// Copyright 2012 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. pub use self::Level::*; pub use self::RenderSpan::*; pub use self::ColorConfig::*; use self::Destination::*; use codemap::{self, COMMAND_LINE_SP, COMMAND_LINE_EXPN, Pos, Span}; use diagnostics; use std::cell::{RefCell, Cell}; use std::{cmp, error, fmt}; use std::io::prelude::*; use std::io; use term::{self, WriterWrapper}; /// maximum number of lines we will print for each error; arbitrary. const MAX_LINES: usize = 6; #[derive(Clone)] pub enum RenderSpan { /// A FullSpan renders with both with an initial line for the /// message, prefixed by file:linenum, followed by a summary of /// the source code covered by the span. FullSpan(Span), /// Similar to a FullSpan, but the cited position is the end of /// the span, instead of the start. Used, at least, for telling /// compiletest/runtest to look at the last line of the span /// (since `end_highlight_lines` displays an arrow to the end /// of the span). EndSpan(Span), /// A suggestion renders with both with an initial line for the /// message, prefixed by file:linenum, followed by a summary /// of hypothetical source code, where the `String` is spliced /// into the lines in place of the code covered by the span. Suggestion(Span, String), /// A FileLine renders with just a line for the message prefixed /// by file:linenum. FileLine(Span), } impl RenderSpan { fn span(&self) -> Span { match *self { FullSpan(s) | Suggestion(s, _) | EndSpan(s) | FileLine(s) => s } } } #[derive(Clone, Copy)] pub enum ColorConfig { Auto, Always, Never } pub trait Emitter { fn emit(&mut self, cmsp: Option<(&codemap::CodeMap, Span)>, msg: &str, code: Option<&str>, lvl: Level); fn custom_emit(&mut self, cm: &codemap::CodeMap, sp: RenderSpan, msg: &str, lvl: Level); } /// Used as a return value to signify a fatal error occurred. (It is also /// used as the argument to panic at the moment, but that will eventually /// not be true.) #[derive(Copy, Clone, Debug)] #[must_use] pub struct FatalError; impl fmt::Display for FatalError { fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> { write!(f, "parser fatal error") } } impl error::Error for FatalError { fn description(&self) -> &str { "The parser has encountered a fatal error" } } /// Signifies that the compiler died with an explicit call to `.bug` /// or `.span_bug` rather than a failed assertion, etc. #[derive(Copy, Clone, Debug)] pub struct ExplicitBug; impl fmt::Display for ExplicitBug { fn fmt(&self, f: &mut fmt::Formatter) -> Result<(), fmt::Error> { write!(f, "parser internal bug") } } impl error::Error for ExplicitBug { fn description(&self) -> &str { "The parser has encountered an internal bug" } } /// A span-handler is like a handler but also /// accepts span information for source-location /// reporting. pub struct SpanHandler { pub handler: Handler, pub cm: codemap::CodeMap, } impl SpanHandler { pub fn new(handler: Handler, cm: codemap::CodeMap) -> SpanHandler { SpanHandler { handler: handler, cm: cm, } } pub fn span_fatal(&self, sp: Span, msg: &str) -> FatalError { self.handler.emit(Some((&self.cm, sp)), msg, Fatal); return FatalError; } pub fn span_fatal_with_code(&self, sp: Span, msg: &str, code: &str) -> FatalError { self.handler.emit_with_code(Some((&self.cm, sp)), msg, code, Fatal); return FatalError; } pub fn span_err(&self, sp: Span, msg: &str) { self.handler.emit(Some((&self.cm, sp)), msg, Error); self.handler.bump_err_count(); } pub fn span_err_with_code(&self, sp: Span, msg: &str, code: &str) { self.handler.emit_with_code(Some((&self.cm, sp)), msg, code, Error); self.handler.bump_err_count(); } pub fn span_warn(&self, sp: Span, msg: &str) { self.handler.emit(Some((&self.cm, sp)), msg, Warning); } pub fn span_warn_with_code(&self, sp: Span, msg: &str, code: &str) { self.handler.emit_with_code(Some((&self.cm, sp)), msg, code, Warning); } pub fn span_note(&self, sp: Span, msg: &str) { self.handler.emit(Some((&self.cm, sp)), msg, Note); } pub fn span_end_note(&self, sp: Span, msg: &str) { self.handler.custom_emit(&self.cm, EndSpan(sp), msg, Note); } pub fn span_help(&self, sp: Span, msg: &str) { self.handler.emit(Some((&self.cm, sp)), msg, Help); } /// Prints out a message with a suggested edit of the code. /// /// See `diagnostic::RenderSpan::Suggestion` for more information. pub fn span_suggestion(&self, sp: Span, msg: &str, suggestion: String) { self.handler.custom_emit(&self.cm, Suggestion(sp, suggestion), msg, Help); } pub fn fileline_note(&self, sp: Span, msg: &str) { self.handler.custom_emit(&self.cm, FileLine(sp), msg, Note); } pub fn fileline_help(&self, sp: Span, msg: &str) { self.handler.custom_emit(&self.cm, FileLine(sp), msg, Help); } pub fn span_bug(&self, sp: Span, msg: &str) -> ! { self.handler.emit(Some((&self.cm, sp)), msg, Bug); panic!(ExplicitBug); } pub fn span_unimpl(&self, sp: Span, msg: &str) -> ! { self.span_bug(sp, &format!("unimplemented {}", msg)); } pub fn handler<'a>(&'a self) -> &'a Handler { &self.handler } } /// A handler deals with errors; certain errors /// (fatal, bug, unimpl) may cause immediate exit, /// others log errors for later reporting. pub struct Handler { err_count: Cell, emit: RefCell>, pub can_emit_warnings: bool } impl Handler { pub fn new(color_config: ColorConfig, registry: Option, can_emit_warnings: bool) -> Handler { let emitter = Box::new(EmitterWriter::stderr(color_config, registry)); Handler::with_emitter(can_emit_warnings, emitter) } pub fn with_emitter(can_emit_warnings: bool, e: Box) -> Handler { Handler { err_count: Cell::new(0), emit: RefCell::new(e), can_emit_warnings: can_emit_warnings } } pub fn fatal(&self, msg: &str) -> FatalError { self.emit.borrow_mut().emit(None, msg, None, Fatal); FatalError } pub fn err(&self, msg: &str) { self.emit.borrow_mut().emit(None, msg, None, Error); self.bump_err_count(); } pub fn bump_err_count(&self) { self.err_count.set(self.err_count.get() + 1); } pub fn err_count(&self) -> usize { self.err_count.get() } pub fn has_errors(&self) -> bool { self.err_count.get() > 0 } pub fn abort_if_errors(&self) { let s; match self.err_count.get() { 0 => return, 1 => s = "aborting due to previous error".to_string(), _ => { s = format!("aborting due to {} previous errors", self.err_count.get()); } } panic!(self.fatal(&s[..])); } pub fn warn(&self, msg: &str) { self.emit.borrow_mut().emit(None, msg, None, Warning); } pub fn note(&self, msg: &str) { self.emit.borrow_mut().emit(None, msg, None, Note); } pub fn help(&self, msg: &str) { self.emit.borrow_mut().emit(None, msg, None, Help); } pub fn bug(&self, msg: &str) -> ! { self.emit.borrow_mut().emit(None, msg, None, Bug); panic!(ExplicitBug); } pub fn unimpl(&self, msg: &str) -> ! { self.bug(&format!("unimplemented {}", msg)); } pub fn emit(&self, cmsp: Option<(&codemap::CodeMap, Span)>, msg: &str, lvl: Level) { if lvl == Warning && !self.can_emit_warnings { return } self.emit.borrow_mut().emit(cmsp, msg, None, lvl); } pub fn emit_with_code(&self, cmsp: Option<(&codemap::CodeMap, Span)>, msg: &str, code: &str, lvl: Level) { if lvl == Warning && !self.can_emit_warnings { return } self.emit.borrow_mut().emit(cmsp, msg, Some(code), lvl); } pub fn custom_emit(&self, cm: &codemap::CodeMap, sp: RenderSpan, msg: &str, lvl: Level) { if lvl == Warning && !self.can_emit_warnings { return } self.emit.borrow_mut().custom_emit(cm, sp, msg, lvl); } } #[derive(Copy, PartialEq, Clone, Debug)] pub enum Level { Bug, Fatal, Error, Warning, Note, Help, } impl fmt::Display for Level { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { use std::fmt::Display; match *self { Bug => "error: internal compiler error".fmt(f), Fatal | Error => "error".fmt(f), Warning => "warning".fmt(f), Note => "note".fmt(f), Help => "help".fmt(f), } } } impl Level { fn color(self) -> term::color::Color { match self { Bug | Fatal | Error => term::color::BRIGHT_RED, Warning => term::color::BRIGHT_YELLOW, Note => term::color::BRIGHT_GREEN, Help => term::color::BRIGHT_CYAN, } } } pub struct EmitterWriter { dst: Destination, registry: Option } enum Destination { Terminal(Box + Send>), Raw(Box), } /// Do not use this for messages that end in `\n` – use `println_maybe_styled` instead. See /// `EmitterWriter::print_maybe_styled` for details. macro_rules! print_maybe_styled { ($writer: expr, $style: expr, $($arg: tt)*) => { $writer.print_maybe_styled(format_args!($($arg)*), $style, false) } } macro_rules! println_maybe_styled { ($writer: expr, $style: expr, $($arg: tt)*) => { $writer.print_maybe_styled(format_args!($($arg)*), $style, true) } } impl EmitterWriter { pub fn stderr(color_config: ColorConfig, registry: Option) -> EmitterWriter { let stderr = io::stderr(); let use_color = match color_config { Always => true, Never => false, Auto => stderr_isatty(), }; if use_color { let dst = match term::stderr() { Some(t) => Terminal(t), None => Raw(Box::new(stderr)), }; EmitterWriter { dst: dst, registry: registry } } else { EmitterWriter { dst: Raw(Box::new(stderr)), registry: registry } } } pub fn new(dst: Box, registry: Option) -> EmitterWriter { EmitterWriter { dst: Raw(dst), registry: registry } } fn print_maybe_styled(&mut self, args: fmt::Arguments, color: term::attr::Attr, print_newline_at_end: bool) -> io::Result<()> { match self.dst { Terminal(ref mut t) => { try!(t.attr(color)); // If `msg` ends in a newline, we need to reset the color before // the newline. We're making the assumption that we end up writing // to a `LineBufferedWriter`, which means that emitting the reset // after the newline ends up buffering the reset until we print // another line or exit. Buffering the reset is a problem if we're // sharing the terminal with any other programs (e.g. other rustc // instances via `make -jN`). // // Note that if `msg` contains any internal newlines, this will // result in the `LineBufferedWriter` flushing twice instead of // once, which still leaves the opportunity for interleaved output // to be miscolored. We assume this is rare enough that we don't // have to worry about it. try!(t.write_fmt(args)); try!(t.reset()); if print_newline_at_end { t.write_all(b"\n") } else { Ok(()) } } Raw(ref mut w) => { try!(w.write_fmt(args)); if print_newline_at_end { w.write_all(b"\n") } else { Ok(()) } } } } fn print_diagnostic(&mut self, topic: &str, lvl: Level, msg: &str, code: Option<&str>) -> io::Result<()> { if !topic.is_empty() { try!(write!(&mut self.dst, "{} ", topic)); } try!(print_maybe_styled!(self, term::attr::ForegroundColor(lvl.color()), "{}: ", lvl.to_string())); try!(print_maybe_styled!(self, term::attr::Bold, "{}", msg)); match code { Some(code) => { let style = term::attr::ForegroundColor(term::color::BRIGHT_MAGENTA); try!(print_maybe_styled!(self, style, " [{}]", code.clone())); } None => () } try!(write!(&mut self.dst, "\n")); Ok(()) } fn emit_(&mut self, cm: &codemap::CodeMap, rsp: RenderSpan, msg: &str, code: Option<&str>, lvl: Level) -> io::Result<()> { let sp = rsp.span(); // We cannot check equality directly with COMMAND_LINE_SP // since PartialEq is manually implemented to ignore the ExpnId let ss = if sp.expn_id == COMMAND_LINE_EXPN { "".to_string() } else if let EndSpan(_) = rsp { let span_end = Span { lo: sp.hi, hi: sp.hi, expn_id: sp.expn_id}; cm.span_to_string(span_end) } else { cm.span_to_string(sp) }; try!(self.print_diagnostic(&ss[..], lvl, msg, code)); match rsp { FullSpan(_) => { try!(self.highlight_lines(cm, sp, lvl, cm.span_to_lines(sp))); try!(self.print_macro_backtrace(cm, sp)); } EndSpan(_) => { try!(self.end_highlight_lines(cm, sp, lvl, cm.span_to_lines(sp))); try!(self.print_macro_backtrace(cm, sp)); } Suggestion(_, ref suggestion) => { try!(self.highlight_suggestion(cm, sp, suggestion)); try!(self.print_macro_backtrace(cm, sp)); } FileLine(..) => { // no source text in this case! } } match code { Some(code) => match self.registry.as_ref().and_then(|registry| registry.find_description(code)) { Some(_) => { try!(self.print_diagnostic(&ss[..], Help, &format!("run `rustc --explain {}` to see a \ detailed explanation", code), None)); } None => () }, None => (), } Ok(()) } fn highlight_suggestion(&mut self, cm: &codemap::CodeMap, sp: Span, suggestion: &str) -> io::Result<()> { let lines = cm.span_to_lines(sp).unwrap(); assert!(!lines.lines.is_empty()); // To build up the result, we want to take the snippet from the first // line that precedes the span, prepend that with the suggestion, and // then append the snippet from the last line that trails the span. let fm = &lines.file; let first_line = &lines.lines[0]; let prefix = fm.get_line(first_line.line_index) .map(|l| &l[..first_line.start_col.0]) .unwrap_or(""); let last_line = lines.lines.last().unwrap(); let suffix = fm.get_line(last_line.line_index) .map(|l| &l[last_line.end_col.0..]) .unwrap_or(""); let complete = format!("{}{}{}", prefix, suggestion, suffix); // print the suggestion without any line numbers, but leave // space for them. This helps with lining up with previous // snippets from the actual error being reported. let fm = &*lines.file; let mut lines = complete.lines(); for (line, line_index) in lines.by_ref().take(MAX_LINES).zip(first_line.line_index..) { let elided_line_num = format!("{}", line_index+1); try!(write!(&mut self.dst, "{0}:{1:2$} {3}\n", fm.name, "", elided_line_num.len(), line)); } // if we elided some lines, add an ellipsis if lines.next().is_some() { let elided_line_num = format!("{}", first_line.line_index + MAX_LINES + 1); try!(write!(&mut self.dst, "{0:1$} {0:2$} ...\n", "", fm.name.len(), elided_line_num.len())); } Ok(()) } fn highlight_lines(&mut self, cm: &codemap::CodeMap, sp: Span, lvl: Level, lines: codemap::FileLinesResult) -> io::Result<()> { let lines = match lines { Ok(lines) => lines, Err(_) => { try!(write!(&mut self.dst, "(internal compiler error: unprintable span)\n")); return Ok(()); } }; let fm = &*lines.file; let line_strings: Option> = lines.lines.iter() .map(|info| fm.get_line(info.line_index)) .collect(); let line_strings = match line_strings { None => { return Ok(()); } Some(line_strings) => line_strings }; // Display only the first MAX_LINES lines. let all_lines = lines.lines.len(); let display_lines = cmp::min(all_lines, MAX_LINES); let display_line_infos = &lines.lines[..display_lines]; let display_line_strings = &line_strings[..display_lines]; // Calculate the widest number to format evenly and fix #11715 assert!(display_line_infos.len() > 0); let mut max_line_num = display_line_infos[display_line_infos.len() - 1].line_index + 1; let mut digits = 0; while max_line_num > 0 { max_line_num /= 10; digits += 1; } // Print the offending lines for (line_info, line) in display_line_infos.iter().zip(display_line_strings) { try!(write!(&mut self.dst, "{}:{:>width$} {}\n", fm.name, line_info.line_index + 1, line, width=digits)); } // If we elided something, put an ellipsis. if display_lines < all_lines { let last_line_index = display_line_infos.last().unwrap().line_index; let s = format!("{}:{} ", fm.name, last_line_index + 1); try!(write!(&mut self.dst, "{0:1$}...\n", "", s.len())); } // FIXME (#3260) // If there's one line at fault we can easily point to the problem if lines.lines.len() == 1 { let lo = cm.lookup_char_pos(sp.lo); let mut digits = 0; let mut num = (lines.lines[0].line_index + 1) / 10; // how many digits must be indent past? while num > 0 { num /= 10; digits += 1; } let mut s = String::new(); // Skip is the number of characters we need to skip because they are // part of the 'filename:line ' part of the previous line. let skip = fm.name.chars().count() + digits + 3; for _ in 0..skip { s.push(' '); } if let Some(orig) = fm.get_line(lines.lines[0].line_index) { let mut col = skip; let mut lastc = ' '; let mut iter = orig.chars().enumerate(); for (pos, ch) in iter.by_ref() { lastc = ch; if pos >= lo.col.to_usize() { break; } // Whenever a tab occurs on the previous line, we insert one on // the error-point-squiggly-line as well (instead of a space). // That way the squiggly line will usually appear in the correct // position. match ch { '\t' => { col += 8 - col%8; s.push('\t'); }, _ => { col += 1; s.push(' '); }, } } try!(write!(&mut self.dst, "{}", s)); let mut s = String::from("^"); let count = match lastc { // Most terminals have a tab stop every eight columns by default '\t' => 8 - col%8, _ => 1, }; col += count; s.extend(::std::iter::repeat('~').take(count)); let hi = cm.lookup_char_pos(sp.hi); if hi.col != lo.col { for (pos, ch) in iter { if pos >= hi.col.to_usize() { break; } let count = match ch { '\t' => 8 - col%8, _ => 1, }; col += count; s.extend(::std::iter::repeat('~').take(count)); } } if s.len() > 1 { // One extra squiggly is replaced by a "^" s.pop(); } try!(println_maybe_styled!(self, term::attr::ForegroundColor(lvl.color()), "{}", s)); } } Ok(()) } /// Here are the differences between this and the normal `highlight_lines`: /// `end_highlight_lines` will always put arrow on the last byte of the /// span (instead of the first byte). Also, when the span is too long (more /// than 6 lines), `end_highlight_lines` will print the first line, then /// dot dot dot, then last line, whereas `highlight_lines` prints the first /// six lines. #[allow(deprecated)] fn end_highlight_lines(&mut self, cm: &codemap::CodeMap, sp: Span, lvl: Level, lines: codemap::FileLinesResult) -> io::Result<()> { let lines = match lines { Ok(lines) => lines, Err(_) => { try!(write!(&mut self.dst, "(internal compiler error: unprintable span)\n")); return Ok(()); } }; let fm = &*lines.file; let lines = &lines.lines[..]; if lines.len() > MAX_LINES { if let Some(line) = fm.get_line(lines[0].line_index) { try!(write!(&mut self.dst, "{}:{} {}\n", fm.name, lines[0].line_index + 1, line)); } try!(write!(&mut self.dst, "...\n")); let last_line_index = lines[lines.len() - 1].line_index; if let Some(last_line) = fm.get_line(last_line_index) { try!(write!(&mut self.dst, "{}:{} {}\n", fm.name, last_line_index + 1, last_line)); } } else { for line_info in lines { if let Some(line) = fm.get_line(line_info.line_index) { try!(write!(&mut self.dst, "{}:{} {}\n", fm.name, line_info.line_index + 1, line)); } } } let last_line_start = format!("{}:{} ", fm.name, lines[lines.len()-1].line_index + 1); let hi = cm.lookup_char_pos(sp.hi); let skip = last_line_start.chars().count(); let mut s = String::new(); for _ in 0..skip { s.push(' '); } if let Some(orig) = fm.get_line(lines[0].line_index) { let iter = orig.chars().enumerate(); for (pos, ch) in iter { // Span seems to use half-opened interval, so subtract 1 if pos >= hi.col.to_usize() - 1 { break; } // Whenever a tab occurs on the previous line, we insert one on // the error-point-squiggly-line as well (instead of a space). // That way the squiggly line will usually appear in the correct // position. match ch { '\t' => s.push('\t'), _ => s.push(' '), } } } s.push('^'); println_maybe_styled!(self, term::attr::ForegroundColor(lvl.color()), "{}", s) } fn print_macro_backtrace(&mut self, cm: &codemap::CodeMap, sp: Span) -> io::Result<()> { let mut last_span = codemap::DUMMY_SP; let mut sp_opt = Some(sp); while let Some(sp) = sp_opt { sp_opt = try!(cm.with_expn_info(sp.expn_id, |expn_info| -> io::Result<_> { match expn_info { Some(ei) => { let (pre, post) = match ei.callee.format { codemap::MacroAttribute(..) => ("#[", "]"), codemap::MacroBang(..) => ("", "!"), }; // Don't print recursive invocations if ei.call_site != last_span { last_span = ei.call_site; let mut diag_string = format!("in this expansion of {}{}{}", pre, ei.callee.name(), post); if let Some(def_site_span) = ei.callee.span { diag_string.push_str(&format!(" (defined in {})", cm.span_to_filename(def_site_span))); } try!(self.print_diagnostic(&cm.span_to_string(ei.call_site), Note, &diag_string, None)); } Ok(Some(ei.call_site)) } None => Ok(None) } })); } Ok(()) } } #[cfg(unix)] fn stderr_isatty() -> bool { use libc; unsafe { libc::isatty(libc::STDERR_FILENO) != 0 } } #[cfg(windows)] fn stderr_isatty() -> bool { type DWORD = u32; type BOOL = i32; type HANDLE = *mut u8; const STD_ERROR_HANDLE: DWORD = -12i32 as DWORD; extern "system" { fn GetStdHandle(which: DWORD) -> HANDLE; fn GetConsoleMode(hConsoleHandle: HANDLE, lpMode: *mut DWORD) -> BOOL; } unsafe { let handle = GetStdHandle(STD_ERROR_HANDLE); let mut out = 0; GetConsoleMode(handle, &mut out) != 0 } } impl Write for Destination { fn write(&mut self, bytes: &[u8]) -> io::Result { match *self { Terminal(ref mut t) => t.write(bytes), Raw(ref mut w) => w.write(bytes), } } fn flush(&mut self) -> io::Result<()> { match *self { Terminal(ref mut t) => t.flush(), Raw(ref mut w) => w.flush(), } } } impl Emitter for EmitterWriter { fn emit(&mut self, cmsp: Option<(&codemap::CodeMap, Span)>, msg: &str, code: Option<&str>, lvl: Level) { let error = match cmsp { Some((cm, COMMAND_LINE_SP)) => self.emit_(cm, FileLine(COMMAND_LINE_SP), msg, code, lvl), Some((cm, sp)) => self.emit_(cm, FullSpan(sp), msg, code, lvl), None => self.print_diagnostic("", lvl, msg, code), }; match error { Ok(()) => {} Err(e) => panic!("failed to print diagnostics: {:?}", e), } } fn custom_emit(&mut self, cm: &codemap::CodeMap, sp: RenderSpan, msg: &str, lvl: Level) { match self.emit_(cm, sp, msg, None, lvl) { Ok(()) => {} Err(e) => panic!("failed to print diagnostics: {:?}", e), } } } pub fn expect(diag: &SpanHandler, opt: Option, msg: M) -> T where M: FnOnce() -> String, { match opt { Some(t) => t, None => diag.handler().bug(&msg()), } } #[cfg(test)] mod test { use super::{EmitterWriter, Level}; use codemap::{mk_sp, CodeMap}; use std::sync::{Arc, Mutex}; use std::io::{self, Write}; use std::str::from_utf8; // Diagnostic doesn't align properly in span where line number increases by one digit #[test] fn test_hilight_suggestion_issue_11715() { struct Sink(Arc>>); impl Write for Sink { fn write(&mut self, data: &[u8]) -> io::Result { Write::write(&mut *self.0.lock().unwrap(), data) } fn flush(&mut self) -> io::Result<()> { Ok(()) } } let data = Arc::new(Mutex::new(Vec::new())); let mut ew = EmitterWriter::new(Box::new(Sink(data.clone())), None); let cm = CodeMap::new(); let content = "abcdefg koksi line3 line4 cinq line6 line7 line8 line9 line10 e-lä-vän tolv dreizehn "; let file = cm.new_filemap_and_lines("dummy.txt", content); let start = file.lines.borrow()[7]; let end = file.lines.borrow()[11]; let sp = mk_sp(start, end); let lvl = Level::Error; println!("span_to_lines"); let lines = cm.span_to_lines(sp); println!("highlight_lines"); ew.highlight_lines(&cm, sp, lvl, lines).unwrap(); println!("done"); let vec = data.lock().unwrap().clone(); let vec: &[u8] = &vec; let str = from_utf8(vec).unwrap(); println!("{}", str); assert_eq!(str, "dummy.txt: 8 line8\n\ dummy.txt: 9 line9\n\ dummy.txt:10 line10\n\ dummy.txt:11 e-lä-vän\n\ dummy.txt:12 tolv\n"); } }