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Add spans to lexer errors

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This commit is contained in:
Jesse Braham 2025-01-27 18:16:52 +01:00
parent 7add446d14
commit 2d95a58ce7
2 changed files with 65 additions and 41 deletions
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7
onihime/src/lexer/error.rs
View File

@ -1,5 +1,7 @@
use std::fmt;
use crate::Span;
/// Kinds of errors which can occur during lexical analysis.
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub enum LexerErrorKind {
@ -35,6 +37,8 @@ impl fmt::Display for LexerErrorKind {
pub struct LexerError {
/// The kind of lexer error.
pub kind: LexerErrorKind,
/// The span of the lexer error.
pub span: Span,
/// Additional context regarding the lexer error.
pub context: Option<String>,
}
@ -42,9 +46,10 @@ pub struct LexerError {
impl LexerError {
/// Construct a new instance of a lexer error.
#[must_use]
pub const fn new(kind: LexerErrorKind) -> Self {
pub const fn new(kind: LexerErrorKind, span: Span) -> Self {
Self {
kind,
span,
context: None,
}
}

99
onihime/src/lexer/mod.rs
View File

@ -96,7 +96,7 @@ impl<'a> Lexer<'a> {
// Invalid tokens:
_ => {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidSymbol));
return Err(LexerError::new(LexerErrorKind::InvalidSymbol, self.span()));
}
};
@ -140,14 +140,14 @@ impl<'a> Lexer<'a> {
let c = if self.peek().is_some_and(|c| !is_separator(c)) {
self.advance().unwrap() // SAFETY: This will never panic
} else {
return Err(LexerError::new(LexerErrorKind::InvalidChar));
return Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()));
};
match c {
'u' if self.peek().is_some_and(|c| !is_separator(c)) => self.complete_unicode_escape(),
'x' if self.peek().is_some_and(|c| !is_separator(c)) => self.complete_ascii_escape(),
_ if self.peek().is_some_and(|c| !is_separator(c)) => {
Err(LexerError::new(LexerErrorKind::InvalidChar))
Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()))
}
_ => Ok(TokenKind::Char),
}
@ -161,7 +161,7 @@ impl<'a> Lexer<'a> {
self.advance();
} else {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidChar));
return Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()));
}
// Expect a single hexadecimal digit:
@ -169,14 +169,14 @@ impl<'a> Lexer<'a> {
self.advance();
} else {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidChar));
return Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()));
}
// We should be at the end of the literal now, i.e. next char should be a
// separator:
if self.peek().is_some_and(|c| !is_separator(c)) {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidChar));
return Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()));
}
Ok(TokenKind::Char)
@ -192,7 +192,7 @@ impl<'a> Lexer<'a> {
Some(c) if c.is_ascii_hexdigit() => count += 1,
_ => {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidChar));
return Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()));
}
};
}
@ -201,7 +201,7 @@ impl<'a> Lexer<'a> {
// not at the end of the literal, then the literal is invalid:
if count == 0 || self.peek().is_some_and(|c| !is_separator(c)) {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidChar));
return Err(LexerError::new(LexerErrorKind::InvalidChar, self.span()));
}
Ok(TokenKind::Char)
@ -215,7 +215,7 @@ impl<'a> Lexer<'a> {
Ok(TokenKind::Keyword)
} else {
self.read_word(); // Recover
Err(LexerError::new(LexerErrorKind::InvalidKeyword))
Err(LexerError::new(LexerErrorKind::InvalidKeyword, self.span()))
}
}
@ -236,7 +236,7 @@ impl<'a> Lexer<'a> {
Some('/') => return self.complete_ratio(),
_ => {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidNumber));
return Err(LexerError::new(LexerErrorKind::InvalidNumber, self.span()));
}
}
}
@ -259,14 +259,14 @@ impl<'a> Lexer<'a> {
}
_ => {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidNumber));
return Err(LexerError::new(LexerErrorKind::InvalidNumber, self.span()));
}
};
}
if !digit_found {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidNumber));
return Err(LexerError::new(LexerErrorKind::InvalidNumber, self.span()));
}
Ok(TokenKind::Integer)
@ -287,7 +287,7 @@ impl<'a> Lexer<'a> {
Some('+') | Some('-') if exp_found && !sign_found => sign_found = true,
Some(_) => {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidNumber));
return Err(LexerError::new(LexerErrorKind::InvalidNumber, self.span()));
}
None => unreachable!(),
};
@ -309,7 +309,7 @@ impl<'a> Lexer<'a> {
Some('+') | Some('-') if !digit_found && !sign_found => sign_found = true,
Some(_) => {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidNumber));
return Err(LexerError::new(LexerErrorKind::InvalidNumber, self.span()));
}
None => unreachable!(),
};
@ -317,7 +317,7 @@ impl<'a> Lexer<'a> {
if !digit_found {
self.read_word(); // Recover
return Err(LexerError::new(LexerErrorKind::InvalidNumber));
return Err(LexerError::new(LexerErrorKind::InvalidNumber, self.span()));
}
Ok(TokenKind::Ratio)
@ -333,7 +333,7 @@ impl<'a> Lexer<'a> {
self.advance(); // '"'
}
Some(_) => {}
None => return Err(LexerError::new(LexerErrorKind::UnclosedString)),
None => return Err(LexerError::new(LexerErrorKind::UnclosedString, self.span())),
}
}
@ -375,17 +375,29 @@ mod tests {
assert_eq!(lexer.slice(), &[]);
}
// Okay... this kind of sucks. But, makes writing tests pretty easy :)
//
// Provide the name of the test, an input string to lex, and a list of expected
// results as parameters to the macro. A test case will be generated
// automagically as a result.
macro_rules! test {
( $name:ident: $input:literal => $expected:expr ) => {
#[test]
fn $name() {
let mut lexer = Lexer::new($input);
for (token, span, slice) in $expected {
for (result, span, slice) in $expected {
let kind = lexer.next().map(|r| match r {
Ok(t) => Ok(t.kind),
Err(e) => Err(e),
Err(mut e) => {
e.context = None; // Don't care about this for testing
Err(e)
}
});
assert_eq!(kind, Some(token));
let result = match result {
Ok(t) => Ok(t),
Err(e) => Err(LexerError::new(e, lexer.span())),
};
assert_eq!(kind, Some(result));
assert_eq!(span, lexer.span().into());
assert_eq!(slice.as_bytes(), lexer.slice());
}
@ -449,9 +461,9 @@ mod tests {
]);
test!(err_invalid_keyword: ": :;" => [
(Err(LexerError::new(LexerErrorKind::InvalidKeyword)), 0..1, ":"),
(Err(LexerErrorKind::InvalidKeyword), 0..1, ":"),
(Ok(TokenKind::Whitespace), 1..2, " "),
(Err(LexerError::new(LexerErrorKind::InvalidKeyword)), 2..3, ":"),
(Err(LexerErrorKind::InvalidKeyword), 2..3, ":"),
(Ok(TokenKind::Comment), 3..4, ";"),
]);
@ -472,47 +484,47 @@ mod tests {
]);
test!(err_invalid_char: r"\ \xF \x0 \x111 \uG \u2222222" => [
(Err(LexerError::new(LexerErrorKind::InvalidChar)), 0..1, r"\"),
(Err(LexerErrorKind::InvalidChar), 0..1, r"\"),
(Ok(TokenKind::Whitespace), 1..2, " "),
(Err(LexerError::new(LexerErrorKind::InvalidChar)), 2..5, r"\xF"),
(Err(LexerErrorKind::InvalidChar), 2..5, r"\xF"),
(Ok(TokenKind::Whitespace), 5..6, " "),
(Err(LexerError::new(LexerErrorKind::InvalidChar)), 6..9, r"\x0"),
(Err(LexerErrorKind::InvalidChar), 6..9, r"\x0"),
(Ok(TokenKind::Whitespace), 9..10, " "),
(Err(LexerError::new(LexerErrorKind::InvalidChar)), 10..15, r"\x111"),
(Err(LexerErrorKind::InvalidChar), 10..15, r"\x111"),
(Ok(TokenKind::Whitespace), 15..16, " "),
(Err(LexerError::new(LexerErrorKind::InvalidChar)), 16..19, r"\uG"),
(Err(LexerErrorKind::InvalidChar), 16..19, r"\uG"),
(Ok(TokenKind::Whitespace), 19..20, " "),
(Err(LexerError::new(LexerErrorKind::InvalidChar)), 20..29, r"\u2222222"),
(Err(LexerErrorKind::InvalidChar), 20..29, r"\u2222222"),
]);
test!(err_invalid_integer: "0b012 0o8 0xFG 1N 0x" => [
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 0..5, "0b012"),
(Err(LexerErrorKind::InvalidNumber), 0..5, "0b012"),
(Ok(TokenKind::Whitespace), 5..6, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 6..9, "0o8"),
(Err(LexerErrorKind::InvalidNumber), 6..9, "0o8"),
(Ok(TokenKind::Whitespace), 9..10, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 10..14, "0xFG"),
(Err(LexerErrorKind::InvalidNumber), 10..14, "0xFG"),
(Ok(TokenKind::Whitespace), 14..15, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 15..17, "1N"),
(Err(LexerErrorKind::InvalidNumber), 15..17, "1N"),
(Ok(TokenKind::Whitespace), 17..18, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 18..20, "0x"),
(Err(LexerErrorKind::InvalidNumber), 18..20, "0x"),
]);
test!(err_invalid_decimal: "1.2.3 4.e6 7.8+ 9.0+e1" => [
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 0..5, "1.2.3"),
(Err(LexerErrorKind::InvalidNumber), 0..5, "1.2.3"),
(Ok(TokenKind::Whitespace), 5..6, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 6..10, "4.e6"),
(Err(LexerErrorKind::InvalidNumber), 6..10, "4.e6"),
(Ok(TokenKind::Whitespace), 10..11, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 11..15, "7.8+"),
(Err(LexerErrorKind::InvalidNumber), 11..15, "7.8+"),
(Ok(TokenKind::Whitespace), 15..16, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 16..22, "9.0+e1"),
(Err(LexerErrorKind::InvalidNumber), 16..22, "9.0+e1"),
]);
test!(err_invalid_ratio: "1/ -2/3+ 4/-" => [
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 0..2, "1/"),
(Err(LexerErrorKind::InvalidNumber), 0..2, "1/"),
(Ok(TokenKind::Whitespace), 2..3, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 3..8, "-2/3+"),
(Err(LexerErrorKind::InvalidNumber), 3..8, "-2/3+"),
(Ok(TokenKind::Whitespace), 8..9, " "),
(Err(LexerError::new(LexerErrorKind::InvalidNumber)), 9..12, "4/-"),
(Err(LexerErrorKind::InvalidNumber), 9..12, "4/-"),
]);
test!(string: "\"föö bar1\nbaz\" \"\" \"凄い 😍\"" => [
@ -524,7 +536,7 @@ mod tests {
]);
test!(err_unclosed_string: "\"oops" => [
(Err(LexerError::new(LexerErrorKind::UnclosedString)), 0..5, "\"oops"),
(Err(LexerErrorKind::UnclosedString), 0..5, "\"oops"),
]);
test!(symbol: "+ rev fold0 nil? x str-cat 猫" => [
@ -543,6 +555,13 @@ mod tests {
(Ok(TokenKind::Symbol), 27..30, ""),
]);
// More macro magic (yay!). Allows for creating proptests in one line, fancy!
//
// Provide the name of the test, a regular expression to generate valid inputs
// with, and the expected `TokenKind` variant as the parameters to the macro.
// A test case will be generated automagically as a result.
//
// e.g. `ptest!(TEST_NAME: REGEX => VARIANT);`
macro_rules! ptest {
( $name:ident: $input:literal => $kind:ident ) => {
proptest::proptest! {