bjoernager/rust
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rust/compiler/rustc_metadata/src/rmeta/decoder.rs
Mara Bos 6c865c1e14 Allow builtin macros to be used more than once. 
This removes E0773 "A builtin-macro was defined more than once."
2025-03-19 14:12:47 +01:00

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// Decoding metadata from a single crate's metadata
use std::iter::TrustedLen;
use std::path::Path;
use std::sync::{Arc, OnceLock};
use std::{io, iter, mem};
pub(super) use cstore_impl::provide;
use proc_macro::bridge::client::ProcMacro;
use rustc_ast as ast;
use rustc_data_structures::fingerprint::Fingerprint;
use rustc_data_structures::fx::FxIndexMap;
use rustc_data_structures::owned_slice::OwnedSlice;
use rustc_data_structures::sync::Lock;
use rustc_data_structures::unhash::UnhashMap;
use rustc_expand::base::{SyntaxExtension, SyntaxExtensionKind};
use rustc_expand::proc_macro::{AttrProcMacro, BangProcMacro, DeriveProcMacro};
use rustc_hir::Safety;
use rustc_hir::def::Res;
use rustc_hir::def_id::{CRATE_DEF_INDEX, LOCAL_CRATE};
use rustc_hir::definitions::{DefPath, DefPathData};
use rustc_hir::diagnostic_items::DiagnosticItems;
use rustc_index::Idx;
use rustc_middle::middle::lib_features::LibFeatures;
use rustc_middle::mir::interpret::{AllocDecodingSession, AllocDecodingState};
use rustc_middle::ty::Visibility;
use rustc_middle::ty::codec::TyDecoder;
use rustc_middle::{bug, implement_ty_decoder};
use rustc_serialize::opaque::MemDecoder;
use rustc_serialize::{Decodable, Decoder};
use rustc_session::Session;
use rustc_session::config::TargetModifier;
use rustc_session::cstore::{CrateSource, ExternCrate};
use rustc_span::hygiene::HygieneDecodeContext;
use rustc_span::{BytePos, DUMMY_SP, Pos, SpanData, SpanDecoder, SyntaxContext, kw};
use tracing::debug;
use crate::creader::CStore;
use crate::rmeta::table::IsDefault;
use crate::rmeta::*;
mod cstore_impl;
/// A reference to the raw binary version of crate metadata.
/// This struct applies [`MemDecoder`]'s validation when constructed
/// so that later constructions are guaranteed to succeed.
pub(crate) struct MetadataBlob(OwnedSlice);
impl std::ops::Deref for MetadataBlob {
type Target = [u8];
#[inline]
fn deref(&self) -> &[u8] {
&self.0[..]
}
}
impl MetadataBlob {
/// Runs the [`MemDecoder`] validation and if it passes, constructs a new [`MetadataBlob`].
pub(crate) fn new(slice: OwnedSlice) -> Result<Self, ()> {
if MemDecoder::new(&slice, 0).is_ok() { Ok(Self(slice)) } else { Err(()) }
}
/// Since this has passed the validation of [`MetadataBlob::new`], this returns bytes which are
/// known to pass the [`MemDecoder`] validation.
pub(crate) fn bytes(&self) -> &OwnedSlice {
&self.0
}
}
/// A map from external crate numbers (as decoded from some crate file) to
/// local crate numbers (as generated during this session). Each external
/// crate may refer to types in other external crates, and each has their
/// own crate numbers.
pub(crate) type CrateNumMap = IndexVec<CrateNum, CrateNum>;
/// Target modifiers - abi or exploit mitigations flags
pub(crate) type TargetModifiers = Vec<TargetModifier>;
pub(crate) struct CrateMetadata {
/// The primary crate data - binary metadata blob.
blob: MetadataBlob,
// --- Some data pre-decoded from the metadata blob, usually for performance ---
/// Data about the top-level items in a crate, as well as various crate-level metadata.
root: CrateRoot,
/// Trait impl data.
/// FIXME: Used only from queries and can use query cache,
/// so pre-decoding can probably be avoided.
trait_impls: FxIndexMap<(u32, DefIndex), LazyArray<(DefIndex, Option<SimplifiedType>)>>,
/// Inherent impls which do not follow the normal coherence rules.
///
/// These can be introduced using either `#![rustc_coherence_is_core]`
/// or `#[rustc_allow_incoherent_impl]`.
incoherent_impls: FxIndexMap<SimplifiedType, LazyArray<DefIndex>>,
/// Proc macro descriptions for this crate, if it's a proc macro crate.
raw_proc_macros: Option<&'static [ProcMacro]>,
/// Source maps for code from the crate.
source_map_import_info: Lock<Vec<Option<ImportedSourceFile>>>,
/// For every definition in this crate, maps its `DefPathHash` to its `DefIndex`.
def_path_hash_map: DefPathHashMapRef<'static>,
/// Likewise for ExpnHash.
expn_hash_map: OnceLock<UnhashMap<ExpnHash, ExpnIndex>>,
/// Used for decoding interpret::AllocIds in a cached & thread-safe manner.
alloc_decoding_state: AllocDecodingState,
/// Caches decoded `DefKey`s.
def_key_cache: Lock<FxHashMap<DefIndex, DefKey>>,
// --- Other significant crate properties ---
/// ID of this crate, from the current compilation session's point of view.
cnum: CrateNum,
/// Maps crate IDs as they are were seen from this crate's compilation sessions into
/// IDs as they are seen from the current compilation session.
cnum_map: CrateNumMap,
/// Same ID set as `cnum_map` plus maybe some injected crates like panic runtime.
dependencies: Vec<CrateNum>,
/// How to link (or not link) this crate to the currently compiled crate.
dep_kind: CrateDepKind,
/// Filesystem location of this crate.
source: Arc<CrateSource>,
/// Whether or not this crate should be consider a private dependency.
/// Used by the 'exported_private_dependencies' lint, and for determining
/// whether to emit suggestions that reference this crate.
private_dep: bool,
/// The hash for the host proc macro. Used to support `-Z dual-proc-macro`.
host_hash: Option<Svh>,
/// The crate was used non-speculatively.
used: bool,
/// Additional data used for decoding `HygieneData` (e.g. `SyntaxContext`
/// and `ExpnId`).
/// Note that we store a `HygieneDecodeContext` for each `CrateMetadata`. This is
/// because `SyntaxContext` ids are not globally unique, so we need
/// to track which ids we've decoded on a per-crate basis.
hygiene_context: HygieneDecodeContext,
// --- Data used only for improving diagnostics ---
/// Information about the `extern crate` item or path that caused this crate to be loaded.
/// If this is `None`, then the crate was injected (e.g., by the allocator).
extern_crate: Option<ExternCrate>,
}
/// Holds information about a rustc_span::SourceFile imported from another crate.
/// See `imported_source_file()` for more information.
#[derive(Clone)]
struct ImportedSourceFile {
/// This SourceFile's byte-offset within the source_map of its original crate
original_start_pos: rustc_span::BytePos,
/// The end of this SourceFile within the source_map of its original crate
original_end_pos: rustc_span::BytePos,
/// The imported SourceFile's representation within the local source_map
translated_source_file: Arc<rustc_span::SourceFile>,
}
pub(super) struct DecodeContext<'a, 'tcx> {
opaque: MemDecoder<'a>,
cdata: Option<CrateMetadataRef<'a>>,
blob: &'a MetadataBlob,
sess: Option<&'tcx Session>,
tcx: Option<TyCtxt<'tcx>>,
lazy_state: LazyState,
// Used for decoding interpret::AllocIds in a cached & thread-safe manner.
alloc_decoding_session: Option<AllocDecodingSession<'a>>,
}
/// Abstract over the various ways one can create metadata decoders.
pub(super) trait Metadata<'a, 'tcx>: Copy {
fn blob(self) -> &'a MetadataBlob;
fn cdata(self) -> Option<CrateMetadataRef<'a>> {
None
}
fn sess(self) -> Option<&'tcx Session> {
None
}
fn tcx(self) -> Option<TyCtxt<'tcx>> {
None
}
fn decoder(self, pos: usize) -> DecodeContext<'a, 'tcx> {
let tcx = self.tcx();
DecodeContext {
// FIXME: This unwrap should never panic because we check that it won't when creating
// `MetadataBlob`. Ideally we'd just have a `MetadataDecoder` and hand out subslices of
// it as we do elsewhere in the compiler using `MetadataDecoder::split_at`. But we own
// the data for the decoder so holding onto the `MemDecoder` too would make us a
// self-referential struct which is downright goofy because `MetadataBlob` is already
// self-referential. Probably `MemDecoder` should contain an `OwnedSlice`, but that
// demands a significant refactoring due to our crate graph.
opaque: MemDecoder::new(self.blob(), pos).unwrap(),
cdata: self.cdata(),
blob: self.blob(),
sess: self.sess().or(tcx.map(|tcx| tcx.sess)),
tcx,
lazy_state: LazyState::NoNode,
alloc_decoding_session: self
.cdata()
.map(|cdata| cdata.cdata.alloc_decoding_state.new_decoding_session()),
}
}
}
impl<'a, 'tcx> Metadata<'a, 'tcx> for &'a MetadataBlob {
#[inline]
fn blob(self) -> &'a MetadataBlob {
self
}
}
impl<'a, 'tcx> Metadata<'a, 'tcx> for (&'a MetadataBlob, &'tcx Session) {
#[inline]
fn blob(self) -> &'a MetadataBlob {
self.0
}
#[inline]
fn sess(self) -> Option<&'tcx Session> {
let (_, sess) = self;
Some(sess)
}
}
impl<'a, 'tcx> Metadata<'a, 'tcx> for CrateMetadataRef<'a> {
#[inline]
fn blob(self) -> &'a MetadataBlob {
&self.cdata.blob
}
#[inline]
fn cdata(self) -> Option<CrateMetadataRef<'a>> {
Some(self)
}
}
impl<'a, 'tcx> Metadata<'a, 'tcx> for (CrateMetadataRef<'a>, &'tcx Session) {
#[inline]
fn blob(self) -> &'a MetadataBlob {
&self.0.cdata.blob
}
#[inline]
fn cdata(self) -> Option<CrateMetadataRef<'a>> {
Some(self.0)
}
#[inline]
fn sess(self) -> Option<&'tcx Session> {
Some(self.1)
}
}
impl<'a, 'tcx> Metadata<'a, 'tcx> for (CrateMetadataRef<'a>, TyCtxt<'tcx>) {
#[inline]
fn blob(self) -> &'a MetadataBlob {
&self.0.cdata.blob
}
#[inline]
fn cdata(self) -> Option<CrateMetadataRef<'a>> {
Some(self.0)
}
#[inline]
fn tcx(self) -> Option<TyCtxt<'tcx>> {
Some(self.1)
}
}
impl<T: ParameterizedOverTcx> LazyValue<T> {
#[inline]
fn decode<'a, 'tcx, M: Metadata<'a, 'tcx>>(self, metadata: M) -> T::Value<'tcx>
where
T::Value<'tcx>: Decodable<DecodeContext<'a, 'tcx>>,
{
let mut dcx = metadata.decoder(self.position.get());
dcx.lazy_state = LazyState::NodeStart(self.position);
T::Value::decode(&mut dcx)
}
}
struct DecodeIterator<'a, 'tcx, T> {
elem_counter: std::ops::Range<usize>,
dcx: DecodeContext<'a, 'tcx>,
_phantom: PhantomData<fn() -> T>,
}
impl<'a, 'tcx, T: Decodable<DecodeContext<'a, 'tcx>>> Iterator for DecodeIterator<'a, 'tcx, T> {
type Item = T;
#[inline(always)]
fn next(&mut self) -> Option<Self::Item> {
self.elem_counter.next().map(|_| T::decode(&mut self.dcx))
}
#[inline(always)]
fn size_hint(&self) -> (usize, Option<usize>) {
self.elem_counter.size_hint()
}
}
impl<'a, 'tcx, T: Decodable<DecodeContext<'a, 'tcx>>> ExactSizeIterator
for DecodeIterator<'a, 'tcx, T>
{
fn len(&self) -> usize {
self.elem_counter.len()
}
}
unsafe impl<'a, 'tcx, T: Decodable<DecodeContext<'a, 'tcx>>> TrustedLen
for DecodeIterator<'a, 'tcx, T>
{
}
impl<T: ParameterizedOverTcx> LazyArray<T> {
#[inline]
fn decode<'a, 'tcx, M: Metadata<'a, 'tcx>>(
self,
metadata: M,
) -> DecodeIterator<'a, 'tcx, T::Value<'tcx>>
where
T::Value<'tcx>: Decodable<DecodeContext<'a, 'tcx>>,
{
let mut dcx = metadata.decoder(self.position.get());
dcx.lazy_state = LazyState::NodeStart(self.position);
DecodeIterator { elem_counter: (0..self.num_elems), dcx, _phantom: PhantomData }
}
}
impl<'a, 'tcx> DecodeContext<'a, 'tcx> {
#[inline]
fn tcx(&self) -> TyCtxt<'tcx> {
let Some(tcx) = self.tcx else {
bug!(
"No TyCtxt found for decoding. \
You need to explicitly pass `(crate_metadata_ref, tcx)` to `decode` instead of just `crate_metadata_ref`."
);
};
tcx
}
#[inline]
pub(crate) fn blob(&self) -> &'a MetadataBlob {
self.blob
}
#[inline]
fn cdata(&self) -> CrateMetadataRef<'a> {
debug_assert!(self.cdata.is_some(), "missing CrateMetadata in DecodeContext");
self.cdata.unwrap()
}
#[inline]
fn map_encoded_cnum_to_current(&self, cnum: CrateNum) -> CrateNum {
self.cdata().map_encoded_cnum_to_current(cnum)
}
#[inline]
fn read_lazy_offset_then<T>(&mut self, f: impl Fn(NonZero<usize>) -> T) -> T {
let distance = self.read_usize();
let position = match self.lazy_state {
LazyState::NoNode => bug!("read_lazy_with_meta: outside of a metadata node"),
LazyState::NodeStart(start) => {
let start = start.get();
assert!(distance <= start);
start - distance
}
LazyState::Previous(last_pos) => last_pos.get() + distance,
};
let position = NonZero::new(position).unwrap();
self.lazy_state = LazyState::Previous(position);
f(position)
}
fn read_lazy<T>(&mut self) -> LazyValue<T> {
self.read_lazy_offset_then(|pos| LazyValue::from_position(pos))
}
fn read_lazy_array<T>(&mut self, len: usize) -> LazyArray<T> {
self.read_lazy_offset_then(|pos| LazyArray::from_position_and_num_elems(pos, len))
}
fn read_lazy_table<I, T>(&mut self, width: usize, len: usize) -> LazyTable<I, T> {
self.read_lazy_offset_then(|pos| LazyTable::from_position_and_encoded_size(pos, width, len))
}
#[inline]
fn read_raw_bytes(&mut self, len: usize) -> &[u8] {
self.opaque.read_raw_bytes(len)
}
}
impl<'a, 'tcx> TyDecoder<'tcx> for DecodeContext<'a, 'tcx> {
const CLEAR_CROSS_CRATE: bool = true;
#[inline]
fn interner(&self) -> TyCtxt<'tcx> {
self.tcx()
}
fn cached_ty_for_shorthand<F>(&mut self, shorthand: usize, or_insert_with: F) -> Ty<'tcx>
where
F: FnOnce(&mut Self) -> Ty<'tcx>,
{
let tcx = self.tcx();
let key = ty::CReaderCacheKey { cnum: Some(self.cdata().cnum), pos: shorthand };
if let Some(&ty) = tcx.ty_rcache.borrow().get(&key) {
return ty;
}
let ty = or_insert_with(self);
tcx.ty_rcache.borrow_mut().insert(key, ty);
ty
}
fn with_position<F, R>(&mut self, pos: usize, f: F) -> R
where
F: FnOnce(&mut Self) -> R,
{
let new_opaque = self.opaque.split_at(pos);
let old_opaque = mem::replace(&mut self.opaque, new_opaque);
let old_state = mem::replace(&mut self.lazy_state, LazyState::NoNode);
let r = f(self);
self.opaque = old_opaque;
self.lazy_state = old_state;
r
}
fn decode_alloc_id(&mut self) -> rustc_middle::mir::interpret::AllocId {
if let Some(alloc_decoding_session) = self.alloc_decoding_session {
alloc_decoding_session.decode_alloc_id(self)
} else {
bug!("Attempting to decode interpret::AllocId without CrateMetadata")
}
}
}
impl<'a, 'tcx> Decodable<DecodeContext<'a, 'tcx>> for ExpnIndex {
#[inline]
fn decode(d: &mut DecodeContext<'a, 'tcx>) -> ExpnIndex {
ExpnIndex::from_u32(d.read_u32())
}
}
impl<'a, 'tcx> SpanDecoder for DecodeContext<'a, 'tcx> {
fn decode_attr_id(&mut self) -> rustc_span::AttrId {
let sess = self.sess.expect("can't decode AttrId without Session");
sess.psess.attr_id_generator.mk_attr_id()
}
fn decode_crate_num(&mut self) -> CrateNum {
let cnum = CrateNum::from_u32(self.read_u32());
self.map_encoded_cnum_to_current(cnum)
}
fn decode_def_index(&mut self) -> DefIndex {
DefIndex::from_u32(self.read_u32())
}
fn decode_def_id(&mut self) -> DefId {
DefId { krate: Decodable::decode(self), index: Decodable::decode(self) }
}
fn decode_syntax_context(&mut self) -> SyntaxContext {
let cdata = self.cdata();
let Some(sess) = self.sess else {
bug!(
"Cannot decode SyntaxContext without Session.\
You need to explicitly pass `(crate_metadata_ref, tcx)` to `decode` instead of just `crate_metadata_ref`."
);
};
let cname = cdata.root.name();
rustc_span::hygiene::decode_syntax_context(self, &cdata.hygiene_context, |_, id| {
debug!("SpecializedDecoder<SyntaxContext>: decoding {}", id);
cdata
.root
.syntax_contexts
.get(cdata, id)
.unwrap_or_else(|| panic!("Missing SyntaxContext {id:?} for crate {cname:?}"))
.decode((cdata, sess))
})
}
fn decode_expn_id(&mut self) -> ExpnId {
let local_cdata = self.cdata();
let Some(sess) = self.sess else {
bug!(
"Cannot decode ExpnId without Session. \
You need to explicitly pass `(crate_metadata_ref, tcx)` to `decode` instead of just `crate_metadata_ref`."
);
};
let cnum = CrateNum::decode(self);
let index = u32::decode(self);
let expn_id = rustc_span::hygiene::decode_expn_id(cnum, index, |expn_id| {
let ExpnId { krate: cnum, local_id: index } = expn_id;
// Lookup local `ExpnData`s in our own crate data. Foreign `ExpnData`s
// are stored in the owning crate, to avoid duplication.
debug_assert_ne!(cnum, LOCAL_CRATE);
let crate_data = if cnum == local_cdata.cnum {
local_cdata
} else {
local_cdata.cstore.get_crate_data(cnum)
};
let expn_data = crate_data
.root
.expn_data
.get(crate_data, index)
.unwrap()
.decode((crate_data, sess));
let expn_hash = crate_data
.root
.expn_hashes
.get(crate_data, index)
.unwrap()
.decode((crate_data, sess));
(expn_data, expn_hash)
});
expn_id
}
fn decode_span(&mut self) -> Span {
let start = self.position();
let tag = SpanTag(self.peek_byte());
let data = if tag.kind() == SpanKind::Indirect {
// Skip past the tag we just peek'd.
self.read_u8();
// indirect tag lengths are safe to access, since they're (0, 8)
let bytes_needed = tag.length().unwrap().0 as usize;
let mut total = [0u8; usize::BITS as usize / 8];
total[..bytes_needed].copy_from_slice(self.read_raw_bytes(bytes_needed));
let offset_or_position = usize::from_le_bytes(total);
let position = if tag.is_relative_offset() {
start - offset_or_position
} else {
offset_or_position
};
self.with_position(position, SpanData::decode)
} else {
SpanData::decode(self)
};
data.span()
}
fn decode_symbol(&mut self) -> Symbol {
let tag = self.read_u8();
match tag {
SYMBOL_STR => {
let s = self.read_str();
Symbol::intern(s)
}
SYMBOL_OFFSET => {
// read str offset
let pos = self.read_usize();
// move to str offset and read
self.opaque.with_position(pos, |d| {
let s = d.read_str();
Symbol::intern(s)
})
}
SYMBOL_PREINTERNED => {
let symbol_index = self.read_u32();
Symbol::new_from_decoded(symbol_index)
}
_ => unreachable!(),
}
}
}
impl<'a, 'tcx> Decodable<DecodeContext<'a, 'tcx>> for SpanData {
fn decode(decoder: &mut DecodeContext<'a, 'tcx>) -> SpanData {
let tag = SpanTag::decode(decoder);
let ctxt = tag.context().unwrap_or_else(|| SyntaxContext::decode(decoder));
if tag.kind() == SpanKind::Partial {
return DUMMY_SP.with_ctxt(ctxt).data();
}
debug_assert!(tag.kind() == SpanKind::Local || tag.kind() == SpanKind::Foreign);
let lo = BytePos::decode(decoder);
let len = tag.length().unwrap_or_else(|| BytePos::decode(decoder));
let hi = lo + len;
let Some(sess) = decoder.sess else {
bug!(
"Cannot decode Span without Session. \
You need to explicitly pass `(crate_metadata_ref, tcx)` to `decode` instead of just `crate_metadata_ref`."
)
};
// Index of the file in the corresponding crate's list of encoded files.
let metadata_index = u32::decode(decoder);
// There are two possibilities here:
// 1. This is a 'local span', which is located inside a `SourceFile`
// that came from this crate. In this case, we use the source map data
// encoded in this crate. This branch should be taken nearly all of the time.
// 2. This is a 'foreign span', which is located inside a `SourceFile`
// that came from a *different* crate (some crate upstream of the one
// whose metadata we're looking at). For example, consider this dependency graph:
//
// A -> B -> C
//
// Suppose that we're currently compiling crate A, and start deserializing
// metadata from crate B. When we deserialize a Span from crate B's metadata,
// there are two possibilities:
//
// 1. The span references a file from crate B. This makes it a 'local' span,
// which means that we can use crate B's serialized source map information.
// 2. The span references a file from crate C. This makes it a 'foreign' span,
// which means we need to use Crate *C* (not crate B) to determine the source
// map information. We only record source map information for a file in the
// crate that 'owns' it, so deserializing a Span may require us to look at
// a transitive dependency.
//
// When we encode a foreign span, we adjust its 'lo' and 'high' values
// to be based on the *foreign* crate (e.g. crate C), not the crate
// we are writing metadata for (e.g. crate B). This allows us to
// treat the 'local' and 'foreign' cases almost identically during deserialization:
// we can call `imported_source_file` for the proper crate, and binary search
// through the returned slice using our span.
let source_file = if tag.kind() == SpanKind::Local {
decoder.cdata().imported_source_file(metadata_index, sess)
} else {
// When we encode a proc-macro crate, all `Span`s should be encoded
// with `TAG_VALID_SPAN_LOCAL`
if decoder.cdata().root.is_proc_macro_crate() {
// Decode `CrateNum` as u32 - using `CrateNum::decode` will ICE
// since we don't have `cnum_map` populated.
let cnum = u32::decode(decoder);
panic!(
"Decoding of crate {:?} tried to access proc-macro dep {:?}",
decoder.cdata().root.header.name,
cnum
);
}
// tag is TAG_VALID_SPAN_FOREIGN, checked by `debug_assert` above
let cnum = CrateNum::decode(decoder);
debug!(
"SpecializedDecoder<Span>::specialized_decode: loading source files from cnum {:?}",
cnum
);
let foreign_data = decoder.cdata().cstore.get_crate_data(cnum);
foreign_data.imported_source_file(metadata_index, sess)
};
// Make sure our span is well-formed.
debug_assert!(
lo + source_file.original_start_pos <= source_file.original_end_pos,
"Malformed encoded span: lo={:?} source_file.original_start_pos={:?} source_file.original_end_pos={:?}",
lo,
source_file.original_start_pos,
source_file.original_end_pos
);
// Make sure we correctly filtered out invalid spans during encoding.
debug_assert!(
hi + source_file.original_start_pos <= source_file.original_end_pos,
"Malformed encoded span: hi={:?} source_file.original_start_pos={:?} source_file.original_end_pos={:?}",
hi,
source_file.original_start_pos,
source_file.original_end_pos
);
let lo = lo + source_file.translated_source_file.start_pos;
let hi = hi + source_file.translated_source_file.start_pos;
// Do not try to decode parent for foreign spans (it wasn't encoded in the first place).
SpanData { lo, hi, ctxt, parent: None }
}
}
impl<'a, 'tcx> Decodable<DecodeContext<'a, 'tcx>> for &'tcx [(ty::Clause<'tcx>, Span)] {
fn decode(d: &mut DecodeContext<'a, 'tcx>) -> Self {
ty::codec::RefDecodable::decode(d)
}
}
impl<'a, 'tcx, T> Decodable<DecodeContext<'a, 'tcx>> for LazyValue<T> {
fn decode(decoder: &mut DecodeContext<'a, 'tcx>) -> Self {
decoder.read_lazy()
}
}
impl<'a, 'tcx, T> Decodable<DecodeContext<'a, 'tcx>> for LazyArray<T> {
#[inline]
fn decode(decoder: &mut DecodeContext<'a, 'tcx>) -> Self {
let len = decoder.read_usize();
if len == 0 { LazyArray::default() } else { decoder.read_lazy_array(len) }
}
}
impl<'a, 'tcx, I: Idx, T> Decodable<DecodeContext<'a, 'tcx>> for LazyTable<I, T> {
fn decode(decoder: &mut DecodeContext<'a, 'tcx>) -> Self {
let width = decoder.read_usize();
let len = decoder.read_usize();
decoder.read_lazy_table(width, len)
}
}
implement_ty_decoder!(DecodeContext<'a, 'tcx>);
impl MetadataBlob {
pub(crate) fn check_compatibility(
&self,
cfg_version: &'static str,
) -> Result<(), Option<String>> {
if !self.blob().starts_with(METADATA_HEADER) {
if self.blob().starts_with(b"rust") {
return Err(Some("<unknown rustc version>".to_owned()));
}
return Err(None);
}
let found_version =
LazyValue::<String>::from_position(NonZero::new(METADATA_HEADER.len() + 8).unwrap())
.decode(self);
if rustc_version(cfg_version) != found_version {
return Err(Some(found_version));
}
Ok(())
}
fn root_pos(&self) -> NonZero<usize> {
let offset = METADATA_HEADER.len();
let pos_bytes = self.blob()[offset..][..8].try_into().unwrap();
let pos = u64::from_le_bytes(pos_bytes);
NonZero::new(pos as usize).unwrap()
}
pub(crate) fn get_header(&self) -> CrateHeader {
let pos = self.root_pos();
LazyValue::<CrateHeader>::from_position(pos).decode(self)
}
pub(crate) fn get_root(&self) -> CrateRoot {
let pos = self.root_pos();
LazyValue::<CrateRoot>::from_position(pos).decode(self)
}
pub(crate) fn list_crate_metadata(
&self,
out: &mut dyn io::Write,
ls_kinds: &[String],
) -> io::Result<()> {
let root = self.get_root();
let all_ls_kinds = vec![
"root".to_owned(),
"lang_items".to_owned(),
"features".to_owned(),
"items".to_owned(),
];
let ls_kinds = if ls_kinds.contains(&"all".to_owned()) { &all_ls_kinds } else { ls_kinds };
for kind in ls_kinds {
match &**kind {
"root" => {
writeln!(out, "Crate info:")?;
writeln!(out, "name {}{}", root.name(), root.extra_filename)?;
writeln!(
out,
"hash {} stable_crate_id {:?}",
root.hash(),
root.stable_crate_id
)?;
writeln!(out, "proc_macro {:?}", root.proc_macro_data.is_some())?;
writeln!(out, "triple {}", root.header.triple.tuple())?;
writeln!(out, "edition {}", root.edition)?;
writeln!(out, "symbol_mangling_version {:?}", root.symbol_mangling_version)?;
writeln!(
out,
"required_panic_strategy {:?} panic_in_drop_strategy {:?}",
root.required_panic_strategy, root.panic_in_drop_strategy
)?;
writeln!(
out,
"has_global_allocator {} has_alloc_error_handler {} has_panic_handler {} has_default_lib_allocator {}",
root.has_global_allocator,
root.has_alloc_error_handler,
root.has_panic_handler,
root.has_default_lib_allocator
)?;
writeln!(
out,
"compiler_builtins {} needs_allocator {} needs_panic_runtime {} no_builtins {} panic_runtime {} profiler_runtime {}",
root.compiler_builtins,
root.needs_allocator,
root.needs_panic_runtime,
root.no_builtins,
root.panic_runtime,
root.profiler_runtime
)?;
writeln!(out, "=External Dependencies=")?;
let dylib_dependency_formats =
root.dylib_dependency_formats.decode(self).collect::<Vec<_>>();
for (i, dep) in root.crate_deps.decode(self).enumerate() {
let CrateDep { name, extra_filename, hash, host_hash, kind, is_private } =
dep;
let number = i + 1;
writeln!(
out,
"{number} {name}{extra_filename} hash {hash} host_hash {host_hash:?} kind {kind:?} {privacy}{linkage}",
privacy = if is_private { "private" } else { "public" },
linkage = if dylib_dependency_formats.is_empty() {
String::new()
} else {
format!(" linkage {:?}", dylib_dependency_formats[i])
}
)?;
}
write!(out, "\n")?;
}
"lang_items" => {
writeln!(out, "=Lang items=")?;
for (id, lang_item) in root.lang_items.decode(self) {
writeln!(
out,
"{} = crate{}",
lang_item.name(),
DefPath::make(LOCAL_CRATE, id, |parent| root
.tables
.def_keys
.get(self, parent)
.unwrap()
.decode(self))
.to_string_no_crate_verbose()
)?;
}
for lang_item in root.lang_items_missing.decode(self) {
writeln!(out, "{} = <missing>", lang_item.name())?;
}
write!(out, "\n")?;
}
"features" => {
writeln!(out, "=Lib features=")?;
for (feature, since) in root.lib_features.decode(self) {
writeln!(
out,
"{}{}",
feature,
if let FeatureStability::AcceptedSince(since) = since {
format!(" since {since}")
} else {
String::new()
}
)?;
}
write!(out, "\n")?;
}
"items" => {
writeln!(out, "=Items=")?;
fn print_item(
blob: &MetadataBlob,
out: &mut dyn io::Write,
item: DefIndex,
indent: usize,
) -> io::Result<()> {
let root = blob.get_root();
let def_kind = root.tables.def_kind.get(blob, item).unwrap();
let def_key = root.tables.def_keys.get(blob, item).unwrap().decode(blob);
#[allow(rustc::symbol_intern_string_literal)]
let def_name = if item == CRATE_DEF_INDEX {
kw::Crate
} else {
def_key
.disambiguated_data
.data
.get_opt_name()
.unwrap_or_else(|| Symbol::intern("???"))
};
let visibility =
root.tables.visibility.get(blob, item).unwrap().decode(blob).map_id(
|index| {
format!(
"crate{}",
DefPath::make(LOCAL_CRATE, index, |parent| root
.tables
.def_keys
.get(blob, parent)
.unwrap()
.decode(blob))
.to_string_no_crate_verbose()
)
},
);
write!(
out,
"{nil: <indent$}{:?} {:?} {} {{",
visibility,
def_kind,
def_name,
nil = "",
)?;
if let Some(children) =
root.tables.module_children_non_reexports.get(blob, item)
{
write!(out, "\n")?;
for child in children.decode(blob) {
print_item(blob, out, child, indent + 4)?;
}
writeln!(out, "{nil: <indent$}}}", nil = "")?;
} else {
writeln!(out, "}}")?;
}
Ok(())
}
print_item(self, out, CRATE_DEF_INDEX, 0)?;
write!(out, "\n")?;
}
_ => {
writeln!(
out,
"unknown -Zls kind. allowed values are: all, root, lang_items, features, items"
)?;
}
}
}
Ok(())
}
}
impl CrateRoot {
pub(crate) fn is_proc_macro_crate(&self) -> bool {
self.proc_macro_data.is_some()
}
pub(crate) fn name(&self) -> Symbol {
self.header.name
}
pub(crate) fn hash(&self) -> Svh {
self.header.hash
}
pub(crate) fn stable_crate_id(&self) -> StableCrateId {
self.stable_crate_id
}
pub(crate) fn decode_crate_deps<'a>(
&self,
metadata: &'a MetadataBlob,
) -> impl ExactSizeIterator<Item = CrateDep> {
self.crate_deps.decode(metadata)
}
pub(crate) fn decode_target_modifiers<'a>(
&self,
metadata: &'a MetadataBlob,
) -> impl ExactSizeIterator<Item = TargetModifier> {
self.target_modifiers.decode(metadata)
}
}
impl<'a> CrateMetadataRef<'a> {
fn missing(self, descr: &str, id: DefIndex) -> ! {
bug!("missing `{descr}` for {:?}", self.local_def_id(id))
}
fn raw_proc_macro(self, id: DefIndex) -> &'a ProcMacro {
// DefIndex's in root.proc_macro_data have a one-to-one correspondence
// with items in 'raw_proc_macros'.
let pos = self
.root
.proc_macro_data
.as_ref()
.unwrap()
.macros
.decode(self)
.position(|i| i == id)
.unwrap();
&self.raw_proc_macros.unwrap()[pos]
}
fn opt_item_name(self, item_index: DefIndex) -> Option<Symbol> {
let def_key = self.def_key(item_index);
def_key.disambiguated_data.data.get_opt_name().or_else(|| {
if def_key.disambiguated_data.data == DefPathData::Ctor {
let parent_index = def_key.parent.expect("no parent for a constructor");
self.def_key(parent_index).disambiguated_data.data.get_opt_name()
} else {
None
}
})
}
fn item_name(self, item_index: DefIndex) -> Symbol {
self.opt_item_name(item_index).expect("no encoded ident for item")
}
fn opt_item_ident(self, item_index: DefIndex, sess: &Session) -> Option<Ident> {
let name = self.opt_item_name(item_index)?;
let span = self
.root
.tables
.def_ident_span
.get(self, item_index)
.unwrap_or_else(|| self.missing("def_ident_span", item_index))
.decode((self, sess));
Some(Ident::new(name, span))
}
fn item_ident(self, item_index: DefIndex, sess: &Session) -> Ident {
self.opt_item_ident(item_index, sess).expect("no encoded ident for item")
}
#[inline]
pub(super) fn map_encoded_cnum_to_current(self, cnum: CrateNum) -> CrateNum {
if cnum == LOCAL_CRATE { self.cnum } else { self.cnum_map[cnum] }
}
fn def_kind(self, item_id: DefIndex) -> DefKind {
self.root
.tables
.def_kind
.get(self, item_id)
.unwrap_or_else(|| self.missing("def_kind", item_id))
}
fn get_span(self, index: DefIndex, sess: &Session) -> Span {
self.root
.tables
.def_span
.get(self, index)
.unwrap_or_else(|| self.missing("def_span", index))
.decode((self, sess))
}
fn load_proc_macro<'tcx>(self, id: DefIndex, tcx: TyCtxt<'tcx>) -> SyntaxExtension {
let (name, kind, helper_attrs) = match *self.raw_proc_macro(id) {
ProcMacro::CustomDerive { trait_name, attributes, client } => {
let helper_attrs =
attributes.iter().cloned().map(Symbol::intern).collect::<Vec<_>>();
(
trait_name,
SyntaxExtensionKind::Derive(Arc::new(DeriveProcMacro { client })),
helper_attrs,
)
}
ProcMacro::Attr { name, client } => {
(name, SyntaxExtensionKind::Attr(Arc::new(AttrProcMacro { client })), Vec::new())
}
ProcMacro::Bang { name, client } => {
(name, SyntaxExtensionKind::Bang(Arc::new(BangProcMacro { client })), Vec::new())
}
};
let sess = tcx.sess;
let attrs: Vec<_> = self.get_item_attrs(id, sess).collect();
SyntaxExtension::new(
sess,
kind,
self.get_span(id, sess),
helper_attrs,
self.root.edition,
Symbol::intern(name),
&attrs,
false,
)
}
fn get_variant(
self,
kind: DefKind,
index: DefIndex,
parent_did: DefId,
) -> (VariantIdx, ty::VariantDef) {
let adt_kind = match kind {
DefKind::Variant => ty::AdtKind::Enum,
DefKind::Struct => ty::AdtKind::Struct,
DefKind::Union => ty::AdtKind::Union,
_ => bug!(),
};
let data = self.root.tables.variant_data.get(self, index).unwrap().decode(self);
let variant_did =
if adt_kind == ty::AdtKind::Enum { Some(self.local_def_id(index)) } else { None };
let ctor = data.ctor.map(|(kind, index)| (kind, self.local_def_id(index)));
(
data.idx,
ty::VariantDef::new(
self.item_name(index),
variant_did,
ctor,
data.discr,
self.get_associated_item_or_field_def_ids(index)
.map(|did| ty::FieldDef {
did,
name: self.item_name(did.index),
vis: self.get_visibility(did.index),
safety: self.get_safety(did.index),
value: self.get_default_field(did.index),
})
.collect(),
parent_did,
None,
data.is_non_exhaustive,
),
)
}
fn get_adt_def<'tcx>(self, item_id: DefIndex, tcx: TyCtxt<'tcx>) -> ty::AdtDef<'tcx> {
let kind = self.def_kind(item_id);
let did = self.local_def_id(item_id);
let adt_kind = match kind {
DefKind::Enum => ty::AdtKind::Enum,
DefKind::Struct => ty::AdtKind::Struct,
DefKind::Union => ty::AdtKind::Union,
_ => bug!("get_adt_def called on a non-ADT {:?}", did),
};
let repr = self.root.tables.repr_options.get(self, item_id).unwrap().decode(self);
let mut variants: Vec<_> = if let ty::AdtKind::Enum = adt_kind {
self.root
.tables
.module_children_non_reexports
.get(self, item_id)
.expect("variants are not encoded for an enum")
.decode(self)
.filter_map(|index| {
let kind = self.def_kind(index);
match kind {
DefKind::Ctor(..) => None,
_ => Some(self.get_variant(kind, index, did)),
}
})
.collect()
} else {
std::iter::once(self.get_variant(kind, item_id, did)).collect()
};
variants.sort_by_key(|(idx, _)| *idx);
tcx.mk_adt_def(
did,
adt_kind,
variants.into_iter().map(|(_, variant)| variant).collect(),
repr,
)
}
fn get_visibility(self, id: DefIndex) -> Visibility<DefId> {
self.root
.tables
.visibility
.get(self, id)
.unwrap_or_else(|| self.missing("visibility", id))
.decode(self)
.map_id(|index| self.local_def_id(index))
}
fn get_safety(self, id: DefIndex) -> Safety {
self.root.tables.safety.get(self, id).unwrap_or_else(|| self.missing("safety", id))
}
fn get_default_field(self, id: DefIndex) -> Option<DefId> {
self.root.tables.default_fields.get(self, id).map(|d| d.decode(self))
}
fn get_trait_item_def_id(self, id: DefIndex) -> Option<DefId> {
self.root.tables.trait_item_def_id.get(self, id).map(|d| d.decode_from_cdata(self))
}
fn get_expn_that_defined(self, id: DefIndex, sess: &Session) -> ExpnId {
self.root
.tables
.expn_that_defined
.get(self, id)
.unwrap_or_else(|| self.missing("expn_that_defined", id))
.decode((self, sess))
}
fn get_debugger_visualizers(self) -> Vec<DebuggerVisualizerFile> {
self.root.debugger_visualizers.decode(self).collect::<Vec<_>>()
}
/// Iterates over all the stability attributes in the given crate.
fn get_lib_features(self) -> LibFeatures {
LibFeatures {
stability: self
.root
.lib_features
.decode(self)
.map(|(sym, stab)| (sym, (stab, DUMMY_SP)))
.collect(),
}
}
/// Iterates over the stability implications in the given crate (when a `#[unstable]` attribute
/// has an `implied_by` meta item, then the mapping from the implied feature to the actual
/// feature is a stability implication).
fn get_stability_implications<'tcx>(self, tcx: TyCtxt<'tcx>) -> &'tcx [(Symbol, Symbol)] {
tcx.arena.alloc_from_iter(self.root.stability_implications.decode(self))
}
/// Iterates over the lang items in the given crate.
fn get_lang_items<'tcx>(self, tcx: TyCtxt<'tcx>) -> &'tcx [(DefId, LangItem)] {
tcx.arena.alloc_from_iter(
self.root
.lang_items
.decode(self)
.map(move |(def_index, index)| (self.local_def_id(def_index), index)),
)
}
fn get_stripped_cfg_items<'tcx>(
self,
cnum: CrateNum,
tcx: TyCtxt<'tcx>,
) -> &'tcx [StrippedCfgItem] {
let item_names = self
.root
.stripped_cfg_items
.decode((self, tcx))
.map(|item| item.map_mod_id(|index| DefId { krate: cnum, index }));
tcx.arena.alloc_from_iter(item_names)
}
/// Iterates over the diagnostic items in the given crate.
fn get_diagnostic_items(self) -> DiagnosticItems {
let mut id_to_name = DefIdMap::default();
let name_to_id = self
.root
.diagnostic_items
.decode(self)
.map(|(name, def_index)| {
let id = self.local_def_id(def_index);
id_to_name.insert(id, name);
(name, id)
})
.collect();
DiagnosticItems { id_to_name, name_to_id }
}
fn get_mod_child(self, id: DefIndex, sess: &Session) -> ModChild {
let ident = self.item_ident(id, sess);
let res = Res::Def(self.def_kind(id), self.local_def_id(id));
let vis = self.get_visibility(id);
ModChild { ident, res, vis, reexport_chain: Default::default() }
}
/// Iterates over all named children of the given module,
/// including both proper items and reexports.
/// Module here is understood in name resolution sense - it can be a `mod` item,
/// or a crate root, or an enum, or a trait.
fn get_module_children(
self,
id: DefIndex,
sess: &'a Session,
) -> impl Iterator<Item = ModChild> {
iter::from_coroutine(
#[coroutine]
move || {
if let Some(data) = &self.root.proc_macro_data {
// If we are loading as a proc macro, we want to return
// the view of this crate as a proc macro crate.
if id == CRATE_DEF_INDEX {
for child_index in data.macros.decode(self) {
yield self.get_mod_child(child_index, sess);
}
}
} else {
// Iterate over all children.
let non_reexports =
self.root.tables.module_children_non_reexports.get(self, id);
for child_index in non_reexports.unwrap().decode(self) {
yield self.get_mod_child(child_index, sess);
}
let reexports = self.root.tables.module_children_reexports.get(self, id);
if !reexports.is_default() {
for reexport in reexports.decode((self, sess)) {
yield reexport;
}
}
}
},
)
}
fn is_ctfe_mir_available(self, id: DefIndex) -> bool {
self.root.tables.mir_for_ctfe.get(self, id).is_some()
}
fn is_item_mir_available(self, id: DefIndex) -> bool {
self.root.tables.optimized_mir.get(self, id).is_some()
}
fn get_fn_has_self_parameter(self, id: DefIndex, sess: &'a Session) -> bool {
self.root
.tables
.fn_arg_names
.get(self, id)
.expect("argument names not encoded for a function")
.decode((self, sess))
.nth(0)
.is_some_and(|ident| ident.name == kw::SelfLower)
}
fn get_associated_item_or_field_def_ids(self, id: DefIndex) -> impl Iterator<Item = DefId> {
self.root
.tables
.associated_item_or_field_def_ids
.get(self, id)
.unwrap_or_else(|| self.missing("associated_item_or_field_def_ids", id))
.decode(self)
.map(move |child_index| self.local_def_id(child_index))
}
fn get_associated_item(self, id: DefIndex, sess: &'a Session) -> ty::AssocItem {
let name = if self.root.tables.opt_rpitit_info.get(self, id).is_some() {
kw::Empty
} else {
self.item_name(id)
};
let (kind, has_self) = match self.def_kind(id) {
DefKind::AssocConst => (ty::AssocKind::Const, false),
DefKind::AssocFn => (ty::AssocKind::Fn, self.get_fn_has_self_parameter(id, sess)),
DefKind::AssocTy => (ty::AssocKind::Type, false),
_ => bug!("cannot get associated-item of `{:?}`", self.def_key(id)),
};
let container = self.root.tables.assoc_container.get(self, id).unwrap();
let opt_rpitit_info =
self.root.tables.opt_rpitit_info.get(self, id).map(|d| d.decode(self));
ty::AssocItem {
name,
kind,
def_id: self.local_def_id(id),
trait_item_def_id: self.get_trait_item_def_id(id),
container,
fn_has_self_parameter: has_self,
opt_rpitit_info,
}
}
fn get_ctor(self, node_id: DefIndex) -> Option<(CtorKind, DefId)> {
match self.def_kind(node_id) {
DefKind::Struct | DefKind::Variant => {
let vdata = self.root.tables.variant_data.get(self, node_id).unwrap().decode(self);
vdata.ctor.map(|(kind, index)| (kind, self.local_def_id(index)))
}
_ => None,
}
}
fn get_item_attrs(
self,
id: DefIndex,
sess: &'a Session,
) -> impl Iterator<Item = hir::Attribute> {
self.root
.tables
.attributes
.get(self, id)
.unwrap_or_else(|| {
// Structure and variant constructors don't have any attributes encoded for them,
// but we assume that someone passing a constructor ID actually wants to look at
// the attributes on the corresponding struct or variant.
let def_key = self.def_key(id);
assert_eq!(def_key.disambiguated_data.data, DefPathData::Ctor);
let parent_id = def_key.parent.expect("no parent for a constructor");
self.root
.tables
.attributes
.get(self, parent_id)
.expect("no encoded attributes for a structure or variant")
})
.decode((self, sess))
}
fn get_inherent_implementations_for_type<'tcx>(
self,
tcx: TyCtxt<'tcx>,
id: DefIndex,
) -> &'tcx [DefId] {
tcx.arena.alloc_from_iter(
self.root
.tables
.inherent_impls
.get(self, id)
.decode(self)
.map(|index| self.local_def_id(index)),
)
}
/// Decodes all traits in the crate (for rustdoc and rustc diagnostics).
fn get_traits(self) -> impl Iterator<Item = DefId> {
self.root.traits.decode(self).map(move |index| self.local_def_id(index))
}
/// Decodes all trait impls in the crate (for rustdoc).
fn get_trait_impls(self) -> impl Iterator<Item = DefId> {
self.cdata.trait_impls.values().flat_map(move |impls| {
impls.decode(self).map(move |(impl_index, _)| self.local_def_id(impl_index))
})
}
fn get_incoherent_impls<'tcx>(self, tcx: TyCtxt<'tcx>, simp: SimplifiedType) -> &'tcx [DefId] {
if let Some(impls) = self.cdata.incoherent_impls.get(&simp) {
tcx.arena.alloc_from_iter(impls.decode(self).map(|idx| self.local_def_id(idx)))
} else {
&[]
}
}
fn get_implementations_of_trait<'tcx>(
self,
tcx: TyCtxt<'tcx>,
trait_def_id: DefId,
) -> &'tcx [(DefId, Option<SimplifiedType>)] {
if self.trait_impls.is_empty() {
return &[];
}
// Do a reverse lookup beforehand to avoid touching the crate_num
// hash map in the loop below.
let key = match self.reverse_translate_def_id(trait_def_id) {
Some(def_id) => (def_id.krate.as_u32(), def_id.index),
None => return &[],
};
if let Some(impls) = self.trait_impls.get(&key) {
tcx.arena.alloc_from_iter(
impls
.decode(self)
.map(|(idx, simplified_self_ty)| (self.local_def_id(idx), simplified_self_ty)),
)
} else {
&[]
}
}
fn get_native_libraries(self, sess: &'a Session) -> impl Iterator<Item = NativeLib> {
self.root.native_libraries.decode((self, sess))
}
fn get_proc_macro_quoted_span(self, index: usize, sess: &Session) -> Span {
self.root
.tables
.proc_macro_quoted_spans
.get(self, index)
.unwrap_or_else(|| panic!("Missing proc macro quoted span: {index:?}"))
.decode((self, sess))
}
fn get_foreign_modules(self, sess: &'a Session) -> impl Iterator<Item = ForeignModule> {
self.root.foreign_modules.decode((self, sess))
}
fn get_dylib_dependency_formats<'tcx>(
self,
tcx: TyCtxt<'tcx>,
) -> &'tcx [(CrateNum, LinkagePreference)] {
tcx.arena.alloc_from_iter(
self.root.dylib_dependency_formats.decode(self).enumerate().flat_map(|(i, link)| {
let cnum = CrateNum::new(i + 1); // We skipped LOCAL_CRATE when encoding
link.map(|link| (self.cnum_map[cnum], link))
}),
)
}
fn get_missing_lang_items<'tcx>(self, tcx: TyCtxt<'tcx>) -> &'tcx [LangItem] {
tcx.arena.alloc_from_iter(self.root.lang_items_missing.decode(self))
}
fn exported_symbols<'tcx>(
self,
tcx: TyCtxt<'tcx>,
) -> &'tcx [(ExportedSymbol<'tcx>, SymbolExportInfo)] {
tcx.arena.alloc_from_iter(self.root.exported_symbols.decode((self, tcx)))
}
fn get_macro(self, id: DefIndex, sess: &Session) -> ast::MacroDef {
match self.def_kind(id) {
DefKind::Macro(_) => {
let macro_rules = self.root.tables.is_macro_rules.get(self, id);
let body =
self.root.tables.macro_definition.get(self, id).unwrap().decode((self, sess));
ast::MacroDef { macro_rules, body: ast::ptr::P(body) }
}
_ => bug!(),
}
}
#[inline]
fn def_key(self, index: DefIndex) -> DefKey {
*self
.def_key_cache
.lock()
.entry(index)
.or_insert_with(|| self.root.tables.def_keys.get(self, index).unwrap().decode(self))
}
// Returns the path leading to the thing with this `id`.
fn def_path(self, id: DefIndex) -> DefPath {
debug!("def_path(cnum={:?}, id={:?})", self.cnum, id);
DefPath::make(self.cnum, id, |parent| self.def_key(parent))
}
#[inline]
fn def_path_hash(self, index: DefIndex) -> DefPathHash {
// This is a hack to workaround the fact that we can't easily encode/decode a Hash64
// into the FixedSizeEncoding, as Hash64 lacks a Default impl. A future refactor to
// relax the Default restriction will likely fix this.
let fingerprint = Fingerprint::new(
self.root.stable_crate_id.as_u64(),
self.root.tables.def_path_hashes.get(self, index),
);
DefPathHash::new(self.root.stable_crate_id, fingerprint.split().1)
}
#[inline]
fn def_path_hash_to_def_index(self, hash: DefPathHash) -> DefIndex {
self.def_path_hash_map.def_path_hash_to_def_index(&hash)
}
fn expn_hash_to_expn_id(self, sess: &Session, index_guess: u32, hash: ExpnHash) -> ExpnId {
debug_assert_eq!(ExpnId::from_hash(hash), None);
let index_guess = ExpnIndex::from_u32(index_guess);
let old_hash = self.root.expn_hashes.get(self, index_guess).map(|lazy| lazy.decode(self));
let index = if old_hash == Some(hash) {
// Fast path: the expn and its index is unchanged from the
// previous compilation session. There is no need to decode anything
// else.
index_guess
} else {
// Slow path: We need to find out the new `DefIndex` of the provided
// `DefPathHash`, if its still exists. This requires decoding every `DefPathHash`
// stored in this crate.
let map = self.cdata.expn_hash_map.get_or_init(|| {
let end_id = self.root.expn_hashes.size() as u32;
let mut map =
UnhashMap::with_capacity_and_hasher(end_id as usize, Default::default());
for i in 0..end_id {
let i = ExpnIndex::from_u32(i);
if let Some(hash) = self.root.expn_hashes.get(self, i) {
map.insert(hash.decode(self), i);
}
}
map
});
map[&hash]
};
let data = self.root.expn_data.get(self, index).unwrap().decode((self, sess));
rustc_span::hygiene::register_expn_id(self.cnum, index, data, hash)
}
/// Imports the source_map from an external crate into the source_map of the crate
/// currently being compiled (the "local crate").
///
/// The import algorithm works analogous to how AST items are inlined from an
/// external crate's metadata:
/// For every SourceFile in the external source_map an 'inline' copy is created in the
/// local source_map. The correspondence relation between external and local
/// SourceFiles is recorded in the `ImportedSourceFile` objects returned from this
/// function. When an item from an external crate is later inlined into this
/// crate, this correspondence information is used to translate the span
/// information of the inlined item so that it refers the correct positions in
/// the local source_map (see `<decoder::DecodeContext as SpecializedDecoder<Span>>`).
///
/// The import algorithm in the function below will reuse SourceFiles already
/// existing in the local source_map. For example, even if the SourceFile of some
/// source file of libstd gets imported many times, there will only ever be
/// one SourceFile object for the corresponding file in the local source_map.
///
/// Note that imported SourceFiles do not actually contain the source code of the
/// file they represent, just information about length, line breaks, and
/// multibyte characters. This information is enough to generate valid debuginfo
/// for items inlined from other crates.
///
/// Proc macro crates don't currently export spans, so this function does not have
/// to work for them.
fn imported_source_file(self, source_file_index: u32, sess: &Session) -> ImportedSourceFile {
fn filter<'a>(sess: &Session, path: Option<&'a Path>) -> Option<&'a Path> {
path.filter(|_| {
// Only spend time on further checks if we have what to translate *to*.
sess.opts.real_rust_source_base_dir.is_some()
// Some tests need the translation to be always skipped.
&& sess.opts.unstable_opts.translate_remapped_path_to_local_path
})
.filter(|virtual_dir| {
// Don't translate away `/rustc/$hash` if we're still remapping to it,
// since that means we're still building `std`/`rustc` that need it,
// and we don't want the real path to leak into codegen/debuginfo.
!sess.opts.remap_path_prefix.iter().any(|(_from, to)| to == virtual_dir)
})
}
let try_to_translate_virtual_to_real = |name: &mut rustc_span::FileName| {
// Translate the virtual `/rustc/$hash` prefix back to a real directory
// that should hold actual sources, where possible.
//
// NOTE: if you update this, you might need to also update bootstrap's code for generating
// the `rust-src` component in `Src::run` in `src/bootstrap/dist.rs`.
let virtual_rust_source_base_dir = [
filter(sess, option_env!("CFG_VIRTUAL_RUST_SOURCE_BASE_DIR").map(Path::new)),
filter(sess, sess.opts.unstable_opts.simulate_remapped_rust_src_base.as_deref()),
];
debug!(
"try_to_translate_virtual_to_real(name={:?}): \
virtual_rust_source_base_dir={:?}, real_rust_source_base_dir={:?}",
name, virtual_rust_source_base_dir, sess.opts.real_rust_source_base_dir,
);
for virtual_dir in virtual_rust_source_base_dir.iter().flatten() {
if let Some(real_dir) = &sess.opts.real_rust_source_base_dir
&& let rustc_span::FileName::Real(old_name) = name
&& let rustc_span::RealFileName::Remapped { local_path: _, virtual_name } =
old_name
&& let Ok(rest) = virtual_name.strip_prefix(virtual_dir)
{
// The std library crates are in
// `$sysroot/lib/rustlib/src/rust/library`, whereas other crates
// may be in `$sysroot/lib/rustlib/src/rust/` directly. So we
// detect crates from the std libs and handle them specially.
const STD_LIBS: &[&str] = &[
"core",
"alloc",
"std",
"test",
"term",
"unwind",
"proc_macro",
"panic_abort",
"panic_unwind",
"profiler_builtins",
"rtstartup",
"rustc-std-workspace-core",
"rustc-std-workspace-alloc",
"rustc-std-workspace-std",
"backtrace",
];
let is_std_lib = STD_LIBS.iter().any(|l| rest.starts_with(l));
let new_path = if is_std_lib {
real_dir.join("library").join(rest)
} else {
real_dir.join(rest)
};
debug!(
"try_to_translate_virtual_to_real: `{}` -> `{}`",
virtual_name.display(),
new_path.display(),
);
// Check if the translated real path is affected by any user-requested
// remaps via --remap-path-prefix. Apply them if so.
// Note that this is a special case for imported rust-src paths specified by
// https://rust-lang.github.io/rfcs/3127-trim-paths.html#handling-sysroot-paths.
// Other imported paths are not currently remapped (see #66251).
let (user_remapped, applied) =
sess.source_map().path_mapping().map_prefix(&new_path);
let new_name = if applied {
rustc_span::RealFileName::Remapped {
local_path: Some(new_path.clone()),
virtual_name: user_remapped.to_path_buf(),
}
} else {
rustc_span::RealFileName::LocalPath(new_path)
};
*old_name = new_name;
}
}
};
let mut import_info = self.cdata.source_map_import_info.lock();
for _ in import_info.len()..=(source_file_index as usize) {
import_info.push(None);
}
import_info[source_file_index as usize]
.get_or_insert_with(|| {
let source_file_to_import = self
.root
.source_map
.get(self, source_file_index)
.expect("missing source file")
.decode(self);
// We can't reuse an existing SourceFile, so allocate a new one
// containing the information we need.
let original_end_pos = source_file_to_import.end_position();
let rustc_span::SourceFile {
mut name,
src_hash,
checksum_hash,
start_pos: original_start_pos,
source_len,
lines,
multibyte_chars,
normalized_pos,
stable_id,
..
} = source_file_to_import;
// If this file is under $sysroot/lib/rustlib/src/
// and the user wish to simulate remapping with -Z simulate-remapped-rust-src-base,
// then we change `name` to a similar state as if the rust was bootstrapped
// with `remap-debuginfo = true`.
// This is useful for testing so that tests about the effects of
// `try_to_translate_virtual_to_real` don't have to worry about how the
// compiler is bootstrapped.
if let Some(virtual_dir) = &sess.opts.unstable_opts.simulate_remapped_rust_src_base
&& let Some(real_dir) = &sess.opts.real_rust_source_base_dir
&& let rustc_span::FileName::Real(ref mut old_name) = name
{
let relative_path = match old_name {
rustc_span::RealFileName::LocalPath(local) => {
local.strip_prefix(real_dir).ok()
}
rustc_span::RealFileName::Remapped { virtual_name, .. } => {
option_env!("CFG_VIRTUAL_RUST_SOURCE_BASE_DIR")
.and_then(|virtual_dir| virtual_name.strip_prefix(virtual_dir).ok())
}
};
debug!(?relative_path, ?virtual_dir, "simulate_remapped_rust_src_base");
for subdir in ["library", "compiler"] {
if let Some(rest) = relative_path.and_then(|p| p.strip_prefix(subdir).ok())
{
*old_name = rustc_span::RealFileName::Remapped {
local_path: None, // FIXME: maybe we should preserve this?
virtual_name: virtual_dir.join(subdir).join(rest),
};
break;
}
}
}
// If this file's path has been remapped to `/rustc/$hash`,
// we might be able to reverse that (also see comments above,
// on `try_to_translate_virtual_to_real`).
try_to_translate_virtual_to_real(&mut name);
let local_version = sess.source_map().new_imported_source_file(
name,
src_hash,
checksum_hash,
stable_id,
source_len.to_u32(),
self.cnum,
lines,
multibyte_chars,
normalized_pos,
source_file_index,
);
debug!(
"CrateMetaData::imported_source_files alloc \
source_file {:?} original (start_pos {:?} source_len {:?}) \
translated (start_pos {:?} source_len {:?})",
local_version.name,
original_start_pos,
source_len,
local_version.start_pos,
local_version.source_len
);
ImportedSourceFile {
original_start_pos,
original_end_pos,
translated_source_file: local_version,
}
})
.clone()
}
fn get_attr_flags(self, index: DefIndex) -> AttrFlags {
self.root.tables.attr_flags.get(self, index)
}
fn get_intrinsic(self, index: DefIndex) -> Option<ty::IntrinsicDef> {
self.root.tables.intrinsic.get(self, index).map(|d| d.decode(self))
}
fn get_doc_link_resolutions(self, index: DefIndex) -> DocLinkResMap {
self.root
.tables
.doc_link_resolutions
.get(self, index)
.expect("no resolutions for a doc link")
.decode(self)
}
fn get_doc_link_traits_in_scope(self, index: DefIndex) -> impl Iterator<Item = DefId> {
self.root
.tables
.doc_link_traits_in_scope
.get(self, index)
.expect("no traits in scope for a doc link")
.decode(self)
}
}
impl CrateMetadata {
pub(crate) fn new(
sess: &Session,
cstore: &CStore,
blob: MetadataBlob,
root: CrateRoot,
raw_proc_macros: Option<&'static [ProcMacro]>,
cnum: CrateNum,
cnum_map: CrateNumMap,
dep_kind: CrateDepKind,
source: CrateSource,
private_dep: bool,
host_hash: Option<Svh>,
) -> CrateMetadata {
let trait_impls = root
.impls
.decode((&blob, sess))
.map(|trait_impls| (trait_impls.trait_id, trait_impls.impls))
.collect();
let alloc_decoding_state =
AllocDecodingState::new(root.interpret_alloc_index.decode(&blob).collect());
let dependencies = cnum_map.iter().copied().collect();
// Pre-decode the DefPathHash->DefIndex table. This is a cheap operation
// that does not copy any data. It just does some data verification.
let def_path_hash_map = root.def_path_hash_map.decode(&blob);
let mut cdata = CrateMetadata {
blob,
root,
trait_impls,
incoherent_impls: Default::default(),
raw_proc_macros,
source_map_import_info: Lock::new(Vec::new()),
def_path_hash_map,
expn_hash_map: Default::default(),
alloc_decoding_state,
cnum,
cnum_map,
dependencies,
dep_kind,
source: Arc::new(source),
private_dep,
host_hash,
used: false,
extern_crate: None,
hygiene_context: Default::default(),
def_key_cache: Default::default(),
};
// Need `CrateMetadataRef` to decode `DefId`s in simplified types.
cdata.incoherent_impls = cdata
.root
.incoherent_impls
.decode(CrateMetadataRef { cdata: &cdata, cstore })
.map(|incoherent_impls| (incoherent_impls.self_ty, incoherent_impls.impls))
.collect();
cdata
}
pub(crate) fn dependencies(&self) -> impl Iterator<Item = CrateNum> {
self.dependencies.iter().copied()
}
pub(crate) fn add_dependency(&mut self, cnum: CrateNum) {
self.dependencies.push(cnum);
}
pub(crate) fn target_modifiers(&self) -> TargetModifiers {
self.root.decode_target_modifiers(&self.blob).collect()
}
pub(crate) fn update_extern_crate(&mut self, new_extern_crate: ExternCrate) -> bool {
let update =
Some(new_extern_crate.rank()) > self.extern_crate.as_ref().map(ExternCrate::rank);
if update {
self.extern_crate = Some(new_extern_crate);
}
update
}
pub(crate) fn source(&self) -> &CrateSource {
&*self.source
}
pub(crate) fn dep_kind(&self) -> CrateDepKind {
self.dep_kind
}
pub(crate) fn set_dep_kind(&mut self, dep_kind: CrateDepKind) {
self.dep_kind = dep_kind;
}
pub(crate) fn update_and_private_dep(&mut self, private_dep: bool) {
self.private_dep &= private_dep;
}
pub(crate) fn used(&self) -> bool {
self.used
}
pub(crate) fn required_panic_strategy(&self) -> Option<PanicStrategy> {
self.root.required_panic_strategy
}
pub(crate) fn needs_panic_runtime(&self) -> bool {
self.root.needs_panic_runtime
}
pub(crate) fn is_private_dep(&self) -> bool {
self.private_dep
}
pub(crate) fn is_panic_runtime(&self) -> bool {
self.root.panic_runtime
}
pub(crate) fn is_profiler_runtime(&self) -> bool {
self.root.profiler_runtime
}
pub(crate) fn is_compiler_builtins(&self) -> bool {
self.root.compiler_builtins
}
pub(crate) fn needs_allocator(&self) -> bool {
self.root.needs_allocator
}
pub(crate) fn has_global_allocator(&self) -> bool {
self.root.has_global_allocator
}
pub(crate) fn has_alloc_error_handler(&self) -> bool {
self.root.has_alloc_error_handler
}
pub(crate) fn has_default_lib_allocator(&self) -> bool {
self.root.has_default_lib_allocator
}
pub(crate) fn is_proc_macro_crate(&self) -> bool {
self.root.is_proc_macro_crate()
}
pub(crate) fn name(&self) -> Symbol {
self.root.header.name
}
pub(crate) fn hash(&self) -> Svh {
self.root.header.hash
}
fn num_def_ids(&self) -> usize {
self.root.tables.def_keys.size()
}
fn local_def_id(&self, index: DefIndex) -> DefId {
DefId { krate: self.cnum, index }
}
// Translate a DefId from the current compilation environment to a DefId
// for an external crate.
fn reverse_translate_def_id(&self, did: DefId) -> Option<DefId> {
for (local, &global) in self.cnum_map.iter_enumerated() {
if global == did.krate {
return Some(DefId { krate: local, index: did.index });
}
}
None
}
}
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