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-rw-r--r--vendor/encode_unicode/src/decoding_iterators.rs494
-rw-r--r--vendor/encode_unicode/src/errors.rs289
-rw-r--r--vendor/encode_unicode/src/lib.rs78
-rw-r--r--vendor/encode_unicode/src/traits.rs1014
-rw-r--r--vendor/encode_unicode/src/utf16_char.rs687
-rw-r--r--vendor/encode_unicode/src/utf16_iterators.rs270
-rw-r--r--vendor/encode_unicode/src/utf8_char.rs647
-rw-r--r--vendor/encode_unicode/src/utf8_iterators.rs352
8 files changed, 3831 insertions, 0 deletions
diff --git a/vendor/encode_unicode/src/decoding_iterators.rs b/vendor/encode_unicode/src/decoding_iterators.rs
new file mode 100644
index 0000000..4ef4125
--- /dev/null
+++ b/vendor/encode_unicode/src/decoding_iterators.rs
@@ -0,0 +1,494 @@
+/* Copyright 2018 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+//! Iterators that turn multiple `u8`s or `u16`s into `Utf*Char`s, but can fail.
+//!
+//! To be predictable, all errors consume one element each.
+//!
+//! The iterator adaptors produce neither offset nor element length to work
+//! well with other adaptors,
+//! while the slice iterators yield both to make more advanced use cases easy.
+
+use errors::{InvalidUtf8Slice, InvalidUtf16FirstUnit, Utf16PairError};
+use errors::InvalidUtf8Slice::*;
+use errors::InvalidUtf8::*;
+use errors::InvalidUtf8FirstByte::*;
+use errors::InvalidUtf16Slice::*;
+use errors::InvalidCodepoint::*;
+use errors::Utf16PairError::*;
+use utf8_char::Utf8Char;
+use utf16_char::Utf16Char;
+use traits::U16UtfExt;
+extern crate core;
+use self::core::borrow::Borrow;
+use self::core::fmt::{self, Debug};
+use self::core::iter::Chain;
+use self::core::option;
+
+
+/// Decodes UTF-8 characters from a byte iterator into `Utf8Char`s.
+///
+/// See [`IterExt::to_utf8chars()`](../trait.IterExt.html#tymethod.to_utf8chars)
+/// for examples and error handling.
+#[derive(Clone, Default)]
+pub struct Utf8CharMerger<B:Borrow<u8>, I:Iterator<Item=B>> {
+ iter: I,
+ /// number of bytes that were read before an error was detected
+ after_err_leftover: u8,
+ /// stack because it simplifies popping.
+ after_err_stack: [u8; 3],
+}
+impl<B:Borrow<u8>, I:Iterator<Item=B>, T:IntoIterator<IntoIter=I,Item=B>>
+From<T> for Utf8CharMerger<B, I> {
+ fn from(t: T) -> Self {
+ Utf8CharMerger {
+ iter: t.into_iter(),
+ after_err_leftover: 0,
+ after_err_stack: [0; 3],
+ }
+ }
+}
+impl<B:Borrow<u8>, I:Iterator<Item=B>> Utf8CharMerger<B,I> {
+ /// Extract the inner iterator.
+ ///
+ /// If the last item produced by `.next()` was an `Err`,
+ /// up to three following bytes might be missing.
+ /// The exact number of missing bytes for each error type should not be relied on.
+ ///
+ /// # Examples
+ ///
+ /// Three bytes swallowed:
+ /// ```
+ /// # use encode_unicode::IterExt;
+ /// let mut merger = b"\xf4\xa1\xb2FS".iter().to_utf8chars();
+ /// assert!(merger.next().unwrap().is_err());
+ /// let mut inner: std::slice::Iter<u8> = merger.into_inner();
+ /// assert_eq!(inner.next(), Some(&b'S')); // b'\xa1', b'\xb2' and b'F' disappeared
+ /// ```
+ ///
+ /// All bytes present:
+ /// ```
+ /// # use encode_unicode::IterExt;
+ /// let mut merger = b"\xb0FS".iter().to_utf8chars();
+ /// assert!(merger.next().unwrap().is_err());
+ /// assert_eq!(merger.into_inner().next(), Some(&b'F'));
+ /// ```
+ ///
+ /// Two bytes missing:
+ /// ```
+ /// # use encode_unicode::IterExt;
+ /// let mut merger = b"\xe0\x80\x80FS".iter().to_utf8chars();
+ /// assert!(merger.next().unwrap().is_err());
+ /// assert_eq!(merger.into_inner().next(), Some(&b'F'));
+ /// ```
+ pub fn into_inner(self) -> I {
+ self.iter
+ }
+
+ fn save(&mut self, bytes: &[u8;4], len: usize) {
+ // forget bytes[0] and push the others onto self.after_err_stack (in reverse).
+ for &after_err in bytes[1..len].iter().rev() {
+ self.after_err_stack[self.after_err_leftover as usize] = after_err;
+ self.after_err_leftover += 1;
+ }
+ }
+ /// Reads len-1 bytes into bytes[1..]
+ fn extra(&mut self, bytes: &mut[u8;4], len: usize) -> Result<(),InvalidUtf8Slice> {
+ // This is the only function that pushes onto after_err_stack,
+ // and it checks that all bytes are continuation bytes before fetching the next one.
+ // Therefore only the last byte retrieved can be a non-continuation byte.
+ // That last byte is also the last to be retrieved from after_err.
+ //
+ // Before this function is called, there has been retrieved at least one byte.
+ // If that byte was a continuation byte, next() produces an error
+ // and won't call this function.
+ // Therefore, we know that after_err is empty at this point.
+ // This means that we can use self.iter directly, and knows where to start pushing
+ debug_assert_eq!(self.after_err_leftover, 0, "first: {:#02x}, stack: {:?}", bytes[0], self.after_err_stack);
+ for i in 1..len {
+ if let Some(extra) = self.iter.next() {
+ let extra = *extra.borrow();
+ bytes[i] = extra;
+ if extra & 0b1100_0000 != 0b1000_0000 {
+ // not a continuation byte
+ self.save(bytes, i+1);
+ return Err(InvalidUtf8Slice::Utf8(NotAContinuationByte(i)))
+ }
+ } else {
+ self.save(bytes, i);
+ return Err(TooShort(len));
+ }
+ }
+ Ok(())
+ }
+}
+impl<B:Borrow<u8>, I:Iterator<Item=B>> Iterator for Utf8CharMerger<B,I> {
+ type Item = Result<Utf8Char,InvalidUtf8Slice>;
+ fn next(&mut self) -> Option<Self::Item> {
+ let first: u8;
+ if self.after_err_leftover != 0 {
+ self.after_err_leftover -= 1;
+ first = self.after_err_stack[self.after_err_leftover as usize];
+ } else if let Some(next) = self.iter.next() {
+ first = *next.borrow();
+ } else {
+ return None;
+ }
+
+ unsafe {
+ let mut bytes = [first, 0, 0, 0];
+ let ok = match first {
+ 0b0000_0000...0b0111_1111 => {/*1 and */Ok(())},
+ 0b1100_0010...0b1101_1111 => {//2 and not overlong
+ self.extra(&mut bytes, 2) // no extra validation required
+ },
+ 0b1110_0000...0b1110_1111 => {//3
+ if let Err(e) = self.extra(&mut bytes, 3) {
+ Err(e)
+ } else if bytes[0] == 0b1110_0000 && bytes[1] <= 0b10_011111 {
+ self.save(&bytes, 3);
+ Err(Utf8(OverLong))
+ } else if bytes[0] == 0b1110_1101 && bytes[1] & 0b11_100000 == 0b10_100000 {
+ self.save(&bytes, 3);
+ Err(Codepoint(Utf16Reserved))
+ } else {
+ Ok(())
+ }
+ },
+ 0b1111_0000...0b1111_0100 => {//4
+ if let Err(e) = self.extra(&mut bytes, 4) {
+ Err(e)
+ } else if bytes[0] == 0b11110_000 && bytes[1] <= 0b10_001111 {
+ self.save(&bytes, 4);
+ Err(InvalidUtf8Slice::Utf8(OverLong))
+ } else if bytes[0] == 0b11110_100 && bytes[1] > 0b10_001111 {
+ self.save(&bytes, 4);
+ Err(InvalidUtf8Slice::Codepoint(TooHigh))
+ } else {
+ Ok(())
+ }
+ },
+ 0b1000_0000...0b1011_1111 => {// continuation byte
+ Err(Utf8(FirstByte(ContinuationByte)))
+ },
+ 0b1100_0000...0b1100_0001 => {// 2 and overlong
+ Err(Utf8(OverLong))
+ },
+ 0b1111_0101...0b1111_0111 => {// 4 and too high codepoint
+ Err(Codepoint(TooHigh))
+ },
+ 0b1111_1000...0b1111_1111 => {
+ Err(Utf8(FirstByte(TooLongSeqence)))
+ },
+ _ => unreachable!("all possible byte values should be covered")
+ };
+ Some(ok.map(|()| Utf8Char::from_array_unchecked(bytes) ))
+ }
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ let (iter_min, iter_max) = self.iter.size_hint();
+ // cannot be exact, so KISS
+ let min = iter_min / 4; // don't bother rounding up or accounting for after_err
+ // handle edge case of max > usize::MAX-3 just in case.
+ // Using wrapping_add() wouldn't violate any API contract as the trait isn't unsafe.
+ let max = iter_max.and_then(|max| {
+ max.checked_add(self.after_err_leftover as usize)
+ });
+ (min, max)
+ }
+}
+impl<B:Borrow<u8>, I:Iterator<Item=B>+Debug> Debug for Utf8CharMerger<B,I> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ let mut in_order = [0u8; 3];
+ for i in 0..self.after_err_leftover as usize {
+ in_order[i] = self.after_err_stack[self.after_err_leftover as usize - i - 1];
+ }
+ fmtr.debug_struct("Utf8CharMerger")
+ .field("buffered", &&in_order[..self.after_err_leftover as usize])
+ .field("inner", &self.iter)
+ .finish()
+ }
+}
+
+
+/// An [`Utf8CharMerger`](struct.Utf8CharMerger.html) that also produces
+/// offsets and lengths, but can only iterate over slices.
+///
+/// See [`SliceExt::utf8char_indices()`](../trait.SliceExt.html#tymethod.utf8char_indices)
+/// for examples and error handling.
+#[derive(Clone, Default)]
+pub struct Utf8CharDecoder<'a> {
+ slice: &'a[u8],
+ index: usize,
+}
+impl<'a> From<&'a[u8]> for Utf8CharDecoder<'a> {
+ fn from(s: &[u8]) -> Utf8CharDecoder {
+ Utf8CharDecoder { slice: s, index: 0 }
+ }
+}
+impl<'a> Utf8CharDecoder<'a> {
+ /// Extract the remainder of the source slice.
+ ///
+ /// # Examples
+ ///
+ /// Unlike `Utf8CharMerger::into_inner()`, bytes directly after an error
+ /// are never swallowed:
+ /// ```
+ /// # use encode_unicode::SliceExt;
+ /// let mut iter = b"\xf4\xa1\xb2FS".utf8char_indices();
+ /// assert!(iter.next().unwrap().1.is_err());
+ /// assert_eq!(iter.as_slice(), b"\xa1\xb2FS");
+ /// ```
+ pub fn as_slice(&self) -> &'a[u8] {
+ &self.slice[self.index..]
+ }
+}
+impl<'a> Iterator for Utf8CharDecoder<'a> {
+ type Item = (usize, Result<Utf8Char,InvalidUtf8Slice>, usize);
+ fn next(&mut self) -> Option<Self::Item> {
+ let start = self.index;
+ match Utf8Char::from_slice_start(&self.slice[self.index..]) {
+ Ok((u8c, len)) => {
+ self.index += len;
+ Some((start, Ok(u8c), len))
+ },
+ Err(TooShort(1)) => None,
+ Err(e) => {
+ self.index += 1;
+ Some((start, Err(e), 1))
+ }
+ }
+ }
+ #[inline]
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ let bytes = self.slice.len() - self.index;
+ // Cannot be exact, so KISS and don't bother rounding up.
+ // The slice is unlikely be full of 4-byte codepoints, so buffers
+ // allocated with the lower bound will have to be grown anyway.
+ (bytes/4, Some(bytes))
+ }
+}
+impl<'a> DoubleEndedIterator for Utf8CharDecoder<'a> {
+ fn next_back(&mut self) -> Option<Self::Item> {
+ if self.index < self.slice.len() {
+ let extras = self.slice.iter()
+ .rev()
+ .take_while(|&b| b & 0b1100_0000 == 0b1000_0000 )
+ .count();
+ let starts = self.slice.len() - (extras+1);
+ match Utf8Char::from_slice_start(&self.slice[starts..]) {
+ Ok((u8c,len)) if len == 1+extras => {
+ self.slice = &self.slice[..starts];
+ Some((starts, Ok(u8c), len))
+ },
+ // This enures errors for every byte in both directions,
+ // but means overlong and codepoint errors will be turned into
+ // tooshort errors.
+ Err(e) if extras == 0 => {
+ self.slice = &self.slice[..self.slice.len()-1];
+ Some((self.slice.len()-1, Err(e), 1))
+ },
+ _ => {
+ self.slice = &self.slice[..self.slice.len()-1];
+ Some((self.slice.len()-1, Err(Utf8(FirstByte(ContinuationByte))), 1))
+ },
+ }
+ } else {
+ None
+ }
+ }
+}
+impl<'a> Debug for Utf8CharDecoder<'a> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ write!(fmtr, "Utf8CharDecoder {{ bytes[{}..]: {:?} }}", self.index, self.as_slice())
+ }
+}
+
+
+
+/// Decodes UTF-16 characters from a `u16` iterator into `Utf16Char`s.
+///
+/// See [`IterExt::to_utf16chars()`](../trait.IterExt.html#tymethod.to_utf16chars)
+/// for examples and error handling.
+#[derive(Clone, Default)]
+pub struct Utf16CharMerger<B:Borrow<u16>, I:Iterator<Item=B>> {
+ iter: I,
+ /// Used when a trailing surrogate was expected, the u16 can be any value.
+ prev: Option<B>,
+}
+impl<B:Borrow<u16>, I:Iterator<Item=B>, T:IntoIterator<IntoIter=I,Item=B>>
+From<T> for Utf16CharMerger<B,I> {
+ fn from(t: T) -> Self {
+ Utf16CharMerger { iter: t.into_iter(), prev: None }
+ }
+}
+impl<B:Borrow<u16>, I:Iterator<Item=B>> Utf16CharMerger<B,I> {
+ /// Extract the inner iterator.
+ ///
+ /// If the last item produced was an `Err`, the first unit might be missing.
+ ///
+ /// # Examples
+ ///
+ /// Unit right after an error missing
+ /// ```
+ /// # use encode_unicode::IterExt;
+ /// # use encode_unicode::error::Utf16PairError;
+ /// let mut merger = [0xd901, 'F' as u16, 'S' as u16].iter().to_utf16chars();
+ /// assert_eq!(merger.next(), Some(Err(Utf16PairError::UnmatchedLeadingSurrogate)));
+ /// let mut inner: std::slice::Iter<u16> = merger.into_inner();
+ /// assert_eq!(inner.next(), Some('S' as u16).as_ref()); // 'F' was consumed by Utf16CharMerger
+ /// ```
+ ///
+ /// Error that doesn't swallow any units
+ /// ```
+ /// # use encode_unicode::IterExt;
+ /// # use encode_unicode::error::Utf16PairError;
+ /// let mut merger = [0xde00, 'F' as u16, 'S' as u16].iter().to_utf16chars();
+ /// assert_eq!(merger.next(), Some(Err(Utf16PairError::UnexpectedTrailingSurrogate)));
+ /// let mut inner: std::slice::Iter<u16> = merger.into_inner();
+ /// assert_eq!(inner.next(), Some('F' as u16).as_ref()); // not consumed
+ /// ```
+ pub fn into_inner(self) -> I {
+ self.iter
+ }
+ /// Returns an iterator over the remaining units.
+ /// Unlike `into_inner()` this will never drop any units.
+ ///
+ /// The exact type of the returned iterator should not be depended on.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// # use encode_unicode::IterExt;
+ /// # use encode_unicode::error::Utf16PairError;
+ /// let slice = [0xd901, 'F' as u16, 'S' as u16];
+ /// let mut merger = slice.iter().to_utf16chars();
+ /// assert_eq!(merger.next(), Some(Err(Utf16PairError::UnmatchedLeadingSurrogate)));
+ /// let mut remaining = merger.into_remaining_units();
+ /// assert_eq!(remaining.next(), Some('F' as u16).as_ref());
+ /// ```
+ pub fn into_remaining_units(self) -> Chain<option::IntoIter<B>,I> {
+ self.prev.into_iter().chain(self.iter)
+ }
+}
+impl<B:Borrow<u16>, I:Iterator<Item=B>> Iterator for Utf16CharMerger<B,I> {
+ type Item = Result<Utf16Char,Utf16PairError>;
+ fn next(&mut self) -> Option<Self::Item> {
+ let first = self.prev.take().or_else(|| self.iter.next() );
+ first.map(|first| unsafe {
+ match first.borrow().utf16_needs_extra_unit() {
+ Ok(false) => Ok(Utf16Char::from_array_unchecked([*first.borrow(), 0])),
+ Ok(true) => match self.iter.next() {
+ Some(second) => match second.borrow().utf16_needs_extra_unit() {
+ Err(InvalidUtf16FirstUnit) => Ok(Utf16Char::from_tuple_unchecked((
+ *first.borrow(),
+ Some(*second.borrow())
+ ))),
+ Ok(_) => {
+ self.prev = Some(second);
+ Err(Utf16PairError::UnmatchedLeadingSurrogate)
+ }
+ },
+ None => Err(Utf16PairError::Incomplete)
+ },
+ Err(InvalidUtf16FirstUnit) => Err(Utf16PairError::UnexpectedTrailingSurrogate),
+ }
+ })
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ let (iter_min, iter_max) = self.iter.size_hint();
+ // cannot be exact, so KISS
+ let min = iter_min / 2; // don't bother rounding up or accounting for self.prev
+ let max = match (iter_max, &self.prev) {
+ (Some(max), &Some(_)) => max.checked_add(1),
+ (max, _) => max,
+ };
+ (min, max)
+ }
+}
+impl<B:Borrow<u16>, I:Iterator<Item=B>+Debug> Debug for Utf16CharMerger<B,I> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmtr.debug_struct("Utf16CharMerger")
+ .field("buffered", &self.prev.as_ref().map(|b| *b.borrow() ))
+ .field("inner", &self.iter)
+ .finish()
+ }
+}
+
+
+/// An [`Utf16CharMerger`](struct.Utf16CharMerger.html) that also produces
+/// offsets and lengths, but can only iterate over slices.
+///
+/// See [`SliceExt::utf16char_indices()`](../trait.SliceExt.html#tymethod.utf16char_indices)
+/// for examples and error handling.
+#[derive(Clone, Default)]
+pub struct Utf16CharDecoder<'a> {
+ slice: &'a[u16],
+ index: usize,
+}
+impl<'a> From<&'a[u16]> for Utf16CharDecoder<'a> {
+ fn from(s: &'a[u16]) -> Self {
+ Utf16CharDecoder{ slice: s, index: 0 }
+ }
+}
+impl<'a> Utf16CharDecoder<'a> {
+ /// Extract the remainder of the source slice.
+ ///
+ /// # Examples
+ ///
+ /// Unlike `Utf16CharMerger::into_inner()`, the unit after an error is never swallowed:
+ /// ```
+ /// # use encode_unicode::SliceExt;
+ /// # use encode_unicode::error::Utf16PairError;
+ /// let mut iter = [0xd901, 'F' as u16, 'S' as u16].utf16char_indices();
+ /// assert_eq!(iter.next(), Some((0, Err(Utf16PairError::UnmatchedLeadingSurrogate), 1)));
+ /// assert_eq!(iter.as_slice(), &['F' as u16, 'S' as u16]);
+ /// ```
+ pub fn as_slice(&self) -> &[u16] {
+ &self.slice[self.index..]
+ }
+}
+impl<'a> Iterator for Utf16CharDecoder<'a> {
+ type Item = (usize,Result<Utf16Char,Utf16PairError>,usize);
+ #[inline]
+ fn next(&mut self) -> Option<Self::Item> {
+ let start = self.index;
+ match Utf16Char::from_slice_start(self.as_slice()) {
+ Ok((u16c,len)) => {
+ self.index += len;
+ Some((start, Ok(u16c), len))
+ },
+ Err(EmptySlice) => None,
+ Err(FirstLowSurrogate) => {
+ self.index += 1;
+ Some((start, Err(UnexpectedTrailingSurrogate), 1))
+ },
+ Err(SecondNotLowSurrogate) => {
+ self.index += 1;
+ Some((start, Err(UnmatchedLeadingSurrogate), 1))
+ },
+ Err(MissingSecond) => {
+ self.index = self.slice.len();
+ Some((start, Err(Incomplete), 1))
+ }
+ }
+ }
+ #[inline]
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ let units = self.slice.len() - self.index;
+ // Cannot be exact, so KISS and don't bother rounding up.
+ // The slice is unlikely be full of surrogate pairs, so buffers
+ // allocated with the lower bound will have to be grown anyway.
+ (units/2, Some(units))
+ }
+}
+impl<'a> Debug for Utf16CharDecoder<'a> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ write!(fmtr, "Utf16CharDecoder {{ units[{}..]: {:?} }}", self.index, self.as_slice())
+ }
+}
diff --git a/vendor/encode_unicode/src/errors.rs b/vendor/encode_unicode/src/errors.rs
new file mode 100644
index 0000000..fb587fa
--- /dev/null
+++ b/vendor/encode_unicode/src/errors.rs
@@ -0,0 +1,289 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+
+//! Boilerplatey error types
+
+extern crate core;
+use self::core::fmt::{self,Display,Formatter};
+#[cfg(feature="std")]
+use std::error::Error;
+
+
+macro_rules! description {($err:ty, $desc:expr) => {
+ #[cfg(not(feature="std"))]
+ impl $err {
+ #[allow(missing_docs)]
+ pub fn description(&self) -> &'static str {
+ ($desc)(self)
+ }
+ }
+ #[cfg(feature="std")]
+ impl Error for $err {
+ fn description(&self) -> &'static str {
+ ($desc)(self)
+ }
+ }
+ impl Display for $err {
+ fn fmt(&self, fmtr: &mut Formatter) -> fmt::Result {
+ write!(fmtr, "{}", self.description())
+ }
+ }
+}}
+
+
+macro_rules! single_cause {(#[$doc1:meta] #[$doc2:meta] $err:ident => $desc:expr) => {
+ // Rust 1.15 doesn't understand $(#[$doc:meta])* $:ident
+ #[$doc1]
+ #[$doc2]
+ #[derive(Clone,Copy, Debug, PartialEq,Eq)]
+ pub struct $err;
+ description!{$err, |_| $desc }
+}}
+
+
+single_cause!{
+ /// Cannot tell whether an `u16` needs an extra unit,
+ /// because it's a trailing surrogate itself.
+ InvalidUtf16FirstUnit => "is a trailing surrogate"
+}
+
+single_cause!{
+ /// Cannot create an `Utf8Char` or `Utf16Char` from the first codepoint of a str,
+ /// because there are none.
+ EmptyStrError => "is empty"
+}
+
+single_cause!{
+ /// Cannot create an `Utf8Char` from a standalone `u8`
+ /// that is not an ASCII character.
+ NonAsciiError => "is not an ASCII character"
+}
+
+single_cause!{
+ /// Cannot create an `Utf16Char` from a standalone `u16` that is not a
+ /// codepoint in the basic multilingual plane, but part of a suurrogate pair.
+ NonBMPError => "is not a codepoint in the basic multilingual plane"
+}
+
+
+
+macro_rules! simple {(#[$tydoc:meta] $err:ident {
+ $($(#[$vardoc:meta])* ::$variant:ident => $string:expr),+,
+ } ) => {
+ #[$tydoc]
+ #[derive(Clone,Copy, Debug, PartialEq,Eq)]
+ pub enum $err {
+ $($(#[$vardoc])* $variant),*
+ }
+ description!{$err, |e: &$err| match *e {$($err::$variant=>$string),*} }
+}}
+
+
+simple!{/// Reasons why an `u32` is not a valid UTF codepoint.
+ InvalidCodepoint {
+ /// It's reserved for UTF-16 surrogate pairs."
+ ::Utf16Reserved => "is reserved for UTF-16 surrogate pairs",
+ /// It's higher than the highest codepoint (which is 0x10ffff).
+ ::TooHigh => "is higher than the highest codepoint",
+ }}
+use self::InvalidCodepoint::*;
+impl InvalidCodepoint {
+ /// Get the range of values for which this error would be given.
+ pub fn error_range(self) -> (u32,u32) {match self {
+ Utf16Reserved => (0xd8_00, 0xdf_ff),
+ TooHigh => (0x00_10_ff_ff, 0xff_ff_ff_ff),
+ }}
+}
+
+
+simple!{/// Reasons why a `[u16; 2]` doesn't form a valid UTF-16 codepoint.
+ InvalidUtf16Array {
+ /// The first unit is a trailing/low surrogate, which is never valid.
+ ::FirstIsTrailingSurrogate => "the first unit is a trailing surrogate, which is never valid",
+ /// The second unit is needed, but is not a trailing surrogate.
+ ::SecondIsNotTrailingSurrogate => "the second unit is needed but is not a trailing surrogate",
+ }}
+
+simple!{/// Reasons why one or two `u16`s are not valid UTF-16, in sinking precedence.
+ InvalidUtf16Tuple {
+ /// The first unit is a trailing/low surrogate, which is never valid.
+ ///
+ /// Note that the value of a low surrogate is actually higher than a high surrogate.
+ ::FirstIsTrailingSurrogate => "the first unit is a trailing / low surrogate, which is never valid",
+ /// You provided a second unit, but the first one stands on its own.
+ ::SuperfluousSecond => "the second unit is superfluous",
+ /// The first and only unit requires a second unit.
+ ::MissingSecond => "the first unit requires a second unit",
+ /// The first unit requires a second unit, but it's not a trailing/low surrogate.
+ ///
+ /// Note that the value of a low surrogate is actually higher than a high surrogate.
+ ::InvalidSecond => "the required second unit is not a trailing / low surrogate",
+ }}
+
+
+simple!{/// Reasons why a slice of `u16`s doesn't start with valid UTF-16.
+ InvalidUtf16Slice {
+ /// The slice is empty.
+ ::EmptySlice => "the slice is empty",
+ /// The first unit is a low surrogate.
+ ::FirstLowSurrogate => "the first unit is a trailing surrogate",
+ /// The first and only unit requires a second unit.
+ ::MissingSecond => "the first and only unit requires a second one",
+ /// The first unit requires a second one, but it's not a trailing surrogate.
+ ::SecondNotLowSurrogate => "the required second unit is not a trailing surrogate",
+ }}
+
+simple!{/// Types of invalid sequences encountered by `Utf16CharParser`.
+ Utf16PairError {
+ /// A trailing surrogate was not preceeded by a leading surrogate.
+ ::UnexpectedTrailingSurrogate => "a trailing surrogate was not preceeded by a leading surrogate",
+ /// A leading surrogate was followed by an unit that was not a trailing surrogate.
+ ::UnmatchedLeadingSurrogate => "a leading surrogate was followed by an unit that was not a trailing surrogate",
+ /// A trailing surrogate was expected when the end was reached.
+ ::Incomplete => "a trailing surrogate was expected when the end was reached",
+ }}
+
+
+simple!{/// Reasons why `Utf8Char::from_str()` or `Utf16Char::from_str()` failed.
+ FromStrError {
+ /// `Utf8Char` or `Utf16Char` cannot store more than a single codepoint.
+ ::MultipleCodepoints => "has more than one codepoint",
+ /// `Utf8Char` or `Utf16Char` cannot be empty.
+ ::Empty => "is empty",
+ }}
+
+
+simple!{/// Reasons why a byte is not the start of a UTF-8 codepoint.
+ InvalidUtf8FirstByte {
+ /// Sequences cannot be longer than 4 bytes. Is given for values >= 240.
+ ::TooLongSeqence => "is greater than 247 (UTF-8 sequences cannot be longer than four bytes)",
+ /// This byte belongs to a previous sequence. Is given for values between 128 and 192 (exclusive).
+ ::ContinuationByte => "is a continuation of a previous sequence",
+ }}
+use self::InvalidUtf8FirstByte::*;
+
+
+
+macro_rules! complex {
+($err:ty
+ {$($sub:ty => $to:expr,)*}
+ {$($desc:pat => $string:expr),+,}
+ => $use_cause:expr =>
+ {$($cause:pat => $result:expr),+,} $(#[$causedoc:meta])*
+) => {
+ $(impl From<$sub> for $err {
+ fn from(error: $sub) -> $err {
+ $to(error)
+ }
+ })*
+ #[cfg(not(feature="std"))]
+ impl $err {
+ #[allow(missing_docs)]
+ pub fn description(&self) -> &'static str {
+ match *self{ $($desc => $string,)* }
+ }
+ /// A hack to avoid two Display impls
+ fn cause(&self) -> Option<&Display> {None}
+ }
+ #[cfg(feature="std")]
+ impl Error for $err {
+ fn description(&self) -> &'static str {
+ match *self{ $($desc => $string,)* }
+ }
+ $(#[$causedoc])*
+ fn cause(&self) -> Option<&Error> {
+ match *self{ $($cause => $result,)* }
+ }
+ }
+ impl Display for $err {
+ fn fmt(&self, fmtr: &mut Formatter) -> fmt::Result {
+ match (self.cause(), $use_cause) {
+ (Some(d),true) => write!(fmtr, "{}: {}", self.description(), d),
+ _ => write!(fmtr, "{}", self.description()),
+ }
+ }
+ }
+}}
+
+
+/// Reasons why a byte sequence is not valid UTF-8, excluding invalid codepoint.
+/// In sinking precedence.
+#[derive(Clone,Copy, Debug, PartialEq,Eq)]
+pub enum InvalidUtf8 {
+ /// Something is wrong with the first byte.
+ FirstByte(InvalidUtf8FirstByte),
+ /// The byte at index 1...3 should be a continuation byte,
+ /// but dosesn't fit the pattern 0b10xx_xxxx.
+ NotAContinuationByte(usize),
+ /// There are too many leading zeros: it could be a byte shorter.
+ ///
+ /// [Decoding this could allow someone to input otherwise prohibited
+ /// characters and sequences, such as "../"](https://tools.ietf.org/html/rfc3629#section-10).
+ OverLong,
+}
+use self::InvalidUtf8::*;
+complex!{InvalidUtf8 {
+ InvalidUtf8FirstByte => FirstByte,
+ } {
+ FirstByte(TooLongSeqence) => "the first byte is greater than 239 (UTF-8 sequences cannot be longer than four bytes)",
+ FirstByte(ContinuationByte) => "the first byte is a continuation of a previous sequence",
+ OverLong => "the sequence contains too many zeros and could be shorter",
+ NotAContinuationByte(_) => "the sequence is too short",
+ } => false => {
+ FirstByte(ref cause) => Some(cause),
+ _ => None,
+ }/// Returns `Some` if the error is a `InvalidUtf8FirstByte`.
+}
+
+
+/// Reasons why a byte array is not valid UTF-8, in sinking precedence.
+#[derive(Clone,Copy, Debug, PartialEq,Eq)]
+pub enum InvalidUtf8Array {
+ /// Not a valid UTF-8 sequence.
+ Utf8(InvalidUtf8),
+ /// Not a valid unicode codepoint.
+ Codepoint(InvalidCodepoint),
+}
+complex!{InvalidUtf8Array {
+ InvalidUtf8 => InvalidUtf8Array::Utf8,
+ InvalidCodepoint => InvalidUtf8Array::Codepoint,
+ } {
+ InvalidUtf8Array::Utf8(_) => "the sequence is invalid UTF-8",
+ InvalidUtf8Array::Codepoint(_) => "the encoded codepoint is invalid",
+ } => true => {
+ InvalidUtf8Array::Utf8(ref u) => Some(u),
+ InvalidUtf8Array::Codepoint(ref c) => Some(c),
+ }/// Always returns `Some`.
+}
+
+
+/// Reasons why a byte slice is not valid UTF-8, in sinking precedence.
+#[derive(Clone,Copy, Debug, PartialEq,Eq)]
+pub enum InvalidUtf8Slice {
+ /// Something is certainly wrong with the first byte.
+ Utf8(InvalidUtf8),
+ /// The encoded codepoint is invalid:
+ Codepoint(InvalidCodepoint),
+ /// The slice is too short; n bytes was required.
+ TooShort(usize),
+}
+complex!{InvalidUtf8Slice {
+ InvalidUtf8 => InvalidUtf8Slice::Utf8,
+ InvalidCodepoint => InvalidUtf8Slice::Codepoint,
+ } {
+ InvalidUtf8Slice::Utf8(_) => "the sequence is invalid UTF-8",
+ InvalidUtf8Slice::Codepoint(_) => "the encoded codepoint is invalid",
+ InvalidUtf8Slice::TooShort(1) => "the slice is empty",
+ InvalidUtf8Slice::TooShort(_) => "the slice is shorter than the sequence",
+ } => true => {
+ InvalidUtf8Slice::Utf8(ref u) => Some(u),
+ InvalidUtf8Slice::Codepoint(ref c) => Some(c),
+ InvalidUtf8Slice::TooShort(_) => None,
+ }
+}
diff --git a/vendor/encode_unicode/src/lib.rs b/vendor/encode_unicode/src/lib.rs
new file mode 100644
index 0000000..c50e126
--- /dev/null
+++ b/vendor/encode_unicode/src/lib.rs
@@ -0,0 +1,78 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+
+/*!
+Miscellaneous UTF-8 and UTF-16 types and methods.
+
+# Optional features:
+* `#![no_std]`-mode: There are a few differences:
+ * `Error` doesn't exist, but `description()` is made available as an inherent impl.
+ * `Extend`/`FromIterator`-implementations for `String`/`Vec<u8>`/`Vec<u16>` are missing.
+ * There is no `io`, so `Utf8Iterator` and `Utf8CharSplitter` doesn't implement `Read`.
+
+ This feature is enabled by setting `default-features=false` in `Cargo.toml`:
+ `encode_unicode = {version="0.3.4", default-features=false}`
+* Integration with the [ascii](https://tomprogrammer.github.io/rust-ascii/ascii/index.html) crate:
+ Convert `Utf8Char` and `Utf16Char` to and from
+ [ascii::`AsciiChar`](https://tomprogrammer.github.io/rust-ascii/ascii/enum.AsciiChar.html).
+
+The minimum supported version of Rust is 1.15,
+older versions might work now but can break with a minor update.
+
+[crates.io page](https://crates.io/crates/encode_unicode)
+[github repository](https://github.com/tormol/encode_unicode)
+
+*/
+
+#![warn(missing_docs)]
+
+#![cfg_attr(not(feature="std"), no_std)]
+// either `cargo clippy` doesn't see theese, or I get a warning when I build.
+#![cfg_attr(feature="clippy", feature(plugin))]
+#![cfg_attr(feature="clippy", plugin(clippy))]
+#![cfg_attr(feature="clippy", allow(derive_hash_xor_eq))]// tested
+#![cfg_attr(feature="clippy", allow(len_without_is_empty))]// UtfxChar is never empty
+#![cfg_attr(feature="clippy", allow(match_same_arms))]// looks better IMO
+#![cfg_attr(feature="clippy", allow(needless_return))]// `foo.bar(); foo` looks unfinished
+#![cfg_attr(feature="clippy", allow(redundant_closure))]// keep it explicit
+#![cfg_attr(feature="clippy", allow(redundant_closure_call))]// not redundant in macros
+#![cfg_attr(feature="clippy", allow(cast_lossless))]// too much noise (and too verbose)
+// precedence: I prefer spaces to parentheses, but it's nice to recheck.
+
+mod errors;
+mod traits;
+mod utf8_char;
+mod utf8_iterators;
+mod utf16_char;
+mod utf16_iterators;
+mod decoding_iterators;
+
+pub use traits::{CharExt, U8UtfExt, U16UtfExt, StrExt, IterExt, SliceExt};
+pub use utf8_char::Utf8Char;
+pub use utf16_char::Utf16Char;
+pub use utf8_iterators::{Utf8Iterator, iter_bytes};
+pub use utf16_iterators::{Utf16Iterator, iter_units};
+
+pub mod error {// keeping the public interface in one file
+ //! Errors returned by various conversion methods in this crate.
+ pub use errors::{FromStrError, EmptyStrError};
+ pub use errors::{InvalidCodepoint, InvalidUtf8};
+ pub use errors::{InvalidUtf8FirstByte,InvalidUtf16FirstUnit};
+ pub use errors::{InvalidUtf8Slice,InvalidUtf16Slice};
+ pub use errors::{InvalidUtf8Array,InvalidUtf16Array,InvalidUtf16Tuple};
+ pub use errors::Utf16PairError;
+}
+
+pub mod iterator {
+ //! Iterator types that you should rarely need to name
+ pub use utf8_iterators::{Utf8Iterator, Utf8CharSplitter, Utf8Chars, Utf8CharIndices};
+ pub use utf16_iterators::{Utf16Iterator, Utf16CharSplitter, Utf16Chars, Utf16CharIndices};
+ pub use decoding_iterators::{Utf8CharMerger, Utf8CharDecoder};
+ pub use decoding_iterators::{Utf16CharMerger, Utf16CharDecoder};
+}
diff --git a/vendor/encode_unicode/src/traits.rs b/vendor/encode_unicode/src/traits.rs
new file mode 100644
index 0000000..3f36903
--- /dev/null
+++ b/vendor/encode_unicode/src/traits.rs
@@ -0,0 +1,1014 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+#![allow(unused_unsafe)]// explicit unsafe{} blocks in unsafe functions are a good thing.
+
+use utf8_char::Utf8Char;
+use utf16_char::Utf16Char;
+use utf8_iterators::*;
+use utf16_iterators::*;
+use decoding_iterators::*;
+use error::*;
+extern crate core;
+use self::core::{char, u32, mem};
+use self::core::ops::{Not, Index, RangeFull};
+use self::core::borrow::Borrow;
+#[cfg(feature="ascii")]
+extern crate ascii;
+#[cfg(feature="ascii")]
+use self::ascii::AsciiStr;
+
+// TODO better docs and tests
+
+/// Methods for working with `u8`s as UTF-8 bytes.
+pub trait U8UtfExt {
+ /// How many more bytes will you need to complete this codepoint?
+ ///
+ /// # Errors
+ ///
+ /// An error is returned if the byte is not a valid start of an UTF-8
+ /// codepoint:
+ ///
+ /// * `128..192`: ContinuationByte
+ /// * `248..`: TooLongSequence
+ ///
+ /// Values in 244..248 represent a too high codepoint, but do not cause an
+ /// error.
+ fn extra_utf8_bytes(self) -> Result<usize,InvalidUtf8FirstByte>;
+
+ /// How many more bytes will you need to complete this codepoint?
+ ///
+ /// This function assumes that the byte is a valid UTF-8 start, and might
+ /// return any value otherwise. (but the function is pure and safe to call
+ /// with any value).
+ fn extra_utf8_bytes_unchecked(self) -> usize;
+}
+
+impl U8UtfExt for u8 {
+ #[inline]
+ fn extra_utf8_bytes(self) -> Result<usize,InvalidUtf8FirstByte> {
+ use error::InvalidUtf8FirstByte::{ContinuationByte,TooLongSeqence};
+ // the bit twiddling is explained in extra_utf8_bytes_unchecked()
+ if self < 128 {
+ return Ok(0);
+ }
+ match ((self as u32)<<25).not().leading_zeros() {
+ n @ 1...3 => Ok(n as usize),
+ 0 => Err(ContinuationByte),
+ _ => Err(TooLongSeqence),
+ }
+ }
+ #[inline]
+ fn extra_utf8_bytes_unchecked(self) -> usize {
+ // For fun I've optimized this function (for x86 instruction count):
+ // The most straightforward implementation, that lets the compiler do
+ // the optimizing:
+ //match self {
+ // 0b0000_0000...0b0111_1111 => 0,
+ // 0b1100_0010...0b1101_1111 => 1,
+ // 0b1110_0000...0b1110_1111 => 2,
+ // 0b1111_0000...0b1111_0100 => 3,
+ // _ => whatever()
+ //}
+ // Using `unsafe{self::core::hint::unreachable_unchecked()}` for the
+ // "don't care" case is a terrible idea: while having the function
+ // non-deterministically return whatever happens to be in a register
+ // MIGHT be acceptable, it permits the function to not `ret`urn at all,
+ // but let execution fall through to whatever comes after it in the
+ // binary! (in other words completely UB).
+ // Currently unreachable_unchecked() might trap too,
+ // which is certainly not what we want.
+ // I also think `unsafe{mem::unitialized()}` is much more likely to
+ // explicitly produce whatever happens to be in a register than tell
+ // the compiler it can ignore this branch but needs to produce a value.
+ //
+ // From the bit patterns we see that for non-ASCII values the result is
+ // (number of leading set bits) - 1
+ // The standard library doesn't have a method for counting leading ones,
+ // but it has leading_zeros(), which can be used after inverting.
+ // This function can therefore be reduced to the one-liner
+ //`self.not().leading_zeros().saturating_sub(1) as usize`, which would
+ // be branchless for architectures with instructions for
+ // leading_zeros() and saturating_sub().
+
+ // Shortest version as long as ASCII-ness can be predicted: (especially
+ // if the BSR instruction which leading_zeros() uses is microcoded or
+ // doesn't exist)
+ // u8.leading_zeros() would cast to a bigger type internally, so that's
+ // free. compensating by shifting left by 24 before inverting lets the
+ // compiler know that the value passed to leading_zeros() is not zero,
+ // for which BSR's output is undefined and leading_zeros() normally has
+ // special case with a branch.
+ // Shifting one bit too many left acts as a saturating_sub(1).
+ if self<128 {0} else {((self as u32)<<25).not().leading_zeros() as usize}
+
+ // Branchless but longer version: (9 instructions)
+ // It's tempting to try (self|0x80).not().leading_zeros().wrapping_sub(1),
+ // but that produces high lengths for ASCII values 0b01xx_xxxx.
+ // If we could somehow (branchlessy) clear that bit for ASCII values...
+ // We can by masking with the value shifted right with sign extension!
+ // (any nonzero number of bits in range works)
+ //let extended = self as i8 as i32;
+ //let ascii_cleared = (extended<<25) & (extended>>25);
+ //ascii_cleared.not().leading_zeros() as usize
+
+ // cmov version: (7 instructions)
+ //(((self as u32)<<24).not().leading_zeros() as usize).saturating_sub(1)
+ }
+}
+
+
+/// Methods for working with `u16`s as UTF-16 units.
+pub trait U16UtfExt {
+ /// Will you need an extra unit to complete this codepoint?
+ ///
+ /// Returns `Err` for trailing surrogates, `Ok(true)` for leading surrogates,
+ /// and `Ok(false)` for others.
+ fn utf16_needs_extra_unit(self) -> Result<bool,InvalidUtf16FirstUnit>;
+
+ /// Does this `u16` need another `u16` to complete a codepoint?
+ /// Returns `(self & 0xfc00) == 0xd800`
+ ///
+ /// Is basically an unchecked variant of `utf16_needs_extra_unit()`.
+ fn is_utf16_leading_surrogate(self) -> bool;
+}
+impl U16UtfExt for u16 {
+ #[inline]
+ fn utf16_needs_extra_unit(self) -> Result<bool,InvalidUtf16FirstUnit> {
+ match self {
+ // https://en.wikipedia.org/wiki/UTF-16#U.2B10000_to_U.2B10FFFF
+ 0x00_00...0xd7_ff | 0xe0_00...0xff_ff => Ok(false),
+ 0xd8_00...0xdb_ff => Ok(true),
+ _ => Err(InvalidUtf16FirstUnit)
+ }
+ }
+ #[inline]
+ fn is_utf16_leading_surrogate(self) -> bool {
+ (self & 0xfc00) == 0xd800// Clear the ten content bytes of a surrogate,
+ // and see if it's a leading surrogate.
+ }
+}
+
+
+
+
+/// Extension trait for `char` that adds methods for converting to and from UTF-8 or UTF-16.
+pub trait CharExt: Sized {
+ /// Get the UTF-8 representation of this codepoint.
+ ///
+ /// `Utf8Char` is to `[u8;4]` what `char` is to `u32`:
+ /// a restricted type that cannot be mutated internally.
+ fn to_utf8(self) -> Utf8Char;
+
+ /// Get the UTF-16 representation of this codepoint.
+ ///
+ /// `Utf16Char` is to `[u16;2]` what `char` is to `u32`:
+ /// a restricted type that cannot be mutated internally.
+ fn to_utf16(self) -> Utf16Char;
+
+ /// Iterate over or [read](https://doc.rust-lang.org/std/io/trait.Read.html)
+ /// the one to four bytes in the UTF-8 representation of this codepoint.
+ ///
+ /// An identical alternative to the unstable `char.encode_utf8()`.
+ /// That method somehow still exist on stable, so I have to use a different name.
+ fn iter_utf8_bytes(self) -> Utf8Iterator;
+
+ /// Iterate over the one or two units in the UTF-16 representation of this codepoint.
+ ///
+ /// An identical alternative to the unstable `char.encode_utf16()`.
+ /// That method somehow still exist on stable, so I have to use a different name.
+ fn iter_utf16_units(self) -> Utf16Iterator;
+
+
+ /// Convert this char to an UTF-8 array, and also return how many bytes of
+ /// the array are used,
+ ///
+ /// The returned array is left-aligned with unused bytes set to zero.
+ fn to_utf8_array(self) -> ([u8; 4], usize);
+
+ /// Convert this `char` to UTF-16.
+ ///
+ /// The second element is non-zero when a surrogate pair is required.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ ///
+ /// assert_eq!('@'.to_utf16_array(), ['@' as u16, 0]);
+ /// assert_eq!('睷'.to_utf16_array(), ['睷' as u16, 0]);
+ /// assert_eq!('\u{abcde}'.to_utf16_array(), [0xda6f, 0xdcde]);
+ /// ```
+ fn to_utf16_array(self) -> [u16; 2];
+
+ /// Convert this `char` to UTF-16.
+ /// The second item is `Some` if a surrogate pair is required.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ ///
+ /// assert_eq!('@'.to_utf16_tuple(), ('@' as u16, None));
+ /// assert_eq!('睷'.to_utf16_tuple(), ('睷' as u16, None));
+ /// assert_eq!('\u{abcde}'.to_utf16_tuple(), (0xda6f, Some(0xdcde)));
+ /// ```
+ fn to_utf16_tuple(self) -> (u16, Option<u16>);
+
+
+
+ /// Create a `char` from the start of an UTF-8 slice,
+ /// and also return how many bytes were used.
+ ///
+ /// # Errors
+ ///
+ /// Returns an `Err` if the slice is empty, doesn't start with a valid
+ /// UTF-8 sequence or is too short for the sequence.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ /// use encode_unicode::error::InvalidUtf8Slice::*;
+ /// use encode_unicode::error::InvalidUtf8::*;
+ ///
+ /// assert_eq!(char::from_utf8_slice_start(&[b'A', b'B', b'C']), Ok(('A',1)));
+ /// assert_eq!(char::from_utf8_slice_start(&[0xdd, 0xbb]), Ok(('\u{77b}',2)));
+ ///
+ /// assert_eq!(char::from_utf8_slice_start(&[]), Err(TooShort(1)));
+ /// assert_eq!(char::from_utf8_slice_start(&[0xf0, 0x99]), Err(TooShort(4)));
+ /// assert_eq!(char::from_utf8_slice_start(&[0xee, b'F', 0x80]), Err(Utf8(NotAContinuationByte(1))));
+ /// assert_eq!(char::from_utf8_slice_start(&[0xee, 0x99, 0x0f]), Err(Utf8(NotAContinuationByte(2))));
+ /// ```
+ fn from_utf8_slice_start(src: &[u8]) -> Result<(Self,usize),InvalidUtf8Slice>;
+
+ /// Create a `char` from the start of an UTF-16 slice,
+ /// and also return how many units were used.
+ ///
+ /// If you want to continue after an error, continue with the next `u16` unit.
+ fn from_utf16_slice_start(src: &[u16]) -> Result<(Self,usize), InvalidUtf16Slice>;
+
+
+ /// Convert an UTF-8 sequence as returned from `.to_utf8_array()` into a `char`
+ ///
+ /// The codepoint must start at the first byte, and leftover bytes are ignored.
+ ///
+ /// # Errors
+ ///
+ /// Returns an `Err` if the array doesn't start with a valid UTF-8 sequence.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ /// use encode_unicode::error::InvalidUtf8Array::*;
+ /// use encode_unicode::error::InvalidUtf8::*;
+ /// use encode_unicode::error::InvalidCodepoint::*;
+ ///
+ /// assert_eq!(char::from_utf8_array([b'A', 0, 0, 0]), Ok('A'));
+ /// assert_eq!(char::from_utf8_array([0xf4, 0x8b, 0xbb, 0xbb]), Ok('\u{10befb}'));
+ /// assert_eq!(char::from_utf8_array([b'A', b'B', b'C', b'D']), Ok('A'));
+ /// assert_eq!(char::from_utf8_array([0, 0, 0xcc, 0xbb]), Ok('\0'));
+ ///
+ /// assert_eq!(char::from_utf8_array([0xef, b'F', 0x80, 0x80]), Err(Utf8(NotAContinuationByte(1))));
+ /// assert_eq!(char::from_utf8_array([0xc1, 0x80, 0, 0]), Err(Utf8(OverLong)));
+ /// assert_eq!(char::from_utf8_array([0xf7, 0xaa, 0x99, 0x88]), Err(Codepoint(TooHigh)));
+ /// ```
+ fn from_utf8_array(utf8: [u8; 4]) -> Result<Self,InvalidUtf8Array>;
+
+ /// Convert a UTF-16 pair as returned from `.to_utf16_array()` into a `char`.
+ ///
+ /// The second element is ignored when not required.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ /// use encode_unicode::error::InvalidUtf16Array;
+ ///
+ /// assert_eq!(char::from_utf16_array(['x' as u16, 'y' as u16]), Ok('x'));
+ /// assert_eq!(char::from_utf16_array(['睷' as u16, 0]), Ok('睷'));
+ /// assert_eq!(char::from_utf16_array([0xda6f, 0xdcde]), Ok('\u{abcde}'));
+ /// assert_eq!(char::from_utf16_array([0xf111, 0xdbad]), Ok('\u{f111}'));
+ /// assert_eq!(char::from_utf16_array([0xdaaf, 0xdaaf]), Err(InvalidUtf16Array::SecondIsNotTrailingSurrogate));
+ /// assert_eq!(char::from_utf16_array([0xdcac, 0x9000]), Err(InvalidUtf16Array::FirstIsTrailingSurrogate));
+ /// ```
+ fn from_utf16_array(utf16: [u16; 2]) -> Result<Self, InvalidUtf16Array>;
+
+ /// Convert a UTF-16 pair as returned from `.to_utf16_tuple()` into a `char`.
+ fn from_utf16_tuple(utf16: (u16, Option<u16>)) -> Result<Self, InvalidUtf16Tuple>;
+
+
+ /// Convert an UTF-8 sequence into a char.
+ ///
+ /// The length of the slice is taken as length of the sequence;
+ /// it should be 1,2,3 or 4.
+ ///
+ /// # Safety
+ ///
+ /// The slice must contain exactly one, valid, UTF-8 sequence.
+ ///
+ /// Passing a slice that produces an invalid codepoint is always undefined
+ /// behavior; Later checks that the codepoint is valid can be removed
+ /// by the compiler.
+ ///
+ /// # Panics
+ ///
+ /// If the slice is empty
+ unsafe fn from_utf8_exact_slice_unchecked(src: &[u8]) -> Self;
+
+ /// Convert a UTF-16 array as returned from `.to_utf16_array()` into a
+ /// `char`.
+ ///
+ /// This function is safe because it avoids creating invalid codepoints,
+ /// but the returned value might not be what one expectedd.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ ///
+ /// // starts with a trailing surrogate - converted as if it was a valid
+ /// // surrogate pair anyway.
+ /// assert_eq!(char::from_utf16_array_unchecked([0xdbad, 0xf19e]), '\u{fb59e}');
+ /// // missing trailing surrogate - ditto
+ /// assert_eq!(char::from_utf16_array_unchecked([0xd802, 0]), '\u{10800}');
+ /// ```
+ fn from_utf16_array_unchecked(utf16: [u16;2]) -> Self;
+
+ /// Convert a UTF-16 tuple as returned from `.to_utf16_tuple()` into a `char`.
+ unsafe fn from_utf16_tuple_unchecked(utf16: (u16, Option<u16>)) -> Self;
+
+
+ /// Produces more detailed errors than `char::from_u32()`
+ ///
+ /// # Errors
+ ///
+ /// This function will return an error if
+ ///
+ /// * the value is greater than 0x10ffff
+ /// * the value is between 0xd800 and 0xdfff (inclusive)
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::CharExt;
+ /// use encode_unicode::error::InvalidCodepoint;
+ ///
+ /// assert_eq!(char::from_u32_detailed(0x41), Ok('A'));
+ /// assert_eq!(char::from_u32_detailed(0x40_00_00), Err(InvalidCodepoint::TooHigh));
+ /// assert_eq!(char::from_u32_detailed(0xd951), Err(InvalidCodepoint::Utf16Reserved));
+ /// assert_eq!(char::from_u32_detailed(0xdddd), Err(InvalidCodepoint::Utf16Reserved));
+ /// assert_eq!(char::from_u32_detailed(0xdd), Ok('Ý'));
+ /// assert_eq!(char::from_u32_detailed(0x1f331), Ok('🌱'));
+ /// ```
+ fn from_u32_detailed(c: u32) -> Result<Self,InvalidCodepoint>;
+}
+
+
+
+impl CharExt for char {
+ /////////
+ //UTF-8//
+ /////////
+
+ fn to_utf8(self) -> Utf8Char {
+ self.into()
+ }
+ fn iter_utf8_bytes(self) -> Utf8Iterator {
+ self.to_utf8().into_iter()
+ }
+
+ fn to_utf8_array(self) -> ([u8; 4], usize) {
+ let len = self.len_utf8();
+ let mut c = self as u32;
+ if len == 1 {// ASCII, the common case
+ ([c as u8, 0, 0, 0], 1)
+ } else {
+ let mut parts = 0;// convert to 6-bit bytes
+ parts |= c & 0x3f; c>>=6;
+ parts<<=8; parts |= c & 0x3f; c>>=6;
+ parts<<=8; parts |= c & 0x3f; c>>=6;
+ parts<<=8; parts |= c & 0x3f;
+ parts |= 0x80_80_80_80;// set the most significant bit
+ parts >>= 8*(4-len);// right-align bytes
+ // Now, unused bytes are zero, (which matters for Utf8Char.eq())
+ // and the rest are 0b10xx_xxxx
+
+ // set header on first byte
+ parts |= (0xff_00u32 >> len) & 0xff;// store length
+ parts &= Not::not(1u32 << 7-len);// clear the next bit after it
+
+ let bytes: [u8; 4] = unsafe{ mem::transmute(u32::from_le(parts)) };
+ (bytes, len)
+ }
+ }
+
+
+ fn from_utf8_slice_start(src: &[u8]) -> Result<(Self,usize),InvalidUtf8Slice> {
+ use errors::InvalidUtf8::*;
+ use errors::InvalidUtf8Slice::*;
+ let first = match src.first() {
+ Some(first) => *first,
+ None => return Err(TooShort(1)),
+ };
+ let bytes = match first.extra_utf8_bytes() {
+ Err(e) => return Err(Utf8(FirstByte(e))),
+ Ok(0) => return Ok((first as char, 1)),
+ Ok(extra) if extra >= src.len()
+ => return Err(TooShort(extra+1)),
+ Ok(extra) => &src[..extra+1],
+ };
+ if let Some(i) = bytes.iter().skip(1).position(|&b| (b >> 6) != 0b10 ) {
+ Err(Utf8(NotAContinuationByte(i+1)))
+ } else if overlong(bytes[0], bytes[1]) {
+ Err(Utf8(OverLong))
+ } else {
+ match char::from_u32_detailed(merge_nonascii_unchecked_utf8(bytes)) {
+ Ok(c) => Ok((c, bytes.len())),
+ Err(e) => Err(Codepoint(e)),
+ }
+ }
+ }
+
+ fn from_utf8_array(utf8: [u8; 4]) -> Result<Self,InvalidUtf8Array> {
+ use errors::InvalidUtf8::*;
+ use errors::InvalidUtf8Array::*;
+ let src = match utf8[0].extra_utf8_bytes() {
+ Err(error) => return Err(Utf8(FirstByte(error))),
+ Ok(0) => return Ok(utf8[0] as char),
+ Ok(extra) => &utf8[..extra+1],
+ };
+ if let Some(i) = src[1..].iter().position(|&b| (b >> 6) != 0b10 ) {
+ Err(Utf8(NotAContinuationByte(i+1)))
+ } else if overlong(utf8[0], utf8[1]) {
+ Err(Utf8(OverLong))
+ } else {
+ char::from_u32_detailed(merge_nonascii_unchecked_utf8(src))
+ .map_err(|e| Codepoint(e) )
+ }
+ }
+
+ unsafe fn from_utf8_exact_slice_unchecked(src: &[u8]) -> Self {
+ if src.len() == 1 {
+ src[0] as char
+ } else {
+ char::from_u32_unchecked(merge_nonascii_unchecked_utf8(src))
+ }
+ }
+
+
+
+ //////////
+ //UTF-16//
+ //////////
+
+ fn to_utf16(self) -> Utf16Char {
+ Utf16Char::from(self)
+ }
+ fn iter_utf16_units(self) -> Utf16Iterator {
+ self.to_utf16().into_iter()
+ }
+
+ fn to_utf16_array(self) -> [u16;2] {
+ let (first, second) = self.to_utf16_tuple();
+ [first, second.unwrap_or(0)]
+ }
+ fn to_utf16_tuple(self) -> (u16, Option<u16>) {
+ if self <= '\u{ffff}' {// single
+ (self as u16, None)
+ } else {// double
+ let c = self as u32 - 0x_01_00_00;
+ let high = 0x_d8_00 + (c >> 10);
+ let low = 0x_dc_00 + (c & 0x_03_ff);
+ (high as u16, Some(low as u16))
+ }
+ }
+
+
+ fn from_utf16_slice_start(src: &[u16]) -> Result<(Self,usize), InvalidUtf16Slice> {
+ use errors::InvalidUtf16Slice::*;
+ unsafe {match (src.get(0), src.get(1)) {
+ (Some(&u @ 0x00_00...0xd7_ff), _) |
+ (Some(&u @ 0xe0_00...0xff_ff), _)
+ => Ok((char::from_u32_unchecked(u as u32), 1)),
+ (Some(&0xdc_00...0xdf_ff), _) => Err(FirstLowSurrogate),
+ (None, _) => Err(EmptySlice),
+ (Some(&f @ 0xd8_00...0xdb_ff), Some(&s @ 0xdc_00...0xdf_ff))
+ => Ok((char::from_utf16_tuple_unchecked((f, Some(s))), 2)),
+ (Some(&0xd8_00...0xdb_ff), Some(_)) => Err(SecondNotLowSurrogate),
+ (Some(&0xd8_00...0xdb_ff), None) => Err(MissingSecond),
+ (Some(_), _) => unreachable!()
+ }}
+ }
+
+ fn from_utf16_array(utf16: [u16;2]) -> Result<Self, InvalidUtf16Array> {
+ use errors::InvalidUtf16Array::*;
+ if let Some(c) = char::from_u32(utf16[0] as u32) {
+ Ok(c) // single
+ } else if utf16[0] < 0xdc_00 && utf16[1] & 0xfc_00 == 0xdc_00 {
+ // correct surrogate pair
+ Ok(combine_surrogates(utf16[0], utf16[1]))
+ } else if utf16[0] < 0xdc_00 {
+ Err(SecondIsNotTrailingSurrogate)
+ } else {
+ Err(FirstIsTrailingSurrogate)
+ }
+ }
+ fn from_utf16_tuple(utf16: (u16, Option<u16>)) -> Result<Self, InvalidUtf16Tuple> {
+ use errors::InvalidUtf16Tuple::*;
+ unsafe{ match utf16 {
+ (0x00_00...0xd7_ff, None) | // single
+ (0xe0_00...0xff_ff, None) | // single
+ (0xd8_00...0xdb_ff, Some(0xdc_00...0xdf_ff)) // correct surrogate
+ => Ok(char::from_utf16_tuple_unchecked(utf16)),
+ (0xd8_00...0xdb_ff, Some(_)) => Err(InvalidSecond),
+ (0xd8_00...0xdb_ff, None ) => Err(MissingSecond),
+ (0xdc_00...0xdf_ff, _ ) => Err(FirstIsTrailingSurrogate),
+ ( _ , Some(_)) => Err(SuperfluousSecond),
+ ( _ , None ) => unreachable!()
+ }}
+ }
+
+ fn from_utf16_array_unchecked(utf16: [u16;2]) -> Self {
+ // treat any array with a surrogate value in [0] as a surrogate because
+ // combine_surrogates() is safe.
+ // `(utf16[0] & 0xf800) == 0xd80` might not be quite as fast as
+ // `utf16[1] != 0`, but avoiding the potential for UB is worth it
+ // since the conversion isn't zero-cost in either case.
+ char::from_u32(utf16[0] as u32)
+ .unwrap_or_else(|| combine_surrogates(utf16[0], utf16[1]) )
+ }
+ unsafe fn from_utf16_tuple_unchecked(utf16: (u16, Option<u16>)) -> Self {
+ match utf16.1 {
+ Some(second) => combine_surrogates(utf16.0, second),
+ None => char::from_u32_unchecked(utf16.0 as u32)
+ }
+ }
+
+
+ fn from_u32_detailed(c: u32) -> Result<Self,InvalidCodepoint> {
+ match char::from_u32(c) {
+ Some(c) => Ok(c),
+ None if c > 0x10_ff_ff => Err(InvalidCodepoint::TooHigh),
+ None => Err(InvalidCodepoint::Utf16Reserved),
+ }
+ }
+}
+
+// Adapted from https://www.cl.cam.ac.uk/~mgk25/ucs/utf8_check.c
+fn overlong(first: u8, second: u8) -> bool {
+ if first < 0x80 {
+ false
+ } else if (first & 0xe0) == 0xc0 {
+ (first & 0xfe) == 0xc0
+ } else if (first & 0xf0) == 0xe0 {
+ first == 0xe0 && (second & 0xe0) == 0x80
+ } else {
+ first == 0xf0 && (second & 0xf0) == 0x80
+ }
+}
+
+/// Decodes the codepoint represented by a multi-byte UTF-8 sequence.
+///
+/// Does not check that the codepoint is valid,
+/// and returns `u32` because casting invalid codepoints to `char` is insta UB.
+fn merge_nonascii_unchecked_utf8(src: &[u8]) -> u32 {
+ let mut c = src[0] as u32 & (0x7f >> src.len());
+ for b in &src[1..] {
+ c = (c << 6) | (b & 0b0011_1111) as u32;
+ }
+ c
+}
+
+/// Create a `char` from a leading and a trailing surrogate.
+///
+/// This function is safe because it ignores the six most significant bits of
+/// each arguments and always produces a codepoint in 0x01_00_00..=0x10_ff_ff.
+fn combine_surrogates(first: u16, second: u16) -> char {
+ unsafe {
+ let high = (first & 0x_03_ff) as u32;
+ let low = (second & 0x_03_ff) as u32;
+ let c = ((high << 10) | low) + 0x_01_00_00; // no, the constant can't be or'd in
+ char::from_u32_unchecked(c)
+ }
+}
+
+
+
+/// Adds `.utf8chars()` and `.utf16chars()` iterator constructors to `&str`.
+pub trait StrExt: AsRef<str> {
+ /// Equivalent to `.chars()` but produces `Utf8Char`s.
+ fn utf8chars(&self) -> Utf8Chars;
+ /// Equivalent to `.chars()` but produces `Utf16Char`s.
+ fn utf16chars(&self) -> Utf16Chars;
+ /// Equivalent to `.char_indices()` but produces `Utf8Char`s.
+ fn utf8char_indices(&self) -> Utf8CharIndices;
+ /// Equivalent to `.char_indices()` but produces `Utf16Char`s.
+ fn utf16char_indices(&self) -> Utf16CharIndices;
+}
+
+impl StrExt for str {
+ fn utf8chars(&self) -> Utf8Chars {
+ Utf8Chars::from(self)
+ }
+ fn utf16chars(&self) -> Utf16Chars {
+ Utf16Chars::from(self)
+ }
+ fn utf8char_indices(&self) -> Utf8CharIndices {
+ Utf8CharIndices::from(self)
+ }
+ fn utf16char_indices(&self) -> Utf16CharIndices {
+ Utf16CharIndices::from(self)
+ }
+}
+
+#[cfg(feature="ascii")]
+impl StrExt for AsciiStr {
+ fn utf8chars(&self) -> Utf8Chars {
+ Utf8Chars::from(self.as_str())
+ }
+ fn utf16chars(&self) -> Utf16Chars {
+ Utf16Chars::from(self.as_str())
+ }
+ fn utf8char_indices(&self) -> Utf8CharIndices {
+ Utf8CharIndices::from(self.as_str())
+ }
+ fn utf16char_indices(&self) -> Utf16CharIndices {
+ Utf16CharIndices::from(self.as_str())
+ }
+}
+
+
+
+/// Iterator methods that convert between `u8`s and `Utf8Char` or `u16`s and `Utf16Char`
+///
+/// All the iterator adapters also accept iterators that produce references of
+/// the type they convert from.
+pub trait IterExt: Iterator+Sized {
+ /// Converts an iterator of `Utf8Char`s or `&Utf8Char`s to an iterator of
+ /// `u8`s.
+ ///
+ /// Has the same effect as `.flat_map()` or `.flatten()`, but the returned
+ /// iterator is ~40% faster.
+ ///
+ /// The iterator also implements `Read`
+ /// (when the `std` feature isn't disabled).
+ /// Reading will never produce an error, and calls to `.read()` and `.next()`
+ /// can be mixed.
+ ///
+ /// The exact number of bytes cannot be known in advance, but `size_hint()`
+ /// gives the possible range.
+ /// (min: all remaining characters are ASCII, max: all require four bytes)
+ ///
+ /// # Examples
+ ///
+ /// From iterator of values:
+ ///
+ /// ```
+ /// use encode_unicode::{IterExt, StrExt};
+ ///
+ /// let iterator = "foo".utf8chars();
+ /// let mut bytes = [0; 4];
+ /// for (u,dst) in iterator.to_bytes().zip(&mut bytes) {*dst=u;}
+ /// assert_eq!(&bytes, b"foo\0");
+ /// ```
+ ///
+ /// From iterator of references:
+ ///
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{IterExt, StrExt, Utf8Char};
+ ///
+ /// let chars: Vec<Utf8Char> = "💣 bomb 💣".utf8chars().collect();
+ /// let bytes: Vec<u8> = chars.iter().to_bytes().collect();
+ /// let flat_map: Vec<u8> = chars.iter().flat_map(|u8c| *u8c ).collect();
+ /// assert_eq!(bytes, flat_map);
+ /// ```
+ ///
+ /// `Read`ing from it:
+ ///
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{IterExt, StrExt};
+ /// use std::io::Read;
+ ///
+ /// let s = "Ååh‽";
+ /// assert_eq!(s.len(), 8);
+ /// let mut buf = [b'E'; 9];
+ /// let mut reader = s.utf8chars().to_bytes();
+ /// assert_eq!(reader.read(&mut buf[..]).unwrap(), 8);
+ /// assert_eq!(reader.read(&mut buf[..]).unwrap(), 0);
+ /// assert_eq!(&buf[..8], s.as_bytes());
+ /// assert_eq!(buf[8], b'E');
+ /// ```
+ fn to_bytes(self) -> Utf8CharSplitter<Self::Item,Self> where Self::Item: Borrow<Utf8Char>;
+
+ /// Converts an iterator of `Utf16Char` (or `&Utf16Char`) to an iterator of
+ /// `u16`s.
+ ///
+ /// Has the same effect as `.flat_map()` or `.flatten()`, but the returned
+ /// iterator is about twice as fast.
+ ///
+ /// The exact number of units cannot be known in advance, but `size_hint()`
+ /// gives the possible range.
+ ///
+ /// # Examples
+ ///
+ /// From iterator of values:
+ ///
+ /// ```
+ /// use encode_unicode::{IterExt, StrExt};
+ ///
+ /// let iterator = "foo".utf16chars();
+ /// let mut units = [0; 4];
+ /// for (u,dst) in iterator.to_units().zip(&mut units) {*dst=u;}
+ ///
+ /// assert_eq!(units, ['f' as u16, 'o' as u16, 'o' as u16, 0]);
+ /// ```
+ ///
+ /// From iterator of references:
+ ///
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{IterExt, StrExt, Utf16Char};
+ ///
+ /// // (💣 takes two units)
+ /// let chars: Vec<Utf16Char> = "💣 bomb 💣".utf16chars().collect();
+ /// let units: Vec<u16> = chars.iter().to_units().collect();
+ /// let flat_map: Vec<u16> = chars.iter().flat_map(|u16c| *u16c ).collect();
+ ///
+ /// assert_eq!(units, flat_map);
+ /// ```
+ fn to_units(self) -> Utf16CharSplitter<Self::Item,Self> where Self::Item: Borrow<Utf16Char>;
+
+ /// Decodes bytes as UTF-8 and groups them into `Utf8Char`s
+ ///
+ /// When errors (invalid values or sequences) are encountered,
+ /// it continues with the byte right after the start of the error sequence.
+ /// This is neither the most intelligent choiche (sometimes it is guaranteed to
+ /// produce another error), nor the easiest to implement, but I believe it to
+ /// be the most predictable.
+ /// It also means that ASCII characters are never hidden by errors.
+ ///
+ /// # Examples
+ ///
+ /// Replace all errors with u+FFFD REPLACEMENT_CHARACTER:
+ /// ```
+ /// use encode_unicode::{Utf8Char, IterExt};
+ ///
+ /// let mut buf = [b'\0'; 255];
+ /// let len = b"foo\xCFbar".iter()
+ /// .to_utf8chars()
+ /// .flat_map(|r| r.unwrap_or(Utf8Char::from('\u{FFFD}')).into_iter() )
+ /// .zip(&mut buf[..])
+ /// .map(|(byte, dst)| *dst = byte )
+ /// .count();
+ ///
+ /// assert_eq!(&buf[..len], "foo\u{FFFD}bar".as_bytes());
+ /// ```
+ ///
+ /// Collect everything up until the first error into a string:
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::iterator::Utf8CharMerger;
+ /// let mut good = String::new();
+ /// for r in Utf8CharMerger::from(b"foo\xcc\xbbbar\xcc\xddbaz") {
+ /// if let Ok(uc) = r {
+ /// good.push_str(uc.as_str());
+ /// } else {
+ /// break;
+ /// }
+ /// }
+ /// assert_eq!(good, "foo̻bar");
+ /// ```
+ ///
+ /// Abort decoding on error:
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{IterExt, Utf8Char};
+ /// use encode_unicode::error::{InvalidUtf8Slice, InvalidUtf8};
+ ///
+ /// let result = b"ab\0\xe0\xbc\xa9 \xf3\x80\x77".iter()
+ /// .to_utf8chars()
+ /// .collect::<Result<String,InvalidUtf8Slice>>();
+ ///
+ /// assert_eq!(result, Err(InvalidUtf8Slice::Utf8(InvalidUtf8::NotAContinuationByte(2))));
+ /// ```
+ fn to_utf8chars(self) -> Utf8CharMerger<Self::Item,Self> where Self::Item: Borrow<u8>;
+
+ /// Decodes bytes as UTF-16 and groups them into `Utf16Char`s
+ ///
+ /// When errors (unmatched leading surrogates or unexpected trailing surrogates)
+ /// are encountered, an error is produced for every unit.
+ ///
+ /// # Examples
+ ///
+ /// Replace errors with '�':
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{IterExt, Utf16Char};
+ ///
+ /// let slice = &['a' as u16, 0xdf00, 0xd83c, 0xdca0][..];
+ /// let string = slice.iter()
+ /// .to_utf16chars()
+ /// .map(|r| r.unwrap_or(Utf16Char::from('\u{fffd}')) ) // REPLACEMENT_CHARACTER
+ /// .collect::<String>();
+ ///
+ /// assert_eq!(string, "a�🂠");
+ /// ```
+ ///
+ /// ```
+ /// use encode_unicode::{IterExt, Utf16Char};
+ /// use encode_unicode::error::Utf16PairError::*;
+ ///
+ /// let slice = [0xdcba, 0xdeff, 0xd8be, 0xdeee, 'Y' as u16, 0xdab1, 0xdab1];
+ /// let mut iter = slice.iter().to_utf16chars();
+ /// assert_eq!(iter.size_hint(), (3, Some(7)));
+ /// assert_eq!(iter.next(), Some(Err(UnexpectedTrailingSurrogate)));
+ /// assert_eq!(iter.next(), Some(Err(UnexpectedTrailingSurrogate)));
+ /// assert_eq!(iter.next(), Some(Ok(Utf16Char::from('\u{3faee}'))));
+ /// assert_eq!(iter.next(), Some(Ok(Utf16Char::from('Y'))));
+ /// assert_eq!(iter.next(), Some(Err(UnmatchedLeadingSurrogate)));
+ /// assert_eq!(iter.next(), Some(Err(Incomplete)));
+ /// assert_eq!(iter.into_remaining_units().next(), None);
+ /// ```
+ ///
+ /// Search for a codepoint and return the codepoint index of the first match:
+ /// ```
+ /// use encode_unicode::{IterExt, Utf16Char};
+ ///
+ /// let position = [0xd875, 0xdd4f, '≈' as u16, '2' as u16].iter()
+ /// .to_utf16chars()
+ /// .position(|r| r == Ok(Utf16Char::from('≈')) );
+ ///
+ /// assert_eq!(position, Some(1));
+ /// ```
+ fn to_utf16chars(self) -> Utf16CharMerger<Self::Item,Self> where Self::Item: Borrow<u16>;
+}
+
+impl<I:Iterator> IterExt for I {
+ fn to_bytes(self) -> Utf8CharSplitter<Self::Item,Self> where Self::Item: Borrow<Utf8Char> {
+ iter_bytes(self)
+ }
+ fn to_units(self) -> Utf16CharSplitter<Self::Item,Self> where Self::Item: Borrow<Utf16Char> {
+ iter_units(self)
+ }
+ fn to_utf8chars(self) -> Utf8CharMerger<Self::Item,Self> where Self::Item: Borrow<u8> {
+ Utf8CharMerger::from(self)
+ }
+ fn to_utf16chars(self) -> Utf16CharMerger<Self::Item,Self> where Self::Item: Borrow<u16> {
+ Utf16CharMerger::from(self)
+ }
+}
+
+
+/// Methods for iterating over `u8` and `u16` slices as UTF-8 or UTF-16 characters.
+///
+/// The iterators are slightly faster than the similar methods in [`IterExt`](trait.IterExt.html)
+/// because they con "push back" items for free after errors and don't need a
+/// separate buffer that must be checked on every call to `.next()`.
+pub trait SliceExt: Index<RangeFull> {
+ /// Decode `u8` slices as UTF-8 and iterate over the codepoints as `Utf8Char`s,
+ ///
+ /// # Examples
+ ///
+ /// Get the index and error type of the first error:
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{SliceExt, Utf8Char};
+ /// use encode_unicode::error::InvalidUtf8Slice;
+ ///
+ /// let slice = b"ab\0\xe0\xbc\xa9 \xf3\x80\x77";
+ /// let result = slice.utf8char_indices()
+ /// .map(|(offset,r,length)| r.map_err(|e| (offset,e,length) ) )
+ /// .collect::<Result<String,(usize,InvalidUtf8Slice,usize)>>();
+ ///
+ /// assert_eq!(result, Err((7, InvalidUtf8Slice::TooShort(4), 1)));
+ /// ```
+ ///
+ /// ```
+ /// use encode_unicode::{SliceExt, Utf8Char};
+ /// use std::error::Error;
+ ///
+ /// let slice = b"\xf0\xbf\xbf\xbfXY\xdd\xbb\xe1\x80\x99quux123";
+ /// let mut fixed_size = [Utf8Char::default(); 8];
+ /// for (cp_i, (byte_index, r, _)) in slice.utf8char_indices().enumerate().take(8) {
+ /// match r {
+ /// Ok(u8c) => fixed_size[cp_i] = u8c,
+ /// Err(e) => panic!("Invalid codepoint at index {} ({})", cp_i, e.description()),
+ /// }
+ /// }
+ /// let chars = ['\u{3ffff}', 'X', 'Y', '\u{77b}', '\u{1019}', 'q', 'u', 'u'];
+ /// assert_eq!(fixed_size, chars);
+ /// ```
+ ///
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{SliceExt, Utf8Char};
+ /// use encode_unicode::error::InvalidUtf8Slice::*;
+ /// use encode_unicode::error::{InvalidUtf8, InvalidUtf8FirstByte, InvalidCodepoint};
+ ///
+ /// let bytes = b"\xfa-\xf4\x8f\xee\xa1\x8f-\xed\xa9\x87\xf0\xcc\xbb";
+ /// let mut errors = Vec::new();
+ /// let mut lengths = Vec::new();
+ /// let mut string = String::new();
+ /// for (offset,result,length) in bytes.utf8char_indices() {
+ /// lengths.push((offset,length));
+ /// let c = result.unwrap_or_else(|error| {
+ /// errors.push((offset,error));
+ /// Utf8Char::from('\u{fffd}') // replacement character
+ /// });
+ /// string.push_str(c.as_str());
+ /// }
+ ///
+ /// assert_eq!(string, "�-��\u{e84f}-����\u{33b}");
+ /// assert_eq!(lengths, [(0,1), (1,1), (2,1), (3,1), (4,3), (7,1),
+ /// (8,1), (9,1), (10,1), (11,1), (12,2)]);
+ /// assert_eq!(errors, [
+ /// ( 0, Utf8(InvalidUtf8::FirstByte(InvalidUtf8FirstByte::TooLongSeqence))),
+ /// ( 2, Utf8(InvalidUtf8::NotAContinuationByte(2))),
+ /// ( 3, Utf8(InvalidUtf8::FirstByte(InvalidUtf8FirstByte::ContinuationByte))),
+ /// ( 8, Codepoint(InvalidCodepoint::Utf16Reserved)),
+ /// ( 9, Utf8(InvalidUtf8::FirstByte(InvalidUtf8FirstByte::ContinuationByte))),
+ /// (10, Utf8(InvalidUtf8::FirstByte(InvalidUtf8FirstByte::ContinuationByte))),
+ /// (11, TooShort(4)), // (but it was not the last element returned!)
+ /// ]);
+ /// ```
+ fn utf8char_indices(&self) -> Utf8CharDecoder where Self::Output: Borrow<[u8]>;
+
+
+ /// Decode `u16` slices as UTF-16 and iterate over the codepoints as `Utf16Char`s,
+ ///
+ /// The iterator produces `(usize,Result<Utf16Char,Utf16Error>,usize)`,
+ /// and the slice is validated as you go.
+ ///
+ /// The first `usize` contains the offset from the start of the slice and
+ /// the last `usize` contains the length of the codepoint or error.
+ /// The length is either 1 or 2, and always 1 for errors.
+ ///
+ /// # Examples
+ ///
+ #[cfg_attr(feature="std", doc=" ```")]
+ #[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+ /// use encode_unicode::{SliceExt, Utf8Char};
+ ///
+ /// let slice = &['a' as u16, 0xdf00, 0xd83c, 0xdca0][..];
+ /// let mut errors = Vec::new();
+ /// let string = slice.utf16char_indices().map(|(offset,r,_)| match r {
+ /// Ok(u16c) => Utf8Char::from(u16c),
+ /// Err(_) => {
+ /// errors.push(offset);
+ /// Utf8Char::from('\u{fffd}') // REPLACEMENT_CHARACTER
+ /// }
+ /// }).collect::<String>();
+ ///
+ /// assert_eq!(string, "a�🂠");
+ /// assert_eq!(errors, [1]);
+ /// ```
+ ///
+ /// Search for a codepoint and return its unit and codepoint index.
+ /// ```
+ /// use encode_unicode::{SliceExt, Utf16Char};
+ ///
+ /// let slice = [0xd875,/*'𝕏'*/ 0xdd4f, '≈' as u16, '2' as u16];
+ /// let position = slice.utf16char_indices()
+ /// .enumerate()
+ /// .find(|&(_,(_,r,_))| r == Ok(Utf16Char::from('≈')) )
+ /// .map(|(codepoint, (offset, _, _))| (codepoint, offset) );
+ ///
+ /// assert_eq!(position, Some((1,2)));
+ /// ```
+ ///
+ /// Error types:
+ /// ```
+ /// use encode_unicode::{SliceExt, Utf16Char};
+ /// use encode_unicode::error::Utf16PairError::*;
+ ///
+ /// let slice = [0xdcba, 0xdeff, 0xd8be, 0xdeee, 'λ' as u16, 0xdab1, 0xdab1];
+ /// let mut iter = slice.utf16char_indices();
+ /// assert_eq!(iter.next(), Some((0, Err(UnexpectedTrailingSurrogate), 1)));
+ /// assert_eq!(iter.next(), Some((1, Err(UnexpectedTrailingSurrogate), 1)));
+ /// assert_eq!(iter.next(), Some((2, Ok(Utf16Char::from('\u{3faee}')), 2)));
+ /// assert_eq!(iter.next(), Some((4, Ok(Utf16Char::from('λ')), 1)));
+ /// assert_eq!(iter.next(), Some((5, Err(UnmatchedLeadingSurrogate), 1)));
+ /// assert_eq!(iter.next(), Some((6, Err(Incomplete), 1)));
+ /// assert_eq!(iter.next(), None);
+ /// assert_eq!(iter.as_slice(), [])
+ /// ```
+ fn utf16char_indices(&self) -> Utf16CharDecoder where Self::Output: Borrow<[u16]>;
+}
+
+impl<S: ?Sized+Index<RangeFull>> SliceExt for S {
+ fn utf8char_indices(&self) -> Utf8CharDecoder where Self::Output: Borrow<[u8]> {
+ Utf8CharDecoder::from(self[..].borrow())
+ }
+ fn utf16char_indices(&self) -> Utf16CharDecoder where Self::Output: Borrow<[u16]> {
+ Utf16CharDecoder::from(self[..].borrow())
+ }
+}
diff --git a/vendor/encode_unicode/src/utf16_char.rs b/vendor/encode_unicode/src/utf16_char.rs
new file mode 100644
index 0000000..d8a6cec
--- /dev/null
+++ b/vendor/encode_unicode/src/utf16_char.rs
@@ -0,0 +1,687 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+use utf16_iterators::Utf16Iterator;
+use traits::{CharExt, U16UtfExt};
+use utf8_char::Utf8Char;
+use errors::{InvalidUtf16Slice, InvalidUtf16Array, InvalidUtf16Tuple};
+use errors::{NonBMPError, EmptyStrError, FromStrError};
+extern crate core;
+use self::core::{hash,fmt};
+use self::core::cmp::Ordering;
+use self::core::borrow::Borrow;
+use self::core::ops::Deref;
+use self::core::str::FromStr;
+#[cfg(feature="std")]
+use self::core::iter::FromIterator;
+#[cfg(feature="std")]
+#[allow(deprecated)]
+use std::ascii::AsciiExt;
+#[cfg(feature="ascii")]
+use self::core::char;
+#[cfg(feature="ascii")]
+extern crate ascii;
+#[cfg(feature="ascii")]
+use self::ascii::{AsciiChar,ToAsciiChar,ToAsciiCharError};
+
+
+// I don't think there is any good default value for char, but char does.
+#[derive(Default)]
+// char doesn't do anything more advanced than u32 for Eq/Ord, so we shouldn't either.
+// When it's a single unit, the second is zero, so Eq works.
+// #[derive(Ord)] however, breaks on surrogate pairs.
+#[derive(PartialEq,Eq)]
+#[derive(Clone,Copy)]
+
+
+/// An unicode codepoint stored as UTF-16.
+///
+/// It can be borrowed as an `u16` slice, and has the same size as `char`.
+pub struct Utf16Char {
+ units: [u16; 2],
+}
+
+
+ /////////////////////
+ //conversion traits//
+/////////////////////
+impl FromStr for Utf16Char {
+ type Err = FromStrError;
+ /// Create an `Utf16Char` from a string slice.
+ /// The string must contain exactly one codepoint.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::error::FromStrError::*;
+ /// use encode_unicode::Utf16Char;
+ /// use std::str::FromStr;
+ ///
+ /// assert_eq!(Utf16Char::from_str("a"), Ok(Utf16Char::from('a')));
+ /// assert_eq!(Utf16Char::from_str("🂠"), Ok(Utf16Char::from('🂠')));
+ /// assert_eq!(Utf16Char::from_str(""), Err(Empty));
+ /// assert_eq!(Utf16Char::from_str("ab"), Err(MultipleCodepoints));
+ /// assert_eq!(Utf16Char::from_str("é"), Err(MultipleCodepoints));// 'e'+u301 combining mark
+ /// ```
+ fn from_str(s: &str) -> Result<Self, FromStrError> {
+ match Utf16Char::from_str_start(s) {
+ Ok((u16c,bytes)) if bytes == s.len() => Ok(u16c),
+ Ok((_,_)) => Err(FromStrError::MultipleCodepoints),
+ Err(EmptyStrError) => Err(FromStrError::Empty),
+ }
+ }
+}
+impl From<char> for Utf16Char {
+ fn from(c: char) -> Self {
+ let (first, second) = c.to_utf16_tuple();
+ Utf16Char{ units: [first, second.unwrap_or(0)] }
+ }
+}
+impl From<Utf8Char> for Utf16Char {
+ fn from(utf8: Utf8Char) -> Utf16Char {
+ let (b, utf8_len) = utf8.to_array();
+ match utf8_len {
+ 1 => Utf16Char{ units: [b[0] as u16, 0] },
+ 4 => {// need surrogate
+ let mut first = 0xd800 - (0x01_00_00u32 >> 10) as u16;
+ first += (b[0] as u16 & 0x07) << 8;
+ first += (b[1] as u16 & 0x3f) << 2;
+ first += (b[2] as u16 & 0x30) >> 4;
+ let mut second = 0xdc00;
+ second |= (b[2] as u16 & 0x0f) << 6;
+ second |= b[3] as u16 & 0x3f;
+ Utf16Char{ units: [first, second] }
+ },
+ _ => { // 2 or 3
+ let mut unit = ((b[0] as u16 & 0x1f) << 6) | (b[1] as u16 & 0x3f);
+ if utf8_len == 3 {
+ unit = (unit << 6) | (b[2] as u16 & 0x3f);
+ }
+ Utf16Char{ units: [unit, 0] }
+ },
+ }
+ }
+}
+impl From<Utf16Char> for char {
+ fn from(uc: Utf16Char) -> char {
+ char::from_utf16_array_unchecked(uc.to_array())
+ }
+}
+impl IntoIterator for Utf16Char {
+ type Item=u16;
+ type IntoIter=Utf16Iterator;
+ /// Iterate over the units.
+ fn into_iter(self) -> Utf16Iterator {
+ Utf16Iterator::from(self)
+ }
+}
+
+#[cfg(feature="std")]
+impl Extend<Utf16Char> for Vec<u16> {
+ fn extend<I:IntoIterator<Item=Utf16Char>>(&mut self, iter: I) {
+ let iter = iter.into_iter();
+ self.reserve(iter.size_hint().0);
+ for u16c in iter {
+ self.push(u16c.units[0]);
+ if u16c.units[1] != 0 {
+ self.push(u16c.units[1]);
+ }
+ }
+ }
+}
+#[cfg(feature="std")]
+impl<'a> Extend<&'a Utf16Char> for Vec<u16> {
+ fn extend<I:IntoIterator<Item=&'a Utf16Char>>(&mut self, iter: I) {
+ self.extend(iter.into_iter().cloned())
+ }
+}
+#[cfg(feature="std")]
+impl FromIterator<Utf16Char> for Vec<u16> {
+ fn from_iter<I:IntoIterator<Item=Utf16Char>>(iter: I) -> Self {
+ let mut vec = Vec::new();
+ vec.extend(iter);
+ return vec;
+ }
+}
+#[cfg(feature="std")]
+impl<'a> FromIterator<&'a Utf16Char> for Vec<u16> {
+ fn from_iter<I:IntoIterator<Item=&'a Utf16Char>>(iter: I) -> Self {
+ Self::from_iter(iter.into_iter().cloned())
+ }
+}
+
+#[cfg(feature="std")]
+impl Extend<Utf16Char> for String {
+ fn extend<I:IntoIterator<Item=Utf16Char>>(&mut self, iter: I) {
+ self.extend(iter.into_iter().map(|u16c| Utf8Char::from(u16c) ));
+ }
+}
+#[cfg(feature="std")]
+impl<'a> Extend<&'a Utf16Char> for String {
+ fn extend<I:IntoIterator<Item=&'a Utf16Char>>(&mut self, iter: I) {
+ self.extend(iter.into_iter().cloned());
+ }
+}
+#[cfg(feature="std")]
+impl FromIterator<Utf16Char> for String {
+ fn from_iter<I:IntoIterator<Item=Utf16Char>>(iter: I) -> Self {
+ let mut s = String::new();
+ s.extend(iter);
+ return s;
+ }
+}
+#[cfg(feature="std")]
+impl<'a> FromIterator<&'a Utf16Char> for String {
+ fn from_iter<I:IntoIterator<Item=&'a Utf16Char>>(iter: I) -> Self {
+ Self::from_iter(iter.into_iter().cloned())
+ }
+}
+
+
+ /////////////////
+ //getter traits//
+/////////////////
+impl AsRef<[u16]> for Utf16Char {
+ #[inline]
+ fn as_ref(&self) -> &[u16] {
+ &self.units[..self.len()]
+ }
+}
+impl Borrow<[u16]> for Utf16Char {
+ #[inline]
+ fn borrow(&self) -> &[u16] {
+ self.as_ref()
+ }
+}
+impl Deref for Utf16Char {
+ type Target = [u16];
+ #[inline]
+ fn deref(&self) -> &[u16] {
+ self.as_ref()
+ }
+}
+
+
+ ////////////////
+ //ascii traits//
+////////////////
+#[cfg(feature="std")]
+#[allow(deprecated)]
+impl AsciiExt for Utf16Char {
+ type Owned = Self;
+ fn is_ascii(&self) -> bool {
+ self.units[0] < 128
+ }
+ fn eq_ignore_ascii_case(&self, other: &Self) -> bool {
+ self.to_ascii_lowercase() == other.to_ascii_lowercase()
+ }
+ fn to_ascii_uppercase(&self) -> Self {
+ let n = self.units[0].wrapping_sub(b'a' as u16);
+ if n < 26 {Utf16Char{ units: [n+b'A' as u16, 0] }}
+ else {*self}
+ }
+ fn to_ascii_lowercase(&self) -> Self {
+ let n = self.units[0].wrapping_sub(b'A' as u16);
+ if n < 26 {Utf16Char{ units: [n+b'a' as u16, 0] }}
+ else {*self}
+ }
+ fn make_ascii_uppercase(&mut self) {
+ *self = self.to_ascii_uppercase()
+ }
+ fn make_ascii_lowercase(&mut self) {
+ *self = self.to_ascii_lowercase();
+ }
+}
+
+#[cfg(feature="ascii")]
+/// Requires the feature "ascii".
+impl From<AsciiChar> for Utf16Char {
+ #[inline]
+ fn from(ac: AsciiChar) -> Self {
+ Utf16Char{ units: [ac.as_byte() as u16, 0] }
+ }
+}
+#[cfg(feature="ascii")]
+/// Requires the feature "ascii".
+impl ToAsciiChar for Utf16Char {
+ #[inline]
+ fn to_ascii_char(self) -> Result<AsciiChar, ToAsciiCharError> {
+ // ToAsciiCHar is not implemented for u16 in ascii 0.9.0
+ if self.is_ascii() {self.units[0] as u8} else {255}.to_ascii_char()
+ }
+ #[inline]
+ unsafe fn to_ascii_char_unchecked(self) -> AsciiChar {
+ (self.units[0] as u8).to_ascii_char_unchecked()
+ }
+}
+
+
+ /////////////////////////////////////////////////////////
+ //Genaral traits that cannot be derived to emulate char//
+/////////////////////////////////////////////////////////
+impl hash::Hash for Utf16Char {
+ fn hash<H : hash::Hasher>(&self, state: &mut H) {
+ self.to_char().hash(state);
+ }
+}
+impl fmt::Debug for Utf16Char {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmt::Debug::fmt(&self.to_char(), fmtr)
+ }
+}
+impl fmt::Display for Utf16Char {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmt::Display::fmt(&Utf8Char::from(*self), fmtr)
+ }
+}
+// Cannot derive these impls because two-unit characters must always compare
+// greater than one-unit ones.
+impl PartialOrd for Utf16Char {
+ #[inline]
+ fn partial_cmp(&self, rhs: &Self) -> Option<Ordering> {
+ Some(self.cmp(rhs))
+ }
+}
+impl Ord for Utf16Char {
+ #[inline]
+ fn cmp(&self, rhs: &Self) -> Ordering {
+ // Shift the first unit by 0xd if surrogate, and 0 otherwise.
+ // This ensures surrogates are always greater than 0xffff, and
+ // that the second unit only affect the result when the first are equal.
+ // Multiplying by a constant factor isn't enough because that factor
+ // would have to be greater than 1023 and smaller than 5.5.
+ // This transformation is less complicated than combine_surrogates().
+ let lhs = (self.units[0] as u32, self.units[1] as u32);
+ let rhs = (rhs.units[0] as u32, rhs.units[1] as u32);
+ let lhs = (lhs.0 << (lhs.1 >> 12)) + lhs.1;
+ let rhs = (rhs.0 << (rhs.1 >> 12)) + rhs.1;
+ lhs.cmp(&rhs)
+ }
+}
+
+
+ ////////////////////////////////
+ //Comparisons with other types//
+////////////////////////////////
+impl PartialEq<char> for Utf16Char {
+ fn eq(&self, u32c: &char) -> bool {
+ *self == Utf16Char::from(*u32c)
+ }
+}
+impl PartialEq<Utf16Char> for char {
+ fn eq(&self, u16c: &Utf16Char) -> bool {
+ Utf16Char::from(*self) == *u16c
+ }
+}
+impl PartialOrd<char> for Utf16Char {
+ fn partial_cmp(&self, u32c: &char) -> Option<Ordering> {
+ self.partial_cmp(&Utf16Char::from(*u32c))
+ }
+}
+impl PartialOrd<Utf16Char> for char {
+ fn partial_cmp(&self, u16c: &Utf16Char) -> Option<Ordering> {
+ Utf16Char::from(*self).partial_cmp(u16c)
+ }
+}
+
+impl PartialEq<Utf8Char> for Utf16Char {
+ fn eq(&self, u8c: &Utf8Char) -> bool {
+ *self == Utf16Char::from(*u8c)
+ }
+}
+impl PartialOrd<Utf8Char> for Utf16Char {
+ fn partial_cmp(&self, u8c: &Utf8Char) -> Option<Ordering> {
+ self.partial_cmp(&Utf16Char::from(*u8c))
+ }
+}
+// The other direction is implemented in utf8_char.rs
+
+/// Only considers the unit equal if the codepoint of the `Utf16Char` is not
+/// made up of a surrogate pair.
+///
+/// There is no impl in the opposite direction, as this should only be used to
+/// compare `Utf16Char`s against constants.
+///
+/// # Examples
+///
+/// ```
+/// # use encode_unicode::Utf16Char;
+/// assert!(Utf16Char::from('6') == b'6' as u16);
+/// assert!(Utf16Char::from('\u{FFFF}') == 0xffff_u16);
+/// assert!(Utf16Char::from_tuple((0xd876, Some(0xdef9))).unwrap() != 0xd876_u16);
+/// ```
+impl PartialEq<u16> for Utf16Char {
+ fn eq(&self, unit: &u16) -> bool {
+ self.units[0] == *unit && self.units[1] == 0
+ }
+}
+/// Only considers the byte equal if the codepoint of the `Utf16Char` is <= U+FF.
+///
+/// # Examples
+///
+/// ```
+/// # use encode_unicode::Utf16Char;
+/// assert!(Utf16Char::from('6') == b'6');
+/// assert!(Utf16Char::from('\u{00FF}') == b'\xff');
+/// assert!(Utf16Char::from('\u{0100}') != b'\0');
+/// ```
+impl PartialEq<u8> for Utf16Char {
+ fn eq(&self, byte: &u8) -> bool {
+ self.units[0] == *byte as u16
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf16Char`s that are not ASCII never compare equal.
+impl PartialEq<AsciiChar> for Utf16Char {
+ #[inline]
+ fn eq(&self, ascii: &AsciiChar) -> bool {
+ self.units[0] == *ascii as u16
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf16Char`s that are not ASCII never compare equal.
+impl PartialEq<Utf16Char> for AsciiChar {
+ #[inline]
+ fn eq(&self, u16c: &Utf16Char) -> bool {
+ *self as u16 == u16c.units[0]
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf16Char`s that are not ASCII always compare greater.
+impl PartialOrd<AsciiChar> for Utf16Char {
+ #[inline]
+ fn partial_cmp(&self, ascii: &AsciiChar) -> Option<Ordering> {
+ self.units[0].partial_cmp(&(*ascii as u16))
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf16Char`s that are not ASCII always compare greater.
+impl PartialOrd<Utf16Char> for AsciiChar {
+ #[inline]
+ fn partial_cmp(&self, u16c: &Utf16Char) -> Option<Ordering> {
+ (*self as u16).partial_cmp(&u16c.units[0])
+ }
+}
+
+
+ ///////////////////////////////////////////////////////
+ //pub impls that should be together for nicer rustdoc//
+///////////////////////////////////////////////////////
+impl Utf16Char {
+ /// Create an `Utf16Char` from the first codepoint in a string slice,
+ /// converting from UTF-8 to UTF-16.
+ ///
+ /// The returned `usize` is the number of UTF-8 bytes used from the str,
+ /// and not the number of UTF-16 units.
+ ///
+ /// Returns an error if the `str` is empty.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::Utf16Char;
+ ///
+ /// assert_eq!(Utf16Char::from_str_start("a"), Ok((Utf16Char::from('a'),1)));
+ /// assert_eq!(Utf16Char::from_str_start("ab"), Ok((Utf16Char::from('a'),1)));
+ /// assert_eq!(Utf16Char::from_str_start("🂠 "), Ok((Utf16Char::from('🂠'),4)));
+ /// assert_eq!(Utf16Char::from_str_start("é"), Ok((Utf16Char::from('e'),1)));// 'e'+u301 combining mark
+ /// assert!(Utf16Char::from_str_start("").is_err());
+ /// ```
+ pub fn from_str_start(s: &str) -> Result<(Self,usize), EmptyStrError> {
+ if s.is_empty() {
+ return Err(EmptyStrError);
+ }
+ let b = s.as_bytes();
+ // Read the last byte first to reduce the number of unnecesary length checks.
+ match b[0] {
+ 0...127 => {// 1 byte => 1 unit
+ let unit = b[0] as u16;// 0b0000_0000_0xxx_xxxx
+ Ok((Utf16Char{ units: [unit, 0] }, 1))
+ },
+ 0b1000_0000...0b1101_1111 => {// 2 bytes => 1 unit
+ let unit = (((b[1] & 0x3f) as u16) << 0) // 0b0000_0000_00xx_xxxx
+ | (((b[0] & 0x1f) as u16) << 6);// 0b0000_0xxx_xx00_0000
+ Ok((Utf16Char{ units: [unit, 0] }, 2))
+ },
+ 0b1110_0000...0b1110_1111 => {// 3 bytes => 1 unit
+ let unit = (((b[2] & 0x3f) as u16) << 0) // 0b0000_0000_00xx_xxxx
+ | (((b[1] & 0x3f) as u16) << 6) // 0b0000_xxxx_xx00_0000
+ | (((b[0] & 0x0f) as u16) << 12);// 0bxxxx_0000_0000_0000
+ Ok((Utf16Char{ units: [unit, 0] }, 3))
+ },
+ _ => {// 4 bytes => 2 units
+ let second = 0xdc00 // 0b1101_1100_0000_0000
+ | (((b[3] & 0x3f) as u16) << 0) // 0b0000_0000_00xx_xxxx
+ | (((b[2] & 0x0f) as u16) << 6);// 0b0000_00xx_xx00_0000
+ let first = 0xd800-(0x01_00_00u32>>10) as u16// 0b1101_0111_1100_0000
+ + (((b[2] & 0x30) as u16) >> 4) // 0b0000_0000_0000_00xx
+ + (((b[1] & 0x3f) as u16) << 2) // 0b0000_0000_xxxx_xx00
+ + (((b[0] & 0x07) as u16) << 8); // 0b0000_0xxx_0000_0000
+ Ok((Utf16Char{ units: [first, second] }, 4))
+ }
+ }
+ }
+ /// Validate and store the first UTF-16 codepoint in the slice.
+ /// Also return how many units were needed.
+ pub fn from_slice_start(src: &[u16]) -> Result<(Self,usize), InvalidUtf16Slice> {
+ char::from_utf16_slice_start(src).map(|(_,len)| {
+ let second = if len==2 {src[1]} else {0};
+ (Utf16Char{ units: [src[0], second] }, len)
+ })
+ }
+ /// Store the first UTF-16 codepoint of the slice.
+ ///
+ /// # Safety
+ ///
+ /// The slice must be non-empty and start with a valid UTF-16 codepoint.
+ /// The length of the slice is never checked.
+ pub unsafe fn from_slice_start_unchecked(src: &[u16]) -> (Self,usize) {
+ let first = *src.get_unchecked(0);
+ if first.is_utf16_leading_surrogate() {
+ (Utf16Char{ units: [first, *src.get_unchecked(1)] }, 2)
+ } else {
+ (Utf16Char{ units: [first, 0] }, 1)
+ }
+ }
+ /// Validate and store an UTF-16 array as returned from `char.to_utf16_array()`.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::Utf16Char;
+ /// use encode_unicode::error::InvalidUtf16Array;
+ ///
+ /// assert_eq!(Utf16Char::from_array(['x' as u16, 'y' as u16]), Ok(Utf16Char::from('x')));
+ /// assert_eq!(Utf16Char::from_array(['睷' as u16, 0]), Ok(Utf16Char::from('睷')));
+ /// assert_eq!(Utf16Char::from_array([0xda6f, 0xdcde]), Ok(Utf16Char::from('\u{abcde}')));
+ /// assert_eq!(Utf16Char::from_array([0xf111, 0xdbad]), Ok(Utf16Char::from('\u{f111}')));
+ /// assert_eq!(Utf16Char::from_array([0xdaaf, 0xdaaf]), Err(InvalidUtf16Array::SecondIsNotTrailingSurrogate));
+ /// assert_eq!(Utf16Char::from_array([0xdcac, 0x9000]), Err(InvalidUtf16Array::FirstIsTrailingSurrogate));
+ /// ```
+ pub fn from_array(units: [u16; 2]) -> Result<Self,InvalidUtf16Array> {
+ if (units[0] & 0xf8_00) != 0xd8_00 {
+ Ok(Utf16Char { units: [units[0], 0] })
+ } else if units[0] < 0xdc_00 && (units[1] & 0xfc_00) == 0xdc_00 {
+ Ok(Utf16Char { units: units })
+ } else if units[0] < 0xdc_00 {
+ Err(InvalidUtf16Array::SecondIsNotTrailingSurrogate)
+ } else {
+ Err(InvalidUtf16Array::FirstIsTrailingSurrogate)
+ }
+ }
+ /// Create an `Utf16Char` from an array as returned from `char.to_utf16_array()`.
+ ///
+ /// # Safety
+ ///
+ /// The units must form a valid codepoint, and the second unit must be 0
+ /// when a surrogate pair is not required.
+ /// Violating this can easily lead to undefined behavior, although unlike
+ /// `char` bad `Utf16Char`s simply existing is not immediately UB.
+ pub unsafe fn from_array_unchecked(units: [u16; 2]) -> Self {
+ Utf16Char { units: units }
+ }
+ /// Validate and store a UTF-16 pair as returned from `char.to_utf16_tuple()`.
+ pub fn from_tuple(utf16: (u16,Option<u16>)) -> Result<Self,InvalidUtf16Tuple> {
+ unsafe {char::from_utf16_tuple(utf16).map(|_|
+ Self::from_tuple_unchecked(utf16)
+ )}
+ }
+ /// Create an `Utf16Char` from a tuple as returned from `char.to_utf16_tuple()`.
+ ///
+ /// # Safety
+ ///
+ /// The units must form a valid codepoint with the second being 0 when a
+ /// surrogate pair is not required.
+ /// Violating this can easily lead to undefined behavior.
+ pub unsafe fn from_tuple_unchecked(utf16: (u16,Option<u16>)) -> Self {
+ Utf16Char { units: [utf16.0, utf16.1.unwrap_or(0)] }
+ }
+ /// Create an `Utf16Char` from a single unit.
+ ///
+ /// Codepoints < '\u{1_0000}' (which fit in a `u16`) are part of the basic
+ /// multilingual plane unless they are reserved for surrogate pairs.
+ ///
+ /// # Errors
+ ///
+ /// Returns `NonBMPError` if the unit is in the range `0xd800..0xe000`
+ /// (which means that it's part of a surrogat pair)
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// # use encode_unicode::Utf16Char;
+ /// assert_eq!(Utf16Char::from_bmp(0x40).unwrap(), '@');
+ /// assert_eq!(Utf16Char::from_bmp('ø' as u16).unwrap(), 'ø');
+ /// assert!(Utf16Char::from_bmp(0xdddd).is_err());
+ /// ```
+ pub fn from_bmp(bmp_codepoint: u16) -> Result<Self,NonBMPError> {
+ if bmp_codepoint & 0xf800 != 0xd800 {
+ Ok(Utf16Char{ units: [bmp_codepoint, 0] })
+ } else {
+ Err(NonBMPError)
+ }
+ }
+ /// Create an `Utf16Char` from a single unit without checking that it's a
+ /// valid codepoint on its own.
+ ///
+ /// # Safety
+ ///
+ /// The unit must be less than 0xd800 or greater than 0xdfff.
+ /// In other words, not part of a surrogate pair.
+ /// Violating this can easily lead to undefined behavior.
+ #[inline]
+ pub unsafe fn from_bmp_unchecked(bmp_codepoint: u16) -> Self {
+ Utf16Char{ units: [bmp_codepoint, 0] }
+ }
+ /// Checks that the codepoint is in the basic multilingual plane.
+ ///
+ /// # Examples
+ /// ```
+ /// # use encode_unicode::Utf16Char;
+ /// assert_eq!(Utf16Char::from('e').is_bmp(), true);
+ /// assert_eq!(Utf16Char::from('€').is_bmp(), true);
+ /// assert_eq!(Utf16Char::from('𝔼').is_bmp(), false);
+ /// ```
+ #[inline]
+ pub fn is_bmp(&self) -> bool {
+ self.units[1] == 0
+ }
+
+ /// The number of units this character is made up of.
+ ///
+ /// Is either 1 or 2 and identical to `.as_char().len_utf16()`
+ /// or `.as_ref().len()`.
+ #[inline]
+ pub fn len(self) -> usize {
+ 1 + (self.units[1] as usize >> 15)
+ }
+ // There is no `.is_emty()` because it would always return false.
+
+ /// Checks that the codepoint is an ASCII character.
+ #[inline]
+ pub fn is_ascii(&self) -> bool {
+ self.units[0] <= 127
+ }
+ /// Checks that two characters are an ASCII case-insensitive match.
+ ///
+ /// Is equivalent to `a.to_ascii_lowercase() == b.to_ascii_lowercase()`.
+ #[cfg(feature="std")]
+ pub fn eq_ignore_ascii_case(&self, other: &Self) -> bool {
+ self.to_ascii_lowercase() == other.to_ascii_lowercase()
+ }
+ /// Converts the character to its ASCII upper case equivalent.
+ ///
+ /// ASCII letters 'a' to 'z' are mapped to 'A' to 'Z',
+ /// but non-ASCII letters are unchanged.
+ #[cfg(feature="std")]
+ pub fn to_ascii_uppercase(&self) -> Self {
+ let n = self.units[0].wrapping_sub(b'a' as u16);
+ if n < 26 {Utf16Char{ units: [n+b'A' as u16, 0] }}
+ else {*self}
+ }
+ /// Converts the character to its ASCII lower case equivalent.
+ ///
+ /// ASCII letters 'A' to 'Z' are mapped to 'a' to 'z',
+ /// but non-ASCII letters are unchanged.
+ #[cfg(feature="std")]
+ pub fn to_ascii_lowercase(&self) -> Self {
+ let n = self.units[0].wrapping_sub(b'A' as u16);
+ if n < 26 {Utf16Char{ units: [n+b'a' as u16, 0] }}
+ else {*self}
+ }
+ /// Converts the character to its ASCII upper case equivalent in-place.
+ ///
+ /// ASCII letters 'a' to 'z' are mapped to 'A' to 'Z',
+ /// but non-ASCII letters are unchanged.
+ #[cfg(feature="std")]
+ pub fn make_ascii_uppercase(&mut self) {
+ *self = self.to_ascii_uppercase()
+ }
+ /// Converts the character to its ASCII lower case equivalent in-place.
+ ///
+ /// ASCII letters 'A' to 'Z' are mapped to 'a' to 'z',
+ /// but non-ASCII letters are unchanged.
+ #[cfg(feature="std")]
+ pub fn make_ascii_lowercase(&mut self) {
+ *self = self.to_ascii_lowercase();
+ }
+
+ /// Convert from UTF-16 to UTF-32
+ pub fn to_char(self) -> char {
+ self.into()
+ }
+ /// Write the internal representation to a slice,
+ /// and then returns the number of `u16`s written.
+ ///
+ /// # Panics
+ /// Will panic the buffer is too small;
+ /// You can get the required length from `.len()`,
+ /// but a buffer of length two is always large enough.
+ pub fn to_slice(self, dst: &mut[u16]) -> usize {
+ // Write the last unit first to avoid repeated length checks.
+ let extra = self.units[1] as usize >> 15;
+ match dst.get_mut(extra) {
+ Some(first) => *first = self.units[extra],
+ None => panic!("The provided buffer is too small.")
+ }
+ if extra != 0 {dst[0] = self.units[0];}
+ extra+1
+ }
+ /// Get the character represented as an array of two units.
+ ///
+ /// The second `u16` is zero for codepoints that fit in one unit.
+ #[inline]
+ pub fn to_array(self) -> [u16;2] {
+ self.units
+ }
+ /// The second `u16` is used for surrogate pairs.
+ #[inline]
+ pub fn to_tuple(self) -> (u16,Option<u16>) {
+ (self.units[0], if self.units[1]==0 {None} else {Some(self.units[1])})
+ }
+}
diff --git a/vendor/encode_unicode/src/utf16_iterators.rs b/vendor/encode_unicode/src/utf16_iterators.rs
new file mode 100644
index 0000000..7adb5ac
--- /dev/null
+++ b/vendor/encode_unicode/src/utf16_iterators.rs
@@ -0,0 +1,270 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+use traits::CharExt;
+use utf16_char::Utf16Char;
+use errors::EmptyStrError;
+extern crate core;
+use self::core::fmt;
+use self::core::borrow::Borrow;
+
+// Invalid values that says the field is consumed or empty.
+const FIRST_USED: u16 = 0x_dc_00;
+const SECOND_USED: u16 = 0;
+
+/// Iterate over the units of the UTF-16 representation of a codepoint.
+#[derive(Clone)]
+pub struct Utf16Iterator {
+ first: u16,
+ second: u16,
+}
+impl From<char> for Utf16Iterator {
+ fn from(c: char) -> Self {
+ let (first, second) = c.to_utf16_tuple();
+ Utf16Iterator{ first: first, second: second.unwrap_or(SECOND_USED) }
+ }
+}
+impl From<Utf16Char> for Utf16Iterator {
+ fn from(uc: Utf16Char) -> Self {
+ let (first, second) = uc.to_tuple();
+ Utf16Iterator{ first: first, second: second.unwrap_or(SECOND_USED) }
+ }
+}
+impl Iterator for Utf16Iterator {
+ type Item=u16;
+ fn next(&mut self) -> Option<u16> {
+ match (self.first, self.second) {
+ (FIRST_USED, SECOND_USED) => { None },
+ (FIRST_USED, second ) => {self.second = SECOND_USED; Some(second)},
+ (first , _ ) => {self.first = FIRST_USED; Some(first )},
+ }
+ }
+ fn size_hint(&self) -> (usize, Option<usize>) {
+ (self.len(), Some(self.len()))
+ }
+}
+impl ExactSizeIterator for Utf16Iterator {
+ fn len(&self) -> usize {
+ (if self.first == FIRST_USED {0} else {1}) +
+ (if self.second == SECOND_USED {0} else {1})
+ }
+}
+impl fmt::Debug for Utf16Iterator {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ let mut clone = self.clone();
+ match (clone.next(), clone.next()) {
+ (Some(one), None) => write!(fmtr, "[{}]", one),
+ (Some(a), Some(b)) => write!(fmtr, "[{}, {}]", a, b),
+ (None, _) => write!(fmtr, "[]"),
+ }
+ }
+}
+
+
+
+/// Converts an iterator of `Utf16Char` (or `&Utf16Char`)
+/// to an iterator of `u16`s.
+/// Is equivalent to calling `.flat_map()` on the original iterator,
+/// but the returned iterator is about twice as fast.
+///
+/// The exact number of units cannot be known in advance, but `size_hint()`
+/// gives the possible range.
+///
+/// # Examples
+///
+/// From iterator of values:
+///
+/// ```
+/// use encode_unicode::{iter_units, CharExt};
+///
+/// let iterator = "foo".chars().map(|c| c.to_utf16() );
+/// let mut units = [0; 4];
+/// for (u,dst) in iter_units(iterator).zip(&mut units) {*dst=u;}
+/// assert_eq!(units, ['f' as u16, 'o' as u16, 'o' as u16, 0]);
+/// ```
+///
+/// From iterator of references:
+///
+#[cfg_attr(feature="std", doc=" ```")]
+#[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+/// use encode_unicode::{iter_units, CharExt, Utf16Char};
+///
+/// // (💣 takes two units)
+/// let chars: Vec<Utf16Char> = "💣 bomb 💣".chars().map(|c| c.to_utf16() ).collect();
+/// let units: Vec<u16> = iter_units(&chars).collect();
+/// let flat_map: Vec<u16> = chars.iter().flat_map(|u16c| *u16c ).collect();
+/// assert_eq!(units, flat_map);
+/// ```
+pub fn iter_units<U:Borrow<Utf16Char>, I:IntoIterator<Item=U>>
+(iterable: I) -> Utf16CharSplitter<U, I::IntoIter> {
+ Utf16CharSplitter{ inner: iterable.into_iter(), prev_second: 0 }
+}
+
+/// The iterator type returned by `iter_units()`
+#[derive(Clone)]
+pub struct Utf16CharSplitter<U:Borrow<Utf16Char>, I:Iterator<Item=U>> {
+ inner: I,
+ prev_second: u16,
+}
+impl<I:Iterator<Item=Utf16Char>> From<I> for Utf16CharSplitter<Utf16Char,I> {
+ /// A less generic constructor than `iter_units()`
+ fn from(iter: I) -> Self {
+ iter_units(iter)
+ }
+}
+impl<U:Borrow<Utf16Char>, I:Iterator<Item=U>> Utf16CharSplitter<U,I> {
+ /// Extracts the source iterator.
+ ///
+ /// Note that `iter_units(iter.into_inner())` is not a no-op:
+ /// If the last returned unit from `next()` was a leading surrogate,
+ /// the trailing surrogate is lost.
+ pub fn into_inner(self) -> I {
+ self.inner
+ }
+}
+impl<U:Borrow<Utf16Char>, I:Iterator<Item=U>> Iterator for Utf16CharSplitter<U,I> {
+ type Item = u16;
+ fn next(&mut self) -> Option<Self::Item> {
+ if self.prev_second == 0 {
+ self.inner.next().map(|u16c| {
+ let units = u16c.borrow().to_array();
+ self.prev_second = units[1];
+ units[0]
+ })
+ } else {
+ let prev_second = self.prev_second;
+ self.prev_second = 0;
+ Some(prev_second)
+ }
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ // Doesn't need to handle unlikely overflows correctly because
+ // size_hint() cannot be relied upon anyway. (the trait isn't unsafe)
+ let (min, max) = self.inner.size_hint();
+ let add = if self.prev_second == 0 {0} else {1};
+ (min.wrapping_add(add), max.map(|max| max.wrapping_mul(2).wrapping_add(add) ))
+ }
+}
+
+
+
+/// An iterator over the codepoints in a `str` represented as `Utf16Char`.
+#[derive(Clone)]
+pub struct Utf16CharIndices<'a>{
+ str: &'a str,
+ index: usize,
+}
+impl<'a> From<&'a str> for Utf16CharIndices<'a> {
+ fn from(s: &str) -> Utf16CharIndices {
+ Utf16CharIndices{str: s, index: 0}
+ }
+}
+impl<'a> Utf16CharIndices<'a> {
+ /// Extract the remainder of the source `str`.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::{StrExt, Utf16Char};
+ /// let mut iter = "abc".utf16char_indices();
+ /// assert_eq!(iter.next_back(), Some((2, Utf16Char::from('c'))));
+ /// assert_eq!(iter.next(), Some((0, Utf16Char::from('a'))));
+ /// assert_eq!(iter.as_str(), "b");
+ /// ```
+ pub fn as_str(&self) -> &'a str {
+ &self.str[self.index..]
+ }
+}
+impl<'a> Iterator for Utf16CharIndices<'a> {
+ type Item = (usize,Utf16Char);
+ fn next(&mut self) -> Option<(usize,Utf16Char)> {
+ match Utf16Char::from_str_start(&self.str[self.index..]) {
+ Ok((u16c, bytes)) => {
+ let item = (self.index, u16c);
+ self.index += bytes;
+ Some(item)
+ },
+ Err(EmptyStrError) => None
+ }
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ let len = self.str.len() - self.index;
+ // For len+3 to overflow, the slice must fill all but two bytes of
+ // addressable memory, and size_hint() doesn't need to be correct.
+ (len.wrapping_add(3)/4, Some(len))
+ }
+}
+impl<'a> DoubleEndedIterator for Utf16CharIndices<'a> {
+ fn next_back(&mut self) -> Option<(usize,Utf16Char)> {
+ if self.index < self.str.len() {
+ let rev = self.str.bytes().rev();
+ let len = 1 + rev.take_while(|b| b & 0b1100_0000 == 0b1000_0000 ).count();
+ let starts = self.str.len() - len;
+ let (u16c,_) = Utf16Char::from_str_start(&self.str[starts..]).unwrap();
+ self.str = &self.str[..starts];
+ Some((starts, u16c))
+ } else {
+ None
+ }
+ }
+}
+impl<'a> fmt::Debug for Utf16CharIndices<'a> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmtr.debug_tuple("Utf16CharIndices")
+ .field(&self.index)
+ .field(&self.as_str())
+ .finish()
+ }
+}
+
+
+/// An iterator over the codepoints in a `str` represented as `Utf16Char`.
+#[derive(Clone)]
+pub struct Utf16Chars<'a>(Utf16CharIndices<'a>);
+impl<'a> From<&'a str> for Utf16Chars<'a> {
+ fn from(s: &str) -> Utf16Chars {
+ Utf16Chars(Utf16CharIndices::from(s))
+ }
+}
+impl<'a> Utf16Chars<'a> {
+ /// Extract the remainder of the source `str`.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::{StrExt, Utf16Char};
+ /// let mut iter = "abc".utf16chars();
+ /// assert_eq!(iter.next(), Some(Utf16Char::from('a')));
+ /// assert_eq!(iter.next_back(), Some(Utf16Char::from('c')));
+ /// assert_eq!(iter.as_str(), "b");
+ /// ```
+ pub fn as_str(&self) -> &'a str {
+ self.0.as_str()
+ }
+}
+impl<'a> Iterator for Utf16Chars<'a> {
+ type Item = Utf16Char;
+ fn next(&mut self) -> Option<Utf16Char> {
+ self.0.next().map(|(_,u16c)| u16c )
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ self.0.size_hint()
+ }
+}
+impl<'a> DoubleEndedIterator for Utf16Chars<'a> {
+ fn next_back(&mut self) -> Option<Utf16Char> {
+ self.0.next_back().map(|(_,u16c)| u16c )
+ }
+}
+impl<'a> fmt::Debug for Utf16Chars<'a> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmtr.debug_tuple("Utf16Chars")
+ .field(&self.as_str())
+ .finish()
+ }
+}
diff --git a/vendor/encode_unicode/src/utf8_char.rs b/vendor/encode_unicode/src/utf8_char.rs
new file mode 100644
index 0000000..9dba4ba
--- /dev/null
+++ b/vendor/encode_unicode/src/utf8_char.rs
@@ -0,0 +1,647 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+use errors::{FromStrError, EmptyStrError, NonAsciiError, InvalidUtf8Slice, InvalidUtf8Array};
+use utf8_iterators::Utf8Iterator;
+use traits::{CharExt, U8UtfExt};
+use utf16_char::Utf16Char;
+extern crate core;
+use self::core::{hash, fmt, str, ptr};
+use self::core::cmp::Ordering;
+use self::core::borrow::Borrow;
+use self::core::ops::Deref;
+use self::core::mem::transmute;
+#[cfg(feature="std")]
+use self::core::iter::FromIterator;
+#[cfg(feature="std")]
+#[allow(deprecated)]
+use std::ascii::AsciiExt;
+#[cfg(feature="ascii")]
+extern crate ascii;
+#[cfg(feature="ascii")]
+use self::ascii::{AsciiChar,ToAsciiChar,ToAsciiCharError};
+
+
+// I don't think there is any good default value for char, but char does.
+#[derive(Default)]
+// char doesn't do anything more advanced than u32 for Eq/Ord, so we shouldn't either.
+// The default impl of Ord for arrays works out because longer codepoints
+// start with more ones, so if they're equal, the length is the same,
+// breaks down for values above 0x1f_ff_ff but those can only be created by unsafe code.
+#[derive(PartialEq,Eq, PartialOrd,Ord)]
+
+#[derive(Clone,Copy)]
+
+
+/// An unicode codepoint stored as UTF-8.
+///
+/// It can be borrowed as a `str`, and has the same size as `char`.
+pub struct Utf8Char {
+ bytes: [u8; 4],
+}
+
+
+ /////////////////////
+ //conversion traits//
+/////////////////////
+impl str::FromStr for Utf8Char {
+ type Err = FromStrError;
+ /// Create an `Utf8Char` from a string slice.
+ /// The string must contain exactly one codepoint.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::error::FromStrError::*;
+ /// use encode_unicode::Utf8Char;
+ /// use std::str::FromStr;
+ ///
+ /// assert_eq!(Utf8Char::from_str("a"), Ok(Utf8Char::from('a')));
+ /// assert_eq!(Utf8Char::from_str("🂠"), Ok(Utf8Char::from('🂠')));
+ /// assert_eq!(Utf8Char::from_str(""), Err(Empty));
+ /// assert_eq!(Utf8Char::from_str("ab"), Err(MultipleCodepoints));
+ /// assert_eq!(Utf8Char::from_str("é"), Err(MultipleCodepoints));// 'e'+u301 combining mark
+ /// ```
+ fn from_str(s: &str) -> Result<Self, FromStrError> {
+ if s.is_empty() {
+ Err(FromStrError::Empty)
+ } else if s.len() != 1+s.as_bytes()[0].extra_utf8_bytes_unchecked() {
+ Err(FromStrError::MultipleCodepoints)
+ } else {
+ let mut bytes = [0; 4];
+ bytes[..s.len()].copy_from_slice(s.as_bytes());
+ Ok(Utf8Char{bytes: bytes})
+ }
+ }
+}
+impl From<Utf16Char> for Utf8Char {
+ fn from(utf16: Utf16Char) -> Utf8Char {
+ match utf16.to_tuple() {
+ (a @ 0...0x00_7f, _) => {
+ Utf8Char{ bytes: [a as u8, 0, 0, 0] }
+ },
+ (u @ 0...0x07_ff, _) => {
+ let b = 0x80 | (u & 0x00_3f) as u8;
+ let a = 0xc0 | ((u & 0x07_c0) >> 6) as u8;
+ Utf8Char{ bytes: [a, b, 0, 0] }
+ },
+ (u, None) => {
+ let c = 0x80 | (u & 0x00_3f) as u8;
+ let b = 0x80 | ((u & 0x0f_c0) >> 6) as u8;
+ let a = 0xe0 | ((u & 0xf0_00) >> 12) as u8;
+ Utf8Char{ bytes: [a, b, c, 0] }
+ },
+ (f, Some(s)) => {
+ let f = f + (0x01_00_00u32 >> 10) as u16;
+ let d = 0x80 | (s & 0x00_3f) as u8;
+ let c = 0x80 | ((s & 0x03_c0) >> 6) as u8
+ | ((f & 0x00_03) << 4) as u8;
+ let b = 0x80 | ((f & 0x00_fc) >> 2) as u8;
+ let a = 0xf0 | ((f & 0x07_00) >> 8) as u8;
+ Utf8Char{ bytes: [a, b, c, d] }
+ }
+ }
+ }
+}
+impl From<char> for Utf8Char {
+ fn from(c: char) -> Self {
+ Utf8Char{ bytes: c.to_utf8_array().0 }
+ }
+}
+impl From<Utf8Char> for char {
+ fn from(uc: Utf8Char) -> char {
+ unsafe{ char::from_utf8_exact_slice_unchecked(&uc.bytes[..uc.len()]) }
+ }
+}
+impl IntoIterator for Utf8Char {
+ type Item=u8;
+ type IntoIter=Utf8Iterator;
+ /// Iterate over the byte values.
+ fn into_iter(self) -> Utf8Iterator {
+ Utf8Iterator::from(self)
+ }
+}
+
+#[cfg(feature="std")]
+impl Extend<Utf8Char> for Vec<u8> {
+ fn extend<I:IntoIterator<Item=Utf8Char>>(&mut self, iter: I) {
+ let iter = iter.into_iter();
+ self.reserve(iter.size_hint().0);
+ for u8c in iter {
+ // twice as fast as self.extend_from_slice(u8c.as_bytes());
+ self.push(u8c.bytes[0]);
+ for &extra in &u8c.bytes[1..] {
+ if extra != 0 {
+ self.push(extra);
+ }
+ }
+ }
+ }
+}
+#[cfg(feature="std")]
+impl<'a> Extend<&'a Utf8Char> for Vec<u8> {
+ fn extend<I:IntoIterator<Item=&'a Utf8Char>>(&mut self, iter: I) {
+ self.extend(iter.into_iter().cloned())
+ }
+}
+#[cfg(feature="std")]
+impl Extend<Utf8Char> for String {
+ fn extend<I:IntoIterator<Item=Utf8Char>>(&mut self, iter: I) {
+ unsafe { self.as_mut_vec().extend(iter) }
+ }
+}
+#[cfg(feature="std")]
+impl<'a> Extend<&'a Utf8Char> for String {
+ fn extend<I:IntoIterator<Item=&'a Utf8Char>>(&mut self, iter: I) {
+ self.extend(iter.into_iter().cloned())
+ }
+}
+#[cfg(feature="std")]
+impl FromIterator<Utf8Char> for String {
+ fn from_iter<I:IntoIterator<Item=Utf8Char>>(iter: I) -> String {
+ let mut string = String::new();
+ string.extend(iter);
+ return string;
+ }
+}
+#[cfg(feature="std")]
+impl<'a> FromIterator<&'a Utf8Char> for String {
+ fn from_iter<I:IntoIterator<Item=&'a Utf8Char>>(iter: I) -> String {
+ iter.into_iter().cloned().collect()
+ }
+}
+#[cfg(feature="std")]
+impl FromIterator<Utf8Char> for Vec<u8> {
+ fn from_iter<I:IntoIterator<Item=Utf8Char>>(iter: I) -> Self {
+ iter.into_iter().collect::<String>().into_bytes()
+ }
+}
+#[cfg(feature="std")]
+impl<'a> FromIterator<&'a Utf8Char> for Vec<u8> {
+ fn from_iter<I:IntoIterator<Item=&'a Utf8Char>>(iter: I) -> Self {
+ iter.into_iter().cloned().collect::<String>().into_bytes()
+ }
+}
+
+
+ /////////////////
+ //getter traits//
+/////////////////
+impl AsRef<[u8]> for Utf8Char {
+ fn as_ref(&self) -> &[u8] {
+ &self.bytes[..self.len()]
+ }
+}
+impl AsRef<str> for Utf8Char {
+ fn as_ref(&self) -> &str {
+ unsafe{ str::from_utf8_unchecked( self.as_ref() ) }
+ }
+}
+impl Borrow<[u8]> for Utf8Char {
+ fn borrow(&self) -> &[u8] {
+ self.as_ref()
+ }
+}
+impl Borrow<str> for Utf8Char {
+ fn borrow(&self) -> &str {
+ self.as_ref()
+ }
+}
+impl Deref for Utf8Char {
+ type Target = str;
+ fn deref(&self) -> &Self::Target {
+ self.as_ref()
+ }
+}
+
+
+ ////////////////
+ //ascii traits//
+////////////////
+#[cfg(feature="std")]
+#[allow(deprecated)]
+impl AsciiExt for Utf8Char {
+ type Owned = Utf8Char;
+ fn is_ascii(&self) -> bool {
+ self.bytes[0].is_ascii()
+ }
+ fn eq_ignore_ascii_case(&self, other: &Self) -> bool {
+ if self.is_ascii() {self.bytes[0].eq_ignore_ascii_case(&other.bytes[0])}
+ else {self == other}
+ }
+ fn to_ascii_uppercase(&self) -> Self::Owned {
+ let mut uc = *self;
+ uc.make_ascii_uppercase();
+ uc
+ }
+ fn to_ascii_lowercase(&self) -> Self::Owned {
+ let mut uc = *self;
+ uc.make_ascii_lowercase();
+ uc
+ }
+ fn make_ascii_uppercase(&mut self) {
+ self.bytes[0].make_ascii_uppercase()
+ }
+ fn make_ascii_lowercase(&mut self) {
+ self.bytes[0].make_ascii_lowercase();
+ }
+}
+
+#[cfg(feature="ascii")]
+/// Requires the feature "ascii".
+impl From<AsciiChar> for Utf8Char {
+ fn from(ac: AsciiChar) -> Self {
+ Utf8Char{ bytes: [ac.as_byte(),0,0,0] }
+ }
+}
+#[cfg(feature="ascii")]
+/// Requires the feature "ascii".
+impl ToAsciiChar for Utf8Char {
+ fn to_ascii_char(self) -> Result<AsciiChar, ToAsciiCharError> {
+ self.bytes[0].to_ascii_char()
+ }
+ unsafe fn to_ascii_char_unchecked(self) -> AsciiChar {
+ self.bytes[0].to_ascii_char_unchecked()
+ }
+}
+
+
+ /////////////////////////////////////////////////////////
+ //Genaral traits that cannot be derived to emulate char//
+/////////////////////////////////////////////////////////
+impl hash::Hash for Utf8Char {
+ fn hash<H : hash::Hasher>(&self, state: &mut H) {
+ self.to_char().hash(state);
+ }
+}
+impl fmt::Debug for Utf8Char {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmt::Debug::fmt(&self.to_char(), fmtr)
+ }
+}
+impl fmt::Display for Utf8Char {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmtr.write_str(self.as_str())
+ }
+}
+
+
+ ////////////////////////////////
+ //Comparisons with other types//
+////////////////////////////////
+impl PartialEq<char> for Utf8Char {
+ fn eq(&self, u32c: &char) -> bool {
+ *self == Utf8Char::from(*u32c)
+ }
+}
+impl PartialEq<Utf8Char> for char {
+ fn eq(&self, u8c: &Utf8Char) -> bool {
+ Utf8Char::from(*self) == *u8c
+ }
+}
+impl PartialOrd<char> for Utf8Char {
+ fn partial_cmp(&self, u32c: &char) -> Option<Ordering> {
+ self.partial_cmp(&Self::from(*u32c))
+ }
+}
+impl PartialOrd<Utf8Char> for char {
+ fn partial_cmp(&self, u8c: &Utf8Char) -> Option<Ordering> {
+ Utf8Char::from(*self).partial_cmp(u8c)
+ }
+}
+
+impl PartialEq<Utf16Char> for Utf8Char {
+ fn eq(&self, u16c: &Utf16Char) -> bool {
+ *self == Self::from(*u16c)
+ }
+}
+impl PartialOrd<Utf16Char> for Utf8Char {
+ fn partial_cmp(&self, u16c: &Utf16Char) -> Option<Ordering> {
+ self.partial_cmp(&Self::from(*u16c))
+ }
+}
+// The other direction is implemented in utf16_char.rs
+
+/// Only considers the byte equal if both it and the `Utf8Char` represents ASCII characters.
+///
+/// There is no impl in the opposite direction, as this should only be used to
+/// compare `Utf8Char`s against constants.
+///
+/// # Examples
+///
+/// ```
+/// # use encode_unicode::Utf8Char;
+/// assert!(Utf8Char::from('8') == b'8');
+/// assert!(Utf8Char::from_array([0xf1,0x80,0x80,0x80]).unwrap() != 0xf1);
+/// assert!(Utf8Char::from('\u{ff}') != 0xff);
+/// assert!(Utf8Char::from('\u{80}') != 0x80);
+/// ```
+impl PartialEq<u8> for Utf8Char {
+ fn eq(&self, byte: &u8) -> bool {
+ self.bytes[0] == *byte && self.bytes[1] == 0
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf8Char`s that are not ASCII never compare equal.
+impl PartialEq<AsciiChar> for Utf8Char {
+ #[inline]
+ fn eq(&self, ascii: &AsciiChar) -> bool {
+ self.bytes[0] == *ascii as u8
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf8Char`s that are not ASCII never compare equal.
+impl PartialEq<Utf8Char> for AsciiChar {
+ #[inline]
+ fn eq(&self, u8c: &Utf8Char) -> bool {
+ u8c == self
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf8Char`s that are not ASCII always compare greater.
+impl PartialOrd<AsciiChar> for Utf8Char {
+ #[inline]
+ fn partial_cmp(&self, ascii: &AsciiChar) -> Option<Ordering> {
+ self.bytes[0].partial_cmp(ascii)
+ }
+}
+#[cfg(feature = "ascii")]
+/// `Utf8Char`s that are not ASCII always compare greater.
+impl PartialOrd<Utf8Char> for AsciiChar {
+ #[inline]
+ fn partial_cmp(&self, u8c: &Utf8Char) -> Option<Ordering> {
+ self.partial_cmp(&u8c.bytes[0])
+ }
+}
+
+
+ ///////////////////////////////////////////////////////
+ //pub impls that should be together for nicer rustdoc//
+///////////////////////////////////////////////////////
+impl Utf8Char {
+ /// Create an `Utf8Char` from the first codepoint in a `str`.
+ ///
+ /// Returns an error if the `str` is empty.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::Utf8Char;
+ ///
+ /// assert_eq!(Utf8Char::from_str_start("a"), Ok((Utf8Char::from('a'),1)));
+ /// assert_eq!(Utf8Char::from_str_start("ab"), Ok((Utf8Char::from('a'),1)));
+ /// assert_eq!(Utf8Char::from_str_start("🂠 "), Ok((Utf8Char::from('🂠'),4)));
+ /// assert_eq!(Utf8Char::from_str_start("é"), Ok((Utf8Char::from('e'),1)));// 'e'+u301 combining mark
+ /// assert!(Utf8Char::from_str_start("").is_err());
+ /// ```
+ pub fn from_str_start(src: &str) -> Result<(Self,usize),EmptyStrError> {
+ unsafe {
+ if src.is_empty() {
+ Err(EmptyStrError)
+ } else {
+ Ok(Utf8Char::from_slice_start_unchecked(src.as_bytes()))
+ }
+ }
+ }
+ /// Create an `Utf8Char` of the first codepoint in an UTF-8 slice.
+ /// Also returns the length of the UTF-8 sequence for the codepoint.
+ ///
+ /// If the slice is from a `str`, use `::from_str_start()` to skip UTF-8 validation.
+ ///
+ /// # Errors
+ ///
+ /// Returns an `Err` if the slice is empty, doesn't start with a valid
+ /// UTF-8 sequence or is too short for the sequence.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::Utf8Char;
+ /// use encode_unicode::error::InvalidUtf8Slice::*;
+ /// use encode_unicode::error::InvalidUtf8::*;
+ ///
+ /// assert_eq!(Utf8Char::from_slice_start(&[b'A', b'B', b'C']), Ok((Utf8Char::from('A'),1)));
+ /// assert_eq!(Utf8Char::from_slice_start(&[0xdd, 0xbb]), Ok((Utf8Char::from('\u{77b}'),2)));
+ ///
+ /// assert_eq!(Utf8Char::from_slice_start(&[]), Err(TooShort(1)));
+ /// assert_eq!(Utf8Char::from_slice_start(&[0xf0, 0x99]), Err(TooShort(4)));
+ /// assert_eq!(Utf8Char::from_slice_start(&[0xee, b'F', 0x80]), Err(Utf8(NotAContinuationByte(1))));
+ /// assert_eq!(Utf8Char::from_slice_start(&[0xee, 0x99, 0x0f]), Err(Utf8(NotAContinuationByte(2))));
+ /// ```
+ pub fn from_slice_start(src: &[u8]) -> Result<(Self,usize),InvalidUtf8Slice> {
+ char::from_utf8_slice_start(src).map(|(_,len)| {
+ let mut bytes = [0; 4];
+ bytes[..len].copy_from_slice(&src[..len]);
+ (Utf8Char{ bytes: bytes }, len)
+ })
+ }
+ /// A `from_slice_start()` that doesn't validate the codepoint.
+ ///
+ /// # Safety
+ ///
+ /// The slice must be non-empty and start with a valid UTF-8 codepoint.
+ /// Invalid or incomplete values might cause reads of uninitalized memory.
+ pub unsafe fn from_slice_start_unchecked(src: &[u8]) -> (Self,usize) {
+ let len = 1+src.get_unchecked(0).extra_utf8_bytes_unchecked();
+ let mut bytes = [0; 4];
+ ptr::copy_nonoverlapping(src.as_ptr(), &mut bytes[0] as *mut u8, len);
+ (Utf8Char{ bytes: bytes }, len)
+ }
+ /// Create an `Utf8Char` from a byte array after validating it.
+ ///
+ /// The codepoint must start at the first byte.
+ /// Unused bytes are set to zero by this function and so can be anything.
+ ///
+ /// # Errors
+ ///
+ /// Returns an `Err` if the array doesn't start with a valid UTF-8 sequence.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::Utf8Char;
+ /// use encode_unicode::error::InvalidUtf8Array::*;
+ /// use encode_unicode::error::InvalidUtf8::*;
+ /// use encode_unicode::error::InvalidCodepoint::*;
+ ///
+ /// assert_eq!(Utf8Char::from_array([b'A', 0, 0, 0]), Ok(Utf8Char::from('A')));
+ /// assert_eq!(Utf8Char::from_array([0xf4, 0x8b, 0xbb, 0xbb]), Ok(Utf8Char::from('\u{10befb}')));
+ /// assert_eq!(Utf8Char::from_array([b'A', b'B', b'C', b'D']), Ok(Utf8Char::from('A')));
+ /// assert_eq!(Utf8Char::from_array([0, 0, 0xcc, 0xbb]), Ok(Utf8Char::from('\0')));
+ ///
+ /// assert_eq!(Utf8Char::from_array([0xef, b'F', 0x80, 0x80]), Err(Utf8(NotAContinuationByte(1))));
+ /// assert_eq!(Utf8Char::from_array([0xc1, 0x80, 0, 0]), Err(Utf8(OverLong)));
+ /// assert_eq!(Utf8Char::from_array([0xf7, 0xaa, 0x99, 0x88]), Err(Codepoint(TooHigh)));
+ /// ```
+ pub fn from_array(utf8: [u8;4]) -> Result<Self,InvalidUtf8Array> {
+ unsafe {
+ // perform all validation
+ try!(char::from_utf8_array(utf8));
+ let extra = utf8[0].extra_utf8_bytes_unchecked() as u32;
+ // zero unused bytes in one operation by transmuting the arrary to
+ // u32, apply an endian-corrected mask and transmute back
+ let mask = u32::from_le(0xff_ff_ff_ff >> 8*(3-extra));
+ let unused_zeroed = mask & transmute::<_,u32>(utf8);
+ Ok(Utf8Char{ bytes: transmute(unused_zeroed) })
+ }
+ }
+ /// Zero-cost constructor.
+ ///
+ /// # Safety
+ ///
+ /// Must contain a valid codepoint starting at the first byte, with the
+ /// unused bytes zeroed.
+ /// Bad values can easily lead to undefined behavior.
+ #[inline]
+ pub unsafe fn from_array_unchecked(utf8: [u8;4]) -> Self {
+ Utf8Char{ bytes: utf8 }
+ }
+ /// Create an `Utf8Char` from a single byte.
+ ///
+ /// The byte must be an ASCII character.
+ ///
+ /// # Errors
+ ///
+ /// Returns `NonAsciiError` if the byte greater than 127.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// # use encode_unicode::Utf8Char;
+ /// assert_eq!(Utf8Char::from_ascii(b'a').unwrap(), 'a');
+ /// assert!(Utf8Char::from_ascii(128).is_err());
+ /// ```
+ pub fn from_ascii(ascii: u8) -> Result<Self,NonAsciiError> {
+ if ascii as i8 >= 0 {
+ Ok(Utf8Char{ bytes: [ascii, 0, 0, 0] })
+ } else {
+ Err(NonAsciiError)
+ }
+ }
+ /// Create an `Utf8Char` from a single byte without checking that it's a
+ /// valid codepoint on its own, which is only true for ASCII characters.
+ ///
+ /// # Safety
+ ///
+ /// The byte must be less than 128.
+ #[inline]
+ pub unsafe fn from_ascii_unchecked(ascii: u8) -> Self {
+ Utf8Char{ bytes: [ascii, 0, 0, 0] }
+ }
+
+ /// The number of bytes this character needs.
+ ///
+ /// Is between 1 and 4 (inclusive) and identical to `.as_ref().len()` or
+ /// `.as_char().len_utf8()`.
+ #[inline]
+ pub fn len(self) -> usize {
+ // Invariants of the extra bytes enambles algorithms that
+ // `u8.extra_utf8_bytes_unchecked()` cannot use.
+ // Some of them turned out to require fewer x86 instructions:
+
+ // Exploits that unused bytes are zero and calculates the number of
+ // trailing zero bytes.
+ // Setting a bit in the first byte prevents the function from returning
+ // 0 for '\0' (which has 32 leading zeros).
+ // trailing and leading is swapped below to optimize for little-endian
+ // architectures.
+ (4 - (u32::to_le(unsafe{transmute(self.bytes)})|1).leading_zeros()/8) as usize
+
+ // Exploits that the extra bytes have their most significant bit set if
+ // in use.
+ // Takes fewer instructions than the one above if popcnt can be used,
+ // (which it cannot by default,
+ // set RUSTFLAGS='-C target-cpu=native' to enable)
+ //let all: u32 = unsafe{transmute(self.bytes)};
+ //let msb_mask = u32::from_be(0x00808080);
+ //let add_one = u32::from_be(0x80000000);
+ //((all & msb_mask) | add_one).count_ones() as usize
+ }
+ // There is no .is_emty() because this type is never empty.
+
+ /// Checks that the codepoint is an ASCII character.
+ pub fn is_ascii(&self) -> bool {
+ self.bytes[0] <= 127
+ }
+ /// Checks that two characters are an ASCII case-insensitive match.
+ ///
+ /// Is equivalent to `a.to_ascii_lowercase() == b.to_ascii_lowercase()`.
+ #[cfg(feature="std")]
+ pub fn eq_ignore_ascii_case(&self, other: &Self) -> bool {
+ if self.is_ascii() {self.bytes[0].eq_ignore_ascii_case(&other.bytes[0])}
+ else {self == other}
+ }
+ /// Converts the character to its ASCII upper case equivalent.
+ ///
+ /// ASCII letters 'a' to 'z' are mapped to 'A' to 'Z',
+ /// but non-ASCII letters are unchanged.
+ #[cfg(feature="std")]
+ pub fn to_ascii_uppercase(&self) -> Self {
+ let mut uc = *self;
+ uc.make_ascii_uppercase();
+ uc
+ }
+ /// Converts the character to its ASCII lower case equivalent.
+ ///
+ /// ASCII letters 'A' to 'Z' are mapped to 'a' to 'z',
+ /// but non-ASCII letters are unchanged.
+ #[cfg(feature="std")]
+ pub fn to_ascii_lowercase(&self) -> Self {
+ let mut uc = *self;
+ uc.make_ascii_lowercase();
+ uc
+ }
+ /// Converts the character to its ASCII upper case equivalent in-place.
+ ///
+ /// ASCII letters 'a' to 'z' are mapped to 'A' to 'Z',
+ /// but non-ASCII letters are unchanged.
+ #[inline]
+ #[cfg(feature="std")]
+ pub fn make_ascii_uppercase(&mut self) {
+ self.bytes[0].make_ascii_uppercase()
+ }
+ /// Converts the character to its ASCII lower case equivalent in-place.
+ ///
+ /// ASCII letters 'A' to 'Z' are mapped to 'a' to 'z',
+ /// but non-ASCII letters are unchanged.
+ #[inline]
+ #[cfg(feature="std")]
+ pub fn make_ascii_lowercase(&mut self) {
+ self.bytes[0].make_ascii_lowercase();
+ }
+
+ /// Convert from UTF-8 to UTF-32
+ pub fn to_char(self) -> char {
+ self.into()
+ }
+ /// Write the internal representation to a slice,
+ /// and then returns the number of bytes written.
+ ///
+ /// # Panics
+ ///
+ /// Will panic the buffer is too small;
+ /// You can get the required length from `.len()`,
+ /// but a buffer of length four is always large enough.
+ pub fn to_slice(self, dst: &mut[u8]) -> usize {
+ if self.len() > dst.len() {
+ panic!("The provided buffer is too small.");
+ }
+ dst[..self.len()].copy_from_slice(&self.bytes[..self.len()]);
+ self.len()
+ }
+ /// Expose the internal array and the number of used bytes.
+ pub fn to_array(self) -> ([u8;4],usize) {
+ (self.bytes, self.len())
+ }
+ /// Return a `str` view of the array the codepoint is stored as.
+ ///
+ /// Is an unambiguous version of `.as_ref()`.
+ pub fn as_str(&self) -> &str {
+ self.deref()
+ }
+}
diff --git a/vendor/encode_unicode/src/utf8_iterators.rs b/vendor/encode_unicode/src/utf8_iterators.rs
new file mode 100644
index 0000000..891d729
--- /dev/null
+++ b/vendor/encode_unicode/src/utf8_iterators.rs
@@ -0,0 +1,352 @@
+/* Copyright 2016 The encode_unicode Developers
+ *
+ * Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
+ * http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
+ * http://opensource.org/licenses/MIT>, at your option. This file may not be
+ * copied, modified, or distributed except according to those terms.
+ */
+
+use utf8_char::Utf8Char;
+use errors::EmptyStrError;
+extern crate core;
+use self::core::{mem, u32, u64};
+use self::core::ops::Not;
+use self::core::fmt;
+use self::core::borrow::Borrow;
+#[cfg(feature="std")]
+use std::io::{Read, Error as ioError};
+
+
+
+/// Read or iterate over the bytes of the UTF-8 representation of a codepoint.
+#[derive(Clone)]
+pub struct Utf8Iterator (u32);
+
+impl From<Utf8Char> for Utf8Iterator {
+ fn from(uc: Utf8Char) -> Self {
+ let used = u32::from_le(unsafe{ mem::transmute(uc.to_array().0) });
+ // uses u64 because shifting an u32 by 32 bits is a no-op.
+ let unused_set = (u64::MAX << uc.len() as u64*8) as u32;
+ Utf8Iterator(used | unused_set)
+ }
+}
+impl From<char> for Utf8Iterator {
+ fn from(c: char) -> Self {
+ Self::from(Utf8Char::from(c))
+ }
+}
+impl Iterator for Utf8Iterator {
+ type Item=u8;
+ fn next(&mut self) -> Option<u8> {
+ let next = self.0 as u8;
+ if next == 0xff {
+ None
+ } else {
+ self.0 = (self.0 >> 8) | 0xff_00_00_00;
+ Some(next)
+ }
+ }
+ fn size_hint(&self) -> (usize, Option<usize>) {
+ (self.len(), Some(self.len()))
+ }
+}
+impl ExactSizeIterator for Utf8Iterator {
+ fn len(&self) -> usize {// not straightforward, but possible
+ let unused_bytes = self.0.not().leading_zeros() / 8;
+ 4 - unused_bytes as usize
+ }
+}
+#[cfg(feature="std")]
+impl Read for Utf8Iterator {
+ /// Always returns Ok
+ fn read(&mut self, buf: &mut[u8]) -> Result<usize, ioError> {
+ // Cannot call self.next() until I know I can write the result.
+ for (i, dst) in buf.iter_mut().enumerate() {
+ match self.next() {
+ Some(b) => *dst = b,
+ None => return Ok(i),
+ }
+ }
+ Ok(buf.len())
+ }
+}
+impl fmt::Debug for Utf8Iterator {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ let mut content = [0; 4];
+ let mut i = 0;
+ for b in self.clone() {
+ content[i] = b;
+ i += 1;
+ }
+ write!(fmtr, "{:?}", &content[..i])
+ }
+}
+
+
+
+/// Converts an iterator of `Utf8Char` (or `&Utf8Char`)
+/// to an iterator of `u8`s.
+/// Is equivalent to calling `.flat_map()` on the original iterator,
+/// but the returned iterator is ~40% faster.
+///
+/// The iterator also implements `Read` (if the `std` feature isn't disabled).
+/// Reading will never produce an error, and calls to `.read()` and `.next()`
+/// can be mixed.
+///
+/// The exact number of bytes cannot be known in advance, but `size_hint()`
+/// gives the possible range.
+/// (min: all remaining characters are ASCII, max: all require four bytes)
+///
+/// # Examples
+///
+/// From iterator of values:
+///
+/// ```
+/// use encode_unicode::{iter_bytes, CharExt};
+///
+/// let iterator = "foo".chars().map(|c| c.to_utf8() );
+/// let mut bytes = [0; 4];
+/// for (u,dst) in iter_bytes(iterator).zip(&mut bytes) {*dst=u;}
+/// assert_eq!(&bytes, b"foo\0");
+/// ```
+///
+/// From iterator of references:
+///
+#[cfg_attr(feature="std", doc=" ```")]
+#[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+/// use encode_unicode::{iter_bytes, CharExt, Utf8Char};
+///
+/// let chars: Vec<Utf8Char> = "💣 bomb 💣".chars().map(|c| c.to_utf8() ).collect();
+/// let bytes: Vec<u8> = iter_bytes(&chars).collect();
+/// let flat_map: Vec<u8> = chars.iter().flat_map(|u8c| *u8c ).collect();
+/// assert_eq!(bytes, flat_map);
+/// ```
+///
+/// `Read`ing from it:
+///
+#[cfg_attr(feature="std", doc=" ```")]
+#[cfg_attr(not(feature="std"), doc=" ```no_compile")]
+/// use encode_unicode::{iter_bytes, CharExt};
+/// use std::io::Read;
+///
+/// let s = "Ååh‽";
+/// assert_eq!(s.len(), 8);
+/// let mut buf = [b'E'; 9];
+/// let mut reader = iter_bytes(s.chars().map(|c| c.to_utf8() ));
+/// assert_eq!(reader.read(&mut buf[..]).unwrap(), 8);
+/// assert_eq!(reader.read(&mut buf[..]).unwrap(), 0);
+/// assert_eq!(&buf[..8], s.as_bytes());
+/// assert_eq!(buf[8], b'E');
+/// ```
+pub fn iter_bytes<U:Borrow<Utf8Char>, I:IntoIterator<Item=U>>
+(iterable: I) -> Utf8CharSplitter<U, I::IntoIter> {
+ Utf8CharSplitter{ inner: iterable.into_iter(), prev: 0 }
+}
+
+/// The iterator type returned by `iter_bytes()`
+///
+/// See its documentation for details.
+#[derive(Clone)]
+pub struct Utf8CharSplitter<U:Borrow<Utf8Char>, I:Iterator<Item=U>> {
+ inner: I,
+ prev: u32,
+}
+impl<I:Iterator<Item=Utf8Char>> From<I> for Utf8CharSplitter<Utf8Char,I> {
+ /// A less generic constructor than `iter_bytes()`
+ fn from(iter: I) -> Self {
+ iter_bytes(iter)
+ }
+}
+impl<U:Borrow<Utf8Char>, I:Iterator<Item=U>> Utf8CharSplitter<U,I> {
+ /// Extracts the source iterator.
+ ///
+ /// Note that `iter_bytes(iter.into_inner())` is not a no-op:
+ /// If the last returned byte from `next()` was not an ASCII by,
+ /// the remaining bytes of that codepoint is lost.
+ pub fn into_inner(self) -> I {
+ self.inner
+ }
+}
+impl<U:Borrow<Utf8Char>, I:Iterator<Item=U>> Iterator for Utf8CharSplitter<U,I> {
+ type Item = u8;
+ fn next(&mut self) -> Option<Self::Item> {
+ if self.prev == 0 {
+ self.inner.next().map(|u8c| {
+ let array = u8c.borrow().to_array().0;
+ self.prev = unsafe{ u32::from_le(mem::transmute(array)) } >> 8;
+ array[0]
+ })
+ } else {
+ let next = self.prev as u8;
+ self.prev >>= 8;
+ Some(next)
+ }
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ // Doesn't need to handle unlikely overflows correctly because
+ // size_hint() cannot be relied upon anyway. (the trait isn't unsafe)
+ let (min, max) = self.inner.size_hint();
+ let add = 4 - (self.prev.leading_zeros() / 8) as usize;
+ (min.wrapping_add(add), max.map(|max| max.wrapping_mul(4).wrapping_add(add) ))
+ }
+}
+#[cfg(feature="std")]
+impl<U:Borrow<Utf8Char>, I:Iterator<Item=U>> Read for Utf8CharSplitter<U,I> {
+ /// Always returns `Ok`
+ fn read(&mut self, buf: &mut[u8]) -> Result<usize, ioError> {
+ let mut i = 0;
+ // write remaining bytes of previous codepoint
+ while self.prev != 0 && i < buf.len() {
+ buf[i] = self.prev as u8;
+ self.prev >>= 8;
+ i += 1;
+ }
+ // write whole characters
+ while i < buf.len() {
+ let bytes = match self.inner.next() {
+ Some(u8c) => u8c.borrow().to_array().0,
+ None => break
+ };
+ buf[i] = bytes[0];
+ i += 1;
+ if bytes[1] != 0 {
+ let len = bytes[0].not().leading_zeros() as usize;
+ let mut written = 1;
+ while written < len {
+ if i < buf.len() {
+ buf[i] = bytes[written];
+ i += 1;
+ written += 1;
+ } else {
+ let bytes_as_u32 = unsafe{ u32::from_le(mem::transmute(bytes)) };
+ self.prev = bytes_as_u32 >> (8*written);
+ return Ok(i);
+ }
+ }
+ }
+ }
+ Ok(i)
+ }
+}
+
+
+
+/// An iterator over the `Utf8Char` of a string slice, and their positions.
+///
+/// This struct is created by the `utf8char_indices() method from [`StrExt`] trait. See its documentation for more.
+#[derive(Clone)]
+pub struct Utf8CharIndices<'a>{
+ str: &'a str,
+ index: usize,
+}
+impl<'a> From<&'a str> for Utf8CharIndices<'a> {
+ fn from(s: &str) -> Utf8CharIndices {
+ Utf8CharIndices{str: s, index: 0}
+ }
+}
+impl<'a> Utf8CharIndices<'a> {
+ /// Extract the remainder of the source `str`.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::{StrExt, Utf8Char};
+ /// let mut iter = "abc".utf8char_indices();
+ /// assert_eq!(iter.next_back(), Some((2, Utf8Char::from('c'))));
+ /// assert_eq!(iter.next(), Some((0, Utf8Char::from('a'))));
+ /// assert_eq!(iter.as_str(), "b");
+ /// ```
+ pub fn as_str(&self) -> &'a str {
+ &self.str[self.index..]
+ }
+}
+impl<'a> Iterator for Utf8CharIndices<'a> {
+ type Item = (usize,Utf8Char);
+ fn next(&mut self) -> Option<(usize,Utf8Char)> {
+ match Utf8Char::from_str_start(&self.str[self.index..]) {
+ Ok((u8c, len)) => {
+ let item = (self.index, u8c);
+ self.index += len;
+ Some(item)
+ },
+ Err(EmptyStrError) => None
+ }
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ let len = self.str.len() - self.index;
+ // For len+3 to overflow, the slice must fill all but two bytes of
+ // addressable memory, and size_hint() doesn't need to be correct.
+ (len.wrapping_add(3)/4, Some(len))
+ }
+}
+impl<'a> DoubleEndedIterator for Utf8CharIndices<'a> {
+ fn next_back(&mut self) -> Option<(usize,Utf8Char)> {
+ // Cannot refactor out the unwrap without switching to ::from_slice()
+ // since slicing the str panics if not on a boundary.
+ if self.index < self.str.len() {
+ let rev = self.str.bytes().rev();
+ let len = 1 + rev.take_while(|b| b & 0b1100_0000 == 0b1000_0000 ).count();
+ let starts = self.str.len() - len;
+ let (u8c,_) = Utf8Char::from_str_start(&self.str[starts..]).unwrap();
+ self.str = &self.str[..starts];
+ Some((starts, u8c))
+ } else {
+ None
+ }
+ }
+}
+impl<'a> fmt::Debug for Utf8CharIndices<'a> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmtr.debug_tuple("Utf8CharIndices")
+ .field(&self.index)
+ .field(&self.as_str())
+ .finish()
+ }
+}
+
+
+/// An iterator over the codepoints in a `str` represented as `Utf8Char`.
+#[derive(Clone)]
+pub struct Utf8Chars<'a>(Utf8CharIndices<'a>);
+impl<'a> From<&'a str> for Utf8Chars<'a> {
+ fn from(s: &str) -> Utf8Chars {
+ Utf8Chars(Utf8CharIndices::from(s))
+ }
+}
+impl<'a> Utf8Chars<'a> {
+ /// Extract the remainder of the source `str`.
+ ///
+ /// # Examples
+ ///
+ /// ```
+ /// use encode_unicode::{StrExt, Utf8Char};
+ /// let mut iter = "abc".utf8chars();
+ /// assert_eq!(iter.next(), Some(Utf8Char::from('a')));
+ /// assert_eq!(iter.next_back(), Some(Utf8Char::from('c')));
+ /// assert_eq!(iter.as_str(), "b");
+ /// ```
+ pub fn as_str(&self) -> &'a str {
+ self.0.as_str()
+ }
+}
+impl<'a> Iterator for Utf8Chars<'a> {
+ type Item = Utf8Char;
+ fn next(&mut self) -> Option<Utf8Char> {
+ self.0.next().map(|(_,u8c)| u8c )
+ }
+ fn size_hint(&self) -> (usize,Option<usize>) {
+ self.0.size_hint()
+ }
+}
+impl<'a> DoubleEndedIterator for Utf8Chars<'a> {
+ fn next_back(&mut self) -> Option<Utf8Char> {
+ self.0.next_back().map(|(_,u8c)| u8c )
+ }
+}
+impl<'a> fmt::Debug for Utf8Chars<'a> {
+ fn fmt(&self, fmtr: &mut fmt::Formatter) -> fmt::Result {
+ fmtr.debug_tuple("Utf8CharIndices")
+ .field(&self.as_str())
+ .finish()
+ }
+}