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1 #![allow(unused_imports)]
2 
3 use std::borrow::Cow;
4 use std::error;
5 use std::ffi::{OsStr, OsString};
6 use std::fmt;
7 use std::iter;
8 use std::ops;
9 use std::path::{Path, PathBuf};
10 use std::ptr;
11 use std::str;
12 use std::vec;
13 
14 use ext_slice::ByteSlice;
15 use utf8::{self, Utf8Error};
16 
17 /// Concatenate the elements given by the iterator together into a single
18 /// `Vec<u8>`.
19 ///
20 /// The elements may be any type that can be cheaply converted into an `&[u8]`.
21 /// This includes, but is not limited to, `&str`, `&BStr` and `&[u8]` itself.
22 ///
23 /// # Examples
24 ///
25 /// Basic usage:
26 ///
27 /// ```
28 /// use bstr;
29 ///
30 /// let s = bstr::concat(&["foo", "bar", "baz"]);
31 /// assert_eq!(s, "foobarbaz".as_bytes());
32 /// ```
33 #[inline]
concat<T, I>(elements: I) -> Vec<u8> where T: AsRef<[u8]>, I: IntoIterator<Item = T>,34 pub fn concat<T, I>(elements: I) -> Vec<u8>
35 where
36     T: AsRef<[u8]>,
37     I: IntoIterator<Item = T>,
38 {
39     let mut dest = vec![];
40     for element in elements {
41         dest.push_str(element);
42     }
43     dest
44 }
45 
46 /// Join the elements given by the iterator with the given separator into a
47 /// single `Vec<u8>`.
48 ///
49 /// Both the separator and the elements may be any type that can be cheaply
50 /// converted into an `&[u8]`. This includes, but is not limited to,
51 /// `&str`, `&BStr` and `&[u8]` itself.
52 ///
53 /// # Examples
54 ///
55 /// Basic usage:
56 ///
57 /// ```
58 /// use bstr;
59 ///
60 /// let s = bstr::join(",", &["foo", "bar", "baz"]);
61 /// assert_eq!(s, "foo,bar,baz".as_bytes());
62 /// ```
63 #[inline]
join<B, T, I>(separator: B, elements: I) -> Vec<u8> where B: AsRef<[u8]>, T: AsRef<[u8]>, I: IntoIterator<Item = T>,64 pub fn join<B, T, I>(separator: B, elements: I) -> Vec<u8>
65 where
66     B: AsRef<[u8]>,
67     T: AsRef<[u8]>,
68     I: IntoIterator<Item = T>,
69 {
70     let mut it = elements.into_iter();
71     let mut dest = vec![];
72     match it.next() {
73         None => return dest,
74         Some(first) => {
75             dest.push_str(first);
76         }
77     }
78     for element in it {
79         dest.push_str(&separator);
80         dest.push_str(element);
81     }
82     dest
83 }
84 
85 impl ByteVec for Vec<u8> {
86     #[inline]
as_vec(&self) -> &Vec<u8>87     fn as_vec(&self) -> &Vec<u8> {
88         self
89     }
90 
91     #[inline]
as_vec_mut(&mut self) -> &mut Vec<u8>92     fn as_vec_mut(&mut self) -> &mut Vec<u8> {
93         self
94     }
95 
96     #[inline]
into_vec(self) -> Vec<u8>97     fn into_vec(self) -> Vec<u8> {
98         self
99     }
100 }
101 
102 /// Ensure that callers cannot implement `ByteSlice` by making an
103 /// umplementable trait its super trait.
104 pub trait Sealed {}
105 impl Sealed for Vec<u8> {}
106 
107 /// A trait that extends `Vec<u8>` with string oriented methods.
108 ///
109 /// Note that when using the constructor methods, such as
110 /// `ByteVec::from_slice`, one should actually call them using the concrete
111 /// type. For example:
112 ///
113 /// ```
114 /// use bstr::{B, ByteVec};
115 ///
116 /// let s = Vec::from_slice(b"abc"); // NOT ByteVec::from_slice("...")
117 /// assert_eq!(s, B("abc"));
118 /// ```
119 pub trait ByteVec: Sealed {
120     /// A method for accessing the raw vector bytes of this type. This is
121     /// always a no-op and callers shouldn't care about it. This only exists
122     /// for making the extension trait work.
123     #[doc(hidden)]
as_vec(&self) -> &Vec<u8>124     fn as_vec(&self) -> &Vec<u8>;
125 
126     /// A method for accessing the raw vector bytes of this type, mutably. This
127     /// is always a no-op and callers shouldn't care about it. This only exists
128     /// for making the extension trait work.
129     #[doc(hidden)]
as_vec_mut(&mut self) -> &mut Vec<u8>130     fn as_vec_mut(&mut self) -> &mut Vec<u8>;
131 
132     /// A method for consuming ownership of this vector. This is always a no-op
133     /// and callers shouldn't care about it. This only exists for making the
134     /// extension trait work.
135     #[doc(hidden)]
into_vec(self) -> Vec<u8> where Self: Sized136     fn into_vec(self) -> Vec<u8>
137     where
138         Self: Sized;
139 
140     /// Create a new owned byte string from the given byte slice.
141     ///
142     /// # Examples
143     ///
144     /// Basic usage:
145     ///
146     /// ```
147     /// use bstr::{B, ByteVec};
148     ///
149     /// let s = Vec::from_slice(b"abc");
150     /// assert_eq!(s, B("abc"));
151     /// ```
152     #[inline]
from_slice<B: AsRef<[u8]>>(bytes: B) -> Vec<u8>153     fn from_slice<B: AsRef<[u8]>>(bytes: B) -> Vec<u8> {
154         bytes.as_ref().to_vec()
155     }
156 
157     /// Create a new byte string from an owned OS string.
158     ///
159     /// On Unix, this always succeeds and is zero cost. On non-Unix systems,
160     /// this returns the original OS string if it is not valid UTF-8.
161     ///
162     /// # Examples
163     ///
164     /// Basic usage:
165     ///
166     /// ```
167     /// use std::ffi::OsString;
168     ///
169     /// use bstr::{B, ByteVec};
170     ///
171     /// let os_str = OsString::from("foo");
172     /// let bs = Vec::from_os_string(os_str).expect("valid UTF-8");
173     /// assert_eq!(bs, B("foo"));
174     /// ```
175     #[inline]
from_os_string(os_str: OsString) -> Result<Vec<u8>, OsString>176     fn from_os_string(os_str: OsString) -> Result<Vec<u8>, OsString> {
177         #[cfg(unix)]
178         #[inline]
179         fn imp(os_str: OsString) -> Result<Vec<u8>, OsString> {
180             use std::os::unix::ffi::OsStringExt;
181 
182             Ok(Vec::from(os_str.into_vec()))
183         }
184 
185         #[cfg(not(unix))]
186         #[inline]
187         fn imp(os_str: OsString) -> Result<Vec<u8>, OsString> {
188             os_str.into_string().map(Vec::from)
189         }
190 
191         imp(os_str)
192     }
193 
194     /// Lossily create a new byte string from an OS string slice.
195     ///
196     /// On Unix, this always succeeds, is zero cost and always returns a slice.
197     /// On non-Unix systems, this does a UTF-8 check. If the given OS string
198     /// slice is not valid UTF-8, then it is lossily decoded into valid UTF-8
199     /// (with invalid bytes replaced by the Unicode replacement codepoint).
200     ///
201     /// # Examples
202     ///
203     /// Basic usage:
204     ///
205     /// ```
206     /// use std::ffi::OsStr;
207     ///
208     /// use bstr::{B, ByteVec};
209     ///
210     /// let os_str = OsStr::new("foo");
211     /// let bs = Vec::from_os_str_lossy(os_str);
212     /// assert_eq!(bs, B("foo"));
213     /// ```
214     #[inline]
from_os_str_lossy<'a>(os_str: &'a OsStr) -> Cow<'a, [u8]>215     fn from_os_str_lossy<'a>(os_str: &'a OsStr) -> Cow<'a, [u8]> {
216         #[cfg(unix)]
217         #[inline]
218         fn imp<'a>(os_str: &'a OsStr) -> Cow<'a, [u8]> {
219             use std::os::unix::ffi::OsStrExt;
220 
221             Cow::Borrowed(os_str.as_bytes())
222         }
223 
224         #[cfg(not(unix))]
225         #[inline]
226         fn imp<'a>(os_str: &'a OsStr) -> Cow<'a, [u8]> {
227             match os_str.to_string_lossy() {
228                 Cow::Borrowed(x) => Cow::Borrowed(x.as_bytes()),
229                 Cow::Owned(x) => Cow::Owned(Vec::from(x)),
230             }
231         }
232 
233         imp(os_str)
234     }
235 
236     /// Create a new byte string from an owned file path.
237     ///
238     /// On Unix, this always succeeds and is zero cost. On non-Unix systems,
239     /// this returns the original path if it is not valid UTF-8.
240     ///
241     /// # Examples
242     ///
243     /// Basic usage:
244     ///
245     /// ```
246     /// use std::path::PathBuf;
247     ///
248     /// use bstr::{B, ByteVec};
249     ///
250     /// let path = PathBuf::from("foo");
251     /// let bs = Vec::from_path_buf(path).expect("must be valid UTF-8");
252     /// assert_eq!(bs, B("foo"));
253     /// ```
254     #[inline]
from_path_buf(path: PathBuf) -> Result<Vec<u8>, PathBuf>255     fn from_path_buf(path: PathBuf) -> Result<Vec<u8>, PathBuf> {
256         Vec::from_os_string(path.into_os_string()).map_err(PathBuf::from)
257     }
258 
259     /// Lossily create a new byte string from a file path.
260     ///
261     /// On Unix, this always succeeds, is zero cost and always returns a slice.
262     /// On non-Unix systems, this does a UTF-8 check. If the given path is not
263     /// valid UTF-8, then it is lossily decoded into valid UTF-8 (with invalid
264     /// bytes replaced by the Unicode replacement codepoint).
265     ///
266     /// # Examples
267     ///
268     /// Basic usage:
269     ///
270     /// ```
271     /// use std::path::Path;
272     ///
273     /// use bstr::{B, ByteVec};
274     ///
275     /// let path = Path::new("foo");
276     /// let bs = Vec::from_path_lossy(path);
277     /// assert_eq!(bs, B("foo"));
278     /// ```
279     #[inline]
from_path_lossy<'a>(path: &'a Path) -> Cow<'a, [u8]>280     fn from_path_lossy<'a>(path: &'a Path) -> Cow<'a, [u8]> {
281         Vec::from_os_str_lossy(path.as_os_str())
282     }
283 
284     /// Appends the given byte to the end of this byte string.
285     ///
286     /// Note that this is equivalent to the generic `Vec::push` method. This
287     /// method is provided to permit callers to explicitly differentiate
288     /// between pushing bytes, codepoints and strings.
289     ///
290     /// # Examples
291     ///
292     /// Basic usage:
293     ///
294     /// ```
295     /// use bstr::ByteVec;
296     ///
297     /// let mut s = <Vec<u8>>::from("abc");
298     /// s.push_byte(b'\xE2');
299     /// s.push_byte(b'\x98');
300     /// s.push_byte(b'\x83');
301     /// assert_eq!(s, "abc☃".as_bytes());
302     /// ```
303     #[inline]
push_byte(&mut self, byte: u8)304     fn push_byte(&mut self, byte: u8) {
305         self.as_vec_mut().push(byte);
306     }
307 
308     /// Appends the given `char` to the end of this byte string.
309     ///
310     /// # Examples
311     ///
312     /// Basic usage:
313     ///
314     /// ```
315     /// use bstr::ByteVec;
316     ///
317     /// let mut s = <Vec<u8>>::from("abc");
318     /// s.push_char('1');
319     /// s.push_char('2');
320     /// s.push_char('3');
321     /// assert_eq!(s, "abc123".as_bytes());
322     /// ```
323     #[inline]
push_char(&mut self, ch: char)324     fn push_char(&mut self, ch: char) {
325         if ch.len_utf8() == 1 {
326             self.push_byte(ch as u8);
327             return;
328         }
329         self.as_vec_mut()
330             .extend_from_slice(ch.encode_utf8(&mut [0; 4]).as_bytes());
331     }
332 
333     /// Appends the given slice to the end of this byte string. This accepts
334     /// any type that be converted to a `&[u8]`. This includes, but is not
335     /// limited to, `&str`, `&BStr`, and of course, `&[u8]` itself.
336     ///
337     /// # Examples
338     ///
339     /// Basic usage:
340     ///
341     /// ```
342     /// use bstr::ByteVec;
343     ///
344     /// let mut s = <Vec<u8>>::from("abc");
345     /// s.push_str(b"123");
346     /// assert_eq!(s, "abc123".as_bytes());
347     /// ```
348     #[inline]
push_str<B: AsRef<[u8]>>(&mut self, bytes: B)349     fn push_str<B: AsRef<[u8]>>(&mut self, bytes: B) {
350         self.as_vec_mut().extend_from_slice(bytes.as_ref());
351     }
352 
353     /// Converts a `Vec<u8>` into a `String` if and only if this byte string is
354     /// valid UTF-8.
355     ///
356     /// If it is not valid UTF-8, then a
357     /// [`FromUtf8Error`](struct.FromUtf8Error.html)
358     /// is returned. (This error can be used to examine why UTF-8 validation
359     /// failed, or to regain the original byte string.)
360     ///
361     /// # Examples
362     ///
363     /// Basic usage:
364     ///
365     /// ```
366     /// use bstr::ByteVec;
367     ///
368     /// # fn example() -> Result<(), Box<dyn std::error::Error>> {
369     /// let bytes = Vec::from("hello");
370     /// let string = bytes.into_string()?;
371     ///
372     /// assert_eq!("hello", string);
373     /// # Ok(()) }; example().unwrap()
374     /// ```
375     ///
376     /// If this byte string is not valid UTF-8, then an error will be returned.
377     /// That error can then be used to inspect the location at which invalid
378     /// UTF-8 was found, or to regain the original byte string:
379     ///
380     /// ```
381     /// use bstr::{B, ByteVec};
382     ///
383     /// let bytes = Vec::from_slice(b"foo\xFFbar");
384     /// let err = bytes.into_string().unwrap_err();
385     ///
386     /// assert_eq!(err.utf8_error().valid_up_to(), 3);
387     /// assert_eq!(err.utf8_error().error_len(), Some(1));
388     ///
389     /// // At no point in this example is an allocation performed.
390     /// let bytes = Vec::from(err.into_vec());
391     /// assert_eq!(bytes, B(b"foo\xFFbar"));
392     /// ```
393     #[inline]
into_string(self) -> Result<String, FromUtf8Error> where Self: Sized,394     fn into_string(self) -> Result<String, FromUtf8Error>
395     where
396         Self: Sized,
397     {
398         match utf8::validate(self.as_vec()) {
399             Err(err) => Err(FromUtf8Error { original: self.into_vec(), err }),
400             Ok(()) => {
401                 // SAFETY: This is safe because of the guarantees provided by
402                 // utf8::validate.
403                 unsafe { Ok(self.into_string_unchecked()) }
404             }
405         }
406     }
407 
408     /// Lossily converts a `Vec<u8>` into a `String`. If this byte string
409     /// contains invalid UTF-8, then the invalid bytes are replaced with the
410     /// Unicode replacement codepoint.
411     ///
412     /// # Examples
413     ///
414     /// Basic usage:
415     ///
416     /// ```
417     /// use bstr::ByteVec;
418     ///
419     /// let bytes = Vec::from_slice(b"foo\xFFbar");
420     /// let string = bytes.into_string_lossy();
421     /// assert_eq!(string, "foo\u{FFFD}bar");
422     /// ```
423     #[inline]
into_string_lossy(self) -> String where Self: Sized,424     fn into_string_lossy(self) -> String
425     where
426         Self: Sized,
427     {
428         match self.as_vec().to_str_lossy() {
429             Cow::Borrowed(_) => {
430                 // SAFETY: to_str_lossy() returning a Cow::Borrowed guarantees
431                 // the entire string is valid utf8.
432                 unsafe { self.into_string_unchecked() }
433             }
434             Cow::Owned(s) => s,
435         }
436     }
437 
438     /// Unsafely convert this byte string into a `String`, without checking for
439     /// valid UTF-8.
440     ///
441     /// # Safety
442     ///
443     /// Callers *must* ensure that this byte string is valid UTF-8 before
444     /// calling this method. Converting a byte string into a `String` that is
445     /// not valid UTF-8 is considered undefined behavior.
446     ///
447     /// This routine is useful in performance sensitive contexts where the
448     /// UTF-8 validity of the byte string is already known and it is
449     /// undesirable to pay the cost of an additional UTF-8 validation check
450     /// that [`into_string`](#method.into_string) performs.
451     ///
452     /// # Examples
453     ///
454     /// Basic usage:
455     ///
456     /// ```
457     /// use bstr::ByteVec;
458     ///
459     /// // SAFETY: This is safe because string literals are guaranteed to be
460     /// // valid UTF-8 by the Rust compiler.
461     /// let s = unsafe { Vec::from("☃βツ").into_string_unchecked() };
462     /// assert_eq!("☃βツ", s);
463     /// ```
464     #[inline]
into_string_unchecked(self) -> String where Self: Sized,465     unsafe fn into_string_unchecked(self) -> String
466     where
467         Self: Sized,
468     {
469         String::from_utf8_unchecked(self.into_vec())
470     }
471 
472     /// Converts this byte string into an OS string, in place.
473     ///
474     /// On Unix, this always succeeds and is zero cost. On non-Unix systems,
475     /// this returns the original byte string if it is not valid UTF-8.
476     ///
477     /// # Examples
478     ///
479     /// Basic usage:
480     ///
481     /// ```
482     /// use std::ffi::OsStr;
483     ///
484     /// use bstr::ByteVec;
485     ///
486     /// let bs = Vec::from("foo");
487     /// let os_str = bs.into_os_string().expect("should be valid UTF-8");
488     /// assert_eq!(os_str, OsStr::new("foo"));
489     /// ```
490     #[inline]
into_os_string(self) -> Result<OsString, Vec<u8>> where Self: Sized,491     fn into_os_string(self) -> Result<OsString, Vec<u8>>
492     where
493         Self: Sized,
494     {
495         #[cfg(unix)]
496         #[inline]
497         fn imp(v: Vec<u8>) -> Result<OsString, Vec<u8>> {
498             use std::os::unix::ffi::OsStringExt;
499 
500             Ok(OsString::from_vec(v))
501         }
502 
503         #[cfg(not(unix))]
504         #[inline]
505         fn imp(v: Vec<u8>) -> Result<OsString, Vec<u8>> {
506             match v.into_string() {
507                 Ok(s) => Ok(OsString::from(s)),
508                 Err(err) => Err(err.into_vec()),
509             }
510         }
511 
512         imp(self.into_vec())
513     }
514 
515     /// Lossily converts this byte string into an OS string, in place.
516     ///
517     /// On Unix, this always succeeds and is zero cost. On non-Unix systems,
518     /// this will perform a UTF-8 check and lossily convert this byte string
519     /// into valid UTF-8 using the Unicode replacement codepoint.
520     ///
521     /// Note that this can prevent the correct roundtripping of file paths on
522     /// non-Unix systems such as Windows, where file paths are an arbitrary
523     /// sequence of 16-bit integers.
524     ///
525     /// # Examples
526     ///
527     /// Basic usage:
528     ///
529     /// ```
530     /// use bstr::ByteVec;
531     ///
532     /// let bs = Vec::from_slice(b"foo\xFFbar");
533     /// let os_str = bs.into_os_string_lossy();
534     /// assert_eq!(os_str.to_string_lossy(), "foo\u{FFFD}bar");
535     /// ```
536     #[inline]
into_os_string_lossy(self) -> OsString where Self: Sized,537     fn into_os_string_lossy(self) -> OsString
538     where
539         Self: Sized,
540     {
541         #[cfg(unix)]
542         #[inline]
543         fn imp(v: Vec<u8>) -> OsString {
544             use std::os::unix::ffi::OsStringExt;
545 
546             OsString::from_vec(v)
547         }
548 
549         #[cfg(not(unix))]
550         #[inline]
551         fn imp(v: Vec<u8>) -> OsString {
552             OsString::from(v.into_string_lossy())
553         }
554 
555         imp(self.into_vec())
556     }
557 
558     /// Converts this byte string into an owned file path, in place.
559     ///
560     /// On Unix, this always succeeds and is zero cost. On non-Unix systems,
561     /// this returns the original byte string if it is not valid UTF-8.
562     ///
563     /// # Examples
564     ///
565     /// Basic usage:
566     ///
567     /// ```
568     /// use bstr::ByteVec;
569     ///
570     /// let bs = Vec::from("foo");
571     /// let path = bs.into_path_buf().expect("should be valid UTF-8");
572     /// assert_eq!(path.as_os_str(), "foo");
573     /// ```
574     #[inline]
into_path_buf(self) -> Result<PathBuf, Vec<u8>> where Self: Sized,575     fn into_path_buf(self) -> Result<PathBuf, Vec<u8>>
576     where
577         Self: Sized,
578     {
579         self.into_os_string().map(PathBuf::from)
580     }
581 
582     /// Lossily converts this byte string into an owned file path, in place.
583     ///
584     /// On Unix, this always succeeds and is zero cost. On non-Unix systems,
585     /// this will perform a UTF-8 check and lossily convert this byte string
586     /// into valid UTF-8 using the Unicode replacement codepoint.
587     ///
588     /// Note that this can prevent the correct roundtripping of file paths on
589     /// non-Unix systems such as Windows, where file paths are an arbitrary
590     /// sequence of 16-bit integers.
591     ///
592     /// # Examples
593     ///
594     /// Basic usage:
595     ///
596     /// ```
597     /// use bstr::ByteVec;
598     ///
599     /// let bs = Vec::from_slice(b"foo\xFFbar");
600     /// let path = bs.into_path_buf_lossy();
601     /// assert_eq!(path.to_string_lossy(), "foo\u{FFFD}bar");
602     /// ```
603     #[inline]
into_path_buf_lossy(self) -> PathBuf where Self: Sized,604     fn into_path_buf_lossy(self) -> PathBuf
605     where
606         Self: Sized,
607     {
608         PathBuf::from(self.into_os_string_lossy())
609     }
610 
611     /// Removes the last byte from this `Vec<u8>` and returns it.
612     ///
613     /// If this byte string is empty, then `None` is returned.
614     ///
615     /// If the last codepoint in this byte string is not ASCII, then removing
616     /// the last byte could make this byte string contain invalid UTF-8.
617     ///
618     /// Note that this is equivalent to the generic `Vec::pop` method. This
619     /// method is provided to permit callers to explicitly differentiate
620     /// between popping bytes and codepoints.
621     ///
622     /// # Examples
623     ///
624     /// Basic usage:
625     ///
626     /// ```
627     /// use bstr::ByteVec;
628     ///
629     /// let mut s = Vec::from("foo");
630     /// assert_eq!(s.pop_byte(), Some(b'o'));
631     /// assert_eq!(s.pop_byte(), Some(b'o'));
632     /// assert_eq!(s.pop_byte(), Some(b'f'));
633     /// assert_eq!(s.pop_byte(), None);
634     /// ```
635     #[inline]
pop_byte(&mut self) -> Option<u8>636     fn pop_byte(&mut self) -> Option<u8> {
637         self.as_vec_mut().pop()
638     }
639 
640     /// Removes the last codepoint from this `Vec<u8>` and returns it.
641     ///
642     /// If this byte string is empty, then `None` is returned. If the last
643     /// bytes of this byte string do not correspond to a valid UTF-8 code unit
644     /// sequence, then the Unicode replacement codepoint is yielded instead in
645     /// accordance with the
646     /// [replacement codepoint substitution policy](index.html#handling-of-invalid-utf8-8).
647     ///
648     /// # Examples
649     ///
650     /// Basic usage:
651     ///
652     /// ```
653     /// use bstr::ByteVec;
654     ///
655     /// let mut s = Vec::from("foo");
656     /// assert_eq!(s.pop_char(), Some('o'));
657     /// assert_eq!(s.pop_char(), Some('o'));
658     /// assert_eq!(s.pop_char(), Some('f'));
659     /// assert_eq!(s.pop_char(), None);
660     /// ```
661     ///
662     /// This shows the replacement codepoint substitution policy. Note that
663     /// the first pop yields a replacement codepoint but actually removes two
664     /// bytes. This is in contrast with subsequent pops when encountering
665     /// `\xFF` since `\xFF` is never a valid prefix for any valid UTF-8
666     /// code unit sequence.
667     ///
668     /// ```
669     /// use bstr::ByteVec;
670     ///
671     /// let mut s = Vec::from_slice(b"f\xFF\xFF\xFFoo\xE2\x98");
672     /// assert_eq!(s.pop_char(), Some('\u{FFFD}'));
673     /// assert_eq!(s.pop_char(), Some('o'));
674     /// assert_eq!(s.pop_char(), Some('o'));
675     /// assert_eq!(s.pop_char(), Some('\u{FFFD}'));
676     /// assert_eq!(s.pop_char(), Some('\u{FFFD}'));
677     /// assert_eq!(s.pop_char(), Some('\u{FFFD}'));
678     /// assert_eq!(s.pop_char(), Some('f'));
679     /// assert_eq!(s.pop_char(), None);
680     /// ```
681     #[inline]
pop_char(&mut self) -> Option<char>682     fn pop_char(&mut self) -> Option<char> {
683         let (ch, size) = utf8::decode_last_lossy(self.as_vec());
684         if size == 0 {
685             return None;
686         }
687         let new_len = self.as_vec().len() - size;
688         self.as_vec_mut().truncate(new_len);
689         Some(ch)
690     }
691 
692     /// Removes a `char` from this `Vec<u8>` at the given byte position and
693     /// returns it.
694     ///
695     /// If the bytes at the given position do not lead to a valid UTF-8 code
696     /// unit sequence, then a
697     /// [replacement codepoint is returned instead](index.html#handling-of-invalid-utf8-8).
698     ///
699     /// # Panics
700     ///
701     /// Panics if `at` is larger than or equal to this byte string's length.
702     ///
703     /// # Examples
704     ///
705     /// Basic usage:
706     ///
707     /// ```
708     /// use bstr::ByteVec;
709     ///
710     /// let mut s = Vec::from("foo☃bar");
711     /// assert_eq!(s.remove_char(3), '☃');
712     /// assert_eq!(s, b"foobar");
713     /// ```
714     ///
715     /// This example shows how the Unicode replacement codepoint policy is
716     /// used:
717     ///
718     /// ```
719     /// use bstr::ByteVec;
720     ///
721     /// let mut s = Vec::from_slice(b"foo\xFFbar");
722     /// assert_eq!(s.remove_char(3), '\u{FFFD}');
723     /// assert_eq!(s, b"foobar");
724     /// ```
725     #[inline]
remove_char(&mut self, at: usize) -> char726     fn remove_char(&mut self, at: usize) -> char {
727         let (ch, size) = utf8::decode_lossy(&self.as_vec()[at..]);
728         assert!(
729             size > 0,
730             "expected {} to be less than {}",
731             at,
732             self.as_vec().len(),
733         );
734         self.as_vec_mut().drain(at..at + size);
735         ch
736     }
737 
738     /// Inserts the given codepoint into this `Vec<u8>` at a particular byte
739     /// position.
740     ///
741     /// This is an `O(n)` operation as it may copy a number of elements in this
742     /// byte string proportional to its length.
743     ///
744     /// # Panics
745     ///
746     /// Panics if `at` is larger than the byte string's length.
747     ///
748     /// # Examples
749     ///
750     /// Basic usage:
751     ///
752     /// ```
753     /// use bstr::ByteVec;
754     ///
755     /// let mut s = Vec::from("foobar");
756     /// s.insert_char(3, '☃');
757     /// assert_eq!(s, "foo☃bar".as_bytes());
758     /// ```
759     #[inline]
insert_char(&mut self, at: usize, ch: char)760     fn insert_char(&mut self, at: usize, ch: char) {
761         self.insert_str(at, ch.encode_utf8(&mut [0; 4]).as_bytes());
762     }
763 
764     /// Inserts the given byte string into this byte string at a particular
765     /// byte position.
766     ///
767     /// This is an `O(n)` operation as it may copy a number of elements in this
768     /// byte string proportional to its length.
769     ///
770     /// The given byte string may be any type that can be cheaply converted
771     /// into a `&[u8]`. This includes, but is not limited to, `&str` and
772     /// `&[u8]`.
773     ///
774     /// # Panics
775     ///
776     /// Panics if `at` is larger than the byte string's length.
777     ///
778     /// # Examples
779     ///
780     /// Basic usage:
781     ///
782     /// ```
783     /// use bstr::ByteVec;
784     ///
785     /// let mut s = Vec::from("foobar");
786     /// s.insert_str(3, "☃☃☃");
787     /// assert_eq!(s, "foo☃☃☃bar".as_bytes());
788     /// ```
789     #[inline]
insert_str<B: AsRef<[u8]>>(&mut self, at: usize, bytes: B)790     fn insert_str<B: AsRef<[u8]>>(&mut self, at: usize, bytes: B) {
791         let bytes = bytes.as_ref();
792         let len = self.as_vec().len();
793         assert!(at <= len, "expected {} to be <= {}", at, len);
794 
795         // SAFETY: We'd like to efficiently splice in the given bytes into
796         // this byte string. Since we are only working with `u8` elements here,
797         // we only need to consider whether our bounds are correct and whether
798         // our byte string has enough space.
799         self.as_vec_mut().reserve(bytes.len());
800         unsafe {
801             // Shift bytes after `at` over by the length of `bytes` to make
802             // room for it. This requires referencing two regions of memory
803             // that may overlap, so we use ptr::copy.
804             ptr::copy(
805                 self.as_vec().as_ptr().add(at),
806                 self.as_vec_mut().as_mut_ptr().add(at + bytes.len()),
807                 len - at,
808             );
809             // Now copy the bytes given into the room we made above. In this
810             // case, we know that the given bytes cannot possibly overlap
811             // with this byte string since we have a mutable borrow of the
812             // latter. Thus, we can use a nonoverlapping copy.
813             ptr::copy_nonoverlapping(
814                 bytes.as_ptr(),
815                 self.as_vec_mut().as_mut_ptr().add(at),
816                 bytes.len(),
817             );
818             self.as_vec_mut().set_len(len + bytes.len());
819         }
820     }
821 
822     /// Removes the specified range in this byte string and replaces it with
823     /// the given bytes. The given bytes do not need to have the same length
824     /// as the range provided.
825     ///
826     /// # Panics
827     ///
828     /// Panics if the given range is invalid.
829     ///
830     /// # Examples
831     ///
832     /// Basic usage:
833     ///
834     /// ```
835     /// use bstr::ByteVec;
836     ///
837     /// let mut s = Vec::from("foobar");
838     /// s.replace_range(2..4, "xxxxx");
839     /// assert_eq!(s, "foxxxxxar".as_bytes());
840     /// ```
841     #[inline]
replace_range<R, B>(&mut self, range: R, replace_with: B) where R: ops::RangeBounds<usize>, B: AsRef<[u8]>,842     fn replace_range<R, B>(&mut self, range: R, replace_with: B)
843     where
844         R: ops::RangeBounds<usize>,
845         B: AsRef<[u8]>,
846     {
847         self.as_vec_mut().splice(range, replace_with.as_ref().iter().cloned());
848     }
849 
850     /// Creates a draining iterator that removes the specified range in this
851     /// `Vec<u8>` and yields each of the removed bytes.
852     ///
853     /// Note that the elements specified by the given range are removed
854     /// regardless of whether the returned iterator is fully exhausted.
855     ///
856     /// Also note that is is unspecified how many bytes are removed from the
857     /// `Vec<u8>` if the `DrainBytes` iterator is leaked.
858     ///
859     /// # Panics
860     ///
861     /// Panics if the given range is not valid.
862     ///
863     /// # Examples
864     ///
865     /// Basic usage:
866     ///
867     /// ```
868     /// use bstr::ByteVec;
869     ///
870     /// let mut s = Vec::from("foobar");
871     /// {
872     ///     let mut drainer = s.drain_bytes(2..4);
873     ///     assert_eq!(drainer.next(), Some(b'o'));
874     ///     assert_eq!(drainer.next(), Some(b'b'));
875     ///     assert_eq!(drainer.next(), None);
876     /// }
877     /// assert_eq!(s, "foar".as_bytes());
878     /// ```
879     #[inline]
drain_bytes<R>(&mut self, range: R) -> DrainBytes where R: ops::RangeBounds<usize>,880     fn drain_bytes<R>(&mut self, range: R) -> DrainBytes
881     where
882         R: ops::RangeBounds<usize>,
883     {
884         DrainBytes { it: self.as_vec_mut().drain(range) }
885     }
886 }
887 
888 /// A draining byte oriented iterator for `Vec<u8>`.
889 ///
890 /// This iterator is created by
891 /// [`ByteVec::drain_bytes`](trait.ByteVec.html#method.drain_bytes).
892 ///
893 /// # Examples
894 ///
895 /// Basic usage:
896 ///
897 /// ```
898 /// use bstr::ByteVec;
899 ///
900 /// let mut s = Vec::from("foobar");
901 /// {
902 ///     let mut drainer = s.drain_bytes(2..4);
903 ///     assert_eq!(drainer.next(), Some(b'o'));
904 ///     assert_eq!(drainer.next(), Some(b'b'));
905 ///     assert_eq!(drainer.next(), None);
906 /// }
907 /// assert_eq!(s, "foar".as_bytes());
908 /// ```
909 #[derive(Debug)]
910 pub struct DrainBytes<'a> {
911     it: vec::Drain<'a, u8>,
912 }
913 
914 impl<'a> iter::FusedIterator for DrainBytes<'a> {}
915 
916 impl<'a> Iterator for DrainBytes<'a> {
917     type Item = u8;
918 
919     #[inline]
next(&mut self) -> Option<u8>920     fn next(&mut self) -> Option<u8> {
921         self.it.next()
922     }
923 }
924 
925 impl<'a> DoubleEndedIterator for DrainBytes<'a> {
926     #[inline]
next_back(&mut self) -> Option<u8>927     fn next_back(&mut self) -> Option<u8> {
928         self.it.next_back()
929     }
930 }
931 
932 impl<'a> ExactSizeIterator for DrainBytes<'a> {
933     #[inline]
len(&self) -> usize934     fn len(&self) -> usize {
935         self.it.len()
936     }
937 }
938 
939 /// An error that may occur when converting a `Vec<u8>` to a `String`.
940 ///
941 /// This error includes the original `Vec<u8>` that failed to convert to a
942 /// `String`. This permits callers to recover the allocation used even if it
943 /// it not valid UTF-8.
944 ///
945 /// # Examples
946 ///
947 /// Basic usage:
948 ///
949 /// ```
950 /// use bstr::{B, ByteVec};
951 ///
952 /// let bytes = Vec::from_slice(b"foo\xFFbar");
953 /// let err = bytes.into_string().unwrap_err();
954 ///
955 /// assert_eq!(err.utf8_error().valid_up_to(), 3);
956 /// assert_eq!(err.utf8_error().error_len(), Some(1));
957 ///
958 /// // At no point in this example is an allocation performed.
959 /// let bytes = Vec::from(err.into_vec());
960 /// assert_eq!(bytes, B(b"foo\xFFbar"));
961 /// ```
962 #[derive(Debug, Eq, PartialEq)]
963 pub struct FromUtf8Error {
964     original: Vec<u8>,
965     err: Utf8Error,
966 }
967 
968 impl FromUtf8Error {
969     /// Return the original bytes as a slice that failed to convert to a
970     /// `String`.
971     ///
972     /// # Examples
973     ///
974     /// Basic usage:
975     ///
976     /// ```
977     /// use bstr::{B, ByteVec};
978     ///
979     /// let bytes = Vec::from_slice(b"foo\xFFbar");
980     /// let err = bytes.into_string().unwrap_err();
981     ///
982     /// // At no point in this example is an allocation performed.
983     /// assert_eq!(err.as_bytes(), B(b"foo\xFFbar"));
984     /// ```
985     #[inline]
as_bytes(&self) -> &[u8]986     pub fn as_bytes(&self) -> &[u8] {
987         &self.original
988     }
989 
990     /// Consume this error and return the original byte string that failed to
991     /// convert to a `String`.
992     ///
993     /// # Examples
994     ///
995     /// Basic usage:
996     ///
997     /// ```
998     /// use bstr::{B, ByteVec};
999     ///
1000     /// let bytes = Vec::from_slice(b"foo\xFFbar");
1001     /// let err = bytes.into_string().unwrap_err();
1002     /// let original = err.into_vec();
1003     ///
1004     /// // At no point in this example is an allocation performed.
1005     /// assert_eq!(original, B(b"foo\xFFbar"));
1006     /// ```
1007     #[inline]
into_vec(self) -> Vec<u8>1008     pub fn into_vec(self) -> Vec<u8> {
1009         self.original
1010     }
1011 
1012     /// Return the underlying UTF-8 error that occurred. This error provides
1013     /// information on the nature and location of the invalid UTF-8 detected.
1014     ///
1015     /// # Examples
1016     ///
1017     /// Basic usage:
1018     ///
1019     /// ```
1020     /// use bstr::{B, ByteVec};
1021     ///
1022     /// let bytes = Vec::from_slice(b"foo\xFFbar");
1023     /// let err = bytes.into_string().unwrap_err();
1024     ///
1025     /// assert_eq!(err.utf8_error().valid_up_to(), 3);
1026     /// assert_eq!(err.utf8_error().error_len(), Some(1));
1027     /// ```
1028     #[inline]
utf8_error(&self) -> &Utf8Error1029     pub fn utf8_error(&self) -> &Utf8Error {
1030         &self.err
1031     }
1032 }
1033 
1034 impl error::Error for FromUtf8Error {
1035     #[inline]
description(&self) -> &str1036     fn description(&self) -> &str {
1037         "invalid UTF-8 vector"
1038     }
1039 }
1040 
1041 impl fmt::Display for FromUtf8Error {
1042     #[inline]
fmt(&self, f: &mut fmt::Formatter) -> fmt::Result1043     fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1044         write!(f, "{}", self.err)
1045     }
1046 }
1047 
1048 #[cfg(test)]
1049 mod tests {
1050     use ext_slice::B;
1051     use ext_vec::ByteVec;
1052 
1053     #[test]
insert()1054     fn insert() {
1055         let mut s = vec![];
1056         s.insert_str(0, "foo");
1057         assert_eq!(s, "foo".as_bytes());
1058 
1059         let mut s = Vec::from("a");
1060         s.insert_str(0, "foo");
1061         assert_eq!(s, "fooa".as_bytes());
1062 
1063         let mut s = Vec::from("a");
1064         s.insert_str(1, "foo");
1065         assert_eq!(s, "afoo".as_bytes());
1066 
1067         let mut s = Vec::from("foobar");
1068         s.insert_str(3, "quux");
1069         assert_eq!(s, "fooquuxbar".as_bytes());
1070 
1071         let mut s = Vec::from("foobar");
1072         s.insert_str(3, "x");
1073         assert_eq!(s, "fooxbar".as_bytes());
1074 
1075         let mut s = Vec::from("foobar");
1076         s.insert_str(0, "x");
1077         assert_eq!(s, "xfoobar".as_bytes());
1078 
1079         let mut s = Vec::from("foobar");
1080         s.insert_str(6, "x");
1081         assert_eq!(s, "foobarx".as_bytes());
1082 
1083         let mut s = Vec::from("foobar");
1084         s.insert_str(3, "quuxbazquux");
1085         assert_eq!(s, "fooquuxbazquuxbar".as_bytes());
1086     }
1087 
1088     #[test]
1089     #[should_panic]
insert_fail1()1090     fn insert_fail1() {
1091         let mut s = vec![];
1092         s.insert_str(1, "foo");
1093     }
1094 
1095     #[test]
1096     #[should_panic]
insert_fail2()1097     fn insert_fail2() {
1098         let mut s = Vec::from("a");
1099         s.insert_str(2, "foo");
1100     }
1101 
1102     #[test]
1103     #[should_panic]
insert_fail3()1104     fn insert_fail3() {
1105         let mut s = Vec::from("foobar");
1106         s.insert_str(7, "foo");
1107     }
1108 }
1109