use crate::{Diagnostic, DiagnosticId, DiagnosticStyledString}; use crate::{Handler, Level, StashKey}; use rustc_lint_defs::Applicability; use rustc_span::{MultiSpan, Span}; use std::fmt::{self, Debug}; use std::ops::{Deref, DerefMut}; use std::thread::panicking; use tracing::debug; /// Used for emitting structured error messages and other diagnostic information. /// /// If there is some state in a downstream crate you would like to /// access in the methods of `DiagnosticBuilder` here, consider /// extending `HandlerFlags`, accessed via `self.handler.flags`. #[must_use] #[derive(Clone)] pub struct DiagnosticBuilder<'a>(Box>); /// This is a large type, and often used as a return value, especially within /// the frequently-used `PResult` type. In theory, return value optimization /// (RVO) should avoid unnecessary copying. In practice, it does not (at the /// time of writing). The split between `DiagnosticBuilder` and /// `DiagnosticBuilderInner` exists to avoid many `memcpy` calls. #[must_use] #[derive(Clone)] struct DiagnosticBuilderInner<'a> { handler: &'a Handler, diagnostic: Diagnostic, allow_suggestions: bool, } /// In general, the `DiagnosticBuilder` uses deref to allow access to /// the fields and methods of the embedded `diagnostic` in a /// transparent way. *However,* many of the methods are intended to /// be used in a chained way, and hence ought to return `self`. In /// that case, we can't just naively forward to the method on the /// `diagnostic`, because the return type would be a `&Diagnostic` /// instead of a `&DiagnosticBuilder<'a>`. This `forward!` macro makes /// it easy to declare such methods on the builder. macro_rules! forward { // Forward pattern for &self -> &Self ( $(#[$attrs:meta])* pub fn $n:ident(&self, $($name:ident: $ty:ty),* $(,)?) -> &Self ) => { $(#[$attrs])* pub fn $n(&self, $($name: $ty),*) -> &Self { self.diagnostic.$n($($name),*); self } }; // Forward pattern for &mut self -> &mut Self ( $(#[$attrs:meta])* pub fn $n:ident(&mut self, $($name:ident: $ty:ty),* $(,)?) -> &mut Self ) => { $(#[$attrs])* pub fn $n(&mut self, $($name: $ty),*) -> &mut Self { self.0.diagnostic.$n($($name),*); self } }; // Forward pattern for &mut self -> &mut Self, with S: Into // type parameter. No obvious way to make this more generic. ( $(#[$attrs:meta])* pub fn $n:ident>( &mut self, $($name:ident: $ty:ty),* $(,)? ) -> &mut Self ) => { $(#[$attrs])* pub fn $n>(&mut self, $($name: $ty),*) -> &mut Self { self.0.diagnostic.$n($($name),*); self } }; } impl<'a> Deref for DiagnosticBuilder<'a> { type Target = Diagnostic; fn deref(&self) -> &Diagnostic { &self.0.diagnostic } } impl<'a> DerefMut for DiagnosticBuilder<'a> { fn deref_mut(&mut self) -> &mut Diagnostic { &mut self.0.diagnostic } } impl<'a> DiagnosticBuilder<'a> { /// Emit the diagnostic. pub fn emit(&mut self) { self.0.handler.emit_diagnostic(&self); self.cancel(); } /// Emit the diagnostic unless `delay` is true, /// in which case the emission will be delayed as a bug. /// /// See `emit` and `delay_as_bug` for details. pub fn emit_unless(&mut self, delay: bool) { if delay { self.delay_as_bug(); } else { self.emit(); } } /// Stashes diagnostic for possible later improvement in a different, /// later stage of the compiler. The diagnostic can be accessed with /// the provided `span` and `key` through `.steal_diagnostic` on `Handler`. /// /// As with `buffer`, this is unless the handler has disabled such buffering. pub fn stash(self, span: Span, key: StashKey) { if let Some((diag, handler)) = self.into_diagnostic() { handler.stash_diagnostic(span, key, diag); } } /// Converts the builder to a `Diagnostic` for later emission, /// unless handler has disabled such buffering. pub fn into_diagnostic(mut self) -> Option<(Diagnostic, &'a Handler)> { if self.0.handler.flags.dont_buffer_diagnostics || self.0.handler.flags.treat_err_as_bug.is_some() { self.emit(); return None; } let handler = self.0.handler; // We must use `Level::Cancelled` for `dummy` to avoid an ICE about an // unused diagnostic. let dummy = Diagnostic::new(Level::Cancelled, ""); let diagnostic = std::mem::replace(&mut self.0.diagnostic, dummy); // Logging here is useful to help track down where in logs an error was // actually emitted. debug!("buffer: diagnostic={:?}", diagnostic); Some((diagnostic, handler)) } /// Buffers the diagnostic for later emission, /// unless handler has disabled such buffering. pub fn buffer(self, buffered_diagnostics: &mut Vec) { buffered_diagnostics.extend(self.into_diagnostic().map(|(diag, _)| diag)); } /// Convenience function for internal use, clients should use one of the /// span_* methods instead. pub fn sub>( &mut self, level: Level, message: &str, span: Option, ) -> &mut Self { let span = span.map(|s| s.into()).unwrap_or_else(MultiSpan::new); self.0.diagnostic.sub(level, message, span, None); self } /// Delay emission of this diagnostic as a bug. /// /// This can be useful in contexts where an error indicates a bug but /// typically this only happens when other compilation errors have already /// happened. In those cases this can be used to defer emission of this /// diagnostic as a bug in the compiler only if no other errors have been /// emitted. /// /// In the meantime, though, callsites are required to deal with the "bug" /// locally in whichever way makes the most sense. pub fn delay_as_bug(&mut self) { self.level = Level::Bug; self.0.handler.delay_as_bug(self.0.diagnostic.clone()); self.cancel(); } /// Adds a span/label to be included in the resulting snippet. /// /// This is pushed onto the [`MultiSpan`] that was created when the diagnostic /// was first built. That means it will be shown together with the original /// span/label, *not* a span added by one of the `span_{note,warn,help,suggestions}` methods. /// /// This span is *not* considered a ["primary span"][`MultiSpan`]; only /// the `Span` supplied when creating the diagnostic is primary. /// /// [`MultiSpan`]: ../rustc_span/struct.MultiSpan.html pub fn span_label(&mut self, span: Span, label: impl Into) -> &mut Self { self.0.diagnostic.span_label(span, label); self } /// Labels all the given spans with the provided label. /// See `span_label` for more information. pub fn span_labels( &mut self, spans: impl IntoIterator, label: impl AsRef, ) -> &mut Self { let label = label.as_ref(); for span in spans { self.0.diagnostic.span_label(span, label); } self } forward!(pub fn note_expected_found( &mut self, expected_label: &dyn fmt::Display, expected: DiagnosticStyledString, found_label: &dyn fmt::Display, found: DiagnosticStyledString, ) -> &mut Self); forward!(pub fn note_expected_found_extra( &mut self, expected_label: &dyn fmt::Display, expected: DiagnosticStyledString, found_label: &dyn fmt::Display, found: DiagnosticStyledString, expected_extra: &dyn fmt::Display, found_extra: &dyn fmt::Display, ) -> &mut Self); forward!(pub fn note_unsuccessfull_coercion( &mut self, expected: DiagnosticStyledString, found: DiagnosticStyledString, ) -> &mut Self); forward!(pub fn note(&mut self, msg: &str) -> &mut Self); forward!(pub fn span_note>( &mut self, sp: S, msg: &str, ) -> &mut Self); forward!(pub fn warn(&mut self, msg: &str) -> &mut Self); forward!(pub fn span_warn>(&mut self, sp: S, msg: &str) -> &mut Self); forward!(pub fn help(&mut self, msg: &str) -> &mut Self); forward!(pub fn span_help>( &mut self, sp: S, msg: &str, ) -> &mut Self); pub fn multipart_suggestion( &mut self, msg: &str, suggestion: Vec<(Span, String)>, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.multipart_suggestion(msg, suggestion, applicability); self } pub fn multipart_suggestions( &mut self, msg: &str, suggestions: Vec>, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.multipart_suggestions(msg, suggestions, applicability); self } pub fn tool_only_multipart_suggestion( &mut self, msg: &str, suggestion: Vec<(Span, String)>, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.tool_only_multipart_suggestion(msg, suggestion, applicability); self } pub fn span_suggestion( &mut self, sp: Span, msg: &str, suggestion: String, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.span_suggestion(sp, msg, suggestion, applicability); self } pub fn span_suggestions( &mut self, sp: Span, msg: &str, suggestions: impl Iterator, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.span_suggestions(sp, msg, suggestions, applicability); self } pub fn span_suggestion_short( &mut self, sp: Span, msg: &str, suggestion: String, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.span_suggestion_short(sp, msg, suggestion, applicability); self } pub fn span_suggestion_verbose( &mut self, sp: Span, msg: &str, suggestion: String, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.span_suggestion_verbose(sp, msg, suggestion, applicability); self } pub fn span_suggestion_hidden( &mut self, sp: Span, msg: &str, suggestion: String, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.span_suggestion_hidden(sp, msg, suggestion, applicability); self } pub fn tool_only_span_suggestion( &mut self, sp: Span, msg: &str, suggestion: String, applicability: Applicability, ) -> &mut Self { if !self.0.allow_suggestions { return self; } self.0.diagnostic.tool_only_span_suggestion(sp, msg, suggestion, applicability); self } forward!(pub fn set_span>(&mut self, sp: S) -> &mut Self); forward!(pub fn code(&mut self, s: DiagnosticId) -> &mut Self); pub fn allow_suggestions(&mut self, allow: bool) -> &mut Self { self.0.allow_suggestions = allow; self } /// Convenience function for internal use, clients should use one of the /// struct_* methods on Handler. crate fn new(handler: &'a Handler, level: Level, message: &str) -> DiagnosticBuilder<'a> { DiagnosticBuilder::new_with_code(handler, level, None, message) } /// Convenience function for internal use, clients should use one of the /// struct_* methods on Handler. crate fn new_with_code( handler: &'a Handler, level: Level, code: Option, message: &str, ) -> DiagnosticBuilder<'a> { let diagnostic = Diagnostic::new_with_code(level, code, message); DiagnosticBuilder::new_diagnostic(handler, diagnostic) } /// Creates a new `DiagnosticBuilder` with an already constructed /// diagnostic. crate fn new_diagnostic(handler: &'a Handler, diagnostic: Diagnostic) -> DiagnosticBuilder<'a> { debug!("Created new diagnostic"); DiagnosticBuilder(Box::new(DiagnosticBuilderInner { handler, diagnostic, allow_suggestions: true, })) } } impl<'a> Debug for DiagnosticBuilder<'a> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { self.0.diagnostic.fmt(f) } } /// Destructor bomb - a `DiagnosticBuilder` must be either emitted or canceled /// or we emit a bug. impl<'a> Drop for DiagnosticBuilder<'a> { fn drop(&mut self) { if !panicking() && !self.cancelled() { let mut db = DiagnosticBuilder::new( self.0.handler, Level::Bug, "the following error was constructed but not emitted", ); db.emit(); self.emit(); panic!(); } } } #[macro_export] macro_rules! struct_span_err { ($session:expr, $span:expr, $code:ident, $($message:tt)*) => ({ $session.struct_span_err_with_code( $span, &format!($($message)*), $crate::error_code!($code), ) }) } #[macro_export] macro_rules! error_code { ($code:ident) => {{ $crate::DiagnosticId::Error(stringify!($code).to_owned()) }}; }