//! A stably addressed token buffer supporting efficient traversal based on a //! cheaply copyable cursor. //! //! *This module is available only if Syn is built with the `"parsing"` feature.* // This module is heavily commented as it contains most of the unsafe code in // Syn, and caution should be used when editing it. The public-facing interface // is 100% safe but the implementation is fragile internally. #[cfg(all( not(all(target_arch = "wasm32", any(target_os = "unknown", target_os = "wasi"))), feature = "proc-macro" ))] use crate::proc_macro as pm; use crate::Lifetime; use proc_macro2::{Delimiter, Group, Ident, Literal, Punct, Spacing, Span, TokenStream, TokenTree}; use std::hint; use std::marker::PhantomData; use std::mem; use std::ptr; use std::slice; /// Internal type which is used instead of `TokenTree` to represent a token tree /// within a `TokenBuffer`. enum Entry { // Mimicking types from proc-macro. Group(Group, TokenBuffer), Ident(Ident), Punct(Punct), Literal(Literal), // End entries contain a raw pointer to the entry from the containing // token tree, or null if this is the outermost level. End(*const Entry), } /// A buffer that can be efficiently traversed multiple times, unlike /// `TokenStream` which requires a deep copy in order to traverse more than /// once. /// /// *This type is available only if Syn is built with the `"parsing"` feature.* pub struct TokenBuffer { // NOTE: Do not implement clone on this - there are raw pointers inside // these entries which will be messed up. Moving the `TokenBuffer` itself is // safe as the data pointed to won't be moved. ptr: *const Entry, len: usize, } impl Drop for TokenBuffer { fn drop(&mut self) { unsafe { let slice = slice::from_raw_parts_mut(self.ptr as *mut Entry, self.len); let _ = Box::from_raw(slice); } } } impl TokenBuffer { // NOTE: Do not mutate the Vec returned from this function once it returns; // the address of its backing memory must remain stable. fn inner_new(stream: TokenStream, up: *const Entry) -> TokenBuffer { let iterator = stream.into_iter(); let mut entries = Vec::with_capacity(iterator.size_hint().0 + 1); let mut next_index_after_last_group = 0; for tt in iterator { match tt { TokenTree::Ident(ident) => { entries.push(Entry::Ident(ident)); } TokenTree::Punct(punct) => { entries.push(Entry::Punct(punct)); } TokenTree::Literal(literal) => { entries.push(Entry::Literal(literal)); } TokenTree::Group(group) => { // We cannot fill in a real `End` pointer until `entries` is // finished growing and getting potentially reallocated. // Instead, we temporarily coopt the spot where the end // pointer would go, and use it to string together an // intrusive linked list of all the Entry::Group entries in // the vector. Later after `entries` is done growing, we'll // traverse the linked list and fill in all the end // pointers with a correct value. let group_up = ptr::null::().wrapping_add(next_index_after_last_group) as *const Entry; let inner = Self::inner_new(group.stream(), group_up); entries.push(Entry::Group(group, inner)); next_index_after_last_group = entries.len(); } } } // Add an `End` entry to the end with a reference to the enclosing token // stream which was passed in. entries.push(Entry::End(up)); // NOTE: This is done to ensure that we don't accidentally modify the // length of the backing buffer. The backing buffer must remain at a // constant address after this point, as we are going to store a raw // pointer into it. let entries = entries.into_boxed_slice(); let len = entries.len(); // Convert boxed slice into a pointer to the first element early, to // avoid invalidating pointers into this slice when we move the Box. // See https://github.com/rust-lang/unsafe-code-guidelines/issues/326 let entries = Box::into_raw(entries) as *mut Entry; // Traverse intrusive linked list of Entry::Group entries and fill in // correct End pointers. while let Some(idx) = next_index_after_last_group.checked_sub(1) { // We know that idx refers to one of the Entry::Group entries, and // that the very last entry is an Entry::End, so the next index // after any group entry is a valid index. let group_up = unsafe { entries.add(next_index_after_last_group) }; // Linked list only takes us to entries which are of type Group. let token_buffer = match unsafe { &*entries.add(idx) } { Entry::Group(_group, token_buffer) => token_buffer, _ => unsafe { hint::unreachable_unchecked() }, }; // Last entry in any TokenBuffer is of type End. let buffer_ptr = token_buffer.ptr as *mut Entry; let last_entry = unsafe { &mut *buffer_ptr.add(token_buffer.len - 1) }; let end_ptr_slot = match last_entry { Entry::End(end_ptr_slot) => end_ptr_slot, _ => unsafe { hint::unreachable_unchecked() }, }; // Step to next element in linked list. next_index_after_last_group = mem::replace(end_ptr_slot, group_up) as usize; } TokenBuffer { ptr: entries, len } } /// Creates a `TokenBuffer` containing all the tokens from the input /// `proc_macro::TokenStream`. /// /// *This method is available only if Syn is built with both the `"parsing"` and /// `"proc-macro"` features.* #[cfg(all( not(all(target_arch = "wasm32", any(target_os = "unknown", target_os = "wasi"))), feature = "proc-macro" ))] pub fn new(stream: pm::TokenStream) -> Self { Self::new2(stream.into()) } /// Creates a `TokenBuffer` containing all the tokens from the input /// `proc_macro2::TokenStream`. pub fn new2(stream: TokenStream) -> Self { Self::inner_new(stream, ptr::null()) } /// 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 { unsafe { Cursor::create(self.ptr, self.ptr.add(self.len - 1)) } } } /// A cheaply copyable cursor into a `TokenBuffer`. /// /// This cursor holds a shared reference into the immutable data which is used /// internally to represent a `TokenStream`, and can be efficiently manipulated /// and copied around. /// /// An empty `Cursor` can be created directly, or one may create a `TokenBuffer` /// object and get a cursor to its first token with `begin()`. /// /// Two cursors are equal if they have the same location in the same input /// stream, and have the same scope. /// /// *This type is available only if Syn is built with the `"parsing"` feature.* pub struct Cursor<'a> { // The current entry which the `Cursor` is pointing at. ptr: *const Entry, // This is the only `Entry::End(..)` object which this cursor is allowed to // point at. All other `End` objects are skipped over in `Cursor::create`. scope: *const Entry, // Cursor is covariant in 'a. This field ensures that our pointers are still // valid. marker: PhantomData<&'a Entry>, } impl<'a> Cursor<'a> { /// Creates a cursor referencing a static empty TokenStream. pub fn empty() -> Self { // It's safe in this situation for us to put an `Entry` object in global // storage, despite it not actually being safe to send across threads // (`Ident` is a reference into a thread-local table). This is because // this entry never includes a `Ident` object. // // This wrapper struct allows us to break the rules and put a `Sync` // object in global storage. struct UnsafeSyncEntry(Entry); unsafe impl Sync for UnsafeSyncEntry {} static EMPTY_ENTRY: UnsafeSyncEntry = UnsafeSyncEntry(Entry::End(0 as *const Entry)); Cursor { ptr: &EMPTY_ENTRY.0, scope: &EMPTY_ENTRY.0, marker: PhantomData, } } /// This create method intelligently exits non-explicitly-entered /// `None`-delimited scopes when the cursor reaches the end of them, /// allowing for them to be treated transparently. unsafe fn create(mut ptr: *const Entry, scope: *const Entry) -> Self { // NOTE: If we're looking at a `End(..)`, we want to advance the cursor // past it, unless `ptr == scope`, which means that we're at the edge of // our cursor's scope. We should only have `ptr != scope` at the exit // from None-delimited groups entered with `ignore_none`. while let Entry::End(exit) = *ptr { if ptr == scope { break; } ptr = exit; } Cursor { ptr, scope, marker: PhantomData, } } /// Get the current entry. fn entry(self) -> &'a Entry { unsafe { &*self.ptr } } /// Bump the cursor to point at the next token after the current one. This /// is undefined behavior if the cursor is currently looking at an /// `Entry::End`. unsafe fn bump(self) -> Cursor<'a> { Cursor::create(self.ptr.offset(1), self.scope) } /// While the cursor is looking at a `None`-delimited group, move it to look /// at the first token inside instead. If the group is empty, this will move /// the cursor past the `None`-delimited group. /// /// WARNING: This mutates its argument. fn ignore_none(&mut self) { while let Entry::Group(group, buf) = self.entry() { if group.delimiter() == Delimiter::None { // NOTE: We call `Cursor::create` here to make sure that // situations where we should immediately exit the span after // entering it are handled correctly. unsafe { *self = Cursor::create(buf.ptr, self.scope); } } else { break; } } } /// Checks whether the cursor is currently pointing at the end of its valid /// scope. pub fn eof(self) -> bool { // We're at eof if we're at the end of our scope. self.ptr == self.scope } /// If the cursor is pointing at a `Group` with the given delimiter, returns /// a cursor into that group and one pointing to the next `TokenTree`. pub fn group(mut self, delim: Delimiter) -> Option<(Cursor<'a>, Span, Cursor<'a>)> { // If we're not trying to enter a none-delimited group, we want to // ignore them. We have to make sure to _not_ ignore them when we want // to enter them, of course. For obvious reasons. if delim != Delimiter::None { self.ignore_none(); } if let Entry::Group(group, buf) = self.entry() { if group.delimiter() == delim { return Some((buf.begin(), group.span(), unsafe { self.bump() })); } } None } /// If the cursor is pointing at a `Ident`, returns it along with a cursor /// pointing at the next `TokenTree`. pub fn ident(mut self) -> Option<(Ident, Cursor<'a>)> { self.ignore_none(); match self.entry() { Entry::Ident(ident) => Some((ident.clone(), unsafe { self.bump() })), _ => None, } } /// If the cursor is pointing at a `Punct`, returns it along with a cursor /// pointing at the next `TokenTree`. pub fn punct(mut self) -> Option<(Punct, Cursor<'a>)> { self.ignore_none(); match self.entry() { Entry::Punct(punct) if punct.as_char() != '\'' => { Some((punct.clone(), unsafe { self.bump() })) } _ => None, } } /// If the cursor is pointing at a `Literal`, return it along with a cursor /// pointing at the next `TokenTree`. pub fn literal(mut self) -> Option<(Literal, Cursor<'a>)> { self.ignore_none(); match self.entry() { Entry::Literal(literal) => Some((literal.clone(), unsafe { self.bump() })), _ => None, } } /// If the cursor is pointing at a `Lifetime`, returns it along with a /// cursor pointing at the next `TokenTree`. pub fn lifetime(mut self) -> Option<(Lifetime, Cursor<'a>)> { self.ignore_none(); match self.entry() { Entry::Punct(punct) if punct.as_char() == '\'' && punct.spacing() == Spacing::Joint => { let next = unsafe { self.bump() }; match next.ident() { Some((ident, rest)) => { let lifetime = Lifetime { apostrophe: punct.span(), ident, }; Some((lifetime, rest)) } None => None, } } _ => None, } } /// Copies all remaining tokens visible from this cursor into a /// `TokenStream`. pub fn token_stream(self) -> TokenStream { let mut tts = Vec::new(); let mut cursor = self; while let Some((tt, rest)) = cursor.token_tree() { tts.push(tt); cursor = rest; } tts.into_iter().collect() } /// If the cursor is pointing at a `TokenTree`, returns it along with a /// cursor pointing at the next `TokenTree`. /// /// Returns `None` if the cursor has reached the end of its stream. /// /// This method does not treat `None`-delimited groups as transparent, and /// will return a `Group(None, ..)` if the cursor is looking at one. pub fn token_tree(self) -> Option<(TokenTree, Cursor<'a>)> { let tree = match self.entry() { Entry::Group(group, _) => group.clone().into(), Entry::Literal(literal) => literal.clone().into(), Entry::Ident(ident) => ident.clone().into(), Entry::Punct(punct) => punct.clone().into(), Entry::End(..) => return None, }; Some((tree, unsafe { self.bump() })) } /// Returns the `Span` of the current token, or `Span::call_site()` if this /// cursor points to eof. pub fn span(self) -> Span { match self.entry() { Entry::Group(group, _) => group.span(), Entry::Literal(literal) => literal.span(), Entry::Ident(ident) => ident.span(), Entry::Punct(punct) => punct.span(), Entry::End(..) => Span::call_site(), } } /// Skip over the next token without cloning it. Returns `None` if this /// cursor points to eof. /// /// This method treats `'lifetimes` as a single token. pub(crate) fn skip(self) -> Option> { match self.entry() { Entry::End(..) => None, // Treat lifetimes as a single tt for the purposes of 'skip'. Entry::Punct(punct) if punct.as_char() == '\'' && punct.spacing() == Spacing::Joint => { let next = unsafe { self.bump() }; match next.entry() { Entry::Ident(_) => Some(unsafe { next.bump() }), _ => Some(next), } } _ => Some(unsafe { self.bump() }), } } } impl<'a> Copy for Cursor<'a> {} impl<'a> Clone for Cursor<'a> { fn clone(&self) -> Self { *self } } impl<'a> Eq for Cursor<'a> {} impl<'a> PartialEq for Cursor<'a> { fn eq(&self, other: &Self) -> bool { let Cursor { ptr, scope, marker } = self; let _ = marker; *ptr == other.ptr && *scope == other.scope } } pub(crate) fn same_scope(a: Cursor, b: Cursor) -> bool { a.scope == b.scope } pub(crate) fn open_span_of_group(cursor: Cursor) -> Span { match cursor.entry() { Entry::Group(group, _) => group.span_open(), _ => cursor.span(), } } pub(crate) fn close_span_of_group(cursor: Cursor) -> Span { match cursor.entry() { Entry::Group(group, _) => group.span_close(), _ => cursor.span(), } }