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mod.rs
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//! Traits, helpers, and type definitions for core I/O functionality.
//!
//! The `std::io` module contains a number of common things you'll need
//! when doing input and output. The most core part of this module is
//! the [`Read`] and [`Write`] traits, which provide the
//! most general interface for reading and writing input and output.
//!
//! # Read and Write
//!
//! Because they are traits, [`Read`] and [`Write`] are implemented by a number
//! of other types, and you can implement them for your types too. As such,
//! you'll see a few different types of I/O throughout the documentation in
//! this module: [`File`]s, [`TcpStream`]s, and sometimes even [`Vec<T>`]s. For
//! example, [`Read`] adds a [`read`][`Read::read`] method, which we can use on
//! [`File`]s:
//!
//! ```no_run
//! use std::io;
//! use std::io::prelude::*;
//! use std::fs::File;
//!
//! fn main() -> io::Result<()> {
//! let mut f = File::open("foo.txt")?;
//! let mut buffer = [0; 10];
//!
//! // read up to 10 bytes
//! let n = f.read(&mut buffer)?;
//!
//! println!("The bytes: {:?}", &buffer[..n]);
//! Ok(())
//! }
//! ```
//!
//! [`Read`] and [`Write`] are so important, implementors of the two traits have a
//! nickname: readers and writers. So you'll sometimes see 'a reader' instead
//! of 'a type that implements the [`Read`] trait'. Much easier!
//!
//! ## Seek and BufRead
//!
//! Beyond that, there are two important traits that are provided: [`Seek`]
//! and [`BufRead`]. Both of these build on top of a reader to control
//! how the reading happens. [`Seek`] lets you control where the next byte is
//! coming from:
//!
//! ```no_run
//! use std::io;
//! use std::io::prelude::*;
//! use std::io::SeekFrom;
//! use std::fs::File;
//!
//! fn main() -> io::Result<()> {
//! let mut f = File::open("foo.txt")?;
//! let mut buffer = [0; 10];
//!
//! // skip to the last 10 bytes of the file
//! f.seek(SeekFrom::End(-10))?;
//!
//! // read up to 10 bytes
//! let n = f.read(&mut buffer)?;
//!
//! println!("The bytes: {:?}", &buffer[..n]);
//! Ok(())
//! }
//! ```
//!
//! [`BufRead`] uses an internal buffer to provide a number of other ways to read, but
//! to show it off, we'll need to talk about buffers in general. Keep reading!
//!
//! ## BufReader and BufWriter
//!
//! Byte-based interfaces are unwieldy and can be inefficient, as we'd need to be
//! making near-constant calls to the operating system. To help with this,
//! `std::io` comes with two structs, [`BufReader`] and [`BufWriter`], which wrap
//! readers and writers. The wrapper uses a buffer, reducing the number of
//! calls and providing nicer methods for accessing exactly what you want.
//!
//! For example, [`BufReader`] works with the [`BufRead`] trait to add extra
//! methods to any reader:
//!
//! ```no_run
//! use std::io;
//! use std::io::prelude::*;
//! use std::io::BufReader;
//! use std::fs::File;
//!
//! fn main() -> io::Result<()> {
//! let f = File::open("foo.txt")?;
//! let mut reader = BufReader::new(f);
//! let mut buffer = String::new();
//!
//! // read a line into buffer
//! reader.read_line(&mut buffer)?;
//!
//! println!("{buffer}");
//! Ok(())
//! }
//! ```
//!
//! [`BufWriter`] doesn't add any new ways of writing; it just buffers every call
//! to [`write`][`Write::write`]:
//!
//! ```no_run
//! use std::io;
//! use std::io::prelude::*;
//! use std::io::BufWriter;
//! use std::fs::File;
//!
//! fn main() -> io::Result<()> {
//! let f = File::create("foo.txt")?;
//! {
//! let mut writer = BufWriter::new(f);
//!
//! // write a byte to the buffer
//! writer.write(&[42])?;
//!
//! } // the buffer is flushed once writer goes out of scope
//!
//! Ok(())
//! }
//! ```
//!
//! ## Standard input and output
//!
//! A very common source of input is standard input:
//!
//! ```no_run
//! use std::io;
//!
//! fn main() -> io::Result<()> {
//! let mut input = String::new();
//!
//! io::stdin().read_line(&mut input)?;
//!
//! println!("You typed: {}", input.trim());
//! Ok(())
//! }
//! ```
//!
//! Note that you cannot use the [`?` operator] in functions that do not return
//! a [`Result<T, E>`][`Result`]. Instead, you can call [`.unwrap()`]
//! or `match` on the return value to catch any possible errors:
//!
//! ```no_run
//! use std::io;
//!
//! let mut input = String::new();
//!
//! io::stdin().read_line(&mut input).unwrap();
//! ```
//!
//! And a very common source of output is standard output:
//!
//! ```no_run
//! use std::io;
//! use std::io::prelude::*;
//!
//! fn main() -> io::Result<()> {
//! io::stdout().write(&[42])?;
//! Ok(())
//! }
//! ```
//!
//! Of course, using [`io::stdout`] directly is less common than something like
//! [`println!`].
//!
//! ## Iterator types
//!
//! A large number of the structures provided by `std::io` are for various
//! ways of iterating over I/O. For example, [`Lines`] is used to split over
//! lines:
//!
//! ```no_run
//! use std::io;
//! use std::io::prelude::*;
//! use std::io::BufReader;
//! use std::fs::File;
//!
//! fn main() -> io::Result<()> {
//! let f = File::open("foo.txt")?;
//! let reader = BufReader::new(f);
//!
//! for line in reader.lines() {
//! println!("{}", line?);
//! }
//! Ok(())
//! }
//! ```
//!
//! ## Functions
//!
//! There are a number of [functions][functions-list] that offer access to various
//! features. For example, we can use three of these functions to copy everything
//! from standard input to standard output:
//!
//! ```no_run
//! use std::io;
//!
//! fn main() -> io::Result<()> {
//! io::copy(&mut io::stdin(), &mut io::stdout())?;
//! Ok(())
//! }
//! ```
//!
//! [functions-list]: #functions-1
//!
//! ## io::Result
//!
//! Last, but certainly not least, is [`io::Result`]. This type is used
//! as the return type of many `std::io` functions that can cause an error, and
//! can be returned from your own functions as well. Many of the examples in this
//! module use the [`?` operator]:
//!
//! ```
//! use std::io;
//!
//! fn read_input() -> io::Result<()> {
//! let mut input = String::new();
//!
//! io::stdin().read_line(&mut input)?;
//!
//! println!("You typed: {}", input.trim());
//!
//! Ok(())
//! }
//! ```
//!
//! The return type of `read_input()`, [`io::Result<()>`][`io::Result`], is a very
//! common type for functions which don't have a 'real' return value, but do want to
//! return errors if they happen. In this case, the only purpose of this function is
//! to read the line and print it, so we use `()`.
//!
//! ## Platform-specific behavior
//!
//! Many I/O functions throughout the standard library are documented to indicate
//! what various library or syscalls they are delegated to. This is done to help
//! applications both understand what's happening under the hood as well as investigate
//! any possibly unclear semantics. Note, however, that this is informative, not a binding
//! contract. The implementation of many of these functions are subject to change over
//! time and may call fewer or more syscalls/library functions.
//!
//! [`File`]: crate::fs::File
//! [`TcpStream`]: crate::net::TcpStream
//! [`io::stdout`]: stdout
//! [`io::Result`]: self::Result
//! [`?` operator]: ../../book/appendix-02-operators.html
//! [`Result`]: crate::result::Result
//! [`.unwrap()`]: crate::result::Result::unwrap
#![stable(feature = "rust1", since = "1.0.0")]
#[cfg(test)]
mod tests;
use crate::cmp;
use crate::fmt;
use crate::mem::replace;
use crate::ops::{Deref, DerefMut};
use crate::slice;
use crate::str;
use crate::sys;
use crate::sys_common::memchr;
#[stable(feature = "bufwriter_into_parts", since = "1.56.0")]
pub use self::buffered::WriterPanicked;
pub(crate) use self::stdio::attempt_print_to_stderr;
#[unstable(feature = "internal_output_capture", issue = "none")]
#[doc(no_inline, hidden)]
pub use self::stdio::set_output_capture;
#[unstable(feature = "is_terminal", issue = "98070")]
pub use self::stdio::IsTerminal;
#[unstable(feature = "print_internals", issue = "none")]
pub use self::stdio::{_eprint, _print};
#[stable(feature = "rust1", since = "1.0.0")]
pub use self::{
buffered::{BufReader, BufWriter, IntoInnerError, LineWriter},
copy::copy,
cursor::Cursor,
error::{Error, ErrorKind, Result},
stdio::{stderr, stdin, stdout, Stderr, StderrLock, Stdin, StdinLock, Stdout, StdoutLock},
util::{empty, repeat, sink, Empty, Repeat, Sink},
};
#[unstable(feature = "read_buf", issue = "78485")]
pub use self::readbuf::{BorrowedBuf, BorrowedCursor};
pub(crate) use error::const_io_error;
mod buffered;
pub(crate) mod copy;
mod cursor;
mod error;
mod impls;
pub mod prelude;
mod readbuf;
mod stdio;
mod util;
const DEFAULT_BUF_SIZE: usize = crate::sys_common::io::DEFAULT_BUF_SIZE;
pub(crate) use stdio::cleanup;
struct Guard<'a> {
buf: &'a mut Vec<u8>,
len: usize,
}
impl Drop for Guard<'_> {
fn drop(&mut self) {
unsafe {
self.buf.set_len(self.len);
}
}
}
// Several `read_to_string` and `read_line` methods in the standard library will
// append data into a `String` buffer, but we need to be pretty careful when
// doing this. The implementation will just call `.as_mut_vec()` and then
// delegate to a byte-oriented reading method, but we must ensure that when
// returning we never leave `buf` in a state such that it contains invalid UTF-8
// in its bounds.
//
// To this end, we use an RAII guard (to protect against panics) which updates
// the length of the string when it is dropped. This guard initially truncates
// the string to the prior length and only after we've validated that the
// new contents are valid UTF-8 do we allow it to set a longer length.
//
// The unsafety in this function is twofold:
//
// 1. We're looking at the raw bytes of `buf`, so we take on the burden of UTF-8
// checks.
// 2. We're passing a raw buffer to the function `f`, and it is expected that
// the function only *appends* bytes to the buffer. We'll get undefined
// behavior if existing bytes are overwritten to have non-UTF-8 data.
pub(crate) unsafe fn append_to_string<F>(buf: &mut String, f: F) -> Result<usize>
where
F: FnOnce(&mut Vec<u8>) -> Result<usize>,
{
let mut g = Guard { len: buf.len(), buf: buf.as_mut_vec() };
let ret = f(g.buf);
if str::from_utf8(&g.buf[g.len..]).is_err() {
ret.and_then(|_| {
Err(error::const_io_error!(
ErrorKind::InvalidData,
"stream did not contain valid UTF-8"
))
})
} else {
g.len = g.buf.len();
ret
}
}
// This uses an adaptive system to extend the vector when it fills. We want to
// avoid paying to allocate and zero a huge chunk of memory if the reader only
// has 4 bytes while still making large reads if the reader does have a ton
// of data to return. Simply tacking on an extra DEFAULT_BUF_SIZE space every
// time is 4,500 times (!) slower than a default reservation size of 32 if the
// reader has a very small amount of data to return.
pub(crate) fn default_read_to_end<R: Read + ?Sized>(r: &mut R, buf: &mut Vec<u8>) -> Result<usize> {
let start_len = buf.len();
let start_cap = buf.capacity();
let mut initialized = 0; // Extra initialized bytes from previous loop iteration
loop {
if buf.len() == buf.capacity() {
buf.reserve(32); // buf is full, need more space
}
let mut read_buf: BorrowedBuf<'_> = buf.spare_capacity_mut().into();
// SAFETY: These bytes were initialized but not filled in the previous loop
unsafe {
read_buf.set_init(initialized);
}
let mut cursor = read_buf.unfilled();
match r.read_buf(cursor.reborrow()) {
Ok(()) => {}
Err(e) if e.kind() == ErrorKind::Interrupted => continue,
Err(e) => return Err(e),
}
if cursor.written() == 0 {
return Ok(buf.len() - start_len);
}
// store how much was initialized but not filled
initialized = cursor.init_ref().len();
// SAFETY: BorrowedBuf's invariants mean this much memory is initialized.
unsafe {
let new_len = read_buf.filled().len() + buf.len();
buf.set_len(new_len);
}
if buf.len() == buf.capacity() && buf.capacity() == start_cap {
// The buffer might be an exact fit. Let's read into a probe buffer
// and see if it returns `Ok(0)`. If so, we've avoided an
// unnecessary doubling of the capacity. But if not, append the
// probe buffer to the primary buffer and let its capacity grow.
let mut probe = [0u8; 32];
loop {
match r.read(&mut probe) {
Ok(0) => return Ok(buf.len() - start_len),
Ok(n) => {
buf.extend_from_slice(&probe[..n]);
break;
}
Err(ref e) if e.kind() == ErrorKind::Interrupted => continue,
Err(e) => return Err(e),
}
}
}
}
}
pub(crate) fn default_read_to_string<R: Read + ?Sized>(
r: &mut R,
buf: &mut String,
) -> Result<usize> {
// Note that we do *not* call `r.read_to_end()` here. We are passing
// `&mut Vec<u8>` (the raw contents of `buf`) into the `read_to_end`
// method to fill it up. An arbitrary implementation could overwrite the
// entire contents of the vector, not just append to it (which is what
// we are expecting).
//
// To prevent extraneously checking the UTF-8-ness of the entire buffer
// we pass it to our hardcoded `default_read_to_end` implementation which
// we know is guaranteed to only read data into the end of the buffer.
unsafe { append_to_string(buf, |b| default_read_to_end(r, b)) }
}
pub(crate) fn default_read_vectored<F>(read: F, bufs: &mut [IoSliceMut<'_>]) -> Result<usize>
where
F: FnOnce(&mut [u8]) -> Result<usize>,
{
let buf = bufs.iter_mut().find(|b| !b.is_empty()).map_or(&mut [][..], |b| &mut **b);
read(buf)
}
pub(crate) fn default_write_vectored<F>(write: F, bufs: &[IoSlice<'_>]) -> Result<usize>
where
F: FnOnce(&[u8]) -> Result<usize>,
{
let buf = bufs.iter().find(|b| !b.is_empty()).map_or(&[][..], |b| &**b);
write(buf)
}
pub(crate) fn default_read_exact<R: Read + ?Sized>(this: &mut R, mut buf: &mut [u8]) -> Result<()> {
while !buf.is_empty() {
match this.read(buf) {
Ok(0) => break,
Ok(n) => {
let tmp = buf;
buf = &mut tmp[n..];
}
Err(ref e) if e.kind() == ErrorKind::Interrupted => {}
Err(e) => return Err(e),
}
}
if !buf.is_empty() {
Err(error::const_io_error!(ErrorKind::UnexpectedEof, "failed to fill whole buffer"))
} else {
Ok(())
}
}
pub(crate) fn default_read_buf<F>(read: F, mut cursor: BorrowedCursor<'_>) -> Result<()>
where
F: FnOnce(&mut [u8]) -> Result<usize>,
{
let n = read(cursor.ensure_init().init_mut())?;
unsafe {
// SAFETY: we initialised using `ensure_init` so there is no uninit data to advance to.
cursor.advance(n);
}
Ok(())
}
/// The `Read` trait allows for reading bytes from a source.
///
/// Implementors of the `Read` trait are called 'readers'.
///
/// Readers are defined by one required method, [`read()`]. Each call to [`read()`]
/// will attempt to pull bytes from this source into a provided buffer. A
/// number of other methods are implemented in terms of [`read()`], giving
/// implementors a number of ways to read bytes while only needing to implement
/// a single method.
///
/// Readers are intended to be composable with one another. Many implementors
/// throughout [`std::io`] take and provide types which implement the `Read`
/// trait.
///
/// Please note that each call to [`read()`] may involve a system call, and
/// therefore, using something that implements [`BufRead`], such as
/// [`BufReader`], will be more efficient.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let mut f = File::open("foo.txt")?;
/// let mut buffer = [0; 10];
///
/// // read up to 10 bytes
/// f.read(&mut buffer)?;
///
/// let mut buffer = Vec::new();
/// // read the whole file
/// f.read_to_end(&mut buffer)?;
///
/// // read into a String, so that you don't need to do the conversion.
/// let mut buffer = String::new();
/// f.read_to_string(&mut buffer)?;
///
/// // and more! See the other methods for more details.
/// Ok(())
/// }
/// ```
///
/// Read from [`&str`] because [`&[u8]`][prim@slice] implements `Read`:
///
/// ```no_run
/// # use std::io;
/// use std::io::prelude::*;
///
/// fn main() -> io::Result<()> {
/// let mut b = "This string will be read".as_bytes();
/// let mut buffer = [0; 10];
///
/// // read up to 10 bytes
/// b.read(&mut buffer)?;
///
/// // etc... it works exactly as a File does!
/// Ok(())
/// }
/// ```
///
/// [`read()`]: Read::read
/// [`&str`]: prim@str
/// [`std::io`]: self
/// [`File`]: crate::fs::File
#[stable(feature = "rust1", since = "1.0.0")]
#[doc(notable_trait)]
#[cfg_attr(not(test), rustc_diagnostic_item = "IoRead")]
pub trait Read {
/// Pull some bytes from this source into the specified buffer, returning
/// how many bytes were read.
///
/// This function does not provide any guarantees about whether it blocks
/// waiting for data, but if an object needs to block for a read and cannot,
/// it will typically signal this via an [`Err`] return value.
///
/// If the return value of this method is [`Ok(n)`], then implementations must
/// guarantee that `0 <= n <= buf.len()`. A nonzero `n` value indicates
/// that the buffer `buf` has been filled in with `n` bytes of data from this
/// source. If `n` is `0`, then it can indicate one of two scenarios:
///
/// 1. This reader has reached its "end of file" and will likely no longer
/// be able to produce bytes. Note that this does not mean that the
/// reader will *always* no longer be able to produce bytes. As an example,
/// on Linux, this method will call the `recv` syscall for a [`TcpStream`],
/// where returning zero indicates the connection was shut down correctly. While
/// for [`File`], it is possible to reach the end of file and get zero as result,
/// but if more data is appended to the file, future calls to `read` will return
/// more data.
/// 2. The buffer specified was 0 bytes in length.
///
/// It is not an error if the returned value `n` is smaller than the buffer size,
/// even when the reader is not at the end of the stream yet.
/// This may happen for example because fewer bytes are actually available right now
/// (e. g. being close to end-of-file) or because read() was interrupted by a signal.
///
/// As this trait is safe to implement, callers cannot rely on `n <= buf.len()` for safety.
/// Extra care needs to be taken when `unsafe` functions are used to access the read bytes.
/// Callers have to ensure that no unchecked out-of-bounds accesses are possible even if
/// `n > buf.len()`.
///
/// No guarantees are provided about the contents of `buf` when this
/// function is called, so implementations cannot rely on any property of the
/// contents of `buf` being true. It is recommended that *implementations*
/// only write data to `buf` instead of reading its contents.
///
/// Correspondingly, however, *callers* of this method must not assume any guarantees
/// about how the implementation uses `buf`. The trait is safe to implement,
/// so it is possible that the code that's supposed to write to the buffer might also read
/// from it. It is your responsibility to make sure that `buf` is initialized
/// before calling `read`. Calling `read` with an uninitialized `buf` (of the kind one
/// obtains via [`MaybeUninit<T>`]) is not safe, and can lead to undefined behavior.
///
/// [`MaybeUninit<T>`]: crate::mem::MaybeUninit
///
/// # Errors
///
/// If this function encounters any form of I/O or other error, an error
/// variant will be returned. If an error is returned then it must be
/// guaranteed that no bytes were read.
///
/// An error of the [`ErrorKind::Interrupted`] kind is non-fatal and the read
/// operation should be retried if there is nothing else to do.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`Ok(n)`]: Ok
/// [`File`]: crate::fs::File
/// [`TcpStream`]: crate::net::TcpStream
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let mut f = File::open("foo.txt")?;
/// let mut buffer = [0; 10];
///
/// // read up to 10 bytes
/// let n = f.read(&mut buffer[..])?;
///
/// println!("The bytes: {:?}", &buffer[..n]);
/// Ok(())
/// }
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
fn read(&mut self, buf: &mut [u8]) -> Result<usize>;
/// Like `read`, except that it reads into a slice of buffers.
///
/// Data is copied to fill each buffer in order, with the final buffer
/// written to possibly being only partially filled. This method must
/// behave equivalently to a single call to `read` with concatenated
/// buffers.
///
/// The default implementation calls `read` with either the first nonempty
/// buffer provided, or an empty one if none exists.
#[stable(feature = "iovec", since = "1.36.0")]
fn read_vectored(&mut self, bufs: &mut [IoSliceMut<'_>]) -> Result<usize> {
default_read_vectored(|b| self.read(b), bufs)
}
/// Determines if this `Read`er has an efficient `read_vectored`
/// implementation.
///
/// If a `Read`er does not override the default `read_vectored`
/// implementation, code using it may want to avoid the method all together
/// and coalesce writes into a single buffer for higher performance.
///
/// The default implementation returns `false`.
#[unstable(feature = "can_vector", issue = "69941")]
fn is_read_vectored(&self) -> bool {
false
}
/// Read all bytes until EOF in this source, placing them into `buf`.
///
/// All bytes read from this source will be appended to the specified buffer
/// `buf`. This function will continuously call [`read()`] to append more data to
/// `buf` until [`read()`] returns either [`Ok(0)`] or an error of
/// non-[`ErrorKind::Interrupted`] kind.
///
/// If successful, this function will return the total number of bytes read.
///
/// # Errors
///
/// If this function encounters an error of the kind
/// [`ErrorKind::Interrupted`] then the error is ignored and the operation
/// will continue.
///
/// If any other read error is encountered then this function immediately
/// returns. Any bytes which have already been read will be appended to
/// `buf`.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`read()`]: Read::read
/// [`Ok(0)`]: Ok
/// [`File`]: crate::fs::File
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let mut f = File::open("foo.txt")?;
/// let mut buffer = Vec::new();
///
/// // read the whole file
/// f.read_to_end(&mut buffer)?;
/// Ok(())
/// }
/// ```
///
/// (See also the [`std::fs::read`] convenience function for reading from a
/// file.)
///
/// [`std::fs::read`]: crate::fs::read
#[stable(feature = "rust1", since = "1.0.0")]
fn read_to_end(&mut self, buf: &mut Vec<u8>) -> Result<usize> {
default_read_to_end(self, buf)
}
/// Read all bytes until EOF in this source, appending them to `buf`.
///
/// If successful, this function returns the number of bytes which were read
/// and appended to `buf`.
///
/// # Errors
///
/// If the data in this stream is *not* valid UTF-8 then an error is
/// returned and `buf` is unchanged.
///
/// See [`read_to_end`] for other error semantics.
///
/// [`read_to_end`]: Read::read_to_end
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`File`]: crate::fs::File
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let mut f = File::open("foo.txt")?;
/// let mut buffer = String::new();
///
/// f.read_to_string(&mut buffer)?;
/// Ok(())
/// }
/// ```
///
/// (See also the [`std::fs::read_to_string`] convenience function for
/// reading from a file.)
///
/// [`std::fs::read_to_string`]: crate::fs::read_to_string
#[stable(feature = "rust1", since = "1.0.0")]
fn read_to_string(&mut self, buf: &mut String) -> Result<usize> {
default_read_to_string(self, buf)
}
/// Read the exact number of bytes required to fill `buf`.
///
/// This function reads as many bytes as necessary to completely fill the
/// specified buffer `buf`.
///
/// No guarantees are provided about the contents of `buf` when this
/// function is called, so implementations cannot rely on any property of the
/// contents of `buf` being true. It is recommended that implementations
/// only write data to `buf` instead of reading its contents. The
/// documentation on [`read`] has a more detailed explanation on this
/// subject.
///
/// # Errors
///
/// If this function encounters an error of the kind
/// [`ErrorKind::Interrupted`] then the error is ignored and the operation
/// will continue.
///
/// If this function encounters an "end of file" before completely filling
/// the buffer, it returns an error of the kind [`ErrorKind::UnexpectedEof`].
/// The contents of `buf` are unspecified in this case.
///
/// If any other read error is encountered then this function immediately
/// returns. The contents of `buf` are unspecified in this case.
///
/// If this function returns an error, it is unspecified how many bytes it
/// has read, but it will never read more than would be necessary to
/// completely fill the buffer.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`read`]: Read::read
/// [`File`]: crate::fs::File
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let mut f = File::open("foo.txt")?;
/// let mut buffer = [0; 10];
///
/// // read exactly 10 bytes
/// f.read_exact(&mut buffer)?;
/// Ok(())
/// }
/// ```
#[stable(feature = "read_exact", since = "1.6.0")]
fn read_exact(&mut self, buf: &mut [u8]) -> Result<()> {
default_read_exact(self, buf)
}
/// Pull some bytes from this source into the specified buffer.
///
/// This is equivalent to the [`read`](Read::read) method, except that it is passed a [`BorrowedCursor`] rather than `[u8]` to allow use
/// with uninitialized buffers. The new data will be appended to any existing contents of `buf`.
///
/// The default implementation delegates to `read`.
#[unstable(feature = "read_buf", issue = "78485")]
fn read_buf(&mut self, buf: BorrowedCursor<'_>) -> Result<()> {
default_read_buf(|b| self.read(b), buf)
}
/// Read the exact number of bytes required to fill `cursor`.
///
/// This is equivalent to the [`read_exact`](Read::read_exact) method, except that it is passed a [`BorrowedCursor`] rather than `[u8]` to
/// allow use with uninitialized buffers.
#[unstable(feature = "read_buf", issue = "78485")]
fn read_buf_exact(&mut self, mut cursor: BorrowedCursor<'_>) -> Result<()> {
while cursor.capacity() > 0 {
let prev_written = cursor.written();
match self.read_buf(cursor.reborrow()) {
Ok(()) => {}
Err(e) if e.kind() == ErrorKind::Interrupted => continue,
Err(e) => return Err(e),
}
if cursor.written() == prev_written {
return Err(Error::new(ErrorKind::UnexpectedEof, "failed to fill buffer"));
}
}
Ok(())
}
/// Creates a "by reference" adaptor for this instance of `Read`.
///
/// The returned adapter also implements `Read` and will simply borrow this
/// current reader.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`File`]: crate::fs::File
///
/// ```no_run
/// use std::io;
/// use std::io::Read;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let mut f = File::open("foo.txt")?;
/// let mut buffer = Vec::new();
/// let mut other_buffer = Vec::new();
///
/// {
/// let reference = f.by_ref();
///
/// // read at most 5 bytes
/// reference.take(5).read_to_end(&mut buffer)?;
///
/// } // drop our &mut reference so we can use f again
///
/// // original file still usable, read the rest
/// f.read_to_end(&mut other_buffer)?;
/// Ok(())
/// }
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
fn by_ref(&mut self) -> &mut Self
where
Self: Sized,
{
self
}
/// Transforms this `Read` instance to an [`Iterator`] over its bytes.
///
/// The returned type implements [`Iterator`] where the [`Item`] is
/// <code>[Result]<[u8], [io::Error]></code>.
/// The yielded item is [`Ok`] if a byte was successfully read and [`Err`]
/// otherwise. EOF is mapped to returning [`None`] from this iterator.
///
/// The default implementation calls `read` for each byte,
/// which can be very inefficient for data that's not in memory,
/// such as [`File`]. Consider using a [`BufReader`] in such cases.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`Item`]: Iterator::Item
/// [`File`]: crate::fs::File "fs::File"
/// [Result]: crate::result::Result "Result"
/// [io::Error]: self::Error "io::Error"
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::io::BufReader;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let f = BufReader::new(File::open("foo.txt")?);
///
/// for byte in f.bytes() {
/// println!("{}", byte.unwrap());
/// }
/// Ok(())
/// }
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
fn bytes(self) -> Bytes<Self>
where
Self: Sized,
{
Bytes { inner: self }
}
/// Creates an adapter which will chain this stream with another.
///
/// The returned `Read` instance will first read all bytes from this object
/// until EOF is encountered. Afterwards the output is equivalent to the
/// output of `next`.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`File`]: crate::fs::File
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let f1 = File::open("foo.txt")?;
/// let f2 = File::open("bar.txt")?;
///
/// let mut handle = f1.chain(f2);
/// let mut buffer = String::new();
///
/// // read the value into a String. We could use any Read method here,
/// // this is just one example.
/// handle.read_to_string(&mut buffer)?;
/// Ok(())
/// }
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
fn chain<R: Read>(self, next: R) -> Chain<Self, R>
where
Self: Sized,
{
Chain { first: self, second: next, done_first: false }
}
/// Creates an adapter which will read at most `limit` bytes from it.
///
/// This function returns a new instance of `Read` which will read at most
/// `limit` bytes, after which it will always return EOF ([`Ok(0)`]). Any
/// read errors will not count towards the number of bytes read and future
/// calls to [`read()`] may succeed.
///
/// # Examples
///
/// [`File`]s implement `Read`:
///
/// [`File`]: crate::fs::File
/// [`Ok(0)`]: Ok
/// [`read()`]: Read::read
///
/// ```no_run
/// use std::io;
/// use std::io::prelude::*;
/// use std::fs::File;
///
/// fn main() -> io::Result<()> {
/// let f = File::open("foo.txt")?;
/// let mut buffer = [0; 5];
///
/// // read at most five bytes
/// let mut handle = f.take(5);
///
/// handle.read(&mut buffer)?;
/// Ok(())
/// }
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
fn take(self, limit: u64) -> Take<Self>
where