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android / toolchain / rustc / refs/heads/main / . / compiler / rustc_interface / src / passes.rs
blob: fd850d2f39a5fc4028afa02a021391e883bdb5db [file] [log] [blame] [edit]
use std::any::Any;
use std::ffi::OsString;
use std::io::{self, BufWriter, Write};
use std::path::{Path, PathBuf};
use std::sync::{Arc, LazyLock};
use std::{env, fs, iter};
use rustc_ast::{self as ast, visit};
use rustc_codegen_ssa::traits::CodegenBackend;
use rustc_data_structures::parallel;
use rustc_data_structures::steal::Steal;
use rustc_data_structures::sync::{AppendOnlyIndexVec, FreezeLock, Lrc, OnceLock, WorkerLocal};
use rustc_expand::base::{ExtCtxt, LintStoreExpand};
use rustc_feature::Features;
use rustc_fs_util::try_canonicalize;
use rustc_hir::def_id::{LOCAL_CRATE, StableCrateId, StableCrateIdMap};
use rustc_hir::definitions::Definitions;
use rustc_incremental::setup_dep_graph;
use rustc_lint::{BufferedEarlyLint, EarlyCheckNode, LintStore, unerased_lint_store};
use rustc_metadata::creader::CStore;
use rustc_middle::arena::Arena;
use rustc_middle::ty::{self, GlobalCtxt, RegisteredTools, TyCtxt};
use rustc_middle::util::Providers;
use rustc_parse::{
new_parser_from_file, new_parser_from_source_str, unwrap_or_emit_fatal, validate_attr,
};
use rustc_passes::{abi_test, hir_stats, layout_test};
use rustc_resolve::Resolver;
use rustc_session::code_stats::VTableSizeInfo;
use rustc_session::config::{CrateType, Input, OutFileName, OutputFilenames, OutputType};
use rustc_session::cstore::Untracked;
use rustc_session::output::{collect_crate_types, filename_for_input, find_crate_name};
use rustc_session::search_paths::PathKind;
use rustc_session::{Limit, Session};
use rustc_span::symbol::{Symbol, sym};
use rustc_span::{FileName, SourceFileHash, SourceFileHashAlgorithm};
use rustc_target::spec::PanicStrategy;
use rustc_trait_selection::traits;
use tracing::{info, instrument};
use crate::interface::{Compiler, Result};
use crate::{errors, proc_macro_decls, util};
pub(crate) fn parse<'a>(sess: &'a Session) -> Result<ast::Crate> {
let krate = sess
.time("parse_crate", || {
let mut parser = unwrap_or_emit_fatal(match &sess.io.input {
Input::File(file) => new_parser_from_file(&sess.psess, file, None),
Input::Str { input, name } => {
new_parser_from_source_str(&sess.psess, name.clone(), input.clone())
}
});
parser.parse_crate_mod()
})
.map_err(|parse_error| parse_error.emit())?;
if sess.opts.unstable_opts.input_stats {
eprintln!("Lines of code: {}", sess.source_map().count_lines());
eprintln!("Pre-expansion node count: {}", count_nodes(&krate));
}
if let Some(ref s) = sess.opts.unstable_opts.show_span {
rustc_ast_passes::show_span::run(sess.dcx(), s, &krate);
}
if sess.opts.unstable_opts.hir_stats {
hir_stats::print_ast_stats(&krate, "PRE EXPANSION AST STATS", "ast-stats-1");
}
Ok(krate)
}
fn count_nodes(krate: &ast::Crate) -> usize {
let mut counter = rustc_ast_passes::node_count::NodeCounter::new();
visit::walk_crate(&mut counter, krate);
counter.count
}
fn pre_expansion_lint<'a>(
sess: &Session,
features: &Features,
lint_store: &LintStore,
registered_tools: &RegisteredTools,
check_node: impl EarlyCheckNode<'a>,
node_name: Symbol,
) {
sess.prof.generic_activity_with_arg("pre_AST_expansion_lint_checks", node_name.as_str()).run(
|| {
rustc_lint::check_ast_node(
sess,
features,
true,
lint_store,
registered_tools,
None,
rustc_lint::BuiltinCombinedPreExpansionLintPass::new(),
check_node,
);
},
);
}
// Cannot implement directly for `LintStore` due to trait coherence.
struct LintStoreExpandImpl<'a>(&'a LintStore);
impl LintStoreExpand for LintStoreExpandImpl<'_> {
fn pre_expansion_lint(
&self,
sess: &Session,
features: &Features,
registered_tools: &RegisteredTools,
node_id: ast::NodeId,
attrs: &[ast::Attribute],
items: &[rustc_ast::ptr::P<ast::Item>],
name: Symbol,
) {
pre_expansion_lint(sess, features, self.0, registered_tools, (node_id, attrs, items), name);
}
}
/// Runs the "early phases" of the compiler: initial `cfg` processing,
/// syntax expansion, secondary `cfg` expansion, synthesis of a test
/// harness if one is to be provided, injection of a dependency on the
/// standard library and prelude, and name resolution.
#[instrument(level = "trace", skip(krate, resolver))]
fn configure_and_expand(
mut krate: ast::Crate,
pre_configured_attrs: &[ast::Attribute],
resolver: &mut Resolver<'_, '_>,
) -> ast::Crate {
let tcx = resolver.tcx();
let sess = tcx.sess;
let features = tcx.features();
let lint_store = unerased_lint_store(tcx.sess);
let crate_name = tcx.crate_name(LOCAL_CRATE);
let lint_check_node = (&krate, pre_configured_attrs);
pre_expansion_lint(
sess,
features,
lint_store,
tcx.registered_tools(()),
lint_check_node,
crate_name,
);
rustc_builtin_macros::register_builtin_macros(resolver);
let num_standard_library_imports = sess.time("crate_injection", || {
rustc_builtin_macros::standard_library_imports::inject(
&mut krate,
pre_configured_attrs,
resolver,
sess,
features,
)
});
util::check_attr_crate_type(sess, pre_configured_attrs, resolver.lint_buffer());
// Expand all macros
krate = sess.time("macro_expand_crate", || {
// Windows dlls do not have rpaths, so they don't know how to find their
// dependencies. It's up to us to tell the system where to find all the
// dependent dlls. Note that this uses cfg!(windows) as opposed to
// targ_cfg because syntax extensions are always loaded for the host
// compiler, not for the target.
//
// This is somewhat of an inherently racy operation, however, as
// multiple threads calling this function could possibly continue
// extending PATH far beyond what it should. To solve this for now we
// just don't add any new elements to PATH which are already there
// within PATH. This is basically a targeted fix at #17360 for rustdoc
// which runs rustc in parallel but has been seen (#33844) to cause
// problems with PATH becoming too long.
let mut old_path = OsString::new();
if cfg!(windows) {
old_path = env::var_os("PATH").unwrap_or(old_path);
let mut new_path = Vec::from_iter(
sess.host_filesearch(PathKind::All).search_paths().map(|p| p.dir.clone()),
);
for path in env::split_paths(&old_path) {
if !new_path.contains(&path) {
new_path.push(path);
}
}
env::set_var(
"PATH",
&env::join_paths(
new_path.iter().filter(|p| env::join_paths(iter::once(p)).is_ok()),
)
.unwrap(),
);
}
// Create the config for macro expansion
let recursion_limit = get_recursion_limit(pre_configured_attrs, sess);
let cfg = rustc_expand::expand::ExpansionConfig {
crate_name: crate_name.to_string(),
features,
recursion_limit,
trace_mac: sess.opts.unstable_opts.trace_macros,
should_test: sess.is_test_crate(),
span_debug: sess.opts.unstable_opts.span_debug,
proc_macro_backtrace: sess.opts.unstable_opts.proc_macro_backtrace,
};
let lint_store = LintStoreExpandImpl(lint_store);
let mut ecx = ExtCtxt::new(sess, cfg, resolver, Some(&lint_store));
ecx.num_standard_library_imports = num_standard_library_imports;
// Expand macros now!
let krate = sess.time("expand_crate", || ecx.monotonic_expander().expand_crate(krate));
// The rest is error reporting
sess.psess.buffered_lints.with_lock(|buffered_lints: &mut Vec<BufferedEarlyLint>| {
buffered_lints.append(&mut ecx.buffered_early_lint);
});
sess.time("check_unused_macros", || {
ecx.check_unused_macros();
});
// If we hit a recursion limit, exit early to avoid later passes getting overwhelmed
// with a large AST
if ecx.reduced_recursion_limit.is_some() {
sess.dcx().abort_if_errors();
unreachable!();
}
if cfg!(windows) {
env::set_var("PATH", &old_path);
}
krate
});
sess.time("maybe_building_test_harness", || {
rustc_builtin_macros::test_harness::inject(&mut krate, sess, features, resolver)
});
let has_proc_macro_decls = sess.time("AST_validation", || {
rustc_ast_passes::ast_validation::check_crate(
sess,
features,
&krate,
resolver.lint_buffer(),
)
});
let crate_types = tcx.crate_types();
let is_executable_crate = crate_types.contains(&CrateType::Executable);
let is_proc_macro_crate = crate_types.contains(&CrateType::ProcMacro);
if crate_types.len() > 1 {
if is_executable_crate {
sess.dcx().emit_err(errors::MixedBinCrate);
}
if is_proc_macro_crate {
sess.dcx().emit_err(errors::MixedProcMacroCrate);
}
}
if is_proc_macro_crate && sess.panic_strategy() == PanicStrategy::Abort {
sess.dcx().emit_warn(errors::ProcMacroCratePanicAbort);
}
sess.time("maybe_create_a_macro_crate", || {
let is_test_crate = sess.is_test_crate();
rustc_builtin_macros::proc_macro_harness::inject(
&mut krate,
sess,
features,
resolver,
is_proc_macro_crate,
has_proc_macro_decls,
is_test_crate,
sess.dcx(),
)
});
// Done with macro expansion!
resolver.resolve_crate(&krate);
krate
}
fn early_lint_checks(tcx: TyCtxt<'_>, (): ()) {
let sess = tcx.sess;
let (resolver, krate) = &*tcx.resolver_for_lowering().borrow();
let mut lint_buffer = resolver.lint_buffer.steal();
if sess.opts.unstable_opts.input_stats {
eprintln!("Post-expansion node count: {}", count_nodes(krate));
}
if sess.opts.unstable_opts.hir_stats {
hir_stats::print_ast_stats(krate, "POST EXPANSION AST STATS", "ast-stats-2");
}
// Needs to go *after* expansion to be able to check the results of macro expansion.
sess.time("complete_gated_feature_checking", || {
rustc_ast_passes::feature_gate::check_crate(krate, sess, tcx.features());
});
// Add all buffered lints from the `ParseSess` to the `Session`.
sess.psess.buffered_lints.with_lock(|buffered_lints| {
info!("{} parse sess buffered_lints", buffered_lints.len());
for early_lint in buffered_lints.drain(..) {
lint_buffer.add_early_lint(early_lint);
}
});
// Gate identifiers containing invalid Unicode codepoints that were recovered during lexing.
sess.psess.bad_unicode_identifiers.with_lock(|identifiers| {
for (ident, mut spans) in identifiers.drain(..) {
spans.sort();
if ident == sym::ferris {
let first_span = spans[0];
sess.dcx().emit_err(errors::FerrisIdentifier { spans, first_span });
} else {
sess.dcx().emit_err(errors::EmojiIdentifier { spans, ident });
}
}
});
let lint_store = unerased_lint_store(tcx.sess);
rustc_lint::check_ast_node(
sess,
tcx.features(),
false,
lint_store,
tcx.registered_tools(()),
Some(lint_buffer),
rustc_lint::BuiltinCombinedEarlyLintPass::new(),
(&**krate, &*krate.attrs),
)
}
// Returns all the paths that correspond to generated files.
fn generated_output_paths(
tcx: TyCtxt<'_>,
outputs: &OutputFilenames,
exact_name: bool,
crate_name: Symbol,
) -> Vec<PathBuf> {
let sess = tcx.sess;
let mut out_filenames = Vec::new();
for output_type in sess.opts.output_types.keys() {
let out_filename = outputs.path(*output_type);
let file = out_filename.as_path().to_path_buf();
match *output_type {
// If the filename has been overridden using `-o`, it will not be modified
// by appending `.rlib`, `.exe`, etc., so we can skip this transformation.
OutputType::Exe if !exact_name => {
for crate_type in tcx.crate_types().iter() {
let p = filename_for_input(sess, *crate_type, crate_name, outputs);
out_filenames.push(p.as_path().to_path_buf());
}
}
OutputType::DepInfo if sess.opts.unstable_opts.dep_info_omit_d_target => {
// Don't add the dep-info output when omitting it from dep-info targets
}
OutputType::DepInfo if out_filename.is_stdout() => {
// Don't add the dep-info output when it goes to stdout
}
_ => {
out_filenames.push(file);
}
}
}
out_filenames
}
fn output_contains_path(output_paths: &[PathBuf], input_path: &Path) -> bool {
let input_path = try_canonicalize(input_path).ok();
if input_path.is_none() {
return false;
}
output_paths.iter().any(|output_path| try_canonicalize(output_path).ok() == input_path)
}
fn output_conflicts_with_dir(output_paths: &[PathBuf]) -> Option<&PathBuf> {
output_paths.iter().find(|output_path| output_path.is_dir())
}
fn escape_dep_filename(filename: &str) -> String {
// Apparently clang and gcc *only* escape spaces:
// https://llvm.org/klaus/clang/commit/9d50634cfc268ecc9a7250226dd5ca0e945240d4
filename.replace(' ', "\\ ")
}
// Makefile comments only need escaping newlines and `\`.
// The result can be unescaped by anything that can unescape `escape_default` and friends.
fn escape_dep_env(symbol: Symbol) -> String {
let s = symbol.as_str();
let mut escaped = String::with_capacity(s.len());
for c in s.chars() {
match c {
'\n' => escaped.push_str(r"\n"),
'\r' => escaped.push_str(r"\r"),
'\\' => escaped.push_str(r"\\"),
_ => escaped.push(c),
}
}
escaped
}
fn write_out_deps(tcx: TyCtxt<'_>, outputs: &OutputFilenames, out_filenames: &[PathBuf]) {
// Write out dependency rules to the dep-info file if requested
let sess = tcx.sess;
if !sess.opts.output_types.contains_key(&OutputType::DepInfo) {
return;
}
let deps_output = outputs.path(OutputType::DepInfo);
let deps_filename = deps_output.as_path();
let result: io::Result<()> = try {
// Build a list of files used to compile the output and
// write Makefile-compatible dependency rules
let mut files: Vec<(String, u64, Option<SourceFileHash>)> = sess
.source_map()
.files()
.iter()
.filter(|fmap| fmap.is_real_file())
.filter(|fmap| !fmap.is_imported())
.map(|fmap| {
(
escape_dep_filename(&fmap.name.prefer_local().to_string()),
fmap.source_len.0 as u64,
fmap.checksum_hash,
)
})
.collect();
let checksum_hash_algo = sess.opts.unstable_opts.checksum_hash_algorithm;
// Account for explicitly marked-to-track files
// (e.g. accessed in proc macros).
let file_depinfo = sess.psess.file_depinfo.borrow();
let normalize_path = |path: PathBuf| {
let file = FileName::from(path);
escape_dep_filename(&file.prefer_local().to_string())
};
// The entries will be used to declare dependencies between files in a
// Makefile-like output, so the iteration order does not matter.
fn hash_iter_files<P: AsRef<Path>>(
it: impl Iterator<Item = P>,
checksum_hash_algo: Option<SourceFileHashAlgorithm>,
) -> impl Iterator<Item = (P, u64, Option<SourceFileHash>)> {
it.map(move |path| {
match checksum_hash_algo.and_then(|algo| {
fs::File::open(path.as_ref())
.and_then(|mut file| {
SourceFileHash::new(algo, &mut file).map(|h| (file, h))
})
.and_then(|(file, h)| file.metadata().map(|m| (m.len(), h)))
.map_err(|e| {
tracing::error!(
"failed to compute checksum, omitting it from dep-info {} {e}",
path.as_ref().display()
)
})
.ok()
}) {
Some((file_len, checksum)) => (path, file_len, Some(checksum)),
None => (path, 0, None),
}
})
}
let extra_tracked_files = hash_iter_files(
file_depinfo.iter().map(|path_sym| normalize_path(PathBuf::from(path_sym.as_str()))),
checksum_hash_algo,
);
files.extend(extra_tracked_files);
// We also need to track used PGO profile files
if let Some(ref profile_instr) = sess.opts.cg.profile_use {
files.extend(hash_iter_files(
iter::once(normalize_path(profile_instr.as_path().to_path_buf())),
checksum_hash_algo,
));
}
if let Some(ref profile_sample) = sess.opts.unstable_opts.profile_sample_use {
files.extend(hash_iter_files(
iter::once(normalize_path(profile_sample.as_path().to_path_buf())),
checksum_hash_algo,
));
}
// Debugger visualizer files
for debugger_visualizer in tcx.debugger_visualizers(LOCAL_CRATE) {
files.extend(hash_iter_files(
iter::once(normalize_path(debugger_visualizer.path.clone().unwrap())),
checksum_hash_algo,
));
}
if sess.binary_dep_depinfo() {
if let Some(ref backend) = sess.opts.unstable_opts.codegen_backend {
if backend.contains('.') {
// If the backend name contain a `.`, it is the path to an external dynamic
// library. If not, it is not a path.
files.extend(hash_iter_files(
iter::once(backend.to_string()),
checksum_hash_algo,
));
}
}
for &cnum in tcx.crates(()) {
let source = tcx.used_crate_source(cnum);
if let Some((path, _)) = &source.dylib {
files.extend(hash_iter_files(
iter::once(escape_dep_filename(&path.display().to_string())),
checksum_hash_algo,
));
}
if let Some((path, _)) = &source.rlib {
files.extend(hash_iter_files(
iter::once(escape_dep_filename(&path.display().to_string())),
checksum_hash_algo,
));
}
if let Some((path, _)) = &source.rmeta {
files.extend(hash_iter_files(
iter::once(escape_dep_filename(&path.display().to_string())),
checksum_hash_algo,
));
}
}
}
let write_deps_to_file = |file: &mut dyn Write| -> io::Result<()> {
for path in out_filenames {
writeln!(
file,
"{}: {}\n",
path.display(),
files
.iter()
.map(|(path, _file_len, _checksum_hash_algo)| path.as_str())
.intersperse(" ")
.collect::<String>()
)?;
}
// Emit a fake target for each input file to the compilation. This
// prevents `make` from spitting out an error if a file is later
// deleted. For more info see #28735
for (path, _file_len, _checksum_hash_algo) in &files {
writeln!(file, "{path}:")?;
}
// Emit special comments with information about accessed environment variables.
let env_depinfo = sess.psess.env_depinfo.borrow();
if !env_depinfo.is_empty() {
// We will soon sort, so the initial order does not matter.
#[allow(rustc::potential_query_instability)]
let mut envs: Vec<_> = env_depinfo
.iter()
.map(|(k, v)| (escape_dep_env(*k), v.map(escape_dep_env)))
.collect();
envs.sort_unstable();
writeln!(file)?;
for (k, v) in envs {
write!(file, "# env-dep:{k}")?;
if let Some(v) = v {
write!(file, "={v}")?;
}
writeln!(file)?;
}
}
// If caller requested this information, add special comments about source file checksums.
// These are not necessarily the same checksums as was used in the debug files.
if sess.opts.unstable_opts.checksum_hash_algorithm().is_some() {
files
.iter()
.filter_map(|(path, file_len, hash_algo)| {
hash_algo.map(|hash_algo| (path, file_len, hash_algo))
})
.try_for_each(|(path, file_len, checksum_hash)| {
writeln!(file, "# checksum:{checksum_hash} file_len:{file_len} {path}")
})?;
}
Ok(())
};
match deps_output {
OutFileName::Stdout => {
let mut file = BufWriter::new(io::stdout());
write_deps_to_file(&mut file)?;
}
OutFileName::Real(ref path) => {
let mut file = fs::File::create_buffered(path)?;
write_deps_to_file(&mut file)?;
}
}
};
match result {
Ok(_) => {
if sess.opts.json_artifact_notifications {
sess.dcx().emit_artifact_notification(deps_filename, "dep-info");
}
}
Err(error) => {
sess.dcx().emit_fatal(errors::ErrorWritingDependencies { path: deps_filename, error });
}
}
}
fn resolver_for_lowering_raw<'tcx>(
tcx: TyCtxt<'tcx>,
(): (),
) -> (&'tcx Steal<(ty::ResolverAstLowering, Lrc<ast::Crate>)>, &'tcx ty::ResolverGlobalCtxt) {
let arenas = Resolver::arenas();
let _ = tcx.registered_tools(()); // Uses `crate_for_resolver`.
let (krate, pre_configured_attrs) = tcx.crate_for_resolver(()).steal();
let mut resolver = Resolver::new(
tcx,
&pre_configured_attrs,
krate.spans.inner_span,
krate.spans.inject_use_span,
&arenas,
);
let krate = configure_and_expand(krate, &pre_configured_attrs, &mut resolver);
// Make sure we don't mutate the cstore from here on.
tcx.untracked().cstore.freeze();
let ty::ResolverOutputs {
global_ctxt: untracked_resolutions,
ast_lowering: untracked_resolver_for_lowering,
} = resolver.into_outputs();
let resolutions = tcx.arena.alloc(untracked_resolutions);
(tcx.arena.alloc(Steal::new((untracked_resolver_for_lowering, Lrc::new(krate)))), resolutions)
}
pub fn write_dep_info(tcx: TyCtxt<'_>) {
// Make sure name resolution and macro expansion is run for
// the side-effect of providing a complete set of all
// accessed files and env vars.
let _ = tcx.resolver_for_lowering();
let sess = tcx.sess;
let _timer = sess.timer("write_dep_info");
let crate_name = tcx.crate_name(LOCAL_CRATE);
let outputs = tcx.output_filenames(());
let output_paths =
generated_output_paths(tcx, &outputs, sess.io.output_file.is_some(), crate_name);
// Ensure the source file isn't accidentally overwritten during compilation.
if let Some(input_path) = sess.io.input.opt_path() {
if sess.opts.will_create_output_file() {
if output_contains_path(&output_paths, input_path) {
sess.dcx().emit_fatal(errors::InputFileWouldBeOverWritten { path: input_path });
}
if let Some(dir_path) = output_conflicts_with_dir(&output_paths) {
sess.dcx().emit_fatal(errors::GeneratedFileConflictsWithDirectory {
input_path,
dir_path,
});
}
}
}
if let Some(ref dir) = sess.io.temps_dir {
if fs::create_dir_all(dir).is_err() {
sess.dcx().emit_fatal(errors::TempsDirError);
}
}
write_out_deps(tcx, &outputs, &output_paths);
let only_dep_info = sess.opts.output_types.contains_key(&OutputType::DepInfo)
&& sess.opts.output_types.len() == 1;
if !only_dep_info {
if let Some(ref dir) = sess.io.output_dir {
if fs::create_dir_all(dir).is_err() {
sess.dcx().emit_fatal(errors::OutDirError);
}
}
}
}
pub static DEFAULT_QUERY_PROVIDERS: LazyLock<Providers> = LazyLock::new(|| {
let providers = &mut Providers::default();
providers.analysis = analysis;
providers.hir_crate = rustc_ast_lowering::lower_to_hir;
providers.resolver_for_lowering_raw = resolver_for_lowering_raw;
providers.stripped_cfg_items =
|tcx, _| tcx.arena.alloc_from_iter(tcx.resolutions(()).stripped_cfg_items.steal());
providers.resolutions = |tcx, ()| tcx.resolver_for_lowering_raw(()).1;
providers.early_lint_checks = early_lint_checks;
proc_macro_decls::provide(providers);
rustc_const_eval::provide(providers);
rustc_middle::hir::provide(providers);
rustc_borrowck::provide(providers);
rustc_mir_build::provide(providers);
rustc_mir_transform::provide(providers);
rustc_monomorphize::provide(providers);
rustc_privacy::provide(providers);
rustc_resolve::provide(providers);
rustc_hir_analysis::provide(providers);
rustc_hir_typeck::provide(providers);
ty::provide(providers);
traits::provide(providers);
rustc_passes::provide(providers);
rustc_traits::provide(providers);
rustc_ty_utils::provide(providers);
rustc_metadata::provide(providers);
rustc_lint::provide(providers);
rustc_symbol_mangling::provide(providers);
rustc_codegen_ssa::provide(providers);
*providers
});
pub(crate) fn create_global_ctxt<'tcx>(
compiler: &'tcx Compiler,
mut krate: rustc_ast::Crate,
gcx_cell: &'tcx OnceLock<GlobalCtxt<'tcx>>,
arena: &'tcx WorkerLocal<Arena<'tcx>>,
hir_arena: &'tcx WorkerLocal<rustc_hir::Arena<'tcx>>,
) -> Result<&'tcx GlobalCtxt<'tcx>> {
let sess = &compiler.sess;
rustc_builtin_macros::cmdline_attrs::inject(
&mut krate,
&sess.psess,
&sess.opts.unstable_opts.crate_attr,
);
let pre_configured_attrs = rustc_expand::config::pre_configure_attrs(sess, &krate.attrs);
// parse `#[crate_name]` even if `--crate-name` was passed, to make sure it matches.
let crate_name = find_crate_name(sess, &pre_configured_attrs);
let crate_types = collect_crate_types(sess, &pre_configured_attrs);
let stable_crate_id = StableCrateId::new(
crate_name,
crate_types.contains(&CrateType::Executable),
sess.opts.cg.metadata.clone(),
sess.cfg_version,
);
let outputs = util::build_output_filenames(&pre_configured_attrs, sess);
let dep_graph = setup_dep_graph(sess)?;
let cstore =
FreezeLock::new(Box::new(CStore::new(compiler.codegen_backend.metadata_loader())) as _);
let definitions = FreezeLock::new(Definitions::new(stable_crate_id));
let stable_crate_ids = FreezeLock::new(StableCrateIdMap::default());
let untracked =
Untracked { cstore, source_span: AppendOnlyIndexVec::new(), definitions, stable_crate_ids };
// We're constructing the HIR here; we don't care what we will
// read, since we haven't even constructed the *input* to
// incr. comp. yet.
dep_graph.assert_ignored();
let query_result_on_disk_cache = rustc_incremental::load_query_result_cache(sess);
let codegen_backend = &compiler.codegen_backend;
let mut providers = *DEFAULT_QUERY_PROVIDERS;
codegen_backend.provide(&mut providers);
if let Some(callback) = compiler.override_queries {
callback(sess, &mut providers);
}
let incremental = dep_graph.is_fully_enabled();
sess.time("setup_global_ctxt", || {
let qcx = gcx_cell.get_or_init(move || {
TyCtxt::create_global_ctxt(
sess,
crate_types,
stable_crate_id,
arena,
hir_arena,
untracked,
dep_graph,
rustc_query_impl::query_callbacks(arena),
rustc_query_impl::query_system(
providers.queries,
providers.extern_queries,
query_result_on_disk_cache,
incremental,
),
providers.hooks,
compiler.current_gcx.clone(),
)
});
qcx.enter(|tcx| {
let feed = tcx.create_crate_num(stable_crate_id).unwrap();
assert_eq!(feed.key(), LOCAL_CRATE);
feed.crate_name(crate_name);
let feed = tcx.feed_unit_query();
feed.features_query(tcx.arena.alloc(rustc_expand::config::features(
sess,
&pre_configured_attrs,
crate_name,
)));
feed.crate_for_resolver(tcx.arena.alloc(Steal::new((krate, pre_configured_attrs))));
feed.output_filenames(Arc::new(outputs));
});
Ok(qcx)
})
}
/// Runs all analyses that we guarantee to run, even if errors were reported in earlier analyses.
/// This function never fails.
fn run_required_analyses(tcx: TyCtxt<'_>) {
if tcx.sess.opts.unstable_opts.hir_stats {
rustc_passes::hir_stats::print_hir_stats(tcx);
}
#[cfg(debug_assertions)]
rustc_passes::hir_id_validator::check_crate(tcx);
let sess = tcx.sess;
sess.time("misc_checking_1", || {
parallel!(
{
sess.time("looking_for_entry_point", || tcx.ensure().entry_fn(()));
sess.time("looking_for_derive_registrar", || {
tcx.ensure().proc_macro_decls_static(())
});
CStore::from_tcx(tcx).report_unused_deps(tcx);
},
{
tcx.hir().par_for_each_module(|module| {
tcx.ensure().check_mod_loops(module);
tcx.ensure().check_mod_attrs(module);
tcx.ensure().check_mod_naked_functions(module);
tcx.ensure().check_mod_unstable_api_usage(module);
tcx.ensure().check_mod_const_bodies(module);
});
},
{
sess.time("unused_lib_feature_checking", || {
rustc_passes::stability::check_unused_or_stable_features(tcx)
});
},
{
// We force these queries to run,
// since they might not otherwise get called.
// This marks the corresponding crate-level attributes
// as used, and ensures that their values are valid.
tcx.ensure().limits(());
tcx.ensure().stability_index(());
}
);
});
rustc_hir_analysis::check_crate(tcx);
sess.time("MIR_coroutine_by_move_body", || {
tcx.hir().par_body_owners(|def_id| {
if tcx.needs_coroutine_by_move_body_def_id(def_id.to_def_id()) {
tcx.ensure_with_value().coroutine_by_move_body_def_id(def_id);
}
});
});
// Freeze definitions as we don't add new ones at this point.
// We need to wait until now since we synthesize a by-move body
// This improves performance by allowing lock-free access to them.
tcx.untracked().definitions.freeze();
sess.time("MIR_borrow_checking", || {
tcx.hir().par_body_owners(|def_id| {
// Run unsafety check because it's responsible for stealing and
// deallocating THIR.
tcx.ensure().check_unsafety(def_id);
tcx.ensure().mir_borrowck(def_id)
});
});
sess.time("MIR_effect_checking", || {
for def_id in tcx.hir().body_owners() {
tcx.ensure().has_ffi_unwind_calls(def_id);
// If we need to codegen, ensure that we emit all errors from
// `mir_drops_elaborated_and_const_checked` now, to avoid discovering
// them later during codegen.
if tcx.sess.opts.output_types.should_codegen()
|| tcx.hir().body_const_context(def_id).is_some()
{
tcx.ensure().mir_drops_elaborated_and_const_checked(def_id);
tcx.ensure().unused_generic_params(ty::InstanceKind::Item(def_id.to_def_id()));
}
}
});
tcx.hir().par_body_owners(|def_id| {
if tcx.is_coroutine(def_id.to_def_id()) {
tcx.ensure().mir_coroutine_witnesses(def_id);
tcx.ensure().check_coroutine_obligations(
tcx.typeck_root_def_id(def_id.to_def_id()).expect_local(),
);
}
});
sess.time("layout_testing", || layout_test::test_layout(tcx));
sess.time("abi_testing", || abi_test::test_abi(tcx));
// If `-Zvalidate-mir` is set, we also want to compute the final MIR for each item
// (either its `mir_for_ctfe` or `optimized_mir`) since that helps uncover any bugs
// in MIR optimizations that may only be reachable through codegen, or other codepaths
// that requires the optimized/ctfe MIR, such as polymorphization, coroutine bodies,
// or evaluating consts.
if tcx.sess.opts.unstable_opts.validate_mir {
sess.time("ensuring_final_MIR_is_computable", || {
tcx.hir().par_body_owners(|def_id| {
tcx.instance_mir(ty::InstanceKind::Item(def_id.into()));
});
});
}
}
/// Runs the type-checking, region checking and other miscellaneous analysis
/// passes on the crate.
fn analysis(tcx: TyCtxt<'_>, (): ()) -> Result<()> {
run_required_analyses(tcx);
let sess = tcx.sess;
// Avoid overwhelming user with errors if borrow checking failed.
// I'm not sure how helpful this is, to be honest, but it avoids a
// lot of annoying errors in the ui tests (basically,
// lint warnings and so on -- kindck used to do this abort, but
// kindck is gone now). -nmatsakis
//
// But we exclude lint errors from this, because lint errors are typically
// less serious and we're more likely to want to continue (#87337).
if let Some(guar) = sess.dcx().has_errors_excluding_lint_errors() {
return Err(guar);
}
sess.time("misc_checking_3", || {
parallel!(
{
tcx.ensure().effective_visibilities(());
parallel!(
{
tcx.ensure().check_private_in_public(());
},
{
tcx.hir()
.par_for_each_module(|module| tcx.ensure().check_mod_deathness(module));
},
{
sess.time("lint_checking", || {
rustc_lint::check_crate(tcx);
});
},
{
tcx.ensure().clashing_extern_declarations(());
}
);
},
{
sess.time("privacy_checking_modules", || {
tcx.hir().par_for_each_module(|module| {
tcx.ensure().check_mod_privacy(module);
});
});
}
);
// This check has to be run after all lints are done processing. We don't
// define a lint filter, as all lint checks should have finished at this point.
sess.time("check_lint_expectations", || tcx.ensure().check_expectations(None));
// This query is only invoked normally if a diagnostic is emitted that needs any
// diagnostic item. If the crate compiles without checking any diagnostic items,
// we will fail to emit overlap diagnostics. Thus we invoke it here unconditionally.
let _ = tcx.all_diagnostic_items(());
});
if sess.opts.unstable_opts.print_vtable_sizes {
let traits = tcx.traits(LOCAL_CRATE);
for &tr in traits {
if !tcx.is_dyn_compatible(tr) {
continue;
}
let name = ty::print::with_no_trimmed_paths!(tcx.def_path_str(tr));
let mut first_dsa = true;
// Number of vtable entries, if we didn't have upcasting
let mut entries_ignoring_upcasting = 0;
// Number of vtable entries needed solely for upcasting
let mut entries_for_upcasting = 0;
let trait_ref = ty::Binder::dummy(ty::TraitRef::identity(tcx, tr));
// A slightly edited version of the code in
// `rustc_trait_selection::traits::vtable::vtable_entries`, that works without self
// type and just counts number of entries.
//
// Note that this is technically wrong, for traits which have associated types in
// supertraits:
//
// trait A: AsRef<Self::T> + AsRef<()> { type T; }
//
// Without self type we can't normalize `Self::T`, so we can't know if `AsRef<Self::T>`
// and `AsRef<()>` are the same trait, thus we assume that those are different, and
// potentially over-estimate how many vtable entries there are.
//
// Similarly this is wrong for traits that have methods with possibly-impossible bounds.
// For example:
//
// trait B<T> { fn f(&self) where T: Copy; }
//
// Here `dyn B<u8>` will have 4 entries, while `dyn B<String>` will only have 3.
// However, since we don't know `T`, we can't know if `T: Copy` holds or not,
// thus we lean on the bigger side and say it has 4 entries.
traits::vtable::prepare_vtable_segments(tcx, trait_ref, |segment| {
match segment {
traits::vtable::VtblSegment::MetadataDSA => {
// If this is the first dsa, it would be included either way,
// otherwise it's needed for upcasting
if std::mem::take(&mut first_dsa) {
entries_ignoring_upcasting += 3;
} else {
entries_for_upcasting += 3;
}
}
traits::vtable::VtblSegment::TraitOwnEntries { trait_ref, emit_vptr } => {
// Lookup the shape of vtable for the trait.
let own_existential_entries =
tcx.own_existential_vtable_entries(trait_ref.def_id());
// The original code here ignores the method if its predicates are
// impossible. We can't really do that as, for example, all not trivial
// bounds on generic parameters are impossible (since we don't know the
// parameters...), see the comment above.
entries_ignoring_upcasting += own_existential_entries.len();
if emit_vptr {
entries_for_upcasting += 1;
}
}
}
std::ops::ControlFlow::Continue::<std::convert::Infallible>(())
});
sess.code_stats.record_vtable_size(tr, &name, VTableSizeInfo {
trait_name: name.clone(),
entries: entries_ignoring_upcasting + entries_for_upcasting,
entries_ignoring_upcasting,
entries_for_upcasting,
upcasting_cost_percent: entries_for_upcasting as f64
/ entries_ignoring_upcasting as f64
* 100.,
})
}
}
Ok(())
}
/// Check for the `#[rustc_error]` annotation, which forces an error in codegen. This is used
/// to write UI tests that actually test that compilation succeeds without reporting
/// an error.
fn check_for_rustc_errors_attr(tcx: TyCtxt<'_>) {
let Some((def_id, _)) = tcx.entry_fn(()) else { return };
for attr in tcx.get_attrs(def_id, sym::rustc_error) {
match attr.meta_item_list() {
// Check if there is a `#[rustc_error(delayed_bug_from_inside_query)]`.
Some(list)
if list.iter().any(|list_item| {
matches!(
list_item.ident().map(|i| i.name),
Some(sym::delayed_bug_from_inside_query)
)
}) =>
{
tcx.ensure().trigger_delayed_bug(def_id);
}
// Bare `#[rustc_error]`.
None => {
tcx.dcx().emit_fatal(errors::RustcErrorFatal { span: tcx.def_span(def_id) });
}
// Some other attribute.
Some(_) => {
tcx.dcx().emit_warn(errors::RustcErrorUnexpectedAnnotation {
span: tcx.def_span(def_id),
});
}
}
}
}
/// Runs the codegen backend, after which the AST and analysis can
/// be discarded.
pub(crate) fn start_codegen<'tcx>(
codegen_backend: &dyn CodegenBackend,
tcx: TyCtxt<'tcx>,
) -> Result<Box<dyn Any>> {
// Don't do code generation if there were any errors. Likewise if
// there were any delayed bugs, because codegen will likely cause
// more ICEs, obscuring the original problem.
if let Some(guar) = tcx.sess.dcx().has_errors_or_delayed_bugs() {
return Err(guar);
}
// Hook for UI tests.
check_for_rustc_errors_attr(tcx);
info!("Pre-codegen\n{:?}", tcx.debug_stats());
let (metadata, need_metadata_module) = rustc_metadata::fs::encode_and_write_metadata(tcx);
let codegen = tcx.sess.time("codegen_crate", move || {
codegen_backend.codegen_crate(tcx, metadata, need_metadata_module)
});
// Don't run this test assertions when not doing codegen. Compiletest tries to build
// build-fail tests in check mode first and expects it to not give an error in that case.
if tcx.sess.opts.output_types.should_codegen() {
rustc_symbol_mangling::test::report_symbol_names(tcx);
}
info!("Post-codegen\n{:?}", tcx.debug_stats());
if tcx.sess.opts.output_types.contains_key(&OutputType::Mir) {
if let Err(error) = rustc_mir_transform::dump_mir::emit_mir(tcx) {
tcx.dcx().emit_fatal(errors::CantEmitMIR { error });
}
}
Ok(codegen)
}
fn get_recursion_limit(krate_attrs: &[ast::Attribute], sess: &Session) -> Limit {
if let Some(attr) = krate_attrs
.iter()
.find(|attr| attr.has_name(sym::recursion_limit) && attr.value_str().is_none())
{
// This is here mainly to check for using a macro, such as
// #![recursion_limit = foo!()]. That is not supported since that
// would require expanding this while in the middle of expansion,
// which needs to know the limit before expanding. Otherwise,
// validation would normally be caught in AstValidator (via
// `check_builtin_attribute`), but by the time that runs the macro
// is expanded, and it doesn't give an error.
validate_attr::emit_fatal_malformed_builtin_attribute(
&sess.psess,
attr,
sym::recursion_limit,
);
}
rustc_middle::middle::limits::get_recursion_limit(krate_attrs, sess)
}