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-rw-r--r--crates/ra_syntax/src/ast/generated.rs74
-rw-r--r--crates/ra_syntax/src/ast/mod.rs12
-rw-r--r--crates/ra_syntax/src/grammar.ron2
-rw-r--r--crates/ra_syntax/src/string_lexing.rs414
-rw-r--r--crates/ra_syntax/src/string_lexing/byte.rs51
-rw-r--r--crates/ra_syntax/src/string_lexing/byte_string.rs51
-rw-r--r--crates/ra_syntax/src/string_lexing/char.rs176
-rw-r--r--crates/ra_syntax/src/string_lexing/mod.rs13
-rw-r--r--crates/ra_syntax/src/string_lexing/parser.rs201
-rw-r--r--crates/ra_syntax/src/string_lexing/string.rs46
-rw-r--r--crates/ra_syntax/src/validation/byte.rs211
-rw-r--r--crates/ra_syntax/src/validation/byte_string.rs178
-rw-r--r--crates/ra_syntax/src/validation/char.rs192
-rw-r--r--crates/ra_syntax/src/validation/mod.rs4
-rw-r--r--crates/ra_syntax/src/yellow/syntax_error.rs23
15 files changed, 1141 insertions, 507 deletions
diff --git a/crates/ra_syntax/src/ast/generated.rs b/crates/ra_syntax/src/ast/generated.rs
index 2e9ae263a..bf056131e 100644
--- a/crates/ra_syntax/src/ast/generated.rs
+++ b/crates/ra_syntax/src/ast/generated.rs
@@ -372,6 +372,80 @@ impl<R: TreeRoot<RaTypes>> BreakExprNode<R> {
372 372
373impl<'a> BreakExpr<'a> {} 373impl<'a> BreakExpr<'a> {}
374 374
375// Byte
376#[derive(Debug, Clone, Copy,)]
377pub struct ByteNode<R: TreeRoot<RaTypes> = OwnedRoot> {
378 pub(crate) syntax: SyntaxNode<R>,
379}
380pub type Byte<'a> = ByteNode<RefRoot<'a>>;
381
382impl<R1: TreeRoot<RaTypes>, R2: TreeRoot<RaTypes>> PartialEq<ByteNode<R1>> for ByteNode<R2> {
383 fn eq(&self, other: &ByteNode<R1>) -> bool { self.syntax == other.syntax }
384}
385impl<R: TreeRoot<RaTypes>> Eq for ByteNode<R> {}
386impl<R: TreeRoot<RaTypes>> Hash for ByteNode<R> {
387 fn hash<H: Hasher>(&self, state: &mut H) { self.syntax.hash(state) }
388}
389
390impl<'a> AstNode<'a> for Byte<'a> {
391 fn cast(syntax: SyntaxNodeRef<'a>) -> Option<Self> {
392 match syntax.kind() {
393 BYTE => Some(Byte { syntax }),
394 _ => None,
395 }
396 }
397 fn syntax(self) -> SyntaxNodeRef<'a> { self.syntax }
398}
399
400impl<R: TreeRoot<RaTypes>> ByteNode<R> {
401 pub fn borrowed(&self) -> Byte {
402 ByteNode { syntax: self.syntax.borrowed() }
403 }
404 pub fn owned(&self) -> ByteNode {
405 ByteNode { syntax: self.syntax.owned() }
406 }
407}
408
409
410impl<'a> Byte<'a> {}
411
412// ByteString
413#[derive(Debug, Clone, Copy,)]
414pub struct ByteStringNode<R: TreeRoot<RaTypes> = OwnedRoot> {
415 pub(crate) syntax: SyntaxNode<R>,
416}
417pub type ByteString<'a> = ByteStringNode<RefRoot<'a>>;
418
419impl<R1: TreeRoot<RaTypes>, R2: TreeRoot<RaTypes>> PartialEq<ByteStringNode<R1>> for ByteStringNode<R2> {
420 fn eq(&self, other: &ByteStringNode<R1>) -> bool { self.syntax == other.syntax }
421}
422impl<R: TreeRoot<RaTypes>> Eq for ByteStringNode<R> {}
423impl<R: TreeRoot<RaTypes>> Hash for ByteStringNode<R> {
424 fn hash<H: Hasher>(&self, state: &mut H) { self.syntax.hash(state) }
425}
426
427impl<'a> AstNode<'a> for ByteString<'a> {
428 fn cast(syntax: SyntaxNodeRef<'a>) -> Option<Self> {
429 match syntax.kind() {
430 BYTE_STRING => Some(ByteString { syntax }),
431 _ => None,
432 }
433 }
434 fn syntax(self) -> SyntaxNodeRef<'a> { self.syntax }
435}
436
437impl<R: TreeRoot<RaTypes>> ByteStringNode<R> {
438 pub fn borrowed(&self) -> ByteString {
439 ByteStringNode { syntax: self.syntax.borrowed() }
440 }
441 pub fn owned(&self) -> ByteStringNode {
442 ByteStringNode { syntax: self.syntax.owned() }
443 }
444}
445
446
447impl<'a> ByteString<'a> {}
448
375// CallExpr 449// CallExpr
376#[derive(Debug, Clone, Copy,)] 450#[derive(Debug, Clone, Copy,)]
377pub struct CallExprNode<R: TreeRoot<RaTypes> = OwnedRoot> { 451pub struct CallExprNode<R: TreeRoot<RaTypes> = OwnedRoot> {
diff --git a/crates/ra_syntax/src/ast/mod.rs b/crates/ra_syntax/src/ast/mod.rs
index f20714ede..7077e3492 100644
--- a/crates/ra_syntax/src/ast/mod.rs
+++ b/crates/ra_syntax/src/ast/mod.rs
@@ -134,6 +134,18 @@ impl<'a> Char<'a> {
134 } 134 }
135} 135}
136 136
137impl<'a> Byte<'a> {
138 pub fn text(&self) -> &SmolStr {
139 &self.syntax().leaf_text().unwrap()
140 }
141}
142
143impl<'a> ByteString<'a> {
144 pub fn text(&self) -> &SmolStr {
145 &self.syntax().leaf_text().unwrap()
146 }
147}
148
137impl<'a> String<'a> { 149impl<'a> String<'a> {
138 pub fn text(&self) -> &SmolStr { 150 pub fn text(&self) -> &SmolStr {
139 &self.syntax().leaf_text().unwrap() 151 &self.syntax().leaf_text().unwrap()
diff --git a/crates/ra_syntax/src/grammar.ron b/crates/ra_syntax/src/grammar.ron
index c3184667e..53cd2118f 100644
--- a/crates/ra_syntax/src/grammar.ron
+++ b/crates/ra_syntax/src/grammar.ron
@@ -412,6 +412,8 @@ Grammar(
412 "RangeExpr": (), 412 "RangeExpr": (),
413 "BinExpr": (), 413 "BinExpr": (),
414 "String": (), 414 "String": (),
415 "Byte": (),
416 "ByteString": (),
415 "Char": (), 417 "Char": (),
416 "Literal": (), 418 "Literal": (),
417 419
diff --git a/crates/ra_syntax/src/string_lexing.rs b/crates/ra_syntax/src/string_lexing.rs
deleted file mode 100644
index d613bb042..000000000
--- a/crates/ra_syntax/src/string_lexing.rs
+++ /dev/null
@@ -1,414 +0,0 @@
1use self::CharComponentKind::*;
2use rowan::{TextRange, TextUnit};
3
4pub fn parse_string_literal(src: &str) -> StringComponentIterator {
5 StringComponentIterator {
6 parser: Parser::new(src),
7 has_closing_quote: false,
8 }
9}
10
11#[derive(Debug, Eq, PartialEq, Clone)]
12pub struct StringComponent {
13 pub range: TextRange,
14 pub kind: StringComponentKind,
15}
16
17impl StringComponent {
18 fn new(range: TextRange, kind: StringComponentKind) -> StringComponent {
19 StringComponent { range, kind }
20 }
21}
22
23#[derive(Debug, Eq, PartialEq, Clone)]
24pub enum StringComponentKind {
25 IgnoreNewline,
26 Char(CharComponentKind),
27}
28
29pub struct StringComponentIterator<'a> {
30 parser: Parser<'a>,
31 pub has_closing_quote: bool,
32}
33
34impl<'a> Iterator for StringComponentIterator<'a> {
35 type Item = StringComponent;
36 fn next(&mut self) -> Option<StringComponent> {
37 if self.parser.pos == 0 {
38 assert!(
39 self.parser.advance() == '"',
40 "string literal should start with double quotes"
41 );
42 }
43
44 if let Some(component) = self.parser.parse_string_component() {
45 return Some(component);
46 }
47
48 // We get here when there are no char components left to parse
49 if self.parser.peek() == Some('"') {
50 self.parser.advance();
51 self.has_closing_quote = true;
52 }
53
54 assert!(
55 self.parser.peek() == None,
56 "string literal should leave no unparsed input: src = {}, pos = {}, length = {}",
57 self.parser.src,
58 self.parser.pos,
59 self.parser.src.len()
60 );
61
62 None
63 }
64}
65
66pub fn parse_char_literal(src: &str) -> CharComponentIterator {
67 CharComponentIterator {
68 parser: Parser::new(src),
69 has_closing_quote: false,
70 }
71}
72
73#[derive(Debug, Eq, PartialEq, Clone)]
74pub struct CharComponent {
75 pub range: TextRange,
76 pub kind: CharComponentKind,
77}
78
79impl CharComponent {
80 fn new(range: TextRange, kind: CharComponentKind) -> CharComponent {
81 CharComponent { range, kind }
82 }
83}
84
85#[derive(Debug, Eq, PartialEq, Clone)]
86pub enum CharComponentKind {
87 CodePoint,
88 AsciiEscape,
89 AsciiCodeEscape,
90 UnicodeEscape,
91}
92
93pub struct CharComponentIterator<'a> {
94 parser: Parser<'a>,
95 pub has_closing_quote: bool,
96}
97
98impl<'a> Iterator for CharComponentIterator<'a> {
99 type Item = CharComponent;
100 fn next(&mut self) -> Option<CharComponent> {
101 if self.parser.pos == 0 {
102 assert!(
103 self.parser.advance() == '\'',
104 "char literal should start with a quote"
105 );
106 }
107
108 if let Some(component) = self.parser.parse_char_component() {
109 return Some(component);
110 }
111
112 // We get here when there are no char components left to parse
113 if self.parser.peek() == Some('\'') {
114 self.parser.advance();
115 self.has_closing_quote = true;
116 }
117
118 assert!(
119 self.parser.peek() == None,
120 "char literal should leave no unparsed input: src = {}, pos = {}, length = {}",
121 self.parser.src,
122 self.parser.pos,
123 self.parser.src.len()
124 );
125
126 None
127 }
128}
129
130pub struct Parser<'a> {
131 src: &'a str,
132 pos: usize,
133}
134
135impl<'a> Parser<'a> {
136 pub fn new(src: &'a str) -> Parser<'a> {
137 Parser { src, pos: 0 }
138 }
139
140 // Utility methods
141
142 pub fn peek(&self) -> Option<char> {
143 if self.pos == self.src.len() {
144 return None;
145 }
146
147 self.src[self.pos..].chars().next()
148 }
149
150 pub fn advance(&mut self) -> char {
151 let next = self
152 .peek()
153 .expect("cannot advance if end of input is reached");
154 self.pos += next.len_utf8();
155 next
156 }
157
158 pub fn skip_whitespace(&mut self) {
159 while self.peek().map(|c| c.is_whitespace()) == Some(true) {
160 self.advance();
161 }
162 }
163
164 pub fn get_pos(&self) -> TextUnit {
165 (self.pos as u32).into()
166 }
167
168 // Char parsing methods
169
170 fn parse_unicode_escape(&mut self, start: TextUnit) -> CharComponent {
171 match self.peek() {
172 Some('{') => {
173 self.advance();
174
175 // Parse anything until we reach `}`
176 while let Some(next) = self.peek() {
177 self.advance();
178 if next == '}' {
179 break;
180 }
181 }
182
183 let end = self.get_pos();
184 CharComponent::new(TextRange::from_to(start, end), UnicodeEscape)
185 }
186 Some(_) | None => {
187 let end = self.get_pos();
188 CharComponent::new(TextRange::from_to(start, end), UnicodeEscape)
189 }
190 }
191 }
192
193 fn parse_ascii_code_escape(&mut self, start: TextUnit) -> CharComponent {
194 let code_start = self.get_pos();
195 while let Some(next) = self.peek() {
196 if next == '\'' || (self.get_pos() - code_start == 2.into()) {
197 break;
198 }
199
200 self.advance();
201 }
202
203 let end = self.get_pos();
204 CharComponent::new(TextRange::from_to(start, end), AsciiCodeEscape)
205 }
206
207 fn parse_escape(&mut self, start: TextUnit) -> CharComponent {
208 if self.peek().is_none() {
209 return CharComponent::new(TextRange::from_to(start, start), AsciiEscape);
210 }
211
212 let next = self.advance();
213 let end = self.get_pos();
214 let range = TextRange::from_to(start, end);
215 match next {
216 'x' => self.parse_ascii_code_escape(start),
217 'u' => self.parse_unicode_escape(start),
218 _ => CharComponent::new(range, AsciiEscape),
219 }
220 }
221
222 pub fn parse_char_component(&mut self) -> Option<CharComponent> {
223 let next = self.peek()?;
224
225 // Ignore character close
226 if next == '\'' {
227 return None;
228 }
229
230 let start = self.get_pos();
231 self.advance();
232
233 if next == '\\' {
234 Some(self.parse_escape(start))
235 } else {
236 let end = self.get_pos();
237 Some(CharComponent::new(
238 TextRange::from_to(start, end),
239 CodePoint,
240 ))
241 }
242 }
243
244 pub fn parse_ignore_newline(&mut self, start: TextUnit) -> Option<StringComponent> {
245 // In string literals, when a `\` occurs immediately before the newline, the `\`,
246 // the newline, and all whitespace at the beginning of the next line are ignored
247 match self.peek() {
248 Some('\n') | Some('\r') => {
249 self.skip_whitespace();
250 Some(StringComponent::new(
251 TextRange::from_to(start, self.get_pos()),
252 StringComponentKind::IgnoreNewline,
253 ))
254 }
255 _ => None,
256 }
257 }
258
259 pub fn parse_string_component(&mut self) -> Option<StringComponent> {
260 let next = self.peek()?;
261
262 // Ignore string close
263 if next == '"' {
264 return None;
265 }
266
267 let start = self.get_pos();
268 self.advance();
269
270 if next == '\\' {
271 // Strings can use `\` to ignore newlines, so we first try to parse one of those
272 // before falling back to parsing char escapes
273 self.parse_ignore_newline(start).or_else(|| {
274 let char_component = self.parse_escape(start);
275 Some(StringComponent::new(
276 char_component.range,
277 StringComponentKind::Char(char_component.kind),
278 ))
279 })
280 } else {
281 let end = self.get_pos();
282 Some(StringComponent::new(
283 TextRange::from_to(start, end),
284 StringComponentKind::Char(CodePoint),
285 ))
286 }
287 }
288}
289
290#[cfg(test)]
291mod tests {
292 use super::*;
293
294 fn parse(src: &str) -> (bool, Vec<CharComponent>) {
295 let component_iterator = &mut super::parse_char_literal(src);
296 let components: Vec<_> = component_iterator.collect();
297 (component_iterator.has_closing_quote, components)
298 }
299
300 fn unclosed_char_component(src: &str) -> CharComponent {
301 let (has_closing_quote, components) = parse(src);
302 assert!(!has_closing_quote, "char should not have closing quote");
303 assert!(components.len() == 1);
304 components[0].clone()
305 }
306
307 fn closed_char_component(src: &str) -> CharComponent {
308 let (has_closing_quote, components) = parse(src);
309 assert!(has_closing_quote, "char should have closing quote");
310 assert!(
311 components.len() == 1,
312 "Literal: {}\nComponents: {:#?}",
313 src,
314 components
315 );
316 components[0].clone()
317 }
318
319 fn closed_char_components(src: &str) -> Vec<CharComponent> {
320 let (has_closing_quote, components) = parse(src);
321 assert!(has_closing_quote, "char should have closing quote");
322 components
323 }
324
325 fn range_closed(src: &str) -> TextRange {
326 TextRange::from_to(1.into(), (src.len() as u32 - 1).into())
327 }
328
329 fn range_unclosed(src: &str) -> TextRange {
330 TextRange::from_to(1.into(), (src.len() as u32).into())
331 }
332
333 #[test]
334 fn test_unicode_escapes() {
335 let unicode_escapes = &[r"{DEAD}", "{BEEF}", "{FF}", "{}", ""];
336 for escape in unicode_escapes {
337 let escape_sequence = format!(r"'\u{}'", escape);
338 let component = closed_char_component(&escape_sequence);
339 let expected_range = range_closed(&escape_sequence);
340 assert_eq!(component.kind, CharComponentKind::UnicodeEscape);
341 assert_eq!(component.range, expected_range);
342 }
343 }
344
345 #[test]
346 fn test_unicode_escapes_unclosed() {
347 let unicode_escapes = &["{DEAD", "{BEEF", "{FF"];
348 for escape in unicode_escapes {
349 let escape_sequence = format!(r"'\u{}'", escape);
350 let component = unclosed_char_component(&escape_sequence);
351 let expected_range = range_unclosed(&escape_sequence);
352 assert_eq!(component.kind, CharComponentKind::UnicodeEscape);
353 assert_eq!(component.range, expected_range);
354 }
355 }
356
357 #[test]
358 fn test_empty_char() {
359 let (has_closing_quote, components) = parse("''");
360 assert!(has_closing_quote, "char should have closing quote");
361 assert!(components.len() == 0);
362 }
363
364 #[test]
365 fn test_unclosed_char() {
366 let component = unclosed_char_component("'a");
367 assert!(component.kind == CodePoint);
368 assert!(component.range == TextRange::from_to(1.into(), 2.into()));
369 }
370
371 #[test]
372 fn test_digit_escapes() {
373 let literals = &[r"", r"5", r"55"];
374
375 for literal in literals {
376 let lit_text = format!(r"'\x{}'", literal);
377 let component = closed_char_component(&lit_text);
378 assert!(component.kind == CharComponentKind::AsciiCodeEscape);
379 assert!(component.range == range_closed(&lit_text));
380 }
381
382 // More than 2 digits starts a new codepoint
383 let components = closed_char_components(r"'\x555'");
384 assert!(components.len() == 2);
385 assert!(components[1].kind == CharComponentKind::CodePoint);
386 }
387
388 #[test]
389 fn test_ascii_escapes() {
390 let literals = &[
391 r"\'", "\\\"", // equivalent to \"
392 r"\n", r"\r", r"\t", r"\\", r"\0",
393 ];
394
395 for literal in literals {
396 let lit_text = format!("'{}'", literal);
397 let component = closed_char_component(&lit_text);
398 assert!(component.kind == CharComponentKind::AsciiEscape);
399 assert!(component.range == range_closed(&lit_text));
400 }
401 }
402
403 #[test]
404 fn test_no_escapes() {
405 let literals = &['"', 'n', 'r', 't', '0', 'x', 'u'];
406
407 for &literal in literals {
408 let lit_text = format!("'{}'", literal);
409 let component = closed_char_component(&lit_text);
410 assert!(component.kind == CharComponentKind::CodePoint);
411 assert!(component.range == range_closed(&lit_text));
412 }
413 }
414}
diff --git a/crates/ra_syntax/src/string_lexing/byte.rs b/crates/ra_syntax/src/string_lexing/byte.rs
new file mode 100644
index 000000000..24424349c
--- /dev/null
+++ b/crates/ra_syntax/src/string_lexing/byte.rs
@@ -0,0 +1,51 @@
1use super::parser::Parser;
2use super::CharComponent;
3
4pub fn parse_byte_literal(src: &str) -> ByteComponentIterator {
5 ByteComponentIterator {
6 parser: Parser::new(src),
7 has_closing_quote: false,
8 }
9}
10
11pub struct ByteComponentIterator<'a> {
12 parser: Parser<'a>,
13 pub has_closing_quote: bool,
14}
15
16impl<'a> Iterator for ByteComponentIterator<'a> {
17 type Item = CharComponent;
18 fn next(&mut self) -> Option<CharComponent> {
19 if self.parser.pos == 0 {
20 assert!(
21 self.parser.advance() == 'b',
22 "Byte literal should start with a `b`"
23 );
24
25 assert!(
26 self.parser.advance() == '\'',
27 "Byte literal should start with a `b`, followed by a quote"
28 );
29 }
30
31 if let Some(component) = self.parser.parse_char_component() {
32 return Some(component);
33 }
34
35 // We get here when there are no char components left to parse
36 if self.parser.peek() == Some('\'') {
37 self.parser.advance();
38 self.has_closing_quote = true;
39 }
40
41 assert!(
42 self.parser.peek() == None,
43 "byte literal should leave no unparsed input: src = {}, pos = {}, length = {}",
44 self.parser.src,
45 self.parser.pos,
46 self.parser.src.len()
47 );
48
49 None
50 }
51}
diff --git a/crates/ra_syntax/src/string_lexing/byte_string.rs b/crates/ra_syntax/src/string_lexing/byte_string.rs
new file mode 100644
index 000000000..5b6dda760
--- /dev/null
+++ b/crates/ra_syntax/src/string_lexing/byte_string.rs
@@ -0,0 +1,51 @@
1use super::parser::Parser;
2use super::StringComponent;
3
4pub fn parse_byte_string_literal(src: &str) -> ByteStringComponentIterator {
5 ByteStringComponentIterator {
6 parser: Parser::new(src),
7 has_closing_quote: false,
8 }
9}
10
11pub struct ByteStringComponentIterator<'a> {
12 parser: Parser<'a>,
13 pub has_closing_quote: bool,
14}
15
16impl<'a> Iterator for ByteStringComponentIterator<'a> {
17 type Item = StringComponent;
18 fn next(&mut self) -> Option<StringComponent> {
19 if self.parser.pos == 0 {
20 assert!(
21 self.parser.advance() == 'b',
22 "byte string literal should start with a `b`"
23 );
24
25 assert!(
26 self.parser.advance() == '"',
27 "byte string literal should start with a `b`, followed by double quotes"
28 );
29 }
30
31 if let Some(component) = self.parser.parse_string_component() {
32 return Some(component);
33 }
34
35 // We get here when there are no char components left to parse
36 if self.parser.peek() == Some('"') {
37 self.parser.advance();
38 self.has_closing_quote = true;
39 }
40
41 assert!(
42 self.parser.peek() == None,
43 "byte string literal should leave no unparsed input: src = {}, pos = {}, length = {}",
44 self.parser.src,
45 self.parser.pos,
46 self.parser.src.len()
47 );
48
49 None
50 }
51}
diff --git a/crates/ra_syntax/src/string_lexing/char.rs b/crates/ra_syntax/src/string_lexing/char.rs
new file mode 100644
index 000000000..885c03b14
--- /dev/null
+++ b/crates/ra_syntax/src/string_lexing/char.rs
@@ -0,0 +1,176 @@
1use super::parser::Parser;
2use super::CharComponent;
3
4pub fn parse_char_literal(src: &str) -> CharComponentIterator {
5 CharComponentIterator {
6 parser: Parser::new(src),
7 has_closing_quote: false,
8 }
9}
10
11pub struct CharComponentIterator<'a> {
12 parser: Parser<'a>,
13 pub has_closing_quote: bool,
14}
15
16impl<'a> Iterator for CharComponentIterator<'a> {
17 type Item = CharComponent;
18 fn next(&mut self) -> Option<CharComponent> {
19 if self.parser.pos == 0 {
20 assert!(
21 self.parser.advance() == '\'',
22 "char literal should start with a quote"
23 );
24 }
25
26 if let Some(component) = self.parser.parse_char_component() {
27 return Some(component);
28 }
29
30 // We get here when there are no char components left to parse
31 if self.parser.peek() == Some('\'') {
32 self.parser.advance();
33 self.has_closing_quote = true;
34 }
35
36 assert!(
37 self.parser.peek() == None,
38 "char literal should leave no unparsed input: src = {}, pos = {}, length = {}",
39 self.parser.src,
40 self.parser.pos,
41 self.parser.src.len()
42 );
43
44 None
45 }
46}
47
48#[cfg(test)]
49mod tests {
50 use rowan::TextRange;
51 use crate::string_lexing::{
52 CharComponent,
53 CharComponentKind::*,
54};
55
56 fn parse(src: &str) -> (bool, Vec<CharComponent>) {
57 let component_iterator = &mut super::parse_char_literal(src);
58 let components: Vec<_> = component_iterator.collect();
59 (component_iterator.has_closing_quote, components)
60 }
61
62 fn unclosed_char_component(src: &str) -> CharComponent {
63 let (has_closing_quote, components) = parse(src);
64 assert!(!has_closing_quote, "char should not have closing quote");
65 assert!(components.len() == 1);
66 components[0].clone()
67 }
68
69 fn closed_char_component(src: &str) -> CharComponent {
70 let (has_closing_quote, components) = parse(src);
71 assert!(has_closing_quote, "char should have closing quote");
72 assert!(
73 components.len() == 1,
74 "Literal: {}\nComponents: {:#?}",
75 src,
76 components
77 );
78 components[0].clone()
79 }
80
81 fn closed_char_components(src: &str) -> Vec<CharComponent> {
82 let (has_closing_quote, components) = parse(src);
83 assert!(has_closing_quote, "char should have closing quote");
84 components
85 }
86
87 fn range_closed(src: &str) -> TextRange {
88 TextRange::from_to(1.into(), (src.len() as u32 - 1).into())
89 }
90
91 fn range_unclosed(src: &str) -> TextRange {
92 TextRange::from_to(1.into(), (src.len() as u32).into())
93 }
94
95 #[test]
96 fn test_unicode_escapes() {
97 let unicode_escapes = &[r"{DEAD}", "{BEEF}", "{FF}", "{}", ""];
98 for escape in unicode_escapes {
99 let escape_sequence = format!(r"'\u{}'", escape);
100 let component = closed_char_component(&escape_sequence);
101 let expected_range = range_closed(&escape_sequence);
102 assert_eq!(component.kind, UnicodeEscape);
103 assert_eq!(component.range, expected_range);
104 }
105 }
106
107 #[test]
108 fn test_unicode_escapes_unclosed() {
109 let unicode_escapes = &["{DEAD", "{BEEF", "{FF"];
110 for escape in unicode_escapes {
111 let escape_sequence = format!(r"'\u{}'", escape);
112 let component = unclosed_char_component(&escape_sequence);
113 let expected_range = range_unclosed(&escape_sequence);
114 assert_eq!(component.kind, UnicodeEscape);
115 assert_eq!(component.range, expected_range);
116 }
117 }
118
119 #[test]
120 fn test_empty_char() {
121 let (has_closing_quote, components) = parse("''");
122 assert!(has_closing_quote, "char should have closing quote");
123 assert!(components.len() == 0);
124 }
125
126 #[test]
127 fn test_unclosed_char() {
128 let component = unclosed_char_component("'a");
129 assert!(component.kind == CodePoint);
130 assert!(component.range == TextRange::from_to(1.into(), 2.into()));
131 }
132
133 #[test]
134 fn test_digit_escapes() {
135 let literals = &[r"", r"5", r"55"];
136
137 for literal in literals {
138 let lit_text = format!(r"'\x{}'", literal);
139 let component = closed_char_component(&lit_text);
140 assert!(component.kind == AsciiCodeEscape);
141 assert!(component.range == range_closed(&lit_text));
142 }
143
144 // More than 2 digits starts a new codepoint
145 let components = closed_char_components(r"'\x555'");
146 assert!(components.len() == 2);
147 assert!(components[1].kind == CodePoint);
148 }
149
150 #[test]
151 fn test_ascii_escapes() {
152 let literals = &[
153 r"\'", "\\\"", // equivalent to \"
154 r"\n", r"\r", r"\t", r"\\", r"\0",
155 ];
156
157 for literal in literals {
158 let lit_text = format!("'{}'", literal);
159 let component = closed_char_component(&lit_text);
160 assert!(component.kind == AsciiEscape);
161 assert!(component.range == range_closed(&lit_text));
162 }
163 }
164
165 #[test]
166 fn test_no_escapes() {
167 let literals = &['"', 'n', 'r', 't', '0', 'x', 'u'];
168
169 for &literal in literals {
170 let lit_text = format!("'{}'", literal);
171 let component = closed_char_component(&lit_text);
172 assert!(component.kind == CodePoint);
173 assert!(component.range == range_closed(&lit_text));
174 }
175 }
176}
diff --git a/crates/ra_syntax/src/string_lexing/mod.rs b/crates/ra_syntax/src/string_lexing/mod.rs
new file mode 100644
index 000000000..94853331f
--- /dev/null
+++ b/crates/ra_syntax/src/string_lexing/mod.rs
@@ -0,0 +1,13 @@
1mod parser;
2mod byte;
3mod byte_string;
4mod char;
5mod string;
6
7pub use self::{
8 byte::parse_byte_literal,
9 byte_string::parse_byte_string_literal,
10 char::parse_char_literal,
11 parser::{CharComponent, CharComponentKind, StringComponent, StringComponentKind},
12 string::parse_string_literal,
13};
diff --git a/crates/ra_syntax/src/string_lexing/parser.rs b/crates/ra_syntax/src/string_lexing/parser.rs
new file mode 100644
index 000000000..4a6d5bc93
--- /dev/null
+++ b/crates/ra_syntax/src/string_lexing/parser.rs
@@ -0,0 +1,201 @@
1use rowan::{TextRange, TextUnit};
2
3use self::CharComponentKind::*;
4
5pub struct Parser<'a> {
6 pub(super) src: &'a str,
7 pub(super) pos: usize,
8}
9
10impl<'a> Parser<'a> {
11 pub fn new(src: &'a str) -> Parser<'a> {
12 Parser { src, pos: 0 }
13 }
14
15 // Utility methods
16
17 pub fn peek(&self) -> Option<char> {
18 if self.pos == self.src.len() {
19 return None;
20 }
21
22 self.src[self.pos..].chars().next()
23 }
24
25 pub fn advance(&mut self) -> char {
26 let next = self
27 .peek()
28 .expect("cannot advance if end of input is reached");
29 self.pos += next.len_utf8();
30 next
31 }
32
33 pub fn skip_whitespace(&mut self) {
34 while self.peek().map(|c| c.is_whitespace()) == Some(true) {
35 self.advance();
36 }
37 }
38
39 pub fn get_pos(&self) -> TextUnit {
40 (self.pos as u32).into()
41 }
42
43 // Char parsing methods
44
45 fn parse_unicode_escape(&mut self, start: TextUnit) -> CharComponent {
46 match self.peek() {
47 Some('{') => {
48 self.advance();
49
50 // Parse anything until we reach `}`
51 while let Some(next) = self.peek() {
52 self.advance();
53 if next == '}' {
54 break;
55 }
56 }
57
58 let end = self.get_pos();
59 CharComponent::new(TextRange::from_to(start, end), UnicodeEscape)
60 }
61 Some(_) | None => {
62 let end = self.get_pos();
63 CharComponent::new(TextRange::from_to(start, end), UnicodeEscape)
64 }
65 }
66 }
67
68 fn parse_ascii_code_escape(&mut self, start: TextUnit) -> CharComponent {
69 let code_start = self.get_pos();
70 while let Some(next) = self.peek() {
71 if next == '\'' || (self.get_pos() - code_start == 2.into()) {
72 break;
73 }
74
75 self.advance();
76 }
77
78 let end = self.get_pos();
79 CharComponent::new(TextRange::from_to(start, end), AsciiCodeEscape)
80 }
81
82 fn parse_escape(&mut self, start: TextUnit) -> CharComponent {
83 if self.peek().is_none() {
84 return CharComponent::new(TextRange::from_to(start, start), AsciiEscape);
85 }
86
87 let next = self.advance();
88 let end = self.get_pos();
89 let range = TextRange::from_to(start, end);
90 match next {
91 'x' => self.parse_ascii_code_escape(start),
92 'u' => self.parse_unicode_escape(start),
93 _ => CharComponent::new(range, AsciiEscape),
94 }
95 }
96
97 pub fn parse_char_component(&mut self) -> Option<CharComponent> {
98 let next = self.peek()?;
99
100 // Ignore character close
101 if next == '\'' {
102 return None;
103 }
104
105 let start = self.get_pos();
106 self.advance();
107
108 if next == '\\' {
109 Some(self.parse_escape(start))
110 } else {
111 let end = self.get_pos();
112 Some(CharComponent::new(
113 TextRange::from_to(start, end),
114 CodePoint,
115 ))
116 }
117 }
118
119 pub fn parse_ignore_newline(&mut self, start: TextUnit) -> Option<StringComponent> {
120 // In string literals, when a `\` occurs immediately before the newline, the `\`,
121 // the newline, and all whitespace at the beginning of the next line are ignored
122 match self.peek() {
123 Some('\n') | Some('\r') => {
124 self.skip_whitespace();
125 Some(StringComponent::new(
126 TextRange::from_to(start, self.get_pos()),
127 StringComponentKind::IgnoreNewline,
128 ))
129 }
130 _ => None,
131 }
132 }
133
134 pub fn parse_string_component(&mut self) -> Option<StringComponent> {
135 let next = self.peek()?;
136
137 // Ignore string close
138 if next == '"' {
139 return None;
140 }
141
142 let start = self.get_pos();
143 self.advance();
144
145 if next == '\\' {
146 // Strings can use `\` to ignore newlines, so we first try to parse one of those
147 // before falling back to parsing char escapes
148 self.parse_ignore_newline(start).or_else(|| {
149 let char_component = self.parse_escape(start);
150 Some(StringComponent::new(
151 char_component.range,
152 StringComponentKind::Char(char_component.kind),
153 ))
154 })
155 } else {
156 let end = self.get_pos();
157 Some(StringComponent::new(
158 TextRange::from_to(start, end),
159 StringComponentKind::Char(CodePoint),
160 ))
161 }
162 }
163}
164
165#[derive(Debug, Eq, PartialEq, Clone)]
166pub struct StringComponent {
167 pub range: TextRange,
168 pub kind: StringComponentKind,
169}
170
171impl StringComponent {
172 fn new(range: TextRange, kind: StringComponentKind) -> StringComponent {
173 StringComponent { range, kind }
174 }
175}
176
177#[derive(Debug, Eq, PartialEq, Clone)]
178pub enum StringComponentKind {
179 IgnoreNewline,
180 Char(CharComponentKind),
181}
182
183#[derive(Debug, Eq, PartialEq, Clone)]
184pub struct CharComponent {
185 pub range: TextRange,
186 pub kind: CharComponentKind,
187}
188
189impl CharComponent {
190 fn new(range: TextRange, kind: CharComponentKind) -> CharComponent {
191 CharComponent { range, kind }
192 }
193}
194
195#[derive(Debug, Eq, PartialEq, Clone)]
196pub enum CharComponentKind {
197 CodePoint,
198 AsciiEscape,
199 AsciiCodeEscape,
200 UnicodeEscape,
201}
diff --git a/crates/ra_syntax/src/string_lexing/string.rs b/crates/ra_syntax/src/string_lexing/string.rs
new file mode 100644
index 000000000..1b23029c6
--- /dev/null
+++ b/crates/ra_syntax/src/string_lexing/string.rs
@@ -0,0 +1,46 @@
1use super::parser::Parser;
2use super::StringComponent;
3
4pub fn parse_string_literal(src: &str) -> StringComponentIterator {
5 StringComponentIterator {
6 parser: Parser::new(src),
7 has_closing_quote: false,
8 }
9}
10
11pub struct StringComponentIterator<'a> {
12 parser: Parser<'a>,
13 pub has_closing_quote: bool,
14}
15
16impl<'a> Iterator for StringComponentIterator<'a> {
17 type Item = StringComponent;
18 fn next(&mut self) -> Option<StringComponent> {
19 if self.parser.pos == 0 {
20 assert!(
21 self.parser.advance() == '"',
22 "string literal should start with double quotes"
23 );
24 }
25
26 if let Some(component) = self.parser.parse_string_component() {
27 return Some(component);
28 }
29
30 // We get here when there are no char components left to parse
31 if self.parser.peek() == Some('"') {
32 self.parser.advance();
33 self.has_closing_quote = true;
34 }
35
36 assert!(
37 self.parser.peek() == None,
38 "string literal should leave no unparsed input: src = {}, pos = {}, length = {}",
39 self.parser.src,
40 self.parser.pos,
41 self.parser.src.len()
42 );
43
44 None
45 }
46}
diff --git a/crates/ra_syntax/src/validation/byte.rs b/crates/ra_syntax/src/validation/byte.rs
new file mode 100644
index 000000000..43c0d7edd
--- /dev/null
+++ b/crates/ra_syntax/src/validation/byte.rs
@@ -0,0 +1,211 @@
1//! Validation of byte literals
2
3use crate::{
4 ast::{self, AstNode},
5 string_lexing::{self, CharComponentKind},
6 TextRange,
7 validation::char,
8 yellow::{
9 SyntaxError,
10 SyntaxErrorKind::*,
11 },
12};
13
14pub(super) fn validate_byte_node(node: ast::Byte, errors: &mut Vec<SyntaxError>) {
15 let literal_text = node.text();
16 let literal_range = node.syntax().range();
17 let mut components = string_lexing::parse_byte_literal(literal_text);
18 let mut len = 0;
19 for component in &mut components {
20 len += 1;
21 let text = &literal_text[component.range];
22 let range = component.range + literal_range.start();
23 validate_byte_component(text, component.kind, range, errors);
24 }
25
26 if !components.has_closing_quote {
27 errors.push(SyntaxError::new(UnclosedByte, literal_range));
28 }
29
30 if len == 0 {
31 errors.push(SyntaxError::new(EmptyByte, literal_range));
32 }
33
34 if len > 1 {
35 errors.push(SyntaxError::new(OverlongByte, literal_range));
36 }
37}
38
39pub(super) fn validate_byte_component(
40 text: &str,
41 kind: CharComponentKind,
42 range: TextRange,
43 errors: &mut Vec<SyntaxError>,
44) {
45 use self::CharComponentKind::*;
46 match kind {
47 AsciiEscape => validate_byte_escape(text, range, errors),
48 AsciiCodeEscape => validate_byte_code_escape(text, range, errors),
49 UnicodeEscape => errors.push(SyntaxError::new(UnicodeEscapeForbidden, range)),
50 CodePoint => {
51 let c = text
52 .chars()
53 .next()
54 .expect("Code points should be one character long");
55
56 // These bytes must always be escaped
57 if c == '\t' || c == '\r' || c == '\n' {
58 errors.push(SyntaxError::new(UnescapedByte, range));
59 }
60
61 // Only ASCII bytes are allowed
62 if c > 0x7F as char {
63 errors.push(SyntaxError::new(ByteOutOfRange, range));
64 }
65 }
66 }
67}
68
69fn validate_byte_escape(text: &str, range: TextRange, errors: &mut Vec<SyntaxError>) {
70 if text.len() == 1 {
71 // Escape sequence consists only of leading `\`
72 errors.push(SyntaxError::new(EmptyByteEscape, range));
73 } else {
74 let escape_code = text.chars().skip(1).next().unwrap();
75 if !char::is_ascii_escape(escape_code) {
76 errors.push(SyntaxError::new(InvalidByteEscape, range));
77 }
78 }
79}
80
81fn validate_byte_code_escape(text: &str, range: TextRange, errors: &mut Vec<SyntaxError>) {
82 // A ByteCodeEscape has 4 chars, example: `\xDD`
83 if text.len() < 4 {
84 errors.push(SyntaxError::new(TooShortByteCodeEscape, range));
85 } else {
86 assert!(
87 text.chars().count() == 4,
88 "ByteCodeEscape cannot be longer than 4 chars"
89 );
90
91 if u8::from_str_radix(&text[2..], 16).is_err() {
92 errors.push(SyntaxError::new(MalformedByteCodeEscape, range));
93 }
94 }
95}
96
97#[cfg(test)]
98mod test {
99 use crate::SourceFileNode;
100
101 fn build_file(literal: &str) -> SourceFileNode {
102 let src = format!("const C: u8 = b'{}';", literal);
103 SourceFileNode::parse(&src)
104 }
105
106 fn assert_valid_byte(literal: &str) {
107 let file = build_file(literal);
108 assert!(
109 file.errors().len() == 0,
110 "Errors for literal '{}': {:?}",
111 literal,
112 file.errors()
113 );
114 }
115
116 fn assert_invalid_byte(literal: &str) {
117 let file = build_file(literal);
118 assert!(file.errors().len() > 0);
119 }
120
121 #[test]
122 fn test_ansi_codepoints() {
123 for byte in 0..128 {
124 match byte {
125 b'\n' | b'\r' | b'\t' => assert_invalid_byte(&(byte as char).to_string()),
126 b'\'' | b'\\' => { /* Ignore character close and backslash */ }
127 _ => assert_valid_byte(&(byte as char).to_string()),
128 }
129 }
130
131 for byte in 128..=255u8 {
132 assert_invalid_byte(&(byte as char).to_string());
133 }
134 }
135
136 #[test]
137 fn test_unicode_codepoints() {
138 let invalid = ["Ƒ", "バ", "メ", "﷽"];
139 for c in &invalid {
140 assert_invalid_byte(c);
141 }
142 }
143
144 #[test]
145 fn test_unicode_multiple_codepoints() {
146 let invalid = ["नी", "👨‍👨‍"];
147 for c in &invalid {
148 assert_invalid_byte(c);
149 }
150 }
151
152 #[test]
153 fn test_valid_byte_escape() {
154 let valid = [r"\'", "\"", "\\\\", "\\\"", r"\n", r"\r", r"\t", r"\0"];
155 for c in &valid {
156 assert_valid_byte(c);
157 }
158 }
159
160 #[test]
161 fn test_invalid_byte_escape() {
162 let invalid = [r"\a", r"\?", r"\"];
163 for c in &invalid {
164 assert_invalid_byte(c);
165 }
166 }
167
168 #[test]
169 fn test_valid_byte_code_escape() {
170 let valid = [r"\x00", r"\x7F", r"\x55", r"\xF0"];
171 for c in &valid {
172 assert_valid_byte(c);
173 }
174 }
175
176 #[test]
177 fn test_invalid_byte_code_escape() {
178 let invalid = [r"\x", r"\x7"];
179 for c in &invalid {
180 assert_invalid_byte(c);
181 }
182 }
183
184 #[test]
185 fn test_invalid_unicode_escape() {
186 let well_formed = [
187 r"\u{FF}",
188 r"\u{0}",
189 r"\u{F}",
190 r"\u{10FFFF}",
191 r"\u{1_0__FF___FF_____}",
192 ];
193 for c in &well_formed {
194 assert_invalid_byte(c);
195 }
196
197 let invalid = [
198 r"\u",
199 r"\u{}",
200 r"\u{",
201 r"\u{FF",
202 r"\u{FFFFFF}",
203 r"\u{_F}",
204 r"\u{00FFFFF}",
205 r"\u{110000}",
206 ];
207 for c in &invalid {
208 assert_invalid_byte(c);
209 }
210 }
211}
diff --git a/crates/ra_syntax/src/validation/byte_string.rs b/crates/ra_syntax/src/validation/byte_string.rs
new file mode 100644
index 000000000..7b830e97c
--- /dev/null
+++ b/crates/ra_syntax/src/validation/byte_string.rs
@@ -0,0 +1,178 @@
1use crate::{
2 ast::{self, AstNode},
3 string_lexing::{self, StringComponentKind},
4 yellow::{
5 SyntaxError,
6 SyntaxErrorKind::*,
7 },
8};
9
10use super::byte;
11
12pub(crate) fn validate_byte_string_node(node: ast::ByteString, errors: &mut Vec<SyntaxError>) {
13 let literal_text = node.text();
14 let literal_range = node.syntax().range();
15 let mut components = string_lexing::parse_byte_string_literal(literal_text);
16 for component in &mut components {
17 let range = component.range + literal_range.start();
18
19 match component.kind {
20 StringComponentKind::Char(kind) => {
21 // Chars must escape \t, \n and \r codepoints, but strings don't
22 let text = &literal_text[component.range];
23 match text {
24 "\t" | "\n" | "\r" => { /* always valid */ }
25 _ => byte::validate_byte_component(text, kind, range, errors),
26 }
27 }
28 StringComponentKind::IgnoreNewline => { /* always valid */ }
29 }
30 }
31
32 if !components.has_closing_quote {
33 errors.push(SyntaxError::new(UnclosedString, literal_range));
34 }
35}
36
37#[cfg(test)]
38mod test {
39 use crate::SourceFileNode;
40
41 fn build_file(literal: &str) -> SourceFileNode {
42 let src = format!(r#"const S: &'static [u8] = b"{}";"#, literal);
43 println!("Source: {}", src);
44 SourceFileNode::parse(&src)
45 }
46
47 fn assert_valid_str(literal: &str) {
48 let file = build_file(literal);
49 assert!(
50 file.errors().len() == 0,
51 "Errors for literal '{}': {:?}",
52 literal,
53 file.errors()
54 );
55 }
56
57 fn assert_invalid_str(literal: &str) {
58 let file = build_file(literal);
59 assert!(file.errors().len() > 0);
60 }
61
62 #[test]
63 fn test_ansi_codepoints() {
64 for byte in 0..128 {
65 match byte {
66 b'\"' | b'\\' => { /* Ignore string close and backslash */ }
67 _ => assert_valid_str(&(byte as char).to_string()),
68 }
69 }
70
71 for byte in 128..=255u8 {
72 assert_invalid_str(&(byte as char).to_string());
73 }
74 }
75
76 #[test]
77 fn test_unicode_codepoints() {
78 let invalid = ["Ƒ", "バ", "メ", "﷽"];
79 for c in &invalid {
80 assert_invalid_str(c);
81 }
82 }
83
84 #[test]
85 fn test_unicode_multiple_codepoints() {
86 let invalid = ["नी", "👨‍👨‍"];
87 for c in &invalid {
88 assert_invalid_str(c);
89 }
90 }
91
92 #[test]
93 fn test_valid_ascii_escape() {
94 let valid = [r"\'", r#"\""#, r"\\", r"\n", r"\r", r"\t", r"\0", "a", "b"];
95 for c in &valid {
96 assert_valid_str(c);
97 }
98 }
99
100 #[test]
101 fn test_invalid_ascii_escape() {
102 let invalid = [r"\a", r"\?", r"\"];
103 for c in &invalid {
104 assert_invalid_str(c);
105 }
106 }
107
108 #[test]
109 fn test_valid_ascii_code_escape() {
110 let valid = [r"\x00", r"\x7F", r"\x55", r"\xF0"];
111 for c in &valid {
112 assert_valid_str(c);
113 }
114 }
115
116 #[test]
117 fn test_invalid_ascii_code_escape() {
118 let invalid = [r"\x", r"\x7"];
119 for c in &invalid {
120 assert_invalid_str(c);
121 }
122 }
123
124 #[test]
125 fn test_invalid_unicode_escape() {
126 let well_formed = [
127 r"\u{FF}",
128 r"\u{0}",
129 r"\u{F}",
130 r"\u{10FFFF}",
131 r"\u{1_0__FF___FF_____}",
132 ];
133 for c in &well_formed {
134 assert_invalid_str(c);
135 }
136
137 let invalid = [
138 r"\u",
139 r"\u{}",
140 r"\u{",
141 r"\u{FF",
142 r"\u{FFFFFF}",
143 r"\u{_F}",
144 r"\u{00FFFFF}",
145 r"\u{110000}",
146 ];
147 for c in &invalid {
148 assert_invalid_str(c);
149 }
150 }
151
152 #[test]
153 fn test_mixed_invalid() {
154 assert_invalid_str(
155 r"This is the tale of a string
156with a newline in between, some emoji (👨‍👨‍) here and there,
157unicode escapes like this: \u{1FFBB} and weird stuff like
158this ﷽",
159 );
160 }
161
162 #[test]
163 fn test_mixed_valid() {
164 assert_valid_str(
165 r"This is the tale of a string
166with a newline in between, no emoji at all,
167nor unicode escapes or weird stuff",
168 );
169 }
170
171 #[test]
172 fn test_ignore_newline() {
173 assert_valid_str(
174 "Hello \
175 World",
176 );
177 }
178}
diff --git a/crates/ra_syntax/src/validation/char.rs b/crates/ra_syntax/src/validation/char.rs
index 63f9bad24..4728c85e6 100644
--- a/crates/ra_syntax/src/validation/char.rs
+++ b/crates/ra_syntax/src/validation/char.rs
@@ -1,3 +1,5 @@
1//! Validation of char literals
2
1use std::u32; 3use std::u32;
2 4
3use arrayvec::ArrayString; 5use arrayvec::ArrayString;
@@ -12,7 +14,7 @@ use crate::{
12 }, 14 },
13}; 15};
14 16
15pub(crate) fn validate_char_node(node: ast::Char, errors: &mut Vec<SyntaxError>) { 17pub(super) fn validate_char_node(node: ast::Char, errors: &mut Vec<SyntaxError>) {
16 let literal_text = node.text(); 18 let literal_text = node.text();
17 let literal_range = node.syntax().range(); 19 let literal_range = node.syntax().range();
18 let mut components = string_lexing::parse_char_literal(literal_text); 20 let mut components = string_lexing::parse_char_literal(literal_text);
@@ -37,7 +39,7 @@ pub(crate) fn validate_char_node(node: ast::Char, errors: &mut Vec<SyntaxError>)
37 } 39 }
38} 40}
39 41
40pub(crate) fn validate_char_component( 42pub(super) fn validate_char_component(
41 text: &str, 43 text: &str,
42 kind: CharComponentKind, 44 kind: CharComponentKind,
43 range: TextRange, 45 range: TextRange,
@@ -46,109 +48,115 @@ pub(crate) fn validate_char_component(
46 // Validate escapes 48 // Validate escapes
47 use self::CharComponentKind::*; 49 use self::CharComponentKind::*;
48 match kind { 50 match kind {
49 AsciiEscape => { 51 AsciiEscape => validate_ascii_escape(text, range, errors),
50 if text.len() == 1 { 52 AsciiCodeEscape => validate_ascii_code_escape(text, range, errors),
51 // Escape sequence consists only of leading `\` 53 UnicodeEscape => validate_unicode_escape(text, range, errors),
52 errors.push(SyntaxError::new(EmptyAsciiEscape, range)); 54 CodePoint => {
53 } else { 55 // These code points must always be escaped
54 let escape_code = text.chars().skip(1).next().unwrap(); 56 if text == "\t" || text == "\r" || text == "\n" {
55 if !is_ascii_escape(escape_code) { 57 errors.push(SyntaxError::new(UnescapedCodepoint, range));
56 errors.push(SyntaxError::new(InvalidAsciiEscape, range));
57 }
58 } 58 }
59 } 59 }
60 AsciiCodeEscape => { 60 }
61 // An AsciiCodeEscape has 4 chars, example: `\xDD` 61}
62 if text.len() < 4 { 62
63 errors.push(SyntaxError::new(TooShortAsciiCodeEscape, range)); 63fn validate_ascii_escape(text: &str, range: TextRange, errors: &mut Vec<SyntaxError>) {
64 } else { 64 if text.len() == 1 {
65 assert!( 65 // Escape sequence consists only of leading `\`
66 text.chars().count() == 4, 66 errors.push(SyntaxError::new(EmptyAsciiEscape, range));
67 "AsciiCodeEscape cannot be longer than 4 chars" 67 } else {
68 ); 68 let escape_code = text.chars().skip(1).next().unwrap();
69 69 if !is_ascii_escape(escape_code) {
70 match u8::from_str_radix(&text[2..], 16) { 70 errors.push(SyntaxError::new(InvalidAsciiEscape, range));
71 Ok(code) if code < 128 => { /* Escape code is valid */ }
72 Ok(_) => errors.push(SyntaxError::new(AsciiCodeEscapeOutOfRange, range)),
73 Err(_) => errors.push(SyntaxError::new(MalformedAsciiCodeEscape, range)),
74 }
75 }
76 } 71 }
77 UnicodeEscape => { 72 }
78 assert!(&text[..2] == "\\u", "UnicodeEscape always starts with \\u"); 73}
79 74
80 if text.len() == 2 { 75pub(super) fn is_ascii_escape(code: char) -> bool {
81 // No starting `{` 76 match code {
82 errors.push(SyntaxError::new(MalformedUnicodeEscape, range)); 77 '\\' | '\'' | '"' | 'n' | 'r' | 't' | '0' => true,
83 return; 78 _ => false,
84 } 79 }
80}
85 81
86 if text.len() == 3 { 82fn validate_ascii_code_escape(text: &str, range: TextRange, errors: &mut Vec<SyntaxError>) {
87 // Only starting `{` 83 // An AsciiCodeEscape has 4 chars, example: `\xDD`
88 errors.push(SyntaxError::new(UnclosedUnicodeEscape, range)); 84 if text.len() < 4 {
89 return; 85 errors.push(SyntaxError::new(TooShortAsciiCodeEscape, range));
90 } 86 } else {
87 assert!(
88 text.chars().count() == 4,
89 "AsciiCodeEscape cannot be longer than 4 chars"
90 );
91 91
92 let mut code = ArrayString::<[_; 6]>::new(); 92 match u8::from_str_radix(&text[2..], 16) {
93 let mut closed = false; 93 Ok(code) if code < 128 => { /* Escape code is valid */ }
94 for c in text[3..].chars() { 94 Ok(_) => errors.push(SyntaxError::new(AsciiCodeEscapeOutOfRange, range)),
95 assert!(!closed, "no characters after escape is closed"); 95 Err(_) => errors.push(SyntaxError::new(MalformedAsciiCodeEscape, range)),
96 96 }
97 if c.is_digit(16) { 97 }
98 if code.len() == 6 { 98}
99 errors.push(SyntaxError::new(OverlongUnicodeEscape, range));
100 return;
101 }
102
103 code.push(c);
104 } else if c == '_' {
105 // Reject leading _
106 if code.len() == 0 {
107 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
108 return;
109 }
110 } else if c == '}' {
111 closed = true;
112 } else {
113 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
114 return;
115 }
116 }
117 99
118 if !closed { 100fn validate_unicode_escape(text: &str, range: TextRange, errors: &mut Vec<SyntaxError>) {
119 errors.push(SyntaxError::new(UnclosedUnicodeEscape, range)) 101 assert!(&text[..2] == "\\u", "UnicodeEscape always starts with \\u");
120 }
121 102
122 if code.len() == 0 { 103 if text.len() == 2 {
123 errors.push(SyntaxError::new(EmptyUnicodeEcape, range)); 104 // No starting `{`
105 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
106 return;
107 }
108
109 if text.len() == 3 {
110 // Only starting `{`
111 errors.push(SyntaxError::new(UnclosedUnicodeEscape, range));
112 return;
113 }
114
115 let mut code = ArrayString::<[_; 6]>::new();
116 let mut closed = false;
117 for c in text[3..].chars() {
118 assert!(!closed, "no characters after escape is closed");
119
120 if c.is_digit(16) {
121 if code.len() == 6 {
122 errors.push(SyntaxError::new(OverlongUnicodeEscape, range));
124 return; 123 return;
125 } 124 }
126 125
127 match u32::from_str_radix(&code, 16) { 126 code.push(c);
128 Ok(code_u32) if code_u32 > 0x10FFFF => { 127 } else if c == '_' {
129 errors.push(SyntaxError::new(UnicodeEscapeOutOfRange, range)); 128 // Reject leading _
130 } 129 if code.len() == 0 {
131 Ok(_) => { 130 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
132 // Valid escape code 131 return;
133 }
134 Err(_) => {
135 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
136 }
137 }
138 }
139 CodePoint => {
140 // These code points must always be escaped
141 if text == "\t" || text == "\r" {
142 errors.push(SyntaxError::new(UnescapedCodepoint, range));
143 } 132 }
133 } else if c == '}' {
134 closed = true;
135 } else {
136 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
137 return;
144 } 138 }
145 } 139 }
146}
147 140
148fn is_ascii_escape(code: char) -> bool { 141 if !closed {
149 match code { 142 errors.push(SyntaxError::new(UnclosedUnicodeEscape, range))
150 '\\' | '\'' | '"' | 'n' | 'r' | 't' | '0' => true, 143 }
151 _ => false, 144
145 if code.len() == 0 {
146 errors.push(SyntaxError::new(EmptyUnicodeEcape, range));
147 return;
148 }
149
150 match u32::from_str_radix(&code, 16) {
151 Ok(code_u32) if code_u32 > 0x10FFFF => {
152 errors.push(SyntaxError::new(UnicodeEscapeOutOfRange, range));
153 }
154 Ok(_) => {
155 // Valid escape code
156 }
157 Err(_) => {
158 errors.push(SyntaxError::new(MalformedUnicodeEscape, range));
159 }
152 } 160 }
153} 161}
154 162
@@ -205,9 +213,7 @@ mod test {
205 213
206 #[test] 214 #[test]
207 fn test_valid_ascii_escape() { 215 fn test_valid_ascii_escape() {
208 let valid = [ 216 let valid = [r"\'", "\"", "\\\\", "\\\"", r"\n", r"\r", r"\t", r"\0"];
209 r"\'", "\"", "\\\\", "\\\"", r"\n", r"\r", r"\t", r"\0", "a", "b",
210 ];
211 for c in &valid { 217 for c in &valid {
212 assert_valid_char(c); 218 assert_valid_char(c);
213 } 219 }
diff --git a/crates/ra_syntax/src/validation/mod.rs b/crates/ra_syntax/src/validation/mod.rs
index 2ff0bc26d..bdee8120c 100644
--- a/crates/ra_syntax/src/validation/mod.rs
+++ b/crates/ra_syntax/src/validation/mod.rs
@@ -5,6 +5,8 @@ use crate::{
5 yellow::SyntaxError, 5 yellow::SyntaxError,
6}; 6};
7 7
8mod byte;
9mod byte_string;
8mod char; 10mod char;
9mod string; 11mod string;
10 12
@@ -12,6 +14,8 @@ pub(crate) fn validate(file: &SourceFileNode) -> Vec<SyntaxError> {
12 let mut errors = Vec::new(); 14 let mut errors = Vec::new();
13 for node in file.syntax().descendants() { 15 for node in file.syntax().descendants() {
14 let _ = visitor_ctx(&mut errors) 16 let _ = visitor_ctx(&mut errors)
17 .visit::<ast::Byte, _>(self::byte::validate_byte_node)
18 .visit::<ast::ByteString, _>(self::byte_string::validate_byte_string_node)
15 .visit::<ast::Char, _>(self::char::validate_char_node) 19 .visit::<ast::Char, _>(self::char::validate_char_node)
16 .visit::<ast::String, _>(self::string::validate_string_node) 20 .visit::<ast::String, _>(self::string::validate_string_node)
17 .accept(node); 21 .accept(node);
diff --git a/crates/ra_syntax/src/yellow/syntax_error.rs b/crates/ra_syntax/src/yellow/syntax_error.rs
index cf7b1d495..c32ee650d 100644
--- a/crates/ra_syntax/src/yellow/syntax_error.rs
+++ b/crates/ra_syntax/src/yellow/syntax_error.rs
@@ -72,6 +72,16 @@ pub enum SyntaxErrorKind {
72 EmptyChar, 72 EmptyChar,
73 UnclosedChar, 73 UnclosedChar,
74 OverlongChar, 74 OverlongChar,
75 EmptyByte,
76 UnclosedByte,
77 OverlongByte,
78 ByteOutOfRange,
79 UnescapedByte,
80 EmptyByteEscape,
81 InvalidByteEscape,
82 TooShortByteCodeEscape,
83 MalformedByteCodeEscape,
84 UnicodeEscapeForbidden,
75 EmptyAsciiEscape, 85 EmptyAsciiEscape,
76 InvalidAsciiEscape, 86 InvalidAsciiEscape,
77 TooShortAsciiCodeEscape, 87 TooShortAsciiCodeEscape,
@@ -98,6 +108,19 @@ impl fmt::Display for SyntaxErrorKind {
98 EmptyChar => write!(f, "Empty char literal"), 108 EmptyChar => write!(f, "Empty char literal"),
99 UnclosedChar => write!(f, "Unclosed char literal"), 109 UnclosedChar => write!(f, "Unclosed char literal"),
100 OverlongChar => write!(f, "Char literal should be one character long"), 110 OverlongChar => write!(f, "Char literal should be one character long"),
111 EmptyByte => write!(f, "Empty byte literal"),
112 UnclosedByte => write!(f, "Unclosed byte literal"),
113 OverlongByte => write!(f, "Byte literal should be one character long"),
114 ByteOutOfRange => write!(f, "Byte should be a valid ASCII character"),
115 UnescapedByte => write!(f, "This byte should always be escaped"),
116 EmptyByteEscape => write!(f, "Empty escape sequence"),
117 InvalidByteEscape => write!(f, "Invalid escape sequence"),
118 TooShortByteCodeEscape => write!(f, "Escape sequence should have two digits"),
119 MalformedByteCodeEscape => write!(f, "Escape sequence should be a hexadecimal number"),
120 UnicodeEscapeForbidden => write!(
121 f,
122 "Unicode escapes are not allowed in byte literals or byte strings"
123 ),
101 TooShortAsciiCodeEscape => write!(f, "Escape sequence should have two digits"), 124 TooShortAsciiCodeEscape => write!(f, "Escape sequence should have two digits"),
102 AsciiCodeEscapeOutOfRange => { 125 AsciiCodeEscapeOutOfRange => {
103 write!(f, "Escape sequence should be between \\x00 and \\x7F") 126 write!(f, "Escape sequence should be between \\x00 and \\x7F")