//! 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`]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`][`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. //! //! ## I/O Safety //! //! Rust follows an I/O safety discipline that is comparable to its memory safety discipline. This //! means that file descriptors can be *exclusively owned*. (Here, "file descriptor" is meant to //! subsume similar concepts that exist across a wide range of operating systems even if they might //! use a different name, such as "handle".) An exclusively owned file descriptor is one that no //! other code is allowed to access in any way, but the owner is allowed to access and even close //! it any time. A type that owns its file descriptor should usually close it in its `drop` //! function. Types like [`File`] own their file descriptor. Similarly, file descriptors //! can be *borrowed*, granting the temporary right to perform operations on this file descriptor. //! This indicates that the file descriptor will not be closed for the lifetime of the borrow, but //! it does *not* imply any right to close this file descriptor, since it will likely be owned by //! someone else. //! //! The platform-specific parts of the Rust standard library expose types that reflect these //! concepts, see [`os::unix`] and [`os::windows`]. //! //! To uphold I/O safety, it is crucial that no code acts on file descriptors it does not own or //! borrow, and no code closes file descriptors it does not own. In other words, a safe function //! that takes a regular integer, treats it as a file descriptor, and acts on it, is *unsound*. //! //! Not upholding I/O safety and acting on a file descriptor without proof of ownership can lead to //! misbehavior and even Undefined Behavior in code that relies on ownership of its file //! descriptors: a closed file descriptor could be re-allocated, so the original owner of that file //! descriptor is now working on the wrong file. Some code might even rely on fully encapsulating //! its file descriptors with no operations being performed by any other part of the program. //! //! Note that exclusive ownership of a file descriptor does *not* imply exclusive ownership of the //! underlying kernel object that the file descriptor references (also called "file description" on //! some operating systems). File descriptors basically work like [`Arc`]: when you receive an owned //! file descriptor, you cannot know whether there are any other file descriptors that reference the //! same kernel object. However, when you create a new kernel object, you know that you are holding //! the only reference to it. Just be careful not to lend it to anyone, since they can obtain a //! clone and then you can no longer know what the reference count is! In that sense, [`OwnedFd`] is //! like `Arc` and [`BorrowedFd<'a>`] is like `&'a Arc` (and similar for the Windows types). In //! particular, given a `BorrowedFd<'a>`, you are not allowed to close the file descriptor -- just //! like how, given a `&'a Arc`, you are not allowed to decrement the reference count and //! potentially free the underlying object. There is no equivalent to `Box` for file descriptors in //! the standard library (that would be a type that guarantees that the reference count is `1`), //! however, it would be possible for a crate to define a type with those semantics. //! //! [`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 //! [`os::unix`]: ../os/unix/io/index.html //! [`os::windows`]: ../os/windows/io/index.html //! [`OwnedFd`]: ../os/fd/struct.OwnedFd.html //! [`BorrowedFd<'a>`]: ../os/fd/struct.BorrowedFd.html //! [`Arc`]: crate::sync::Arc #![stable(feature = "rust1", since = "1.0.0")] #[cfg(test)] mod tests; use crate::cmp; use crate::fmt; use crate::mem::take; 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; #[unstable(feature = "raw_os_error_ty", issue = "107792")] pub use self::error::RawOsError; 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; #[stable(feature = "is_terminal", since = "1.70.0")] pub use self::stdio::IsTerminal; #[unstable(feature = "print_internals", issue = "none")] #[doc(hidden)] 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 core::io::{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 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, 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(buf: &mut String, f: F) -> Result where F: FnOnce(&mut Vec) -> Result, { 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 } } // Here we must serve many masters with conflicting goals: // // - avoid allocating unless necessary // - avoid overallocating if we know the exact size (#89165) // - avoid passing large buffers to readers that always initialize the free capacity if they perform short reads (#23815, #23820) // - pass large buffers to readers that do not initialize the spare capacity. this can amortize per-call overheads // - and finally pass not-too-small and not-too-large buffers to Windows read APIs because they manage to suffer from both problems // at the same time, i.e. small reads suffer from syscall overhead, all reads incur initialization cost // proportional to buffer size (#110650) // pub(crate) fn default_read_to_end( r: &mut R, buf: &mut Vec, size_hint: Option, ) -> Result { let start_len = buf.len(); let start_cap = buf.capacity(); // Optionally limit the maximum bytes read on each iteration. // This adds an arbitrary fiddle factor to allow for more data than we expect. let mut max_read_size = size_hint .and_then(|s| s.checked_add(1024)?.checked_next_multiple_of(DEFAULT_BUF_SIZE)) .unwrap_or(DEFAULT_BUF_SIZE); let mut initialized = 0; // Extra initialized bytes from previous loop iteration const PROBE_SIZE: usize = 32; fn small_probe_read(r: &mut R, buf: &mut Vec) -> Result { let mut probe = [0u8; PROBE_SIZE]; loop { match r.read(&mut probe) { Ok(n) => { buf.extend_from_slice(&probe[..n]); return Ok(n); } Err(ref e) if e.is_interrupted() => continue, Err(e) => return Err(e), } } } // avoid inflating empty/small vecs before we have determined that there's anything to read if (size_hint.is_none() || size_hint == Some(0)) && buf.capacity() - buf.len() < PROBE_SIZE { let read = small_probe_read(r, buf)?; if read == 0 { return Ok(0); } } loop { 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 read = small_probe_read(r, buf)?; if read == 0 { return Ok(buf.len() - start_len); } } if buf.len() == buf.capacity() { buf.reserve(PROBE_SIZE); // buf is full, need more space } let mut spare = buf.spare_capacity_mut(); let buf_len = cmp::min(spare.len(), max_read_size); spare = &mut spare[..buf_len]; let mut read_buf: BorrowedBuf<'_> = spare.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(); loop { match r.read_buf(cursor.reborrow()) { Ok(()) => break, Err(e) if e.is_interrupted() => continue, Err(e) => return Err(e), } } let unfilled_but_initialized = cursor.init_ref().len(); let bytes_read = cursor.written(); let was_fully_initialized = read_buf.init_len() == buf_len; if bytes_read == 0 { return Ok(buf.len() - start_len); } // store how much was initialized but not filled initialized = unfilled_but_initialized; // SAFETY: BorrowedBuf's invariants mean this much memory is initialized. unsafe { let new_len = bytes_read + buf.len(); buf.set_len(new_len); } // Use heuristics to determine the max read size if no initial size hint was provided if size_hint.is_none() { // The reader is returning short reads but it doesn't call ensure_init(). // In that case we no longer need to restrict read sizes to avoid // initialization costs. if !was_fully_initialized { max_read_size = usize::MAX; } // we have passed a larger buffer than previously and the // reader still hasn't returned a short read if buf_len >= max_read_size && bytes_read == buf_len { max_read_size = max_read_size.saturating_mul(2); } } } } pub(crate) fn default_read_to_string( r: &mut R, buf: &mut String, size_hint: Option, ) -> Result { // Note that we do *not* call `r.read_to_end()` here. We are passing // `&mut Vec` (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, size_hint)) } } pub(crate) fn default_read_vectored(read: F, bufs: &mut [IoSliceMut<'_>]) -> Result where F: FnOnce(&mut [u8]) -> Result, { let buf = bufs.iter_mut().find(|b| !b.is_empty()).map_or(&mut [][..], |b| &mut **b); read(buf) } pub(crate) fn default_write_vectored(write: F, bufs: &[IoSlice<'_>]) -> Result where F: FnOnce(&[u8]) -> Result, { let buf = bufs.iter().find(|b| !b.is_empty()).map_or(&[][..], |b| &**b); write(buf) } pub(crate) fn default_read_exact(this: &mut R, mut buf: &mut [u8]) -> Result<()> { while !buf.is_empty() { match this.read(buf) { Ok(0) => break, Ok(n) => { buf = &mut buf[n..]; } Err(ref e) if e.is_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(read: F, mut cursor: BorrowedCursor<'_>) -> Result<()> where F: FnOnce(&mut [u8]) -> Result, { 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. /// /// Repeated calls to the reader use the same cursor, so for example /// calling `read_to_end` twice on a [`File`] will only return the file's /// contents once. It's recommended to first call `rewind()` in that case. /// /// # 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 in unsafe code 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 in unsafe code 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`]) is not safe, and can lead to undefined behavior. /// /// [`MaybeUninit`]: 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; /// 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 { 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) -> Result { default_read_to_end(self, buf, None) } /// 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 { default_read_to_string(self, buf, None) } /// 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 similar to the [`read_exact`](Read::read_exact) method, except /// that it is passed a [`BorrowedCursor`] rather than `[u8]` to allow use /// with uninitialized buffers. /// /// # 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`]. /// /// If any other read error is encountered then this function immediately /// returns. /// /// If this function returns an error, all bytes read will be appended to `cursor`. #[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.is_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 /// [Result]<[u8], [io::Error]>. /// 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 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(self, next: R) -> Chain 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 where Self: Sized, { Take { inner: self, limit } } } /// Read all bytes from a [reader][Read] into a new [`String`]. /// /// This is a convenience function for [`Read::read_to_string`]. Using this /// function avoids having to create a variable first and provides more type /// safety since you can only get the buffer out if there were no errors. (If you /// use [`Read::read_to_string`] you have to remember to check whether the read /// succeeded because otherwise your buffer will be empty or only partially full.) /// /// # Performance /// /// The downside of this function's increased ease of use and type safety is /// that it gives you less control over performance. For example, you can't /// pre-allocate memory like you can using [`String::with_capacity`] and /// [`Read::read_to_string`]. Also, you can't re-use the buffer if an error /// occurs while reading. /// /// In many cases, this function's performance will be adequate and the ease of use /// and type safety tradeoffs will be worth it. However, there are cases where you /// need more control over performance, and in those cases you should definitely use /// [`Read::read_to_string`] directly. /// /// Note that in some special cases, such as when reading files, this function will /// pre-allocate memory based on the size of the input it is reading. In those /// cases, the performance should be as good as if you had used /// [`Read::read_to_string`] with a manually pre-allocated buffer. /// /// # Errors /// /// This function forces you to handle errors because the output (the `String`) /// is wrapped in a [`Result`]. See [`Read::read_to_string`] for the errors /// that can occur. If any error occurs, you will get an [`Err`], so you /// don't have to worry about your buffer being empty or partially full. /// /// # Examples /// /// ```no_run /// # use std::io; /// fn main() -> io::Result<()> { /// let stdin = io::read_to_string(io::stdin())?; /// println!("Stdin was:"); /// println!("{stdin}"); /// Ok(()) /// } /// ``` #[stable(feature = "io_read_to_string", since = "1.65.0")] pub fn read_to_string(mut reader: R) -> Result { let mut buf = String::new(); reader.read_to_string(&mut buf)?; Ok(buf) } /// A buffer type used with `Read::read_vectored`. /// /// It is semantically a wrapper around an `&mut [u8]`, but is guaranteed to be /// ABI compatible with the `iovec` type on Unix platforms and `WSABUF` on /// Windows. #[stable(feature = "iovec", since = "1.36.0")] #[repr(transparent)] pub struct IoSliceMut<'a>(sys::io::IoSliceMut<'a>); #[stable(feature = "iovec_send_sync", since = "1.44.0")] unsafe impl<'a> Send for IoSliceMut<'a> {} #[stable(feature = "iovec_send_sync", since = "1.44.0")] unsafe impl<'a> Sync for IoSliceMut<'a> {} #[stable(feature = "iovec", since = "1.36.0")] impl<'a> fmt::Debug for IoSliceMut<'a> { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Debug::fmt(self.0.as_slice(), fmt) } } impl<'a> IoSliceMut<'a> { /// Creates a new `IoSliceMut` wrapping a byte slice. /// /// # Panics /// /// Panics on Windows if the slice is larger than 4GB. #[stable(feature = "iovec", since = "1.36.0")] #[inline] pub fn new(buf: &'a mut [u8]) -> IoSliceMut<'a> { IoSliceMut(sys::io::IoSliceMut::new(buf)) } /// Advance the internal cursor of the slice. /// /// Also see [`IoSliceMut::advance_slices`] to advance the cursors of /// multiple buffers. /// /// # Panics /// /// Panics when trying to advance beyond the end of the slice. /// /// # Examples /// /// ``` /// #![feature(io_slice_advance)] /// /// use std::io::IoSliceMut; /// use std::ops::Deref; /// /// let mut data = [1; 8]; /// let mut buf = IoSliceMut::new(&mut data); /// /// // Mark 3 bytes as read. /// buf.advance(3); /// assert_eq!(buf.deref(), [1; 5].as_ref()); /// ``` #[unstable(feature = "io_slice_advance", issue = "62726")] #[inline] pub fn advance(&mut self, n: usize) { self.0.advance(n) } /// Advance a slice of slices. /// /// Shrinks the slice to remove any `IoSliceMut`s that are fully advanced over. /// If the cursor ends up in the middle of an `IoSliceMut`, it is modified /// to start at that cursor. /// /// For example, if we have a slice of two 8-byte `IoSliceMut`s, and we advance by 10 bytes, /// the result will only include the second `IoSliceMut`, advanced by 2 bytes. /// /// # Panics /// /// Panics when trying to advance beyond the end of the slices. /// /// # Examples /// /// ``` /// #![feature(io_slice_advance)] /// /// use std::io::IoSliceMut; /// use std::ops::Deref; /// /// let mut buf1 = [1; 8]; /// let mut buf2 = [2; 16]; /// let mut buf3 = [3; 8]; /// let mut bufs = &mut [ /// IoSliceMut::new(&mut buf1), /// IoSliceMut::new(&mut buf2), /// IoSliceMut::new(&mut buf3), /// ][..]; /// /// // Mark 10 bytes as read. /// IoSliceMut::advance_slices(&mut bufs, 10); /// assert_eq!(bufs[0].deref(), [2; 14].as_ref()); /// assert_eq!(bufs[1].deref(), [3; 8].as_ref()); /// ``` #[unstable(feature = "io_slice_advance", issue = "62726")] #[inline] pub fn advance_slices(bufs: &mut &mut [IoSliceMut<'a>], n: usize) { // Number of buffers to remove. let mut remove = 0; // Remaining length before reaching n. let mut left = n; for buf in bufs.iter() { if let Some(remainder) = left.checked_sub(buf.len()) { left = remainder; remove += 1; } else { break; } } *bufs = &mut take(bufs)[remove..]; if bufs.is_empty() { assert!(left == 0, "advancing io slices beyond their length"); } else { bufs[0].advance(left); } } } #[stable(feature = "iovec", since = "1.36.0")] impl<'a> Deref for IoSliceMut<'a> { type Target = [u8]; #[inline] fn deref(&self) -> &[u8] { self.0.as_slice() } } #[stable(feature = "iovec", since = "1.36.0")] impl<'a> DerefMut for IoSliceMut<'a> { #[inline] fn deref_mut(&mut self) -> &mut [u8] { self.0.as_mut_slice() } } /// A buffer type used with `Write::write_vectored`. /// /// It is semantically a wrapper around a `&[u8]`, but is guaranteed to be /// ABI compatible with the `iovec` type on Unix platforms and `WSABUF` on /// Windows. #[stable(feature = "iovec", since = "1.36.0")] #[derive(Copy, Clone)] #[repr(transparent)] pub struct IoSlice<'a>(sys::io::IoSlice<'a>); #[stable(feature = "iovec_send_sync", since = "1.44.0")] unsafe impl<'a> Send for IoSlice<'a> {} #[stable(feature = "iovec_send_sync", since = "1.44.0")] unsafe impl<'a> Sync for IoSlice<'a> {} #[stable(feature = "iovec", since = "1.36.0")] impl<'a> fmt::Debug for IoSlice<'a> { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Debug::fmt(self.0.as_slice(), fmt) } } impl<'a> IoSlice<'a> { /// Creates a new `IoSlice` wrapping a byte slice. /// /// # Panics /// /// Panics on Windows if the slice is larger than 4GB. #[stable(feature = "iovec", since = "1.36.0")] #[must_use] #[inline] pub fn new(buf: &'a [u8]) -> IoSlice<'a> { IoSlice(sys::io::IoSlice::new(buf)) } /// Advance the internal cursor of the slice. /// /// Also see [`IoSlice::advance_slices`] to advance the cursors of multiple /// buffers. /// /// # Panics /// /// Panics when trying to advance beyond the end of the slice. /// /// # Examples /// /// ``` /// #![feature(io_slice_advance)] /// /// use std::io::IoSlice; /// use std::ops::Deref; /// /// let data = [1; 8]; /// let mut buf = IoSlice::new(&data); /// /// // Mark 3 bytes as read. /// buf.advance(3); /// assert_eq!(buf.deref(), [1; 5].as_ref()); /// ``` #[unstable(feature = "io_slice_advance", issue = "62726")] #[inline] pub fn advance(&mut self, n: usize) { self.0.advance(n) } /// Advance a slice of slices. /// /// Shrinks the slice to remove any `IoSlice`s that are fully advanced over. /// If the cursor ends up in the middle of an `IoSlice`, it is modified /// to start at that cursor. /// /// For example, if we have a slice of two 8-byte `IoSlice`s, and we advance by 10 bytes, /// the result will only include the second `IoSlice`, advanced by 2 bytes. /// /// # Panics /// /// Panics when trying to advance beyond the end of the slices. /// /// # Examples /// /// ``` /// #![feature(io_slice_advance)] /// /// use std::io::IoSlice; /// use std::ops::Deref; /// /// let buf1 = [1; 8]; /// let buf2 = [2; 16]; /// let buf3 = [3; 8]; /// let mut bufs = &mut [ /// IoSlice::new(&buf1), /// IoSlice::new(&buf2), /// IoSlice::new(&buf3), /// ][..]; /// /// // Mark 10 bytes as written. /// IoSlice::advance_slices(&mut bufs, 10); /// assert_eq!(bufs[0].deref(), [2; 14].as_ref()); /// assert_eq!(bufs[1].deref(), [3; 8].as_ref()); #[unstable(feature = "io_slice_advance", issue = "62726")] #[inline] pub fn advance_slices(bufs: &mut &mut [IoSlice<'a>], n: usize) { // Number of buffers to remove. let mut remove = 0; // Remaining length before reaching n. This prevents overflow // that could happen if the length of slices in `bufs` were instead // accumulated. Those slice may be aliased and, if they are large // enough, their added length may overflow a `usize`. let mut left = n; for buf in bufs.iter() { if let Some(remainder) = left.checked_sub(buf.len()) { left = remainder; remove += 1; } else { break; } } *bufs = &mut take(bufs)[remove..]; if bufs.is_empty() { assert!(left == 0, "advancing io slices beyond their length"); } else { bufs[0].advance(left); } } } #[stable(feature = "iovec", since = "1.36.0")] impl<'a> Deref for IoSlice<'a> { type Target = [u8]; #[inline] fn deref(&self) -> &[u8] { self.0.as_slice() } } /// A trait for objects which are byte-oriented sinks. /// /// Implementors of the `Write` trait are sometimes called 'writers'. /// /// Writers are defined by two required methods, [`write`] and [`flush`]: /// /// * The [`write`] method will attempt to write some data into the object, /// returning how many bytes were successfully written. /// /// * The [`flush`] method is useful for adapters and explicit buffers /// themselves for ensuring that all buffered data has been pushed out to the /// 'true sink'. /// /// Writers are intended to be composable with one another. Many implementors /// throughout [`std::io`] take and provide types which implement the `Write` /// trait. /// /// [`write`]: Write::write /// [`flush`]: Write::flush /// [`std::io`]: self /// /// # Examples /// /// ```no_run /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let data = b"some bytes"; /// /// let mut pos = 0; /// let mut buffer = File::create("foo.txt")?; /// /// while pos < data.len() { /// let bytes_written = buffer.write(&data[pos..])?; /// pos += bytes_written; /// } /// Ok(()) /// } /// ``` /// /// The trait also provides convenience methods like [`write_all`], which calls /// `write` in a loop until its entire input has been written. /// /// [`write_all`]: Write::write_all #[stable(feature = "rust1", since = "1.0.0")] #[doc(notable_trait)] #[cfg_attr(not(test), rustc_diagnostic_item = "IoWrite")] pub trait Write { /// Write a buffer into this writer, returning how many bytes were written. /// /// This function will attempt to write the entire contents of `buf`, but /// the entire write might not succeed, or the write may also generate an /// error. Typically, a call to `write` represents one attempt to write to /// any wrapped object. /// /// Calls to `write` are not guaranteed to block waiting for data to be /// written, and a write which would otherwise block can be indicated through /// an [`Err`] variant. /// /// If this method consumed `n > 0` bytes of `buf` it must return [`Ok(n)`]. /// If the return value is `Ok(n)` then `n` must satisfy `n <= buf.len()`. /// A return value of `Ok(0)` typically means that the underlying object is /// no longer able to accept bytes and will likely not be able to in the /// future as well, or that the buffer provided is empty. /// /// # Errors /// /// Each call to `write` may generate an I/O error indicating that the /// operation could not be completed. If an error is returned then no bytes /// in the buffer were written to this writer. /// /// It is **not** considered an error if the entire buffer could not be /// written to this writer. /// /// An error of the [`ErrorKind::Interrupted`] kind is non-fatal and the /// write operation should be retried if there is nothing else to do. /// /// # Examples /// /// ```no_run /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let mut buffer = File::create("foo.txt")?; /// /// // Writes some prefix of the byte string, not necessarily all of it. /// buffer.write(b"some bytes")?; /// Ok(()) /// } /// ``` /// /// [`Ok(n)`]: Ok #[stable(feature = "rust1", since = "1.0.0")] fn write(&mut self, buf: &[u8]) -> Result; /// Like [`write`], except that it writes from a slice of buffers. /// /// Data is copied from each buffer in order, with the final buffer /// read from possibly being only partially consumed. This method must /// behave as a call to [`write`] with the buffers concatenated would. /// /// The default implementation calls [`write`] with either the first nonempty /// buffer provided, or an empty one if none exists. /// /// # Examples /// /// ```no_run /// use std::io::IoSlice; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let data1 = [1; 8]; /// let data2 = [15; 8]; /// let io_slice1 = IoSlice::new(&data1); /// let io_slice2 = IoSlice::new(&data2); /// /// let mut buffer = File::create("foo.txt")?; /// /// // Writes some prefix of the byte string, not necessarily all of it. /// buffer.write_vectored(&[io_slice1, io_slice2])?; /// Ok(()) /// } /// ``` /// /// [`write`]: Write::write #[stable(feature = "iovec", since = "1.36.0")] fn write_vectored(&mut self, bufs: &[IoSlice<'_>]) -> Result { default_write_vectored(|b| self.write(b), bufs) } /// Determines if this `Write`r has an efficient [`write_vectored`] /// implementation. /// /// If a `Write`r does not override the default [`write_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`. /// /// [`write_vectored`]: Write::write_vectored #[unstable(feature = "can_vector", issue = "69941")] fn is_write_vectored(&self) -> bool { false } /// Flush this output stream, ensuring that all intermediately buffered /// contents reach their destination. /// /// # Errors /// /// It is considered an error if not all bytes could be written due to /// I/O errors or EOF being reached. /// /// # Examples /// /// ```no_run /// use std::io::prelude::*; /// use std::io::BufWriter; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let mut buffer = BufWriter::new(File::create("foo.txt")?); /// /// buffer.write_all(b"some bytes")?; /// buffer.flush()?; /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn flush(&mut self) -> Result<()>; /// Attempts to write an entire buffer into this writer. /// /// This method will continuously call [`write`] until there is no more data /// to be written or an error of non-[`ErrorKind::Interrupted`] kind is /// returned. This method will not return until the entire buffer has been /// successfully written or such an error occurs. The first error that is /// not of [`ErrorKind::Interrupted`] kind generated from this method will be /// returned. /// /// If the buffer contains no data, this will never call [`write`]. /// /// # Errors /// /// This function will return the first error of /// non-[`ErrorKind::Interrupted`] kind that [`write`] returns. /// /// [`write`]: Write::write /// /// # Examples /// /// ```no_run /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let mut buffer = File::create("foo.txt")?; /// /// buffer.write_all(b"some bytes")?; /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn write_all(&mut self, mut buf: &[u8]) -> Result<()> { while !buf.is_empty() { match self.write(buf) { Ok(0) => { return Err(error::const_io_error!( ErrorKind::WriteZero, "failed to write whole buffer", )); } Ok(n) => buf = &buf[n..], Err(ref e) if e.is_interrupted() => {} Err(e) => return Err(e), } } Ok(()) } /// Attempts to write multiple buffers into this writer. /// /// This method will continuously call [`write_vectored`] until there is no /// more data to be written or an error of non-[`ErrorKind::Interrupted`] /// kind is returned. This method will not return until all buffers have /// been successfully written or such an error occurs. The first error that /// is not of [`ErrorKind::Interrupted`] kind generated from this method /// will be returned. /// /// If the buffer contains no data, this will never call [`write_vectored`]. /// /// # Notes /// /// Unlike [`write_vectored`], this takes a *mutable* reference to /// a slice of [`IoSlice`]s, not an immutable one. That's because we need to /// modify the slice to keep track of the bytes already written. /// /// Once this function returns, the contents of `bufs` are unspecified, as /// this depends on how many calls to [`write_vectored`] were necessary. It is /// best to understand this function as taking ownership of `bufs` and to /// not use `bufs` afterwards. The underlying buffers, to which the /// [`IoSlice`]s point (but not the [`IoSlice`]s themselves), are unchanged and /// can be reused. /// /// [`write_vectored`]: Write::write_vectored /// /// # Examples /// /// ``` /// #![feature(write_all_vectored)] /// # fn main() -> std::io::Result<()> { /// /// use std::io::{Write, IoSlice}; /// /// let mut writer = Vec::new(); /// let bufs = &mut [ /// IoSlice::new(&[1]), /// IoSlice::new(&[2, 3]), /// IoSlice::new(&[4, 5, 6]), /// ]; /// /// writer.write_all_vectored(bufs)?; /// // Note: the contents of `bufs` is now undefined, see the Notes section. /// /// assert_eq!(writer, &[1, 2, 3, 4, 5, 6]); /// # Ok(()) } /// ``` #[unstable(feature = "write_all_vectored", issue = "70436")] fn write_all_vectored(&mut self, mut bufs: &mut [IoSlice<'_>]) -> Result<()> { // Guarantee that bufs is empty if it contains no data, // to avoid calling write_vectored if there is no data to be written. IoSlice::advance_slices(&mut bufs, 0); while !bufs.is_empty() { match self.write_vectored(bufs) { Ok(0) => { return Err(error::const_io_error!( ErrorKind::WriteZero, "failed to write whole buffer", )); } Ok(n) => IoSlice::advance_slices(&mut bufs, n), Err(ref e) if e.is_interrupted() => {} Err(e) => return Err(e), } } Ok(()) } /// Writes a formatted string into this writer, returning any error /// encountered. /// /// This method is primarily used to interface with the /// [`format_args!()`] macro, and it is rare that this should /// explicitly be called. The [`write!()`] macro should be favored to /// invoke this method instead. /// /// This function internally uses the [`write_all`] method on /// this trait and hence will continuously write data so long as no errors /// are received. This also means that partial writes are not indicated in /// this signature. /// /// [`write_all`]: Write::write_all /// /// # Errors /// /// This function will return any I/O error reported while formatting. /// /// # Examples /// /// ```no_run /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let mut buffer = File::create("foo.txt")?; /// /// // this call /// write!(buffer, "{:.*}", 2, 1.234567)?; /// // turns into this: /// buffer.write_fmt(format_args!("{:.*}", 2, 1.234567))?; /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn write_fmt(&mut self, fmt: fmt::Arguments<'_>) -> Result<()> { // Create a shim which translates a Write to a fmt::Write and saves // off I/O errors. instead of discarding them struct Adapter<'a, T: ?Sized + 'a> { inner: &'a mut T, error: Result<()>, } impl fmt::Write for Adapter<'_, T> { fn write_str(&mut self, s: &str) -> fmt::Result { match self.inner.write_all(s.as_bytes()) { Ok(()) => Ok(()), Err(e) => { self.error = Err(e); Err(fmt::Error) } } } } let mut output = Adapter { inner: self, error: Ok(()) }; match fmt::write(&mut output, fmt) { Ok(()) => Ok(()), Err(..) => { // check if the error came from the underlying `Write` or not if output.error.is_err() { output.error } else { Err(error::const_io_error!(ErrorKind::Uncategorized, "formatter error")) } } } } /// Creates a "by reference" adapter for this instance of `Write`. /// /// The returned adapter also implements `Write` and will simply borrow this /// current writer. /// /// # Examples /// /// ```no_run /// use std::io::Write; /// use std::fs::File; /// /// fn main() -> std::io::Result<()> { /// let mut buffer = File::create("foo.txt")?; /// /// let reference = buffer.by_ref(); /// /// // we can use reference just like our original buffer /// reference.write_all(b"some bytes")?; /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn by_ref(&mut self) -> &mut Self where Self: Sized, { self } } /// The `Seek` trait provides a cursor which can be moved within a stream of /// bytes. /// /// The stream typically has a fixed size, allowing seeking relative to either /// end or the current offset. /// /// # Examples /// /// [`File`]s implement `Seek`: /// /// [`File`]: crate::fs::File /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// use std::io::SeekFrom; /// /// fn main() -> io::Result<()> { /// let mut f = File::open("foo.txt")?; /// /// // move the cursor 42 bytes from the start of the file /// f.seek(SeekFrom::Start(42))?; /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] #[cfg_attr(not(test), rustc_diagnostic_item = "IoSeek")] pub trait Seek { /// Seek to an offset, in bytes, in a stream. /// /// A seek beyond the end of a stream is allowed, but behavior is defined /// by the implementation. /// /// If the seek operation completed successfully, /// this method returns the new position from the start of the stream. /// That position can be used later with [`SeekFrom::Start`]. /// /// # Errors /// /// Seeking can fail, for example because it might involve flushing a buffer. /// /// Seeking to a negative offset is considered an error. #[stable(feature = "rust1", since = "1.0.0")] fn seek(&mut self, pos: SeekFrom) -> Result; /// Rewind to the beginning of a stream. /// /// This is a convenience method, equivalent to `seek(SeekFrom::Start(0))`. /// /// # Errors /// /// Rewinding can fail, for example because it might involve flushing a buffer. /// /// # Example /// /// ```no_run /// use std::io::{Read, Seek, Write}; /// use std::fs::OpenOptions; /// /// let mut f = OpenOptions::new() /// .write(true) /// .read(true) /// .create(true) /// .open("foo.txt").unwrap(); /// /// let hello = "Hello!\n"; /// write!(f, "{hello}").unwrap(); /// f.rewind().unwrap(); /// /// let mut buf = String::new(); /// f.read_to_string(&mut buf).unwrap(); /// assert_eq!(&buf, hello); /// ``` #[stable(feature = "seek_rewind", since = "1.55.0")] fn rewind(&mut self) -> Result<()> { self.seek(SeekFrom::Start(0))?; Ok(()) } /// Returns the length of this stream (in bytes). /// /// This method is implemented using up to three seek operations. If this /// method returns successfully, the seek position is unchanged (i.e. the /// position before calling this method is the same as afterwards). /// However, if this method returns an error, the seek position is /// unspecified. /// /// If you need to obtain the length of *many* streams and you don't care /// about the seek position afterwards, you can reduce the number of seek /// operations by simply calling `seek(SeekFrom::End(0))` and using its /// return value (it is also the stream length). /// /// Note that length of a stream can change over time (for example, when /// data is appended to a file). So calling this method multiple times does /// not necessarily return the same length each time. /// /// # Example /// /// ```no_run /// #![feature(seek_stream_len)] /// use std::{ /// io::{self, Seek}, /// fs::File, /// }; /// /// fn main() -> io::Result<()> { /// let mut f = File::open("foo.txt")?; /// /// let len = f.stream_len()?; /// println!("The file is currently {len} bytes long"); /// Ok(()) /// } /// ``` #[unstable(feature = "seek_stream_len", issue = "59359")] fn stream_len(&mut self) -> Result { let old_pos = self.stream_position()?; let len = self.seek(SeekFrom::End(0))?; // Avoid seeking a third time when we were already at the end of the // stream. The branch is usually way cheaper than a seek operation. if old_pos != len { self.seek(SeekFrom::Start(old_pos))?; } Ok(len) } /// Returns the current seek position from the start of the stream. /// /// This is equivalent to `self.seek(SeekFrom::Current(0))`. /// /// # Example /// /// ```no_run /// use std::{ /// io::{self, BufRead, BufReader, Seek}, /// fs::File, /// }; /// /// fn main() -> io::Result<()> { /// let mut f = BufReader::new(File::open("foo.txt")?); /// /// let before = f.stream_position()?; /// f.read_line(&mut String::new())?; /// let after = f.stream_position()?; /// /// println!("The first line was {} bytes long", after - before); /// Ok(()) /// } /// ``` #[stable(feature = "seek_convenience", since = "1.51.0")] fn stream_position(&mut self) -> Result { self.seek(SeekFrom::Current(0)) } /// Seeks relative to the current position. /// /// This is equivalent to `self.seek(SeekFrom::Current(offset))` but /// doesn't return the new position which can allow some implementations /// such as [`BufReader`] to perform more efficient seeks. /// /// # Example /// /// ```no_run /// #![feature(seek_seek_relative)] /// use std::{ /// io::{self, Seek}, /// fs::File, /// }; /// /// fn main() -> io::Result<()> { /// let mut f = File::open("foo.txt")?; /// f.seek_relative(10)?; /// assert_eq!(f.stream_position()?, 10); /// Ok(()) /// } /// ``` /// /// [`BufReader`]: crate::io::BufReader #[unstable(feature = "seek_seek_relative", issue = "117374")] fn seek_relative(&mut self, offset: i64) -> Result<()> { self.seek(SeekFrom::Current(offset))?; Ok(()) } } /// Enumeration of possible methods to seek within an I/O object. /// /// It is used by the [`Seek`] trait. #[derive(Copy, PartialEq, Eq, Clone, Debug)] #[stable(feature = "rust1", since = "1.0.0")] pub enum SeekFrom { /// Sets the offset to the provided number of bytes. #[stable(feature = "rust1", since = "1.0.0")] Start(#[stable(feature = "rust1", since = "1.0.0")] u64), /// Sets the offset to the size of this object plus the specified number of /// bytes. /// /// It is possible to seek beyond the end of an object, but it's an error to /// seek before byte 0. #[stable(feature = "rust1", since = "1.0.0")] End(#[stable(feature = "rust1", since = "1.0.0")] i64), /// Sets the offset to the current position plus the specified number of /// bytes. /// /// It is possible to seek beyond the end of an object, but it's an error to /// seek before byte 0. #[stable(feature = "rust1", since = "1.0.0")] Current(#[stable(feature = "rust1", since = "1.0.0")] i64), } fn read_until(r: &mut R, delim: u8, buf: &mut Vec) -> Result { let mut read = 0; loop { let (done, used) = { let available = match r.fill_buf() { Ok(n) => n, Err(ref e) if e.is_interrupted() => continue, Err(e) => return Err(e), }; match memchr::memchr(delim, available) { Some(i) => { buf.extend_from_slice(&available[..=i]); (true, i + 1) } None => { buf.extend_from_slice(available); (false, available.len()) } } }; r.consume(used); read += used; if done || used == 0 { return Ok(read); } } } fn skip_until(r: &mut R, delim: u8) -> Result { let mut read = 0; loop { let (done, used) = { let available = match r.fill_buf() { Ok(n) => n, Err(ref e) if e.kind() == ErrorKind::Interrupted => continue, Err(e) => return Err(e), }; match memchr::memchr(delim, available) { Some(i) => (true, i + 1), None => (false, available.len()), } }; r.consume(used); read += used; if done || used == 0 { return Ok(read); } } } /// A `BufRead` is a type of `Read`er which has an internal buffer, allowing it /// to perform extra ways of reading. /// /// For example, reading line-by-line is inefficient without using a buffer, so /// if you want to read by line, you'll need `BufRead`, which includes a /// [`read_line`] method as well as a [`lines`] iterator. /// /// # Examples /// /// A locked standard input implements `BufRead`: /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// /// let stdin = io::stdin(); /// for line in stdin.lock().lines() { /// println!("{}", line.unwrap()); /// } /// ``` /// /// If you have something that implements [`Read`], you can use the [`BufReader` /// type][`BufReader`] to turn it into a `BufRead`. /// /// For example, [`File`] implements [`Read`], but not `BufRead`. /// [`BufReader`] to the rescue! /// /// [`File`]: crate::fs::File /// [`read_line`]: BufRead::read_line /// [`lines`]: BufRead::lines /// /// ```no_run /// use std::io::{self, BufReader}; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let f = File::open("foo.txt")?; /// let f = BufReader::new(f); /// /// for line in f.lines() { /// println!("{}", line.unwrap()); /// } /// /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait BufRead: Read { /// Returns the contents of the internal buffer, filling it with more data /// from the inner reader if it is empty. /// /// This function is a lower-level call. It needs to be paired with the /// [`consume`] method to function properly. When calling this /// method, none of the contents will be "read" in the sense that later /// calling `read` may return the same contents. As such, [`consume`] must /// be called with the number of bytes that are consumed from this buffer to /// ensure that the bytes are never returned twice. /// /// [`consume`]: BufRead::consume /// /// An empty buffer returned indicates that the stream has reached EOF. /// /// # Errors /// /// This function will return an I/O error if the underlying reader was /// read, but returned an error. /// /// # Examples /// /// A locked standard input implements `BufRead`: /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// /// let stdin = io::stdin(); /// let mut stdin = stdin.lock(); /// /// let buffer = stdin.fill_buf().unwrap(); /// /// // work with buffer /// println!("{buffer:?}"); /// /// // ensure the bytes we worked with aren't returned again later /// let length = buffer.len(); /// stdin.consume(length); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn fill_buf(&mut self) -> Result<&[u8]>; /// Tells this buffer that `amt` bytes have been consumed from the buffer, /// so they should no longer be returned in calls to `read`. /// /// This function is a lower-level call. It needs to be paired with the /// [`fill_buf`] method to function properly. This function does /// not perform any I/O, it simply informs this object that some amount of /// its buffer, returned from [`fill_buf`], has been consumed and should /// no longer be returned. As such, this function may do odd things if /// [`fill_buf`] isn't called before calling it. /// /// The `amt` must be `<=` the number of bytes in the buffer returned by /// [`fill_buf`]. /// /// # Examples /// /// Since `consume()` is meant to be used with [`fill_buf`], /// that method's example includes an example of `consume()`. /// /// [`fill_buf`]: BufRead::fill_buf #[stable(feature = "rust1", since = "1.0.0")] fn consume(&mut self, amt: usize); /// Check if the underlying `Read` has any data left to be read. /// /// This function may fill the buffer to check for data, /// so this functions returns `Result`, not `bool`. /// /// Default implementation calls `fill_buf` and checks that /// returned slice is empty (which means that there is no data left, /// since EOF is reached). /// /// Examples /// /// ``` /// #![feature(buf_read_has_data_left)] /// use std::io; /// use std::io::prelude::*; /// /// let stdin = io::stdin(); /// let mut stdin = stdin.lock(); /// /// while stdin.has_data_left().unwrap() { /// let mut line = String::new(); /// stdin.read_line(&mut line).unwrap(); /// // work with line /// println!("{line:?}"); /// } /// ``` #[unstable(feature = "buf_read_has_data_left", reason = "recently added", issue = "86423")] fn has_data_left(&mut self) -> Result { self.fill_buf().map(|b| !b.is_empty()) } /// Read all bytes into `buf` until the delimiter `byte` or EOF is reached. /// /// This function will read bytes from the underlying stream until the /// delimiter or EOF is found. Once found, all bytes up to, and including, /// the delimiter (if found) will be appended to `buf`. /// /// If successful, this function will return the total number of bytes read. /// /// This function is blocking and should be used carefully: it is possible for /// an attacker to continuously send bytes without ever sending the delimiter /// or EOF. /// /// # Errors /// /// This function will ignore all instances of [`ErrorKind::Interrupted`] and /// will otherwise return any errors returned by [`fill_buf`]. /// /// If an I/O error is encountered then all bytes read so far will be /// present in `buf` and its length will have been adjusted appropriately. /// /// [`fill_buf`]: BufRead::fill_buf /// /// # Examples /// /// [`std::io::Cursor`][`Cursor`] is a type that implements `BufRead`. In /// this example, we use [`Cursor`] to read all the bytes in a byte slice /// in hyphen delimited segments: /// /// ``` /// use std::io::{self, BufRead}; /// /// let mut cursor = io::Cursor::new(b"lorem-ipsum"); /// let mut buf = vec![]; /// /// // cursor is at 'l' /// let num_bytes = cursor.read_until(b'-', &mut buf) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 6); /// assert_eq!(buf, b"lorem-"); /// buf.clear(); /// /// // cursor is at 'i' /// let num_bytes = cursor.read_until(b'-', &mut buf) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 5); /// assert_eq!(buf, b"ipsum"); /// buf.clear(); /// /// // cursor is at EOF /// let num_bytes = cursor.read_until(b'-', &mut buf) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 0); /// assert_eq!(buf, b""); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn read_until(&mut self, byte: u8, buf: &mut Vec) -> Result { read_until(self, byte, buf) } /// Skip all bytes until the delimiter `byte` or EOF is reached. /// /// This function will read (and discard) bytes from the underlying stream until the /// delimiter or EOF is found. /// /// If successful, this function will return the total number of bytes read, /// including the delimiter byte. /// /// This is useful for efficiently skipping data such as NUL-terminated strings /// in binary file formats without buffering. /// /// This function is blocking and should be used carefully: it is possible for /// an attacker to continuously send bytes without ever sending the delimiter /// or EOF. /// /// # Errors /// /// This function will ignore all instances of [`ErrorKind::Interrupted`] and /// will otherwise return any errors returned by [`fill_buf`]. /// /// If an I/O error is encountered then all bytes read so far will be /// present in `buf` and its length will have been adjusted appropriately. /// /// [`fill_buf`]: BufRead::fill_buf /// /// # Examples /// /// [`std::io::Cursor`][`Cursor`] is a type that implements `BufRead`. In /// this example, we use [`Cursor`] to read some NUL-terminated information /// about Ferris from a binary string, skipping the fun fact: /// /// ``` /// #![feature(bufread_skip_until)] /// /// use std::io::{self, BufRead}; /// /// let mut cursor = io::Cursor::new(b"Ferris\0Likes long walks on the beach\0Crustacean\0"); /// /// // read name /// let mut name = Vec::new(); /// let num_bytes = cursor.read_until(b'\0', &mut name) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 7); /// assert_eq!(name, b"Ferris\0"); /// /// // skip fun fact /// let num_bytes = cursor.skip_until(b'\0') /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 30); /// /// // read animal type /// let mut animal = Vec::new(); /// let num_bytes = cursor.read_until(b'\0', &mut animal) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 11); /// assert_eq!(animal, b"Crustacean\0"); /// ``` #[unstable(feature = "bufread_skip_until", issue = "111735")] fn skip_until(&mut self, byte: u8) -> Result { skip_until(self, byte) } /// Read all bytes until a newline (the `0xA` byte) is reached, and append /// them to the provided `String` buffer. /// /// Previous content of the buffer will be preserved. To avoid appending to /// the buffer, you need to [`clear`] it first. /// /// This function will read bytes from the underlying stream until the /// newline delimiter (the `0xA` byte) or EOF is found. Once found, all bytes /// up to, and including, the delimiter (if found) will be appended to /// `buf`. /// /// If successful, this function will return the total number of bytes read. /// /// If this function returns [`Ok(0)`], the stream has reached EOF. /// /// This function is blocking and should be used carefully: it is possible for /// an attacker to continuously send bytes without ever sending a newline /// or EOF. You can use [`take`] to limit the maximum number of bytes read. /// /// [`Ok(0)`]: Ok /// [`clear`]: String::clear /// [`take`]: crate::io::Read::take /// /// # Errors /// /// This function has the same error semantics as [`read_until`] and will /// also return an error if the read bytes are not valid UTF-8. If an I/O /// error is encountered then `buf` may contain some bytes already read in /// the event that all data read so far was valid UTF-8. /// /// [`read_until`]: BufRead::read_until /// /// # Examples /// /// [`std::io::Cursor`][`Cursor`] is a type that implements `BufRead`. In /// this example, we use [`Cursor`] to read all the lines in a byte slice: /// /// ``` /// use std::io::{self, BufRead}; /// /// let mut cursor = io::Cursor::new(b"foo\nbar"); /// let mut buf = String::new(); /// /// // cursor is at 'f' /// let num_bytes = cursor.read_line(&mut buf) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 4); /// assert_eq!(buf, "foo\n"); /// buf.clear(); /// /// // cursor is at 'b' /// let num_bytes = cursor.read_line(&mut buf) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 3); /// assert_eq!(buf, "bar"); /// buf.clear(); /// /// // cursor is at EOF /// let num_bytes = cursor.read_line(&mut buf) /// .expect("reading from cursor won't fail"); /// assert_eq!(num_bytes, 0); /// assert_eq!(buf, ""); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn read_line(&mut self, buf: &mut String) -> Result { // Note that we are not calling the `.read_until` method here, but // rather our hardcoded implementation. For more details as to why, see // the comments in `read_to_end`. unsafe { append_to_string(buf, |b| read_until(self, b'\n', b)) } } /// Returns an iterator over the contents of this reader split on the byte /// `byte`. /// /// The iterator returned from this function will return instances of /// [io::Result]<[Vec]\>. Each vector returned will *not* have /// the delimiter byte at the end. /// /// This function will yield errors whenever [`read_until`] would have /// also yielded an error. /// /// [io::Result]: self::Result "io::Result" /// [`read_until`]: BufRead::read_until /// /// # Examples /// /// [`std::io::Cursor`][`Cursor`] is a type that implements `BufRead`. In /// this example, we use [`Cursor`] to iterate over all hyphen delimited /// segments in a byte slice /// /// ``` /// use std::io::{self, BufRead}; /// /// let cursor = io::Cursor::new(b"lorem-ipsum-dolor"); /// /// let mut split_iter = cursor.split(b'-').map(|l| l.unwrap()); /// assert_eq!(split_iter.next(), Some(b"lorem".to_vec())); /// assert_eq!(split_iter.next(), Some(b"ipsum".to_vec())); /// assert_eq!(split_iter.next(), Some(b"dolor".to_vec())); /// assert_eq!(split_iter.next(), None); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn split(self, byte: u8) -> Split where Self: Sized, { Split { buf: self, delim: byte } } /// Returns an iterator over the lines of this reader. /// /// The iterator returned from this function will yield instances of /// [io::Result]<[String]>. Each string returned will *not* have a newline /// byte (the `0xA` byte) or `CRLF` (`0xD`, `0xA` bytes) at the end. /// /// [io::Result]: self::Result "io::Result" /// /// # Examples /// /// [`std::io::Cursor`][`Cursor`] is a type that implements `BufRead`. In /// this example, we use [`Cursor`] to iterate over all the lines in a byte /// slice. /// /// ``` /// use std::io::{self, BufRead}; /// /// let cursor = io::Cursor::new(b"lorem\nipsum\r\ndolor"); /// /// let mut lines_iter = cursor.lines().map(|l| l.unwrap()); /// assert_eq!(lines_iter.next(), Some(String::from("lorem"))); /// assert_eq!(lines_iter.next(), Some(String::from("ipsum"))); /// assert_eq!(lines_iter.next(), Some(String::from("dolor"))); /// assert_eq!(lines_iter.next(), None); /// ``` /// /// # Errors /// /// Each line of the iterator has the same error semantics as [`BufRead::read_line`]. #[stable(feature = "rust1", since = "1.0.0")] fn lines(self) -> Lines where Self: Sized, { Lines { buf: self } } } /// Adapter to chain together two readers. /// /// This struct is generally created by calling [`chain`] on a reader. /// Please see the documentation of [`chain`] for more details. /// /// [`chain`]: Read::chain #[stable(feature = "rust1", since = "1.0.0")] #[derive(Debug)] pub struct Chain { first: T, second: U, done_first: bool, } impl Chain { /// Consumes the `Chain`, returning the wrapped readers. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let mut foo_file = File::open("foo.txt")?; /// let mut bar_file = File::open("bar.txt")?; /// /// let chain = foo_file.chain(bar_file); /// let (foo_file, bar_file) = chain.into_inner(); /// Ok(()) /// } /// ``` #[stable(feature = "more_io_inner_methods", since = "1.20.0")] pub fn into_inner(self) -> (T, U) { (self.first, self.second) } /// Gets references to the underlying readers in this `Chain`. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let mut foo_file = File::open("foo.txt")?; /// let mut bar_file = File::open("bar.txt")?; /// /// let chain = foo_file.chain(bar_file); /// let (foo_file, bar_file) = chain.get_ref(); /// Ok(()) /// } /// ``` #[stable(feature = "more_io_inner_methods", since = "1.20.0")] pub fn get_ref(&self) -> (&T, &U) { (&self.first, &self.second) } /// Gets mutable references to the underlying readers in this `Chain`. /// /// Care should be taken to avoid modifying the internal I/O state of the /// underlying readers as doing so may corrupt the internal state of this /// `Chain`. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let mut foo_file = File::open("foo.txt")?; /// let mut bar_file = File::open("bar.txt")?; /// /// let mut chain = foo_file.chain(bar_file); /// let (foo_file, bar_file) = chain.get_mut(); /// Ok(()) /// } /// ``` #[stable(feature = "more_io_inner_methods", since = "1.20.0")] pub fn get_mut(&mut self) -> (&mut T, &mut U) { (&mut self.first, &mut self.second) } } #[stable(feature = "rust1", since = "1.0.0")] impl Read for Chain { fn read(&mut self, buf: &mut [u8]) -> Result { if !self.done_first { match self.first.read(buf)? { 0 if !buf.is_empty() => self.done_first = true, n => return Ok(n), } } self.second.read(buf) } fn read_vectored(&mut self, bufs: &mut [IoSliceMut<'_>]) -> Result { if !self.done_first { match self.first.read_vectored(bufs)? { 0 if bufs.iter().any(|b| !b.is_empty()) => self.done_first = true, n => return Ok(n), } } self.second.read_vectored(bufs) } } #[stable(feature = "chain_bufread", since = "1.9.0")] impl BufRead for Chain { fn fill_buf(&mut self) -> Result<&[u8]> { if !self.done_first { match self.first.fill_buf()? { buf if buf.is_empty() => { self.done_first = true; } buf => return Ok(buf), } } self.second.fill_buf() } fn consume(&mut self, amt: usize) { if !self.done_first { self.first.consume(amt) } else { self.second.consume(amt) } } } impl SizeHint for Chain { #[inline] fn lower_bound(&self) -> usize { SizeHint::lower_bound(&self.first) + SizeHint::lower_bound(&self.second) } #[inline] fn upper_bound(&self) -> Option { match (SizeHint::upper_bound(&self.first), SizeHint::upper_bound(&self.second)) { (Some(first), Some(second)) => first.checked_add(second), _ => None, } } } /// Reader adapter which limits the bytes read from an underlying reader. /// /// This struct is generally created by calling [`take`] on a reader. /// Please see the documentation of [`take`] for more details. /// /// [`take`]: Read::take #[stable(feature = "rust1", since = "1.0.0")] #[derive(Debug)] pub struct Take { inner: T, limit: u64, } impl Take { /// Returns the number of bytes that can be read before this instance will /// return EOF. /// /// # Note /// /// This instance may reach `EOF` after reading fewer bytes than indicated by /// this method if the underlying [`Read`] instance reaches EOF. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let f = File::open("foo.txt")?; /// /// // read at most five bytes /// let handle = f.take(5); /// /// println!("limit: {}", handle.limit()); /// Ok(()) /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub fn limit(&self) -> u64 { self.limit } /// Sets the number of bytes that can be read before this instance will /// return EOF. This is the same as constructing a new `Take` instance, so /// the amount of bytes read and the previous limit value don't matter when /// calling this method. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let f = File::open("foo.txt")?; /// /// // read at most five bytes /// let mut handle = f.take(5); /// handle.set_limit(10); /// /// assert_eq!(handle.limit(), 10); /// Ok(()) /// } /// ``` #[stable(feature = "take_set_limit", since = "1.27.0")] pub fn set_limit(&mut self, limit: u64) { self.limit = limit; } /// Consumes the `Take`, returning the wrapped reader. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let mut file = File::open("foo.txt")?; /// /// let mut buffer = [0; 5]; /// let mut handle = file.take(5); /// handle.read(&mut buffer)?; /// /// let file = handle.into_inner(); /// Ok(()) /// } /// ``` #[stable(feature = "io_take_into_inner", since = "1.15.0")] pub fn into_inner(self) -> T { self.inner } /// Gets a reference to the underlying reader. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let mut file = File::open("foo.txt")?; /// /// let mut buffer = [0; 5]; /// let mut handle = file.take(5); /// handle.read(&mut buffer)?; /// /// let file = handle.get_ref(); /// Ok(()) /// } /// ``` #[stable(feature = "more_io_inner_methods", since = "1.20.0")] pub fn get_ref(&self) -> &T { &self.inner } /// Gets a mutable reference to the underlying reader. /// /// Care should be taken to avoid modifying the internal I/O state of the /// underlying reader as doing so may corrupt the internal limit of this /// `Take`. /// /// # Examples /// /// ```no_run /// use std::io; /// use std::io::prelude::*; /// use std::fs::File; /// /// fn main() -> io::Result<()> { /// let mut file = File::open("foo.txt")?; /// /// let mut buffer = [0; 5]; /// let mut handle = file.take(5); /// handle.read(&mut buffer)?; /// /// let file = handle.get_mut(); /// Ok(()) /// } /// ``` #[stable(feature = "more_io_inner_methods", since = "1.20.0")] pub fn get_mut(&mut self) -> &mut T { &mut self.inner } } #[stable(feature = "rust1", since = "1.0.0")] impl Read for Take { fn read(&mut self, buf: &mut [u8]) -> Result { // Don't call into inner reader at all at EOF because it may still block if self.limit == 0 { return Ok(0); } let max = cmp::min(buf.len() as u64, self.limit) as usize; let n = self.inner.read(&mut buf[..max])?; assert!(n as u64 <= self.limit, "number of read bytes exceeds limit"); self.limit -= n as u64; Ok(n) } fn read_buf(&mut self, mut buf: BorrowedCursor<'_>) -> Result<()> { // Don't call into inner reader at all at EOF because it may still block if self.limit == 0 { return Ok(()); } if self.limit <= buf.capacity() as u64 { // if we just use an as cast to convert, limit may wrap around on a 32 bit target let limit = cmp::min(self.limit, usize::MAX as u64) as usize; let extra_init = cmp::min(limit as usize, buf.init_ref().len()); // SAFETY: no uninit data is written to ibuf let ibuf = unsafe { &mut buf.as_mut()[..limit] }; let mut sliced_buf: BorrowedBuf<'_> = ibuf.into(); // SAFETY: extra_init bytes of ibuf are known to be initialized unsafe { sliced_buf.set_init(extra_init); } let mut cursor = sliced_buf.unfilled(); self.inner.read_buf(cursor.reborrow())?; let new_init = cursor.init_ref().len(); let filled = sliced_buf.len(); // cursor / sliced_buf / ibuf must drop here unsafe { // SAFETY: filled bytes have been filled and therefore initialized buf.advance(filled); // SAFETY: new_init bytes of buf's unfilled buffer have been initialized buf.set_init(new_init); } self.limit -= filled as u64; } else { let written = buf.written(); self.inner.read_buf(buf.reborrow())?; self.limit -= (buf.written() - written) as u64; } Ok(()) } } #[stable(feature = "rust1", since = "1.0.0")] impl BufRead for Take { fn fill_buf(&mut self) -> Result<&[u8]> { // Don't call into inner reader at all at EOF because it may still block if self.limit == 0 { return Ok(&[]); } let buf = self.inner.fill_buf()?; let cap = cmp::min(buf.len() as u64, self.limit) as usize; Ok(&buf[..cap]) } fn consume(&mut self, amt: usize) { // Don't let callers reset the limit by passing an overlarge value let amt = cmp::min(amt as u64, self.limit) as usize; self.limit -= amt as u64; self.inner.consume(amt); } } impl SizeHint for Take { #[inline] fn lower_bound(&self) -> usize { cmp::min(SizeHint::lower_bound(&self.inner) as u64, self.limit) as usize } #[inline] fn upper_bound(&self) -> Option { match SizeHint::upper_bound(&self.inner) { Some(upper_bound) => Some(cmp::min(upper_bound as u64, self.limit) as usize), None => self.limit.try_into().ok(), } } } /// An iterator over `u8` values of a reader. /// /// This struct is generally created by calling [`bytes`] on a reader. /// Please see the documentation of [`bytes`] for more details. /// /// [`bytes`]: Read::bytes #[stable(feature = "rust1", since = "1.0.0")] #[derive(Debug)] pub struct Bytes { inner: R, } #[stable(feature = "rust1", since = "1.0.0")] impl Iterator for Bytes { type Item = Result; // Not `#[inline]`. This function gets inlined even without it, but having // the inline annotation can result in worse code generation. See #116785. fn next(&mut self) -> Option> { SpecReadByte::spec_read_byte(&mut self.inner) } #[inline] fn size_hint(&self) -> (usize, Option) { SizeHint::size_hint(&self.inner) } } /// For the specialization of `Bytes::next`. trait SpecReadByte { fn spec_read_byte(&mut self) -> Option>; } impl SpecReadByte for R where Self: Read, { #[inline] default fn spec_read_byte(&mut self) -> Option> { inlined_slow_read_byte(self) } } /// Read a single byte in a slow, generic way. This is used by the default /// `spec_read_byte`. #[inline] fn inlined_slow_read_byte(reader: &mut R) -> Option> { let mut byte = 0; loop { return match reader.read(slice::from_mut(&mut byte)) { Ok(0) => None, Ok(..) => Some(Ok(byte)), Err(ref e) if e.is_interrupted() => continue, Err(e) => Some(Err(e)), }; } } // Used by `BufReader::spec_read_byte`, for which the `inline(ever)` is // important. #[inline(never)] fn uninlined_slow_read_byte(reader: &mut R) -> Option> { inlined_slow_read_byte(reader) } trait SizeHint { fn lower_bound(&self) -> usize; fn upper_bound(&self) -> Option; fn size_hint(&self) -> (usize, Option) { (self.lower_bound(), self.upper_bound()) } } impl SizeHint for T { #[inline] default fn lower_bound(&self) -> usize { 0 } #[inline] default fn upper_bound(&self) -> Option { None } } impl SizeHint for &mut T { #[inline] fn lower_bound(&self) -> usize { SizeHint::lower_bound(*self) } #[inline] fn upper_bound(&self) -> Option { SizeHint::upper_bound(*self) } } impl SizeHint for Box { #[inline] fn lower_bound(&self) -> usize { SizeHint::lower_bound(&**self) } #[inline] fn upper_bound(&self) -> Option { SizeHint::upper_bound(&**self) } } impl SizeHint for &[u8] { #[inline] fn lower_bound(&self) -> usize { self.len() } #[inline] fn upper_bound(&self) -> Option { Some(self.len()) } } /// An iterator over the contents of an instance of `BufRead` split on a /// particular byte. /// /// This struct is generally created by calling [`split`] on a `BufRead`. /// Please see the documentation of [`split`] for more details. /// /// [`split`]: BufRead::split #[stable(feature = "rust1", since = "1.0.0")] #[derive(Debug)] pub struct Split { buf: B, delim: u8, } #[stable(feature = "rust1", since = "1.0.0")] impl Iterator for Split { type Item = Result>; fn next(&mut self) -> Option>> { let mut buf = Vec::new(); match self.buf.read_until(self.delim, &mut buf) { Ok(0) => None, Ok(_n) => { if buf[buf.len() - 1] == self.delim { buf.pop(); } Some(Ok(buf)) } Err(e) => Some(Err(e)), } } } /// An iterator over the lines of an instance of `BufRead`. /// /// This struct is generally created by calling [`lines`] on a `BufRead`. /// Please see the documentation of [`lines`] for more details. /// /// [`lines`]: BufRead::lines #[stable(feature = "rust1", since = "1.0.0")] #[derive(Debug)] #[cfg_attr(not(test), rustc_diagnostic_item = "IoLines")] pub struct Lines { buf: B, } #[stable(feature = "rust1", since = "1.0.0")] impl Iterator for Lines { type Item = Result; fn next(&mut self) -> Option> { let mut buf = String::new(); match self.buf.read_line(&mut buf) { Ok(0) => None, Ok(_n) => { if buf.ends_with('\n') { buf.pop(); if buf.ends_with('\r') { buf.pop(); } } Some(Ok(buf)) } Err(e) => Some(Err(e)), } } }