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Quelle key.rs
Sprache: unbekannt
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// This file is part of ICU4X. For terms of use, please see the file
// called LICENSE at the top level of the ICU4X source tree
// (online at: https://github.com/unicode-org/icu4x/blob/main/LICENSE ).
use crate::error::{DataError, DataErrorKind};
use crate::fallback::{LocaleFallbackConfig, LocaleFallbackPriority, LocaleFallbackS upplement};
use alloc::borrow::Cow;
use core::fmt;
use core::fmt::Write;
use core::ops::Deref;
use writeable::{LengthHint, Writeable};
use zerovec::ule::*;
#[doc(hidden)]
#[macro_export]
macro_rules! leading_tag {
() => {
"\nicu4x_key_tag"
};
}
#[doc(hidden)]
#[macro_export]
macro_rules! trailing_tag {
() => {
"\n"
};
}
#[doc(hidden)]
#[macro_export]
macro_rules! tagged {
($without_tags:expr) => {
concat!(
$crate::leading_tag!(),
$without_tags,
$crate::trailing_tag!()
)
};
}
/// A compact hash of a [`DataKey`]. Useful for keys in maps.
///
/// The hash will be stable over time within major releases.
#[derive(Debug, PartialEq, Eq, PartialOrd, Ord, Copy, Clone, Hash, ULE)]
#[cfg_attr(feature = "serde", derive(serde::Serialize, serde::Deserialize))]
#[repr(transparent)]
pub struct DataKeyHash([u8; 4]);
impl DataKeyHash {
const fn compute_from_path(path: DataKeyPath) -> Self {
let hash = fxhash_32(
path.tagged.as_bytes(),
leading_tag!().len(),
trailing_tag!().len(),
);
Self(hash.to_le_bytes())
}
/// Gets the hash value as a byte array.
pub const fn to_bytes(self) -> [u8; 4] {
self.0
}
}
/// Const function to compute the FxHash of a byte array.
///
/// FxHash is a speedy hash algorithm used within rustc. The algorithm is satisfactory for our
/// use case since the strings being hashed originate from a trusted source (the ICU4X
/// components), and the hashes are computed at compile time, so we can check for collisions.
///
/// We could have considered a SHA or other cryptographic hash function. However, we are using
/// FxHash because:
///
/// 1. There is precedent for this algorithm in Rust
/// 2. The algorithm is easy to implement as a const function
/// 3. The amount of code is small enough that we can reasonably keep the algorithm in-tree
/// 4. FxHash is designed to output 32-bit or 64-bit values, whereas SHA outputs more bits,
/// such that truncation would be required in order to fit into a u32, partially reducing
/// the benefit of a cryptographically secure algorithm
// The indexing operations in this function have been reviewed in detail and won't panic.
#[allow(clippy::indexing_slicing)]
const fn fxhash_32(bytes: &[u8], ignore_leading: usize, ignore_trailing: usize) -> u32 {
// This code is adapted from https://github.com/rust-lang/rustc-hash,
// whose license text is reproduced below.
//
// Copyright 2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// 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.
if ignore_leading + ignore_trailing >= bytes.len() {
return 0;
}
#[inline]
const fn hash_word_32(mut hash: u32, word: u32) -> u32 {
const ROTATE: u32 = 5;
const SEED32: u32 = 0x9e_37_79_b9;
hash = hash.rotate_left(ROTATE);
hash ^= word;
hash = hash.wrapping_mul(SEED32);
hash
}
let mut cursor = ignore_leading;
let end = bytes.len() - ignore_trailing;
let mut hash = 0;
while end - cursor >= 4 {
let word = u32::from_le_bytes([
bytes[cursor],
bytes[cursor + 1],
bytes[cursor + 2],
bytes[cursor + 3],
]);
hash = hash_word_32(hash, word);
cursor += 4;
}
if end - cursor >= 2 {
let word = u16::from_le_bytes([bytes[cursor], bytes[cursor + 1]]);
hash = hash_word_32(hash, word as u32);
cursor += 2;
}
if end - cursor >= 1 {
hash = hash_word_32(hash, bytes[cursor] as u32);
}
hash
}
impl<'a> zerovec::maps::ZeroMapKV<'a> for DataKeyHash {
type Container = zerovec::ZeroVec<'a, DataKeyHash>;
type Slice = zerovec::ZeroSlice<DataKeyHash>;
type GetType = <DataKeyHash as AsULE>::ULE;
type OwnedType = DataKeyHash;
}
impl AsULE for DataKeyHash {
type ULE = Self;
#[inline]
fn to_unaligned(self) -> Self::ULE {
self
}
#[inline]
fn from_unaligned(unaligned: Self::ULE) -> Self {
unaligned
}
}
// Safe since the ULE type is `self`.
unsafe impl EqULE for DataKeyHash {}
/// The string path of a data key. For example, "foo@1"
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord)]
pub struct DataKeyPath {
// This string literal is wrapped in leading_tag!() and trailing_tag!() to make it detectable
// in a compiled binary.
tagged: &'static str,
}
impl DataKeyPath {
/// Gets the path as a static string slice.
#[inline]
pub const fn get(self) -> &'static str {
unsafe {
// Safe due to invariant that self.path is tagged correctly
core::str::from_utf8_unchecked(core::slice::from_raw_parts(
self.tagged.as_ptr().add(leading_tag!().len()),
self.tagged.len() - trailing_tag!().len() - leading_tag!().len(),
))
}
}
}
impl Deref for DataKeyPath {
type Target = str;
#[inline]
fn deref(&self) -> &Self::Target {
self.get()
}
}
/// Metadata statically associated with a particular [`DataKey`].
#[derive(Debug, PartialEq, Eq, Copy, Clone, PartialOrd, Ord)]
#[non_exhaustive]
pub struct DataKeyMetadata {
/// What to prioritize when fallbacking on this [`DataKey`].
pub fallback_priority: LocaleFallbackPriority,
/// A Unicode extension keyword to consider when loading data for this [`DataKey`].
pub extension_key: Option<icu_locid::extensions::unicode::Key>,
/// Optional choice for additional fallbacking data required for loading this marker.
///
/// For more information, see `LocaleFallbackConfig::fallback_supplement`.
pub fallback_supplement: Option<LocaleFallbackSupplement>,
/// Whether the key has a singleton value, as opposed to per-locale values. Singleton
/// keys behave differently, e.g. they never perform fallback, and can be optimized
/// in data providers.
pub singleton: bool,
}
impl DataKeyMetadata {
/// Const-friendly version of [`Default::default`].
pub const fn const_default() -> Self {
Self {
fallback_priority: LocaleFallbackPriority::const_default(),
extension_key: None,
fallback_supplement: None,
singleton: false,
}
}
#[doc(hidden)]
pub const fn construct_internal(
fallback_priority: LocaleFallbackPriority,
extension_key: Option<icu_locid::extensions::unicode::Key>,
fallback_supplement: Option<LocaleFallbackSupplement>,
singleton: bool,
) -> Self {
Self {
fallback_priority,
extension_key,
fallback_supplement,
singleton,
}
}
}
impl Default for DataKeyMetadata {
#[inline]
fn default() -> Self {
Self::const_default()
}
}
/// Used for loading data from an ICU4X data provider.
///
/// A resource key is tightly coupled with the code that uses it to load data at runtime.
/// Executables can be searched for `DataKey` instances to produce optimized data files.
/// Therefore, users should not generally create DataKey instances; they should instead use
/// the ones exported by a component.
///
/// `DataKey`s are created with the [`data_key!`](crate::data_key) macro:
///
/// ```
/// # use icu_provider::DataKey;
/// const K: DataKey = icu_provider::data_key!("foo/bar@1");
/// ```
///
/// The human-readable path string ends with `@` followed by one or more digits (the version
/// number). Paths do not contain characters other than ASCII letters and digits, `_`, `/`.
///
/// Invalid paths are compile-time errors (as [`data_key!`](crate::data_key) uses `const`).
///
/// ```compile_fail,E0080
/// # use icu_provider::DataKey;
/// const K: DataKey = icu_provider::data_key!("foo/../bar@1");
/// ```
#[derive(Copy, Clone)]
pub struct DataKey {
path: DataKeyPath,
hash: DataKeyHash,
metadata: DataKeyMetadata,
}
impl PartialEq for DataKey {
#[inline]
fn eq(&self, other: &Self) -> bool {
self.hash == other.hash && self.path == other.path && self.metadata == other.metadata
}
}
impl Eq for DataKey {}
impl Ord for DataKey {
fn cmp(&self, other: &Self) -> core::cmp::Ordering {
self.path
.cmp(&other.path)
.then_with(|| self.metadata.cmp(&other.metadata))
}
}
impl PartialOrd for DataKey {
#[inline]
fn partial_cmp(&self, other: &Self) -> Option<core::cmp::Ordering> {
Some(self.cmp(other))
}
}
impl core::hash::Hash for DataKey {
#[inline]
fn hash<H: core::hash::Hasher>(&self, state: &mut H) {
self.hash.hash(state)
}
}
impl DataKey {
/// Gets a human-readable representation of a [`DataKey`].
///
/// The human-readable path string ends with `@` followed by one or more digits (the version
/// number). Paths do not contain characters other than ASCII letters and digits, `_`, `/`.
///
/// Useful for reading and writing data to a file system.
#[inline]
pub const fn path(self) -> DataKeyPath {
self.path
}
/// Gets a platform-independent hash of a [`DataKey`].
///
/// The hash is 4 bytes and allows for fast key comparison.
///
/// # Example
///
/// ```
/// use icu_provider::DataKey;
/// use icu_provider::DataKeyHash;
///
/// const KEY: DataKey = icu_provider::data_key!("foo@1");
/// const KEY_HASH: DataKeyHash = KEY.hashed();
///
/// assert_eq!(KEY_HASH.to_bytes(), [0xe2, 0xb6, 0x17, 0x71]);
/// ```
#[inline]
pub const fn hashed(self) -> DataKeyHash {
self.hash
}
/// Gets the metadata associated with this [`DataKey`].
#[inline]
pub const fn metadata(self) -> DataKeyMetadata {
self.metadata
}
/// Returns the [`LocaleFallbackConfig`] for this [`DataKey`].
#[inline]
pub const fn fallback_config(self) -> LocaleFallbackConfig {
let mut config = LocaleFallbackConfig::const_default();
config.priority = self.metadata.fallback_priority;
config.extension_key = self.metadata.extension_key;
config.fallback_supplement = self.metadata.fallback_supplement;
config
}
/// Constructs a [`DataKey`] from a path and metadata.
///
/// # Examples
///
/// ```
/// use icu_provider::data_key;
/// use icu_provider::DataKey;
///
/// const CONST_KEY: DataKey = data_key!("foo@1");
///
/// let runtime_key =
/// DataKey::from_path_and_metadata(CONST_KEY.path(), CONST_KEY.metadata());
///
/// assert_eq!(CONST_KEY, runtime_key);
/// ```
#[inline]
pub const fn from_path_and_metadata(path: DataKeyPath, metadata: DataKeyMetadata) -> Self {
Self {
path,
hash: DataKeyHash::compute_from_path(path),
metadata,
}
}
#[doc(hidden)]
// Error is a str of the expected character class and the index where it wasn't encountered
// The indexing operations in this function have been reviewed in detail and won't panic.
#[allow(clippy::indexing_slicing)]
pub const fn construct_internal(
path: &'static str,
metadata: DataKeyMetadata,
) -> Result<Self, (&'static str, usize)> {
if path.len() < leading_tag!().len() + trailing_tag!().len() {
return Err(("tag", 0));
}
// Start and end of the untagged part
let start = leading_tag!().len();
let end = path.len() - trailing_tag!().len();
// Check tags
let mut i = 0;
while i < leading_tag!().len() {
if path.as_bytes()[i] != leading_tag!().as_bytes()[i] {
return Err(("tag", 0));
}
i += 1;
}
i = 0;
while i < trailing_tag!().len() {
if path.as_bytes()[end + i] != trailing_tag!().as_bytes()[i] {
return Err(("tag", end + 1));
}
i += 1;
}
match Self::validate_path_manual_slice(path, start, end) {
Ok(()) => (),
Err(e) => return Err(e),
};
let path = DataKeyPath { tagged: path };
Ok(Self {
path,
hash: DataKeyHash::compute_from_path(path),
metadata,
})
}
const fn validate_path_manual_slice(
path: &'static str,
start: usize,
end: usize,
) -> Result<(), (&'static str, usize)> {
debug_assert!(start <= end);
debug_assert!(end <= path.len());
// Regex: [a-zA-Z0-9_][a-zA-Z0-9_/]*@[0-9]+
enum State {
Empty,
Body,
At,
Version,
}
use State::*;
let mut i = start;
let mut state = Empty;
loop {
let byte = if i < end {
#[allow(clippy::indexing_slicing)] // protected by debug assertion
Some(path.as_bytes()[i])
} else {
None
};
state = match (state, byte) {
(Empty | Body, Some(b'a'..=b'z' | b'A'..=b'Z' | b'0'..=b'9' | b'_')) => Body,
(Body, Some(b'/')) => Body,
(Body, Some(b'@')) => At,
(At | Version, Some(b'0'..=b'9')) => Version,
// One of these cases will be hit at the latest when i == end, so the loop converges.
(Version, None) => {
return Ok(());
}
(Empty, _) => return Err(("[a-zA-Z0-9_]", i)),
(Body, _) => return Err(("[a-zA-z0-9_/@]", i)),
(At, _) => return Err(("[0-9]", i)),
(Version, _) => return Err(("[0-9]", i)),
};
i += 1;
}
}
/// Returns [`Ok`] if this data key matches the argument, or the appropriate error.
///
/// Convenience method for data providers that support a single [`DataKey`].
///
/// # Examples
///
/// ```
/// use icu_provider::prelude::*;
///
/// const FOO_BAR: DataKey = icu_provider::data_key!("foo/bar@1");
/// const FOO_BAZ: DataKey = icu_provider::data_key!("foo/baz@1");
/// const BAR_BAZ: DataKey = icu_provider::data_key!("bar/baz@1");
///
/// assert!(matches!(FOO_BAR.match_key(FOO_BAR), Ok(())));
/// assert!(matches!(
/// FOO_BAR.match_key(FOO_BAZ),
/// Err(DataError {
/// kind: DataErrorKind::MissingDataKey,
/// ..
/// })
/// ));
/// assert!(matches!(
/// FOO_BAR.match_key(BAR_BAZ),
/// Err(DataError {
/// kind: DataErrorKind::MissingDataKey,
/// ..
/// })
/// ));
///
/// // The error context contains the argument:
/// assert_eq!(FOO_BAR.match_key(BAR_BAZ).unwrap_err().key, Some(BAR_BAZ));
/// ```
pub fn match_key(self, key: Self) -> Result<(), DataError> {
if self == key {
Ok(())
} else {
Err(DataErrorKind::MissingDataKey.with_key(key))
}
}
}
/// See [`DataKey`].
#[macro_export]
macro_rules! data_key {
($path:expr) => {{
$crate::data_key!($path, $crate::DataKeyMetadata::const_default())
}};
($path:expr, $metadata:expr) => {{
// Force the DataKey into a const context
const RESOURCE_KEY_MACRO_CONST: $crate::DataKey = {
match $crate::DataKey::construct_internal($crate::tagged!($path), $metadata) {
Ok(v) => v,
#[allow(clippy::panic)] // Const context
Err(_) => panic!(concat!("Invalid resource key: ", $path)),
// TODO Once formatting is const:
// Err((expected, index)) => panic!(
// "Invalid resource key {:?}: expected {:?}, found {:?} ",
// $path,
// expected,
// $crate::tagged!($path).get(index..))
// );
}
};
RESOURCE_KEY_MACRO_CONST
}};
}
impl fmt::Debug for DataKey {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str("DataKey{")?;
fmt::Display::fmt(self, f)?;
f.write_char('}')?;
Ok(())
}
}
impl Writeable for DataKey {
fn write_to<W: core::fmt::Write + ?Sized>(&self, sink: &mut W) -> core::fmt::Result {
self.path().write_to(sink)
}
fn writeable_length_hint(&self) -> LengthHint {
self.path().writeable_length_hint()
}
fn write_to_string(&self) -> Cow<str> {
Cow::Borrowed(self.path().get())
}
}
writeable::impl_display_with_writeable!(DataKey);
#[test]
fn test_path_syntax() {
// Valid keys:
DataKey::construct_internal(tagged!("hello/world@1"), Default::default()).unwrap();
DataKey::construct_internal(tagged!("hello/world/foo@1"), Default::default()).unwrap();
DataKey::construct_internal(tagged!("hello/world@999"), Default::default()).unwrap();
DataKey::construct_internal(tagged!("hello_world/foo@1"), Default::default()).unwrap();
DataKey::construct_internal(tagged!("hello_458/world@1"), Default::default()).unwrap();
DataKey::construct_internal(tagged!("hello_world@1"), Default::default()).unwrap();
// No version:
assert_eq!(
DataKey::construct_internal(tagged!("hello/world"), Default::default()),
Err((
"[a-zA-z0-9_/@]",
concat!(leading_tag!(), "hello/world").len()
))
);
assert_eq!(
DataKey::construct_internal(tagged!("hello/world@"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "hello/world@").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("hello/world@foo"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "hello/world@").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("hello/world@1foo"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "hello/world@1").len()))
);
// Meta no longer accepted:
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[R]"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[u-ca]"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[R][u-ca]"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
// Invalid meta:
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[U]"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[uca]"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[u-"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[u-caa]"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
assert_eq!(
DataKey::construct_internal(tagged!("foo@1[R"), Default::default()),
Err(("[0-9]", concat!(leading_tag!(), "foo@1").len()))
);
// Invalid characters:
assert_eq!(
DataKey::construct_internal(tagged!("你好/世界@1"), Default::default()),
Err(("[a-zA-Z0-9_]", leading_tag!().len()))
);
// Invalid tag:
assert_eq!(
DataKey::construct_internal(
concat!("hello/world@1", trailing_tag!()),
Default::default()
),
Err(("tag", 0))
);
assert_eq!(
DataKey::construct_internal(concat!(leading_tag!(), "hello/world@1"), Default::default()),
Err(("tag", concat!(leading_tag!(), "hello/world@1").len()))
);
assert_eq!(
DataKey::construct_internal("hello/world@1", Default::default()),
Err(("tag", 0))
);
}
#[test]
fn test_key_to_string() {
struct KeyTestCase {
pub key: DataKey,
pub expected: &'static str,
}
for cas in [
KeyTestCase {
key: data_key!("core/cardinal@1"),
expected: "core/cardinal@1",
},
KeyTestCase {
key: data_key!("core/maxlengthsubcatg@1"),
expected: "core/maxlengthsubcatg@1",
},
KeyTestCase {
key: data_key!("core/cardinal@65535"),
expected: "core/cardinal@65535",
},
] {
writeable::assert_writeable_eq!(&cas.key, cas.expected);
assert_eq!(cas.expected, &*cas.key.path());
}
}
#[test]
fn test_hash_word_32() {
assert_eq!(0, fxhash_32(b"", 0, 0));
assert_eq!(0, fxhash_32(b"a", 1, 0));
assert_eq!(0, fxhash_32(b"a", 0, 1));
assert_eq!(0, fxhash_32(b"a", 0, 10));
assert_eq!(0, fxhash_32(b"a", 10, 0));
assert_eq!(0, fxhash_32(b"a", 1, 1));
assert_eq!(0xF3051F19, fxhash_32(b"a", 0, 0));
assert_eq!(0x2F9DF119, fxhash_32(b"ab", 0, 0));
assert_eq!(0xCB1D9396, fxhash_32(b"abc", 0, 0));
assert_eq!(0x8628F119, fxhash_32(b"abcd", 0, 0));
assert_eq!(0xBEBDB56D, fxhash_32(b"abcde", 0, 0));
assert_eq!(0x1CE8476D, fxhash_32(b"abcdef", 0, 0));
assert_eq!(0xC0F176A4, fxhash_32(b"abcdefg", 0, 0));
assert_eq!(0x09AB476D, fxhash_32(b"abcdefgh", 0, 0));
assert_eq!(0xB72F5D88, fxhash_32(b"abcdefghi", 0, 0));
}
#[test]
fn test_key_hash() {
struct KeyTestCase {
pub key: DataKey,
pub hash: DataKeyHash,
}
for cas in [
KeyTestCase {
key: data_key!("core/cardinal@1"),
hash: DataKeyHash([172, 207, 42, 236]),
},
KeyTestCase {
key: data_key!("core/maxlengthsubcatg@1"),
hash: DataKeyHash([193, 6, 79, 61]),
},
KeyTestCase {
key: data_key!("core/cardinal@65535"),
hash: DataKeyHash([176, 131, 182, 223]),
},
] {
assert_eq!(cas.hash, cas.key.hashed(), "{}", cas.key);
}
}
[ Dauer der Verarbeitung: 0.31 Sekunden
(vorverarbeitet)
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2026-04-04
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