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|
use crate::ast::{self, BinOpKind};
use crate::token::{self, BinOpToken, Token};
use rustc_span::symbol::kw;
/// Associative operator with precedence.
///
/// This is the enum which specifies operator precedence and fixity to the parser.
#[derive(Copy, Clone, PartialEq, Debug)]
pub enum AssocOp {
/// `+`
Add,
/// `-`
Subtract,
/// `*`
Multiply,
/// `/`
Divide,
/// `%`
Modulus,
/// `&&`
LAnd,
/// `||`
LOr,
/// `^`
BitXor,
/// `&`
BitAnd,
/// `|`
BitOr,
/// `<<`
ShiftLeft,
/// `>>`
ShiftRight,
/// `==`
Equal,
/// `<`
Less,
/// `<=`
LessEqual,
/// `!=`
NotEqual,
/// `>`
Greater,
/// `>=`
GreaterEqual,
/// `=`
Assign,
/// `?=` where ? is one of the BinOpToken
AssignOp(BinOpToken),
/// `as`
As,
/// `..` range
DotDot,
/// `..=` range
DotDotEq,
/// `:`
Colon,
}
#[derive(PartialEq, Debug)]
pub enum Fixity {
/// The operator is left-associative
Left,
/// The operator is right-associative
Right,
/// The operator is not associative
None,
}
impl AssocOp {
/// Creates a new AssocOP from a token
pub fn from_token(t: &Token) -> Option<AssocOp> {
use AssocOp::*;
match t.kind {
token::BinOpEq(k) => Some(AssignOp(k)),
token::Eq => Some(Assign),
token::BinOp(BinOpToken::Star) => Some(Multiply),
token::BinOp(BinOpToken::Slash) => Some(Divide),
token::BinOp(BinOpToken::Percent) => Some(Modulus),
token::BinOp(BinOpToken::Plus) => Some(Add),
token::BinOp(BinOpToken::Minus) => Some(Subtract),
token::BinOp(BinOpToken::Shl) => Some(ShiftLeft),
token::BinOp(BinOpToken::Shr) => Some(ShiftRight),
token::BinOp(BinOpToken::And) => Some(BitAnd),
token::BinOp(BinOpToken::Caret) => Some(BitXor),
token::BinOp(BinOpToken::Or) => Some(BitOr),
token::Lt => Some(Less),
token::Le => Some(LessEqual),
token::Ge => Some(GreaterEqual),
token::Gt => Some(Greater),
token::EqEq => Some(Equal),
token::Ne => Some(NotEqual),
token::AndAnd => Some(LAnd),
token::OrOr => Some(LOr),
token::DotDot => Some(DotDot),
token::DotDotEq => Some(DotDotEq),
// DotDotDot is no longer supported, but we need some way to display the error
token::DotDotDot => Some(DotDotEq),
token::Colon => Some(Colon),
// `<-` should probably be `< -`
token::LArrow => Some(Less),
_ if t.is_keyword(kw::As) => Some(As),
_ => None,
}
}
/// Creates a new AssocOp from ast::BinOpKind.
pub fn from_ast_binop(op: BinOpKind) -> Self {
use AssocOp::*;
match op {
BinOpKind::Lt => Less,
BinOpKind::Gt => Greater,
BinOpKind::Le => LessEqual,
BinOpKind::Ge => GreaterEqual,
BinOpKind::Eq => Equal,
BinOpKind::Ne => NotEqual,
BinOpKind::Mul => Multiply,
BinOpKind::Div => Divide,
BinOpKind::Rem => Modulus,
BinOpKind::Add => Add,
BinOpKind::Sub => Subtract,
BinOpKind::Shl => ShiftLeft,
BinOpKind::Shr => ShiftRight,
BinOpKind::BitAnd => BitAnd,
BinOpKind::BitXor => BitXor,
BinOpKind::BitOr => BitOr,
BinOpKind::And => LAnd,
BinOpKind::Or => LOr,
}
}
/// Gets the precedence of this operator
pub fn precedence(&self) -> usize {
use AssocOp::*;
match *self {
As | Colon => 14,
Multiply | Divide | Modulus => 13,
Add | Subtract => 12,
ShiftLeft | ShiftRight => 11,
BitAnd => 10,
BitXor => 9,
BitOr => 8,
Less | Greater | LessEqual | GreaterEqual | Equal | NotEqual => 7,
LAnd => 6,
LOr => 5,
DotDot | DotDotEq => 4,
Assign | AssignOp(_) => 2,
}
}
/// Gets the fixity of this operator
pub fn fixity(&self) -> Fixity {
use AssocOp::*;
// NOTE: it is a bug to have an operators that has same precedence but different fixities!
match *self {
Assign | AssignOp(_) => Fixity::Right,
As | Multiply | Divide | Modulus | Add | Subtract | ShiftLeft | ShiftRight | BitAnd
| BitXor | BitOr | Less | Greater | LessEqual | GreaterEqual | Equal | NotEqual
| LAnd | LOr | Colon => Fixity::Left,
DotDot | DotDotEq => Fixity::None,
}
}
pub fn is_comparison(&self) -> bool {
use AssocOp::*;
match *self {
Less | Greater | LessEqual | GreaterEqual | Equal | NotEqual => true,
Assign | AssignOp(_) | As | Multiply | Divide | Modulus | Add | Subtract
| ShiftLeft | ShiftRight | BitAnd | BitXor | BitOr | LAnd | LOr | DotDot | DotDotEq
| Colon => false,
}
}
pub fn is_assign_like(&self) -> bool {
use AssocOp::*;
match *self {
Assign | AssignOp(_) => true,
Less | Greater | LessEqual | GreaterEqual | Equal | NotEqual | As | Multiply
| Divide | Modulus | Add | Subtract | ShiftLeft | ShiftRight | BitAnd | BitXor
| BitOr | LAnd | LOr | DotDot | DotDotEq | Colon => false,
}
}
pub fn to_ast_binop(&self) -> Option<BinOpKind> {
use AssocOp::*;
match *self {
Less => Some(BinOpKind::Lt),
Greater => Some(BinOpKind::Gt),
LessEqual => Some(BinOpKind::Le),
GreaterEqual => Some(BinOpKind::Ge),
Equal => Some(BinOpKind::Eq),
NotEqual => Some(BinOpKind::Ne),
Multiply => Some(BinOpKind::Mul),
Divide => Some(BinOpKind::Div),
Modulus => Some(BinOpKind::Rem),
Add => Some(BinOpKind::Add),
Subtract => Some(BinOpKind::Sub),
ShiftLeft => Some(BinOpKind::Shl),
ShiftRight => Some(BinOpKind::Shr),
BitAnd => Some(BinOpKind::BitAnd),
BitXor => Some(BinOpKind::BitXor),
BitOr => Some(BinOpKind::BitOr),
LAnd => Some(BinOpKind::And),
LOr => Some(BinOpKind::Or),
Assign | AssignOp(_) | As | DotDot | DotDotEq | Colon => None,
}
}
/// This operator could be used to follow a block unambiguously.
///
/// This is used for error recovery at the moment, providing a suggestion to wrap blocks with
/// parentheses while having a high degree of confidence on the correctness of the suggestion.
pub fn can_continue_expr_unambiguously(&self) -> bool {
use AssocOp::*;
matches!(
self,
BitXor | // `{ 42 } ^ 3`
Assign | // `{ 42 } = { 42 }`
Divide | // `{ 42 } / 42`
Modulus | // `{ 42 } % 2`
ShiftRight | // `{ 42 } >> 2`
LessEqual | // `{ 42 } <= 3`
Greater | // `{ 42 } > 3`
GreaterEqual | // `{ 42 } >= 3`
AssignOp(_) | // `{ 42 } +=`
As | // `{ 42 } as usize`
// Equal | // `{ 42 } == { 42 }` Accepting these here would regress incorrect
// NotEqual | // `{ 42 } != { 42 } struct literals parser recovery.
Colon, // `{ 42 }: usize`
)
}
}
pub const PREC_CLOSURE: i8 = -40;
pub const PREC_JUMP: i8 = -30;
pub const PREC_RANGE: i8 = -10;
// The range 2..=14 is reserved for AssocOp binary operator precedences.
pub const PREC_PREFIX: i8 = 50;
pub const PREC_POSTFIX: i8 = 60;
pub const PREC_PAREN: i8 = 99;
pub const PREC_FORCE_PAREN: i8 = 100;
#[derive(Debug, Clone, Copy)]
pub enum ExprPrecedence {
Closure,
Break,
Continue,
Ret,
Yield,
Yeet,
Range,
Binary(BinOpKind),
Cast,
Type,
Assign,
AssignOp,
Box,
AddrOf,
Let,
Unary,
Call,
MethodCall,
Field,
Index,
Try,
InlineAsm,
Mac,
Array,
Repeat,
Tup,
Lit,
Path,
Paren,
If,
While,
ForLoop,
Loop,
Match,
ConstBlock,
Block,
TryBlock,
Struct,
Async,
Await,
Err,
}
impl ExprPrecedence {
pub fn order(self) -> i8 {
match self {
ExprPrecedence::Closure => PREC_CLOSURE,
ExprPrecedence::Break
| ExprPrecedence::Continue
| ExprPrecedence::Ret
| ExprPrecedence::Yield
| ExprPrecedence::Yeet => PREC_JUMP,
// `Range` claims to have higher precedence than `Assign`, but `x .. x = x` fails to
// parse, instead of parsing as `(x .. x) = x`. Giving `Range` a lower precedence
// ensures that `pprust` will add parentheses in the right places to get the desired
// parse.
ExprPrecedence::Range => PREC_RANGE,
// Binop-like expr kinds, handled by `AssocOp`.
ExprPrecedence::Binary(op) => AssocOp::from_ast_binop(op).precedence() as i8,
ExprPrecedence::Cast => AssocOp::As.precedence() as i8,
ExprPrecedence::Type => AssocOp::Colon.precedence() as i8,
ExprPrecedence::Assign |
ExprPrecedence::AssignOp => AssocOp::Assign.precedence() as i8,
// Unary, prefix
ExprPrecedence::Box
| ExprPrecedence::AddrOf
// Here `let pats = expr` has `let pats =` as a "unary" prefix of `expr`.
// However, this is not exactly right. When `let _ = a` is the LHS of a binop we
// need parens sometimes. E.g. we can print `(let _ = a) && b` as `let _ = a && b`
// but we need to print `(let _ = a) < b` as-is with parens.
| ExprPrecedence::Let
| ExprPrecedence::Unary => PREC_PREFIX,
// Unary, postfix
ExprPrecedence::Await
| ExprPrecedence::Call
| ExprPrecedence::MethodCall
| ExprPrecedence::Field
| ExprPrecedence::Index
| ExprPrecedence::Try
| ExprPrecedence::InlineAsm
| ExprPrecedence::Mac => PREC_POSTFIX,
// Never need parens
ExprPrecedence::Array
| ExprPrecedence::Repeat
| ExprPrecedence::Tup
| ExprPrecedence::Lit
| ExprPrecedence::Path
| ExprPrecedence::Paren
| ExprPrecedence::If
| ExprPrecedence::While
| ExprPrecedence::ForLoop
| ExprPrecedence::Loop
| ExprPrecedence::Match
| ExprPrecedence::ConstBlock
| ExprPrecedence::Block
| ExprPrecedence::TryBlock
| ExprPrecedence::Async
| ExprPrecedence::Struct
| ExprPrecedence::Err => PREC_PAREN,
}
}
}
/// In `let p = e`, operators with precedence `<=` this one requires parentheses in `e`.
pub fn prec_let_scrutinee_needs_par() -> usize {
AssocOp::LAnd.precedence()
}
/// Suppose we have `let _ = e` and the `order` of `e`.
/// Is the `order` such that `e` in `let _ = e` needs parentheses when it is on the RHS?
///
/// Conversely, suppose that we have `(let _ = a) OP b` and `order` is that of `OP`.
/// Can we print this as `let _ = a OP b`?
pub fn needs_par_as_let_scrutinee(order: i8) -> bool {
order <= prec_let_scrutinee_needs_par() as i8
}
/// Expressions that syntactically contain an "exterior" struct literal i.e., not surrounded by any
/// parens or other delimiters, e.g., `X { y: 1 }`, `X { y: 1 }.method()`, `foo == X { y: 1 }` and
/// `X { y: 1 } == foo` all do, but `(X { y: 1 }) == foo` does not.
pub fn contains_exterior_struct_lit(value: &ast::Expr) -> bool {
match value.kind {
ast::ExprKind::Struct(..) => true,
ast::ExprKind::Assign(ref lhs, ref rhs, _)
| ast::ExprKind::AssignOp(_, ref lhs, ref rhs)
| ast::ExprKind::Binary(_, ref lhs, ref rhs) => {
// X { y: 1 } + X { y: 2 }
contains_exterior_struct_lit(&lhs) || contains_exterior_struct_lit(&rhs)
}
ast::ExprKind::Await(ref x)
| ast::ExprKind::Unary(_, ref x)
| ast::ExprKind::Cast(ref x, _)
| ast::ExprKind::Type(ref x, _)
| ast::ExprKind::Field(ref x, _)
| ast::ExprKind::Index(ref x, _) => {
// &X { y: 1 }, X { y: 1 }.y
contains_exterior_struct_lit(&x)
}
ast::ExprKind::MethodCall(.., ref exprs, _) => {
// X { y: 1 }.bar(...)
contains_exterior_struct_lit(&exprs[0])
}
_ => false,
}
}
|