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#![allow(unused_variables)] #![allow(missing_docs)] use super::*; /// A slice-backed vector-like data structure. /// /// This is a very similar concept to `ArrayVec`, but instead /// of the backing memory being an owned array, the backing /// memory is a unique-borrowed slice. You can thus create /// one of these structures "around" some slice that you're /// working with to make it easier to manipulate. /// /// * Has a fixed capacity (the initial slice size). /// * Has a variable length. pub struct SliceVec<'s, T> { data: &'s mut [T], len: usize, } impl<'s, T> Default for SliceVec<'s, T> { #[inline(always)] #[must_use] fn default() -> Self { Self { data: &mut [], len: 0 } } } impl<'s, T> Deref for SliceVec<'s, T> { type Target = [T]; #[inline(always)] #[must_use] fn deref(&self) -> &Self::Target { &self.data[..self.len] } } impl<'s, T> DerefMut for SliceVec<'s, T> { #[inline(always)] #[must_use] fn deref_mut(&mut self) -> &mut Self::Target { &mut self.data[..self.len] } } impl<'s, T, I> Index<I> for SliceVec<'s, T> where I: SliceIndex<[T]>, { type Output = <I as SliceIndex<[T]>>::Output; #[inline(always)] #[must_use] fn index(&self, index: I) -> &Self::Output { &self.deref()[index] } } impl<'s, T, I> IndexMut<I> for SliceVec<'s, T> where I: SliceIndex<[T]>, { #[inline(always)] #[must_use] fn index_mut(&mut self, index: I) -> &mut Self::Output { &mut self.deref_mut()[index] } } impl<'s, T> SliceVec<'s, T> { #[inline] pub fn append(&mut self, other: &mut Self) where T: Default, { for item in other.drain(..) { self.push(item) } } /// A `*mut` pointer to the backing slice. /// /// ## Safety /// /// This pointer has provenance over the _entire_ backing slice. #[inline(always)] #[must_use] pub fn as_mut_ptr(&mut self) -> *mut T { self.data.as_mut_ptr() } /// Performs a `deref_mut`, into unique slice form. #[inline(always)] #[must_use] pub fn as_mut_slice(&mut self) -> &mut [T] { self.deref_mut() } /// A `*const` pointer to the backing slice. /// /// ## Safety /// /// This pointer has provenance over the _entire_ backing slice. #[inline(always)] #[must_use] pub fn as_ptr(&self) -> *const T { self.data.as_ptr() } /// Performs a `deref`, into shared slice form. #[inline(always)] #[must_use] pub fn as_slice(&self) -> &[T] { self.deref() } /// The capacity of the `SliceVec`. /// /// This the length of the initial backing slice. #[inline(always)] #[must_use] pub fn capacity(&self) -> usize { self.data.len() } /// Truncates the `SliceVec` down to length 0. #[inline(always)] pub fn clear(&mut self) where T: Default, { self.truncate(0) } /// Creates a draining iterator that removes the specified range in the vector /// and yields the removed items. /// /// ## Panics /// * If the start is greater than the end /// * If the end is past the edge of the vec. /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [6, 7, 8]; /// let mut sv = SliceVec::from(&mut arr); /// let drained_values: ArrayVec<[i32; 4]> = sv.drain(1..).collect(); /// assert_eq!(sv.as_slice(), &[6][..]); /// assert_eq!(drained_values.as_slice(), &[7, 8][..]); /// /// sv.drain(..); /// assert_eq!(sv.as_slice(), &[]); /// ``` #[inline] pub fn drain<'p, R: RangeBounds<usize>>( &'p mut self, range: R, ) -> SliceVecDrain<'p, 's, T> where T: Default, { use core::ops::Bound; let start = match range.start_bound() { Bound::Included(x) => *x, Bound::Excluded(x) => x.saturating_add(1), Bound::Unbounded => 0, }; let end = match range.end_bound() { Bound::Included(x) => x.saturating_add(1), Bound::Excluded(x) => *x, Bound::Unbounded => self.len, }; assert!( start <= end, "SliceVec::drain> Illegal range, {} to {}", start, end ); assert!( end <= self.len, "SliceVec::drain> Range ends at {} but length is only {}!", end, self.len ); SliceVecDrain { parent: self, target_start: start, target_index: start, target_end: end, } } #[inline] pub fn extend_from_slice(&mut self, sli: &[T]) where T: Clone, { if sli.is_empty() { return; } let new_len = self.len + sli.len(); if new_len > self.capacity() { panic!( "SliceVec::extend_from_slice> total length {} exceeds capacity {}", new_len, self.capacity() ) } let target = &mut self.data[self.len..new_len]; target.clone_from_slice(sli); self.set_len(new_len); } /// Fill the vector until its capacity has been reached. /// /// Successively fills unused space in the spare slice of the vector with /// elements from the iterator. It then returns the remaining iterator /// without exhausting it. This also allows appending the head of an /// infinite iterator. /// /// This is an alternative to `Extend::extend` method for cases where the /// length of the iterator can not be checked. Since this vector can not /// reallocate to increase its capacity, it is unclear what to do with /// remaining elements in the iterator and the iterator itself. The /// interface also provides no way to communicate this to the caller. /// /// ## Panics /// * If the `next` method of the provided iterator panics. /// /// ## Example /// /// ```rust /// # use tinyvec::*; /// let mut arr = [7, 7, 7, 7]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 0); /// let mut to_inf = sv.fill(0..); /// assert_eq!(&sv[..], [0, 1, 2, 3]); /// assert_eq!(to_inf.next(), Some(4)); /// ``` #[inline] pub fn fill<I: IntoIterator<Item = T>>(&mut self, iter: I) -> I::IntoIter { let mut iter = iter.into_iter(); for element in iter.by_ref().take(self.capacity() - self.len()) { self.push(element); } iter } /// Wraps up a slice and uses the given length as the initial length. /// /// If you want to simply use the full slice, use `from` instead. /// /// ## Panics /// /// * The length specified must be less than or equal to the capacity of the /// slice. #[inline] #[must_use] #[allow(clippy::match_wild_err_arm)] pub fn from_slice_len(data: &'s mut [T], len: usize) -> Self { assert!(len <= data.len()); Self { data, len } } /// Inserts an item at the position given, moving all following elements +1 /// index. /// /// ## Panics /// * If `index` > `len` /// * If the capacity is exhausted /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [1, 2, 3, 0, 0]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 3); /// sv.insert(1, 4); /// assert_eq!(sv.as_slice(), &[1, 4, 2, 3]); /// sv.insert(4, 5); /// assert_eq!(sv.as_slice(), &[1, 4, 2, 3, 5]); /// ``` #[inline] pub fn insert(&mut self, index: usize, item: T) { if index > self.len { panic!("SliceVec::insert> index {} is out of bounds {}", index, self.len); } // Try to push the element. self.push(item); // And move it into its place. self.as_mut_slice()[index..].rotate_right(1); } /// Checks if the length is 0. #[inline(always)] #[must_use] pub fn is_empty(&self) -> bool { self.len == 0 } /// The length of the `SliceVec` (in elements). #[inline(always)] #[must_use] pub fn len(&self) -> usize { self.len } /// Remove and return the last element of the vec, if there is one. /// /// ## Failure /// * If the vec is empty you get `None`. /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [1, 2]; /// let mut sv = SliceVec::from(&mut arr); /// assert_eq!(sv.pop(), Some(2)); /// assert_eq!(sv.pop(), Some(1)); /// assert_eq!(sv.pop(), None); /// ``` #[inline] pub fn pop(&mut self) -> Option<T> where T: Default, { if self.len > 0 { self.len -= 1; let out = take(&mut self.data[self.len]); Some(out) } else { None } } /// Place an element onto the end of the vec. /// /// ## Panics /// * If the length of the vec would overflow the capacity. /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [0, 0]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 0); /// assert_eq!(&sv[..], []); /// sv.push(1); /// assert_eq!(&sv[..], [1]); /// sv.push(2); /// assert_eq!(&sv[..], [1, 2]); /// // sv.push(3); this would overflow the ArrayVec and panic! /// ``` #[inline(always)] pub fn push(&mut self, val: T) { if self.len < self.capacity() { self.data[self.len] = val; self.len += 1; } else { panic!("SliceVec::push> capacity overflow") } } /// Removes the item at `index`, shifting all others down by one index. /// /// Returns the removed element. /// /// ## Panics /// /// * If the index is out of bounds. /// /// ## Example /// /// ```rust /// # use tinyvec::*; /// let mut arr = [1, 2, 3]; /// let mut sv = SliceVec::from(&mut arr); /// assert_eq!(sv.remove(1), 2); /// assert_eq!(&sv[..], [1, 3]); /// ``` #[inline] pub fn remove(&mut self, index: usize) -> T where T: Default, { let targets: &mut [T] = &mut self.deref_mut()[index..]; let item = take(&mut targets[0]); targets.rotate_left(1); self.len -= 1; item } /// As [`resize_with`](SliceVec::resize_with) /// and it clones the value as the closure. /// /// ## Example /// /// ```rust /// # use tinyvec::*; /// // bigger /// let mut arr = ["hello", "", "", "", ""]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 1); /// sv.resize(3, "world"); /// assert_eq!(&sv[..], ["hello", "world", "world"]); /// /// // smaller /// let mut arr = ['a', 'b', 'c', 'd']; /// let mut sv = SliceVec::from(&mut arr); /// sv.resize(2, 'z'); /// assert_eq!(&sv[..], ['a', 'b']); /// ``` #[inline] pub fn resize(&mut self, new_len: usize, new_val: T) where T: Clone, { self.resize_with(new_len, || new_val.clone()) } /// Resize the vec to the new length. /// /// * If it needs to be longer, it's filled with repeated calls to the /// provided function. /// * If it needs to be shorter, it's truncated. /// * If the type needs to drop the truncated slots are filled with calls to /// the provided function. /// /// ## Example /// /// ```rust /// # use tinyvec::*; /// let mut arr = [1, 2, 3, 7, 7, 7, 7]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 3); /// sv.resize_with(5, Default::default); /// assert_eq!(&sv[..], [1, 2, 3, 0, 0]); /// /// let mut arr = [0, 0, 0, 0]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 0); /// let mut p = 1; /// sv.resize_with(4, || { /// p *= 2; /// p /// }); /// assert_eq!(&sv[..], [2, 4, 8, 16]); /// ``` #[inline] pub fn resize_with<F: FnMut() -> T>(&mut self, new_len: usize, mut f: F) { match new_len.checked_sub(self.len) { None => { if needs_drop::<T>() { while self.len() > new_len { self.len -= 1; self.data[self.len] = f(); } } else { self.len = new_len; } } Some(new_elements) => { for _ in 0..new_elements { self.push(f()); } } } } /// Walk the vec and keep only the elements that pass the predicate given. /// /// ## Example /// /// ```rust /// # use tinyvec::*; /// /// let mut arr = [1, 1, 2, 3, 3, 4]; /// let mut sv = SliceVec::from(&mut arr); /// sv.retain(|&x| x % 2 == 0); /// assert_eq!(&sv[..], [2, 4]); /// ``` #[inline] pub fn retain<F: FnMut(&T) -> bool>(&mut self, mut acceptable: F) where T: Default, { // Drop guard to contain exactly the remaining elements when the test // panics. struct JoinOnDrop<'vec, Item> { items: &'vec mut [Item], done_end: usize, // Start of tail relative to `done_end`. tail_start: usize, } impl<Item> Drop for JoinOnDrop<'_, Item> { fn drop(&mut self) { self.items[self.done_end..].rotate_left(self.tail_start); } } let mut rest = JoinOnDrop { items: self.data, done_end: 0, tail_start: 0 }; for idx in 0..self.len { // Loop start invariant: idx = rest.done_end + rest.tail_start if !acceptable(&rest.items[idx]) { let _ = take(&mut rest.items[idx]); self.len -= 1; rest.tail_start += 1; } else { rest.items.swap(rest.done_end, idx); rest.done_end += 1; } } } /// Forces the length of the vector to `new_len`. /// /// ## Panics /// * If `new_len` is greater than the vec's capacity. /// /// ## Safety /// * This is a fully safe operation! The inactive memory already counts as /// "initialized" by Rust's rules. /// * Other than "the memory is initialized" there are no other guarantees /// regarding what you find in the inactive portion of the vec. #[inline(always)] pub fn set_len(&mut self, new_len: usize) { if new_len > self.capacity() { // Note(Lokathor): Technically we don't have to panic here, and we could // just let some other call later on trigger a panic on accident when the // length is wrong. However, it's a lot easier to catch bugs when things // are more "fail-fast". panic!( "SliceVec::set_len> new length {} exceeds capacity {}", new_len, self.capacity() ) } else { self.len = new_len; } } /// Splits the collection at the point given. /// /// * `[0, at)` stays in this vec (and this vec is now full). /// * `[at, len)` ends up in the new vec (with any spare capacity). /// /// ## Panics /// * if `at` > `self.len()` /// /// ## Example /// /// ```rust /// # use tinyvec::*; /// let mut arr = [1, 2, 3]; /// let mut sv = SliceVec::from(&mut arr); /// let sv2 = sv.split_off(1); /// assert_eq!(&sv[..], [1]); /// assert_eq!(&sv2[..], [2, 3]); /// ``` #[inline] pub fn split_off<'a>(&'a mut self, at: usize) -> SliceVec<'s, T> { let mut new = Self::default(); let backing: &'s mut [T] = replace(&mut self.data, &mut []); let (me, other) = backing.split_at_mut(at); new.len = self.len - at; new.data = other; self.len = me.len(); self.data = me; new } /// Remove an element, swapping the end of the vec into its place. /// /// ## Panics /// * If the index is out of bounds. /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = ["foo", "bar", "quack", "zap"]; /// let mut sv = SliceVec::from(&mut arr); /// /// assert_eq!(sv.swap_remove(1), "bar"); /// assert_eq!(&sv[..], ["foo", "zap", "quack"]); /// /// assert_eq!(sv.swap_remove(0), "foo"); /// assert_eq!(&sv[..], ["quack", "zap"]); /// ``` #[inline] pub fn swap_remove(&mut self, index: usize) -> T where T: Default, { assert!( index < self.len, "SliceVec::swap_remove> index {} is out of bounds {}", index, self.len ); if index == self.len - 1 { self.pop().unwrap() } else { let i = self.pop().unwrap(); replace(&mut self[index], i) } } /// Reduces the vec's length to the given value. /// /// If the vec is already shorter than the input, nothing happens. #[inline] pub fn truncate(&mut self, new_len: usize) where T: Default, { if needs_drop::<T>() { while self.len > new_len { self.pop(); } } else { self.len = self.len.min(new_len); } } /// Wraps a slice, using the given length as the starting length. /// /// If you want to use the whole length of the slice, you can just use the /// `From` impl. /// /// ## Failure /// /// If the given length is greater than the length of the slice you get /// `None`. #[inline] pub fn try_from_slice_len(data: &'s mut [T], len: usize) -> Option<Self> { if len <= data.len() { Some(Self { data, len }) } else { None } } } #[cfg(feature = "grab_spare_slice")] impl<'s, T> SliceVec<'s, T> { /// Obtain the shared slice of the array _after_ the active memory. /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [0; 4]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 0); /// assert_eq!(sv.grab_spare_slice().len(), 4); /// sv.push(10); /// sv.push(11); /// sv.push(12); /// sv.push(13); /// assert_eq!(sv.grab_spare_slice().len(), 0); /// ``` #[inline(always)] pub fn grab_spare_slice(&self) -> &[T] { &self.data[self.len..] } /// Obtain the mutable slice of the array _after_ the active memory. /// /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [0; 4]; /// let mut sv = SliceVec::from_slice_len(&mut arr, 0); /// assert_eq!(sv.grab_spare_slice_mut().len(), 4); /// sv.push(10); /// sv.push(11); /// assert_eq!(sv.grab_spare_slice_mut().len(), 2); /// ``` #[inline(always)] pub fn grab_spare_slice_mut(&mut self) -> &mut [T] { &mut self.data[self.len..] } } impl<'s, T> From<&'s mut [T]> for SliceVec<'s, T> { /// Uses the full slice as the initial length. /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [0_i32; 2]; /// let mut sv = SliceVec::from(&mut arr[..]); /// ``` fn from(data: &'s mut [T]) -> Self { let len = data.len(); Self { data, len } } } impl<'s, T, A> From<&'s mut A> for SliceVec<'s, T> where A: AsMut<[T]>, { /// Calls `AsRef::as_mut` then uses the full slice as the initial length. /// ## Example /// ```rust /// # use tinyvec::*; /// let mut arr = [0, 0]; /// let mut sv = SliceVec::from(&mut arr); /// ``` fn from(a: &'s mut A) -> Self { let data = a.as_mut(); let len = data.len(); Self { data, len } } } /// Draining iterator for [`SliceVec`] /// /// See [`SliceVec::drain`](SliceVec::drain) pub struct SliceVecDrain<'p, 's, T: Default> { parent: &'p mut SliceVec<'s, T>, target_start: usize, target_index: usize, target_end: usize, } impl<'p, 's, T: Default> Iterator for SliceVecDrain<'p, 's, T> { type Item = T; #[inline] fn next(&mut self) -> Option<Self::Item> { if self.target_index != self.target_end { let out = take(&mut self.parent[self.target_index]); self.target_index += 1; Some(out) } else { None } } } impl<'p, 's, T: Default> FusedIterator for SliceVecDrain<'p, 's, T> {} impl<'p, 's, T: Default> Drop for SliceVecDrain<'p, 's, T> { #[inline] fn drop(&mut self) { // Changed because it was moving `self`, it's also more clear and the std // does the same self.for_each(drop); // Implementation very similar to [`SliceVec::remove`](SliceVec::remove) let count = self.target_end - self.target_start; let targets: &mut [T] = &mut self.parent.deref_mut()[self.target_start..]; targets.rotate_left(count); self.parent.len -= count; } } impl<'s, T> AsMut<[T]> for SliceVec<'s, T> { #[inline(always)] #[must_use] fn as_mut(&mut self) -> &mut [T] { &mut *self } } impl<'s, T> AsRef<[T]> for SliceVec<'s, T> { #[inline(always)] #[must_use] fn as_ref(&self) -> &[T] { &*self } } impl<'s, T> Borrow<[T]> for SliceVec<'s, T> { #[inline(always)] #[must_use] fn borrow(&self) -> &[T] { &*self } } impl<'s, T> BorrowMut<[T]> for SliceVec<'s, T> { #[inline(always)] #[must_use] fn borrow_mut(&mut self) -> &mut [T] { &mut *self } } impl<'s, T> Extend<T> for SliceVec<'s, T> { #[inline] fn extend<I: IntoIterator<Item = T>>(&mut self, iter: I) { for t in iter { self.push(t) } } } impl<'s, T> IntoIterator for SliceVec<'s, T> { type Item = &'s mut T; type IntoIter = core::slice::IterMut<'s, T>; #[inline(always)] #[must_use] fn into_iter(self) -> Self::IntoIter { self.data.iter_mut() } } impl<'s, T> PartialEq for SliceVec<'s, T> where T: PartialEq, { #[inline] #[must_use] fn eq(&self, other: &Self) -> bool { self.as_slice().eq(other.as_slice()) } } impl<'s, T> Eq for SliceVec<'s, T> where T: Eq {} impl<'s, T> PartialOrd for SliceVec<'s, T> where T: PartialOrd, { #[inline] #[must_use] fn partial_cmp(&self, other: &Self) -> Option<core::cmp::Ordering> { self.as_slice().partial_cmp(other.as_slice()) } } impl<'s, T> Ord for SliceVec<'s, T> where T: Ord, { #[inline] #[must_use] fn cmp(&self, other: &Self) -> core::cmp::Ordering { self.as_slice().cmp(other.as_slice()) } } impl<'s, T> PartialEq<&[T]> for SliceVec<'s, T> where T: PartialEq, { #[inline] #[must_use] fn eq(&self, other: &&[T]) -> bool { self.as_slice().eq(*other) } } impl<'s, T> Hash for SliceVec<'s, T> where T: Hash, { #[inline] fn hash<H: Hasher>(&self, state: &mut H) { self.as_slice().hash(state) } } #[cfg(feature = "experimental_write_impl")] impl<'s> core::fmt::Write for SliceVec<'s, u8> { fn write_str(&mut self, s: &str) -> core::fmt::Result { let my_len = self.len(); let str_len = s.as_bytes().len(); if my_len + str_len <= self.capacity() { let remainder = &mut self.data[my_len..]; let target = &mut remainder[..str_len]; target.copy_from_slice(s.as_bytes()); Ok(()) } else { Err(core::fmt::Error) } } } // // // // // // // // // Formatting impls // // // // // // // // impl<'s, T> Binary for SliceVec<'s, T> where T: Binary, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } Binary::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> Debug for SliceVec<'s, T> where T: Debug, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } Debug::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> Display for SliceVec<'s, T> where T: Display, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } Display::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> LowerExp for SliceVec<'s, T> where T: LowerExp, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } LowerExp::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> LowerHex for SliceVec<'s, T> where T: LowerHex, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } LowerHex::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> Octal for SliceVec<'s, T> where T: Octal, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } Octal::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> Pointer for SliceVec<'s, T> where T: Pointer, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } Pointer::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> UpperExp for SliceVec<'s, T> where T: UpperExp, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } UpperExp::fmt(elem, f)?; } write!(f, "]") } } impl<'s, T> UpperHex for SliceVec<'s, T> where T: UpperHex, { #[allow(clippy::missing_inline_in_public_items)] fn fmt(&self, f: &mut Formatter) -> core::fmt::Result { write!(f, "[")?; for (i, elem) in self.iter().enumerate() { if i > 0 { write!(f, ", ")?; } UpperHex::fmt(elem, f)?; } write!(f, "]") } }