//! Utilities for formatting and printing strings. #![stable(feature = "rust1", since = "1.0.0")] use crate::cell::{Cell, Ref, RefCell, RefMut, SyncUnsafeCell, UnsafeCell}; use crate::char::EscapeDebugExtArgs; use crate::iter; use crate::marker::PhantomData; use crate::mem; use crate::num::fmt as numfmt; use crate::ops::Deref; use crate::result; use crate::str; mod builders; #[cfg(not(no_fp_fmt_parse))] mod float; #[cfg(no_fp_fmt_parse)] mod nofloat; mod num; #[stable(feature = "fmt_flags_align", since = "1.28.0")] #[cfg_attr(not(test), rustc_diagnostic_item = "Alignment")] /// Possible alignments returned by `Formatter::align` #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum Alignment { #[stable(feature = "fmt_flags_align", since = "1.28.0")] /// Indication that contents should be left-aligned. Left, #[stable(feature = "fmt_flags_align", since = "1.28.0")] /// Indication that contents should be right-aligned. Right, #[stable(feature = "fmt_flags_align", since = "1.28.0")] /// Indication that contents should be center-aligned. Center, } #[stable(feature = "debug_builders", since = "1.2.0")] pub use self::builders::{DebugList, DebugMap, DebugSet, DebugStruct, DebugTuple}; #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[doc(hidden)] pub mod rt { pub mod v1; } /// The type returned by formatter methods. /// /// # Examples /// /// ``` /// use std::fmt; /// /// #[derive(Debug)] /// struct Triangle { /// a: f32, /// b: f32, /// c: f32 /// } /// /// impl fmt::Display for Triangle { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// write!(f, "({}, {}, {})", self.a, self.b, self.c) /// } /// } /// /// let pythagorean_triple = Triangle { a: 3.0, b: 4.0, c: 5.0 }; /// /// assert_eq!(format!("{pythagorean_triple}"), "(3, 4, 5)"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub type Result = result::Result<(), Error>; /// The error type which is returned from formatting a message into a stream. /// /// This type does not support transmission of an error other than that an error /// occurred. Any extra information must be arranged to be transmitted through /// some other means. /// /// An important thing to remember is that the type `fmt::Error` should not be /// confused with [`std::io::Error`] or [`std::error::Error`], which you may also /// have in scope. /// /// [`std::io::Error`]: ../../std/io/struct.Error.html /// [`std::error::Error`]: ../../std/error/trait.Error.html /// /// # Examples /// /// ```rust /// use std::fmt::{self, write}; /// /// let mut output = String::new(); /// if let Err(fmt::Error) = write(&mut output, format_args!("Hello {}!", "world")) { /// panic!("An error occurred"); /// } /// ``` #[stable(feature = "rust1", since = "1.0.0")] #[derive(Copy, Clone, Debug, Default, Eq, Hash, Ord, PartialEq, PartialOrd)] pub struct Error; /// A trait for writing or formatting into Unicode-accepting buffers or streams. /// /// This trait only accepts UTF-8–encoded data and is not [flushable]. If you only /// want to accept Unicode and you don't need flushing, you should implement this trait; /// otherwise you should implement [`std::io::Write`]. /// /// [`std::io::Write`]: ../../std/io/trait.Write.html /// [flushable]: ../../std/io/trait.Write.html#tymethod.flush #[stable(feature = "rust1", since = "1.0.0")] pub trait Write { /// Writes a string slice into this writer, returning whether the write /// succeeded. /// /// This method can only succeed if the entire string slice was successfully /// written, and this method will not return until all data has been /// written or an error occurs. /// /// # Errors /// /// This function will return an instance of [`Error`] on error. /// /// The purpose of std::fmt::Error is to abort the formatting operation when the underlying /// destination encounters some error preventing it from accepting more text; it should /// generally be propagated rather than handled, at least when implementing formatting traits. /// /// # Examples /// /// ``` /// use std::fmt::{Error, Write}; /// /// fn writer(f: &mut W, s: &str) -> Result<(), Error> { /// f.write_str(s) /// } /// /// let mut buf = String::new(); /// writer(&mut buf, "hola").unwrap(); /// assert_eq!(&buf, "hola"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn write_str(&mut self, s: &str) -> Result; /// Writes a [`char`] into this writer, returning whether the write succeeded. /// /// A single [`char`] may be encoded as more than one byte. /// This method can only succeed if the entire byte sequence was successfully /// written, and this method will not return until all data has been /// written or an error occurs. /// /// # Errors /// /// This function will return an instance of [`Error`] on error. /// /// # Examples /// /// ``` /// use std::fmt::{Error, Write}; /// /// fn writer(f: &mut W, c: char) -> Result<(), Error> { /// f.write_char(c) /// } /// /// let mut buf = String::new(); /// writer(&mut buf, 'a').unwrap(); /// writer(&mut buf, 'b').unwrap(); /// assert_eq!(&buf, "ab"); /// ``` #[stable(feature = "fmt_write_char", since = "1.1.0")] fn write_char(&mut self, c: char) -> Result { self.write_str(c.encode_utf8(&mut [0; 4])) } /// Glue for usage of the [`write!`] macro with implementors of this trait. /// /// This method should generally not be invoked manually, but rather through /// the [`write!`] macro itself. /// /// # Errors /// /// This function will return an instance of [`Error`] on error. Please see /// [write_str](Write::write_str) for details. /// /// # Examples /// /// ``` /// use std::fmt::{Error, Write}; /// /// fn writer(f: &mut W, s: &str) -> Result<(), Error> { /// f.write_fmt(format_args!("{s}")) /// } /// /// let mut buf = String::new(); /// writer(&mut buf, "world").unwrap(); /// assert_eq!(&buf, "world"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn write_fmt(mut self: &mut Self, args: Arguments<'_>) -> Result { write(&mut self, args) } } #[stable(feature = "fmt_write_blanket_impl", since = "1.4.0")] impl Write for &mut W { fn write_str(&mut self, s: &str) -> Result { (**self).write_str(s) } fn write_char(&mut self, c: char) -> Result { (**self).write_char(c) } fn write_fmt(&mut self, args: Arguments<'_>) -> Result { (**self).write_fmt(args) } } /// Configuration for formatting. /// /// A `Formatter` represents various options related to formatting. Users do not /// construct `Formatter`s directly; a mutable reference to one is passed to /// the `fmt` method of all formatting traits, like [`Debug`] and [`Display`]. /// /// To interact with a `Formatter`, you'll call various methods to change the /// various options related to formatting. For examples, please see the /// documentation of the methods defined on `Formatter` below. #[allow(missing_debug_implementations)] #[stable(feature = "rust1", since = "1.0.0")] pub struct Formatter<'a> { flags: u32, fill: char, align: rt::v1::Alignment, width: Option, precision: Option, buf: &'a mut (dyn Write + 'a), } impl<'a> Formatter<'a> { /// Creates a new formatter with default settings. /// /// This can be used as a micro-optimization in cases where a full `Arguments` /// structure (as created by `format_args!`) is not necessary; `Arguments` /// is a little more expensive to use in simple formatting scenarios. /// /// Currently not intended for use outside of the standard library. #[unstable(feature = "fmt_internals", reason = "internal to standard library", issue = "none")] #[doc(hidden)] pub fn new(buf: &'a mut (dyn Write + 'a)) -> Formatter<'a> { Formatter { flags: 0, fill: ' ', align: rt::v1::Alignment::Unknown, width: None, precision: None, buf, } } } // NB. Argument is essentially an optimized partially applied formatting function, // equivalent to `exists T.(&T, fn(&T, &mut Formatter<'_>) -> Result`. extern "C" { type Opaque; } /// This struct represents the generic "argument" which is taken by the Xprintf /// family of functions. It contains a function to format the given value. At /// compile time it is ensured that the function and the value have the correct /// types, and then this struct is used to canonicalize arguments to one type. #[cfg_attr(not(bootstrap), lang = "format_argument")] #[derive(Copy, Clone)] #[allow(missing_debug_implementations)] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[doc(hidden)] pub struct ArgumentV1<'a> { value: &'a Opaque, formatter: fn(&Opaque, &mut Formatter<'_>) -> Result, } /// This struct represents the unsafety of constructing an `Arguments`. /// It exists, rather than an unsafe function, in order to simplify the expansion /// of `format_args!(..)` and reduce the scope of the `unsafe` block. #[cfg_attr(not(bootstrap), lang = "format_unsafe_arg")] #[allow(missing_debug_implementations)] #[doc(hidden)] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] pub struct UnsafeArg { _private: (), } impl UnsafeArg { /// See documentation where `UnsafeArg` is required to know when it is safe to /// create and use `UnsafeArg`. #[doc(hidden)] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[inline(always)] pub unsafe fn new() -> Self { Self { _private: () } } } // This guarantees a single stable value for the function pointer associated with // indices/counts in the formatting infrastructure. // // Note that a function defined as such would not be correct as functions are // always tagged unnamed_addr with the current lowering to LLVM IR, so their // address is not considered important to LLVM and as such the as_usize cast // could have been miscompiled. In practice, we never call as_usize on non-usize // containing data (as a matter of static generation of the formatting // arguments), so this is merely an additional check. // // We primarily want to ensure that the function pointer at `USIZE_MARKER` has // an address corresponding *only* to functions that also take `&usize` as their // first argument. The read_volatile here ensures that we can safely ready out a // usize from the passed reference and that this address does not point at a // non-usize taking function. #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] static USIZE_MARKER: fn(&usize, &mut Formatter<'_>) -> Result = |ptr, _| { // SAFETY: ptr is a reference let _v: usize = unsafe { crate::ptr::read_volatile(ptr) }; loop {} }; macro_rules! arg_new { ($f: ident, $t: ident) => { #[doc(hidden)] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[inline] pub fn $f<'b, T: $t>(x: &'b T) -> ArgumentV1<'_> { Self::new(x, $t::fmt) } }; } #[rustc_diagnostic_item = "ArgumentV1Methods"] impl<'a> ArgumentV1<'a> { #[doc(hidden)] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[inline] pub fn new<'b, T>(x: &'b T, f: fn(&T, &mut Formatter<'_>) -> Result) -> ArgumentV1<'b> { // SAFETY: `mem::transmute(x)` is safe because // 1. `&'b T` keeps the lifetime it originated with `'b` // (so as to not have an unbounded lifetime) // 2. `&'b T` and `&'b Opaque` have the same memory layout // (when `T` is `Sized`, as it is here) // `mem::transmute(f)` is safe since `fn(&T, &mut Formatter<'_>) -> Result` // and `fn(&Opaque, &mut Formatter<'_>) -> Result` have the same ABI // (as long as `T` is `Sized`) unsafe { ArgumentV1 { formatter: mem::transmute(f), value: mem::transmute(x) } } } arg_new!(new_display, Display); arg_new!(new_debug, Debug); arg_new!(new_octal, Octal); arg_new!(new_lower_hex, LowerHex); arg_new!(new_upper_hex, UpperHex); arg_new!(new_pointer, Pointer); arg_new!(new_binary, Binary); arg_new!(new_lower_exp, LowerExp); arg_new!(new_upper_exp, UpperExp); #[doc(hidden)] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] pub fn from_usize(x: &usize) -> ArgumentV1<'_> { ArgumentV1::new(x, USIZE_MARKER) } fn as_usize(&self) -> Option { // We are type punning a bit here: USIZE_MARKER only takes an &usize but // formatter takes an &Opaque. Rust understandably doesn't think we should compare // the function pointers if they don't have the same signature, so we cast to // usizes to tell it that we just want to compare addresses. if self.formatter as usize == USIZE_MARKER as usize { // SAFETY: The `formatter` field is only set to USIZE_MARKER if // the value is a usize, so this is safe Some(unsafe { *(self.value as *const _ as *const usize) }) } else { None } } } // flags available in the v1 format of format_args #[derive(Copy, Clone)] enum FlagV1 { SignPlus, SignMinus, Alternate, SignAwareZeroPad, DebugLowerHex, DebugUpperHex, } impl<'a> Arguments<'a> { /// When using the format_args!() macro, this function is used to generate the /// Arguments structure. #[doc(hidden)] #[inline] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[rustc_const_unstable(feature = "const_fmt_arguments_new", issue = "none")] pub const fn new_v1(pieces: &'a [&'static str], args: &'a [ArgumentV1<'a>]) -> Arguments<'a> { if pieces.len() < args.len() || pieces.len() > args.len() + 1 { panic!("invalid args"); } Arguments { pieces, fmt: None, args } } /// This function is used to specify nonstandard formatting parameters. /// /// An `UnsafeArg` is required because the following invariants must be held /// in order for this function to be safe: /// 1. The `pieces` slice must be at least as long as `fmt`. /// 2. Every [`rt::v1::Argument::position`] value within `fmt` must be a /// valid index of `args`. /// 3. Every [`rt::v1::Count::Param`] within `fmt` must contain a valid index of /// `args`. #[doc(hidden)] #[inline] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] #[rustc_const_unstable(feature = "const_fmt_arguments_new", issue = "none")] pub const fn new_v1_formatted( pieces: &'a [&'static str], args: &'a [ArgumentV1<'a>], fmt: &'a [rt::v1::Argument], _unsafe_arg: UnsafeArg, ) -> Arguments<'a> { Arguments { pieces, fmt: Some(fmt), args } } /// Estimates the length of the formatted text. /// /// This is intended to be used for setting initial `String` capacity /// when using `format!`. Note: this is neither the lower nor upper bound. #[doc(hidden)] #[inline] #[unstable(feature = "fmt_internals", reason = "internal to format_args!", issue = "none")] pub fn estimated_capacity(&self) -> usize { let pieces_length: usize = self.pieces.iter().map(|x| x.len()).sum(); if self.args.is_empty() { pieces_length } else if !self.pieces.is_empty() && self.pieces[0].is_empty() && pieces_length < 16 { // If the format string starts with an argument, // don't preallocate anything, unless length // of pieces is significant. 0 } else { // There are some arguments, so any additional push // will reallocate the string. To avoid that, // we're "pre-doubling" the capacity here. pieces_length.checked_mul(2).unwrap_or(0) } } } /// This structure represents a safely precompiled version of a format string /// and its arguments. This cannot be generated at runtime because it cannot /// safely be done, so no constructors are given and the fields are private /// to prevent modification. /// /// The [`format_args!`] macro will safely create an instance of this structure. /// The macro validates the format string at compile-time so usage of the /// [`write()`] and [`format()`] functions can be safely performed. /// /// You can use the `Arguments<'a>` that [`format_args!`] returns in `Debug` /// and `Display` contexts as seen below. The example also shows that `Debug` /// and `Display` format to the same thing: the interpolated format string /// in `format_args!`. /// /// ```rust /// let debug = format!("{:?}", format_args!("{} foo {:?}", 1, 2)); /// let display = format!("{}", format_args!("{} foo {:?}", 1, 2)); /// assert_eq!("1 foo 2", display); /// assert_eq!(display, debug); /// ``` /// /// [`format()`]: ../../std/fmt/fn.format.html #[cfg_attr(not(bootstrap), lang = "format_arguments")] #[stable(feature = "rust1", since = "1.0.0")] #[derive(Copy, Clone)] pub struct Arguments<'a> { // Format string pieces to print. pieces: &'a [&'static str], // Placeholder specs, or `None` if all specs are default (as in "{}{}"). fmt: Option<&'a [rt::v1::Argument]>, // Dynamic arguments for interpolation, to be interleaved with string // pieces. (Every argument is preceded by a string piece.) args: &'a [ArgumentV1<'a>], } impl<'a> Arguments<'a> { /// Get the formatted string, if it has no arguments to be formatted at runtime. /// /// This can be used to avoid allocations in some cases. /// /// # Guarantees /// /// For `format_args!("just a literal")`, this function is guaranteed to /// return `Some("just a literal")`. /// /// For most cases with placeholders, this function will return `None`. /// /// However, the compiler may perform optimizations that can cause this /// function to return `Some(_)` even if the format string contains /// placeholders. For example, `format_args!("Hello, {}!", "world")` may be /// optimized to `format_args!("Hello, world!")`, such that `as_str()` /// returns `Some("Hello, world!")`. /// /// The behavior for anything but the trivial case (without placeholders) /// is not guaranteed, and should not be relied upon for anything other /// than optimization. /// /// # Examples /// /// ```rust /// use std::fmt::Arguments; /// /// fn write_str(_: &str) { /* ... */ } /// /// fn write_fmt(args: &Arguments) { /// if let Some(s) = args.as_str() { /// write_str(s) /// } else { /// write_str(&args.to_string()); /// } /// } /// ``` /// /// ```rust /// assert_eq!(format_args!("hello").as_str(), Some("hello")); /// assert_eq!(format_args!("").as_str(), Some("")); /// assert_eq!(format_args!("{:?}", std::env::current_dir()).as_str(), None); /// ``` #[stable(feature = "fmt_as_str", since = "1.52.0")] #[rustc_const_unstable(feature = "const_arguments_as_str", issue = "103900")] #[must_use] #[inline] pub const fn as_str(&self) -> Option<&'static str> { match (self.pieces, self.args) { ([], []) => Some(""), ([s], []) => Some(s), _ => None, } } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for Arguments<'_> { fn fmt(&self, fmt: &mut Formatter<'_>) -> Result { Display::fmt(self, fmt) } } #[stable(feature = "rust1", since = "1.0.0")] impl Display for Arguments<'_> { fn fmt(&self, fmt: &mut Formatter<'_>) -> Result { write(fmt.buf, *self) } } /// `?` formatting. /// /// `Debug` should format the output in a programmer-facing, debugging context. /// /// Generally speaking, you should just `derive` a `Debug` implementation. /// /// When used with the alternate format specifier `#?`, the output is pretty-printed. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// This trait can be used with `#[derive]` if all fields implement `Debug`. When /// `derive`d for structs, it will use the name of the `struct`, then `{`, then a /// comma-separated list of each field's name and `Debug` value, then `}`. For /// `enum`s, it will use the name of the variant and, if applicable, `(`, then the /// `Debug` values of the fields, then `)`. /// /// # Stability /// /// Derived `Debug` formats are not stable, and so may change with future Rust /// versions. Additionally, `Debug` implementations of types provided by the /// standard library (`std`, `core`, `alloc`, etc.) are not stable, and /// may also change with future Rust versions. /// /// # Examples /// /// Deriving an implementation: /// /// ``` /// #[derive(Debug)] /// struct Point { /// x: i32, /// y: i32, /// } /// /// let origin = Point { x: 0, y: 0 }; /// /// assert_eq!(format!("The origin is: {origin:?}"), "The origin is: Point { x: 0, y: 0 }"); /// ``` /// /// Manually implementing: /// /// ``` /// use std::fmt; /// /// struct Point { /// x: i32, /// y: i32, /// } /// /// impl fmt::Debug for Point { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// f.debug_struct("Point") /// .field("x", &self.x) /// .field("y", &self.y) /// .finish() /// } /// } /// /// let origin = Point { x: 0, y: 0 }; /// /// assert_eq!(format!("The origin is: {origin:?}"), "The origin is: Point { x: 0, y: 0 }"); /// ``` /// /// There are a number of helper methods on the [`Formatter`] struct to help you with manual /// implementations, such as [`debug_struct`]. /// /// [`debug_struct`]: Formatter::debug_struct /// /// Types that do not wish to use the standard suite of debug representations /// provided by the `Formatter` trait (`debug_struct`, `debug_tuple`, /// `debug_list`, `debug_set`, `debug_map`) can do something totally custom by /// manually writing an arbitrary representation to the `Formatter`. /// /// ``` /// # use std::fmt; /// # struct Point { /// # x: i32, /// # y: i32, /// # } /// # /// impl fmt::Debug for Point { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// write!(f, "Point [{} {}]", self.x, self.y) /// } /// } /// ``` /// /// `Debug` implementations using either `derive` or the debug builder API /// on [`Formatter`] support pretty-printing using the alternate flag: `{:#?}`. /// /// Pretty-printing with `#?`: /// /// ``` /// #[derive(Debug)] /// struct Point { /// x: i32, /// y: i32, /// } /// /// let origin = Point { x: 0, y: 0 }; /// /// assert_eq!(format!("The origin is: {origin:#?}"), /// "The origin is: Point { /// x: 0, /// y: 0, /// }"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] #[rustc_on_unimplemented( on( crate_local, label = "`{Self}` cannot be formatted using `{{:?}}`", note = "add `#[derive(Debug)]` to `{Self}` or manually `impl {Debug} for {Self}`" ), message = "`{Self}` doesn't implement `{Debug}`", label = "`{Self}` cannot be formatted using `{{:?}}` because it doesn't implement `{Debug}`" )] #[doc(alias = "{:?}")] #[rustc_diagnostic_item = "Debug"] #[rustc_trivial_field_reads] pub trait Debug { /// Formats the value using the given formatter. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Position { /// longitude: f32, /// latitude: f32, /// } /// /// impl fmt::Debug for Position { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// f.debug_tuple("") /// .field(&self.longitude) /// .field(&self.latitude) /// .finish() /// } /// } /// /// let position = Position { longitude: 1.987, latitude: 2.983 }; /// assert_eq!(format!("{position:?}"), "(1.987, 2.983)"); /// /// assert_eq!(format!("{position:#?}"), "( /// 1.987, /// 2.983, /// )"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } // Separate module to reexport the macro `Debug` from prelude without the trait `Debug`. pub(crate) mod macros { /// Derive macro generating an impl of the trait `Debug`. #[rustc_builtin_macro] #[stable(feature = "builtin_macro_prelude", since = "1.38.0")] #[allow_internal_unstable(core_intrinsics, fmt_helpers_for_derive)] pub macro Debug($item:item) { /* compiler built-in */ } } #[stable(feature = "builtin_macro_prelude", since = "1.38.0")] #[doc(inline)] pub use macros::Debug; /// Format trait for an empty format, `{}`. /// /// Implementing this trait for a type will automatically implement the /// [`ToString`][tostring] trait for the type, allowing the usage /// of the [`.to_string()`][tostring_function] method. Prefer implementing /// the `Display` trait for a type, rather than [`ToString`][tostring]. /// /// `Display` is similar to [`Debug`], but `Display` is for user-facing /// output, and so cannot be derived. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// [tostring]: ../../std/string/trait.ToString.html /// [tostring_function]: ../../std/string/trait.ToString.html#tymethod.to_string /// /// # Examples /// /// Implementing `Display` on a type: /// /// ``` /// use std::fmt; /// /// struct Point { /// x: i32, /// y: i32, /// } /// /// impl fmt::Display for Point { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// write!(f, "({}, {})", self.x, self.y) /// } /// } /// /// let origin = Point { x: 0, y: 0 }; /// /// assert_eq!(format!("The origin is: {origin}"), "The origin is: (0, 0)"); /// ``` #[rustc_on_unimplemented( on( any(_Self = "std::path::Path", _Self = "std::path::PathBuf"), label = "`{Self}` cannot be formatted with the default formatter; call `.display()` on it", note = "call `.display()` or `.to_string_lossy()` to safely print paths, \ as they may contain non-Unicode data" ), message = "`{Self}` doesn't implement `{Display}`", label = "`{Self}` cannot be formatted with the default formatter", note = "in format strings you may be able to use `{{:?}}` (or {{:#?}} for pretty-print) instead" )] #[doc(alias = "{}")] #[rustc_diagnostic_item = "Display"] #[stable(feature = "rust1", since = "1.0.0")] pub trait Display { /// Formats the value using the given formatter. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Position { /// longitude: f32, /// latitude: f32, /// } /// /// impl fmt::Display for Position { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// write!(f, "({}, {})", self.longitude, self.latitude) /// } /// } /// /// assert_eq!("(1.987, 2.983)", /// format!("{}", Position { longitude: 1.987, latitude: 2.983, })); /// ``` #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `o` formatting. /// /// The `Octal` trait should format its output as a number in base-8. /// /// For primitive signed integers (`i8` to `i128`, and `isize`), /// negative values are formatted as the two’s complement representation. /// /// The alternate flag, `#`, adds a `0o` in front of the output. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with `i32`: /// /// ``` /// let x = 42; // 42 is '52' in octal /// /// assert_eq!(format!("{x:o}"), "52"); /// assert_eq!(format!("{x:#o}"), "0o52"); /// /// assert_eq!(format!("{:o}", -16), "37777777760"); /// ``` /// /// Implementing `Octal` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::Octal for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// let val = self.0; /// /// fmt::Octal::fmt(&val, f) // delegate to i32's implementation /// } /// } /// /// let l = Length(9); /// /// assert_eq!(format!("l as octal is: {l:o}"), "l as octal is: 11"); /// /// assert_eq!(format!("l as octal is: {l:#06o}"), "l as octal is: 0o0011"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait Octal { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `b` formatting. /// /// The `Binary` trait should format its output as a number in binary. /// /// For primitive signed integers ([`i8`] to [`i128`], and [`isize`]), /// negative values are formatted as the two’s complement representation. /// /// The alternate flag, `#`, adds a `0b` in front of the output. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with [`i32`]: /// /// ``` /// let x = 42; // 42 is '101010' in binary /// /// assert_eq!(format!("{x:b}"), "101010"); /// assert_eq!(format!("{x:#b}"), "0b101010"); /// /// assert_eq!(format!("{:b}", -16), "11111111111111111111111111110000"); /// ``` /// /// Implementing `Binary` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::Binary for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// let val = self.0; /// /// fmt::Binary::fmt(&val, f) // delegate to i32's implementation /// } /// } /// /// let l = Length(107); /// /// assert_eq!(format!("l as binary is: {l:b}"), "l as binary is: 1101011"); /// /// assert_eq!( /// format!("l as binary is: {l:#032b}"), /// "l as binary is: 0b000000000000000000000001101011" /// ); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait Binary { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `x` formatting. /// /// The `LowerHex` trait should format its output as a number in hexadecimal, with `a` through `f` /// in lower case. /// /// For primitive signed integers (`i8` to `i128`, and `isize`), /// negative values are formatted as the two’s complement representation. /// /// The alternate flag, `#`, adds a `0x` in front of the output. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with `i32`: /// /// ``` /// let x = 42; // 42 is '2a' in hex /// /// assert_eq!(format!("{x:x}"), "2a"); /// assert_eq!(format!("{x:#x}"), "0x2a"); /// /// assert_eq!(format!("{:x}", -16), "fffffff0"); /// ``` /// /// Implementing `LowerHex` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::LowerHex for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// let val = self.0; /// /// fmt::LowerHex::fmt(&val, f) // delegate to i32's implementation /// } /// } /// /// let l = Length(9); /// /// assert_eq!(format!("l as hex is: {l:x}"), "l as hex is: 9"); /// /// assert_eq!(format!("l as hex is: {l:#010x}"), "l as hex is: 0x00000009"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait LowerHex { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `X` formatting. /// /// The `UpperHex` trait should format its output as a number in hexadecimal, with `A` through `F` /// in upper case. /// /// For primitive signed integers (`i8` to `i128`, and `isize`), /// negative values are formatted as the two’s complement representation. /// /// The alternate flag, `#`, adds a `0x` in front of the output. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with `i32`: /// /// ``` /// let x = 42; // 42 is '2A' in hex /// /// assert_eq!(format!("{x:X}"), "2A"); /// assert_eq!(format!("{x:#X}"), "0x2A"); /// /// assert_eq!(format!("{:X}", -16), "FFFFFFF0"); /// ``` /// /// Implementing `UpperHex` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::UpperHex for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// let val = self.0; /// /// fmt::UpperHex::fmt(&val, f) // delegate to i32's implementation /// } /// } /// /// let l = Length(i32::MAX); /// /// assert_eq!(format!("l as hex is: {l:X}"), "l as hex is: 7FFFFFFF"); /// /// assert_eq!(format!("l as hex is: {l:#010X}"), "l as hex is: 0x7FFFFFFF"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait UpperHex { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `p` formatting. /// /// The `Pointer` trait should format its output as a memory location. This is commonly presented /// as hexadecimal. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with `&i32`: /// /// ``` /// let x = &42; /// /// let address = format!("{x:p}"); // this produces something like '0x7f06092ac6d0' /// ``` /// /// Implementing `Pointer` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::Pointer for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// // use `as` to convert to a `*const T`, which implements Pointer, which we can use /// /// let ptr = self as *const Self; /// fmt::Pointer::fmt(&ptr, f) /// } /// } /// /// let l = Length(42); /// /// println!("l is in memory here: {l:p}"); /// /// let l_ptr = format!("{l:018p}"); /// assert_eq!(l_ptr.len(), 18); /// assert_eq!(&l_ptr[..2], "0x"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] #[rustc_diagnostic_item = "Pointer"] pub trait Pointer { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `e` formatting. /// /// The `LowerExp` trait should format its output in scientific notation with a lower-case `e`. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with `f64`: /// /// ``` /// let x = 42.0; // 42.0 is '4.2e1' in scientific notation /// /// assert_eq!(format!("{x:e}"), "4.2e1"); /// ``` /// /// Implementing `LowerExp` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::LowerExp for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// let val = f64::from(self.0); /// fmt::LowerExp::fmt(&val, f) // delegate to f64's implementation /// } /// } /// /// let l = Length(100); /// /// assert_eq!( /// format!("l in scientific notation is: {l:e}"), /// "l in scientific notation is: 1e2" /// ); /// /// assert_eq!( /// format!("l in scientific notation is: {l:05e}"), /// "l in scientific notation is: 001e2" /// ); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait LowerExp { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// `E` formatting. /// /// The `UpperExp` trait should format its output in scientific notation with an upper-case `E`. /// /// For more information on formatters, see [the module-level documentation][module]. /// /// [module]: ../../std/fmt/index.html /// /// # Examples /// /// Basic usage with `f64`: /// /// ``` /// let x = 42.0; // 42.0 is '4.2E1' in scientific notation /// /// assert_eq!(format!("{x:E}"), "4.2E1"); /// ``` /// /// Implementing `UpperExp` on a type: /// /// ``` /// use std::fmt; /// /// struct Length(i32); /// /// impl fmt::UpperExp for Length { /// fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { /// let val = f64::from(self.0); /// fmt::UpperExp::fmt(&val, f) // delegate to f64's implementation /// } /// } /// /// let l = Length(100); /// /// assert_eq!( /// format!("l in scientific notation is: {l:E}"), /// "l in scientific notation is: 1E2" /// ); /// /// assert_eq!( /// format!("l in scientific notation is: {l:05E}"), /// "l in scientific notation is: 001E2" /// ); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub trait UpperExp { /// Formats the value using the given formatter. #[stable(feature = "rust1", since = "1.0.0")] fn fmt(&self, f: &mut Formatter<'_>) -> Result; } /// The `write` function takes an output stream, and an `Arguments` struct /// that can be precompiled with the `format_args!` macro. /// /// The arguments will be formatted according to the specified format string /// into the output stream provided. /// /// # Examples /// /// Basic usage: /// /// ``` /// use std::fmt; /// /// let mut output = String::new(); /// fmt::write(&mut output, format_args!("Hello {}!", "world")) /// .expect("Error occurred while trying to write in String"); /// assert_eq!(output, "Hello world!"); /// ``` /// /// Please note that using [`write!`] might be preferable. Example: /// /// ``` /// use std::fmt::Write; /// /// let mut output = String::new(); /// write!(&mut output, "Hello {}!", "world") /// .expect("Error occurred while trying to write in String"); /// assert_eq!(output, "Hello world!"); /// ``` /// /// [`write!`]: crate::write! #[stable(feature = "rust1", since = "1.0.0")] pub fn write(output: &mut dyn Write, args: Arguments<'_>) -> Result { let mut formatter = Formatter::new(output); let mut idx = 0; match args.fmt { None => { // We can use default formatting parameters for all arguments. for (i, arg) in args.args.iter().enumerate() { // SAFETY: args.args and args.pieces come from the same Arguments, // which guarantees the indexes are always within bounds. let piece = unsafe { args.pieces.get_unchecked(i) }; if !piece.is_empty() { formatter.buf.write_str(*piece)?; } (arg.formatter)(arg.value, &mut formatter)?; idx += 1; } } Some(fmt) => { // Every spec has a corresponding argument that is preceded by // a string piece. for (i, arg) in fmt.iter().enumerate() { // SAFETY: fmt and args.pieces come from the same Arguments, // which guarantees the indexes are always within bounds. let piece = unsafe { args.pieces.get_unchecked(i) }; if !piece.is_empty() { formatter.buf.write_str(*piece)?; } // SAFETY: arg and args.args come from the same Arguments, // which guarantees the indexes are always within bounds. unsafe { run(&mut formatter, arg, args.args) }?; idx += 1; } } } // There can be only one trailing string piece left. if let Some(piece) = args.pieces.get(idx) { formatter.buf.write_str(*piece)?; } Ok(()) } unsafe fn run(fmt: &mut Formatter<'_>, arg: &rt::v1::Argument, args: &[ArgumentV1<'_>]) -> Result { fmt.fill = arg.format.fill; fmt.align = arg.format.align; fmt.flags = arg.format.flags; // SAFETY: arg and args come from the same Arguments, // which guarantees the indexes are always within bounds. unsafe { fmt.width = getcount(args, &arg.format.width); fmt.precision = getcount(args, &arg.format.precision); } // Extract the correct argument debug_assert!(arg.position < args.len()); // SAFETY: arg and args come from the same Arguments, // which guarantees its index is always within bounds. let value = unsafe { args.get_unchecked(arg.position) }; // Then actually do some printing (value.formatter)(value.value, fmt) } unsafe fn getcount(args: &[ArgumentV1<'_>], cnt: &rt::v1::Count) -> Option { match *cnt { rt::v1::Count::Is(n) => Some(n), rt::v1::Count::Implied => None, rt::v1::Count::Param(i) => { debug_assert!(i < args.len()); // SAFETY: cnt and args come from the same Arguments, // which guarantees this index is always within bounds. unsafe { args.get_unchecked(i).as_usize() } } } } /// Padding after the end of something. Returned by `Formatter::padding`. #[must_use = "don't forget to write the post padding"] pub(crate) struct PostPadding { fill: char, padding: usize, } impl PostPadding { fn new(fill: char, padding: usize) -> PostPadding { PostPadding { fill, padding } } /// Write this post padding. pub(crate) fn write(self, f: &mut Formatter<'_>) -> Result { for _ in 0..self.padding { f.buf.write_char(self.fill)?; } Ok(()) } } impl<'a> Formatter<'a> { fn wrap_buf<'b, 'c, F>(&'b mut self, wrap: F) -> Formatter<'c> where 'b: 'c, F: FnOnce(&'b mut (dyn Write + 'b)) -> &'c mut (dyn Write + 'c), { Formatter { // We want to change this buf: wrap(self.buf), // And preserve these flags: self.flags, fill: self.fill, align: self.align, width: self.width, precision: self.precision, } } // Helper methods used for padding and processing formatting arguments that // all formatting traits can use. /// Performs the correct padding for an integer which has already been /// emitted into a str. The str should *not* contain the sign for the /// integer, that will be added by this method. /// /// # Arguments /// /// * is_nonnegative - whether the original integer was either positive or zero. /// * prefix - if the '#' character (Alternate) is provided, this /// is the prefix to put in front of the number. /// * buf - the byte array that the number has been formatted into /// /// This function will correctly account for the flags provided as well as /// the minimum width. It will not take precision into account. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo { nb: i32 } /// /// impl Foo { /// fn new(nb: i32) -> Foo { /// Foo { /// nb, /// } /// } /// } /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// // We need to remove "-" from the number output. /// let tmp = self.nb.abs().to_string(); /// /// formatter.pad_integral(self.nb >= 0, "Foo ", &tmp) /// } /// } /// /// assert_eq!(format!("{}", Foo::new(2)), "2"); /// assert_eq!(format!("{}", Foo::new(-1)), "-1"); /// assert_eq!(format!("{}", Foo::new(0)), "0"); /// assert_eq!(format!("{:#}", Foo::new(-1)), "-Foo 1"); /// assert_eq!(format!("{:0>#8}", Foo::new(-1)), "00-Foo 1"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub fn pad_integral(&mut self, is_nonnegative: bool, prefix: &str, buf: &str) -> Result { let mut width = buf.len(); let mut sign = None; if !is_nonnegative { sign = Some('-'); width += 1; } else if self.sign_plus() { sign = Some('+'); width += 1; } let prefix = if self.alternate() { width += prefix.chars().count(); Some(prefix) } else { None }; // Writes the sign if it exists, and then the prefix if it was requested #[inline(never)] fn write_prefix(f: &mut Formatter<'_>, sign: Option, prefix: Option<&str>) -> Result { if let Some(c) = sign { f.buf.write_char(c)?; } if let Some(prefix) = prefix { f.buf.write_str(prefix) } else { Ok(()) } } // The `width` field is more of a `min-width` parameter at this point. match self.width { // If there's no minimum length requirements then we can just // write the bytes. None => { write_prefix(self, sign, prefix)?; self.buf.write_str(buf) } // Check if we're over the minimum width, if so then we can also // just write the bytes. Some(min) if width >= min => { write_prefix(self, sign, prefix)?; self.buf.write_str(buf) } // The sign and prefix goes before the padding if the fill character // is zero Some(min) if self.sign_aware_zero_pad() => { let old_fill = crate::mem::replace(&mut self.fill, '0'); let old_align = crate::mem::replace(&mut self.align, rt::v1::Alignment::Right); write_prefix(self, sign, prefix)?; let post_padding = self.padding(min - width, rt::v1::Alignment::Right)?; self.buf.write_str(buf)?; post_padding.write(self)?; self.fill = old_fill; self.align = old_align; Ok(()) } // Otherwise, the sign and prefix goes after the padding Some(min) => { let post_padding = self.padding(min - width, rt::v1::Alignment::Right)?; write_prefix(self, sign, prefix)?; self.buf.write_str(buf)?; post_padding.write(self) } } } /// This function takes a string slice and emits it to the internal buffer /// after applying the relevant formatting flags specified. The flags /// recognized for generic strings are: /// /// * width - the minimum width of what to emit /// * fill/align - what to emit and where to emit it if the string /// provided needs to be padded /// * precision - the maximum length to emit, the string is truncated if it /// is longer than this length /// /// Notably this function ignores the `flag` parameters. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo; /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// formatter.pad("Foo") /// } /// } /// /// assert_eq!(format!("{Foo:<4}"), "Foo "); /// assert_eq!(format!("{Foo:0>4}"), "0Foo"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub fn pad(&mut self, s: &str) -> Result { // Make sure there's a fast path up front if self.width.is_none() && self.precision.is_none() { return self.buf.write_str(s); } // The `precision` field can be interpreted as a `max-width` for the // string being formatted. let s = if let Some(max) = self.precision { // If our string is longer that the precision, then we must have // truncation. However other flags like `fill`, `width` and `align` // must act as always. if let Some((i, _)) = s.char_indices().nth(max) { // LLVM here can't prove that `..i` won't panic `&s[..i]`, but // we know that it can't panic. Use `get` + `unwrap_or` to avoid // `unsafe` and otherwise don't emit any panic-related code // here. s.get(..i).unwrap_or(s) } else { &s } } else { &s }; // The `width` field is more of a `min-width` parameter at this point. match self.width { // If we're under the maximum length, and there's no minimum length // requirements, then we can just emit the string None => self.buf.write_str(s), Some(width) => { let chars_count = s.chars().count(); // If we're under the maximum width, check if we're over the minimum // width, if so it's as easy as just emitting the string. if chars_count >= width { self.buf.write_str(s) } // If we're under both the maximum and the minimum width, then fill // up the minimum width with the specified string + some alignment. else { let align = rt::v1::Alignment::Left; let post_padding = self.padding(width - chars_count, align)?; self.buf.write_str(s)?; post_padding.write(self) } } } } /// Write the pre-padding and return the unwritten post-padding. Callers are /// responsible for ensuring post-padding is written after the thing that is /// being padded. pub(crate) fn padding( &mut self, padding: usize, default: rt::v1::Alignment, ) -> result::Result { let align = match self.align { rt::v1::Alignment::Unknown => default, _ => self.align, }; let (pre_pad, post_pad) = match align { rt::v1::Alignment::Left => (0, padding), rt::v1::Alignment::Right | rt::v1::Alignment::Unknown => (padding, 0), rt::v1::Alignment::Center => (padding / 2, (padding + 1) / 2), }; for _ in 0..pre_pad { self.buf.write_char(self.fill)?; } Ok(PostPadding::new(self.fill, post_pad)) } /// Takes the formatted parts and applies the padding. /// Assumes that the caller already has rendered the parts with required precision, /// so that `self.precision` can be ignored. fn pad_formatted_parts(&mut self, formatted: &numfmt::Formatted<'_>) -> Result { if let Some(mut width) = self.width { // for the sign-aware zero padding, we render the sign first and // behave as if we had no sign from the beginning. let mut formatted = formatted.clone(); let old_fill = self.fill; let old_align = self.align; let mut align = old_align; if self.sign_aware_zero_pad() { // a sign always goes first let sign = formatted.sign; self.buf.write_str(sign)?; // remove the sign from the formatted parts formatted.sign = ""; width = width.saturating_sub(sign.len()); align = rt::v1::Alignment::Right; self.fill = '0'; self.align = rt::v1::Alignment::Right; } // remaining parts go through the ordinary padding process. let len = formatted.len(); let ret = if width <= len { // no padding self.write_formatted_parts(&formatted) } else { let post_padding = self.padding(width - len, align)?; self.write_formatted_parts(&formatted)?; post_padding.write(self) }; self.fill = old_fill; self.align = old_align; ret } else { // this is the common case and we take a shortcut self.write_formatted_parts(formatted) } } fn write_formatted_parts(&mut self, formatted: &numfmt::Formatted<'_>) -> Result { fn write_bytes(buf: &mut dyn Write, s: &[u8]) -> Result { // SAFETY: This is used for `numfmt::Part::Num` and `numfmt::Part::Copy`. // It's safe to use for `numfmt::Part::Num` since every char `c` is between // `b'0'` and `b'9'`, which means `s` is valid UTF-8. // It's also probably safe in practice to use for `numfmt::Part::Copy(buf)` // since `buf` should be plain ASCII, but it's possible for someone to pass // in a bad value for `buf` into `numfmt::to_shortest_str` since it is a // public function. // FIXME: Determine whether this could result in UB. buf.write_str(unsafe { str::from_utf8_unchecked(s) }) } if !formatted.sign.is_empty() { self.buf.write_str(formatted.sign)?; } for part in formatted.parts { match *part { numfmt::Part::Zero(mut nzeroes) => { const ZEROES: &str = // 64 zeroes "0000000000000000000000000000000000000000000000000000000000000000"; while nzeroes > ZEROES.len() { self.buf.write_str(ZEROES)?; nzeroes -= ZEROES.len(); } if nzeroes > 0 { self.buf.write_str(&ZEROES[..nzeroes])?; } } numfmt::Part::Num(mut v) => { let mut s = [0; 5]; let len = part.len(); for c in s[..len].iter_mut().rev() { *c = b'0' + (v % 10) as u8; v /= 10; } write_bytes(self.buf, &s[..len])?; } numfmt::Part::Copy(buf) => { write_bytes(self.buf, buf)?; } } } Ok(()) } /// Writes some data to the underlying buffer contained within this /// formatter. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo; /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// formatter.write_str("Foo") /// // This is equivalent to: /// // write!(formatter, "Foo") /// } /// } /// /// assert_eq!(format!("{Foo}"), "Foo"); /// assert_eq!(format!("{Foo:0>8}"), "Foo"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub fn write_str(&mut self, data: &str) -> Result { self.buf.write_str(data) } /// Writes some formatted information into this instance. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(i32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// formatter.write_fmt(format_args!("Foo {}", self.0)) /// } /// } /// /// assert_eq!(format!("{}", Foo(-1)), "Foo -1"); /// assert_eq!(format!("{:0>8}", Foo(2)), "Foo 2"); /// ``` #[stable(feature = "rust1", since = "1.0.0")] pub fn write_fmt(&mut self, fmt: Arguments<'_>) -> Result { write(self.buf, fmt) } /// Flags for formatting #[must_use] #[stable(feature = "rust1", since = "1.0.0")] #[deprecated( since = "1.24.0", note = "use the `sign_plus`, `sign_minus`, `alternate`, \ or `sign_aware_zero_pad` methods instead" )] pub fn flags(&self) -> u32 { self.flags } /// Character used as 'fill' whenever there is alignment. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo; /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// let c = formatter.fill(); /// if let Some(width) = formatter.width() { /// for _ in 0..width { /// write!(formatter, "{c}")?; /// } /// Ok(()) /// } else { /// write!(formatter, "{c}") /// } /// } /// } /// /// // We set alignment to the right with ">". /// assert_eq!(format!("{Foo:G>3}"), "GGG"); /// assert_eq!(format!("{Foo:t>6}"), "tttttt"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn fill(&self) -> char { self.fill } /// Flag indicating what form of alignment was requested. /// /// # Examples /// /// ``` /// extern crate core; /// /// use std::fmt::{self, Alignment}; /// /// struct Foo; /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// let s = if let Some(s) = formatter.align() { /// match s { /// Alignment::Left => "left", /// Alignment::Right => "right", /// Alignment::Center => "center", /// } /// } else { /// "into the void" /// }; /// write!(formatter, "{s}") /// } /// } /// /// assert_eq!(format!("{Foo:<}"), "left"); /// assert_eq!(format!("{Foo:>}"), "right"); /// assert_eq!(format!("{Foo:^}"), "center"); /// assert_eq!(format!("{Foo}"), "into the void"); /// ``` #[must_use] #[stable(feature = "fmt_flags_align", since = "1.28.0")] pub fn align(&self) -> Option { match self.align { rt::v1::Alignment::Left => Some(Alignment::Left), rt::v1::Alignment::Right => Some(Alignment::Right), rt::v1::Alignment::Center => Some(Alignment::Center), rt::v1::Alignment::Unknown => None, } } /// Optionally specified integer width that the output should be. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(i32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// if let Some(width) = formatter.width() { /// // If we received a width, we use it /// write!(formatter, "{:width$}", format!("Foo({})", self.0), width = width) /// } else { /// // Otherwise we do nothing special /// write!(formatter, "Foo({})", self.0) /// } /// } /// } /// /// assert_eq!(format!("{:10}", Foo(23)), "Foo(23) "); /// assert_eq!(format!("{}", Foo(23)), "Foo(23)"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn width(&self) -> Option { self.width } /// Optionally specified precision for numeric types. Alternatively, the /// maximum width for string types. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(f32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// if let Some(precision) = formatter.precision() { /// // If we received a precision, we use it. /// write!(formatter, "Foo({1:.*})", precision, self.0) /// } else { /// // Otherwise we default to 2. /// write!(formatter, "Foo({:.2})", self.0) /// } /// } /// } /// /// assert_eq!(format!("{:.4}", Foo(23.2)), "Foo(23.2000)"); /// assert_eq!(format!("{}", Foo(23.2)), "Foo(23.20)"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn precision(&self) -> Option { self.precision } /// Determines if the `+` flag was specified. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(i32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// if formatter.sign_plus() { /// write!(formatter, /// "Foo({}{})", /// if self.0 < 0 { '-' } else { '+' }, /// self.0.abs()) /// } else { /// write!(formatter, "Foo({})", self.0) /// } /// } /// } /// /// assert_eq!(format!("{:+}", Foo(23)), "Foo(+23)"); /// assert_eq!(format!("{:+}", Foo(-23)), "Foo(-23)"); /// assert_eq!(format!("{}", Foo(23)), "Foo(23)"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn sign_plus(&self) -> bool { self.flags & (1 << FlagV1::SignPlus as u32) != 0 } /// Determines if the `-` flag was specified. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(i32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// if formatter.sign_minus() { /// // You want a minus sign? Have one! /// write!(formatter, "-Foo({})", self.0) /// } else { /// write!(formatter, "Foo({})", self.0) /// } /// } /// } /// /// assert_eq!(format!("{:-}", Foo(23)), "-Foo(23)"); /// assert_eq!(format!("{}", Foo(23)), "Foo(23)"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn sign_minus(&self) -> bool { self.flags & (1 << FlagV1::SignMinus as u32) != 0 } /// Determines if the `#` flag was specified. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(i32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// if formatter.alternate() { /// write!(formatter, "Foo({})", self.0) /// } else { /// write!(formatter, "{}", self.0) /// } /// } /// } /// /// assert_eq!(format!("{:#}", Foo(23)), "Foo(23)"); /// assert_eq!(format!("{}", Foo(23)), "23"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn alternate(&self) -> bool { self.flags & (1 << FlagV1::Alternate as u32) != 0 } /// Determines if the `0` flag was specified. /// /// # Examples /// /// ``` /// use std::fmt; /// /// struct Foo(i32); /// /// impl fmt::Display for Foo { /// fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { /// assert!(formatter.sign_aware_zero_pad()); /// assert_eq!(formatter.width(), Some(4)); /// // We ignore the formatter's options. /// write!(formatter, "{}", self.0) /// } /// } /// /// assert_eq!(format!("{:04}", Foo(23)), "23"); /// ``` #[must_use] #[stable(feature = "fmt_flags", since = "1.5.0")] pub fn sign_aware_zero_pad(&self) -> bool { self.flags & (1 << FlagV1::SignAwareZeroPad as u32) != 0 } // FIXME: Decide what public API we want for these two flags. // https://github.com/rust-lang/rust/issues/48584 fn debug_lower_hex(&self) -> bool { self.flags & (1 << FlagV1::DebugLowerHex as u32) != 0 } fn debug_upper_hex(&self) -> bool { self.flags & (1 << FlagV1::DebugUpperHex as u32) != 0 } /// Creates a [`DebugStruct`] builder designed to assist with creation of /// [`fmt::Debug`] implementations for structs. /// /// [`fmt::Debug`]: self::Debug /// /// # Examples /// /// ```rust /// use std::fmt; /// use std::net::Ipv4Addr; /// /// struct Foo { /// bar: i32, /// baz: String, /// addr: Ipv4Addr, /// } /// /// impl fmt::Debug for Foo { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// fmt.debug_struct("Foo") /// .field("bar", &self.bar) /// .field("baz", &self.baz) /// .field("addr", &format_args!("{}", self.addr)) /// .finish() /// } /// } /// /// assert_eq!( /// "Foo { bar: 10, baz: \"Hello World\", addr: 127.0.0.1 }", /// format!("{:?}", Foo { /// bar: 10, /// baz: "Hello World".to_string(), /// addr: Ipv4Addr::new(127, 0, 0, 1), /// }) /// ); /// ``` #[stable(feature = "debug_builders", since = "1.2.0")] pub fn debug_struct<'b>(&'b mut self, name: &str) -> DebugStruct<'b, 'a> { builders::debug_struct_new(self, name) } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_struct_fields_finish` is more general, but this is faster for 1 field. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_struct_field1_finish<'b>( &'b mut self, name: &str, name1: &str, value1: &dyn Debug, ) -> Result { let mut builder = builders::debug_struct_new(self, name); builder.field(name1, value1); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_struct_fields_finish` is more general, but this is faster for 2 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_struct_field2_finish<'b>( &'b mut self, name: &str, name1: &str, value1: &dyn Debug, name2: &str, value2: &dyn Debug, ) -> Result { let mut builder = builders::debug_struct_new(self, name); builder.field(name1, value1); builder.field(name2, value2); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_struct_fields_finish` is more general, but this is faster for 3 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_struct_field3_finish<'b>( &'b mut self, name: &str, name1: &str, value1: &dyn Debug, name2: &str, value2: &dyn Debug, name3: &str, value3: &dyn Debug, ) -> Result { let mut builder = builders::debug_struct_new(self, name); builder.field(name1, value1); builder.field(name2, value2); builder.field(name3, value3); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_struct_fields_finish` is more general, but this is faster for 4 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_struct_field4_finish<'b>( &'b mut self, name: &str, name1: &str, value1: &dyn Debug, name2: &str, value2: &dyn Debug, name3: &str, value3: &dyn Debug, name4: &str, value4: &dyn Debug, ) -> Result { let mut builder = builders::debug_struct_new(self, name); builder.field(name1, value1); builder.field(name2, value2); builder.field(name3, value3); builder.field(name4, value4); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_struct_fields_finish` is more general, but this is faster for 5 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_struct_field5_finish<'b>( &'b mut self, name: &str, name1: &str, value1: &dyn Debug, name2: &str, value2: &dyn Debug, name3: &str, value3: &dyn Debug, name4: &str, value4: &dyn Debug, name5: &str, value5: &dyn Debug, ) -> Result { let mut builder = builders::debug_struct_new(self, name); builder.field(name1, value1); builder.field(name2, value2); builder.field(name3, value3); builder.field(name4, value4); builder.field(name5, value5); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// For the cases not covered by `debug_struct_field[12345]_finish`. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_struct_fields_finish<'b>( &'b mut self, name: &str, names: &[&str], values: &[&dyn Debug], ) -> Result { assert_eq!(names.len(), values.len()); let mut builder = builders::debug_struct_new(self, name); for (name, value) in iter::zip(names, values) { builder.field(name, value); } builder.finish() } /// Creates a `DebugTuple` builder designed to assist with creation of /// `fmt::Debug` implementations for tuple structs. /// /// # Examples /// /// ```rust /// use std::fmt; /// use std::marker::PhantomData; /// /// struct Foo(i32, String, PhantomData); /// /// impl fmt::Debug for Foo { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// fmt.debug_tuple("Foo") /// .field(&self.0) /// .field(&self.1) /// .field(&format_args!("_")) /// .finish() /// } /// } /// /// assert_eq!( /// "Foo(10, \"Hello\", _)", /// format!("{:?}", Foo(10, "Hello".to_string(), PhantomData::)) /// ); /// ``` #[stable(feature = "debug_builders", since = "1.2.0")] pub fn debug_tuple<'b>(&'b mut self, name: &str) -> DebugTuple<'b, 'a> { builders::debug_tuple_new(self, name) } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_tuple_fields_finish` is more general, but this is faster for 1 field. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_tuple_field1_finish<'b>(&'b mut self, name: &str, value1: &dyn Debug) -> Result { let mut builder = builders::debug_tuple_new(self, name); builder.field(value1); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_tuple_fields_finish` is more general, but this is faster for 2 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_tuple_field2_finish<'b>( &'b mut self, name: &str, value1: &dyn Debug, value2: &dyn Debug, ) -> Result { let mut builder = builders::debug_tuple_new(self, name); builder.field(value1); builder.field(value2); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_tuple_fields_finish` is more general, but this is faster for 3 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_tuple_field3_finish<'b>( &'b mut self, name: &str, value1: &dyn Debug, value2: &dyn Debug, value3: &dyn Debug, ) -> Result { let mut builder = builders::debug_tuple_new(self, name); builder.field(value1); builder.field(value2); builder.field(value3); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_tuple_fields_finish` is more general, but this is faster for 4 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_tuple_field4_finish<'b>( &'b mut self, name: &str, value1: &dyn Debug, value2: &dyn Debug, value3: &dyn Debug, value4: &dyn Debug, ) -> Result { let mut builder = builders::debug_tuple_new(self, name); builder.field(value1); builder.field(value2); builder.field(value3); builder.field(value4); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// `debug_tuple_fields_finish` is more general, but this is faster for 5 fields. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_tuple_field5_finish<'b>( &'b mut self, name: &str, value1: &dyn Debug, value2: &dyn Debug, value3: &dyn Debug, value4: &dyn Debug, value5: &dyn Debug, ) -> Result { let mut builder = builders::debug_tuple_new(self, name); builder.field(value1); builder.field(value2); builder.field(value3); builder.field(value4); builder.field(value5); builder.finish() } /// Used to shrink `derive(Debug)` code, for faster compilation and smaller binaries. /// For the cases not covered by `debug_tuple_field[12345]_finish`. #[doc(hidden)] #[unstable(feature = "fmt_helpers_for_derive", issue = "none")] pub fn debug_tuple_fields_finish<'b>( &'b mut self, name: &str, values: &[&dyn Debug], ) -> Result { let mut builder = builders::debug_tuple_new(self, name); for value in values { builder.field(value); } builder.finish() } /// Creates a `DebugList` builder designed to assist with creation of /// `fmt::Debug` implementations for list-like structures. /// /// # Examples /// /// ```rust /// use std::fmt; /// /// struct Foo(Vec); /// /// impl fmt::Debug for Foo { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// fmt.debug_list().entries(self.0.iter()).finish() /// } /// } /// /// assert_eq!(format!("{:?}", Foo(vec![10, 11])), "[10, 11]"); /// ``` #[stable(feature = "debug_builders", since = "1.2.0")] pub fn debug_list<'b>(&'b mut self) -> DebugList<'b, 'a> { builders::debug_list_new(self) } /// Creates a `DebugSet` builder designed to assist with creation of /// `fmt::Debug` implementations for set-like structures. /// /// # Examples /// /// ```rust /// use std::fmt; /// /// struct Foo(Vec); /// /// impl fmt::Debug for Foo { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// fmt.debug_set().entries(self.0.iter()).finish() /// } /// } /// /// assert_eq!(format!("{:?}", Foo(vec![10, 11])), "{10, 11}"); /// ``` /// /// [`format_args!`]: crate::format_args /// /// In this more complex example, we use [`format_args!`] and `.debug_set()` /// to build a list of match arms: /// /// ```rust /// use std::fmt; /// /// struct Arm<'a, L: 'a, R: 'a>(&'a (L, R)); /// struct Table<'a, K: 'a, V: 'a>(&'a [(K, V)], V); /// /// impl<'a, L, R> fmt::Debug for Arm<'a, L, R> /// where /// L: 'a + fmt::Debug, R: 'a + fmt::Debug /// { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// L::fmt(&(self.0).0, fmt)?; /// fmt.write_str(" => ")?; /// R::fmt(&(self.0).1, fmt) /// } /// } /// /// impl<'a, K, V> fmt::Debug for Table<'a, K, V> /// where /// K: 'a + fmt::Debug, V: 'a + fmt::Debug /// { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// fmt.debug_set() /// .entries(self.0.iter().map(Arm)) /// .entry(&Arm(&(format_args!("_"), &self.1))) /// .finish() /// } /// } /// ``` #[stable(feature = "debug_builders", since = "1.2.0")] pub fn debug_set<'b>(&'b mut self) -> DebugSet<'b, 'a> { builders::debug_set_new(self) } /// Creates a `DebugMap` builder designed to assist with creation of /// `fmt::Debug` implementations for map-like structures. /// /// # Examples /// /// ```rust /// use std::fmt; /// /// struct Foo(Vec<(String, i32)>); /// /// impl fmt::Debug for Foo { /// fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { /// fmt.debug_map().entries(self.0.iter().map(|&(ref k, ref v)| (k, v))).finish() /// } /// } /// /// assert_eq!( /// format!("{:?}", Foo(vec![("A".to_string(), 10), ("B".to_string(), 11)])), /// r#"{"A": 10, "B": 11}"# /// ); /// ``` #[stable(feature = "debug_builders", since = "1.2.0")] pub fn debug_map<'b>(&'b mut self) -> DebugMap<'b, 'a> { builders::debug_map_new(self) } } #[stable(since = "1.2.0", feature = "formatter_write")] impl Write for Formatter<'_> { fn write_str(&mut self, s: &str) -> Result { self.buf.write_str(s) } fn write_char(&mut self, c: char) -> Result { self.buf.write_char(c) } fn write_fmt(&mut self, args: Arguments<'_>) -> Result { write(self.buf, args) } } #[stable(feature = "rust1", since = "1.0.0")] impl Display for Error { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Display::fmt("an error occurred when formatting an argument", f) } } // Implementations of the core formatting traits macro_rules! fmt_refs { ($($tr:ident),*) => { $( #[stable(feature = "rust1", since = "1.0.0")] impl $tr for &T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { $tr::fmt(&**self, f) } } #[stable(feature = "rust1", since = "1.0.0")] impl $tr for &mut T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { $tr::fmt(&**self, f) } } )* } } fmt_refs! { Debug, Display, Octal, Binary, LowerHex, UpperHex, LowerExp, UpperExp } #[unstable(feature = "never_type", issue = "35121")] impl Debug for ! { fn fmt(&self, _: &mut Formatter<'_>) -> Result { *self } } #[unstable(feature = "never_type", issue = "35121")] impl Display for ! { fn fmt(&self, _: &mut Formatter<'_>) -> Result { *self } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for bool { #[inline] fn fmt(&self, f: &mut Formatter<'_>) -> Result { Display::fmt(self, f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Display for bool { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Display::fmt(if *self { "true" } else { "false" }, f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for str { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.write_char('"')?; let mut from = 0; for (i, c) in self.char_indices() { let esc = c.escape_debug_ext(EscapeDebugExtArgs { escape_grapheme_extended: true, escape_single_quote: false, escape_double_quote: true, }); // If char needs escaping, flush backlog so far and write, else skip if esc.len() != 1 { f.write_str(&self[from..i])?; for c in esc { f.write_char(c)?; } from = i + c.len_utf8(); } } f.write_str(&self[from..])?; f.write_char('"') } } #[stable(feature = "rust1", since = "1.0.0")] impl Display for str { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.pad(self) } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for char { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.write_char('\'')?; for c in self.escape_debug_ext(EscapeDebugExtArgs { escape_grapheme_extended: true, escape_single_quote: true, escape_double_quote: false, }) { f.write_char(c)? } f.write_char('\'') } } #[stable(feature = "rust1", since = "1.0.0")] impl Display for char { fn fmt(&self, f: &mut Formatter<'_>) -> Result { if f.width.is_none() && f.precision.is_none() { f.write_char(*self) } else { f.pad(self.encode_utf8(&mut [0; 4])) } } } #[stable(feature = "rust1", since = "1.0.0")] impl Pointer for *const T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { // Cast is needed here because `.expose_addr()` requires `T: Sized`. pointer_fmt_inner((*self as *const ()).expose_addr(), f) } } /// Since the formatting will be identical for all pointer types, use a non-monomorphized /// implementation for the actual formatting to reduce the amount of codegen work needed. /// /// This uses `ptr_addr: usize` and not `ptr: *const ()` to be able to use this for /// `fn(...) -> ...` without using [problematic] "Oxford Casts". /// /// [problematic]: https://github.com/rust-lang/rust/issues/95489 pub(crate) fn pointer_fmt_inner(ptr_addr: usize, f: &mut Formatter<'_>) -> Result { let old_width = f.width; let old_flags = f.flags; // The alternate flag is already treated by LowerHex as being special- // it denotes whether to prefix with 0x. We use it to work out whether // or not to zero extend, and then unconditionally set it to get the // prefix. if f.alternate() { f.flags |= 1 << (FlagV1::SignAwareZeroPad as u32); if f.width.is_none() { f.width = Some((usize::BITS / 4) as usize + 2); } } f.flags |= 1 << (FlagV1::Alternate as u32); let ret = LowerHex::fmt(&ptr_addr, f); f.width = old_width; f.flags = old_flags; ret } #[stable(feature = "rust1", since = "1.0.0")] impl Pointer for *mut T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Pointer::fmt(&(*self as *const T), f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Pointer for &T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Pointer::fmt(&(*self as *const T), f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Pointer for &mut T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Pointer::fmt(&(&**self as *const T), f) } } // Implementation of Display/Debug for various core types #[stable(feature = "rust1", since = "1.0.0")] impl Debug for *const T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Pointer::fmt(self, f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for *mut T { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Pointer::fmt(self, f) } } macro_rules! peel { ($name:ident, $($other:ident,)*) => (tuple! { $($other,)* }) } macro_rules! tuple { () => (); ( $($name:ident,)+ ) => ( maybe_tuple_doc! { $($name)+ @ #[stable(feature = "rust1", since = "1.0.0")] impl<$($name:Debug),+> Debug for ($($name,)+) where last_type!($($name,)+): ?Sized { #[allow(non_snake_case, unused_assignments)] fn fmt(&self, f: &mut Formatter<'_>) -> Result { let mut builder = f.debug_tuple(""); let ($(ref $name,)+) = *self; $( builder.field(&$name); )+ builder.finish() } } } peel! { $($name,)+ } ) } macro_rules! maybe_tuple_doc { ($a:ident @ #[$meta:meta] $item:item) => { #[doc(fake_variadic)] #[doc = "This trait is implemented for tuples up to twelve items long."] #[$meta] $item }; ($a:ident $($rest_a:ident)+ @ #[$meta:meta] $item:item) => { #[doc(hidden)] #[$meta] $item }; } macro_rules! last_type { ($a:ident,) => { $a }; ($a:ident, $($rest_a:ident,)+) => { last_type!($($rest_a,)+) }; } tuple! { E, D, C, B, A, Z, Y, X, W, V, U, T, } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for [T] { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.debug_list().entries(self.iter()).finish() } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for () { #[inline] fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.pad("()") } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for PhantomData { fn fmt(&self, f: &mut Formatter<'_>) -> Result { write!(f, "PhantomData<{}>", crate::any::type_name::()) } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for Cell { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.debug_struct("Cell").field("value", &self.get()).finish() } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for RefCell { fn fmt(&self, f: &mut Formatter<'_>) -> Result { match self.try_borrow() { Ok(borrow) => f.debug_struct("RefCell").field("value", &borrow).finish(), Err(_) => { // The RefCell is mutably borrowed so we can't look at its value // here. Show a placeholder instead. struct BorrowedPlaceholder; impl Debug for BorrowedPlaceholder { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.write_str("") } } f.debug_struct("RefCell").field("value", &BorrowedPlaceholder).finish() } } } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for Ref<'_, T> { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Debug::fmt(&**self, f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Debug for RefMut<'_, T> { fn fmt(&self, f: &mut Formatter<'_>) -> Result { Debug::fmt(&*(self.deref()), f) } } #[stable(feature = "core_impl_debug", since = "1.9.0")] impl Debug for UnsafeCell { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.debug_struct("UnsafeCell").finish_non_exhaustive() } } #[unstable(feature = "sync_unsafe_cell", issue = "95439")] impl Debug for SyncUnsafeCell { fn fmt(&self, f: &mut Formatter<'_>) -> Result { f.debug_struct("SyncUnsafeCell").finish_non_exhaustive() } } // If you expected tests to be here, look instead at the core/tests/fmt.rs file, // it's a lot easier than creating all of the rt::Piece structures here. // There are also tests in the alloc crate, for those that need allocations.