diff --git a/src/liballoc/collections/vec_deque.rs b/src/liballoc/collections/vec_deque.rs index 9d56f17700a85..78b3ad3b83873 100644 --- a/src/liballoc/collections/vec_deque.rs +++ b/src/liballoc/collections/vec_deque.rs @@ -959,6 +959,9 @@ impl VecDeque { /// Returns a pair of slices which contain, in order, the contents of the /// `VecDeque`. /// + /// If [`make_contiguous`](#method.make_contiguous) was previously called, all elements + /// of the `VecDeque` will be in the first slice and the second slice will be empty. + /// /// # Examples /// /// ``` @@ -989,6 +992,9 @@ impl VecDeque { /// Returns a pair of slices which contain, in order, the contents of the /// `VecDeque`. /// + /// If [`make_contiguous`](#method.make_contiguous) was previously called, all elements + /// of the `VecDeque` will be in the first slice and the second slice will be empty. + /// /// # Examples /// /// ``` @@ -2043,6 +2049,148 @@ impl VecDeque { } } + /// Rearranges the internal storage of this deque so it is one contiguous slice, which is then returned. + /// + /// This method does not allocate and does not change the order of the inserted elements. + /// As it returns a mutable slice, this can be used to sort or binary search a deque. + /// + /// Once the internal storage is contiguous, the [`as_slices`](#method.as_slices) and + /// [`as_mut_slices`](#method.as_mut_slices) methods will return the entire contents of the + /// `VecDeque` in a single slice. + /// + /// # Examples + /// + /// Sorting the content of a deque. + /// + /// ``` + /// #![feature(deque_make_contiguous)] + /// + /// use std::collections::VecDeque; + /// + /// let mut buf = VecDeque::with_capacity(15); + /// + /// buf.push_back(2); + /// buf.push_back(1); + /// buf.push_front(3); + /// + /// // sorting the deque + /// buf.make_contiguous().sort(); + /// assert_eq!(buf.as_slices(), (&[1, 2, 3] as &[_], &[] as &[_])); + /// + /// // sorting it in reverse order + /// buf.make_contiguous().sort_by(|a, b| b.cmp(a)); + /// assert_eq!(buf.as_slices(), (&[3, 2, 1] as &[_], &[] as &[_])); + /// ``` + /// + /// Getting immutable access to the contiguous slice. + /// + /// ```rust + /// #![feature(deque_make_contiguous)] + /// + /// use std::collections::VecDeque; + /// + /// let mut buf = VecDeque::new(); + /// + /// buf.push_back(2); + /// buf.push_back(1); + /// buf.push_front(3); + /// + /// buf.make_contiguous(); + /// if let (slice, &[]) = buf.as_slices() { + /// // we can now be sure that `slice` contains all elements of the deque, + /// // while still having immutable access to `buf`. + /// assert_eq!(buf.len(), slice.len()); + /// assert_eq!(slice, &[3, 2, 1] as &[_]); + /// } + /// ``` + #[unstable(feature = "deque_make_contiguous", issue = "none")] + pub fn make_contiguous(&mut self) -> &mut [T] { + if self.is_contiguous() { + let tail = self.tail; + let head = self.head; + return unsafe { &mut self.buffer_as_mut_slice()[tail..head] }; + } + + let buf = self.buf.ptr(); + let cap = self.cap(); + let len = self.len(); + + let free = self.tail - self.head; + let tail_len = cap - self.tail; + + if free >= tail_len { + // there is enough free space to copy the tail in one go, + // this means that we first shift the head backwards, and then + // copy the tail to the correct position. + // + // from: DEFGH....ABC + // to: ABCDEFGH.... + unsafe { + ptr::copy(buf, buf.add(tail_len), self.head); + // ...DEFGH.ABC + ptr::copy_nonoverlapping(buf.add(self.tail), buf, tail_len); + // ABCDEFGH.... + + self.tail = 0; + self.head = len; + } + } else if free >= self.head { + // there is enough free space to copy the head in one go, + // this means that we first shift the tail forwards, and then + // copy the head to the correct position. + // + // from: FGH....ABCDE + // to: ...ABCDEFGH. + unsafe { + ptr::copy(buf.add(self.tail), buf.add(self.head), tail_len); + // FGHABCDE.... + ptr::copy_nonoverlapping(buf, buf.add(self.head + tail_len), self.head); + // ...ABCDEFGH. + + self.tail = self.head; + self.head = self.tail + len; + } + } else { + // free is smaller than both head and tail, + // this means we have to slowly "swap" the tail and the head. + // + // from: EFGHI...ABCD or HIJK.ABCDEFG + // to: ABCDEFGHI... or ABCDEFGHIJK. + let mut left_edge: usize = 0; + let mut right_edge: usize = self.tail; + unsafe { + // The general problem looks like this + // GHIJKLM...ABCDEF - before any swaps + // ABCDEFM...GHIJKL - after 1 pass of swaps + // ABCDEFGHIJM...KL - swap until the left edge reaches the temp store + // - then restart the algorithm with a new (smaller) store + // Sometimes the temp store is reached when the right edge is at the end + // of the buffer - this means we've hit the right order with fewer swaps! + // E.g + // EF..ABCD + // ABCDEF.. - after four only swaps we've finished + while left_edge < len && right_edge != cap { + let mut right_offset = 0; + for i in left_edge..right_edge { + right_offset = (i - left_edge) % (cap - right_edge); + let src: isize = (right_edge + right_offset) as isize; + ptr::swap(buf.add(i), buf.offset(src)); + } + let n_ops = right_edge - left_edge; + left_edge += n_ops; + right_edge += right_offset + 1; + } + + self.tail = 0; + self.head = len; + } + } + + let tail = self.tail; + let head = self.head; + unsafe { &mut self.buffer_as_mut_slice()[tail..head] } + } + /// Rotates the double-ended queue `mid` places to the left. /// /// Equivalently, @@ -2802,63 +2950,16 @@ impl From> for Vec { /// assert_eq!(vec, [8, 9, 1, 2, 3, 4]); /// assert_eq!(vec.as_ptr(), ptr); /// ``` - fn from(other: VecDeque) -> Self { + fn from(mut other: VecDeque) -> Self { + other.make_contiguous(); + unsafe { let buf = other.buf.ptr(); let len = other.len(); - let tail = other.tail; - let head = other.head; let cap = other.cap(); - // Need to move the ring to the front of the buffer, as vec will expect this. - if other.is_contiguous() { - ptr::copy(buf.add(tail), buf, len); - } else { - if (tail - head) >= cmp::min(cap - tail, head) { - // There is enough free space in the centre for the shortest block so we can - // do this in at most three copy moves. - if (cap - tail) > head { - // right hand block is the long one; move that enough for the left - ptr::copy(buf.add(tail), buf.add(tail - head), cap - tail); - // copy left in the end - ptr::copy(buf, buf.add(cap - head), head); - // shift the new thing to the start - ptr::copy(buf.add(tail - head), buf, len); - } else { - // left hand block is the long one, we can do it in two! - ptr::copy(buf, buf.add(cap - tail), head); - ptr::copy(buf.add(tail), buf, cap - tail); - } - } else { - // Need to use N swaps to move the ring - // We can use the space at the end of the ring as a temp store - - let mut left_edge: usize = 0; - let mut right_edge: usize = tail; - - // The general problem looks like this - // GHIJKLM...ABCDEF - before any swaps - // ABCDEFM...GHIJKL - after 1 pass of swaps - // ABCDEFGHIJM...KL - swap until the left edge reaches the temp store - // - then restart the algorithm with a new (smaller) store - // Sometimes the temp store is reached when the right edge is at the end - // of the buffer - this means we've hit the right order with fewer swaps! - // E.g - // EF..ABCD - // ABCDEF.. - after four only swaps we've finished - - while left_edge < len && right_edge != cap { - let mut right_offset = 0; - for i in left_edge..right_edge { - right_offset = (i - left_edge) % (cap - right_edge); - let src: isize = (right_edge + right_offset) as isize; - ptr::swap(buf.add(i), buf.offset(src)); - } - let n_ops = right_edge - left_edge; - left_edge += n_ops; - right_edge += right_offset + 1; - } - } + if other.head != 0 { + ptr::copy(buf.add(other.tail), buf, len); } let out = Vec::from_raw_parts(buf, len, cap); mem::forget(other); diff --git a/src/liballoc/collections/vec_deque/tests.rs b/src/liballoc/collections/vec_deque/tests.rs index f2ce5b1d15dde..8ef5ec78e056e 100644 --- a/src/liballoc/collections/vec_deque/tests.rs +++ b/src/liballoc/collections/vec_deque/tests.rs @@ -1,6 +1,6 @@ use super::*; -use ::test; +use test; #[bench] #[cfg_attr(miri, ignore)] // Miri does not support benchmarks @@ -130,6 +130,87 @@ fn test_insert() { } } +#[test] +fn make_contiguous_big_tail() { + let mut tester = VecDeque::with_capacity(15); + + for i in 0..3 { + tester.push_back(i); + } + + for i in 3..10 { + tester.push_front(i); + } + + // 012......9876543 + assert_eq!(tester.capacity(), 15); + assert_eq!((&[9, 8, 7, 6, 5, 4, 3] as &[_], &[0, 1, 2] as &[_]), tester.as_slices()); + + let expected_start = tester.head; + tester.make_contiguous(); + assert_eq!(tester.tail, expected_start); + assert_eq!((&[9, 8, 7, 6, 5, 4, 3, 0, 1, 2] as &[_], &[] as &[_]), tester.as_slices()); +} + +#[test] +fn make_contiguous_big_head() { + let mut tester = VecDeque::with_capacity(15); + + for i in 0..8 { + tester.push_back(i); + } + + for i in 8..10 { + tester.push_front(i); + } + + // 01234567......98 + let expected_start = 0; + tester.make_contiguous(); + assert_eq!(tester.tail, expected_start); + assert_eq!((&[9, 8, 0, 1, 2, 3, 4, 5, 6, 7] as &[_], &[] as &[_]), tester.as_slices()); +} + +#[test] +fn make_contiguous_small_free() { + let mut tester = VecDeque::with_capacity(15); + + for i in 'A' as u8..'I' as u8 { + tester.push_back(i as char); + } + + for i in 'I' as u8..'N' as u8 { + tester.push_front(i as char); + } + + // ABCDEFGH...MLKJI + let expected_start = 0; + tester.make_contiguous(); + assert_eq!(tester.tail, expected_start); + assert_eq!( + (&['M', 'L', 'K', 'J', 'I', 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'] as &[_], &[] as &[_]), + tester.as_slices() + ); + + tester.clear(); + for i in 'I' as u8..'N' as u8 { + tester.push_back(i as char); + } + + for i in 'A' as u8..'I' as u8 { + tester.push_front(i as char); + } + + // IJKLM...HGFEDCBA + let expected_start = 0; + tester.make_contiguous(); + assert_eq!(tester.tail, expected_start); + assert_eq!( + (&['H', 'G', 'F', 'E', 'D', 'C', 'B', 'A', 'I', 'J', 'K', 'L', 'M'] as &[_], &[] as &[_]), + tester.as_slices() + ); +} + #[test] fn test_remove() { // This test checks that every single combination of tail position, length, and