TopLevel, String);
impl MimeClassifier {
//Performs MIME Type Sniffing Algorithm (sections 7 and 8)
pub fn classify(&self,
context: LoadContext,
no_sniff_flag: NoSniffFlag,
apache_bug_flag: ApacheBugFlag,
supplied_type: &Option<MimeType>,
data: &[u8]) -> MimeType {
let supplied_type_or_octet_stream = supplied_type.clone()
.unwrap_or((TopLevel::Application,
"octet-stream".to_owned()));
match context {
LoadContext::Browsing => match *supplied_type {
None => self.sniff_unknown_type(no_sniff_flag, data),
Some(ref supplied_type) => {
let &(ref media_type, ref media_subtype) = supplied_type;
if MimeClassifier::is_explicit_unknown(media_type, media_subtype) {
self.sniff_unknown_type(no_sniff_flag, data)
} else {
match no_sniff_flag {
NoSniffFlag::On => supplied_type.clone(),
NoSniffFlag::Off => match apache_bug_flag {
ApacheBugFlag::On => self.sniff_text_or_data(data),
ApacheBugFlag::Off => match MimeClassifier::get_media_type(media_type,
media_subtype) {
Some(MediaType::Html) => self.feeds_classifier.classify(data),
Some(MediaType::Image) => self.image_classifier.classify(data),
Some(MediaType::AudioVideo) => self.audio_video_classifier.classify(data),
Some(MediaType::Xml) | None => None,
}.unwrap_or(supplied_type.clone())
}
}
}
}
},
LoadContext::Image => {
// Section 8.2 Sniffing an image context
match MimeClassifier::maybe_get_media_type(supplied_type) {
Some(MediaType::Xml) => None,
_ => self.image_classifier.classify(data),
}.unwrap_or(supplied_type_or_octet_stream)
},
LoadContext::AudioVideo => {
// Section 8.3 Sniffing an image context
match MimeClassifier::maybe_get_media_type(supplied_type) {
Some(MediaType::Xml) => None,
_ => self.audio_video_classifier.classify(data),
}.unwrap_or(supplied_type_or_octet_stream)
},
LoadContext::Plugin => {
// 8.4 Sniffing in a plugin context
//
// This section was *not* finalized in the specs at the time
// of this implementation.
match *supplied_type {
None => (TopLevel::Application, "octet-stream".to_owned()),
_ => supplied_type_or_octet_stream,
}
},
LoadContext::Style => {
// 8.5 Sniffing in a style context
//
// This section was *not* finalized in the specs at the time
// of this implementation.
match *supplied_type {
None => (TopLevel::Text, "css".to_owned()),
_ => supplied_type_or_octet_stream,
}
},
LoadContext::Script => {
// 8.6 Sniffing in a script context
//
// This section was *not* finalized in the specs at the time
// of this implementation.
match *supplied_type {
None => (TopLevel::Text, "javascript".to_owned()),
_ => supplied_type_or_octet_stream,
}
},
LoadContext::Font => {
// 8.7 Sniffing in a font context
match MimeClassifier::maybe_get_media_type(supplied_type) {
Some(MediaType::Xml) => None,
_ => self.font_classifier.classify(data),
}.unwrap_or(supplied_type_or_octet_stream)
},
LoadContext::TextTrack => {
// 8.8 Sniffing in a text track context
//
// This section was *not* finalized in the specs at the time
// of this implementation.
(TopLevel::Text, "vtt".to_owned())
},
LoadContext::CacheManifest => {
// 8.9 Sniffing in a cache manifest context
//
// This section was *not* finalized in the specs at the time
// of this implementation.
(TopLevel::Text, "cache-manifest".to_owned())
},
}
}
pub fn new() -> MimeClassifier {
MimeClassifier {
image_classifier: GroupedClassifier::image_classifer(),
audio_video_classifier: GroupedClassifier::audio_video_classifier(),
scriptable_classifier: GroupedClassifier::scriptable_classifier(),
plaintext_classifier: GroupedClassifier::plaintext_classifier(),
archive_classifier: GroupedClassifier::archive_classifier(),
binary_or_plaintext: BinaryOrPlaintextClassifier,
feeds_classifier: FeedsClassifier,
font_classifier: GroupedClassifier::font_classifier()
}
}
pub fn validate(&self) -> Result<(), String> {
try!(self.image_classifier.validate());
try!(self.audio_video_classifier.validate());
try!(self.scriptable_classifier.validate());
try!(self.plaintext_classifier.validate());
try!(self.archive_classifier.validate());
try!(self.binary_or_plaintext.validate());
try!(self.feeds_classifier.validate());
try!(self.font_classifier.validate());
Ok(())
}
//some sort of iterator over the classifiers might be better?
fn sniff_unknown_type(&self, no_sniff_flag: NoSniffFlag, data: &[u8]) -> MimeType {
let should_sniff_scriptable = no_sniff_flag == NoSniffFlag::Off;
let sniffed = if should_sniff_scriptable {
self.scriptable_classifier.classify(data)
} else {
None
};
sniffed.or_else(|| self.plaintext_classifier.classify(data))
.or_else(|| self.image_classifier.classify(data))
.or_else(|| self.audio_video_classifier.classify(data))
.or_else(|| self.archive_classifier.classify(data))
.or_else(|| self.binary_or_plaintext.classify(data))
.expect("BinaryOrPlaintextClassifier always succeeds")
}
fn sniff_text_or_data(&self, data: &[u8]) -> MimeType {
self.binary_or_plaintext.classify(data).expect("BinaryOrPlaintextClassifier always succeeds")
}
fn is_xml(tp: &TopLevel, sub_tp: &str) -> bool {
sub_tp.ends_with("+xml") ||
match (tp, sub_tp) {
(&TopLevel::Application, "xml") | (&TopLevel::Text, "xml") => true,
_ => false
}
}
fn is_html(tp: &TopLevel, sub_tp: &str) -> bool {
*tp == TopLevel::Text && sub_tp == "html"
}
fn is_image(tp: &TopLevel) -> bool {
*tp == TopLevel::Image
}
fn is_audio_video(tp: &TopLevel, sub_tp: &str) -> bool {
*tp == TopLevel::Audio ||
*tp == TopLevel::Video ||
(*tp == TopLevel::Application && sub_tp == "ogg")
}
fn is_explicit_unknown(tp: &TopLevel, sub_tp: &str) -> bool {
if let TopLevel::Ext(ref e) = *tp {
return e == "unknown" && sub_tp == "unknown";
}
match (tp, sub_tp) {
(&TopLevel::Application, "unknown") |
(&TopLevel::Star, "*") => true,
_ => false
}
}
fn get_media_type(media_type: &TopLevel,
media_subtype: &str) -> Option<MediaType> {
if MimeClassifier::is_xml(media_type, media_subtype) {
Some(MediaType::Xml)
} else if MimeClassifier::is_html(media_type, media_subtype) {
Some(MediaType::Html)
} else if MimeClassifier::is_image(media_type) {
Some(MediaType::Image)
} else if MimeClassifier::is_audio_video(media_type, media_subtype) {
Some(MediaType::AudioVideo)
} else {
None
}
}
fn maybe_get_media_type(supplied_type: &Option<MimeType>) -> Option<MediaType> {
supplied_type.as_ref().and_then(|&(ref media_type, ref media_subtype)| {
MimeClassifier::get_media_type(media_type, media_subtype)
})
}
}
pub fn as_string_option(tup: Option<(TopLevel, &'static str)>) -> Option<MimeType> {
tup.map(|(a, b)| (a.to_owned(), b.to_owned()))
}
//Interface used for composite types
trait MIMEChecker {
fn classify(&self, data: &[u8]) -> Option<MimeType>;
/// Validate the MIME checker configuration
fn validate(&self) -> Result<(), String>;
}
trait Matches {
fn matches(&mut self, matches: &[u8]) -> bool;
}
impl <'a, T: Iterator<Item=&'a u8> + Clone> Matches for T {
// Matching function that works on an iterator.
// see if the next matches.len() bytes in data_iterator equal matches
// move iterator and return true or just return false
//
// Params
// self: an iterator
// matches: a vector of bytes to match
//
// Return
// true if the next n elements of self match n elements of matches
// false otherwise
//
// Side effects
// moves the iterator when match is found
fn matches(&mut self, matches: &[u8]) -> bool {
if self.clone().nth(matches.len()).is_none() {
// there are less than matches.len() elements in self
return false
}
let result = self.clone().zip(matches).all(|(s, m)| *s == *m);
if result {
self.nth(matches.len());
}
result
}
}
struct ByteMatcher {
pattern: &'static [u8],
mask: &'static [u8],
leading_ignore: &'static [u8],
content_type: (TopLevel, &'static str)
}
impl ByteMatcher {
fn matches(&self, data: &[u8]) -> Option<usize> {
if data.len() < self.pattern.len() {
None
} else if data == self.pattern {
Some(self.pattern.len())
} else {
data[..data.len() - self.pattern.len() + 1].iter()
.position(|x| !self.leading_ignore.contains(x))
.and_then(|start|
if data[start..].iter()
.zip(self.pattern.iter()).zip(self.mask.iter())
.all(|((&data, &pattern), &mask)| (data & mask) == pattern) {
Some(start + self.pattern.len())
} else {
None
})
}
}
}
impl MIMEChecker for ByteMatcher {
fn classify(&self, data: &[u8]) -> Option<MimeType> {
self.matches(data).map(|_| {
(self.content_type.0.to_owned(), self.content_type.1.to_owned())
})
}
fn validate(&self) -> Result<(), String> {
if self.pattern.len() == 0 {
return Err(format!(
"Zero length pattern for {}/{}",
self.content_type.0, self.content_type.1
))
}
if self.pattern.len() != self.mask.len() {
return Err(format!(
"Unequal pattern and mask length for {}/{}",
self.content_type.0, self.content_type.1
))
}
if self.pattern.iter().zip(self.mask.iter()).any(
|(&pattern, &mask)| pattern & mask != pattern
) {
return Err(format!(
"Pattern not pre-masked for {}/{}",
self.content_type.0, self.content_type.1
))
}
Ok(())
}
}
struct TagTerminatedByteMatcher {
matcher: ByteMatcher
}
impl MIMEChecker for TagTerminatedByteMatcher {
fn classify(&self, data: &[u8]) -> Option<MimeType> {
self.matcher.matches(data).and_then(|j|
if j < data.len() && (data[j] == b' ' || data[j] == b'>') {
Some((self.matcher.content_type.0.to_owned(),
self.matcher.content_type.1.to_owned()))
} else {
None
})
}
fn validate(&self) -> Result<(), String> {
self.matcher.validate()
}
}
pub struct Mp4Matcher;
impl Mp4Matcher {
pub fn matches(&self, data: &[u8]) -> bool {
if data.len() < 12 {
return false;
}
let box_size = ((data[0] as u32) << 24 | (data[1] as u32) << 16 |
(data[2] as u32) << 8 | (data[3] as u32)) as usize;
if (data.len() < box_size) || (box_size % 4 != 0) {
return false;
}
let ftyp = [0x66, 0x74, 0x79, 0x70];
if !data[4..].starts_with(&ftyp) {
return false;
}
let mp4 = [0x6D, 0x70, 0x34];
data[8..].starts_with(&mp4) ||
data[16..box_size].chunks(4).any(|chunk| chunk.starts_with(&mp4))
}
}
impl MIMEChecker for Mp4Matcher {
fn classify(&self, data: &[u8]) -> Option<MimeType> {
if self.matches(data) {
Some((TopLevel::Video, "mp4".to_owned()))
} else {
None
}
}
fn validate(&self) -> Result<(), String> {
Ok(())
}
}
struct BinaryOrPlaintextClassifier;
impl BinaryOrPlaintextClassifier {
fn classify_impl(&self, data: &[u8]) -> (TopLevel, &'static str) {
if data.starts_with(&[0xFFu8, 0xFEu8]) ||
data.starts_with(&[0xFEu8, 0xFFu8]) ||
data.starts_with(&[0xEFu8, 0xBBu8, 0xBFu8])
{
(TopLevel::Text, "plain")
} else if data.iter().any(|&x| x <= 0x08u8 ||
x == 0x0Bu8 ||
(x >= 0x0Eu8 && x <= 0x1Au8) ||
(x >= 0x1Cu8 && x <= 0x1Fu8)) {
(TopLevel::Application, "octet-stream")
} else {
(TopLevel::Text, "plain")
}
}
}
impl MIMEChecker for BinaryOrPlaintextClassifier {
fn classify(&self, data: &[u8]) -> Option<MimeType> {
as_string_option(Some(self.classify_impl(data)))
}
fn validate(&self) -> Result<(), String> {
Ok(())
}
}
struct GroupedClassifier {
byte_matchers: Vec<Box<MIMEChecker + Send + Sync>>,
}
impl GroupedClassifier {
fn image_classifer() -> GroupedClassifier {
GroupedClassifier {
byte_matchers: vec![
box ByteMatcher::image_x_icon(),
box ByteMatcher::image_x_icon_cursor(),
box ByteMatcher::image_bmp(),
box ByteMatcher::image_gif89a(),
box ByteMatcher::image_gif87a(),
box ByteMatcher::image_webp(),
box ByteMatcher::image_png(),
box ByteMatcher::image_jpeg(),
]
}
}
fn audio_video_classifier() -> GroupedClassifier {
GroupedClassifier {
byte_matchers: vec![
box ByteMatcher::video_webm(),
box ByteMatcher::audio_basic(),
box ByteMatcher::audio_aiff(),
box ByteMatcher::audio_mpeg(),
box ByteMatcher::application_ogg(),
box ByteMatcher::audio_midi(),
box ByteMatcher::video_avi(),
box ByteMatcher::audio_wave(),
box Mp4Matcher
]
}
}
fn scriptable_classifier() -> GroupedClassifier {
GroupedClassifier {
byte_matchers: vec![
box ByteMatcher::text_html_doctype(),
box ByteMatcher::text_html_page(),
box ByteMatcher::text_html_head(),
box ByteMatcher::text_html_script(),
box ByteMatcher::text_html_iframe(),
box ByteMatcher::text_html_h1(),
box ByteMatcher::text_html_div(),
box ByteMatcher::text_html_font(),
box ByteMatcher::text_html_table(),
box ByteMatcher::text_html_a(),
box ByteMatcher::text_html_style(),
box ByteMatcher::text_html_title(),
box ByteMatcher::text_html_b(),
box ByteMatcher::text_html_body(),
box ByteMatcher::text_html_br(),
box ByteMatcher::text_html_p(),
box ByteMatcher::text_html_comment(),
box ByteMatcher::text_xml(),
box ByteMatcher::application_pdf()
]
}
}
fn plaintext_classifier() -> GroupedClassifier {
GroupedClassifier {
byte_matchers: vec![
box ByteMatcher::text_plain_utf_8_bom(),
box ByteMatcher::text_plain_utf_16le_bom(),
box ByteMatcher::text_plain_utf_16be_bom(),
box ByteMatcher::application_postscript()
]
}
}
fn archive_classifier() -> GroupedClassifier {
GroupedClassifier {
byte_matchers: vec![
box ByteMatcher::application_x_gzip(),
box ByteMatcher::application_zip(),
box ByteMatcher::application_x_rar_compressed()
]
}
}
fn font_classifier() -> GroupedClassifier {
GroupedClassifier {
byte_matchers: vec![
box ByteMatcher::application_font_woff(),
box ByteMatcher::true_type_collection(),
box ByteMatcher::open_type(),
box ByteMatcher::true_type(),
box ByteMatcher::application_vnd_ms_font_object(),
]
}
}
}
impl MIMEChecker for GroupedClassifier {
fn classify(&self, data: &[u8]) -> Option<MimeType> {
self.byte_matchers
.iter()
.filter_map(|matcher| matcher.classify(data))
.next()
}
fn validate(&self) -> Result<(), String> {
for byte_matcher in &self.byte_matchers {
try!(byte_matcher.validate())
}
Ok(())
}
}
enum Match {
Start,
DidNotMatch,
StartAndEnd
}
impl Match {
fn chain<F: FnOnce() -> Match>(self, f: F) -> Match {
if let Match::DidNotMatch = self {
return f();
}
self
}
}
fn eats_until<'a, T>(matcher: &mut T, start: &[u8], end: &[u8]) -> Match
where T: Iterator<Item=&'a u8> + Clone {
if !matcher.matches(start) {
Match::DidNotMatch
} else if end.len() == 1 {
if matcher.any(|&x| x == end[0]) {
Match::StartAndEnd
} else {
Match::Start
}
} else {
while !matcher.matches(end) {
if matcher.next().is_none() {
return Match::Start;
}
}
Match::StartAndEnd
}
}
struct FeedsClassifier;
impl FeedsClassifier {
// Implements sniffing for mislabeled feeds (https://mimesniff.spec.whatwg.org/#sniffing-a-mislabeled-feed)
fn classify_impl(&self, data: &[u8]) -> Option<(TopLevel, &'static str)> {
// Step 4: can not be feed unless length is > 3
if data.len() < 3 {
return None;
}
let mut matcher = data.iter();
// eat the first three acceptable byte sequences if they are equal to UTF-8 BOM
let utf8_bom = &[0xEFu8, 0xBBu8, 0xBFu8];
matcher.matches(utf8_bom);
// continuously search for next "<" until end of matcher
// TODO: need max_bytes to prevent inadvertently examining html document
// eg. an html page with a feed example
loop {
if matcher.find(|&x| *x == b'<').is_none() {
return None;
}
// Steps 5.2.1 to 5.2.4
match eats_until(&mut matcher, b"?", b"?>")
.chain(|| eats_until(&mut matcher, b"!--", b"-->"))
.chain(|| eats_until(&mut matcher, b"!", b">")) {
Match::StartAndEnd => continue,
Match::DidNotMatch => {},
Match::Start => return None
}
// Step 5.2.5
if matcher.matches(b"rss") {
return Some((TopLevel::Application, "rss+xml"));
}
// Step 5.2.6
if matcher.matches(b"feed") {
return Some((TopLevel::Application, "atom+xml"));
}
// Step 5.2.7
if matcher.matches(b"rdf:RDF") {
while matcher.next().is_some() {
match eats_until(&mut matcher,
b"http://purl.org/rss/1.0/",
b"http://www.w3.org/1999/02/22-rdf-syntax-ns#")
.chain(|| eats_until(&mut matcher,
b"http://www.w3.org/1999/02/22-rdf-syntax-ns#",
b"http://purl.org/rss/1.0/")) {
Match::StartAndEnd => return Some((TopLevel::Application, "rss+xml")),
Match::DidNotMatch => {},
Match::Start => return None
}
}
return None;
}
}
}
}
impl MIMEChecker for FeedsClassifier {
fn classify(&self, data: &[u8]) -> Option<MimeType> {
as_string_option(self.classify_impl(data))
}
fn validate(&self) -> Result<(), String> {
Ok(())
}
}
//Contains hard coded byte matchers
//TODO: These should be configured and not hard coded
impl ByteMatcher {
//A Windows Icon signature
fn image_x_icon() -> ByteMatcher {
ByteMatcher {
pattern: b"\x00\x00\x01\x00",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Image, "x-icon"),
leading_ignore: &[]
}
}
//A Windows Cursor signature.
fn image_x_icon_cursor() -> ByteMatcher {
ByteMatcher {
pattern: b"\x00\x00\x02\x00",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Image, "x-icon"),
leading_ignore: &[]
}
}
//The string "BM", a BMP signature.
fn image_bmp() -> ByteMatcher {
ByteMatcher {
pattern: b"BM",
mask: b"\xFF\xFF",
content_type: (TopLevel::Image, "bmp"),
leading_ignore: &[]
}
}
//The string "GIF89a", a GIF signature.
fn image_gif89a() -> ByteMatcher {
ByteMatcher {
pattern: b"GIF89a",
mask: b"\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Image, "gif"),
leading_ignore: &[]
}
}
//The string "GIF87a", a GIF signature.
fn image_gif87a() -> ByteMatcher {
ByteMatcher {
pattern: b"GIF87a",
mask: b"\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Image, "gif"),
leading_ignore: &[]
}
}
//The string "RIFF" followed by four bytes followed by the string "WEBPVP".
fn image_webp() -> ByteMatcher {
ByteMatcher {
pattern: b"RIFF\x00\x00\x00\x00WEBPVP",
mask: b"\xFF\xFF\xFF\xFF\x00\x00\x00\x00\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Image, "webp"),
leading_ignore: &[]
}
}
//An error-checking byte followed by the string "PNG" followed by CR LF SUB LF, the PNG
//signature.
fn image_png() -> ByteMatcher {
ByteMatcher {
pattern: b"\x89PNG\r\n\x1A\n",
mask: b"\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Image, "png"),
leading_ignore: &[]
}
}
// The JPEG Start of Image marker followed by the indicator byte of another marker.
fn image_jpeg() -> ByteMatcher {
ByteMatcher {
pattern: b"\xFF\xD8\xFF",
mask: b"\xFF\xFF\xFF",
content_type: (TopLevel::Image, "jpeg"),
leading_ignore: &[]
}
}
//The WebM signature. [TODO: Use more bytes?]
fn video_webm() -> ByteMatcher {
ByteMatcher {
pattern: b"\x1A\x45\xDF\xA3",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Video, "webm"),
leading_ignore: &[]
}
}
//The string ".snd", the basic audio signature.
fn audio_basic() -> ByteMatcher {
ByteMatcher {
pattern: b".snd",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Audio, "basic"),
leading_ignore: &[]
}
}
//The string "FORM" followed by four bytes followed by the string "AIFF", the AIFF signature.
fn audio_aiff() -> ByteMatcher {
ByteMatcher {
pattern: b"FORM\x00\x00\x00\x00AIFF",
mask: b"\xFF\xFF\xFF\xFF\x00\x00\x00\x00\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Audio, "aiff"),
leading_ignore: &[]
}
}
//The string "ID3", the ID3v2-tagged MP3 signature.
fn audio_mpeg() -> ByteMatcher {
ByteMatcher {
pattern: b"ID3",
mask: b"\xFF\xFF\xFF",
content_type: (TopLevel::Audio, "mpeg"),
leading_ignore: &[]
}
}
//The string "OggS" followed by NUL, the Ogg container signature.
fn application_ogg() -> ByteMatcher {
ByteMatcher {
pattern: b"OggS\x00",
mask: b"\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "ogg"),
leading_ignore: &[]
}
}
//The string "MThd" followed by four bytes representing the number 6 in 32 bits (big-endian),
//the MIDI signature.
fn audio_midi() -> ByteMatcher {
ByteMatcher {
pattern: b"MThd\x00\x00\x00\x06",
mask: b"\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Audio, "midi"),
leading_ignore: &[]
}
}
//The string "RIFF" followed by four bytes followed by the string "AVI ", the AVI signature.
fn video_avi() -> ByteMatcher {
ByteMatcher {
pattern: b"RIFF\x00\x00\x00\x00AVI ",
mask: b"\xFF\xFF\xFF\xFF\x00\x00\x00\x00\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Video, "avi"),
leading_ignore: &[]
}
}
// The string "RIFF" followed by four bytes followed by the string "WAVE", the WAVE signature.
fn audio_wave() -> ByteMatcher {
ByteMatcher {
pattern: b"RIFF\x00\x00\x00\x00WAVE",
mask: b"\xFF\xFF\xFF\xFF\x00\x00\x00\x00\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Audio, "wave"),
leading_ignore: &[]
}
}
// doctype terminated with Tag terminating (TT) Byte
fn text_html_doctype() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<!DOCTYPE HTML",
mask: b"\xFF\xFF\xDF\xDF\xDF\xDF\xDF\xDF\xDF\xFF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// HTML terminated with Tag terminating (TT) Byte: 0x20 (SP)
fn text_html_page() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<HTML",
mask: b"\xFF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// head terminated with Tag Terminating (TT) Byte
fn text_html_head() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<HEAD",
mask: b"\xFF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// script terminated with Tag Terminating (TT) Byte
fn text_html_script() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<SCRIPT",
mask: b"\xFF\xDF\xDF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// iframe terminated with Tag Terminating (TT) Byte
fn text_html_iframe() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<IFRAME",
mask: b"\xFF\xDF\xDF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// h1 terminated with Tag Terminating (TT) Byte
fn text_html_h1() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<H1",
mask: b"\xFF\xDF\xFF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// div terminated with Tag Terminating (TT) Byte
fn text_html_div() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<DIV",
mask: b"\xFF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// font terminated with Tag Terminating (TT) Byte
fn text_html_font() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<FONT",
mask: b"\xFF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// table terminated with Tag Terminating (TT) Byte
fn text_html_table() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<TABLE",
mask: b"\xFF\xDF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// a terminated with Tag Terminating (TT) Byte
fn text_html_a() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<A",
mask: b"\xFF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// style terminated with Tag Terminating (TT) Byte
fn text_html_style() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<STYLE",
mask: b"\xFF\xDF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// title terminated with Tag Terminating (TT) Byte
fn text_html_title() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<TITLE",
mask: b"\xFF\xDF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// b terminated with Tag Terminating (TT) Byte
fn text_html_b() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<B",
mask: b"\xFF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// body terminated with Tag Terminating (TT) Byte
fn text_html_body() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<BODY",
mask: b"\xFF\xDF\xDF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// br terminated with Tag Terminating (TT) Byte
fn text_html_br() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<BR",
mask: b"\xFF\xDF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// p terminated with Tag Terminating (TT) Byte
fn text_html_p() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<P",
mask: b"\xFF\xDF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
// comment terminated with Tag Terminating (TT) Byte
fn text_html_comment() -> TagTerminatedByteMatcher {
TagTerminatedByteMatcher {
matcher: ByteMatcher {
pattern: b"<!--",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Text, "html"),
leading_ignore: b"\t\n\x0C\r "
}
}
}
//The string "<?xml".
fn text_xml() -> ByteMatcher {
ByteMatcher {
pattern: b"<?xml",
mask: b"\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Text, "xml"),
leading_ignore: b"\t\n\x0C\r "
}
}
//The string "%PDF-", the PDF signature.
fn application_pdf() -> ByteMatcher {
ByteMatcher {
pattern: b"%PDF-",
mask: b"\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "pdf"),
leading_ignore: &[]
}
}
//34 bytes followed by the string "LP", the Embedded OpenType signature.
fn application_vnd_ms_font_object() -> ByteMatcher {
ByteMatcher {
pattern: b"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\
\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\
\x00\x00LP",
mask: b"\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\
\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\
\x00\x00\xFF\xFF",
content_type: (TopLevel::Application, "vnd.ms-fontobject"),
leading_ignore: &[]
}
}
//4 bytes representing the version number 1.0, a TrueType signature.
fn true_type() -> ByteMatcher {
ByteMatcher {
pattern: b"\x00\x01\x00\x00",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "font-sfnt"),
leading_ignore: &[]
}
}
//The string "OTTO", the OpenType signature.
fn open_type() -> ByteMatcher {
ByteMatcher {
pattern: b"OTTO",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "font-sfnt"),
leading_ignore: &[]
}
}
// The string "ttcf", the TrueType Collection signature.
fn true_type_collection() -> ByteMatcher {
ByteMatcher {
pattern: b"ttcf",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "font-sfnt"),
leading_ignore: &[]
}
}
// The string "wOFF", the Web Open Font Format signature.
fn application_font_woff() -> ByteMatcher {
ByteMatcher {
pattern: b"wOFF",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "font-woff"),
leading_ignore: &[]
}
}
//The GZIP archive signature.
fn application_x_gzip() -> ByteMatcher {
ByteMatcher {
pattern: b"\x1F\x8B\x08",
mask: b"\xFF\xFF\xFF",
content_type: (TopLevel::Application, "x-gzip"),
leading_ignore: &[]
}
}
//The string "PK" followed by ETX EOT, the ZIP archive signature.
fn application_zip() -> ByteMatcher {
ByteMatcher {
pattern: b"PK\x03\x04",
mask: b"\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "zip"),
leading_ignore: &[]
}
}
//The string "Rar " followed by SUB BEL NUL, the RAR archive signature.
fn application_x_rar_compressed() -> ByteMatcher {
ByteMatcher {
pattern: b"Rar \x1A\x07\x00",
mask: b"\xFF\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "x-rar-compressed"),
leading_ignore: &[]
}
}
// The string "%!PS-Adobe-", the PostScript signature.
fn application_postscript() -> ByteMatcher {
ByteMatcher {
pattern: b"%!PS-Adobe-",
mask: b"\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF",
content_type: (TopLevel::Application, "postscript"),
leading_ignore: &[]
}
}
// UTF-16BE BOM
fn text_plain_utf_16be_bom() -> ByteMatcher {
ByteMatcher {
pattern: b"\xFE\xFF\x00\x00",
mask: b"\xFF\xFF\x00\x00",
content_type: (TopLevel::Text, "plain"),
leading_ignore: &[]
}
}
//UTF-16LE BOM
fn text_plain_utf_16le_bom() -> ByteMatcher {
ByteMatcher {
pattern: b"\xFF\xFE\x00\x00",
mask: b"\xFF\xFF\x00\x00",
content_type: (TopLevel::Text, "plain"),
leading_ignore: &[]
}
}
//UTF-8 BOM
fn text_plain_utf_8_bom() -> ByteMatcher {
ByteMatcher {
pattern: b"\xEF\xBB\xBF\x00",
mask: b"\xFF\xFF\xFF\x00",
content_type: (TopLevel::Text, "plain"),
leading_ignore: &[]
}
}
}
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