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// Copyright Mozilla Foundation. See the COPYRIGHT
// file at the top-level directory of this distribution.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// option. This file may not be copied, modified, or distributed
// except according to those terms.
#![cfg_attr(
feature = "cargo-clippy",
allow(doc_markdown, inline_always, new_ret_no_self)
)]
//! encoding_rs is a Gecko-oriented Free Software / Open Source implementation
//! Gecko-oriented means that converting to and from UTF-16 is supported in
//! addition to converting to and from UTF-8, that the performance and
//! streamability goals are browser-oriented, and that FFI-friendliness is a
//! goal.
//!
//! Additionally, the `mem` module provides functions that are useful for
//! applications that need to be able to deal with legacy in-memory
//! representations of Unicode.
//!
//! For expectation setting, please be sure to read the sections
//! [_UTF-16LE, UTF-16BE and Unicode Encoding Schemes_](#utf-16le-utf-16be-and-unicode-encoding-schemes),
//! [_ISO-8859-1_](#iso-8859-1) and [_Web / Browser Focus_](#web--browser-focus) below.
//!
//! design and internals of the crate.
//!
//! # Availability
//!
//! The code is available under the
//! See the
//! file for details.
//!
//! # Integration with `std::io`
//!
//! This crate doesn't implement traits from `std::io`. However, for the case of
//! wrapping a `std::io::Read` in a decoder that implements `std::io::Read` and
//! presents the data from the wrapped `std::io::Read` as UTF-8 is addressed by
//!
//! # Examples
//!
//! Example programs:
//!
//!
//! Decode using the non-streaming API:
//!
//! ```
//! #[cfg(feature = "alloc")] {
//! use encoding_rs::*;
//!
//! let expectation = "\u{30CF}\u{30ED}\u{30FC}\u{30FB}\u{30EF}\u{30FC}\u{30EB}\u{30C9}";
//! let bytes = b"\x83n\x83\x8D\x81[\x81E\x83\x8F\x81[\x83\x8B\x83h";
//!
//! let (cow, encoding_used, had_errors) = SHIFT_JIS.decode(bytes);
//! assert_eq!(&cow[..], expectation);
//! assert_eq!(encoding_used, SHIFT_JIS);
//! assert!(!had_errors);
//! }
//! ```
//!
//! Decode using the streaming API with minimal `unsafe`:
//!
//! ```
//! use encoding_rs::*;
//!
//! let expectation = "\u{30CF}\u{30ED}\u{30FC}\u{30FB}\u{30EF}\u{30FC}\u{30EB}\u{30C9}";
//!
//! // Use an array of byte slices to demonstrate content arriving piece by
//! // piece from the network.
//! let bytes: [&'static [u8]; 4] = [b"\x83",
//! b"n\x83\x8D\x81",
//! b"[\x81E\x83\x8F\x81[\x83",
//! b"\x8B\x83h"];
//!
//! // Very short output buffer to demonstrate the output buffer getting full.
//! // Normally, you'd use something like `[0u8; 2048]`.
//! let mut buffer_bytes = [0u8; 8];
//! let mut buffer: &mut str = std::str::from_utf8_mut(&mut buffer_bytes[..]).unwrap();
//!
//! // How many bytes in the buffer currently hold significant data.
//! let mut bytes_in_buffer = 0usize;
//!
//! // Collect the output to a string for demonstration purposes.
//! let mut output = String::new();
//!
//! // The `Decoder`
//! let mut decoder = SHIFT_JIS.new_decoder();
//!
//! // Track whether we see errors.
//! let mut total_had_errors = false;
//!
//! // Decode using a fixed-size intermediate buffer (for demonstrating the
//! // use of a fixed-size buffer; normally when the output of an incremental
//! // decode goes to a `String` one would use `Decoder.decode_to_string()` to
//! // avoid the intermediate buffer).
//! for input in &bytes[..] {
//! // The number of bytes already read from current `input` in total.
//! let mut total_read_from_current_input = 0usize;
//!
//! loop {
//! let (result, read, written, had_errors) =
//! decoder.decode_to_str(&input[total_read_from_current_input..],
//! &mut buffer[bytes_in_buffer..],
//! false);
//! total_read_from_current_input += read;
//! bytes_in_buffer += written;
//! total_had_errors |= had_errors;
//! match result {
//! CoderResult::InputEmpty => {
//! // We have consumed the current input buffer. Break out of
//! // the inner loop to get the next input buffer from the
//! // outer loop.
//! break;
//! },
//! CoderResult::OutputFull => {
//! // Write the current buffer out and consider the buffer
//! // empty.
//! output.push_str(&buffer[..bytes_in_buffer]);
//! bytes_in_buffer = 0usize;
//! continue;
//! }
//! }
//! }
//! }
//!
//! // Process EOF
//! loop {
//! let (result, _, written, had_errors) =
//! decoder.decode_to_str(b"",
//! &mut buffer[bytes_in_buffer..],
//! true);
//! bytes_in_buffer += written;
//! total_had_errors |= had_errors;
//! // Write the current buffer out and consider the buffer empty.
//! // Need to do this here for both `match` arms, because we exit the
//! // loop on `CoderResult::InputEmpty`.
//! output.push_str(&buffer[..bytes_in_buffer]);
//! bytes_in_buffer = 0usize;
//! match result {
//! CoderResult::InputEmpty => {
//! // Done!
//! break;
//! },
//! CoderResult::OutputFull => {
//! continue;
//! }
//! }
//! }
//!
//! assert_eq!(&output[..], expectation);
//! assert!(!total_had_errors);
//! ```
//!
//! ## UTF-16LE, UTF-16BE and Unicode Encoding Schemes
//!
//! The Encoding Standard doesn't specify encoders for UTF-16LE and UTF-16BE,
//! __so this crate does not provide encoders for those encodings__!
//! Along with the replacement encoding, their _output encoding_ (i.e. the
//! encoding used for form submission and error handling in the query string
//! of URLs) is UTF-8, so you get an UTF-8 encoder if you request an encoder
//! for them.
//!
//! Additionally, the Encoding Standard factors BOM handling into wrapper
//! algorithms so that BOM handling isn't part of the definition of the
//! encodings themselves. The Unicode _encoding schemes_ in the Unicode
//! Standard define BOM handling or lack thereof as part of the encoding
//! scheme.
//!
//! When used with the `_without_bom_handling` entry points, the UTF-16LE
//! and UTF-16BE _encodings_ match the same-named _encoding schemes_ from
//! the Unicode Standard.
//!
//! When used with the `_with_bom_removal` entry points, the UTF-8
//! _encoding_ matches the UTF-8 _encoding scheme_ from the Unicode
//! Standard.
//!
//! This crate does not provide a mode that matches the UTF-16 _encoding
//! scheme_ from the Unicode Stardard. The UTF-16BE encoding used with
//! the entry points without `_bom_` qualifiers is the closest match,
//! but in that case, the UTF-8 BOM triggers UTF-8 decoding, which is
//! not part of the behavior of the UTF-16 _encoding scheme_ per the
//! Unicode Standard.
//!
//! The UTF-32 family of Unicode encoding schemes is not supported
//! by this crate. The Encoding Standard doesn't define any UTF-32
//! family encodings, since they aren't necessary for consuming Web
//! content.
//!
//! While gb18030 is capable of representing U+FEFF, the Encoding
//! Standard does not treat the gb18030 byte representation of U+FEFF
//! as a BOM, so neither does this crate.
//!
//! ## ISO-8859-1
//!
//! ISO-8859-1 does not exist as a distinct encoding from windows-1252 in
//! the Encoding Standard. Therefore, an encoding that maps the unsigned
//! byte value to the same Unicode scalar value is not available via
//! `Encoding` in this crate.
//!
//! However, the functions whose name starts with `convert` and contains
//! `latin1` in the `mem` module support such conversions, which are known as
//!
//! ## Web / Browser Focus
//!
//! Both in terms of scope and performance, the focus is on the Web. For scope,
//! this means that encoding_rs implements the Encoding Standard fully and
//! doesn't implement encodings that are not specified in the Encoding
//! Standard. For performance, this means that decoding performance is
//! important as well as performance for encoding into UTF-8 or encoding the
//! Basic Latin range (ASCII) into legacy encodings. Non-Basic Latin needs to
//! be encoded into legacy encodings in only two places in the Web platform: in
//! the query part of URLs, in which case it's a matter of relatively rare
//! error handling, and in form submission, in which case the user action and
//! networking tend to hide the performance of the encoder.
//!
//! Deemphasizing performance of encoding non-Basic Latin text into legacy
//! encodings enables smaller code size thanks to the encoder side using the
//! decode-optimized data tables without having encode-optimized data tables at
//! all. Even in decoders, smaller lookup table size is preferred over avoiding
//! multiplication operations.
//!
//! Additionally, performance is a non-goal for the ASCII-incompatible
//! ISO-2022-JP encoding, which are rarely used on the Web. Instead of
//! performance, the decoder for ISO-2022-JP optimizes for ease/clarity
//! of implementation.
//!
//! Despite the browser focus, the hope is that non-browser applications
//! that wish to consume Web content or submit Web forms in a Web-compatible
//! way will find encoding_rs useful. While encoding_rs does not try to match
//! Windows behavior, many of the encodings are close enough to legacy
//! encodings implemented by Windows that applications that need to consume
//! data in legacy Windows encodins may find encoding_rs useful. The
//! code page identifiers onto encoding_rs `Encoding`s and vice versa.
//!
//! For decoding email, UTF-7 support is needed (unfortunately) in additition
//! to the encodings defined in the Encoding Standard. The
//! UTF-7 decoding for email purposes.
//!
//! For single-byte DOS encodings beyond the ones supported by the Encoding
//!
//! # Preparing Text for the Encoders
//!
//! Normalizing text into Unicode Normalization Form C prior to encoding text
//! into a legacy encoding minimizes unmappable characters. Text can be
//! normalized to Unicode Normalization Form C using the
//!
//! The exception is windows-1258, which after normalizing to Unicode
//! Normalization Form C requires tone marks to be decomposed in order to
//! minimize unmappable characters. Vietnamese tone marks can be decomposed
//!
//! # Streaming & Non-Streaming; Rust & C/C++
//!
//! The API in Rust has two modes of operation: streaming and non-streaming.
//! The streaming API is the foundation of the implementation and should be
//! used when processing data that arrives piecemeal from an i/o stream. The
//! streaming API has an FFI wrapper (as a [separate crate][1]) that exposes it
//! to C callers. The non-streaming part of the API is for Rust callers only and
//! is smart about borrowing instead of copying when possible. When
//! streamability is not needed, the non-streaming API should be preferrer in
//! order to avoid copying data when a borrow suffices.
//!
//! There is no analogous C API exposed via FFI, mainly because C doesn't have
//! standard types for growable byte buffers and Unicode strings that know
//! their length.
//!
//! The C API (header file generated at `target/include/encoding_rs.h` when
//! building encoding_rs) can, in turn, be wrapped for use from C++. Such a
//! C++ wrapper can re-create the non-streaming API in C++ for C++ callers.
//! The C binding comes with a [C++17 wrapper][2] that uses standard library +
//! [GSL][3] types and that recreates the non-streaming API in C++ on top of
//! the streaming API. A C++ wrapper with XPCOM/MFBT types is available as
//! [`mozilla::Encoding`][4].
//!
//! The `Encoding` type is common to both the streaming and non-streaming
//! modes. In the streaming mode, decoding operations are performed with a
//! `Decoder` and encoding operations with an `Encoder` object obtained via
//! `Encoding`. In the non-streaming mode, decoding and encoding operations are
//! performed using methods on `Encoding` objects themselves, so the `Decoder`
//! and `Encoder` objects are not used at all.
//!
//!
//! # Memory management
//!
//! The non-streaming mode never performs heap allocations (even the methods
//! that write into a `Vec<u8>` or a `String` by taking them as arguments do
//! not reallocate the backing buffer of the `Vec<u8>` or the `String`). That
//! is, the non-streaming mode uses caller-allocated buffers exclusively.
//!
//! The methods of the streaming mode that return a `Vec<u8>` or a `String`
//! perform heap allocations but only to allocate the backing buffer of the
//! `Vec<u8>` or the `String`.
//!
//! `Encoding` is always statically allocated. `Decoder` and `Encoder` need no
//! `Drop` cleanup.
//!
//! # Buffer reading and writing behavior
//!
//! Based on experience gained with the `java.nio.charset` encoding converter
//! API and with the Gecko uconv encoding converter API, the buffer reading
//! and writing behaviors of encoding_rs are asymmetric: input buffers are
//! fully drained but output buffers are not always fully filled.
//!
//! When reading from an input buffer, encoding_rs always consumes all input
//! up to the next error or to the end of the buffer. In particular, when
//! decoding, even if the input buffer ends in the middle of a byte sequence
//! for a character, the decoder consumes all input. This has the benefit that
//! the caller of the API can always fill the next buffer from the start from
//! whatever source the bytes come from and never has to first copy the last
//! bytes of the previous buffer to the start of the next buffer. However, when
//! encoding, the UTF-8 input buffers have to end at a character boundary, which
//! is a requirement for the Rust `str` type anyway, and UTF-16 input buffer
//! boundaries falling in the middle of a surrogate pair result in both
//! suggorates being treated individually as unpaired surrogates.
//!
//! Additionally, decoders guarantee that they can be fed even one byte at a
//! time and encoders guarantee that they can be fed even one code point at a
//! time. This has the benefit of not placing restrictions on the size of
//! chunks the content arrives e.g. from network.
//!
//! When writing into an output buffer, encoding_rs makes sure that the code
//! unit sequence for a character is never split across output buffer
//! boundaries. This may result in wasted space at the end of an output buffer,
//! but the advantages are that the output side of both decoders and encoders
//! is greatly simplified compared to designs that attempt to fill output
//! buffers exactly even when that entails splitting a code unit sequence and
//! when encoding_rs methods return to the caller, the output produces thus
//! far is always valid taken as whole. (In the case of encoding to ISO-2022-JP,
//! the output needs to be considered as a whole, because the latest output
//! buffer taken alone might not be valid taken alone if the transition away
//! from the ASCII state occurred in an earlier output buffer. However, since
//! the ISO-2022-JP decoder doesn't treat streams that don't end in the ASCII
//! state as being in error despite the encoder generating a transition to the
//! ASCII state at the end, the claim about the partial output taken as a whole
//! being valid is true even for ISO-2022-JP.)
//!
//! # Error Reporting
//!
//! Based on experience gained with the `java.nio.charset` encoding converter
//! API and with the Gecko uconv encoding converter API, the error reporting
//! behaviors of encoding_rs are asymmetric: decoder errors include offsets
//! that leave it up to the caller to extract the erroneous bytes from the
//! input stream if the caller wishes to do so but encoder errors provide the
//! code point associated with the error without requiring the caller to
//! extract it from the input on its own.
//!
//! On the encoder side, an error is always triggered by the most recently
//! pushed Unicode scalar, which makes it simple to pass the `char` to the
//! caller. Also, it's very typical for the caller to wish to do something with
//! this data: generate a numeric escape for the character. Additionally, the
//! ISO-2022-JP encoder reports U+FFFD instead of the actual input character in
//! certain cases, so requiring the caller to extract the character from the
//! input buffer would require the caller to handle ISO-2022-JP details.
//! Furthermore, requiring the caller to extract the character from the input
//! buffer would require the caller to implement UTF-8 or UTF-16 math, which is
//! the job of an encoding conversion library.
//!
//! On the decoder side, errors are triggered in more complex ways. For
//! example, when decoding the sequence ESC, '$', _buffer boundary_, 'A' as
//! ISO-2022-JP, the ESC byte is in error, but this is discovered only after
//! the buffer boundary when processing 'A'. Thus, the bytes in error might not
//! be the ones most recently pushed to the decoder and the error might not even
//! be in the current buffer.
//!
//! Some encoding conversion APIs address the problem by not acknowledging
//! trailing bytes of an input buffer as consumed if it's still possible for
//! future bytes to cause the trailing bytes to be in error. This way, error
//! reporting can always refer to the most recently pushed buffer. This has the
//! problem that the caller of the API has to copy the unconsumed trailing
//! bytes to the start of the next buffer before being able to fill the rest
//! of the next buffer. This is annoying, error-prone and inefficient.
//!
//! A possible solution would be making the decoder remember recently consumed
//! bytes in order to be able to include a copy of the erroneous bytes when
//! reporting an error. This has two problem: First, callers a rarely
//! interested in the erroneous bytes, so attempts to identify them are most
//! often just overhead anyway. Second, the rare applications that are
//! interested typically care about the location of the error in the input
//! stream.
//!
//! To keep the API convenient for common uses and the overhead low while making
//! it possible to develop applications, such as HTML validators, that care
//! about which bytes were in error, encoding_rs reports the length of the
//! erroneous sequence and the number of bytes consumed after the erroneous
//! sequence. As long as the caller doesn't discard the 6 most recent bytes,
//! this makes it possible for callers that care about the erroneous bytes to
//! locate them.
//!
//! # No Convenience API for Custom Replacements
//!
//! The Web Platform and, therefore, the Encoding Standard supports only one
//! error recovery mode for decoders and only one error recovery mode for
//! encoders. The supported error recovery mode for decoders is emitting the
//! REPLACEMENT CHARACTER on error. The supported error recovery mode for
//! encoders is emitting an HTML decimal numeric character reference for
//! unmappable characters.
//!
//! Since encoding_rs is Web-focused, these are the only error recovery modes
//! for which convenient support is provided. Moreover, on the decoder side,
//! there aren't really good alternatives for emitting the REPLACEMENT CHARACTER
//! on error (other than treating errors as fatal). In particular, simply
//! ignoring errors is a
//! [security problem](http://www.unicode.org/reports/tr36/#Substituting_for_Ill_Formed_Subsequences),
//! so it would be a bad idea for encoding_rs to provide a mode that encouraged
//! callers to ignore errors.
//!
//! On the encoder side, there are plausible alternatives for HTML decimal
//! numeric character references. For example, when outputting CSS, CSS-style
//! escapes would seem to make sense. However, instead of facilitating the
//! output of CSS, JS, etc. in non-UTF-8 encodings, encoding_rs takes the design
//! position that you shouldn't generate output in encodings other than UTF-8,
//! except where backward compatibility with interacting with the legacy Web
//! requires it. The legacy Web requires it only when parsing the query strings
//! of URLs and when submitting forms, and those two both use HTML decimal
//! numeric character references.
//!
//! While encoding_rs doesn't make encoder replacements other than HTML decimal
//! numeric character references easy, it does make them _possible_.
//! `encode_from_utf8()`, which emits HTML decimal numeric character references
//! for unmappable characters, is implemented on top of
//! `encode_from_utf8_without_replacement()`. Applications that really, really
//! want other replacement schemes for unmappable characters can likewise
//! implement them on top of `encode_from_utf8_without_replacement()`.
//!
//! # No Extensibility by Design
//!
//! The set of encodings supported by encoding_rs is not extensible by design.
//! That is, `Encoding`, `Decoder` and `Encoder` are intentionally `struct`s
//! rather than `trait`s. encoding_rs takes the design position that all future
//! text interchange should be done using UTF-8, which can represent all of
//! Unicode. (It is, in fact, the only encoding supported by the Encoding
//! Standard and encoding_rs that can represent all of Unicode and that has
//! encoder support. UTF-16LE and UTF-16BE don't have encoder support, and
//! gb18030 cannot encode U+E5E5.) The other encodings are supported merely for
//! legacy compatibility and not due to non-UTF-8 encodings having benefits
//! other than being able to consume legacy content.
//!
//! Considering that UTF-8 can represent all of Unicode and is already supported
//! by all Web browsers, introducing a new encoding wouldn't add to the
//! expressiveness but would add to compatibility problems. In that sense,
//! adding new encodings to the Web Platform doesn't make sense, and, in fact,
//! post-UTF-8 attempts at encodings, such as BOCU-1, have been rejected from
//! the Web Platform. On the other hand, the set of legacy encodings that must
//! be supported for a Web browser to be able to be successful is not going to
//! expand. Empirically, the set of encodings specified in the Encoding Standard
//! is already sufficient and the set of legacy encodings won't grow
//! retroactively.
//!
//! Since extensibility doesn't make sense considering the Web focus of
//! encoding_rs and adding encodings to Web clients would be actively harmful,
//! it makes sense to make the set of encodings that encoding_rs supports
//! non-extensible and to take the (admittedly small) benefits arising from
//! that, such as the size of `Decoder` and `Encoder` objects being known ahead
//! of time, which enables stack allocation thereof.
//!
//! This does have downsides for applications that might want to put encoding_rs
//! to non-Web uses if those non-Web uses involve legacy encodings that aren't
//! needed for Web uses. The needs of such applications should not complicate
//! encoding_rs itself, though. It is up to those applications to provide a
//! framework that delegates the operations with encodings that encoding_rs
//! supports to encoding_rs and operations with other encodings to something
//! else (as opposed to encoding_rs itself providing an extensibility
//! framework).
//!
//! # Panics
//!
//! Methods in encoding_rs can panic if the API is used against the requirements
//! stated in the documentation, if a state that's supposed to be impossible
//! is reached due to an internal bug or on integer overflow. When used
//! according to documentation with buffer sizes that stay below integer
//! overflow, in the absence of internal bugs, encoding_rs does not panic.
//!
//! Panics arising from API misuse aren't documented beyond this on individual
//! methods.
//!
//! # At-Risk Parts of the API
//!
//! The foreseeable source of partially backward-incompatible API change is the
//! way the instances of `Encoding` are made available.
//!
//! If Rust changes to allow the entries of `[&'static Encoding; N]` to be
//! initialized with `static`s of type `&'static Encoding`, the non-reference
//! `FOO_INIT` public `Encoding` instances will be removed from the public API.
//!
//! If Rust changes to make the referent of `pub const FOO: &'static Encoding`
//! unique when the constant is used in different crates, the reference-typed
//! `static`s for the encoding instances will be changed from `static` to
//! `const` and the non-reference-typed `_INIT` instances will be removed.
//!
//! # Mapping Spec Concepts onto the API
//!
//! <table>
//! <thead>
//! <tr><th>Spec Concept</th><th>Streaming</th><th>Non-Streaming</th></tr>
//! </thead>
//! <tbody>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#encoding">encoding</a></td><td><code>&'static Encoding</code></td><td><code>&'static Encoding</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#utf-8">UTF-8 encoding</a></td><td><code>UTF_8</code></td><td><code>UTF_8</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#concept-encoding-get">get an encoding</a></td><td><code>Encoding::for_label(<var>label</var>)</code></td><td><code>Encoding::for_label(<var>label</var>)</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#name">name</a></td><td><code><var>encoding</var>.name()</code></td><td><code><var>encoding</var>.name()</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#get-an-output-encoding">get an output encoding</a></td><td><code><var>encoding</var>.output_encoding()</code></td><td><code><var>encoding</var>.output_encoding()</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#decode">decode</a></td><td><code>let d = <var>encoding</var>.new_decoder();<br>let res = d.decode_to_<var>*</var>(<var>src</var>, <var>dst</var>, false);<br>// …</br>let last_res = d.decode_to_<var>*</var>(<var>src</var>, <var>dst</var>, true);</code></td><td><code><var>encoding</var>.decode(<var>src</var>)</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#utf-8-decode">UTF-8 decode</a></td><td><code>let d = UTF_8.new_decoder_with_bom_removal();<br>let res = d.decode_to_<var>*</var>(<var>src</var>, <var>dst</var>, false);<br>// …</br>let last_res = d.decode_to_<var>*</var>(<var>src</var>, <var>dst</var>, true);</code></td><td><code>UTF_8.decode_with_bom_removal(<var>src</var>)</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#utf-8-decode-without-bom">UTF-8 decode without BOM</a></td><td><code>let d = UTF_8.new_decoder_without_bom_handling();<br>let res = d.decode_to_<var>*</var>(<var>src</var>, <var>dst</var>, false);<br>// …</br>let last_res = d.decode_to_<var>*</var>(<var>src</var>, <var>dst</var>, true);</code></td><td><code>UTF_8.decode_without_bom_handling(<var>src</var>)</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#utf-8-decode-without-bom-or-fail">UTF-8 decode without BOM or fail</a></td><td><code>let d = UTF_8.new_decoder_without_bom_handling();<br>let res = d.decode_to_<var>*</var>_without_replacement(<var>src</var>, <var>dst</var>, false);<br>// … (fail if malformed)</br>let last_res = d.decode_to_<var>*</var>_without_replacement(<var>src</var>, <var>dst</var>, true);<br>// (fail if malformed)</code></td><td><code>UTF_8.decode_without_bom_handling_and_without_replacement(<var>src</var>)</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#encode">encode</a></td><td><code>let e = <var>encoding</var>.new_encoder();<br>let res = e.encode_to_<var>*</var>(<var>src</var>, <var>dst</var>, false);<br>// …</br>let last_res = e.encode_to_<var>*</var>(<var>src</var>, <var>dst</var>, true);</code></td><td><code><var>encoding</var>.encode(<var>src</var>)</code></td></tr>
//! <tr><td><a href="https://encoding.spec.whatwg.org/#utf-8-encode">UTF-8 encode</a></td><td>Use the UTF-8 nature of Rust strings directly:<br><code><var>write</var>(<var>src</var>.as_bytes());<br>// refill src<br><var>write</var>(<var>src</var>.as_bytes());<br>// refill src<br><var>write</var>(<var>src</var>.as_bytes());<br>// …</code></td><td>Use the UTF-8 nature of Rust strings directly:<br><code><var>src</var>.as_bytes()</code></td></tr>
//! </tbody>
//! </table>
//!
//! # Compatibility with the rust-encoding API
//!
//! The crate
//! is a drop-in replacement for rust-encoding 0.2.32 that implements (most of)
//! the API of rust-encoding 0.2.32 on top of encoding_rs.
//!
//! # Mapping rust-encoding concepts to encoding_rs concepts
//!
//! The following table provides a mapping from rust-encoding constructs to
//! encoding_rs ones.
//!
//! <table>
//! <thead>
//! <tr><th>rust-encoding</th><th>encoding_rs</th></tr>
//! </thead>
//! <tbody>
//! <tr><td><code>encoding::EncodingRef</code></td><td><code>&'static encoding_rs::Encoding</code></td></tr>
//! <tr><td><code>encoding::all::<var>WINDOWS_31J</var></code> (not based on the WHATWG name for some encodings)</td><td><code>encoding_rs::<var>SHIFT_JIS</var></code> (always the WHATWG name uppercased and hyphens replaced with underscores)</td></tr>
//! <tr><td><code>encoding::all::ERROR</code></td><td>Not available because not in the Encoding Standard</td></tr>
//! <tr><td><code>encoding::all::ASCII</code></td><td>Not available because not in the Encoding Standard</td></tr>
//! <tr><td><code>encoding::all::ISO_8859_1</code></td><td>Not available because not in the Encoding Standard</td></tr>
//! <tr><td><code>encoding::all::HZ</code></td><td>Not available because not in the Encoding Standard</td></tr>
//! <tr><td><code>encoding::label::encoding_from_whatwg_label(<var>string</var>)</code></td><td><code>encoding_rs::Encoding::for_label(<var>string</var>)</code></td></tr>
//! <tr><td><code><var>enc</var>.whatwg_name()</code> (always lower case)</td><td><code><var>enc</var>.name()</code> (potentially mixed case)</td></tr>
//! <tr><td><code><var>enc</var>.name()</code></td><td>Not available because not in the Encoding Standard</td></tr>
//! <tr><td><code>encoding::decode(<var>bytes</var>, encoding::DecoderTrap::Replace, <var>enc</var>)</code></td><td><code><var>enc</var>.decode(<var>bytes</var>)</code></td></tr>
//! <tr><td><code><var>enc</var>.decode(<var>bytes</var>, encoding::DecoderTrap::Replace)</code></td><td><code><var>enc</var>.decode_without_bom_handling(<var>bytes</var>)</code></td></tr>
//! <tr><td><code><var>enc</var>.encode(<var>string</var>, encoding::EncoderTrap::NcrEscape)</code></td><td><code><var>enc</var>.encode(<var>string</var>)</code></td></tr>
//! <tr><td><code><var>enc</var>.raw_decoder()</code></td><td><code><var>enc</var>.new_decoder_without_bom_handling()</code></td></tr>
//! <tr><td><code><var>enc</var>.raw_encoder()</code></td><td><code><var>enc</var>.new_encoder()</code></td></tr>
//! <tr><td><code>encoding::RawDecoder</code></td><td><code>encoding_rs::Decoder</code></td></tr>
//! <tr><td><code>encoding::RawEncoder</code></td><td><code>encoding_rs::Encoder</code></td></tr>
//! <tr><td><code><var>raw_decoder</var>.raw_feed(<var>src</var>, <var>dst_string</var>)</code></td><td><code><var>dst_string</var>.reserve(<var>decoder</var>.max_utf8_buffer_length_without_replacement(<var>src</var>.len()));<br><var>decoder</var>.decode_to_string_without_replacement(<var>src</var>, <var>dst_string</var>, false)</code></td></tr>
//! <tr><td><code><var>raw_encoder</var>.raw_feed(<var>src</var>, <var>dst_vec</var>)</code></td><td><code><var>dst_vec</var>.reserve(<var>encoder</var>.max_buffer_length_from_utf8_without_replacement(<var>src</var>.len()));<br><var>encoder</var>.encode_from_utf8_to_vec_without_replacement(<var>src</var>, <var>dst_vec</var>, false)</code></td></tr>
//! <tr><td><code><var>raw_decoder</var>.raw_finish(<var>dst</var>)</code></td><td><code><var>dst_string</var>.reserve(<var>decoder</var>.max_utf8_buffer_length_without_replacement(0));<br><var>decoder</var>.decode_to_string_without_replacement(b"", <var>dst</var>, true)</code></td></tr>
//! <tr><td><code><var>raw_encoder</var>.raw_finish(<var>dst</var>)</code></td><td><code><var>dst_vec</var>.reserve(<var>encoder</var>.max_buffer_length_from_utf8_without_replacement(0));<br><var>encoder</var>.encode_from_utf8_to_vec_without_replacement("", <var>dst</var>, true)</code></td></tr>
//! <tr><td><code>encoding::DecoderTrap::Strict</code></td><td><code>decode*</code> methods that have <code>_without_replacement</code> in their name (and treating the `Malformed` result as fatal).</td></tr>
//! <tr><td><code>encoding::DecoderTrap::Replace</code></td><td><code>decode*</code> methods that <i>do not</i> have <code>_without_replacement</code> in their name.</td></tr>
//! <tr><td><code>encoding::DecoderTrap::Ignore</code></td><td>It is a bad idea to ignore errors due to security issues, but this could be implemented using <code>decode*</code> methods that have <code>_without_replacement</code> in their name.</td></tr>
//! <tr><td><code>encoding::DecoderTrap::Call(DecoderTrapFunc)</code></td><td>Can be implemented using <code>decode*</code> methods that have <code>_without_replacement</code> in their name.</td></tr>
//! <tr><td><code>encoding::EncoderTrap::Strict</code></td><td><code>encode*</code> methods that have <code>_without_replacement</code> in their name (and treating the `Unmappable` result as fatal).</td></tr>
//! <tr><td><code>encoding::EncoderTrap::Replace</code></td><td>Can be implemented using <code>encode*</code> methods that have <code>_without_replacement</code> in their name.</td></tr>
//! <tr><td><code>encoding::EncoderTrap::Ignore</code></td><td>It is a bad idea to ignore errors due to security issues, but this could be implemented using <code>encode*</code> methods that have <code>_without_replacement</code> in their name.</td></tr>
//! <tr><td><code>encoding::EncoderTrap::NcrEscape</code></td><td><code>encode*</code> methods that <i>do not</i> have <code>_without_replacement</code> in their name.</td></tr>
//! <tr><td><code>encoding::EncoderTrap::Call(EncoderTrapFunc)</code></td><td>Can be implemented using <code>encode*</code> methods that have <code>_without_replacement</code> in their name.</td></tr>
//! </tbody>
//! </table>
//!
//! # Relationship with Windows Code Pages
//!
//! Despite the Web and browser focus, the encodings defined by the Encoding
//! Standard and implemented by this crate may be useful for decoding legacy
//! data that uses Windows code pages. The following table names the single-byte
//! encodings
//! that have a closely related Windows code page, the number of the closest
//! code page, a column indicating whether Windows maps unassigned code points
//! to the Unicode Private Use Area instead of U+FFFD and a remark number
//! indicating remarks in the list after the table.
//!
//! <table>
//! <thead>
//! <tr><th>Encoding</th><th>Code Page</th><th>PUA</th><th>Remarks</th></tr>
//! </thead>
//! <tbody>
//! <tr><td>Shift_JIS</td><td>932</td><td></td><td></td></tr>
//! <tr><td>GBK</td><td>936</td><td></td><td></td></tr>
//! <tr><td>EUC-KR</td><td>949</td><td></td><td></td></tr>
//! <tr><td>Big5</td><td>950</td><td></td><td></td></tr>
//! <tr><td>IBM866</td><td>866</td><td></td><td></td></tr>
//! <tr><td>windows-874</td><td>874</td><td>•</td><td></td></tr>
//! <tr><td>UTF-16LE</td><td>1200</td><td></td><td></td></tr>
//! <tr><td>UTF-16BE</td><td>1201</td><td></td><td></td></tr>
//! <tr><td>windows-1250</td><td>1250</td><td></td><td></td></tr>
//! <tr><td>windows-1251</td><td>1251</td><td></td><td></td></tr>
//! <tr><td>windows-1252</td><td>1252</td><td></td><td></td></tr>
//! <tr><td>windows-1253</td><td>1253</td><td>•</td><td></td></tr>
//! <tr><td>windows-1254</td><td>1254</td><td></td><td></td></tr>
//! <tr><td>windows-1255</td><td>1255</td><td>•</td><td></td></tr>
//! <tr><td>windows-1256</td><td>1256</td><td></td><td></td></tr>
//! <tr><td>windows-1257</td><td>1257</td><td>•</td><td></td></tr>
//! <tr><td>windows-1258</td><td>1258</td><td></td><td></td></tr>
//! <tr><td>macintosh</td><td>10000</td><td></td><td>1</td></tr>
//! <tr><td>x-mac-cyrillic</td><td>10017</td><td></td><td>2</td></tr>
//! <tr><td>KOI8-R</td><td>20866</td><td></td><td></td></tr>
//! <tr><td>EUC-JP</td><td>20932</td><td></td><td></td></tr>
//! <tr><td>KOI8-U</td><td>21866</td><td></td><td></td></tr>
//! <tr><td>ISO-8859-2</td><td>28592</td><td></td><td></td></tr>
//! <tr><td>ISO-8859-3</td><td>28593</td><td></td><td></td></tr>
//! <tr><td>ISO-8859-4</td><td>28594</td><td></td><td></td></tr>
//! <tr><td>ISO-8859-5</td><td>28595</td><td></td><td></td></tr>
//! <tr><td>ISO-8859-6</td><td>28596</td><td>•</td><td></td></tr>
//! <tr><td>ISO-8859-7</td><td>28597</td><td>•</td><td>3</td></tr>
//! <tr><td>ISO-8859-8</td><td>28598</td><td>•</td><td>4</td></tr>
//! <tr><td>ISO-8859-13</td><td>28603</td><td>•</td><td></td></tr>
//! <tr><td>ISO-8859-15</td><td>28605</td><td></td><td></td></tr>
//! <tr><td>ISO-8859-8-I</td><td>38598</td><td></td><td>5</td></tr>
//! <tr><td>ISO-2022-JP</td><td>50220</td><td></td><td></td></tr>
//! <tr><td>gb18030</td><td>54936</td><td></td><td></td></tr>
//! <tr><td>UTF-8</td><td>65001</td><td></td><td></td></tr>
//! </tbody>
//! </table>
//!
//! 1. Windows decodes 0xBD to U+2126 OHM SIGN instead of U+03A9 GREEK CAPITAL LETTER OMEGA.
//! 2. Windows decodes 0xFF to U+00A4 CURRENCY SIGN instead of U+20AC EURO SIGN.
//! 3. Windows decodes the currency signs at 0xA4 and 0xA5 as well as 0xAA,
//! which should be U+037A GREEK YPOGEGRAMMENI, to PUA code points. Windows
//! decodes 0xA1 to U+02BD MODIFIER LETTER REVERSED COMMA instead of U+2018
//! LEFT SINGLE QUOTATION MARK and 0xA2 to U+02BC MODIFIER LETTER APOSTROPHE
//! instead of U+2019 RIGHT SINGLE QUOTATION MARK.
//! 4. Windows decodes 0xAF to OVERLINE instead of MACRON and 0xFE and 0xFD to PUA instead
//! of LRM and RLM.
//! 5. Remarks from the previous item apply.
//!
//! The differences between this crate and Windows in the case of multibyte encodings
//! are not yet fully documented here. The lack of remarks above should not be taken
//! as indication of lack of differences.
//!
//! # Notable Differences from IANA Naming
//!
//! In some cases, the Encoding Standard specifies the popular unextended encoding
//! name where in IANA terms one of the other labels would be more precise considering
//! the extensions that the Encoding Standard has unified into the encoding.
//!
//! <table>
//! <thead>
//! <tr><th>Encoding</th><th>IANA</th></tr>
//! </thead>
//! <tbody>
//! <tr><td>Big5</td><td>Big5-HKSCS</td></tr>
//! <tr><td>EUC-KR</td><td>windows-949</td></tr>
//! <tr><td>Shift_JIS</td><td>windows-31j</td></tr>
//! <tr><td>x-mac-cyrillic</td><td>x-mac-ukrainian</td></tr>
//! </tbody>
//! </table>
//!
//! In other cases where the Encoding Standard unifies unextended and extended
//! variants of an encoding, the encoding gets the name of the extended
//! variant.
//!
//! <table>
//! <thead>
//! <tr><th>IANA</th><th>Unified into Encoding</th></tr>
//! </thead>
//! <tbody>
//! <tr><td>ISO-8859-1</td><td>windows-1252</td></tr>
//! <tr><td>ISO-8859-9</td><td>windows-1254</td></tr>
//! <tr><td>TIS-620</td><td>windows-874</td></tr>
//! </tbody>
//! </table>
//!
//! See the section [_UTF-16LE, UTF-16BE and Unicode Encoding Schemes_](#utf-16le-utf-16be-and-unicode-encoding-schemes)
//! for discussion about the UTF-16 family.
#![no_std]
#![cfg_attr(feature = "simd-accel", feature(core_intrinsics, portable_simd))]
#[cfg(feature = "alloc")]
#[cfg_attr(test, macro_use)]
extern crate alloc;
extern crate core;
#[macro_use]
extern crate cfg_if;
#[cfg(feature = "serde")]
extern crate serde;
#[cfg(all(test, feature = "serde"))]
extern crate bincode;
#[cfg(all(test, feature = "serde"))]
#[macro_use]
extern crate serde_derive;
#[cfg(all(test, feature = "serde"))]
extern crate serde_json;
#[macro_use]
mod macros;
#[cfg(all(
feature = "simd-accel",
any(
target_feature = "sse2",
all(target_endian = "little", target_arch = "aarch64"),
all(target_endian = "little", target_feature = "neon")
)
))]
mod simd_funcs;
#[cfg(all(test, feature = "alloc"))]
mod testing;
mod big5;
mod euc_jp;
mod euc_kr;
mod gb18030;
mod iso_2022_jp;
mod replacement;
mod shift_jis;
mod single_byte;
mod utf_16;
mod utf_8;
mod x_user_defined;
mod ascii;
mod data;
mod handles;
mod variant;
pub mod mem;
use crate::ascii::ascii_valid_up_to;
use crate::ascii::iso_2022_jp_ascii_valid_up_to;
use crate::utf_8::utf8_valid_up_to;
use crate::variant::*;
#[cfg(feature = "alloc")]
use alloc::borrow::Cow;
#[cfg(feature = "alloc")]
use alloc::string::String;
#[cfg(feature = "alloc")]
use alloc::vec::Vec;
use core::cmp::Ordering;
use core::hash::Hash;
use core::hash::Hasher;
#[cfg(feature = "serde")]
use serde::de::Visitor;
#[cfg(feature = "serde")]
use serde::{Deserialize, Deserializer, Serialize, Serializer};
/// This has to be the max length of an NCR instead of max
/// minus one, because we can't rely on getting the minus
/// one from the space reserved for the current unmappable,
/// because the ISO-2022-JP encoder can fill up that space
/// with a state transition escape.
const NCR_EXTRA: usize = 10; // 
// BEGIN GENERATED CODE. PLEASE DO NOT EDIT.
// Instead, please regenerate using generate-encoding-data.py
const LONGEST_LABEL_LENGTH: usize = 19; // cseucpkdfmtjapanese
/// The initializer for the [Big5](static.BIG5.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static BIG5_INIT: Encoding = Encoding {
name: "Big5",
variant: VariantEncoding::Big5,
};
/// The Big5 encoding.
///
/// This is Big5 with HKSCS with mappings to more recent Unicode assignments
/// instead of the Private Use Area code points that have been used historically.
/// It is believed to be able to decode existing Web content in a way that makes
/// sense.
///
/// To avoid form submissions generating data that Web servers don't understand,
/// the encoder doesn't use the HKSCS byte sequences that precede the unextended
/// Big5 in the lexical order.
///
///
/// This encoding is designed to be suited for decoding the Windows code page 950
/// and its HKSCS patched "951" variant such that the text makes sense, given
/// assignments that Unicode has made after those encodings used Private Use
/// Area characters.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static BIG5: &'static Encoding = &BIG5_INIT;
/// The initializer for the [EUC-JP](static.EUC_JP.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static EUC_JP_INIT: Encoding = Encoding {
name: "EUC-JP",
variant: VariantEncoding::EucJp,
};
/// The EUC-JP encoding.
///
/// This is the legacy Unix encoding for Japanese.
///
/// For compatibility with Web servers that don't expect three-byte sequences
/// in form submissions, the encoder doesn't generate three-byte sequences.
/// That is, the JIS X 0212 support is decode-only.
///
///
/// This encoding roughly matches the Windows code page 20932. There are error
/// handling differences and a handful of 2-byte sequences that decode differently.
/// Additionall, Windows doesn't support 3-byte sequences.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static EUC_JP: &'static Encoding = &EUC_JP_INIT;
/// The initializer for the [EUC-KR](static.EUC_KR.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static EUC_KR_INIT: Encoding = Encoding {
name: "EUC-KR",
variant: VariantEncoding::EucKr,
};
/// The EUC-KR encoding.
///
/// This is the Korean encoding for Windows. It extends the Unix legacy encoding
/// for Korean, based on KS X 1001 (which also formed the base of MacKorean on Mac OS
/// Classic), with all the characters from the Hangul Syllables block of Unicode.
///
///
/// This encoding matches the Windows code page 949, except Windows decodes byte 0x80
/// to U+0080 and some byte sequences that are error per the Encoding Standard to
/// the question mark or the Private Use Area.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static EUC_KR: &'static Encoding = &EUC_KR_INIT;
/// The initializer for the [GBK](static.GBK.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static GBK_INIT: Encoding = Encoding {
name: "GBK",
variant: VariantEncoding::Gbk,
};
/// The GBK encoding.
///
/// The decoder for this encoding is the same as the decoder for gb18030.
/// The encoder side of this encoding is GBK with Windows code page 936 euro
/// sign behavior. GBK extends GB2312-80 to cover the CJK Unified Ideographs
/// Unicode block as well as a handful of ideographs from the CJK Unified
/// Ideographs Extension A and CJK Compatibility Ideographs blocks.
///
/// Unlike e.g. in the case of ISO-8859-1 and windows-1252, GBK encoder wasn't
/// unified with the gb18030 encoder in the Encoding Standard out of concern
/// that servers that expect GBK form submissions might not be able to handle
/// the four-byte sequences.
///
/// [Index visualization for the two-byte sequences](https://encoding.spec.whatwg.org/gb18030.html),
/// [Visualization of BMP coverage of the two-byte index](https://encoding.spec.whatwg.org/gb18030-bmp.html)
///
/// The encoder of this encoding roughly matches the Windows code page 936.
/// The decoder side is a superset.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static GBK: &'static Encoding = &GBK_INIT;
/// The initializer for the [IBM866](static.IBM866.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static IBM866_INIT: Encoding = Encoding {
name: "IBM866",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.ibm866, 0x0440, 96, 16),
};
/// The IBM866 encoding.
///
/// This the most notable one of the DOS Cyrillic code pages. It has the same
/// box drawing characters as code page 437, so it can be used for decoding
/// DOS-era ASCII + box drawing data.
///
///
/// This encoding matches the Windows code page 866.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static IBM866: &'static Encoding = &IBM866_INIT;
/// The initializer for the [ISO-2022-JP](static.ISO_2022_JP.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_2022_JP_INIT: Encoding = Encoding {
name: "ISO-2022-JP",
variant: VariantEncoding::Iso2022Jp,
};
/// The ISO-2022-JP encoding.
///
/// This the primary pre-UTF-8 encoding for Japanese email. It uses the ASCII
/// byte range to encode non-Basic Latin characters. It's the only encoding
/// supported by this crate whose encoder is stateful.
///
///
/// This encoding roughly matches the Windows code page 50220. Notably, Windows
/// uses U+30FB in place of the REPLACEMENT CHARACTER and otherwise differs in
/// error handling.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_2022_JP: &'static Encoding = &ISO_2022_JP_INIT;
/// The initializer for the [ISO-8859-10](static.ISO_8859_10.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_10_INIT: Encoding = Encoding {
name: "ISO-8859-10",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_10, 0x00DA, 90, 6),
};
/// The ISO-8859-10 encoding.
///
/// This is the Nordic part of the ISO/IEC 8859 encoding family. This encoding
/// is also known as Latin 6.
///
///
/// The Windows code page number for this encoding is 28600, but kernel32.dll
/// does not support this encoding.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_10: &'static Encoding = &ISO_8859_10_INIT;
/// The initializer for the [ISO-8859-13](static.ISO_8859_13.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_13_INIT: Encoding = Encoding {
name: "ISO-8859-13",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_13, 0x00DF, 95, 1),
};
/// The ISO-8859-13 encoding.
///
/// This is the Baltic part of the ISO/IEC 8859 encoding family. This encoding
/// is also known as Latin 7.
///
///
/// This encoding matches the Windows code page 28603, except Windows decodes
/// unassigned code points to the Private Use Area of Unicode.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_13: &'static Encoding = &ISO_8859_13_INIT;
/// The initializer for the [ISO-8859-14](static.ISO_8859_14.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_14_INIT: Encoding = Encoding {
name: "ISO-8859-14",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_14, 0x00DF, 95, 17),
};
/// The ISO-8859-14 encoding.
///
/// This is the Celtic part of the ISO/IEC 8859 encoding family. This encoding
/// is also known as Latin 8.
///
///
/// The Windows code page number for this encoding is 28604, but kernel32.dll
/// does not support this encoding.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_14: &'static Encoding = &ISO_8859_14_INIT;
/// The initializer for the [ISO-8859-15](static.ISO_8859_15.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_15_INIT: Encoding = Encoding {
name: "ISO-8859-15",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_15, 0x00BF, 63, 65),
};
/// The ISO-8859-15 encoding.
///
/// This is the revised Western European part of the ISO/IEC 8859 encoding
/// family. This encoding is also known as Latin 9.
///
///
/// This encoding matches the Windows code page 28605.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_15: &'static Encoding = &ISO_8859_15_INIT;
/// The initializer for the [ISO-8859-16](static.ISO_8859_16.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_16_INIT: Encoding = Encoding {
name: "ISO-8859-16",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_16, 0x00DF, 95, 4),
};
/// The ISO-8859-16 encoding.
///
/// This is the South-Eastern European part of the ISO/IEC 8859 encoding
/// family. This encoding is also known as Latin 10.
///
///
/// The Windows code page number for this encoding is 28606, but kernel32.dll
/// does not support this encoding.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_16: &'static Encoding = &ISO_8859_16_INIT;
/// The initializer for the [ISO-8859-2](static.ISO_8859_2.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_2_INIT: Encoding = Encoding {
name: "ISO-8859-2",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_2, 0x00DF, 95, 1),
};
/// The ISO-8859-2 encoding.
///
/// This is the Central European part of the ISO/IEC 8859 encoding family. This encoding is also known as Latin 2.
///
///
/// This encoding matches the Windows code page 28592.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_2: &'static Encoding = &ISO_8859_2_INIT;
/// The initializer for the [ISO-8859-3](static.ISO_8859_3.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_3_INIT: Encoding = Encoding {
name: "ISO-8859-3",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_3, 0x00DF, 95, 4),
};
/// The ISO-8859-3 encoding.
///
/// This is the South European part of the ISO/IEC 8859 encoding family. This encoding is also known as Latin 3.
///
///
/// This encoding matches the Windows code page 28593.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_3: &'static Encoding = &ISO_8859_3_INIT;
/// The initializer for the [ISO-8859-4](static.ISO_8859_4.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_4_INIT: Encoding = Encoding {
name: "ISO-8859-4",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_4, 0x00DF, 95, 1),
};
/// The ISO-8859-4 encoding.
///
/// This is the North European part of the ISO/IEC 8859 encoding family. This encoding is also known as Latin 4.
///
///
/// This encoding matches the Windows code page 28594.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_4: &'static Encoding = &ISO_8859_4_INIT;
/// The initializer for the [ISO-8859-5](static.ISO_8859_5.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_5_INIT: Encoding = Encoding {
name: "ISO-8859-5",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_5, 0x040E, 46, 66),
};
/// The ISO-8859-5 encoding.
///
/// This is the Cyrillic part of the ISO/IEC 8859 encoding family.
///
///
/// This encoding matches the Windows code page 28595.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_5: &'static Encoding = &ISO_8859_5_INIT;
/// The initializer for the [ISO-8859-6](static.ISO_8859_6.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_6_INIT: Encoding = Encoding {
name: "ISO-8859-6",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_6, 0x0621, 65, 26),
};
/// The ISO-8859-6 encoding.
///
/// This is the Arabic part of the ISO/IEC 8859 encoding family.
///
///
/// This encoding matches the Windows code page 28596, except Windows decodes
/// unassigned code points to the Private Use Area of Unicode.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_6: &'static Encoding = &ISO_8859_6_INIT;
/// The initializer for the [ISO-8859-7](static.ISO_8859_7.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_7_INIT: Encoding = Encoding {
name: "ISO-8859-7",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_7, 0x03A3, 83, 44),
};
/// The ISO-8859-7 encoding.
///
/// This is the Greek part of the ISO/IEC 8859 encoding family.
///
///
/// This encoding roughly matches the Windows code page 28597. Windows decodes
/// unassigned code points, the currency signs at 0xA4 and 0xA5 as well as
/// 0xAA, which should be U+037A GREEK YPOGEGRAMMENI, to the Private Use Area
/// of Unicode. Windows decodes 0xA1 to U+02BD MODIFIER LETTER REVERSED COMMA
/// instead of U+2018 LEFT SINGLE QUOTATION MARK and 0xA2 to U+02BC MODIFIER
/// LETTER APOSTROPHE instead of U+2019 RIGHT SINGLE QUOTATION MARK.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_7: &'static Encoding = &ISO_8859_7_INIT;
/// The initializer for the [ISO-8859-8](static.ISO_8859_8.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_8_INIT: Encoding = Encoding {
name: "ISO-8859-8",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_8, 0x05D0, 96, 27),
};
/// The ISO-8859-8 encoding.
///
/// This is the Hebrew part of the ISO/IEC 8859 encoding family in visual order.
///
///
/// This encoding roughly matches the Windows code page 28598. Windows decodes
/// 0xAF to OVERLINE instead of MACRON and 0xFE and 0xFD to the Private Use
/// Area instead of LRM and RLM. Windows decodes unassigned code points to
/// the private use area.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_8: &'static Encoding = &ISO_8859_8_INIT;
/// The initializer for the [ISO-8859-8-I](static.ISO_8859_8_I.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static ISO_8859_8_I_INIT: Encoding = Encoding {
name: "ISO-8859-8-I",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.iso_8859_8, 0x05D0, 96, 27),
};
/// The ISO-8859-8-I encoding.
///
/// This is the Hebrew part of the ISO/IEC 8859 encoding family in logical order.
///
///
/// This encoding roughly matches the Windows code page 38598. Windows decodes
/// 0xAF to OVERLINE instead of MACRON and 0xFE and 0xFD to the Private Use
/// Area instead of LRM and RLM. Windows decodes unassigned code points to
/// the private use area.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static ISO_8859_8_I: &'static Encoding = &ISO_8859_8_I_INIT;
/// The initializer for the [KOI8-R](static.KOI8_R.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static KOI8_R_INIT: Encoding = Encoding {
name: "KOI8-R",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.koi8_r, 0x044E, 64, 1),
};
/// The KOI8-R encoding.
///
///
///
/// This encoding matches the Windows code page 20866.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static KOI8_R: &'static Encoding = &KOI8_R_INIT;
/// The initializer for the [KOI8-U](static.KOI8_U.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static KOI8_U_INIT: Encoding = Encoding {
name: "KOI8-U",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.koi8_u, 0x044E, 64, 1),
};
/// The KOI8-U encoding.
///
/// This is an encoding for Ukrainian adapted from KOI8-R.
///
///
/// This encoding matches the Windows code page 21866.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static KOI8_U: &'static Encoding = &KOI8_U_INIT;
/// The initializer for the [Shift_JIS](static.SHIFT_JIS.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static SHIFT_JIS_INIT: Encoding = Encoding {
name: "Shift_JIS",
variant: VariantEncoding::ShiftJis,
};
/// The Shift_JIS encoding.
///
/// This is the Japanese encoding for Windows.
///
///
/// This encoding matches the Windows code page 932, except Windows decodes some byte
/// sequences that are error per the Encoding Standard to the question mark or the
/// Private Use Area and generally uses U+30FB in place of the REPLACEMENT CHARACTER.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static SHIFT_JIS: &'static Encoding = &SHIFT_JIS_INIT;
/// The initializer for the [UTF-16BE](static.UTF_16BE.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static UTF_16BE_INIT: Encoding = Encoding {
name: "UTF-16BE",
variant: VariantEncoding::Utf16Be,
};
/// The UTF-16BE encoding.
///
/// This decode-only encoding uses 16-bit code units due to Unicode originally
/// having been designed as a 16-bit reportoire. In the absence of a byte order
/// mark the big endian byte order is assumed.
///
/// There is no corresponding encoder in this crate or in the Encoding
/// Standard. The output encoding of this encoding is UTF-8.
///
/// This encoding matches the Windows code page 1201.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static UTF_16BE: &'static Encoding = &UTF_16BE_INIT;
/// The initializer for the [UTF-16LE](static.UTF_16LE.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static UTF_16LE_INIT: Encoding = Encoding {
name: "UTF-16LE",
variant: VariantEncoding::Utf16Le,
};
/// The UTF-16LE encoding.
///
/// This decode-only encoding uses 16-bit code units due to Unicode originally
/// having been designed as a 16-bit reportoire. In the absence of a byte order
/// mark the little endian byte order is assumed.
///
/// There is no corresponding encoder in this crate or in the Encoding
/// Standard. The output encoding of this encoding is UTF-8.
///
/// This encoding matches the Windows code page 1200.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static UTF_16LE: &'static Encoding = &UTF_16LE_INIT;
/// The initializer for the [UTF-8](static.UTF_8.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static UTF_8_INIT: Encoding = Encoding {
name: "UTF-8",
variant: VariantEncoding::Utf8,
};
/// The UTF-8 encoding.
///
/// This is the encoding that should be used for all new development it can
/// represent all of Unicode.
///
/// This encoding matches the Windows code page 65001, except Windows differs
/// in the number of errors generated for some erroneous byte sequences.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static UTF_8: &'static Encoding = &UTF_8_INIT;
/// The initializer for the [gb18030](static.GB18030.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static GB18030_INIT: Encoding = Encoding {
name: "gb18030",
variant: VariantEncoding::Gb18030,
};
/// The gb18030 encoding.
///
/// This encoding matches GB18030-2005 except the two-byte sequence 0xA3 0xA0
/// maps to U+3000 for compatibility with existing Web content. As a result,
/// this encoding can represent all of Unicode except for the private-use
/// character U+E5E5.
///
/// [Index visualization for the two-byte sequences](https://encoding.spec.whatwg.org/gb18030.html),
/// [Visualization of BMP coverage of the two-byte index](https://encoding.spec.whatwg.org/gb18030-bmp.html)
///
/// This encoding matches the Windows code page 54936.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static GB18030: &'static Encoding = &GB18030_INIT;
/// The initializer for the [macintosh](static.MACINTOSH.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static MACINTOSH_INIT: Encoding = Encoding {
name: "macintosh",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.macintosh, 0x00CD, 106, 3),
};
/// The macintosh encoding.
///
/// This is the MacRoman encoding from Mac OS Classic.
///
///
/// This encoding matches the Windows code page 10000, except Windows decodes
/// 0xBD to U+2126 OHM SIGN instead of U+03A9 GREEK CAPITAL LETTER OMEGA.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static MACINTOSH: &'static Encoding = &MACINTOSH_INIT;
/// The initializer for the [replacement](static.REPLACEMENT.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static REPLACEMENT_INIT: Encoding = Encoding {
name: "replacement",
variant: VariantEncoding::Replacement,
};
/// The replacement encoding.
///
/// This decode-only encoding decodes all non-zero-length streams to a single
/// REPLACEMENT CHARACTER. Its purpose is to avoid the use of an
/// ASCII-compatible fallback encoding (typically windows-1252) for some
/// encodings that are no longer supported by the Web Platform and that
/// would be dangerous to treat as ASCII-compatible.
///
/// There is no corresponding encoder. The output encoding of this encoding
/// is UTF-8.
///
/// This encoding does not have a Windows code page number.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static REPLACEMENT: &'static Encoding = &REPLACEMENT_INIT;
/// The initializer for the [windows-1250](static.WINDOWS_1250.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1250_INIT: Encoding = Encoding {
name: "windows-1250",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1250, 0x00DC, 92, 2),
};
/// The windows-1250 encoding.
///
/// This is the Central European encoding for Windows.
///
///
/// This encoding matches the Windows code page 1250.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1250: &'static Encoding = &WINDOWS_1250_INIT;
/// The initializer for the [windows-1251](static.WINDOWS_1251.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1251_INIT: Encoding = Encoding {
name: "windows-1251",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1251, 0x0410, 64, 64),
};
/// The windows-1251 encoding.
///
/// This is the Cyrillic encoding for Windows.
///
///
/// This encoding matches the Windows code page 1251.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1251: &'static Encoding = &WINDOWS_1251_INIT;
/// The initializer for the [windows-1252](static.WINDOWS_1252.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1252_INIT: Encoding = Encoding {
name: "windows-1252",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1252, 0x00A0, 32, 96),
};
/// The windows-1252 encoding.
///
/// This is the Western encoding for Windows. It is an extension of ISO-8859-1,
/// which is known as Latin 1.
///
///
/// This encoding matches the Windows code page 1252.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1252: &'static Encoding = &WINDOWS_1252_INIT;
/// The initializer for the [windows-1253](static.WINDOWS_1253.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1253_INIT: Encoding = Encoding {
name: "windows-1253",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1253, 0x03A3, 83, 44),
};
/// The windows-1253 encoding.
///
/// This is the Greek encoding for Windows. It is mostly an extension of
/// ISO-8859-7, but U+0386 is mapped to a different byte.
///
///
/// This encoding matches the Windows code page 1253, except Windows decodes
/// unassigned code points to the Private Use Area of Unicode.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1253: &'static Encoding = &WINDOWS_1253_INIT;
/// The initializer for the [windows-1254](static.WINDOWS_1254.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1254_INIT: Encoding = Encoding {
name: "windows-1254",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1254, 0x00DF, 95, 17),
};
/// The windows-1254 encoding.
///
/// This is the Turkish encoding for Windows. It is an extension of ISO-8859-9,
/// which is known as Latin 5.
///
///
/// This encoding matches the Windows code page 1254.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1254: &'static Encoding = &WINDOWS_1254_INIT;
/// The initializer for the [windows-1255](static.WINDOWS_1255.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1255_INIT: Encoding = Encoding {
name: "windows-1255",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1255, 0x05D0, 96, 27),
};
/// The windows-1255 encoding.
///
/// This is the Hebrew encoding for Windows. It is an extension of ISO-8859-8-I,
/// except for a currency sign swap.
///
///
/// This encoding matches the Windows code page 1255, except Windows decodes
/// unassigned code points to the Private Use Area of Unicode.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1255: &'static Encoding = &WINDOWS_1255_INIT;
/// The initializer for the [windows-1256](static.WINDOWS_1256.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1256_INIT: Encoding = Encoding {
name: "windows-1256",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1256, 0x0621, 65, 22),
};
/// The windows-1256 encoding.
///
/// This is the Arabic encoding for Windows.
///
///
/// This encoding matches the Windows code page 1256.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1256: &'static Encoding = &WINDOWS_1256_INIT;
/// The initializer for the [windows-1257](static.WINDOWS_1257.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1257_INIT: Encoding = Encoding {
name: "windows-1257",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1257, 0x00DF, 95, 1),
};
/// The windows-1257 encoding.
///
/// This is the Baltic encoding for Windows.
///
///
/// This encoding matches the Windows code page 1257, except Windows decodes
/// unassigned code points to the Private Use Area of Unicode.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1257: &'static Encoding = &WINDOWS_1257_INIT;
/// The initializer for the [windows-1258](static.WINDOWS_1258.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_1258_INIT: Encoding = Encoding {
name: "windows-1258",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_1258, 0x00DF, 95, 4),
};
/// The windows-1258 encoding.
///
/// This is the Vietnamese encoding for Windows.
///
///
/// This encoding matches the Windows code page 1258 when used in the
/// non-normalizing mode. Unlike with the other single-byte encodings, the
/// result of decoding is not necessarily in Normalization Form C. On the
/// other hand, input in the Normalization Form C is not encoded without
/// replacement. In general, it's a bad idea to encode to encodings other
/// than UTF-8, but this encoding is especially hazardous to encode to.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_1258: &'static Encoding = &WINDOWS_1258_INIT;
/// The initializer for the [windows-874](static.WINDOWS_874.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static WINDOWS_874_INIT: Encoding = Encoding {
name: "windows-874",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.windows_874, 0x0E01, 33, 58),
};
/// The windows-874 encoding.
///
/// This is the Thai encoding for Windows. It is an extension of TIS-620 / ISO-8859-11.
///
///
/// This encoding matches the Windows code page 874, except Windows decodes
/// unassigned code points to the Private Use Area of Unicode.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static WINDOWS_874: &'static Encoding = &WINDOWS_874_INIT;
/// The initializer for the [x-mac-cyrillic](static.X_MAC_CYRILLIC.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static X_MAC_CYRILLIC_INIT: Encoding = Encoding {
name: "x-mac-cyrillic",
variant: VariantEncoding::SingleByte(&data::SINGLE_BYTE_DATA.x_mac_cyrillic, 0x0430, 96, 31),
};
/// The x-mac-cyrillic encoding.
///
/// This is the MacUkrainian encoding from Mac OS Classic.
///
///
/// This encoding matches the Windows code page 10017.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static X_MAC_CYRILLIC: &'static Encoding = &X_MAC_CYRILLIC_INIT;
/// The initializer for the [x-user-defined](static.X_USER_DEFINED.html) encoding.
///
/// For use only for taking the address of this form when
/// Rust prohibits the use of the non-`_INIT` form directly,
/// such as in initializers of other `static`s. If in doubt,
/// use the corresponding non-`_INIT` reference-typed `static`.
///
/// This part of the public API will go away if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate or if Rust starts allowing static arrays
/// to be initialized with `pub static FOO: &'static Encoding`
/// items.
pub static X_USER_DEFINED_INIT: Encoding = Encoding {
name: "x-user-defined",
variant: VariantEncoding::UserDefined,
};
/// The x-user-defined encoding.
///
/// This encoding offsets the non-ASCII bytes by `0xF700` thereby decoding
/// them to the Private Use Area of Unicode. It was used for loading binary
/// data into a JavaScript string using `XMLHttpRequest` before XHR supported
/// the `"arraybuffer"` response type.
///
/// This encoding does not have a Windows code page number.
///
/// This will change from `static` to `const` if Rust changes
/// to make the referent of `pub const FOO: &'static Encoding`
/// unique cross-crate, so don't take the address of this
/// `static`.
pub static X_USER_DEFINED: &'static Encoding = &X_USER_DEFINED_INIT;
static LABELS_SORTED: [&'static str; 228] = [
"l1",
"l2",
"l3",
"l4",
"l5",
"l6",
"l9",
"866",
"mac",
"koi",
"gbk",
"big5",
"utf8",
"koi8",
"sjis",
"ucs-2",
"ms932",
"cp866",
"utf-8",
"cp819",
"ascii",
"x-gbk",
"greek",
"cp1250",
"cp1251",
"latin1",
"gb2312",
"cp1252",
"latin2",
"cp1253",
"latin3",
"cp1254",
"latin4",
"cp1255",
"csbig5",
"latin5",
"utf-16",
"cp1256",
"ibm866",
"latin6",
"cp1257",
"cp1258",
"greek8",
"ibm819",
"arabic",
"visual",
"korean",
"euc-jp",
"koi8-r",
"koi8_r",
"euc-kr",
"x-sjis",
"koi8-u",
"hebrew",
"tis-620",
"gb18030",
"ksc5601",
"gb_2312",
"dos-874",
"cn-big5",
"unicode",
"chinese",
"logical",
"cskoi8r",
"cseuckr",
"koi8-ru",
"x-cp1250",
"ksc_5601",
"x-cp1251",
"iso88591",
"csgb2312",
"x-cp1252",
"iso88592",
"x-cp1253",
"iso88593",
"ecma-114",
"x-cp1254",
"iso88594",
"x-cp1255",
"iso88595",
"x-x-big5",
"x-cp1256",
"csibm866",
"iso88596",
"x-cp1257",
"iso88597",
"asmo-708",
"ecma-118",
"elot_928",
"x-cp1258",
"iso88598",
"iso88599",
"cyrillic",
"utf-16be",
"utf-16le",
"us-ascii",
"ms_kanji",
"x-euc-jp",
"iso885910",
"iso8859-1",
"iso885911",
"iso8859-2",
"iso8859-3",
"iso885913",
"iso8859-4",
"iso885914",
"iso8859-5",
"iso885915",
"iso8859-6",
"iso8859-7",
"iso8859-8",
"iso-ir-58",
"iso8859-9",
"csunicode",
"macintosh",
"shift-jis",
"shift_jis",
"iso-ir-100",
"iso8859-10",
"iso-ir-110",
"gb_2312-80",
"iso-8859-1",
"iso_8859-1",
"iso-ir-101",
"iso8859-11",
"iso-8859-2",
"iso_8859-2",
"hz-gb-2312",
"iso-8859-3",
"iso_8859-3",
"iso8859-13",
"iso-8859-4",
"iso_8859-4",
"iso8859-14",
"iso-ir-144",
"iso-8859-5",
"iso_8859-5",
"iso8859-15",
"iso-8859-6",
"iso_8859-6",
"iso-ir-126",
"iso-8859-7",
"iso_8859-7",
"iso-ir-127",
"iso-ir-157",
"iso-8859-8",
"iso_8859-8",
"iso-ir-138",
"iso-ir-148",
"iso-8859-9",
"iso_8859-9",
"iso-ir-109",
"iso-ir-149",
"big5-hkscs",
"csshiftjis",
"iso-8859-10",
"iso-8859-11",
"csisolatin1",
"csisolatin2",
"iso-8859-13",
"csisolatin3",
"iso-8859-14",
"windows-874",
"csisolatin4",
"iso-8859-15",
"iso_8859-15",
"csisolatin5",
"iso-8859-16",
"csisolatin6",
"windows-949",
"csisolatin9",
"csiso88596e",
"csiso88598e",
"unicodefffe",
"unicodefeff",
"csmacintosh",
"csiso88596i",
"csiso88598i",
"windows-31j",
"x-mac-roman",
"iso-2022-cn",
"iso-2022-jp",
"csiso2022jp",
"iso-2022-kr",
"csiso2022kr",
"replacement",
"windows-1250",
"windows-1251",
"windows-1252",
"windows-1253",
"windows-1254",
"windows-1255",
"windows-1256",
"windows-1257",
"windows-1258",
"iso-8859-6-e",
"iso-8859-8-e",
"iso-8859-6-i",
"iso-8859-8-i",
"sun_eu_greek",
"csksc56011987",
"unicode20utf8",
"unicode11utf8",
"ks_c_5601-1987",
"ansi_x3.4-1968",
"ks_c_5601-1989",
"x-mac-cyrillic",
"x-user-defined",
"csiso58gb231280",
"iso-10646-ucs-2",
"iso_8859-1:1987",
"iso_8859-2:1987",
"iso_8859-6:1987",
"iso_8859-7:1987",
"iso_8859-3:1988",
"iso_8859-4:1988",
"iso_8859-5:1988",
"iso_8859-8:1988",
"x-unicode20utf8",
"iso_8859-9:1989",
"csisolatingreek",
"x-mac-ukrainian",
"iso-2022-cn-ext",
"csisolatinarabic",
"csisolatinhebrew",
"unicode-1-1-utf-8",
"csisolatincyrillic",
"cseucpkdfmtjapanese",
];
static ENCODINGS_IN_LABEL_SORT: [&'static Encoding; 228] = [
&WINDOWS_1252_INIT,
&ISO_8859_2_INIT,
&ISO_8859_3_INIT,
&ISO_8859_4_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_10_INIT,
&ISO_8859_15_INIT,
&IBM866_INIT,
&MACINTOSH_INIT,
&KOI8_R_INIT,
&GBK_INIT,
&BIG5_INIT,
&UTF_8_INIT,
&KOI8_R_INIT,
&SHIFT_JIS_INIT,
&UTF_16LE_INIT,
&SHIFT_JIS_INIT,
&IBM866_INIT,
&UTF_8_INIT,
&WINDOWS_1252_INIT,
&WINDOWS_1252_INIT,
&GBK_INIT,
&ISO_8859_7_INIT,
&WINDOWS_1250_INIT,
&WINDOWS_1251_INIT,
&WINDOWS_1252_INIT,
&GBK_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_2_INIT,
&WINDOWS_1253_INIT,
&ISO_8859_3_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_4_INIT,
&WINDOWS_1255_INIT,
&BIG5_INIT,
&WINDOWS_1254_INIT,
&UTF_16LE_INIT,
&WINDOWS_1256_INIT,
&IBM866_INIT,
&ISO_8859_10_INIT,
&WINDOWS_1257_INIT,
&WINDOWS_1258_INIT,
&ISO_8859_7_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_6_INIT,
&ISO_8859_8_INIT,
&EUC_KR_INIT,
&EUC_JP_INIT,
&KOI8_R_INIT,
&KOI8_R_INIT,
&EUC_KR_INIT,
&SHIFT_JIS_INIT,
&KOI8_U_INIT,
&ISO_8859_8_INIT,
&WINDOWS_874_INIT,
&GB18030_INIT,
&EUC_KR_INIT,
&GBK_INIT,
&WINDOWS_874_INIT,
&BIG5_INIT,
&UTF_16LE_INIT,
&GBK_INIT,
&ISO_8859_8_I_INIT,
&KOI8_R_INIT,
&EUC_KR_INIT,
&KOI8_U_INIT,
&WINDOWS_1250_INIT,
&EUC_KR_INIT,
&WINDOWS_1251_INIT,
&WINDOWS_1252_INIT,
&GBK_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_2_INIT,
&WINDOWS_1253_INIT,
&ISO_8859_3_INIT,
&ISO_8859_6_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_4_INIT,
&WINDOWS_1255_INIT,
&ISO_8859_5_INIT,
&BIG5_INIT,
&WINDOWS_1256_INIT,
&IBM866_INIT,
&ISO_8859_6_INIT,
&WINDOWS_1257_INIT,
&ISO_8859_7_INIT,
&ISO_8859_6_INIT,
&ISO_8859_7_INIT,
&ISO_8859_7_INIT,
&WINDOWS_1258_INIT,
&ISO_8859_8_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_5_INIT,
&UTF_16BE_INIT,
&UTF_16LE_INIT,
&WINDOWS_1252_INIT,
&SHIFT_JIS_INIT,
&EUC_JP_INIT,
&ISO_8859_10_INIT,
&WINDOWS_1252_INIT,
&WINDOWS_874_INIT,
&ISO_8859_2_INIT,
&ISO_8859_3_INIT,
&ISO_8859_13_INIT,
&ISO_8859_4_INIT,
&ISO_8859_14_INIT,
&ISO_8859_5_INIT,
&ISO_8859_15_INIT,
&ISO_8859_6_INIT,
&ISO_8859_7_INIT,
&ISO_8859_8_INIT,
&GBK_INIT,
&WINDOWS_1254_INIT,
&UTF_16LE_INIT,
&MACINTOSH_INIT,
&SHIFT_JIS_INIT,
&SHIFT_JIS_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_10_INIT,
&ISO_8859_4_INIT,
&GBK_INIT,
&WINDOWS_1252_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_2_INIT,
&WINDOWS_874_INIT,
&ISO_8859_2_INIT,
&ISO_8859_2_INIT,
&REPLACEMENT_INIT,
&ISO_8859_3_INIT,
&ISO_8859_3_INIT,
&ISO_8859_13_INIT,
&ISO_8859_4_INIT,
&ISO_8859_4_INIT,
&ISO_8859_14_INIT,
&ISO_8859_5_INIT,
&ISO_8859_5_INIT,
&ISO_8859_5_INIT,
&ISO_8859_15_INIT,
&ISO_8859_6_INIT,
&ISO_8859_6_INIT,
&ISO_8859_7_INIT,
&ISO_8859_7_INIT,
&ISO_8859_7_INIT,
&ISO_8859_6_INIT,
&ISO_8859_10_INIT,
&ISO_8859_8_INIT,
&ISO_8859_8_INIT,
&ISO_8859_8_INIT,
&WINDOWS_1254_INIT,
&WINDOWS_1254_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_3_INIT,
&EUC_KR_INIT,
&BIG5_INIT,
&SHIFT_JIS_INIT,
&ISO_8859_10_INIT,
&WINDOWS_874_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_2_INIT,
&ISO_8859_13_INIT,
&ISO_8859_3_INIT,
&ISO_8859_14_INIT,
&WINDOWS_874_INIT,
&ISO_8859_4_INIT,
&ISO_8859_15_INIT,
&ISO_8859_15_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_16_INIT,
&ISO_8859_10_INIT,
&EUC_KR_INIT,
&ISO_8859_15_INIT,
&ISO_8859_6_INIT,
&ISO_8859_8_INIT,
&UTF_16BE_INIT,
&UTF_16LE_INIT,
&MACINTOSH_INIT,
&ISO_8859_6_INIT,
&ISO_8859_8_I_INIT,
&SHIFT_JIS_INIT,
&MACINTOSH_INIT,
&REPLACEMENT_INIT,
&ISO_2022_JP_INIT,
&ISO_2022_JP_INIT,
&REPLACEMENT_INIT,
&REPLACEMENT_INIT,
&REPLACEMENT_INIT,
&WINDOWS_1250_INIT,
&WINDOWS_1251_INIT,
&WINDOWS_1252_INIT,
&WINDOWS_1253_INIT,
&WINDOWS_1254_INIT,
&WINDOWS_1255_INIT,
&WINDOWS_1256_INIT,
&WINDOWS_1257_INIT,
&WINDOWS_1258_INIT,
&ISO_8859_6_INIT,
&ISO_8859_8_INIT,
&ISO_8859_6_INIT,
&ISO_8859_8_I_INIT,
&ISO_8859_7_INIT,
&EUC_KR_INIT,
&UTF_8_INIT,
&UTF_8_INIT,
&EUC_KR_INIT,
&WINDOWS_1252_INIT,
&EUC_KR_INIT,
&X_MAC_CYRILLIC_INIT,
&X_USER_DEFINED_INIT,
&GBK_INIT,
&UTF_16LE_INIT,
&WINDOWS_1252_INIT,
&ISO_8859_2_INIT,
&ISO_8859_6_INIT,
&ISO_8859_7_INIT,
&ISO_8859_3_INIT,
&ISO_8859_4_INIT,
&ISO_8859_5_INIT,
&ISO_8859_8_INIT,
&UTF_8_INIT,
&WINDOWS_1254_INIT,
&ISO_8859_7_INIT,
&X_MAC_CYRILLIC_INIT,
&REPLACEMENT_INIT,
&ISO_8859_6_INIT,
&ISO_8859_8_INIT,
&UTF_8_INIT,
&ISO_8859_5_INIT,
&EUC_JP_INIT,
];
// END GENERATED CODE
/// An encoding as defined in the [Encoding Standard][1].
///
/// An _encoding_ defines a mapping from a `u8` sequence to a `char` sequence
/// and, in most cases, vice versa. Each encoding has a name, an output
/// encoding, and one or more labels.
///
/// _Labels_ are ASCII-case-insensitive strings that are used to identify an
/// encoding in formats and protocols. The _name_ of the encoding is the
/// preferred label in the case appropriate for returning from the
/// [`characterSet`][2] property of the `Document` DOM interface.
///
/// The _output encoding_ is the encoding used for form submission and URL
/// parsing on Web pages in the encoding. This is UTF-8 for the replacement,
/// UTF-16LE and UTF-16BE encodings and the encoding itself for other
/// encodings.
///
///
/// # Streaming vs. Non-Streaming
///
/// When you have the entire input in a single buffer, you can use the
/// methods [`decode()`][3], [`decode_with_bom_removal()`][3],
/// [`decode_without_bom_handling()`][5],
/// [`decode_without_bom_handling_and_without_replacement()`][6] and
/// [`encode()`][7]. (These methods are available to Rust callers only and are
/// not available in the C API.) Unlike the rest of the API available to Rust,
/// these methods perform heap allocations. You should the `Decoder` and
/// `Encoder` objects when your input is split into multiple buffers or when
/// you want to control the allocation of the output buffers.
///
/// [3]: #method.decode
/// [4]: #method.decode_with_bom_removal
/// [5]: #method.decode_without_bom_handling
/// [6]: #method.decode_without_bom_handling_and_without_replacement
/// [7]: #method.encode
///
/// # Instances
///
/// All instances of `Encoding` are statically allocated and have the `'static`
/// lifetime. There is precisely one unique `Encoding` instance for each
/// encoding defined in the Encoding Standard.
///
/// To obtain a reference to a particular encoding whose identity you know at
/// compile time, use a `static` that refers to encoding. There is a `static`
/// for each encoding. The `static`s are named in all caps with hyphens
/// replaced with underscores (and in C/C++ have `_ENCODING` appended to the
/// name). For example, if you know at compile time that you will want to
/// decode using the UTF-8 encoding, use the `UTF_8` `static` (`UTF_8_ENCODING`
/// in C/C++).
///
/// Additionally, there are non-reference-typed forms ending with `_INIT` to
/// work around the problem that `static`s of the type `&'static Encoding`
/// cannot be used to initialize items of an array whose type is
/// `[&'static Encoding; N]`.
///
/// If you don't know what encoding you need at compile time and need to
/// dynamically get an encoding by label, use
/// <code>Encoding::<a href="#method.for_label">for_label</a>(<var>label</var>)</code>.
///
/// Instances of `Encoding` can be compared with `==` (in both Rust and in
/// C/C++).
pub struct Encoding {
name: &'static str,
variant: VariantEncoding,
}
impl Encoding {
/// Implements the
/// algorithm.
///
/// If, after ASCII-lowercasing and removing leading and trailing
/// whitespace, the argument matches a label defined in the Encoding
/// Standard, `Some(&'static Encoding)` representing the corresponding
/// encoding is returned. If there is no match, `None` is returned.
///
/// This is the right method to use if the action upon the method returning
/// `None` is to use a fallback encoding (e.g. `WINDOWS_1252`) instead.
/// When the action upon the method returning `None` is not to proceed with
/// a fallback but to refuse processing, `for_label_no_replacement()` is more
/// appropriate.
///
/// The argument is of type `&[u8]` instead of `&str` to save callers
/// that are extracting the label from a non-UTF-8 protocol the trouble
/// of conversion to UTF-8. (If you have a `&str`, just call `.as_bytes()`
/// on it.)
///
/// Available via the C wrapper.
///
/// # Example
/// ```
/// use encoding_rs::Encoding;
///
/// assert_eq!(Some(encoding_rs::UTF_8), Encoding::for_label(b"utf-8"));
/// assert_eq!(Some(encoding_rs::UTF_8), Encoding::for_label(b"unicode11utf8"));
///
/// assert_eq!(Some(encoding_rs::ISO_8859_2), Encoding::for_label(b"latin2"));
///
/// assert_eq!(Some(encoding_rs::UTF_16BE), Encoding::for_label(b"utf-16be"));
///
/// assert_eq!(None, Encoding::for_label(b"unrecognized label"));
/// ```
pub fn for_label(label: &[u8]) -> Option<&'static Encoding> {
let mut trimmed = [0u8; LONGEST_LABEL_LENGTH];
let mut trimmed_pos = 0usize;
let mut iter = label.into_iter();
// before
loop {
match iter.next() {
None => {
return None;
}
Some(byte) => {
// The characters used in labels are:
// a-z (except q, but excluding it below seems excessive)
// 0-9
// . _ - :
match *byte {
0x09u8 | 0x0Au8 | 0x0Cu8 | 0x0Du8 | 0x20u8 => {
continue;
}
b'A'..=b'Z' => {
trimmed[trimmed_pos] = *byte + 0x20u8;
trimmed_pos = 1usize;
break;
}
b'a'..=b'z' | b'0'..=b'9' | b'-' | b'_' | b':' | b'.' => {
trimmed[trimmed_pos] = *byte;
trimmed_pos = 1usize;
break;
}
_ => {
return None;
}
}
}
}
}
// inside
loop {
match iter.next() {
None => {
break;
}
Some(byte) => {
match *byte {
0x09u8 | 0x0Au8 | 0x0Cu8 | 0x0Du8 | 0x20u8 => {
break;
}
b'A'..=b'Z' => {
if trimmed_pos == LONGEST_LABEL_LENGTH {
// There's no encoding with a label this long
return None;
}
trimmed[trimmed_pos] = *byte + 0x20u8;
trimmed_pos += 1usize;
continue;
}
b'a'..=b'z' | b'0'..=b'9' | b'-' | b'_' | b':' | b'.' => {
if trimmed_pos == LONGEST_LABEL_LENGTH {
// There's no encoding with a label this long
return None;
}
trimmed[trimmed_pos] = *byte;
trimmed_pos += 1usize;
continue;
}
_ => {
return None;
}
}
}
}
}
// after
loop {
match iter.next() {
None => {
break;
}
Some(byte) => {
match *byte {
0x09u8 | 0x0Au8 | 0x0Cu8 | 0x0Du8 | 0x20u8 => {
continue;
}
_ => {
// There's no label with space in the middle
return None;
}
}
}
}
}
let candidate = &trimmed[..trimmed_pos];
match LABELS_SORTED.binary_search_by(|probe| {
let bytes = probe.as_bytes();
let c = bytes.len().cmp(&candidate.len());
if c != Ordering::Equal {
return c;
}
let probe_iter = bytes.iter().rev();
let candidate_iter = candidate.iter().rev();
probe_iter.cmp(candidate_iter)
}) {
Ok(i) => Some(ENCODINGS_IN_LABEL_SORT[i]),
Err(_) => None,
}
}
/// This method behaves the same as `for_label()`, except when `for_label()`
/// would return `Some(REPLACEMENT)`, this method returns `None` instead.
///
/// This method is useful in scenarios where a fatal error is required
/// upon invalid label, because in those cases the caller typically wishes
/// to treat the labels that map to the replacement encoding as fatal
/// errors, too.
///
/// It is not OK to use this method when the action upon the method returning
/// `None` is to use a fallback encoding (e.g. `WINDOWS_1252`). In such a
/// case, the `for_label()` method should be used instead in order to avoid
/// unsafe fallback for labels that `for_label()` maps to `Some(REPLACEMENT)`.
///
/// Available via the C wrapper.
#[inline]
pub fn for_label_no_replacement(label: &[u8]) -> Option<&'static Encoding> {
match Encoding::for_label(label) {
None => None,
Some(encoding) => {
if encoding == REPLACEMENT {
None
} else {
Some(encoding)
}
}
}
}
/// Performs non-incremental BOM sniffing.
///
/// The argument must either be a buffer representing the entire input
/// stream (non-streaming case) or a buffer representing at least the first
/// three bytes of the input stream (streaming case).
///
/// Returns `Some((UTF_8, 3))`, `Some((UTF_16LE, 2))` or
/// `Some((UTF_16BE, 2))` if the argument starts with the UTF-8, UTF-16LE
/// or UTF-16BE BOM or `None` otherwise.
///
/// Available via the C wrapper.
#[inline]
pub fn for_bom(buffer: &[u8]) -> Option<(&'static Encoding, usize)> {
if buffer.starts_with(b"\xEF\xBB\xBF") {
Some((UTF_8, 3))
} else if buffer.starts_with(b"\xFF\xFE") {
Some((UTF_16LE, 2))
} else if buffer.starts_with(b"\xFE\xFF") {
Some((UTF_16BE, 2))
} else {
None
}
}
/// Returns the name of this encoding.
///
/// This name is appropriate to return as-is from the DOM
/// `document.characterSet` property.
///
/// Available via the C wrapper.
#[inline]
pub fn name(&'static self) -> &'static str {
self.name
}
/// Checks whether the _output encoding_ of this encoding can encode every
/// `char`. (Only true if the output encoding is UTF-8.)
///
/// Available via the C wrapper.
#[inline]
pub fn can_encode_everything(&'static self) -> bool {
self.output_encoding() == UTF_8
}
/// Checks whether the bytes 0x00...0x7F map exclusively to the characters
/// U+0000...U+007F and vice versa.
///
/// Available via the C wrapper.
#[inline]
pub fn is_ascii_compatible(&'static self) -> bool {
!(self == REPLACEMENT || self == UTF_16BE || self == UTF_16LE || self == ISO_2022_JP)
}
/// Checks whether this encoding maps one byte to one Basic Multilingual
/// Plane code point (i.e. byte length equals decoded UTF-16 length) and
/// vice versa (for mappable characters).
///
/// `true` iff this encoding is on the list of [Legacy single-byte
/// in the spec or x-user-defined.
///
/// Available via the C wrapper.
#[inline]
pub fn is_single_byte(&'static self) -> bool {
self.variant.is_single_byte()
}
/// Checks whether the bytes 0x00...0x7F map mostly to the characters
/// U+0000...U+007F and vice versa.
#[cfg(feature = "alloc")]
#[inline]
fn is_potentially_borrowable(&'static self) -> bool {
!(self == REPLACEMENT || self == UTF_16BE || self == UTF_16LE)
}
/// Returns the _output encoding_ of this encoding. This is UTF-8 for
/// UTF-16BE, UTF-16LE, and replacement and the encoding itself otherwise.
///
/// _Note:_ The _output encoding_ concept is needed for form submission and
/// error handling in the query strings of URLs in the Web Platform.
///
/// Available via the C wrapper.
#[inline]
pub fn output_encoding(&'static self) -> &'static Encoding {
if self == REPLACEMENT || self == UTF_16BE || self == UTF_16LE {
UTF_8
} else {
self
}
}
/// Decode complete input to `Cow<'a, str>` _with BOM sniffing_ and with
/// malformed sequences replaced with the REPLACEMENT CHARACTER when the
/// entire input is available as a single buffer (i.e. the end of the
/// buffer marks the end of the stream).
///
/// The BOM, if any, does not appear in the output.
///
/// This method implements the (non-streaming version of) the
///
/// The second item in the returned tuple is the encoding that was actually
/// used (which may differ from this encoding thanks to BOM sniffing).
///
/// The third item in the returned tuple indicates whether there were
/// malformed sequences (that were replaced with the REPLACEMENT CHARACTER).
///
/// _Note:_ It is wrong to use this when the input buffer represents only
/// a segment of the input instead of the whole input. Use `new_decoder()`
/// when decoding segmented input.
///
/// This method performs a one or two heap allocations for the backing
/// buffer of the `String` when unable to borrow. (One allocation if not
/// errors and potentially another one in the presence of errors.) The
/// first allocation assumes jemalloc and may not be optimal with
/// allocators that do not use power-of-two buckets. A borrow is performed
/// if decoding UTF-8 and the input is valid UTF-8, if decoding an
/// ASCII-compatible encoding and the input is ASCII-only, or when decoding
/// ISO-2022-JP and the input is entirely in the ASCII state without state
/// transitions.
///
/// # Panics
///
/// If the size calculation for a heap-allocated backing buffer overflows
/// `usize`.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
#[inline]
pub fn decode<'a>(&'static self, bytes: &'a [u8]) -> (Cow<'a, str>, &'static Encoding, bool) {
let (encoding, without_bom) = match Encoding::for_bom(bytes) {
Some((encoding, bom_length)) => (encoding, &bytes[bom_length..]),
None => (self, bytes),
};
let (cow, had_errors) = encoding.decode_without_bom_handling(without_bom);
(cow, encoding, had_errors)
}
/// Decode complete input to `Cow<'a, str>` _with BOM removal_ and with
/// malformed sequences replaced with the REPLACEMENT CHARACTER when the
/// entire input is available as a single buffer (i.e. the end of the
/// buffer marks the end of the stream).
///
/// Only an initial byte sequence that is a BOM for this encoding is removed.
///
/// When invoked on `UTF_8`, this method implements the (non-streaming
/// version of) the
/// concept.
///
/// The second item in the returned pair indicates whether there were
/// malformed sequences (that were replaced with the REPLACEMENT CHARACTER).
///
/// _Note:_ It is wrong to use this when the input buffer represents only
/// a segment of the input instead of the whole input. Use
/// `new_decoder_with_bom_removal()` when decoding segmented input.
///
/// This method performs a one or two heap allocations for the backing
/// buffer of the `String` when unable to borrow. (One allocation if not
/// errors and potentially another one in the presence of errors.) The
/// first allocation assumes jemalloc and may not be optimal with
/// allocators that do not use power-of-two buckets. A borrow is performed
/// if decoding UTF-8 and the input is valid UTF-8, if decoding an
/// ASCII-compatible encoding and the input is ASCII-only, or when decoding
/// ISO-2022-JP and the input is entirely in the ASCII state without state
/// transitions.
///
/// # Panics
///
/// If the size calculation for a heap-allocated backing buffer overflows
/// `usize`.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
#[inline]
pub fn decode_with_bom_removal<'a>(&'static self, bytes: &'a [u8]) -> (Cow<'a, str>, bool) {
let without_bom = if self == UTF_8 && bytes.starts_with(b"\xEF\xBB\xBF") {
&bytes[3..]
} else if (self == UTF_16LE && bytes.starts_with(b"\xFF\xFE"))
|| (self == UTF_16BE && bytes.starts_with(b"\xFE\xFF"))
{
&bytes[2..]
} else {
bytes
};
self.decode_without_bom_handling(without_bom)
}
/// Decode complete input to `Cow<'a, str>` _without BOM handling_ and
/// with malformed sequences replaced with the REPLACEMENT CHARACTER when
/// the entire input is available as a single buffer (i.e. the end of the
/// buffer marks the end of the stream).
///
/// When invoked on `UTF_8`, this method implements the (non-streaming
/// version of) the
/// spec concept.
///
/// The second item in the returned pair indicates whether there were
/// malformed sequences (that were replaced with the REPLACEMENT CHARACTER).
///
/// _Note:_ It is wrong to use this when the input buffer represents only
/// a segment of the input instead of the whole input. Use
/// `new_decoder_without_bom_handling()` when decoding segmented input.
///
/// This method performs a one or two heap allocations for the backing
/// buffer of the `String` when unable to borrow. (One allocation if not
/// errors and potentially another one in the presence of errors.) The
/// first allocation assumes jemalloc and may not be optimal with
/// allocators that do not use power-of-two buckets. A borrow is performed
/// if decoding UTF-8 and the input is valid UTF-8, if decoding an
/// ASCII-compatible encoding and the input is ASCII-only, or when decoding
/// ISO-2022-JP and the input is entirely in the ASCII state without state
/// transitions.
///
/// # Panics
///
/// If the size calculation for a heap-allocated backing buffer overflows
/// `usize`.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn decode_without_bom_handling<'a>(&'static self, bytes: &'a [u8]) -> (Cow<'a, str>, bool) {
let (mut decoder, mut string, mut total_read) = if self.is_potentially_borrowable() {
let valid_up_to = if self == UTF_8 {
utf8_valid_up_to(bytes)
} else if self == ISO_2022_JP {
iso_2022_jp_ascii_valid_up_to(bytes)
} else {
ascii_valid_up_to(bytes)
};
if valid_up_to == bytes.len() {
let str: &str = unsafe { core::str::from_utf8_unchecked(bytes) };
return (Cow::Borrowed(str), false);
}
let decoder = self.new_decoder_without_bom_handling();
let rounded_without_replacement = checked_next_power_of_two(checked_add(
valid_up_to,
decoder.max_utf8_buffer_length_without_replacement(bytes.len() - valid_up_to),
));
let with_replacement = checked_add(
valid_up_to,
decoder.max_utf8_buffer_length(bytes.len() - valid_up_to),
);
let mut string = String::with_capacity(
checked_min(rounded_without_replacement, with_replacement).unwrap(),
);
unsafe {
let vec = string.as_mut_vec();
vec.set_len(valid_up_to);
core::ptr::copy_nonoverlapping(bytes.as_ptr(), vec.as_mut_ptr(), valid_up_to);
}
(decoder, string, valid_up_to)
} else {
let decoder = self.new_decoder_without_bom_handling();
let rounded_without_replacement = checked_next_power_of_two(
decoder.max_utf8_buffer_length_without_replacement(bytes.len()),
);
let with_replacement = decoder.max_utf8_buffer_length(bytes.len());
let string = String::with_capacity(
checked_min(rounded_without_replacement, with_replacement).unwrap(),
);
(decoder, string, 0)
};
let mut total_had_errors = false;
loop {
let (result, read, had_errors) =
decoder.decode_to_string(&bytes[total_read..], &mut string, true);
total_read += read;
total_had_errors |= had_errors;
match result {
CoderResult::InputEmpty => {
debug_assert_eq!(total_read, bytes.len());
return (Cow::Owned(string), total_had_errors);
}
CoderResult::OutputFull => {
// Allocate for the worst case. That is, we should come
// here at most once per invocation of this method.
let needed = decoder.max_utf8_buffer_length(bytes.len() - total_read);
string.reserve(needed.unwrap());
}
}
}
}
/// Decode complete input to `Cow<'a, str>` _without BOM handling_ and
/// _with malformed sequences treated as fatal_ when the entire input is
/// available as a single buffer (i.e. the end of the buffer marks the end
/// of the stream).
///
/// When invoked on `UTF_8`, this method implements the (non-streaming
/// version of) the
/// [_UTF-8 decode without BOM or fail_](https://encoding.spec.whatwg.org/#utf-8-decode-without-bom-or-fail)
/// spec concept.
///
/// Returns `None` if a malformed sequence was encountered and the result
/// of the decode as `Some(String)` otherwise.
///
/// _Note:_ It is wrong to use this when the input buffer represents only
/// a segment of the input instead of the whole input. Use
/// `new_decoder_without_bom_handling()` when decoding segmented input.
///
/// This method performs a single heap allocation for the backing
/// buffer of the `String` when unable to borrow. A borrow is performed if
/// decoding UTF-8 and the input is valid UTF-8, if decoding an
/// ASCII-compatible encoding and the input is ASCII-only, or when decoding
/// ISO-2022-JP and the input is entirely in the ASCII state without state
/// transitions.
///
/// # Panics
///
/// If the size calculation for a heap-allocated backing buffer overflows
/// `usize`.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn decode_without_bom_handling_and_without_replacement<'a>(
&'static self,
bytes: &'a [u8],
) -> Option<Cow<'a, str>> {
if self == UTF_8 {
let valid_up_to = utf8_valid_up_to(bytes);
if valid_up_to == bytes.len() {
let str: &str = unsafe { core::str::from_utf8_unchecked(bytes) };
return Some(Cow::Borrowed(str));
}
return None;
}
let (mut decoder, mut string, input) = if self.is_potentially_borrowable() {
let valid_up_to = if self == ISO_2022_JP {
iso_2022_jp_ascii_valid_up_to(bytes)
} else {
ascii_valid_up_to(bytes)
};
if valid_up_to == bytes.len() {
let str: &str = unsafe { core::str::from_utf8_unchecked(bytes) };
return Some(Cow::Borrowed(str));
}
let decoder = self.new_decoder_without_bom_handling();
let mut string = String::with_capacity(
checked_add(
valid_up_to,
decoder.max_utf8_buffer_length_without_replacement(bytes.len() - valid_up_to),
)
.unwrap(),
);
unsafe {
let vec = string.as_mut_vec();
vec.set_len(valid_up_to);
core::ptr::copy_nonoverlapping(bytes.as_ptr(), vec.as_mut_ptr(), valid_up_to);
}
(decoder, string, &bytes[valid_up_to..])
} else {
let decoder = self.new_decoder_without_bom_handling();
let string = String::with_capacity(
decoder
.max_utf8_buffer_length_without_replacement(bytes.len())
.unwrap(),
);
(decoder, string, bytes)
};
let (result, read) = decoder.decode_to_string_without_replacement(input, &mut string, true);
match result {
DecoderResult::InputEmpty => {
debug_assert_eq!(read, input.len());
Some(Cow::Owned(string))
}
DecoderResult::Malformed(_, _) => None,
DecoderResult::OutputFull => unreachable!(),
}
}
/// Encode complete input to `Cow<'a, [u8]>` using the
/// [_output encoding_](Encoding::output_encoding) of this encoding with
/// unmappable characters replaced with decimal numeric character references
/// when the entire input is available as a single buffer (i.e. the end of
/// the buffer marks the end of the stream).
///
/// This method implements the (non-streaming version of) the
/// spec concept, it is slightly more efficient to use
/// <code><var>string</var>.as_bytes()</code> instead of invoking this
/// method on `UTF_8`.
///
/// The second item in the returned tuple is the encoding that was actually
/// used (*which may differ from this encoding thanks to some encodings
/// having UTF-8 as their output encoding*).
///
/// The third item in the returned tuple indicates whether there were
/// unmappable characters (that were replaced with HTML numeric character
/// references).
///
/// _Note:_ It is wrong to use this when the input buffer represents only
/// a segment of the input instead of the whole input. Use `new_encoder()`
/// when encoding segmented output.
///
/// When encoding to UTF-8 or when encoding an ASCII-only input to a
/// ASCII-compatible encoding, this method returns a borrow of the input
/// without a heap allocation. Otherwise, this method performs a single
/// heap allocation for the backing buffer of the `Vec<u8>` if there are no
/// unmappable characters and potentially multiple heap allocations if
/// there are. These allocations are tuned for jemalloc and may not be
/// optimal when using a different allocator that doesn't use power-of-two
/// buckets.
///
/// # Panics
///
/// If the size calculation for a heap-allocated backing buffer overflows
/// `usize`.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn encode<'a>(&'static self, string: &'a str) -> (Cow<'a, [u8]>, &'static Encoding, bool) {
let output_encoding = self.output_encoding();
if output_encoding == UTF_8 {
return (Cow::Borrowed(string.as_bytes()), output_encoding, false);
}
debug_assert!(output_encoding.is_potentially_borrowable());
let bytes = string.as_bytes();
let valid_up_to = if output_encoding == ISO_2022_JP {
iso_2022_jp_ascii_valid_up_to(bytes)
} else {
ascii_valid_up_to(bytes)
};
if valid_up_to == bytes.len() {
return (Cow::Borrowed(bytes), output_encoding, false);
}
let mut encoder = output_encoding.new_encoder();
let mut vec: Vec<u8> = Vec::with_capacity(
(checked_add(
valid_up_to,
encoder.max_buffer_length_from_utf8_if_no_unmappables(string.len() - valid_up_to),
))
.unwrap()
.next_power_of_two(),
);
unsafe {
vec.set_len(valid_up_to);
core::ptr::copy_nonoverlapping(bytes.as_ptr(), vec.as_mut_ptr(), valid_up_to);
}
let mut total_read = valid_up_to;
let mut total_had_errors = false;
loop {
let (result, read, had_errors) =
encoder.encode_from_utf8_to_vec(&string[total_read..], &mut vec, true);
total_read += read;
total_had_errors |= had_errors;
match result {
CoderResult::InputEmpty => {
debug_assert_eq!(total_read, string.len());
return (Cow::Owned(vec), output_encoding, total_had_errors);
}
CoderResult::OutputFull => {
// reserve_exact wants to know how much more on top of current
// length--not current capacity.
let needed = encoder
.max_buffer_length_from_utf8_if_no_unmappables(string.len() - total_read);
let rounded = (checked_add(vec.capacity(), needed))
.unwrap()
.next_power_of_two();
let additional = rounded - vec.len();
vec.reserve_exact(additional);
}
}
}
}
fn new_variant_decoder(&'static self) -> VariantDecoder {
self.variant.new_variant_decoder()
}
/// Instantiates a new decoder for this encoding with BOM sniffing enabled.
///
/// BOM sniffing may cause the returned decoder to morph into a decoder
/// for UTF-8, UTF-16LE or UTF-16BE instead of this encoding. The BOM
/// does not appear in the output.
///
/// Available via the C wrapper.
#[inline]
pub fn new_decoder(&'static self) -> Decoder {
Decoder::new(self, self.new_variant_decoder(), BomHandling::Sniff)
}
/// Instantiates a new decoder for this encoding with BOM removal.
///
/// If the input starts with bytes that are the BOM for this encoding,
/// those bytes are removed. However, the decoder never morphs into a
/// decoder for another encoding: A BOM for another encoding is treated as
/// (potentially malformed) input to the decoding algorithm for this
/// encoding.
///
/// Available via the C wrapper.
#[inline]
pub fn new_decoder_with_bom_removal(&'static self) -> Decoder {
Decoder::new(self, self.new_variant_decoder(), BomHandling::Remove)
}
/// Instantiates a new decoder for this encoding with BOM handling disabled.
///
/// If the input starts with bytes that look like a BOM, those bytes are
/// not treated as a BOM. (Hence, the decoder never morphs into a decoder
/// for another encoding.)
///
/// _Note:_ If the caller has performed BOM sniffing on its own but has not
/// removed the BOM, the caller should use `new_decoder_with_bom_removal()`
/// instead of this method to cause the BOM to be removed.
///
/// Available via the C wrapper.
#[inline]
pub fn new_decoder_without_bom_handling(&'static self) -> Decoder {
Decoder::new(self, self.new_variant_decoder(), BomHandling::Off)
}
/// Instantiates a new encoder for the [_output encoding_](Encoding::output_encoding)
/// of this encoding.
///
/// _Note:_ The output encoding of UTF-16BE, UTF-16LE, and replacement is UTF-8. There
/// is no encoder for UTF-16BE, UTF-16LE, and replacement themselves.
///
/// Available via the C wrapper.
#[inline]
pub fn new_encoder(&'static self) -> Encoder {
let enc = self.output_encoding();
enc.variant.new_encoder(enc)
}
/// Validates UTF-8.
///
/// Returns the index of the first byte that makes the input malformed as
/// UTF-8 or the length of the slice if the slice is entirely valid.
///
/// This is currently faster than the corresponding standard library
/// functionality. If this implementation gets upstreamed to the standard
/// library, this method may be removed in the future.
///
/// Available via the C wrapper.
pub fn utf8_valid_up_to(bytes: &[u8]) -> usize {
utf8_valid_up_to(bytes)
}
/// Validates ASCII.
///
/// Returns the index of the first byte that makes the input malformed as
/// ASCII or the length of the slice if the slice is entirely valid.
///
/// Available via the C wrapper.
pub fn ascii_valid_up_to(bytes: &[u8]) -> usize {
ascii_valid_up_to(bytes)
}
/// Validates ISO-2022-JP ASCII-state data.
///
/// Returns the index of the first byte that makes the input not
/// representable in the ASCII state of ISO-2022-JP or the length of the
/// slice if the slice is entirely representable in the ASCII state of
/// ISO-2022-JP.
///
/// Available via the C wrapper.
pub fn iso_2022_jp_ascii_valid_up_to(bytes: &[u8]) -> usize {
iso_2022_jp_ascii_valid_up_to(bytes)
}
}
impl PartialEq for Encoding {
#[inline]
fn eq(&self, other: &Encoding) -> bool {
(self as *const Encoding) == (other as *const Encoding)
}
}
impl Eq for Encoding {}
#[cfg(test)]
impl PartialOrd for Encoding {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
(self as *const Encoding as usize).partial_cmp(&(other as *const Encoding as usize))
}
}
#[cfg(test)]
impl Ord for Encoding {
fn cmp(&self, other: &Self) -> Ordering {
(self as *const Encoding as usize).cmp(&(other as *const Encoding as usize))
}
}
impl Hash for Encoding {
#[inline]
fn hash<H: Hasher>(&self, state: &mut H) {
(self as *const Encoding).hash(state);
}
}
impl core::fmt::Debug for Encoding {
#[inline]
fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result {
write!(f, "Encoding {{ {} }}", self.name)
}
}
#[cfg(feature = "serde")]
impl Serialize for Encoding {
#[inline]
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
serializer.serialize_str(self.name)
}
}
#[cfg(feature = "serde")]
struct EncodingVisitor;
#[cfg(feature = "serde")]
impl<'de> Visitor<'de> for EncodingVisitor {
type Value = &'static Encoding;
fn expecting(&self, formatter: &mut core::fmt::Formatter) -> core::fmt::Result {
formatter.write_str("a valid encoding label")
}
fn visit_str<E>(self, value: &str) -> Result<&'static Encoding, E>
where
E: serde::de::Error,
{
if let Some(enc) = Encoding::for_label(value.as_bytes()) {
Ok(enc)
} else {
Err(E::custom(alloc::format!(
"invalid encoding label: {}",
value
)))
}
}
}
#[cfg(feature = "serde")]
impl<'de> Deserialize<'de> for &'static Encoding {
fn deserialize<D>(deserializer: D) -> Result<&'static Encoding, D::Error>
where
D: Deserializer<'de>,
{
deserializer.deserialize_str(EncodingVisitor)
}
}
/// Tracks the life cycle of a decoder from BOM sniffing to conversion to end.
#[derive(PartialEq, Debug, Copy, Clone)]
enum DecoderLifeCycle {
/// The decoder has seen no input yet.
AtStart,
/// The decoder has seen no input yet but expects UTF-8.
AtUtf8Start,
/// The decoder has seen no input yet but expects UTF-16BE.
AtUtf16BeStart,
/// The decoder has seen no input yet but expects UTF-16LE.
AtUtf16LeStart,
/// The decoder has seen EF.
SeenUtf8First,
/// The decoder has seen EF, BB.
SeenUtf8Second,
/// The decoder has seen FE.
SeenUtf16BeFirst,
/// The decoder has seen FF.
SeenUtf16LeFirst,
/// Saw EF, BB but not BF, there was a buffer boundary after BB and the
/// underlying decoder reported EF as an error, so we need to remember to
/// push BB before the next buffer.
ConvertingWithPendingBB,
/// No longer looking for a BOM and EOF not yet seen.
Converting,
/// EOF has been seen.
Finished,
}
/// Communicate the BOM handling mode.
#[derive(Debug, Copy, Clone)]
enum BomHandling {
/// Don't handle the BOM
Off,
/// Sniff for UTF-8, UTF-16BE or UTF-16LE BOM
Sniff,
/// Remove the BOM only if it's the BOM for this encoding
Remove,
}
/// Result of a (potentially partial) decode or encode operation with
/// replacement.
#[must_use]
#[derive(Debug, PartialEq, Eq)]
pub enum CoderResult {
/// The input was exhausted.
///
/// If this result was returned from a call where `last` was `true`, the
/// conversion process has completed. Otherwise, the caller should call a
/// decode or encode method again with more input.
InputEmpty,
/// The converter cannot produce another unit of output, because the output
/// buffer does not have enough space left.
///
/// The caller must provide more output space upon the next call and re-push
/// the remaining input to the converter.
OutputFull,
}
/// Result of a (potentially partial) decode operation without replacement.
#[must_use]
#[derive(Debug, PartialEq, Eq)]
pub enum DecoderResult {
/// The input was exhausted.
///
/// If this result was returned from a call where `last` was `true`, the
/// decoding process has completed. Otherwise, the caller should call a
/// decode method again with more input.
InputEmpty,
/// The decoder cannot produce another unit of output, because the output
/// buffer does not have enough space left.
///
/// The caller must provide more output space upon the next call and re-push
/// the remaining input to the decoder.
OutputFull,
/// The decoder encountered a malformed byte sequence.
///
/// The caller must either treat this as a fatal error or must append one
/// REPLACEMENT CHARACTER (U+FFFD) to the output and then re-push the
/// the remaining input to the decoder.
///
/// The first wrapped integer indicates the length of the malformed byte
/// sequence. The second wrapped integer indicates the number of bytes
/// that were consumed after the malformed sequence. If the second
/// integer is zero, the last byte that was consumed is the last byte of
/// the malformed sequence. Note that the malformed bytes may have been part
/// of an earlier input buffer.
///
/// The first wrapped integer can have values 1, 2, 3 or 4. The second
/// wrapped integer can have values 0, 1, 2 or 3. The worst-case sum
/// of the two is 6, which happens with ISO-2022-JP.
Malformed(u8, u8), // u8 instead of usize to avoid useless bloat
}
/// A converter that decodes a byte stream into Unicode according to a
/// character encoding in a streaming (incremental) manner.
///
/// The various `decode_*` methods take an input buffer (`src`) and an output
/// buffer `dst` both of which are caller-allocated. There are variants for
/// both UTF-8 and UTF-16 output buffers.
///
/// A `decode_*` method decodes bytes from `src` into Unicode characters stored
/// into `dst` until one of the following three things happens:
///
/// 1. A malformed byte sequence is encountered (`*_without_replacement`
/// variants only).
///
/// 2. The output buffer has been filled so near capacity that the decoder
/// cannot be sure that processing an additional byte of input wouldn't
/// cause so much output that the output buffer would overflow.
///
/// 3. All the input bytes have been processed.
///
/// The `decode_*` method then returns tuple of a status indicating which one
/// of the three reasons to return happened, how many input bytes were read,
/// how many output code units (`u8` when decoding into UTF-8 and `u16`
/// when decoding to UTF-16) were written (except when decoding into `String`,
/// whose length change indicates this), and in the case of the
/// variants performing replacement, a boolean indicating whether an error was
/// replaced with the REPLACEMENT CHARACTER during the call.
///
/// The number of bytes "written" is what's logically written. Garbage may be
/// written in the output buffer beyond the point logically written to.
/// Therefore, if you wish to decode into an `&mut str`, you should use the
/// methods that take an `&mut str` argument instead of the ones that take an
/// `&mut [u8]` argument. The former take care of overwriting the trailing
/// garbage to ensure the UTF-8 validity of the `&mut str` as a whole, but the
/// latter don't.
///
/// In the case of the `*_without_replacement` variants, the status is a
/// [`DecoderResult`][1] enumeration (possibilities `Malformed`, `OutputFull` and
/// `InputEmpty` corresponding to the three cases listed above).
///
/// In the case of methods whose name does not end with
/// `*_without_replacement`, malformed sequences are automatically replaced
/// with the REPLACEMENT CHARACTER and errors do not cause the methods to
/// return early.
///
/// When decoding to UTF-8, the output buffer must have at least 4 bytes of
/// space. When decoding to UTF-16, the output buffer must have at least two
/// UTF-16 code units (`u16`) of space.
///
/// When decoding to UTF-8 without replacement, the methods are guaranteed
/// not to return indicating that more output space is needed if the length
/// of the output buffer is at least the length returned by
/// [`max_utf8_buffer_length_without_replacement()`][2]. When decoding to UTF-8
/// with replacement, the length of the output buffer that guarantees the
/// methods not to return indicating that more output space is needed is given
/// by [`max_utf8_buffer_length()`][3]. When decoding to UTF-16 with
/// or without replacement, the length of the output buffer that guarantees
/// the methods not to return indicating that more output space is needed is
/// given by [`max_utf16_buffer_length()`][4].
///
/// The output written into `dst` is guaranteed to be valid UTF-8 or UTF-16,
/// and the output after each `decode_*` call is guaranteed to consist of
/// complete characters. (I.e. the code unit sequence for the last character is
/// guaranteed not to be split across output buffers.)
///
/// The boolean argument `last` indicates that the end of the stream is reached
/// when all the bytes in `src` have been consumed.
///
/// A `Decoder` object can be used to incrementally decode a byte stream.
///
/// During the processing of a single stream, the caller must call `decode_*`
/// zero or more times with `last` set to `false` and then call `decode_*` at
/// least once with `last` set to `true`. If `decode_*` returns `InputEmpty`,
/// the processing of the stream has ended. Otherwise, the caller must call
/// `decode_*` again with `last` set to `true` (or treat a `Malformed` result as
/// a fatal error).
///
/// Once the stream has ended, the `Decoder` object must not be used anymore.
/// That is, you need to create another one to process another stream.
///
/// When the decoder returns `OutputFull` or the decoder returns `Malformed` and
/// the caller does not wish to treat it as a fatal error, the input buffer
/// `src` may not have been completely consumed. In that case, the caller must
/// pass the unconsumed contents of `src` to `decode_*` again upon the next
/// call.
///
/// [1]: enum.DecoderResult.html
/// [2]: #method.max_utf8_buffer_length_without_replacement
/// [3]: #method.max_utf8_buffer_length
/// [4]: #method.max_utf16_buffer_length
///
/// # Infinite loops
///
/// When converting with a fixed-size output buffer whose size is too small to
/// accommodate one character or (when applicable) one numeric character
/// reference of output, an infinite loop ensues. When converting with a
/// fixed-size output buffer, it generally makes sense to make the buffer
/// fairly large (e.g. couple of kilobytes).
pub struct Decoder {
encoding: &'static Encoding,
variant: VariantDecoder,
life_cycle: DecoderLifeCycle,
}
impl Decoder {
fn new(enc: &'static Encoding, decoder: VariantDecoder, sniffing: BomHandling) -> Decoder {
Decoder {
encoding: enc,
variant: decoder,
life_cycle: match sniffing {
BomHandling::Off => DecoderLifeCycle::Converting,
BomHandling::Sniff => DecoderLifeCycle::AtStart,
BomHandling::Remove => {
if enc == UTF_8 {
DecoderLifeCycle::AtUtf8Start
} else if enc == UTF_16BE {
DecoderLifeCycle::AtUtf16BeStart
} else if enc == UTF_16LE {
DecoderLifeCycle::AtUtf16LeStart
} else {
DecoderLifeCycle::Converting
}
}
},
}
}
/// The `Encoding` this `Decoder` is for.
///
/// BOM sniffing can change the return value of this method during the life
/// of the decoder.
///
/// Available via the C wrapper.
#[inline]
pub fn encoding(&self) -> &'static Encoding {
self.encoding
}
/// Query the worst-case UTF-8 output size _with replacement_.
///
/// Returns the size of the output buffer in UTF-8 code units (`u8`)
/// that will not overflow given the current state of the decoder and
/// `byte_length` number of additional input bytes when decoding with
/// errors handled by outputting a REPLACEMENT CHARACTER for each malformed
/// sequence or `None` if `usize` would overflow.
///
/// Available via the C wrapper.
pub fn max_utf8_buffer_length(&self, byte_length: usize) -> Option<usize> {
// Need to consider a) the decoder morphing due to the BOM and b) a partial
// BOM getting pushed to the underlying decoder.
match self.life_cycle {
DecoderLifeCycle::Converting
| DecoderLifeCycle::AtUtf8Start
| DecoderLifeCycle::AtUtf16LeStart
| DecoderLifeCycle::AtUtf16BeStart => {
return self.variant.max_utf8_buffer_length(byte_length);
}
DecoderLifeCycle::AtStart => {
if let Some(utf8_bom) = checked_add(3, byte_length.checked_mul(3)) {
if let Some(utf16_bom) = checked_add(
1,
checked_mul(3, checked_div(byte_length.checked_add(1), 2)),
) {
let utf_bom = core::cmp::max(utf8_bom, utf16_bom);
let encoding = self.encoding();
if encoding == UTF_8 || encoding == UTF_16LE || encoding == UTF_16BE {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf_bom);
} else if let Some(non_bom) =
self.variant.max_utf8_buffer_length(byte_length)
{
return Some(core::cmp::max(utf_bom, non_bom));
}
}
}
}
DecoderLifeCycle::SeenUtf8First | DecoderLifeCycle::SeenUtf8Second => {
// Add two bytes even when only one byte has been seen,
// because the one byte can become a lead byte in multibyte
// decoders, but only after the decoder has been queried
// for max length, so the decoder's own logic for adding
// one for a pending lead cannot work.
if let Some(sum) = byte_length.checked_add(2) {
if let Some(utf8_bom) = checked_add(3, sum.checked_mul(3)) {
if self.encoding() == UTF_8 {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf8_bom);
} else if let Some(non_bom) = self.variant.max_utf8_buffer_length(sum) {
return Some(core::cmp::max(utf8_bom, non_bom));
}
}
}
}
DecoderLifeCycle::ConvertingWithPendingBB => {
if let Some(sum) = byte_length.checked_add(2) {
return self.variant.max_utf8_buffer_length(sum);
}
}
DecoderLifeCycle::SeenUtf16LeFirst | DecoderLifeCycle::SeenUtf16BeFirst => {
// Add two bytes even when only one byte has been seen,
// because the one byte can become a lead byte in multibyte
// decoders, but only after the decoder has been queried
// for max length, so the decoder's own logic for adding
// one for a pending lead cannot work.
if let Some(sum) = byte_length.checked_add(2) {
if let Some(utf16_bom) =
checked_add(1, checked_mul(3, checked_div(sum.checked_add(1), 2)))
{
let encoding = self.encoding();
if encoding == UTF_16LE || encoding == UTF_16BE {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf16_bom);
} else if let Some(non_bom) = self.variant.max_utf8_buffer_length(sum) {
return Some(core::cmp::max(utf16_bom, non_bom));
}
}
}
}
DecoderLifeCycle::Finished => panic!("Must not use a decoder that has finished."),
}
None
}
/// Query the worst-case UTF-8 output size _without replacement_.
///
/// Returns the size of the output buffer in UTF-8 code units (`u8`)
/// that will not overflow given the current state of the decoder and
/// `byte_length` number of additional input bytes when decoding without
/// replacement error handling or `None` if `usize` would overflow.
///
/// Note that this value may be too small for the `_with_replacement` case.
/// Use `max_utf8_buffer_length()` for that case.
///
/// Available via the C wrapper.
pub fn max_utf8_buffer_length_without_replacement(&self, byte_length: usize) -> Option<usize> {
// Need to consider a) the decoder morphing due to the BOM and b) a partial
// BOM getting pushed to the underlying decoder.
match self.life_cycle {
DecoderLifeCycle::Converting
| DecoderLifeCycle::AtUtf8Start
| DecoderLifeCycle::AtUtf16LeStart
| DecoderLifeCycle::AtUtf16BeStart => {
return self
.variant
.max_utf8_buffer_length_without_replacement(byte_length);
}
DecoderLifeCycle::AtStart => {
if let Some(utf8_bom) = byte_length.checked_add(3) {
if let Some(utf16_bom) = checked_add(
1,
checked_mul(3, checked_div(byte_length.checked_add(1), 2)),
) {
let utf_bom = core::cmp::max(utf8_bom, utf16_bom);
let encoding = self.encoding();
if encoding == UTF_8 || encoding == UTF_16LE || encoding == UTF_16BE {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf_bom);
} else if let Some(non_bom) = self
.variant
.max_utf8_buffer_length_without_replacement(byte_length)
{
return Some(core::cmp::max(utf_bom, non_bom));
}
}
}
}
DecoderLifeCycle::SeenUtf8First | DecoderLifeCycle::SeenUtf8Second => {
// Add two bytes even when only one byte has been seen,
// because the one byte can become a lead byte in multibyte
// decoders, but only after the decoder has been queried
// for max length, so the decoder's own logic for adding
// one for a pending lead cannot work.
if let Some(sum) = byte_length.checked_add(2) {
if let Some(utf8_bom) = sum.checked_add(3) {
if self.encoding() == UTF_8 {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf8_bom);
} else if let Some(non_bom) =
self.variant.max_utf8_buffer_length_without_replacement(sum)
{
return Some(core::cmp::max(utf8_bom, non_bom));
}
}
}
}
DecoderLifeCycle::ConvertingWithPendingBB => {
if let Some(sum) = byte_length.checked_add(2) {
return self.variant.max_utf8_buffer_length_without_replacement(sum);
}
}
DecoderLifeCycle::SeenUtf16LeFirst | DecoderLifeCycle::SeenUtf16BeFirst => {
// Add two bytes even when only one byte has been seen,
// because the one byte can become a lead byte in multibyte
// decoders, but only after the decoder has been queried
// for max length, so the decoder's own logic for adding
// one for a pending lead cannot work.
if let Some(sum) = byte_length.checked_add(2) {
if let Some(utf16_bom) =
checked_add(1, checked_mul(3, checked_div(sum.checked_add(1), 2)))
{
let encoding = self.encoding();
if encoding == UTF_16LE || encoding == UTF_16BE {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf16_bom);
} else if let Some(non_bom) =
self.variant.max_utf8_buffer_length_without_replacement(sum)
{
return Some(core::cmp::max(utf16_bom, non_bom));
}
}
}
}
DecoderLifeCycle::Finished => panic!("Must not use a decoder that has finished."),
}
None
}
/// Incrementally decode a byte stream into UTF-8 with malformed sequences
/// replaced with the REPLACEMENT CHARACTER.
///
/// See the documentation of the struct for documentation for `decode_*`
/// methods collectively.
///
/// Available via the C wrapper.
pub fn decode_to_utf8(
&mut self,
src: &[u8],
dst: &mut [u8],
last: bool,
) -> (CoderResult, usize, usize, bool) {
let mut had_errors = false;
let mut total_read = 0usize;
let mut total_written = 0usize;
loop {
let (result, read, written) = self.decode_to_utf8_without_replacement(
&src[total_read..],
&mut dst[total_written..],
last,
);
total_read += read;
total_written += written;
match result {
DecoderResult::InputEmpty => {
return (
CoderResult::InputEmpty,
total_read,
total_written,
had_errors,
);
}
DecoderResult::OutputFull => {
return (
CoderResult::OutputFull,
total_read,
total_written,
had_errors,
);
}
DecoderResult::Malformed(_, _) => {
had_errors = true;
// There should always be space for the U+FFFD, because
// otherwise we'd have gotten OutputFull already.
// XXX: is the above comment actually true for UTF-8 itself?
// TODO: Consider having fewer bound checks here.
dst[total_written] = 0xEFu8;
total_written += 1;
dst[total_written] = 0xBFu8;
total_written += 1;
dst[total_written] = 0xBDu8;
total_written += 1;
}
}
}
}
/// Incrementally decode a byte stream into UTF-8 with malformed sequences
/// replaced with the REPLACEMENT CHARACTER with type system signaling
/// of UTF-8 validity.
///
/// This methods calls `decode_to_utf8` and then zeroes
/// out up to three bytes that aren't logically part of the write in order
/// to retain the UTF-8 validity even for the unwritten part of the buffer.
///
/// See the documentation of the struct for documentation for `decode_*`
/// methods collectively.
///
/// Available to Rust only.
pub fn decode_to_str(
&mut self,
src: &[u8],
dst: &mut str,
last: bool,
) -> (CoderResult, usize, usize, bool) {
let bytes: &mut [u8] = unsafe { dst.as_bytes_mut() };
let (result, read, written, replaced) = self.decode_to_utf8(src, bytes, last);
let len = bytes.len();
let mut trail = written;
// Non-UTF-8 ASCII-compatible decoders may write up to `MAX_STRIDE_SIZE`
// bytes of trailing garbage. No need to optimize non-ASCII-compatible
// encodings to avoid overwriting here.
if self.encoding != UTF_8 {
let max = core::cmp::min(len, trail + ascii::MAX_STRIDE_SIZE);
while trail < max {
bytes[trail] = 0;
trail += 1;
}
}
while trail < len && ((bytes[trail] & 0xC0) == 0x80) {
bytes[trail] = 0;
trail += 1;
}
(result, read, written, replaced)
}
/// Incrementally decode a byte stream into UTF-8 with malformed sequences
/// replaced with the REPLACEMENT CHARACTER using a `String` receiver.
///
/// Like the others, this method follows the logic that the output buffer is
/// caller-allocated. This method treats the capacity of the `String` as
/// the output limit. That is, this method guarantees not to cause a
/// reallocation of the backing buffer of `String`.
///
/// The return value is a tuple that contains the `DecoderResult`, the
/// number of bytes read and a boolean indicating whether replacements
/// were done. The number of bytes written is signaled via the length of
/// the `String` changing.
///
/// See the documentation of the struct for documentation for `decode_*`
/// methods collectively.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn decode_to_string(
&mut self,
src: &[u8],
dst: &mut String,
last: bool,
) -> (CoderResult, usize, bool) {
unsafe {
let vec = dst.as_mut_vec();
let old_len = vec.len();
let capacity = vec.capacity();
vec.set_len(capacity);
let (result, read, written, replaced) =
self.decode_to_utf8(src, &mut vec[old_len..], last);
vec.set_len(old_len + written);
(result, read, replaced)
}
}
public_decode_function!(/// Incrementally decode a byte stream into UTF-8
/// _without replacement_.
///
/// See the documentation of the struct for
/// documentation for `decode_*` methods
/// collectively.
///
/// Available via the C wrapper.
,
decode_to_utf8_without_replacement,
decode_to_utf8_raw,
decode_to_utf8_checking_end,
decode_to_utf8_after_one_potential_bom_byte,
decode_to_utf8_after_two_potential_bom_bytes,
decode_to_utf8_checking_end_with_offset,
u8);
/// Incrementally decode a byte stream into UTF-8 with type system signaling
/// of UTF-8 validity.
///
/// This methods calls `decode_to_utf8` and then zeroes out up to three
/// bytes that aren't logically part of the write in order to retain the
/// UTF-8 validity even for the unwritten part of the buffer.
///
/// See the documentation of the struct for documentation for `decode_*`
/// methods collectively.
///
/// Available to Rust only.
pub fn decode_to_str_without_replacement(
&mut self,
src: &[u8],
dst: &mut str,
last: bool,
) -> (DecoderResult, usize, usize) {
let bytes: &mut [u8] = unsafe { dst.as_bytes_mut() };
let (result, read, written) = self.decode_to_utf8_without_replacement(src, bytes, last);
let len = bytes.len();
let mut trail = written;
// Non-UTF-8 ASCII-compatible decoders may write up to `MAX_STRIDE_SIZE`
// bytes of trailing garbage. No need to optimize non-ASCII-compatible
// encodings to avoid overwriting here.
if self.encoding != UTF_8 {
let max = core::cmp::min(len, trail + ascii::MAX_STRIDE_SIZE);
while trail < max {
bytes[trail] = 0;
trail += 1;
}
}
while trail < len && ((bytes[trail] & 0xC0) == 0x80) {
bytes[trail] = 0;
trail += 1;
}
(result, read, written)
}
/// Incrementally decode a byte stream into UTF-8 using a `String` receiver.
///
/// Like the others, this method follows the logic that the output buffer is
/// caller-allocated. This method treats the capacity of the `String` as
/// the output limit. That is, this method guarantees not to cause a
/// reallocation of the backing buffer of `String`.
///
/// The return value is a pair that contains the `DecoderResult` and the
/// number of bytes read. The number of bytes written is signaled via
/// the length of the `String` changing.
///
/// See the documentation of the struct for documentation for `decode_*`
/// methods collectively.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn decode_to_string_without_replacement(
&mut self,
src: &[u8],
dst: &mut String,
last: bool,
) -> (DecoderResult, usize) {
unsafe {
let vec = dst.as_mut_vec();
let old_len = vec.len();
let capacity = vec.capacity();
vec.set_len(capacity);
let (result, read, written) =
self.decode_to_utf8_without_replacement(src, &mut vec[old_len..], last);
vec.set_len(old_len + written);
(result, read)
}
}
/// Query the worst-case UTF-16 output size (with or without replacement).
///
/// Returns the size of the output buffer in UTF-16 code units (`u16`)
/// that will not overflow given the current state of the decoder and
/// `byte_length` number of additional input bytes or `None` if `usize`
/// would overflow.
///
/// Since the REPLACEMENT CHARACTER fits into one UTF-16 code unit, the
/// return value of this method applies also in the
/// `_without_replacement` case.
///
/// Available via the C wrapper.
pub fn max_utf16_buffer_length(&self, byte_length: usize) -> Option<usize> {
// Need to consider a) the decoder morphing due to the BOM and b) a partial
// BOM getting pushed to the underlying decoder.
match self.life_cycle {
DecoderLifeCycle::Converting
| DecoderLifeCycle::AtUtf8Start
| DecoderLifeCycle::AtUtf16LeStart
| DecoderLifeCycle::AtUtf16BeStart => {
return self.variant.max_utf16_buffer_length(byte_length);
}
DecoderLifeCycle::AtStart => {
if let Some(utf8_bom) = byte_length.checked_add(1) {
if let Some(utf16_bom) =
checked_add(1, checked_div(byte_length.checked_add(1), 2))
{
let utf_bom = core::cmp::max(utf8_bom, utf16_bom);
let encoding = self.encoding();
if encoding == UTF_8 || encoding == UTF_16LE || encoding == UTF_16BE {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf_bom);
} else if let Some(non_bom) =
self.variant.max_utf16_buffer_length(byte_length)
{
return Some(core::cmp::max(utf_bom, non_bom));
}
}
}
}
DecoderLifeCycle::SeenUtf8First | DecoderLifeCycle::SeenUtf8Second => {
// Add two bytes even when only one byte has been seen,
// because the one byte can become a lead byte in multibyte
// decoders, but only after the decoder has been queried
// for max length, so the decoder's own logic for adding
// one for a pending lead cannot work.
if let Some(sum) = byte_length.checked_add(2) {
if let Some(utf8_bom) = sum.checked_add(1) {
if self.encoding() == UTF_8 {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf8_bom);
} else if let Some(non_bom) = self.variant.max_utf16_buffer_length(sum) {
return Some(core::cmp::max(utf8_bom, non_bom));
}
}
}
}
DecoderLifeCycle::ConvertingWithPendingBB => {
if let Some(sum) = byte_length.checked_add(2) {
return self.variant.max_utf16_buffer_length(sum);
}
}
DecoderLifeCycle::SeenUtf16LeFirst | DecoderLifeCycle::SeenUtf16BeFirst => {
// Add two bytes even when only one byte has been seen,
// because the one byte can become a lead byte in multibyte
// decoders, but only after the decoder has been queried
// for max length, so the decoder's own logic for adding
// one for a pending lead cannot work.
if let Some(sum) = byte_length.checked_add(2) {
if let Some(utf16_bom) = checked_add(1, checked_div(sum.checked_add(1), 2)) {
let encoding = self.encoding();
if encoding == UTF_16LE || encoding == UTF_16BE {
// No need to consider the internal state of the underlying decoder,
// because it is at start, because no data has reached it yet.
return Some(utf16_bom);
} else if let Some(non_bom) = self.variant.max_utf16_buffer_length(sum) {
return Some(core::cmp::max(utf16_bom, non_bom));
}
}
}
}
DecoderLifeCycle::Finished => panic!("Must not use a decoder that has finished."),
}
None
}
/// Incrementally decode a byte stream into UTF-16 with malformed sequences
/// replaced with the REPLACEMENT CHARACTER.
///
/// See the documentation of the struct for documentation for `decode_*`
/// methods collectively.
///
/// Available via the C wrapper.
pub fn decode_to_utf16(
&mut self,
src: &[u8],
dst: &mut [u16],
last: bool,
) -> (CoderResult, usize, usize, bool) {
let mut had_errors = false;
let mut total_read = 0usize;
let mut total_written = 0usize;
loop {
let (result, read, written) = self.decode_to_utf16_without_replacement(
&src[total_read..],
&mut dst[total_written..],
last,
);
total_read += read;
total_written += written;
match result {
DecoderResult::InputEmpty => {
return (
CoderResult::InputEmpty,
total_read,
total_written,
had_errors,
);
}
DecoderResult::OutputFull => {
return (
CoderResult::OutputFull,
total_read,
total_written,
had_errors,
);
}
DecoderResult::Malformed(_, _) => {
had_errors = true;
// There should always be space for the U+FFFD, because
// otherwise we'd have gotten OutputFull already.
dst[total_written] = 0xFFFD;
total_written += 1;
}
}
}
}
public_decode_function!(/// Incrementally decode a byte stream into UTF-16
/// _without replacement_.
///
/// See the documentation of the struct for
/// documentation for `decode_*` methods
/// collectively.
///
/// Available via the C wrapper.
,
decode_to_utf16_without_replacement,
decode_to_utf16_raw,
decode_to_utf16_checking_end,
decode_to_utf16_after_one_potential_bom_byte,
decode_to_utf16_after_two_potential_bom_bytes,
decode_to_utf16_checking_end_with_offset,
u16);
/// Checks for compatibility with storing Unicode scalar values as unsigned
/// bytes taking into account the state of the decoder.
///
/// Returns `None` if the decoder is not in a neutral state, including waiting
/// for the BOM, or if the encoding is never Latin1-byte-compatible.
///
/// Otherwise returns the index of the first byte whose unsigned value doesn't
/// directly correspond to the decoded Unicode scalar value, or the length
/// of the input if all bytes in the input decode directly to scalar values
/// corresponding to the unsigned byte values.
///
/// Does not change the state of the decoder.
///
/// Do not use this unless you are supporting SpiderMonkey/V8-style string
/// storage optimizations.
///
/// Available via the C wrapper.
pub fn latin1_byte_compatible_up_to(&self, bytes: &[u8]) -> Option<usize> {
match self.life_cycle {
DecoderLifeCycle::Converting => {
return self.variant.latin1_byte_compatible_up_to(bytes);
}
DecoderLifeCycle::Finished => panic!("Must not use a decoder that has finished."),
_ => None,
}
}
}
/// Result of a (potentially partial) encode operation without replacement.
#[must_use]
#[derive(Debug, PartialEq, Eq)]
pub enum EncoderResult {
/// The input was exhausted.
///
/// If this result was returned from a call where `last` was `true`, the
/// decoding process has completed. Otherwise, the caller should call a
/// decode method again with more input.
InputEmpty,
/// The encoder cannot produce another unit of output, because the output
/// buffer does not have enough space left.
///
/// The caller must provide more output space upon the next call and re-push
/// the remaining input to the decoder.
OutputFull,
/// The encoder encountered an unmappable character.
///
/// The caller must either treat this as a fatal error or must append
/// a placeholder to the output and then re-push the remaining input to the
/// encoder.
Unmappable(char),
}
impl EncoderResult {
fn unmappable_from_bmp(bmp: u16) -> EncoderResult {
EncoderResult::Unmappable(::core::char::from_u32(u32::from(bmp)).unwrap())
}
}
/// A converter that encodes a Unicode stream into bytes according to a
/// character encoding in a streaming (incremental) manner.
///
/// The various `encode_*` methods take an input buffer (`src`) and an output
/// buffer `dst` both of which are caller-allocated. There are variants for
/// both UTF-8 and UTF-16 input buffers.
///
/// An `encode_*` method encode characters from `src` into bytes characters
/// stored into `dst` until one of the following three things happens:
///
/// 1. An unmappable character is encountered (`*_without_replacement` variants
/// only).
///
/// 2. The output buffer has been filled so near capacity that the decoder
/// cannot be sure that processing an additional character of input wouldn't
/// cause so much output that the output buffer would overflow.
///
/// 3. All the input characters have been processed.
///
/// The `encode_*` method then returns tuple of a status indicating which one
/// of the three reasons to return happened, how many input code units (`u8`
/// when encoding from UTF-8 and `u16` when encoding from UTF-16) were read,
/// how many output bytes were written (except when encoding into `Vec<u8>`,
/// whose length change indicates this), and in the case of the variants that
/// perform replacement, a boolean indicating whether an unmappable
/// character was replaced with a numeric character reference during the call.
///
/// The number of bytes "written" is what's logically written. Garbage may be
/// written in the output buffer beyond the point logically written to.
///
/// In the case of the methods whose name ends with
/// `*_without_replacement`, the status is an [`EncoderResult`][1] enumeration
/// (possibilities `Unmappable`, `OutputFull` and `InputEmpty` corresponding to
/// the three cases listed above).
///
/// In the case of methods whose name does not end with
/// `*_without_replacement`, unmappable characters are automatically replaced
/// with the corresponding numeric character references and unmappable
/// characters do not cause the methods to return early.
///
/// When encoding from UTF-8 without replacement, the methods are guaranteed
/// not to return indicating that more output space is needed if the length
/// of the output buffer is at least the length returned by
/// [`max_buffer_length_from_utf8_without_replacement()`][2]. When encoding from
/// UTF-8 with replacement, the length of the output buffer that guarantees the
/// methods not to return indicating that more output space is needed in the
/// absence of unmappable characters is given by
/// [`max_buffer_length_from_utf8_if_no_unmappables()`][3]. When encoding from
/// UTF-16 without replacement, the methods are guaranteed not to return
/// indicating that more output space is needed if the length of the output
/// buffer is at least the length returned by
/// [`max_buffer_length_from_utf16_without_replacement()`][4]. When encoding
/// from UTF-16 with replacement, the the length of the output buffer that
/// guarantees the methods not to return indicating that more output space is
/// needed in the absence of unmappable characters is given by
/// [`max_buffer_length_from_utf16_if_no_unmappables()`][5].
/// When encoding with replacement, applications are not expected to size the
/// buffer for the worst case ahead of time but to resize the buffer if there
/// are unmappable characters. This is why max length queries are only available
/// for the case where there are no unmappable characters.
///
/// When encoding from UTF-8, each `src` buffer _must_ be valid UTF-8. (When
/// calling from Rust, the type system takes care of this.) When encoding from
/// UTF-16, unpaired surrogates in the input are treated as U+FFFD REPLACEMENT
/// CHARACTERS. Therefore, in order for astral characters not to turn into a
/// pair of REPLACEMENT CHARACTERS, the caller must ensure that surrogate pairs
/// are not split across input buffer boundaries.
///
/// After an `encode_*` call returns, the output produced so far, taken as a
/// whole from the start of the stream, is guaranteed to consist of a valid
/// byte sequence in the target encoding. (I.e. the code unit sequence for a
/// character is guaranteed not to be split across output buffers. However, due
/// to the stateful nature of ISO-2022-JP, the stream needs to be considered
/// from the start for it to be valid. For other encodings, the validity holds
/// on a per-output buffer basis.)
///
/// The boolean argument `last` indicates that the end of the stream is reached
/// when all the characters in `src` have been consumed. This argument is needed
/// for ISO-2022-JP and is ignored for other encodings.
///
/// An `Encoder` object can be used to incrementally encode a byte stream.
///
/// During the processing of a single stream, the caller must call `encode_*`
/// zero or more times with `last` set to `false` and then call `encode_*` at
/// least once with `last` set to `true`. If `encode_*` returns `InputEmpty`,
/// the processing of the stream has ended. Otherwise, the caller must call
/// `encode_*` again with `last` set to `true` (or treat an `Unmappable` result
/// as a fatal error).
///
/// Once the stream has ended, the `Encoder` object must not be used anymore.
/// That is, you need to create another one to process another stream.
///
/// When the encoder returns `OutputFull` or the encoder returns `Unmappable`
/// and the caller does not wish to treat it as a fatal error, the input buffer
/// `src` may not have been completely consumed. In that case, the caller must
/// pass the unconsumed contents of `src` to `encode_*` again upon the next
/// call.
///
/// [1]: enum.EncoderResult.html
/// [2]: #method.max_buffer_length_from_utf8_without_replacement
/// [3]: #method.max_buffer_length_from_utf8_if_no_unmappables
/// [4]: #method.max_buffer_length_from_utf16_without_replacement
/// [5]: #method.max_buffer_length_from_utf16_if_no_unmappables
///
/// # Infinite loops
///
/// When converting with a fixed-size output buffer whose size is too small to
/// accommodate one character of output, an infinite loop ensues. When
/// converting with a fixed-size output buffer, it generally makes sense to
/// make the buffer fairly large (e.g. couple of kilobytes).
pub struct Encoder {
encoding: &'static Encoding,
variant: VariantEncoder,
}
impl Encoder {
fn new(enc: &'static Encoding, encoder: VariantEncoder) -> Encoder {
Encoder {
encoding: enc,
variant: encoder,
}
}
/// The `Encoding` this `Encoder` is for.
#[inline]
pub fn encoding(&self) -> &'static Encoding {
self.encoding
}
/// Returns `true` if this is an ISO-2022-JP encoder that's not in the
/// ASCII state and `false` otherwise.
#[inline]
pub fn has_pending_state(&self) -> bool {
self.variant.has_pending_state()
}
/// Query the worst-case output size when encoding from UTF-8 with
/// replacement.
///
/// Returns the size of the output buffer in bytes that will not overflow
/// given the current state of the encoder and `byte_length` number of
/// additional input code units if there are no unmappable characters in
/// the input or `None` if `usize` would overflow.
///
/// Available via the C wrapper.
pub fn max_buffer_length_from_utf8_if_no_unmappables(
&self,
byte_length: usize,
) -> Option<usize> {
checked_add(
if self.encoding().can_encode_everything() {
0
} else {
NCR_EXTRA
},
self.max_buffer_length_from_utf8_without_replacement(byte_length),
)
}
/// Query the worst-case output size when encoding from UTF-8 without
/// replacement.
///
/// Returns the size of the output buffer in bytes that will not overflow
/// given the current state of the encoder and `byte_length` number of
/// additional input code units or `None` if `usize` would overflow.
///
/// Available via the C wrapper.
pub fn max_buffer_length_from_utf8_without_replacement(
&self,
byte_length: usize,
) -> Option<usize> {
self.variant
.max_buffer_length_from_utf8_without_replacement(byte_length)
}
/// Incrementally encode into byte stream from UTF-8 with unmappable
/// characters replaced with HTML (decimal) numeric character references.
///
/// See the documentation of the struct for documentation for `encode_*`
/// methods collectively.
///
/// Available via the C wrapper.
pub fn encode_from_utf8(
&mut self,
src: &str,
dst: &mut [u8],
last: bool,
) -> (CoderResult, usize, usize, bool) {
let dst_len = dst.len();
let effective_dst_len = if self.encoding().can_encode_everything() {
dst_len
} else {
if dst_len < NCR_EXTRA {
if src.is_empty() && !(last && self.has_pending_state()) {
return (CoderResult::InputEmpty, 0, 0, false);
}
return (CoderResult::OutputFull, 0, 0, false);
}
dst_len - NCR_EXTRA
};
let mut had_unmappables = false;
let mut total_read = 0usize;
let mut total_written = 0usize;
loop {
let (result, read, written) = self.encode_from_utf8_without_replacement(
&src[total_read..],
&mut dst[total_written..effective_dst_len],
last,
);
total_read += read;
total_written += written;
match result {
EncoderResult::InputEmpty => {
return (
CoderResult::InputEmpty,
total_read,
total_written,
had_unmappables,
);
}
EncoderResult::OutputFull => {
return (
CoderResult::OutputFull,
total_read,
total_written,
had_unmappables,
);
}
EncoderResult::Unmappable(unmappable) => {
had_unmappables = true;
debug_assert!(dst.len() - total_written >= NCR_EXTRA);
debug_assert_ne!(self.encoding(), UTF_16BE);
debug_assert_ne!(self.encoding(), UTF_16LE);
// Additionally, Iso2022JpEncoder is responsible for
// transitioning to ASCII when returning with Unmappable.
total_written += write_ncr(unmappable, &mut dst[total_written..]);
if total_written >= effective_dst_len {
if total_read == src.len() && !(last && self.has_pending_state()) {
return (
CoderResult::InputEmpty,
total_read,
total_written,
had_unmappables,
);
}
return (
CoderResult::OutputFull,
total_read,
total_written,
had_unmappables,
);
}
}
}
}
}
/// Incrementally encode into byte stream from UTF-8 with unmappable
/// characters replaced with HTML (decimal) numeric character references.
///
/// See the documentation of the struct for documentation for `encode_*`
/// methods collectively.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn encode_from_utf8_to_vec(
&mut self,
src: &str,
dst: &mut Vec<u8>,
last: bool,
) -> (CoderResult, usize, bool) {
unsafe {
let old_len = dst.len();
let capacity = dst.capacity();
dst.set_len(capacity);
let (result, read, written, replaced) =
self.encode_from_utf8(src, &mut dst[old_len..], last);
dst.set_len(old_len + written);
(result, read, replaced)
}
}
/// Incrementally encode into byte stream from UTF-8 _without replacement_.
///
/// See the documentation of the struct for documentation for `encode_*`
/// methods collectively.
///
/// Available via the C wrapper.
pub fn encode_from_utf8_without_replacement(
&mut self,
src: &str,
dst: &mut [u8],
last: bool,
) -> (EncoderResult, usize, usize) {
self.variant.encode_from_utf8_raw(src, dst, last)
}
/// Incrementally encode into byte stream from UTF-8 _without replacement_.
///
/// See the documentation of the struct for documentation for `encode_*`
/// methods collectively.
///
/// Available to Rust only and only with the `alloc` feature enabled (enabled
/// by default).
#[cfg(feature = "alloc")]
pub fn encode_from_utf8_to_vec_without_replacement(
&mut self,
src: &str,
dst: &mut Vec<u8>,
last: bool,
) -> (EncoderResult, usize) {
unsafe {
let old_len = dst.len();
let capacity = dst.capacity();
dst.set_len(capacity);
let (result, read, written) =
self.encode_from_utf8_without_replacement(src, &mut dst[old_len..], last);
dst.set_len(old_len + written);
(result, read)
}
}
/// Query the worst-case output size when encoding from UTF-16 with
/// replacement.
///
/// Returns the size of the output buffer in bytes that will not overflow
/// given the current state of the encoder and `u16_length` number of
/// additional input code units if there are no unmappable characters in
/// the input or `None` if `usize` would overflow.
///
/// Available via the C wrapper.
pub fn max_buffer_length_from_utf16_if_no_unmappables(
&self,
u16_length: usize,
) -> Option<usize> {
checked_add(
if self.encoding().can_encode_everything() {
0
} else {
NCR_EXTRA
},
self.max_buffer_length_from_utf16_without_replacement(u16_length),
)
}
/// Query the worst-case output size when encoding from UTF-16 without
/// replacement.
///
/// Returns the size of the output buffer in bytes that will not overflow
/// given the current state of the encoder and `u16_length` number of
/// additional input code units or `None` if `usize` would overflow.
///
/// Available via the C wrapper.
pub fn max_buffer_length_from_utf16_without_replacement(
&self,
u16_length: usize,
) -> Option<usize> {
self.variant
.max_buffer_length_from_utf16_without_replacement(u16_length)
}
/// Incrementally encode into byte stream from UTF-16 with unmappable
/// characters replaced with HTML (decimal) numeric character references.
///
/// See the documentation of the struct for documentation for `encode_*`
/// methods collectively.
///
/// Available via the C wrapper.
pub fn encode_from_utf16(
&mut self,
src: &[u16],
dst: &mut [u8],
last: bool,
) -> (CoderResult, usize, usize, bool) {
let dst_len = dst.len();
let effective_dst_len = if self.encoding().can_encode_everything() {
dst_len
} else {
if dst_len < NCR_EXTRA {
if src.is_empty() && !(last && self.has_pending_state()) {
return (CoderResult::InputEmpty, 0, 0, false);
}
return (CoderResult::OutputFull, 0, 0, false);
}
dst_len - NCR_EXTRA
};
let mut had_unmappables = false;
let mut total_read = 0usize;
let mut total_written = 0usize;
loop {
let (result, read, written) = self.encode_from_utf16_without_replacement(
&src[total_read..],
&mut dst[total_written..effective_dst_len],
last,
);
total_read += read;
total_written += written;
match result {
EncoderResult::InputEmpty => {
return (
CoderResult::InputEmpty,
total_read,
total_written,
had_unmappables,
);
}
EncoderResult::OutputFull => {
return (
CoderResult::OutputFull,
total_read,
total_written,
had_unmappables,
);
}
EncoderResult::Unmappable(unmappable) => {
had_unmappables = true;
debug_assert!(dst.len() - total_written >= NCR_EXTRA);
// There are no UTF-16 encoders and even if there were,
// they'd never have unmappables.
debug_assert_ne!(self.encoding(), UTF_16BE);
debug_assert_ne!(self.encoding(), UTF_16LE);
// Additionally, Iso2022JpEncoder is responsible for
// transitioning to ASCII when returning with Unmappable
// from the jis0208 state. That is, when we encode
// ISO-2022-JP and come here, the encoder is in either the
// ASCII or the Roman state. We are allowed to generate any
// printable ASCII excluding \ and ~.
total_written += write_ncr(unmappable, &mut dst[total_written..]);
if total_written >= effective_dst_len {
if total_read == src.len() && !(last && self.has_pending_state()) {
return (
CoderResult::InputEmpty,
total_read,
total_written,
had_unmappables,
);
}
return (
CoderResult::OutputFull,
total_read,
total_written,
had_unmappables,
);
}
}
}
}
}
/// Incrementally encode into byte stream from UTF-16 _without replacement_.
///
/// See the documentation of the struct for documentation for `encode_*`
/// methods collectively.
///
/// Available via the C wrapper.
pub fn encode_from_utf16_without_replacement(
&mut self,
src: &[u16],
dst: &mut [u8],
last: bool,
) -> (EncoderResult, usize, usize) {
self.variant.encode_from_utf16_raw(src, dst, last)
}
}
/// Format an unmappable as NCR without heap allocation.
fn write_ncr(unmappable: char, dst: &mut [u8]) -> usize {
// len is the number of decimal digits needed to represent unmappable plus
// 3 (the length of "&#" and ";").
let mut number = unmappable as u32;
let len = if number >= 1_000_000u32 {
10usize
} else if number >= 100_000u32 {
9usize
} else if number >= 10_000u32 {
8usize
} else if number >= 1_000u32 {
7usize
} else if number >= 100u32 {
6usize
} else {
// to see if this case is possible
5usize
};
debug_assert!(number >= 10u32);
debug_assert!(len <= dst.len());
let mut pos = len - 1;
dst[pos] = b';';
pos -= 1;
loop {
let rightmost = number % 10;
dst[pos] = rightmost as u8 + b'0';
pos -= 1;
if number < 10 {
break;
}
number /= 10;
}
dst[1] = b'#';
dst[0] = b'&';
len
}
#[inline(always)]
fn in_range16(i: u16, start: u16, end: u16) -> bool {
i.wrapping_sub(start) < (end - start)
}
#[inline(always)]
fn in_range32(i: u32, start: u32, end: u32) -> bool {
i.wrapping_sub(start) < (end - start)
}
#[inline(always)]
fn in_inclusive_range8(i: u8, start: u8, end: u8) -> bool {
i.wrapping_sub(start) <= (end - start)
}
#[inline(always)]
fn in_inclusive_range16(i: u16, start: u16, end: u16) -> bool {
i.wrapping_sub(start) <= (end - start)
}
#[inline(always)]
fn in_inclusive_range32(i: u32, start: u32, end: u32) -> bool {
i.wrapping_sub(start) <= (end - start)
}
#[inline(always)]
fn in_inclusive_range(i: usize, start: usize, end: usize) -> bool {
i.wrapping_sub(start) <= (end - start)
}
#[inline(always)]
fn checked_add(num: usize, opt: Option<usize>) -> Option<usize> {
if let Some(n) = opt {
n.checked_add(num)
} else {
None
}
}
#[inline(always)]
fn checked_add_opt(one: Option<usize>, other: Option<usize>) -> Option<usize> {
if let Some(n) = one {
checked_add(n, other)
} else {
None
}
}
#[inline(always)]
fn checked_mul(num: usize, opt: Option<usize>) -> Option<usize> {
if let Some(n) = opt {
n.checked_mul(num)
} else {
None
}
}
#[inline(always)]
fn checked_div(opt: Option<usize>, num: usize) -> Option<usize> {
if let Some(n) = opt {
n.checked_div(num)
} else {
None
}
}
#[cfg(feature = "alloc")]
#[inline(always)]
fn checked_next_power_of_two(opt: Option<usize>) -> Option<usize> {
opt.map(|n| n.next_power_of_two())
}
#[cfg(feature = "alloc")]
#[inline(always)]
fn checked_min(one: Option<usize>, other: Option<usize>) -> Option<usize> {
if let Some(a) = one {
if let Some(b) = other {
Some(::core::cmp::min(a, b))
} else {
Some(a)
}
} else {
other
}
}
// ############## TESTS ###############
#[cfg(all(test, feature = "serde"))]
#[derive(Serialize, Deserialize, Debug, PartialEq)]
struct Demo {
num: u32,
name: String,
enc: &'static Encoding,
}
#[cfg(test)]
mod test_labels_names;
#[cfg(all(test, feature = "alloc"))]
mod tests {
use super::*;
use alloc::borrow::Cow;
fn sniff_to_utf16(
initial_encoding: &'static Encoding,
expected_encoding: &'static Encoding,
bytes: &[u8],
expect: &[u16],
breaks: &[usize],
) {
let mut decoder = initial_encoding.new_decoder();
let mut dest: Vec<u16> =
Vec::with_capacity(decoder.max_utf16_buffer_length(bytes.len()).unwrap());
let capacity = dest.capacity();
dest.resize(capacity, 0u16);
let mut total_written = 0usize;
let mut start = 0usize;
for br in breaks {
let (result, read, written, _) =
decoder.decode_to_utf16(&bytes[start..*br], &mut dest[total_written..], false);
total_written += written;
assert_eq!(read, *br - start);
match result {
CoderResult::InputEmpty => {}
CoderResult::OutputFull => {
unreachable!();
}
}
start = *br;
}
let (result, read, written, _) =
decoder.decode_to_utf16(&bytes[start..], &mut dest[total_written..], true);
total_written += written;
match result {
CoderResult::InputEmpty => {}
CoderResult::OutputFull => {
unreachable!();
}
}
assert_eq!(read, bytes.len() - start);
assert_eq!(total_written, expect.len());
assert_eq!(&dest[..total_written], expect);
assert_eq!(decoder.encoding(), expected_encoding);
}
// Any copyright to the test code below this comment is dedicated to the
#[test]
fn test_bom_sniffing() {
// ASCII
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\x61\x62",
&[0x0061u16, 0x0062u16],
&[],
);
// UTF-8
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[1],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[2],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[3],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[4],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[2, 3],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[1, 2],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[1, 3],
);
sniff_to_utf16(
WINDOWS_1252,
UTF_8,
b"\xEF\xBB\xBF\x61\x62",
&[0x0061u16, 0x0062u16],
&[1, 2, 3, 4],
);
sniff_to_utf16(WINDOWS_1252, UTF_8, b"\xEF\xBB\xBF", &[], &[]);
// Not UTF-8
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xEF\xBB\x61\x62",
&[0x00EFu16, 0x00BBu16, 0x0061u16, 0x0062u16],
&[],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xEF\xBB\x61\x62",
&[0x00EFu16, 0x00BBu16, 0x0061u16, 0x0062u16],
&[1],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xEF\x61\x62",
&[0x00EFu16, 0x0061u16, 0x0062u16],
&[],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xEF\x61\x62",
&[0x00EFu16, 0x0061u16, 0x0062u16],
&[1],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xEF\xBB",
&[0x00EFu16, 0x00BBu16],
&[],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xEF\xBB",
&[0x00EFu16, 0x00BBu16],
&[1],
);
sniff_to_utf16(WINDOWS_1252, WINDOWS_1252, b"\xEF", &[0x00EFu16], &[]);
// Not UTF-16
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xFE\x61\x62",
&[0x00FEu16, 0x0061u16, 0x0062u16],
&[],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xFE\x61\x62",
&[0x00FEu16, 0x0061u16, 0x0062u16],
&[1],
);
sniff_to_utf16(WINDOWS_1252, WINDOWS_1252, b"\xFE", &[0x00FEu16], &[]);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xFF\x61\x62",
&[0x00FFu16, 0x0061u16, 0x0062u16],
&[],
);
sniff_to_utf16(
WINDOWS_1252,
WINDOWS_1252,
b"\xFF\x61\x62",
&[0x00FFu16, 0x0061u16, 0x0062u16],
&[1],
);
sniff_to_utf16(WINDOWS_1252, WINDOWS_1252, b"\xFF", &[0x00FFu16], &[]);
// UTF-16
sniff_to_utf16(WINDOWS_1252, UTF_16BE, b"\xFE\xFF", &[], &[]);
sniff_to_utf16(WINDOWS_1252, UTF_16BE, b"\xFE\xFF", &[], &[1]);
sniff_to_utf16(WINDOWS_1252, UTF_16LE, b"\xFF\xFE", &[], &[]);
sniff_to_utf16(WINDOWS_1252, UTF_16LE, b"\xFF\xFE", &[], &[1]);
}
#[test]
fn test_output_encoding() {
assert_eq!(REPLACEMENT.output_encoding(), UTF_8);
assert_eq!(UTF_16BE.output_encoding(), UTF_8);
assert_eq!(UTF_16LE.output_encoding(), UTF_8);
assert_eq!(UTF_8.output_encoding(), UTF_8);
assert_eq!(WINDOWS_1252.output_encoding(), WINDOWS_1252);
assert_eq!(REPLACEMENT.new_encoder().encoding(), UTF_8);
assert_eq!(UTF_16BE.new_encoder().encoding(), UTF_8);
assert_eq!(UTF_16LE.new_encoder().encoding(), UTF_8);
assert_eq!(UTF_8.new_encoder().encoding(), UTF_8);
assert_eq!(WINDOWS_1252.new_encoder().encoding(), WINDOWS_1252);
}
#[test]
fn test_label_resolution() {
assert_eq!(Encoding::for_label(b"utf-8"), Some(UTF_8));
assert_eq!(Encoding::for_label(b"UTF-8"), Some(UTF_8));
assert_eq!(
Encoding::for_label(b" \t \n \x0C \n utf-8 \r \n \t \x0C "),
Some(UTF_8)
);
assert_eq!(Encoding::for_label(b"utf-8 _"), None);
assert_eq!(Encoding::for_label(b"bogus"), None);
assert_eq!(Encoding::for_label(b"bogusbogusbogusbogus"), None);
}
#[test]
fn test_decode_valid_windows_1257_to_cow() {
let (cow, encoding, had_errors) = WINDOWS_1257.decode(b"abc\x80\xE4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{00E4}");
}
}
assert_eq!(encoding, WINDOWS_1257);
assert!(!had_errors);
}
#[test]
fn test_decode_invalid_windows_1257_to_cow() {
let (cow, encoding, had_errors) = WINDOWS_1257.decode(b"abc\x80\xA1\xE4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{FFFD}\u{00E4}");
}
}
assert_eq!(encoding, WINDOWS_1257);
assert!(had_errors);
}
#[test]
fn test_decode_ascii_only_windows_1257_to_cow() {
let (cow, encoding, had_errors) = WINDOWS_1257.decode(b"abc");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "abc");
}
Cow::Owned(_) => unreachable!(),
}
assert_eq!(encoding, WINDOWS_1257);
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_valid_utf8_as_windows_1257_to_cow() {
let (cow, encoding, had_errors) = WINDOWS_1257.decode(b"\xEF\xBB\xBF\xE2\x82\xAC\xC3\xA4");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "\u{20AC}\u{00E4}");
}
Cow::Owned(_) => unreachable!(),
}
assert_eq!(encoding, UTF_8);
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_invalid_utf8_as_windows_1257_to_cow() {
let (cow, encoding, had_errors) =
WINDOWS_1257.decode(b"\xEF\xBB\xBF\xE2\x82\xAC\x80\xC3\xA4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "\u{20AC}\u{FFFD}\u{00E4}");
}
}
assert_eq!(encoding, UTF_8);
assert!(had_errors);
}
#[test]
fn test_decode_bomful_valid_utf8_as_utf_8_to_cow() {
let (cow, encoding, had_errors) = UTF_8.decode(b"\xEF\xBB\xBF\xE2\x82\xAC\xC3\xA4");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "\u{20AC}\u{00E4}");
}
Cow::Owned(_) => unreachable!(),
}
assert_eq!(encoding, UTF_8);
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_invalid_utf8_as_utf_8_to_cow() {
let (cow, encoding, had_errors) = UTF_8.decode(b"\xEF\xBB\xBF\xE2\x82\xAC\x80\xC3\xA4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "\u{20AC}\u{FFFD}\u{00E4}");
}
}
assert_eq!(encoding, UTF_8);
assert!(had_errors);
}
#[test]
fn test_decode_bomful_valid_utf8_as_utf_8_to_cow_with_bom_removal() {
let (cow, had_errors) = UTF_8.decode_with_bom_removal(b"\xEF\xBB\xBF\xE2\x82\xAC\xC3\xA4");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "\u{20AC}\u{00E4}");
}
Cow::Owned(_) => unreachable!(),
}
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_valid_utf8_as_windows_1257_to_cow_with_bom_removal() {
let (cow, had_errors) =
WINDOWS_1257.decode_with_bom_removal(b"\xEF\xBB\xBF\xE2\x82\xAC\xC3\xA4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(
s,
"\u{013C}\u{00BB}\u{00E6}\u{0101}\u{201A}\u{00AC}\u{0106}\u{00A4}"
);
}
}
assert!(!had_errors);
}
#[test]
fn test_decode_valid_windows_1257_to_cow_with_bom_removal() {
let (cow, had_errors) = WINDOWS_1257.decode_with_bom_removal(b"abc\x80\xE4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{00E4}");
}
}
assert!(!had_errors);
}
#[test]
fn test_decode_invalid_windows_1257_to_cow_with_bom_removal() {
let (cow, had_errors) = WINDOWS_1257.decode_with_bom_removal(b"abc\x80\xA1\xE4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{FFFD}\u{00E4}");
}
}
assert!(had_errors);
}
#[test]
fn test_decode_ascii_only_windows_1257_to_cow_with_bom_removal() {
let (cow, had_errors) = WINDOWS_1257.decode_with_bom_removal(b"abc");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "abc");
}
Cow::Owned(_) => unreachable!(),
}
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_valid_utf8_to_cow_without_bom_handling() {
let (cow, had_errors) =
UTF_8.decode_without_bom_handling(b"\xEF\xBB\xBF\xE2\x82\xAC\xC3\xA4");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "\u{FEFF}\u{20AC}\u{00E4}");
}
Cow::Owned(_) => unreachable!(),
}
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_invalid_utf8_to_cow_without_bom_handling() {
let (cow, had_errors) =
UTF_8.decode_without_bom_handling(b"\xEF\xBB\xBF\xE2\x82\xAC\x80\xC3\xA4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "\u{FEFF}\u{20AC}\u{FFFD}\u{00E4}");
}
}
assert!(had_errors);
}
#[test]
fn test_decode_valid_windows_1257_to_cow_without_bom_handling() {
let (cow, had_errors) = WINDOWS_1257.decode_without_bom_handling(b"abc\x80\xE4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{00E4}");
}
}
assert!(!had_errors);
}
#[test]
fn test_decode_invalid_windows_1257_to_cow_without_bom_handling() {
let (cow, had_errors) = WINDOWS_1257.decode_without_bom_handling(b"abc\x80\xA1\xE4");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{FFFD}\u{00E4}");
}
}
assert!(had_errors);
}
#[test]
fn test_decode_ascii_only_windows_1257_to_cow_without_bom_handling() {
let (cow, had_errors) = WINDOWS_1257.decode_without_bom_handling(b"abc");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "abc");
}
Cow::Owned(_) => unreachable!(),
}
assert!(!had_errors);
}
#[test]
fn test_decode_bomful_valid_utf8_to_cow_without_bom_handling_and_without_replacement() {
match UTF_8.decode_without_bom_handling_and_without_replacement(
b"\xEF\xBB\xBF\xE2\x82\xAC\xC3\xA4",
) {
Some(cow) => match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "\u{FEFF}\u{20AC}\u{00E4}");
}
Cow::Owned(_) => unreachable!(),
},
None => unreachable!(),
}
}
#[test]
fn test_decode_bomful_invalid_utf8_to_cow_without_bom_handling_and_without_replacement() {
assert!(UTF_8
.decode_without_bom_handling_and_without_replacement(
b"\xEF\xBB\xBF\xE2\x82\xAC\x80\xC3\xA4"
)
.is_none());
}
#[test]
fn test_decode_valid_windows_1257_to_cow_without_bom_handling_and_without_replacement() {
match WINDOWS_1257.decode_without_bom_handling_and_without_replacement(b"abc\x80\xE4") {
Some(cow) => match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, "abc\u{20AC}\u{00E4}");
}
},
None => unreachable!(),
}
}
#[test]
fn test_decode_invalid_windows_1257_to_cow_without_bom_handling_and_without_replacement() {
assert!(WINDOWS_1257
.decode_without_bom_handling_and_without_replacement(b"abc\x80\xA1\xE4")
.is_none());
}
#[test]
fn test_decode_ascii_only_windows_1257_to_cow_without_bom_handling_and_without_replacement() {
match WINDOWS_1257.decode_without_bom_handling_and_without_replacement(b"abc") {
Some(cow) => match cow {
Cow::Borrowed(s) => {
assert_eq!(s, "abc");
}
Cow::Owned(_) => unreachable!(),
},
None => unreachable!(),
}
}
#[test]
fn test_encode_ascii_only_windows_1257_to_cow() {
let (cow, encoding, had_errors) = WINDOWS_1257.encode("abc");
match cow {
Cow::Borrowed(s) => {
assert_eq!(s, b"abc");
}
Cow::Owned(_) => unreachable!(),
}
assert_eq!(encoding, WINDOWS_1257);
assert!(!had_errors);
}
#[test]
fn test_encode_valid_windows_1257_to_cow() {
let (cow, encoding, had_errors) = WINDOWS_1257.encode("abc\u{20AC}\u{00E4}");
match cow {
Cow::Borrowed(_) => unreachable!(),
Cow::Owned(s) => {
assert_eq!(s, b"abc\x80\xE4");
}
}
assert_eq!(encoding, WINDOWS_1257);
assert!(!had_errors);
}
#[test]
fn test_utf16_space_with_one_bom_byte() {
let mut decoder = UTF_16LE.new_decoder();
let mut dst = [0u16; 12];
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF", &mut dst[..needed], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF", &mut dst[..needed], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_utf8_space_with_one_bom_byte() {
let mut decoder = UTF_8.new_decoder();
let mut dst = [0u16; 12];
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF", &mut dst[..needed], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF", &mut dst[..needed], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_utf16_space_with_two_bom_bytes() {
let mut decoder = UTF_16LE.new_decoder();
let mut dst = [0u16; 12];
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xEF", &mut dst[..needed], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xBB", &mut dst[..needed], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF", &mut dst[..needed], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_utf8_space_with_two_bom_bytes() {
let mut decoder = UTF_8.new_decoder();
let mut dst = [0u16; 12];
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xEF", &mut dst[..needed], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xBB", &mut dst[..needed], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let needed = decoder.max_utf16_buffer_length(1).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF", &mut dst[..needed], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_utf16_space_with_one_bom_byte_and_a_second_byte_in_same_call() {
let mut decoder = UTF_16LE.new_decoder();
let mut dst = [0u16; 12];
{
let needed = decoder.max_utf16_buffer_length(2).unwrap();
let (result, _, _, _) = decoder.decode_to_utf16(b"\xFF\xFF", &mut dst[..needed], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_too_short_buffer_with_iso_2022_jp_ascii_from_utf8() {
let mut dst = [0u8; 8];
let mut encoder = ISO_2022_JP.new_encoder();
{
let (result, _, _, _) = encoder.encode_from_utf8("", &mut dst[..], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let (result, _, _, _) = encoder.encode_from_utf8("", &mut dst[..], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_too_short_buffer_with_iso_2022_jp_roman_from_utf8() {
let mut dst = [0u8; 16];
let mut encoder = ISO_2022_JP.new_encoder();
{
let (result, _, _, _) = encoder.encode_from_utf8("\u{A5}", &mut dst[..], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let (result, _, _, _) = encoder.encode_from_utf8("", &mut dst[..8], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let (result, _, _, _) = encoder.encode_from_utf8("", &mut dst[..8], true);
assert_eq!(result, CoderResult::OutputFull);
}
}
#[test]
fn test_buffer_end_iso_2022_jp_from_utf8() {
let mut dst = [0u8; 18];
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf8("\u{A5}\u{1F4A9}", &mut dst[..], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) = encoder.encode_from_utf8("\u{A5}\u{1F4A9}", &mut dst[..], true);
assert_eq!(result, CoderResult::OutputFull);
}
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) = encoder.encode_from_utf8("\u{1F4A9}", &mut dst[..13], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) = encoder.encode_from_utf8("\u{1F4A9}", &mut dst[..13], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_too_short_buffer_with_iso_2022_jp_ascii_from_utf16() {
let mut dst = [0u8; 8];
let mut encoder = ISO_2022_JP.new_encoder();
{
let (result, _, _, _) = encoder.encode_from_utf16(&[0u16; 0], &mut dst[..], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let (result, _, _, _) = encoder.encode_from_utf16(&[0u16; 0], &mut dst[..], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_too_short_buffer_with_iso_2022_jp_roman_from_utf16() {
let mut dst = [0u8; 16];
let mut encoder = ISO_2022_JP.new_encoder();
{
let (result, _, _, _) = encoder.encode_from_utf16(&[0xA5u16], &mut dst[..], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let (result, _, _, _) = encoder.encode_from_utf16(&[0u16; 0], &mut dst[..8], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let (result, _, _, _) = encoder.encode_from_utf16(&[0u16; 0], &mut dst[..8], true);
assert_eq!(result, CoderResult::OutputFull);
}
}
#[test]
fn test_buffer_end_iso_2022_jp_from_utf16() {
let mut dst = [0u8; 18];
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf16(&[0xA5u16, 0xD83Du16, 0xDCA9u16], &mut dst[..], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf16(&[0xA5u16, 0xD83Du16, 0xDCA9u16], &mut dst[..], true);
assert_eq!(result, CoderResult::OutputFull);
}
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf16(&[0xD83Du16, 0xDCA9u16], &mut dst[..13], false);
assert_eq!(result, CoderResult::InputEmpty);
}
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf16(&[0xD83Du16, 0xDCA9u16], &mut dst[..13], true);
assert_eq!(result, CoderResult::InputEmpty);
}
}
#[test]
fn test_buffer_end_utf16be() {
let mut decoder = UTF_16BE.new_decoder_without_bom_handling();
let mut dest = [0u8; 4];
assert_eq!(
decoder.decode_to_utf8(&[0xD8, 0x00], &mut dest, false),
(CoderResult::InputEmpty, 2, 0, false)
);
let _ = decoder.decode_to_utf8(&[0xD8, 0x00], &mut dest, true);
}
#[test]
fn test_hash() {
let mut encodings = ::alloc::collections::btree_set::BTreeSet::new();
encodings.insert(UTF_8);
encodings.insert(ISO_2022_JP);
assert!(encodings.contains(UTF_8));
assert!(encodings.contains(ISO_2022_JP));
assert!(!encodings.contains(WINDOWS_1252));
encodings.remove(ISO_2022_JP);
assert!(!encodings.contains(ISO_2022_JP));
}
#[test]
fn test_iso_2022_jp_ncr_extra_from_utf16() {
let mut dst = [0u8; 17];
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf16(&[0x3041u16, 0xFFFFu16], &mut dst[..], true);
assert_eq!(result, CoderResult::OutputFull);
}
}
#[test]
fn test_iso_2022_jp_ncr_extra_from_utf8() {
let mut dst = [0u8; 17];
{
let mut encoder = ISO_2022_JP.new_encoder();
let (result, _, _, _) =
encoder.encode_from_utf8("\u{3041}\u{FFFF}", &mut dst[..], true);
assert_eq!(result, CoderResult::OutputFull);
}
}
#[test]
fn test_max_length_with_bom_to_utf8() {
let mut output = [0u8; 20];
let mut decoder = REPLACEMENT.new_decoder();
let input = b"\xEF\xBB\xBFA";
{
let needed = decoder
.max_utf8_buffer_length_without_replacement(input.len())
.unwrap();
let (result, read, written) =
decoder.decode_to_utf8_without_replacement(input, &mut output[..needed], true);
assert_eq!(result, DecoderResult::InputEmpty);
assert_eq!(read, input.len());
assert_eq!(written, 1);
assert_eq!(output[0], 0x41);
}
}
#[cfg(feature = "serde")]
#[test]
fn test_serde() {
let demo = Demo {
num: 42,
name: "foo".into(),
enc: UTF_8,
};
let serialized = serde_json::to_string(&demo).unwrap();
let deserialized: Demo = serde_json::from_str(&serialized).unwrap();
assert_eq!(deserialized, demo);
let bincoded = bincode::serialize(&demo).unwrap();
let debincoded: Demo = bincode::deserialize(&bincoded[..]).unwrap();
assert_eq!(debincoded, demo);
}
#[test]
fn test_is_single_byte() {
assert!(!BIG5.is_single_byte());
assert!(!EUC_JP.is_single_byte());
assert!(!EUC_KR.is_single_byte());
assert!(!GB18030.is_single_byte());
assert!(!GBK.is_single_byte());
assert!(!REPLACEMENT.is_single_byte());
assert!(!SHIFT_JIS.is_single_byte());
assert!(!UTF_8.is_single_byte());
assert!(!UTF_16BE.is_single_byte());
assert!(!UTF_16LE.is_single_byte());
assert!(!ISO_2022_JP.is_single_byte());
assert!(IBM866.is_single_byte());
assert!(ISO_8859_2.is_single_byte());
assert!(ISO_8859_3.is_single_byte());
assert!(ISO_8859_4.is_single_byte());
assert!(ISO_8859_5.is_single_byte());
assert!(ISO_8859_6.is_single_byte());
assert!(ISO_8859_7.is_single_byte());
assert!(ISO_8859_8.is_single_byte());
assert!(ISO_8859_10.is_single_byte());
assert!(ISO_8859_13.is_single_byte());
assert!(ISO_8859_14.is_single_byte());
assert!(ISO_8859_15.is_single_byte());
assert!(ISO_8859_16.is_single_byte());
assert!(ISO_8859_8_I.is_single_byte());
assert!(KOI8_R.is_single_byte());
assert!(KOI8_U.is_single_byte());
assert!(MACINTOSH.is_single_byte());
assert!(WINDOWS_874.is_single_byte());
assert!(WINDOWS_1250.is_single_byte());
assert!(WINDOWS_1251.is_single_byte());
assert!(WINDOWS_1252.is_single_byte());
assert!(WINDOWS_1253.is_single_byte());
assert!(WINDOWS_1254.is_single_byte());
assert!(WINDOWS_1255.is_single_byte());
assert!(WINDOWS_1256.is_single_byte());
assert!(WINDOWS_1257.is_single_byte());
assert!(WINDOWS_1258.is_single_byte());
assert!(X_MAC_CYRILLIC.is_single_byte());
assert!(X_USER_DEFINED.is_single_byte());
}
#[test]
fn test_latin1_byte_compatible_up_to() {
let buffer = b"a\x81\xB6\xF6\xF0\x82\xB4";
assert_eq!(
BIG5.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
EUC_JP
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
EUC_KR
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
GB18030
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
GBK.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert!(REPLACEMENT
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.is_none());
assert_eq!(
SHIFT_JIS
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
UTF_8
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert!(UTF_16BE
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.is_none());
assert!(UTF_16LE
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.is_none());
assert_eq!(
ISO_2022_JP
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
IBM866
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
ISO_8859_2
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_3
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_4
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_5
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_6
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_7
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_8
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
3
);
assert_eq!(
ISO_8859_10
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
ISO_8859_13
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
ISO_8859_14
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
ISO_8859_15
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
6
);
assert_eq!(
ISO_8859_16
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
ISO_8859_8_I
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
3
);
assert_eq!(
KOI8_R
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
KOI8_U
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
MACINTOSH
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
WINDOWS_874
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
2
);
assert_eq!(
WINDOWS_1250
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
WINDOWS_1251
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
WINDOWS_1252
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
5
);
assert_eq!(
WINDOWS_1253
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
3
);
assert_eq!(
WINDOWS_1254
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
WINDOWS_1255
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
3
);
assert_eq!(
WINDOWS_1256
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
WINDOWS_1257
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
WINDOWS_1258
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
4
);
assert_eq!(
X_MAC_CYRILLIC
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert_eq!(
X_USER_DEFINED
.new_decoder_without_bom_handling()
.latin1_byte_compatible_up_to(buffer)
.unwrap(),
1
);
assert!(UTF_8
.new_decoder()
.latin1_byte_compatible_up_to(buffer)
.is_none());
let mut decoder = UTF_8.new_decoder();
let mut output = [0u16; 4];
let _ = decoder.decode_to_utf16(b"\xEF", &mut output, false);
assert!(decoder.latin1_byte_compatible_up_to(buffer).is_none());
let _ = decoder.decode_to_utf16(b"\xBB\xBF", &mut output, false);
assert_eq!(decoder.latin1_byte_compatible_up_to(buffer), Some(1));
let _ = decoder.decode_to_utf16(b"\xEF", &mut output, false);
assert_eq!(decoder.latin1_byte_compatible_up_to(buffer), None);
}
}