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% Drop Check
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We have seen how lifetimes provide us some fairly simple rules for ensuring
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that we never read dangling references. However up to this point we have only ever
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interacted with the *outlives* relationship in an inclusive manner. That is,
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when we talked about `'a: 'b`, it was ok for `'a` to live *exactly* as long as
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`'b`. At first glance, this seems to be a meaningless distinction. Nothing ever
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gets dropped at the same time as another, right? This is why we used the
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following desugarring of `let` statements:
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```rust,ignore
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let x;
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let y;
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```
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```rust,ignore
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{
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let x;
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{
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let y;
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}
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}
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```
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Each creates its own scope, clearly establishing that one drops before the
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other. However, what if we do the following?
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```rust,ignore
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let (x, y) = (vec![], vec![]);
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```
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Does either value strictly outlive the other? The answer is in fact *no*,
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neither value strictly outlives the other. Of course, one of x or y will be
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dropped before the other, but the actual order is not specified. Tuples aren't
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special in this regard; composite structures just don't guarantee their
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destruction order as of Rust 1.0.
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We *could* specify this for the fields of built-in composites like tuples and
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structs. However, what about something like Vec? Vec has to manually drop its
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elements via pure-library code. In general, anything that implements Drop has
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a chance to fiddle with its innards during its final death knell. Therefore
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the compiler can't sufficiently reason about the actual destruction order
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of the contents of any type that implements Drop.
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So why do we care? We care because if the type system isn't careful, it could
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accidentally make dangling pointers. Consider the following simple program:
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```rust
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struct Inspector<'a>(&'a u8);
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fn main() {
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let (inspector, days);
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days = Box::new(1);
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inspector = Inspector(&days);
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}
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```
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This program is totally sound and compiles today. The fact that `days` does
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not *strictly* outlive `inspector` doesn't matter. As long as the `inspector`
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is alive, so is days.
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However if we add a destructor, the program will no longer compile!
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```rust,ignore
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struct Inspector<'a>(&'a u8);
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impl<'a> Drop for Inspector<'a> {
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fn drop(&mut self) {
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println!("I was only {} days from retirement!", self.0);
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}
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}
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fn main() {
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let (inspector, days);
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days = Box::new(1);
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inspector = Inspector(&days);
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// Let's say `days` happens to get dropped first.
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// Then when Inspector is dropped, it will try to read free'd memory!
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}
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```
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```text
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<anon>:12:28: 12:32 error: `days` does not live long enough
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<anon>:12 inspector = Inspector(&days);
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^~~~
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<anon>:9:11: 15:2 note: reference must be valid for the block at 9:10...
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<anon>:9 fn main() {
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<anon>:10 let (inspector, days);
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<anon>:11 days = Box::new(1);
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<anon>:12 inspector = Inspector(&days);
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<anon>:13 // Let's say `days` happens to get dropped first.
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<anon>:14 // Then when Inspector is dropped, it will try to read free'd memory!
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...
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<anon>:10:27: 15:2 note: ...but borrowed value is only valid for the block suffix following statement 0 at 10:26
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<anon>:10 let (inspector, days);
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<anon>:11 days = Box::new(1);
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<anon>:12 inspector = Inspector(&days);
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<anon>:13 // Let's say `days` happens to get dropped first.
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<anon>:14 // Then when Inspector is dropped, it will try to read free'd memory!
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<anon>:15 }
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```
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Implementing Drop lets the Inspector execute some arbitrary code during its
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death. This means it can potentially observe that types that are supposed to
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live as long as it does actually were destroyed first.
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Interestingly, only generic types need to worry about this. If they aren't
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generic, then the only lifetimes they can harbor are `'static`, which will truly
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live *forever*. This is why this problem is referred to as *sound generic drop*.
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Sound generic drop is enforced by the *drop checker*. As of this writing, some
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of the finer details of how the drop checker validates types is totally up in
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the air. However The Big Rule is the subtlety that we have focused on this whole
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section:
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**For a generic type to soundly implement drop, its generics arguments must
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strictly outlive it.**
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Obeying this rule is (usually) necessary to satisfy the borrow
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checker; obeying it is sufficient but not necessary to be
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sound. That is, if your type obeys this rule then it's definitely
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sound to drop.
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The reason that it is not always necessary to satisfy the above rule
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is that some Drop implementations will not access borrowed data even
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though their type gives them the capability for such access.
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For example, this variant of the above `Inspector` example will never
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accessed borrowed data:
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```rust,ignore
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struct Inspector<'a>(&'a u8, &'static str);
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impl<'a> Drop for Inspector<'a> {
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fn drop(&mut self) {
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println!("Inspector(_, {}) knows when *not* to inspect.", self.1);
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}
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}
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fn main() {
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let (inspector, days);
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days = Box::new(1);
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inspector = Inspector(&days, "gadget");
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// Let's say `days` happens to get dropped first.
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// Even when Inspector is dropped, its destructor will not access the
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// borrowed `days`.
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}
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```
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Likewise, this variant will also never access borrowed data:
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```rust,ignore
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use std::fmt;
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struct Inspector<T: fmt::Display>(T, &'static str);
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impl<T: fmt::Display> Drop for Inspector<T> {
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fn drop(&mut self) {
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println!("Inspector(_, {}) knows when *not* to inspect.", self.1);
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}
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}
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fn main() {
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let (inspector, days): (Inspector<&u8>, Box<u8>);
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days = Box::new(1);
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inspector = Inspector(&days, "gadget");
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// Let's say `days` happens to get dropped first.
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// Even when Inspector is dropped, its destructor will not access the
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// borrowed `days`.
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}
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```
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However, *both* of the above variants are rejected by the borrow
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checker during the analysis of `fn main`, saying that `days` does not
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live long enough.
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The reason is that the borrow checking analysis of `main` does not
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know about the internals of each Inspector's Drop implementation. As
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far as the borrow checker knows while it is analyzing `main`, the body
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of an inspector's destructor might access that borrowed data.
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Therefore, the drop checker forces all borrowed data in a value to
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strictly outlive that value.
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# An Escape Hatch
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The precise rules that govern drop checking may be less restrictive in
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the future.
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The current analysis is deliberately conservative; forcing all
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borrowed data in a value to outlive that value is certainly sound.
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Future versions of the language may improve its precision (i.e. to
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reduce the number of cases where sound code is rejected as unsafe).
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In the meantime, there is an unstable attribute that one can use to
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assert (unsafely) that a generic type's destructor is *guaranteed* to
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not access any expired data, even if its type gives it the capability
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to do so.
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That attribute is called `unsafe_destructor_blind_to_params`.
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To deploy it on the Inspector example from above, we would write:
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```rust,ignore
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struct Inspector<'a>(&'a u8, &'static str);
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impl<'a> Drop for Inspector<'a> {
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#[unsafe_destructor_blind_to_params]
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fn drop(&mut self) {
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println!("Inspector(_, {}) knows when *not* to inspect.", self.1);
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}
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}
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```
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This attribute has the word `unsafe` in it because the compiler is not
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checking the implicit assertion that no potentially expired data
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(e.g. `self.0` above) is accessed.
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It is sometimes obvious that no such access can occur, like the case above.
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However, when dealing with a generic type parameter, such access can
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occur indirectly. Examples of such indirect access are:
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* invoking a callback,
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* via a trait method call.
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(Future changes to the language, such as impl specialization, may add
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other avenues for such indirect access.)
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Here is an example of invoking a callback:
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|
```rust,ignore
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struct Inspector<T>(T, &'static str, Box<for <'r> fn(&'r T) -> String>);
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impl<T> Drop for Inspector<T> {
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fn drop(&mut self) {
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// The `self.2` call could access a borrow e.g. if `T` is `&'a _`.
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|
println!("Inspector({}, {}) unwittingly inspects expired data.",
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(self.2)(&self.0), self.1);
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}
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}
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```
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Here is an example of a trait method call:
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|
```rust,ignore
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use std::fmt;
|
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|
|
|
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|
|
struct Inspector<T: fmt::Display>(T, &'static str);
|
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|
|
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|
impl<T: fmt::Display> Drop for Inspector<T> {
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|
fn drop(&mut self) {
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|
// There is a hidden call to `<T as Display>::fmt` below, which
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|
// could access a borrow e.g. if `T` is `&'a _`
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|
println!("Inspector({}, {}) unwittingly inspects expired data.",
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self.0, self.1);
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}
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}
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|
```
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And of course, all of these accesses could be further hidden within
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|
some other method invoked by the destructor, rather than being written
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|
directly within it.
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In all of the above cases where the `&'a u8` is accessed in the
|
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|
|
destructor, adding the `#[unsafe_destructor_blind_to_params]`
|
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|
|
attribute makes the type vulnerable to misuse that the borrower
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|
checker will not catch, inviting havoc. It is better to avoid adding
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|
the attribute.
|
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|
|
|
|
|
|
# Is that all about drop checker?
|
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|
|
|
|
|
|
It turns out that when writing unsafe code, we generally don't need to
|
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|
|
worry at all about doing the right thing for the drop checker. However there
|
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|
|
is one special case that you need to worry about, which we will look at in
|
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|
|
the next section.
|
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|