//! 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 rustc_span::source_map::{FilePathMapping, SourceMap}; use crate::emitter::{Emitter, HumanReadableErrorType}; use crate::registry::Registry; use crate::{Applicability, DiagnosticId}; use crate::{CodeSuggestion, SubDiagnostic}; use rustc_data_structures::sync::Lrc; use rustc_span::hygiene::ExpnData; use rustc_span::{MultiSpan, Span, SpanLabel}; use std::io::{self, Write}; use std::path::Path; use std::sync::{Arc, Mutex}; use std::vec; use rustc_serialize::json::{as_json, as_pretty_json}; #[cfg(test)] mod tests; pub struct JsonEmitter { dst: Box, registry: Option, sm: Lrc, pretty: bool, ui_testing: bool, json_rendered: HumanReadableErrorType, macro_backtrace: bool, } impl JsonEmitter { pub fn stderr( registry: Option, source_map: Lrc, pretty: bool, json_rendered: HumanReadableErrorType, macro_backtrace: bool, ) -> JsonEmitter { JsonEmitter { dst: Box::new(io::BufWriter::new(io::stderr())), registry, sm: source_map, pretty, ui_testing: false, json_rendered, macro_backtrace, } } pub fn basic( pretty: bool, json_rendered: HumanReadableErrorType, macro_backtrace: bool, ) -> JsonEmitter { let file_path_mapping = FilePathMapping::empty(); JsonEmitter::stderr( None, Lrc::new(SourceMap::new(file_path_mapping)), pretty, json_rendered, macro_backtrace, ) } pub fn new( dst: Box, registry: Option, source_map: Lrc, pretty: bool, json_rendered: HumanReadableErrorType, macro_backtrace: bool, ) -> JsonEmitter { JsonEmitter { dst, registry, sm: source_map, pretty, ui_testing: false, json_rendered, macro_backtrace, } } pub fn ui_testing(self, ui_testing: bool) -> Self { Self { ui_testing, ..self } } } impl Emitter for JsonEmitter { fn emit_diagnostic(&mut self, diag: &crate::Diagnostic) { let data = Diagnostic::from_errors_diagnostic(diag, self); let result = if self.pretty { writeln!(&mut self.dst, "{}", as_pretty_json(&data)) } else { writeln!(&mut self.dst, "{}", as_json(&data)) } .and_then(|_| self.dst.flush()); 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 = if self.pretty { writeln!(&mut self.dst, "{}", as_pretty_json(&data)) } else { writeln!(&mut self.dst, "{}", as_json(&data)) } .and_then(|_| self.dst.flush()); if let Err(e) = result { panic!("failed to print notification: {:?}", e); } } fn source_map(&self) -> Option<&Lrc> { Some(&self.sm) } fn should_show_explain(&self) -> bool { match self.json_rendered { HumanReadableErrorType::Short(_) => false, _ => true, } } } // The following data types are provided just for serialisation. #[derive(RustcEncodable)] struct Diagnostic { /// The primary error message. message: String, code: Option, /// "error: internal compiler error", "error", "warning", "note", "help". level: &'static str, spans: Vec, /// Associated diagnostic messages. children: Vec, /// The message as rustc would render it. rendered: Option, } #[derive(RustcEncodable)] 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, /// Label that should be placed at this location (if any) label: Option, /// If we are suggesting a replacement, this will contain text /// that should be sliced in atop this span. suggested_replacement: Option, /// If the suggestion is approximate suggestion_applicability: Option, /// Macro invocations that created the code at this span, if any. expansion: Option>, } #[derive(RustcEncodable)] struct DiagnosticSpanLine { text: String, /// 1-based, character offset in self.text. highlight_start: usize, highlight_end: usize, } #[derive(RustcEncodable)] 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(RustcEncodable)] struct DiagnosticCode { /// The code itself. code: String, /// An explanation for the code. explanation: Option<&'static str>, } #[derive(RustcEncodable)] struct ArtifactNotification<'a> { /// The path of the artifact. artifact: &'a Path, /// What kind of artifact we're emitting. emit: &'a str, } impl Diagnostic { fn from_errors_diagnostic(diag: &crate::Diagnostic, je: &JsonEmitter) -> Diagnostic { let sugg = diag.suggestions.iter().map(|sugg| Diagnostic { message: sugg.msg.clone(), code: None, level: "help", spans: DiagnosticSpan::from_suggestion(sugg, je), children: vec![], rendered: None, }); // generate regular command line output and store it in the json // A threadsafe buffer for writing. #[derive(Default, Clone)] struct BufWriter(Arc>>); impl Write for BufWriter { fn write(&mut self, buf: &[u8]) -> io::Result { self.0.lock().unwrap().write(buf) } fn flush(&mut self) -> io::Result<()> { self.0.lock().unwrap().flush() } } let buf = BufWriter::default(); let output = buf.clone(); je.json_rendered .new_emitter(Box::new(buf), Some(je.sm.clone()), false, None, je.macro_backtrace) .ui_testing(je.ui_testing) .emit_diagnostic(diag); let output = Arc::try_unwrap(output.0).unwrap().into_inner().unwrap(); let output = String::from_utf8(output).unwrap(); Diagnostic { message: diag.message(), code: DiagnosticCode::map_opt_string(diag.code.clone(), je), level: diag.level.to_str(), spans: DiagnosticSpan::from_multispan(&diag.span, je), children: diag .children .iter() .map(|c| Diagnostic::from_sub_diagnostic(c, je)) .chain(sugg) .collect(), rendered: Some(output), } } fn from_sub_diagnostic(diag: &SubDiagnostic, je: &JsonEmitter) -> Diagnostic { Diagnostic { message: diag.message(), code: None, level: diag.level.to_str(), spans: diag .render_span .as_ref() .map(|sp| DiagnosticSpan::from_multispan(sp, je)) .unwrap_or_else(|| DiagnosticSpan::from_multispan(&diag.span, je)), children: vec![], rendered: None, } } } impl DiagnosticSpan { fn from_span_label( span: SpanLabel, suggestion: Option<(&String, Applicability)>, je: &JsonEmitter, ) -> DiagnosticSpan { Self::from_span_etc(span.span, span.is_primary, span.label, suggestion, je) } fn from_span_etc( span: Span, is_primary: bool, label: Option, 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( span: Span, is_primary: bool, label: Option, suggestion: Option<(&String, Applicability)>, mut backtrace: impl Iterator, je: &JsonEmitter, ) -> DiagnosticSpan { let start = je.sm.lookup_char_pos(span.lo()); let end = je.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(bt.def_site, false, None, None, vec![].into_iter(), je); Box::new(DiagnosticSpanMacroExpansion { span: call_site, macro_decl_name: bt.kind.descr(), def_site_span, }) }); DiagnosticSpan { file_name: 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, je: &JsonEmitter) -> Vec { msp.span_labels() .into_iter() .map(|span_str| Self::from_span_label(span_str, None, je)) .collect() } fn from_suggestion(suggestion: &CodeSuggestion, je: &JsonEmitter) -> Vec { 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)), 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(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 { je.sm .span_to_lines(span) .map(|lines| { // We can't get any lines if the source is unavailable. if !je.sm.ensure_source_file_source_present(lines.file.clone()) { return vec![]; } let sf = &*lines.file; 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() }) .unwrap_or_else(|_| vec![]) } } impl DiagnosticCode { fn map_opt_string(s: Option, je: &JsonEmitter) -> Option { s.map(|s| { let s = match s { DiagnosticId::Error(s) => s, DiagnosticId::Lint(s) => s, }; let je_result = je.registry.as_ref().map(|registry| registry.try_find_description(&s)).unwrap(); DiagnosticCode { code: s, explanation: je_result.unwrap_or(None) } }) } }