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rust/compiler/rustc_errors/src/lib.rs
bors fe896efa97 Auto merge of #114104 - oli-obk:syn2, r=compiler-errors 
Lots of tiny incremental simplifications of `EmitterWriter` internals

ignore the first commit, it's https://github.com/rust-lang/rust/pull/114088 squashed and rebased, but it's needed to use to use `derive_setters`, as they need a newer `syn` version.

Then this PR starts out with removing many arguments that are almost always defaulted to `None` or `false` and replace them with builder methods that can set these fields in the few cases that want to set them.

After that it's one commit after the other that removes or merges things until everything becomes some very simple trait objects
2023-08-04 18:46:19 +00:00

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//! Diagnostics creation and emission for `rustc`.
//!
//! This module contains the code for creating and emitting diagnostics.
#![doc(html_root_url = "https://doc.rust-lang.org/nightly/nightly-rustc/")]
#![feature(array_windows)]
#![feature(extract_if)]
#![feature(if_let_guard)]
#![feature(let_chains)]
#![feature(never_type)]
#![feature(result_option_inspect)]
#![feature(rustc_attrs)]
#![feature(yeet_expr)]
#![feature(try_blocks)]
#![feature(box_patterns)]
#![feature(error_reporter)]
#![allow(incomplete_features)]
#![cfg_attr(not(bootstrap), allow(internal_features))]
#[macro_use]
extern crate rustc_macros;
#[macro_use]
extern crate tracing;
extern crate self as rustc_errors;
pub use emitter::ColorConfig;
use rustc_lint_defs::LintExpectationId;
use Level::*;
use emitter::{is_case_difference, Emitter, EmitterWriter};
use registry::Registry;
use rustc_data_structures::fx::{FxHashMap, FxHashSet, FxIndexMap, FxIndexSet};
use rustc_data_structures::stable_hasher::{Hash128, StableHasher};
use rustc_data_structures::sync::{self, IntoDynSyncSend, Lock, Lrc};
use rustc_data_structures::AtomicRef;
pub use rustc_error_messages::{
fallback_fluent_bundle, fluent_bundle, DelayDm, DiagnosticMessage, FluentBundle,
LanguageIdentifier, LazyFallbackBundle, MultiSpan, SpanLabel, SubdiagnosticMessage,
};
use rustc_fluent_macro::fluent_messages;
pub use rustc_lint_defs::{pluralize, Applicability};
use rustc_span::source_map::SourceMap;
pub use rustc_span::ErrorGuaranteed;
use rustc_span::{Loc, Span};
use std::borrow::Cow;
use std::error::Report;
use std::fmt;
use std::hash::Hash;
use std::io::Write;
use std::num::NonZeroUsize;
use std::panic;
use std::path::{Path, PathBuf};
use termcolor::{Color, ColorSpec};
pub mod annotate_snippet_emitter_writer;
mod diagnostic;
mod diagnostic_builder;
mod diagnostic_impls;
pub mod emitter;
pub mod error;
pub mod json;
mod lock;
pub mod markdown;
pub mod registry;
mod snippet;
mod styled_buffer;
#[cfg(test)]
mod tests;
pub mod translation;
pub use diagnostic_builder::IntoDiagnostic;
pub use snippet::Style;
pub type PErr<'a> = DiagnosticBuilder<'a, ErrorGuaranteed>;
pub type PResult<'a, T> = Result<T, PErr<'a>>;
fluent_messages! { "../messages.ftl" }
// `PResult` is used a lot. Make sure it doesn't unintentionally get bigger.
// (See also the comment on `DiagnosticBuilderInner`'s `diagnostic` field.)
#[cfg(all(target_arch = "x86_64", target_pointer_width = "64"))]
rustc_data_structures::static_assert_size!(PResult<'_, ()>, 16);
#[cfg(all(target_arch = "x86_64", target_pointer_width = "64"))]
rustc_data_structures::static_assert_size!(PResult<'_, bool>, 16);
#[derive(Debug, PartialEq, Eq, Clone, Copy, Hash, Encodable, Decodable)]
pub enum SuggestionStyle {
/// Hide the suggested code when displaying this suggestion inline.
HideCodeInline,
/// Always hide the suggested code but display the message.
HideCodeAlways,
/// Do not display this suggestion in the cli output, it is only meant for tools.
CompletelyHidden,
/// Always show the suggested code.
/// This will *not* show the code if the suggestion is inline *and* the suggested code is
/// empty.
ShowCode,
/// Always show the suggested code independently.
ShowAlways,
}
impl SuggestionStyle {
fn hide_inline(&self) -> bool {
!matches!(*self, SuggestionStyle::ShowCode)
}
}
#[derive(Clone, Debug, PartialEq, Hash, Encodable, Decodable)]
pub struct CodeSuggestion {
/// Each substitute can have multiple variants due to multiple
/// applicable suggestions
///
/// `foo.bar` might be replaced with `a.b` or `x.y` by replacing
/// `foo` and `bar` on their own:
///
/// ```ignore (illustrative)
/// vec![
/// Substitution { parts: vec![(0..3, "a"), (4..7, "b")] },
/// Substitution { parts: vec![(0..3, "x"), (4..7, "y")] },
/// ]
/// ```
///
/// or by replacing the entire span:
///
/// ```ignore (illustrative)
/// vec![
/// Substitution { parts: vec![(0..7, "a.b")] },
/// Substitution { parts: vec![(0..7, "x.y")] },
/// ]
/// ```
pub substitutions: Vec<Substitution>,
pub msg: DiagnosticMessage,
/// Visual representation of this suggestion.
pub style: SuggestionStyle,
/// Whether or not the suggestion is approximate
///
/// Sometimes we may show suggestions with placeholders,
/// which are useful for users but not useful for
/// tools like rustfix
pub applicability: Applicability,
}
#[derive(Clone, Debug, PartialEq, Hash, Encodable, Decodable)]
/// See the docs on `CodeSuggestion::substitutions`
pub struct Substitution {
pub parts: Vec<SubstitutionPart>,
}
#[derive(Clone, Debug, PartialEq, Hash, Encodable, Decodable)]
pub struct SubstitutionPart {
pub span: Span,
pub snippet: String,
}
/// Used to translate between `Span`s and byte positions within a single output line in highlighted
/// code of structured suggestions.
#[derive(Debug, Clone, Copy)]
pub struct SubstitutionHighlight {
start: usize,
end: usize,
}
impl SubstitutionPart {
pub fn is_addition(&self, sm: &SourceMap) -> bool {
!self.snippet.is_empty() && !self.replaces_meaningful_content(sm)
}
pub fn is_deletion(&self, sm: &SourceMap) -> bool {
self.snippet.trim().is_empty() && self.replaces_meaningful_content(sm)
}
pub fn is_replacement(&self, sm: &SourceMap) -> bool {
!self.snippet.is_empty() && self.replaces_meaningful_content(sm)
}
fn replaces_meaningful_content(&self, sm: &SourceMap) -> bool {
sm.span_to_snippet(self.span)
.map_or(!self.span.is_empty(), |snippet| !snippet.trim().is_empty())
}
}
impl CodeSuggestion {
/// Returns the assembled code suggestions, whether they should be shown with an underline
/// and whether the substitution only differs in capitalization.
pub fn splice_lines(
&self,
sm: &SourceMap,
) -> Vec<(String, Vec<SubstitutionPart>, Vec<Vec<SubstitutionHighlight>>, bool)> {
// For the `Vec<Vec<SubstitutionHighlight>>` value, the first level of the vector
// corresponds to the output snippet's lines, while the second level corresponds to the
// substrings within that line that should be highlighted.
use rustc_span::{CharPos, Pos};
/// Append to a buffer the remainder of the line of existing source code, and return the
/// count of lines that have been added for accurate highlighting.
fn push_trailing(
buf: &mut String,
line_opt: Option<&Cow<'_, str>>,
lo: &Loc,
hi_opt: Option<&Loc>,
) -> usize {
let mut line_count = 0;
let (lo, hi_opt) = (lo.col.to_usize(), hi_opt.map(|hi| hi.col.to_usize()));
if let Some(line) = line_opt {
if let Some(lo) = line.char_indices().map(|(i, _)| i).nth(lo) {
let hi_opt = hi_opt.and_then(|hi| line.char_indices().map(|(i, _)| i).nth(hi));
match hi_opt {
Some(hi) if hi > lo => {
line_count = line[lo..hi].matches('\n').count();
buf.push_str(&line[lo..hi])
}
Some(_) => (),
None => {
line_count = line[lo..].matches('\n').count();
buf.push_str(&line[lo..])
}
}
}
if hi_opt.is_none() {
buf.push('\n');
}
}
line_count
}
assert!(!self.substitutions.is_empty());
self.substitutions
.iter()
.filter(|subst| {
// Suggestions coming from macros can have malformed spans. This is a heavy
// handed approach to avoid ICEs by ignoring the suggestion outright.
let invalid = subst.parts.iter().any(|item| sm.is_valid_span(item.span).is_err());
if invalid {
debug!("splice_lines: suggestion contains an invalid span: {:?}", subst);
}
!invalid
})
.cloned()
.filter_map(|mut substitution| {
// Assumption: all spans are in the same file, and all spans
// are disjoint. Sort in ascending order.
substitution.parts.sort_by_key(|part| part.span.lo());
// Find the bounding span.
let lo = substitution.parts.iter().map(|part| part.span.lo()).min()?;
let hi = substitution.parts.iter().map(|part| part.span.hi()).max()?;
let bounding_span = Span::with_root_ctxt(lo, hi);
// The different spans might belong to different contexts, if so ignore suggestion.
let lines = sm.span_to_lines(bounding_span).ok()?;
assert!(!lines.lines.is_empty() || bounding_span.is_dummy());
// We can't splice anything if the source is unavailable.
if !sm.ensure_source_file_source_present(lines.file.clone()) {
return None;
}
let mut highlights = vec![];
// To build up the result, we do this for each span:
// - push the line segment trailing the previous span
// (at the beginning a "phantom" span pointing at the start of the line)
// - push lines between the previous and current span (if any)
// - if the previous and current span are not on the same line
// push the line segment leading up to the current span
// - splice in the span substitution
//
// Finally push the trailing line segment of the last span
let sf = &lines.file;
let mut prev_hi = sm.lookup_char_pos(bounding_span.lo());
prev_hi.col = CharPos::from_usize(0);
let mut prev_line =
lines.lines.get(0).and_then(|line0| sf.get_line(line0.line_index));
let mut buf = String::new();
let mut line_highlight = vec![];
// We need to keep track of the difference between the existing code and the added
// or deleted code in order to point at the correct column *after* substitution.
let mut acc = 0;
for part in &substitution.parts {
let cur_lo = sm.lookup_char_pos(part.span.lo());
if prev_hi.line == cur_lo.line {
let mut count =
push_trailing(&mut buf, prev_line.as_ref(), &prev_hi, Some(&cur_lo));
while count > 0 {
highlights.push(std::mem::take(&mut line_highlight));
acc = 0;
count -= 1;
}
} else {
acc = 0;
highlights.push(std::mem::take(&mut line_highlight));
let mut count = push_trailing(&mut buf, prev_line.as_ref(), &prev_hi, None);
while count > 0 {
highlights.push(std::mem::take(&mut line_highlight));
count -= 1;
}
// push lines between the previous and current span (if any)
for idx in prev_hi.line..(cur_lo.line - 1) {
if let Some(line) = sf.get_line(idx) {
buf.push_str(line.as_ref());
buf.push('\n');
highlights.push(std::mem::take(&mut line_highlight));
}
}
if let Some(cur_line) = sf.get_line(cur_lo.line - 1) {
let end = match cur_line.char_indices().nth(cur_lo.col.to_usize()) {
Some((i, _)) => i,
None => cur_line.len(),
};
buf.push_str(&cur_line[..end]);
}
}
// Add a whole line highlight per line in the snippet.
let len: isize = part
.snippet
.split('\n')
.next()
.unwrap_or(&part.snippet)
.chars()
.map(|c| match c {
'\t' => 4,
_ => 1,
})
.sum();
line_highlight.push(SubstitutionHighlight {
start: (cur_lo.col.0 as isize + acc) as usize,
end: (cur_lo.col.0 as isize + acc + len) as usize,
});
buf.push_str(&part.snippet);
let cur_hi = sm.lookup_char_pos(part.span.hi());
// Account for the difference between the width of the current code and the
// snippet being suggested, so that the *later* suggestions are correctly
// aligned on the screen. Note that cur_hi and cur_lo can be on different
// lines, so cur_hi.col can be smaller than cur_lo.col
acc += len - (cur_hi.col.0 as isize - cur_lo.col.0 as isize);
prev_hi = cur_hi;
prev_line = sf.get_line(prev_hi.line - 1);
for line in part.snippet.split('\n').skip(1) {
acc = 0;
highlights.push(std::mem::take(&mut line_highlight));
let end: usize = line
.chars()
.map(|c| match c {
'\t' => 4,
_ => 1,
})
.sum();
line_highlight.push(SubstitutionHighlight { start: 0, end });
}
}
highlights.push(std::mem::take(&mut line_highlight));
let only_capitalization = is_case_difference(sm, &buf, bounding_span);
// if the replacement already ends with a newline, don't print the next line
if !buf.ends_with('\n') {
push_trailing(&mut buf, prev_line.as_ref(), &prev_hi, None);
}
// remove trailing newlines
while buf.ends_with('\n') {
buf.pop();
}
Some((buf, substitution.parts, highlights, only_capitalization))
})
.collect()
}
}
pub use rustc_span::fatal_error::{FatalError, FatalErrorMarker};
/// Signifies that the compiler died with an explicit call to `.bug`
/// or `.span_bug` rather than a failed assertion, etc.
pub struct ExplicitBug;
/// Signifies that the compiler died with an explicit call to `.delay_*_bug`
/// rather than a failed assertion, etc.
pub struct DelayedBugPanic;
use crate::diagnostic_impls::{DelayedAtWithNewline, DelayedAtWithoutNewline};
pub use diagnostic::{
AddToDiagnostic, DecorateLint, Diagnostic, DiagnosticArg, DiagnosticArgValue, DiagnosticId,
DiagnosticStyledString, IntoDiagnosticArg, SubDiagnostic,
};
pub use diagnostic_builder::{DiagnosticBuilder, EmissionGuarantee, Noted};
pub use diagnostic_impls::{
DiagnosticArgFromDisplay, DiagnosticSymbolList, ExpectedLifetimeParameter,
IndicateAnonymousLifetime, InvalidFlushedDelayedDiagnosticLevel, LabelKind,
SingleLabelManySpans,
};
use std::backtrace::{Backtrace, BacktraceStatus};
/// A handler deals with errors and other compiler output.
/// Certain errors (fatal, bug, unimpl) may cause immediate exit,
/// others log errors for later reporting.
pub struct Handler {
inner: Lock<HandlerInner>,
}
/// This inner struct exists to keep it all behind a single lock;
/// this is done to prevent possible deadlocks in a multi-threaded compiler,
/// as well as inconsistent state observation.
struct HandlerInner {
flags: HandlerFlags,
/// The number of lint errors that have been emitted.
lint_err_count: usize,
/// The number of errors that have been emitted, including duplicates.
///
/// This is not necessarily the count that's reported to the user once
/// compilation ends.
err_count: usize,
warn_count: usize,
deduplicated_err_count: usize,
emitter: IntoDynSyncSend<Box<dyn Emitter + sync::Send>>,
delayed_span_bugs: Vec<DelayedDiagnostic>,
delayed_good_path_bugs: Vec<DelayedDiagnostic>,
/// This flag indicates that an expected diagnostic was emitted and suppressed.
/// This is used for the `delayed_good_path_bugs` check.
suppressed_expected_diag: bool,
/// This set contains the `DiagnosticId` of all emitted diagnostics to avoid
/// emitting the same diagnostic with extended help (`--teach`) twice, which
/// would be unnecessary repetition.
taught_diagnostics: FxHashSet<DiagnosticId>,
/// Used to suggest rustc --explain `<error code>`
emitted_diagnostic_codes: FxIndexSet<DiagnosticId>,
/// This set contains a hash of every diagnostic that has been emitted by
/// this handler. These hashes is used to avoid emitting the same error
/// twice.
emitted_diagnostics: FxHashSet<Hash128>,
/// Stashed diagnostics emitted in one stage of the compiler that may be
/// stolen by other stages (e.g. to improve them and add more information).
/// The stashed diagnostics count towards the total error count.
/// When `.abort_if_errors()` is called, these are also emitted.
stashed_diagnostics: FxIndexMap<(Span, StashKey), Diagnostic>,
/// The warning count, used for a recap upon finishing
deduplicated_warn_count: usize,
future_breakage_diagnostics: Vec<Diagnostic>,
/// The [`Self::unstable_expect_diagnostics`] should be empty when this struct is
/// dropped. However, it can have values if the compilation is stopped early
/// or is only partially executed. To avoid ICEs, like in rust#94953 we only
/// check if [`Self::unstable_expect_diagnostics`] is empty, if the expectation ids
/// have been converted.
check_unstable_expect_diagnostics: bool,
/// Expected [`Diagnostic`][diagnostic::Diagnostic]s store a [`LintExpectationId`] as part of
/// the lint level. [`LintExpectationId`]s created early during the compilation
/// (before `HirId`s have been defined) are not stable and can therefore not be
/// stored on disk. This buffer stores these diagnostics until the ID has been
/// replaced by a stable [`LintExpectationId`]. The [`Diagnostic`][diagnostic::Diagnostic]s are the
/// submitted for storage and added to the list of fulfilled expectations.
unstable_expect_diagnostics: Vec<Diagnostic>,
/// expected diagnostic will have the level `Expect` which additionally
/// carries the [`LintExpectationId`] of the expectation that can be
/// marked as fulfilled. This is a collection of all [`LintExpectationId`]s
/// that have been marked as fulfilled this way.
///
/// [RFC-2383]: https://rust-lang.github.io/rfcs/2383-lint-reasons.html
fulfilled_expectations: FxHashSet<LintExpectationId>,
/// The file where the ICE information is stored. This allows delayed_span_bug backtraces to be
/// stored along side the main panic backtrace.
ice_file: Option<PathBuf>,
}
/// A key denoting where from a diagnostic was stashed.
#[derive(Copy, Clone, PartialEq, Eq, Hash)]
pub enum StashKey {
ItemNoType,
UnderscoreForArrayLengths,
EarlySyntaxWarning,
CallIntoMethod,
/// When an invalid lifetime e.g. `'2` should be reinterpreted
/// as a char literal in the parser
LifetimeIsChar,
/// Maybe there was a typo where a comma was forgotten before
/// FRU syntax
MaybeFruTypo,
CallAssocMethod,
TraitMissingMethod,
OpaqueHiddenTypeMismatch,
}
fn default_track_diagnostic(d: &mut Diagnostic, f: &mut dyn FnMut(&mut Diagnostic)) {
(*f)(d)
}
pub static TRACK_DIAGNOSTICS: AtomicRef<fn(&mut Diagnostic, &mut dyn FnMut(&mut Diagnostic))> =
AtomicRef::new(&(default_track_diagnostic as _));
#[derive(Copy, Clone, Default)]
pub struct HandlerFlags {
/// If false, warning-level lints are suppressed.
/// (rustc: see `--allow warnings` and `--cap-lints`)
pub can_emit_warnings: bool,
/// If true, error-level diagnostics are upgraded to bug-level.
/// (rustc: see `-Z treat-err-as-bug`)
pub treat_err_as_bug: Option<NonZeroUsize>,
/// If true, immediately emit diagnostics that would otherwise be buffered.
/// (rustc: see `-Z dont-buffer-diagnostics` and `-Z treat-err-as-bug`)
pub dont_buffer_diagnostics: bool,
/// If true, immediately print bugs registered with `delay_span_bug`.
/// (rustc: see `-Z report-delayed-bugs`)
pub report_delayed_bugs: bool,
/// Show macro backtraces.
/// (rustc: see `-Z macro-backtrace`)
pub macro_backtrace: bool,
/// If true, identical diagnostics are reported only once.
pub deduplicate_diagnostics: bool,
/// Track where errors are created. Enabled with `-Ztrack-diagnostics`.
pub track_diagnostics: bool,
}
impl Drop for HandlerInner {
fn drop(&mut self) {
self.emit_stashed_diagnostics();
if !self.has_errors() {
let bugs = std::mem::replace(&mut self.delayed_span_bugs, Vec::new());
self.flush_delayed(bugs, "no errors encountered even though `delay_span_bug` issued");
}
// FIXME(eddyb) this explains what `delayed_good_path_bugs` are!
// They're `delayed_span_bugs` but for "require some diagnostic happened"
// instead of "require some error happened". Sadly that isn't ideal, as
// lints can be `#[allow]`'d, potentially leading to this triggering.
// Also, "good path" should be replaced with a better naming.
if !self.has_any_message() && !self.suppressed_expected_diag {
let bugs = std::mem::replace(&mut self.delayed_good_path_bugs, Vec::new());
self.flush_delayed(
bugs,
"no warnings or errors encountered even though `delayed_good_path_bugs` issued",
);
}
if self.check_unstable_expect_diagnostics {
assert!(
self.unstable_expect_diagnostics.is_empty(),
"all diagnostics with unstable expectations should have been converted",
);
}
}
}
impl Handler {
pub fn with_tty_emitter(
sm: Option<Lrc<SourceMap>>,
fallback_bundle: LazyFallbackBundle,
) -> Self {
let emitter = Box::new(EmitterWriter::stderr(ColorConfig::Auto, fallback_bundle).sm(sm));
Self::with_emitter(emitter)
}
pub fn disable_warnings(mut self) -> Self {
self.inner.get_mut().flags.can_emit_warnings = false;
self
}
pub fn treat_err_as_bug(mut self, treat_err_as_bug: NonZeroUsize) -> Self {
self.inner.get_mut().flags.treat_err_as_bug = Some(treat_err_as_bug);
self
}
pub fn with_flags(mut self, flags: HandlerFlags) -> Self {
self.inner.get_mut().flags = flags;
self
}
pub fn with_ice_file(mut self, ice_file: PathBuf) -> Self {
self.inner.get_mut().ice_file = Some(ice_file);
self
}
pub fn with_emitter(emitter: Box<dyn Emitter + sync::Send>) -> Self {
Self {
inner: Lock::new(HandlerInner {
flags: HandlerFlags { can_emit_warnings: true, ..Default::default() },
lint_err_count: 0,
err_count: 0,
warn_count: 0,
deduplicated_err_count: 0,
deduplicated_warn_count: 0,
emitter: IntoDynSyncSend(emitter),
delayed_span_bugs: Vec::new(),
delayed_good_path_bugs: Vec::new(),
suppressed_expected_diag: false,
taught_diagnostics: Default::default(),
emitted_diagnostic_codes: Default::default(),
emitted_diagnostics: Default::default(),
stashed_diagnostics: Default::default(),
future_breakage_diagnostics: Vec::new(),
check_unstable_expect_diagnostics: false,
unstable_expect_diagnostics: Vec::new(),
fulfilled_expectations: Default::default(),
ice_file: None,
}),
}
}
/// Translate `message` eagerly with `args` to `SubdiagnosticMessage::Eager`.
pub fn eagerly_translate<'a>(
&self,
message: DiagnosticMessage,
args: impl Iterator<Item = DiagnosticArg<'a, 'static>>,
) -> SubdiagnosticMessage {
SubdiagnosticMessage::Eager(Cow::from(self.eagerly_translate_to_string(message, args)))
}
/// Translate `message` eagerly with `args` to `String`.
pub fn eagerly_translate_to_string<'a>(
&self,
message: DiagnosticMessage,
args: impl Iterator<Item = DiagnosticArg<'a, 'static>>,
) -> String {
let inner = self.inner.borrow();
let args = crate::translation::to_fluent_args(args);
inner.emitter.translate_message(&message, &args).map_err(Report::new).unwrap().to_string()
}
// This is here to not allow mutation of flags;
// as of this writing it's only used in tests in librustc_middle.
pub fn can_emit_warnings(&self) -> bool {
self.inner.lock().flags.can_emit_warnings
}
/// Resets the diagnostic error count as well as the cached emitted diagnostics.
///
/// NOTE: *do not* call this function from rustc. It is only meant to be called from external
/// tools that want to reuse a `Parser` cleaning the previously emitted diagnostics as well as
/// the overall count of emitted error diagnostics.
pub fn reset_err_count(&self) {
let mut inner = self.inner.borrow_mut();
inner.err_count = 0;
inner.warn_count = 0;
inner.deduplicated_err_count = 0;
inner.deduplicated_warn_count = 0;
// actually free the underlying memory (which `clear` would not do)
inner.delayed_span_bugs = Default::default();
inner.delayed_good_path_bugs = Default::default();
inner.taught_diagnostics = Default::default();
inner.emitted_diagnostic_codes = Default::default();
inner.emitted_diagnostics = Default::default();
inner.stashed_diagnostics = Default::default();
}
/// Stash a given diagnostic with the given `Span` and [`StashKey`] as the key.
/// Retrieve a stashed diagnostic with `steal_diagnostic`.
pub fn stash_diagnostic(&self, span: Span, key: StashKey, diag: Diagnostic) {
let mut inner = self.inner.borrow_mut();
inner.stash((span.with_parent(None), key), diag);
}
/// Steal a previously stashed diagnostic with the given `Span` and [`StashKey`] as the key.
pub fn steal_diagnostic(&self, span: Span, key: StashKey) -> Option<DiagnosticBuilder<'_, ()>> {
let mut inner = self.inner.borrow_mut();
inner
.steal((span.with_parent(None), key))
.map(|diag| DiagnosticBuilder::new_diagnostic(self, diag))
}
pub fn has_stashed_diagnostic(&self, span: Span, key: StashKey) -> bool {
self.inner.borrow().stashed_diagnostics.get(&(span.with_parent(None), key)).is_some()
}
/// Emit all stashed diagnostics.
pub fn emit_stashed_diagnostics(&self) -> Option<ErrorGuaranteed> {
self.inner.borrow_mut().emit_stashed_diagnostics()
}
/// Construct a builder with the `msg` at the level appropriate for the specific `EmissionGuarantee`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_diagnostic<G: EmissionGuarantee>(
&self,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, G> {
G::make_diagnostic_builder(self, msg)
}
/// Construct a builder at the `Warning` level at the given `span` and with the `msg`.
///
/// Attempting to `.emit()` the builder will only emit if either:
/// * `can_emit_warnings` is `true`
/// * `is_force_warn` was set in `DiagnosticId::Lint`
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_warn(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, ()> {
let mut result = self.struct_warn(msg);
result.set_span(span);
result
}
/// Construct a builder at the `Warning` level at the given `span` and with the `msg`.
/// The `id` is used for lint emissions which should also fulfill a lint expectation.
///
/// Attempting to `.emit()` the builder will only emit if either:
/// * `can_emit_warnings` is `true`
/// * `is_force_warn` was set in `DiagnosticId::Lint`
#[track_caller]
pub fn struct_span_warn_with_expectation(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
id: LintExpectationId,
) -> DiagnosticBuilder<'_, ()> {
let mut result = self.struct_warn_with_expectation(msg, id);
result.set_span(span);
result
}
/// Construct a builder at the `Allow` level at the given `span` and with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_allow(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, ()> {
let mut result = self.struct_allow(msg);
result.set_span(span);
result
}
/// Construct a builder at the `Warning` level at the given `span` and with the `msg`.
/// Also include a code.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_warn_with_code(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) -> DiagnosticBuilder<'_, ()> {
let mut result = self.struct_span_warn(span, msg);
result.code(code);
result
}
/// Construct a builder at the `Warning` level with the `msg`.
///
/// Attempting to `.emit()` the builder will only emit if either:
/// * `can_emit_warnings` is `true`
/// * `is_force_warn` was set in `DiagnosticId::Lint`
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_warn(&self, msg: impl Into<DiagnosticMessage>) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Warning(None), msg)
}
/// Construct a builder at the `Warning` level with the `msg`. The `id` is used for
/// lint emissions which should also fulfill a lint expectation.
///
/// Attempting to `.emit()` the builder will only emit if either:
/// * `can_emit_warnings` is `true`
/// * `is_force_warn` was set in `DiagnosticId::Lint`
#[track_caller]
pub fn struct_warn_with_expectation(
&self,
msg: impl Into<DiagnosticMessage>,
id: LintExpectationId,
) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Warning(Some(id)), msg)
}
/// Construct a builder at the `Allow` level with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_allow(&self, msg: impl Into<DiagnosticMessage>) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Allow, msg)
}
/// Construct a builder at the `Expect` level with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_expect(
&self,
msg: impl Into<DiagnosticMessage>,
id: LintExpectationId,
) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Expect(id), msg)
}
/// Construct a builder at the `Error` level at the given `span` and with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_err(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, ErrorGuaranteed> {
let mut result = self.struct_err(msg);
result.set_span(span);
result
}
/// Construct a builder at the `Error` level at the given `span`, with the `msg`, and `code`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_err_with_code(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) -> DiagnosticBuilder<'_, ErrorGuaranteed> {
let mut result = self.struct_span_err(span, msg);
result.code(code);
result
}
/// Construct a builder at the `Error` level with the `msg`.
// FIXME: This method should be removed (every error should have an associated error code).
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_err(
&self,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, ErrorGuaranteed> {
DiagnosticBuilder::new_guaranteeing_error(self, msg)
}
/// This should only be used by `rustc_middle::lint::struct_lint_level`. Do not use it for hard errors.
#[doc(hidden)]
#[track_caller]
pub fn struct_err_lint(&self, msg: impl Into<DiagnosticMessage>) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Error { lint: true }, msg)
}
/// Construct a builder at the `Error` level with the `msg` and the `code`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_err_with_code(
&self,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) -> DiagnosticBuilder<'_, ErrorGuaranteed> {
let mut result = self.struct_err(msg);
result.code(code);
result
}
/// Construct a builder at the `Warn` level with the `msg` and the `code`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_warn_with_code(
&self,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) -> DiagnosticBuilder<'_, ()> {
let mut result = self.struct_warn(msg);
result.code(code);
result
}
/// Construct a builder at the `Fatal` level at the given `span` and with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_fatal(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, !> {
let mut result = self.struct_fatal(msg);
result.set_span(span);
result
}
/// Construct a builder at the `Fatal` level at the given `span`, with the `msg`, and `code`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_span_fatal_with_code(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) -> DiagnosticBuilder<'_, !> {
let mut result = self.struct_span_fatal(span, msg);
result.code(code);
result
}
/// Construct a builder at the `Error` level with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_fatal(&self, msg: impl Into<DiagnosticMessage>) -> DiagnosticBuilder<'_, !> {
DiagnosticBuilder::new_fatal(self, msg)
}
/// Construct a builder at the `Help` level with the `msg`.
#[rustc_lint_diagnostics]
pub fn struct_help(&self, msg: impl Into<DiagnosticMessage>) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Help, msg)
}
/// Construct a builder at the `Note` level with the `msg`.
#[rustc_lint_diagnostics]
#[track_caller]
pub fn struct_note_without_error(
&self,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, ()> {
DiagnosticBuilder::new(self, Level::Note, msg)
}
#[rustc_lint_diagnostics]
#[track_caller]
pub fn span_fatal(&self, span: impl Into<MultiSpan>, msg: impl Into<DiagnosticMessage>) -> ! {
self.emit_diag_at_span(Diagnostic::new(Fatal, msg), span);
FatalError.raise()
}
#[rustc_lint_diagnostics]
#[track_caller]
pub fn span_fatal_with_code(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) -> ! {
self.emit_diag_at_span(Diagnostic::new_with_code(Fatal, Some(code), msg), span);
FatalError.raise()
}
#[rustc_lint_diagnostics]
#[track_caller]
pub fn span_err(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
) -> ErrorGuaranteed {
self.emit_diag_at_span(Diagnostic::new(Error { lint: false }, msg), span).unwrap()
}
#[rustc_lint_diagnostics]
#[track_caller]
pub fn span_err_with_code(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) {
self.emit_diag_at_span(
Diagnostic::new_with_code(Error { lint: false }, Some(code), msg),
span,
);
}
#[rustc_lint_diagnostics]
#[track_caller]
pub fn span_warn(&self, span: impl Into<MultiSpan>, msg: impl Into<DiagnosticMessage>) {
self.emit_diag_at_span(Diagnostic::new(Warning(None), msg), span);
}
#[rustc_lint_diagnostics]
#[track_caller]
pub fn span_warn_with_code(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
code: DiagnosticId,
) {
self.emit_diag_at_span(Diagnostic::new_with_code(Warning(None), Some(code), msg), span);
}
pub fn span_bug(&self, span: impl Into<MultiSpan>, msg: impl Into<String>) -> ! {
self.inner.borrow_mut().span_bug(span, msg)
}
/// For documentation on this, see `Session::delay_span_bug`.
#[track_caller]
pub fn delay_span_bug(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<String>,
) -> ErrorGuaranteed {
self.inner.borrow_mut().delay_span_bug(span, msg)
}
// FIXME(eddyb) note the comment inside `impl Drop for HandlerInner`, that's
// where the explanation of what "good path" is (also, it should be renamed).
pub fn delay_good_path_bug(&self, msg: impl Into<DiagnosticMessage>) {
self.inner.borrow_mut().delay_good_path_bug(msg)
}
#[track_caller]
pub fn span_bug_no_panic(&self, span: impl Into<MultiSpan>, msg: impl Into<DiagnosticMessage>) {
self.emit_diag_at_span(Diagnostic::new(Bug, msg), span);
}
#[track_caller]
#[rustc_lint_diagnostics]
pub fn span_note_without_error(
&self,
span: impl Into<MultiSpan>,
msg: impl Into<DiagnosticMessage>,
) {
self.emit_diag_at_span(Diagnostic::new(Note, msg), span);
}
#[track_caller]
#[rustc_lint_diagnostics]
pub fn span_note_diag(
&self,
span: Span,
msg: impl Into<DiagnosticMessage>,
) -> DiagnosticBuilder<'_, ()> {
let mut db = DiagnosticBuilder::new(self, Note, msg);
db.set_span(span);
db
}
// NOTE: intentionally doesn't raise an error so rustc_codegen_ssa only reports fatal errors in the main thread
#[rustc_lint_diagnostics]
pub fn fatal(&self, msg: impl Into<DiagnosticMessage>) -> FatalError {
self.inner.borrow_mut().fatal(msg)
}
#[rustc_lint_diagnostics]
pub fn err(&self, msg: impl Into<DiagnosticMessage>) -> ErrorGuaranteed {
self.inner.borrow_mut().err(msg)
}
#[rustc_lint_diagnostics]
pub fn warn(&self, msg: impl Into<DiagnosticMessage>) {
let mut db = DiagnosticBuilder::new(self, Warning(None), msg);
db.emit();
}
#[rustc_lint_diagnostics]
pub fn note_without_error(&self, msg: impl Into<DiagnosticMessage>) {
DiagnosticBuilder::new(self, Note, msg).emit();
}
pub fn bug(&self, msg: impl Into<DiagnosticMessage>) -> ! {
self.inner.borrow_mut().bug(msg)
}
#[inline]
pub fn err_count(&self) -> usize {
self.inner.borrow().err_count()
}
pub fn has_errors(&self) -> Option<ErrorGuaranteed> {
self.inner.borrow().has_errors().then(|| {
#[allow(deprecated)]
ErrorGuaranteed::unchecked_claim_error_was_emitted()
})
}
pub fn has_errors_or_lint_errors(&self) -> Option<ErrorGuaranteed> {
self.inner.borrow().has_errors_or_lint_errors().then(|| {
#[allow(deprecated)]
ErrorGuaranteed::unchecked_claim_error_was_emitted()
})
}
pub fn has_errors_or_delayed_span_bugs(&self) -> Option<ErrorGuaranteed> {
self.inner.borrow().has_errors_or_delayed_span_bugs().then(|| {
#[allow(deprecated)]
ErrorGuaranteed::unchecked_claim_error_was_emitted()
})
}
pub fn is_compilation_going_to_fail(&self) -> Option<ErrorGuaranteed> {
self.inner.borrow().is_compilation_going_to_fail().then(|| {
#[allow(deprecated)]
ErrorGuaranteed::unchecked_claim_error_was_emitted()
})
}
pub fn print_error_count(&self, registry: &Registry) {
self.inner.borrow_mut().print_error_count(registry)
}
pub fn take_future_breakage_diagnostics(&self) -> Vec<Diagnostic> {
std::mem::take(&mut self.inner.borrow_mut().future_breakage_diagnostics)
}
pub fn abort_if_errors(&self) {
self.inner.borrow_mut().abort_if_errors()
}
/// `true` if we haven't taught a diagnostic with this code already.
/// The caller must then teach the user about such a diagnostic.
///
/// Used to suppress emitting the same error multiple times with extended explanation when
/// calling `-Zteach`.
pub fn must_teach(&self, code: &DiagnosticId) -> bool {
self.inner.borrow_mut().must_teach(code)
}
pub fn force_print_diagnostic(&self, db: Diagnostic) {
self.inner.borrow_mut().force_print_diagnostic(db)
}
pub fn emit_diagnostic(&self, diagnostic: &mut Diagnostic) -> Option<ErrorGuaranteed> {
self.inner.borrow_mut().emit_diagnostic(diagnostic)
}
pub fn emit_err<'a>(&'a self, err: impl IntoDiagnostic<'a>) -> ErrorGuaranteed {
self.create_err(err).emit()
}
pub fn create_err<'a>(
&'a self,
err: impl IntoDiagnostic<'a>,
) -> DiagnosticBuilder<'a, ErrorGuaranteed> {
err.into_diagnostic(self)
}
pub fn create_warning<'a>(
&'a self,
warning: impl IntoDiagnostic<'a, ()>,
) -> DiagnosticBuilder<'a, ()> {
warning.into_diagnostic(self)
}
pub fn emit_warning<'a>(&'a self, warning: impl IntoDiagnostic<'a, ()>) {
self.create_warning(warning).emit()
}
pub fn create_almost_fatal<'a>(
&'a self,
fatal: impl IntoDiagnostic<'a, FatalError>,
) -> DiagnosticBuilder<'a, FatalError> {
fatal.into_diagnostic(self)
}
pub fn emit_almost_fatal<'a>(
&'a self,
fatal: impl IntoDiagnostic<'a, FatalError>,
) -> FatalError {
self.create_almost_fatal(fatal).emit()
}
pub fn create_fatal<'a>(
&'a self,
fatal: impl IntoDiagnostic<'a, !>,
) -> DiagnosticBuilder<'a, !> {
fatal.into_diagnostic(self)
}
pub fn emit_fatal<'a>(&'a self, fatal: impl IntoDiagnostic<'a, !>) -> ! {
self.create_fatal(fatal).emit()
}
pub fn create_bug<'a>(
&'a self,
bug: impl IntoDiagnostic<'a, diagnostic_builder::Bug>,
) -> DiagnosticBuilder<'a, diagnostic_builder::Bug> {
bug.into_diagnostic(self)
}
pub fn emit_bug<'a>(
&'a self,
bug: impl IntoDiagnostic<'a, diagnostic_builder::Bug>,
) -> diagnostic_builder::Bug {
self.create_bug(bug).emit()
}
pub fn emit_note<'a>(&'a self, note: impl IntoDiagnostic<'a, Noted>) -> Noted {
self.create_note(note).emit()
}
pub fn create_note<'a>(
&'a self,
note: impl IntoDiagnostic<'a, Noted>,
) -> DiagnosticBuilder<'a, Noted> {
note.into_diagnostic(self)
}
fn emit_diag_at_span(
&self,
mut diag: Diagnostic,
sp: impl Into<MultiSpan>,
) -> Option<ErrorGuaranteed> {
let mut inner = self.inner.borrow_mut();
inner.emit_diagnostic(diag.set_span(sp))
}
pub fn emit_artifact_notification(&self, path: &Path, artifact_type: &str) {
self.inner.borrow_mut().emit_artifact_notification(path, artifact_type)
}
pub fn emit_future_breakage_report(&self, diags: Vec<Diagnostic>) {
self.inner.borrow_mut().emitter.emit_future_breakage_report(diags)
}
pub fn emit_unused_externs(
&self,
lint_level: rustc_lint_defs::Level,
loud: bool,
unused_externs: &[&str],
) {
let mut inner = self.inner.borrow_mut();
if loud && lint_level.is_error() {
inner.bump_err_count();
}
inner.emit_unused_externs(lint_level, unused_externs)
}
pub fn update_unstable_expectation_id(
&self,
unstable_to_stable: &FxHashMap<LintExpectationId, LintExpectationId>,
) {
let mut inner = self.inner.borrow_mut();
let diags = std::mem::take(&mut inner.unstable_expect_diagnostics);
inner.check_unstable_expect_diagnostics = true;
if !diags.is_empty() {
inner.suppressed_expected_diag = true;
for mut diag in diags.into_iter() {
diag.update_unstable_expectation_id(unstable_to_stable);
// Here the diagnostic is given back to `emit_diagnostic` where it was first
// intercepted. Now it should be processed as usual, since the unstable expectation
// id is now stable.
inner.emit_diagnostic(&mut diag);
}
}
inner
.stashed_diagnostics
.values_mut()
.for_each(|diag| diag.update_unstable_expectation_id(unstable_to_stable));
inner
.future_breakage_diagnostics
.iter_mut()
.for_each(|diag| diag.update_unstable_expectation_id(unstable_to_stable));
}
/// This methods steals all [`LintExpectationId`]s that are stored inside
/// [`HandlerInner`] and indicate that the linked expectation has been fulfilled.
#[must_use]
pub fn steal_fulfilled_expectation_ids(&self) -> FxHashSet<LintExpectationId> {
assert!(
self.inner.borrow().unstable_expect_diagnostics.is_empty(),
"`HandlerInner::unstable_expect_diagnostics` should be empty at this point",
);
std::mem::take(&mut self.inner.borrow_mut().fulfilled_expectations)
}
pub fn flush_delayed(&self) {
let mut inner = self.inner.lock();
let bugs = std::mem::replace(&mut inner.delayed_span_bugs, Vec::new());
inner.flush_delayed(bugs, "no errors encountered even though `delay_span_bug` issued");
}
}
impl HandlerInner {
fn must_teach(&mut self, code: &DiagnosticId) -> bool {
self.taught_diagnostics.insert(code.clone())
}
fn force_print_diagnostic(&mut self, db: Diagnostic) {
self.emitter.emit_diagnostic(&db);
}
/// Emit all stashed diagnostics.
fn emit_stashed_diagnostics(&mut self) -> Option<ErrorGuaranteed> {
let has_errors = self.has_errors();
let diags = self.stashed_diagnostics.drain(..).map(|x| x.1).collect::<Vec<_>>();
let mut reported = None;
for mut diag in diags {
// Decrement the count tracking the stash; emitting will increment it.
if diag.is_error() {
if matches!(diag.level, Level::Error { lint: true }) {
self.lint_err_count -= 1;
} else {
self.err_count -= 1;
}
} else {
if diag.is_force_warn() {
self.warn_count -= 1;
} else {
// Unless they're forced, don't flush stashed warnings when
// there are errors, to avoid causing warning overload. The
// stash would've been stolen already if it were important.
if has_errors {
continue;
}
}
}
let reported_this = self.emit_diagnostic(&mut diag);
reported = reported.or(reported_this);
}
reported
}
// FIXME(eddyb) this should ideally take `diagnostic` by value.
fn emit_diagnostic(&mut self, diagnostic: &mut Diagnostic) -> Option<ErrorGuaranteed> {
// The `LintExpectationId` can be stable or unstable depending on when it was created.
// Diagnostics created before the definition of `HirId`s are unstable and can not yet
// be stored. Instead, they are buffered until the `LintExpectationId` is replaced by
// a stable one by the `LintLevelsBuilder`.
if let Some(LintExpectationId::Unstable { .. }) = diagnostic.level.get_expectation_id() {
self.unstable_expect_diagnostics.push(diagnostic.clone());
return None;
}
if diagnostic.level == Level::DelayedBug {
// FIXME(eddyb) this should check for `has_errors` and stop pushing
// once *any* errors were emitted (and truncate `delayed_span_bugs`
// when an error is first emitted, also), but maybe there's a case
// in which that's not sound? otherwise this is really inefficient.
let backtrace = std::backtrace::Backtrace::capture();
self.delayed_span_bugs
.push(DelayedDiagnostic::with_backtrace(diagnostic.clone(), backtrace));
if !self.flags.report_delayed_bugs {
#[allow(deprecated)]
return Some(ErrorGuaranteed::unchecked_claim_error_was_emitted());
}
}
if diagnostic.has_future_breakage() {
// Future breakages aren't emitted if they're Level::Allowed,
// but they still need to be constructed and stashed below,
// so they'll trigger the good-path bug check.
self.suppressed_expected_diag = true;
self.future_breakage_diagnostics.push(diagnostic.clone());
}
if let Some(expectation_id) = diagnostic.level.get_expectation_id() {
self.suppressed_expected_diag = true;
self.fulfilled_expectations.insert(expectation_id.normalize());
}
if matches!(diagnostic.level, Warning(_))
&& !self.flags.can_emit_warnings
&& !diagnostic.is_force_warn()
{
if diagnostic.has_future_breakage() {
(*TRACK_DIAGNOSTICS)(diagnostic, &mut |_| {});
}
return None;
}
if matches!(diagnostic.level, Level::Expect(_) | Level::Allow) {
(*TRACK_DIAGNOSTICS)(diagnostic, &mut |_| {});
return None;
}
let mut guaranteed = None;
(*TRACK_DIAGNOSTICS)(diagnostic, &mut |diagnostic| {
if let Some(ref code) = diagnostic.code {
self.emitted_diagnostic_codes.insert(code.clone());
}
let already_emitted = |this: &mut Self| {
let mut hasher = StableHasher::new();
diagnostic.hash(&mut hasher);
let diagnostic_hash = hasher.finish();
!this.emitted_diagnostics.insert(diagnostic_hash)
};
// Only emit the diagnostic if we've been asked to deduplicate or
// haven't already emitted an equivalent diagnostic.
if !(self.flags.deduplicate_diagnostics && already_emitted(self)) {
debug!(?diagnostic);
debug!(?self.emitted_diagnostics);
let already_emitted_sub = |sub: &mut SubDiagnostic| {
debug!(?sub);
if sub.level != Level::OnceNote {
return false;
}
let mut hasher = StableHasher::new();
sub.hash(&mut hasher);
let diagnostic_hash = hasher.finish();
debug!(?diagnostic_hash);
!self.emitted_diagnostics.insert(diagnostic_hash)
};
diagnostic.children.extract_if(already_emitted_sub).for_each(|_| {});
self.emitter.emit_diagnostic(diagnostic);
if diagnostic.is_error() {
self.deduplicated_err_count += 1;
} else if let Warning(_) = diagnostic.level {
self.deduplicated_warn_count += 1;
}
}
if diagnostic.is_error() {
if matches!(diagnostic.level, Level::Error { lint: true }) {
self.bump_lint_err_count();
} else {
self.bump_err_count();
}
#[allow(deprecated)]
{
guaranteed = Some(ErrorGuaranteed::unchecked_claim_error_was_emitted());
}
} else {
self.bump_warn_count();
}
});
guaranteed
}
fn emit_artifact_notification(&mut self, path: &Path, artifact_type: &str) {
self.emitter.emit_artifact_notification(path, artifact_type);
}
fn emit_unused_externs(&mut self, lint_level: rustc_lint_defs::Level, unused_externs: &[&str]) {
self.emitter.emit_unused_externs(lint_level, unused_externs);
}
fn treat_err_as_bug(&self) -> bool {
self.flags.treat_err_as_bug.is_some_and(|c| {
self.err_count() + self.lint_err_count + self.delayed_bug_count() >= c.get()
})
}
fn delayed_bug_count(&self) -> usize {
self.delayed_span_bugs.len() + self.delayed_good_path_bugs.len()
}
fn print_error_count(&mut self, registry: &Registry) {
self.emit_stashed_diagnostics();
let warnings = match self.deduplicated_warn_count {
0 => Cow::from(""),
1 => Cow::from("1 warning emitted"),
count => Cow::from(format!("{count} warnings emitted")),
};
let errors = match self.deduplicated_err_count {
0 => Cow::from(""),
1 => Cow::from("aborting due to previous error"),
count => Cow::from(format!("aborting due to {count} previous errors")),
};
if self.treat_err_as_bug() {
return;
}
match (errors.len(), warnings.len()) {
(0, 0) => return,
(0, _) => self.emitter.emit_diagnostic(&Diagnostic::new(
Level::Warning(None),
DiagnosticMessage::Str(warnings),
)),
(_, 0) => {
let _ = self.fatal(errors);
}
(_, _) => {
let _ = self.fatal(format!("{errors}; {warnings}"));
}
}
let can_show_explain = self.emitter.should_show_explain();
let are_there_diagnostics = !self.emitted_diagnostic_codes.is_empty();
if can_show_explain && are_there_diagnostics {
let mut error_codes = self
.emitted_diagnostic_codes
.iter()
.filter_map(|x| match &x {
DiagnosticId::Error(s) if registry.try_find_description(s).is_ok() => {
Some(s.clone())
}
_ => None,
})
.collect::<Vec<_>>();
if !error_codes.is_empty() {
error_codes.sort();
if error_codes.len() > 1 {
let limit = if error_codes.len() > 9 { 9 } else { error_codes.len() };
self.failure(format!(
"Some errors have detailed explanations: {}{}",
error_codes[..limit].join(", "),
if error_codes.len() > 9 { "..." } else { "." }
));
self.failure(format!(
"For more information about an error, try \
`rustc --explain {}`.",
&error_codes[0]
));
} else {
self.failure(format!(
"For more information about this error, try \
`rustc --explain {}`.",
&error_codes[0]
));
}
}
}
}
fn stash(&mut self, key: (Span, StashKey), diagnostic: Diagnostic) {
// Track the diagnostic for counts, but don't panic-if-treat-err-as-bug
// yet; that happens when we actually emit the diagnostic.
if diagnostic.is_error() {
if matches!(diagnostic.level, Level::Error { lint: true }) {
self.lint_err_count += 1;
} else {
self.err_count += 1;
}
} else {
// Warnings are only automatically flushed if they're forced.
if diagnostic.is_force_warn() {
self.warn_count += 1;
}
}
// FIXME(Centril, #69537): Consider reintroducing panic on overwriting a stashed diagnostic
// if/when we have a more robust macro-friendly replacement for `(span, key)` as a key.
// See the PR for a discussion.
self.stashed_diagnostics.insert(key, diagnostic);
}
fn steal(&mut self, key: (Span, StashKey)) -> Option<Diagnostic> {
let diagnostic = self.stashed_diagnostics.remove(&key)?;
if diagnostic.is_error() {
if matches!(diagnostic.level, Level::Error { lint: true }) {
self.lint_err_count -= 1;
} else {
self.err_count -= 1;
}
} else {
if diagnostic.is_force_warn() {
self.warn_count -= 1;
}
}
Some(diagnostic)
}
#[inline]
fn err_count(&self) -> usize {
self.err_count
}
fn has_errors(&self) -> bool {
self.err_count() > 0
}
fn has_errors_or_lint_errors(&self) -> bool {
self.has_errors() || self.lint_err_count > 0
}
fn has_errors_or_delayed_span_bugs(&self) -> bool {
self.has_errors() || !self.delayed_span_bugs.is_empty()
}
fn has_any_message(&self) -> bool {
self.err_count() > 0 || self.lint_err_count > 0 || self.warn_count > 0
}
fn is_compilation_going_to_fail(&self) -> bool {
self.has_errors() || self.lint_err_count > 0 || !self.delayed_span_bugs.is_empty()
}
fn abort_if_errors(&mut self) {
self.emit_stashed_diagnostics();
if self.has_errors() {
FatalError.raise();
}
}
#[track_caller]
fn span_bug(&mut self, sp: impl Into<MultiSpan>, msg: impl Into<String>) -> ! {
self.emit_diag_at_span(Diagnostic::new(Bug, msg.into()), sp);
panic::panic_any(ExplicitBug);
}
fn emit_diag_at_span(&mut self, mut diag: Diagnostic, sp: impl Into<MultiSpan>) {
self.emit_diagnostic(diag.set_span(sp));
}
/// For documentation on this, see `Session::delay_span_bug`.
#[track_caller]
fn delay_span_bug(
&mut self,
sp: impl Into<MultiSpan>,
msg: impl Into<String>,
) -> ErrorGuaranteed {
// This is technically `self.treat_err_as_bug()` but `delay_span_bug` is called before
// incrementing `err_count` by one, so we need to +1 the comparing.
// FIXME: Would be nice to increment err_count in a more coherent way.
if self.flags.treat_err_as_bug.is_some_and(|c| {
self.err_count() + self.lint_err_count + self.delayed_bug_count() + 1 >= c.get()
}) {
// FIXME: don't abort here if report_delayed_bugs is off
self.span_bug(sp, msg.into());
}
let mut diagnostic = Diagnostic::new(Level::DelayedBug, msg.into());
diagnostic.set_span(sp.into());
self.emit_diagnostic(&mut diagnostic).unwrap()
}
// FIXME(eddyb) note the comment inside `impl Drop for HandlerInner`, that's
// where the explanation of what "good path" is (also, it should be renamed).
fn delay_good_path_bug(&mut self, msg: impl Into<DiagnosticMessage>) {
let mut diagnostic = Diagnostic::new(Level::DelayedBug, msg);
if self.flags.report_delayed_bugs {
self.emit_diagnostic(&mut diagnostic);
}
let backtrace = std::backtrace::Backtrace::capture();
self.delayed_good_path_bugs.push(DelayedDiagnostic::with_backtrace(diagnostic, backtrace));
}
fn failure(&mut self, msg: impl Into<DiagnosticMessage>) {
self.emit_diagnostic(&mut Diagnostic::new(FailureNote, msg));
}
fn fatal(&mut self, msg: impl Into<DiagnosticMessage>) -> FatalError {
self.emit(Fatal, msg);
FatalError
}
fn err(&mut self, msg: impl Into<DiagnosticMessage>) -> ErrorGuaranteed {
self.emit(Error { lint: false }, msg)
}
/// Emit an error; level should be `Error` or `Fatal`.
fn emit(&mut self, level: Level, msg: impl Into<DiagnosticMessage>) -> ErrorGuaranteed {
if self.treat_err_as_bug() {
self.bug(msg);
}
self.emit_diagnostic(&mut Diagnostic::new(level, msg)).unwrap()
}
fn bug(&mut self, msg: impl Into<DiagnosticMessage>) -> ! {
self.emit_diagnostic(&mut Diagnostic::new(Bug, msg));
panic::panic_any(ExplicitBug);
}
fn flush_delayed(
&mut self,
bugs: impl IntoIterator<Item = DelayedDiagnostic>,
explanation: impl Into<DiagnosticMessage> + Copy,
) {
let mut no_bugs = true;
// If backtraces are enabled, also print the query stack
let backtrace = std::env::var_os("RUST_BACKTRACE").map_or(true, |x| &x != "0");
for bug in bugs {
if let Some(file) = self.ice_file.as_ref()
&& let Ok(mut out) = std::fs::File::options().create(true).append(true).open(file)
{
let _ = write!(
&mut out,
"delayed span bug: {}\n{}\n",
bug.inner.styled_message().iter().filter_map(|(msg, _)| msg.as_str()).collect::<String>(),
&bug.note
);
}
let mut bug =
if backtrace || self.ice_file.is_none() { bug.decorate() } else { bug.inner };
if no_bugs {
// Put the overall explanation before the `DelayedBug`s, to
// frame them better (e.g. separate warnings from them).
self.emit_diagnostic(&mut Diagnostic::new(Bug, explanation));
no_bugs = false;
}
// "Undelay" the `DelayedBug`s (into plain `Bug`s).
if bug.level != Level::DelayedBug {
// NOTE(eddyb) not panicking here because we're already producing
// an ICE, and the more information the merrier.
bug.subdiagnostic(InvalidFlushedDelayedDiagnosticLevel {
span: bug.span.primary_span().unwrap(),
level: bug.level,
});
}
bug.level = Level::Bug;
self.emit_diagnostic(&mut bug);
}
// Panic with `DelayedBugPanic` to avoid "unexpected panic" messages.
if !no_bugs {
panic::panic_any(DelayedBugPanic);
}
}
fn bump_lint_err_count(&mut self) {
self.lint_err_count += 1;
self.panic_if_treat_err_as_bug();
}
fn bump_err_count(&mut self) {
self.err_count += 1;
self.panic_if_treat_err_as_bug();
}
fn bump_warn_count(&mut self) {
self.warn_count += 1;
}
fn panic_if_treat_err_as_bug(&self) {
if self.treat_err_as_bug() {
match (
self.err_count() + self.lint_err_count,
self.delayed_bug_count(),
self.flags.treat_err_as_bug.map(|c| c.get()).unwrap_or(0),
) {
(1, 0, 1) => panic!("aborting due to `-Z treat-err-as-bug=1`"),
(0, 1, 1) => panic!("aborting due delayed bug with `-Z treat-err-as-bug=1`"),
(count, delayed_count, as_bug) => {
if delayed_count > 0 {
panic!(
"aborting after {count} errors and {delayed_count} delayed bugs due to `-Z treat-err-as-bug={as_bug}`",
)
} else {
panic!(
"aborting after {count} errors due to `-Z treat-err-as-bug={as_bug}`",
)
}
}
}
}
}
}
struct DelayedDiagnostic {
inner: Diagnostic,
note: Backtrace,
}
impl DelayedDiagnostic {
fn with_backtrace(diagnostic: Diagnostic, backtrace: Backtrace) -> Self {
DelayedDiagnostic { inner: diagnostic, note: backtrace }
}
fn decorate(mut self) -> Diagnostic {
match self.note.status() {
BacktraceStatus::Captured => {
let inner = &self.inner;
self.inner.subdiagnostic(DelayedAtWithNewline {
span: inner.span.primary_span().unwrap(),
emitted_at: inner.emitted_at.clone(),
note: self.note,
});
}
// Avoid the needless newline when no backtrace has been captured,
// the display impl should just be a single line.
_ => {
let inner = &self.inner;
self.inner.subdiagnostic(DelayedAtWithoutNewline {
span: inner.span.primary_span().unwrap(),
emitted_at: inner.emitted_at.clone(),
note: self.note,
});
}
}
self.inner
}
}
#[derive(Copy, PartialEq, Eq, Clone, Hash, Debug, Encodable, Decodable)]
pub enum Level {
Bug,
DelayedBug,
Fatal,
Error {
/// If this error comes from a lint, don't abort compilation even when abort_if_errors() is called.
lint: bool,
},
/// This [`LintExpectationId`] is used for expected lint diagnostics, which should
/// also emit a warning due to the `force-warn` flag. In all other cases this should
/// be `None`.
Warning(Option<LintExpectationId>),
Note,
/// A note that is only emitted once.
OnceNote,
Help,
FailureNote,
Allow,
Expect(LintExpectationId),
}
impl fmt::Display for Level {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
self.to_str().fmt(f)
}
}
impl Level {
fn color(self) -> ColorSpec {
let mut spec = ColorSpec::new();
match self {
Bug | DelayedBug | Fatal | Error { .. } => {
spec.set_fg(Some(Color::Red)).set_intense(true);
}
Warning(_) => {
spec.set_fg(Some(Color::Yellow)).set_intense(cfg!(windows));
}
Note | OnceNote => {
spec.set_fg(Some(Color::Green)).set_intense(true);
}
Help => {
spec.set_fg(Some(Color::Cyan)).set_intense(true);
}
FailureNote => {}
Allow | Expect(_) => unreachable!(),
}
spec
}
pub fn to_str(self) -> &'static str {
match self {
Bug | DelayedBug => "error: internal compiler error",
Fatal | Error { .. } => "error",
Warning(_) => "warning",
Note | OnceNote => "note",
Help => "help",
FailureNote => "failure-note",
Allow => panic!("Shouldn't call on allowed error"),
Expect(_) => panic!("Shouldn't call on expected error"),
}
}
pub fn is_failure_note(&self) -> bool {
matches!(*self, FailureNote)
}
pub fn get_expectation_id(&self) -> Option<LintExpectationId> {
match self {
Level::Expect(id) | Level::Warning(Some(id)) => Some(*id),
_ => None,
}
}
}
// FIXME(eddyb) this doesn't belong here AFAICT, should be moved to callsite.
pub fn add_elided_lifetime_in_path_suggestion(
source_map: &SourceMap,
diag: &mut Diagnostic,
n: usize,
path_span: Span,
incl_angl_brckt: bool,
insertion_span: Span,
) {
diag.subdiagnostic(ExpectedLifetimeParameter { span: path_span, count: n });
if !source_map.is_span_accessible(insertion_span) {
// Do not try to suggest anything if generated by a proc-macro.
return;
}
let anon_lts = vec!["'_"; n].join(", ");
let suggestion =
if incl_angl_brckt { format!("<{anon_lts}>") } else { format!("{anon_lts}, ") };
diag.subdiagnostic(IndicateAnonymousLifetime {
span: insertion_span.shrink_to_hi(),
count: n,
suggestion,
});
}
pub fn report_ambiguity_error<'a, G: EmissionGuarantee>(
db: &mut DiagnosticBuilder<'a, G>,
ambiguity: rustc_lint_defs::AmbiguityErrorDiag,
) {
db.span_label(ambiguity.label_span, ambiguity.label_msg);
db.note(ambiguity.note_msg);
db.span_note(ambiguity.b1_span, ambiguity.b1_note_msg);
for help_msg in ambiguity.b1_help_msgs {
db.help(help_msg);
}
db.span_note(ambiguity.b2_span, ambiguity.b2_note_msg);
for help_msg in ambiguity.b2_help_msgs {
db.help(help_msg);
}
}
#[derive(Clone, Copy, PartialEq, Hash, Debug)]
pub enum TerminalUrl {
No,
Yes,
Auto,
}
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