clone.rs source code [crates/core/src/clone.rs]

1	//! The `Clone` trait for types that cannot be 'implicitly copied'.
2	//!
3	//! In Rust, some simple types are "implicitly copyable" and when you
4	//! assign them or pass them as arguments, the receiver will get a copy,
5	//! leaving the original value in place. These types do not require
6	//! allocation to copy and do not have finalizers (i.e., they do not
7	//! contain owned boxes or implement [`Drop`]), so the compiler considers
8	//! them cheap and safe to copy. For other types copies must be made
9	//! explicitly, by convention implementing the [`Clone`] trait and calling
10	//! the [`clone`] method.
11	//!
12	//! [`clone`]: Clone::clone
13	//!
14	//! Basic usage example:
15	//!
16	//! ```
17	//! let s = String::new(); // String type implements Clone
18	//! let copy = s.clone(); // so we can clone it
19	//! ```
20	//!
21	//! To easily implement the Clone trait, you can also use
22	//! `#[derive(Clone)]`. Example:
23	//!
24	//! ```
25	//! #[derive(Clone)] // we add the Clone trait to Morpheus struct
26	//! struct Morpheus {
27	//! blue_pill: f32,
28	//! red_pill: i64,
29	//! }
30	//!
31	//! fn main() {
32	//! let f = Morpheus { blue_pill: `0.0`, red_pill: `0` };
33	//! let copy = f.clone(); // and now we can clone it!
34	//! }
35	//! ```
36
37	#![stable(feature = "rust1", since = "1.0.0")]
38
39	mod uninit;
40
41	/// A common trait for the ability to explicitly duplicate an object.
42	///
43	/// Differs from [`Copy`] in that [`Copy`] is implicit and an inexpensive bit-wise copy, while
44	/// `Clone` is always explicit and may or may not be expensive. In order to enforce
45	/// these characteristics, Rust does not allow you to reimplement [`Copy`], but you
46	/// may reimplement `Clone` and run arbitrary code.
47	///
48	/// Since `Clone` is more general than [`Copy`], you can automatically make anything
49	/// [`Copy`] be `Clone` as well.
50	///
51	/// ## Derivable
52	///
53	/// This trait can be used with `#[derive]` if all fields are `Clone`. The `derive`d
54	/// implementation of [`Clone`] calls [`clone`] on each field.
55	///
56	/// [`clone`]: Clone::clone
57	///
58	/// For a generic struct, `#[derive]` implements `Clone` conditionally by adding bound `Clone` on
59	/// generic parameters.
60	///
61	/// ```
62	/// // `derive` implements Clone for Reading<T> when T is Clone.
63	/// #[derive(Clone)]
64	/// struct Reading<T> {
65	/// frequency: T,
66	/// }
67	/// ```
68	///
69	/// ## How can I implement `Clone`?
70	///
71	/// Types that are [`Copy`] should have a trivial implementation of `Clone`. More formally:
72	/// if `T: Copy`, `x: T`, and `y: &T`, then `let x = y.clone();` is equivalent to `let x = y;`.*
73	/// Manual implementations should be careful to uphold this invariant; however, unsafe code
74	/// must not rely on it to ensure memory safety.
75	///
76	/// An example is a generic struct holding a function pointer. In this case, the
77	/// implementation of `Clone` cannot be `derive`d, but can be implemented as:
78	///
79	/// ```
80	/// struct Generate<T>(fn() -> T);
81	///
82	/// impl<T> Copy for Generate<T> {}
83	///
84	/// impl<T> Clone for Generate<T> {
85	/// fn clone(&self) -> Self {
86	/// *self
87	/// }
88	/// }
89	/// ```
90	///
91	/// If we `derive`:
92	///
93	/// ```
94	/// #[derive(Copy, Clone)]
95	/// struct Generate<T>(fn() -> T);
96	/// ```
97	///
98	/// the auto-derived implementations will have unnecessary `T: Copy` and `T: Clone` bounds:
99	///
100	/// ```
101	/// # struct Generate<T>(fn() -> T);
102	///
103	/// // Automatically derived
104	/// impl<T: Copy> Copy for Generate<T> { }
105	///
106	/// // Automatically derived
107	/// impl<T: Clone> Clone for Generate<T> {
108	/// fn clone(&self) -> Generate<T> {
109	/// Generate(Clone::clone(&self.0))
110	/// }
111	/// }
112	/// ```
113	///
114	/// The bounds are unnecessary because clearly the function itself should be
115	/// copy- and cloneable even if its return type is not:
116	///
117	/// ```compile_fail,E0599
118	/// #[derive(Copy, Clone)]
119	/// struct Generate<T>(fn() -> T);
120	///
121	/// struct NotCloneable;
122	///
123	/// fn generate_not_cloneable() -> NotCloneable {
124	/// NotCloneable
125	/// }
126	///
127	/// Generate(generate_not_cloneable).clone(); // error: trait bounds were not satisfied
128	/// // Note: With the manual implementations the above line will compile.
129	/// ```
130	///
131	/// ## Additional implementors
132	///
133	/// In addition to the [implementors listed below][impls],
134	/// the following types also implement `Clone`:
135	///
136	/// Function item types (i.e., the distinct types defined for each function)*
137	/// Function pointer types (e.g., `fn() -> i32`)*
138	/// Closure types, if they capture no value from the environment*
139	/// or if all such captured values implement `Clone` themselves.
140	/// Note that variables captured by shared reference always implement `Clone`
141	/// (even if the referent doesn't),
142	/// while variables captured by mutable reference never implement `Clone`.
143	///
144	/// [impls]: #implementors
145	#[stable(feature = "rust1", since = "1.0.0")]
146	#[lang = "clone"]
147	#[rustc_diagnostic_item = "Clone"]
148	#[rustc_trivial_field_reads]
149	pub trait Clone: Sized {
150	/// Returns a copy of the value.
151	///
152	/// # Examples
153	///
154	/// ```
155	/// # #![allow(noop_method_call)]
156	/// let hello = "Hello"; // &str implements Clone
157	///
158	/// assert_eq!("Hello", hello.clone());
159	/// ```
160	#[stable(feature = "rust1", since = "1.0.0")]
161	#[must_use = "cloning is often expensive and is not expected to have side effects"]
162	// Clone::clone is special because the compiler generates MIR to implement it for some types.
163	// See InstanceKind::CloneShim.
164	#[lang = "clone_fn"]
165	fn clone(&self) -> Self;
166
167	/// Performs copy-assignment from `source`.
168	///
169	/// `a.clone_from(&b)` is equivalent to `a = b.clone()` in functionality,
170	/// but can be overridden to reuse the resources of `a` to avoid unnecessary
171	/// allocations.
172	#[inline]
173	#[stable(feature = "rust1", since = "1.0.0")]
174	fn clone_from(&mut self, source: &Self) {
175	*self = source.clone()
176	}
177	}
178
179	/// Derive macro generating an impl of the trait `Clone`.
180	#[rustc_builtin_macro]
181	#[stable(feature = "builtin_macro_prelude", since = "1.38.0")]
182	#[allow_internal_unstable(core_intrinsics, derive_clone_copy)]
183	pub macro Clone($item:item) {
184	/ compiler built-in /
185	}
186
187	/// Trait for objects whose [`Clone`] impl is lightweight (e.g. reference-counted)
188	///
189	/// Cloning an object implementing this trait should in general:
190	/// - be O(1) (constant) time regardless of the amount of data managed by the object,
191	/// - not require a memory allocation,
192	/// - not require copying more than roughly 64 bytes (a typical cache line size),
193	/// - not block the current thread,
194	/// - not have any semantic side effects (e.g. allocating a file descriptor), and
195	/// - not have overhead larger than a couple of atomic operations.
196	///
197	/// The `UseCloned` trait does not provide a method; instead, it indicates that
198	/// `Clone::clone` is lightweight, and allows the use of the `.use` syntax.
199	///
200	/// ## .use postfix syntax
201	///
202	/// Values can be `.use`d by adding `.use` postfix to the value you want to use.
203	///
204	/// ```ignore (this won't work until we land use)
205	/// fn foo(f: Foo) {
206	/// // if `Foo` implements `Copy` f would be copied into x.
207	/// // if `Foo` implements `UseCloned` f would be cloned into x.
208	/// // otherwise f would be moved into x.
209	/// let x = f.use;
210	/// // ...
211	/// }
212	/// ```
213	///
214	/// ## use closures
215	///
216	/// Use closures allow captured values to be automatically used.
217	/// This is similar to have a closure that you would call `.use` over each captured value.
218	#[unstable(feature = "ergonomic_clones", issue = "132290")]
219	#[cfg_attr(not(bootstrap), lang = "use_cloned")]
220	pub trait UseCloned: Clone {
221	// Empty.
222	}
223
224	macro_rules! impl_use_cloned {
225	($($t:ty)*) => {
226	$(
227	#[unstable(feature = "ergonomic_clones", issue = "132290")]
228	impl UseCloned for $t {}
229	)*
230	}
231	}
232
233	impl_use_cloned! {
234	usize u8 u16 u32 u64 u128
235	isize i8 i16 i32 i64 i128
236	f16 f32 f64 f128
237	bool char
238	}
239
240	// FIXME(aburka): these structs are used solely by #[derive] to
241	// assert that every component of a type implements Clone or Copy.
242	//
243	// These structs should never appear in user code.
244	#[doc(hidden)]
245	#[allow(missing_debug_implementations)]
246	#[unstable(
247	feature = "derive_clone_copy",
248	reason = "deriving hack, should not be public",
249	issue = "none"
250	)]
251	pub struct AssertParamIsClone<T: Clone + ?Sized> {
252	_field: crate::marker::PhantomData<T>,
253	}
254	#[doc(hidden)]
255	#[allow(missing_debug_implementations)]
256	#[unstable(
257	feature = "derive_clone_copy",
258	reason = "deriving hack, should not be public",
259	issue = "none"
260	)]
261	pub struct AssertParamIsCopy<T: Copy + ?Sized> {
262	_field: crate::marker::PhantomData<T>,
263	}
264
265	/// A generalization of [`Clone`] to [dynamically-sized types][DST] stored in arbitrary containers.
266	///
267	/// This trait is implemented for all types implementing [`Clone`], [slices](slice) of all
268	/// such types, and other dynamically-sized types in the standard library.
269	/// You may also implement this trait to enable cloning custom DSTs
270	/// (structures containing dynamically-sized fields), or use it as a supertrait to enable
271	/// cloning a [trait object].
272	///
273	/// This trait is normally used via operations on container types which support DSTs,
274	/// so you should not typically need to call `.clone_to_uninit()` explicitly except when
275	/// implementing such a container or otherwise performing explicit management of an allocation,
276	/// or when implementing `CloneToUninit` itself.
277	///
278	/// # Safety
279	///
280	/// Implementations must ensure that when `.clone_to_uninit(dest)` returns normally rather than
281	/// panicking, it always leaves `dest` initialized as a valid value of type `Self`.*
282	///
283	/// # Examples
284	///
285	// FIXME(#126799): when `Box::clone` allows use of `CloneToUninit`, rewrite these examples with it
286	// since `Rc` is a distraction.
287	///
288	/// If you are defining a trait, you can add `CloneToUninit` as a supertrait to enable cloning of
289	/// `dyn` values of your trait:
290	///
291	/// ```
292	/// #![feature(clone_to_uninit)]
293	/// use std::rc::Rc;
294	///
295	/// trait Foo: std::fmt::Debug + std::clone::CloneToUninit {
296	/// fn modify(&mut self);
297	/// fn value(&self) -> i32;
298	/// }
299	///
300	/// impl Foo for i32 {
301	/// fn modify(&mut self) {
302	/// self = `10`;
303	/// }
304	/// fn value(&self) -> i32 {
305	/// *self
306	/// }
307	/// }
308	///
309	/// let first: Rc<dyn Foo> = Rc::new(`1234`);
310	///
311	/// let mut second = first.clone();
312	/// Rc::make_mut(&mut second).modify(); // make_mut() will call clone_to_uninit()
313	///
314	/// assert_eq!(first.value(), `1234`);
315	/// assert_eq!(second.value(), `12340`);
316	/// ```
317	///
318	/// The following is an example of implementing `CloneToUninit` for a custom DST.
319	/// (It is essentially a limited form of what `derive(CloneToUninit)` would do,
320	/// if such a derive macro existed.)
321	///
322	/// ```
323	/// #![feature(clone_to_uninit)]
324	/// use std::clone::CloneToUninit;
325	/// use std::mem::offset_of;
326	/// use std::rc::Rc;
327	///
328	/// #[derive(PartialEq)]
329	/// struct MyDst<T: ?Sized> {
330	/// label: String,
331	/// contents: T,
332	/// }
333	///
334	/// unsafe impl<T: ?Sized + CloneToUninit> CloneToUninit for MyDst<T> {
335	/// unsafe fn clone_to_uninit(&self, dest: *mut u8) {
336	/// // The offset of `self.contents` is dynamic because it depends on the alignment of T
337	/// // which can be dynamic (if `T = dyn SomeTrait`). Therefore, we have to obtain it
338	/// // dynamically by examining `self`, rather than using `offset_of!`.
339	/// //
340	/// // SAFETY: `self` by definition points somewhere before `&self.contents` in the same
341	/// // allocation.
342	/// let offset_of_contents = unsafe {
343	/// (&raw const self.contents).byte_offset_from_unsigned(self)
344	/// };
345	///
346	/// // Clone the sized* fields of `self` (just one, in this example).*
347	/// // (By cloning this first and storing it temporarily in a local variable, we avoid
348	/// // leaking it in case of any panic, using the ordinary automatic cleanup of local
349	/// // variables. Such a leak would be sound, but undesirable.)
350	/// let label = self.label.clone();
351	///
352	/// // SAFETY: The caller must provide a `dest` such that these field offsets are valid
353	/// // to write to.
354	/// unsafe {
355	/// // Clone the unsized field directly from `self` to `dest`.
356	/// self.contents.clone_to_uninit(dest.add(offset_of_contents));
357	///
358	/// // Now write all the sized fields.
359	/// //
360	/// // Note that we only do this once all of the clone() and clone_to_uninit() calls
361	/// // have completed, and therefore we know that there are no more possible panics;
362	/// // this ensures no memory leaks in case of panic.
363	/// dest.add(offset_of!(Self, label)).cast::<String>().write(label);
364	/// }
365	/// // All fields of the struct have been initialized; therefore, the struct is initialized,
366	/// // and we have satisfied our `unsafe impl CloneToUninit` obligations.
367	/// }
368	/// }
369	///
370	/// fn main() {
371	/// // Construct MyDst<[u8; 4]>, then coerce to MyDst<[u8]>.
372	/// let first: Rc<MyDst<[u8]>> = Rc::new(MyDst {
373	/// label: String::from("hello"),
374	/// contents: [`1`, `2`, `3`, `4`],
375	/// });
376	///
377	/// let mut second = first.clone();
378	/// // make_mut() will call clone_to_uninit().
379	/// for elem in Rc::make_mut(&mut second).contents.iter_mut() {
380	/// elem = `10`;
381	/// }
382	///
383	/// assert_eq!(first.contents, [`1`, `2`, `3`, `4`]);
384	/// assert_eq!(second.contents, [`10`, `20`, `30`, `40`]);
385	/// assert_eq!(second.label, "hello");
386	/// }
387	/// ```
388	///
389	/// # See Also
390	///
391	/// * [`Clone::clone_from`] is a safe function which may be used instead when [`Self: Sized`](Sized)
392	/// and the destination is already initialized; it may be able to reuse allocations owned by
393	/// the destination, whereas `clone_to_uninit` cannot, since its destination is assumed to be
394	/// uninitialized.
395	/// [`ToOwned`], which allocates a new destination container.*
396	///
397	/// [`ToOwned`]: ../../std/borrow/trait.ToOwned.html
398	/// [DST]: https://doc.rust-lang.org/reference/dynamically-sized-types.html
399	/// [trait object]: https://doc.rust-lang.org/reference/types/trait-object.html
400	#[unstable(feature = "clone_to_uninit", issue = "126799")]
401	pub unsafe trait CloneToUninit {
402	/// Performs copy-assignment from `self` to `dest`.
403	///
404	/// This is analogous to `std::ptr::write(dest.cast(), self.clone())`,
405	/// except that `Self` may be a dynamically-sized type ([`!Sized`](Sized)).
406	///
407	/// Before this function is called, `dest` may point to uninitialized memory.
408	/// After this function is called, `dest` will point to initialized memory; it will be
409	/// sound to create a `&Self` reference from the pointer with the [pointer metadata]
410	/// from `self`.
411	///
412	/// # Safety
413	///
414	/// Behavior is undefined if any of the following conditions are violated:
415	///
416	/// `dest` must be [valid] for writes for `size_of_val(self)` bytes.*
417	/// `dest` must be properly aligned to `align_of_val(self)`.*
418	///
419	/// [valid]: crate::ptr#safety
420	/// [pointer metadata]: crate::ptr::metadata()
421	///
422	/// # Panics
423	///
424	/// This function may panic. (For example, it might panic if memory allocation for a clone
425	/// of a value owned by `self` fails.)
426	/// If the call panics, then `dest` should be treated as uninitialized memory; it must not be*
427	/// read or dropped, because even if it was previously valid, it may have been partially
428	/// overwritten.
429	///
430	/// The caller may wish to to take care to deallocate the allocation pointed to by `dest`,
431	/// if applicable, to avoid a memory leak (but this is not a requirement).
432	///
433	/// Implementors should avoid leaking values by, upon unwinding, dropping all component values
434	/// that might have already been created. (For example, if a `[Foo]` of length 3 is being
435	/// cloned, and the second of the three calls to `Foo::clone()` unwinds, then the first `Foo`
436	/// cloned should be dropped.)
437	unsafe fn clone_to_uninit(&self, dest: *mut u8);
438	}
439
440	#[unstable(feature = "clone_to_uninit", issue = "126799")]
441	unsafe impl<T: Clone> CloneToUninit for T {
442	#[inline]
443	unsafe fn clone_to_uninit(&self, dest: *mut u8) {
444	// SAFETY: we're calling a specialization with the same contract
445	unsafe { <T as self::uninit::CopySpec>::clone_one(self, dst:dest.cast::<T>()) }
446	}
447	}
448
449	#[unstable(feature = "clone_to_uninit", issue = "126799")]
450	unsafe impl<T: Clone> CloneToUninit for [T] {
451	#[inline]
452	#[cfg_attr(debug_assertions, track_caller)]
453	unsafe fn clone_to_uninit(&self, dest: *mut u8) {
454	let dest: *mut [T] = dest.with_metadata_of(self);
455	// SAFETY: we're calling a specialization with the same contract
456	unsafe { <T as self::uninit::CopySpec>::clone_slice(self, dst:dest) }
457	}
458	}
459
460	#[unstable(feature = "clone_to_uninit", issue = "126799")]
461	unsafe impl CloneToUninit for str {
462	#[inline]
463	#[cfg_attr(debug_assertions, track_caller)]
464	unsafe fn clone_to_uninit(&self, dest: *mut u8) {
465	// SAFETY: str is just a [u8] with UTF-8 invariant
466	unsafe { self.as_bytes().clone_to_uninit(dest) }
467	}
468	}
469
470	#[unstable(feature = "clone_to_uninit", issue = "126799")]
471	unsafe impl CloneToUninit for crate::ffi::CStr {
472	#[cfg_attr(debug_assertions, track_caller)]
473	unsafe fn clone_to_uninit(&self, dest: *mut u8) {
474	// SAFETY: For now, CStr is just a #[repr(trasnsparent)] [c_char] with some invariants.
475	// And we can cast [c_char] to [u8] on all supported platforms (see: to_bytes_with_nul).
476	// The pointer metadata properly preserves the length (so NUL is also copied).
477	// See: `cstr_metadata_is_length_with_nul` in tests.
478	unsafe { self.to_bytes_with_nul().clone_to_uninit(dest) }
479	}
480	}
481
482	#[unstable(feature = "bstr", issue = "134915")]
483	unsafe impl CloneToUninit for crate::bstr::ByteStr {
484	#[inline]
485	#[cfg_attr(debug_assertions, track_caller)]
486	unsafe fn clone_to_uninit(&self, dst: *mut u8) {
487	// SAFETY: ByteStr is a `#[repr(transparent)]` wrapper around `[u8]`
488	unsafe { self.as_bytes().clone_to_uninit(dest:dst) }
489	}
490	}
491
492	/// Implementations of `Clone` for primitive types.
493	///
494	/// Implementations that cannot be described in Rust
495	/// are implemented in `traits::SelectionContext::copy_clone_conditions()`
496	/// in `rustc_trait_selection`.
497	mod impls {
498	macro_rules! impl_clone {
499	($($t:ty)*) => {
500	$(
501	#[stable(feature = "rust1", since = "1.0.0")]
502	impl Clone for $t {
503	#[inline(always)]
504	fn clone(&self) -> Self {
505	*self
506	}
507	}
508	)*
509	}
510	}
511
512	impl_clone! {
513	usize u8 u16 u32 u64 u128
514	isize i8 i16 i32 i64 i128
515	f16 f32 f64 f128
516	bool char
517	}
518
519	#[unstable(feature = "never_type", issue = "35121")]
520	impl Clone for ! {
521	#[inline]
522	fn clone(&self) -> Self {
523	*self
524	}
525	}
526
527	#[stable(feature = "rust1", since = "1.0.0")]
528	impl<T: ?Sized> Clone for *const T {
529	#[inline(always)]
530	fn clone(&self) -> Self {
531	*self
532	}
533	}
534
535	#[stable(feature = "rust1", since = "1.0.0")]
536	impl<T: ?Sized> Clone for *mut T {
537	#[inline(always)]
538	fn clone(&self) -> Self {
539	*self
540	}
541	}
542
543	/// Shared references can be cloned, but mutable references cannot!
544	#[stable(feature = "rust1", since = "1.0.0")]
545	impl<T: ?Sized> Clone for &T {
546	#[inline(always)]
547	#[rustc_diagnostic_item = "noop_method_clone"]
548	fn clone(&self) -> Self {
549	*self
550	}
551	}
552
553	/// Shared references can be cloned, but mutable references cannot!
554	#[stable(feature = "rust1", since = "1.0.0")]
555	impl<T: ?Sized> !Clone for &mut T {}
556	}
557