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//! Machinery for hygienic macros.
//!
//! Inspired by Matthew Flatt et al., “Macros That Work Together: Compile-Time Bindings, Partial
//! Expansion, and Definition Contexts,” *Journal of Functional Programming* 22, no. 2
//! (March 1, 2012): 181–216, <https://doi.org/10.1017/S0956796812000093>.
// Hygiene data is stored in a global variable and accessed via TLS, which
// means that accesses are somewhat expensive. (`HygieneData::with`
// encapsulates a single access.) Therefore, on hot code paths it is worth
// ensuring that multiple HygieneData accesses are combined into a single
// `HygieneData::with`.
//
// This explains why `HygieneData`, `SyntaxContext` and `ExpnId` have interfaces
// with a certain amount of redundancy in them. For example,
// `SyntaxContext::outer_expn_data` combines `SyntaxContext::outer` and
// `ExpnId::expn_data` so that two `HygieneData` accesses can be performed within
// a single `HygieneData::with` call.
//
// It also explains why many functions appear in `HygieneData` and again in
// `SyntaxContext` or `ExpnId`. For example, `HygieneData::outer` and
// `SyntaxContext::outer` do the same thing, but the former is for use within a
// `HygieneData::with` call while the latter is for use outside such a call.
// When modifying this file it is important to understand this distinction,
// because getting it wrong can lead to nested `HygieneData::with` calls that
// trigger runtime aborts. (Fortunately these are obvious and easy to fix.)
use crate::def_id::{CrateNum, DefId, StableCrateId, CRATE_DEF_ID, LOCAL_CRATE};
use crate::edition::Edition;
use crate::symbol::{kw, sym, Symbol};
use crate::{with_session_globals, HashStableContext, Span, SpanDecoder, SpanEncoder, DUMMY_SP};
use rustc_data_structures::fingerprint::Fingerprint;
use rustc_data_structures::fx::{FxHashMap, FxHashSet};
use rustc_data_structures::stable_hasher::{Hash64, HashStable, HashingControls, StableHasher};
use rustc_data_structures::sync::{Lock, Lrc, WorkerLocal};
use rustc_data_structures::unhash::UnhashMap;
use rustc_index::IndexVec;
use rustc_macros::HashStable_Generic;
use rustc_serialize::{Decodable, Decoder, Encodable, Encoder};
use std::cell::RefCell;
use std::collections::hash_map::Entry;
use std::fmt;
use std::hash::Hash;
/// A `SyntaxContext` represents a chain of pairs `(ExpnId, Transparency)` named "marks".
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct SyntaxContext(u32);
#[derive(Debug, Encodable, Decodable, Clone)]
pub struct SyntaxContextData {
outer_expn: ExpnId,
outer_transparency: Transparency,
parent: SyntaxContext,
/// This context, but with all transparent and semi-transparent expansions filtered away.
opaque: SyntaxContext,
/// This context, but with all transparent expansions filtered away.
opaque_and_semitransparent: SyntaxContext,
/// Name of the crate to which `$crate` with this context would resolve.
dollar_crate_name: Symbol,
}
rustc_index::newtype_index! {
/// A unique ID associated with a macro invocation and expansion.
#[orderable]
pub struct ExpnIndex {}
}
/// A unique ID associated with a macro invocation and expansion.
#[derive(Clone, Copy, PartialEq, Eq, Hash)]
pub struct ExpnId {
pub krate: CrateNum,
pub local_id: ExpnIndex,
}
impl fmt::Debug for ExpnId {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
// Generate crate_::{{expn_}}.
write!(f, "{:?}::{{{{expn{}}}}}", self.krate, self.local_id.as_u32())
}
}
rustc_index::newtype_index! {
/// A unique ID associated with a macro invocation and expansion.
#[debug_format = "expn{}"]
pub struct LocalExpnId {}
}
// To ensure correctness of incremental compilation,
// `LocalExpnId` must not implement `Ord` or `PartialOrd`.
// See https://github.com/rust-lang/rust/issues/90317.
impl !Ord for LocalExpnId {}
impl !PartialOrd for LocalExpnId {}
/// Assert that the provided `HashStableContext` is configured with the 'default'
/// `HashingControls`. We should always have bailed out before getting to here
/// with a non-default mode. With this check in place, we can avoid the need
/// to maintain separate versions of `ExpnData` hashes for each permutation
/// of `HashingControls` settings.
fn assert_default_hashing_controls<CTX: HashStableContext>(ctx: &CTX, msg: &str) {
match ctx.hashing_controls() {
// Note that we require that `hash_spans` be set according to the global
// `-Z incremental-ignore-spans` option. Normally, this option is disabled,
// which will cause us to require that this method always be called with `Span` hashing
// enabled.
//
// Span hashing can also be disabled without `-Z incremental-ignore-spans`.
// This is the case for instance when building a hash for name mangling.
// Such configuration must not be used for metadata.
HashingControls { hash_spans }
if hash_spans != ctx.unstable_opts_incremental_ignore_spans() => {}
other => panic!("Attempted hashing of {msg} with non-default HashingControls: {other:?}"),
}
}
/// A unique hash value associated to an expansion.
#[derive(Clone, Copy, PartialEq, Eq, Hash, Debug, Encodable, Decodable, HashStable_Generic)]
pub struct ExpnHash(Fingerprint);
impl ExpnHash {
/// Returns the [StableCrateId] identifying the crate this [ExpnHash]
/// originates from.
#[inline]
pub fn stable_crate_id(self) -> StableCrateId {
StableCrateId(self.0.split().0)
}
/// Returns the crate-local part of the [ExpnHash].
///
/// Used for assertions.
#[inline]
pub fn local_hash(self) -> Hash64 {
self.0.split().1
}
#[inline]
pub fn is_root(self) -> bool {
self.0 == Fingerprint::ZERO
}
/// Builds a new [ExpnHash] with the given [StableCrateId] and
/// `local_hash`, where `local_hash` must be unique within its crate.
fn new(stable_crate_id: StableCrateId, local_hash: Hash64) -> ExpnHash {
ExpnHash(Fingerprint::new(stable_crate_id.0, local_hash))
}
}
/// A property of a macro expansion that determines how identifiers
/// produced by that expansion are resolved.
#[derive(Copy, Clone, PartialEq, Eq, PartialOrd, Hash, Debug, Encodable, Decodable)]
#[derive(HashStable_Generic)]
pub enum Transparency {
/// Identifier produced by a transparent expansion is always resolved at call-site.
/// Call-site spans in procedural macros, hygiene opt-out in `macro` should use this.
Transparent,
/// Identifier produced by a semi-transparent expansion may be resolved
/// either at call-site or at definition-site.
/// If it's a local variable, label or `$crate` then it's resolved at def-site.
/// Otherwise it's resolved at call-site.
/// `macro_rules` macros behave like this, built-in macros currently behave like this too,
/// but that's an implementation detail.
SemiTransparent,
/// Identifier produced by an opaque expansion is always resolved at definition-site.
/// Def-site spans in procedural macros, identifiers from `macro` by default use this.
Opaque,
}
impl LocalExpnId {
/// The ID of the theoretical expansion that generates freshly parsed, unexpanded AST.
pub const ROOT: LocalExpnId = LocalExpnId::from_u32(0);
#[inline]
fn from_raw(idx: ExpnIndex) -> LocalExpnId {
LocalExpnId::from_u32(idx.as_u32())
}
#[inline]
pub fn as_raw(self) -> ExpnIndex {
ExpnIndex::from_u32(self.as_u32())
}
pub fn fresh_empty() -> LocalExpnId {
HygieneData::with(|data| {
let expn_id = data.local_expn_data.push(None);
let _eid = data.local_expn_hashes.push(ExpnHash(Fingerprint::ZERO));
debug_assert_eq!(expn_id, _eid);
expn_id
})
}
pub fn fresh(mut expn_data: ExpnData, ctx: impl HashStableContext) -> LocalExpnId {
debug_assert_eq!(expn_data.parent.krate, LOCAL_CRATE);
let expn_hash = update_disambiguator(&mut expn_data, ctx);
HygieneData::with(|data| {
let expn_id = data.local_expn_data.push(Some(expn_data));
let _eid = data.local_expn_hashes.push(expn_hash);
debug_assert_eq!(expn_id, _eid);
let _old_id = data.expn_hash_to_expn_id.insert(expn_hash, expn_id.to_expn_id());
debug_assert!(_old_id.is_none());
expn_id
})
}
#[inline]
pub fn expn_data(self) -> ExpnData {
HygieneData::with(|data| data.local_expn_data(self).clone())
}
#[inline]
pub fn to_expn_id(self) -> ExpnId {
ExpnId { krate: LOCAL_CRATE, local_id: self.as_raw() }
}
#[inline]
pub fn set_expn_data(self, mut expn_data: ExpnData, ctx: impl HashStableContext) {
debug_assert_eq!(expn_data.parent.krate, LOCAL_CRATE);
let expn_hash = update_disambiguator(&mut expn_data, ctx);
HygieneData::with(|data| {
let old_expn_data = &mut data.local_expn_data[self];
assert!(old_expn_data.is_none(), "expansion data is reset for an expansion ID");
*old_expn_data = Some(expn_data);
debug_assert_eq!(data.local_expn_hashes[self].0, Fingerprint::ZERO);
data.local_expn_hashes[self] = expn_hash;
let _old_id = data.expn_hash_to_expn_id.insert(expn_hash, self.to_expn_id());
debug_assert!(_old_id.is_none());
});
}
#[inline]
pub fn is_descendant_of(self, ancestor: LocalExpnId) -> bool {
self.to_expn_id().is_descendant_of(ancestor.to_expn_id())
}
/// Returns span for the macro which originally caused this expansion to happen.
///
/// Stops backtracing at include! boundary.
#[inline]
pub fn expansion_cause(self) -> Option<Span> {
self.to_expn_id().expansion_cause()
}
}
impl ExpnId {
/// The ID of the theoretical expansion that generates freshly parsed, unexpanded AST.
/// Invariant: we do not create any ExpnId with local_id == 0 and krate != 0.
pub const fn root() -> ExpnId {
ExpnId { krate: LOCAL_CRATE, local_id: ExpnIndex::from_u32(0) }
}
#[inline]
pub fn expn_hash(self) -> ExpnHash {
HygieneData::with(|data| data.expn_hash(self))
}
#[inline]
pub fn from_hash(hash: ExpnHash) -> Option<ExpnId> {
HygieneData::with(|data| data.expn_hash_to_expn_id.get(&hash).copied())
}
#[inline]
pub fn as_local(self) -> Option<LocalExpnId> {
if self.krate == LOCAL_CRATE { Some(LocalExpnId::from_raw(self.local_id)) } else { None }
}
#[inline]
#[track_caller]
pub fn expect_local(self) -> LocalExpnId {
self.as_local().unwrap()
}
#[inline]
pub fn expn_data(self) -> ExpnData {
HygieneData::with(|data| data.expn_data(self).clone())
}
#[inline]
pub fn is_descendant_of(self, ancestor: ExpnId) -> bool {
// a few "fast path" cases to avoid locking HygieneData
if ancestor == ExpnId::root() || ancestor == self {
return true;
}
if ancestor.krate != self.krate {
return false;
}
HygieneData::with(|data| data.is_descendant_of(self, ancestor))
}
/// `expn_id.outer_expn_is_descendant_of(ctxt)` is equivalent to but faster than
/// `expn_id.is_descendant_of(ctxt.outer_expn())`.
pub fn outer_expn_is_descendant_of(self, ctxt: SyntaxContext) -> bool {
HygieneData::with(|data| data.is_descendant_of(self, data.outer_expn(ctxt)))
}
/// Returns span for the macro which originally caused this expansion to happen.
///
/// Stops backtracing at include! boundary.
pub fn expansion_cause(mut self) -> Option<Span> {
let mut last_macro = None;
loop {
// Fast path to avoid locking.
if self == ExpnId::root() {
break;
}
let expn_data = self.expn_data();
// Stop going up the backtrace once include! is encountered
if expn_data.kind == ExpnKind::Macro(MacroKind::Bang, sym::include) {
break;
}
self = expn_data.call_site.ctxt().outer_expn();
last_macro = Some(expn_data.call_site);
}
last_macro
}
}
#[derive(Debug)]
pub(crate) struct HygieneData {
/// Each expansion should have an associated expansion data, but sometimes there's a delay
/// between creation of an expansion ID and obtaining its data (e.g. macros are collected
/// first and then resolved later), so we use an `Option` here.
local_expn_data: IndexVec<LocalExpnId, Option<ExpnData>>,
local_expn_hashes: IndexVec<LocalExpnId, ExpnHash>,
/// Data and hash information from external crates. We may eventually want to remove these
/// maps, and fetch the information directly from the other crate's metadata like DefIds do.
foreign_expn_data: FxHashMap<ExpnId, ExpnData>,
foreign_expn_hashes: FxHashMap<ExpnId, ExpnHash>,
expn_hash_to_expn_id: UnhashMap<ExpnHash, ExpnId>,
syntax_context_data: Vec<SyntaxContextData>,
syntax_context_map: FxHashMap<(SyntaxContext, ExpnId, Transparency), SyntaxContext>,
/// Maps the `local_hash` of an `ExpnData` to the next disambiguator value.
/// This is used by `update_disambiguator` to keep track of which `ExpnData`s
/// would have collisions without a disambiguator.
/// The keys of this map are always computed with `ExpnData.disambiguator`
/// set to 0.
expn_data_disambiguators: UnhashMap<Hash64, u32>,
}
impl HygieneData {
pub(crate) fn new(edition: Edition) -> Self {
let root_data = ExpnData::default(
ExpnKind::Root,
DUMMY_SP,
edition,
Some(CRATE_DEF_ID.to_def_id()),
None,
);
HygieneData {
local_expn_data: IndexVec::from_elem_n(Some(root_data), 1),
local_expn_hashes: IndexVec::from_elem_n(ExpnHash(Fingerprint::ZERO), 1),
foreign_expn_data: FxHashMap::default(),
foreign_expn_hashes: FxHashMap::default(),
expn_hash_to_expn_id: std::iter::once((ExpnHash(Fingerprint::ZERO), ExpnId::root()))
.collect(),
syntax_context_data: vec![SyntaxContextData {
outer_expn: ExpnId::root(),
outer_transparency: Transparency::Opaque,
parent: SyntaxContext(0),
opaque: SyntaxContext(0),
opaque_and_semitransparent: SyntaxContext(0),
dollar_crate_name: kw::DollarCrate,
}],
syntax_context_map: FxHashMap::default(),
expn_data_disambiguators: UnhashMap::default(),
}
}
fn with<T, F: FnOnce(&mut HygieneData) -> T>(f: F) -> T {
with_session_globals(|session_globals| f(&mut session_globals.hygiene_data.borrow_mut()))
}
#[inline]
fn expn_hash(&self, expn_id: ExpnId) -> ExpnHash {
match expn_id.as_local() {
Some(expn_id) => self.local_expn_hashes[expn_id],
None => self.foreign_expn_hashes[&expn_id],
}
}
fn local_expn_data(&self, expn_id: LocalExpnId) -> &ExpnData {
self.local_expn_data[expn_id].as_ref().expect("no expansion data for an expansion ID")
}
fn expn_data(&self, expn_id: ExpnId) -> &ExpnData {
if let Some(expn_id) = expn_id.as_local() {
self.local_expn_data[expn_id].as_ref().expect("no expansion data for an expansion ID")
} else {
&self.foreign_expn_data[&expn_id]
}
}
fn is_descendant_of(&self, mut expn_id: ExpnId, ancestor: ExpnId) -> bool {
// a couple "fast path" cases to avoid traversing parents in the loop below
if ancestor == ExpnId::root() {
return true;
}
if expn_id.krate != ancestor.krate {
return false;
}
loop {
if expn_id == ancestor {
return true;
}
if expn_id == ExpnId::root() {
return false;
}
expn_id = self.expn_data(expn_id).parent;
}
}
fn normalize_to_macros_2_0(&self, ctxt: SyntaxContext) -> SyntaxContext {
self.syntax_context_data[ctxt.0 as usize].opaque
}
fn normalize_to_macro_rules(&self, ctxt: SyntaxContext) -> SyntaxContext {
self.syntax_context_data[ctxt.0 as usize].opaque_and_semitransparent
}
fn outer_expn(&self, ctxt: SyntaxContext) -> ExpnId {
self.syntax_context_data[ctxt.0 as usize].outer_expn
}
fn outer_mark(&self, ctxt: SyntaxContext) -> (ExpnId, Transparency) {
let data = &self.syntax_context_data[ctxt.0 as usize];
(data.outer_expn, data.outer_transparency)
}
fn parent_ctxt(&self, ctxt: SyntaxContext) -> SyntaxContext {
self.syntax_context_data[ctxt.0 as usize].parent
}
fn remove_mark(&self, ctxt: &mut SyntaxContext) -> (ExpnId, Transparency) {
let outer_mark = self.outer_mark(*ctxt);
*ctxt = self.parent_ctxt(*ctxt);
outer_mark
}
fn marks(&self, mut ctxt: SyntaxContext) -> Vec<(ExpnId, Transparency)> {
let mut marks = Vec::new();
while !ctxt.is_root() {
debug!("marks: getting parent of {:?}", ctxt);
marks.push(self.outer_mark(ctxt));
ctxt = self.parent_ctxt(ctxt);
}
marks.reverse();
marks
}
fn walk_chain(&self, mut span: Span, to: SyntaxContext) -> Span {
let orig_span = span;
debug!("walk_chain({:?}, {:?})", span, to);
debug!("walk_chain: span ctxt = {:?}", span.ctxt());
while span.ctxt() != to && span.from_expansion() {
let outer_expn = self.outer_expn(span.ctxt());
debug!("walk_chain({:?}): outer_expn={:?}", span, outer_expn);
let expn_data = self.expn_data(outer_expn);
debug!("walk_chain({:?}): expn_data={:?}", span, expn_data);
span = expn_data.call_site;
}
debug!("walk_chain: for span {:?} >>> return span = {:?}", orig_span, span);
span
}
// We need to walk up and update return span if we meet macro instantiation to be collapsed
fn walk_chain_collapsed(
&self,
mut span: Span,
to: Span,
collapse_debuginfo_feature_enabled: bool,
) -> Span {
let orig_span = span;
let mut ret_span = span;
debug!(
"walk_chain_collapsed({:?}, {:?}), feature_enable={}",
span, to, collapse_debuginfo_feature_enabled,
);
debug!("walk_chain_collapsed: span ctxt = {:?}", span.ctxt());
while !span.eq_ctxt(to) && span.from_expansion() {
let outer_expn = self.outer_expn(span.ctxt());
debug!("walk_chain_collapsed({:?}): outer_expn={:?}", span, outer_expn);
let expn_data = self.expn_data(outer_expn);
debug!("walk_chain_collapsed({:?}): expn_data={:?}", span, expn_data);
span = expn_data.call_site;
if !collapse_debuginfo_feature_enabled || expn_data.collapse_debuginfo {
ret_span = span;
}
}
debug!("walk_chain_collapsed: for span {:?} >>> return span = {:?}", orig_span, ret_span);
ret_span
}
fn adjust(&self, ctxt: &mut SyntaxContext, expn_id: ExpnId) -> Option<ExpnId> {
let mut scope = None;
while !self.is_descendant_of(expn_id, self.outer_expn(*ctxt)) {
scope = Some(self.remove_mark(ctxt).0);
}
scope
}
fn apply_mark(
&mut self,
ctxt: SyntaxContext,
expn_id: ExpnId,
transparency: Transparency,
) -> SyntaxContext {
assert_ne!(expn_id, ExpnId::root());
if transparency == Transparency::Opaque {
return self.apply_mark_internal(ctxt, expn_id, transparency);
}
let call_site_ctxt = self.expn_data(expn_id).call_site.ctxt();
let mut call_site_ctxt = if transparency == Transparency::SemiTransparent {
self.normalize_to_macros_2_0(call_site_ctxt)
} else {
self.normalize_to_macro_rules(call_site_ctxt)
};
if call_site_ctxt.is_root() {
return self.apply_mark_internal(ctxt, expn_id, transparency);
}
// Otherwise, `expn_id` is a macros 1.0 definition and the call site is in a
// macros 2.0 expansion, i.e., a macros 1.0 invocation is in a macros 2.0 definition.
//
// In this case, the tokens from the macros 1.0 definition inherit the hygiene
// at their invocation. That is, we pretend that the macros 1.0 definition
// was defined at its invocation (i.e., inside the macros 2.0 definition)
// so that the macros 2.0 definition remains hygienic.
//
// See the example at `test/ui/hygiene/legacy_interaction.rs`.
for (expn_id, transparency) in self.marks(ctxt) {
call_site_ctxt = self.apply_mark_internal(call_site_ctxt, expn_id, transparency);
}
self.apply_mark_internal(call_site_ctxt, expn_id, transparency)
}
fn apply_mark_internal(
&mut self,
ctxt: SyntaxContext,
expn_id: ExpnId,
transparency: Transparency,
) -> SyntaxContext {
let syntax_context_data = &mut self.syntax_context_data;
let mut opaque = syntax_context_data[ctxt.0 as usize].opaque;
let mut opaque_and_semitransparent =
syntax_context_data[ctxt.0 as usize].opaque_and_semitransparent;
if transparency >= Transparency::Opaque {
let parent = opaque;
opaque = *self
.syntax_context_map
.entry((parent, expn_id, transparency))
.or_insert_with(|| {
let new_opaque = SyntaxContext(syntax_context_data.len() as u32);
syntax_context_data.push(SyntaxContextData {
outer_expn: expn_id,
outer_transparency: transparency,
parent,
opaque: new_opaque,
opaque_and_semitransparent: new_opaque,
dollar_crate_name: kw::DollarCrate,
});
new_opaque
});
}
if transparency >= Transparency::SemiTransparent {
let parent = opaque_and_semitransparent;
opaque_and_semitransparent = *self
.syntax_context_map
.entry((parent, expn_id, transparency))
.or_insert_with(|| {
let new_opaque_and_semitransparent =
SyntaxContext(syntax_context_data.len() as u32);
syntax_context_data.push(SyntaxContextData {
outer_expn: expn_id,
outer_transparency: transparency,
parent,
opaque,
opaque_and_semitransparent: new_opaque_and_semitransparent,
dollar_crate_name: kw::DollarCrate,
});
new_opaque_and_semitransparent
});
}
let parent = ctxt;
*self.syntax_context_map.entry((parent, expn_id, transparency)).or_insert_with(|| {
let new_opaque_and_semitransparent_and_transparent =
SyntaxContext(syntax_context_data.len() as u32);
syntax_context_data.push(SyntaxContextData {
outer_expn: expn_id,
outer_transparency: transparency,
parent,
opaque,
opaque_and_semitransparent,
dollar_crate_name: kw::DollarCrate,
});
new_opaque_and_semitransparent_and_transparent
})
}
}
pub fn walk_chain(span: Span, to: SyntaxContext) -> Span {
HygieneData::with(|data| data.walk_chain(span, to))
}
pub fn walk_chain_collapsed(
span: Span,
to: Span,
collapse_debuginfo_feature_enabled: bool,
) -> Span {
HygieneData::with(|hdata| {
hdata.walk_chain_collapsed(span, to, collapse_debuginfo_feature_enabled)
})
}
pub fn update_dollar_crate_names(mut get_name: impl FnMut(SyntaxContext) -> Symbol) {
// The new contexts that need updating are at the end of the list and have `$crate` as a name.
let (len, to_update) = HygieneData::with(|data| {
(
data.syntax_context_data.len(),
data.syntax_context_data
.iter()
.rev()
.take_while(|scdata| scdata.dollar_crate_name == kw::DollarCrate)
.count(),
)
});
// The callback must be called from outside of the `HygieneData` lock,
// since it will try to acquire it too.
let range_to_update = len - to_update..len;
let names: Vec<_> =
range_to_update.clone().map(|idx| get_name(SyntaxContext::from_u32(idx as u32))).collect();
HygieneData::with(|data| {
range_to_update.zip(names).for_each(|(idx, name)| {
data.syntax_context_data[idx].dollar_crate_name = name;
})
})
}
pub fn debug_hygiene_data(verbose: bool) -> String {
HygieneData::with(|data| {
if verbose {
format!("{data:#?}")
} else {
let mut s = String::from("Expansions:");
let mut debug_expn_data = |(id, expn_data): (&ExpnId, &ExpnData)| {
s.push_str(&format!(
"\n{:?}: parent: {:?}, call_site_ctxt: {:?}, def_site_ctxt: {:?}, kind: {:?}",
id,
expn_data.parent,
expn_data.call_site.ctxt(),
expn_data.def_site.ctxt(),
expn_data.kind,
))
};
data.local_expn_data.iter_enumerated().for_each(|(id, expn_data)| {
let expn_data = expn_data.as_ref().expect("no expansion data for an expansion ID");
debug_expn_data((&id.to_expn_id(), expn_data))
});
// Sort the hash map for more reproducible output.
// Because of this, it is fine to rely on the unstable iteration order of the map.
#[allow(rustc::potential_query_instability)]
let mut foreign_expn_data: Vec<_> = data.foreign_expn_data.iter().collect();
foreign_expn_data.sort_by_key(|(id, _)| (id.krate, id.local_id));
foreign_expn_data.into_iter().for_each(debug_expn_data);
s.push_str("\n\nSyntaxContexts:");
data.syntax_context_data.iter().enumerate().for_each(|(id, ctxt)| {
s.push_str(&format!(
"\n#{}: parent: {:?}, outer_mark: ({:?}, {:?})",
id, ctxt.parent, ctxt.outer_expn, ctxt.outer_transparency,
));
});
s
}
})
}
impl SyntaxContext {
#[inline]
pub const fn root() -> Self {
SyntaxContext(0)
}
#[inline]
pub const fn is_root(self) -> bool {
self.0 == SyntaxContext::root().as_u32()
}
#[inline]
pub(crate) const fn as_u32(self) -> u32 {
self.0
}
#[inline]
pub(crate) const fn from_u32(raw: u32) -> SyntaxContext {
SyntaxContext(raw)
}
/// Extend a syntax context with a given expansion and transparency.
pub fn apply_mark(self, expn_id: ExpnId, transparency: Transparency) -> SyntaxContext {
HygieneData::with(|data| data.apply_mark(self, expn_id, transparency))
}
/// Pulls a single mark off of the syntax context. This effectively moves the
/// context up one macro definition level. That is, if we have a nested macro
/// definition as follows:
///
/// ```ignore (illustrative)
/// macro_rules! f {
/// macro_rules! g {
/// ...
/// }
/// }
/// ```
///
/// and we have a SyntaxContext that is referring to something declared by an invocation
/// of g (call it g1), calling remove_mark will result in the SyntaxContext for the
/// invocation of f that created g1.
/// Returns the mark that was removed.
pub fn remove_mark(&mut self) -> ExpnId {
HygieneData::with(|data| data.remove_mark(self).0)
}
pub fn marks(self) -> Vec<(ExpnId, Transparency)> {
HygieneData::with(|data| data.marks(self))
}
/// Adjust this context for resolution in a scope created by the given expansion.
/// For example, consider the following three resolutions of `f`:
///
/// ```rust
/// #![feature(decl_macro)]
/// mod foo { pub fn f() {} } // `f`'s `SyntaxContext` is empty.
/// m!(f);
/// macro m($f:ident) {
/// mod bar {
/// pub fn f() {} // `f`'s `SyntaxContext` has a single `ExpnId` from `m`.
/// pub fn $f() {} // `$f`'s `SyntaxContext` is empty.
/// }
/// foo::f(); // `f`'s `SyntaxContext` has a single `ExpnId` from `m`
/// //^ Since `mod foo` is outside this expansion, `adjust` removes the mark from `f`,
/// //| and it resolves to `::foo::f`.
/// bar::f(); // `f`'s `SyntaxContext` has a single `ExpnId` from `m`
/// //^ Since `mod bar` not outside this expansion, `adjust` does not change `f`,
/// //| and it resolves to `::bar::f`.
/// bar::$f(); // `f`'s `SyntaxContext` is empty.
/// //^ Since `mod bar` is not outside this expansion, `adjust` does not change `$f`,
/// //| and it resolves to `::bar::$f`.
/// }
/// ```
/// This returns the expansion whose definition scope we use to privacy check the resolution,
/// or `None` if we privacy check as usual (i.e., not w.r.t. a macro definition scope).
pub fn adjust(&mut self, expn_id: ExpnId) -> Option<ExpnId> {
HygieneData::with(|data| data.adjust(self, expn_id))
}
/// Like `SyntaxContext::adjust`, but also normalizes `self` to macros 2.0.
pub(crate) fn normalize_to_macros_2_0_and_adjust(&mut self, expn_id: ExpnId) -> Option<ExpnId> {
HygieneData::with(|data| {
*self = data.normalize_to_macros_2_0(*self);
data.adjust(self, expn_id)
})
}
/// Adjust this context for resolution in a scope created by the given expansion
/// via a glob import with the given `SyntaxContext`.
/// For example:
///
/// ```compile_fail,E0425
/// #![feature(decl_macro)]
/// m!(f);
/// macro m($i:ident) {
/// mod foo {
/// pub fn f() {} // `f`'s `SyntaxContext` has a single `ExpnId` from `m`.
/// pub fn $i() {} // `$i`'s `SyntaxContext` is empty.
/// }
/// n!(f);
/// macro n($j:ident) {
/// use foo::*;
/// f(); // `f`'s `SyntaxContext` has a mark from `m` and a mark from `n`
/// //^ `glob_adjust` removes the mark from `n`, so this resolves to `foo::f`.
/// $i(); // `$i`'s `SyntaxContext` has a mark from `n`
/// //^ `glob_adjust` removes the mark from `n`, so this resolves to `foo::$i`.
/// $j(); // `$j`'s `SyntaxContext` has a mark from `m`
/// //^ This cannot be glob-adjusted, so this is a resolution error.
/// }
/// }
/// ```
/// This returns `None` if the context cannot be glob-adjusted.
/// Otherwise, it returns the scope to use when privacy checking (see `adjust` for details).
pub(crate) fn glob_adjust(
&mut self,
expn_id: ExpnId,
glob_span: Span,
) -> Option<Option<ExpnId>> {
HygieneData::with(|data| {
let mut scope = None;
let mut glob_ctxt = data.normalize_to_macros_2_0(glob_span.ctxt());
while !data.is_descendant_of(expn_id, data.outer_expn(glob_ctxt)) {
scope = Some(data.remove_mark(&mut glob_ctxt).0);
if data.remove_mark(self).0 != scope.unwrap() {
return None;
}
}
if data.adjust(self, expn_id).is_some() {
return None;
}
Some(scope)
})
}
/// Undo `glob_adjust` if possible:
///
/// ```ignore (illustrative)
/// if let Some(privacy_checking_scope) = self.reverse_glob_adjust(expansion, glob_ctxt) {
/// assert!(self.glob_adjust(expansion, glob_ctxt) == Some(privacy_checking_scope));
/// }
/// ```
pub(crate) fn reverse_glob_adjust(
&mut self,
expn_id: ExpnId,
glob_span: Span,
) -> Option<Option<ExpnId>> {
HygieneData::with(|data| {
if data.adjust(self, expn_id).is_some() {
return None;
}
let mut glob_ctxt = data.normalize_to_macros_2_0(glob_span.ctxt());
let mut marks = Vec::new();
while !data.is_descendant_of(expn_id, data.outer_expn(glob_ctxt)) {
marks.push(data.remove_mark(&mut glob_ctxt));
}
let scope = marks.last().map(|mark| mark.0);
while let Some((expn_id, transparency)) = marks.pop() {
*self = data.apply_mark(*self, expn_id, transparency);
}
Some(scope)
})
}
pub fn hygienic_eq(self, other: SyntaxContext, expn_id: ExpnId) -> bool {
HygieneData::with(|data| {
let mut self_normalized = data.normalize_to_macros_2_0(self);
data.adjust(&mut self_normalized, expn_id);
self_normalized == data.normalize_to_macros_2_0(other)
})
}
#[inline]
pub fn normalize_to_macros_2_0(self) -> SyntaxContext {
HygieneData::with(|data| data.normalize_to_macros_2_0(self))
}
#[inline]
pub fn normalize_to_macro_rules(self) -> SyntaxContext {
HygieneData::with(|data| data.normalize_to_macro_rules(self))
}
#[inline]
pub fn outer_expn(self) -> ExpnId {
HygieneData::with(|data| data.outer_expn(self))
}
/// `ctxt.outer_expn_data()` is equivalent to but faster than
/// `ctxt.outer_expn().expn_data()`.
#[inline]
pub fn outer_expn_data(self) -> ExpnData {
HygieneData::with(|data| data.expn_data(data.outer_expn(self)).clone())
}
#[inline]
fn outer_mark(self) -> (ExpnId, Transparency) {
HygieneData::with(|data| data.outer_mark(self))
}
pub(crate) fn dollar_crate_name(self) -> Symbol {
HygieneData::with(|data| data.syntax_context_data[self.0 as usize].dollar_crate_name)
}
pub fn edition(self) -> Edition {
HygieneData::with(|data| data.expn_data(data.outer_expn(self)).edition)
}
}
impl fmt::Debug for SyntaxContext {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "#{}", self.0)
}
}
impl Span {
/// Reuses the span but adds information like the kind of the desugaring and features that are
/// allowed inside this span.
pub fn mark_with_reason(
self,
allow_internal_unstable: Option<Lrc<[Symbol]>>,
reason: DesugaringKind,
edition: Edition,
ctx: impl HashStableContext,
) -> Span {
let expn_data = ExpnData {
allow_internal_unstable,
..ExpnData::default(ExpnKind::Desugaring(reason), self, edition, None, None)
};
let expn_id = LocalExpnId::fresh(expn_data, ctx);
self.apply_mark(expn_id.to_expn_id(), Transparency::Transparent)
}
}
/// A subset of properties from both macro definition and macro call available through global data.
/// Avoid using this if you have access to the original definition or call structures.
#[derive(Clone, Debug, Encodable, Decodable, HashStable_Generic)]
pub struct ExpnData {
// --- The part unique to each expansion.
/// The kind of this expansion - macro or compiler desugaring.
pub kind: ExpnKind,
/// The expansion that produced this expansion.
pub parent: ExpnId,
/// The location of the actual macro invocation or syntax sugar , e.g.
/// `let x = foo!();` or `if let Some(y) = x {}`
///
/// This may recursively refer to other macro invocations, e.g., if
/// `foo!()` invoked `bar!()` internally, and there was an
/// expression inside `bar!`; the call_site of the expression in
/// the expansion would point to the `bar!` invocation; that
/// call_site span would have its own ExpnData, with the call_site
/// pointing to the `foo!` invocation.
pub call_site: Span,
/// Used to force two `ExpnData`s to have different `Fingerprint`s.
/// Due to macro expansion, it's possible to end up with two `ExpnId`s
/// that have identical `ExpnData`s. This violates the contract of `HashStable`
/// - the two `ExpnId`s are not equal, but their `Fingerprint`s are equal
/// (since the numerical `ExpnId` value is not considered by the `HashStable`
/// implementation).
///
/// The `disambiguator` field is set by `update_disambiguator` when two distinct
/// `ExpnId`s would end up with the same `Fingerprint`. Since `ExpnData` includes
/// a `krate` field, this value only needs to be unique within a single crate.
disambiguator: u32,
// --- The part specific to the macro/desugaring definition.
// --- It may be reasonable to share this part between expansions with the same definition,
// --- but such sharing is known to bring some minor inconveniences without also bringing
// --- noticeable perf improvements (PR #62898).
/// The span of the macro definition (possibly dummy).
/// This span serves only informational purpose and is not used for resolution.
pub def_site: Span,
/// List of `#[unstable]`/feature-gated features that the macro is allowed to use
/// internally without forcing the whole crate to opt-in
/// to them.
pub allow_internal_unstable: Option<Lrc<[Symbol]>>,
/// Edition of the crate in which the macro is defined.
pub edition: Edition,
/// The `DefId` of the macro being invoked,
/// if this `ExpnData` corresponds to a macro invocation
pub macro_def_id: Option<DefId>,
/// The normal module (`mod`) in which the expanded macro was defined.
pub parent_module: Option<DefId>,
/// Suppresses the `unsafe_code` lint for code produced by this macro.
pub(crate) allow_internal_unsafe: bool,
/// Enables the macro helper hack (`ident!(...)` -> `$crate::ident!(...)`) for this macro.
pub local_inner_macros: bool,
/// Should debuginfo for the macro be collapsed to the outermost expansion site (in other
/// words, was the macro definition annotated with `#[collapse_debuginfo]`)?
pub(crate) collapse_debuginfo: bool,
}
impl !PartialEq for ExpnData {}
impl !Hash for ExpnData {}
impl ExpnData {
pub fn new(
kind: ExpnKind,
parent: ExpnId,
call_site: Span,
def_site: Span,
allow_internal_unstable: Option<Lrc<[Symbol]>>,
edition: Edition,
macro_def_id: Option<DefId>,
parent_module: Option<DefId>,
allow_internal_unsafe: bool,
local_inner_macros: bool,
collapse_debuginfo: bool,
) -> ExpnData {
ExpnData {
kind,
parent,
call_site,
def_site,
allow_internal_unstable,
edition,
macro_def_id,
parent_module,
disambiguator: 0,
allow_internal_unsafe,
local_inner_macros,
collapse_debuginfo,
}
}
/// Constructs expansion data with default properties.
pub fn default(
kind: ExpnKind,
call_site: Span,
edition: Edition,
macro_def_id: Option<DefId>,
parent_module: Option<DefId>,
) -> ExpnData {
ExpnData {
kind,
parent: ExpnId::root(),
call_site,
def_site: DUMMY_SP,
allow_internal_unstable: None,
edition,
macro_def_id,
parent_module,
disambiguator: 0,
allow_internal_unsafe: false,
local_inner_macros: false,
collapse_debuginfo: false,
}
}
pub fn allow_unstable(
kind: ExpnKind,
call_site: Span,
edition: Edition,
allow_internal_unstable: Lrc<[Symbol]>,
macro_def_id: Option<DefId>,
parent_module: Option<DefId>,
) -> ExpnData {
ExpnData {
allow_internal_unstable: Some(allow_internal_unstable),
..ExpnData::default(kind, call_site, edition, macro_def_id, parent_module)
}
}
#[inline]
pub fn is_root(&self) -> bool {
matches!(self.kind, ExpnKind::Root)
}
#[inline]
fn hash_expn(&self, ctx: &mut impl HashStableContext) -> Hash64 {
let mut hasher = StableHasher::new();
self.hash_stable(ctx, &mut hasher);
hasher.finish()
}
}
/// Expansion kind.
#[derive(Clone, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)]
pub enum ExpnKind {
/// No expansion, aka root expansion. Only `ExpnId::root()` has this kind.
Root,
/// Expansion produced by a macro.
Macro(MacroKind, Symbol),
/// Transform done by the compiler on the AST.
AstPass(AstPass),
/// Desugaring done by the compiler during HIR lowering.
Desugaring(DesugaringKind),
}
impl ExpnKind {
pub fn descr(&self) -> String {
match *self {
ExpnKind::Root => kw::PathRoot.to_string(),
ExpnKind::Macro(macro_kind, name) => match macro_kind {
MacroKind::Bang => format!("{name}!"),
MacroKind::Attr => format!("#[{name}]"),
MacroKind::Derive => format!("#[derive({name})]"),
},
ExpnKind::AstPass(kind) => kind.descr().to_string(),
ExpnKind::Desugaring(kind) => format!("desugaring of {}", kind.descr()),
}
}
}
/// The kind of macro invocation or definition.
#[derive(Clone, Copy, PartialEq, Eq, Encodable, Decodable, Hash, Debug)]
#[derive(HashStable_Generic)]
pub enum MacroKind {
/// A bang macro `foo!()`.
Bang,
/// An attribute macro `#[foo]`.
Attr,
/// A derive macro `#[derive(Foo)]`
Derive,
}
impl MacroKind {
pub fn descr(self) -> &'static str {
match self {
MacroKind::Bang => "macro",
MacroKind::Attr => "attribute macro",
MacroKind::Derive => "derive macro",
}
}
pub fn descr_expected(self) -> &'static str {
match self {
MacroKind::Attr => "attribute",
_ => self.descr(),
}
}
pub fn article(self) -> &'static str {
match self {
MacroKind::Attr => "an",
_ => "a",
}
}
}
/// The kind of AST transform.
#[derive(Clone, Copy, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)]
pub enum AstPass {
StdImports,
TestHarness,
ProcMacroHarness,
}
impl AstPass {
pub fn descr(self) -> &'static str {
match self {
AstPass::StdImports => "standard library imports",
AstPass::TestHarness => "test harness",
AstPass::ProcMacroHarness => "proc macro harness",
}
}
}
/// The kind of compiler desugaring.
#[derive(Clone, Copy, PartialEq, Debug, Encodable, Decodable, HashStable_Generic)]
pub enum DesugaringKind {
/// We desugar `if c { i } else { e }` to `match $ExprKind::Use(c) { true => i, _ => e }`.
/// However, we do not want to blame `c` for unreachability but rather say that `i`
/// is unreachable. This desugaring kind allows us to avoid blaming `c`.
/// This also applies to `while` loops.
CondTemporary,
QuestionMark,
TryBlock,
YeetExpr,
/// Desugaring of an `impl Trait` in return type position
/// to an `type Foo = impl Trait;` and replacing the
/// `impl Trait` with `Foo`.
OpaqueTy,
Async,
Await,
ForLoop,
WhileLoop,
/// `async Fn()` bound modifier
BoundModifier,
}
impl DesugaringKind {
/// The description wording should combine well with "desugaring of {}".
pub fn descr(self) -> &'static str {
match self {
DesugaringKind::CondTemporary => "`if` or `while` condition",
DesugaringKind::Async => "`async` block or function",
DesugaringKind::Await => "`await` expression",
DesugaringKind::QuestionMark => "operator `?`",
DesugaringKind::TryBlock => "`try` block",
DesugaringKind::YeetExpr => "`do yeet` expression",
DesugaringKind::OpaqueTy => "`impl Trait`",
DesugaringKind::ForLoop => "`for` loop",
DesugaringKind::WhileLoop => "`while` loop",
DesugaringKind::BoundModifier => "trait bound modifier",
}
}
}
#[derive(Default)]
pub struct HygieneEncodeContext {
/// All `SyntaxContexts` for which we have written `SyntaxContextData` into crate metadata.
/// This is `None` after we finish encoding `SyntaxContexts`, to ensure
/// that we don't accidentally try to encode any more `SyntaxContexts`
serialized_ctxts: Lock<FxHashSet<SyntaxContext>>,
/// The `SyntaxContexts` that we have serialized (e.g. as a result of encoding `Spans`)
/// in the most recent 'round' of serializing. Serializing `SyntaxContextData`
/// may cause us to serialize more `SyntaxContext`s, so serialize in a loop
/// until we reach a fixed point.
latest_ctxts: Lock<FxHashSet<SyntaxContext>>,
serialized_expns: Lock<FxHashSet<ExpnId>>,
latest_expns: Lock<FxHashSet<ExpnId>>,
}
impl HygieneEncodeContext {
/// Record the fact that we need to serialize the corresponding `ExpnData`.
pub fn schedule_expn_data_for_encoding(&self, expn: ExpnId) {
if !self.serialized_expns.lock().contains(&expn) {
self.latest_expns.lock().insert(expn);
}
}
pub fn encode<T>(
&self,
encoder: &mut T,
mut encode_ctxt: impl FnMut(&mut T, u32, &SyntaxContextData),
mut encode_expn: impl FnMut(&mut T, ExpnId, &ExpnData, ExpnHash),
) {
// When we serialize a `SyntaxContextData`, we may end up serializing
// a `SyntaxContext` that we haven't seen before
while !self.latest_ctxts.lock().is_empty() || !self.latest_expns.lock().is_empty() {
debug!(
"encode_hygiene: Serializing a round of {:?} SyntaxContextData: {:?}",
self.latest_ctxts.lock().len(),
self.latest_ctxts
);
// Consume the current round of SyntaxContexts.
// Drop the lock() temporary early
let latest_ctxts = { std::mem::take(&mut *self.latest_ctxts.lock()) };
// It's fine to iterate over a HashMap, because the serialization
// of the table that we insert data into doesn't depend on insertion
// order
#[allow(rustc::potential_query_instability)]
for_all_ctxts_in(latest_ctxts.into_iter(), |index, ctxt, data| {
if self.serialized_ctxts.lock().insert(ctxt) {
encode_ctxt(encoder, index, data);
}
});
let latest_expns = { std::mem::take(&mut *self.latest_expns.lock()) };
// Same as above, this is fine as we are inserting into a order-independent hashset
#[allow(rustc::potential_query_instability)]
for_all_expns_in(latest_expns.into_iter(), |expn, data, hash| {
if self.serialized_expns.lock().insert(expn) {
encode_expn(encoder, expn, data, hash);
}
});
}
debug!("encode_hygiene: Done serializing SyntaxContextData");
}
}
#[derive(Default)]
/// Additional information used to assist in decoding hygiene data
struct HygieneDecodeContextInner {
// Maps serialized `SyntaxContext` ids to a `SyntaxContext` in the current
// global `HygieneData`. When we deserialize a `SyntaxContext`, we need to create
// a new id in the global `HygieneData`. This map tracks the ID we end up picking,
// so that multiple occurrences of the same serialized id are decoded to the same
// `SyntaxContext`. This only stores `SyntaxContext`s which are completly decoded.
remapped_ctxts: Vec<Option<SyntaxContext>>,
/// Maps serialized `SyntaxContext` ids that are currently being decoded to a `SyntaxContext`.
decoding: FxHashMap<u32, SyntaxContext>,
}
#[derive(Default)]
/// Additional information used to assist in decoding hygiene data
pub struct HygieneDecodeContext {
inner: Lock<HygieneDecodeContextInner>,
/// A set of serialized `SyntaxContext` ids that are currently being decoded on each thread.
local_in_progress: WorkerLocal<RefCell<FxHashMap<u32, ()>>>,
}
/// Register an expansion which has been decoded from the on-disk-cache for the local crate.
pub fn register_local_expn_id(data: ExpnData, hash: ExpnHash) -> ExpnId {
HygieneData::with(|hygiene_data| {
let expn_id = hygiene_data.local_expn_data.next_index();
hygiene_data.local_expn_data.push(Some(data));
let _eid = hygiene_data.local_expn_hashes.push(hash);
debug_assert_eq!(expn_id, _eid);
let expn_id = expn_id.to_expn_id();
let _old_id = hygiene_data.expn_hash_to_expn_id.insert(hash, expn_id);
debug_assert!(_old_id.is_none());
expn_id
})
}
/// Register an expansion which has been decoded from the metadata of a foreign crate.
pub fn register_expn_id(
krate: CrateNum,
local_id: ExpnIndex,
data: ExpnData,
hash: ExpnHash,
) -> ExpnId {
debug_assert!(data.parent == ExpnId::root() || krate == data.parent.krate);
let expn_id = ExpnId { krate, local_id };
HygieneData::with(|hygiene_data| {
let _old_data = hygiene_data.foreign_expn_data.insert(expn_id, data);
debug_assert!(_old_data.is_none() || cfg!(parallel_compiler));
let _old_hash = hygiene_data.foreign_expn_hashes.insert(expn_id, hash);
debug_assert!(_old_hash.is_none() || _old_hash == Some(hash));
let _old_id = hygiene_data.expn_hash_to_expn_id.insert(hash, expn_id);
debug_assert!(_old_id.is_none() || _old_id == Some(expn_id));
});
expn_id
}
/// Decode an expansion from the metadata of a foreign crate.
pub fn decode_expn_id(
krate: CrateNum,
index: u32,
decode_data: impl FnOnce(ExpnId) -> (ExpnData, ExpnHash),
) -> ExpnId {
if index == 0 {
trace!("decode_expn_id: deserialized root");
return ExpnId::root();
}
let index = ExpnIndex::from_u32(index);
// This function is used to decode metadata, so it cannot decode information about LOCAL_CRATE.
debug_assert_ne!(krate, LOCAL_CRATE);
let expn_id = ExpnId { krate, local_id: index };
// Fast path if the expansion has already been decoded.
if HygieneData::with(|hygiene_data| hygiene_data.foreign_expn_data.contains_key(&expn_id)) {
return expn_id;
}
// Don't decode the data inside `HygieneData::with`, since we need to recursively decode
// other ExpnIds
let (expn_data, hash) = decode_data(expn_id);
register_expn_id(krate, index, expn_data, hash)
}
// Decodes `SyntaxContext`, using the provided `HygieneDecodeContext`
// to track which `SyntaxContext`s we have already decoded.
// The provided closure will be invoked to deserialize a `SyntaxContextData`
// if we haven't already seen the id of the `SyntaxContext` we are deserializing.
pub fn decode_syntax_context<D: Decoder, F: FnOnce(&mut D, u32) -> SyntaxContextData>(
d: &mut D,
context: &HygieneDecodeContext,
decode_data: F,
) -> SyntaxContext {
let raw_id: u32 = Decodable::decode(d);
if raw_id == 0 {
trace!("decode_syntax_context: deserialized root");
// The root is special
return SyntaxContext::root();
}
let ctxt = {
let mut inner = context.inner.lock();
if let Some(ctxt) = inner.remapped_ctxts.get(raw_id as usize).copied().flatten() {
// This has already beeen decoded.
return ctxt;
}
match inner.decoding.entry(raw_id) {
Entry::Occupied(ctxt_entry) => {
match context.local_in_progress.borrow_mut().entry(raw_id) {
Entry::Occupied(..) => {
// We're decoding this already on the current thread. Return here
// and let the function higher up the stack finish decoding to handle
// recursive cases.
return *ctxt_entry.get();
}
Entry::Vacant(entry) => {
entry.insert(());
// Some other thread is current decoding this. Race with it.
*ctxt_entry.get()
}
}
}
Entry::Vacant(entry) => {
// We are the first thread to start decoding. Mark the current thread as being progress.
context.local_in_progress.borrow_mut().insert(raw_id, ());
// Allocate and store SyntaxContext id *before* calling the decoder function,
// as the SyntaxContextData may reference itself.
let new_ctxt = HygieneData::with(|hygiene_data| {
let new_ctxt = SyntaxContext(hygiene_data.syntax_context_data.len() as u32);
// Push a dummy SyntaxContextData to ensure that nobody else can get the
// same ID as us. This will be overwritten after call `decode_Data`
hygiene_data.syntax_context_data.push(SyntaxContextData {
outer_expn: ExpnId::root(),
outer_transparency: Transparency::Transparent,
parent: SyntaxContext::root(),
opaque: SyntaxContext::root(),
opaque_and_semitransparent: SyntaxContext::root(),
dollar_crate_name: kw::Empty,
});
new_ctxt
});
entry.insert(new_ctxt);
new_ctxt
}
}
};
// Don't try to decode data while holding the lock, since we need to
// be able to recursively decode a SyntaxContext
let mut ctxt_data = decode_data(d, raw_id);
// Reset `dollar_crate_name` so that it will be updated by `update_dollar_crate_names`
// We don't care what the encoding crate set this to - we want to resolve it
// from the perspective of the current compilation session
ctxt_data.dollar_crate_name = kw::DollarCrate;
// Overwrite the dummy data with our decoded SyntaxContextData
HygieneData::with(|hygiene_data| {
let dummy = std::mem::replace(
&mut hygiene_data.syntax_context_data[ctxt.as_u32() as usize],
ctxt_data,
);
if cfg!(not(parallel_compiler)) {
// Make sure nothing weird happened while `decode_data` was running.
// We used `kw::Empty` for the dummy value and we expect nothing to be
// modifying the dummy entry.
// This does not hold for the parallel compiler as another thread may
// have inserted the fully decoded data.
assert_eq!(dummy.dollar_crate_name, kw::Empty);
}
});
// Mark the context as completed
context.local_in_progress.borrow_mut().remove(&raw_id);
let mut inner = context.inner.lock();
let new_len = raw_id as usize + 1;
if inner.remapped_ctxts.len() < new_len {
inner.remapped_ctxts.resize(new_len, None);
}
inner.remapped_ctxts[raw_id as usize] = Some(ctxt);
inner.decoding.remove(&raw_id);
ctxt
}
fn for_all_ctxts_in<F: FnMut(u32, SyntaxContext, &SyntaxContextData)>(
ctxts: impl Iterator<Item = SyntaxContext>,
mut f: F,
) {
let all_data: Vec<_> = HygieneData::with(|data| {
ctxts.map(|ctxt| (ctxt, data.syntax_context_data[ctxt.0 as usize].clone())).collect()
});
for (ctxt, data) in all_data.into_iter() {
f(ctxt.0, ctxt, &data);
}
}
fn for_all_expns_in(
expns: impl Iterator<Item = ExpnId>,
mut f: impl FnMut(ExpnId, &ExpnData, ExpnHash),
) {
let all_data: Vec<_> = HygieneData::with(|data| {
expns.map(|expn| (expn, data.expn_data(expn).clone(), data.expn_hash(expn))).collect()
});
for (expn, data, hash) in all_data.into_iter() {
f(expn, &data, hash);
}
}
impl<E: SpanEncoder> Encodable<E> for LocalExpnId {
fn encode(&self, e: &mut E) {
self.to_expn_id().encode(e);
}
}
impl<D: SpanDecoder> Decodable<D> for LocalExpnId {
fn decode(d: &mut D) -> Self {
ExpnId::expect_local(ExpnId::decode(d))
}
}
pub fn raw_encode_syntax_context<E: Encoder>(
ctxt: SyntaxContext,
context: &HygieneEncodeContext,
e: &mut E,
) {
if !context.serialized_ctxts.lock().contains(&ctxt) {
context.latest_ctxts.lock().insert(ctxt);
}
ctxt.0.encode(e);
}
/// Updates the `disambiguator` field of the corresponding `ExpnData`
/// such that the `Fingerprint` of the `ExpnData` does not collide with
/// any other `ExpnIds`.
///
/// This method is called only when an `ExpnData` is first associated
/// with an `ExpnId` (when the `ExpnId` is initially constructed, or via
/// `set_expn_data`). It is *not* called for foreign `ExpnId`s deserialized
/// from another crate's metadata - since `ExpnHash` includes the stable crate id,
/// collisions are only possible between `ExpnId`s within the same crate.
fn update_disambiguator(expn_data: &mut ExpnData, mut ctx: impl HashStableContext) -> ExpnHash {
// This disambiguator should not have been set yet.
assert_eq!(expn_data.disambiguator, 0, "Already set disambiguator for ExpnData: {expn_data:?}");
assert_default_hashing_controls(&ctx, "ExpnData (disambiguator)");
let mut expn_hash = expn_data.hash_expn(&mut ctx);
let disambiguator = HygieneData::with(|data| {
// If this is the first ExpnData with a given hash, then keep our
// disambiguator at 0 (the default u32 value)
let disambig = data.expn_data_disambiguators.entry(expn_hash).or_default();
let disambiguator = *disambig;
*disambig += 1;
disambiguator
});
if disambiguator != 0 {
debug!("Set disambiguator for expn_data={:?} expn_hash={:?}", expn_data, expn_hash);
expn_data.disambiguator = disambiguator;
expn_hash = expn_data.hash_expn(&mut ctx);
// Verify that the new disambiguator makes the hash unique
#[cfg(debug_assertions)]
HygieneData::with(|data| {
assert_eq!(
data.expn_data_disambiguators.get(&expn_hash),
None,
"Hash collision after disambiguator update!",
);
});
}
ExpnHash::new(ctx.def_path_hash(LOCAL_CRATE.as_def_id()).stable_crate_id(), expn_hash)
}
impl<CTX: HashStableContext> HashStable<CTX> for SyntaxContext {
fn hash_stable(&self, ctx: &mut CTX, hasher: &mut StableHasher) {
const TAG_EXPANSION: u8 = 0;
const TAG_NO_EXPANSION: u8 = 1;
if self.is_root() {
TAG_NO_EXPANSION.hash_stable(ctx, hasher);
} else {
TAG_EXPANSION.hash_stable(ctx, hasher);
let (expn_id, transparency) = self.outer_mark();
expn_id.hash_stable(ctx, hasher);
transparency.hash_stable(ctx, hasher);
}
}
}
impl<CTX: HashStableContext> HashStable<CTX> for ExpnId {
fn hash_stable(&self, ctx: &mut CTX, hasher: &mut StableHasher) {
assert_default_hashing_controls(ctx, "ExpnId");
let hash = if *self == ExpnId::root() {
// Avoid fetching TLS storage for a trivial often-used value.
Fingerprint::ZERO
} else {
self.expn_hash().0
};
hash.hash_stable(ctx, hasher);
}
}