compiler/rustc_errors/src/json.rs - rust-lang/rust - Git at Google

 //! A JSON emitter for errors.
 //!
 //! This works by converting errors to a simplified structural format (see the
 //! structs at the start of the file) and then serializing them. These should
 //! contain as much information about the error as possible.
 //!
 //! The format of the JSON output should be considered *unstable*. For now the
 //! structs at the end of this file (Diagnostic*) specify the error format.

 // FIXME: spec the JSON output properly.

 use std::error::Report;
 use std::io::{self, Write};
 use std::path::Path;
 use std::sync::{Arc, Mutex};
 use std::vec;

 use derive_setters::Setters;
 use rustc_data_structures::sync::IntoDynSyncSend;
 use rustc_error_messages::FluentArgs;
 use rustc_lint_defs::Applicability;
 use rustc_span::Span;
 use rustc_span::hygiene::ExpnData;
 use rustc_span::source_map::{FilePathMapping, SourceMap};
 use serde::Serialize;
 use termcolor::{ColorSpec, WriteColor};

 use crate::diagnostic::IsLint;
 use crate::emitter::{
     ColorConfig, Destination, Emitter, HumanEmitter, HumanReadableErrorType, OutputTheme,
     TimingEvent, should_show_source_code,
 };
 use crate::registry::Registry;
 use crate::timings::{TimingRecord, TimingSection};
 use crate::translation::{Translator, to_fluent_args};
 use crate::{CodeSuggestion, MultiSpan, SpanLabel, Subdiag, Suggestions, TerminalUrl};

 #[cfg(test)]
 mod tests;

 #[derive(Setters)]
 pub struct JsonEmitter {
     #[setters(skip)]
     dst: IntoDynSyncSend<Box<dyn Write + Send>>,
     #[setters(skip)]
     sm: Option<Arc<SourceMap>>,
     #[setters(skip)]
     translator: Translator,
     #[setters(skip)]
     pretty: bool,
     ui_testing: bool,
     ignored_directories_in_source_blocks: Vec<String>,
     #[setters(skip)]
     json_rendered: HumanReadableErrorType,
     color_config: ColorConfig,
     diagnostic_width: Option<usize>,
     macro_backtrace: bool,
     track_diagnostics: bool,
     terminal_url: TerminalUrl,
 }

 impl JsonEmitter {
     pub fn new(
         dst: Box<dyn Write + Send>,
         sm: Option<Arc<SourceMap>>,
         translator: Translator,
         pretty: bool,
         json_rendered: HumanReadableErrorType,
         color_config: ColorConfig,
     ) -> JsonEmitter {
         JsonEmitter {
             dst: IntoDynSyncSend(dst),
             sm,
             translator,
             pretty,
             ui_testing: false,
             ignored_directories_in_source_blocks: Vec::new(),
             json_rendered,
             color_config,
             diagnostic_width: None,
             macro_backtrace: false,
             track_diagnostics: false,
             terminal_url: TerminalUrl::No,
         }
     }

     fn emit(&mut self, val: EmitTyped<'_>) -> io::Result<()> {
         if self.pretty {
             serde_json::to_writer_pretty(&mut *self.dst, &val)?
         } else {
             serde_json::to_writer(&mut *self.dst, &val)?
         };
         self.dst.write_all(b"\n")?;
         self.dst.flush()
     }
 }

 #[derive(Serialize)]
 #[serde(tag = "$message_type", rename_all = "snake_case")]
 enum EmitTyped<'a> {
     Diagnostic(Diagnostic),
     Artifact(ArtifactNotification<'a>),
     SectionTiming(SectionTimestamp<'a>),
     FutureIncompat(FutureIncompatReport<'a>),
     UnusedExtern(UnusedExterns<'a>),
 }

 impl Emitter for JsonEmitter {
     fn emit_diagnostic(&mut self, diag: crate::DiagInner, registry: &Registry) {
         let data = Diagnostic::from_errors_diagnostic(diag, self, registry);
         let result = self.emit(EmitTyped::Diagnostic(data));
         if let Err(e) = result {
             panic!("failed to print diagnostics: {e:?}");
         }
     }

     fn emit_artifact_notification(&mut self, path: &Path, artifact_type: &str) {
         let data = ArtifactNotification { artifact: path, emit: artifact_type };
         let result = self.emit(EmitTyped::Artifact(data));
         if let Err(e) = result {
             panic!("failed to print notification: {e:?}");
         }
     }

     fn emit_timing_section(&mut self, record: TimingRecord, event: TimingEvent) {
         let event = match event {
             TimingEvent::Start => "start",
             TimingEvent::End => "end",
         };
         let name = match record.section {
             TimingSection::Linking => "link",
             TimingSection::Codegen => "codegen",
         };
         let data = SectionTimestamp { name, event, timestamp: record.timestamp };
         let result = self.emit(EmitTyped::SectionTiming(data));
         if let Err(e) = result {
             panic!("failed to print timing section: {e:?}");
         }
     }

     fn emit_future_breakage_report(&mut self, diags: Vec<crate::DiagInner>, registry: &Registry) {
         let data: Vec<FutureBreakageItem<'_>> = diags
             .into_iter()
             .map(|mut diag| {
                 // Allowed or expected lints don't normally (by definition) emit a lint
                 // but future incompat lints are special and are emitted anyway.
                 //
                 // So to avoid ICEs and confused users we "upgrade" the lint level for
                 // those `FutureBreakageItem` to warn.
                 if matches!(diag.level, crate::Level::Allow | crate::Level::Expect) {
                     diag.level = crate::Level::Warning;
                 }
                 FutureBreakageItem {
                     diagnostic: EmitTyped::Diagnostic(Diagnostic::from_errors_diagnostic(
                         diag, self, registry,
                     )),
                 }
             })
             .collect();
         let report = FutureIncompatReport { future_incompat_report: data };
         let result = self.emit(EmitTyped::FutureIncompat(report));
         if let Err(e) = result {
             panic!("failed to print future breakage report: {e:?}");
         }
     }

     fn emit_unused_externs(&mut self, lint_level: rustc_lint_defs::Level, unused_externs: &[&str]) {
         let lint_level = lint_level.as_str();
         let data = UnusedExterns { lint_level, unused_extern_names: unused_externs };
         let result = self.emit(EmitTyped::UnusedExtern(data));
         if let Err(e) = result {
             panic!("failed to print unused externs: {e:?}");
         }
     }

     fn source_map(&self) -> Option<&SourceMap> {
         self.sm.as_deref()
     }

     fn should_show_explain(&self) -> bool {
         !self.json_rendered.short()
     }

     fn translator(&self) -> &Translator {
         &self.translator
     }
 }

 // The following data types are provided just for serialisation.

 #[derive(Serialize)]
 struct Diagnostic {
     /// The primary error message.
     message: String,
     code: Option<DiagnosticCode>,
     /// "error: internal compiler error", "error", "warning", "note", "help".
     level: &'static str,
     spans: Vec<DiagnosticSpan>,
     /// Associated diagnostic messages.
     children: Vec<Diagnostic>,
     /// The message as rustc would render it.
     rendered: Option<String>,
 }

 #[derive(Serialize)]
 struct DiagnosticSpan {
     file_name: String,
     byte_start: u32,
     byte_end: u32,
     /// 1-based.
     line_start: usize,
     line_end: usize,
     /// 1-based, character offset.
     column_start: usize,
     column_end: usize,
     /// Is this a "primary" span -- meaning the point, or one of the points,
     /// where the error occurred?
     is_primary: bool,
     /// Source text from the start of line_start to the end of line_end.
     text: Vec<DiagnosticSpanLine>,
     /// Label that should be placed at this location (if any)
     label: Option<String>,
     /// If we are suggesting a replacement, this will contain text
     /// that should be sliced in atop this span.
     suggested_replacement: Option<String>,
     /// If the suggestion is approximate
     suggestion_applicability: Option<Applicability>,
     /// Macro invocations that created the code at this span, if any.
     expansion: Option<Box<DiagnosticSpanMacroExpansion>>,
 }

 #[derive(Serialize)]
 struct DiagnosticSpanLine {
     text: String,

     /// 1-based, character offset in self.text.
     highlight_start: usize,

     highlight_end: usize,
 }

 #[derive(Serialize)]
 struct DiagnosticSpanMacroExpansion {
     /// span where macro was applied to generate this code; note that
     /// this may itself derive from a macro (if
     /// `span.expansion.is_some()`)
     span: DiagnosticSpan,

     /// name of macro that was applied (e.g., "foo!" or "#[derive(Eq)]")
     macro_decl_name: String,

     /// span where macro was defined (if known)
     def_site_span: DiagnosticSpan,
 }

 #[derive(Serialize)]
 struct DiagnosticCode {
     /// The error code (e.g. "E1234"), if the diagnostic has one. Or the lint
     /// name, if it's a lint without an error code.
     code: String,
     /// An explanation for the code.
     explanation: Option<&'static str>,
 }

 #[derive(Serialize)]
 struct ArtifactNotification<'a> {
     /// The path of the artifact.
     artifact: &'a Path,
     /// What kind of artifact we're emitting.
     emit: &'a str,
 }

 #[derive(Serialize)]
 struct SectionTimestamp<'a> {
     /// Name of the section
     name: &'a str,
     /// Start/end of the section
     event: &'a str,
     /// Opaque timestamp.
     timestamp: u128,
 }

 #[derive(Serialize)]
 struct FutureBreakageItem<'a> {
     // Always EmitTyped::Diagnostic, but we want to make sure it gets serialized
     // with "$message_type".
     diagnostic: EmitTyped<'a>,
 }

 #[derive(Serialize)]
 struct FutureIncompatReport<'a> {
     future_incompat_report: Vec<FutureBreakageItem<'a>>,
 }

 // NOTE: Keep this in sync with the equivalent structs in rustdoc's
 // doctest component (as well as cargo).
 // We could unify this struct the one in rustdoc but they have different
 // ownership semantics, so doing so would create wasteful allocations.
 #[derive(Serialize)]
 struct UnusedExterns<'a> {
     /// The severity level of the unused dependencies lint
     lint_level: &'a str,
     /// List of unused externs by their names.
     unused_extern_names: &'a [&'a str],
 }

 impl Diagnostic {
     /// Converts from `rustc_errors::DiagInner` to `Diagnostic`.
     fn from_errors_diagnostic(
         diag: crate::DiagInner,
         je: &JsonEmitter,
         registry: &Registry,
     ) -> Diagnostic {
         let args = to_fluent_args(diag.args.iter());
         let sugg_to_diag = |sugg: &CodeSuggestion| {
             let translated_message =
                 je.translator.translate_message(&sugg.msg, &args).map_err(Report::new).unwrap();
             Diagnostic {
                 message: translated_message.to_string(),
                 code: None,
                 level: "help",
                 spans: DiagnosticSpan::from_suggestion(sugg, &args, je),
                 children: vec![],
                 rendered: None,
             }
         };
         let sugg = match &diag.suggestions {
             Suggestions::Enabled(suggestions) => suggestions.iter().map(sugg_to_diag),
             Suggestions::Sealed(suggestions) => suggestions.iter().map(sugg_to_diag),
             Suggestions::Disabled => [].iter().map(sugg_to_diag),
         };

         // generate regular command line output and store it in the json

         // A threadsafe buffer for writing.
         #[derive(Default, Clone)]
         struct BufWriter(Arc<Mutex<Vec<u8>>>);

         impl Write for BufWriter {
             fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
                 self.0.lock().unwrap().write(buf)
             }
             fn flush(&mut self) -> io::Result<()> {
                 self.0.lock().unwrap().flush()
             }
         }
         impl WriteColor for BufWriter {
             fn supports_color(&self) -> bool {
                 false
             }

             fn set_color(&mut self, _spec: &ColorSpec) -> io::Result<()> {
                 Ok(())
             }

             fn reset(&mut self) -> io::Result<()> {
                 Ok(())
             }
         }

         let translated_message = je.translator.translate_messages(&diag.messages, &args);

         let code = if let Some(code) = diag.code {
             Some(DiagnosticCode {
                 code: code.to_string(),
                 explanation: registry.try_find_description(code).ok(),
             })
         } else if let Some(IsLint { name, .. }) = &diag.is_lint {
             Some(DiagnosticCode { code: name.to_string(), explanation: None })
         } else {
             None
         };
         let level = diag.level.to_str();
         let spans = DiagnosticSpan::from_multispan(&diag.span, &args, je);
         let mut children: Vec<Diagnostic> = diag
             .children
             .iter()
             .map(|c| Diagnostic::from_sub_diagnostic(c, &args, je))
             .chain(sugg)
             .collect();
         if je.track_diagnostics && diag.span.has_primary_spans() && !diag.span.is_dummy() {
             children
                 .insert(0, Diagnostic::from_sub_diagnostic(&diag.emitted_at_sub_diag(), &args, je));
         }
         let buf = BufWriter::default();
         let mut dst: Destination = Box::new(buf.clone());
         let short = je.json_rendered.short();
         match je.color_config {
             ColorConfig::Always | ColorConfig::Auto => dst = Box::new(termcolor::Ansi::new(dst)),
             ColorConfig::Never => {}
         }
         HumanEmitter::new(dst, je.translator.clone())
             .short_message(short)
             .sm(je.sm.clone())
             .diagnostic_width(je.diagnostic_width)
             .macro_backtrace(je.macro_backtrace)
             .track_diagnostics(je.track_diagnostics)
             .terminal_url(je.terminal_url)
             .ui_testing(je.ui_testing)
             .ignored_directories_in_source_blocks(je.ignored_directories_in_source_blocks.clone())
             .theme(if let HumanReadableErrorType::Unicode = je.json_rendered {
                 OutputTheme::Unicode
             } else {
                 OutputTheme::Ascii
             })
             .emit_diagnostic(diag, registry);
         let buf = Arc::try_unwrap(buf.0).unwrap().into_inner().unwrap();
         let buf = String::from_utf8(buf).unwrap();

         Diagnostic {
             message: translated_message.to_string(),
             code,
             level,
             spans,
             children,
             rendered: Some(buf),
         }
     }

     fn from_sub_diagnostic(
         subdiag: &Subdiag,
         args: &FluentArgs<'_>,
         je: &JsonEmitter,
     ) -> Diagnostic {
         let translated_message = je.translator.translate_messages(&subdiag.messages, args);
         Diagnostic {
             message: translated_message.to_string(),
             code: None,
             level: subdiag.level.to_str(),
             spans: DiagnosticSpan::from_multispan(&subdiag.span, args, je),
             children: vec![],
             rendered: None,
         }
     }
 }

 impl DiagnosticSpan {
     fn from_span_label(
         span: SpanLabel,
         suggestion: Option<(&String, Applicability)>,
         args: &FluentArgs<'_>,
         je: &JsonEmitter,
     ) -> DiagnosticSpan {
         Self::from_span_etc(
             span.span,
             span.is_primary,
             span.label
                 .as_ref()
                 .map(|m| je.translator.translate_message(m, args).unwrap())
                 .map(|m| m.to_string()),
             suggestion,
             je,
         )
     }

     fn from_span_etc(
         span: Span,
         is_primary: bool,
         label: Option<String>,
         suggestion: Option<(&String, Applicability)>,
         je: &JsonEmitter,
     ) -> DiagnosticSpan {
         // obtain the full backtrace from the `macro_backtrace`
         // helper; in some ways, it'd be better to expand the
         // backtrace ourselves, but the `macro_backtrace` helper makes
         // some decision, such as dropping some frames, and I don't
         // want to duplicate that logic here.
         let backtrace = span.macro_backtrace();
         DiagnosticSpan::from_span_full(span, is_primary, label, suggestion, backtrace, je)
     }

     fn from_span_full(
         mut span: Span,
         is_primary: bool,
         label: Option<String>,
         suggestion: Option<(&String, Applicability)>,
         mut backtrace: impl Iterator<Item = ExpnData>,
         je: &JsonEmitter,
     ) -> DiagnosticSpan {
         let empty_source_map;
         let sm = match &je.sm {
             Some(s) => s,
             None => {
                 span = rustc_span::DUMMY_SP;
                 empty_source_map = Arc::new(SourceMap::new(FilePathMapping::empty()));
                 empty_source_map
                     .new_source_file(std::path::PathBuf::from("empty.rs").into(), String::new());
                 &empty_source_map
             }
         };
         let start = sm.lookup_char_pos(span.lo());
         // If this goes from the start of a line to the end and the replacement
         // is an empty string, increase the length to include the newline so we don't
         // leave an empty line
         if start.col.0 == 0
             && let Some((suggestion, _)) = suggestion
             && suggestion.is_empty()
             && let Ok(after) = sm.span_to_next_source(span)
             && after.starts_with('\n')
         {
             span = span.with_hi(span.hi() + rustc_span::BytePos(1));
         }
         let end = sm.lookup_char_pos(span.hi());
         let backtrace_step = backtrace.next().map(|bt| {
             let call_site = Self::from_span_full(bt.call_site, false, None, None, backtrace, je);
             let def_site_span = Self::from_span_full(
                 sm.guess_head_span(bt.def_site),
                 false,
                 None,
                 None,
                 [].into_iter(),
                 je,
             );
             Box::new(DiagnosticSpanMacroExpansion {
                 span: call_site,
                 macro_decl_name: bt.kind.descr(),
                 def_site_span,
             })
         });

         DiagnosticSpan {
             file_name: sm.filename_for_diagnostics(&start.file.name).to_string(),
             byte_start: start.file.original_relative_byte_pos(span.lo()).0,
             byte_end: start.file.original_relative_byte_pos(span.hi()).0,
             line_start: start.line,
             line_end: end.line,
             column_start: start.col.0 + 1,
             column_end: end.col.0 + 1,
             is_primary,
             text: DiagnosticSpanLine::from_span(span, je),
             suggested_replacement: suggestion.map(|x| x.0.clone()),
             suggestion_applicability: suggestion.map(|x| x.1),
             expansion: backtrace_step,
             label,
         }
     }

     fn from_multispan(
         msp: &MultiSpan,
         args: &FluentArgs<'_>,
         je: &JsonEmitter,
     ) -> Vec<DiagnosticSpan> {
         msp.span_labels()
             .into_iter()
             .map(|span_str| Self::from_span_label(span_str, None, args, je))
             .collect()
     }

     fn from_suggestion(
         suggestion: &CodeSuggestion,
         args: &FluentArgs<'_>,
         je: &JsonEmitter,
     ) -> Vec<DiagnosticSpan> {
         suggestion
             .substitutions
             .iter()
             .flat_map(|substitution| {
                 substitution.parts.iter().map(move |suggestion_inner| {
                     let span_label =
                         SpanLabel { span: suggestion_inner.span, is_primary: true, label: None };
                     DiagnosticSpan::from_span_label(
                         span_label,
                         Some((&suggestion_inner.snippet, suggestion.applicability)),
                         args,
                         je,
                     )
                 })
             })
             .collect()
     }
 }

 impl DiagnosticSpanLine {
     fn line_from_source_file(
         sf: &rustc_span::SourceFile,
         index: usize,
         h_start: usize,
         h_end: usize,
     ) -> DiagnosticSpanLine {
         DiagnosticSpanLine {
             text: sf.get_line(index).map_or_else(String::new, |l| l.into_owned()),
             highlight_start: h_start,
             highlight_end: h_end,
         }
     }

     /// Creates a list of DiagnosticSpanLines from span - each line with any part
     /// of `span` gets a DiagnosticSpanLine, with the highlight indicating the
     /// `span` within the line.
     fn from_span(span: Span, je: &JsonEmitter) -> Vec<DiagnosticSpanLine> {
         je.sm
             .as_ref()
             .and_then(|sm| {
                 let lines = sm.span_to_lines(span).ok()?;
                 // We can't get any lines if the source is unavailable.
                 if !should_show_source_code(
                     &je.ignored_directories_in_source_blocks,
                     &sm,
                     &lines.file,
                 ) {
                     return None;
                 }

                 let sf = &*lines.file;
                 let span_lines = lines
                     .lines
                     .iter()
                     .map(|line| {
                         DiagnosticSpanLine::line_from_source_file(
                             sf,
                             line.line_index,
                             line.start_col.0 + 1,
                             line.end_col.0 + 1,
                         )
                     })
                     .collect();
                 Some(span_lines)
             })
             .unwrap_or_default()
     }
 }
	//! A JSON emitter for errors.
	//!
	//! This works by converting errors to a simplified structural format (see the
	//! structs at the start of the file) and then serializing them. These should
	//! contain as much information about the error as possible.
	//!
	//! The format of the JSON output should be considered unstable. For now the
	//! structs at the end of this file (Diagnostic*) specify the error format.

	// FIXME: spec the JSON output properly.

	use std::error::Report;
	use std::io::{self, Write};
	use std::path::Path;
	use std::sync::{Arc, Mutex};
	use std::vec;

	use derive_setters::Setters;
	use rustc_data_structures::sync::IntoDynSyncSend;
	use rustc_error_messages::FluentArgs;
	use rustc_lint_defs::Applicability;
	use rustc_span::Span;
	use rustc_span::hygiene::ExpnData;
	use rustc_span::source_map::{FilePathMapping, SourceMap};
	use serde::Serialize;
	use termcolor::{ColorSpec, WriteColor};

	use crate::diagnostic::IsLint;
	use crate::emitter::{
	ColorConfig, Destination, Emitter, HumanEmitter, HumanReadableErrorType, OutputTheme,
	TimingEvent, should_show_source_code,
	};
	use crate::registry::Registry;
	use crate::timings::{TimingRecord, TimingSection};
	use crate::translation::{Translator, to_fluent_args};
	use crate::{CodeSuggestion, MultiSpan, SpanLabel, Subdiag, Suggestions, TerminalUrl};

	#[cfg(test)]
	mod tests;

	#[derive(Setters)]
	pub struct JsonEmitter {
	#[setters(skip)]
	dst: IntoDynSyncSend<Box<dyn Write + Send>>,
	#[setters(skip)]
	sm: Option<Arc<SourceMap>>,
	#[setters(skip)]
	translator: Translator,
	#[setters(skip)]
	pretty: bool,
	ui_testing: bool,
	ignored_directories_in_source_blocks: Vec<String>,
	#[setters(skip)]
	json_rendered: HumanReadableErrorType,
	color_config: ColorConfig,
	diagnostic_width: Option<usize>,
	macro_backtrace: bool,
	track_diagnostics: bool,
	terminal_url: TerminalUrl,
	}

	impl JsonEmitter {
	pub fn new(
	dst: Box<dyn Write + Send>,
	sm: Option<Arc<SourceMap>>,
	translator: Translator,
	pretty: bool,
	json_rendered: HumanReadableErrorType,
	color_config: ColorConfig,
	) -> JsonEmitter {
	JsonEmitter {
	dst: IntoDynSyncSend(dst),
	sm,
	translator,
	pretty,
	ui_testing: false,
	ignored_directories_in_source_blocks: Vec::new(),
	json_rendered,
	color_config,
	diagnostic_width: None,
	macro_backtrace: false,
	track_diagnostics: false,
	terminal_url: TerminalUrl::No,
	}
	}

	fn emit(&mut self, val: EmitTyped<'_>) -> io::Result<()> {
	if self.pretty {
	serde_json::to_writer_pretty(&mut *self.dst, &val)?
	} else {
	serde_json::to_writer(&mut *self.dst, &val)?
	};
	self.dst.write_all(b"\n")?;
	self.dst.flush()
	}
	}

	#[derive(Serialize)]
	#[serde(tag = "$message_type", rename_all = "snake_case")]
	enum EmitTyped<'a> {
	Diagnostic(Diagnostic),
	Artifact(ArtifactNotification<'a>),
	SectionTiming(SectionTimestamp<'a>),
	FutureIncompat(FutureIncompatReport<'a>),
	UnusedExtern(UnusedExterns<'a>),
	}

	impl Emitter for JsonEmitter {
	fn emit_diagnostic(&mut self, diag: crate::DiagInner, registry: &Registry) {
	let data = Diagnostic::from_errors_diagnostic(diag, self, registry);
	let result = self.emit(EmitTyped::Diagnostic(data));
	if let Err(e) = result {
	panic!("failed to print diagnostics: {e:?}");
	}
	}

	fn emit_artifact_notification(&mut self, path: &Path, artifact_type: &str) {
	let data = ArtifactNotification { artifact: path, emit: artifact_type };
	let result = self.emit(EmitTyped::Artifact(data));
	if let Err(e) = result {
	panic!("failed to print notification: {e:?}");
	}
	}

	fn emit_timing_section(&mut self, record: TimingRecord, event: TimingEvent) {
	let event = match event {
	TimingEvent::Start => "start",
	TimingEvent::End => "end",
	};
	let name = match record.section {
	TimingSection::Linking => "link",
	TimingSection::Codegen => "codegen",
	};
	let data = SectionTimestamp { name, event, timestamp: record.timestamp };
	let result = self.emit(EmitTyped::SectionTiming(data));
	if let Err(e) = result {
	panic!("failed to print timing section: {e:?}");
	}
	}

	fn emit_future_breakage_report(&mut self, diags: Vec<crate::DiagInner>, registry: &Registry) {
	let data: Vec<FutureBreakageItem<'_>> = diags
	.into_iter()
	.map(\|mut diag\| {
	// Allowed or expected lints don't normally (by definition) emit a lint
	// but future incompat lints are special and are emitted anyway.
	//
	// So to avoid ICEs and confused users we "upgrade" the lint level for
	// those `FutureBreakageItem` to warn.
	if matches!(diag.level, crate::Level::Allow \| crate::Level::Expect) {
	diag.level = crate::Level::Warning;
	}
	FutureBreakageItem {
	diagnostic: EmitTyped::Diagnostic(Diagnostic::from_errors_diagnostic(
	diag, self, registry,
	)),
	}
	})
	.collect();
	let report = FutureIncompatReport { future_incompat_report: data };
	let result = self.emit(EmitTyped::FutureIncompat(report));
	if let Err(e) = result {
	panic!("failed to print future breakage report: {e:?}");
	}
	}

	fn emit_unused_externs(&mut self, lint_level: rustc_lint_defs::Level, unused_externs: &[&str]) {
	let lint_level = lint_level.as_str();
	let data = UnusedExterns { lint_level, unused_extern_names: unused_externs };
	let result = self.emit(EmitTyped::UnusedExtern(data));
	if let Err(e) = result {
	panic!("failed to print unused externs: {e:?}");
	}
	}

	fn source_map(&self) -> Option<&SourceMap> {
	self.sm.as_deref()
	}

	fn should_show_explain(&self) -> bool {
	!self.json_rendered.short()
	}

	fn translator(&self) -> &Translator {
	&self.translator
	}
	}

	// The following data types are provided just for serialisation.

	#[derive(Serialize)]
	struct Diagnostic {
	/// The primary error message.
	message: String,
	code: Option<DiagnosticCode>,
	/// "error: internal compiler error", "error", "warning", "note", "help".
	level: &'static str,
	spans: Vec<DiagnosticSpan>,
	/// Associated diagnostic messages.
	children: Vec<Diagnostic>,
	/// The message as rustc would render it.
	rendered: Option<String>,
	}

	#[derive(Serialize)]
	struct DiagnosticSpan {
	file_name: String,
	byte_start: u32,
	byte_end: u32,
	/// 1-based.
	line_start: usize,
	line_end: usize,
	/// 1-based, character offset.
	column_start: usize,
	column_end: usize,
	/// Is this a "primary" span -- meaning the point, or one of the points,
	/// where the error occurred?
	is_primary: bool,
	/// Source text from the start of line_start to the end of line_end.
	text: Vec<DiagnosticSpanLine>,
	/// Label that should be placed at this location (if any)
	label: Option<String>,
	/// If we are suggesting a replacement, this will contain text
	/// that should be sliced in atop this span.
	suggested_replacement: Option<String>,
	/// If the suggestion is approximate
	suggestion_applicability: Option<Applicability>,
	/// Macro invocations that created the code at this span, if any.
	expansion: Option<Box<DiagnosticSpanMacroExpansion>>,
	}

	#[derive(Serialize)]
	struct DiagnosticSpanLine {
	text: String,

	/// 1-based, character offset in self.text.
	highlight_start: usize,

	highlight_end: usize,
	}

	#[derive(Serialize)]
	struct DiagnosticSpanMacroExpansion {
	/// span where macro was applied to generate this code; note that
	/// this may itself derive from a macro (if
	/// `span.expansion.is_some()`)
	span: DiagnosticSpan,

	/// name of macro that was applied (e.g., "foo!" or "#[derive(Eq)]")
	macro_decl_name: String,

	/// span where macro was defined (if known)
	def_site_span: DiagnosticSpan,
	}

	#[derive(Serialize)]
	struct DiagnosticCode {
	/// The error code (e.g. "E1234"), if the diagnostic has one. Or the lint
	/// name, if it's a lint without an error code.
	code: String,
	/// An explanation for the code.
	explanation: Option<&'static str>,
	}

	#[derive(Serialize)]
	struct ArtifactNotification<'a> {
	/// The path of the artifact.
	artifact: &'a Path,
	/// What kind of artifact we're emitting.
	emit: &'a str,
	}

	#[derive(Serialize)]
	struct SectionTimestamp<'a> {
	/// Name of the section
	name: &'a str,
	/// Start/end of the section
	event: &'a str,
	/// Opaque timestamp.
	timestamp: u128,
	}

	#[derive(Serialize)]
	struct FutureBreakageItem<'a> {
	// Always EmitTyped::Diagnostic, but we want to make sure it gets serialized
	// with "$message_type".
	diagnostic: EmitTyped<'a>,
	}

	#[derive(Serialize)]
	struct FutureIncompatReport<'a> {
	future_incompat_report: Vec<FutureBreakageItem<'a>>,
	}

	// NOTE: Keep this in sync with the equivalent structs in rustdoc's
	// doctest component (as well as cargo).
	// We could unify this struct the one in rustdoc but they have different
	// ownership semantics, so doing so would create wasteful allocations.
	#[derive(Serialize)]
	struct UnusedExterns<'a> {
	/// The severity level of the unused dependencies lint
	lint_level: &'a str,
	/// List of unused externs by their names.
	unused_extern_names: &'a [&'a str],
	}

	impl Diagnostic {
	/// Converts from `rustc_errors::DiagInner` to `Diagnostic`.
	fn from_errors_diagnostic(
	diag: crate::DiagInner,
	je: &JsonEmitter,
	registry: &Registry,
	) -> Diagnostic {
	let args = to_fluent_args(diag.args.iter());
	let sugg_to_diag = \|sugg: &CodeSuggestion\| {
	let translated_message =
	je.translator.translate_message(&sugg.msg, &args).map_err(Report::new).unwrap();
	Diagnostic {
	message: translated_message.to_string(),
	code: None,
	level: "help",
	spans: DiagnosticSpan::from_suggestion(sugg, &args, je),
	children: vec![],
	rendered: None,
	}
	};
	let sugg = match &diag.suggestions {
	Suggestions::Enabled(suggestions) => suggestions.iter().map(sugg_to_diag),
	Suggestions::Sealed(suggestions) => suggestions.iter().map(sugg_to_diag),
	Suggestions::Disabled => [].iter().map(sugg_to_diag),
	};

	// generate regular command line output and store it in the json

	// A threadsafe buffer for writing.
	#[derive(Default, Clone)]
	struct BufWriter(Arc<Mutex<Vec<u8>>>);

	impl Write for BufWriter {
	fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
	self.0.lock().unwrap().write(buf)
	}
	fn flush(&mut self) -> io::Result<()> {
	self.0.lock().unwrap().flush()
	}
	}
	impl WriteColor for BufWriter {
	fn supports_color(&self) -> bool {
	false
	}

	fn set_color(&mut self, _spec: &ColorSpec) -> io::Result<()> {
	Ok(())
	}

	fn reset(&mut self) -> io::Result<()> {
	Ok(())
	}
	}

	let translated_message = je.translator.translate_messages(&diag.messages, &args);

	let code = if let Some(code) = diag.code {
	Some(DiagnosticCode {
	code: code.to_string(),
	explanation: registry.try_find_description(code).ok(),
	})
	} else if let Some(IsLint { name, .. }) = &diag.is_lint {
	Some(DiagnosticCode { code: name.to_string(), explanation: None })
	} else {
	None
	};
	let level = diag.level.to_str();
	let spans = DiagnosticSpan::from_multispan(&diag.span, &args, je);
	let mut children: Vec<Diagnostic> = diag
	.children
	.iter()
	.map(\|c\| Diagnostic::from_sub_diagnostic(c, &args, je))
	.chain(sugg)
	.collect();
	if je.track_diagnostics && diag.span.has_primary_spans() && !diag.span.is_dummy() {
	children
	.insert(0, Diagnostic::from_sub_diagnostic(&diag.emitted_at_sub_diag(), &args, je));
	}
	let buf = BufWriter::default();
	let mut dst: Destination = Box::new(buf.clone());
	let short = je.json_rendered.short();
	match je.color_config {
	ColorConfig::Always \| ColorConfig::Auto => dst = Box::new(termcolor::Ansi::new(dst)),
	ColorConfig::Never => {}
	}
	HumanEmitter::new(dst, je.translator.clone())
	.short_message(short)
	.sm(je.sm.clone())
	.diagnostic_width(je.diagnostic_width)
	.macro_backtrace(je.macro_backtrace)
	.track_diagnostics(je.track_diagnostics)
	.terminal_url(je.terminal_url)
	.ui_testing(je.ui_testing)
	.ignored_directories_in_source_blocks(je.ignored_directories_in_source_blocks.clone())
	.theme(if let HumanReadableErrorType::Unicode = je.json_rendered {
	OutputTheme::Unicode
	} else {
	OutputTheme::Ascii
	})
	.emit_diagnostic(diag, registry);
	let buf = Arc::try_unwrap(buf.0).unwrap().into_inner().unwrap();
	let buf = String::from_utf8(buf).unwrap();

	Diagnostic {
	message: translated_message.to_string(),
	code,
	level,
	spans,
	children,
	rendered: Some(buf),
	}
	}

	fn from_sub_diagnostic(
	subdiag: &Subdiag,
	args: &FluentArgs<'_>,
	je: &JsonEmitter,
	) -> Diagnostic {
	let translated_message = je.translator.translate_messages(&subdiag.messages, args);
	Diagnostic {
	message: translated_message.to_string(),
	code: None,
	level: subdiag.level.to_str(),
	spans: DiagnosticSpan::from_multispan(&subdiag.span, args, je),
	children: vec![],
	rendered: None,
	}
	}
	}

	impl DiagnosticSpan {
	fn from_span_label(
	span: SpanLabel,
	suggestion: Option<(&String, Applicability)>,
	args: &FluentArgs<'_>,
	je: &JsonEmitter,
	) -> DiagnosticSpan {
	Self::from_span_etc(
	span.span,
	span.is_primary,
	span.label
	.as_ref()
	.map(\|m\| je.translator.translate_message(m, args).unwrap())
	.map(\|m\| m.to_string()),
	suggestion,
	je,
	)
	}

	fn from_span_etc(
	span: Span,
	is_primary: bool,
	label: Option<String>,
	suggestion: Option<(&String, Applicability)>,
	je: &JsonEmitter,
	) -> DiagnosticSpan {
	// obtain the full backtrace from the `macro_backtrace`
	// helper; in some ways, it'd be better to expand the
	// backtrace ourselves, but the `macro_backtrace` helper makes
	// some decision, such as dropping some frames, and I don't
	// want to duplicate that logic here.
	let backtrace = span.macro_backtrace();
	DiagnosticSpan::from_span_full(span, is_primary, label, suggestion, backtrace, je)
	}

	fn from_span_full(
	mut span: Span,
	is_primary: bool,
	label: Option<String>,
	suggestion: Option<(&String, Applicability)>,
	mut backtrace: impl Iterator<Item = ExpnData>,
	je: &JsonEmitter,
	) -> DiagnosticSpan {
	let empty_source_map;
	let sm = match &je.sm {
	Some(s) => s,
	None => {
	span = rustc_span::DUMMY_SP;
	empty_source_map = Arc::new(SourceMap::new(FilePathMapping::empty()));
	empty_source_map
	.new_source_file(std::path::PathBuf::from("empty.rs").into(), String::new());
	&empty_source_map
	}
	};
	let start = sm.lookup_char_pos(span.lo());
	// If this goes from the start of a line to the end and the replacement
	// is an empty string, increase the length to include the newline so we don't
	// leave an empty line
	if start.col.0 == 0
	&& let Some((suggestion, _)) = suggestion
	&& suggestion.is_empty()
	&& let Ok(after) = sm.span_to_next_source(span)
	&& after.starts_with('\n')
	{
	span = span.with_hi(span.hi() + rustc_span::BytePos(1));
	}
	let end = sm.lookup_char_pos(span.hi());
	let backtrace_step = backtrace.next().map(\|bt\| {
	let call_site = Self::from_span_full(bt.call_site, false, None, None, backtrace, je);
	let def_site_span = Self::from_span_full(
	sm.guess_head_span(bt.def_site),
	false,
	None,
	None,
	[].into_iter(),
	je,
	);
	Box::new(DiagnosticSpanMacroExpansion {
	span: call_site,
	macro_decl_name: bt.kind.descr(),
	def_site_span,
	})
	});

	DiagnosticSpan {
	file_name: sm.filename_for_diagnostics(&start.file.name).to_string(),
	byte_start: start.file.original_relative_byte_pos(span.lo()).0,
	byte_end: start.file.original_relative_byte_pos(span.hi()).0,
	line_start: start.line,
	line_end: end.line,
	column_start: start.col.0 + 1,
	column_end: end.col.0 + 1,
	is_primary,
	text: DiagnosticSpanLine::from_span(span, je),
	suggested_replacement: suggestion.map(\|x\| x.0.clone()),
	suggestion_applicability: suggestion.map(\|x\| x.1),
	expansion: backtrace_step,
	label,
	}
	}

	fn from_multispan(
	msp: &MultiSpan,
	args: &FluentArgs<'_>,
	je: &JsonEmitter,
	) -> Vec<DiagnosticSpan> {
	msp.span_labels()
	.into_iter()
	.map(\|span_str\| Self::from_span_label(span_str, None, args, je))
	.collect()
	}

	fn from_suggestion(
	suggestion: &CodeSuggestion,
	args: &FluentArgs<'_>,
	je: &JsonEmitter,
	) -> Vec<DiagnosticSpan> {
	suggestion
	.substitutions
	.iter()
	.flat_map(\|substitution\| {
	substitution.parts.iter().map(move \|suggestion_inner\| {
	let span_label =
	SpanLabel { span: suggestion_inner.span, is_primary: true, label: None };
	DiagnosticSpan::from_span_label(
	span_label,
	Some((&suggestion_inner.snippet, suggestion.applicability)),
	args,
	je,
	)
	})
	})
	.collect()
	}
	}

	impl DiagnosticSpanLine {
	fn line_from_source_file(
	sf: &rustc_span::SourceFile,
	index: usize,
	h_start: usize,
	h_end: usize,
	) -> DiagnosticSpanLine {
	DiagnosticSpanLine {
	text: sf.get_line(index).map_or_else(String::new, \|l\| l.into_owned()),
	highlight_start: h_start,
	highlight_end: h_end,
	}
	}

	/// Creates a list of DiagnosticSpanLines from span - each line with any part
	/// of `span` gets a DiagnosticSpanLine, with the highlight indicating the
	/// `span` within the line.
	fn from_span(span: Span, je: &JsonEmitter) -> Vec<DiagnosticSpanLine> {
	je.sm
	.as_ref()
	.and_then(\|sm\| {
	let lines = sm.span_to_lines(span).ok()?;
	// We can't get any lines if the source is unavailable.
	if !should_show_source_code(
	&je.ignored_directories_in_source_blocks,
	&sm,
	&lines.file,
	) {
	return None;
	}

	let sf = &*lines.file;
	let span_lines = lines
	.lines
	.iter()
	.map(\|line\| {
	DiagnosticSpanLine::line_from_source_file(
	sf,
	line.line_index,
	line.start_col.0 + 1,
	line.end_col.0 + 1,
	)
	})
	.collect();
	Some(span_lines)
	})
	.unwrap_or_default()
	}
	}