#![allow( clippy::assertions_on_result_states, clippy::items_after_statements, clippy::needless_pass_by_value, clippy::needless_raw_string_hashes, clippy::non_ascii_literal, clippy::octal_escapes )] use proc_macro2::{Ident, Literal, Punct, Spacing, Span, TokenStream, TokenTree}; use std::ffi::CStr; use std::iter; use std::str::{self, FromStr}; #[test] fn idents() { assert_eq!( Ident::new("String", Span::call_site()).to_string(), "String" ); assert_eq!(Ident::new("fn", Span::call_site()).to_string(), "fn"); assert_eq!(Ident::new("_", Span::call_site()).to_string(), "_"); } #[test] fn raw_idents() { assert_eq!( Ident::new_raw("String", Span::call_site()).to_string(), "r#String" ); assert_eq!(Ident::new_raw("fn", Span::call_site()).to_string(), "r#fn"); } #[test] #[should_panic(expected = "`r#_` cannot be a raw identifier")] fn ident_raw_underscore() { Ident::new_raw("_", Span::call_site()); } #[test] #[should_panic(expected = "`r#super` cannot be a raw identifier")] fn ident_raw_reserved() { Ident::new_raw("super", Span::call_site()); } #[test] #[should_panic(expected = "Ident is not allowed to be empty; use Option")] fn ident_empty() { Ident::new("", Span::call_site()); } #[test] #[should_panic(expected = "Ident cannot be a number; use Literal instead")] fn ident_number() { Ident::new("255", Span::call_site()); } #[test] #[should_panic(expected = "\"a#\" is not a valid Ident")] fn ident_invalid() { Ident::new("a#", Span::call_site()); } #[test] #[should_panic(expected = "not a valid Ident")] fn raw_ident_empty() { Ident::new("r#", Span::call_site()); } #[test] #[should_panic(expected = "not a valid Ident")] fn raw_ident_number() { Ident::new("r#255", Span::call_site()); } #[test] #[should_panic(expected = "\"r#a#\" is not a valid Ident")] fn raw_ident_invalid() { Ident::new("r#a#", Span::call_site()); } #[test] #[should_panic(expected = "not a valid Ident")] fn lifetime_empty() { Ident::new("'", Span::call_site()); } #[test] #[should_panic(expected = "not a valid Ident")] fn lifetime_number() { Ident::new("'255", Span::call_site()); } #[test] #[should_panic(expected = r#""'a#" is not a valid Ident"#)] fn lifetime_invalid() { Ident::new("'a#", Span::call_site()); } #[test] fn literal_string() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected.trim()); } assert(Literal::string(""), r#" "" "#); assert(Literal::string("aA"), r#" "aA" "#); assert(Literal::string("\t"), r#" "\t" "#); assert(Literal::string("❤"), r#" "❤" "#); assert(Literal::string("'"), r#" "'" "#); assert(Literal::string("\""), r#" "\"" "#); assert(Literal::string("\0"), r#" "\0" "#); assert(Literal::string("\u{1}"), r#" "\u{1}" "#); assert( Literal::string("a\00b\07c\08d\0e\0"), r#" "a\x000b\x007c\08d\0e\0" "#, ); "\"\\\r\n x\"".parse::().unwrap(); "\"\\\r\n \rx\"".parse::().unwrap_err(); } #[test] fn literal_raw_string() { "r\"\r\n\"".parse::().unwrap(); fn raw_string_literal_with_hashes(n: usize) -> String { let mut literal = String::new(); literal.push('r'); literal.extend(iter::repeat('#').take(n)); literal.push('"'); literal.push('"'); literal.extend(iter::repeat('#').take(n)); literal } raw_string_literal_with_hashes(255) .parse::() .unwrap(); // https://github.com/rust-lang/rust/pull/95251 raw_string_literal_with_hashes(256) .parse::() .unwrap_err(); } #[test] fn literal_byte_character() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected.trim()); } assert(Literal::byte_character(b'a'), r#" b'a' "#); assert(Literal::byte_character(b'\0'), r#" b'\0' "#); assert(Literal::byte_character(b'\t'), r#" b'\t' "#); assert(Literal::byte_character(b'\n'), r#" b'\n' "#); assert(Literal::byte_character(b'\r'), r#" b'\r' "#); assert(Literal::byte_character(b'\''), r#" b'\'' "#); assert(Literal::byte_character(b'\\'), r#" b'\\' "#); assert(Literal::byte_character(b'\x1f'), r#" b'\x1F' "#); assert(Literal::byte_character(b'"'), r#" b'"' "#); } #[test] fn literal_byte_string() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected.trim()); } assert(Literal::byte_string(b""), r#" b"" "#); assert(Literal::byte_string(b"\0"), r#" b"\0" "#); assert(Literal::byte_string(b"\t"), r#" b"\t" "#); assert(Literal::byte_string(b"\n"), r#" b"\n" "#); assert(Literal::byte_string(b"\r"), r#" b"\r" "#); assert(Literal::byte_string(b"\""), r#" b"\"" "#); assert(Literal::byte_string(b"\\"), r#" b"\\" "#); assert(Literal::byte_string(b"\x1f"), r#" b"\x1F" "#); assert(Literal::byte_string(b"'"), r#" b"'" "#); assert( Literal::byte_string(b"a\00b\07c\08d\0e\0"), r#" b"a\x000b\x007c\08d\0e\0" "#, ); "b\"\\\r\n x\"".parse::().unwrap(); "b\"\\\r\n \rx\"".parse::().unwrap_err(); "b\"\\\r\n \u{a0}x\"".parse::().unwrap_err(); "br\"\u{a0}\"".parse::().unwrap_err(); } #[test] fn literal_c_string() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected.trim()); } assert(Literal::c_string(<&CStr>::default()), r#" c"" "#); assert( Literal::c_string(CStr::from_bytes_with_nul(b"aA\0").unwrap()), r#" c"aA" "#, ); assert( Literal::c_string(CStr::from_bytes_with_nul(b"aA\0").unwrap()), r#" c"aA" "#, ); assert( Literal::c_string(CStr::from_bytes_with_nul(b"\t\0").unwrap()), r#" c"\t" "#, ); assert( Literal::c_string(CStr::from_bytes_with_nul(b"\xE2\x9D\xA4\0").unwrap()), r#" c"❤" "#, ); assert( Literal::c_string(CStr::from_bytes_with_nul(b"'\0").unwrap()), r#" c"'" "#, ); assert( Literal::c_string(CStr::from_bytes_with_nul(b"\"\0").unwrap()), r#" c"\"" "#, ); assert( Literal::c_string(CStr::from_bytes_with_nul(b"\x7F\xFF\xFE\xCC\xB3\0").unwrap()), r#" c"\u{7f}\xFF\xFE\u{333}" "#, ); let strings = r###" c"hello\x80我叫\u{1F980}" // from the RFC cr"\" cr##"Hello "world"!"## c"\t\n\r\"\\" "###; let mut tokens = strings.parse::().unwrap().into_iter(); for expected in &[ r#"c"hello\x80我叫\u{1F980}""#, r#"cr"\""#, r###"cr##"Hello "world"!"##"###, r#"c"\t\n\r\"\\""#, ] { match tokens.next().unwrap() { TokenTree::Literal(literal) => { assert_eq!(literal.to_string(), *expected); } unexpected => panic!("unexpected token: {:?}", unexpected), } } if let Some(unexpected) = tokens.next() { panic!("unexpected token: {:?}", unexpected); } for invalid in &[r#"c"\0""#, r#"c"\x00""#, r#"c"\u{0}""#, "c\"\0\""] { if let Ok(unexpected) = invalid.parse::() { panic!("unexpected token: {:?}", unexpected); } } } #[test] fn literal_character() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected.trim()); } assert(Literal::character('a'), r#" 'a' "#); assert(Literal::character('\t'), r#" '\t' "#); assert(Literal::character('❤'), r#" '❤' "#); assert(Literal::character('\''), r#" '\'' "#); assert(Literal::character('"'), r#" '"' "#); assert(Literal::character('\0'), r#" '\0' "#); assert(Literal::character('\u{1}'), r#" '\u{1}' "#); } #[test] fn literal_integer() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected); } assert(Literal::u8_suffixed(10), "10u8"); assert(Literal::u16_suffixed(10), "10u16"); assert(Literal::u32_suffixed(10), "10u32"); assert(Literal::u64_suffixed(10), "10u64"); assert(Literal::u128_suffixed(10), "10u128"); assert(Literal::usize_suffixed(10), "10usize"); assert(Literal::i8_suffixed(10), "10i8"); assert(Literal::i16_suffixed(10), "10i16"); assert(Literal::i32_suffixed(10), "10i32"); assert(Literal::i64_suffixed(10), "10i64"); assert(Literal::i128_suffixed(10), "10i128"); assert(Literal::isize_suffixed(10), "10isize"); assert(Literal::u8_unsuffixed(10), "10"); assert(Literal::u16_unsuffixed(10), "10"); assert(Literal::u32_unsuffixed(10), "10"); assert(Literal::u64_unsuffixed(10), "10"); assert(Literal::u128_unsuffixed(10), "10"); assert(Literal::usize_unsuffixed(10), "10"); assert(Literal::i8_unsuffixed(10), "10"); assert(Literal::i16_unsuffixed(10), "10"); assert(Literal::i32_unsuffixed(10), "10"); assert(Literal::i64_unsuffixed(10), "10"); assert(Literal::i128_unsuffixed(10), "10"); assert(Literal::isize_unsuffixed(10), "10"); assert(Literal::i32_suffixed(-10), "-10i32"); assert(Literal::i32_unsuffixed(-10), "-10"); } #[test] fn literal_float() { #[track_caller] fn assert(literal: Literal, expected: &str) { assert_eq!(literal.to_string(), expected); } assert(Literal::f32_suffixed(10.0), "10f32"); assert(Literal::f32_suffixed(-10.0), "-10f32"); assert(Literal::f64_suffixed(10.0), "10f64"); assert(Literal::f64_suffixed(-10.0), "-10f64"); assert(Literal::f32_unsuffixed(10.0), "10.0"); assert(Literal::f32_unsuffixed(-10.0), "-10.0"); assert(Literal::f64_unsuffixed(10.0), "10.0"); assert(Literal::f64_unsuffixed(-10.0), "-10.0"); assert( Literal::f64_unsuffixed(1e100), "10000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000.0", ); } #[test] fn literal_suffix() { fn token_count(p: &str) -> usize { p.parse::().unwrap().into_iter().count() } assert_eq!(token_count("999u256"), 1); assert_eq!(token_count("999r#u256"), 3); assert_eq!(token_count("1."), 1); assert_eq!(token_count("1.f32"), 3); assert_eq!(token_count("1.0_0"), 1); assert_eq!(token_count("1._0"), 3); assert_eq!(token_count("1._m"), 3); assert_eq!(token_count("\"\"s"), 1); assert_eq!(token_count("r\"\"r"), 1); assert_eq!(token_count("r#\"\"#r"), 1); assert_eq!(token_count("b\"\"b"), 1); assert_eq!(token_count("br\"\"br"), 1); assert_eq!(token_count("br#\"\"#br"), 1); assert_eq!(token_count("c\"\"c"), 1); assert_eq!(token_count("cr\"\"cr"), 1); assert_eq!(token_count("cr#\"\"#cr"), 1); assert_eq!(token_count("'c'c"), 1); assert_eq!(token_count("b'b'b"), 1); assert_eq!(token_count("0E"), 1); assert_eq!(token_count("0o0A"), 1); assert_eq!(token_count("0E--0"), 4); assert_eq!(token_count("0.0ECMA"), 1); } #[test] fn literal_iter_negative() { let negative_literal = Literal::i32_suffixed(-3); let tokens = TokenStream::from(TokenTree::Literal(negative_literal)); let mut iter = tokens.into_iter(); match iter.next().unwrap() { TokenTree::Punct(punct) => { assert_eq!(punct.as_char(), '-'); assert_eq!(punct.spacing(), Spacing::Alone); } unexpected => panic!("unexpected token {:?}", unexpected), } match iter.next().unwrap() { TokenTree::Literal(literal) => { assert_eq!(literal.to_string(), "3i32"); } unexpected => panic!("unexpected token {:?}", unexpected), } assert!(iter.next().is_none()); } #[test] fn literal_parse() { assert!("1".parse::().is_ok()); assert!("-1".parse::().is_ok()); assert!("-1u12".parse::().is_ok()); assert!("1.0".parse::().is_ok()); assert!("-1.0".parse::().is_ok()); assert!("-1.0f12".parse::().is_ok()); assert!("'a'".parse::().is_ok()); assert!("\"\n\"".parse::().is_ok()); assert!("0 1".parse::().is_err()); assert!(" 0".parse::().is_err()); assert!("0 ".parse::().is_err()); assert!("/* comment */0".parse::().is_err()); assert!("0/* comment */".parse::().is_err()); assert!("0// comment".parse::().is_err()); assert!("- 1".parse::().is_err()); assert!("- 1.0".parse::().is_err()); assert!("-\"\"".parse::().is_err()); } #[test] fn literal_span() { let positive = "0.1".parse::().unwrap(); let negative = "-0.1".parse::().unwrap(); let subspan = positive.subspan(1..2); #[cfg(not(span_locations))] { let _ = negative; assert!(subspan.is_none()); } #[cfg(span_locations)] { assert_eq!(positive.span().start().column, 0); assert_eq!(positive.span().end().column, 3); assert_eq!(negative.span().start().column, 0); assert_eq!(negative.span().end().column, 4); assert_eq!(subspan.unwrap().source_text().unwrap(), "."); } assert!(positive.subspan(1..4).is_none()); } #[cfg(span_locations)] #[test] fn source_text() { let input = " 𓀕 a z "; let mut tokens = input .parse::() .unwrap() .into_iter(); let first = tokens.next().unwrap(); assert_eq!("𓀕", first.span().source_text().unwrap()); let second = tokens.next().unwrap(); let third = tokens.next().unwrap(); assert_eq!("z", third.span().source_text().unwrap()); assert_eq!("a", second.span().source_text().unwrap()); } #[test] fn roundtrip() { fn roundtrip(p: &str) { println!("parse: {}", p); let s = p.parse::().unwrap().to_string(); println!("first: {}", s); let s2 = s.parse::().unwrap().to_string(); assert_eq!(s, s2); } roundtrip("a"); roundtrip("<<"); roundtrip("<<="); roundtrip( " 1 1.0 1f32 2f64 1usize 4isize 4e10 1_000 1_0i32 8u8 9 0 0xffffffffffffffffffffffffffffffff 1x 1u80 1f320 ", ); roundtrip("'a"); roundtrip("'_"); roundtrip("'static"); roundtrip(r"'\u{10__FFFF}'"); roundtrip("\"\\u{10_F0FF__}foo\\u{1_0_0_0__}\""); } #[test] fn fail() { fn fail(p: &str) { if let Ok(s) = p.parse::() { panic!("should have failed to parse: {}\n{:#?}", p, s); } } fail("' static"); fail("r#1"); fail("r#_"); fail("\"\\u{0000000}\""); // overlong unicode escape (rust allows at most 6 hex digits) fail("\"\\u{999999}\""); // outside of valid range of char fail("\"\\u{_0}\""); // leading underscore fail("\"\\u{}\""); // empty fail("b\"\r\""); // bare carriage return in byte string fail("r\"\r\""); // bare carriage return in raw string fail("\"\\\r \""); // backslash carriage return fail("'aa'aa"); fail("br##\"\"#"); fail("cr##\"\"#"); fail("\"\\\n\u{85}\r\""); } #[cfg(span_locations)] #[test] fn span_test() { check_spans( "\ /// This is a document comment testing 123 { testing 234 }", &[ (1, 0, 1, 30), // # (1, 0, 1, 30), // [ ... ] (1, 0, 1, 30), // doc (1, 0, 1, 30), // = (1, 0, 1, 30), // "This is..." (2, 0, 2, 7), // testing (2, 8, 2, 11), // 123 (3, 0, 5, 1), // { ... } (4, 2, 4, 9), // testing (4, 10, 4, 13), // 234 ], ); } #[cfg(procmacro2_semver_exempt)] #[test] fn default_span() { let start = Span::call_site().start(); assert_eq!(start.line, 1); assert_eq!(start.column, 0); let end = Span::call_site().end(); assert_eq!(end.line, 1); assert_eq!(end.column, 0); let source_file = Span::call_site().source_file(); assert_eq!(source_file.path().to_string_lossy(), ""); assert!(!source_file.is_real()); } #[cfg(procmacro2_semver_exempt)] #[test] fn span_join() { let source1 = "aaa\nbbb" .parse::() .unwrap() .into_iter() .collect::>(); let source2 = "ccc\nddd" .parse::() .unwrap() .into_iter() .collect::>(); assert!(source1[0].span().source_file() != source2[0].span().source_file()); assert_eq!( source1[0].span().source_file(), source1[1].span().source_file() ); let joined1 = source1[0].span().join(source1[1].span()); let joined2 = source1[0].span().join(source2[0].span()); assert!(joined1.is_some()); assert!(joined2.is_none()); let start = joined1.unwrap().start(); let end = joined1.unwrap().end(); assert_eq!(start.line, 1); assert_eq!(start.column, 0); assert_eq!(end.line, 2); assert_eq!(end.column, 3); assert_eq!( joined1.unwrap().source_file(), source1[0].span().source_file() ); } #[test] fn no_panic() { let s = str::from_utf8(b"b\'\xc2\x86 \x00\x00\x00^\"").unwrap(); assert!(s.parse::().is_err()); } #[test] fn punct_before_comment() { let mut tts = TokenStream::from_str("~// comment").unwrap().into_iter(); match tts.next().unwrap() { TokenTree::Punct(tt) => { assert_eq!(tt.as_char(), '~'); assert_eq!(tt.spacing(), Spacing::Alone); } wrong => panic!("wrong token {:?}", wrong), } } #[test] fn joint_last_token() { // This test verifies that we match the behavior of libproc_macro *not* in // the range nightly-2020-09-06 through nightly-2020-09-10, in which this // behavior was temporarily broken. // See https://github.com/rust-lang/rust/issues/76399 let joint_punct = Punct::new(':', Spacing::Joint); let stream = TokenStream::from(TokenTree::Punct(joint_punct)); let punct = match stream.into_iter().next().unwrap() { TokenTree::Punct(punct) => punct, _ => unreachable!(), }; assert_eq!(punct.spacing(), Spacing::Joint); } #[test] fn raw_identifier() { let mut tts = TokenStream::from_str("r#dyn").unwrap().into_iter(); match tts.next().unwrap() { TokenTree::Ident(raw) => assert_eq!("r#dyn", raw.to_string()), wrong => panic!("wrong token {:?}", wrong), } assert!(tts.next().is_none()); } #[test] fn test_debug_ident() { let ident = Ident::new("proc_macro", Span::call_site()); #[cfg(not(span_locations))] let expected = "Ident(proc_macro)"; #[cfg(span_locations)] let expected = "Ident { sym: proc_macro }"; assert_eq!(expected, format!("{:?}", ident)); } #[test] fn test_debug_tokenstream() { let tts = TokenStream::from_str("[a + 1]").unwrap(); #[cfg(not(span_locations))] let expected = "\ TokenStream [ Group { delimiter: Bracket, stream: TokenStream [ Ident { sym: a, }, Punct { char: '+', spacing: Alone, }, Literal { lit: 1, }, ], }, ]\ "; #[cfg(not(span_locations))] let expected_before_trailing_commas = "\ TokenStream [ Group { delimiter: Bracket, stream: TokenStream [ Ident { sym: a }, Punct { char: '+', spacing: Alone }, Literal { lit: 1 } ] } ]\ "; #[cfg(span_locations)] let expected = "\ TokenStream [ Group { delimiter: Bracket, stream: TokenStream [ Ident { sym: a, span: bytes(2..3), }, Punct { char: '+', spacing: Alone, span: bytes(4..5), }, Literal { lit: 1, span: bytes(6..7), }, ], span: bytes(1..8), }, ]\ "; #[cfg(span_locations)] let expected_before_trailing_commas = "\ TokenStream [ Group { delimiter: Bracket, stream: TokenStream [ Ident { sym: a, span: bytes(2..3) }, Punct { char: '+', spacing: Alone, span: bytes(4..5) }, Literal { lit: 1, span: bytes(6..7) } ], span: bytes(1..8) } ]\ "; let actual = format!("{:#?}", tts); if actual.ends_with(",\n]") { assert_eq!(expected, actual); } else { assert_eq!(expected_before_trailing_commas, actual); } } #[test] fn default_tokenstream_is_empty() { let default_token_stream = ::default(); assert!(default_token_stream.is_empty()); } #[test] fn tokenstream_size_hint() { let tokens = "a b (c d) e".parse::().unwrap(); assert_eq!(tokens.into_iter().size_hint(), (4, Some(4))); } #[test] fn tuple_indexing() { // This behavior may change depending on https://github.com/rust-lang/rust/pull/71322 let mut tokens = "tuple.0.0".parse::().unwrap().into_iter(); assert_eq!("tuple", tokens.next().unwrap().to_string()); assert_eq!(".", tokens.next().unwrap().to_string()); assert_eq!("0.0", tokens.next().unwrap().to_string()); assert!(tokens.next().is_none()); } #[cfg(span_locations)] #[test] fn non_ascii_tokens() { check_spans("// abc", &[]); check_spans("// ábc", &[]); check_spans("// abc x", &[]); check_spans("// ábc x", &[]); check_spans("/* abc */ x", &[(1, 10, 1, 11)]); check_spans("/* ábc */ x", &[(1, 10, 1, 11)]); check_spans("/* ab\nc */ x", &[(2, 5, 2, 6)]); check_spans("/* áb\nc */ x", &[(2, 5, 2, 6)]); check_spans("/*** abc */ x", &[(1, 12, 1, 13)]); check_spans("/*** ábc */ x", &[(1, 12, 1, 13)]); check_spans(r#""abc""#, &[(1, 0, 1, 5)]); check_spans(r#""ábc""#, &[(1, 0, 1, 5)]); check_spans(r##"r#"abc"#"##, &[(1, 0, 1, 8)]); check_spans(r##"r#"ábc"#"##, &[(1, 0, 1, 8)]); check_spans("r#\"a\nc\"#", &[(1, 0, 2, 3)]); check_spans("r#\"á\nc\"#", &[(1, 0, 2, 3)]); check_spans("'a'", &[(1, 0, 1, 3)]); check_spans("'á'", &[(1, 0, 1, 3)]); check_spans("//! abc", &[(1, 0, 1, 7), (1, 0, 1, 7), (1, 0, 1, 7)]); check_spans("//! ábc", &[(1, 0, 1, 7), (1, 0, 1, 7), (1, 0, 1, 7)]); check_spans("//! abc\n", &[(1, 0, 1, 7), (1, 0, 1, 7), (1, 0, 1, 7)]); check_spans("//! ábc\n", &[(1, 0, 1, 7), (1, 0, 1, 7), (1, 0, 1, 7)]); check_spans("/*! abc */", &[(1, 0, 1, 10), (1, 0, 1, 10), (1, 0, 1, 10)]); check_spans("/*! ábc */", &[(1, 0, 1, 10), (1, 0, 1, 10), (1, 0, 1, 10)]); check_spans("/*! a\nc */", &[(1, 0, 2, 4), (1, 0, 2, 4), (1, 0, 2, 4)]); check_spans("/*! á\nc */", &[(1, 0, 2, 4), (1, 0, 2, 4), (1, 0, 2, 4)]); check_spans("abc", &[(1, 0, 1, 3)]); check_spans("ábc", &[(1, 0, 1, 3)]); check_spans("ábć", &[(1, 0, 1, 3)]); check_spans("abc// foo", &[(1, 0, 1, 3)]); check_spans("ábc// foo", &[(1, 0, 1, 3)]); check_spans("ábć// foo", &[(1, 0, 1, 3)]); check_spans("b\"a\\\n c\"", &[(1, 0, 2, 3)]); } #[cfg(span_locations)] fn check_spans(p: &str, mut lines: &[(usize, usize, usize, usize)]) { let ts = p.parse::().unwrap(); check_spans_internal(ts, &mut lines); assert!(lines.is_empty(), "leftover ranges: {:?}", lines); } #[cfg(span_locations)] fn check_spans_internal(ts: TokenStream, lines: &mut &[(usize, usize, usize, usize)]) { for i in ts { if let Some((&(sline, scol, eline, ecol), rest)) = lines.split_first() { *lines = rest; let start = i.span().start(); assert_eq!(start.line, sline, "sline did not match for {}", i); assert_eq!(start.column, scol, "scol did not match for {}", i); let end = i.span().end(); assert_eq!(end.line, eline, "eline did not match for {}", i); assert_eq!(end.column, ecol, "ecol did not match for {}", i); if let TokenTree::Group(g) = i { check_spans_internal(g.stream().clone(), lines); } } } } #[test] fn whitespace() { // space, horizontal tab, vertical tab, form feed, carriage return, line // feed, non-breaking space, left-to-right mark, right-to-left mark let various_spaces = " \t\u{b}\u{c}\r\n\u{a0}\u{200e}\u{200f}"; let tokens = various_spaces.parse::().unwrap(); assert_eq!(tokens.into_iter().count(), 0); let lone_carriage_returns = " \r \r\r\n "; lone_carriage_returns.parse::().unwrap(); } #[test] fn byte_order_mark() { let string = "\u{feff}foo"; let tokens = string.parse::().unwrap(); match tokens.into_iter().next().unwrap() { TokenTree::Ident(ident) => assert_eq!(ident, "foo"), _ => unreachable!(), } let string = "foo\u{feff}"; string.parse::().unwrap_err(); } #[cfg(span_locations)] fn create_span() -> proc_macro2::Span { let tts: TokenStream = "1".parse().unwrap(); match tts.into_iter().next().unwrap() { TokenTree::Literal(literal) => literal.span(), _ => unreachable!(), } } #[cfg(span_locations)] #[test] fn test_invalidate_current_thread_spans() { let actual = format!("{:#?}", create_span()); assert_eq!(actual, "bytes(1..2)"); let actual = format!("{:#?}", create_span()); assert_eq!(actual, "bytes(3..4)"); proc_macro2::extra::invalidate_current_thread_spans(); let actual = format!("{:#?}", create_span()); // Test that span offsets have been reset after the call // to invalidate_current_thread_spans() assert_eq!(actual, "bytes(1..2)"); } #[cfg(span_locations)] #[test] #[should_panic(expected = "Invalid span with no related FileInfo!")] fn test_use_span_after_invalidation() { let span = create_span(); proc_macro2::extra::invalidate_current_thread_spans(); span.source_text(); }