use std::cmp; use std::error; use std::fmt; use std::result; use crate::ast; use crate::hir; /// A type alias for dealing with errors returned by this crate. pub type Result = result::Result; /// This error type encompasses any error that can be returned by this crate. #[derive(Clone, Debug, Eq, PartialEq)] pub enum Error { /// An error that occurred while translating concrete syntax into abstract /// syntax (AST). Parse(ast::Error), /// An error that occurred while translating abstract syntax into a high /// level intermediate representation (HIR). Translate(hir::Error), /// Hints that destructuring should not be exhaustive. /// /// This enum may grow additional variants, so this makes sure clients /// don't count on exhaustive matching. (Otherwise, adding a new variant /// could break existing code.) #[doc(hidden)] __Nonexhaustive, } impl From for Error { fn from(err: ast::Error) -> Error { Error::Parse(err) } } impl From for Error { fn from(err: hir::Error) -> Error { Error::Translate(err) } } impl error::Error for Error { // TODO: Remove this method entirely on the next breaking semver release. #[allow(deprecated)] fn description(&self) -> &str { match *self { Error::Parse(ref x) => x.description(), Error::Translate(ref x) => x.description(), _ => unreachable!(), } } } impl fmt::Display for Error { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match *self { Error::Parse(ref x) => x.fmt(f), Error::Translate(ref x) => x.fmt(f), _ => unreachable!(), } } } /// A helper type for formatting nice error messages. /// /// This type is responsible for reporting regex parse errors in a nice human /// readable format. Most of its complexity is from interspersing notational /// markers pointing out the position where an error occurred. #[derive(Debug)] pub struct Formatter<'e, E> { /// The original regex pattern in which the error occurred. pattern: &'e str, /// The error kind. It must impl fmt::Display. err: &'e E, /// The primary span of the error. span: &'e ast::Span, /// An auxiliary and optional span, in case the error needs to point to /// two locations (e.g., when reporting a duplicate capture group name). aux_span: Option<&'e ast::Span>, } impl<'e> From<&'e ast::Error> for Formatter<'e, ast::ErrorKind> { fn from(err: &'e ast::Error) -> Self { Formatter { pattern: err.pattern(), err: err.kind(), span: err.span(), aux_span: err.auxiliary_span(), } } } impl<'e> From<&'e hir::Error> for Formatter<'e, hir::ErrorKind> { fn from(err: &'e hir::Error) -> Self { Formatter { pattern: err.pattern(), err: err.kind(), span: err.span(), aux_span: None, } } } impl<'e, E: fmt::Display> fmt::Display for Formatter<'e, E> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { let spans = Spans::from_formatter(self); if self.pattern.contains('\n') { let divider = repeat_char('~', 79); writeln!(f, "regex parse error:")?; writeln!(f, "{}", divider)?; let notated = spans.notate(); write!(f, "{}", notated)?; writeln!(f, "{}", divider)?; // If we have error spans that cover multiple lines, then we just // note the line numbers. if !spans.multi_line.is_empty() { let mut notes = vec![]; for span in &spans.multi_line { notes.push(format!( "on line {} (column {}) through line {} (column {})", span.start.line, span.start.column, span.end.line, span.end.column - 1 )); } writeln!(f, "{}", notes.join("\n"))?; } write!(f, "error: {}", self.err)?; } else { writeln!(f, "regex parse error:")?; let notated = Spans::from_formatter(self).notate(); write!(f, "{}", notated)?; write!(f, "error: {}", self.err)?; } Ok(()) } } /// This type represents an arbitrary number of error spans in a way that makes /// it convenient to notate the regex pattern. ("Notate" means "point out /// exactly where the error occurred in the regex pattern.") /// /// Technically, we can only ever have two spans given our current error /// structure. However, after toiling with a specific algorithm for handling /// two spans, it became obvious that an algorithm to handle an arbitrary /// number of spans was actually much simpler. struct Spans<'p> { /// The original regex pattern string. pattern: &'p str, /// The total width that should be used for line numbers. The width is /// used for left padding the line numbers for alignment. /// /// A value of `0` means line numbers should not be displayed. That is, /// the pattern is itself only one line. line_number_width: usize, /// All error spans that occur on a single line. This sequence always has /// length equivalent to the number of lines in `pattern`, where the index /// of the sequence represents a line number, starting at `0`. The spans /// in each line are sorted in ascending order. by_line: Vec>, /// All error spans that occur over one or more lines. That is, the start /// and end position of the span have different line numbers. The spans are /// sorted in ascending order. multi_line: Vec, } impl<'p> Spans<'p> { /// Build a sequence of spans from a formatter. fn from_formatter<'e, E: fmt::Display>( fmter: &'p Formatter<'e, E>, ) -> Spans<'p> { let mut line_count = fmter.pattern.lines().count(); // If the pattern ends with a `\n` literal, then our line count is // off by one, since a span can occur immediately after the last `\n`, // which is consider to be an additional line. if fmter.pattern.ends_with('\n') { line_count += 1; } let line_number_width = if line_count <= 1 { 0 } else { line_count.to_string().len() }; let mut spans = Spans { pattern: &fmter.pattern, line_number_width, by_line: vec![vec![]; line_count], multi_line: vec![], }; spans.add(fmter.span.clone()); if let Some(span) = fmter.aux_span { spans.add(span.clone()); } spans } /// Add the given span to this sequence, putting it in the right place. fn add(&mut self, span: ast::Span) { // This is grossly inefficient since we sort after each add, but right // now, we only ever add two spans at most. if span.is_one_line() { let i = span.start.line - 1; // because lines are 1-indexed self.by_line[i].push(span); self.by_line[i].sort(); } else { self.multi_line.push(span); self.multi_line.sort(); } } /// Notate the pattern string with carents (`^`) pointing at each span /// location. This only applies to spans that occur within a single line. fn notate(&self) -> String { let mut notated = String::new(); for (i, line) in self.pattern.lines().enumerate() { if self.line_number_width > 0 { notated.push_str(&self.left_pad_line_number(i + 1)); notated.push_str(": "); } else { notated.push_str(" "); } notated.push_str(line); notated.push('\n'); if let Some(notes) = self.notate_line(i) { notated.push_str(¬es); notated.push('\n'); } } notated } /// Return notes for the line indexed at `i` (zero-based). If there are no /// spans for the given line, then `None` is returned. Otherwise, an /// appropriately space padded string with correctly positioned `^` is /// returned, accounting for line numbers. fn notate_line(&self, i: usize) -> Option { let spans = &self.by_line[i]; if spans.is_empty() { return None; } let mut notes = String::new(); for _ in 0..self.line_number_padding() { notes.push(' '); } let mut pos = 0; for span in spans { for _ in pos..(span.start.column - 1) { notes.push(' '); pos += 1; } let note_len = span.end.column.saturating_sub(span.start.column); for _ in 0..cmp::max(1, note_len) { notes.push('^'); pos += 1; } } Some(notes) } /// Left pad the given line number with spaces such that it is aligned with /// other line numbers. fn left_pad_line_number(&self, n: usize) -> String { let n = n.to_string(); let pad = self.line_number_width.checked_sub(n.len()).unwrap(); let mut result = repeat_char(' ', pad); result.push_str(&n); result } /// Return the line number padding beginning at the start of each line of /// the pattern. /// /// If the pattern is only one line, then this returns a fixed padding /// for visual indentation. fn line_number_padding(&self) -> usize { if self.line_number_width == 0 { 4 } else { 2 + self.line_number_width } } } fn repeat_char(c: char, count: usize) -> String { ::std::iter::repeat(c).take(count).collect() } #[cfg(test)] mod tests { use crate::ast::parse::Parser; fn assert_panic_message(pattern: &str, expected_msg: &str) { let result = Parser::new().parse(pattern); match result { Ok(_) => { panic!("regex should not have parsed"); } Err(err) => { assert_eq!(err.to_string(), expected_msg.trim()); } } } // See: https://github.com/rust-lang/regex/issues/464 #[test] fn regression_464() { let err = Parser::new().parse("a{\n").unwrap_err(); // This test checks that the error formatter doesn't panic. assert!(!err.to_string().is_empty()); } // See: https://github.com/rust-lang/regex/issues/545 #[test] fn repetition_quantifier_expects_a_valid_decimal() { assert_panic_message( r"\\u{[^}]*}", r#" regex parse error: \\u{[^}]*} ^ error: repetition quantifier expects a valid decimal "#, ); } }