Implicit conversions
Overview
When an expression appears in a context in which an expression of a specific type is expected, the expression is implicitly converted to that type if possible.
For built-in types, implicit conversions are permitted when:
- The conversion is lossless: every possible value for the source expression converts to a distinct value in the target type.
- The conversion is semantics-preserving: corresponding values in the source and destination type have the same abstract meaning.
These rules aim to ensure that implicit conversions are unsurprising: the value that is provided as the operand of an operation should match how that operation interprets the value, because the identity and abstract meaning of the value are preserved by any implicit conversions that are applied.
It is possible for user-defined types to extend the set of valid implicit conversions. Such extensions are expected to also follow these rules.
Properties of implicit conversions
Lossless
We expect implicit conversion to never lose information: if two values are distinguishable before the conversion, they should generally be distinguishable after the conversion. It should be possible to define a conversion in the opposite direction that restores the original value, but such a conversion is not expected to be provided in general, and might be computationally expensive.
Because an implicit conversion is converting from a narrower type to a wider type, implicit conversions do not necessarily preserve static information about the source value.
Semantics-preserving
We expect implicit conversions to preserve the meaning of converted values. The
assessment of this criterion will necessarily be subjective, because the
meanings of values generally live in the mind of the programmer rather than in
the program text. However, the semantic interpretation is expected to be
consistent from one conversion to another, so we can provide a test: if multiple
paths of implicit conversions from a type A
to a type B
exist, and the same
value of type A
would convert to different values of type B
along different
paths, then at least one of those conversions must not be semantics-preserving.
A semantics-preserving conversion does not necessarily preserve the meaning of particular syntax when applied to the value. The same syntax may map to different operations in the new type. For example, division may mean different things in integer and floating-point types, and member access may find different members in a derived class pointer versus in a base class pointer.
Examples
Conversion from i32
to Vector(int)
by forming a vector of N zeroes is
lossless but not semantics-preserving.
Conversion from i32
to f32
by rounding to the nearest representable value is
semantics-preserving but not lossless.
Conversion from String
to StringView
is lossless, because we can compute the
String
value from the StringView
value, and semantics-preserving because the
string value denoted is the same. Conversion in the other direction may or may
not be semantics-preserving depending on whether we consider the address to be a
salient part of a StringView
's value.
Built-in types
Data types
The following implicit numeric conversions are available:
iN
oruN
->iM
ifM
>N
uN
->uM
ifM
>N
fN
->fM
ifM
>N
iN
oruN
->fM
if every value of typeiN
oruN
can be represented infM
:i12
oru11
(or smaller) ->f16
i25
oru24
(or smaller) ->f32
i54
oru53
(or smaller) ->f64
i65
oru64
(or smaller) ->f80
(x86 only)i114
oru113
(or smaller) ->f128
(if available)i238
oru237
(or smaller) ->f256
(if available)
In each case, the numerical value is the same before and after the conversion. An integer zero is translated into a floating-point positive zero.
An integer constant can be implicitly converted to any type iM
, uM
, or fM
in which that value can be exactly represented. A floating-point constant can be
implicitly converted to any type fM
in which that value is between the least
representable finite value and the greatest representable finite value
(inclusive), and converts to the nearest representable finite value, with ties
broken by picking the value for which the mantissa is even.
The above conversions are also precisely those that C++ considers non-narrowing, except:
Carbon also permits integer to floating-point conversions in more cases. The most important of these is that Carbon permits
i32
to be implicitly converted tof64
. Lossy conversions, such as fromi32
tof32
, are not permitted.What Carbon considers to be an integer constant or floating-point constant may differ from what C++ considers to be a constant expression.
Note: We have not yet decided what will qualify as a constant in this context, but it will include at least integer and floating-point literals, with optional enclosing parentheses. It is possible that such constants will have singleton types; see issue #508.
In addition to the above rules, a negative integer constant k
can be
implicitly converted to the type uN
if the value k
+ 2N can be
exactly represented, and converts to that value. Note that this conversion
violates the "semantics-preserving" test. For example, (-1 as u8) as i32
produces the value 255
whereas -1 as i32
produces the value -1
. However,
this conversion is important in order to allow bitwise operations with masks, so
we allow it:
// We allow ^0 == -1 to convert to `u32` to represent an all-ones value.
var a: u32 = ^0;
// ^4 == -5 is negative, but we want to allow it to convert to u32 here.
var b: u32 = a & ^4;
Same type
The following conversion is available for every type T
:
T
->T
Pointer conversions
The following pointer conversion is available:
T*
->U*
ifT
is a class derived from the classU
.
Even though we can convert Derived*
to Base*
, we cannot convert Derived**
to Base**
because that would allow storing a Derived2*
into a Derived*
:
abstract class Base {}
class Derived extends Base {}
class Derived2 extends Base {}
var d2: Derived2 = {};
var p: Derived*;
var q: Derived2* = &d2;
var r: Base** = &p;
// Bad: would store q to p.
*r = q;
Type-of-types
A type T
with type-of-type TT1
can be implicitly converted to the type-of-type TT2
if T
satisfies the requirements
of TT2
.
Consistency with as
An implicit conversion of an expression E
of type T
to type U
, when
permitted, always has the same meaning as the
explicit cast expression E as U
. Moreover, because such
an implicit conversion is expected to exactly preserve the value,
(E as U) as T
, if valid, should be expected to result in the same value as
produced by E
even if the as T
cast cannot be performed as an implicit
conversion.
Extensibility
Implicit conversions can be defined for user-defined types such as
classes by implementing the ImplicitAs
interface, which
extends
the As
interface used to implement as
expressions:
interface ImplicitAs(Dest:! Type) {
extends As(Dest);
// Inherited from As(Dest):
// fn Convert[me: Self]() -> Dest;
}
When attempting to implicitly convert an expression x
to type U
, the
expression is rewritten to x.(ImplicitAs(U).Convert)()
.
Note that implicit conversions are not transitive. Even if an
impl A as ImplicitAs(B)
and an impl B as ImplicitAs(C)
are both provided, an
expression of type A
cannot be implicitly converted to type C
. Allowing
transitivity would introduce the risk of ambiguity issues as code evolves and
would in general require a search of a potentially unbounded set of intermediate
types.
Alternatives considered
- Provide lossy and non-semantics-preserving implicit conversions from C++
- Provide no implicit conversions
- Provide no extensibility
- Apply implicit conversions transitively
- Do not allow negative constants to convert to unsigned types