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|
//! `mbe` (short for Macro By Example) crate contains code for handling
//! `macro_rules` macros. It uses `TokenTree` (from `tt` package) as the
//! interface, although it contains some code to bridge `SyntaxNode`s and
//! `TokenTree`s as well!
//!
//! The tes for this functionality live in another crate:
//! `hir_def::macro_expansion_tests::mbe`.
#![warn(rust_2018_idioms, unused_lifetimes, semicolon_in_expressions_from_macros)]
mod parser;
mod expander;
mod syntax_bridge;
mod tt_iter;
mod to_parser_input;
#[cfg(test)]
mod benchmark;
mod token_map;
use std::fmt;
use crate::{
parser::{MetaTemplate, MetaVarKind, Op},
tt_iter::TtIter,
};
// FIXME: we probably should re-think `token_tree_to_syntax_node` interfaces
pub use ::parser::TopEntryPoint;
pub use tt::{Delimiter, DelimiterKind, Punct};
pub use crate::{
syntax_bridge::{
parse_exprs_with_sep, parse_to_token_tree, syntax_node_to_token_tree,
syntax_node_to_token_tree_with_modifications, token_tree_to_syntax_node, SyntheticToken,
SyntheticTokenId,
},
token_map::TokenMap,
};
#[derive(Debug, PartialEq, Eq, Clone)]
pub enum ParseError {
UnexpectedToken(Box<str>),
Expected(Box<str>),
InvalidRepeat,
RepetitionEmptyTokenTree,
}
impl ParseError {
fn expected(e: &str) -> ParseError {
ParseError::Expected(e.into())
}
fn unexpected(e: &str) -> ParseError {
ParseError::UnexpectedToken(e.into())
}
}
impl fmt::Display for ParseError {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
ParseError::UnexpectedToken(it) => f.write_str(it),
ParseError::Expected(it) => f.write_str(it),
ParseError::InvalidRepeat => f.write_str("invalid repeat"),
ParseError::RepetitionEmptyTokenTree => f.write_str("empty token tree in repetition"),
}
}
}
#[derive(Debug, PartialEq, Eq, Clone)]
pub enum ExpandError {
BindingError(Box<Box<str>>),
LeftoverTokens,
ConversionError,
LimitExceeded,
NoMatchingRule,
UnexpectedToken,
}
impl ExpandError {
fn binding_error(e: impl Into<Box<str>>) -> ExpandError {
ExpandError::BindingError(Box::new(e.into()))
}
}
impl fmt::Display for ExpandError {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
ExpandError::NoMatchingRule => f.write_str("no rule matches input tokens"),
ExpandError::UnexpectedToken => f.write_str("unexpected token in input"),
ExpandError::BindingError(e) => f.write_str(e),
ExpandError::ConversionError => f.write_str("could not convert tokens"),
ExpandError::LimitExceeded => f.write_str("Expand exceed limit"),
ExpandError::LeftoverTokens => f.write_str("leftover tokens"),
}
}
}
/// This struct contains AST for a single `macro_rules` definition. What might
/// be very confusing is that AST has almost exactly the same shape as
/// `tt::TokenTree`, but there's a crucial difference: in macro rules, `$ident`
/// and `$()*` have special meaning (see `Var` and `Repeat` data structures)
#[derive(Clone, Debug, PartialEq, Eq)]
pub struct DeclarativeMacro {
rules: Vec<Rule>,
/// Highest id of the token we have in TokenMap
shift: Shift,
}
#[derive(Clone, Debug, PartialEq, Eq)]
struct Rule {
lhs: MetaTemplate,
rhs: MetaTemplate,
}
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub struct Shift(u32);
impl Shift {
pub fn new(tt: &tt::Subtree) -> Shift {
// Note that TokenId is started from zero,
// We have to add 1 to prevent duplication.
let value = max_id(tt).map_or(0, |it| it + 1);
return Shift(value);
// Find the max token id inside a subtree
fn max_id(subtree: &tt::Subtree) -> Option<u32> {
let filter = |tt: &_| match tt {
tt::TokenTree::Subtree(subtree) => {
let tree_id = max_id(subtree);
match subtree.delimiter {
Some(it) if it.id != tt::TokenId::unspecified() => {
Some(tree_id.map_or(it.id.0, |t| t.max(it.id.0)))
}
_ => tree_id,
}
}
tt::TokenTree::Leaf(leaf) => {
let &(tt::Leaf::Ident(tt::Ident { id, .. })
| tt::Leaf::Punct(tt::Punct { id, .. })
| tt::Leaf::Literal(tt::Literal { id, .. })) = leaf;
(id != tt::TokenId::unspecified()).then_some(id.0)
}
};
subtree.token_trees.iter().filter_map(filter).max()
}
}
/// Shift given TokenTree token id
pub fn shift_all(self, tt: &mut tt::Subtree) {
for t in &mut tt.token_trees {
match t {
tt::TokenTree::Leaf(
tt::Leaf::Ident(tt::Ident { id, .. })
| tt::Leaf::Punct(tt::Punct { id, .. })
| tt::Leaf::Literal(tt::Literal { id, .. }),
) => *id = self.shift(*id),
tt::TokenTree::Subtree(tt) => {
if let Some(it) = tt.delimiter.as_mut() {
it.id = self.shift(it.id);
}
self.shift_all(tt)
}
}
}
}
pub fn shift(self, id: tt::TokenId) -> tt::TokenId {
if id == tt::TokenId::unspecified() {
id
} else {
tt::TokenId(id.0 + self.0)
}
}
pub fn unshift(self, id: tt::TokenId) -> Option<tt::TokenId> {
id.0.checked_sub(self.0).map(tt::TokenId)
}
}
#[derive(Debug, Eq, PartialEq)]
pub enum Origin {
Def,
Call,
}
impl DeclarativeMacro {
/// The old, `macro_rules! m {}` flavor.
pub fn parse_macro_rules(tt: &tt::Subtree) -> Result<DeclarativeMacro, ParseError> {
// Note: this parsing can be implemented using mbe machinery itself, by
// matching against `$($lhs:tt => $rhs:tt);*` pattern, but implementing
// manually seems easier.
let mut src = TtIter::new(tt);
let mut rules = Vec::new();
while src.len() > 0 {
let rule = Rule::parse(&mut src, true)?;
rules.push(rule);
if let Err(()) = src.expect_char(';') {
if src.len() > 0 {
return Err(ParseError::expected("expected `;`"));
}
break;
}
}
for Rule { lhs, .. } in &rules {
validate(lhs)?;
}
Ok(DeclarativeMacro { rules, shift: Shift::new(tt) })
}
/// The new, unstable `macro m {}` flavor.
pub fn parse_macro2(tt: &tt::Subtree) -> Result<DeclarativeMacro, ParseError> {
let mut src = TtIter::new(tt);
let mut rules = Vec::new();
if Some(tt::DelimiterKind::Brace) == tt.delimiter_kind() {
cov_mark::hit!(parse_macro_def_rules);
while src.len() > 0 {
let rule = Rule::parse(&mut src, true)?;
rules.push(rule);
if let Err(()) = src.expect_any_char(&[';', ',']) {
if src.len() > 0 {
return Err(ParseError::expected("expected `;` or `,` to delimit rules"));
}
break;
}
}
} else {
cov_mark::hit!(parse_macro_def_simple);
let rule = Rule::parse(&mut src, false)?;
if src.len() != 0 {
return Err(ParseError::expected("remaining tokens in macro def"));
}
rules.push(rule);
}
for Rule { lhs, .. } in &rules {
validate(lhs)?;
}
Ok(DeclarativeMacro { rules, shift: Shift::new(tt) })
}
pub fn expand(&self, tt: &tt::Subtree) -> ExpandResult<tt::Subtree> {
// apply shift
let mut tt = tt.clone();
self.shift.shift_all(&mut tt);
expander::expand_rules(&self.rules, &tt)
}
pub fn map_id_down(&self, id: tt::TokenId) -> tt::TokenId {
self.shift.shift(id)
}
pub fn map_id_up(&self, id: tt::TokenId) -> (tt::TokenId, Origin) {
match self.shift.unshift(id) {
Some(id) => (id, Origin::Call),
None => (id, Origin::Def),
}
}
pub fn shift(&self) -> Shift {
self.shift
}
}
impl Rule {
fn parse(src: &mut TtIter<'_>, expect_arrow: bool) -> Result<Self, ParseError> {
let lhs = src.expect_subtree().map_err(|()| ParseError::expected("expected subtree"))?;
if expect_arrow {
src.expect_char('=').map_err(|()| ParseError::expected("expected `=`"))?;
src.expect_char('>').map_err(|()| ParseError::expected("expected `>`"))?;
}
let rhs = src.expect_subtree().map_err(|()| ParseError::expected("expected subtree"))?;
let lhs = MetaTemplate::parse_pattern(lhs)?;
let rhs = MetaTemplate::parse_template(rhs)?;
Ok(crate::Rule { lhs, rhs })
}
}
fn validate(pattern: &MetaTemplate) -> Result<(), ParseError> {
for op in pattern.iter() {
match op {
Op::Subtree { tokens, .. } => validate(tokens)?,
Op::Repeat { tokens: subtree, separator, .. } => {
// Checks that no repetition which could match an empty token
// https://github.com/rust-lang/rust/blob/a58b1ed44f5e06976de2bdc4d7dc81c36a96934f/src/librustc_expand/mbe/macro_rules.rs#L558
let lsh_is_empty_seq = separator.is_none() && subtree.iter().all(|child_op| {
match *child_op {
// vis is optional
Op::Var { kind: Some(kind), .. } => kind == MetaVarKind::Vis,
Op::Repeat {
kind: parser::RepeatKind::ZeroOrMore | parser::RepeatKind::ZeroOrOne,
..
} => true,
_ => false,
}
});
if lsh_is_empty_seq {
return Err(ParseError::RepetitionEmptyTokenTree);
}
validate(subtree)?
}
_ => (),
}
}
Ok(())
}
pub type ExpandResult<T> = ValueResult<T, ExpandError>;
#[derive(Debug, Clone, Eq, PartialEq)]
pub struct ValueResult<T, E> {
pub value: T,
pub err: Option<E>,
}
impl<T, E> ValueResult<T, E> {
pub fn ok(value: T) -> Self {
Self { value, err: None }
}
pub fn only_err(err: E) -> Self
where
T: Default,
{
Self { value: Default::default(), err: Some(err) }
}
pub fn map<U>(self, f: impl FnOnce(T) -> U) -> ValueResult<U, E> {
ValueResult { value: f(self.value), err: self.err }
}
pub fn map_err<E2>(self, f: impl FnOnce(E) -> E2) -> ValueResult<T, E2> {
ValueResult { value: self.value, err: self.err.map(f) }
}
pub fn result(self) -> Result<T, E> {
self.err.map_or(Ok(self.value), Err)
}
}
impl<T: Default, E> From<Result<T, E>> for ValueResult<T, E> {
fn from(result: Result<T, E>) -> Self {
result.map_or_else(Self::only_err, Self::ok)
}
}
|
