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linux/rust/kernel/str.rs
Danilo Krummrich a321f3ad0a rust: str: add {make,to}_{upper,lower}case() to CString 
Add functions to convert a CString to upper- / lowercase, either
in-place or by creating a copy of the original CString.

Naming follows the one from the Rust stdlib, where functions starting
with 'to' create a copy and functions starting with 'make' perform an
in-place conversion.

This is required by the Nova project (GSP only Rust successor of
Nouveau) to convert stringified enum values (representing different GPU
chipsets) to strings in order to generate the corresponding firmware
paths. See also [1].

Link: https://rust-for-linux.zulipchat.com/#narrow/stream/288089-General/topic/String.20manipulation.20in.20kernel.20Rust [1]
Reviewed-by: Alice Ryhl <aliceryhl@google.com>
Signed-off-by: Danilo Krummrich <dakr@redhat.com>
Reviewed-by: Benno Lossin <benno.lossin@proton.me>
Link: https://lore.kernel.org/r/20240223163726.12397-1-dakr@redhat.com
[ Reworded to fix typo and to make the link use the `Link:` tag. ]
Signed-off-by: Miguel Ojeda <ojeda@kernel.org>
2024-04-02 17:41:56 +02:00

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// SPDX-License-Identifier: GPL-2.0
//! String representations.
use alloc::alloc::AllocError;
use alloc::vec::Vec;
use core::fmt::{self, Write};
use core::ops::{self, Deref, DerefMut, Index};
use crate::{
bindings,
error::{code::*, Error},
};
/// Byte string without UTF-8 validity guarantee.
#[repr(transparent)]
pub struct BStr([u8]);
impl BStr {
/// Returns the length of this string.
#[inline]
pub const fn len(&self) -> usize {
self.0.len()
}
/// Returns `true` if the string is empty.
#[inline]
pub const fn is_empty(&self) -> bool {
self.len() == 0
}
/// Creates a [`BStr`] from a `[u8]`.
#[inline]
pub const fn from_bytes(bytes: &[u8]) -> &Self {
// SAFETY: `BStr` is transparent to `[u8]`.
unsafe { &*(bytes as *const [u8] as *const BStr) }
}
}
impl fmt::Display for BStr {
/// Formats printable ASCII characters, escaping the rest.
///
/// ```
/// # use kernel::{fmt, b_str, str::{BStr, CString}};
/// let ascii = b_str!("Hello, BStr!");
/// let s = CString::try_from_fmt(fmt!("{}", ascii)).unwrap();
/// assert_eq!(s.as_bytes(), "Hello, BStr!".as_bytes());
///
/// let non_ascii = b_str!("🦀");
/// let s = CString::try_from_fmt(fmt!("{}", non_ascii)).unwrap();
/// assert_eq!(s.as_bytes(), "\\xf0\\x9f\\xa6\\x80".as_bytes());
/// ```
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
for &b in &self.0 {
match b {
// Common escape codes.
b'\t' => f.write_str("\\t")?,
b'\n' => f.write_str("\\n")?,
b'\r' => f.write_str("\\r")?,
// Printable characters.
0x20..=0x7e => f.write_char(b as char)?,
_ => write!(f, "\\x{:02x}", b)?,
}
}
Ok(())
}
}
impl fmt::Debug for BStr {
/// Formats printable ASCII characters with a double quote on either end,
/// escaping the rest.
///
/// ```
/// # use kernel::{fmt, b_str, str::{BStr, CString}};
/// // Embedded double quotes are escaped.
/// let ascii = b_str!("Hello, \"BStr\"!");
/// let s = CString::try_from_fmt(fmt!("{:?}", ascii)).unwrap();
/// assert_eq!(s.as_bytes(), "\"Hello, \\\"BStr\\\"!\"".as_bytes());
///
/// let non_ascii = b_str!("😺");
/// let s = CString::try_from_fmt(fmt!("{:?}", non_ascii)).unwrap();
/// assert_eq!(s.as_bytes(), "\"\\xf0\\x9f\\x98\\xba\"".as_bytes());
/// ```
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.write_char('"')?;
for &b in &self.0 {
match b {
// Common escape codes.
b'\t' => f.write_str("\\t")?,
b'\n' => f.write_str("\\n")?,
b'\r' => f.write_str("\\r")?,
// String escape characters.
b'\"' => f.write_str("\\\"")?,
b'\\' => f.write_str("\\\\")?,
// Printable characters.
0x20..=0x7e => f.write_char(b as char)?,
_ => write!(f, "\\x{:02x}", b)?,
}
}
f.write_char('"')
}
}
impl Deref for BStr {
type Target = [u8];
#[inline]
fn deref(&self) -> &Self::Target {
&self.0
}
}
/// Creates a new [`BStr`] from a string literal.
///
/// `b_str!` converts the supplied string literal to byte string, so non-ASCII
/// characters can be included.
///
/// # Examples
///
/// ```
/// # use kernel::b_str;
/// # use kernel::str::BStr;
/// const MY_BSTR: &BStr = b_str!("My awesome BStr!");
/// ```
#[macro_export]
macro_rules! b_str {
($str:literal) => {{
const S: &'static str = $str;
const C: &'static $crate::str::BStr = $crate::str::BStr::from_bytes(S.as_bytes());
C
}};
}
/// Possible errors when using conversion functions in [`CStr`].
#[derive(Debug, Clone, Copy)]
pub enum CStrConvertError {
/// Supplied bytes contain an interior `NUL`.
InteriorNul,
/// Supplied bytes are not terminated by `NUL`.
NotNulTerminated,
}
impl From<CStrConvertError> for Error {
#[inline]
fn from(_: CStrConvertError) -> Error {
EINVAL
}
}
/// A string that is guaranteed to have exactly one `NUL` byte, which is at the
/// end.
///
/// Used for interoperability with kernel APIs that take C strings.
#[repr(transparent)]
pub struct CStr([u8]);
impl CStr {
/// Returns the length of this string excluding `NUL`.
#[inline]
pub const fn len(&self) -> usize {
self.len_with_nul() - 1
}
/// Returns the length of this string with `NUL`.
#[inline]
pub const fn len_with_nul(&self) -> usize {
// SAFETY: This is one of the invariant of `CStr`.
// We add a `unreachable_unchecked` here to hint the optimizer that
// the value returned from this function is non-zero.
if self.0.is_empty() {
unsafe { core::hint::unreachable_unchecked() };
}
self.0.len()
}
/// Returns `true` if the string only includes `NUL`.
#[inline]
pub const fn is_empty(&self) -> bool {
self.len() == 0
}
/// Wraps a raw C string pointer.
///
/// # Safety
///
/// `ptr` must be a valid pointer to a `NUL`-terminated C string, and it must
/// last at least `'a`. When `CStr` is alive, the memory pointed by `ptr`
/// must not be mutated.
#[inline]
pub unsafe fn from_char_ptr<'a>(ptr: *const core::ffi::c_char) -> &'a Self {
// SAFETY: The safety precondition guarantees `ptr` is a valid pointer
// to a `NUL`-terminated C string.
let len = unsafe { bindings::strlen(ptr) } + 1;
// SAFETY: Lifetime guaranteed by the safety precondition.
let bytes = unsafe { core::slice::from_raw_parts(ptr as _, len as _) };
// SAFETY: As `len` is returned by `strlen`, `bytes` does not contain interior `NUL`.
// As we have added 1 to `len`, the last byte is known to be `NUL`.
unsafe { Self::from_bytes_with_nul_unchecked(bytes) }
}
/// Creates a [`CStr`] from a `[u8]`.
///
/// The provided slice must be `NUL`-terminated, does not contain any
/// interior `NUL` bytes.
pub const fn from_bytes_with_nul(bytes: &[u8]) -> Result<&Self, CStrConvertError> {
if bytes.is_empty() {
return Err(CStrConvertError::NotNulTerminated);
}
if bytes[bytes.len() - 1] != 0 {
return Err(CStrConvertError::NotNulTerminated);
}
let mut i = 0;
// `i + 1 < bytes.len()` allows LLVM to optimize away bounds checking,
// while it couldn't optimize away bounds checks for `i < bytes.len() - 1`.
while i + 1 < bytes.len() {
if bytes[i] == 0 {
return Err(CStrConvertError::InteriorNul);
}
i += 1;
}
// SAFETY: We just checked that all properties hold.
Ok(unsafe { Self::from_bytes_with_nul_unchecked(bytes) })
}
/// Creates a [`CStr`] from a `[u8]` without performing any additional
/// checks.
///
/// # Safety
///
/// `bytes` *must* end with a `NUL` byte, and should only have a single
/// `NUL` byte (or the string will be truncated).
#[inline]
pub const unsafe fn from_bytes_with_nul_unchecked(bytes: &[u8]) -> &CStr {
// SAFETY: Properties of `bytes` guaranteed by the safety precondition.
unsafe { core::mem::transmute(bytes) }
}
/// Creates a mutable [`CStr`] from a `[u8]` without performing any
/// additional checks.
///
/// # Safety
///
/// `bytes` *must* end with a `NUL` byte, and should only have a single
/// `NUL` byte (or the string will be truncated).
#[inline]
pub unsafe fn from_bytes_with_nul_unchecked_mut(bytes: &mut [u8]) -> &mut CStr {
// SAFETY: Properties of `bytes` guaranteed by the safety precondition.
unsafe { &mut *(bytes as *mut [u8] as *mut CStr) }
}
/// Returns a C pointer to the string.
#[inline]
pub const fn as_char_ptr(&self) -> *const core::ffi::c_char {
self.0.as_ptr() as _
}
/// Convert the string to a byte slice without the trailing `NUL` byte.
#[inline]
pub fn as_bytes(&self) -> &[u8] {
&self.0[..self.len()]
}
/// Convert the string to a byte slice containing the trailing `NUL` byte.
#[inline]
pub const fn as_bytes_with_nul(&self) -> &[u8] {
&self.0
}
/// Yields a [`&str`] slice if the [`CStr`] contains valid UTF-8.
///
/// If the contents of the [`CStr`] are valid UTF-8 data, this
/// function will return the corresponding [`&str`] slice. Otherwise,
/// it will return an error with details of where UTF-8 validation failed.
///
/// # Examples
///
/// ```
/// # use kernel::str::CStr;
/// let cstr = CStr::from_bytes_with_nul(b"foo\0").unwrap();
/// assert_eq!(cstr.to_str(), Ok("foo"));
/// ```
#[inline]
pub fn to_str(&self) -> Result<&str, core::str::Utf8Error> {
core::str::from_utf8(self.as_bytes())
}
/// Unsafely convert this [`CStr`] into a [`&str`], without checking for
/// valid UTF-8.
///
/// # Safety
///
/// The contents must be valid UTF-8.
///
/// # Examples
///
/// ```
/// # use kernel::c_str;
/// # use kernel::str::CStr;
/// let bar = c_str!("ツ");
/// // SAFETY: String literals are guaranteed to be valid UTF-8
/// // by the Rust compiler.
/// assert_eq!(unsafe { bar.as_str_unchecked() }, "ツ");
/// ```
#[inline]
pub unsafe fn as_str_unchecked(&self) -> &str {
unsafe { core::str::from_utf8_unchecked(self.as_bytes()) }
}
/// Convert this [`CStr`] into a [`CString`] by allocating memory and
/// copying over the string data.
pub fn to_cstring(&self) -> Result<CString, AllocError> {
CString::try_from(self)
}
/// Converts this [`CStr`] to its ASCII lower case equivalent in-place.
///
/// ASCII letters 'A' to 'Z' are mapped to 'a' to 'z',
/// but non-ASCII letters are unchanged.
///
/// To return a new lowercased value without modifying the existing one, use
/// [`to_ascii_lowercase()`].
///
/// [`to_ascii_lowercase()`]: #method.to_ascii_lowercase
pub fn make_ascii_lowercase(&mut self) {
// INVARIANT: This doesn't introduce or remove NUL bytes in the C
// string.
self.0.make_ascii_lowercase();
}
/// Converts this [`CStr`] to its ASCII upper case equivalent in-place.
///
/// ASCII letters 'a' to 'z' are mapped to 'A' to 'Z',
/// but non-ASCII letters are unchanged.
///
/// To return a new uppercased value without modifying the existing one, use
/// [`to_ascii_uppercase()`].
///
/// [`to_ascii_uppercase()`]: #method.to_ascii_uppercase
pub fn make_ascii_uppercase(&mut self) {
// INVARIANT: This doesn't introduce or remove NUL bytes in the C
// string.
self.0.make_ascii_uppercase();
}
/// Returns a copy of this [`CString`] where each character is mapped to its
/// ASCII lower case equivalent.
///
/// ASCII letters 'A' to 'Z' are mapped to 'a' to 'z',
/// but non-ASCII letters are unchanged.
///
/// To lowercase the value in-place, use [`make_ascii_lowercase`].
///
/// [`make_ascii_lowercase`]: str::make_ascii_lowercase
pub fn to_ascii_lowercase(&self) -> Result<CString, AllocError> {
let mut s = self.to_cstring()?;
s.make_ascii_lowercase();
Ok(s)
}
/// Returns a copy of this [`CString`] where each character is mapped to its
/// ASCII upper case equivalent.
///
/// ASCII letters 'a' to 'z' are mapped to 'A' to 'Z',
/// but non-ASCII letters are unchanged.
///
/// To uppercase the value in-place, use [`make_ascii_uppercase`].
///
/// [`make_ascii_uppercase`]: str::make_ascii_uppercase
pub fn to_ascii_uppercase(&self) -> Result<CString, AllocError> {
let mut s = self.to_cstring()?;
s.make_ascii_uppercase();
Ok(s)
}
}
impl fmt::Display for CStr {
/// Formats printable ASCII characters, escaping the rest.
///
/// ```
/// # use kernel::c_str;
/// # use kernel::fmt;
/// # use kernel::str::CStr;
/// # use kernel::str::CString;
/// let penguin = c_str!("🐧");
/// let s = CString::try_from_fmt(fmt!("{}", penguin)).unwrap();
/// assert_eq!(s.as_bytes_with_nul(), "\\xf0\\x9f\\x90\\xa7\0".as_bytes());
///
/// let ascii = c_str!("so \"cool\"");
/// let s = CString::try_from_fmt(fmt!("{}", ascii)).unwrap();
/// assert_eq!(s.as_bytes_with_nul(), "so \"cool\"\0".as_bytes());
/// ```
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
for &c in self.as_bytes() {
if (0x20..0x7f).contains(&c) {
// Printable character.
f.write_char(c as char)?;
} else {
write!(f, "\\x{:02x}", c)?;
}
}
Ok(())
}
}
impl fmt::Debug for CStr {
/// Formats printable ASCII characters with a double quote on either end, escaping the rest.
///
/// ```
/// # use kernel::c_str;
/// # use kernel::fmt;
/// # use kernel::str::CStr;
/// # use kernel::str::CString;
/// let penguin = c_str!("🐧");
/// let s = CString::try_from_fmt(fmt!("{:?}", penguin)).unwrap();
/// assert_eq!(s.as_bytes_with_nul(), "\"\\xf0\\x9f\\x90\\xa7\"\0".as_bytes());
///
/// // Embedded double quotes are escaped.
/// let ascii = c_str!("so \"cool\"");
/// let s = CString::try_from_fmt(fmt!("{:?}", ascii)).unwrap();
/// assert_eq!(s.as_bytes_with_nul(), "\"so \\\"cool\\\"\"\0".as_bytes());
/// ```
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.write_str("\"")?;
for &c in self.as_bytes() {
match c {
// Printable characters.
b'\"' => f.write_str("\\\"")?,
0x20..=0x7e => f.write_char(c as char)?,
_ => write!(f, "\\x{:02x}", c)?,
}
}
f.write_str("\"")
}
}
impl AsRef<BStr> for CStr {
#[inline]
fn as_ref(&self) -> &BStr {
BStr::from_bytes(self.as_bytes())
}
}
impl Deref for CStr {
type Target = BStr;
#[inline]
fn deref(&self) -> &Self::Target {
self.as_ref()
}
}
impl Index<ops::RangeFrom<usize>> for CStr {
type Output = CStr;
#[inline]
fn index(&self, index: ops::RangeFrom<usize>) -> &Self::Output {
// Delegate bounds checking to slice.
// Assign to _ to mute clippy's unnecessary operation warning.
let _ = &self.as_bytes()[index.start..];
// SAFETY: We just checked the bounds.
unsafe { Self::from_bytes_with_nul_unchecked(&self.0[index.start..]) }
}
}
impl Index<ops::RangeFull> for CStr {
type Output = CStr;
#[inline]
fn index(&self, _index: ops::RangeFull) -> &Self::Output {
self
}
}
mod private {
use core::ops;
// Marker trait for index types that can be forward to `BStr`.
pub trait CStrIndex {}
impl CStrIndex for usize {}
impl CStrIndex for ops::Range<usize> {}
impl CStrIndex for ops::RangeInclusive<usize> {}
impl CStrIndex for ops::RangeToInclusive<usize> {}
}
impl<Idx> Index<Idx> for CStr
where
Idx: private::CStrIndex,
BStr: Index<Idx>,
{
type Output = <BStr as Index<Idx>>::Output;
#[inline]
fn index(&self, index: Idx) -> &Self::Output {
&self.as_ref()[index]
}
}
/// Creates a new [`CStr`] from a string literal.
///
/// The string literal should not contain any `NUL` bytes.
///
/// # Examples
///
/// ```
/// # use kernel::c_str;
/// # use kernel::str::CStr;
/// const MY_CSTR: &CStr = c_str!("My awesome CStr!");
/// ```
#[macro_export]
macro_rules! c_str {
($str:expr) => {{
const S: &str = concat!($str, "\0");
const C: &$crate::str::CStr = match $crate::str::CStr::from_bytes_with_nul(S.as_bytes()) {
Ok(v) => v,
Err(_) => panic!("string contains interior NUL"),
};
C
}};
}
#[cfg(test)]
mod tests {
use super::*;
use alloc::format;
const ALL_ASCII_CHARS: &'static str =
"\\x01\\x02\\x03\\x04\\x05\\x06\\x07\\x08\\x09\\x0a\\x0b\\x0c\\x0d\\x0e\\x0f\
\\x10\\x11\\x12\\x13\\x14\\x15\\x16\\x17\\x18\\x19\\x1a\\x1b\\x1c\\x1d\\x1e\\x1f \
!\"#$%&'()*+,-./0123456789:;<=>?@\
ABCDEFGHIJKLMNOPQRSTUVWXYZ[\\]^_`abcdefghijklmnopqrstuvwxyz{|}~\\x7f\
\\x80\\x81\\x82\\x83\\x84\\x85\\x86\\x87\\x88\\x89\\x8a\\x8b\\x8c\\x8d\\x8e\\x8f\
\\x90\\x91\\x92\\x93\\x94\\x95\\x96\\x97\\x98\\x99\\x9a\\x9b\\x9c\\x9d\\x9e\\x9f\
\\xa0\\xa1\\xa2\\xa3\\xa4\\xa5\\xa6\\xa7\\xa8\\xa9\\xaa\\xab\\xac\\xad\\xae\\xaf\
\\xb0\\xb1\\xb2\\xb3\\xb4\\xb5\\xb6\\xb7\\xb8\\xb9\\xba\\xbb\\xbc\\xbd\\xbe\\xbf\
\\xc0\\xc1\\xc2\\xc3\\xc4\\xc5\\xc6\\xc7\\xc8\\xc9\\xca\\xcb\\xcc\\xcd\\xce\\xcf\
\\xd0\\xd1\\xd2\\xd3\\xd4\\xd5\\xd6\\xd7\\xd8\\xd9\\xda\\xdb\\xdc\\xdd\\xde\\xdf\
\\xe0\\xe1\\xe2\\xe3\\xe4\\xe5\\xe6\\xe7\\xe8\\xe9\\xea\\xeb\\xec\\xed\\xee\\xef\
\\xf0\\xf1\\xf2\\xf3\\xf4\\xf5\\xf6\\xf7\\xf8\\xf9\\xfa\\xfb\\xfc\\xfd\\xfe\\xff";
#[test]
fn test_cstr_to_str() {
let good_bytes = b"\xf0\x9f\xa6\x80\0";
let checked_cstr = CStr::from_bytes_with_nul(good_bytes).unwrap();
let checked_str = checked_cstr.to_str().unwrap();
assert_eq!(checked_str, "🦀");
}
#[test]
#[should_panic]
fn test_cstr_to_str_panic() {
let bad_bytes = b"\xc3\x28\0";
let checked_cstr = CStr::from_bytes_with_nul(bad_bytes).unwrap();
checked_cstr.to_str().unwrap();
}
#[test]
fn test_cstr_as_str_unchecked() {
let good_bytes = b"\xf0\x9f\x90\xA7\0";
let checked_cstr = CStr::from_bytes_with_nul(good_bytes).unwrap();
let unchecked_str = unsafe { checked_cstr.as_str_unchecked() };
assert_eq!(unchecked_str, "🐧");
}
#[test]
fn test_cstr_display() {
let hello_world = CStr::from_bytes_with_nul(b"hello, world!\0").unwrap();
assert_eq!(format!("{}", hello_world), "hello, world!");
let non_printables = CStr::from_bytes_with_nul(b"\x01\x09\x0a\0").unwrap();
assert_eq!(format!("{}", non_printables), "\\x01\\x09\\x0a");
let non_ascii = CStr::from_bytes_with_nul(b"d\xe9j\xe0 vu\0").unwrap();
assert_eq!(format!("{}", non_ascii), "d\\xe9j\\xe0 vu");
let good_bytes = CStr::from_bytes_with_nul(b"\xf0\x9f\xa6\x80\0").unwrap();
assert_eq!(format!("{}", good_bytes), "\\xf0\\x9f\\xa6\\x80");
}
#[test]
fn test_cstr_display_all_bytes() {
let mut bytes: [u8; 256] = [0; 256];
// fill `bytes` with [1..=255] + [0]
for i in u8::MIN..=u8::MAX {
bytes[i as usize] = i.wrapping_add(1);
}
let cstr = CStr::from_bytes_with_nul(&bytes).unwrap();
assert_eq!(format!("{}", cstr), ALL_ASCII_CHARS);
}
#[test]
fn test_cstr_debug() {
let hello_world = CStr::from_bytes_with_nul(b"hello, world!\0").unwrap();
assert_eq!(format!("{:?}", hello_world), "\"hello, world!\"");
let non_printables = CStr::from_bytes_with_nul(b"\x01\x09\x0a\0").unwrap();
assert_eq!(format!("{:?}", non_printables), "\"\\x01\\x09\\x0a\"");
let non_ascii = CStr::from_bytes_with_nul(b"d\xe9j\xe0 vu\0").unwrap();
assert_eq!(format!("{:?}", non_ascii), "\"d\\xe9j\\xe0 vu\"");
let good_bytes = CStr::from_bytes_with_nul(b"\xf0\x9f\xa6\x80\0").unwrap();
assert_eq!(format!("{:?}", good_bytes), "\"\\xf0\\x9f\\xa6\\x80\"");
}
#[test]
fn test_bstr_display() {
let hello_world = BStr::from_bytes(b"hello, world!");
assert_eq!(format!("{}", hello_world), "hello, world!");
let escapes = BStr::from_bytes(b"_\t_\n_\r_\\_\'_\"_");
assert_eq!(format!("{}", escapes), "_\\t_\\n_\\r_\\_'_\"_");
let others = BStr::from_bytes(b"\x01");
assert_eq!(format!("{}", others), "\\x01");
let non_ascii = BStr::from_bytes(b"d\xe9j\xe0 vu");
assert_eq!(format!("{}", non_ascii), "d\\xe9j\\xe0 vu");
let good_bytes = BStr::from_bytes(b"\xf0\x9f\xa6\x80");
assert_eq!(format!("{}", good_bytes), "\\xf0\\x9f\\xa6\\x80");
}
#[test]
fn test_bstr_debug() {
let hello_world = BStr::from_bytes(b"hello, world!");
assert_eq!(format!("{:?}", hello_world), "\"hello, world!\"");
let escapes = BStr::from_bytes(b"_\t_\n_\r_\\_\'_\"_");
assert_eq!(format!("{:?}", escapes), "\"_\\t_\\n_\\r_\\\\_'_\\\"_\"");
let others = BStr::from_bytes(b"\x01");
assert_eq!(format!("{:?}", others), "\"\\x01\"");
let non_ascii = BStr::from_bytes(b"d\xe9j\xe0 vu");
assert_eq!(format!("{:?}", non_ascii), "\"d\\xe9j\\xe0 vu\"");
let good_bytes = BStr::from_bytes(b"\xf0\x9f\xa6\x80");
assert_eq!(format!("{:?}", good_bytes), "\"\\xf0\\x9f\\xa6\\x80\"");
}
}
/// Allows formatting of [`fmt::Arguments`] into a raw buffer.
///
/// It does not fail if callers write past the end of the buffer so that they can calculate the
/// size required to fit everything.
///
/// # Invariants
///
/// The memory region between `pos` (inclusive) and `end` (exclusive) is valid for writes if `pos`
/// is less than `end`.
pub(crate) struct RawFormatter {
// Use `usize` to use `saturating_*` functions.
beg: usize,
pos: usize,
end: usize,
}
impl RawFormatter {
/// Creates a new instance of [`RawFormatter`] with an empty buffer.
fn new() -> Self {
// INVARIANT: The buffer is empty, so the region that needs to be writable is empty.
Self {
beg: 0,
pos: 0,
end: 0,
}
}
/// Creates a new instance of [`RawFormatter`] with the given buffer pointers.
///
/// # Safety
///
/// If `pos` is less than `end`, then the region between `pos` (inclusive) and `end`
/// (exclusive) must be valid for writes for the lifetime of the returned [`RawFormatter`].
pub(crate) unsafe fn from_ptrs(pos: *mut u8, end: *mut u8) -> Self {
// INVARIANT: The safety requirements guarantee the type invariants.
Self {
beg: pos as _,
pos: pos as _,
end: end as _,
}
}
/// Creates a new instance of [`RawFormatter`] with the given buffer.
///
/// # Safety
///
/// The memory region starting at `buf` and extending for `len` bytes must be valid for writes
/// for the lifetime of the returned [`RawFormatter`].
pub(crate) unsafe fn from_buffer(buf: *mut u8, len: usize) -> Self {
let pos = buf as usize;
// INVARIANT: We ensure that `end` is never less then `buf`, and the safety requirements
// guarantees that the memory region is valid for writes.
Self {
pos,
beg: pos,
end: pos.saturating_add(len),
}
}
/// Returns the current insert position.
///
/// N.B. It may point to invalid memory.
pub(crate) fn pos(&self) -> *mut u8 {
self.pos as _
}
/// Returns the number of bytes written to the formatter.
pub(crate) fn bytes_written(&self) -> usize {
self.pos - self.beg
}
}
impl fmt::Write for RawFormatter {
fn write_str(&mut self, s: &str) -> fmt::Result {
// `pos` value after writing `len` bytes. This does not have to be bounded by `end`, but we
// don't want it to wrap around to 0.
let pos_new = self.pos.saturating_add(s.len());
// Amount that we can copy. `saturating_sub` ensures we get 0 if `pos` goes past `end`.
let len_to_copy = core::cmp::min(pos_new, self.end).saturating_sub(self.pos);
if len_to_copy > 0 {
// SAFETY: If `len_to_copy` is non-zero, then we know `pos` has not gone past `end`
// yet, so it is valid for write per the type invariants.
unsafe {
core::ptr::copy_nonoverlapping(
s.as_bytes().as_ptr(),
self.pos as *mut u8,
len_to_copy,
)
};
}
self.pos = pos_new;
Ok(())
}
}
/// Allows formatting of [`fmt::Arguments`] into a raw buffer.
///
/// Fails if callers attempt to write more than will fit in the buffer.
pub(crate) struct Formatter(RawFormatter);
impl Formatter {
/// Creates a new instance of [`Formatter`] with the given buffer.
///
/// # Safety
///
/// The memory region starting at `buf` and extending for `len` bytes must be valid for writes
/// for the lifetime of the returned [`Formatter`].
pub(crate) unsafe fn from_buffer(buf: *mut u8, len: usize) -> Self {
// SAFETY: The safety requirements of this function satisfy those of the callee.
Self(unsafe { RawFormatter::from_buffer(buf, len) })
}
}
impl Deref for Formatter {
type Target = RawFormatter;
fn deref(&self) -> &Self::Target {
&self.0
}
}
impl fmt::Write for Formatter {
fn write_str(&mut self, s: &str) -> fmt::Result {
self.0.write_str(s)?;
// Fail the request if we go past the end of the buffer.
if self.0.pos > self.0.end {
Err(fmt::Error)
} else {
Ok(())
}
}
}
/// An owned string that is guaranteed to have exactly one `NUL` byte, which is at the end.
///
/// Used for interoperability with kernel APIs that take C strings.
///
/// # Invariants
///
/// The string is always `NUL`-terminated and contains no other `NUL` bytes.
///
/// # Examples
///
/// ```
/// use kernel::{str::CString, fmt};
///
/// let s = CString::try_from_fmt(fmt!("{}{}{}", "abc", 10, 20)).unwrap();
/// assert_eq!(s.as_bytes_with_nul(), "abc1020\0".as_bytes());
///
/// let tmp = "testing";
/// let s = CString::try_from_fmt(fmt!("{tmp}{}", 123)).unwrap();
/// assert_eq!(s.as_bytes_with_nul(), "testing123\0".as_bytes());
///
/// // This fails because it has an embedded `NUL` byte.
/// let s = CString::try_from_fmt(fmt!("a\0b{}", 123));
/// assert_eq!(s.is_ok(), false);
/// ```
pub struct CString {
buf: Vec<u8>,
}
impl CString {
/// Creates an instance of [`CString`] from the given formatted arguments.
pub fn try_from_fmt(args: fmt::Arguments<'_>) -> Result<Self, Error> {
// Calculate the size needed (formatted string plus `NUL` terminator).
let mut f = RawFormatter::new();
f.write_fmt(args)?;
f.write_str("\0")?;
let size = f.bytes_written();
// Allocate a vector with the required number of bytes, and write to it.
let mut buf = Vec::try_with_capacity(size)?;
// SAFETY: The buffer stored in `buf` is at least of size `size` and is valid for writes.
let mut f = unsafe { Formatter::from_buffer(buf.as_mut_ptr(), size) };
f.write_fmt(args)?;
f.write_str("\0")?;
// SAFETY: The number of bytes that can be written to `f` is bounded by `size`, which is
// `buf`'s capacity. The contents of the buffer have been initialised by writes to `f`.
unsafe { buf.set_len(f.bytes_written()) };
// Check that there are no `NUL` bytes before the end.
// SAFETY: The buffer is valid for read because `f.bytes_written()` is bounded by `size`
// (which the minimum buffer size) and is non-zero (we wrote at least the `NUL` terminator)
// so `f.bytes_written() - 1` doesn't underflow.
let ptr = unsafe { bindings::memchr(buf.as_ptr().cast(), 0, (f.bytes_written() - 1) as _) };
if !ptr.is_null() {
return Err(EINVAL);
}
// INVARIANT: We wrote the `NUL` terminator and checked above that no other `NUL` bytes
// exist in the buffer.
Ok(Self { buf })
}
}
impl Deref for CString {
type Target = CStr;
fn deref(&self) -> &Self::Target {
// SAFETY: The type invariants guarantee that the string is `NUL`-terminated and that no
// other `NUL` bytes exist.
unsafe { CStr::from_bytes_with_nul_unchecked(self.buf.as_slice()) }
}
}
impl DerefMut for CString {
fn deref_mut(&mut self) -> &mut Self::Target {
// SAFETY: A `CString` is always NUL-terminated and contains no other
// NUL bytes.
unsafe { CStr::from_bytes_with_nul_unchecked_mut(self.buf.as_mut_slice()) }
}
}
impl<'a> TryFrom<&'a CStr> for CString {
type Error = AllocError;
fn try_from(cstr: &'a CStr) -> Result<CString, AllocError> {
let mut buf = Vec::new();
buf.try_extend_from_slice(cstr.as_bytes_with_nul())
.map_err(|_| AllocError)?;
// INVARIANT: The `CStr` and `CString` types have the same invariants for
// the string data, and we copied it over without changes.
Ok(CString { buf })
}
}
impl fmt::Debug for CString {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Debug::fmt(&**self, f)
}
}
/// A convenience alias for [`core::format_args`].
#[macro_export]
macro_rules! fmt {
($($f:tt)*) => ( core::format_args!($($f)*) )
}
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