use super::*;
use crate::punctuated::Punctuated;
#[cfg(feature = "extra-traits")]
use crate::tt::TokenStreamHelper;
use proc_macro2::{Span, TokenStream};
#[cfg(feature = "printing")]
use quote::IdentFragment;
#[cfg(feature = "printing")]
use std::fmt::{self, Display};
use std::hash::{Hash, Hasher};
#[cfg(all(feature = "parsing", feature = "full"))]
use std::mem;
ast_enum_of_structs! {
pub enum Expr #manual_extra_traits {
Array(ExprArray),
Assign(ExprAssign),
AssignOp(ExprAssignOp),
Async(ExprAsync),
Await(ExprAwait),
Binary(ExprBinary),
Block(ExprBlock),
Box(ExprBox),
Break(ExprBreak),
Call(ExprCall),
Cast(ExprCast),
Closure(ExprClosure),
Continue(ExprContinue),
Field(ExprField),
ForLoop(ExprForLoop),
Group(ExprGroup),
If(ExprIf),
Index(ExprIndex),
Let(ExprLet),
Lit(ExprLit),
Loop(ExprLoop),
Macro(ExprMacro),
Match(ExprMatch),
MethodCall(ExprMethodCall),
Paren(ExprParen),
Path(ExprPath),
Range(ExprRange),
Reference(ExprReference),
Repeat(ExprRepeat),
Return(ExprReturn),
Struct(ExprStruct),
Try(ExprTry),
TryBlock(ExprTryBlock),
Tuple(ExprTuple),
Type(ExprType),
Unary(ExprUnary),
Unsafe(ExprUnsafe),
Verbatim(TokenStream),
While(ExprWhile),
Yield(ExprYield),
#[doc(hidden)]
__Nonexhaustive,
}
}
ast_struct! {
pub struct ExprArray #full {
pub attrs: Vec<Attribute>,
pub bracket_token: token::Bracket,
pub elems: Punctuated<Expr, Token![,]>,
}
}
ast_struct! {
pub struct ExprAssign #full {
pub attrs: Vec<Attribute>,
pub left: Box<Expr>,
pub eq_token: Token![=],
pub right: Box<Expr>,
}
}
ast_struct! {
pub struct ExprAssignOp #full {
pub attrs: Vec<Attribute>,
pub left: Box<Expr>,
pub op: BinOp,
pub right: Box<Expr>,
}
}
ast_struct! {
pub struct ExprAsync #full {
pub attrs: Vec<Attribute>,
pub async_token: Token![async],
pub capture: Option<Token![move]>,
pub block: Block,
}
}
ast_struct! {
pub struct ExprAwait #full {
pub attrs: Vec<Attribute>,
pub base: Box<Expr>,
pub dot_token: Token![.],
pub await_token: token::Await,
}
}
ast_struct! {
pub struct ExprBinary {
pub attrs: Vec<Attribute>,
pub left: Box<Expr>,
pub op: BinOp,
pub right: Box<Expr>,
}
}
ast_struct! {
pub struct ExprBlock #full {
pub attrs: Vec<Attribute>,
pub label: Option<Label>,
pub block: Block,
}
}
ast_struct! {
pub struct ExprBox #full {
pub attrs: Vec<Attribute>,
pub box_token: Token![box],
pub expr: Box<Expr>,
}
}
ast_struct! {
pub struct ExprBreak #full {
pub attrs: Vec<Attribute>,
pub break_token: Token![break],
pub label: Option<Lifetime>,
pub expr: Option<Box<Expr>>,
}
}
ast_struct! {
pub struct ExprCall {
pub attrs: Vec<Attribute>,
pub func: Box<Expr>,
pub paren_token: token::Paren,
pub args: Punctuated<Expr, Token![,]>,
}
}
ast_struct! {
pub struct ExprCast {
pub attrs: Vec<Attribute>,
pub expr: Box<Expr>,
pub as_token: Token![as],
pub ty: Box<Type>,
}
}
ast_struct! {
pub struct ExprClosure #full {
pub attrs: Vec<Attribute>,
pub asyncness: Option<Token![async]>,
pub movability: Option<Token![static]>,
pub capture: Option<Token![move]>,
pub or1_token: Token![|],
pub inputs: Punctuated<Pat, Token![,]>,
pub or2_token: Token![|],
pub output: ReturnType,
pub body: Box<Expr>,
}
}
ast_struct! {
pub struct ExprContinue #full {
pub attrs: Vec<Attribute>,
pub continue_token: Token![continue],
pub label: Option<Lifetime>,
}
}
ast_struct! {
pub struct ExprField {
pub attrs: Vec<Attribute>,
pub base: Box<Expr>,
pub dot_token: Token![.],
pub member: Member,
}
}
ast_struct! {
pub struct ExprForLoop #full {
pub attrs: Vec<Attribute>,
pub label: Option<Label>,
pub for_token: Token![for],
pub pat: Pat,
pub in_token: Token![in],
pub expr: Box<Expr>,
pub body: Block,
}
}
ast_struct! {
pub struct ExprGroup #full {
pub attrs: Vec<Attribute>,
pub group_token: token::Group,
pub expr: Box<Expr>,
}
}
ast_struct! {
pub struct ExprIf #full {
pub attrs: Vec<Attribute>,
pub if_token: Token![if],
pub cond: Box<Expr>,
pub then_branch: Block,
pub else_branch: Option<(Token![else], Box<Expr>)>,
}
}
ast_struct! {
pub struct ExprIndex {
pub attrs: Vec<Attribute>,
pub expr: Box<Expr>,
pub bracket_token: token::Bracket,
pub index: Box<Expr>,
}
}
ast_struct! {
pub struct ExprLet #full {
pub attrs: Vec<Attribute>,
pub let_token: Token![let],
pub pat: Pat,
pub eq_token: Token![=],
pub expr: Box<Expr>,
}
}
ast_struct! {
pub struct ExprLit {
pub attrs: Vec<Attribute>,
pub lit: Lit,
}
}
ast_struct! {
pub struct ExprLoop #full {
pub attrs: Vec<Attribute>,
pub label: Option<Label>,
pub loop_token: Token![loop],
pub body: Block,
}
}
ast_struct! {
pub struct ExprMacro #full {
pub attrs: Vec<Attribute>,
pub mac: Macro,
}
}
ast_struct! {
pub struct ExprMatch #full {
pub attrs: Vec<Attribute>,
pub match_token: Token![match],
pub expr: Box<Expr>,
pub brace_token: token::Brace,
pub arms: Vec<Arm>,
}
}
ast_struct! {
pub struct ExprMethodCall #full {
pub attrs: Vec<Attribute>,
pub receiver: Box<Expr>,
pub dot_token: Token![.],
pub method: Ident,
pub turbofish: Option<MethodTurbofish>,
pub paren_token: token::Paren,
pub args: Punctuated<Expr, Token![,]>,
}
}
ast_struct! {
pub struct ExprParen {
pub attrs: Vec<Attribute>,
pub paren_token: token::Paren,
pub expr: Box<Expr>,
}
}
ast_struct! {
pub struct ExprPath {
pub attrs: Vec<Attribute>,
pub qself: Option<QSelf>,
pub path: Path,
}
}
ast_struct! {
pub struct ExprRange #full {
pub attrs: Vec<Attribute>,
pub from: Option<Box<Expr>>,
pub limits: RangeLimits,
pub to: Option<Box<Expr>>,
}
}
ast_struct! {
pub struct ExprReference #full {
pub attrs: Vec<Attribute>,
pub and_token: Token![&],
pub raw: Reserved,
pub mutability: Option<Token![mut]>,
pub expr: Box<Expr>,
}
}
ast_struct! {
pub struct ExprRepeat #full {
pub attrs: Vec<Attribute>,
pub bracket_token: token::Bracket,
pub expr: Box<Expr>,
pub semi_token: Token![;],
pub len: Box<Expr>,
}
}
ast_struct! {
pub struct ExprReturn #full {
pub attrs: Vec<Attribute>,
pub return_token: Token![return],
pub expr: Option<Box<Expr>>,
}
}
ast_struct! {
pub struct ExprStruct #full {
pub attrs: Vec<Attribute>,
pub path: Path,
pub brace_token: token::Brace,
pub fields: Punctuated<FieldValue, Token![,]>,
pub dot2_token: Option<Token![..]>,
pub rest: Option<Box<Expr>>,
}
}
ast_struct! {
pub struct ExprTry #full {
pub attrs: Vec<Attribute>,
pub expr: Box<Expr>,
pub question_token: Token![?],
}
}
ast_struct! {
pub struct ExprTryBlock #full {
pub attrs: Vec<Attribute>,
pub try_token: Token![try],
pub block: Block,
}
}
ast_struct! {
pub struct ExprTuple #full {
pub attrs: Vec<Attribute>,
pub paren_token: token::Paren,
pub elems: Punctuated<Expr, Token![,]>,
}
}
ast_struct! {
pub struct ExprType #full {
pub attrs: Vec<Attribute>,
pub expr: Box<Expr>,
pub colon_token: Token![:],
pub ty: Box<Type>,
}
}
ast_struct! {
pub struct ExprUnary {
pub attrs: Vec<Attribute>,
pub op: UnOp,
pub expr: Box<Expr>,
}
}
ast_struct! {
pub struct ExprUnsafe #full {
pub attrs: Vec<Attribute>,
pub unsafe_token: Token![unsafe],
pub block: Block,
}
}
ast_struct! {
pub struct ExprWhile #full {
pub attrs: Vec<Attribute>,
pub label: Option<Label>,
pub while_token: Token![while],
pub cond: Box<Expr>,
pub body: Block,
}
}
ast_struct! {
pub struct ExprYield #full {
pub attrs: Vec<Attribute>,
pub yield_token: Token![yield],
pub expr: Option<Box<Expr>>,
}
}
#[cfg(feature = "extra-traits")]
impl Eq for Expr {}
#[cfg(feature = "extra-traits")]
impl PartialEq for Expr {
fn eq(&self, other: &Self) -> bool {
match (self, other) {
(Expr::Array(this), Expr::Array(other)) => this == other,
(Expr::Assign(this), Expr::Assign(other)) => this == other,
(Expr::AssignOp(this), Expr::AssignOp(other)) => this == other,
(Expr::Async(this), Expr::Async(other)) => this == other,
(Expr::Await(this), Expr::Await(other)) => this == other,
(Expr::Binary(this), Expr::Binary(other)) => this == other,
(Expr::Block(this), Expr::Block(other)) => this == other,
(Expr::Box(this), Expr::Box(other)) => this == other,
(Expr::Break(this), Expr::Break(other)) => this == other,
(Expr::Call(this), Expr::Call(other)) => this == other,
(Expr::Cast(this), Expr::Cast(other)) => this == other,
(Expr::Closure(this), Expr::Closure(other)) => this == other,
(Expr::Continue(this), Expr::Continue(other)) => this == other,
(Expr::Field(this), Expr::Field(other)) => this == other,
(Expr::ForLoop(this), Expr::ForLoop(other)) => this == other,
(Expr::Group(this), Expr::Group(other)) => this == other,
(Expr::If(this), Expr::If(other)) => this == other,
(Expr::Index(this), Expr::Index(other)) => this == other,
(Expr::Let(this), Expr::Let(other)) => this == other,
(Expr::Lit(this), Expr::Lit(other)) => this == other,
(Expr::Loop(this), Expr::Loop(other)) => this == other,
(Expr::Macro(this), Expr::Macro(other)) => this == other,
(Expr::Match(this), Expr::Match(other)) => this == other,
(Expr::MethodCall(this), Expr::MethodCall(other)) => this == other,
(Expr::Paren(this), Expr::Paren(other)) => this == other,
(Expr::Path(this), Expr::Path(other)) => this == other,
(Expr::Range(this), Expr::Range(other)) => this == other,
(Expr::Reference(this), Expr::Reference(other)) => this == other,
(Expr::Repeat(this), Expr::Repeat(other)) => this == other,
(Expr::Return(this), Expr::Return(other)) => this == other,
(Expr::Struct(this), Expr::Struct(other)) => this == other,
(Expr::Try(this), Expr::Try(other)) => this == other,
(Expr::TryBlock(this), Expr::TryBlock(other)) => this == other,
(Expr::Tuple(this), Expr::Tuple(other)) => this == other,
(Expr::Type(this), Expr::Type(other)) => this == other,
(Expr::Unary(this), Expr::Unary(other)) => this == other,
(Expr::Unsafe(this), Expr::Unsafe(other)) => this == other,
(Expr::Verbatim(this), Expr::Verbatim(other)) => {
TokenStreamHelper(this) == TokenStreamHelper(other)
}
(Expr::While(this), Expr::While(other)) => this == other,
(Expr::Yield(this), Expr::Yield(other)) => this == other,
_ => false,
}
}
}
#[cfg(feature = "extra-traits")]
impl Hash for Expr {
fn hash<H>(&self, hash: &mut H)
where
H: Hasher,
{
match self {
Expr::Array(expr) => {
hash.write_u8(0);
expr.hash(hash);
}
Expr::Assign(expr) => {
hash.write_u8(1);
expr.hash(hash);
}
Expr::AssignOp(expr) => {
hash.write_u8(2);
expr.hash(hash);
}
Expr::Async(expr) => {
hash.write_u8(3);
expr.hash(hash);
}
Expr::Await(expr) => {
hash.write_u8(4);
expr.hash(hash);
}
Expr::Binary(expr) => {
hash.write_u8(5);
expr.hash(hash);
}
Expr::Block(expr) => {
hash.write_u8(6);
expr.hash(hash);
}
Expr::Box(expr) => {
hash.write_u8(7);
expr.hash(hash);
}
Expr::Break(expr) => {
hash.write_u8(8);
expr.hash(hash);
}
Expr::Call(expr) => {
hash.write_u8(9);
expr.hash(hash);
}
Expr::Cast(expr) => {
hash.write_u8(10);
expr.hash(hash);
}
Expr::Closure(expr) => {
hash.write_u8(11);
expr.hash(hash);
}
Expr::Continue(expr) => {
hash.write_u8(12);
expr.hash(hash);
}
Expr::Field(expr) => {
hash.write_u8(13);
expr.hash(hash);
}
Expr::ForLoop(expr) => {
hash.write_u8(14);
expr.hash(hash);
}
Expr::Group(expr) => {
hash.write_u8(15);
expr.hash(hash);
}
Expr::If(expr) => {
hash.write_u8(16);
expr.hash(hash);
}
Expr::Index(expr) => {
hash.write_u8(17);
expr.hash(hash);
}
Expr::Let(expr) => {
hash.write_u8(18);
expr.hash(hash);
}
Expr::Lit(expr) => {
hash.write_u8(19);
expr.hash(hash);
}
Expr::Loop(expr) => {
hash.write_u8(20);
expr.hash(hash);
}
Expr::Macro(expr) => {
hash.write_u8(21);
expr.hash(hash);
}
Expr::Match(expr) => {
hash.write_u8(22);
expr.hash(hash);
}
Expr::MethodCall(expr) => {
hash.write_u8(23);
expr.hash(hash);
}
Expr::Paren(expr) => {
hash.write_u8(24);
expr.hash(hash);
}
Expr::Path(expr) => {
hash.write_u8(25);
expr.hash(hash);
}
Expr::Range(expr) => {
hash.write_u8(26);
expr.hash(hash);
}
Expr::Reference(expr) => {
hash.write_u8(27);
expr.hash(hash);
}
Expr::Repeat(expr) => {
hash.write_u8(28);
expr.hash(hash);
}
Expr::Return(expr) => {
hash.write_u8(29);
expr.hash(hash);
}
Expr::Struct(expr) => {
hash.write_u8(30);
expr.hash(hash);
}
Expr::Try(expr) => {
hash.write_u8(31);
expr.hash(hash);
}
Expr::TryBlock(expr) => {
hash.write_u8(32);
expr.hash(hash);
}
Expr::Tuple(expr) => {
hash.write_u8(33);
expr.hash(hash);
}
Expr::Type(expr) => {
hash.write_u8(34);
expr.hash(hash);
}
Expr::Unary(expr) => {
hash.write_u8(35);
expr.hash(hash);
}
Expr::Unsafe(expr) => {
hash.write_u8(36);
expr.hash(hash);
}
Expr::Verbatim(expr) => {
hash.write_u8(37);
TokenStreamHelper(expr).hash(hash);
}
Expr::While(expr) => {
hash.write_u8(38);
expr.hash(hash);
}
Expr::Yield(expr) => {
hash.write_u8(39);
expr.hash(hash);
}
Expr::__Nonexhaustive => unreachable!(),
}
}
}
impl Expr {
#[cfg(all(feature = "parsing", feature = "full"))]
pub(crate) fn replace_attrs(&mut self, new: Vec<Attribute>) -> Vec<Attribute> {
match self {
Expr::Box(ExprBox { attrs, .. })
| Expr::Array(ExprArray { attrs, .. })
| Expr::Call(ExprCall { attrs, .. })
| Expr::MethodCall(ExprMethodCall { attrs, .. })
| Expr::Tuple(ExprTuple { attrs, .. })
| Expr::Binary(ExprBinary { attrs, .. })
| Expr::Unary(ExprUnary { attrs, .. })
| Expr::Lit(ExprLit { attrs, .. })
| Expr::Cast(ExprCast { attrs, .. })
| Expr::Type(ExprType { attrs, .. })
| Expr::Let(ExprLet { attrs, .. })
| Expr::If(ExprIf { attrs, .. })
| Expr::While(ExprWhile { attrs, .. })
| Expr::ForLoop(ExprForLoop { attrs, .. })
| Expr::Loop(ExprLoop { attrs, .. })
| Expr::Match(ExprMatch { attrs, .. })
| Expr::Closure(ExprClosure { attrs, .. })
| Expr::Unsafe(ExprUnsafe { attrs, .. })
| Expr::Block(ExprBlock { attrs, .. })
| Expr::Assign(ExprAssign { attrs, .. })
| Expr::AssignOp(ExprAssignOp { attrs, .. })
| Expr::Field(ExprField { attrs, .. })
| Expr::Index(ExprIndex { attrs, .. })
| Expr::Range(ExprRange { attrs, .. })
| Expr::Path(ExprPath { attrs, .. })
| Expr::Reference(ExprReference { attrs, .. })
| Expr::Break(ExprBreak { attrs, .. })
| Expr::Continue(ExprContinue { attrs, .. })
| Expr::Return(ExprReturn { attrs, .. })
| Expr::Macro(ExprMacro { attrs, .. })
| Expr::Struct(ExprStruct { attrs, .. })
| Expr::Repeat(ExprRepeat { attrs, .. })
| Expr::Paren(ExprParen { attrs, .. })
| Expr::Group(ExprGroup { attrs, .. })
| Expr::Try(ExprTry { attrs, .. })
| Expr::Async(ExprAsync { attrs, .. })
| Expr::Await(ExprAwait { attrs, .. })
| Expr::TryBlock(ExprTryBlock { attrs, .. })
| Expr::Yield(ExprYield { attrs, .. }) => mem::replace(attrs, new),
Expr::Verbatim(_) => Vec::new(),
Expr::__Nonexhaustive => unreachable!(),
}
}
}
ast_enum! {
#[derive(Eq, PartialEq, Hash)]
pub enum Member #manual_extra_traits {
Named(Ident),
Unnamed(Index),
}
}
#[cfg(feature = "printing")]
impl IdentFragment for Member {
fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
match self {
Member::Named(m) => Display::fmt(m, formatter),
Member::Unnamed(m) => Display::fmt(&m.index, formatter),
}
}
fn span(&self) -> Option<Span> {
match self {
Member::Named(m) => Some(m.span()),
Member::Unnamed(m) => Some(m.span),
}
}
}
ast_struct! {
pub struct Index #manual_extra_traits {
pub index: u32,
pub span: Span,
}
}
impl From<usize> for Index {
fn from(index: usize) -> Index {
assert!(index < u32::max_value() as usize);
Index {
index: index as u32,
span: Span::call_site(),
}
}
}
impl Eq for Index {}
impl PartialEq for Index {
fn eq(&self, other: &Self) -> bool {
self.index == other.index
}
}
impl Hash for Index {
fn hash<H: Hasher>(&self, state: &mut H) {
self.index.hash(state);
}
}
#[cfg(feature = "printing")]
impl IdentFragment for Index {
fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
Display::fmt(&self.index, formatter)
}
fn span(&self) -> Option<Span> {
Some(self.span)
}
}
#[cfg(feature = "full")]
ast_struct! {
#[derive(Default)]
pub struct Reserved {
_private: (),
}
}
#[cfg(feature = "full")]
ast_struct! {
pub struct MethodTurbofish {
pub colon2_token: Token![::],
pub lt_token: Token![<],
pub args: Punctuated<GenericMethodArgument, Token![,]>,
pub gt_token: Token![>],
}
}
#[cfg(feature = "full")]
ast_enum! {
pub enum GenericMethodArgument {
Type(Type),
Const(Expr),
}
}
#[cfg(feature = "full")]
ast_struct! {
pub struct FieldValue {
pub attrs: Vec<Attribute>,
pub member: Member,
pub colon_token: Option<Token![:]>,
pub expr: Expr,
}
}
#[cfg(feature = "full")]
ast_struct! {
pub struct Label {
pub name: Lifetime,
pub colon_token: Token![:],
}
}
#[cfg(feature = "full")]
ast_struct! {
pub struct Arm {
pub attrs: Vec<Attribute>,
pub pat: Pat,
pub guard: Option<(Token![if], Box<Expr>)>,
pub fat_arrow_token: Token![=>],
pub body: Box<Expr>,
pub comma: Option<Token![,]>,
}
}
#[cfg(feature = "full")]
ast_enum! {
#[cfg_attr(feature = "clone-impls", derive(Copy))]
pub enum RangeLimits {
HalfOpen(Token![..]),
Closed(Token![..=]),
}
}
#[cfg(any(feature = "parsing", feature = "printing"))]
#[cfg(feature = "full")]
pub(crate) fn requires_terminator(expr: &Expr) -> bool {
match *expr {
Expr::Unsafe(..)
| Expr::Block(..)
| Expr::If(..)
| Expr::Match(..)
| Expr::While(..)
| Expr::Loop(..)
| Expr::ForLoop(..)
| Expr::Async(..)
| Expr::TryBlock(..) => false,
_ => true,
}
}
#[cfg(feature = "parsing")]
pub(crate) mod parsing {
use super::*;
use crate::parse::discouraged::Speculative;
use crate::parse::{Parse, ParseStream, Result};
use crate::path;
crate::custom_keyword!(raw);
#[derive(Copy, Clone)]
pub struct AllowStruct(bool);
#[derive(Copy, Clone, PartialEq, PartialOrd)]
enum Precedence {
Any,
Assign,
Range,
Or,
And,
Compare,
BitOr,
BitXor,
BitAnd,
Shift,
Arithmetic,
Term,
Cast,
}
impl Precedence {
fn of(op: &BinOp) -> Self {
match *op {
BinOp::Add(_) | BinOp::Sub(_) => Precedence::Arithmetic,
BinOp::Mul(_) | BinOp::Div(_) | BinOp::Rem(_) => Precedence::Term,
BinOp::And(_) => Precedence::And,
BinOp::Or(_) => Precedence::Or,
BinOp::BitXor(_) => Precedence::BitXor,
BinOp::BitAnd(_) => Precedence::BitAnd,
BinOp::BitOr(_) => Precedence::BitOr,
BinOp::Shl(_) | BinOp::Shr(_) => Precedence::Shift,
BinOp::Eq(_)
| BinOp::Lt(_)
| BinOp::Le(_)
| BinOp::Ne(_)
| BinOp::Ge(_)
| BinOp::Gt(_) => Precedence::Compare,
BinOp::AddEq(_)
| BinOp::SubEq(_)
| BinOp::MulEq(_)
| BinOp::DivEq(_)
| BinOp::RemEq(_)
| BinOp::BitXorEq(_)
| BinOp::BitAndEq(_)
| BinOp::BitOrEq(_)
| BinOp::ShlEq(_)
| BinOp::ShrEq(_) => Precedence::Assign,
}
}
}
impl Parse for Expr {
fn parse(input: ParseStream) -> Result<Self> {
ambiguous_expr(input, AllowStruct(true))
}
}
#[cfg(feature = "full")]
fn expr_no_struct(input: ParseStream) -> Result<Expr> {
ambiguous_expr(input, AllowStruct(false))
}
#[cfg(feature = "full")]
fn parse_expr(
input: ParseStream,
mut lhs: Expr,
allow_struct: AllowStruct,
base: Precedence,
) -> Result<Expr> {
loop {
if input
.fork()
.parse::<BinOp>()
.ok()
.map_or(false, |op| Precedence::of(&op) >= base)
{
let op: BinOp = input.parse()?;
let precedence = Precedence::of(&op);
let mut rhs = unary_expr(input, allow_struct)?;
loop {
let next = peek_precedence(input);
if next > precedence || next == precedence && precedence == Precedence::Assign {
rhs = parse_expr(input, rhs, allow_struct, next)?;
} else {
break;
}
}
lhs = if precedence == Precedence::Assign {
Expr::AssignOp(ExprAssignOp {
attrs: Vec::new(),
left: Box::new(lhs),
op,
right: Box::new(rhs),
})
} else {
Expr::Binary(ExprBinary {
attrs: Vec::new(),
left: Box::new(lhs),
op,
right: Box::new(rhs),
})
};
} else if Precedence::Assign >= base
&& input.peek(Token![=])
&& !input.peek(Token![==])
&& !input.peek(Token![=>])
{
let eq_token: Token![=] = input.parse()?;
let mut rhs = unary_expr(input, allow_struct)?;
loop {
let next = peek_precedence(input);
if next >= Precedence::Assign {
rhs = parse_expr(input, rhs, allow_struct, next)?;
} else {
break;
}
}
lhs = Expr::Assign(ExprAssign {
attrs: Vec::new(),
left: Box::new(lhs),
eq_token,
right: Box::new(rhs),
});
} else if Precedence::Range >= base && input.peek(Token![..]) {
let limits: RangeLimits = input.parse()?;
let rhs = if input.is_empty()
|| input.peek(Token![,])
|| input.peek(Token![;])
|| !allow_struct.0 && input.peek(token::Brace)
{
None
} else {
let mut rhs = unary_expr(input, allow_struct)?;
loop {
let next = peek_precedence(input);
if next > Precedence::Range {
rhs = parse_expr(input, rhs, allow_struct, next)?;
} else {
break;
}
}
Some(rhs)
};
lhs = Expr::Range(ExprRange {
attrs: Vec::new(),
from: Some(Box::new(lhs)),
limits,
to: rhs.map(Box::new),
});
} else if Precedence::Cast >= base && input.peek(Token![as]) {
let as_token: Token![as] = input.parse()?;
let ty = input.call(Type::without_plus)?;
lhs = Expr::Cast(ExprCast {
attrs: Vec::new(),
expr: Box::new(lhs),
as_token,
ty: Box::new(ty),
});
} else if Precedence::Cast >= base && input.peek(Token![:]) && !input.peek(Token![::]) {
let colon_token: Token![:] = input.parse()?;
let ty = input.call(Type::without_plus)?;
lhs = Expr::Type(ExprType {
attrs: Vec::new(),
expr: Box::new(lhs),
colon_token,
ty: Box::new(ty),
});
} else {
break;
}
}
Ok(lhs)
}
#[cfg(not(feature = "full"))]
fn parse_expr(
input: ParseStream,
mut lhs: Expr,
allow_struct: AllowStruct,
base: Precedence,
) -> Result<Expr> {
loop {
if input
.fork()
.parse::<BinOp>()
.ok()
.map_or(false, |op| Precedence::of(&op) >= base)
{
let op: BinOp = input.parse()?;
let precedence = Precedence::of(&op);
let mut rhs = unary_expr(input, allow_struct)?;
loop {
let next = peek_precedence(input);
if next > precedence || next == precedence && precedence == Precedence::Assign {
rhs = parse_expr(input, rhs, allow_struct, next)?;
} else {
break;
}
}
lhs = Expr::Binary(ExprBinary {
attrs: Vec::new(),
left: Box::new(lhs),
op,
right: Box::new(rhs),
});
} else if Precedence::Cast >= base && input.peek(Token![as]) {
let as_token: Token![as] = input.parse()?;
let ty = input.call(Type::without_plus)?;
lhs = Expr::Cast(ExprCast {
attrs: Vec::new(),
expr: Box::new(lhs),
as_token,
ty: Box::new(ty),
});
} else {
break;
}
}
Ok(lhs)
}
fn peek_precedence(input: ParseStream) -> Precedence {
if let Ok(op) = input.fork().parse() {
Precedence::of(&op)
} else if input.peek(Token![=]) && !input.peek(Token![=>]) {
Precedence::Assign
} else if input.peek(Token![..]) {
Precedence::Range
} else if input.peek(Token![as]) || input.peek(Token![:]) && !input.peek(Token![::]) {
Precedence::Cast
} else {
Precedence::Any
}
}
fn ambiguous_expr(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
let lhs = unary_expr(input, allow_struct)?;
parse_expr(input, lhs, allow_struct, Precedence::Any)
}
#[cfg(feature = "full")]
fn unary_expr(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
let begin = input.fork();
let ahead = input.fork();
let attrs = ahead.call(Attribute::parse_outer)?;
if ahead.peek(Token![&])
|| ahead.peek(Token![box])
|| ahead.peek(Token![*])
|| ahead.peek(Token![!])
|| ahead.peek(Token![-])
{
input.advance_to(&ahead);
if input.peek(Token![&]) {
let and_token: Token![&] = input.parse()?;
let raw: Option<raw> = if input.peek(raw)
&& (input.peek2(Token![mut]) || input.peek2(Token![const]))
{
Some(input.parse()?)
} else {
None
};
let mutability: Option<Token![mut]> = input.parse()?;
if raw.is_some() && mutability.is_none() {
input.parse::<Token![const]>()?;
}
let expr = Box::new(unary_expr(input, allow_struct)?);
if raw.is_some() {
Ok(Expr::Verbatim(verbatim::between(begin, input)))
} else {
Ok(Expr::Reference(ExprReference {
attrs,
and_token,
raw: Reserved::default(),
mutability,
expr,
}))
}
} else if input.peek(Token![box]) {
Ok(Expr::Box(ExprBox {
attrs,
box_token: input.parse()?,
expr: Box::new(unary_expr(input, allow_struct)?),
}))
} else {
Ok(Expr::Unary(ExprUnary {
attrs,
op: input.parse()?,
expr: Box::new(unary_expr(input, allow_struct)?),
}))
}
} else {
trailer_expr(input, allow_struct)
}
}
#[cfg(not(feature = "full"))]
fn unary_expr(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
let ahead = input.fork();
let attrs = ahead.call(Attribute::parse_outer)?;
if ahead.peek(Token![*]) || ahead.peek(Token![!]) || ahead.peek(Token![-]) {
input.advance_to(&ahead);
Ok(Expr::Unary(ExprUnary {
attrs,
op: input.parse()?,
expr: Box::new(unary_expr(input, allow_struct)?),
}))
} else {
trailer_expr(input, allow_struct)
}
}
#[cfg(feature = "full")]
fn trailer_expr(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
if input.peek(token::Group) {
return input.call(expr_group).map(Expr::Group);
}
let outer_attrs = input.call(Attribute::parse_outer)?;
let atom = atom_expr(input, allow_struct)?;
let mut e = trailer_helper(input, atom)?;
let inner_attrs = e.replace_attrs(Vec::new());
let attrs = private::attrs(outer_attrs, inner_attrs);
e.replace_attrs(attrs);
Ok(e)
}
#[cfg(feature = "full")]
fn trailer_helper(input: ParseStream, mut e: Expr) -> Result<Expr> {
loop {
if input.peek(token::Paren) {
let content;
e = Expr::Call(ExprCall {
attrs: Vec::new(),
func: Box::new(e),
paren_token: parenthesized!(content in input),
args: content.parse_terminated(Expr::parse)?,
});
} else if input.peek(Token![.]) && !input.peek(Token![..]) {
let dot_token: Token![.] = input.parse()?;
if input.peek(token::Await) {
e = Expr::Await(ExprAwait {
attrs: Vec::new(),
base: Box::new(e),
dot_token,
await_token: input.parse()?,
});
continue;
}
let member: Member = input.parse()?;
let turbofish = if member.is_named() && input.peek(Token![::]) {
Some(MethodTurbofish {
colon2_token: input.parse()?,
lt_token: input.parse()?,
args: {
let mut args = Punctuated::new();
loop {
if input.peek(Token![>]) {
break;
}
let value = input.call(generic_method_argument)?;
args.push_value(value);
if input.peek(Token![>]) {
break;
}
let punct = input.parse()?;
args.push_punct(punct);
}
args
},
gt_token: input.parse()?,
})
} else {
None
};
if turbofish.is_some() || input.peek(token::Paren) {
if let Member::Named(method) = member {
let content;
e = Expr::MethodCall(ExprMethodCall {
attrs: Vec::new(),
receiver: Box::new(e),
dot_token,
method,
turbofish,
paren_token: parenthesized!(content in input),
args: content.parse_terminated(Expr::parse)?,
});
continue;
}
}
e = Expr::Field(ExprField {
attrs: Vec::new(),
base: Box::new(e),
dot_token,
member,
});
} else if input.peek(token::Bracket) {
let content;
e = Expr::Index(ExprIndex {
attrs: Vec::new(),
expr: Box::new(e),
bracket_token: bracketed!(content in input),
index: content.parse()?,
});
} else if input.peek(Token![?]) {
e = Expr::Try(ExprTry {
attrs: Vec::new(),
expr: Box::new(e),
question_token: input.parse()?,
});
} else {
break;
}
}
Ok(e)
}
#[cfg(not(feature = "full"))]
fn trailer_expr(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
let mut e = atom_expr(input, allow_struct)?;
loop {
if input.peek(token::Paren) {
let content;
e = Expr::Call(ExprCall {
attrs: Vec::new(),
func: Box::new(e),
paren_token: parenthesized!(content in input),
args: content.parse_terminated(Expr::parse)?,
});
} else if input.peek(Token![.]) && !input.peek(Token![..]) && !input.peek2(token::Await)
{
e = Expr::Field(ExprField {
attrs: Vec::new(),
base: Box::new(e),
dot_token: input.parse()?,
member: input.parse()?,
});
} else if input.peek(token::Bracket) {
let content;
e = Expr::Index(ExprIndex {
attrs: Vec::new(),
expr: Box::new(e),
bracket_token: bracketed!(content in input),
index: content.parse()?,
});
} else {
break;
}
}
Ok(e)
}
#[cfg(feature = "full")]
fn atom_expr(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
if input.peek(token::Group) {
input.call(expr_group).map(Expr::Group)
} else if input.peek(Lit) {
input.parse().map(Expr::Lit)
} else if input.peek(Token![async])
&& (input.peek2(token::Brace) || input.peek2(Token![move]) && input.peek3(token::Brace))
{
input.call(expr_async).map(Expr::Async)
} else if input.peek(Token![try]) && input.peek2(token::Brace) {
input.call(expr_try_block).map(Expr::TryBlock)
} else if input.peek(Token![|])
|| input.peek(Token![async]) && (input.peek2(Token![|]) || input.peek2(Token![move]))
|| input.peek(Token![static])
|| input.peek(Token![move])
{
expr_closure(input, allow_struct).map(Expr::Closure)
} else if input.peek(Ident)
|| input.peek(Token![::])
|| input.peek(Token![<])
|| input.peek(Token![self])
|| input.peek(Token![Self])
|| input.peek(Token![super])
|| input.peek(Token![extern])
|| input.peek(Token![crate])
{
path_or_macro_or_struct(input, allow_struct)
} else if input.peek(token::Paren) {
paren_or_tuple(input)
} else if input.peek(Token![break]) {
expr_break(input, allow_struct).map(Expr::Break)
} else if input.peek(Token![continue]) {
input.call(expr_continue).map(Expr::Continue)
} else if input.peek(Token![return]) {
expr_ret(input, allow_struct).map(Expr::Return)
} else if input.peek(token::Bracket) {
array_or_repeat(input)
} else if input.peek(Token![let]) {
input.call(expr_let).map(Expr::Let)
} else if input.peek(Token![if]) {
input.parse().map(Expr::If)
} else if input.peek(Token![while]) {
input.parse().map(Expr::While)
} else if input.peek(Token![for]) {
input.parse().map(Expr::ForLoop)
} else if input.peek(Token![loop]) {
input.parse().map(Expr::Loop)
} else if input.peek(Token![match]) {
input.parse().map(Expr::Match)
} else if input.peek(Token![yield]) {
input.call(expr_yield).map(Expr::Yield)
} else if input.peek(Token![unsafe]) {
input.call(expr_unsafe).map(Expr::Unsafe)
} else if input.peek(token::Brace) {
input.call(expr_block).map(Expr::Block)
} else if input.peek(Token![..]) {
expr_range(input, allow_struct).map(Expr::Range)
} else if input.peek(Lifetime) {
let the_label: Label = input.parse()?;
let mut expr = if input.peek(Token![while]) {
Expr::While(input.parse()?)
} else if input.peek(Token![for]) {
Expr::ForLoop(input.parse()?)
} else if input.peek(Token![loop]) {
Expr::Loop(input.parse()?)
} else if input.peek(token::Brace) {
Expr::Block(input.call(expr_block)?)
} else {
return Err(input.error("expected loop or block expression"));
};
match &mut expr {
Expr::While(ExprWhile { label, .. })
| Expr::ForLoop(ExprForLoop { label, .. })
| Expr::Loop(ExprLoop { label, .. })
| Expr::Block(ExprBlock { label, .. }) => *label = Some(the_label),
_ => unreachable!(),
}
Ok(expr)
} else {
Err(input.error("expected expression"))
}
}
#[cfg(not(feature = "full"))]
fn atom_expr(input: ParseStream, _allow_struct: AllowStruct) -> Result<Expr> {
if input.peek(Lit) {
input.parse().map(Expr::Lit)
} else if input.peek(token::Paren) {
input.call(expr_paren).map(Expr::Paren)
} else if input.peek(Ident)
|| input.peek(Token![::])
|| input.peek(Token![<])
|| input.peek(Token![self])
|| input.peek(Token![Self])
|| input.peek(Token![super])
|| input.peek(Token![extern])
|| input.peek(Token![crate])
{
input.parse().map(Expr::Path)
} else {
Err(input.error("unsupported expression; enable syn's features=[\"full\"]"))
}
}
#[cfg(feature = "full")]
fn path_or_macro_or_struct(input: ParseStream, allow_struct: AllowStruct) -> Result<Expr> {
let expr: ExprPath = input.parse()?;
if expr.qself.is_some() {
return Ok(Expr::Path(expr));
}
if input.peek(Token![!]) && !input.peek(Token![!=]) {
let mut contains_arguments = false;
for segment in &expr.path.segments {
match segment.arguments {
PathArguments::None => {}
PathArguments::AngleBracketed(_) | PathArguments::Parenthesized(_) => {
contains_arguments = true;
}
}
}
if !contains_arguments {
let bang_token: Token![!] = input.parse()?;
let (delimiter, tokens) = mac::parse_delimiter(input)?;
return Ok(Expr::Macro(ExprMacro {
attrs: Vec::new(),
mac: Macro {
path: expr.path,
bang_token,
delimiter,
tokens,
},
}));
}
}
if allow_struct.0 && input.peek(token::Brace) {
let outer_attrs = Vec::new();
expr_struct_helper(input, outer_attrs, expr.path).map(Expr::Struct)
} else {
Ok(Expr::Path(expr))
}
}
#[cfg(feature = "full")]
fn paren_or_tuple(input: ParseStream) -> Result<Expr> {
let content;
let paren_token = parenthesized!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
if content.is_empty() {
return Ok(Expr::Tuple(ExprTuple {
attrs: inner_attrs,
paren_token,
elems: Punctuated::new(),
}));
}
let first: Expr = content.parse()?;
if content.is_empty() {
return Ok(Expr::Paren(ExprParen {
attrs: inner_attrs,
paren_token,
expr: Box::new(first),
}));
}
let mut elems = Punctuated::new();
elems.push_value(first);
while !content.is_empty() {
let punct = content.parse()?;
elems.push_punct(punct);
if content.is_empty() {
break;
}
let value = content.parse()?;
elems.push_value(value);
}
Ok(Expr::Tuple(ExprTuple {
attrs: inner_attrs,
paren_token,
elems,
}))
}
#[cfg(feature = "full")]
fn array_or_repeat(input: ParseStream) -> Result<Expr> {
let content;
let bracket_token = bracketed!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
if content.is_empty() {
return Ok(Expr::Array(ExprArray {
attrs: inner_attrs,
bracket_token,
elems: Punctuated::new(),
}));
}
let first: Expr = content.parse()?;
if content.is_empty() || content.peek(Token![,]) {
let mut elems = Punctuated::new();
elems.push_value(first);
while !content.is_empty() {
let punct = content.parse()?;
elems.push_punct(punct);
if content.is_empty() {
break;
}
let value = content.parse()?;
elems.push_value(value);
}
Ok(Expr::Array(ExprArray {
attrs: inner_attrs,
bracket_token,
elems,
}))
} else if content.peek(Token![;]) {
let semi_token: Token![;] = content.parse()?;
let len: Expr = content.parse()?;
Ok(Expr::Repeat(ExprRepeat {
attrs: inner_attrs,
bracket_token,
expr: Box::new(first),
semi_token,
len: Box::new(len),
}))
} else {
Err(content.error("expected `,` or `;`"))
}
}
#[cfg(feature = "full")]
pub(crate) fn expr_early(input: ParseStream) -> Result<Expr> {
let mut attrs = input.call(Attribute::parse_outer)?;
let mut expr = if input.peek(Token![if]) {
Expr::If(input.parse()?)
} else if input.peek(Token![while]) {
Expr::While(input.parse()?)
} else if input.peek(Token![for]) {
Expr::ForLoop(input.parse()?)
} else if input.peek(Token![loop]) {
Expr::Loop(input.parse()?)
} else if input.peek(Token![match]) {
Expr::Match(input.parse()?)
} else if input.peek(Token![try]) && input.peek2(token::Brace) {
Expr::TryBlock(input.call(expr_try_block)?)
} else if input.peek(Token![unsafe]) {
Expr::Unsafe(input.call(expr_unsafe)?)
} else if input.peek(token::Brace) {
Expr::Block(input.call(expr_block)?)
} else {
let allow_struct = AllowStruct(true);
let mut expr = unary_expr(input, allow_struct)?;
attrs.extend(expr.replace_attrs(Vec::new()));
expr.replace_attrs(attrs);
return parse_expr(input, expr, allow_struct, Precedence::Any);
};
if input.peek(Token![.]) && !input.peek(Token![..]) || input.peek(Token![?]) {
expr = trailer_helper(input, expr)?;
attrs.extend(expr.replace_attrs(Vec::new()));
expr.replace_attrs(attrs);
let allow_struct = AllowStruct(true);
return parse_expr(input, expr, allow_struct, Precedence::Any);
}
attrs.extend(expr.replace_attrs(Vec::new()));
expr.replace_attrs(attrs);
Ok(expr)
}
impl Parse for ExprLit {
fn parse(input: ParseStream) -> Result<Self> {
Ok(ExprLit {
attrs: Vec::new(),
lit: input.parse()?,
})
}
}
#[cfg(feature = "full")]
fn expr_group(input: ParseStream) -> Result<ExprGroup> {
let group = crate::group::parse_group(input)?;
Ok(ExprGroup {
attrs: Vec::new(),
group_token: group.token,
expr: group.content.parse()?,
})
}
#[cfg(not(feature = "full"))]
fn expr_paren(input: ParseStream) -> Result<ExprParen> {
let content;
Ok(ExprParen {
attrs: Vec::new(),
paren_token: parenthesized!(content in input),
expr: content.parse()?,
})
}
#[cfg(feature = "full")]
fn generic_method_argument(input: ParseStream) -> Result<GenericMethodArgument> {
input.parse().map(GenericMethodArgument::Type)
}
#[cfg(feature = "full")]
fn expr_let(input: ParseStream) -> Result<ExprLet> {
Ok(ExprLet {
attrs: Vec::new(),
let_token: input.parse()?,
pat: {
let leading_vert: Option<Token![|]> = input.parse()?;
let pat: Pat = input.parse()?;
if leading_vert.is_some()
|| input.peek(Token![|]) && !input.peek(Token![||]) && !input.peek(Token![|=])
{
let mut cases = Punctuated::new();
cases.push_value(pat);
while input.peek(Token![|])
&& !input.peek(Token![||])
&& !input.peek(Token![|=])
{
let punct = input.parse()?;
cases.push_punct(punct);
let pat: Pat = input.parse()?;
cases.push_value(pat);
}
Pat::Or(PatOr {
attrs: Vec::new(),
leading_vert,
cases,
})
} else {
pat
}
},
eq_token: input.parse()?,
expr: Box::new(input.call(expr_no_struct)?),
})
}
#[cfg(feature = "full")]
impl Parse for ExprIf {
fn parse(input: ParseStream) -> Result<Self> {
Ok(ExprIf {
attrs: Vec::new(),
if_token: input.parse()?,
cond: Box::new(input.call(expr_no_struct)?),
then_branch: input.parse()?,
else_branch: {
if input.peek(Token![else]) {
Some(input.call(else_block)?)
} else {
None
}
},
})
}
}
#[cfg(feature = "full")]
fn else_block(input: ParseStream) -> Result<(Token![else], Box<Expr>)> {
let else_token: Token![else] = input.parse()?;
let lookahead = input.lookahead1();
let else_branch = if input.peek(Token![if]) {
input.parse().map(Expr::If)?
} else if input.peek(token::Brace) {
Expr::Block(ExprBlock {
attrs: Vec::new(),
label: None,
block: input.parse()?,
})
} else {
return Err(lookahead.error());
};
Ok((else_token, Box::new(else_branch)))
}
#[cfg(feature = "full")]
impl Parse for ExprForLoop {
fn parse(input: ParseStream) -> Result<Self> {
let label: Option<Label> = input.parse()?;
let for_token: Token![for] = input.parse()?;
let leading_vert: Option<Token![|]> = input.parse()?;
let mut pat: Pat = input.parse()?;
if leading_vert.is_some() || input.peek(Token![|]) {
let mut cases = Punctuated::new();
cases.push_value(pat);
while input.peek(Token![|]) {
let punct = input.parse()?;
cases.push_punct(punct);
let pat: Pat = input.parse()?;
cases.push_value(pat);
}
pat = Pat::Or(PatOr {
attrs: Vec::new(),
leading_vert,
cases,
});
}
let in_token: Token![in] = input.parse()?;
let expr: Expr = input.call(expr_no_struct)?;
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let stmts = content.call(Block::parse_within)?;
Ok(ExprForLoop {
attrs: inner_attrs,
label,
for_token,
pat,
in_token,
expr: Box::new(expr),
body: Block { brace_token, stmts },
})
}
}
#[cfg(feature = "full")]
impl Parse for ExprLoop {
fn parse(input: ParseStream) -> Result<Self> {
let label: Option<Label> = input.parse()?;
let loop_token: Token![loop] = input.parse()?;
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let stmts = content.call(Block::parse_within)?;
Ok(ExprLoop {
attrs: inner_attrs,
label,
loop_token,
body: Block { brace_token, stmts },
})
}
}
#[cfg(feature = "full")]
impl Parse for ExprMatch {
fn parse(input: ParseStream) -> Result<Self> {
let match_token: Token![match] = input.parse()?;
let expr = expr_no_struct(input)?;
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let mut arms = Vec::new();
while !content.is_empty() {
arms.push(content.call(Arm::parse)?);
}
Ok(ExprMatch {
attrs: inner_attrs,
match_token,
expr: Box::new(expr),
brace_token,
arms,
})
}
}
macro_rules! impl_by_parsing_expr {
(
$(
$expr_type:ty, $variant:ident, $msg:expr,
)*
) => {
$(
#[cfg(all(feature = "full", feature = "printing"))]
impl Parse for $expr_type {
fn parse(input: ParseStream) -> Result<Self> {
let mut expr: Expr = input.parse()?;
loop {
match expr {
Expr::$variant(inner) => return Ok(inner),
Expr::Group(next) => expr = *next.expr,
_ => return Err(Error::new_spanned(expr, $msg)),
}
}
}
}
)*
};
}
impl_by_parsing_expr! {
ExprBox, Box, "expected box expression",
ExprArray, Array, "expected slice literal expression",
ExprCall, Call, "expected function call expression",
ExprMethodCall, MethodCall, "expected method call expression",
ExprTuple, Tuple, "expected tuple expression",
ExprBinary, Binary, "expected binary operation",
ExprUnary, Unary, "expected unary operation",
ExprCast, Cast, "expected cast expression",
ExprType, Type, "expected type ascription expression",
ExprLet, Let, "expected let guard",
ExprClosure, Closure, "expected closure expression",
ExprUnsafe, Unsafe, "expected unsafe block",
ExprBlock, Block, "expected blocked scope",
ExprAssign, Assign, "expected assignment expression",
ExprAssignOp, AssignOp, "expected compound assignment expression",
ExprField, Field, "expected struct field access",
ExprIndex, Index, "expected indexing expression",
ExprRange, Range, "expected range expression",
ExprReference, Reference, "expected referencing operation",
ExprBreak, Break, "expected break expression",
ExprContinue, Continue, "expected continue expression",
ExprReturn, Return, "expected return expression",
ExprMacro, Macro, "expected macro invocation expression",
ExprStruct, Struct, "expected struct literal expression",
ExprRepeat, Repeat, "expected array literal constructed from one repeated element",
ExprParen, Paren, "expected parenthesized expression",
ExprTry, Try, "expected try expression",
ExprAsync, Async, "expected async block",
ExprTryBlock, TryBlock, "expected try block",
ExprYield, Yield, "expected yield expression",
}
#[cfg(feature = "full")]
fn expr_try_block(input: ParseStream) -> Result<ExprTryBlock> {
Ok(ExprTryBlock {
attrs: Vec::new(),
try_token: input.parse()?,
block: input.parse()?,
})
}
#[cfg(feature = "full")]
fn expr_yield(input: ParseStream) -> Result<ExprYield> {
Ok(ExprYield {
attrs: Vec::new(),
yield_token: input.parse()?,
expr: {
if !input.is_empty() && !input.peek(Token![,]) && !input.peek(Token![;]) {
Some(input.parse()?)
} else {
None
}
},
})
}
#[cfg(feature = "full")]
fn expr_closure(input: ParseStream, allow_struct: AllowStruct) -> Result<ExprClosure> {
let asyncness: Option<Token![async]> = input.parse()?;
let movability: Option<Token![static]> = if asyncness.is_none() {
input.parse()?
} else {
None
};
let capture: Option<Token![move]> = input.parse()?;
let or1_token: Token![|] = input.parse()?;
let mut inputs = Punctuated::new();
loop {
if input.peek(Token![|]) {
break;
}
let value = closure_arg(input)?;
inputs.push_value(value);
if input.peek(Token![|]) {
break;
}
let punct: Token![,] = input.parse()?;
inputs.push_punct(punct);
}
let or2_token: Token![|] = input.parse()?;
let (output, body) = if input.peek(Token![->]) {
let arrow_token: Token![->] = input.parse()?;
let ty: Type = input.parse()?;
let body: Block = input.parse()?;
let output = ReturnType::Type(arrow_token, Box::new(ty));
let block = Expr::Block(ExprBlock {
attrs: Vec::new(),
label: None,
block: body,
});
(output, block)
} else {
let body = ambiguous_expr(input, allow_struct)?;
(ReturnType::Default, body)
};
Ok(ExprClosure {
attrs: Vec::new(),
asyncness,
movability,
capture,
or1_token,
inputs,
or2_token,
output,
body: Box::new(body),
})
}
#[cfg(feature = "full")]
fn expr_async(input: ParseStream) -> Result<ExprAsync> {
Ok(ExprAsync {
attrs: Vec::new(),
async_token: input.parse()?,
capture: input.parse()?,
block: input.parse()?,
})
}
#[cfg(feature = "full")]
fn closure_arg(input: ParseStream) -> Result<Pat> {
let attrs = input.call(Attribute::parse_outer)?;
let mut pat: Pat = input.parse()?;
if input.peek(Token![:]) {
Ok(Pat::Type(PatType {
attrs,
pat: Box::new(pat),
colon_token: input.parse()?,
ty: input.parse()?,
}))
} else {
match &mut pat {
Pat::Box(pat) => pat.attrs = attrs,
Pat::Ident(pat) => pat.attrs = attrs,
Pat::Lit(pat) => pat.attrs = attrs,
Pat::Macro(pat) => pat.attrs = attrs,
Pat::Or(pat) => pat.attrs = attrs,
Pat::Path(pat) => pat.attrs = attrs,
Pat::Range(pat) => pat.attrs = attrs,
Pat::Reference(pat) => pat.attrs = attrs,
Pat::Rest(pat) => pat.attrs = attrs,
Pat::Slice(pat) => pat.attrs = attrs,
Pat::Struct(pat) => pat.attrs = attrs,
Pat::Tuple(pat) => pat.attrs = attrs,
Pat::TupleStruct(pat) => pat.attrs = attrs,
Pat::Type(_) => unreachable!(),
Pat::Verbatim(_) => {}
Pat::Wild(pat) => pat.attrs = attrs,
Pat::__Nonexhaustive => unreachable!(),
}
Ok(pat)
}
}
#[cfg(feature = "full")]
impl Parse for ExprWhile {
fn parse(input: ParseStream) -> Result<Self> {
let label: Option<Label> = input.parse()?;
let while_token: Token![while] = input.parse()?;
let cond = expr_no_struct(input)?;
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let stmts = content.call(Block::parse_within)?;
Ok(ExprWhile {
attrs: inner_attrs,
label,
while_token,
cond: Box::new(cond),
body: Block { brace_token, stmts },
})
}
}
#[cfg(feature = "full")]
impl Parse for Label {
fn parse(input: ParseStream) -> Result<Self> {
Ok(Label {
name: input.parse()?,
colon_token: input.parse()?,
})
}
}
#[cfg(feature = "full")]
impl Parse for Option<Label> {
fn parse(input: ParseStream) -> Result<Self> {
if input.peek(Lifetime) {
input.parse().map(Some)
} else {
Ok(None)
}
}
}
#[cfg(feature = "full")]
fn expr_continue(input: ParseStream) -> Result<ExprContinue> {
Ok(ExprContinue {
attrs: Vec::new(),
continue_token: input.parse()?,
label: input.parse()?,
})
}
#[cfg(feature = "full")]
fn expr_break(input: ParseStream, allow_struct: AllowStruct) -> Result<ExprBreak> {
Ok(ExprBreak {
attrs: Vec::new(),
break_token: input.parse()?,
label: input.parse()?,
expr: {
if input.is_empty()
|| input.peek(Token![,])
|| input.peek(Token![;])
|| !allow_struct.0 && input.peek(token::Brace)
{
None
} else {
let expr = ambiguous_expr(input, allow_struct)?;
Some(Box::new(expr))
}
},
})
}
#[cfg(feature = "full")]
fn expr_ret(input: ParseStream, allow_struct: AllowStruct) -> Result<ExprReturn> {
Ok(ExprReturn {
attrs: Vec::new(),
return_token: input.parse()?,
expr: {
if input.is_empty() || input.peek(Token![,]) || input.peek(Token![;]) {
None
} else {
let expr = ambiguous_expr(input, allow_struct)?;
Some(Box::new(expr))
}
},
})
}
#[cfg(feature = "full")]
impl Parse for FieldValue {
fn parse(input: ParseStream) -> Result<Self> {
let attrs = input.call(Attribute::parse_outer)?;
let member: Member = input.parse()?;
let (colon_token, value) = if input.peek(Token![:]) || !member.is_named() {
let colon_token: Token![:] = input.parse()?;
let value: Expr = input.parse()?;
(Some(colon_token), value)
} else if let Member::Named(ident) = &member {
let value = Expr::Path(ExprPath {
attrs: Vec::new(),
qself: None,
path: Path::from(ident.clone()),
});
(None, value)
} else {
unreachable!()
};
Ok(FieldValue {
attrs,
member,
colon_token,
expr: value,
})
}
}
#[cfg(feature = "full")]
fn expr_struct_helper(
input: ParseStream,
outer_attrs: Vec<Attribute>,
path: Path,
) -> Result<ExprStruct> {
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let attrs = private::attrs(outer_attrs, inner_attrs);
let mut fields = Punctuated::new();
while !content.is_empty() {
if content.peek(Token![..]) {
return Ok(ExprStruct {
attrs,
brace_token,
path,
fields,
dot2_token: Some(content.parse()?),
rest: Some(Box::new(content.parse()?)),
});
}
fields.push(content.parse()?);
if !content.peek(Token![,]) {
break;
}
let punct: Token![,] = content.parse()?;
fields.push_punct(punct);
}
Ok(ExprStruct {
attrs,
brace_token,
path,
fields,
dot2_token: None,
rest: None,
})
}
#[cfg(feature = "full")]
fn expr_unsafe(input: ParseStream) -> Result<ExprUnsafe> {
let unsafe_token: Token![unsafe] = input.parse()?;
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let stmts = content.call(Block::parse_within)?;
Ok(ExprUnsafe {
attrs: inner_attrs,
unsafe_token,
block: Block { brace_token, stmts },
})
}
#[cfg(feature = "full")]
pub fn expr_block(input: ParseStream) -> Result<ExprBlock> {
let label: Option<Label> = input.parse()?;
let content;
let brace_token = braced!(content in input);
let inner_attrs = content.call(Attribute::parse_inner)?;
let stmts = content.call(Block::parse_within)?;
Ok(ExprBlock {
attrs: inner_attrs,
label,
block: Block { brace_token, stmts },
})
}
#[cfg(feature = "full")]
fn expr_range(input: ParseStream, allow_struct: AllowStruct) -> Result<ExprRange> {
Ok(ExprRange {
attrs: Vec::new(),
from: None,
limits: input.parse()?,
to: {
if input.is_empty()
|| input.peek(Token![,])
|| input.peek(Token![;])
|| !allow_struct.0 && input.peek(token::Brace)
{
None
} else {
let to = ambiguous_expr(input, allow_struct)?;
Some(Box::new(to))
}
},
})
}
#[cfg(feature = "full")]
impl Parse for RangeLimits {
fn parse(input: ParseStream) -> Result<Self> {
let lookahead = input.lookahead1();
if lookahead.peek(Token![..=]) {
input.parse().map(RangeLimits::Closed)
} else if lookahead.peek(Token![...]) {
let dot3: Token![...] = input.parse()?;
Ok(RangeLimits::Closed(Token![..=](dot3.spans)))
} else if lookahead.peek(Token![..]) {
input.parse().map(RangeLimits::HalfOpen)
} else {
Err(lookahead.error())
}
}
}
impl Parse for ExprPath {
fn parse(input: ParseStream) -> Result<Self> {
#[cfg(not(feature = "full"))]
let attrs = Vec::new();
#[cfg(feature = "full")]
let attrs = input.call(Attribute::parse_outer)?;
let (qself, path) = path::parsing::qpath(input, true)?;
Ok(ExprPath { attrs, qself, path })
}
}
impl Parse for Member {
fn parse(input: ParseStream) -> Result<Self> {
if input.peek(Ident) {
input.parse().map(Member::Named)
} else if input.peek(LitInt) {
input.parse().map(Member::Unnamed)
} else {
Err(input.error("expected identifier or integer"))
}
}
}
#[cfg(feature = "full")]
impl Parse for Arm {
fn parse(input: ParseStream) -> Result<Arm> {
let requires_comma;
Ok(Arm {
attrs: input.call(Attribute::parse_outer)?,
pat: {
let leading_vert: Option<Token![|]> = input.parse()?;
let pat: Pat = input.parse()?;
if leading_vert.is_some() || input.peek(Token![|]) {
let mut cases = Punctuated::new();
cases.push_value(pat);
while input.peek(Token![|]) {
let punct = input.parse()?;
cases.push_punct(punct);
let pat: Pat = input.parse()?;
cases.push_value(pat);
}
Pat::Or(PatOr {
attrs: Vec::new(),
leading_vert,
cases,
})
} else {
pat
}
},
guard: {
if input.peek(Token![if]) {
let if_token: Token![if] = input.parse()?;
let guard: Expr = input.parse()?;
Some((if_token, Box::new(guard)))
} else {
None
}
},
fat_arrow_token: input.parse()?,
body: {
let body = input.call(expr_early)?;
requires_comma = requires_terminator(&body);
Box::new(body)
},
comma: {
if requires_comma && !input.is_empty() {
Some(input.parse()?)
} else {
input.parse()?
}
},
})
}
}
impl Parse for Index {
fn parse(input: ParseStream) -> Result<Self> {
let lit: LitInt = input.parse()?;
if lit.suffix().is_empty() {
Ok(Index {
index: lit
.base10_digits()
.parse()
.map_err(|err| Error::new(lit.span(), err))?,
span: lit.span(),
})
} else {
Err(Error::new(lit.span(), "expected unsuffixed integer"))
}
}
}
#[cfg(feature = "full")]
impl Member {
fn is_named(&self) -> bool {
match *self {
Member::Named(_) => true,
Member::Unnamed(_) => false,
}
}
}
}
#[cfg(feature = "printing")]
pub(crate) mod printing {
use super::*;
use proc_macro2::{Literal, TokenStream};
use quote::{ToTokens, TokenStreamExt};
#[cfg(feature = "full")]
use crate::attr::FilterAttrs;
#[cfg(feature = "full")]
use crate::print::TokensOrDefault;
#[cfg(feature = "full")]
fn wrap_bare_struct(tokens: &mut TokenStream, e: &Expr) {
if let Expr::Struct(_) = *e {
token::Paren::default().surround(tokens, |tokens| {
e.to_tokens(tokens);
});
} else {
e.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
pub(crate) fn outer_attrs_to_tokens(attrs: &[Attribute], tokens: &mut TokenStream) {
tokens.append_all(attrs.outer());
}
#[cfg(feature = "full")]
fn inner_attrs_to_tokens(attrs: &[Attribute], tokens: &mut TokenStream) {
tokens.append_all(attrs.inner());
}
#[cfg(not(feature = "full"))]
pub(crate) fn outer_attrs_to_tokens(_attrs: &[Attribute], _tokens: &mut TokenStream) {}
#[cfg(not(feature = "full"))]
fn inner_attrs_to_tokens(_attrs: &[Attribute], _tokens: &mut TokenStream) {}
#[cfg(feature = "full")]
impl ToTokens for ExprBox {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.box_token.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprArray {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.bracket_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
self.elems.to_tokens(tokens);
})
}
}
impl ToTokens for ExprCall {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.func.to_tokens(tokens);
self.paren_token.surround(tokens, |tokens| {
self.args.to_tokens(tokens);
})
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprMethodCall {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.receiver.to_tokens(tokens);
self.dot_token.to_tokens(tokens);
self.method.to_tokens(tokens);
self.turbofish.to_tokens(tokens);
self.paren_token.surround(tokens, |tokens| {
self.args.to_tokens(tokens);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for MethodTurbofish {
fn to_tokens(&self, tokens: &mut TokenStream) {
self.colon2_token.to_tokens(tokens);
self.lt_token.to_tokens(tokens);
self.args.to_tokens(tokens);
self.gt_token.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for GenericMethodArgument {
fn to_tokens(&self, tokens: &mut TokenStream) {
match self {
GenericMethodArgument::Type(t) => t.to_tokens(tokens),
GenericMethodArgument::Const(c) => c.to_tokens(tokens),
}
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprTuple {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.paren_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
self.elems.to_tokens(tokens);
if self.elems.len() == 1 && !self.elems.trailing_punct() {
<Token![,]>::default().to_tokens(tokens);
}
})
}
}
impl ToTokens for ExprBinary {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.left.to_tokens(tokens);
self.op.to_tokens(tokens);
self.right.to_tokens(tokens);
}
}
impl ToTokens for ExprUnary {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.op.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
impl ToTokens for ExprLit {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.lit.to_tokens(tokens);
}
}
impl ToTokens for ExprCast {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.expr.to_tokens(tokens);
self.as_token.to_tokens(tokens);
self.ty.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprType {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.expr.to_tokens(tokens);
self.colon_token.to_tokens(tokens);
self.ty.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
fn maybe_wrap_else(tokens: &mut TokenStream, else_: &Option<(Token![else], Box<Expr>)>) {
if let Some((else_token, else_)) = else_ {
else_token.to_tokens(tokens);
match **else_ {
Expr::If(_) | Expr::Block(_) => {
else_.to_tokens(tokens);
}
_ => {
token::Brace::default().surround(tokens, |tokens| {
else_.to_tokens(tokens);
});
}
}
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprLet {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.let_token.to_tokens(tokens);
self.pat.to_tokens(tokens);
self.eq_token.to_tokens(tokens);
wrap_bare_struct(tokens, &self.expr);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprIf {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.if_token.to_tokens(tokens);
wrap_bare_struct(tokens, &self.cond);
self.then_branch.to_tokens(tokens);
maybe_wrap_else(tokens, &self.else_branch);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprWhile {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.label.to_tokens(tokens);
self.while_token.to_tokens(tokens);
wrap_bare_struct(tokens, &self.cond);
self.body.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
tokens.append_all(&self.body.stmts);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprForLoop {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.label.to_tokens(tokens);
self.for_token.to_tokens(tokens);
self.pat.to_tokens(tokens);
self.in_token.to_tokens(tokens);
wrap_bare_struct(tokens, &self.expr);
self.body.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
tokens.append_all(&self.body.stmts);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprLoop {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.label.to_tokens(tokens);
self.loop_token.to_tokens(tokens);
self.body.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
tokens.append_all(&self.body.stmts);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprMatch {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.match_token.to_tokens(tokens);
wrap_bare_struct(tokens, &self.expr);
self.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
for (i, arm) in self.arms.iter().enumerate() {
arm.to_tokens(tokens);
let is_last = i == self.arms.len() - 1;
if !is_last && requires_terminator(&arm.body) && arm.comma.is_none() {
<Token![,]>::default().to_tokens(tokens);
}
}
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprAsync {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.async_token.to_tokens(tokens);
self.capture.to_tokens(tokens);
self.block.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprAwait {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.base.to_tokens(tokens);
self.dot_token.to_tokens(tokens);
self.await_token.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprTryBlock {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.try_token.to_tokens(tokens);
self.block.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprYield {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.yield_token.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprClosure {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.asyncness.to_tokens(tokens);
self.movability.to_tokens(tokens);
self.capture.to_tokens(tokens);
self.or1_token.to_tokens(tokens);
self.inputs.to_tokens(tokens);
self.or2_token.to_tokens(tokens);
self.output.to_tokens(tokens);
self.body.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprUnsafe {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.unsafe_token.to_tokens(tokens);
self.block.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
tokens.append_all(&self.block.stmts);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprBlock {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.label.to_tokens(tokens);
self.block.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
tokens.append_all(&self.block.stmts);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprAssign {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.left.to_tokens(tokens);
self.eq_token.to_tokens(tokens);
self.right.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprAssignOp {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.left.to_tokens(tokens);
self.op.to_tokens(tokens);
self.right.to_tokens(tokens);
}
}
impl ToTokens for ExprField {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.base.to_tokens(tokens);
self.dot_token.to_tokens(tokens);
self.member.to_tokens(tokens);
}
}
impl ToTokens for Member {
fn to_tokens(&self, tokens: &mut TokenStream) {
match self {
Member::Named(ident) => ident.to_tokens(tokens),
Member::Unnamed(index) => index.to_tokens(tokens),
}
}
}
impl ToTokens for Index {
fn to_tokens(&self, tokens: &mut TokenStream) {
let mut lit = Literal::i64_unsuffixed(i64::from(self.index));
lit.set_span(self.span);
tokens.append(lit);
}
}
impl ToTokens for ExprIndex {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.expr.to_tokens(tokens);
self.bracket_token.surround(tokens, |tokens| {
self.index.to_tokens(tokens);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprRange {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.from.to_tokens(tokens);
match &self.limits {
RangeLimits::HalfOpen(t) => t.to_tokens(tokens),
RangeLimits::Closed(t) => t.to_tokens(tokens),
}
self.to.to_tokens(tokens);
}
}
impl ToTokens for ExprPath {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
private::print_path(tokens, &self.qself, &self.path);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprReference {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.and_token.to_tokens(tokens);
self.mutability.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprBreak {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.break_token.to_tokens(tokens);
self.label.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprContinue {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.continue_token.to_tokens(tokens);
self.label.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprReturn {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.return_token.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprMacro {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.mac.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprStruct {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.path.to_tokens(tokens);
self.brace_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
self.fields.to_tokens(tokens);
if self.rest.is_some() {
TokensOrDefault(&self.dot2_token).to_tokens(tokens);
self.rest.to_tokens(tokens);
}
})
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprRepeat {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.bracket_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
self.expr.to_tokens(tokens);
self.semi_token.to_tokens(tokens);
self.len.to_tokens(tokens);
})
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprGroup {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.group_token.surround(tokens, |tokens| {
self.expr.to_tokens(tokens);
});
}
}
impl ToTokens for ExprParen {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.paren_token.surround(tokens, |tokens| {
inner_attrs_to_tokens(&self.attrs, tokens);
self.expr.to_tokens(tokens);
});
}
}
#[cfg(feature = "full")]
impl ToTokens for ExprTry {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.expr.to_tokens(tokens);
self.question_token.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for Label {
fn to_tokens(&self, tokens: &mut TokenStream) {
self.name.to_tokens(tokens);
self.colon_token.to_tokens(tokens);
}
}
#[cfg(feature = "full")]
impl ToTokens for FieldValue {
fn to_tokens(&self, tokens: &mut TokenStream) {
outer_attrs_to_tokens(&self.attrs, tokens);
self.member.to_tokens(tokens);
if let Some(colon_token) = &self.colon_token {
colon_token.to_tokens(tokens);
self.expr.to_tokens(tokens);
}
}
}
#[cfg(feature = "full")]
impl ToTokens for Arm {
fn to_tokens(&self, tokens: &mut TokenStream) {
tokens.append_all(&self.attrs);
self.pat.to_tokens(tokens);
if let Some((if_token, guard)) = &self.guard {
if_token.to_tokens(tokens);
guard.to_tokens(tokens);
}
self.fat_arrow_token.to_tokens(tokens);
self.body.to_tokens(tokens);
self.comma.to_tokens(tokens);
}
}
}