- Overview
- Precedence
- Names
- Operators
- Conversions and casts
if
expressions- Numeric type literal expressions
- Alternatives considered
- References
Expressions are the portions of Carbon syntax that produce values. Because types in Carbon are values, this includes anywhere that a type is specified.
fn Foo(a: i32*) -> i32 {
return *a;
}
Here, the parameter type i32*
, the return type i32
, and the operand *a
of
the return
statement are all expressions.
Expressions are interpreted based on a partial precedence ordering. Expression components which lack a relative ordering must be disambiguated by the developer, for example by adding parentheses; otherwise, the expression will be invalid due to ambiguity. Precedence orderings will only be added when it's reasonable to expect most developers to understand the precedence without parentheses.
The precedence diagram is defined thusly:
%%{init: {'themeVariables': {'fontFamily': 'monospace'}}}%%
graph BT
parens["(...)"]
braces["{...}"]
click braces "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/classes.md#literals"
unqualifiedName["x"]
click unqualifiedName "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/README.md#unqualified-names"
memberAccess>"x.y<br>
x.(...)"]
click memberAccess "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/member_access.md"
negation["-x"]
click negation "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/arithmetic.md"
complement["^x"]
click complement "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/bitwise.md"
unary((" "))
as["x as T"]
click as "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/implicit_conversions.md"
multiplication>"x * y<br>
x / y"]
click multiplication "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/arithmetic.md"
addition>"x + y<br>
x - y"]
click addition "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/arithmetic.md"
modulo["x % y"]
click modulo "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/arithmetic.md"
bitwise_and>"x & y"]
bitwise_or>"x | y"]
bitwise_xor>"x ^ y"]
click bitwise_and "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/bitwise.md"
click bitwise_or "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/bitwise.md"
click bitwise_xor "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/bitwise.md"
shift["x << y<br>
x >> y"]
click shift "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/bitwise.md"
comparison["x == y<br>
x != y<br>
x < y<br>
x <= y<br>
x > y<br>
x >= y"]
click comparison "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/comparison_operators.md"
not["not x"]
click not "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/logical_operators.md"
logicalOperand((" "))
and>"x and y"]
click and "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/logical_operators.md"
or>"x or y"]
click or "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/logical_operators.md"
logicalExpression((" "))
if>"if x then y else z"]
click if "https://github.com/carbon-language/carbon-lang/blob/trunk/docs/design/expressions/if.md"
expressionEnd["x;"]
memberAccess --> parens & braces & unqualifiedName
negation --> memberAccess
complement --> memberAccess
unary --> negation & complement
%% Use a longer arrow here to put `not` next to `and` and `or`.
not -----> memberAccess
multiplication & modulo & as & bitwise_and & bitwise_or & bitwise_xor & shift --> unary
addition --> multiplication
comparison --> modulo & addition & as & bitwise_and & bitwise_or & bitwise_xor & shift
logicalOperand --> comparison & not
and & or --> logicalOperand
logicalExpression --> and & or
if & expressionEnd --> logicalExpression
The diagram's attributes are:
-
Each non-empty node represents a precedence group. Empty circles are used to simplify the graph, and do not represent a precedence group.
-
When an expression is composed from different precedence groups, the interpretation is determined by the precedence edges:
-
A precedence edge A --> B means that A is lower precedence than B, so A can contain B without parentheses. For example,
or --> not
means thatnot x or y
is treated as(not x) or y
. -
Precedence edges are transitive. For example,
or --> == --> as
means thator
is lower precedence thanas
.
-
-
When an expression is composed from a single precedence group, the interpretation is determined by the associativity of the precedence group:
graph TD non["Non-associative"] left>"Left associative"]
- For example,
+
and-
are left-associative and in the same precedence group, soa + b + c - d
is treated as((a + b) + c) - d
.
- For example,
An unqualified name is a word that is not a
keyword and is not preceded by a period (.
).
TODO: Name lookup rules for unqualified names.
A qualified name is a word that appears immediately after a period. Qualified names appear in the following contexts:
- Designators:
.
word - Simple member access expressions: expression
.
word
var x: auto = {.hello = 1, .world = 2};
^^^^^ ^^^^^ qualified name
^^^^^^ ^^^^^^ designator
x.hello = x.world;
^^^^^ ^^^^^ qualified name
^^^^^^^ ^^^^^^^ member access expression
Qualified names refer to members of an entity determined by the context in which the expression appears. For a member access, the entity is named by the expression preceding the period. In a struct literal, the entity is the struct type. For example:
package Foo api;
namespace N;
fn N.F() {}
fn G() {
// Same as `(Foo.N).F()`.
// `Foo.N` names namespace `N` in package `Foo`.
// `(Foo.N).F` names function `F` in namespace `N`.
Foo.N.F();
}
// `.n` refers to the member `n` of `{.n: i32}`.
fn H(a: {.n: i32}) -> i32 {
// `a.n` is resolved to the member `{.n: i32}.n`,
// and names the corresponding subobject of `a`.
return a.n;
}
fn J() {
// `.n` refers to the member `n of `{.n: i32}`.
H({.n = 5 as i32});
}
Member access expressions associate left-to-right. If the member name is more complex than a single word, a compound member access expression can be used, with parentheses around the member name:
- expression
.
(
expression)
interface I { fn F[self: Self](); }
class X {}
external impl X as I { fn F[self: Self]() {} }
// `x.I.F()` would mean `(x.I).F()`.
fn Q(x: X) { x.(I.F)(); }
Most expressions are modeled as operators:
Category | Operator | Syntax | Function |
---|---|---|---|
Arithmetic | - (unary) |
-x |
The negation of x . |
Bitwise | ^ (unary) |
^x |
The bitwise complement of x . |
Arithmetic | + |
x + y |
The sum of x and y . |
Arithmetic | - (binary) |
x - y |
The difference of x and y . |
Arithmetic | * |
x * y |
The product of x and y . |
Arithmetic | / |
x / y |
x divided by y , or the quotient thereof. |
Arithmetic | % |
x % y |
x modulo y . |
Bitwise | & |
x & y |
The bitwise AND of x and y . |
Bitwise | | |
x | y |
The bitwise OR of x and y . |
Bitwise | ^ (binary) |
x ^ y |
The bitwise XOR of x and y . |
Bitwise | << |
x << y |
x bit-shifted left y places. |
Bitwise | >> |
x >> y |
x bit-shifted right y places. |
Conversion | as |
x as T |
Converts the value x to the type T . |
Comparison | == |
x == y |
Equality: true if x is equal to y . |
Comparison | != |
x != y |
Inequality: true if x is not equal to y . |
Comparison | < |
x < y |
Less than: true if x is less than y . |
Comparison | <= |
x <= y |
Less than or equal: true if x is less than or equal to y . |
Comparison | > |
x > y |
Greater than: true if x is greater than to y . |
Comparison | >= |
x >= y |
Greater than or equal: true if x is greater than or equal to y . |
Logical | and |
x and y |
A short-circuiting logical AND: true if both operands are true . |
Logical | or |
x or y |
A short-circuiting logical OR: true if either operand is true . |
Logical | not |
not x |
Logical NOT: true if the operand is false . |
When an expression appears in a context in which an expression of a specific type is expected, implicit conversions are applied to convert the expression to the target type.
Expressions can also be converted to a specific type using an
as
expression.
fn Bar(n: i32);
fn Baz(n: i64) {
// OK, same as Bar(n as i32)
Bar(n);
}
An if
expression chooses between two expressions.
fn Run(args: Span(StringView)) {
var file: StringView = if args.size() > 1 then args[1] else "/dev/stdin";
}
if
expressions are analogous to ?:
ternary expressions in C and C++.
Carbon's syntax provides a simple way to represent different types of integers
and floating-point numbers. Each type is identified with a keyword-like syntax,
prefixed with either i
, u
, or f
followed by a multiple of 8, representing
the size in bits of the data type.
These are referred to as numeric type literals.
Other expression documents will list more alternatives; this lists alternatives not noted elsewhere.
Other expression documents will list more references; this lists references not noted elsewhere.
- Proposal #555: Operator precedence.