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//! Various extension methods to ast Expr Nodes, which are hard to code-generate.
use crate::{
ast::{self, child_opt, children, AstChildren, AstNode},
SmolStr,
SyntaxKind::*,
SyntaxToken, T,
};
#[derive(Debug, Clone, PartialEq, Eq)]
pub enum ElseBranch {
Block(ast::Block),
IfExpr(ast::IfExpr),
}
impl ast::IfExpr {
pub fn then_branch(&self) -> Option<ast::Block> {
self.blocks().nth(0)
}
pub fn else_branch(&self) -> Option<ElseBranch> {
let res = match self.blocks().nth(1) {
Some(block) => ElseBranch::Block(block),
None => {
let elif: ast::IfExpr = child_opt(self)?;
ElseBranch::IfExpr(elif)
}
};
Some(res)
}
fn blocks(&self) -> AstChildren<ast::Block> {
children(self)
}
}
impl ast::RefExpr {
pub fn is_mut(&self) -> bool {
self.syntax().children_with_tokens().any(|n| n.kind() == T![mut])
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
pub enum PrefixOp {
/// The `*` operator for dereferencing
Deref,
/// The `!` operator for logical inversion
Not,
/// The `-` operator for negation
Neg,
}
impl ast::PrefixExpr {
pub fn op_kind(&self) -> Option<PrefixOp> {
match self.op_token()?.kind() {
T![*] => Some(PrefixOp::Deref),
T![!] => Some(PrefixOp::Not),
T![-] => Some(PrefixOp::Neg),
_ => None,
}
}
pub fn op_token(&self) -> Option<SyntaxToken> {
self.syntax().first_child_or_token()?.into_token()
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
pub enum BinOp {
/// The `||` operator for boolean OR
BooleanOr,
/// The `&&` operator for boolean AND
BooleanAnd,
/// The `==` operator for equality testing
EqualityTest,
/// The `!=` operator for equality testing
NegatedEqualityTest,
/// The `<=` operator for lesser-equal testing
LesserEqualTest,
/// The `>=` operator for greater-equal testing
GreaterEqualTest,
/// The `<` operator for comparison
LesserTest,
/// The `>` operator for comparison
GreaterTest,
/// The `+` operator for addition
Addition,
/// The `*` operator for multiplication
Multiplication,
/// The `-` operator for subtraction
Subtraction,
/// The `/` operator for division
Division,
/// The `%` operator for remainder after division
Remainder,
/// The `<<` operator for left shift
LeftShift,
/// The `>>` operator for right shift
RightShift,
/// The `^` operator for bitwise XOR
BitwiseXor,
/// The `|` operator for bitwise OR
BitwiseOr,
/// The `&` operator for bitwise AND
BitwiseAnd,
/// The `..` operator for right-open ranges
RangeRightOpen,
/// The `..=` operator for right-closed ranges
RangeRightClosed,
/// The `=` operator for assignment
Assignment,
/// The `+=` operator for assignment after addition
AddAssign,
/// The `/=` operator for assignment after division
DivAssign,
/// The `*=` operator for assignment after multiplication
MulAssign,
/// The `%=` operator for assignment after remainders
RemAssign,
/// The `>>=` operator for assignment after shifting right
ShrAssign,
/// The `<<=` operator for assignment after shifting left
ShlAssign,
/// The `-=` operator for assignment after subtraction
SubAssign,
/// The `|=` operator for assignment after bitwise OR
BitOrAssign,
/// The `&=` operator for assignment after bitwise AND
BitAndAssign,
/// The `^=` operator for assignment after bitwise XOR
BitXorAssign,
}
impl ast::BinExpr {
fn op_details(&self) -> Option<(SyntaxToken, BinOp)> {
self.syntax().children_with_tokens().filter_map(|it| it.into_token()).find_map(|c| match c
.kind()
{
T![||] => Some((c, BinOp::BooleanOr)),
T![&&] => Some((c, BinOp::BooleanAnd)),
T![==] => Some((c, BinOp::EqualityTest)),
T![!=] => Some((c, BinOp::NegatedEqualityTest)),
T![<=] => Some((c, BinOp::LesserEqualTest)),
T![>=] => Some((c, BinOp::GreaterEqualTest)),
T![<] => Some((c, BinOp::LesserTest)),
T![>] => Some((c, BinOp::GreaterTest)),
T![+] => Some((c, BinOp::Addition)),
T![*] => Some((c, BinOp::Multiplication)),
T![-] => Some((c, BinOp::Subtraction)),
T![/] => Some((c, BinOp::Division)),
T![%] => Some((c, BinOp::Remainder)),
T![<<] => Some((c, BinOp::LeftShift)),
T![>>] => Some((c, BinOp::RightShift)),
T![^] => Some((c, BinOp::BitwiseXor)),
T![|] => Some((c, BinOp::BitwiseOr)),
T![&] => Some((c, BinOp::BitwiseAnd)),
T![..] => Some((c, BinOp::RangeRightOpen)),
T![..=] => Some((c, BinOp::RangeRightClosed)),
T![=] => Some((c, BinOp::Assignment)),
T![+=] => Some((c, BinOp::AddAssign)),
T![/=] => Some((c, BinOp::DivAssign)),
T![*=] => Some((c, BinOp::MulAssign)),
T![%=] => Some((c, BinOp::RemAssign)),
T![>>=] => Some((c, BinOp::ShrAssign)),
T![<<=] => Some((c, BinOp::ShlAssign)),
T![-=] => Some((c, BinOp::SubAssign)),
T![|=] => Some((c, BinOp::BitOrAssign)),
T![&=] => Some((c, BinOp::BitAndAssign)),
T![^=] => Some((c, BinOp::BitXorAssign)),
_ => None,
})
}
pub fn op_kind(&self) -> Option<BinOp> {
self.op_details().map(|t| t.1)
}
pub fn op_token(&self) -> Option<SyntaxToken> {
self.op_details().map(|t| t.0)
}
pub fn lhs(&self) -> Option<ast::Expr> {
children(self).nth(0)
}
pub fn rhs(&self) -> Option<ast::Expr> {
children(self).nth(1)
}
pub fn sub_exprs(&self) -> (Option<ast::Expr>, Option<ast::Expr>) {
let mut children = children(self);
let first = children.next();
let second = children.next();
(first, second)
}
}
pub enum ArrayExprKind {
Repeat { initializer: Option<ast::Expr>, repeat: Option<ast::Expr> },
ElementList(AstChildren<ast::Expr>),
}
impl ast::ArrayExpr {
pub fn kind(&self) -> ArrayExprKind {
if self.is_repeat() {
ArrayExprKind::Repeat {
initializer: children(self).nth(0),
repeat: children(self).nth(1),
}
} else {
ArrayExprKind::ElementList(children(self))
}
}
fn is_repeat(&self) -> bool {
self.syntax().children_with_tokens().any(|it| it.kind() == T![;])
}
}
#[derive(Clone, Debug, PartialEq, Eq, Hash)]
pub enum LiteralKind {
String,
ByteString,
Char,
Byte,
IntNumber { suffix: Option<SmolStr> },
FloatNumber { suffix: Option<SmolStr> },
Bool,
}
impl ast::Literal {
pub fn token(&self) -> SyntaxToken {
self.syntax()
.children_with_tokens()
.find(|e| e.kind() != ATTR && !e.kind().is_trivia())
.and_then(|e| e.into_token())
.unwrap()
}
pub fn kind(&self) -> LiteralKind {
match self.token().kind() {
INT_NUMBER => {
let int_suffix_list = [
"isize", "i128", "i64", "i32", "i16", "i8", "usize", "u128", "u64", "u32",
"u16", "u8",
];
// The lexer treats e.g. `1f64` as an integer literal. See
// https://github.com/rust-analyzer/rust-analyzer/issues/1592
// and the comments on the linked PR.
let float_suffix_list = ["f32", "f64"];
let text = self.token().text().to_string();
let float_suffix = float_suffix_list
.iter()
.find(|&s| text.ends_with(s))
.map(|&suf| SmolStr::new(suf));
if float_suffix.is_some() {
LiteralKind::FloatNumber { suffix: float_suffix }
} else {
let suffix = int_suffix_list
.iter()
.find(|&s| text.ends_with(s))
.map(|&suf| SmolStr::new(suf));
LiteralKind::IntNumber { suffix }
}
}
FLOAT_NUMBER => {
let allowed_suffix_list = ["f64", "f32"];
let text = self.token().text().to_string();
let suffix = allowed_suffix_list
.iter()
.find(|&s| text.ends_with(s))
.map(|&suf| SmolStr::new(suf));
LiteralKind::FloatNumber { suffix }
}
STRING | RAW_STRING => LiteralKind::String,
T![true] | T![false] => LiteralKind::Bool,
BYTE_STRING | RAW_BYTE_STRING => LiteralKind::ByteString,
CHAR => LiteralKind::Char,
BYTE => LiteralKind::Byte,
_ => unreachable!(),
}
}
}
#[test]
fn test_literal_with_attr() {
let parse = ast::SourceFile::parse(r#"const _: &str = { #[attr] "Hello" };"#);
let lit = parse.tree().syntax().descendants().find_map(ast::Literal::cast).unwrap();
assert_eq!(lit.token().text(), r#""Hello""#);
}
impl ast::NamedField {
pub fn parent_struct_lit(&self) -> ast::StructLit {
self.syntax().ancestors().find_map(ast::StructLit::cast).unwrap()
}
}
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