Skip to content

Latest commit

 

History

History
337 lines (283 loc) · 16 KB

expressions.md

File metadata and controls

337 lines (283 loc) · 16 KB

Expressions

Syntax
Expression :
      ExpressionWithoutBlock
   | ExpressionWithBlock

ExpressionWithoutBlock :
   OuterAttribute*
   (
         LiteralExpression
      | PathExpression
      | OperatorExpression
      | GroupedExpression
      | ArrayExpression
      | AwaitExpression
      | IndexExpression
      | TupleExpression
      | TupleIndexingExpression
      | StructExpression
      | CallExpression
      | MethodCallExpression
      | FieldExpression
      | ClosureExpression
      | AsyncBlockExpression
      | ContinueExpression
      | BreakExpression
      | RangeExpression
      | ReturnExpression
      | UnderscoreExpression
      | MacroInvocation
   )

ExpressionWithBlock :
   OuterAttribute*
   (
         BlockExpression
      | ConstBlockExpression
      | UnsafeBlockExpression
      | LoopExpression
      | IfExpression
      | IfLetExpression
      | MatchExpression
   )

An expression may have two roles: it always produces a value, and it may have effects (otherwise known as "side effects"). An expression evaluates to a value, and has effects during evaluation. Many expressions contain sub-expressions, called the operands of the expression. The meaning of each kind of expression dictates several things:

  • Whether or not to evaluate the operands when evaluating the expression
  • The order in which to evaluate the operands
  • How to combine the operands' values to obtain the value of the expression

In this way, the structure of expressions dictates the structure of execution. Blocks are just another kind of expression, so blocks, statements, expressions, and blocks again can recursively nest inside each other to an arbitrary depth.

Note: We give names to the operands of expressions so that we may discuss them, but these names are not stable and may be changed.

Expression precedence

The precedence of Rust operators and expressions is ordered as follows, going from strong to weak. Binary Operators at the same precedence level are grouped in the order given by their associativity.

Operator/Expression Associativity
Paths
Method calls
Field expressions left to right
Function calls, array indexing
?
Unary - * ! & &mut
as left to right
* / % left to right
+ - left to right
<< >> left to right
& left to right
^ left to right
| left to right
== != < > <= >= Require parentheses
&& left to right
|| left to right
.. ..= Require parentheses
= += -= *= /= %=
&= |= ^= <<= >>=
right to left
return break closures

Evaluation order of operands

The following list of expressions all evaluate their operands the same way, as described after the list. Other expressions either don't take operands or evaluate them conditionally as described on their respective pages.

  • Dereference expression
  • Error propagation expression
  • Negation expression
  • Arithmetic and logical binary operators
  • Comparison operators
  • Type cast expression
  • Grouped expression
  • Array expression
  • Await expression
  • Index expression
  • Tuple expression
  • Tuple index expression
  • Struct expression
  • Call expression
  • Method call expression
  • Field expression
  • Break expression
  • Range expression
  • Return expression

The operands of these expressions are evaluated prior to applying the effects of the expression. Expressions taking multiple operands are evaluated left to right as written in the source code.

Note: Which subexpressions are the operands of an expression is determined by expression precedence as per the previous section.

For example, the two next method calls will always be called in the same order:

# // Using vec instead of array to avoid references
# // since there is no stable owned array iterator
# // at the time this example was written.
let mut one_two = vec![1, 2].into_iter();
assert_eq!(
    (1, 2),
    (one_two.next().unwrap(), one_two.next().unwrap())
);

Note: Since this is applied recursively, these expressions are also evaluated from innermost to outermost, ignoring siblings until there are no inner subexpressions.

Place Expressions and Value Expressions

Expressions are divided into two main categories: place expressions and value expressions; there is also a third, minor category of expressions called assignee expressions. Within each expression, operands may likewise occur in either place context or value context. The evaluation of an expression depends both on its own category and the context it occurs within.

A place expression is an expression that represents a memory location. These expressions are paths which refer to local variables, static variables, dereferences (*expr), array indexing expressions (expr[expr]), field references (expr.f) and parenthesized place expressions. All other expressions are value expressions.

A value expression is an expression that represents an actual value.

The following contexts are place expression contexts:

Note: Historically, place expressions were called lvalues and value expressions were called rvalues.

An assignee expression is an expression that appears in the left operand of an assignment expression. Explicitly, the assignee expressions are:

Arbitrary parenthesisation is permitted inside assignee expressions.

Moved and copied types

When a place expression is evaluated in a value expression context, or is bound by value in a pattern, it denotes the value held in that memory location. If the type of that value implements Copy, then the value will be copied. In the remaining situations, if that type is Sized, then it may be possible to move the value. Only the following place expressions may be moved out of:

  • Variables which are not currently borrowed.
  • Temporary values.
  • Fields of a place expression which can be moved out of and don't implement Drop.
  • The result of dereferencing an expression with type [Box<T>] and that can also be moved out of.

After moving out of a place expression that evaluates to a local variable, the location is deinitialized and cannot be read from again until it is reinitialized. In all other cases, trying to use a place expression in a value expression context is an error.

Mutability

For a place expression to be assigned to, mutably borrowed, implicitly mutably borrowed, or bound to a pattern containing ref mut, it must be mutable. We call these mutable place expressions. In contrast, other place expressions are called immutable place expressions.

The following expressions can be mutable place expression contexts:

  • Mutable variables which are not currently borrowed.
  • Mutable static items.
  • Temporary values.
  • Fields: this evaluates the subexpression in a mutable place expression context.
  • Dereferences of a *mut T pointer.
  • Dereference of a variable, or field of a variable, with type &mut T. Note: This is an exception to the requirement of the next rule.
  • Dereferences of a type that implements DerefMut: this then requires that the value being dereferenced is evaluated in a mutable place expression context.
  • Array indexing of a type that implements IndexMut: this then evaluates the value being indexed, but not the index, in mutable place expression context.

Temporaries

When using a value expression in most place expression contexts, a temporary unnamed memory location is created and initialized to that value. The expression evaluates to that location instead, except if promoted to a static. The drop scope of the temporary is usually the end of the enclosing statement.

Implicit Borrows

Certain expressions will treat an expression as a place expression by implicitly borrowing it. For example, it is possible to compare two unsized slices for equality directly, because the == operator implicitly borrows its operands:

# let c = [1, 2, 3];
# let d = vec![1, 2, 3];
let a: &[i32];
let b: &[i32];
# a = &c;
# b = &d;
// ...
*a == *b;
// Equivalent form:
::std::cmp::PartialEq::eq(&*a, &*b);

Implicit borrows may be taken in the following expressions:

Overloading Traits

Many of the following operators and expressions can also be overloaded for other types using traits in std::ops or std::cmp. These traits also exist in core::ops and core::cmp with the same names.

Expression Attributes

Outer attributes before an expression are allowed only in a few specific cases:

They are never allowed before: