// Copyright The rust-url developers. // // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your // option. This file may not be copied, modified, or distributed // except according to those terms.
//! This module provides the lower-level API for UTS 46. //! //! [`Uts46::process`] is the core that the other convenience //! methods build on. //! //! UTS 46 flags map to this API as follows: //! //! * _CheckHyphens_ - _true_: [`Hyphens::Check`], _false_: [`Hyphens::Allow`]; the WHATWG URL Standard sets this to _false_ for normal (non-conformance-checker) user agents. //! * _CheckBidi_ - Always _true_; cannot be configured, since this flag is _true_ even when WHATWG URL Standard _beStrict_ is _false_. //! * _CheckJoiners_ - Always _true_; cannot be configured, since this flag is _true_ even when WHATWG URL Standard _beStrict_ is _false_. //! * _UseSTD3ASCIIRules_ - _true_: [`AsciiDenyList::STD3`], _false_: [`AsciiDenyList::EMPTY`]; however, the check the WHATWG URL Standard performs right after the UTS 46 invocation corresponds to [`AsciiDenyList::URL`]. //! * _Transitional_Processing_ - Always _false_ but could be implemented as a preprocessing step. This flag is deprecated and for Web purposes the transition is over in the sense that all of Firefox, Safari, or Chrome set this flag to _false_. //! * _VerifyDnsLength_ - _true_: [`DnsLength::Verify`], _false_: [`DnsLength::Ignore`]; the WHATWG URL Standard sets this to _false_ for normal (non-conformance-checker) user agents. //! * _IgnoreInvalidPunycode_ - Always _false_; cannot be configured. (Not yet covered by the WHATWG URL Standard, but 2 out of 3 major browser clearly behave as if this was _false_).
usecrate::punycode::Decoder; usecrate::punycode::InternalCaller; use alloc::borrow::Cow; use alloc::string::String; use core::fmt::Write; use idna_adapter::*; use smallvec::SmallVec; use utf8_iter::Utf8CharsEx;
/// ICU4C-compatible constraint. (Note: ICU4C measures /// UTF-16 and we measure UTF-32. This means that we /// allow longer non-BMP inputs. For this implementation, /// the denial-of-service scaling does not depend on BMP vs. /// non-BMP: only the scalar values matter.) /// /// https://unicode-org.atlassian.net/browse/ICU-13727 const PUNYCODE_ENCODE_MAX_INPUT_LENGTH: usize = 1000;
/// For keeping track of what kind of numerals have been /// seen in an RTL label. #[derive(Debug, PartialEq, Eq)] enum RtlNumeralState {
Undecided,
European,
Arabic,
}
/// Computes the mask for upper-case ASCII. constfn upper_case_mask() -> u128 { letmut accu = 0u128; letmut b = 0u8; while b < 128 { if (b >= b'A') && (b <= b'Z') {
accu |= 1u128 << b;
}
b += 1;
}
accu
}
/// Bit set for upper-case ASCII. const UPPER_CASE_MASK: u128 = upper_case_mask();
/// Computes the mask for glyphless ASCII. constfn glyphless_mask() -> u128 { letmut accu = 0u128; letmut b = 0u8; while b < 128 { if (b <= b' ') || (b == 0x7F) {
accu |= 1u128 << b;
}
b += 1;
}
accu
}
/// Bit set for glyphless ASCII. const GLYPHLESS_MASK: u128 = glyphless_mask();
/// The mask for the ASCII dot. const DOT_MASK: u128 = 1 << b'.';
/// Computes the ASCII deny list for STD3 ASCII rules. constfn ldh_mask() -> u128 { letmut accu = 0u128; letmut b = 0u8; while b < 128 { if !((b >= b'a' && b <= b'z') || (b >= b'0' && b <= b'9') || b == b'-' || b == b'.') {
accu |= 1u128 << b;
}
b += 1;
}
accu
}
#[inline(always)] fn has_punycode_prefix(slice: &[u8]) -> bool { if slice.len() < 4 { returnfalse;
} // Sadly, the optimizer doesn't figure out that more idiomatic code // should compile to masking on 32-bit value. let a = slice[0]; let b = slice[1]; let c = slice[2]; let d = slice[3]; let u = (u32::from(d) << 24) | (u32::from(c) << 16) | (u32::from(b) << 8) | u32::from(a);
(u & PUNYCODE_PREFIX_MASK) == PUNYCODE_PREFIX
}
#[inline(always)] fn is_passthrough_ascii_label(label: &[u8]) -> bool { // XXX if we aren't performing _CheckHyphens_, this could // check for "xn--" and pass through YouTube CDN node names. if label.len() >= 4 && label[2] == b'-' && label[3] == b'-' { returnfalse;
} iflet Some((&first, tail)) = label.split_first() { // We need to check the first and last character // more strictly in case this turns out to be a // label in a bidi domain name. This has the side // effect that this function only accepts labels // that also conform to the STD3 rules. // // XXX: If we are in the fail-fast mode (i.e. we don't need // to be able to overwrite anything with U+FFFD), we could // merely record that we've seen a digit here and error out // if we later discover that the domain name is a bidi // domain name. if !in_inclusive_range8(first, b'a', b'z') { returnfalse;
} for &b in tail { // If we used LDH_MASK, we'd have to check // the bytes for the ASCII range anyhow. if in_inclusive_range8(b, b'a', b'z') { continue;
} if in_inclusive_range8(b, b'0', b'9') { continue;
} if b == b'-' { continue;
} returnfalse;
}
label.last() != Some(&b'-')
} else { // empty true
}
}
#[inline(always)] fn split_ascii_fast_path_prefix(label: &[u8]) -> (&[u8], &[u8]) { iflet Some(pos) = label.iter().position(|b| !b.is_ascii()) { if pos == 0 { // First is non-ASCII
(&[], label)
} else { // Leave one ASCII character in the suffix // in case it's a letter that a combining // character combines with. let (head, tail) = label.split_at(pos - 1);
(head, tail)
}
} else { // All ASCII
(label, &[])
}
}
// Input known to be lower-case, but may contain non-ASCII. #[inline(always)] fn apply_ascii_deny_list_to_lower_cased_unicode(c: char, deny_list: u128) -> char { iflet Some(shifted) = 1u128.checked_shl(u32::from(c)) { if (deny_list & shifted) == 0 {
c
} else { '\u{FFFD}'
}
} else {
c
}
}
// Input known to be ASCII, but may contain upper case ASCII. #[inline(always)] fn apply_ascii_deny_list_to_potentially_upper_case_ascii(b: u8, deny_list: u128) -> char { if (deny_list & (1u128 << b)) == 0 { return char::from(b);
} if in_inclusive_range8(b, b'A', b'Z') { return char::from(b + 0x20);
} '\u{FFFD}'
}
#[inline(always)] fn is_ascii(label: &[char]) -> bool { for c in label.iter() { if !c.is_ascii() { returnfalse;
}
} true
}
#[inline(always)] fn classify_for_punycode(label: &[char]) -> PunycodeClassification { letmut iter = label.iter().copied(); loop { iflet Some(c) = iter.next() { if c.is_ascii() { continue;
} if c == '\u{FFFD}' { return PunycodeClassification::Error;
} for c in iter { if c == '\u{FFFD}' { return PunycodeClassification::Error;
}
} return PunycodeClassification::Unicode;
} return PunycodeClassification::Ascii;
}
}
/// The ASCII deny list to be applied. #[derive(PartialEq, Eq, Copy, Clone)] #[repr(transparent)] pubstruct AsciiDenyList {
bits: u128,
}
impl AsciiDenyList { /// Computes (preferably at compile time) an ASCII deny list. /// /// Setting `deny_glyphless` to `true` denies U+0020 SPACE and below /// as well as U+007F DELETE for convenience without having to list /// these characters in the `deny_list` string. /// /// `deny_list` is the list of ASCII characters to deny. This /// list must not contain any of: /// * Letters /// * Digits /// * Hyphen /// * Dot (period / full-stop) /// * Non-ASCII /// /// # Panics /// /// If the deny list contains characters listed as prohibited above. pubconstfn new(deny_glyphless: bool, deny_list: &str) -> Self { letmut bits = UPPER_CASE_MASK; if deny_glyphless {
bits |= GLYPHLESS_MASK;
} letmut i = 0; let bytes = deny_list.as_bytes(); while i < bytes.len() { let b = bytes[i];
assert!(b < 0x80, "ASCII deny list must be ASCII."); // assert_ne not yet available in const context.
assert!(b != b'.', "ASCII deny list must not contain the dot.");
assert!(b != b'-', "ASCII deny list must not contain the hyphen.");
assert!(
!((b >= b'0') && (b <= b'9')), "ASCII deny list must not contain digits."
);
assert!(
!((b >= b'a') && (b <= b'z')), "ASCII deny list must not contain letters."
);
assert!(
!((b >= b'A') && (b <= b'Z')), "ASCII deny list must not contain letters."
);
bits |= 1u128 << b;
i += 1;
}
AsciiDenyList { bits }
}
/// No ASCII deny list. This corresponds to _UseSTD3ASCIIRules=false_. /// /// Equivalent to `AsciiDenyList::new(false, "")`. /// /// Note: Not denying the space and control characters can result in /// strange behavior. Without a deny list provided to the UTS 46 /// operation, the caller is expected perform filtering afterwards, /// but it's more efficient to use `AsciiDenyList` than post-processing, /// because the internals of this crate can optimize away checks in /// certain cases. pubconst EMPTY: AsciiDenyList = AsciiDenyList::new(false, "");
/// The STD3 deny list. This corresponds to _UseSTD3ASCIIRules=true_. /// /// Note that this deny list rejects the underscore, which occurs in /// pseudo-hosts used by various TXT record-based protocols, and also /// characters that may occurs in non-DNS naming, such as NetBIOS. pubconst STD3: AsciiDenyList = AsciiDenyList { bits: ldh_mask() };
/// [Forbidden domain code point](https://url.spec.whatwg.org/#forbidden-domain-code-point) from the WHATWG URL Standard. /// /// Equivalent to `AsciiDenyList::new(true, "%#/:<>?@[\\]^|")`. /// /// Note that this deny list rejects IPv6 addresses, so (as in URL /// parsing) you need to check for IPv6 addresses first and not /// put them through UTS 46 processing. pubconst URL: AsciiDenyList = AsciiDenyList::new(true, "%#/:<>?@[\\]^|");
}
/// The _CheckHyphens_ mode. #[derive(PartialEq, Eq, Copy, Clone)] #[non_exhaustive] // non_exhaustive in case a middle mode that prohibits only first and last position needs to be added pubenum Hyphens { /// _CheckHyphens=false_: Do not place positional restrictions on hyphens. /// /// This mode is used by the WHATWG URL Standard for normal User Agent processing /// (i.e. not conformance checking).
Allow,
/// Prohibit hyphens in the first and last position in the label but allow in /// the third and fourth position. /// /// Note that this mode rejects real-world names, including some GitHub user pages.
CheckFirstLast,
/// _CheckHyphens=true_: Prohibit hyphens in the first, third, fourth, /// and last position in the label. /// /// Note that this mode rejects real-world names, including YouTube CDN nodes /// and some GitHub user pages.
Check,
}
/// The UTS 46 _VerifyDNSLength_ flag. #[derive(PartialEq, Eq, Copy, Clone)] #[non_exhaustive] pubenum DnsLength { /// _VerifyDNSLength=false_. (Possibly relevant for allowing non-DNS naming systems.)
Ignore, /// _VerifyDNSLength=true_ with the exception that the trailing root label dot is /// allowed.
VerifyAllowRootDot, /// _VerifyDNSLength=true_. (The trailing root label dot is not allowed.)
Verify,
}
/// Policy for customizing behavior in case of an error. #[derive(PartialEq, Eq, Copy, Clone)] #[non_exhaustive] pubenum ErrorPolicy { /// Return as early as possible without producing output in case of error.
FailFast, /// In case of error, mark errors with the REPLACEMENT CHARACTER. (The output /// containing REPLACEMENT CHARACTERs may be show to the user to illustrate /// what was wrong but must not be used for naming in a network protocol.)
MarkErrors,
}
/// The success outcome of [`Uts46::process`] #[derive(PartialEq, Eq, Copy, Clone, Debug)] pubenum ProcessingSuccess { /// There were no errors. The caller must consider the input to be the output. /// /// This asserts that the input can be safely passed to [`core::str::from_utf8_unchecked`]. /// /// (Distinct from `WroteToSink` in order to allow `Cow` behavior to be implemented on top of /// [`Uts46::process`].)
Passthrough,
/// There were no errors. The caller must consider what was written to the sink to be the output. /// /// (Distinct from `Passthrough` in order to allow `Cow` behavior to be implemented on top of /// [`Uts46::process`].)
WroteToSink,
}
/// The failure outcome of [`Uts46::process`] #[derive(PartialEq, Eq, Copy, Clone, Debug)] pubenum ProcessingError { /// There was a validity error according to the chosen options. /// /// In case of `Operation::ToAscii`, there is no output. Otherwise, output was written to the /// sink and the output contains at least one U+FFFD REPLACEMENT CHARACTER to denote an error.
ValidityError,
/// The sink emitted [`core::fmt::Error`]. The partial output written to the sink must not /// be used.
SinkError,
}
impl From<crate::punycode::PunycodeEncodeError> for ProcessingError { fn from(_: crate::punycode::PunycodeEncodeError) -> Self {
unreachable!( "Punycode overflows should not be possible due to PUNYCODE_ENCODE_MAX_INPUT_LENGTH"
);
}
}
/// Performs the _VerifyDNSLength_ check on the output of the _ToASCII_ operation. /// /// If the second argument is `false`, the trailing root label dot is allowed. /// /// # Panics /// /// Panics in debug mode if the argument isn't ASCII. pubfn verify_dns_length(domain_name: &str, allow_trailing_dot: bool) -> bool { let bytes = domain_name.as_bytes();
debug_assert!(bytes.is_ascii()); let domain_name_without_trailing_dot = iflet Some(without) = bytes.strip_suffix(b".") { if !allow_trailing_dot { returnfalse;
}
without
} else {
bytes
}; if domain_name_without_trailing_dot.len() > 253 { returnfalse;
} for label in domain_name_without_trailing_dot.split(|b| *b == b'.') { if label.is_empty() { returnfalse;
} if label.len() > 63 { returnfalse;
}
} true
}
/// An implementation of UTS #46. pubstruct Uts46 {
data: idna_adapter::Adapter,
}
impl Uts46 { /// Constructor using data compiled into the binary. #[cfg(feature = "compiled_data")] pubconstfn new() -> Self { Self {
data: idna_adapter::Adapter::new(),
}
}
// XXX Should there be an `icu_provider` feature for enabling // a constructor for run-time data loading?
/// Performs the [ToASCII](https://www.unicode.org/reports/tr46/#ToASCII) operation /// from UTS #46 with the options indicated. /// /// # Arguments /// /// * `domain_name` - The input domain name as UTF-8 bytes. (The UTF-8ness is checked by /// this method and input that is not well-formed UTF-8 is treated as an error. If you /// already have a `&str`, call `.as_bytes()` on it.) /// * `ascii_deny_list` - What ASCII deny list, if any, to apply. The UTS 46 /// _UseSTD3ASCIIRules_ flag or the WHATWG URL Standard forbidden domain code point /// processing is handled via this argument. Most callers are probably the best off /// by using [`AsciiDenyList::URL`] here. /// * `hyphens` - The UTS 46 _CheckHyphens_ flag. Most callers are probably the best /// off by using [`Hyphens::Allow`] here. /// * `dns_length` - The UTS 46 _VerifyDNSLength_ flag. pubfn to_ascii<'a>(
&self,
domain_name: &'a [u8],
ascii_deny_list: AsciiDenyList,
hyphens: Hyphens,
dns_length: DnsLength,
) -> Result<Cow<'a, str>, crate::Errors> { letmut s = String::new(); matchself.process(
domain_name,
ascii_deny_list,
hyphens,
ErrorPolicy::FailFast,
|_, _, _| false,
&mut s,
None,
) { // SAFETY: `ProcessingSuccess::Passthrough` asserts that `domain_name` is ASCII.
Ok(ProcessingSuccess::Passthrough) => { let cow = Cow::Borrowed(unsafe { core::str::from_utf8_unchecked(domain_name) }); if dns_length != DnsLength::Ignore
&& !verify_dns_length(&cow, dns_length == DnsLength::VerifyAllowRootDot)
{
Err(crate::Errors::default())
} else {
Ok(cow)
}
}
Ok(ProcessingSuccess::WroteToSink) => { let cow: Cow<'_, str> = Cow::Owned(s); if dns_length != DnsLength::Ignore
&& !verify_dns_length(&cow, dns_length == DnsLength::VerifyAllowRootDot)
{
Err(crate::Errors::default())
} else {
Ok(cow)
}
}
Err(ProcessingError::ValidityError) => Err(crate::Errors::default()),
Err(ProcessingError::SinkError) => unreachable!(),
}
}
/// Performs the [ToUnicode](https://www.unicode.org/reports/tr46/#ToUnicode) operation /// from UTS #46 according to the options given. When there /// are errors, there is still output, which may be rendered user, even through /// the output must not be used in networking protocols. Errors are denoted /// by U+FFFD REPLACEMENT CHARACTERs in the output. (That is, if the second item of the /// return tuple is `Err`, the first item of the return tuple is guaranteed to contain /// at least one U+FFFD.) /// /// Most applications probably shouldn't use this method and should be using /// [`Uts46::to_user_interface`] instead. /// /// # Arguments /// /// * `domain_name` - The input domain name as UTF-8 bytes. (The UTF-8ness is checked by /// this method and input that is not well-formed UTF-8 is treated as an error. If you /// already have a `&str`, call `.as_bytes()` on it.) /// * `ascii_deny_list` - What ASCII deny list, if any, to apply. The UTS 46 /// _UseSTD3ASCIIRules_ flag or the WHATWG URL Standard forbidden domain code point /// processing is handled via this argument. Most callers are probably the best off /// by using [`AsciiDenyList::URL`] here. /// * `hyphens` - The UTS 46 _CheckHyphens_ flag. Most callers are probably the best /// off by using [`Hyphens::Allow`] here. pubfn to_unicode<'a>(
&self,
domain_name: &'a [u8],
ascii_deny_list: AsciiDenyList,
hyphens: Hyphens,
) -> (Cow<'a, str>, Result<(), crate::Errors>) { self.to_user_interface(domain_name, ascii_deny_list, hyphens, |_, _, _| true)
}
/// Performs the [ToUnicode](https://www.unicode.org/reports/tr46/#ToUnicode) operation /// from UTS #46 according to options given with some /// error-free Unicode labels output according to /// [ToASCII](https://www.unicode.org/reports/tr46/#ToASCII) instead as decided by /// application policy implemented via the `output_as_unicode` closure. The purpose /// is to convert user-visible domains to the Unicode form in general but to render /// potentially misleading labels as Punycode. /// /// This is an imperfect security mechanism, because [the Punycode form itself may be /// resemble a user-recognizable name](https://www.unicode.org/reports/tr36/#TablePunycodeSpoofing). /// However, since this mechanism is common practice, this API provides support for The /// the mechanism. /// /// ASCII labels always pass through as ASCII and labels with errors always pass through /// as Unicode. For non-erroneous labels that contain at least one non-ASCII character /// (implies non-empty), `output_as_unicode` is called with the Unicode form of the label, /// the TLD (potentially empty), and a flag indicating whether the domain name as a whole /// is a bidi domain name. If the return value is `true`, the label passes through as /// Unicode. If the return value is `false`, the label is converted to Punycode. /// /// When there are errors, there is still output, which may be rendered user, even through /// the output must not be used in networking protocols. Errors are denoted by /// U+FFFD REPLACEMENT CHARACTERs in the output. (That is, if the second item /// of the return tuple is `Err`, the first item of the return tuple is guaranteed to contain /// at least one U+FFFD.) Labels that contain errors are not converted to Punycode. /// /// # Arguments /// /// * `domain_name` - The input domain name as UTF-8 bytes. (The UTF-8ness is checked by /// this method and input that is not well-formed UTF-8 is treated as an error. If you /// already have a `&str`, call `.as_bytes()` on it.) /// * `ascii_deny_list` - What ASCII deny list, if any, to apply. The UTS 46 /// _UseSTD3ASCIIRules_ flag or the WHATWG URL Standard forbidden domain code point /// processing is handled via this argument. Most callers are probably the best off /// by using [`AsciiDenyList::URL`] here. /// * `hyphens` - The UTS 46 _CheckHyphens_ flag. Most callers are probably the best /// off by using [`Hyphens::Allow`] here. /// * `output_as_unicode` - A closure for deciding if a label should be output as Unicode /// (as opposed to Punycode). The first argument is the label for which a decision is /// needed (always non-empty slice). The second argument is the TLD (potentially empty). /// The third argument is `true` iff the domain name as a whole is a bidi domain name. /// Only non-erroneous labels that contain at least one non-ASCII character are passed /// to the closure as the first argument. The second and third argument values are /// guaranteed to remain the same during a single call to `process`, and the closure /// may cache computations derived from the second and third argument (hence the /// `FnMut` type). pubfn to_user_interface<'a, OutputUnicode: FnMut(&[char], &[char], bool) -> bool>(
&self,
domain_name: &'a [u8],
ascii_deny_list: AsciiDenyList,
hyphens: Hyphens,
output_as_unicode: OutputUnicode,
) -> (Cow<'a, str>, Result<(), crate::Errors>) { letmut s = String::new(); matchself.process(
domain_name,
ascii_deny_list,
hyphens,
ErrorPolicy::MarkErrors,
output_as_unicode,
&mut s,
None,
) { // SAFETY: `ProcessingSuccess::Passthrough` asserts that `domain_name` is ASCII.
Ok(ProcessingSuccess::Passthrough) => (
Cow::Borrowed(unsafe { core::str::from_utf8_unchecked(domain_name) }),
Ok(()),
),
Ok(ProcessingSuccess::WroteToSink) => (Cow::Owned(s), Ok(())),
Err(ProcessingError::ValidityError) => (Cow::Owned(s), Err(crate::Errors::default())),
Err(ProcessingError::SinkError) => unreachable!(),
}
}
/// The lower-level function that [`Uts46::to_ascii`], [`Uts46::to_unicode`], and /// [`Uts46::to_user_interface`] are built on to allow support for output types other /// than `Cow<'a, str>` (e.g. string types in a non-Rust programming language). /// /// # Arguments /// /// * `domain_name` - The input domain name as UTF-8 bytes. (The UTF-8ness is checked by /// this method and input that is not well-formed UTF-8 is treated as an error. If you /// already have a `&str`, call `.as_bytes()` on it.) /// * `ascii_deny_list` - What ASCII deny list, if any, to apply. The UTS 46 /// _UseSTD3ASCIIRules_ flag or the WHATWG URL Standard forbidden domain code point /// processing is handled via this argument. Most callers are probably the best off /// by using [`AsciiDenyList::URL`] here. /// * `hyphens` - The UTS 46 _CheckHyphens_ flag. Most callers are probably the best /// off by using [`Hyphens::Allow`] here. /// * `error_policy` - Whether to fail fast or to produce output that may be rendered /// for the user to examine in case of errors. /// * `output_as_unicode` - A closure for deciding if a label should be output as Unicode /// (as opposed to Punycode). The first argument is the label for which a decision is /// needed (always non-empty slice). The second argument is the TLD (potentially empty). /// The third argument is `true` iff the domain name as a whole is a bidi domain name. /// Only non-erroneous labels that contain at least one non-ASCII character are passed /// to the closure as the first argument. The second and third argument values are /// guaranteed to remain the same during a single call to `process`, and the closure /// may cache computations derived from the second and third argument (hence the /// `FnMut` type). To perform the _ToASCII_ operation, `|_, _, _| false` must be /// passed as the closure. To perform the _ToUnicode_ operation, `|_, _, _| true` must /// be passed as the closure. A more complex closure may be used to prepare a domain /// name for display in a user interface so that labels are converted to the Unicode /// form in general but potentially misleading labels are converted to the Punycode /// form. /// * `sink` - The object that receives the output (in the non-passthrough case). /// * `ascii_sink` - A second sink that receives the _ToASCII_ form only if there /// were no errors and `sink` received at least one character of non-ASCII output. /// The purpose of this argument is to enable a user interface display form of the /// domain and the _ToASCII_ form of the domain to be computed efficiently together. /// This argument is useless when `output_as_unicode` always returns `false`, in /// which case the _ToASCII_ form ends up in `sink` already. If `ascii_sink` receives /// no output and the return value is `Ok(ProcessingSuccess::WroteToSink)`, use the /// output received by `sink` also as the _ToASCII_ result. /// /// # Return value /// /// * `Ok(ProcessingSuccess::Passthrough)` - The caller must treat /// `unsafe { core::str::from_utf8_unchecked(domain_name) }` as the output. (This /// return value asserts that calling `core::str::from_utf8_unchecked(domain_name)` /// is safe.) /// * `Ok(ProcessingSuccess::WroteToSink)` - The caller must treat was was written /// to `sink` as the output. If another sink was passed as `ascii_sink` but it did /// not receive output, the caller must treat what was written to `sink` also as /// the _ToASCII_ output. Otherwise, if `ascii_sink` received output, the caller /// must treat what was written to `ascii_sink` as the _ToASCII_ output. /// * `Err(ProcessingError::ValidityError)` - The input was in error and must /// not be used for DNS lookup or otherwise in a network protocol. If `error_policy` /// was `ErrorPolicy::MarkErrors`, the output written to `sink` may be displayed /// to the user as an illustration of where the error was or the errors were. /// * `Err(ProcessingError::SinkError)` - Either `sink` or `ascii_sink` returned /// [`core::fmt::Error`]. The partial output written to `sink` `ascii_sink` must not /// be used. If `W` never returns [`core::fmt::Error`], this method never returns /// `Err(ProcessingError::SinkError)`. /// /// # Safety-usable invariant /// /// If the return value is `Ok(ProcessingSuccess::Passthrough)`, `domain_name` is /// ASCII and `core::str::from_utf8_unchecked(domain_name)` is safe. (Note: /// Other return values do _not_ imply that `domain_name` wasn't ASCII!) /// /// # Security considerations /// /// Showing labels whose Unicode form might mislead the user as Punycode instead is /// an imperfect security mechanism, because [the Punycode form itself may be resemble /// a user-recognizable name](https://www.unicode.org/reports/tr36/#TablePunycodeSpoofing). /// However, since this mechanism is common practice, this API provides support for the /// the mechanism. /// /// Punycode processing is quadratic, so to avoid denial of service, this method imposes /// length limits on Punycode treating especially long inputs as being in error. These /// limits are well higher than the DNS length limits and are not more restrictive than /// the limits imposed by ICU4C. #[allow(clippy::too_many_arguments)] pubfn process<W: Write + ?Sized, OutputUnicode: FnMut(&[char], &[char], bool) -> bool>(
&self,
domain_name: &[u8],
ascii_deny_list: AsciiDenyList,
hyphens: Hyphens,
error_policy: ErrorPolicy, mut output_as_unicode: OutputUnicode,
sink: &mut W,
ascii_sink: Option<&mut W>,
) -> Result<ProcessingSuccess, ProcessingError> { let fail_fast = error_policy == ErrorPolicy::FailFast; letmut domain_buffer = SmallVec::<[char; 253]>::new(); letmut already_punycode = SmallVec::<[AlreadyAsciiLabel; 8]>::new(); // `process_inner` could be pasted inline here, but it's out of line in order // to avoid duplicating that code when monomorphizing over `W` and `OutputUnicode`. let (passthrough_up_to, is_bidi, had_errors) = self.process_inner(
domain_name,
ascii_deny_list,
hyphens,
fail_fast,
&mut domain_buffer,
&mut already_punycode,
); if passthrough_up_to == domain_name.len() {
debug_assert!(!had_errors); return Ok(ProcessingSuccess::Passthrough);
} // Checked only after passthrough as a micro optimization. if fail_fast && had_errors { return Err(ProcessingError::ValidityError);
}
debug_assert_eq!(had_errors, domain_buffer.contains(&'\u{FFFD}')); let without_dot = iflet Some(without_dot) = domain_buffer.strip_suffix(&['.']) {
without_dot
} else {
&domain_buffer[..]
}; // unwrap is OK, because we always have at least one label let tld = without_dot.rsplit(|c| *c == '.').next().unwrap(); letmut had_unicode_output = false; letmut seen_label = false; letmut already_punycode_iter = already_punycode.iter(); letmut passthrough_up_to_extended = passthrough_up_to; letmut flushed_prefix = false; for label in domain_buffer.split(|c| *c == '.') { // Unwrap is OK, because there are supposed to be as many items in // `already_punycode` as there are labels. let input_punycode = *already_punycode_iter.next().unwrap(); if seen_label { if flushed_prefix {
sink.write_char('.')?;
} else {
debug_assert_eq!(domain_name[passthrough_up_to_extended], b'.');
passthrough_up_to_extended += 1; if passthrough_up_to_extended == domain_name.len() {
debug_assert!(!had_errors); return Ok(ProcessingSuccess::Passthrough);
}
}
}
seen_label = true;
iflet AlreadyAsciiLabel::MixedCaseAscii(mixed_case) = input_punycode { iflet Some(first_upper_case) =
mixed_case.iter().position(|c| c.is_ascii_uppercase())
{ let (head, tail) = mixed_case.split_at(first_upper_case); let slice_to_write = if flushed_prefix {
head
} else {
flushed_prefix = true;
passthrough_up_to_extended += head.len();
debug_assert_ne!(passthrough_up_to_extended, domain_name.len());
&domain_name[..passthrough_up_to_extended]
}; // SAFETY: `mixed_case` and `domain_name` up to `passthrough_up_to_extended` are known to be ASCII.
sink.write_str(unsafe { core::str::from_utf8_unchecked(slice_to_write) })?; for c in tail.iter() {
sink.write_char(char::from(c.to_ascii_lowercase()))?;
}
} elseif flushed_prefix { // SAFETY: `mixed_case` is known to be ASCII.
sink.write_str(unsafe { core::str::from_utf8_unchecked(mixed_case) })?;
} else {
passthrough_up_to_extended += mixed_case.len(); if passthrough_up_to_extended == domain_name.len() {
debug_assert!(!had_errors); return Ok(ProcessingSuccess::Passthrough);
}
} continue;
}
let potentially_punycode = if fail_fast {
debug_assert!(classify_for_punycode(label) != PunycodeClassification::Error);
!is_ascii(label)
} else {
classify_for_punycode(label) == PunycodeClassification::Unicode
}; let passthrough = if potentially_punycode { let unicode = output_as_unicode(label, tld, is_bidi);
had_unicode_output |= unicode;
unicode
} else { true
}; if passthrough { if !flushed_prefix {
flushed_prefix = true; // SAFETY: `domain_name` up to `passthrough_up_to_extended` is known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(&domain_name[..passthrough_up_to_extended])
})?;
} for c in label.iter().copied() {
sink.write_char(c)?;
}
} elseiflet AlreadyAsciiLabel::MixedCasePunycode(mixed_case) = input_punycode { iflet Some(first_upper_case) =
mixed_case.iter().position(|c| c.is_ascii_uppercase())
{ let (head, tail) = mixed_case.split_at(first_upper_case); let slice_to_write = if flushed_prefix {
head
} else {
flushed_prefix = true;
passthrough_up_to_extended += head.len();
debug_assert_ne!(passthrough_up_to_extended, domain_name.len());
&domain_name[..passthrough_up_to_extended]
}; // SAFETY: `mixed_case` and `domain_name` up to `passthrough_up_to_extended` are known to be ASCII.
sink.write_str(unsafe { core::str::from_utf8_unchecked(slice_to_write) })?; for c in tail.iter() {
sink.write_char(char::from(c.to_ascii_lowercase()))?;
}
} elseif flushed_prefix { // SAFETY: `mixed_case` is known to be ASCII.
sink.write_str(unsafe { core::str::from_utf8_unchecked(mixed_case) })?;
} else {
passthrough_up_to_extended += mixed_case.len(); if passthrough_up_to_extended == domain_name.len() {
debug_assert!(!had_errors); return Ok(ProcessingSuccess::Passthrough);
}
}
} else { if !flushed_prefix {
flushed_prefix = true; // SAFETY: `domain_name` up to `passthrough_up_to_extended` is known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(&domain_name[..passthrough_up_to_extended])
})?;
}
write_punycode_label(label, sink)?;
}
}
if had_errors { return Err(ProcessingError::ValidityError);
}
if had_unicode_output { iflet Some(sink) = ascii_sink { letmut seen_label = false; letmut already_punycode_iter = already_punycode.iter(); letmut passthrough_up_to_extended = passthrough_up_to; letmut flushed_prefix = false; for label in domain_buffer.split(|c| *c == '.') { // Unwrap is OK, because there are supposed to be as many items in // `already_punycode` as there are labels. let input_punycode = *already_punycode_iter.next().unwrap(); if seen_label { if flushed_prefix {
sink.write_char('.')?;
} else {
debug_assert_eq!(domain_name[passthrough_up_to_extended], b'.');
passthrough_up_to_extended += 1;
}
}
seen_label = true;
iflet AlreadyAsciiLabel::MixedCaseAscii(mixed_case) = input_punycode { iflet Some(first_upper_case) =
mixed_case.iter().position(|c| c.is_ascii_uppercase())
{ let (head, tail) = mixed_case.split_at(first_upper_case); let slice_to_write = if flushed_prefix {
head
} else {
flushed_prefix = true;
passthrough_up_to_extended += head.len();
debug_assert_ne!(passthrough_up_to_extended, domain_name.len());
&domain_name[..passthrough_up_to_extended]
}; // SAFETY: `mixed_case` and `domain_name` up to `passthrough_up_to_extended` are known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(slice_to_write)
})?; for c in tail.iter() {
sink.write_char(char::from(c.to_ascii_lowercase()))?;
}
} elseif flushed_prefix { // SAFETY: `mixed_case` is known to be ASCII.
sink.write_str(unsafe { core::str::from_utf8_unchecked(mixed_case) })?;
} else {
passthrough_up_to_extended += mixed_case.len();
} continue;
}
if is_ascii(label) { if !flushed_prefix {
flushed_prefix = true; // SAFETY: `domain_name` up to `passthrough_up_to_extended` is known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(
&domain_name[..passthrough_up_to_extended],
)
})?;
} for c in label.iter().copied() {
sink.write_char(c)?;
}
} elseiflet AlreadyAsciiLabel::MixedCasePunycode(mixed_case) = input_punycode
{ iflet Some(first_upper_case) =
mixed_case.iter().position(|c| c.is_ascii_uppercase())
{ let (head, tail) = mixed_case.split_at(first_upper_case); let slice_to_write = if flushed_prefix {
head
} else {
flushed_prefix = true;
passthrough_up_to_extended += head.len();
debug_assert_ne!(passthrough_up_to_extended, domain_name.len());
&domain_name[..passthrough_up_to_extended]
}; // SAFETY: `mixed_case` and `domain_name` up to `passthrough_up_to_extended` are known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(slice_to_write)
})?; for c in tail.iter() {
sink.write_char(char::from(c.to_ascii_lowercase()))?;
}
} elseif flushed_prefix { // SAFETY: `mixed_case` is known to be ASCII.
sink.write_str(unsafe { core::str::from_utf8_unchecked(mixed_case) })?;
} else {
passthrough_up_to_extended += mixed_case.len();
}
} else { if !flushed_prefix {
flushed_prefix = true; // SAFETY: `domain_name` up to `passthrough_up_to_extended` is known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(
&domain_name[..passthrough_up_to_extended],
)
})?;
}
write_punycode_label(label, sink)?;
}
} if !flushed_prefix { // SAFETY: `domain_name` up to `passthrough_up_to_extended` is known to be ASCII.
sink.write_str(unsafe {
core::str::from_utf8_unchecked(&domain_name[..passthrough_up_to_extended])
})?;
}
}
}
Ok(ProcessingSuccess::WroteToSink)
}
/// The part of `process` that doesn't need to be generic over the sink. #[inline(always)] fn process_inner<'a>(
&self,
domain_name: &'a [u8],
ascii_deny_list: AsciiDenyList,
hyphens: Hyphens,
fail_fast: bool,
domain_buffer: &mut SmallVec<[char; 253]>,
already_punycode: &mut SmallVec<[AlreadyAsciiLabel<'a>; 8]>,
) -> (usize, bool, bool) { // Sadly, this even faster-path ASCII tier is needed to avoid regressing // performance. letmut iter = domain_name.iter(); letmut most_recent_label_start = iter.clone(); loop { iflet Some(&b) = iter.next() { if in_inclusive_range8(b, b'a', b'z') { continue;
} if b == b'.' {
most_recent_label_start = iter.clone(); continue;
} returnself.process_innermost(
domain_name,
ascii_deny_list,
hyphens,
fail_fast,
domain_buffer,
already_punycode,
most_recent_label_start.as_slice(),
);
} else { // Success! The whole input passes through on the fastest path! return (domain_name.len(), false, false);
}
}
}
/// The part of `process` that doesn't need to be generic over the sink and /// can avoid monomorphizing in the interest of code size. /// Separating this into a different stack frame compared to `process_inner` /// improves performance in the ICU4X case. #[allow(clippy::too_many_arguments)] #[inline(never)] fn process_innermost<'a>(
&self,
domain_name: &'a [u8],
ascii_deny_list: AsciiDenyList,
hyphens: Hyphens,
fail_fast: bool,
domain_buffer: &mut SmallVec<[char; 253]>,
already_punycode: &mut SmallVec<[AlreadyAsciiLabel<'a>; 8]>,
tail: &'a [u8],
) -> (usize, bool, bool) { let deny_list = ascii_deny_list.bits; let deny_list_deny_dot = deny_list | DOT_MASK;
letmut had_errors = false;
letmut passthrough_up_to = domain_name.len() - tail.len(); // Index into `domain_name` // 253 ASCII characters is the max length for a valid domain name // (excluding the root dot). letmut current_label_start; // Index into `domain_buffer` letmut seen_label = false; letmut in_prefix = true; for label in tail.split(|b| *b == b'.') { // We check for passthrough only for the prefix. That is, if we // haven't moved on and started filling `domain_buffer`. Keeping // this stuff in one loop where the first items keep being skipped // once they have been skipped at least once instead of working // this into a fancier loop structure in order to make sure that // no item from the iterator is lost or processed twice. // Furthermore, after the passthrough fails, restarting the // normalization process after each pre-existing ASCII dot also // provides an opportunity for the processing to get back onto // an ASCII fast path that bypasses the normalizer for ASCII // after a pre-existing ASCII dot (pre-existing in the sense // of not coming from e.g. normalizing an ideographic dot). if in_prefix && is_passthrough_ascii_label(label) { if seen_label {
debug_assert_eq!(domain_name[passthrough_up_to], b'.');
passthrough_up_to += 1;
}
seen_label = true;
passthrough_up_to += label.len(); continue;
} if seen_label { if in_prefix {
debug_assert_eq!(domain_name[passthrough_up_to], b'.');
passthrough_up_to += 1;
} else {
domain_buffer.push('.');
}
}
seen_label = true;
in_prefix = false;
current_label_start = domain_buffer.len(); if !label.is_empty() { let (ascii, non_ascii) = split_ascii_fast_path_prefix(label); let non_punycode_ascii_label = if non_ascii.is_empty() { if has_punycode_prefix(ascii) { if (ascii.last() != Some(&b'-'))
&& (ascii.len() - 4 <= PUNYCODE_DECODE_MAX_INPUT_LENGTH)
{ iflet Ok(decode) =
Decoder::default().decode::<u8, InternalCaller>(&ascii[4..])
{ // 63 ASCII characters is the max length for a valid DNS label and xn-- takes 4 // characters. letmut label_buffer = SmallVec::<[char; 59]>::new();
label_buffer.extend(decode);
ifself.check_label(
hyphens,
&mut domain_buffer[current_label_start..],
fail_fast,
&mut had_errors, true, true,
) { return (0, false, true);
}
} else { // Punycode failed if fail_fast { return (0, false, true);
}
had_errors = true;
domain_buffer.push('\u{FFFD}'); letmut iter = ascii.iter(); // Discard the first character that we replaced. let _ = iter.next();
domain_buffer.extend(iter.map(|c| { // Can't have dot here, so `deny_list` vs `deny_list_deny_dot` does // not matter.
apply_ascii_deny_list_to_potentially_upper_case_ascii(
*c, deny_list,
)
}));
}; // If there were errors, we won't be trying to use this // anyway later, so it's fine to put it here unconditionally.
already_punycode.push(AlreadyAsciiLabel::MixedCasePunycode(label)); continue;
} elseif fail_fast { return (0, false, true);
} // Else fall through to the complex path and rediscover error // there. false
} else { true
}
} else { false
}; for c in ascii.iter().map(|c| { // Can't have dot here, so `deny_list` vs `deny_list_deny_dot` does // not matter.
apply_ascii_deny_list_to_potentially_upper_case_ascii(*c, deny_list)
}) { if c == '\u{FFFD}' { if fail_fast { return (0, false, true);
}
had_errors = true;
}
domain_buffer.push(c);
} if non_punycode_ascii_label { if hyphens != Hyphens::Allow
&& check_hyphens(
&mut domain_buffer[current_label_start..],
hyphens == Hyphens::CheckFirstLast,
fail_fast,
&mut had_errors,
)
{ return (0, false, true);
}
already_punycode.push(if had_errors {
AlreadyAsciiLabel::Other
} else {
AlreadyAsciiLabel::MixedCaseAscii(label)
}); continue;
}
already_punycode.push(AlreadyAsciiLabel::Other); letmut first_needs_combining_mark_check = ascii.is_empty(); letmut needs_contextj_check = !non_ascii.is_empty(); letmut mapping = self
.data
.map_normalize(non_ascii.chars())
.map(|c| apply_ascii_deny_list_to_lower_cased_unicode(c, deny_list)); loop { let n = mapping.next(); match n {
None | Some('.') => { if domain_buffer[current_label_start..]
.starts_with(&['x', 'n', '-', '-'])
{ letmut punycode_precondition_failed = false; for c in domain_buffer[current_label_start + 4..].iter_mut() { if !c.is_ascii() { if fail_fast { return (0, false, true);
}
had_errors = true;
*c = '\u{FFFD}';
punycode_precondition_failed = true;
}
}
iflet Some(last) = domain_buffer.last_mut() { if *last == '-' { // Either there's nothing after the "xn--" prefix // and we got the last hyphen of "xn--", or there // are no Punycode digits after the last delimiter // which would result in Punycode decode outputting // ASCII only. if fail_fast { return (0, false, true);
}
had_errors = true;
*last = '\u{FFFD}';
punycode_precondition_failed = true;
}
} else {
unreachable!();
}
#[inline(always)] fn has_appropriately_joining_char<I: Iterator<Item = char>>(
&self,
iter: I,
required_mask: JoiningTypeMask,
) -> bool { for c in iter { let jt = self.data.joining_type(c); if jt.to_mask().intersects(required_mask) { returntrue;
} if jt.is_transparent() { continue;
} returnfalse;
} false
}
#[inline(always)] fn is_bidi(&self, buffer: &[char]) -> bool { for &c in buffer { if c < '\u{0590}' { // Below Hebrew continue;
} if in_inclusive_range_char(c, '\u{0900}', '\u{FB1C}') {
debug_assert_ne!(c, '\u{200F}'); // disallowed continue;
} if in_inclusive_range_char(c, '\u{1F000}', '\u{3FFFF}') { continue;
} if in_inclusive_range_char(c, '\u{FF00}', '\u{107FF}') { continue;
} if in_inclusive_range_char(c, '\u{11000}', '\u{1E7FF}') { continue;
} if RTL_MASK.intersects(self.data.bidi_class(c).to_mask()) { returntrue;
}
} false
}
}
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