1 //! Validates all used crates and extern libraries and loads their metadata
3 use crate::cstore::{self, CStore, CrateSource, MetadataBlob};
4 use crate::locator::{self, CratePaths};
5 use crate::decoder::proc_macro_def_path_table;
6 use crate::schema::CrateRoot;
7 use rustc_data_structures::sync::{Lrc, RwLock, Lock};
9 use rustc::hir::def_id::CrateNum;
10 use rustc_data_structures::svh::Svh;
11 use rustc::middle::allocator::AllocatorKind;
12 use rustc::middle::cstore::DepKind;
13 use rustc::mir::interpret::AllocDecodingState;
14 use rustc::session::{Session, CrateDisambiguator};
15 use rustc::session::config::{Sanitizer, self};
16 use rustc_target::spec::{PanicStrategy, TargetTriple};
17 use rustc::session::search_paths::PathKind;
18 use rustc::middle::cstore::{ExternCrate, ExternCrateSource};
19 use rustc::util::common::record_time;
20 use rustc::util::nodemap::FxHashSet;
21 use rustc::hir::map::Definitions;
24 use std::path::PathBuf;
29 use syntax::ext::base::SyntaxExtension;
30 use syntax::symbol::Symbol;
32 use syntax::{span_err, span_fatal};
33 use syntax_pos::{Span, DUMMY_SP};
34 use log::{debug, info, log_enabled};
37 pub dylib: Option<(PathBuf, PathKind)>,
38 pub rlib: Option<(PathBuf, PathKind)>,
39 pub rmeta: Option<(PathBuf, PathKind)>,
40 pub metadata: MetadataBlob,
43 pub struct CrateLoader<'a> {
44 pub sess: &'a Session,
46 local_crate_name: Symbol,
49 fn dump_crates(cstore: &CStore) {
50 info!("resolved crates:");
51 cstore.iter_crate_data(|_, data| {
52 info!(" name: {}", data.root.name);
53 info!(" cnum: {}", data.cnum);
54 info!(" hash: {}", data.root.hash);
55 info!(" reqd: {:?}", *data.dep_kind.lock());
56 let CrateSource { dylib, rlib, rmeta } = data.source.clone();
57 dylib.map(|dl| info!(" dylib: {}", dl.0.display()));
58 rlib.map(|rl| info!(" rlib: {}", rl.0.display()));
59 rmeta.map(|rl| info!(" rmeta: {}", rl.0.display()));
63 // Extra info about a crate loaded for plugins or exported macros.
64 struct ExtensionCrate {
66 dylib: Option<PathBuf>,
71 Registered(Lrc<cstore::CrateMetadata>),
75 impl Deref for PMDSource {
76 type Target = MetadataBlob;
78 fn deref(&self) -> &MetadataBlob {
80 PMDSource::Registered(ref cmd) => &cmd.blob,
81 PMDSource::Owned(ref lib) => &lib.metadata
92 LocatorError(locator::Context<'a>),
95 impl<'a> LoadError<'a> {
96 fn report(self) -> ! {
98 LoadError::LocatorError(mut locate_ctxt) => locate_ctxt.report_errs(),
103 impl<'a> CrateLoader<'a> {
104 pub fn new(sess: &'a Session, cstore: &'a CStore, local_crate_name: &str) -> Self {
108 local_crate_name: Symbol::intern(local_crate_name),
112 fn existing_match(&self, name: Symbol, hash: Option<&Svh>, kind: PathKind)
113 -> Option<CrateNum> {
115 self.cstore.iter_crate_data(|cnum, data| {
116 if data.name != name { return }
119 Some(hash) if *hash == data.root.hash => { ret = Some(cnum); return }
124 // When the hash is None we're dealing with a top-level dependency
125 // in which case we may have a specification on the command line for
126 // this library. Even though an upstream library may have loaded
127 // something of the same name, we have to make sure it was loaded
128 // from the exact same location as well.
130 // We're also sure to compare *paths*, not actual byte slices. The
131 // `source` stores paths which are normalized which may be different
132 // from the strings on the command line.
133 let source = &self.cstore.get_crate_data(cnum).source;
134 if let Some(entry) = self.sess.opts.externs.get(&*name.as_str()) {
135 // Only use `--extern crate_name=path` here, not `--extern crate_name`.
136 let found = entry.locations.iter().filter_map(|l| l.as_ref()).any(|l| {
137 let l = fs::canonicalize(l).ok();
138 source.dylib.as_ref().map(|p| &p.0) == l.as_ref() ||
139 source.rlib.as_ref().map(|p| &p.0) == l.as_ref()
147 // Alright, so we've gotten this far which means that `data` has the
148 // right name, we don't have a hash, and we don't have a --extern
149 // pointing for ourselves. We're still not quite yet done because we
150 // have to make sure that this crate was found in the crate lookup
151 // path (this is a top-level dependency) as we don't want to
152 // implicitly load anything inside the dependency lookup path.
153 let prev_kind = source.dylib.as_ref().or(source.rlib.as_ref())
154 .or(source.rmeta.as_ref())
155 .expect("No sources for crate").1;
156 if ret.is_none() && (prev_kind == kind || prev_kind == PathKind::All) {
163 fn verify_no_symbol_conflicts(&self,
166 // Check for (potential) conflicts with the local crate
167 if self.local_crate_name == root.name &&
168 self.sess.local_crate_disambiguator() == root.disambiguator {
169 span_fatal!(self.sess, span, E0519,
170 "the current crate is indistinguishable from one of its \
171 dependencies: it has the same crate-name `{}` and was \
172 compiled with the same `-C metadata` arguments. This \
173 will result in symbol conflicts between the two.",
177 // Check for conflicts with any crate loaded so far
178 self.cstore.iter_crate_data(|_, other| {
179 if other.root.name == root.name && // same crate-name
180 other.root.disambiguator == root.disambiguator && // same crate-disambiguator
181 other.root.hash != root.hash { // but different SVH
182 span_fatal!(self.sess, span, E0523,
183 "found two different crates with name `{}` that are \
184 not distinguished by differing `-C metadata`. This \
185 will result in symbol conflicts between the two.",
193 host_lib: Option<Library>,
194 root: &Option<CratePaths>,
200 ) -> (CrateNum, Lrc<cstore::CrateMetadata>) {
201 let crate_root = lib.metadata.get_root();
202 self.verify_no_symbol_conflicts(span, &crate_root);
204 let private_dep = self.sess.opts.externs.get(&name.as_str())
205 .map(|e| e.is_private_dep)
208 info!("register crate `extern crate {} as {}` (private_dep = {})",
209 crate_root.name, ident, private_dep);
212 // Claim this crate number and cache it
213 let cnum = self.cstore.alloc_new_crate_num();
215 // Stash paths for top-most crate locally if necessary.
216 let crate_paths = if root.is_none() {
218 ident: ident.to_string(),
219 dylib: lib.dylib.clone().map(|p| p.0),
220 rlib: lib.rlib.clone().map(|p| p.0),
221 rmeta: lib.rmeta.clone().map(|p| p.0),
226 // Maintain a reference to the top most crate.
227 let root = if root.is_some() { root } else { &crate_paths };
229 let Library { dylib, rlib, rmeta, metadata } = lib;
230 let cnum_map = self.resolve_crate_deps(root, &crate_root, &metadata, cnum, span, dep_kind);
232 let dependencies: Vec<CrateNum> = cnum_map.iter().cloned().collect();
234 let proc_macros = crate_root.proc_macro_decls_static.map(|_| {
235 if self.sess.opts.debugging_opts.dual_proc_macros {
236 let host_lib = host_lib.unwrap();
237 self.load_derive_macros(
238 &host_lib.metadata.get_root(),
239 host_lib.dylib.clone().map(|p| p.0),
243 self.load_derive_macros(&crate_root, dylib.clone().map(|p| p.0), span)
247 let def_path_table = record_time(&self.sess.perf_stats.decode_def_path_tables_time, || {
248 if let Some(proc_macros) = &proc_macros {
249 proc_macro_def_path_table(&crate_root, proc_macros)
251 crate_root.def_path_table.decode((&metadata, self.sess))
255 let interpret_alloc_index: Vec<u32> = crate_root.interpret_alloc_index
258 let trait_impls = crate_root
260 .decode((&metadata, self.sess))
261 .map(|trait_impls| (trait_impls.trait_id, trait_impls.impls))
264 let cmeta = cstore::CrateMetadata {
265 name: crate_root.name,
266 imported_name: ident,
267 extern_crate: Lock::new(None),
268 def_path_table: Lrc::new(def_path_table),
275 dependencies: Lock::new(dependencies),
276 source_map_import_info: RwLock::new(vec![]),
277 alloc_decoding_state: AllocDecodingState::new(interpret_alloc_index),
278 dep_kind: Lock::new(dep_kind),
279 source: cstore::CrateSource {
287 let cmeta = Lrc::new(cmeta);
288 self.cstore.set_crate_data(cnum, cmeta.clone());
292 fn load_proc_macro<'b> (
294 locate_ctxt: &mut locator::Context<'b>,
296 ) -> Option<(LoadResult, Option<Library>)>
300 // Use a new locator Context so trying to load a proc macro doesn't affect the error
302 let mut proc_macro_locator = locate_ctxt.clone();
304 // Try to load a proc macro
305 proc_macro_locator.is_proc_macro = Some(true);
307 // Load the proc macro crate for the target
308 let (locator, target_result) = if self.sess.opts.debugging_opts.dual_proc_macros {
309 proc_macro_locator.reset();
310 let result = match self.load(&mut proc_macro_locator)? {
311 LoadResult::Previous(cnum) => return Some((LoadResult::Previous(cnum), None)),
312 LoadResult::Loaded(library) => Some(LoadResult::Loaded(library))
314 // Don't look for a matching hash when looking for the host crate.
315 // It won't be the same as the target crate hash
316 locate_ctxt.hash = None;
317 // Use the locate_ctxt when looking for the host proc macro crate, as that is required
318 // so we want it to affect the error message
319 (locate_ctxt, result)
321 (&mut proc_macro_locator, None)
324 // Load the proc macro crate for the host
327 locator.is_proc_macro = Some(true);
328 locator.target = &self.sess.host;
329 locator.triple = TargetTriple::from_triple(config::host_triple());
330 locator.filesearch = self.sess.host_filesearch(path_kind);
332 let host_result = self.load(locator)?;
334 Some(if self.sess.opts.debugging_opts.dual_proc_macros {
335 let host_result = match host_result {
336 LoadResult::Previous(..) => {
337 panic!("host and target proc macros must be loaded in lock-step")
339 LoadResult::Loaded(library) => library
341 (target_result.unwrap(), Some(host_result))
347 fn resolve_crate<'b>(
349 root: &'b Option<CratePaths>,
352 hash: Option<&'b Svh>,
353 extra_filename: Option<&'b str>,
356 mut dep_kind: DepKind,
357 ) -> Result<(CrateNum, Lrc<cstore::CrateMetadata>), LoadError<'b>> {
358 info!("resolving crate `extern crate {} as {}`", name, ident);
359 let result = if let Some(cnum) = self.existing_match(name, hash, path_kind) {
360 (LoadResult::Previous(cnum), None)
362 info!("falling back to a load");
363 let mut locate_ctxt = locator::Context {
368 hash: hash.map(|a| &*a),
369 extra_filename: extra_filename,
370 filesearch: self.sess.target_filesearch(path_kind),
371 target: &self.sess.target.target,
372 triple: self.sess.opts.target_triple.clone(),
374 rejected_via_hash: vec![],
375 rejected_via_triple: vec![],
376 rejected_via_kind: vec![],
377 rejected_via_version: vec![],
378 rejected_via_filename: vec![],
379 should_match_name: true,
380 is_proc_macro: Some(false),
381 metadata_loader: &*self.cstore.metadata_loader,
384 self.load(&mut locate_ctxt).map(|r| (r, None)).or_else(|| {
385 dep_kind = DepKind::UnexportedMacrosOnly;
386 self.load_proc_macro(&mut locate_ctxt, path_kind)
387 }).ok_or_else(move || LoadError::LocatorError(locate_ctxt))?
391 (LoadResult::Previous(cnum), None) => {
392 let data = self.cstore.get_crate_data(cnum);
393 if data.root.proc_macro_decls_static.is_some() {
394 dep_kind = DepKind::UnexportedMacrosOnly;
396 data.dep_kind.with_lock(|data_dep_kind| {
397 *data_dep_kind = cmp::max(*data_dep_kind, dep_kind);
401 (LoadResult::Loaded(library), host_library) => {
402 Ok(self.register_crate(host_library, root, ident, span, library, dep_kind, name))
408 fn load(&mut self, locate_ctxt: &mut locator::Context<'_>) -> Option<LoadResult> {
409 let library = locate_ctxt.maybe_load_library_crate()?;
411 // In the case that we're loading a crate, but not matching
412 // against a hash, we could load a crate which has the same hash
413 // as an already loaded crate. If this is the case prevent
414 // duplicates by just using the first crate.
416 // Note that we only do this for target triple crates, though, as we
417 // don't want to match a host crate against an equivalent target one
419 let root = library.metadata.get_root();
420 if locate_ctxt.triple == self.sess.opts.target_triple {
421 let mut result = LoadResult::Loaded(library);
422 self.cstore.iter_crate_data(|cnum, data| {
423 if data.root.name == root.name && root.hash == data.root.hash {
424 assert!(locate_ctxt.hash.is_none());
425 info!("load success, going to previous cnum: {}", cnum);
426 result = LoadResult::Previous(cnum);
431 Some(LoadResult::Loaded(library))
435 fn update_extern_crate(&mut self,
437 mut extern_crate: ExternCrate,
438 visited: &mut FxHashSet<(CrateNum, bool)>)
440 if !visited.insert((cnum, extern_crate.direct)) { return }
442 let cmeta = self.cstore.get_crate_data(cnum);
443 let mut old_extern_crate = cmeta.extern_crate.borrow_mut();
446 // - something over nothing (tuple.0);
447 // - direct extern crate to indirect (tuple.1);
448 // - shorter paths to longer (tuple.2).
452 cmp::Reverse(extern_crate.path_len),
454 let old_rank = match *old_extern_crate {
455 None => (false, false, cmp::Reverse(usize::max_value())),
459 cmp::Reverse(c.path_len),
462 if old_rank >= new_rank {
463 return; // no change needed
466 *old_extern_crate = Some(extern_crate);
467 drop(old_extern_crate);
469 // Propagate the extern crate info to dependencies.
470 extern_crate.direct = false;
471 for &dep_cnum in cmeta.dependencies.borrow().iter() {
472 self.update_extern_crate(dep_cnum, extern_crate, visited);
476 // Go through the crate metadata and load any crates that it references
477 fn resolve_crate_deps(&mut self,
478 root: &Option<CratePaths>,
479 crate_root: &CrateRoot,
480 metadata: &MetadataBlob,
484 -> cstore::CrateNumMap {
485 debug!("resolving deps of external crate");
486 if crate_root.proc_macro_decls_static.is_some() {
487 return cstore::CrateNumMap::new();
490 // The map from crate numbers in the crate we're resolving to local crate numbers.
491 // We map 0 and all other holes in the map to our parent crate. The "additional"
492 // self-dependencies should be harmless.
493 std::iter::once(krate).chain(crate_root.crate_deps
496 info!("resolving dep crate {} hash: `{}` extra filename: `{}`", dep.name, dep.hash,
498 if dep.kind == DepKind::UnexportedMacrosOnly {
501 let dep_kind = match dep_kind {
502 DepKind::MacrosOnly => DepKind::MacrosOnly,
505 let (local_cnum, ..) = self.resolve_crate(
506 root, dep.name, dep.name, Some(&dep.hash), Some(&dep.extra_filename), span,
507 PathKind::Dependency, dep_kind,
508 ).unwrap_or_else(|err| err.report());
513 fn read_extension_crate(&mut self, span: Span, orig_name: Symbol, rename: Symbol)
515 info!("read extension crate `extern crate {} as {}`", orig_name, rename);
516 let target_triple = self.sess.opts.target_triple.clone();
517 let host_triple = TargetTriple::from_triple(config::host_triple());
518 let is_cross = target_triple != host_triple;
519 let mut target_only = false;
520 let mut locate_ctxt = locator::Context {
526 extra_filename: None,
527 filesearch: self.sess.host_filesearch(PathKind::Crate),
528 target: &self.sess.host,
531 rejected_via_hash: vec![],
532 rejected_via_triple: vec![],
533 rejected_via_kind: vec![],
534 rejected_via_version: vec![],
535 rejected_via_filename: vec![],
536 should_match_name: true,
538 metadata_loader: &*self.cstore.metadata_loader,
540 let library = self.load(&mut locate_ctxt).or_else(|| {
544 // Try loading from target crates. This will abort later if we
545 // try to load a plugin registrar function,
548 locate_ctxt.target = &self.sess.target.target;
549 locate_ctxt.triple = target_triple;
550 locate_ctxt.filesearch = self.sess.target_filesearch(PathKind::Crate);
552 self.load(&mut locate_ctxt)
554 let library = match library {
556 None => locate_ctxt.report_errs(),
559 let (dylib, metadata) = match library {
560 LoadResult::Previous(cnum) => {
561 let data = self.cstore.get_crate_data(cnum);
562 (data.source.dylib.clone(), PMDSource::Registered(data))
564 LoadResult::Loaded(library) => {
565 let dylib = library.dylib.clone();
566 let metadata = PMDSource::Owned(library);
573 dylib: dylib.map(|p| p.0),
578 /// Loads custom derive macros.
580 /// Note that this is intentionally similar to how we load plugins today,
581 /// but also intentionally separate. Plugins are likely always going to be
582 /// implemented as dynamic libraries, but we have a possible future where
583 /// custom derive (and other macro-1.1 style features) are implemented via
584 /// executables and custom IPC.
585 fn load_derive_macros(&mut self, root: &CrateRoot, dylib: Option<PathBuf>, span: Span)
586 -> Vec<(ast::Name, Lrc<SyntaxExtension>)> {
588 use crate::dynamic_lib::DynamicLibrary;
589 use proc_macro::bridge::client::ProcMacro;
590 use syntax_ext::deriving::custom::ProcMacroDerive;
591 use syntax_ext::proc_macro_impl::{AttrProcMacro, BangProcMacro};
593 let path = match dylib {
594 Some(dylib) => dylib,
595 None => span_bug!(span, "proc-macro crate not dylib"),
597 // Make sure the path contains a / or the linker will search for it.
598 let path = env::current_dir().unwrap().join(path);
599 let lib = match DynamicLibrary::open(Some(&path)) {
601 Err(err) => self.sess.span_fatal(span, &err),
604 let sym = self.sess.generate_proc_macro_decls_symbol(root.disambiguator);
606 let sym = match lib.symbol(&sym) {
608 Err(err) => self.sess.span_fatal(span, &err),
610 *(sym as *const &[ProcMacro])
613 let extensions = decls.iter().map(|&decl| {
615 ProcMacro::CustomDerive { trait_name, attributes, client } => {
616 let attrs = attributes.iter().cloned().map(Symbol::intern).collect::<Vec<_>>();
617 (trait_name, SyntaxExtension::ProcMacroDerive(
618 Box::new(ProcMacroDerive {
620 attrs: attrs.clone(),
626 ProcMacro::Attr { name, client } => {
627 (name, SyntaxExtension::AttrProcMacro(
628 Box::new(AttrProcMacro { client }),
632 ProcMacro::Bang { name, client } => {
633 (name, SyntaxExtension::ProcMacro {
634 expander: Box::new(BangProcMacro { client }),
635 allow_internal_unstable: None,
636 edition: root.edition,
640 }).map(|(name, ext)| (Symbol::intern(name), Lrc::new(ext))).collect();
642 // Intentionally leak the dynamic library. We can't ever unload it
643 // since the library can make things that will live arbitrarily long.
649 /// Look for a plugin registrar. Returns library path, crate
650 /// SVH and DefIndex of the registrar function.
651 pub fn find_plugin_registrar(&mut self,
654 -> Option<(PathBuf, CrateDisambiguator)> {
655 let name = Symbol::intern(name);
656 let ekrate = self.read_extension_crate(span, name, name);
658 if ekrate.target_only {
659 // Need to abort before syntax expansion.
660 let message = format!("plugin `{}` is not available for triple `{}` \
663 config::host_triple(),
664 self.sess.opts.target_triple);
665 span_fatal!(self.sess, span, E0456, "{}", &message);
668 let root = ekrate.metadata.get_root();
669 match ekrate.dylib.as_ref() {
671 Some((dylib.to_path_buf(), root.disambiguator))
674 span_err!(self.sess, span, E0457,
675 "plugin `{}` only found in rlib format, but must be available \
678 // No need to abort because the loading code will just ignore this
685 fn inject_panic_runtime(&mut self, krate: &ast::Crate) {
686 // If we're only compiling an rlib, then there's no need to select a
687 // panic runtime, so we just skip this section entirely.
688 let any_non_rlib = self.sess.crate_types.borrow().iter().any(|ct| {
689 *ct != config::CrateType::Rlib
692 info!("panic runtime injection skipped, only generating rlib");
693 self.sess.injected_panic_runtime.set(None);
697 // If we need a panic runtime, we try to find an existing one here. At
698 // the same time we perform some general validation of the DAG we've got
699 // going such as ensuring everything has a compatible panic strategy.
701 // The logic for finding the panic runtime here is pretty much the same
702 // as the allocator case with the only addition that the panic strategy
703 // compilation mode also comes into play.
704 let desired_strategy = self.sess.panic_strategy();
705 let mut runtime_found = false;
706 let mut needs_panic_runtime = attr::contains_name(&krate.attrs,
707 "needs_panic_runtime");
709 self.cstore.iter_crate_data(|cnum, data| {
710 needs_panic_runtime = needs_panic_runtime ||
711 data.root.needs_panic_runtime;
712 if data.root.panic_runtime {
713 // Inject a dependency from all #![needs_panic_runtime] to this
714 // #![panic_runtime] crate.
715 self.inject_dependency_if(cnum, "a panic runtime",
716 &|data| data.root.needs_panic_runtime);
717 runtime_found = runtime_found || *data.dep_kind.lock() == DepKind::Explicit;
721 // If an explicitly linked and matching panic runtime was found, or if
722 // we just don't need one at all, then we're done here and there's
723 // nothing else to do.
724 if !needs_panic_runtime || runtime_found {
725 self.sess.injected_panic_runtime.set(None);
729 // By this point we know that we (a) need a panic runtime and (b) no
730 // panic runtime was explicitly linked. Here we just load an appropriate
731 // default runtime for our panic strategy and then inject the
734 // We may resolve to an already loaded crate (as the crate may not have
735 // been explicitly linked prior to this) and we may re-inject
736 // dependencies again, but both of those situations are fine.
738 // Also note that we have yet to perform validation of the crate graph
739 // in terms of everyone has a compatible panic runtime format, that's
740 // performed later as part of the `dependency_format` module.
741 let name = match desired_strategy {
742 PanicStrategy::Unwind => Symbol::intern("panic_unwind"),
743 PanicStrategy::Abort => Symbol::intern("panic_abort"),
745 info!("panic runtime not found -- loading {}", name);
747 let dep_kind = DepKind::Implicit;
749 self.resolve_crate(&None, name, name, None, None, DUMMY_SP, PathKind::Crate, dep_kind)
750 .unwrap_or_else(|err| err.report());
752 // Sanity check the loaded crate to ensure it is indeed a panic runtime
753 // and the panic strategy is indeed what we thought it was.
754 if !data.root.panic_runtime {
755 self.sess.err(&format!("the crate `{}` is not a panic runtime",
758 if data.root.panic_strategy != desired_strategy {
759 self.sess.err(&format!("the crate `{}` does not have the panic \
761 name, desired_strategy.desc()));
764 self.sess.injected_panic_runtime.set(Some(cnum));
765 self.inject_dependency_if(cnum, "a panic runtime",
766 &|data| data.root.needs_panic_runtime);
769 fn inject_sanitizer_runtime(&mut self) {
770 if let Some(ref sanitizer) = self.sess.opts.debugging_opts.sanitizer {
771 // Sanitizers can only be used on some tested platforms with
772 // executables linked to `std`
773 const ASAN_SUPPORTED_TARGETS: &[&str] = &["x86_64-unknown-linux-gnu",
774 "x86_64-apple-darwin"];
775 const TSAN_SUPPORTED_TARGETS: &[&str] = &["x86_64-unknown-linux-gnu",
776 "x86_64-apple-darwin"];
777 const LSAN_SUPPORTED_TARGETS: &[&str] = &["x86_64-unknown-linux-gnu"];
778 const MSAN_SUPPORTED_TARGETS: &[&str] = &["x86_64-unknown-linux-gnu"];
780 let supported_targets = match *sanitizer {
781 Sanitizer::Address => ASAN_SUPPORTED_TARGETS,
782 Sanitizer::Thread => TSAN_SUPPORTED_TARGETS,
783 Sanitizer::Leak => LSAN_SUPPORTED_TARGETS,
784 Sanitizer::Memory => MSAN_SUPPORTED_TARGETS,
786 if !supported_targets.contains(&&*self.sess.opts.target_triple.triple()) {
787 self.sess.err(&format!("{:?}Sanitizer only works with the `{}` target",
789 supported_targets.join("` or `")
794 // firstyear 2017 - during testing I was unable to access an OSX machine
795 // to make this work on different crate types. As a result, today I have
796 // only been able to test and support linux as a target.
797 if self.sess.opts.target_triple.triple() == "x86_64-unknown-linux-gnu" {
798 if !self.sess.crate_types.borrow().iter().all(|ct| {
801 config::CrateType::Staticlib |
802 config::CrateType::Executable => true,
803 // This crate will be compiled with the required
804 // instrumentation pass
805 config::CrateType::Rlib |
806 config::CrateType::Dylib |
807 config::CrateType::Cdylib =>
810 self.sess.err(&format!("Only executables, staticlibs, \
811 cdylibs, dylibs and rlibs can be compiled with \
820 if !self.sess.crate_types.borrow().iter().all(|ct| {
823 config::CrateType::Executable => true,
824 // This crate will be compiled with the required
825 // instrumentation pass
826 config::CrateType::Rlib => false,
828 self.sess.err(&format!("Only executables and rlibs can be \
829 compiled with `-Z sanitizer`"));
838 let mut uses_std = false;
839 self.cstore.iter_crate_data(|_, data| {
840 if data.name == "std" {
846 let name = match *sanitizer {
847 Sanitizer::Address => "rustc_asan",
848 Sanitizer::Leak => "rustc_lsan",
849 Sanitizer::Memory => "rustc_msan",
850 Sanitizer::Thread => "rustc_tsan",
852 info!("loading sanitizer: {}", name);
854 let symbol = Symbol::intern(name);
855 let dep_kind = DepKind::Explicit;
857 self.resolve_crate(&None, symbol, symbol, None, None, DUMMY_SP,
858 PathKind::Crate, dep_kind)
859 .unwrap_or_else(|err| err.report());
861 // Sanity check the loaded crate to ensure it is indeed a sanitizer runtime
862 if !data.root.sanitizer_runtime {
863 self.sess.err(&format!("the crate `{}` is not a sanitizer runtime",
867 self.sess.err("Must link std to be compiled with `-Z sanitizer`");
872 fn inject_profiler_runtime(&mut self) {
873 if self.sess.opts.debugging_opts.profile ||
874 self.sess.opts.debugging_opts.pgo_gen.enabled()
876 info!("loading profiler");
878 let symbol = Symbol::intern("profiler_builtins");
879 let dep_kind = DepKind::Implicit;
881 self.resolve_crate(&None, symbol, symbol, None, None, DUMMY_SP,
882 PathKind::Crate, dep_kind)
883 .unwrap_or_else(|err| err.report());
885 // Sanity check the loaded crate to ensure it is indeed a profiler runtime
886 if !data.root.profiler_runtime {
887 self.sess.err(&format!("the crate `profiler_builtins` is not \
888 a profiler runtime"));
893 fn inject_allocator_crate(&mut self, krate: &ast::Crate) {
894 let has_global_allocator = has_global_allocator(krate);
895 self.sess.has_global_allocator.set(has_global_allocator);
897 // Check to see if we actually need an allocator. This desire comes
898 // about through the `#![needs_allocator]` attribute and is typically
899 // written down in liballoc.
900 let mut needs_allocator = attr::contains_name(&krate.attrs,
902 self.cstore.iter_crate_data(|_, data| {
903 needs_allocator = needs_allocator || data.root.needs_allocator;
905 if !needs_allocator {
906 self.sess.allocator_kind.set(None);
910 // At this point we've determined that we need an allocator. Let's see
911 // if our compilation session actually needs an allocator based on what
913 let all_rlib = self.sess.crate_types.borrow()
917 config::CrateType::Rlib => true,
922 self.sess.allocator_kind.set(None);
926 // Ok, we need an allocator. Not only that but we're actually going to
927 // create an artifact that needs one linked in. Let's go find the one
928 // that we're going to link in.
930 // First up we check for global allocators. Look at the crate graph here
931 // and see what's a global allocator, including if we ourselves are a
933 let mut global_allocator = if has_global_allocator {
938 self.cstore.iter_crate_data(|_, data| {
939 if !data.root.has_global_allocator {
942 match global_allocator {
943 Some(Some(other_crate)) => {
944 self.sess.err(&format!("the #[global_allocator] in {} \
945 conflicts with this global \
951 self.sess.err(&format!("the #[global_allocator] in this \
952 crate conflicts with global \
953 allocator in: {}", data.root.name));
955 None => global_allocator = Some(Some(data.root.name)),
958 if global_allocator.is_some() {
959 self.sess.allocator_kind.set(Some(AllocatorKind::Global));
963 // Ok we haven't found a global allocator but we still need an
964 // allocator. At this point our allocator request is typically fulfilled
965 // by the standard library, denoted by the `#![default_lib_allocator]`
967 let mut has_default = attr::contains_name(&krate.attrs, "default_lib_allocator");
968 self.cstore.iter_crate_data(|_, data| {
969 if data.root.has_default_lib_allocator {
975 self.sess.err("no global memory allocator found but one is \
976 required; link to std or \
977 add #[global_allocator] to a static item \
978 that implements the GlobalAlloc trait.");
980 self.sess.allocator_kind.set(Some(AllocatorKind::DefaultLib));
982 fn has_global_allocator(krate: &ast::Crate) -> bool {
984 let mut f = Finder(false);
985 visit::walk_crate(&mut f, krate);
988 impl<'ast> visit::Visitor<'ast> for Finder {
989 fn visit_item(&mut self, i: &'ast ast::Item) {
990 if attr::contains_name(&i.attrs, "global_allocator") {
993 visit::walk_item(self, i)
1000 fn inject_dependency_if(&self,
1003 needs_dep: &dyn Fn(&cstore::CrateMetadata) -> bool) {
1004 // don't perform this validation if the session has errors, as one of
1005 // those errors may indicate a circular dependency which could cause
1006 // this to stack overflow.
1007 if self.sess.has_errors() {
1011 // Before we inject any dependencies, make sure we don't inject a
1012 // circular dependency by validating that this crate doesn't
1013 // transitively depend on any crates satisfying `needs_dep`.
1014 for dep in self.cstore.crate_dependencies_in_rpo(krate) {
1015 let data = self.cstore.get_crate_data(dep);
1016 if needs_dep(&data) {
1017 self.sess.err(&format!("the crate `{}` cannot depend \
1018 on a crate that needs {}, but \
1019 it depends on `{}`",
1020 self.cstore.get_crate_data(krate).root.name,
1026 // All crates satisfying `needs_dep` do not explicitly depend on the
1027 // crate provided for this compile, but in order for this compilation to
1028 // be successfully linked we need to inject a dependency (to order the
1029 // crates on the command line correctly).
1030 self.cstore.iter_crate_data(|cnum, data| {
1031 if !needs_dep(data) {
1035 info!("injecting a dep from {} to {}", cnum, krate);
1036 data.dependencies.borrow_mut().push(krate);
1041 impl<'a> CrateLoader<'a> {
1042 pub fn postprocess(&mut self, krate: &ast::Crate) {
1043 self.inject_sanitizer_runtime();
1044 self.inject_profiler_runtime();
1045 self.inject_allocator_crate(krate);
1046 self.inject_panic_runtime(krate);
1048 if log_enabled!(log::Level::Info) {
1049 dump_crates(&self.cstore);
1053 pub fn process_extern_crate(
1054 &mut self, item: &ast::Item, definitions: &Definitions,
1057 ast::ItemKind::ExternCrate(orig_name) => {
1058 debug!("resolving extern crate stmt. ident: {} orig_name: {:?}",
1059 item.ident, orig_name);
1060 let orig_name = match orig_name {
1061 Some(orig_name) => {
1062 crate::validate_crate_name(Some(self.sess), &orig_name.as_str(),
1066 None => item.ident.name,
1068 let dep_kind = if attr::contains_name(&item.attrs, "no_link") {
1069 DepKind::UnexportedMacrosOnly
1074 let (cnum, ..) = self.resolve_crate(
1075 &None, item.ident.name, orig_name, None, None,
1076 item.span, PathKind::Crate, dep_kind,
1077 ).unwrap_or_else(|err| err.report());
1079 let def_id = definitions.opt_local_def_id(item.id).unwrap();
1080 let path_len = definitions.def_path(def_id.index).data.len();
1081 self.update_extern_crate(
1084 src: ExternCrateSource::Extern(def_id),
1089 &mut FxHashSet::default(),
1091 self.cstore.add_extern_mod_stmt_cnum(item.id, cnum);
1098 pub fn process_path_extern(
1103 let cnum = self.resolve_crate(
1104 &None, name, name, None, None, span, PathKind::Crate, DepKind::Explicit
1105 ).unwrap_or_else(|err| err.report()).0;
1107 self.update_extern_crate(
1110 src: ExternCrateSource::Path,
1112 // to have the least priority in `update_extern_crate`
1113 path_len: usize::max_value(),
1116 &mut FxHashSet::default(),
1122 pub fn maybe_process_path_extern(
1126 ) -> Option<CrateNum> {
1127 let cnum = self.resolve_crate(
1128 &None, name, name, None, None, span, PathKind::Crate, DepKind::Explicit
1131 self.update_extern_crate(
1134 src: ExternCrateSource::Path,
1136 // to have the least priority in `update_extern_crate`
1137 path_len: usize::max_value(),
1140 &mut FxHashSet::default(),