8.8 KiB
% Type Conversions
At the end of the day, everything is just a pile of bits somewhere, and type systems are just there to help us use those bits right. Needing to reinterpret those piles of bits as different types is a common problem and Rust consequently gives you several ways to do that.
First we'll look at the ways that Safe Rust gives you to reinterpret values. The most trivial way to do this is to just destructure a value into its constituent parts and then build a new type out of them. e.g.
struct Foo {
x: u32,
y: u16,
}
struct Bar {
a: u32,
b: u16,
}
fn reinterpret(foo: Foo) -> Bar {
let Foo { x, y } = foo;
Bar { a: x, b: y }
}
But this is, at best, annoying to do. For common conversions, rust provides more ergonomic alternatives.
Auto-Deref
(Maybe nix this in favour of receiver coercions)
Deref is a trait that allows you to overload the unary *
to specify a type
you dereference to. This is largely only intended to be implemented by pointer
types like &
, Box
, and Rc
. The dot operator will automatically perform
automatic dereferencing, so that foo.bar() will work uniformly on Foo
, &Foo
, &&Foo
, &Rc<Box<&mut&Box<Foo>>>
and so-on. Search bottoms out on the first match,
so implementing methods on pointers is generally to be avoided, as it will shadow
"actual" methods.
Coercions
Types can implicitly be coerced to change in certain contexts. These changes are generally just weakening of types, largely focused around pointers and lifetimes. They mostly exist to make Rust "just work" in more cases, and are largely harmless.
Here's all the kinds of coercion:
Coercion is allowed between the following types:
-
T
toU
ifT
is a subtype ofU
(the 'identity' case); -
T_1
toT_3
whereT_1
coerces toT_2
andT_2
coerces toT_3
(transitivity case); -
&mut T
to&T
; -
*mut T
to*const T
; -
&T
to*const T
; -
&mut T
to*mut T
; -
T
toU
ifT
implementsCoerceUnsized<U>
(see below) andT = Foo<...>
andU = Foo<...>
; -
From TyCtor(
T
) to TyCtor(coerce_inner(T
));
where TyCtor(T
) is one of &T
, &mut T
, *const T
, *mut T
, or Box<T>
.
And where coerce_inner is defined as
-
coerce_inner(
[T, ..n]
) =[T]
; -
coerce_inner(
T
) =U
whereT
is a concrete type which implements the traitU
; -
coerce_inner(
T
) =U
whereT
is a sub-trait ofU
; -
coerce_inner(
Foo<..., T, ...>
) =Foo<..., coerce_inner(T), ...>
whereFoo
is a struct and only the last field has typeT
andT
is not part of the type of any other fields; -
coerce_inner(
(..., T)
) =(..., coerce_inner(T))
.
Coercions only occur at a coercion site. Exhaustively, the coercion sites are:
-
In
let
statements where an explicit type is given: inlet _: U = e;
,e
is coerced to to have typeU
; -
In statics and consts, similarly to
let
statements; -
In argument position for function calls. The value being coerced is the actual parameter and it is coerced to the type of the formal parameter. For example, where
foo
is defined asfn foo(x: U) { ... }
and is called withfoo(e);
,e
is coerced to have typeU
; -
Where a field of a struct or variant is instantiated. E.g., where
struct Foo { x: U }
and the instantiation isFoo { x: e }
,e
is coerced to to have typeU
; -
The result of a function, either the final line of a block if it is not semi- colon terminated or any expression in a
return
statement. For example, forfn foo() -> U { e }
,e
is coerced to to have typeU
;
If the expression in one of these coercion sites is a coercion-propagating expression, then the relevant sub-expressions in that expression are also coercion sites. Propagation recurses from these new coercion sites. Propagating expressions and their relevant sub-expressions are:
-
array literals, where the array has type
[U, ..n]
, each sub-expression in the array literal is a coercion site for coercion to typeU
; -
array literals with repeating syntax, where the array has type
[U, ..n]
, the repeated sub-expression is a coercion site for coercion to typeU
; -
tuples, where a tuple is a coercion site to type
(U_0, U_1, ..., U_n)
, each sub-expression is a coercion site for the respective type, e.g., the zero-th sub-expression is a coercion site toU_0
; -
the box expression, if the expression has type
Box<U>
, the sub-expression is a coercion site toU
; -
parenthesised sub-expressions (
(e)
), if the expression has typeU
, then the sub-expression is a coercion site toU
; -
blocks, if a block has type
U
, then the last expression in the block (if it is not semicolon-terminated) is a coercion site toU
. This includes blocks which are part of control flow statements, such asif
/else
, if the block has a known type.
Note that we do not perform coercions when matching traits (except for
receivers, see below). If there is an impl for some type U
and T
coerces to
U
, that does not constitute an implementation for T
. For example, the
following will not type check, even though it is OK to coerce t
to &T
and
there is an impl for &T
:
struct T;
trait Trait {}
fn foo<X: Trait>(t: X) {}
impl<'a> Trait for &'a T {}
fn main() {
let t: &mut T = &mut T;
foo(t); //~ ERROR failed to find an implementation of trait Trait for &mut T
}
In a cast expression, e as U
, the compiler will first attempt to coerce e
to
U
, only if that fails will the conversion rules for casts (see below) be
applied.
Casts
Casts are a superset of coercions: every coercion can be explicitly invoked via a cast, but some conversions require a cast. These "true casts" are generally regarded as dangerous or problematic actions. True casts revolve around raw pointers and the primitive numeric types. True casts aren't checked.
Here's an exhaustive list of all the true casts:
e
has typeT
andT
coerces toU
; coercion-caste
has type*T
,U
is*U_0
, and eitherU_0: Sized
or unsize_kind(T
) = unsize_kind(U_0
); ptr-ptr-caste
has type*T
andU
is a numeric type, whileT: Sized
; ptr-addr-caste
is an integer andU
is*U_0
, whileU_0: Sized
; addr-ptr-caste
has typeT
andT
andU
are any numeric types; numeric-caste
is a C-like enum andU
is an integer type; enum-caste
has typebool
orchar
andU
is an integer; prim-int-caste
has typeu8
andU
ischar
; u8-char-caste
has type&[T; n]
andU
is*const T
; array-ptr-caste
is a function pointer type andU
has type*T
, whileT: Sized
; fptr-ptr-caste
is a function pointer type andU
is an integer; fptr-addr-cast
where &.T
and *T
are references of either mutability,
and where unsize_kind(T
) is the kind of the unsize info
in T
- the vtable for a trait definition (e.g. fmt::Display
or
Iterator
, not Iterator<Item=u8>
) or a length (or ()
if T: Sized
).
Note that lengths are not adjusted when casting raw slices -
T: *const [u16] as *const [u8]
creates a slice that only includes
half of the original memory.
Casting is not transitive, that is, even if e as U1 as U2
is a valid
expression, e as U2
is not necessarily so (in fact it will only be valid if
U1
coerces to U2
).
For numeric casts, there are quite a few cases to consider:
- casting between two integers of the same size (e.g. i32 -> u32) is a no-op
- casting from a smaller integer to a bigger integer (e.g. u32 -> u8) will truncate
- casting from a larger integer to a smaller integer (e.g. u8 -> u32) will
- zero-extend if the target is unsigned
- sign-extend if the target is signed
- casting from a float to an integer will:
- round the float towards zero if finite
- NOTE: currently this will cause Undefined Behaviour if the rounded value cannot be represented by the target integer type. This is a bug and will be fixed.
- casting from an integer to float will produce the floating point representation of the integer, rounded if necessary (rounding strategy unspecified).
- casting from an f32 to an f64 is perfect and lossless.
- casting from an f64 to an f32 will produce the closest possible value
(rounding strategy unspecified).
- NOTE: currently this will cause Undefined Behaviour if the value is finite but larger or smaller than the largest or smallest finite value representable by f32. This is a bug and will be fixed.
The casts involving rawptrs also allow us to completely bypass type-safety
by re-interpretting a pointer of T to a pointer of U for arbitrary types, as
well as interpret integers as addresses. However it is impossible to actually
capitalize on this violation in Safe Rust, because derefencing a raw ptr is
unsafe
.
Conversion Traits
TODO