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Linux/rust/kernel/list.rs

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Diff markup

Differences between /rust/kernel/list.rs (Architecture alpha) and /rust/kernel/list.rs (Architecture ppc)


  1 // SPDX-License-Identifier: GPL-2.0                 1 // SPDX-License-Identifier: GPL-2.0
  2                                                     2 
  3 // Copyright (C) 2024 Google LLC.                   3 // Copyright (C) 2024 Google LLC.
  4                                                     4 
  5 //! A linked list implementation.                   5 //! A linked list implementation.
  6                                                     6 
  7 use crate::init::PinInit;                           7 use crate::init::PinInit;
  8 use crate::sync::ArcBorrow;                         8 use crate::sync::ArcBorrow;
  9 use crate::types::Opaque;                           9 use crate::types::Opaque;
 10 use core::iter::{DoubleEndedIterator, FusedIte     10 use core::iter::{DoubleEndedIterator, FusedIterator};
 11 use core::marker::PhantomData;                     11 use core::marker::PhantomData;
 12 use core::ptr;                                     12 use core::ptr;
 13                                                    13 
 14 mod impl_list_item_mod;                            14 mod impl_list_item_mod;
 15 pub use self::impl_list_item_mod::{                15 pub use self::impl_list_item_mod::{
 16     impl_has_list_links, impl_has_list_links_s     16     impl_has_list_links, impl_has_list_links_self_ptr, impl_list_item, HasListLinks, HasSelfPtr,
 17 };                                                 17 };
 18                                                    18 
 19 mod arc;                                           19 mod arc;
 20 pub use self::arc::{impl_list_arc_safe, Atomic     20 pub use self::arc::{impl_list_arc_safe, AtomicTracker, ListArc, ListArcSafe, TryNewListArc};
 21                                                    21 
 22 mod arc_field;                                     22 mod arc_field;
 23 pub use self::arc_field::{define_list_arc_fiel     23 pub use self::arc_field::{define_list_arc_field_getter, ListArcField};
 24                                                    24 
 25 /// A linked list.                                 25 /// A linked list.
 26 ///                                                26 ///
 27 /// All elements in this linked list will be [     27 /// All elements in this linked list will be [`ListArc`] references to the value. Since a value can
 28 /// only have one `ListArc` (for each pair of      28 /// only have one `ListArc` (for each pair of prev/next pointers), this ensures that the same
 29 /// prev/next pointers are not used for severa     29 /// prev/next pointers are not used for several linked lists.
 30 ///                                                30 ///
 31 /// # Invariants                                   31 /// # Invariants
 32 ///                                                32 ///
 33 /// * If the list is empty, then `first` is nu     33 /// * If the list is empty, then `first` is null. Otherwise, `first` points at the `ListLinks`
 34 ///   field of the first element in the list.      34 ///   field of the first element in the list.
 35 /// * All prev/next pointers in `ListLinks` fi     35 /// * All prev/next pointers in `ListLinks` fields of items in the list are valid and form a cycle.
 36 /// * For every item in the list, the list own     36 /// * For every item in the list, the list owns the associated [`ListArc`] reference and has
 37 ///   exclusive access to the `ListLinks` fiel     37 ///   exclusive access to the `ListLinks` field.
 38 pub struct List<T: ?Sized + ListItem<ID>, cons     38 pub struct List<T: ?Sized + ListItem<ID>, const ID: u64 = 0> {
 39     first: *mut ListLinksFields,                   39     first: *mut ListLinksFields,
 40     _ty: PhantomData<ListArc<T, ID>>,              40     _ty: PhantomData<ListArc<T, ID>>,
 41 }                                                  41 }
 42                                                    42 
 43 // SAFETY: This is a container of `ListArc<T,      43 // SAFETY: This is a container of `ListArc<T, ID>`, and access to the container allows the same
 44 // type of access to the `ListArc<T, ID>` elem     44 // type of access to the `ListArc<T, ID>` elements.
 45 unsafe impl<T, const ID: u64> Send for List<T,     45 unsafe impl<T, const ID: u64> Send for List<T, ID>
 46 where                                              46 where
 47     ListArc<T, ID>: Send,                          47     ListArc<T, ID>: Send,
 48     T: ?Sized + ListItem<ID>,                      48     T: ?Sized + ListItem<ID>,
 49 {                                                  49 {
 50 }                                                  50 }
 51 // SAFETY: This is a container of `ListArc<T,      51 // SAFETY: This is a container of `ListArc<T, ID>`, and access to the container allows the same
 52 // type of access to the `ListArc<T, ID>` elem     52 // type of access to the `ListArc<T, ID>` elements.
 53 unsafe impl<T, const ID: u64> Sync for List<T,     53 unsafe impl<T, const ID: u64> Sync for List<T, ID>
 54 where                                              54 where
 55     ListArc<T, ID>: Sync,                          55     ListArc<T, ID>: Sync,
 56     T: ?Sized + ListItem<ID>,                      56     T: ?Sized + ListItem<ID>,
 57 {                                                  57 {
 58 }                                                  58 }
 59                                                    59 
 60 /// Implemented by types where a [`ListArc<Sel     60 /// Implemented by types where a [`ListArc<Self>`] can be inserted into a [`List`].
 61 ///                                                61 ///
 62 /// # Safety                                       62 /// # Safety
 63 ///                                                63 ///
 64 /// Implementers must ensure that they provide     64 /// Implementers must ensure that they provide the guarantees documented on methods provided by
 65 /// this trait.                                    65 /// this trait.
 66 ///                                                66 ///
 67 /// [`ListArc<Self>`]: ListArc                     67 /// [`ListArc<Self>`]: ListArc
 68 pub unsafe trait ListItem<const ID: u64 = 0>:      68 pub unsafe trait ListItem<const ID: u64 = 0>: ListArcSafe<ID> {
 69     /// Views the [`ListLinks`] for this value     69     /// Views the [`ListLinks`] for this value.
 70     ///                                            70     ///
 71     /// # Guarantees                               71     /// # Guarantees
 72     ///                                            72     ///
 73     /// If there is a previous call to `prepar     73     /// If there is a previous call to `prepare_to_insert` and there is no call to `post_remove`
 74     /// since the most recent such call, then      74     /// since the most recent such call, then this returns the same pointer as the one returned by
 75     /// the most recent call to `prepare_to_in     75     /// the most recent call to `prepare_to_insert`.
 76     ///                                            76     ///
 77     /// Otherwise, the returned pointer points     77     /// Otherwise, the returned pointer points at a read-only [`ListLinks`] with two null pointers.
 78     ///                                            78     ///
 79     /// # Safety                                   79     /// # Safety
 80     ///                                            80     ///
 81     /// The provided pointer must point at a v     81     /// The provided pointer must point at a valid value. (It need not be in an `Arc`.)
 82     unsafe fn view_links(me: *const Self) -> *     82     unsafe fn view_links(me: *const Self) -> *mut ListLinks<ID>;
 83                                                    83 
 84     /// View the full value given its [`ListLi     84     /// View the full value given its [`ListLinks`] field.
 85     ///                                            85     ///
 86     /// Can only be used when the value is in      86     /// Can only be used when the value is in a list.
 87     ///                                            87     ///
 88     /// # Guarantees                               88     /// # Guarantees
 89     ///                                            89     ///
 90     /// * Returns the same pointer as the one      90     /// * Returns the same pointer as the one passed to the most recent call to `prepare_to_insert`.
 91     /// * The returned pointer is valid until      91     /// * The returned pointer is valid until the next call to `post_remove`.
 92     ///                                            92     ///
 93     /// # Safety                                   93     /// # Safety
 94     ///                                            94     ///
 95     /// * The provided pointer must originate      95     /// * The provided pointer must originate from the most recent call to `prepare_to_insert`, or
 96     ///   from a call to `view_links` that hap     96     ///   from a call to `view_links` that happened after the most recent call to
 97     ///   `prepare_to_insert`.                     97     ///   `prepare_to_insert`.
 98     /// * Since the most recent call to `prepa     98     /// * Since the most recent call to `prepare_to_insert`, the `post_remove` method must not have
 99     ///   been called.                             99     ///   been called.
100     unsafe fn view_value(me: *mut ListLinks<ID    100     unsafe fn view_value(me: *mut ListLinks<ID>) -> *const Self;
101                                                   101 
102     /// This is called when an item is inserte    102     /// This is called when an item is inserted into a [`List`].
103     ///                                           103     ///
104     /// # Guarantees                              104     /// # Guarantees
105     ///                                           105     ///
106     /// The caller is granted exclusive access    106     /// The caller is granted exclusive access to the returned [`ListLinks`] until `post_remove` is
107     /// called.                                   107     /// called.
108     ///                                           108     ///
109     /// # Safety                                  109     /// # Safety
110     ///                                           110     ///
111     /// * The provided pointer must point at a    111     /// * The provided pointer must point at a valid value in an [`Arc`].
112     /// * Calls to `prepare_to_insert` and `po    112     /// * Calls to `prepare_to_insert` and `post_remove` on the same value must alternate.
113     /// * The caller must own the [`ListArc`]     113     /// * The caller must own the [`ListArc`] for this value.
114     /// * The caller must not give up ownershi    114     /// * The caller must not give up ownership of the [`ListArc`] unless `post_remove` has been
115     ///   called after this call to `prepare_t    115     ///   called after this call to `prepare_to_insert`.
116     ///                                           116     ///
117     /// [`Arc`]: crate::sync::Arc                 117     /// [`Arc`]: crate::sync::Arc
118     unsafe fn prepare_to_insert(me: *const Sel    118     unsafe fn prepare_to_insert(me: *const Self) -> *mut ListLinks<ID>;
119                                                   119 
120     /// This undoes a previous call to `prepar    120     /// This undoes a previous call to `prepare_to_insert`.
121     ///                                           121     ///
122     /// # Guarantees                              122     /// # Guarantees
123     ///                                           123     ///
124     /// The returned pointer is the pointer th    124     /// The returned pointer is the pointer that was originally passed to `prepare_to_insert`.
125     ///                                           125     ///
126     /// # Safety                                  126     /// # Safety
127     ///                                           127     ///
128     /// The provided pointer must be the point    128     /// The provided pointer must be the pointer returned by the most recent call to
129     /// `prepare_to_insert`.                      129     /// `prepare_to_insert`.
130     unsafe fn post_remove(me: *mut ListLinks<I    130     unsafe fn post_remove(me: *mut ListLinks<ID>) -> *const Self;
131 }                                                 131 }
132                                                   132 
133 #[repr(C)]                                        133 #[repr(C)]
134 #[derive(Copy, Clone)]                            134 #[derive(Copy, Clone)]
135 struct ListLinksFields {                          135 struct ListLinksFields {
136     next: *mut ListLinksFields,                   136     next: *mut ListLinksFields,
137     prev: *mut ListLinksFields,                   137     prev: *mut ListLinksFields,
138 }                                                 138 }
139                                                   139 
140 /// The prev/next pointers for an item in a li    140 /// The prev/next pointers for an item in a linked list.
141 ///                                               141 ///
142 /// # Invariants                                  142 /// # Invariants
143 ///                                               143 ///
144 /// The fields are null if and only if this it    144 /// The fields are null if and only if this item is not in a list.
145 #[repr(transparent)]                              145 #[repr(transparent)]
146 pub struct ListLinks<const ID: u64 = 0> {         146 pub struct ListLinks<const ID: u64 = 0> {
147     // This type is `!Unpin` for aliasing reas    147     // This type is `!Unpin` for aliasing reasons as the pointers are part of an intrusive linked
148     // list.                                      148     // list.
149     inner: Opaque<ListLinksFields>,               149     inner: Opaque<ListLinksFields>,
150 }                                                 150 }
151                                                   151 
152 // SAFETY: The only way to access/modify the p    152 // SAFETY: The only way to access/modify the pointers inside of `ListLinks<ID>` is via holding the
153 // associated `ListArc<T, ID>`. Since that typ    153 // associated `ListArc<T, ID>`. Since that type correctly implements `Send`, it is impossible to
154 // move this an instance of this type to a dif    154 // move this an instance of this type to a different thread if the pointees are `!Send`.
155 unsafe impl<const ID: u64> Send for ListLinks<    155 unsafe impl<const ID: u64> Send for ListLinks<ID> {}
156 // SAFETY: The type is opaque so immutable ref    156 // SAFETY: The type is opaque so immutable references to a ListLinks are useless. Therefore, it's
157 // okay to have immutable access to a ListLink    157 // okay to have immutable access to a ListLinks from several threads at once.
158 unsafe impl<const ID: u64> Sync for ListLinks<    158 unsafe impl<const ID: u64> Sync for ListLinks<ID> {}
159                                                   159 
160 impl<const ID: u64> ListLinks<ID> {               160 impl<const ID: u64> ListLinks<ID> {
161     /// Creates a new initializer for this typ    161     /// Creates a new initializer for this type.
162     pub fn new() -> impl PinInit<Self> {          162     pub fn new() -> impl PinInit<Self> {
163         // INVARIANT: Pin-init initializers ca    163         // INVARIANT: Pin-init initializers can't be used on an existing `Arc`, so this value will
164         // not be constructed in an `Arc` that    164         // not be constructed in an `Arc` that already has a `ListArc`.
165         ListLinks {                               165         ListLinks {
166             inner: Opaque::new(ListLinksFields    166             inner: Opaque::new(ListLinksFields {
167                 prev: ptr::null_mut(),            167                 prev: ptr::null_mut(),
168                 next: ptr::null_mut(),            168                 next: ptr::null_mut(),
169             }),                                   169             }),
170         }                                         170         }
171     }                                             171     }
172                                                   172 
173     /// # Safety                                  173     /// # Safety
174     ///                                           174     ///
175     /// `me` must be dereferenceable.             175     /// `me` must be dereferenceable.
176     #[inline]                                     176     #[inline]
177     unsafe fn fields(me: *mut Self) -> *mut Li    177     unsafe fn fields(me: *mut Self) -> *mut ListLinksFields {
178         // SAFETY: The caller promises that th    178         // SAFETY: The caller promises that the pointer is valid.
179         unsafe { Opaque::raw_get(ptr::addr_of!    179         unsafe { Opaque::raw_get(ptr::addr_of!((*me).inner)) }
180     }                                             180     }
181                                                   181 
182     /// # Safety                                  182     /// # Safety
183     ///                                           183     ///
184     /// `me` must be dereferenceable.             184     /// `me` must be dereferenceable.
185     #[inline]                                     185     #[inline]
186     unsafe fn from_fields(me: *mut ListLinksFi    186     unsafe fn from_fields(me: *mut ListLinksFields) -> *mut Self {
187         me.cast()                                 187         me.cast()
188     }                                             188     }
189 }                                                 189 }
190                                                   190 
191 /// Similar to [`ListLinks`], but also contain    191 /// Similar to [`ListLinks`], but also contains a pointer to the full value.
192 ///                                               192 ///
193 /// This type can be used instead of [`ListLin    193 /// This type can be used instead of [`ListLinks`] to support lists with trait objects.
194 #[repr(C)]                                        194 #[repr(C)]
195 pub struct ListLinksSelfPtr<T: ?Sized, const I    195 pub struct ListLinksSelfPtr<T: ?Sized, const ID: u64 = 0> {
196     /// The `ListLinks` field inside this valu    196     /// The `ListLinks` field inside this value.
197     ///                                           197     ///
198     /// This is public so that it can be used     198     /// This is public so that it can be used with `impl_has_list_links!`.
199     pub inner: ListLinks<ID>,                     199     pub inner: ListLinks<ID>,
200     // UnsafeCell is not enough here because w    200     // UnsafeCell is not enough here because we use `Opaque::uninit` as a dummy value, and
201     // `ptr::null()` doesn't work for `T: ?Siz    201     // `ptr::null()` doesn't work for `T: ?Sized`.
202     self_ptr: Opaque<*const T>,                   202     self_ptr: Opaque<*const T>,
203 }                                                 203 }
204                                                   204 
205 // SAFETY: The fields of a ListLinksSelfPtr ca    205 // SAFETY: The fields of a ListLinksSelfPtr can be moved across thread boundaries.
206 unsafe impl<T: ?Sized + Send, const ID: u64> S    206 unsafe impl<T: ?Sized + Send, const ID: u64> Send for ListLinksSelfPtr<T, ID> {}
207 // SAFETY: The type is opaque so immutable ref    207 // SAFETY: The type is opaque so immutable references to a ListLinksSelfPtr are useless. Therefore,
208 // it's okay to have immutable access to a Lis    208 // it's okay to have immutable access to a ListLinks from several threads at once.
209 //                                                209 //
210 // Note that `inner` being a public field does    210 // Note that `inner` being a public field does not prevent this type from being opaque, since
211 // `inner` is a opaque type.                      211 // `inner` is a opaque type.
212 unsafe impl<T: ?Sized + Sync, const ID: u64> S    212 unsafe impl<T: ?Sized + Sync, const ID: u64> Sync for ListLinksSelfPtr<T, ID> {}
213                                                   213 
214 impl<T: ?Sized, const ID: u64> ListLinksSelfPt    214 impl<T: ?Sized, const ID: u64> ListLinksSelfPtr<T, ID> {
215     /// The offset from the [`ListLinks`] to t    215     /// The offset from the [`ListLinks`] to the self pointer field.
216     pub const LIST_LINKS_SELF_PTR_OFFSET: usiz    216     pub const LIST_LINKS_SELF_PTR_OFFSET: usize = core::mem::offset_of!(Self, self_ptr);
217                                                   217 
218     /// Creates a new initializer for this typ    218     /// Creates a new initializer for this type.
219     pub fn new() -> impl PinInit<Self> {          219     pub fn new() -> impl PinInit<Self> {
220         // INVARIANT: Pin-init initializers ca    220         // INVARIANT: Pin-init initializers can't be used on an existing `Arc`, so this value will
221         // not be constructed in an `Arc` that    221         // not be constructed in an `Arc` that already has a `ListArc`.
222         Self {                                    222         Self {
223             inner: ListLinks {                    223             inner: ListLinks {
224                 inner: Opaque::new(ListLinksFi    224                 inner: Opaque::new(ListLinksFields {
225                     prev: ptr::null_mut(),        225                     prev: ptr::null_mut(),
226                     next: ptr::null_mut(),        226                     next: ptr::null_mut(),
227                 }),                               227                 }),
228             },                                    228             },
229             self_ptr: Opaque::uninit(),           229             self_ptr: Opaque::uninit(),
230         }                                         230         }
231     }                                             231     }
232 }                                                 232 }
233                                                   233 
234 impl<T: ?Sized + ListItem<ID>, const ID: u64>     234 impl<T: ?Sized + ListItem<ID>, const ID: u64> List<T, ID> {
235     /// Creates a new empty list.                 235     /// Creates a new empty list.
236     pub const fn new() -> Self {                  236     pub const fn new() -> Self {
237         Self {                                    237         Self {
238             first: ptr::null_mut(),               238             first: ptr::null_mut(),
239             _ty: PhantomData,                     239             _ty: PhantomData,
240         }                                         240         }
241     }                                             241     }
242                                                   242 
243     /// Returns whether this list is empty.       243     /// Returns whether this list is empty.
244     pub fn is_empty(&self) -> bool {              244     pub fn is_empty(&self) -> bool {
245         self.first.is_null()                      245         self.first.is_null()
246     }                                             246     }
247                                                   247 
248     /// Add the provided item to the back of t    248     /// Add the provided item to the back of the list.
249     pub fn push_back(&mut self, item: ListArc<    249     pub fn push_back(&mut self, item: ListArc<T, ID>) {
250         let raw_item = ListArc::into_raw(item)    250         let raw_item = ListArc::into_raw(item);
251         // SAFETY:                                251         // SAFETY:
252         // * We just got `raw_item` from a `Li    252         // * We just got `raw_item` from a `ListArc`, so it's in an `Arc`.
253         // * Since we have ownership of the `L    253         // * Since we have ownership of the `ListArc`, `post_remove` must have been called after
254         //   the most recent call to `prepare_    254         //   the most recent call to `prepare_to_insert`, if any.
255         // * We own the `ListArc`.                255         // * We own the `ListArc`.
256         // * Removing items from this list is     256         // * Removing items from this list is always done using `remove_internal_inner`, which
257         //   calls `post_remove` before giving    257         //   calls `post_remove` before giving up ownership.
258         let list_links = unsafe { T::prepare_t    258         let list_links = unsafe { T::prepare_to_insert(raw_item) };
259         // SAFETY: We have not yet called `pos    259         // SAFETY: We have not yet called `post_remove`, so `list_links` is still valid.
260         let item = unsafe { ListLinks::fields(    260         let item = unsafe { ListLinks::fields(list_links) };
261                                                   261 
262         if self.first.is_null() {                 262         if self.first.is_null() {
263             self.first = item;                    263             self.first = item;
264             // SAFETY: The caller just gave us    264             // SAFETY: The caller just gave us ownership of these fields.
265             // INVARIANT: A linked list with o    265             // INVARIANT: A linked list with one item should be cyclic.
266             unsafe {                              266             unsafe {
267                 (*item).next = item;              267                 (*item).next = item;
268                 (*item).prev = item;              268                 (*item).prev = item;
269             }                                     269             }
270         } else {                                  270         } else {
271             let next = self.first;                271             let next = self.first;
272             // SAFETY: By the type invariant,     272             // SAFETY: By the type invariant, this pointer is valid or null. We just checked that
273             // it's not null, so it must be va    273             // it's not null, so it must be valid.
274             let prev = unsafe { (*next).prev }    274             let prev = unsafe { (*next).prev };
275             // SAFETY: Pointers in a linked li    275             // SAFETY: Pointers in a linked list are never dangling, and the caller just gave us
276             // ownership of the fields on `ite    276             // ownership of the fields on `item`.
277             // INVARIANT: This correctly inser    277             // INVARIANT: This correctly inserts `item` between `prev` and `next`.
278             unsafe {                              278             unsafe {
279                 (*item).next = next;              279                 (*item).next = next;
280                 (*item).prev = prev;              280                 (*item).prev = prev;
281                 (*prev).next = item;              281                 (*prev).next = item;
282                 (*next).prev = item;              282                 (*next).prev = item;
283             }                                     283             }
284         }                                         284         }
285     }                                             285     }
286                                                   286 
287     /// Add the provided item to the front of     287     /// Add the provided item to the front of the list.
288     pub fn push_front(&mut self, item: ListArc    288     pub fn push_front(&mut self, item: ListArc<T, ID>) {
289         let raw_item = ListArc::into_raw(item)    289         let raw_item = ListArc::into_raw(item);
290         // SAFETY:                                290         // SAFETY:
291         // * We just got `raw_item` from a `Li    291         // * We just got `raw_item` from a `ListArc`, so it's in an `Arc`.
292         // * If this requirement is violated,     292         // * If this requirement is violated, then the previous caller of `prepare_to_insert`
293         //   violated the safety requirement t    293         //   violated the safety requirement that they can't give up ownership of the `ListArc`
294         //   until they call `post_remove`.       294         //   until they call `post_remove`.
295         // * We own the `ListArc`.                295         // * We own the `ListArc`.
296         // * Removing items] from this list is    296         // * Removing items] from this list is always done using `remove_internal_inner`, which
297         //   calls `post_remove` before giving    297         //   calls `post_remove` before giving up ownership.
298         let list_links = unsafe { T::prepare_t    298         let list_links = unsafe { T::prepare_to_insert(raw_item) };
299         // SAFETY: We have not yet called `pos    299         // SAFETY: We have not yet called `post_remove`, so `list_links` is still valid.
300         let item = unsafe { ListLinks::fields(    300         let item = unsafe { ListLinks::fields(list_links) };
301                                                   301 
302         if self.first.is_null() {                 302         if self.first.is_null() {
303             // SAFETY: The caller just gave us    303             // SAFETY: The caller just gave us ownership of these fields.
304             // INVARIANT: A linked list with o    304             // INVARIANT: A linked list with one item should be cyclic.
305             unsafe {                              305             unsafe {
306                 (*item).next = item;              306                 (*item).next = item;
307                 (*item).prev = item;              307                 (*item).prev = item;
308             }                                     308             }
309         } else {                                  309         } else {
310             let next = self.first;                310             let next = self.first;
311             // SAFETY: We just checked that `n    311             // SAFETY: We just checked that `next` is non-null.
312             let prev = unsafe { (*next).prev }    312             let prev = unsafe { (*next).prev };
313             // SAFETY: Pointers in a linked li    313             // SAFETY: Pointers in a linked list are never dangling, and the caller just gave us
314             // ownership of the fields on `ite    314             // ownership of the fields on `item`.
315             // INVARIANT: This correctly inser    315             // INVARIANT: This correctly inserts `item` between `prev` and `next`.
316             unsafe {                              316             unsafe {
317                 (*item).next = next;              317                 (*item).next = next;
318                 (*item).prev = prev;              318                 (*item).prev = prev;
319                 (*prev).next = item;              319                 (*prev).next = item;
320                 (*next).prev = item;              320                 (*next).prev = item;
321             }                                     321             }
322         }                                         322         }
323         self.first = item;                        323         self.first = item;
324     }                                             324     }
325                                                   325 
326     /// Removes the last item from this list.     326     /// Removes the last item from this list.
327     pub fn pop_back(&mut self) -> Option<ListA    327     pub fn pop_back(&mut self) -> Option<ListArc<T, ID>> {
328         if self.first.is_null() {                 328         if self.first.is_null() {
329             return None;                          329             return None;
330         }                                         330         }
331                                                   331 
332         // SAFETY: We just checked that the li    332         // SAFETY: We just checked that the list is not empty.
333         let last = unsafe { (*self.first).prev    333         let last = unsafe { (*self.first).prev };
334         // SAFETY: The last item of this list     334         // SAFETY: The last item of this list is in this list.
335         Some(unsafe { self.remove_internal(las    335         Some(unsafe { self.remove_internal(last) })
336     }                                             336     }
337                                                   337 
338     /// Removes the first item from this list.    338     /// Removes the first item from this list.
339     pub fn pop_front(&mut self) -> Option<List    339     pub fn pop_front(&mut self) -> Option<ListArc<T, ID>> {
340         if self.first.is_null() {                 340         if self.first.is_null() {
341             return None;                          341             return None;
342         }                                         342         }
343                                                   343 
344         // SAFETY: The first item of this list    344         // SAFETY: The first item of this list is in this list.
345         Some(unsafe { self.remove_internal(sel    345         Some(unsafe { self.remove_internal(self.first) })
346     }                                             346     }
347                                                   347 
348     /// Removes the provided item from this li    348     /// Removes the provided item from this list and returns it.
349     ///                                           349     ///
350     /// This returns `None` if the item is not    350     /// This returns `None` if the item is not in the list. (Note that by the safety requirements,
351     /// this means that the item is not in any    351     /// this means that the item is not in any list.)
352     ///                                           352     ///
353     /// # Safety                                  353     /// # Safety
354     ///                                           354     ///
355     /// `item` must not be in a different link    355     /// `item` must not be in a different linked list (with the same id).
356     pub unsafe fn remove(&mut self, item: &T)     356     pub unsafe fn remove(&mut self, item: &T) -> Option<ListArc<T, ID>> {
357         let mut item = unsafe { ListLinks::fie    357         let mut item = unsafe { ListLinks::fields(T::view_links(item)) };
358         // SAFETY: The user provided a referen    358         // SAFETY: The user provided a reference, and reference are never dangling.
359         //                                        359         //
360         // As for why this is not a data race,    360         // As for why this is not a data race, there are two cases:
361         //                                        361         //
362         //  * If `item` is not in any list, th    362         //  * If `item` is not in any list, then these fields are read-only and null.
363         //  * If `item` is in this list, then     363         //  * If `item` is in this list, then we have exclusive access to these fields since we
364         //    have a mutable reference to the     364         //    have a mutable reference to the list.
365         //                                        365         //
366         // In either case, there's no race.       366         // In either case, there's no race.
367         let ListLinksFields { next, prev } = u    367         let ListLinksFields { next, prev } = unsafe { *item };
368                                                   368 
369         debug_assert_eq!(next.is_null(), prev.    369         debug_assert_eq!(next.is_null(), prev.is_null());
370         if !next.is_null() {                      370         if !next.is_null() {
371             // This is really a no-op, but thi    371             // This is really a no-op, but this ensures that `item` is a raw pointer that was
372             // obtained without going through     372             // obtained without going through a pointer->reference->pointer conversion roundtrip.
373             // This ensures that the list is v    373             // This ensures that the list is valid under the more restrictive strict provenance
374             // ruleset.                           374             // ruleset.
375             //                                    375             //
376             // SAFETY: We just checked that `n    376             // SAFETY: We just checked that `next` is not null, and it's not dangling by the
377             // list invariants.                   377             // list invariants.
378             unsafe {                              378             unsafe {
379                 debug_assert_eq!(item, (*next)    379                 debug_assert_eq!(item, (*next).prev);
380                 item = (*next).prev;              380                 item = (*next).prev;
381             }                                     381             }
382                                                   382 
383             // SAFETY: We just checked that `i    383             // SAFETY: We just checked that `item` is in a list, so the caller guarantees that it
384             // is in this list. The pointers a    384             // is in this list. The pointers are in the right order.
385             Some(unsafe { self.remove_internal    385             Some(unsafe { self.remove_internal_inner(item, next, prev) })
386         } else {                                  386         } else {
387             None                                  387             None
388         }                                         388         }
389     }                                             389     }
390                                                   390 
391     /// Removes the provided item from the lis    391     /// Removes the provided item from the list.
392     ///                                           392     ///
393     /// # Safety                                  393     /// # Safety
394     ///                                           394     ///
395     /// `item` must point at an item in this l    395     /// `item` must point at an item in this list.
396     unsafe fn remove_internal(&mut self, item:    396     unsafe fn remove_internal(&mut self, item: *mut ListLinksFields) -> ListArc<T, ID> {
397         // SAFETY: The caller promises that th    397         // SAFETY: The caller promises that this pointer is not dangling, and there's no data race
398         // since we have a mutable reference t    398         // since we have a mutable reference to the list containing `item`.
399         let ListLinksFields { next, prev } = u    399         let ListLinksFields { next, prev } = unsafe { *item };
400         // SAFETY: The pointers are ok and in     400         // SAFETY: The pointers are ok and in the right order.
401         unsafe { self.remove_internal_inner(it    401         unsafe { self.remove_internal_inner(item, next, prev) }
402     }                                             402     }
403                                                   403 
404     /// Removes the provided item from the lis    404     /// Removes the provided item from the list.
405     ///                                           405     ///
406     /// # Safety                                  406     /// # Safety
407     ///                                           407     ///
408     /// The `item` pointer must point at an it    408     /// The `item` pointer must point at an item in this list, and we must have `(*item).next ==
409     /// next` and `(*item).prev == prev`.         409     /// next` and `(*item).prev == prev`.
410     unsafe fn remove_internal_inner(              410     unsafe fn remove_internal_inner(
411         &mut self,                                411         &mut self,
412         item: *mut ListLinksFields,               412         item: *mut ListLinksFields,
413         next: *mut ListLinksFields,               413         next: *mut ListLinksFields,
414         prev: *mut ListLinksFields,               414         prev: *mut ListLinksFields,
415     ) -> ListArc<T, ID> {                         415     ) -> ListArc<T, ID> {
416         // SAFETY: We have exclusive access to    416         // SAFETY: We have exclusive access to the pointers of items in the list, and the prev/next
417         // pointers are always valid for items    417         // pointers are always valid for items in a list.
418         //                                        418         //
419         // INVARIANT: There are three cases:      419         // INVARIANT: There are three cases:
420         //  * If the list has at least three i    420         //  * If the list has at least three items, then after removing the item, `prev` and `next`
421         //    will be next to each other.         421         //    will be next to each other.
422         //  * If the list has two items, then     422         //  * If the list has two items, then the remaining item will point at itself.
423         //  * If the list has one item, then `    423         //  * If the list has one item, then `next == prev == item`, so these writes have no
424         //    effect. The list remains unchang    424         //    effect. The list remains unchanged and `item` is still in the list for now.
425         unsafe {                                  425         unsafe {
426             (*next).prev = prev;                  426             (*next).prev = prev;
427             (*prev).next = next;                  427             (*prev).next = next;
428         }                                         428         }
429         // SAFETY: We have exclusive access to    429         // SAFETY: We have exclusive access to items in the list.
430         // INVARIANT: `item` is being removed,    430         // INVARIANT: `item` is being removed, so the pointers should be null.
431         unsafe {                                  431         unsafe {
432             (*item).prev = ptr::null_mut();       432             (*item).prev = ptr::null_mut();
433             (*item).next = ptr::null_mut();       433             (*item).next = ptr::null_mut();
434         }                                         434         }
435         // INVARIANT: There are three cases:      435         // INVARIANT: There are three cases:
436         //  * If `item` was not the first item    436         //  * If `item` was not the first item, then `self.first` should remain unchanged.
437         //  * If `item` was the first item and    437         //  * If `item` was the first item and there is another item, then we just updated
438         //    `prev->next` to `next`, which is    438         //    `prev->next` to `next`, which is the new first item, and setting `item->next` to null
439         //    did not modify `prev->next`.        439         //    did not modify `prev->next`.
440         //  * If `item` was the only item in t    440         //  * If `item` was the only item in the list, then `prev == item`, and we just set
441         //    `item->next` to null, so this co    441         //    `item->next` to null, so this correctly sets `first` to null now that the list is
442         //    empty.                              442         //    empty.
443         if self.first == item {                   443         if self.first == item {
444             // SAFETY: The `prev` pointer is t    444             // SAFETY: The `prev` pointer is the value that `item->prev` had when it was in this
445             // list, so it must be valid. Ther    445             // list, so it must be valid. There is no race since `prev` is still in the list and we
446             // still have exclusive access to     446             // still have exclusive access to the list.
447             self.first = unsafe { (*prev).next    447             self.first = unsafe { (*prev).next };
448         }                                         448         }
449                                                   449 
450         // SAFETY: `item` used to be in the li    450         // SAFETY: `item` used to be in the list, so it is dereferenceable by the type invariants
451         // of `List`.                             451         // of `List`.
452         let list_links = unsafe { ListLinks::f    452         let list_links = unsafe { ListLinks::from_fields(item) };
453         // SAFETY: Any pointer in the list ori    453         // SAFETY: Any pointer in the list originates from a `prepare_to_insert` call.
454         let raw_item = unsafe { T::post_remove    454         let raw_item = unsafe { T::post_remove(list_links) };
455         // SAFETY: The above call to `post_rem    455         // SAFETY: The above call to `post_remove` guarantees that we can recreate the `ListArc`.
456         unsafe { ListArc::from_raw(raw_item) }    456         unsafe { ListArc::from_raw(raw_item) }
457     }                                             457     }
458                                                   458 
459     /// Moves all items from `other` into `sel    459     /// Moves all items from `other` into `self`.
460     ///                                           460     ///
461     /// The items of `other` are added to the     461     /// The items of `other` are added to the back of `self`, so the last item of `other` becomes
462     /// the last item of `self`.                  462     /// the last item of `self`.
463     pub fn push_all_back(&mut self, other: &mu    463     pub fn push_all_back(&mut self, other: &mut List<T, ID>) {
464         // First, we insert the elements into     464         // First, we insert the elements into `self`. At the end, we make `other` empty.
465         if self.is_empty() {                      465         if self.is_empty() {
466             // INVARIANT: All of the elements     466             // INVARIANT: All of the elements in `other` become elements of `self`.
467             self.first = other.first;             467             self.first = other.first;
468         } else if !other.is_empty() {             468         } else if !other.is_empty() {
469             let other_first = other.first;        469             let other_first = other.first;
470             // SAFETY: The other list is not e    470             // SAFETY: The other list is not empty, so this pointer is valid.
471             let other_last = unsafe { (*other_    471             let other_last = unsafe { (*other_first).prev };
472             let self_first = self.first;          472             let self_first = self.first;
473             // SAFETY: The self list is not em    473             // SAFETY: The self list is not empty, so this pointer is valid.
474             let self_last = unsafe { (*self_fi    474             let self_last = unsafe { (*self_first).prev };
475                                                   475 
476             // SAFETY: We have exclusive acces    476             // SAFETY: We have exclusive access to both lists, so we can update the pointers.
477             // INVARIANT: This correctly sets     477             // INVARIANT: This correctly sets the pointers to merge both lists. We do not need to
478             // update `self.first` because the    478             // update `self.first` because the first element of `self` does not change.
479             unsafe {                              479             unsafe {
480                 (*self_first).prev = other_las    480                 (*self_first).prev = other_last;
481                 (*other_last).next = self_firs    481                 (*other_last).next = self_first;
482                 (*self_last).next = other_firs    482                 (*self_last).next = other_first;
483                 (*other_first).prev = self_las    483                 (*other_first).prev = self_last;
484             }                                     484             }
485         }                                         485         }
486                                                   486 
487         // INVARIANT: The other list is now em    487         // INVARIANT: The other list is now empty, so update its pointer.
488         other.first = ptr::null_mut();            488         other.first = ptr::null_mut();
489     }                                             489     }
490                                                   490 
491     /// Returns a cursor to the first element     491     /// Returns a cursor to the first element of the list.
492     ///                                           492     ///
493     /// If the list is empty, this returns `No    493     /// If the list is empty, this returns `None`.
494     pub fn cursor_front(&mut self) -> Option<C    494     pub fn cursor_front(&mut self) -> Option<Cursor<'_, T, ID>> {
495         if self.first.is_null() {                 495         if self.first.is_null() {
496             None                                  496             None
497         } else {                                  497         } else {
498             Some(Cursor {                         498             Some(Cursor {
499                 current: self.first,              499                 current: self.first,
500                 list: self,                       500                 list: self,
501             })                                    501             })
502         }                                         502         }
503     }                                             503     }
504                                                   504 
505     /// Creates an iterator over the list.        505     /// Creates an iterator over the list.
506     pub fn iter(&self) -> Iter<'_, T, ID> {       506     pub fn iter(&self) -> Iter<'_, T, ID> {
507         // INVARIANT: If the list is empty, bo    507         // INVARIANT: If the list is empty, both pointers are null. Otherwise, both pointers point
508         // at the first element of the same li    508         // at the first element of the same list.
509         Iter {                                    509         Iter {
510             current: self.first,                  510             current: self.first,
511             stop: self.first,                     511             stop: self.first,
512             _ty: PhantomData,                     512             _ty: PhantomData,
513         }                                         513         }
514     }                                             514     }
515 }                                                 515 }
516                                                   516 
517 impl<T: ?Sized + ListItem<ID>, const ID: u64>     517 impl<T: ?Sized + ListItem<ID>, const ID: u64> Default for List<T, ID> {
518     fn default() -> Self {                        518     fn default() -> Self {
519         List::new()                               519         List::new()
520     }                                             520     }
521 }                                                 521 }
522                                                   522 
523 impl<T: ?Sized + ListItem<ID>, const ID: u64>     523 impl<T: ?Sized + ListItem<ID>, const ID: u64> Drop for List<T, ID> {
524     fn drop(&mut self) {                          524     fn drop(&mut self) {
525         while let Some(item) = self.pop_front(    525         while let Some(item) = self.pop_front() {
526             drop(item);                           526             drop(item);
527         }                                         527         }
528     }                                             528     }
529 }                                                 529 }
530                                                   530 
531 /// An iterator over a [`List`].                  531 /// An iterator over a [`List`].
532 ///                                               532 ///
533 /// # Invariants                                  533 /// # Invariants
534 ///                                               534 ///
535 /// * There must be a [`List`] that is immutab    535 /// * There must be a [`List`] that is immutably borrowed for the duration of `'a`.
536 /// * The `current` pointer is null or points     536 /// * The `current` pointer is null or points at a value in that [`List`].
537 /// * The `stop` pointer is equal to the `firs    537 /// * The `stop` pointer is equal to the `first` field of that [`List`].
538 #[derive(Clone)]                                  538 #[derive(Clone)]
539 pub struct Iter<'a, T: ?Sized + ListItem<ID>,     539 pub struct Iter<'a, T: ?Sized + ListItem<ID>, const ID: u64 = 0> {
540     current: *mut ListLinksFields,                540     current: *mut ListLinksFields,
541     stop: *mut ListLinksFields,                   541     stop: *mut ListLinksFields,
542     _ty: PhantomData<&'a ListArc<T, ID>>,         542     _ty: PhantomData<&'a ListArc<T, ID>>,
543 }                                                 543 }
544                                                   544 
545 impl<'a, T: ?Sized + ListItem<ID>, const ID: u    545 impl<'a, T: ?Sized + ListItem<ID>, const ID: u64> Iterator for Iter<'a, T, ID> {
546     type Item = ArcBorrow<'a, T>;                 546     type Item = ArcBorrow<'a, T>;
547                                                   547 
548     fn next(&mut self) -> Option<ArcBorrow<'a,    548     fn next(&mut self) -> Option<ArcBorrow<'a, T>> {
549         if self.current.is_null() {               549         if self.current.is_null() {
550             return None;                          550             return None;
551         }                                         551         }
552                                                   552 
553         let current = self.current;               553         let current = self.current;
554                                                   554 
555         // SAFETY: We just checked that `curre    555         // SAFETY: We just checked that `current` is not null, so it is in a list, and hence not
556         // dangling. There's no race because t    556         // dangling. There's no race because the iterator holds an immutable borrow to the list.
557         let next = unsafe { (*current).next };    557         let next = unsafe { (*current).next };
558         // INVARIANT: If `current` was the las    558         // INVARIANT: If `current` was the last element of the list, then this updates it to null.
559         // Otherwise, we update it to the next    559         // Otherwise, we update it to the next element.
560         self.current = if next != self.stop {     560         self.current = if next != self.stop {
561             next                                  561             next
562         } else {                                  562         } else {
563             ptr::null_mut()                       563             ptr::null_mut()
564         };                                        564         };
565                                                   565 
566         // SAFETY: The `current` pointer point    566         // SAFETY: The `current` pointer points at a value in the list.
567         let item = unsafe { T::view_value(List    567         let item = unsafe { T::view_value(ListLinks::from_fields(current)) };
568         // SAFETY:                                568         // SAFETY:
569         // * All values in a list are stored i    569         // * All values in a list are stored in an `Arc`.
570         // * The value cannot be removed from     570         // * The value cannot be removed from the list for the duration of the lifetime annotated
571         //   on the returned `ArcBorrow`, beca    571         //   on the returned `ArcBorrow`, because removing it from the list would require mutable
572         //   access to the list. However, the     572         //   access to the list. However, the `ArcBorrow` is annotated with the iterator's
573         //   lifetime, and the list is immutab    573         //   lifetime, and the list is immutably borrowed for that lifetime.
574         // * Values in a list never have a `Un    574         // * Values in a list never have a `UniqueArc` reference.
575         Some(unsafe { ArcBorrow::from_raw(item    575         Some(unsafe { ArcBorrow::from_raw(item) })
576     }                                             576     }
577 }                                                 577 }
578                                                   578 
579 /// A cursor into a [`List`].                     579 /// A cursor into a [`List`].
580 ///                                               580 ///
581 /// # Invariants                                  581 /// # Invariants
582 ///                                               582 ///
583 /// The `current` pointer points a value in `l    583 /// The `current` pointer points a value in `list`.
584 pub struct Cursor<'a, T: ?Sized + ListItem<ID>    584 pub struct Cursor<'a, T: ?Sized + ListItem<ID>, const ID: u64 = 0> {
585     current: *mut ListLinksFields,                585     current: *mut ListLinksFields,
586     list: &'a mut List<T, ID>,                    586     list: &'a mut List<T, ID>,
587 }                                                 587 }
588                                                   588 
589 impl<'a, T: ?Sized + ListItem<ID>, const ID: u    589 impl<'a, T: ?Sized + ListItem<ID>, const ID: u64> Cursor<'a, T, ID> {
590     /// Access the current element of this cur    590     /// Access the current element of this cursor.
591     pub fn current(&self) -> ArcBorrow<'_, T>     591     pub fn current(&self) -> ArcBorrow<'_, T> {
592         // SAFETY: The `current` pointer point    592         // SAFETY: The `current` pointer points a value in the list.
593         let me = unsafe { T::view_value(ListLi    593         let me = unsafe { T::view_value(ListLinks::from_fields(self.current)) };
594         // SAFETY:                                594         // SAFETY:
595         // * All values in a list are stored i    595         // * All values in a list are stored in an `Arc`.
596         // * The value cannot be removed from     596         // * The value cannot be removed from the list for the duration of the lifetime annotated
597         //   on the returned `ArcBorrow`, beca    597         //   on the returned `ArcBorrow`, because removing it from the list would require mutable
598         //   access to the cursor or the list.    598         //   access to the cursor or the list. However, the `ArcBorrow` holds an immutable borrow
599         //   on the cursor, which in turn hold    599         //   on the cursor, which in turn holds a mutable borrow on the list, so any such
600         //   mutable access requires first rel    600         //   mutable access requires first releasing the immutable borrow on the cursor.
601         // * Values in a list never have a `Un    601         // * Values in a list never have a `UniqueArc` reference, because the list has a `ListArc`
602         //   reference, and `UniqueArc` refere    602         //   reference, and `UniqueArc` references must be unique.
603         unsafe { ArcBorrow::from_raw(me) }        603         unsafe { ArcBorrow::from_raw(me) }
604     }                                             604     }
605                                                   605 
606     /// Move the cursor to the next element.      606     /// Move the cursor to the next element.
607     pub fn next(self) -> Option<Cursor<'a, T,     607     pub fn next(self) -> Option<Cursor<'a, T, ID>> {
608         // SAFETY: The `current` field is alwa    608         // SAFETY: The `current` field is always in a list.
609         let next = unsafe { (*self.current).ne    609         let next = unsafe { (*self.current).next };
610                                                   610 
611         if next == self.list.first {              611         if next == self.list.first {
612             None                                  612             None
613         } else {                                  613         } else {
614             // INVARIANT: Since `self.current`    614             // INVARIANT: Since `self.current` is in the `list`, its `next` pointer is also in the
615             // `list`.                            615             // `list`.
616             Some(Cursor {                         616             Some(Cursor {
617                 current: next,                    617                 current: next,
618                 list: self.list,                  618                 list: self.list,
619             })                                    619             })
620         }                                         620         }
621     }                                             621     }
622                                                   622 
623     /// Move the cursor to the previous elemen    623     /// Move the cursor to the previous element.
624     pub fn prev(self) -> Option<Cursor<'a, T,     624     pub fn prev(self) -> Option<Cursor<'a, T, ID>> {
625         // SAFETY: The `current` field is alwa    625         // SAFETY: The `current` field is always in a list.
626         let prev = unsafe { (*self.current).pr    626         let prev = unsafe { (*self.current).prev };
627                                                   627 
628         if self.current == self.list.first {      628         if self.current == self.list.first {
629             None                                  629             None
630         } else {                                  630         } else {
631             // INVARIANT: Since `self.current`    631             // INVARIANT: Since `self.current` is in the `list`, its `prev` pointer is also in the
632             // `list`.                            632             // `list`.
633             Some(Cursor {                         633             Some(Cursor {
634                 current: prev,                    634                 current: prev,
635                 list: self.list,                  635                 list: self.list,
636             })                                    636             })
637         }                                         637         }
638     }                                             638     }
639                                                   639 
640     /// Remove the current element from the li    640     /// Remove the current element from the list.
641     pub fn remove(self) -> ListArc<T, ID> {       641     pub fn remove(self) -> ListArc<T, ID> {
642         // SAFETY: The `current` pointer alway    642         // SAFETY: The `current` pointer always points at a member of the list.
643         unsafe { self.list.remove_internal(sel    643         unsafe { self.list.remove_internal(self.current) }
644     }                                             644     }
645 }                                                 645 }
646                                                   646 
647 impl<'a, T: ?Sized + ListItem<ID>, const ID: u    647 impl<'a, T: ?Sized + ListItem<ID>, const ID: u64> FusedIterator for Iter<'a, T, ID> {}
648                                                   648 
649 impl<'a, T: ?Sized + ListItem<ID>, const ID: u    649 impl<'a, T: ?Sized + ListItem<ID>, const ID: u64> IntoIterator for &'a List<T, ID> {
650     type IntoIter = Iter<'a, T, ID>;              650     type IntoIter = Iter<'a, T, ID>;
651     type Item = ArcBorrow<'a, T>;                 651     type Item = ArcBorrow<'a, T>;
652                                                   652 
653     fn into_iter(self) -> Iter<'a, T, ID> {       653     fn into_iter(self) -> Iter<'a, T, ID> {
654         self.iter()                               654         self.iter()
655     }                                             655     }
656 }                                                 656 }
657                                                   657 
658 /// An owning iterator into a [`List`].           658 /// An owning iterator into a [`List`].
659 pub struct IntoIter<T: ?Sized + ListItem<ID>,     659 pub struct IntoIter<T: ?Sized + ListItem<ID>, const ID: u64 = 0> {
660     list: List<T, ID>,                            660     list: List<T, ID>,
661 }                                                 661 }
662                                                   662 
663 impl<T: ?Sized + ListItem<ID>, const ID: u64>     663 impl<T: ?Sized + ListItem<ID>, const ID: u64> Iterator for IntoIter<T, ID> {
664     type Item = ListArc<T, ID>;                   664     type Item = ListArc<T, ID>;
665                                                   665 
666     fn next(&mut self) -> Option<ListArc<T, ID    666     fn next(&mut self) -> Option<ListArc<T, ID>> {
667         self.list.pop_front()                     667         self.list.pop_front()
668     }                                             668     }
669 }                                                 669 }
670                                                   670 
671 impl<T: ?Sized + ListItem<ID>, const ID: u64>     671 impl<T: ?Sized + ListItem<ID>, const ID: u64> FusedIterator for IntoIter<T, ID> {}
672                                                   672 
673 impl<T: ?Sized + ListItem<ID>, const ID: u64>     673 impl<T: ?Sized + ListItem<ID>, const ID: u64> DoubleEndedIterator for IntoIter<T, ID> {
674     fn next_back(&mut self) -> Option<ListArc<    674     fn next_back(&mut self) -> Option<ListArc<T, ID>> {
675         self.list.pop_back()                      675         self.list.pop_back()
676     }                                             676     }
677 }                                                 677 }
678                                                   678 
679 impl<T: ?Sized + ListItem<ID>, const ID: u64>     679 impl<T: ?Sized + ListItem<ID>, const ID: u64> IntoIterator for List<T, ID> {
680     type IntoIter = IntoIter<T, ID>;              680     type IntoIter = IntoIter<T, ID>;
681     type Item = ListArc<T, ID>;                   681     type Item = ListArc<T, ID>;
682                                                   682 
683     fn into_iter(self) -> IntoIter<T, ID> {       683     fn into_iter(self) -> IntoIter<T, ID> {
684         IntoIter { list: self }                   684         IntoIter { list: self }
685     }                                             685     }
686 }                                                 686 }
                                                      

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