//! Stateful iteration over token trees. //! //! We use this as the source of tokens for parser. use crate::{Leaf, Subtree, TokenTree}; #[derive(Copy, Clone, Debug, Eq, PartialEq)] struct EntryId(usize); #[derive(Copy, Clone, Debug, Eq, PartialEq)] struct EntryPtr(EntryId, usize); /// Internal type which is used instead of `TokenTree` to represent a token tree /// within a `TokenBuffer`. #[derive(Debug)] enum Entry<'t> { // Mimicking types from proc-macro. Subtree(Option<&'t TokenTree>, &'t Subtree, EntryId), Leaf(&'t TokenTree), // End entries contain a pointer to the entry from the containing // token tree, or None if this is the outermost level. End(Option), } /// A token tree buffer /// The safe version of `syn` [`TokenBuffer`](https://github.com/dtolnay/syn/blob/6533607f91686545cb034d2838beea338d9d0742/src/buffer.rs#L41) #[derive(Debug)] pub struct TokenBuffer<'t> { buffers: Vec]>>, } trait TokenList<'a> { fn entries(&self) -> (Vec<(usize, (&'a Subtree, Option<&'a TokenTree>))>, Vec>); } impl<'a> TokenList<'a> for &'a [TokenTree] { fn entries(&self) -> (Vec<(usize, (&'a Subtree, Option<&'a TokenTree>))>, Vec>) { // Must contain everything in tokens and then the Entry::End let start_capacity = self.len() + 1; let mut entries = Vec::with_capacity(start_capacity); let mut children = vec![]; for (idx, tt) in self.iter().enumerate() { match tt { TokenTree::Leaf(_) => { entries.push(Entry::Leaf(tt)); } TokenTree::Subtree(subtree) => { entries.push(Entry::End(None)); children.push((idx, (subtree, Some(tt)))); } } } (children, entries) } } impl<'a> TokenList<'a> for &'a Subtree { fn entries(&self) -> (Vec<(usize, (&'a Subtree, Option<&'a TokenTree>))>, Vec>) { // Must contain everything in tokens and then the Entry::End let mut entries = vec![]; let mut children = vec![]; entries.push(Entry::End(None)); children.push((0usize, (*self, None))); (children, entries) } } impl<'t> TokenBuffer<'t> { pub fn from_tokens(tokens: &'t [TokenTree]) -> TokenBuffer<'t> { Self::new(tokens) } pub fn from_subtree(subtree: &'t Subtree) -> TokenBuffer<'t> { Self::new(subtree) } fn new>(tokens: T) -> TokenBuffer<'t> { let mut buffers = vec![]; let idx = TokenBuffer::new_inner(tokens, &mut buffers, None); assert_eq!(idx, 0); TokenBuffer { buffers } } fn new_inner>( tokens: T, buffers: &mut Vec]>>, next: Option, ) -> usize { let (children, mut entries) = tokens.entries(); entries.push(Entry::End(next)); let res = buffers.len(); buffers.push(entries.into_boxed_slice()); for (child_idx, (subtree, tt)) in children { let idx = TokenBuffer::new_inner( subtree.token_trees.as_slice(), buffers, Some(EntryPtr(EntryId(res), child_idx + 1)), ); buffers[res].as_mut()[child_idx] = Entry::Subtree(tt, subtree, EntryId(idx)); } res } /// Creates a cursor referencing the first token in the buffer and able to /// traverse until the end of the buffer. pub fn begin(&self) -> Cursor<'_> { Cursor::create(self, EntryPtr(EntryId(0), 0)) } fn entry(&self, ptr: &EntryPtr) -> Option<&Entry<'_>> { let id = ptr.0; self.buffers[id.0].get(ptr.1) } } #[derive(Debug)] pub enum TokenTreeRef<'a> { Subtree(&'a Subtree, Option<&'a TokenTree>), Leaf(&'a Leaf, &'a TokenTree), } impl<'a> TokenTreeRef<'a> { pub fn cloned(&self) -> TokenTree { match &self { TokenTreeRef::Subtree(subtree, tt) => match tt { Some(it) => (*it).clone(), None => (*subtree).clone().into(), }, TokenTreeRef::Leaf(_, tt) => (*tt).clone(), } } } /// A safe version of `Cursor` from `syn` crate #[derive(Copy, Clone, Debug)] pub struct Cursor<'a> { buffer: &'a TokenBuffer<'a>, ptr: EntryPtr, } impl<'a> PartialEq for Cursor<'a> { fn eq(&self, other: &Cursor<'_>) -> bool { self.ptr == other.ptr && std::ptr::eq(self.buffer, other.buffer) } } impl<'a> Eq for Cursor<'a> {} impl<'a> Cursor<'a> { /// Check whether it is eof pub fn eof(self) -> bool { matches!(self.buffer.entry(&self.ptr), None | Some(Entry::End(None))) } /// If the cursor is pointing at the end of a subtree, returns /// the parent subtree pub fn end(self) -> Option<&'a Subtree> { match self.entry() { Some(Entry::End(Some(ptr))) => { let idx = ptr.1; if let Some(Entry::Subtree(_, subtree, _)) = self.buffer.entry(&EntryPtr(ptr.0, idx - 1)) { return Some(subtree); } None } _ => None, } } fn entry(self) -> Option<&'a Entry<'a>> { self.buffer.entry(&self.ptr) } /// If the cursor is pointing at a `Subtree`, returns /// a cursor into that subtree pub fn subtree(self) -> Option> { match self.entry() { Some(Entry::Subtree(_, _, entry_id)) => { Some(Cursor::create(self.buffer, EntryPtr(*entry_id, 0))) } _ => None, } } /// If the cursor is pointing at a `TokenTree`, returns it pub fn token_tree(self) -> Option> { match self.entry() { Some(Entry::Leaf(tt)) => match tt { TokenTree::Leaf(leaf) => Some(TokenTreeRef::Leaf(leaf, tt)), TokenTree::Subtree(subtree) => Some(TokenTreeRef::Subtree(subtree, Some(tt))), }, Some(Entry::Subtree(tt, subtree, _)) => Some(TokenTreeRef::Subtree(subtree, *tt)), Some(Entry::End(_)) | None => None, } } fn create(buffer: &'a TokenBuffer<'_>, ptr: EntryPtr) -> Cursor<'a> { Cursor { buffer, ptr } } /// Bump the cursor pub fn bump(self) -> Cursor<'a> { if let Some(Entry::End(exit)) = self.buffer.entry(&self.ptr) { match exit { Some(exit) => Cursor::create(self.buffer, *exit), None => self, } } else { Cursor::create(self.buffer, EntryPtr(self.ptr.0, self.ptr.1 + 1)) } } /// Bump the cursor, if it is a subtree, returns /// a cursor into that subtree pub fn bump_subtree(self) -> Cursor<'a> { match self.entry() { Some(Entry::Subtree(_, _, _)) => self.subtree().unwrap(), _ => self.bump(), } } /// Check whether it is a top level pub fn is_root(&self) -> bool { let entry_id = self.ptr.0; entry_id.0 == 0 } }