// This file is part of ICU4X. For terms of use, please see the file // called LICENSE at the top level of the ICU4X source tree // (online at: https://github.com/unicode-org/icu4x/blob/main/LICENSE ). // https://github.com/unicode-org/icu4x/blob/main/documents/process/boilerplate.md#library-annotations #![cfg_attr(all(not(test), not(doc)), no_std)] #![cfg_attr( not(test), deny( clippy::indexing_slicing, clippy::unwrap_used, clippy::expect_used, clippy::panic, clippy::exhaustive_structs, clippy::exhaustive_enums, missing_debug_implementations, ) )] //! `writeable` is a utility crate of the [`ICU4X`] project. //! //! It includes [`Writeable`], a core trait representing an object that can be written to a //! sink implementing `std::fmt::Write`. It is an alternative to `std::fmt::Display` with the //! addition of a function indicating the number of bytes to be written. //! //! `Writeable` improves upon `std::fmt::Display` in two ways: //! //! 1. More efficient, since the sink can pre-allocate bytes. //! 2. Smaller code, since the format machinery can be short-circuited. //! //! # Examples //! //! ``` //! use std::fmt; //! use writeable::assert_writeable_eq; //! use writeable::LengthHint; //! use writeable::Writeable; //! //! struct WelcomeMessage<'s> { //! pub name: &'s str, //! } //! //! impl<'s> Writeable for WelcomeMessage<'s> { //! fn write_to(&self, sink: &mut W) -> fmt::Result { //! sink.write_str("Hello, ")?; //! sink.write_str(self.name)?; //! sink.write_char('!')?; //! Ok(()) //! } //! //! fn writeable_length_hint(&self) -> LengthHint { //! // "Hello, " + '!' + length of name //! LengthHint::exact(8 + self.name.len()) //! } //! } //! //! let message = WelcomeMessage { name: "Alice" }; //! assert_writeable_eq!(&message, "Hello, Alice!"); //! //! // Types implementing `Writeable` are recommended to also implement `fmt::Display`. //! // This can be simply done by redirecting to the `Writeable` implementation: //! writeable::impl_display_with_writeable!(WelcomeMessage<'_>); //! ``` //! //! [`ICU4X`]: ../icu/index.html extern crate alloc; mod cmp; #[cfg(feature = "either")] mod either; mod impls; mod ops; mod parts_write_adapter; mod testing; mod try_writeable; use alloc::borrow::Cow; use alloc::string::String; use core::fmt; pub use try_writeable::TryWriteable; /// Helper types for trait impls. pub mod adapters { use super::*; pub use parts_write_adapter::CoreWriteAsPartsWrite; pub use try_writeable::TryWriteableInfallibleAsWriteable; pub use try_writeable::WriteableAsTryWriteableInfallible; } #[doc(hidden)] pub mod _internal { pub use super::testing::try_writeable_to_parts_for_test; pub use super::testing::writeable_to_parts_for_test; } /// A hint to help consumers of `Writeable` pre-allocate bytes before they call /// [`write_to`](Writeable::write_to). /// /// This behaves like `Iterator::size_hint`: it is a tuple where the first element is the /// lower bound, and the second element is the upper bound. If the upper bound is `None` /// either there is no known upper bound, or the upper bound is larger than `usize`. /// /// `LengthHint` implements std`::ops::{Add, Mul}` and similar traits for easy composition. /// During computation, the lower bound will saturate at `usize::MAX`, while the upper /// bound will become `None` if `usize::MAX` is exceeded. #[derive(Debug, PartialEq, Eq, Copy, Clone)] #[non_exhaustive] pub struct LengthHint(pub usize, pub Option); impl LengthHint { pub fn undefined() -> Self { Self(0, None) } /// `write_to` will use exactly n bytes. pub fn exact(n: usize) -> Self { Self(n, Some(n)) } /// `write_to` will use at least n bytes. pub fn at_least(n: usize) -> Self { Self(n, None) } /// `write_to` will use at most n bytes. pub fn at_most(n: usize) -> Self { Self(0, Some(n)) } /// `write_to` will use between `n` and `m` bytes. pub fn between(n: usize, m: usize) -> Self { Self(Ord::min(n, m), Some(Ord::max(n, m))) } /// Returns a recommendation for the number of bytes to pre-allocate. /// If an upper bound exists, this is used, otherwise the lower bound /// (which might be 0). /// /// # Examples /// /// ``` /// use writeable::Writeable; /// /// fn pre_allocate_string(w: &impl Writeable) -> String { /// String::with_capacity(w.writeable_length_hint().capacity()) /// } /// ``` pub fn capacity(&self) -> usize { self.1.unwrap_or(self.0) } /// Returns whether the `LengthHint` indicates that the string is exactly 0 bytes long. pub fn is_zero(&self) -> bool { self.1 == Some(0) } } /// [`Part`]s are used as annotations for formatted strings. For example, a string like /// `Alice, Bob` could assign a `NAME` part to the substrings `Alice` and `Bob`, and a /// `PUNCTUATION` part to `, `. This allows for example to apply styling only to names. /// /// `Part` contains two fields, whose usage is left up to the producer of the [`Writeable`]. /// Conventionally, the `category` field will identify the formatting logic that produces /// the string/parts, whereas the `value` field will have semantic meaning. `NAME` and /// `PUNCTUATION` could thus be defined as /// ``` /// # use writeable::Part; /// const NAME: Part = Part { /// category: "userlist", /// value: "name", /// }; /// const PUNCTUATION: Part = Part { /// category: "userlist", /// value: "punctuation", /// }; /// ``` /// /// That said, consumers should not usually have to inspect `Part` internals. Instead, /// formatters should expose the `Part`s they produces as constants. #[derive(Clone, Copy, Debug, PartialEq)] #[allow(clippy::exhaustive_structs)] // stable pub struct Part { pub category: &'static str, pub value: &'static str, } impl Part { /// A part that should annotate error segments in [`TryWriteable`] output. /// /// For an example, see [`TryWriteable`]. pub const ERROR: Part = Part { category: "writeable", value: "error", }; } /// A sink that supports annotating parts of the string with `Part`s. pub trait PartsWrite: fmt::Write { type SubPartsWrite: PartsWrite + ?Sized; fn with_part( &mut self, part: Part, f: impl FnMut(&mut Self::SubPartsWrite) -> fmt::Result, ) -> fmt::Result; } /// `Writeable` is an alternative to `std::fmt::Display` with the addition of a length function. pub trait Writeable { /// Writes a string to the given sink. Errors from the sink are bubbled up. /// The default implementation delegates to `write_to_parts`, and discards any /// `Part` annotations. fn write_to(&self, sink: &mut W) -> fmt::Result { self.write_to_parts(&mut parts_write_adapter::CoreWriteAsPartsWrite(sink)) } /// Write bytes and `Part` annotations to the given sink. Errors from the /// sink are bubbled up. The default implementation delegates to `write_to`, /// and doesn't produce any `Part` annotations. fn write_to_parts(&self, sink: &mut S) -> fmt::Result { self.write_to(sink) } /// Returns a hint for the number of UTF-8 bytes that will be written to the sink. /// /// Override this method if it can be computed quickly. fn writeable_length_hint(&self) -> LengthHint { LengthHint::undefined() } /// Creates a new `String` with the data from this `Writeable`. Like `ToString`, /// but smaller and faster. /// /// The default impl allocates an owned `String`. However, if it is possible to return a /// borrowed string, overwrite this method to return a `Cow::Borrowed`. /// /// To remove the `Cow` wrapper, call `.into_owned()` or `.as_str()` as appropriate. /// /// # Examples /// /// Inspect a `Writeable` before writing it to the sink: /// /// ``` /// use core::fmt::{Result, Write}; /// use writeable::Writeable; /// /// fn write_if_ascii(w: &W, sink: &mut S) -> Result /// where /// W: Writeable + ?Sized, /// S: Write + ?Sized, /// { /// let s = w.write_to_string(); /// if s.is_ascii() { /// sink.write_str(&s) /// } else { /// Ok(()) /// } /// } /// ``` /// /// Convert the `Writeable` into a fully owned `String`: /// /// ``` /// use writeable::Writeable; /// /// fn make_string(w: &impl Writeable) -> String { /// w.write_to_string().into_owned() /// } /// ``` fn write_to_string(&self) -> Cow { let hint = self.writeable_length_hint(); if hint.is_zero() { return Cow::Borrowed(""); } let mut output = String::with_capacity(hint.capacity()); let _ = self.write_to(&mut output); Cow::Owned(output) } /// Compares the contents of this `Writeable` to the given bytes /// without allocating a String to hold the `Writeable` contents. /// /// This returns a lexicographical comparison, the same as if the Writeable /// were first converted to a String and then compared with `Ord`. For a /// locale-sensitive string ordering, use an ICU4X Collator. /// /// # Examples /// /// ``` /// use core::cmp::Ordering; /// use core::fmt; /// use writeable::Writeable; /// /// struct WelcomeMessage<'s> { /// pub name: &'s str, /// } /// /// impl<'s> Writeable for WelcomeMessage<'s> { /// // see impl in Writeable docs /// # fn write_to(&self, sink: &mut W) -> fmt::Result { /// # sink.write_str("Hello, ")?; /// # sink.write_str(self.name)?; /// # sink.write_char('!')?; /// # Ok(()) /// # } /// } /// /// let message = WelcomeMessage { name: "Alice" }; /// let message_str = message.write_to_string(); /// /// assert_eq!(Ordering::Equal, message.writeable_cmp_bytes(b"Hello, Alice!")); /// /// assert_eq!(Ordering::Greater, message.writeable_cmp_bytes(b"Alice!")); /// assert_eq!(Ordering::Greater, (*message_str).cmp("Alice!")); /// /// assert_eq!(Ordering::Less, message.writeable_cmp_bytes(b"Hello, Bob!")); /// assert_eq!(Ordering::Less, (*message_str).cmp("Hello, Bob!")); /// ``` fn writeable_cmp_bytes(&self, other: &[u8]) -> core::cmp::Ordering { let mut wc = cmp::WriteComparator::new(other); let _ = self.write_to(&mut wc); wc.finish().reverse() } } /// Implements [`Display`](core::fmt::Display) for types that implement [`Writeable`]. /// /// It's recommended to do this for every [`Writeable`] type, as it will add /// support for `core::fmt` features like [`fmt!`](std::fmt), /// [`print!`](std::print), [`write!`](std::write), etc. #[macro_export] macro_rules! impl_display_with_writeable { ($type:ty) => { /// This trait is implemented for compatibility with [`fmt!`](alloc::fmt). /// To create a string, [`Writeable::write_to_string`] is usually more efficient. impl core::fmt::Display for $type { #[inline] fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { $crate::Writeable::write_to(&self, f) } } }; } /// Testing macros for types implementing [`Writeable`]. /// /// Arguments, in order: /// /// 1. The [`Writeable`] under test /// 2. The expected string value /// 3. [`*_parts_eq`] only: a list of parts (`[(start, end, Part)]`) /// /// Any remaining arguments get passed to `format!` /// /// The macros tests the following: /// /// - Equality of string content /// - Equality of parts ([`*_parts_eq`] only) /// - Validity of size hint /// - Reflexivity of `cmp_bytes` and order against largest and smallest strings /// /// # Examples /// /// ``` /// # use writeable::Writeable; /// # use writeable::LengthHint; /// # use writeable::Part; /// # use writeable::assert_writeable_eq; /// # use writeable::assert_writeable_parts_eq; /// # use std::fmt::{self, Write}; /// /// const WORD: Part = Part { /// category: "foo", /// value: "word", /// }; /// /// struct Demo; /// impl Writeable for Demo { /// fn write_to_parts( /// &self, /// sink: &mut S, /// ) -> fmt::Result { /// sink.with_part(WORD, |w| w.write_str("foo")) /// } /// fn writeable_length_hint(&self) -> LengthHint { /// LengthHint::exact(3) /// } /// } /// /// writeable::impl_display_with_writeable!(Demo); /// /// assert_writeable_eq!(&Demo, "foo"); /// assert_writeable_eq!(&Demo, "foo", "Message: {}", "Hello World"); /// /// assert_writeable_parts_eq!(&Demo, "foo", [(0, 3, WORD)]); /// assert_writeable_parts_eq!( /// &Demo, /// "foo", /// [(0, 3, WORD)], /// "Message: {}", /// "Hello World" /// ); /// ``` /// /// [`*_parts_eq`]: assert_writeable_parts_eq #[macro_export] macro_rules! assert_writeable_eq { ($actual_writeable:expr, $expected_str:expr $(,)?) => { $crate::assert_writeable_eq!($actual_writeable, $expected_str, "") }; ($actual_writeable:expr, $expected_str:expr, $($arg:tt)+) => {{ $crate::assert_writeable_eq!(@internal, $actual_writeable, $expected_str, $($arg)*); }}; (@internal, $actual_writeable:expr, $expected_str:expr, $($arg:tt)+) => {{ let actual_writeable = &$actual_writeable; let (actual_str, actual_parts) = $crate::_internal::writeable_to_parts_for_test(actual_writeable); let actual_len = actual_str.len(); assert_eq!(actual_str, $expected_str, $($arg)*); assert_eq!(actual_str, $crate::Writeable::write_to_string(actual_writeable), $($arg)+); let length_hint = $crate::Writeable::writeable_length_hint(actual_writeable); let lower = length_hint.0; assert!( lower <= actual_len, "hint lower bound {lower} larger than actual length {actual_len}: {}", format!($($arg)*), ); if let Some(upper) = length_hint.1 { assert!( actual_len <= upper, "hint upper bound {upper} smaller than actual length {actual_len}: {}", format!($($arg)*), ); } assert_eq!(actual_writeable.to_string(), $expected_str); let ordering = $crate::Writeable::writeable_cmp_bytes(actual_writeable, $expected_str.as_bytes()); assert_eq!(ordering, core::cmp::Ordering::Equal, $($arg)*); let ordering = $crate::Writeable::writeable_cmp_bytes(actual_writeable, "\u{10FFFF}".as_bytes()); assert_eq!(ordering, core::cmp::Ordering::Less, $($arg)*); if $expected_str != "" { let ordering = $crate::Writeable::writeable_cmp_bytes(actual_writeable, "".as_bytes()); assert_eq!(ordering, core::cmp::Ordering::Greater, $($arg)*); } actual_parts // return for assert_writeable_parts_eq }}; } /// See [`assert_writeable_eq`]. #[macro_export] macro_rules! assert_writeable_parts_eq { ($actual_writeable:expr, $expected_str:expr, $expected_parts:expr $(,)?) => { $crate::assert_writeable_parts_eq!($actual_writeable, $expected_str, $expected_parts, "") }; ($actual_writeable:expr, $expected_str:expr, $expected_parts:expr, $($arg:tt)+) => {{ let actual_parts = $crate::assert_writeable_eq!(@internal, $actual_writeable, $expected_str, $($arg)*); assert_eq!(actual_parts, $expected_parts, $($arg)+); }}; }