9f60e7c306
Closes #11362.
664 lines
25 KiB
Markdown
664 lines
25 KiB
Markdown
% The Rust References and Lifetimes Guide
|
||
|
||
# Introduction
|
||
|
||
References are one of the more flexible and powerful tools available in
|
||
Rust. A reference can point anywhere: into the managed or exchange
|
||
heap, into the stack, and even into the interior of another data structure. A
|
||
reference is as flexible as a C pointer or C++ reference. However,
|
||
unlike C and C++ compilers, the Rust compiler includes special static checks
|
||
that ensure that programs use references safely. Another advantage of
|
||
references is that they are invisible to the garbage collector, so
|
||
working with references helps reduce the overhead of automatic memory
|
||
management.
|
||
|
||
Despite their complete safety, a reference's representation at runtime
|
||
is the same as that of an ordinary pointer in a C program. They introduce zero
|
||
overhead. The compiler does all safety checks at compile time.
|
||
|
||
Although references have rather elaborate theoretical
|
||
underpinnings (region pointers), the core concepts will be familiar to
|
||
anyone who has worked with C or C++. Therefore, the best way to explain
|
||
how they are used—and their limitations—is probably just to work
|
||
through several examples.
|
||
|
||
# By example
|
||
|
||
References, sometimes known as *borrowed pointers*, are only valid for
|
||
a limited duration. References never claim any kind of ownership
|
||
over the data that they point to: instead, they are used for cases
|
||
where you would like to use data for a short time.
|
||
|
||
As an example, consider a simple struct type `Point`:
|
||
|
||
~~~
|
||
struct Point {x: f64, y: f64}
|
||
~~~
|
||
|
||
We can use this simple definition to allocate points in many different ways. For
|
||
example, in this code, each of these three local variables contains a
|
||
point, but allocated in a different place:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
let on_the_stack : Point = Point {x: 3.0, y: 4.0};
|
||
let managed_box : @Point = @Point {x: 5.0, y: 1.0};
|
||
let owned_box : ~Point = ~Point {x: 7.0, y: 9.0};
|
||
~~~
|
||
|
||
Suppose we wanted to write a procedure that computed the distance between any
|
||
two points, no matter where they were stored. For example, we might like to
|
||
compute the distance between `on_the_stack` and `managed_box`, or between
|
||
`managed_box` and `owned_box`. One option is to define a function that takes
|
||
two arguments of type `Point`—that is, it takes the points by value. But if we
|
||
define it this way, calling the function will cause the points to be
|
||
copied. For points, this is probably not so bad, but often copies are
|
||
expensive. Worse, if the data type contains mutable fields, copying can change
|
||
the semantics of your program in unexpected ways. So we'd like to define a
|
||
function that takes the points by pointer. We can use references to do
|
||
this:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
# fn sqrt(f: f64) -> f64 { 0.0 }
|
||
fn compute_distance(p1: &Point, p2: &Point) -> f64 {
|
||
let x_d = p1.x - p2.x;
|
||
let y_d = p1.y - p2.y;
|
||
sqrt(x_d * x_d + y_d * y_d)
|
||
}
|
||
~~~
|
||
|
||
Now we can call `compute_distance()` in various ways:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
# let on_the_stack : Point = Point{x: 3.0, y: 4.0};
|
||
# let managed_box : @Point = @Point{x: 5.0, y: 1.0};
|
||
# let owned_box : ~Point = ~Point{x: 7.0, y: 9.0};
|
||
# fn compute_distance(p1: &Point, p2: &Point) -> f64 { 0.0 }
|
||
compute_distance(&on_the_stack, managed_box);
|
||
compute_distance(managed_box, owned_box);
|
||
~~~
|
||
|
||
Here, the `&` operator takes the address of the variable
|
||
`on_the_stack`; this is because `on_the_stack` has the type `Point`
|
||
(that is, a struct value) and we have to take its address to get a
|
||
value. We also call this _borrowing_ the local variable
|
||
`on_the_stack`, because we have created an alias: that is, another
|
||
name for the same data.
|
||
|
||
In contrast, we can pass the boxes `managed_box` and `owned_box` to
|
||
`compute_distance` directly. The compiler automatically converts a box like
|
||
`@Point` or `~Point` to a reference like `&Point`. This is another form
|
||
of borrowing: in this case, the caller lends the contents of the managed or
|
||
owned box to the callee.
|
||
|
||
Whenever a caller lends data to a callee, there are some limitations on what
|
||
the caller can do with the original. For example, if the contents of a
|
||
variable have been lent out, you cannot send that variable to another task. In
|
||
addition, the compiler will reject any code that might cause the borrowed
|
||
value to be freed or overwrite its component fields with values of different
|
||
types (I'll get into what kinds of actions those are shortly). This rule
|
||
should make intuitive sense: you must wait for a borrower to return the value
|
||
that you lent it (that is, wait for the reference to go out of scope)
|
||
before you can make full use of it again.
|
||
|
||
# Other uses for the & operator
|
||
|
||
In the previous example, the value `on_the_stack` was defined like so:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
let on_the_stack: Point = Point {x: 3.0, y: 4.0};
|
||
~~~
|
||
|
||
This declaration means that code can only pass `Point` by value to other
|
||
functions. As a consequence, we had to explicitly take the address of
|
||
`on_the_stack` to get a reference. Sometimes however it is more
|
||
convenient to move the & operator into the definition of `on_the_stack`:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
let on_the_stack2: &Point = &Point {x: 3.0, y: 4.0};
|
||
~~~
|
||
|
||
Applying `&` to an rvalue (non-assignable location) is just a convenient
|
||
shorthand for creating a temporary and taking its address. A more verbose
|
||
way to write the same code is:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
let tmp = Point {x: 3.0, y: 4.0};
|
||
let on_the_stack2 : &Point = &tmp;
|
||
~~~
|
||
|
||
# Taking the address of fields
|
||
|
||
As in C, the `&` operator is not limited to taking the address of
|
||
local variables. It can also take the address of fields or
|
||
individual array elements. For example, consider this type definition
|
||
for `rectangle`:
|
||
|
||
~~~
|
||
struct Point {x: f64, y: f64} // as before
|
||
struct Size {w: f64, h: f64} // as before
|
||
struct Rectangle {origin: Point, size: Size}
|
||
~~~
|
||
|
||
Now, as before, we can define rectangles in a few different ways:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}
|
||
# struct Size {w: f64, h: f64} // as before
|
||
# struct Rectangle {origin: Point, size: Size}
|
||
let rect_stack = &Rectangle {origin: Point {x: 1.0, y: 2.0},
|
||
size: Size {w: 3.0, h: 4.0}};
|
||
let rect_managed = @Rectangle {origin: Point {x: 3.0, y: 4.0},
|
||
size: Size {w: 3.0, h: 4.0}};
|
||
let rect_owned = ~Rectangle {origin: Point {x: 5.0, y: 6.0},
|
||
size: Size {w: 3.0, h: 4.0}};
|
||
~~~
|
||
|
||
In each case, we can extract out individual subcomponents with the `&`
|
||
operator. For example, I could write:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64} // as before
|
||
# struct Size {w: f64, h: f64} // as before
|
||
# struct Rectangle {origin: Point, size: Size}
|
||
# let rect_stack = &Rectangle {origin: Point {x: 1.0, y: 2.0}, size: Size {w: 3.0, h: 4.0}};
|
||
# let rect_managed = @Rectangle {origin: Point {x: 3.0, y: 4.0}, size: Size {w: 3.0, h: 4.0}};
|
||
# let rect_owned = ~Rectangle {origin: Point {x: 5.0, y: 6.0}, size: Size {w: 3.0, h: 4.0}};
|
||
# fn compute_distance(p1: &Point, p2: &Point) -> f64 { 0.0 }
|
||
compute_distance(&rect_stack.origin, &rect_managed.origin);
|
||
~~~
|
||
|
||
which would borrow the field `origin` from the rectangle on the stack
|
||
as well as from the managed box, and then compute the distance between them.
|
||
|
||
# Borrowing managed boxes and rooting
|
||
|
||
We’ve seen a few examples so far of borrowing heap boxes, both managed
|
||
and owned. Up till this point, we’ve glossed over issues of
|
||
safety. As stated in the introduction, at runtime a reference
|
||
is simply a pointer, nothing more. Therefore, avoiding C's problems
|
||
with dangling pointers requires a compile-time safety check.
|
||
|
||
The basis for the check is the notion of _lifetimes_. A lifetime is a
|
||
static approximation of the span of execution during which the pointer
|
||
is valid: it always corresponds to some expression or block within the
|
||
program. Code inside that expression can use the pointer without
|
||
restrictions. But if the pointer escapes from that expression (for
|
||
example, if the expression contains an assignment expression that
|
||
assigns the pointer to a mutable field of a data structure with a
|
||
broader scope than the pointer itself), the compiler reports an
|
||
error. We'll be discussing lifetimes more in the examples to come, and
|
||
a more thorough introduction is also available.
|
||
|
||
When the `&` operator creates a reference, the compiler must
|
||
ensure that the pointer remains valid for its entire
|
||
lifetime. Sometimes this is relatively easy, such as when taking the
|
||
address of a local variable or a field that is stored on the stack:
|
||
|
||
~~~
|
||
struct X { f: int }
|
||
fn example1() {
|
||
let mut x = X { f: 3 };
|
||
let y = &mut x.f; // -+ L
|
||
... // |
|
||
} // -+
|
||
~~~
|
||
|
||
Here, the lifetime of the reference `y` is simply L, the
|
||
remainder of the function body. The compiler need not do any other
|
||
work to prove that code will not free `x.f`. This is true even if the
|
||
code mutates `x`.
|
||
|
||
The situation gets more complex when borrowing data inside heap boxes:
|
||
|
||
~~~
|
||
# struct X { f: int }
|
||
fn example2() {
|
||
let mut x = @X { f: 3 };
|
||
let y = &x.f; // -+ L
|
||
... // |
|
||
} // -+
|
||
~~~
|
||
|
||
In this example, the value `x` is a heap box, and `y` is therefore a
|
||
pointer into that heap box. Again the lifetime of `y` is L, the
|
||
remainder of the function body. But there is a crucial difference:
|
||
suppose `x` were to be reassigned during the lifetime L? If the
|
||
compiler isn't careful, the managed box could become *unrooted*, and
|
||
would therefore be subject to garbage collection. A heap box that is
|
||
unrooted is one such that no pointer values in the heap point to
|
||
it. It would violate memory safety for the box that was originally
|
||
assigned to `x` to be garbage-collected, since a non-heap
|
||
pointer *`y`* still points into it.
|
||
|
||
> ***Note:*** Our current implementation implements the garbage collector
|
||
> using reference counting and cycle detection.
|
||
|
||
For this reason, whenever an `&` expression borrows the interior of a
|
||
managed box stored in a mutable location, the compiler inserts a
|
||
temporary that ensures that the managed box remains live for the
|
||
entire lifetime. So, the above example would be compiled as if it were
|
||
written
|
||
|
||
~~~
|
||
# struct X { f: int }
|
||
fn example2() {
|
||
let mut x = @X {f: 3};
|
||
let x1 = x;
|
||
let y = &x1.f; // -+ L
|
||
... // |
|
||
} // -+
|
||
~~~
|
||
|
||
Now if `x` is reassigned, the pointer `y` will still remain valid. This
|
||
process is called *rooting*.
|
||
|
||
# Borrowing owned boxes
|
||
|
||
The previous example demonstrated *rooting*, the process by which the
|
||
compiler ensures that managed boxes remain live for the duration of a
|
||
borrow. Unfortunately, rooting does not work for borrows of owned
|
||
boxes, because it is not possible to have two references to a owned
|
||
box.
|
||
|
||
For owned boxes, therefore, the compiler will only allow a borrow *if
|
||
the compiler can guarantee that the owned box will not be reassigned
|
||
or moved for the lifetime of the pointer*. This does not necessarily
|
||
mean that the owned box is stored in immutable memory. For example,
|
||
the following function is legal:
|
||
|
||
~~~
|
||
# fn some_condition() -> bool { true }
|
||
# struct Foo { f: int }
|
||
fn example3() -> int {
|
||
let mut x = ~Foo {f: 3};
|
||
if some_condition() {
|
||
let y = &x.f; // -+ L
|
||
return *y; // |
|
||
} // -+
|
||
x = ~Foo {f: 4};
|
||
...
|
||
# return 0;
|
||
}
|
||
~~~
|
||
|
||
Here, as before, the interior of the variable `x` is being borrowed
|
||
and `x` is declared as mutable. However, the compiler can prove that
|
||
`x` is not assigned anywhere in the lifetime L of the variable
|
||
`y`. Therefore, it accepts the function, even though `x` is mutable
|
||
and in fact is mutated later in the function.
|
||
|
||
It may not be clear why we are so concerned about mutating a borrowed
|
||
variable. The reason is that the runtime system frees any owned box
|
||
_as soon as its owning reference changes or goes out of
|
||
scope_. Therefore, a program like this is illegal (and would be
|
||
rejected by the compiler):
|
||
|
||
~~~ {.ignore}
|
||
fn example3() -> int {
|
||
let mut x = ~X {f: 3};
|
||
let y = &x.f;
|
||
x = ~X {f: 4}; // Error reported here.
|
||
*y
|
||
}
|
||
~~~
|
||
|
||
To make this clearer, consider this diagram showing the state of
|
||
memory immediately before the re-assignment of `x`:
|
||
|
||
~~~ {.notrust}
|
||
Stack Exchange Heap
|
||
|
||
x +----------+
|
||
| ~{f:int} | ----+
|
||
y +----------+ |
|
||
| &int | ----+
|
||
+----------+ | +---------+
|
||
+--> | f: 3 |
|
||
+---------+
|
||
~~~
|
||
|
||
Once the reassignment occurs, the memory will look like this:
|
||
|
||
~~~ {.notrust}
|
||
Stack Exchange Heap
|
||
|
||
x +----------+ +---------+
|
||
| ~{f:int} | -------> | f: 4 |
|
||
y +----------+ +---------+
|
||
| &int | ----+
|
||
+----------+ | +---------+
|
||
+--> | (freed) |
|
||
+---------+
|
||
~~~
|
||
|
||
Here you can see that the variable `y` still points at the old box,
|
||
which has been freed.
|
||
|
||
In fact, the compiler can apply the same kind of reasoning to any
|
||
memory that is _(uniquely) owned by the stack frame_. So we could
|
||
modify the previous example to introduce additional owned pointers
|
||
and structs, and the compiler will still be able to detect possible
|
||
mutations:
|
||
|
||
~~~ {.ignore}
|
||
fn example3() -> int {
|
||
struct R { g: int }
|
||
struct S { f: ~R }
|
||
|
||
let mut x = ~S {f: ~R {g: 3}};
|
||
let y = &x.f.g;
|
||
x = ~S {f: ~R {g: 4}}; // Error reported here.
|
||
x.f = ~R {g: 5}; // Error reported here.
|
||
*y
|
||
}
|
||
~~~
|
||
|
||
In this case, two errors are reported, one when the variable `x` is
|
||
modified and another when `x.f` is modified. Either modification would
|
||
invalidate the pointer `y`.
|
||
|
||
# Borrowing and enums
|
||
|
||
The previous example showed that the type system forbids any borrowing
|
||
of owned boxes found in aliasable, mutable memory. This restriction
|
||
prevents pointers from pointing into freed memory. There is one other
|
||
case where the compiler must be very careful to ensure that pointers
|
||
remain valid: pointers into the interior of an `enum`.
|
||
|
||
As an example, let’s look at the following `shape` type that can
|
||
represent both rectangles and circles:
|
||
|
||
~~~
|
||
struct Point {x: f64, y: f64}; // as before
|
||
struct Size {w: f64, h: f64}; // as before
|
||
enum Shape {
|
||
Circle(Point, f64), // origin, radius
|
||
Rectangle(Point, Size) // upper-left, dimensions
|
||
}
|
||
~~~
|
||
|
||
Now we might write a function to compute the area of a shape. This
|
||
function takes a reference to a shape, to avoid the need for
|
||
copying.
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}; // as before
|
||
# struct Size {w: f64, h: f64}; // as before
|
||
# enum Shape {
|
||
# Circle(Point, f64), // origin, radius
|
||
# Rectangle(Point, Size) // upper-left, dimensions
|
||
# }
|
||
# static tau: f64 = 6.28;
|
||
fn compute_area(shape: &Shape) -> f64 {
|
||
match *shape {
|
||
Circle(_, radius) => 0.5 * tau * radius * radius,
|
||
Rectangle(_, ref size) => size.w * size.h
|
||
}
|
||
}
|
||
~~~
|
||
|
||
The first case matches against circles. Here, the pattern extracts the
|
||
radius from the shape variant and the action uses it to compute the
|
||
area of the circle. (Like any up-to-date engineer, we use the [tau
|
||
circle constant][tau] and not that dreadfully outdated notion of pi).
|
||
|
||
[tau]: http://www.math.utah.edu/~palais/pi.html
|
||
|
||
The second match is more interesting. Here we match against a
|
||
rectangle and extract its size: but rather than copy the `size`
|
||
struct, we use a by-reference binding to create a pointer to it. In
|
||
other words, a pattern binding like `ref size` binds the name `size`
|
||
to a pointer of type `&size` into the _interior of the enum_.
|
||
|
||
To make this more clear, let's look at a diagram of memory layout in
|
||
the case where `shape` points at a rectangle:
|
||
|
||
~~~ {.notrust}
|
||
Stack Memory
|
||
|
||
+-------+ +---------------+
|
||
| shape | ------> | rectangle( |
|
||
+-------+ | {x: f64, |
|
||
| size | -+ | y: f64}, |
|
||
+-------+ +----> | {w: f64, |
|
||
| h: f64}) |
|
||
+---------------+
|
||
~~~
|
||
|
||
Here you can see that rectangular shapes are composed of five words of
|
||
memory. The first is a tag indicating which variant this enum is
|
||
(`rectangle`, in this case). The next two words are the `x` and `y`
|
||
fields for the point and the remaining two are the `w` and `h` fields
|
||
for the size. The binding `size` is then a pointer into the inside of
|
||
the shape.
|
||
|
||
Perhaps you can see where the danger lies: if the shape were somehow
|
||
to be reassigned, perhaps to a circle, then although the memory used
|
||
to store that shape value would still be valid, _it would have a
|
||
different type_! The following diagram shows what memory would look
|
||
like if code overwrote `shape` with a circle:
|
||
|
||
~~~ {.notrust}
|
||
Stack Memory
|
||
|
||
+-------+ +---------------+
|
||
| shape | ------> | circle( |
|
||
+-------+ | {x: f64, |
|
||
| size | -+ | y: f64}, |
|
||
+-------+ +----> | f64) |
|
||
| |
|
||
+---------------+
|
||
~~~
|
||
|
||
As you can see, the `size` pointer would be pointing at a `f64`
|
||
instead of a struct. This is not good: dereferencing the second field
|
||
of a `f64` as if it were a struct with two fields would be a memory
|
||
safety violation.
|
||
|
||
So, in fact, for every `ref` binding, the compiler will impose the
|
||
same rules as the ones we saw for borrowing the interior of a owned
|
||
box: it must be able to guarantee that the `enum` will not be
|
||
overwritten for the duration of the borrow. In fact, the compiler
|
||
would accept the example we gave earlier. The example is safe because
|
||
the shape pointer has type `&Shape`, which means "reference to
|
||
immutable memory containing a `shape`". If, however, the type of that
|
||
pointer were `&mut Shape`, then the ref binding would be ill-typed.
|
||
Just as with owned boxes, the compiler will permit `ref` bindings
|
||
into data owned by the stack frame even if the data are mutable,
|
||
but otherwise it requires that the data reside in immutable memory.
|
||
|
||
# Returning references
|
||
|
||
So far, all of the examples we have looked at, use references in a
|
||
“downward” direction. That is, a method or code block creates a
|
||
reference, then uses it within the same scope. It is also
|
||
possible to return references as the result of a function, but
|
||
as we'll see, doing so requires some explicit annotation.
|
||
|
||
For example, we could write a subroutine like this:
|
||
|
||
~~~
|
||
struct Point {x: f64, y: f64}
|
||
fn get_x<'r>(p: &'r Point) -> &'r f64 { &p.x }
|
||
~~~
|
||
|
||
Here, the function `get_x()` returns a pointer into the structure it
|
||
was given. The type of the parameter (`&'r Point`) and return type
|
||
(`&'r f64`) both use a new syntactic form that we have not seen so
|
||
far. Here the identifier `r` names the lifetime of the pointer
|
||
explicitly. So in effect, this function declares that it takes a
|
||
pointer with lifetime `r` and returns a pointer with that same
|
||
lifetime.
|
||
|
||
In general, it is only possible to return references if they
|
||
are derived from a parameter to the procedure. In that case, the
|
||
pointer result will always have the same lifetime as one of the
|
||
parameters; named lifetimes indicate which parameter that
|
||
is.
|
||
|
||
In the previous examples, function parameter types did not include a
|
||
lifetime name. In those examples, the compiler simply creates a fresh
|
||
name for the lifetime automatically: that is, the lifetime name is
|
||
guaranteed to refer to a distinct lifetime from the lifetimes of all
|
||
other parameters.
|
||
|
||
Named lifetimes that appear in function signatures are conceptually
|
||
the same as the other lifetimes we have seen before, but they are a bit
|
||
abstract: they don’t refer to a specific expression within `get_x()`,
|
||
but rather to some expression within the *caller of `get_x()`*. The
|
||
lifetime `r` is actually a kind of *lifetime parameter*: it is defined
|
||
by the caller to `get_x()`, just as the value for the parameter `p` is
|
||
defined by that caller.
|
||
|
||
In any case, whatever the lifetime of `r` is, the pointer produced by
|
||
`&p.x` always has the same lifetime as `p` itself: a pointer to a
|
||
field of a struct is valid as long as the struct is valid. Therefore,
|
||
the compiler accepts the function `get_x()`.
|
||
|
||
To emphasize this point, let’s look at a variation on the example, this
|
||
time one that does not compile:
|
||
|
||
~~~ {.ignore}
|
||
struct Point {x: f64, y: f64}
|
||
fn get_x_sh(p: @Point) -> &f64 {
|
||
&p.x // Error reported here
|
||
}
|
||
~~~
|
||
|
||
Here, the function `get_x_sh()` takes a managed box as input and
|
||
returns a reference. As before, the lifetime of the reference
|
||
that will be returned is a parameter (specified by the
|
||
caller). That means that `get_x_sh()` promises to return a reference
|
||
that is valid for as long as the caller would like: this is
|
||
subtly different from the first example, which promised to return a
|
||
pointer that was valid for as long as its pointer argument was valid.
|
||
|
||
Within `get_x_sh()`, we see the expression `&p.x` which takes the
|
||
address of a field of a managed box. The presence of this expression
|
||
implies that the compiler must guarantee that, so long as the
|
||
resulting pointer is valid, the managed box will not be reclaimed by
|
||
the garbage collector. But recall that `get_x_sh()` also promised to
|
||
return a pointer that was valid for as long as the caller wanted it to
|
||
be. Clearly, `get_x_sh()` is not in a position to make both of these
|
||
guarantees; in fact, it cannot guarantee that the pointer will remain
|
||
valid at all once it returns, as the parameter `p` may or may not be
|
||
live in the caller. Therefore, the compiler will report an error here.
|
||
|
||
In general, if you borrow a managed (or owned) box to create a
|
||
reference, it will only be valid within the function
|
||
and cannot be returned. This is why the typical way to return references
|
||
is to take references as input (the only other case in
|
||
which it can be legal to return a reference is if it
|
||
points at a static constant).
|
||
|
||
# Named lifetimes
|
||
|
||
Let's look at named lifetimes in more detail. Named lifetimes allow
|
||
for grouping of parameters by lifetime. For example, consider this
|
||
function:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}; // as before
|
||
# struct Size {w: f64, h: f64}; // as before
|
||
# enum Shape {
|
||
# Circle(Point, f64), // origin, radius
|
||
# Rectangle(Point, Size) // upper-left, dimensions
|
||
# }
|
||
# fn compute_area(shape: &Shape) -> f64 { 0.0 }
|
||
fn select<'r, T>(shape: &'r Shape, threshold: f64,
|
||
a: &'r T, b: &'r T) -> &'r T {
|
||
if compute_area(shape) > threshold {a} else {b}
|
||
}
|
||
~~~
|
||
|
||
This function takes three references and assigns each the same
|
||
lifetime `r`. In practice, this means that, in the caller, the
|
||
lifetime `r` will be the *intersection of the lifetime of the three
|
||
region parameters*. This may be overly conservative, as in this
|
||
example:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}; // as before
|
||
# struct Size {w: f64, h: f64}; // as before
|
||
# enum Shape {
|
||
# Circle(Point, f64), // origin, radius
|
||
# Rectangle(Point, Size) // upper-left, dimensions
|
||
# }
|
||
# fn compute_area(shape: &Shape) -> f64 { 0.0 }
|
||
# fn select<'r, T>(shape: &Shape, threshold: f64,
|
||
# a: &'r T, b: &'r T) -> &'r T {
|
||
# if compute_area(shape) > threshold {a} else {b}
|
||
# }
|
||
// -+ r
|
||
fn select_based_on_unit_circle<'r, T>( // |-+ B
|
||
threshold: f64, a: &'r T, b: &'r T) -> &'r T { // | |
|
||
// | |
|
||
let shape = Circle(Point {x: 0., y: 0.}, 1.); // | |
|
||
select(&shape, threshold, a, b) // | |
|
||
} // |-+
|
||
// -+
|
||
~~~
|
||
|
||
In this call to `select()`, the lifetime of the first parameter shape
|
||
is B, the function body. Both of the second two parameters `a` and `b`
|
||
share the same lifetime, `r`, which is a lifetime parameter of
|
||
`select_based_on_unit_circle()`. The caller will infer the
|
||
intersection of these two lifetimes as the lifetime of the returned
|
||
value, and hence the return value of `select()` will be assigned a
|
||
lifetime of B. This will in turn lead to a compilation error, because
|
||
`select_based_on_unit_circle()` is supposed to return a value with the
|
||
lifetime `r`.
|
||
|
||
To address this, we can modify the definition of `select()` to
|
||
distinguish the lifetime of the first parameter from the lifetime of
|
||
the latter two. After all, the first parameter is not being
|
||
returned. Here is how the new `select()` might look:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}; // as before
|
||
# struct Size {w: f64, h: f64}; // as before
|
||
# enum Shape {
|
||
# Circle(Point, f64), // origin, radius
|
||
# Rectangle(Point, Size) // upper-left, dimensions
|
||
# }
|
||
# fn compute_area(shape: &Shape) -> f64 { 0.0 }
|
||
fn select<'r, 'tmp, T>(shape: &'tmp Shape, threshold: f64,
|
||
a: &'r T, b: &'r T) -> &'r T {
|
||
if compute_area(shape) > threshold {a} else {b}
|
||
}
|
||
~~~
|
||
|
||
Here you can see that `shape`'s lifetime is now named `tmp`. The
|
||
parameters `a`, `b`, and the return value all have the lifetime `r`.
|
||
However, since the lifetime `tmp` is not returned, it would be more
|
||
concise to just omit the named lifetime for `shape` altogether:
|
||
|
||
~~~
|
||
# struct Point {x: f64, y: f64}; // as before
|
||
# struct Size {w: f64, h: f64}; // as before
|
||
# enum Shape {
|
||
# Circle(Point, f64), // origin, radius
|
||
# Rectangle(Point, Size) // upper-left, dimensions
|
||
# }
|
||
# fn compute_area(shape: &Shape) -> f64 { 0.0 }
|
||
fn select<'r, T>(shape: &Shape, threshold: f64,
|
||
a: &'r T, b: &'r T) -> &'r T {
|
||
if compute_area(shape) > threshold {a} else {b}
|
||
}
|
||
~~~
|
||
|
||
This is equivalent to the previous definition.
|
||
|
||
# Conclusion
|
||
|
||
So there you have it: a (relatively) brief tour of the lifetime
|
||
system. For more details, we refer to the (yet to be written) reference
|
||
document on references, which will explain the full notation
|
||
and give more examples.
|