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chromium / external / github.com / rust-lang / rust / e957ed9d10ec589bdd523b88b4b44c41b1ecf763 / . / src / librustc / session / mod.rs
blob: d2beb64b3886146001c860b42cc91671d611358b [file] [log] [blame]
pub use self::code_stats::{DataTypeKind, SizeKind, FieldInfo, VariantInfo};
use self::code_stats::CodeStats;
use crate::dep_graph::cgu_reuse_tracker::CguReuseTracker;
use crate::hir::def_id::CrateNum;
use rustc_data_structures::fingerprint::Fingerprint;
use crate::lint;
use crate::lint::builtin::BuiltinLintDiagnostics;
use crate::middle::allocator::AllocatorKind;
use crate::middle::dependency_format;
use crate::session::config::{OutputType, Lto};
use crate::session::search_paths::{PathKind, SearchPath};
use crate::util::nodemap::{FxHashMap, FxHashSet};
use crate::util::common::{duration_to_secs_str, ErrorReported};
use crate::util::common::ProfileQueriesMsg;
use rustc_data_structures::base_n;
use rustc_data_structures::sync::{
self, Lrc, Lock, OneThread, Once, RwLock, AtomicU64, AtomicUsize, Ordering,
Ordering::SeqCst,
};
use crate::errors::{self, DiagnosticBuilder, DiagnosticId, Applicability};
use crate::errors::emitter::{Emitter, EmitterWriter};
use syntax::ast::{self, NodeId};
use syntax::edition::Edition;
use syntax::feature_gate::{self, AttributeType};
use syntax::json::JsonEmitter;
use syntax::source_map;
use syntax::parse::{self, ParseSess};
use syntax_pos::{MultiSpan, Span};
use crate::util::profiling::SelfProfiler;
use rustc_target::spec::{PanicStrategy, RelroLevel, Target, TargetTriple};
use rustc_data_structures::flock;
use jobserver::Client;
use std;
use std::cell::{self, Cell, RefCell};
use std::env;
use std::fmt;
use std::io::Write;
use std::path::PathBuf;
use std::time::Duration;
use std::sync::mpsc;
mod code_stats;
pub mod config;
pub mod filesearch;
pub mod search_paths;
pub struct OptimizationFuel {
/// If -zfuel=crate=n is specified, initially set to n. Otherwise 0.
remaining: u64,
/// We're rejecting all further optimizations.
out_of_fuel: bool,
}
/// Represents the data associated with a compilation
/// session for a single crate.
pub struct Session {
pub target: config::Config,
pub host: Target,
pub opts: config::Options,
pub host_tlib_path: SearchPath,
/// This is `None` if the host and target are the same.
pub target_tlib_path: Option<SearchPath>,
pub parse_sess: ParseSess,
pub sysroot: PathBuf,
/// The name of the root source file of the crate, in the local file system.
/// `None` means that there is no source file.
pub local_crate_source_file: Option<PathBuf>,
/// The directory the compiler has been executed in plus a flag indicating
/// if the value stored here has been affected by path remapping.
pub working_dir: (PathBuf, bool),
// FIXME: lint_store and buffered_lints are not thread-safe,
// but are only used in a single thread
pub lint_store: RwLock<lint::LintStore>,
pub buffered_lints: Lock<Option<lint::LintBuffer>>,
/// Set of (DiagnosticId, Option<Span>, message) tuples tracking
/// (sub)diagnostics that have been set once, but should not be set again,
/// in order to avoid redundantly verbose output (Issue #24690, #44953).
pub one_time_diagnostics: Lock<FxHashSet<(DiagnosticMessageId, Option<Span>, String)>>,
pub plugin_llvm_passes: OneThread<RefCell<Vec<String>>>,
pub plugin_attributes: OneThread<RefCell<Vec<(String, AttributeType)>>>,
pub crate_types: Once<Vec<config::CrateType>>,
pub dependency_formats: Once<dependency_format::Dependencies>,
/// The crate_disambiguator is constructed out of all the `-C metadata`
/// arguments passed to the compiler. Its value together with the crate-name
/// forms a unique global identifier for the crate. It is used to allow
/// multiple crates with the same name to coexist. See the
/// rustc_codegen_llvm::back::symbol_names module for more information.
pub crate_disambiguator: Once<CrateDisambiguator>,
features: Once<feature_gate::Features>,
/// The maximum recursion limit for potentially infinitely recursive
/// operations such as auto-dereference and monomorphization.
pub recursion_limit: Once<usize>,
/// The maximum length of types during monomorphization.
pub type_length_limit: Once<usize>,
/// The maximum number of stackframes allowed in const eval
pub const_eval_stack_frame_limit: usize,
/// The metadata::creader module may inject an allocator/panic_runtime
/// dependency if it didn't already find one, and this tracks what was
/// injected.
pub allocator_kind: Once<Option<AllocatorKind>>,
pub injected_panic_runtime: Once<Option<CrateNum>>,
/// Map from imported macro spans (which consist of
/// the localized span for the macro body) to the
/// macro name and definition span in the source crate.
pub imported_macro_spans: OneThread<RefCell<FxHashMap<Span, (String, Span)>>>,
incr_comp_session: OneThread<RefCell<IncrCompSession>>,
/// Used for incremental compilation tests. Will only be populated if
/// `-Zquery-dep-graph` is specified.
pub cgu_reuse_tracker: CguReuseTracker,
/// Used by -Z profile-queries in util::common
pub profile_channel: Lock<Option<mpsc::Sender<ProfileQueriesMsg>>>,
/// Used by -Z self-profile
pub self_profiling_active: bool,
/// Used by -Z self-profile
pub self_profiling: Lock<SelfProfiler>,
/// Some measurements that are being gathered during compilation.
pub perf_stats: PerfStats,
/// Data about code being compiled, gathered during compilation.
pub code_stats: Lock<CodeStats>,
next_node_id: OneThread<Cell<ast::NodeId>>,
/// If -zfuel=crate=n is specified, Some(crate).
optimization_fuel_crate: Option<String>,
/// Tracks fuel info if If -zfuel=crate=n is specified
optimization_fuel: Lock<OptimizationFuel>,
// The next two are public because the driver needs to read them.
/// If -zprint-fuel=crate, Some(crate).
pub print_fuel_crate: Option<String>,
/// Always set to zero and incremented so that we can print fuel expended by a crate.
pub print_fuel: AtomicU64,
/// Loaded up early on in the initialization of this `Session` to avoid
/// false positives about a job server in our environment.
pub jobserver: Client,
/// Metadata about the allocators for the current crate being compiled
pub has_global_allocator: Once<bool>,
/// Metadata about the panic handlers for the current crate being compiled
pub has_panic_handler: Once<bool>,
/// Cap lint level specified by a driver specifically.
pub driver_lint_caps: FxHashMap<lint::LintId, lint::Level>,
}
pub struct PerfStats {
/// The accumulated time spent on computing symbol hashes
pub symbol_hash_time: Lock<Duration>,
/// The accumulated time spent decoding def path tables from metadata
pub decode_def_path_tables_time: Lock<Duration>,
/// Total number of values canonicalized queries constructed.
pub queries_canonicalized: AtomicUsize,
/// Number of times this query is invoked.
pub normalize_ty_after_erasing_regions: AtomicUsize,
/// Number of times this query is invoked.
pub normalize_projection_ty: AtomicUsize,
}
/// Enum to support dispatch of one-time diagnostics (in Session.diag_once)
enum DiagnosticBuilderMethod {
Note,
SpanNote,
SpanSuggestion(String), // suggestion
// add more variants as needed to support one-time diagnostics
}
/// Diagnostic message ID—used by `Session.one_time_diagnostics` to avoid
/// emitting the same message more than once
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub enum DiagnosticMessageId {
ErrorId(u16), // EXXXX error code as integer
LintId(lint::LintId),
StabilityId(u32), // issue number
}
impl From<&'static lint::Lint> for DiagnosticMessageId {
fn from(lint: &'static lint::Lint) -> Self {
DiagnosticMessageId::LintId(lint::LintId::of(lint))
}
}
impl Session {
pub fn local_crate_disambiguator(&self) -> CrateDisambiguator {
*self.crate_disambiguator.get()
}
pub fn struct_span_warn<'a, S: Into<MultiSpan>>(
&'a self,
sp: S,
msg: &str,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_span_warn(sp, msg)
}
pub fn struct_span_warn_with_code<'a, S: Into<MultiSpan>>(
&'a self,
sp: S,
msg: &str,
code: DiagnosticId,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_span_warn_with_code(sp, msg, code)
}
pub fn struct_warn<'a>(&'a self, msg: &str) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_warn(msg)
}
pub fn struct_span_err<'a, S: Into<MultiSpan>>(
&'a self,
sp: S,
msg: &str,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_span_err(sp, msg)
}
pub fn struct_span_err_with_code<'a, S: Into<MultiSpan>>(
&'a self,
sp: S,
msg: &str,
code: DiagnosticId,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_span_err_with_code(sp, msg, code)
}
// FIXME: This method should be removed (every error should have an associated error code).
pub fn struct_err<'a>(&'a self, msg: &str) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_err(msg)
}
pub fn struct_err_with_code<'a>(
&'a self,
msg: &str,
code: DiagnosticId,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_err_with_code(msg, code)
}
pub fn struct_span_fatal<'a, S: Into<MultiSpan>>(
&'a self,
sp: S,
msg: &str,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_span_fatal(sp, msg)
}
pub fn struct_span_fatal_with_code<'a, S: Into<MultiSpan>>(
&'a self,
sp: S,
msg: &str,
code: DiagnosticId,
) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_span_fatal_with_code(sp, msg, code)
}
pub fn struct_fatal<'a>(&'a self, msg: &str) -> DiagnosticBuilder<'a> {
self.diagnostic().struct_fatal(msg)
}
pub fn span_fatal<S: Into<MultiSpan>>(&self, sp: S, msg: &str) -> ! {
self.diagnostic().span_fatal(sp, msg).raise()
}
pub fn span_fatal_with_code<S: Into<MultiSpan>>(
&self,
sp: S,
msg: &str,
code: DiagnosticId,
) -> ! {
self.diagnostic()
.span_fatal_with_code(sp, msg, code)
.raise()
}
pub fn fatal(&self, msg: &str) -> ! {
self.diagnostic().fatal(msg).raise()
}
pub fn span_err_or_warn<S: Into<MultiSpan>>(&self, is_warning: bool, sp: S, msg: &str) {
if is_warning {
self.span_warn(sp, msg);
} else {
self.span_err(sp, msg);
}
}
pub fn span_err<S: Into<MultiSpan>>(&self, sp: S, msg: &str) {
self.diagnostic().span_err(sp, msg)
}
pub fn span_err_with_code<S: Into<MultiSpan>>(&self, sp: S, msg: &str, code: DiagnosticId) {
self.diagnostic().span_err_with_code(sp, &msg, code)
}
pub fn err(&self, msg: &str) {
self.diagnostic().err(msg)
}
pub fn err_count(&self) -> usize {
self.diagnostic().err_count()
}
pub fn has_errors(&self) -> bool {
self.diagnostic().has_errors()
}
pub fn abort_if_errors(&self) {
self.diagnostic().abort_if_errors();
}
pub fn compile_status(&self) -> Result<(), CompileIncomplete> {
compile_result_from_err_count(self.err_count())
}
pub fn track_errors<F, T>(&self, f: F) -> Result<T, ErrorReported>
where
F: FnOnce() -> T,
{
let old_count = self.err_count();
let result = f();
let errors = self.err_count() - old_count;
if errors == 0 {
Ok(result)
} else {
Err(ErrorReported)
}
}
pub fn span_warn<S: Into<MultiSpan>>(&self, sp: S, msg: &str) {
self.diagnostic().span_warn(sp, msg)
}
pub fn span_warn_with_code<S: Into<MultiSpan>>(&self, sp: S, msg: &str, code: DiagnosticId) {
self.diagnostic().span_warn_with_code(sp, msg, code)
}
pub fn warn(&self, msg: &str) {
self.diagnostic().warn(msg)
}
pub fn opt_span_warn<S: Into<MultiSpan>>(&self, opt_sp: Option<S>, msg: &str) {
match opt_sp {
Some(sp) => self.span_warn(sp, msg),
None => self.warn(msg),
}
}
/// Delay a span_bug() call until abort_if_errors()
pub fn delay_span_bug<S: Into<MultiSpan>>(&self, sp: S, msg: &str) {
self.diagnostic().delay_span_bug(sp, msg)
}
pub fn note_without_error(&self, msg: &str) {
self.diagnostic().note_without_error(msg)
}
pub fn span_note_without_error<S: Into<MultiSpan>>(&self, sp: S, msg: &str) {
self.diagnostic().span_note_without_error(sp, msg)
}
pub fn span_unimpl<S: Into<MultiSpan>>(&self, sp: S, msg: &str) -> ! {
self.diagnostic().span_unimpl(sp, msg)
}
pub fn unimpl(&self, msg: &str) -> ! {
self.diagnostic().unimpl(msg)
}
pub fn buffer_lint<S: Into<MultiSpan>>(
&self,
lint: &'static lint::Lint,
id: ast::NodeId,
sp: S,
msg: &str,
) {
match *self.buffered_lints.borrow_mut() {
Some(ref mut buffer) => {
buffer.add_lint(lint, id, sp.into(), msg, BuiltinLintDiagnostics::Normal)
}
None => bug!("can't buffer lints after HIR lowering"),
}
}
pub fn buffer_lint_with_diagnostic<S: Into<MultiSpan>>(
&self,
lint: &'static lint::Lint,
id: ast::NodeId,
sp: S,
msg: &str,
diagnostic: BuiltinLintDiagnostics,
) {
match *self.buffered_lints.borrow_mut() {
Some(ref mut buffer) => buffer.add_lint(lint, id, sp.into(), msg, diagnostic),
None => bug!("can't buffer lints after HIR lowering"),
}
}
pub fn reserve_node_ids(&self, count: usize) -> ast::NodeId {
let id = self.next_node_id.get();
match id.as_usize().checked_add(count) {
Some(next) => {
self.next_node_id.set(ast::NodeId::from_usize(next));
}
None => bug!("Input too large, ran out of node ids!"),
}
id
}
pub fn next_node_id(&self) -> NodeId {
self.reserve_node_ids(1)
}
pub(crate) fn current_node_id_count(&self) -> usize {
self.next_node_id.get().as_u32() as usize
}
pub fn diagnostic<'a>(&'a self) -> &'a errors::Handler {
&self.parse_sess.span_diagnostic
}
/// Analogous to calling methods on the given `DiagnosticBuilder`, but
/// deduplicates on lint ID, span (if any), and message for this `Session`
fn diag_once<'a, 'b>(
&'a self,
diag_builder: &'b mut DiagnosticBuilder<'a>,
method: DiagnosticBuilderMethod,
msg_id: DiagnosticMessageId,
message: &str,
span_maybe: Option<Span>,
) {
let id_span_message = (msg_id, span_maybe, message.to_owned());
let fresh = self.one_time_diagnostics
.borrow_mut()
.insert(id_span_message);
if fresh {
match method {
DiagnosticBuilderMethod::Note => {
diag_builder.note(message);
}
DiagnosticBuilderMethod::SpanNote => {
let span = span_maybe.expect("span_note needs a span");
diag_builder.span_note(span, message);
}
DiagnosticBuilderMethod::SpanSuggestion(suggestion) => {
let span = span_maybe.expect("span_suggestion_* needs a span");
diag_builder.span_suggestion(
span,
message,
suggestion,
Applicability::Unspecified,
);
}
}
}
}
pub fn diag_span_note_once<'a, 'b>(
&'a self,
diag_builder: &'b mut DiagnosticBuilder<'a>,
msg_id: DiagnosticMessageId,
span: Span,
message: &str,
) {
self.diag_once(
diag_builder,
DiagnosticBuilderMethod::SpanNote,
msg_id,
message,
Some(span),
);
}
pub fn diag_note_once<'a, 'b>(
&'a self,
diag_builder: &'b mut DiagnosticBuilder<'a>,
msg_id: DiagnosticMessageId,
message: &str,
) {
self.diag_once(
diag_builder,
DiagnosticBuilderMethod::Note,
msg_id,
message,
None,
);
}
pub fn diag_span_suggestion_once<'a, 'b>(
&'a self,
diag_builder: &'b mut DiagnosticBuilder<'a>,
msg_id: DiagnosticMessageId,
span: Span,
message: &str,
suggestion: String,
) {
self.diag_once(
diag_builder,
DiagnosticBuilderMethod::SpanSuggestion(suggestion),
msg_id,
message,
Some(span),
);
}
pub fn source_map<'a>(&'a self) -> &'a source_map::SourceMap {
self.parse_sess.source_map()
}
pub fn verbose(&self) -> bool {
self.opts.debugging_opts.verbose
}
pub fn time_passes(&self) -> bool {
self.opts.debugging_opts.time_passes
}
pub fn profile_queries(&self) -> bool {
self.opts.debugging_opts.profile_queries
|| self.opts.debugging_opts.profile_queries_and_keys
}
pub fn profile_queries_and_keys(&self) -> bool {
self.opts.debugging_opts.profile_queries_and_keys
}
pub fn instrument_mcount(&self) -> bool {
self.opts.debugging_opts.instrument_mcount
}
pub fn count_llvm_insns(&self) -> bool {
self.opts.debugging_opts.count_llvm_insns
}
pub fn time_llvm_passes(&self) -> bool {
self.opts.debugging_opts.time_llvm_passes
}
pub fn codegen_stats(&self) -> bool {
self.opts.debugging_opts.codegen_stats
}
pub fn meta_stats(&self) -> bool {
self.opts.debugging_opts.meta_stats
}
pub fn asm_comments(&self) -> bool {
self.opts.debugging_opts.asm_comments
}
pub fn verify_llvm_ir(&self) -> bool {
self.opts.debugging_opts.verify_llvm_ir
|| cfg!(always_verify_llvm_ir)
}
pub fn borrowck_stats(&self) -> bool {
self.opts.debugging_opts.borrowck_stats
}
pub fn print_llvm_passes(&self) -> bool {
self.opts.debugging_opts.print_llvm_passes
}
/// Get the features enabled for the current compilation session.
/// DO NOT USE THIS METHOD if there is a TyCtxt available, as it circumvents
/// dependency tracking. Use tcx.features() instead.
#[inline]
pub fn features_untracked(&self) -> &feature_gate::Features {
self.features.get()
}
pub fn init_features(&self, features: feature_gate::Features) {
self.features.set(features);
}
/// Calculates the flavor of LTO to use for this compilation.
pub fn lto(&self) -> config::Lto {
// If our target has codegen requirements ignore the command line
if self.target.target.options.requires_lto {
return config::Lto::Fat;
}
// If the user specified something, return that. If they only said `-C
// lto` and we've for whatever reason forced off ThinLTO via the CLI,
// then ensure we can't use a ThinLTO.
match self.opts.cg.lto {
config::LtoCli::Unspecified => {
// The compiler was invoked without the `-Clto` flag. Fall
// through to the default handling
}
config::LtoCli::No => {
// The user explicitly opted out of any kind of LTO
return config::Lto::No;
}
config::LtoCli::Yes |
config::LtoCli::Fat |
config::LtoCli::NoParam => {
// All of these mean fat LTO
return config::Lto::Fat;
}
config::LtoCli::Thin => {
return if self.opts.cli_forced_thinlto_off {
config::Lto::Fat
} else {
config::Lto::Thin
};
}
}
// Ok at this point the target doesn't require anything and the user
// hasn't asked for anything. Our next decision is whether or not
// we enable "auto" ThinLTO where we use multiple codegen units and
// then do ThinLTO over those codegen units. The logic below will
// either return `No` or `ThinLocal`.
// If processing command line options determined that we're incompatible
// with ThinLTO (e.g., `-C lto --emit llvm-ir`) then return that option.
if self.opts.cli_forced_thinlto_off {
return config::Lto::No;
}
// If `-Z thinlto` specified process that, but note that this is mostly
// a deprecated option now that `-C lto=thin` exists.
if let Some(enabled) = self.opts.debugging_opts.thinlto {
if enabled {
return config::Lto::ThinLocal;
} else {
return config::Lto::No;
}
}
// If there's only one codegen unit and LTO isn't enabled then there's
// no need for ThinLTO so just return false.
if self.codegen_units() == 1 {
return config::Lto::No;
}
// Now we're in "defaults" territory. By default we enable ThinLTO for
// optimized compiles (anything greater than O0).
match self.opts.optimize {
config::OptLevel::No => config::Lto::No,
_ => config::Lto::ThinLocal,
}
}
/// Returns the panic strategy for this compile session. If the user explicitly selected one
/// using '-C panic', use that, otherwise use the panic strategy defined by the target.
pub fn panic_strategy(&self) -> PanicStrategy {
self.opts
.cg
.panic
.unwrap_or(self.target.target.options.panic_strategy)
}
pub fn fewer_names(&self) -> bool {
let more_names = self.opts
.output_types
.contains_key(&OutputType::LlvmAssembly)
|| self.opts.output_types.contains_key(&OutputType::Bitcode);
self.opts.debugging_opts.fewer_names || !more_names
}
pub fn no_landing_pads(&self) -> bool {
self.opts.debugging_opts.no_landing_pads || self.panic_strategy() == PanicStrategy::Abort
}
pub fn unstable_options(&self) -> bool {
self.opts.debugging_opts.unstable_options
}
pub fn overflow_checks(&self) -> bool {
self.opts
.cg
.overflow_checks
.or(self.opts.debugging_opts.force_overflow_checks)
.unwrap_or(self.opts.debug_assertions)
}
pub fn crt_static(&self) -> bool {
// If the target does not opt in to crt-static support, use its default.
if self.target.target.options.crt_static_respected {
self.crt_static_feature()
} else {
self.target.target.options.crt_static_default
}
}
pub fn crt_static_feature(&self) -> bool {
let requested_features = self.opts.cg.target_feature.split(',');
let found_negative = requested_features.clone().any(|r| r == "-crt-static");
let found_positive = requested_features.clone().any(|r| r == "+crt-static");
// If the target we're compiling for requests a static crt by default,
// then see if the `-crt-static` feature was passed to disable that.
// Otherwise if we don't have a static crt by default then see if the
// `+crt-static` feature was passed.
if self.target.target.options.crt_static_default {
!found_negative
} else {
found_positive
}
}
pub fn must_not_eliminate_frame_pointers(&self) -> bool {
// "mcount" function relies on stack pointer.
// See https://sourceware.org/binutils/docs/gprof/Implementation.html
if self.instrument_mcount() {
true
} else if let Some(x) = self.opts.cg.force_frame_pointers {
x
} else {
!self.target.target.options.eliminate_frame_pointer
}
}
/// Returns the symbol name for the registrar function,
/// given the crate Svh and the function DefIndex.
pub fn generate_plugin_registrar_symbol(&self, disambiguator: CrateDisambiguator) -> String {
format!(
"__rustc_plugin_registrar_{}__",
disambiguator.to_fingerprint().to_hex()
)
}
pub fn generate_proc_macro_decls_symbol(&self, disambiguator: CrateDisambiguator) -> String {
format!(
"__rustc_proc_macro_decls_{}__",
disambiguator.to_fingerprint().to_hex()
)
}
pub fn target_filesearch(&self, kind: PathKind) -> filesearch::FileSearch<'_> {
filesearch::FileSearch::new(
&self.sysroot,
self.opts.target_triple.triple(),
&self.opts.search_paths,
// target_tlib_path==None means it's the same as host_tlib_path.
self.target_tlib_path.as_ref().unwrap_or(&self.host_tlib_path),
kind,
)
}
pub fn host_filesearch(&self, kind: PathKind) -> filesearch::FileSearch<'_> {
filesearch::FileSearch::new(
&self.sysroot,
config::host_triple(),
&self.opts.search_paths,
&self.host_tlib_path,
kind,
)
}
pub fn set_incr_session_load_dep_graph(&self, load: bool) {
let mut incr_comp_session = self.incr_comp_session.borrow_mut();
if let IncrCompSession::Active { ref mut load_dep_graph, .. } = *incr_comp_session {
*load_dep_graph = load;
}
}
pub fn incr_session_load_dep_graph(&self) -> bool {
let incr_comp_session = self.incr_comp_session.borrow();
match *incr_comp_session {
IncrCompSession::Active { load_dep_graph, .. } => load_dep_graph,
_ => false,
}
}
pub fn init_incr_comp_session(
&self,
session_dir: PathBuf,
lock_file: flock::Lock,
load_dep_graph: bool,
) {
let mut incr_comp_session = self.incr_comp_session.borrow_mut();
if let IncrCompSession::NotInitialized = *incr_comp_session {
} else {
bug!(
"Trying to initialize IncrCompSession `{:?}`",
*incr_comp_session
)
}
*incr_comp_session = IncrCompSession::Active {
session_directory: session_dir,
lock_file,
load_dep_graph,
};
}
pub fn finalize_incr_comp_session(&self, new_directory_path: PathBuf) {
let mut incr_comp_session = self.incr_comp_session.borrow_mut();
if let IncrCompSession::Active { .. } = *incr_comp_session {
} else {
bug!(
"Trying to finalize IncrCompSession `{:?}`",
*incr_comp_session
)
}
// Note: This will also drop the lock file, thus unlocking the directory
*incr_comp_session = IncrCompSession::Finalized {
session_directory: new_directory_path,
};
}
pub fn mark_incr_comp_session_as_invalid(&self) {
let mut incr_comp_session = self.incr_comp_session.borrow_mut();
let session_directory = match *incr_comp_session {
IncrCompSession::Active {
ref session_directory,
..
} => session_directory.clone(),
IncrCompSession::InvalidBecauseOfErrors { .. } => return,
_ => bug!(
"Trying to invalidate IncrCompSession `{:?}`",
*incr_comp_session
),
};
// Note: This will also drop the lock file, thus unlocking the directory
*incr_comp_session = IncrCompSession::InvalidBecauseOfErrors { session_directory };
}
pub fn incr_comp_session_dir(&self) -> cell::Ref<'_, PathBuf> {
let incr_comp_session = self.incr_comp_session.borrow();
cell::Ref::map(
incr_comp_session,
|incr_comp_session| match *incr_comp_session {
IncrCompSession::NotInitialized => bug!(
"Trying to get session directory from IncrCompSession `{:?}`",
*incr_comp_session
),
IncrCompSession::Active {
ref session_directory,
..
}
| IncrCompSession::Finalized {
ref session_directory,
}
| IncrCompSession::InvalidBecauseOfErrors {
ref session_directory,
} => session_directory,
},
)
}
pub fn incr_comp_session_dir_opt(&self) -> Option<cell::Ref<'_, PathBuf>> {
if self.opts.incremental.is_some() {
Some(self.incr_comp_session_dir())
} else {
None
}
}
#[inline(never)]
#[cold]
fn profiler_active<F: FnOnce(&mut SelfProfiler) -> ()>(&self, f: F) {
let mut profiler = self.self_profiling.borrow_mut();
f(&mut profiler);
}
#[inline(always)]
pub fn profiler<F: FnOnce(&mut SelfProfiler) -> ()>(&self, f: F) {
if unlikely!(self.self_profiling_active) {
self.profiler_active(f)
}
}
pub fn print_profiler_results(&self) {
let mut profiler = self.self_profiling.borrow_mut();
profiler.print_results(&self.opts);
}
pub fn save_json_results(&self) {
let profiler = self.self_profiling.borrow();
profiler.save_results(&self.opts);
}
pub fn print_perf_stats(&self) {
println!(
"Total time spent computing symbol hashes: {}",
duration_to_secs_str(*self.perf_stats.symbol_hash_time.lock())
);
println!(
"Total time spent decoding DefPath tables: {}",
duration_to_secs_str(*self.perf_stats.decode_def_path_tables_time.lock())
);
println!("Total queries canonicalized: {}",
self.perf_stats.queries_canonicalized.load(Ordering::Relaxed));
println!("normalize_ty_after_erasing_regions: {}",
self.perf_stats.normalize_ty_after_erasing_regions.load(Ordering::Relaxed));
println!("normalize_projection_ty: {}",
self.perf_stats.normalize_projection_ty.load(Ordering::Relaxed));
}
/// We want to know if we're allowed to do an optimization for crate foo from -z fuel=foo=n.
/// This expends fuel if applicable, and records fuel if applicable.
pub fn consider_optimizing<T: Fn() -> String>(&self, crate_name: &str, msg: T) -> bool {
let mut ret = true;
if let Some(ref c) = self.optimization_fuel_crate {
if c == crate_name {
assert_eq!(self.threads(), 1);
let mut fuel = self.optimization_fuel.lock();
ret = fuel.remaining != 0;
if fuel.remaining == 0 && !fuel.out_of_fuel {
eprintln!("optimization-fuel-exhausted: {}", msg());
fuel.out_of_fuel = true;
} else if fuel.remaining > 0 {
fuel.remaining -= 1;
}
}
}
if let Some(ref c) = self.print_fuel_crate {
if c == crate_name {
assert_eq!(self.threads(), 1);
self.print_fuel.fetch_add(1, SeqCst);
}
}
ret
}
/// Returns the number of query threads that should be used for this
/// compilation
pub fn threads_from_opts(opts: &config::Options) -> usize {
opts.debugging_opts.threads.unwrap_or(::num_cpus::get())
}
/// Returns the number of query threads that should be used for this
/// compilation
pub fn threads(&self) -> usize {
Self::threads_from_opts(&self.opts)
}
/// Returns the number of codegen units that should be used for this
/// compilation
pub fn codegen_units(&self) -> usize {
if let Some(n) = self.opts.cli_forced_codegen_units {
return n;
}
if let Some(n) = self.target.target.options.default_codegen_units {
return n as usize;
}
// Why is 16 codegen units the default all the time?
//
// The main reason for enabling multiple codegen units by default is to
// leverage the ability for the codegen backend to do codegen and
// optimization in parallel. This allows us, especially for large crates, to
// make good use of all available resources on the machine once we've
// hit that stage of compilation. Large crates especially then often
// take a long time in codegen/optimization and this helps us amortize that
// cost.
//
// Note that a high number here doesn't mean that we'll be spawning a
// large number of threads in parallel. The backend of rustc contains
// global rate limiting through the `jobserver` crate so we'll never
// overload the system with too much work, but rather we'll only be
// optimizing when we're otherwise cooperating with other instances of
// rustc.
//
// Rather a high number here means that we should be able to keep a lot
// of idle cpus busy. By ensuring that no codegen unit takes *too* long
// to build we'll be guaranteed that all cpus will finish pretty closely
// to one another and we should make relatively optimal use of system
// resources
//
// Note that the main cost of codegen units is that it prevents LLVM
// from inlining across codegen units. Users in general don't have a lot
// of control over how codegen units are split up so it's our job in the
// compiler to ensure that undue performance isn't lost when using
// codegen units (aka we can't require everyone to slap `#[inline]` on
// everything).
//
// If we're compiling at `-O0` then the number doesn't really matter too
// much because performance doesn't matter and inlining is ok to lose.
// In debug mode we just want to try to guarantee that no cpu is stuck
// doing work that could otherwise be farmed to others.
//
// In release mode, however (O1 and above) performance does indeed
// matter! To recover the loss in performance due to inlining we'll be
// enabling ThinLTO by default (the function for which is just below).
// This will ensure that we recover any inlining wins we otherwise lost
// through codegen unit partitioning.
//
// ---
//
// Ok that's a lot of words but the basic tl;dr; is that we want a high
// number here -- but not too high. Additionally we're "safe" to have it
// always at the same number at all optimization levels.
//
// As a result 16 was chosen here! Mostly because it was a power of 2
// and most benchmarks agreed it was roughly a local optimum. Not very
// scientific.
16
}
pub fn teach(&self, code: &DiagnosticId) -> bool {
self.opts.debugging_opts.teach && self.diagnostic().must_teach(code)
}
pub fn rust_2015(&self) -> bool {
self.opts.edition == Edition::Edition2015
}
/// Are we allowed to use features from the Rust 2018 edition?
pub fn rust_2018(&self) -> bool {
self.opts.edition >= Edition::Edition2018
}
pub fn edition(&self) -> Edition {
self.opts.edition
}
/// True if we cannot skip the PLT for shared library calls.
pub fn needs_plt(&self) -> bool {
// Check if the current target usually needs PLT to be enabled.
// The user can use the command line flag to override it.
let needs_plt = self.target.target.options.needs_plt;
let dbg_opts = &self.opts.debugging_opts;
let relro_level = dbg_opts.relro_level
.unwrap_or(self.target.target.options.relro_level);
// Only enable this optimization by default if full relro is also enabled.
// In this case, lazy binding was already unavailable, so nothing is lost.
// This also ensures `-Wl,-z,now` is supported by the linker.
let full_relro = RelroLevel::Full == relro_level;
// If user didn't explicitly forced us to use / skip the PLT,
// then try to skip it where possible.
dbg_opts.plt.unwrap_or(needs_plt || !full_relro)
}
}
pub fn build_session(
sopts: config::Options,
local_crate_source_file: Option<PathBuf>,
registry: errors::registry::Registry,
) -> Session {
let file_path_mapping = sopts.file_path_mapping();
build_session_with_source_map(
sopts,
local_crate_source_file,
registry,
Lrc::new(source_map::SourceMap::new(file_path_mapping)),
None,
)
}
pub fn build_session_with_source_map(
sopts: config::Options,
local_crate_source_file: Option<PathBuf>,
registry: errors::registry::Registry,
source_map: Lrc<source_map::SourceMap>,
emitter_dest: Option<Box<dyn Write + Send>>,
) -> Session {
// FIXME: This is not general enough to make the warning lint completely override
// normal diagnostic warnings, since the warning lint can also be denied and changed
// later via the source code.
let warnings_allow = sopts
.lint_opts
.iter()
.filter(|&&(ref key, _)| *key == "warnings")
.map(|&(_, ref level)| *level == lint::Allow)
.last()
.unwrap_or(false);
let cap_lints_allow = sopts.lint_cap.map_or(false, |cap| cap == lint::Allow);
let can_emit_warnings = !(warnings_allow || cap_lints_allow);
let treat_err_as_bug = sopts.debugging_opts.treat_err_as_bug;
let dont_buffer_diagnostics = sopts.debugging_opts.dont_buffer_diagnostics;
let report_delayed_bugs = sopts.debugging_opts.report_delayed_bugs;
let external_macro_backtrace = sopts.debugging_opts.external_macro_backtrace;
let emitter: Box<dyn Emitter + sync::Send> =
match (sopts.error_format, emitter_dest) {
(config::ErrorOutputType::HumanReadable(color_config), None) => Box::new(
EmitterWriter::stderr(
color_config,
Some(source_map.clone()),
false,
sopts.debugging_opts.teach,
).ui_testing(sopts.debugging_opts.ui_testing),
),
(config::ErrorOutputType::HumanReadable(_), Some(dst)) => Box::new(
EmitterWriter::new(dst, Some(source_map.clone()), false, false)
.ui_testing(sopts.debugging_opts.ui_testing),
),
(config::ErrorOutputType::Json(pretty), None) => Box::new(
JsonEmitter::stderr(
Some(registry),
source_map.clone(),
pretty,
).ui_testing(sopts.debugging_opts.ui_testing),
),
(config::ErrorOutputType::Json(pretty), Some(dst)) => Box::new(
JsonEmitter::new(
dst,
Some(registry),
source_map.clone(),
pretty,
).ui_testing(sopts.debugging_opts.ui_testing),
),
(config::ErrorOutputType::Short(color_config), None) => Box::new(
EmitterWriter::stderr(color_config, Some(source_map.clone()), true, false),
),
(config::ErrorOutputType::Short(_), Some(dst)) => {
Box::new(EmitterWriter::new(dst, Some(source_map.clone()), true, false))
}
};
let diagnostic_handler = errors::Handler::with_emitter_and_flags(
emitter,
errors::HandlerFlags {
can_emit_warnings,
treat_err_as_bug,
report_delayed_bugs,
dont_buffer_diagnostics,
external_macro_backtrace,
..Default::default()
},
);
build_session_(sopts, local_crate_source_file, diagnostic_handler, source_map)
}
pub fn build_session_(
sopts: config::Options,
local_crate_source_file: Option<PathBuf>,
span_diagnostic: errors::Handler,
source_map: Lrc<source_map::SourceMap>,
) -> Session {
let host_triple = TargetTriple::from_triple(config::host_triple());
let host = Target::search(&host_triple).unwrap_or_else(|e|
span_diagnostic
.fatal(&format!("Error loading host specification: {}", e))
.raise()
);
let target_cfg = config::build_target_config(&sopts, &span_diagnostic);
let p_s = parse::ParseSess::with_span_handler(span_diagnostic, source_map);
let sysroot = match &sopts.maybe_sysroot {
Some(sysroot) => sysroot.clone(),
None => filesearch::get_or_default_sysroot(),
};
let host_triple = config::host_triple();
let target_triple = sopts.target_triple.triple();
let host_tlib_path = SearchPath::from_sysroot_and_triple(&sysroot, host_triple);
let target_tlib_path = if host_triple == target_triple {
None
} else {
Some(SearchPath::from_sysroot_and_triple(&sysroot, target_triple))
};
let file_path_mapping = sopts.file_path_mapping();
let local_crate_source_file =
local_crate_source_file.map(|path| file_path_mapping.map_prefix(path).0);
let optimization_fuel_crate = sopts.debugging_opts.fuel.as_ref().map(|i| i.0.clone());
let optimization_fuel = Lock::new(OptimizationFuel {
remaining: sopts.debugging_opts.fuel.as_ref().map(|i| i.1).unwrap_or(0),
out_of_fuel: false,
});
let print_fuel_crate = sopts.debugging_opts.print_fuel.clone();
let print_fuel = AtomicU64::new(0);
let working_dir = env::current_dir().unwrap_or_else(|e|
p_s.span_diagnostic
.fatal(&format!("Current directory is invalid: {}", e))
.raise()
);
let working_dir = file_path_mapping.map_prefix(working_dir);
let cgu_reuse_tracker = if sopts.debugging_opts.query_dep_graph {
CguReuseTracker::new()
} else {
CguReuseTracker::new_disabled()
};
let self_profiling_active = sopts.debugging_opts.self_profile ||
sopts.debugging_opts.profile_json;
let sess = Session {
target: target_cfg,
host,
opts: sopts,
host_tlib_path,
target_tlib_path,
parse_sess: p_s,
sysroot,
local_crate_source_file,
working_dir,
lint_store: RwLock::new(lint::LintStore::new()),
buffered_lints: Lock::new(Some(Default::default())),
one_time_diagnostics: Default::default(),
plugin_llvm_passes: OneThread::new(RefCell::new(Vec::new())),
plugin_attributes: OneThread::new(RefCell::new(Vec::new())),
crate_types: Once::new(),
dependency_formats: Once::new(),
crate_disambiguator: Once::new(),
features: Once::new(),
recursion_limit: Once::new(),
type_length_limit: Once::new(),
const_eval_stack_frame_limit: 100,
next_node_id: OneThread::new(Cell::new(NodeId::from_u32(1))),
allocator_kind: Once::new(),
injected_panic_runtime: Once::new(),
imported_macro_spans: OneThread::new(RefCell::new(FxHashMap::default())),
incr_comp_session: OneThread::new(RefCell::new(IncrCompSession::NotInitialized)),
cgu_reuse_tracker,
self_profiling_active,
self_profiling: Lock::new(SelfProfiler::new()),
profile_channel: Lock::new(None),
perf_stats: PerfStats {
symbol_hash_time: Lock::new(Duration::from_secs(0)),
decode_def_path_tables_time: Lock::new(Duration::from_secs(0)),
queries_canonicalized: AtomicUsize::new(0),
normalize_ty_after_erasing_regions: AtomicUsize::new(0),
normalize_projection_ty: AtomicUsize::new(0),
},
code_stats: Default::default(),
optimization_fuel_crate,
optimization_fuel,
print_fuel_crate,
print_fuel,
// Note that this is unsafe because it may misinterpret file descriptors
// on Unix as jobserver file descriptors. We hopefully execute this near
// the beginning of the process though to ensure we don't get false
// positives, or in other words we try to execute this before we open
// any file descriptors ourselves.
//
// Pick a "reasonable maximum" if we don't otherwise have
// a jobserver in our environment, capping out at 32 so we
// don't take everything down by hogging the process run queue.
// The fixed number is used to have deterministic compilation
// across machines.
//
// Also note that we stick this in a global because there could be
// multiple `Session` instances in this process, and the jobserver is
// per-process.
jobserver: unsafe {
static mut GLOBAL_JOBSERVER: *mut Client = 0 as *mut _;
static INIT: std::sync::Once = std::sync::ONCE_INIT;
INIT.call_once(|| {
let client = Client::from_env().unwrap_or_else(|| {
Client::new(32).expect("failed to create jobserver")
});
GLOBAL_JOBSERVER = Box::into_raw(Box::new(client));
});
(*GLOBAL_JOBSERVER).clone()
},
has_global_allocator: Once::new(),
has_panic_handler: Once::new(),
driver_lint_caps: Default::default(),
};
validate_commandline_args_with_session_available(&sess);
sess
}
// If it is useful to have a Session available already for validating a
// commandline argument, you can do so here.
fn validate_commandline_args_with_session_available(sess: &Session) {
if sess.opts.incremental.is_some() {
match sess.lto() {
Lto::Thin |
Lto::Fat => {
sess.err("can't perform LTO when compiling incrementally");
}
Lto::ThinLocal |
Lto::No => {
// This is fine
}
}
}
// Since we don't know if code in an rlib will be linked to statically or
// dynamically downstream, rustc generates `__imp_` symbols that help the
// MSVC linker deal with this lack of knowledge (#27438). Unfortunately,
// these manually generated symbols confuse LLD when it tries to merge
// bitcode during ThinLTO. Therefore we disallow dynamic linking on MSVC
// when compiling for LLD ThinLTO. This way we can validly just not generate
// the `dllimport` attributes and `__imp_` symbols in that case.
if sess.opts.debugging_opts.cross_lang_lto.enabled() &&
sess.opts.cg.prefer_dynamic &&
sess.target.target.options.is_like_msvc {
sess.err("Linker plugin based LTO is not supported together with \
`-C prefer-dynamic` when targeting MSVC");
}
}
/// Hash value constructed out of all the `-C metadata` arguments passed to the
/// compiler. Together with the crate-name forms a unique global identifier for
/// the crate.
#[derive(Eq, PartialEq, Ord, PartialOrd, Hash, Debug, Clone, Copy, RustcEncodable, RustcDecodable)]
pub struct CrateDisambiguator(Fingerprint);
impl CrateDisambiguator {
pub fn to_fingerprint(self) -> Fingerprint {
self.0
}
}
impl fmt::Display for CrateDisambiguator {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> Result<(), fmt::Error> {
let (a, b) = self.0.as_value();
let as_u128 = a as u128 | ((b as u128) << 64);
f.write_str(&base_n::encode(as_u128, base_n::CASE_INSENSITIVE))
}
}
impl From<Fingerprint> for CrateDisambiguator {
fn from(fingerprint: Fingerprint) -> CrateDisambiguator {
CrateDisambiguator(fingerprint)
}
}
impl_stable_hash_via_hash!(CrateDisambiguator);
/// Holds data on the current incremental compilation session, if there is one.
#[derive(Debug)]
pub enum IncrCompSession {
/// This is the state the session will be in until the incr. comp. dir is
/// needed.
NotInitialized,
/// This is the state during which the session directory is private and can
/// be modified.
Active {
session_directory: PathBuf,
lock_file: flock::Lock,
load_dep_graph: bool,
},
/// This is the state after the session directory has been finalized. In this
/// state, the contents of the directory must not be modified any more.
Finalized { session_directory: PathBuf },
/// This is an error state that is reached when some compilation error has
/// occurred. It indicates that the contents of the session directory must
/// not be used, since they might be invalid.
InvalidBecauseOfErrors { session_directory: PathBuf },
}
pub fn early_error(output: config::ErrorOutputType, msg: &str) -> ! {
let emitter: Box<dyn Emitter + sync::Send> = match output {
config::ErrorOutputType::HumanReadable(color_config) => {
Box::new(EmitterWriter::stderr(color_config, None, false, false))
}
config::ErrorOutputType::Json(pretty) => Box::new(JsonEmitter::basic(pretty)),
config::ErrorOutputType::Short(color_config) => {
Box::new(EmitterWriter::stderr(color_config, None, true, false))
}
};
let handler = errors::Handler::with_emitter(true, false, emitter);
handler.emit(&MultiSpan::new(), msg, errors::Level::Fatal);
errors::FatalError.raise();
}
pub fn early_warn(output: config::ErrorOutputType, msg: &str) {
let emitter: Box<dyn Emitter + sync::Send> = match output {
config::ErrorOutputType::HumanReadable(color_config) => {
Box::new(EmitterWriter::stderr(color_config, None, false, false))
}
config::ErrorOutputType::Json(pretty) => Box::new(JsonEmitter::basic(pretty)),
config::ErrorOutputType::Short(color_config) => {
Box::new(EmitterWriter::stderr(color_config, None, true, false))
}
};
let handler = errors::Handler::with_emitter(true, false, emitter);
handler.emit(&MultiSpan::new(), msg, errors::Level::Warning);
}
#[derive(Copy, Clone, Debug)]
pub enum CompileIncomplete {
Stopped,
Errored(ErrorReported),
}
impl From<ErrorReported> for CompileIncomplete {
fn from(err: ErrorReported) -> CompileIncomplete {
CompileIncomplete::Errored(err)
}
}
pub type CompileResult = Result<(), CompileIncomplete>;
pub fn compile_result_from_err_count(err_count: usize) -> CompileResult {
if err_count == 0 {
Ok(())
} else {
Err(CompileIncomplete::Errored(ErrorReported))
}
}