// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // // ignore-lexer-test FIXME #15679 //! String manipulation //! //! For more details, see std::str #![doc(primitive = "str")] use self::OldSearcher::{TwoWay, TwoWayLong}; use clone::Clone; use cmp::{self, Eq}; use default::Default; use error::Error; use fmt; use iter::ExactSizeIterator; use iter::{Map, Iterator, IteratorExt, DoubleEndedIterator}; use marker::Sized; use mem; use num::Int; use ops::{Fn, FnMut}; use option::Option::{self, None, Some}; use ptr::PtrExt; use raw::{Repr, Slice}; use result::Result::{self, Ok, Err}; use slice::{self, SliceExt}; use usize; pub use self::pattern::Pattern; pub use self::pattern::{Searcher, ReverseSearcher, DoubleEndedSearcher, SearchStep}; mod pattern; macro_rules! delegate_iter { (exact $te:ty : $ti:ty) => { delegate_iter!{$te : $ti} impl<'a> ExactSizeIterator for $ti { #[inline] fn len(&self) -> usize { self.0.len() } } }; ($te:ty : $ti:ty) => { #[stable(feature = "rust1", since = "1.0.0")] impl<'a> Iterator for $ti { type Item = $te; #[inline] fn next(&mut self) -> Option<$te> { self.0.next() } #[inline] fn size_hint(&self) -> (usize, Option) { self.0.size_hint() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> DoubleEndedIterator for $ti { #[inline] fn next_back(&mut self) -> Option<$te> { self.0.next_back() } } }; (pattern $te:ty : $ti:ty) => { #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> Iterator for $ti { type Item = $te; #[inline] fn next(&mut self) -> Option<$te> { self.0.next() } #[inline] fn size_hint(&self) -> (usize, Option) { self.0.size_hint() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> DoubleEndedIterator for $ti where P::Searcher: DoubleEndedSearcher<'a> { #[inline] fn next_back(&mut self) -> Option<$te> { self.0.next_back() } } }; (pattern forward $te:ty : $ti:ty) => { #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> Iterator for $ti where P::Searcher: DoubleEndedSearcher<'a> { type Item = $te; #[inline] fn next(&mut self) -> Option<$te> { self.0.next() } #[inline] fn size_hint(&self) -> (usize, Option) { self.0.size_hint() } } } } /// A trait to abstract the idea of creating a new instance of a type from a /// string. #[stable(feature = "rust1", since = "1.0.0")] pub trait FromStr { /// The associated error which can be returned from parsing. #[stable(feature = "rust1", since = "1.0.0")] type Err; /// Parses a string `s` to return an optional value of this type. If the /// string is ill-formatted, the None is returned. #[stable(feature = "rust1", since = "1.0.0")] fn from_str(s: &str) -> Result; } #[stable(feature = "rust1", since = "1.0.0")] impl FromStr for bool { type Err = ParseBoolError; /// Parse a `bool` from a string. /// /// Yields an `Option`, because `s` may or may not actually be /// parseable. /// /// # Examples /// /// ```rust /// assert_eq!("true".parse(), Ok(true)); /// assert_eq!("false".parse(), Ok(false)); /// assert!("not even a boolean".parse::().is_err()); /// ``` #[inline] fn from_str(s: &str) -> Result { match s { "true" => Ok(true), "false" => Ok(false), _ => Err(ParseBoolError { _priv: () }), } } } /// An error returned when parsing a `bool` from a string fails. #[derive(Debug, Clone, PartialEq)] #[stable(feature = "rust1", since = "1.0.0")] pub struct ParseBoolError { _priv: () } #[stable(feature = "rust1", since = "1.0.0")] impl fmt::Display for ParseBoolError { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { "provided string was not `true` or `false`".fmt(f) } } #[stable(feature = "rust1", since = "1.0.0")] impl Error for ParseBoolError { fn description(&self) -> &str { "failed to parse bool" } } /* Section: Creating a string */ /// Errors which can occur when attempting to interpret a byte slice as a `str`. #[derive(Copy, Eq, PartialEq, Clone, Debug)] #[unstable(feature = "core", reason = "error enumeration recently added and definitions may be refined")] pub enum Utf8Error { /// An invalid byte was detected at the byte offset given. /// /// The offset is guaranteed to be in bounds of the slice in question, and /// the byte at the specified offset was the first invalid byte in the /// sequence detected. InvalidByte(usize), /// The byte slice was invalid because more bytes were needed but no more /// bytes were available. TooShort, } /// Converts a slice of bytes to a string slice without performing any /// allocations. /// /// Once the slice has been validated as utf-8, it is transmuted in-place and /// returned as a '&str' instead of a '&[u8]' /// /// # Failure /// /// Returns `Err` if the slice is not utf-8 with a description as to why the /// provided slice is not utf-8. #[stable(feature = "rust1", since = "1.0.0")] pub fn from_utf8(v: &[u8]) -> Result<&str, Utf8Error> { try!(run_utf8_validation_iterator(&mut v.iter())); Ok(unsafe { from_utf8_unchecked(v) }) } /// Converts a slice of bytes to a string slice without checking /// that the string contains valid UTF-8. #[stable(feature = "rust1", since = "1.0.0")] pub unsafe fn from_utf8_unchecked<'a>(v: &'a [u8]) -> &'a str { mem::transmute(v) } /// Constructs a static string slice from a given raw pointer. /// /// This function will read memory starting at `s` until it finds a 0, and then /// transmute the memory up to that point as a string slice, returning the /// corresponding `&'static str` value. /// /// This function is unsafe because the caller must ensure the C string itself /// has the static lifetime and that the memory `s` is valid up to and including /// the first null byte. /// /// # Panics /// /// This function will panic if the string pointed to by `s` is not valid UTF-8. #[unstable(feature = "core")] #[deprecated(since = "1.0.0", reason = "use std::ffi::c_str_to_bytes + str::from_utf8")] pub unsafe fn from_c_str(s: *const i8) -> &'static str { let s = s as *const u8; let mut len = 0; while *s.offset(len as isize) != 0 { len += 1; } let v: &'static [u8] = ::mem::transmute(Slice { data: s, len: len }); from_utf8(v).ok().expect("from_c_str passed invalid utf-8 data") } /// Something that can be used to compare against a character #[unstable(feature = "core")] #[deprecated(since = "1.0.0", reason = "use `Pattern` instead")] // NB: Rather than removing it, make it private and move it into self::pattern pub trait CharEq { /// Determine if the splitter should split at the given character fn matches(&mut self, char) -> bool; /// Indicate if this is only concerned about ASCII characters, /// which can allow for a faster implementation. fn only_ascii(&self) -> bool; } #[allow(deprecated) /* for CharEq */ ] impl CharEq for char { #[inline] fn matches(&mut self, c: char) -> bool { *self == c } #[inline] fn only_ascii(&self) -> bool { (*self as u32) < 128 } } #[allow(deprecated) /* for CharEq */ ] impl CharEq for F where F: FnMut(char) -> bool { #[inline] fn matches(&mut self, c: char) -> bool { (*self)(c) } #[inline] fn only_ascii(&self) -> bool { false } } #[allow(deprecated) /* for CharEq */ ] impl<'a> CharEq for &'a [char] { #[inline] #[allow(deprecated) /* for CharEq */ ] fn matches(&mut self, c: char) -> bool { self.iter().any(|&m| { let mut m = m; m.matches(c) }) } #[inline] #[allow(deprecated) /* for CharEq */ ] fn only_ascii(&self) -> bool { self.iter().all(|m| m.only_ascii()) } } #[stable(feature = "rust1", since = "1.0.0")] impl Error for Utf8Error { fn description(&self) -> &str { match *self { Utf8Error::TooShort => "invalid utf-8: not enough bytes", Utf8Error::InvalidByte(..) => "invalid utf-8: corrupt contents", } } } #[stable(feature = "rust1", since = "1.0.0")] impl fmt::Display for Utf8Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { Utf8Error::InvalidByte(n) => { write!(f, "invalid utf-8: invalid byte at index {}", n) } Utf8Error::TooShort => { write!(f, "invalid utf-8: byte slice too short") } } } } /* Section: Iterators */ /// Iterator for the char (representing *Unicode Scalar Values*) of a string /// /// Created with the method `.chars()`. #[derive(Clone)] #[stable(feature = "rust1", since = "1.0.0")] pub struct Chars<'a> { iter: slice::Iter<'a, u8> } // Return the initial codepoint accumulator for the first byte. // The first byte is special, only want bottom 5 bits for width 2, 4 bits // for width 3, and 3 bits for width 4 macro_rules! utf8_first_byte { ($byte:expr, $width:expr) => (($byte & (0x7F >> $width)) as u32) } // return the value of $ch updated with continuation byte $byte macro_rules! utf8_acc_cont_byte { ($ch:expr, $byte:expr) => (($ch << 6) | ($byte & CONT_MASK) as u32) } macro_rules! utf8_is_cont_byte { ($byte:expr) => (($byte & !CONT_MASK) == TAG_CONT_U8) } #[inline] fn unwrap_or_0(opt: Option<&u8>) -> u8 { match opt { Some(&byte) => byte, None => 0, } } /// Reads the next code point out of a byte iterator (assuming a /// UTF-8-like encoding). #[unstable(feature = "core")] #[inline] pub fn next_code_point(bytes: &mut slice::Iter) -> Option { // Decode UTF-8 let x = match bytes.next() { None => return None, Some(&next_byte) if next_byte < 128 => return Some(next_byte as u32), Some(&next_byte) => next_byte, }; // Multibyte case follows // Decode from a byte combination out of: [[[x y] z] w] // NOTE: Performance is sensitive to the exact formulation here let init = utf8_first_byte!(x, 2); let y = unwrap_or_0(bytes.next()); let mut ch = utf8_acc_cont_byte!(init, y); if x >= 0xE0 { // [[x y z] w] case // 5th bit in 0xE0 .. 0xEF is always clear, so `init` is still valid let z = unwrap_or_0(bytes.next()); let y_z = utf8_acc_cont_byte!((y & CONT_MASK) as u32, z); ch = init << 12 | y_z; if x >= 0xF0 { // [x y z w] case // use only the lower 3 bits of `init` let w = unwrap_or_0(bytes.next()); ch = (init & 7) << 18 | utf8_acc_cont_byte!(y_z, w); } } Some(ch) } /// Reads the last code point out of a byte iterator (assuming a /// UTF-8-like encoding). #[unstable(feature = "core")] #[inline] pub fn next_code_point_reverse(bytes: &mut slice::Iter) -> Option { // Decode UTF-8 let w = match bytes.next_back() { None => return None, Some(&next_byte) if next_byte < 128 => return Some(next_byte as u32), Some(&back_byte) => back_byte, }; // Multibyte case follows // Decode from a byte combination out of: [x [y [z w]]] let mut ch; let z = unwrap_or_0(bytes.next_back()); ch = utf8_first_byte!(z, 2); if utf8_is_cont_byte!(z) { let y = unwrap_or_0(bytes.next_back()); ch = utf8_first_byte!(y, 3); if utf8_is_cont_byte!(y) { let x = unwrap_or_0(bytes.next_back()); ch = utf8_first_byte!(x, 4); ch = utf8_acc_cont_byte!(ch, y); } ch = utf8_acc_cont_byte!(ch, z); } ch = utf8_acc_cont_byte!(ch, w); Some(ch) } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> Iterator for Chars<'a> { type Item = char; #[inline] fn next(&mut self) -> Option { next_code_point(&mut self.iter).map(|ch| { // str invariant says `ch` is a valid Unicode Scalar Value unsafe { mem::transmute(ch) } }) } #[inline] fn size_hint(&self) -> (usize, Option) { let (len, _) = self.iter.size_hint(); (len.saturating_add(3) / 4, Some(len)) } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> DoubleEndedIterator for Chars<'a> { #[inline] fn next_back(&mut self) -> Option { next_code_point_reverse(&mut self.iter).map(|ch| { // str invariant says `ch` is a valid Unicode Scalar Value unsafe { mem::transmute(ch) } }) } } /// External iterator for a string's characters and their byte offsets. /// Use with the `std::iter` module. #[derive(Clone)] #[stable(feature = "rust1", since = "1.0.0")] pub struct CharIndices<'a> { front_offset: usize, iter: Chars<'a>, } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> Iterator for CharIndices<'a> { type Item = (usize, char); #[inline] fn next(&mut self) -> Option<(usize, char)> { let (pre_len, _) = self.iter.iter.size_hint(); match self.iter.next() { None => None, Some(ch) => { let index = self.front_offset; let (len, _) = self.iter.iter.size_hint(); self.front_offset += pre_len - len; Some((index, ch)) } } } #[inline] fn size_hint(&self) -> (usize, Option) { self.iter.size_hint() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> DoubleEndedIterator for CharIndices<'a> { #[inline] fn next_back(&mut self) -> Option<(usize, char)> { match self.iter.next_back() { None => None, Some(ch) => { let (len, _) = self.iter.iter.size_hint(); let index = self.front_offset + len; Some((index, ch)) } } } } /// External iterator for a string's bytes. /// Use with the `std::iter` module. /// /// Created with `StrExt::bytes` #[stable(feature = "rust1", since = "1.0.0")] #[derive(Clone)] pub struct Bytes<'a>(Map, BytesDeref>); delegate_iter!{exact u8 : Bytes<'a>} /// A temporary fn new type that ensures that the `Bytes` iterator /// is cloneable. #[derive(Copy, Clone)] struct BytesDeref; impl<'a> Fn<(&'a u8,)> for BytesDeref { type Output = u8; #[inline] extern "rust-call" fn call(&self, (ptr,): (&'a u8,)) -> u8 { *ptr } } /// An iterator over the substrings of a string, separated by `sep`. struct CharSplits<'a, P: Pattern<'a>> { /// The slice remaining to be iterated start: usize, end: usize, matcher: P::Searcher, /// Whether an empty string at the end is allowed allow_trailing_empty: bool, finished: bool, } /// An iterator over the substrings of a string, separated by `sep`, /// splitting at most `count` times. struct CharSplitsN<'a, P: Pattern<'a>> { iter: CharSplits<'a, P>, /// The number of splits remaining count: usize, invert: bool, } /// An iterator over the lines of a string, separated by `\n`. #[stable(feature = "rust1", since = "1.0.0")] pub struct Lines<'a> { inner: CharSplits<'a, char>, } /// An iterator over the lines of a string, separated by either `\n` or (`\r\n`). #[stable(feature = "rust1", since = "1.0.0")] pub struct LinesAny<'a> { inner: Map, fn(&str) -> &str>, } impl<'a, P: Pattern<'a>> CharSplits<'a, P> { #[inline] fn get_end(&mut self) -> Option<&'a str> { if !self.finished && (self.allow_trailing_empty || self.end - self.start > 0) { self.finished = true; unsafe { let string = self.matcher.haystack().slice_unchecked(self.start, self.end); Some(string) } } else { None } } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> Iterator for CharSplits<'a, P> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { if self.finished { return None } let haystack = self.matcher.haystack(); match self.matcher.next_match() { Some((a, b)) => unsafe { let elt = haystack.slice_unchecked(self.start, a); self.start = b; Some(elt) }, None => self.get_end(), } } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> DoubleEndedIterator for CharSplits<'a, P> where P::Searcher: DoubleEndedSearcher<'a> { #[inline] fn next_back(&mut self) -> Option<&'a str> { if self.finished { return None } if !self.allow_trailing_empty { self.allow_trailing_empty = true; match self.next_back() { Some(elt) if !elt.is_empty() => return Some(elt), _ => if self.finished { return None } } } let haystack = self.matcher.haystack(); match self.matcher.next_match_back() { Some((a, b)) => unsafe { let elt = haystack.slice_unchecked(b, self.end); self.end = a; Some(elt) }, None => unsafe { self.finished = true; Some(haystack.slice_unchecked(self.start, self.end)) }, } } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> Iterator for CharSplitsN<'a, P> where P::Searcher: DoubleEndedSearcher<'a> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { if self.count != 0 { self.count -= 1; if self.invert { self.iter.next_back() } else { self.iter.next() } } else { self.iter.get_end() } } } /// The internal state of an iterator that searches for matches of a substring /// within a larger string using two-way search #[derive(Clone)] struct TwoWaySearcher { // constants crit_pos: usize, period: usize, byteset: u64, // variables position: usize, memory: usize } /* This is the Two-Way search algorithm, which was introduced in the paper: Crochemore, M., Perrin, D., 1991, Two-way string-matching, Journal of the ACM 38(3):651-675. Here's some background information. A *word* is a string of symbols. The *length* of a word should be a familiar notion, and here we denote it for any word x by |x|. (We also allow for the possibility of the *empty word*, a word of length zero). If x is any non-empty word, then an integer p with 0 < p <= |x| is said to be a *period* for x iff for all i with 0 <= i <= |x| - p - 1, we have x[i] == x[i+p]. For example, both 1 and 2 are periods for the string "aa". As another example, the only period of the string "abcd" is 4. We denote by period(x) the *smallest* period of x (provided that x is non-empty). This is always well-defined since every non-empty word x has at least one period, |x|. We sometimes call this *the period* of x. If u, v and x are words such that x = uv, where uv is the concatenation of u and v, then we say that (u, v) is a *factorization* of x. Let (u, v) be a factorization for a word x. Then if w is a non-empty word such that both of the following hold - either w is a suffix of u or u is a suffix of w - either w is a prefix of v or v is a prefix of w then w is said to be a *repetition* for the factorization (u, v). Just to unpack this, there are four possibilities here. Let w = "abc". Then we might have: - w is a suffix of u and w is a prefix of v. ex: ("lolabc", "abcde") - w is a suffix of u and v is a prefix of w. ex: ("lolabc", "ab") - u is a suffix of w and w is a prefix of v. ex: ("bc", "abchi") - u is a suffix of w and v is a prefix of w. ex: ("bc", "a") Note that the word vu is a repetition for any factorization (u,v) of x = uv, so every factorization has at least one repetition. If x is a string and (u, v) is a factorization for x, then a *local period* for (u, v) is an integer r such that there is some word w such that |w| = r and w is a repetition for (u, v). We denote by local_period(u, v) the smallest local period of (u, v). We sometimes call this *the local period* of (u, v). Provided that x = uv is non-empty, this is well-defined (because each non-empty word has at least one factorization, as noted above). It can be proven that the following is an equivalent definition of a local period for a factorization (u, v): any positive integer r such that x[i] == x[i+r] for all i such that |u| - r <= i <= |u| - 1 and such that both x[i] and x[i+r] are defined. (i.e. i > 0 and i + r < |x|). Using the above reformulation, it is easy to prove that 1 <= local_period(u, v) <= period(uv) A factorization (u, v) of x such that local_period(u,v) = period(x) is called a *critical factorization*. The algorithm hinges on the following theorem, which is stated without proof: **Critical Factorization Theorem** Any word x has at least one critical factorization (u, v) such that |u| < period(x). The purpose of maximal_suffix is to find such a critical factorization. */ impl TwoWaySearcher { #[allow(dead_code)] fn new(needle: &[u8]) -> TwoWaySearcher { let (crit_pos_false, period_false) = TwoWaySearcher::maximal_suffix(needle, false); let (crit_pos_true, period_true) = TwoWaySearcher::maximal_suffix(needle, true); let (crit_pos, period) = if crit_pos_false > crit_pos_true { (crit_pos_false, period_false) } else { (crit_pos_true, period_true) }; // This isn't in the original algorithm, as far as I'm aware. let byteset = needle.iter() .fold(0, |a, &b| (1 << ((b & 0x3f) as usize)) | a); // A particularly readable explanation of what's going on here can be found // in Crochemore and Rytter's book "Text Algorithms", ch 13. Specifically // see the code for "Algorithm CP" on p. 323. // // What's going on is we have some critical factorization (u, v) of the // needle, and we want to determine whether u is a suffix of // &v[..period]. If it is, we use "Algorithm CP1". Otherwise we use // "Algorithm CP2", which is optimized for when the period of the needle // is large. if &needle[..crit_pos] == &needle[period.. period + crit_pos] { TwoWaySearcher { crit_pos: crit_pos, period: period, byteset: byteset, position: 0, memory: 0 } } else { TwoWaySearcher { crit_pos: crit_pos, period: cmp::max(crit_pos, needle.len() - crit_pos) + 1, byteset: byteset, position: 0, memory: usize::MAX // Dummy value to signify that the period is long } } } // One of the main ideas of Two-Way is that we factorize the needle into // two halves, (u, v), and begin trying to find v in the haystack by scanning // left to right. If v matches, we try to match u by scanning right to left. // How far we can jump when we encounter a mismatch is all based on the fact // that (u, v) is a critical factorization for the needle. #[inline] fn next(&mut self, haystack: &[u8], needle: &[u8], long_period: bool) -> Option<(usize, usize)> { 'search: loop { // Check that we have room to search in if self.position + needle.len() > haystack.len() { return None; } // Quickly skip by large portions unrelated to our substring if (self.byteset >> ((haystack[self.position + needle.len() - 1] & 0x3f) as usize)) & 1 == 0 { self.position += needle.len(); if !long_period { self.memory = 0; } continue 'search; } // See if the right part of the needle matches let start = if long_period { self.crit_pos } else { cmp::max(self.crit_pos, self.memory) }; for i in start..needle.len() { if needle[i] != haystack[self.position + i] { self.position += i - self.crit_pos + 1; if !long_period { self.memory = 0; } continue 'search; } } // See if the left part of the needle matches let start = if long_period { 0 } else { self.memory }; for i in (start..self.crit_pos).rev() { if needle[i] != haystack[self.position + i] { self.position += self.period; if !long_period { self.memory = needle.len() - self.period; } continue 'search; } } // We have found a match! let match_pos = self.position; self.position += needle.len(); // add self.period for all matches if !long_period { self.memory = 0; // set to needle.len() - self.period for all matches } return Some((match_pos, match_pos + needle.len())); } } // Computes a critical factorization (u, v) of `arr`. // Specifically, returns (i, p), where i is the starting index of v in some // critical factorization (u, v) and p = period(v) #[inline] #[allow(dead_code)] fn maximal_suffix(arr: &[u8], reversed: bool) -> (usize, usize) { use num::wrapping::WrappingOps; let mut left = -1; // Corresponds to i in the paper let mut right = 0; // Corresponds to j in the paper let mut offset = 1; // Corresponds to k in the paper let mut period = 1; // Corresponds to p in the paper while right + offset < arr.len() { let a; let b; if reversed { a = arr[left.wrapping_add(offset)]; b = arr[right + offset]; } else { a = arr[right + offset]; b = arr[left.wrapping_add(offset)]; } if a < b { // Suffix is smaller, period is entire prefix so far. right += offset; offset = 1; period = right.wrapping_sub(left); } else if a == b { // Advance through repetition of the current period. if offset == period { right += offset; offset = 1; } else { offset += 1; } } else { // Suffix is larger, start over from current location. left = right; right += 1; offset = 1; period = 1; } } (left.wrapping_add(1), period) } } /// The internal state of an iterator that searches for matches of a substring /// within a larger string using a dynamically chosen search algorithm #[derive(Clone)] // NB: This is kept around for convenience because // it is planned to be used again in the future enum OldSearcher { TwoWay(TwoWaySearcher), TwoWayLong(TwoWaySearcher), } impl OldSearcher { #[allow(dead_code)] fn new(haystack: &[u8], needle: &[u8]) -> OldSearcher { if needle.len() == 0 { // Handle specially unimplemented!() // FIXME: Tune this. // FIXME(#16715): This unsigned integer addition will probably not // overflow because that would mean that the memory almost solely // consists of the needle. Needs #16715 to be formally fixed. } else if needle.len() + 20 > haystack.len() { // Use naive searcher unimplemented!() } else { let searcher = TwoWaySearcher::new(needle); if searcher.memory == usize::MAX { // If the period is long TwoWayLong(searcher) } else { TwoWay(searcher) } } } } #[derive(Clone)] // NB: This is kept around for convenience because // it is planned to be used again in the future struct OldMatchIndices<'a, 'b> { // constants haystack: &'a str, needle: &'b str, searcher: OldSearcher } // FIXME: #21637 Prevents a Clone impl /// An iterator over the start and end indices of the matches of a /// substring within a larger string #[unstable(feature = "core", reason = "type may be removed")] pub struct MatchIndices<'a, P: Pattern<'a>>(P::Searcher); #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> Iterator for MatchIndices<'a, P> { type Item = (usize, usize); #[inline] fn next(&mut self) -> Option<(usize, usize)> { self.0.next_match() } } /// An iterator over the substrings of a string separated by a given /// search string #[unstable(feature = "core")] #[deprecated(since = "1.0.0", reason = "use `Split` with a `&str`")] pub struct SplitStr<'a, P: Pattern<'a>>(Split<'a, P>); impl<'a, P: Pattern<'a>> Iterator for SplitStr<'a, P> { type Item = &'a str; #[inline] #[allow(deprecated)] fn next(&mut self) -> Option<&'a str> { Iterator::next(&mut self.0) } } impl<'a, 'b> OldMatchIndices<'a, 'b> { #[inline] #[allow(dead_code)] fn next(&mut self) -> Option<(usize, usize)> { match self.searcher { TwoWay(ref mut searcher) => searcher.next(self.haystack.as_bytes(), self.needle.as_bytes(), false), TwoWayLong(ref mut searcher) => searcher.next(self.haystack.as_bytes(), self.needle.as_bytes(), true), } } } /* Section: Comparing strings */ // share the implementation of the lang-item vs. non-lang-item // eq_slice. /// NOTE: This function is (ab)used in rustc::middle::trans::_match /// to compare &[u8] byte slices that are not necessarily valid UTF-8. #[inline] fn eq_slice_(a: &str, b: &str) -> bool { // NOTE: In theory n should be libc::size_t and not usize, but libc is not available here #[allow(improper_ctypes)] extern { fn memcmp(s1: *const i8, s2: *const i8, n: usize) -> i32; } a.len() == b.len() && unsafe { memcmp(a.as_ptr() as *const i8, b.as_ptr() as *const i8, a.len()) == 0 } } /// Bytewise slice equality /// NOTE: This function is (ab)used in rustc::middle::trans::_match /// to compare &[u8] byte slices that are not necessarily valid UTF-8. #[lang="str_eq"] #[inline] fn eq_slice(a: &str, b: &str) -> bool { eq_slice_(a, b) } /* Section: Misc */ /// Walk through `iter` checking that it's a valid UTF-8 sequence, /// returning `true` in that case, or, if it is invalid, `false` with /// `iter` reset such that it is pointing at the first byte in the /// invalid sequence. #[inline(always)] fn run_utf8_validation_iterator(iter: &mut slice::Iter) -> Result<(), Utf8Error> { let whole = iter.as_slice(); loop { // save the current thing we're pointing at. let old = iter.clone(); // restore the iterator we had at the start of this codepoint. macro_rules! err { () => {{ *iter = old.clone(); return Err(Utf8Error::InvalidByte(whole.len() - iter.as_slice().len())) }}} macro_rules! next { () => { match iter.next() { Some(a) => *a, // we needed data, but there was none: error! None => return Err(Utf8Error::TooShort), } }} let first = match iter.next() { Some(&b) => b, // we're at the end of the iterator and a codepoint // boundary at the same time, so this string is valid. None => return Ok(()) }; // ASCII characters are always valid, so only large // bytes need more examination. if first >= 128 { let w = UTF8_CHAR_WIDTH[first as usize] as usize; let second = next!(); // 2-byte encoding is for codepoints \u{0080} to \u{07ff} // first C2 80 last DF BF // 3-byte encoding is for codepoints \u{0800} to \u{ffff} // first E0 A0 80 last EF BF BF // excluding surrogates codepoints \u{d800} to \u{dfff} // ED A0 80 to ED BF BF // 4-byte encoding is for codepoints \u{1000}0 to \u{10ff}ff // first F0 90 80 80 last F4 8F BF BF // // Use the UTF-8 syntax from the RFC // // https://tools.ietf.org/html/rfc3629 // UTF8-1 = %x00-7F // UTF8-2 = %xC2-DF UTF8-tail // UTF8-3 = %xE0 %xA0-BF UTF8-tail / %xE1-EC 2( UTF8-tail ) / // %xED %x80-9F UTF8-tail / %xEE-EF 2( UTF8-tail ) // UTF8-4 = %xF0 %x90-BF 2( UTF8-tail ) / %xF1-F3 3( UTF8-tail ) / // %xF4 %x80-8F 2( UTF8-tail ) match w { 2 => if second & !CONT_MASK != TAG_CONT_U8 {err!()}, 3 => { match (first, second, next!() & !CONT_MASK) { (0xE0 , 0xA0 ... 0xBF, TAG_CONT_U8) | (0xE1 ... 0xEC, 0x80 ... 0xBF, TAG_CONT_U8) | (0xED , 0x80 ... 0x9F, TAG_CONT_U8) | (0xEE ... 0xEF, 0x80 ... 0xBF, TAG_CONT_U8) => {} _ => err!() } } 4 => { match (first, second, next!() & !CONT_MASK, next!() & !CONT_MASK) { (0xF0 , 0x90 ... 0xBF, TAG_CONT_U8, TAG_CONT_U8) | (0xF1 ... 0xF3, 0x80 ... 0xBF, TAG_CONT_U8, TAG_CONT_U8) | (0xF4 , 0x80 ... 0x8F, TAG_CONT_U8, TAG_CONT_U8) => {} _ => err!() } } _ => err!() } } } } // https://tools.ietf.org/html/rfc3629 static UTF8_CHAR_WIDTH: [u8; 256] = [ 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, // 0x1F 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, // 0x3F 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, // 0x5F 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, // 0x7F 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, // 0x9F 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, // 0xBF 0,0,2,2,2,2,2,2,2,2,2,2,2,2,2,2, 2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2, // 0xDF 3,3,3,3,3,3,3,3,3,3,3,3,3,3,3,3, // 0xEF 4,4,4,4,4,0,0,0,0,0,0,0,0,0,0,0, // 0xFF ]; /// Struct that contains a `char` and the index of the first byte of /// the next `char` in a string. This can be used as a data structure /// for iterating over the UTF-8 bytes of a string. #[derive(Copy)] #[unstable(feature = "core", reason = "naming is uncertain with container conventions")] pub struct CharRange { /// Current `char` pub ch: char, /// Index of the first byte of the next `char` pub next: usize, } /// Mask of the value bits of a continuation byte const CONT_MASK: u8 = 0b0011_1111u8; /// Value of the tag bits (tag mask is !CONT_MASK) of a continuation byte const TAG_CONT_U8: u8 = 0b1000_0000u8; /* Section: Trait implementations */ mod traits { use cmp::{Ordering, Ord, PartialEq, PartialOrd, Eq}; use cmp::Ordering::{Less, Equal, Greater}; use iter::IteratorExt; use option::Option; use option::Option::Some; use ops; use str::{StrExt, eq_slice}; #[stable(feature = "rust1", since = "1.0.0")] impl Ord for str { #[inline] fn cmp(&self, other: &str) -> Ordering { for (s_b, o_b) in self.bytes().zip(other.bytes()) { match s_b.cmp(&o_b) { Greater => return Greater, Less => return Less, Equal => () } } self.len().cmp(&other.len()) } } #[stable(feature = "rust1", since = "1.0.0")] impl PartialEq for str { #[inline] fn eq(&self, other: &str) -> bool { eq_slice(self, other) } #[inline] fn ne(&self, other: &str) -> bool { !(*self).eq(other) } } #[stable(feature = "rust1", since = "1.0.0")] impl Eq for str {} #[stable(feature = "rust1", since = "1.0.0")] impl PartialOrd for str { #[inline] fn partial_cmp(&self, other: &str) -> Option { Some(self.cmp(other)) } } /// Returns a slice of the given string from the byte range /// [`begin`..`end`). /// /// This operation is `O(1)`. /// /// Panics when `begin` and `end` do not point to valid characters /// or point beyond the last character of the string. /// /// # Example /// /// ```rust /// let s = "Löwe 老虎 Léopard"; /// assert_eq!(&s[0 .. 1], "L"); /// /// assert_eq!(&s[1 .. 9], "öwe 老"); /// /// // these will panic: /// // byte 2 lies within `ö`: /// // &s[2 ..3]; /// /// // byte 8 lies within `老` /// // &s[1 .. 8]; /// /// // byte 100 is outside the string /// // &s[3 .. 100]; /// ``` #[stable(feature = "rust1", since = "1.0.0")] impl ops::Index> for str { type Output = str; #[inline] fn index(&self, index: &ops::Range) -> &str { // is_char_boundary checks that the index is in [0, .len()] if index.start <= index.end && self.is_char_boundary(index.start) && self.is_char_boundary(index.end) { unsafe { self.slice_unchecked(index.start, index.end) } } else { super::slice_error_fail(self, index.start, index.end) } } } /// Returns a slice of the string from the beginning to byte /// `end`. /// /// Equivalent to `self[0 .. end]`. /// /// Panics when `end` does not point to a valid character, or is /// out of bounds. #[stable(feature = "rust1", since = "1.0.0")] impl ops::Index> for str { type Output = str; #[inline] fn index(&self, index: &ops::RangeTo) -> &str { // is_char_boundary checks that the index is in [0, .len()] if self.is_char_boundary(index.end) { unsafe { self.slice_unchecked(0, index.end) } } else { super::slice_error_fail(self, 0, index.end) } } } /// Returns a slice of the string from `begin` to its end. /// /// Equivalent to `self[begin .. self.len()]`. /// /// Panics when `begin` does not point to a valid character, or is /// out of bounds. #[stable(feature = "rust1", since = "1.0.0")] impl ops::Index> for str { type Output = str; #[inline] fn index(&self, index: &ops::RangeFrom) -> &str { // is_char_boundary checks that the index is in [0, .len()] if self.is_char_boundary(index.start) { unsafe { self.slice_unchecked(index.start, self.len()) } } else { super::slice_error_fail(self, index.start, self.len()) } } } #[stable(feature = "rust1", since = "1.0.0")] impl ops::Index for str { type Output = str; #[inline] fn index(&self, _index: &ops::RangeFull) -> &str { self } } } /// Any string that can be represented as a slice #[unstable(feature = "core", reason = "Instead of taking this bound generically, this trait will be \ replaced with one of slicing syntax (&foo[..]), deref coercions, or \ a more generic conversion trait")] pub trait Str { /// Work with `self` as a slice. fn as_slice<'a>(&'a self) -> &'a str; } impl Str for str { #[inline] fn as_slice<'a>(&'a self) -> &'a str { self } } impl<'a, S: ?Sized> Str for &'a S where S: Str { #[inline] fn as_slice(&self) -> &str { Str::as_slice(*self) } } /// Return type of `StrExt::split` #[stable(feature = "rust1", since = "1.0.0")] pub struct Split<'a, P: Pattern<'a>>(CharSplits<'a, P>); #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> Iterator for Split<'a, P> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { self.0.next() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a, P: Pattern<'a>> DoubleEndedIterator for Split<'a, P> where P::Searcher: DoubleEndedSearcher<'a> { #[inline] fn next_back(&mut self) -> Option<&'a str> { self.0.next_back() } } /// Return type of `StrExt::split_terminator` #[stable(feature = "rust1", since = "1.0.0")] pub struct SplitTerminator<'a, P: Pattern<'a>>(CharSplits<'a, P>); delegate_iter!{pattern &'a str : SplitTerminator<'a, P>} /// Return type of `StrExt::splitn` #[stable(feature = "rust1", since = "1.0.0")] pub struct SplitN<'a, P: Pattern<'a>>(CharSplitsN<'a, P>); delegate_iter!{pattern forward &'a str : SplitN<'a, P>} /// Return type of `StrExt::rsplitn` #[stable(feature = "rust1", since = "1.0.0")] pub struct RSplitN<'a, P: Pattern<'a>>(CharSplitsN<'a, P>); delegate_iter!{pattern forward &'a str : RSplitN<'a, P>} /// Methods for string slices #[allow(missing_docs)] pub trait StrExt { // NB there are no docs here are they're all located on the StrExt trait in // libcollections, not here. fn contains<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool; fn contains_char<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool; fn chars<'a>(&'a self) -> Chars<'a>; fn bytes<'a>(&'a self) -> Bytes<'a>; fn char_indices<'a>(&'a self) -> CharIndices<'a>; fn split<'a, P: Pattern<'a>>(&'a self, pat: P) -> Split<'a, P>; fn splitn<'a, P: Pattern<'a>>(&'a self, count: usize, pat: P) -> SplitN<'a, P>; fn split_terminator<'a, P: Pattern<'a>>(&'a self, pat: P) -> SplitTerminator<'a, P>; fn rsplitn<'a, P: Pattern<'a>>(&'a self, count: usize, pat: P) -> RSplitN<'a, P>; fn match_indices<'a, P: Pattern<'a>>(&'a self, pat: P) -> MatchIndices<'a, P>; fn split_str<'a, P: Pattern<'a>>(&'a self, pat: P) -> SplitStr<'a, P>; fn lines<'a>(&'a self) -> Lines<'a>; fn lines_any<'a>(&'a self) -> LinesAny<'a>; fn char_len(&self) -> usize; fn slice_chars<'a>(&'a self, begin: usize, end: usize) -> &'a str; unsafe fn slice_unchecked<'a>(&'a self, begin: usize, end: usize) -> &'a str; fn starts_with<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool; fn ends_with<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool where P::Searcher: ReverseSearcher<'a>; fn trim_matches<'a, P: Pattern<'a>>(&'a self, pat: P) -> &'a str where P::Searcher: DoubleEndedSearcher<'a>; fn trim_left_matches<'a, P: Pattern<'a>>(&'a self, pat: P) -> &'a str; fn trim_right_matches<'a, P: Pattern<'a>>(&'a self, pat: P) -> &'a str where P::Searcher: ReverseSearcher<'a>; fn is_char_boundary(&self, index: usize) -> bool; fn char_range_at(&self, start: usize) -> CharRange; fn char_range_at_reverse(&self, start: usize) -> CharRange; fn char_at(&self, i: usize) -> char; fn char_at_reverse(&self, i: usize) -> char; fn as_bytes<'a>(&'a self) -> &'a [u8]; fn find<'a, P: Pattern<'a>>(&'a self, pat: P) -> Option; fn rfind<'a, P: Pattern<'a>>(&'a self, pat: P) -> Option where P::Searcher: ReverseSearcher<'a>; fn find_str<'a, P: Pattern<'a>>(&'a self, pat: P) -> Option; fn slice_shift_char<'a>(&'a self) -> Option<(char, &'a str)>; fn subslice_offset(&self, inner: &str) -> usize; fn as_ptr(&self) -> *const u8; fn len(&self) -> usize; fn is_empty(&self) -> bool; fn parse(&self) -> Result; } #[inline(never)] fn slice_error_fail(s: &str, begin: usize, end: usize) -> ! { assert!(begin <= end); panic!("index {} and/or {} in `{}` do not lie on character boundary", begin, end, s); } impl StrExt for str { #[inline] fn contains<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool { pat.is_contained_in(self) } #[inline] fn contains_char<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool { pat.is_contained_in(self) } #[inline] fn chars(&self) -> Chars { Chars{iter: self.as_bytes().iter()} } #[inline] fn bytes(&self) -> Bytes { Bytes(self.as_bytes().iter().map(BytesDeref)) } #[inline] fn char_indices(&self) -> CharIndices { CharIndices { front_offset: 0, iter: self.chars() } } #[inline] fn split<'a, P: Pattern<'a>>(&'a self, pat: P) -> Split<'a, P> { Split(CharSplits { start: 0, end: self.len(), matcher: pat.into_searcher(self), allow_trailing_empty: true, finished: false, }) } #[inline] fn splitn<'a, P: Pattern<'a>>(&'a self, count: usize, pat: P) -> SplitN<'a, P> { SplitN(CharSplitsN { iter: self.split(pat).0, count: count, invert: false, }) } #[inline] fn split_terminator<'a, P: Pattern<'a>>(&'a self, pat: P) -> SplitTerminator<'a, P> { SplitTerminator(CharSplits { allow_trailing_empty: false, ..self.split(pat).0 }) } #[inline] fn rsplitn<'a, P: Pattern<'a>>(&'a self, count: usize, pat: P) -> RSplitN<'a, P> { RSplitN(CharSplitsN { iter: self.split(pat).0, count: count, invert: true, }) } #[inline] fn match_indices<'a, P: Pattern<'a>>(&'a self, pat: P) -> MatchIndices<'a, P> { MatchIndices(pat.into_searcher(self)) } #[inline] #[allow(deprecated) /* for SplitStr */ ] fn split_str<'a, P: Pattern<'a>>(&'a self, pat: P) -> SplitStr<'a, P> { SplitStr(self.split(pat)) } #[inline] fn lines(&self) -> Lines { Lines { inner: self.split_terminator('\n').0 } } fn lines_any(&self) -> LinesAny { fn f(line: &str) -> &str { let l = line.len(); if l > 0 && line.as_bytes()[l - 1] == b'\r' { &line[0 .. l - 1] } else { line } } let f: fn(&str) -> &str = f; // coerce to fn pointer LinesAny { inner: self.lines().map(f) } } #[inline] fn char_len(&self) -> usize { self.chars().count() } fn slice_chars(&self, begin: usize, end: usize) -> &str { assert!(begin <= end); let mut count = 0; let mut begin_byte = None; let mut end_byte = None; // This could be even more efficient by not decoding, // only finding the char boundaries for (idx, _) in self.char_indices() { if count == begin { begin_byte = Some(idx); } if count == end { end_byte = Some(idx); break; } count += 1; } if begin_byte.is_none() && count == begin { begin_byte = Some(self.len()) } if end_byte.is_none() && count == end { end_byte = Some(self.len()) } match (begin_byte, end_byte) { (None, _) => panic!("slice_chars: `begin` is beyond end of string"), (_, None) => panic!("slice_chars: `end` is beyond end of string"), (Some(a), Some(b)) => unsafe { self.slice_unchecked(a, b) } } } #[inline] unsafe fn slice_unchecked(&self, begin: usize, end: usize) -> &str { mem::transmute(Slice { data: self.as_ptr().offset(begin as int), len: end - begin, }) } #[inline] fn starts_with<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool { pat.is_prefix_of(self) } #[inline] fn ends_with<'a, P: Pattern<'a>>(&'a self, pat: P) -> bool where P::Searcher: ReverseSearcher<'a> { pat.is_suffix_of(self) } #[inline] fn trim_matches<'a, P: Pattern<'a>>(&'a self, pat: P) -> &'a str where P::Searcher: DoubleEndedSearcher<'a> { let mut i = 0; let mut j = 0; let mut matcher = pat.into_searcher(self); if let Some((a, b)) = matcher.next_reject() { i = a; j = b; // Rember earliest known match, correct it below if // last match is different } if let Some((_, b)) = matcher.next_reject_back() { j = b; } unsafe { // Searcher is known to return valid indices self.slice_unchecked(i, j) } } #[inline] fn trim_left_matches<'a, P: Pattern<'a>>(&'a self, pat: P) -> &'a str { let mut i = self.len(); let mut matcher = pat.into_searcher(self); if let Some((a, _)) = matcher.next_reject() { i = a; } unsafe { // Searcher is known to return valid indices self.slice_unchecked(i, self.len()) } } #[inline] fn trim_right_matches<'a, P: Pattern<'a>>(&'a self, pat: P) -> &'a str where P::Searcher: ReverseSearcher<'a> { let mut j = 0; let mut matcher = pat.into_searcher(self); if let Some((_, b)) = matcher.next_reject_back() { j = b; } unsafe { // Searcher is known to return valid indices self.slice_unchecked(0, j) } } #[inline] fn is_char_boundary(&self, index: usize) -> bool { if index == self.len() { return true; } match self.as_bytes().get(index) { None => false, Some(&b) => b < 128u8 || b >= 192u8, } } #[inline] fn char_range_at(&self, i: usize) -> CharRange { let (c, n) = char_range_at_raw(self.as_bytes(), i); CharRange { ch: unsafe { mem::transmute(c) }, next: n } } #[inline] fn char_range_at_reverse(&self, start: usize) -> CharRange { let mut prev = start; prev = prev.saturating_sub(1); if self.as_bytes()[prev] < 128 { return CharRange{ch: self.as_bytes()[prev] as char, next: prev} } // Multibyte case is a fn to allow char_range_at_reverse to inline cleanly fn multibyte_char_range_at_reverse(s: &str, mut i: usize) -> CharRange { // while there is a previous byte == 10...... while i > 0 && s.as_bytes()[i] & !CONT_MASK == TAG_CONT_U8 { i -= 1; } let mut val = s.as_bytes()[i] as u32; let w = UTF8_CHAR_WIDTH[val as usize] as usize; assert!((w != 0)); val = utf8_first_byte!(val, w); val = utf8_acc_cont_byte!(val, s.as_bytes()[i + 1]); if w > 2 { val = utf8_acc_cont_byte!(val, s.as_bytes()[i + 2]); } if w > 3 { val = utf8_acc_cont_byte!(val, s.as_bytes()[i + 3]); } return CharRange {ch: unsafe { mem::transmute(val) }, next: i}; } return multibyte_char_range_at_reverse(self, prev); } #[inline] fn char_at(&self, i: usize) -> char { self.char_range_at(i).ch } #[inline] fn char_at_reverse(&self, i: usize) -> char { self.char_range_at_reverse(i).ch } #[inline] fn as_bytes(&self) -> &[u8] { unsafe { mem::transmute(self) } } fn find<'a, P: Pattern<'a>>(&'a self, pat: P) -> Option { pat.into_searcher(self).next_match().map(|(i, _)| i) } fn rfind<'a, P: Pattern<'a>>(&'a self, pat: P) -> Option where P::Searcher: ReverseSearcher<'a> { pat.into_searcher(self).next_match_back().map(|(i, _)| i) } fn find_str<'a, P: Pattern<'a>>(&'a self, pat: P) -> Option { self.find(pat) } #[inline] fn slice_shift_char(&self) -> Option<(char, &str)> { if self.is_empty() { None } else { let CharRange {ch, next} = self.char_range_at(0); let next_s = unsafe { self.slice_unchecked(next, self.len()) }; Some((ch, next_s)) } } fn subslice_offset(&self, inner: &str) -> usize { let a_start = self.as_ptr() as usize; let a_end = a_start + self.len(); let b_start = inner.as_ptr() as usize; let b_end = b_start + inner.len(); assert!(a_start <= b_start); assert!(b_end <= a_end); b_start - a_start } #[inline] fn as_ptr(&self) -> *const u8 { self.repr().data } #[inline] fn len(&self) -> usize { self.repr().len } #[inline] fn is_empty(&self) -> bool { self.len() == 0 } #[inline] fn parse(&self) -> Result { FromStr::from_str(self) } } /// Pluck a code point out of a UTF-8-like byte slice and return the /// index of the next code point. #[inline] #[unstable(feature = "core")] pub fn char_range_at_raw(bytes: &[u8], i: usize) -> (u32, usize) { if bytes[i] < 128u8 { return (bytes[i] as u32, i + 1); } // Multibyte case is a fn to allow char_range_at to inline cleanly fn multibyte_char_range_at(bytes: &[u8], i: usize) -> (u32, usize) { let mut val = bytes[i] as u32; let w = UTF8_CHAR_WIDTH[val as usize] as usize; assert!((w != 0)); val = utf8_first_byte!(val, w); val = utf8_acc_cont_byte!(val, bytes[i + 1]); if w > 2 { val = utf8_acc_cont_byte!(val, bytes[i + 2]); } if w > 3 { val = utf8_acc_cont_byte!(val, bytes[i + 3]); } return (val, i + w); } multibyte_char_range_at(bytes, i) } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> Default for &'a str { #[stable(feature = "rust1", since = "1.0.0")] fn default() -> &'a str { "" } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> Iterator for Lines<'a> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { self.inner.next() } #[inline] fn size_hint(&self) -> (usize, Option) { self.inner.size_hint() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> DoubleEndedIterator for Lines<'a> { #[inline] fn next_back(&mut self) -> Option<&'a str> { self.inner.next_back() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> Iterator for LinesAny<'a> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { self.inner.next() } #[inline] fn size_hint(&self) -> (usize, Option) { self.inner.size_hint() } } #[stable(feature = "rust1", since = "1.0.0")] impl<'a> DoubleEndedIterator for LinesAny<'a> { #[inline] fn next_back(&mut self) -> Option<&'a str> { self.inner.next_back() } }