mod never_type; mod coercion; use std::fmt::Write; use std::sync::Arc; use hir_def::{ body::BodySourceMap, db::DefDatabase, nameres::CrateDefMap, AssocItemId, DefWithBodyId, LocalModuleId, Lookup, ModuleDefId, }; use hir_expand::Source; use insta::assert_snapshot; use ra_db::{fixture::WithFixture, salsa::Database, FilePosition, SourceDatabase}; use ra_syntax::{ algo, ast::{self, AstNode}, }; use test_utils::covers; use crate::{db::HirDatabase, display::HirDisplay, test_db::TestDB, InferenceResult}; // These tests compare the inference results for all expressions in a file // against snapshots of the expected results using insta. Use cargo-insta to // update the snapshots. #[test] fn cfg_impl_block() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:foo cfg:test use foo::S as T; struct S; #[cfg(test)] impl S { fn foo1(&self) -> i32 { 0 } } #[cfg(not(test))] impl S { fn foo2(&self) -> i32 { 0 } } fn test() { let t = (S.foo1(), S.foo2(), T.foo3(), T.foo4()); t<|>; } //- /foo.rs crate:foo struct S; #[cfg(not(test))] impl S { fn foo3(&self) -> i32 { 0 } } #[cfg(test)] impl S { fn foo4(&self) -> i32 { 0 } } "#, ); assert_eq!("(i32, {unknown}, i32, {unknown})", type_at_pos(&db, pos)); } #[test] fn infer_await() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:std struct IntFuture; impl Future for IntFuture { type Output = u64; } fn test() { let r = IntFuture; let v = r.await; v<|>; } //- /std.rs crate:std #[prelude_import] use future::*; mod future { trait Future { type Output; } } "#, ); assert_eq!("u64", type_at_pos(&db, pos)); } #[test] fn infer_box() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:std fn test() { let x = box 1; let t = (x, box x, box &1, box [1]); t<|>; } //- /std.rs crate:std #[prelude_import] use prelude::*; mod prelude {} mod boxed { pub struct Box { inner: *mut T, } } "#, ); assert_eq!("(Box, Box>, Box<&i32>, Box<[i32;_]>)", type_at_pos(&db, pos)); } #[test] fn infer_adt_self() { let (db, pos) = TestDB::with_position( r#" //- /main.rs enum Nat { Succ(Self), Demo(Nat), Zero } fn test() { let foo: Nat = Nat::Zero; if let Nat::Succ(x) = foo { x<|> } } "#, ); assert_eq!("Nat", type_at_pos(&db, pos)); } #[test] fn infer_try() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:std fn test() { let r: Result = Result::Ok(1); let v = r?; v<|>; } //- /std.rs crate:std #[prelude_import] use ops::*; mod ops { trait Try { type Ok; type Error; } } #[prelude_import] use result::*; mod result { enum Result { Ok(O), Err(E) } impl crate::ops::Try for Result { type Ok = O; type Error = E; } } "#, ); assert_eq!("i32", type_at_pos(&db, pos)); } #[test] fn infer_for_loop() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:std use std::collections::Vec; fn test() { let v = Vec::new(); v.push("foo"); for x in v { x<|>; } } //- /std.rs crate:std #[prelude_import] use iter::*; mod iter { trait IntoIterator { type Item; } } mod collections { struct Vec {} impl Vec { fn new() -> Self { Vec {} } fn push(&mut self, t: T) { } } impl crate::iter::IntoIterator for Vec { type Item=T; } } "#, ); assert_eq!("&str", type_at_pos(&db, pos)); } #[test] fn infer_while_let() { let (db, pos) = TestDB::with_position( r#" //- /main.rs enum Option { Some(T), None } fn test() { let foo: Option = None; while let Option::Some(x) = foo { <|>x } } "#, ); assert_eq!("f32", type_at_pos(&db, pos)); } #[test] fn infer_basics() { assert_snapshot!( infer(r#" fn test(a: u32, b: isize, c: !, d: &str) { a; b; c; d; 1usize; 1isize; "test"; 1.0f32; }"#), @r###" [9; 10) 'a': u32 [17; 18) 'b': isize [27; 28) 'c': ! [33; 34) 'd': &str [42; 121) '{ ...f32; }': ! [48; 49) 'a': u32 [55; 56) 'b': isize [62; 63) 'c': ! [69; 70) 'd': &str [76; 82) '1usize': usize [88; 94) '1isize': isize [100; 106) '"test"': &str [112; 118) '1.0f32': f32 "### ); } #[test] fn infer_let() { assert_snapshot!( infer(r#" fn test() { let a = 1isize; let b: usize = 1; let c = b; let d: u32; let e; let f: i32 = e; } "#), @r###" [11; 118) '{ ...= e; }': () [21; 22) 'a': isize [25; 31) '1isize': isize [41; 42) 'b': usize [52; 53) '1': usize [63; 64) 'c': usize [67; 68) 'b': usize [78; 79) 'd': u32 [94; 95) 'e': i32 [105; 106) 'f': i32 [114; 115) 'e': i32 "### ); } #[test] fn infer_paths() { assert_snapshot!( infer(r#" fn a() -> u32 { 1 } mod b { fn c() -> u32 { 1 } } fn test() { a(); b::c(); } "#), @r###" [15; 20) '{ 1 }': u32 [17; 18) '1': u32 [48; 53) '{ 1 }': u32 [50; 51) '1': u32 [67; 91) '{ ...c(); }': () [73; 74) 'a': fn a() -> u32 [73; 76) 'a()': u32 [82; 86) 'b::c': fn c() -> u32 [82; 88) 'b::c()': u32 "### ); } #[test] fn infer_path_type() { assert_snapshot!( infer(r#" struct S; impl S { fn foo() -> i32 { 1 } } fn test() { S::foo(); ::foo(); } "#), @r###" [41; 46) '{ 1 }': i32 [43; 44) '1': i32 [60; 93) '{ ...o(); }': () [66; 72) 'S::foo': fn foo() -> i32 [66; 74) 'S::foo()': i32 [80; 88) '::foo': fn foo() -> i32 [80; 90) '::foo()': i32 "### ); } #[test] fn infer_slice_method() { assert_snapshot!( infer(r#" #[lang = "slice"] impl [T] { fn foo(&self) -> T { loop {} } } #[lang = "slice_alloc"] impl [T] {} fn test() { <[_]>::foo(b"foo"); } "#), @r###" [45; 49) 'self': &[T] [56; 79) '{ ... }': T [66; 73) 'loop {}': ! [71; 73) '{}': () [133; 160) '{ ...o"); }': () [139; 149) '<[_]>::foo': fn foo(&[T]) -> T [139; 157) '<[_]>:..."foo")': u8 [150; 156) 'b"foo"': &[u8] "### ); } #[test] fn infer_struct() { assert_snapshot!( infer(r#" struct A { b: B, c: C, } struct B; struct C(usize); fn test() { let c = C(1); B; let a: A = A { b: B, c: C(1) }; a.b; a.c; } "#), @r###" [72; 154) '{ ...a.c; }': () [82; 83) 'c': C [86; 87) 'C': C(usize) -> C [86; 90) 'C(1)': C [88; 89) '1': usize [96; 97) 'B': B [107; 108) 'a': A [114; 133) 'A { b:...C(1) }': A [121; 122) 'B': B [127; 128) 'C': C(usize) -> C [127; 131) 'C(1)': C [129; 130) '1': usize [139; 140) 'a': A [139; 142) 'a.b': B [148; 149) 'a': A [148; 151) 'a.c': C "### ); } #[test] fn infer_enum() { assert_snapshot!( infer(r#" enum E { V1 { field: u32 }, V2 } fn test() { E::V1 { field: 1 }; E::V2; }"#), @r###" [48; 82) '{ E:...:V2; }': () [52; 70) 'E::V1 ...d: 1 }': E [67; 68) '1': u32 [74; 79) 'E::V2': E "### ); } #[test] fn infer_refs() { assert_snapshot!( infer(r#" fn test(a: &u32, b: &mut u32, c: *const u32, d: *mut u32) { a; *a; &a; &mut a; b; *b; &b; c; *c; d; *d; } "#), @r###" [9; 10) 'a': &u32 [18; 19) 'b': &mut u32 [31; 32) 'c': *const u32 [46; 47) 'd': *mut u32 [59; 150) '{ ... *d; }': () [65; 66) 'a': &u32 [72; 74) '*a': u32 [73; 74) 'a': &u32 [80; 82) '&a': &&u32 [81; 82) 'a': &u32 [88; 94) '&mut a': &mut &u32 [93; 94) 'a': &u32 [100; 101) 'b': &mut u32 [107; 109) '*b': u32 [108; 109) 'b': &mut u32 [115; 117) '&b': &&mut u32 [116; 117) 'b': &mut u32 [123; 124) 'c': *const u32 [130; 132) '*c': u32 [131; 132) 'c': *const u32 [138; 139) 'd': *mut u32 [145; 147) '*d': u32 [146; 147) 'd': *mut u32 "### ); } #[test] fn infer_literals() { assert_snapshot!( infer(r##" fn test() { 5i32; 5f32; 5f64; "hello"; b"bytes"; 'c'; b'b'; 3.14; 5000; false; true; r#" //! doc // non-doc mod foo {} "#; br#"yolo"#; } "##), @r###" [11; 221) '{ ...o"#; }': () [17; 21) '5i32': i32 [27; 31) '5f32': f32 [37; 41) '5f64': f64 [47; 54) '"hello"': &str [60; 68) 'b"bytes"': &[u8] [74; 77) ''c'': char [83; 87) 'b'b'': u8 [93; 97) '3.14': f64 [103; 107) '5000': i32 [113; 118) 'false': bool [124; 128) 'true': bool [134; 202) 'r#" ... "#': &str [208; 218) 'br#"yolo"#': &[u8] "### ); } #[test] fn infer_unary_op() { assert_snapshot!( infer(r#" enum SomeType {} fn test(x: SomeType) { let b = false; let c = !b; let a = 100; let d: i128 = -a; let e = -100; let f = !!!true; let g = !42; let h = !10u32; let j = !a; -3.14; !3; -x; !x; -"hello"; !"hello"; } "#), @r###" [27; 28) 'x': SomeType [40; 272) '{ ...lo"; }': () [50; 51) 'b': bool [54; 59) 'false': bool [69; 70) 'c': bool [73; 75) '!b': bool [74; 75) 'b': bool [85; 86) 'a': i128 [89; 92) '100': i128 [102; 103) 'd': i128 [112; 114) '-a': i128 [113; 114) 'a': i128 [124; 125) 'e': i32 [128; 132) '-100': i32 [129; 132) '100': i32 [142; 143) 'f': bool [146; 153) '!!!true': bool [147; 153) '!!true': bool [148; 153) '!true': bool [149; 153) 'true': bool [163; 164) 'g': i32 [167; 170) '!42': i32 [168; 170) '42': i32 [180; 181) 'h': u32 [184; 190) '!10u32': u32 [185; 190) '10u32': u32 [200; 201) 'j': i128 [204; 206) '!a': i128 [205; 206) 'a': i128 [212; 217) '-3.14': f64 [213; 217) '3.14': f64 [223; 225) '!3': i32 [224; 225) '3': i32 [231; 233) '-x': {unknown} [232; 233) 'x': SomeType [239; 241) '!x': {unknown} [240; 241) 'x': SomeType [247; 255) '-"hello"': {unknown} [248; 255) '"hello"': &str [261; 269) '!"hello"': {unknown} [262; 269) '"hello"': &str "### ); } #[test] fn infer_backwards() { assert_snapshot!( infer(r#" fn takes_u32(x: u32) {} struct S { i32_field: i32 } fn test() -> &mut &f64 { let a = unknown_function(); takes_u32(a); let b = unknown_function(); S { i32_field: b }; let c = unknown_function(); &mut &c } "#), @r###" [14; 15) 'x': u32 [22; 24) '{}': () [78; 231) '{ ...t &c }': &mut &f64 [88; 89) 'a': u32 [92; 108) 'unknow...nction': {unknown} [92; 110) 'unknow...tion()': u32 [116; 125) 'takes_u32': fn takes_u32(u32) -> () [116; 128) 'takes_u32(a)': () [126; 127) 'a': u32 [138; 139) 'b': i32 [142; 158) 'unknow...nction': {unknown} [142; 160) 'unknow...tion()': i32 [166; 184) 'S { i3...d: b }': S [181; 182) 'b': i32 [194; 195) 'c': f64 [198; 214) 'unknow...nction': {unknown} [198; 216) 'unknow...tion()': f64 [222; 229) '&mut &c': &mut &f64 [227; 229) '&c': &f64 [228; 229) 'c': f64 "### ); } #[test] fn infer_self() { assert_snapshot!( infer(r#" struct S; impl S { fn test(&self) { self; } fn test2(self: &Self) { self; } fn test3() -> Self { S {} } fn test4() -> Self { Self {} } } "#), @r###" [34; 38) 'self': &S [40; 61) '{ ... }': () [50; 54) 'self': &S [75; 79) 'self': &S [88; 109) '{ ... }': () [98; 102) 'self': &S [133; 153) '{ ... }': S [143; 147) 'S {}': S [177; 200) '{ ... }': S [187; 194) 'Self {}': S "### ); } #[test] fn infer_binary_op() { assert_snapshot!( infer(r#" fn f(x: bool) -> i32 { 0i32 } fn test() -> bool { let x = a && b; let y = true || false; let z = x == y; let t = x != y; let minus_forty: isize = -40isize; let h = minus_forty <= CONST_2; let c = f(z || y) + 5; let d = b; let g = minus_forty ^= i; let ten: usize = 10; let ten_is_eleven = ten == some_num; ten < 3 } "#), @r###" [6; 7) 'x': bool [22; 34) '{ 0i32 }': i32 [28; 32) '0i32': i32 [54; 370) '{ ... < 3 }': bool [64; 65) 'x': bool [68; 69) 'a': bool [68; 74) 'a && b': bool [73; 74) 'b': bool [84; 85) 'y': bool [88; 92) 'true': bool [88; 101) 'true || false': bool [96; 101) 'false': bool [111; 112) 'z': bool [115; 116) 'x': bool [115; 121) 'x == y': bool [120; 121) 'y': bool [131; 132) 't': bool [135; 136) 'x': bool [135; 141) 'x != y': bool [140; 141) 'y': bool [151; 162) 'minus_forty': isize [172; 180) '-40isize': isize [173; 180) '40isize': isize [190; 191) 'h': bool [194; 205) 'minus_forty': isize [194; 216) 'minus_...ONST_2': bool [209; 216) 'CONST_2': isize [226; 227) 'c': i32 [230; 231) 'f': fn f(bool) -> i32 [230; 239) 'f(z || y)': i32 [230; 243) 'f(z || y) + 5': i32 [232; 233) 'z': bool [232; 238) 'z || y': bool [237; 238) 'y': bool [242; 243) '5': i32 [253; 254) 'd': {unknown} [257; 258) 'b': {unknown} [268; 269) 'g': () [272; 283) 'minus_forty': isize [272; 288) 'minus_...y ^= i': () [287; 288) 'i': isize [298; 301) 'ten': usize [311; 313) '10': usize [323; 336) 'ten_is_eleven': bool [339; 342) 'ten': usize [339; 354) 'ten == some_num': bool [346; 354) 'some_num': usize [361; 364) 'ten': usize [361; 368) 'ten < 3': bool [367; 368) '3': usize "### ); } #[test] fn infer_field_autoderef() { assert_snapshot!( infer(r#" struct A { b: B, } struct B; fn test1(a: A) { let a1 = a; a1.b; let a2 = &a; a2.b; let a3 = &mut a; a3.b; let a4 = &&&&&&&a; a4.b; let a5 = &mut &&mut &&mut a; a5.b; } fn test2(a1: *const A, a2: *mut A) { a1.b; a2.b; } "#), @r###" [44; 45) 'a': A [50; 213) '{ ...5.b; }': () [60; 62) 'a1': A [65; 66) 'a': A [72; 74) 'a1': A [72; 76) 'a1.b': B [86; 88) 'a2': &A [91; 93) '&a': &A [92; 93) 'a': A [99; 101) 'a2': &A [99; 103) 'a2.b': B [113; 115) 'a3': &mut A [118; 124) '&mut a': &mut A [123; 124) 'a': A [130; 132) 'a3': &mut A [130; 134) 'a3.b': B [144; 146) 'a4': &&&&&&&A [149; 157) '&&&&&&&a': &&&&&&&A [150; 157) '&&&&&&a': &&&&&&A [151; 157) '&&&&&a': &&&&&A [152; 157) '&&&&a': &&&&A [153; 157) '&&&a': &&&A [154; 157) '&&a': &&A [155; 157) '&a': &A [156; 157) 'a': A [163; 165) 'a4': &&&&&&&A [163; 167) 'a4.b': B [177; 179) 'a5': &mut &&mut &&mut A [182; 200) '&mut &...&mut a': &mut &&mut &&mut A [187; 200) '&&mut &&mut a': &&mut &&mut A [188; 200) '&mut &&mut a': &mut &&mut A [193; 200) '&&mut a': &&mut A [194; 200) '&mut a': &mut A [199; 200) 'a': A [206; 208) 'a5': &mut &&mut &&mut A [206; 210) 'a5.b': B [224; 226) 'a1': *const A [238; 240) 'a2': *mut A [250; 273) '{ ...2.b; }': () [256; 258) 'a1': *const A [256; 260) 'a1.b': B [266; 268) 'a2': *mut A [266; 270) 'a2.b': B "### ); } #[test] fn infer_argument_autoderef() { assert_snapshot!( infer(r#" #[lang = "deref"] pub trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct A(T); impl A { fn foo(&self) -> &T { &self.0 } } struct B(T); impl Deref for B { type Target = T; fn deref(&self) -> &Self::Target { &self.0 } } fn test() { let t = A::foo(&&B(B(A(42)))); } "#), @r###" [68; 72) 'self': &Self [139; 143) 'self': &A [151; 174) '{ ... }': &T [161; 168) '&self.0': &T [162; 166) 'self': &A [162; 168) 'self.0': T [255; 259) 'self': &B [278; 301) '{ ... }': &T [288; 295) '&self.0': &T [289; 293) 'self': &B [289; 295) 'self.0': T [315; 353) '{ ...))); }': () [325; 326) 't': &i32 [329; 335) 'A::foo': fn foo(&A) -> &T [329; 350) 'A::foo...42))))': &i32 [336; 349) '&&B(B(A(42)))': &&B>> [337; 349) '&B(B(A(42)))': &B>> [338; 339) 'B': B>>(T) -> B [338; 349) 'B(B(A(42)))': B>> [340; 341) 'B': B>(T) -> B [340; 348) 'B(A(42))': B> [342; 343) 'A': A(T) -> A [342; 347) 'A(42)': A [344; 346) '42': i32 "### ); } #[test] fn infer_method_argument_autoderef() { assert_snapshot!( infer(r#" #[lang = "deref"] pub trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct A(*mut T); impl A { fn foo(&self, x: &A) -> &T { &*x.0 } } struct B(T); impl Deref for B { type Target = T; fn deref(&self) -> &Self::Target { &self.0 } } fn test(a: A) { let t = A(0 as *mut _).foo(&&B(B(a))); } "#), @r###" [68; 72) 'self': &Self [144; 148) 'self': &A [150; 151) 'x': &A [166; 187) '{ ... }': &T [176; 181) '&*x.0': &T [177; 181) '*x.0': T [178; 179) 'x': &A [178; 181) 'x.0': *mut T [268; 272) 'self': &B [291; 314) '{ ... }': &T [301; 308) '&self.0': &T [302; 306) 'self': &B [302; 308) 'self.0': T [326; 327) 'a': A [337; 383) '{ ...))); }': () [347; 348) 't': &i32 [351; 352) 'A': A(*mut T) -> A [351; 365) 'A(0 as *mut _)': A [351; 380) 'A(0 as...B(a)))': &i32 [353; 354) '0': i32 [353; 364) '0 as *mut _': *mut i32 [370; 379) '&&B(B(a))': &&B>> [371; 379) '&B(B(a))': &B>> [372; 373) 'B': B>>(T) -> B [372; 379) 'B(B(a))': B>> [374; 375) 'B': B>(T) -> B [374; 378) 'B(a)': B> [376; 377) 'a': A "### ); } #[test] fn bug_484() { assert_snapshot!( infer(r#" fn test() { let x = if true {}; } "#), @r###" [11; 37) '{ l... {}; }': () [20; 21) 'x': () [24; 34) 'if true {}': () [27; 31) 'true': bool [32; 34) '{}': () "### ); } #[test] fn infer_in_elseif() { assert_snapshot!( infer(r#" struct Foo { field: i32 } fn main(foo: Foo) { if true { } else if false { foo.field } } "#), @r###" [35; 38) 'foo': Foo [45; 109) '{ ... } }': () [51; 107) 'if tru... }': () [54; 58) 'true': bool [59; 67) '{ }': () [73; 107) 'if fal... }': () [76; 81) 'false': bool [82; 107) '{ ... }': i32 [92; 95) 'foo': Foo [92; 101) 'foo.field': i32 "### ) } #[test] fn infer_if_match_with_return() { assert_snapshot!( infer(r#" fn foo() { let _x1 = if true { 1 } else { return; }; let _x2 = if true { 2 } else { return }; let _x3 = match true { true => 3, _ => { return; } }; let _x4 = match true { true => 4, _ => return }; }"#), @r###" [10; 323) '{ ... }; }': () [20; 23) '_x1': i32 [26; 80) 'if tru... }': i32 [29; 33) 'true': bool [34; 51) '{ ... }': i32 [44; 45) '1': i32 [57; 80) '{ ... }': ! [67; 73) 'return': ! [90; 93) '_x2': i32 [96; 149) 'if tru... }': i32 [99; 103) 'true': bool [104; 121) '{ ... }': i32 [114; 115) '2': i32 [127; 149) '{ ... }': ! [137; 143) 'return': ! [159; 162) '_x3': i32 [165; 247) 'match ... }': i32 [171; 175) 'true': bool [186; 190) 'true': bool [194; 195) '3': i32 [205; 206) '_': bool [210; 241) '{ ... }': ! [224; 230) 'return': ! [257; 260) '_x4': i32 [263; 320) 'match ... }': i32 [269; 273) 'true': bool [284; 288) 'true': bool [292; 293) '4': i32 [303; 304) '_': bool [308; 314) 'return': ! "### ) } #[test] fn infer_inherent_method() { assert_snapshot!( infer(r#" struct A; impl A { fn foo(self, x: u32) -> i32 {} } mod b { impl super::A { fn bar(&self, x: u64) -> i64 {} } } fn test(a: A) { a.foo(1); (&a).bar(1); a.bar(1); } "#), @r###" [32; 36) 'self': A [38; 39) 'x': u32 [53; 55) '{}': () [103; 107) 'self': &A [109; 110) 'x': u64 [124; 126) '{}': () [144; 145) 'a': A [150; 198) '{ ...(1); }': () [156; 157) 'a': A [156; 164) 'a.foo(1)': i32 [162; 163) '1': u32 [170; 181) '(&a).bar(1)': i64 [171; 173) '&a': &A [172; 173) 'a': A [179; 180) '1': u64 [187; 188) 'a': A [187; 195) 'a.bar(1)': i64 [193; 194) '1': u64 "### ); } #[test] fn infer_inherent_method_str() { assert_snapshot!( infer(r#" #[lang = "str"] impl str { fn foo(&self) -> i32 {} } fn test() { "foo".foo(); } "#), @r###" [40; 44) 'self': &str [53; 55) '{}': () [69; 89) '{ ...o(); }': () [75; 80) '"foo"': &str [75; 86) '"foo".foo()': i32 "### ); } #[test] fn infer_tuple() { assert_snapshot!( infer(r#" fn test(x: &str, y: isize) { let a: (u32, &str) = (1, "a"); let b = (a, x); let c = (y, x); let d = (c, x); let e = (1, "e"); let f = (e, "d"); } "#), @r###" [9; 10) 'x': &str [18; 19) 'y': isize [28; 170) '{ ...d"); }': () [38; 39) 'a': (u32, &str) [55; 63) '(1, "a")': (u32, &str) [56; 57) '1': u32 [59; 62) '"a"': &str [73; 74) 'b': ((u32, &str), &str) [77; 83) '(a, x)': ((u32, &str), &str) [78; 79) 'a': (u32, &str) [81; 82) 'x': &str [93; 94) 'c': (isize, &str) [97; 103) '(y, x)': (isize, &str) [98; 99) 'y': isize [101; 102) 'x': &str [113; 114) 'd': ((isize, &str), &str) [117; 123) '(c, x)': ((isize, &str), &str) [118; 119) 'c': (isize, &str) [121; 122) 'x': &str [133; 134) 'e': (i32, &str) [137; 145) '(1, "e")': (i32, &str) [138; 139) '1': i32 [141; 144) '"e"': &str [155; 156) 'f': ((i32, &str), &str) [159; 167) '(e, "d")': ((i32, &str), &str) [160; 161) 'e': (i32, &str) [163; 166) '"d"': &str "### ); } #[test] fn infer_array() { assert_snapshot!( infer(r#" fn test(x: &str, y: isize) { let a = [x]; let b = [a, a]; let c = [b, b]; let d = [y, 1, 2, 3]; let d = [1, y, 2, 3]; let e = [y]; let f = [d, d]; let g = [e, e]; let h = [1, 2]; let i = ["a", "b"]; let b = [a, ["b"]]; let x: [u8; 0] = []; } "#), @r###" [9; 10) 'x': &str [18; 19) 'y': isize [28; 293) '{ ... []; }': () [38; 39) 'a': [&str;_] [42; 45) '[x]': [&str;_] [43; 44) 'x': &str [55; 56) 'b': [[&str;_];_] [59; 65) '[a, a]': [[&str;_];_] [60; 61) 'a': [&str;_] [63; 64) 'a': [&str;_] [75; 76) 'c': [[[&str;_];_];_] [79; 85) '[b, b]': [[[&str;_];_];_] [80; 81) 'b': [[&str;_];_] [83; 84) 'b': [[&str;_];_] [96; 97) 'd': [isize;_] [100; 112) '[y, 1, 2, 3]': [isize;_] [101; 102) 'y': isize [104; 105) '1': isize [107; 108) '2': isize [110; 111) '3': isize [122; 123) 'd': [isize;_] [126; 138) '[1, y, 2, 3]': [isize;_] [127; 128) '1': isize [130; 131) 'y': isize [133; 134) '2': isize [136; 137) '3': isize [148; 149) 'e': [isize;_] [152; 155) '[y]': [isize;_] [153; 154) 'y': isize [165; 166) 'f': [[isize;_];_] [169; 175) '[d, d]': [[isize;_];_] [170; 171) 'd': [isize;_] [173; 174) 'd': [isize;_] [185; 186) 'g': [[isize;_];_] [189; 195) '[e, e]': [[isize;_];_] [190; 191) 'e': [isize;_] [193; 194) 'e': [isize;_] [206; 207) 'h': [i32;_] [210; 216) '[1, 2]': [i32;_] [211; 212) '1': i32 [214; 215) '2': i32 [226; 227) 'i': [&str;_] [230; 240) '["a", "b"]': [&str;_] [231; 234) '"a"': &str [236; 239) '"b"': &str [251; 252) 'b': [[&str;_];_] [255; 265) '[a, ["b"]]': [[&str;_];_] [256; 257) 'a': [&str;_] [259; 264) '["b"]': [&str;_] [260; 263) '"b"': &str [275; 276) 'x': [u8;_] [288; 290) '[]': [u8;_] "### ); } #[test] fn infer_pattern() { assert_snapshot!( infer(r#" fn test(x: &i32) { let y = x; let &z = x; let a = z; let (c, d) = (1, "hello"); for (e, f) in some_iter { let g = e; } if let [val] = opt { let h = val; } let lambda = |a: u64, b, c: i32| { a + b; c }; let ref ref_to_x = x; let mut mut_x = x; let ref mut mut_ref_to_x = x; let k = mut_ref_to_x; } "#), @r###" [9; 10) 'x': &i32 [18; 369) '{ ...o_x; }': () [28; 29) 'y': &i32 [32; 33) 'x': &i32 [43; 45) '&z': &i32 [44; 45) 'z': i32 [48; 49) 'x': &i32 [59; 60) 'a': i32 [63; 64) 'z': i32 [74; 80) '(c, d)': (i32, &str) [75; 76) 'c': i32 [78; 79) 'd': &str [83; 95) '(1, "hello")': (i32, &str) [84; 85) '1': i32 [87; 94) '"hello"': &str [102; 152) 'for (e... }': () [106; 112) '(e, f)': ({unknown}, {unknown}) [107; 108) 'e': {unknown} [110; 111) 'f': {unknown} [116; 125) 'some_iter': {unknown} [126; 152) '{ ... }': () [140; 141) 'g': {unknown} [144; 145) 'e': {unknown} [158; 205) 'if let... }': () [165; 170) '[val]': {unknown} [173; 176) 'opt': {unknown} [177; 205) '{ ... }': () [191; 192) 'h': {unknown} [195; 198) 'val': {unknown} [215; 221) 'lambda': |u64, u64, i32| -> i32 [224; 256) '|a: u6...b; c }': |u64, u64, i32| -> i32 [225; 226) 'a': u64 [233; 234) 'b': u64 [236; 237) 'c': i32 [244; 256) '{ a + b; c }': i32 [246; 247) 'a': u64 [246; 251) 'a + b': u64 [250; 251) 'b': u64 [253; 254) 'c': i32 [267; 279) 'ref ref_to_x': &&i32 [282; 283) 'x': &i32 [293; 302) 'mut mut_x': &i32 [305; 306) 'x': &i32 [316; 336) 'ref mu...f_to_x': &mut &i32 [339; 340) 'x': &i32 [350; 351) 'k': &mut &i32 [354; 366) 'mut_ref_to_x': &mut &i32 "### ); } #[test] fn infer_pattern_match_ergonomics() { assert_snapshot!( infer(r#" struct A(T); fn test() { let A(n) = &A(1); let A(n) = &mut A(1); } "#), @r###" [28; 79) '{ ...(1); }': () [38; 42) 'A(n)': A [40; 41) 'n': &i32 [45; 50) '&A(1)': &A [46; 47) 'A': A(T) -> A [46; 50) 'A(1)': A [48; 49) '1': i32 [60; 64) 'A(n)': A [62; 63) 'n': &mut i32 [67; 76) '&mut A(1)': &mut A [72; 73) 'A': A(T) -> A [72; 76) 'A(1)': A [74; 75) '1': i32 "### ); } #[test] fn infer_pattern_match_ergonomics_ref() { covers!(match_ergonomics_ref); assert_snapshot!( infer(r#" fn test() { let v = &(1, &2); let (_, &w) = v; } "#), @r###" [11; 57) '{ ...= v; }': () [21; 22) 'v': &(i32, &i32) [25; 33) '&(1, &2)': &(i32, &i32) [26; 33) '(1, &2)': (i32, &i32) [27; 28) '1': i32 [30; 32) '&2': &i32 [31; 32) '2': i32 [43; 50) '(_, &w)': (i32, &i32) [44; 45) '_': i32 [47; 49) '&w': &i32 [48; 49) 'w': i32 [53; 54) 'v': &(i32, &i32) "### ); } #[test] fn infer_adt_pattern() { assert_snapshot!( infer(r#" enum E { A { x: usize }, B } struct S(u32, E); fn test() { let e = E::A { x: 3 }; let S(y, z) = foo; let E::A { x: new_var } = e; match e { E::A { x } => x, E::B if foo => 1, E::B => 10, }; let ref d @ E::A { .. } = e; d; } "#), @r###" [68; 289) '{ ... d; }': () [78; 79) 'e': E [82; 95) 'E::A { x: 3 }': E [92; 93) '3': usize [106; 113) 'S(y, z)': S [108; 109) 'y': u32 [111; 112) 'z': E [116; 119) 'foo': S [129; 148) 'E::A {..._var }': E [139; 146) 'new_var': usize [151; 152) 'e': E [159; 245) 'match ... }': usize [165; 166) 'e': E [177; 187) 'E::A { x }': E [184; 185) 'x': usize [191; 192) 'x': usize [202; 206) 'E::B': E [210; 213) 'foo': bool [217; 218) '1': usize [228; 232) 'E::B': E [236; 238) '10': usize [256; 275) 'ref d ...{ .. }': &E [264; 275) 'E::A { .. }': E [278; 279) 'e': E [285; 286) 'd': &E "### ); } #[test] fn infer_struct_generics() { assert_snapshot!( infer(r#" struct A { x: T, } fn test(a1: A, i: i32) { a1.x; let a2 = A { x: i }; a2.x; let a3 = A:: { x: 1 }; a3.x; } "#), @r###" [36; 38) 'a1': A [48; 49) 'i': i32 [56; 147) '{ ...3.x; }': () [62; 64) 'a1': A [62; 66) 'a1.x': u32 [76; 78) 'a2': A [81; 91) 'A { x: i }': A [88; 89) 'i': i32 [97; 99) 'a2': A [97; 101) 'a2.x': i32 [111; 113) 'a3': A [116; 134) 'A:: [131; 132) '1': i128 [140; 142) 'a3': A [140; 144) 'a3.x': i128 "### ); } #[test] fn infer_tuple_struct_generics() { assert_snapshot!( infer(r#" struct A(T); enum Option { Some(T), None } use Option::*; fn test() { A(42); A(42u128); Some("x"); Option::Some("x"); None; let x: Option = None; } "#), @r###" [76; 184) '{ ...one; }': () [82; 83) 'A': A(T) -> A [82; 87) 'A(42)': A [84; 86) '42': i32 [93; 94) 'A': A(T) -> A [93; 102) 'A(42u128)': A [95; 101) '42u128': u128 [108; 112) 'Some': Some<&str>(T) -> Option [108; 117) 'Some("x")': Option<&str> [113; 116) '"x"': &str [123; 135) 'Option::Some': Some<&str>(T) -> Option [123; 140) 'Option...e("x")': Option<&str> [136; 139) '"x"': &str [146; 150) 'None': Option<{unknown}> [160; 161) 'x': Option [177; 181) 'None': Option "### ); } #[test] fn infer_generics_in_patterns() { assert_snapshot!( infer(r#" struct A { x: T, } enum Option { Some(T), None, } fn test(a1: A, o: Option) { let A { x: x2 } = a1; let A:: { x: x3 } = A { x: 1 }; match o { Option::Some(t) => t, _ => 1, }; } "#), @r###" [79; 81) 'a1': A [91; 92) 'o': Option [107; 244) '{ ... }; }': () [117; 128) 'A { x: x2 }': A [124; 126) 'x2': u32 [131; 133) 'a1': A [143; 161) 'A:: [157; 159) 'x3': i64 [164; 174) 'A { x: 1 }': A [171; 172) '1': i64 [180; 241) 'match ... }': u64 [186; 187) 'o': Option [198; 213) 'Option::Some(t)': Option [211; 212) 't': u64 [217; 218) 't': u64 [228; 229) '_': Option [233; 234) '1': u64 "### ); } #[test] fn infer_function_generics() { assert_snapshot!( infer(r#" fn id(t: T) -> T { t } fn test() { id(1u32); id::(1); let x: u64 = id(1); } "#), @r###" [10; 11) 't': T [21; 26) '{ t }': T [23; 24) 't': T [38; 98) '{ ...(1); }': () [44; 46) 'id': fn id(T) -> T [44; 52) 'id(1u32)': u32 [47; 51) '1u32': u32 [58; 68) 'id::': fn id(T) -> T [58; 71) 'id::(1)': i128 [69; 70) '1': i128 [81; 82) 'x': u64 [90; 92) 'id': fn id(T) -> T [90; 95) 'id(1)': u64 [93; 94) '1': u64 "### ); } #[test] fn infer_impl_generics() { assert_snapshot!( infer(r#" struct A { x: T1, y: T2, } impl A { fn x(self) -> X { self.x } fn y(self) -> Y { self.y } fn z(self, t: T) -> (X, Y, T) { (self.x, self.y, t) } } fn test() -> i128 { let a = A { x: 1u64, y: 1i64 }; a.x(); a.y(); a.z(1i128); a.z::(1); } "#), @r###" [74; 78) 'self': A [85; 107) '{ ... }': X [95; 99) 'self': A [95; 101) 'self.x': X [117; 121) 'self': A [128; 150) '{ ... }': Y [138; 142) 'self': A [138; 144) 'self.y': Y [163; 167) 'self': A [169; 170) 't': T [188; 223) '{ ... }': (X, Y, T) [198; 217) '(self.....y, t)': (X, Y, T) [199; 203) 'self': A [199; 205) 'self.x': X [207; 211) 'self': A [207; 213) 'self.y': Y [215; 216) 't': T [245; 342) '{ ...(1); }': () [255; 256) 'a': A [259; 281) 'A { x:...1i64 }': A [266; 270) '1u64': u64 [275; 279) '1i64': i64 [287; 288) 'a': A [287; 292) 'a.x()': u64 [298; 299) 'a': A [298; 303) 'a.y()': i64 [309; 310) 'a': A [309; 319) 'a.z(1i128)': (u64, i64, i128) [313; 318) '1i128': i128 [325; 326) 'a': A [325; 339) 'a.z::(1)': (u64, i64, u128) [337; 338) '1': u128 "### ); } #[test] fn infer_impl_generics_with_autoderef() { assert_snapshot!( infer(r#" enum Option { Some(T), None, } impl Option { fn as_ref(&self) -> Option<&T> {} } fn test(o: Option) { (&o).as_ref(); o.as_ref(); } "#), @r###" [78; 82) 'self': &Option [98; 100) '{}': () [111; 112) 'o': Option [127; 165) '{ ...f(); }': () [133; 146) '(&o).as_ref()': Option<&u32> [134; 136) '&o': &Option [135; 136) 'o': Option [152; 153) 'o': Option [152; 162) 'o.as_ref()': Option<&u32> "### ); } #[test] fn infer_generic_chain() { assert_snapshot!( infer(r#" struct A { x: T, } impl A { fn x(self) -> T2 { self.x } } fn id(t: T) -> T { t } fn test() -> i128 { let x = 1; let y = id(x); let a = A { x: id(y) }; let z = id(a.x); let b = A { x: z }; b.x() } "#), @r###" [53; 57) 'self': A [65; 87) '{ ... }': T2 [75; 79) 'self': A [75; 81) 'self.x': T2 [99; 100) 't': T [110; 115) '{ t }': T [112; 113) 't': T [135; 261) '{ ....x() }': i128 [146; 147) 'x': i128 [150; 151) '1': i128 [162; 163) 'y': i128 [166; 168) 'id': fn id(T) -> T [166; 171) 'id(x)': i128 [169; 170) 'x': i128 [182; 183) 'a': A [186; 200) 'A { x: id(y) }': A [193; 195) 'id': fn id(T) -> T [193; 198) 'id(y)': i128 [196; 197) 'y': i128 [211; 212) 'z': i128 [215; 217) 'id': fn id(T) -> T [215; 222) 'id(a.x)': i128 [218; 219) 'a': A [218; 221) 'a.x': i128 [233; 234) 'b': A [237; 247) 'A { x: z }': A [244; 245) 'z': i128 [254; 255) 'b': A [254; 259) 'b.x()': i128 "### ); } #[test] fn infer_associated_const() { assert_snapshot!( infer(r#" struct Struct; impl Struct { const FOO: u32 = 1; } enum Enum {} impl Enum { const BAR: u32 = 2; } trait Trait { const ID: u32; } struct TraitTest; impl Trait for TraitTest { const ID: u32 = 5; } fn test() { let x = Struct::FOO; let y = Enum::BAR; let z = TraitTest::ID; } "#), @r###" [52; 53) '1': u32 [105; 106) '2': u32 [213; 214) '5': u32 [229; 307) '{ ...:ID; }': () [239; 240) 'x': u32 [243; 254) 'Struct::FOO': u32 [264; 265) 'y': u32 [268; 277) 'Enum::BAR': u32 [287; 288) 'z': u32 [291; 304) 'TraitTest::ID': u32 "### ); } #[test] fn infer_associated_method_struct() { assert_snapshot!( infer(r#" struct A { x: u32 } impl A { fn new() -> A { A { x: 0 } } } fn test() { let a = A::new(); a.x; } "#), @r###" [49; 75) '{ ... }': A [59; 69) 'A { x: 0 }': A [66; 67) '0': u32 [88; 122) '{ ...a.x; }': () [98; 99) 'a': A [102; 108) 'A::new': fn new() -> A [102; 110) 'A::new()': A [116; 117) 'a': A [116; 119) 'a.x': u32 "### ); } #[test] fn infer_associated_method_enum() { assert_snapshot!( infer(r#" enum A { B, C } impl A { pub fn b() -> A { A::B } pub fn c() -> A { A::C } } fn test() { let a = A::b(); a; let c = A::c(); c; } "#), @r###" [47; 67) '{ ... }': A [57; 61) 'A::B': A [88; 108) '{ ... }': A [98; 102) 'A::C': A [121; 178) '{ ... c; }': () [131; 132) 'a': A [135; 139) 'A::b': fn b() -> A [135; 141) 'A::b()': A [147; 148) 'a': A [158; 159) 'c': A [162; 166) 'A::c': fn c() -> A [162; 168) 'A::c()': A [174; 175) 'c': A "### ); } #[test] fn infer_associated_method_with_modules() { assert_snapshot!( infer(r#" mod a { struct A; impl A { pub fn thing() -> A { A {} }} } mod b { struct B; impl B { pub fn thing() -> u32 { 99 }} mod c { struct C; impl C { pub fn thing() -> C { C {} }} } } use b::c; fn test() { let x = a::A::thing(); let y = b::B::thing(); let z = c::C::thing(); } "#), @r###" [56; 64) '{ A {} }': A [58; 62) 'A {}': A [126; 132) '{ 99 }': u32 [128; 130) '99': u32 [202; 210) '{ C {} }': C [204; 208) 'C {}': C [241; 325) '{ ...g(); }': () [251; 252) 'x': A [255; 266) 'a::A::thing': fn thing() -> A [255; 268) 'a::A::thing()': A [278; 279) 'y': u32 [282; 293) 'b::B::thing': fn thing() -> u32 [282; 295) 'b::B::thing()': u32 [305; 306) 'z': C [309; 320) 'c::C::thing': fn thing() -> C [309; 322) 'c::C::thing()': C "### ); } #[test] fn infer_associated_method_generics() { assert_snapshot!( infer(r#" struct Gen { val: T } impl Gen { pub fn make(val: T) -> Gen { Gen { val } } } fn test() { let a = Gen::make(0u32); } "#), @r###" [64; 67) 'val': T [82; 109) '{ ... }': Gen [92; 103) 'Gen { val }': Gen [98; 101) 'val': T [123; 155) '{ ...32); }': () [133; 134) 'a': Gen [137; 146) 'Gen::make': fn make(T) -> Gen [137; 152) 'Gen::make(0u32)': Gen [147; 151) '0u32': u32 "### ); } #[test] fn infer_associated_method_generics_with_default_param() { assert_snapshot!( infer(r#" struct Gen { val: T } impl Gen { pub fn make() -> Gen { loop { } } } fn test() { let a = Gen::make(); } "#), @r###" [80; 104) '{ ... }': Gen [90; 98) 'loop { }': ! [95; 98) '{ }': () [118; 146) '{ ...e(); }': () [128; 129) 'a': Gen [132; 141) 'Gen::make': fn make() -> Gen [132; 143) 'Gen::make()': Gen "### ); } #[test] fn infer_associated_method_generics_with_default_tuple_param() { let t = type_at( r#" //- /main.rs struct Gen { val: T } impl Gen { pub fn make() -> Gen { loop { } } } fn test() { let a = Gen::make(); a.val<|>; } "#, ); assert_eq!(t, "()"); } #[test] fn infer_associated_method_generics_without_args() { assert_snapshot!( infer(r#" struct Gen { val: T } impl Gen { pub fn make() -> Gen { loop { } } } fn test() { let a = Gen::::make(); } "#), @r###" [76; 100) '{ ... }': Gen [86; 94) 'loop { }': ! [91; 94) '{ }': () [114; 149) '{ ...e(); }': () [124; 125) 'a': Gen [128; 144) 'Gen::<...::make': fn make() -> Gen [128; 146) 'Gen::<...make()': Gen "### ); } #[test] fn infer_associated_method_generics_2_type_params_without_args() { assert_snapshot!( infer(r#" struct Gen { val: T, val2: U, } impl Gen { pub fn make() -> Gen { loop { } } } fn test() { let a = Gen::::make(); } "#), @r###" [102; 126) '{ ... }': Gen [112; 120) 'loop { }': ! [117; 120) '{ }': () [140; 180) '{ ...e(); }': () [150; 151) 'a': Gen [154; 175) 'Gen::<...::make': fn make() -> Gen [154; 177) 'Gen::<...make()': Gen "### ); } #[test] fn infer_type_alias() { assert_snapshot!( infer(r#" struct A { x: X, y: Y } type Foo = A; type Bar = A; type Baz = A; fn test(x: Foo, y: Bar<&str>, z: Baz) { x.x; x.y; y.x; y.y; z.x; z.y; } "#), @r###" [116; 117) 'x': A [124; 125) 'y': A<&str, u128> [138; 139) 'z': A [154; 211) '{ ...z.y; }': () [160; 161) 'x': A [160; 163) 'x.x': u32 [169; 170) 'x': A [169; 172) 'x.y': i128 [178; 179) 'y': A<&str, u128> [178; 181) 'y.x': &str [187; 188) 'y': A<&str, u128> [187; 190) 'y.y': u128 [196; 197) 'z': A [196; 199) 'z.x': u8 [205; 206) 'z': A [205; 208) 'z.y': i8 "### ) } #[test] #[should_panic] // we currently can't handle this fn recursive_type_alias() { assert_snapshot!( infer(r#" struct A {} type Foo = Foo; type Bar = A; fn test(x: Foo) {} "#), @"" ) } #[test] fn no_panic_on_field_of_enum() { assert_snapshot!( infer(r#" enum X {} fn test(x: X) { x.some_field; } "#), @r###" [20; 21) 'x': X [26; 47) '{ ...eld; }': () [32; 33) 'x': X [32; 44) 'x.some_field': {unknown} "### ); } #[test] fn bug_585() { assert_snapshot!( infer(r#" fn test() { X {}; match x { A::B {} => (), A::Y() => (), } } "#), @r###" [11; 89) '{ ... } }': () [17; 21) 'X {}': {unknown} [27; 87) 'match ... }': () [33; 34) 'x': {unknown} [45; 52) 'A::B {}': {unknown} [56; 58) '()': () [68; 74) 'A::Y()': {unknown} [78; 80) '()': () "### ); } #[test] fn bug_651() { assert_snapshot!( infer(r#" fn quux() { let y = 92; 1 + y; } "#), @r###" [11; 41) '{ ...+ y; }': () [21; 22) 'y': i32 [25; 27) '92': i32 [33; 34) '1': i32 [33; 38) '1 + y': i32 [37; 38) 'y': i32 "### ); } #[test] fn recursive_vars() { covers!(type_var_cycles_resolve_completely); covers!(type_var_cycles_resolve_as_possible); assert_snapshot!( infer(r#" fn test() { let y = unknown; [y, &y]; } "#), @r###" [11; 48) '{ ...&y]; }': () [21; 22) 'y': &{unknown} [25; 32) 'unknown': &{unknown} [38; 45) '[y, &y]': [&&{unknown};_] [39; 40) 'y': &{unknown} [42; 44) '&y': &&{unknown} [43; 44) 'y': &{unknown} "### ); } #[test] fn recursive_vars_2() { covers!(type_var_cycles_resolve_completely); covers!(type_var_cycles_resolve_as_possible); assert_snapshot!( infer(r#" fn test() { let x = unknown; let y = unknown; [(x, y), (&y, &x)]; } "#), @r###" [11; 80) '{ ...x)]; }': () [21; 22) 'x': &&{unknown} [25; 32) 'unknown': &&{unknown} [42; 43) 'y': &&{unknown} [46; 53) 'unknown': &&{unknown} [59; 77) '[(x, y..., &x)]': [(&&&{unknown}, &&&{unknown});_] [60; 66) '(x, y)': (&&&{unknown}, &&&{unknown}) [61; 62) 'x': &&{unknown} [64; 65) 'y': &&{unknown} [68; 76) '(&y, &x)': (&&&{unknown}, &&&{unknown}) [69; 71) '&y': &&&{unknown} [70; 71) 'y': &&{unknown} [73; 75) '&x': &&&{unknown} [74; 75) 'x': &&{unknown} "### ); } #[test] fn infer_type_param() { assert_snapshot!( infer(r#" fn id(x: T) -> T { x } fn clone(x: &T) -> T { *x } fn test() { let y = 10u32; id(y); let x: bool = clone(z); id::(1); } "#), @r###" [10; 11) 'x': T [21; 30) '{ x }': T [27; 28) 'x': T [44; 45) 'x': &T [56; 66) '{ *x }': T [62; 64) '*x': T [63; 64) 'x': &T [78; 158) '{ ...(1); }': () [88; 89) 'y': u32 [92; 97) '10u32': u32 [103; 105) 'id': fn id(T) -> T [103; 108) 'id(y)': u32 [106; 107) 'y': u32 [118; 119) 'x': bool [128; 133) 'clone': fn clone(&T) -> T [128; 136) 'clone(z)': bool [134; 135) 'z': &bool [142; 152) 'id::': fn id(T) -> T [142; 155) 'id::(1)': i128 [153; 154) '1': i128 "### ); } #[test] fn infer_std_crash_1() { // caused stack overflow, taken from std assert_snapshot!( infer(r#" enum Maybe { Real(T), Fake, } fn write() { match something_unknown { Maybe::Real(ref mut something) => (), } } "#), @r###" [54; 139) '{ ... } }': () [60; 137) 'match ... }': () [66; 83) 'someth...nknown': Maybe<{unknown}> [94; 124) 'Maybe:...thing)': Maybe<{unknown}> [106; 123) 'ref mu...ething': &mut {unknown} [128; 130) '()': () "### ); } #[test] fn infer_std_crash_2() { covers!(type_var_resolves_to_int_var); // caused "equating two type variables, ...", taken from std assert_snapshot!( infer(r#" fn test_line_buffer() { &[0, b'\n', 1, b'\n']; } "#), @r###" [23; 53) '{ ...n']; }': () [29; 50) '&[0, b...b'\n']': &[u8;_] [30; 50) '[0, b'...b'\n']': [u8;_] [31; 32) '0': u8 [34; 39) 'b'\n'': u8 [41; 42) '1': u8 [44; 49) 'b'\n'': u8 "### ); } #[test] fn infer_std_crash_3() { // taken from rustc assert_snapshot!( infer(r#" pub fn compute() { match nope!() { SizeSkeleton::Pointer { non_zero: true, tail } => {} } } "#), @r###" [18; 108) '{ ... } }': () [24; 106) 'match ... }': () [30; 37) 'nope!()': {unknown} [48; 94) 'SizeSk...tail }': {unknown} [82; 86) 'true': {unknown} [88; 92) 'tail': {unknown} [98; 100) '{}': () "### ); } #[test] fn infer_std_crash_4() { // taken from rustc assert_snapshot!( infer(r#" pub fn primitive_type() { match *self { BorrowedRef { type_: Primitive(p), ..} => {}, } } "#), @r###" [25; 106) '{ ... } }': () [31; 104) 'match ... }': () [37; 42) '*self': {unknown} [38; 42) 'self': {unknown} [53; 91) 'Borrow...), ..}': {unknown} [74; 86) 'Primitive(p)': {unknown} [84; 85) 'p': {unknown} [95; 97) '{}': () "### ); } #[test] fn infer_std_crash_5() { // taken from rustc assert_snapshot!( infer(r#" fn extra_compiler_flags() { for content in doesnt_matter { let name = if doesnt_matter { first } else { &content }; let content = if ICE_REPORT_COMPILER_FLAGS_STRIP_VALUE.contains(&name) { name } else { content }; } } "#), @r###" [27; 323) '{ ... } }': () [33; 321) 'for co... }': () [37; 44) 'content': &{unknown} [48; 61) 'doesnt_matter': {unknown} [62; 321) '{ ... }': () [76; 80) 'name': &&{unknown} [83; 167) 'if doe... }': &&{unknown} [86; 99) 'doesnt_matter': bool [100; 129) '{ ... }': &&{unknown} [114; 119) 'first': &&{unknown} [135; 167) '{ ... }': &&{unknown} [149; 157) '&content': &&{unknown} [150; 157) 'content': &{unknown} [182; 189) 'content': &{unknown} [192; 314) 'if ICE... }': &{unknown} [195; 232) 'ICE_RE..._VALUE': {unknown} [195; 248) 'ICE_RE...&name)': bool [242; 247) '&name': &&&{unknown} [243; 247) 'name': &&{unknown} [249; 277) '{ ... }': &&{unknown} [263; 267) 'name': &&{unknown} [283; 314) '{ ... }': &{unknown} [297; 304) 'content': &{unknown} "### ); } #[test] fn infer_nested_generics_crash() { // another crash found typechecking rustc assert_snapshot!( infer(r#" struct Canonical { value: V, } struct QueryResponse { value: V, } fn test(query_response: Canonical>) { &query_response.value; } "#), @r###" [92; 106) 'query_response': Canonical> [137; 167) '{ ...lue; }': () [143; 164) '&query....value': &QueryResponse [144; 158) 'query_response': Canonical> [144; 164) 'query_....value': QueryResponse "### ); } #[test] fn bug_1030() { assert_snapshot!(infer(r#" struct HashSet; struct FxHasher; type FxHashSet = HashSet; impl HashSet { fn default() -> HashSet {} } pub fn main_loop() { FxHashSet::default(); } "#), @r###" [144; 146) '{}': () [169; 198) '{ ...t(); }': () [175; 193) 'FxHash...efault': fn default<{unknown}, FxHasher>() -> HashSet [175; 195) 'FxHash...ault()': HashSet<{unknown}, FxHasher> "### ); } #[test] fn cross_crate_associated_method_call() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:other_crate fn test() { let x = other_crate::foo::S::thing(); x<|>; } //- /lib.rs crate:other_crate mod foo { struct S; impl S { fn thing() -> i128 {} } } "#, ); assert_eq!("i128", type_at_pos(&db, pos)); } #[test] fn infer_const() { assert_snapshot!( infer(r#" struct Foo; impl Foo { const ASSOC_CONST: u32 = 0; } const GLOBAL_CONST: u32 = 101; fn test() { const LOCAL_CONST: u32 = 99; let x = LOCAL_CONST; let z = GLOBAL_CONST; let id = Foo::ASSOC_CONST; } "#), @r###" [49; 50) '0': u32 [80; 83) '101': u32 [95; 213) '{ ...NST; }': () [138; 139) 'x': {unknown} [142; 153) 'LOCAL_CONST': {unknown} [163; 164) 'z': u32 [167; 179) 'GLOBAL_CONST': u32 [189; 191) 'id': u32 [194; 210) 'Foo::A..._CONST': u32 "### ); } #[test] fn infer_static() { assert_snapshot!( infer(r#" static GLOBAL_STATIC: u32 = 101; static mut GLOBAL_STATIC_MUT: u32 = 101; fn test() { static LOCAL_STATIC: u32 = 99; static mut LOCAL_STATIC_MUT: u32 = 99; let x = LOCAL_STATIC; let y = LOCAL_STATIC_MUT; let z = GLOBAL_STATIC; let w = GLOBAL_STATIC_MUT; } "#), @r###" [29; 32) '101': u32 [70; 73) '101': u32 [85; 280) '{ ...MUT; }': () [173; 174) 'x': {unknown} [177; 189) 'LOCAL_STATIC': {unknown} [199; 200) 'y': {unknown} [203; 219) 'LOCAL_...IC_MUT': {unknown} [229; 230) 'z': u32 [233; 246) 'GLOBAL_STATIC': u32 [256; 257) 'w': u32 [260; 277) 'GLOBAL...IC_MUT': u32 "### ); } #[test] fn infer_trait_method_simple() { // the trait implementation is intentionally incomplete -- it shouldn't matter assert_snapshot!( infer(r#" trait Trait1 { fn method(&self) -> u32; } struct S1; impl Trait1 for S1 {} trait Trait2 { fn method(&self) -> i128; } struct S2; impl Trait2 for S2 {} fn test() { S1.method(); // -> u32 S2.method(); // -> i128 } "#), @r###" [31; 35) 'self': &Self [110; 114) 'self': &Self [170; 228) '{ ...i128 }': () [176; 178) 'S1': S1 [176; 187) 'S1.method()': u32 [203; 205) 'S2': S2 [203; 214) 'S2.method()': i128 "### ); } #[test] fn infer_trait_method_scoped() { // the trait implementation is intentionally incomplete -- it shouldn't matter assert_snapshot!( infer(r#" struct S; mod foo { pub trait Trait1 { fn method(&self) -> u32; } impl Trait1 for super::S {} } mod bar { pub trait Trait2 { fn method(&self) -> i128; } impl Trait2 for super::S {} } mod foo_test { use super::S; use super::foo::Trait1; fn test() { S.method(); // -> u32 } } mod bar_test { use super::S; use super::bar::Trait2; fn test() { S.method(); // -> i128 } } "#), @r###" [63; 67) 'self': &Self [169; 173) 'self': &Self [300; 337) '{ ... }': () [310; 311) 'S': S [310; 320) 'S.method()': u32 [416; 454) '{ ... }': () [426; 427) 'S': S [426; 436) 'S.method()': i128 "### ); } #[test] fn infer_trait_method_generic_1() { // the trait implementation is intentionally incomplete -- it shouldn't matter assert_snapshot!( infer(r#" trait Trait { fn method(&self) -> T; } struct S; impl Trait for S {} fn test() { S.method(); } "#), @r###" [33; 37) 'self': &Self [92; 111) '{ ...d(); }': () [98; 99) 'S': S [98; 108) 'S.method()': u32 "### ); } #[test] fn infer_trait_method_generic_more_params() { // the trait implementation is intentionally incomplete -- it shouldn't matter assert_snapshot!( infer(r#" trait Trait { fn method1(&self) -> (T1, T2, T3); fn method2(&self) -> (T3, T2, T1); } struct S1; impl Trait for S1 {} struct S2; impl Trait for S2 {} fn test() { S1.method1(); // u8, u16, u32 S1.method2(); // u32, u16, u8 S2.method1(); // i8, i16, {unknown} S2.method2(); // {unknown}, i16, i8 } "#), @r###" [43; 47) 'self': &Self [82; 86) 'self': &Self [210; 361) '{ ..., i8 }': () [216; 218) 'S1': S1 [216; 228) 'S1.method1()': (u8, u16, u32) [250; 252) 'S1': S1 [250; 262) 'S1.method2()': (u32, u16, u8) [284; 286) 'S2': S2 [284; 296) 'S2.method1()': (i8, i16, {unknown}) [324; 326) 'S2': S2 [324; 336) 'S2.method2()': ({unknown}, i16, i8) "### ); } #[test] fn infer_trait_method_generic_2() { // the trait implementation is intentionally incomplete -- it shouldn't matter assert_snapshot!( infer(r#" trait Trait { fn method(&self) -> T; } struct S(T); impl Trait for S {} fn test() { S(1u32).method(); } "#), @r###" [33; 37) 'self': &Self [102; 127) '{ ...d(); }': () [108; 109) 'S': S(T) -> S [108; 115) 'S(1u32)': S [108; 124) 'S(1u32...thod()': u32 [110; 114) '1u32': u32 "### ); } #[test] fn infer_trait_assoc_method() { assert_snapshot!( infer(r#" trait Default { fn default() -> Self; } struct S; impl Default for S {} fn test() { let s1: S = Default::default(); let s2 = S::default(); let s3 = ::default(); } "#), @r###" [87; 193) '{ ...t(); }': () [97; 99) 's1': S [105; 121) 'Defaul...efault': fn default() -> Self [105; 123) 'Defaul...ault()': S [133; 135) 's2': S [138; 148) 'S::default': fn default() -> Self [138; 150) 'S::default()': S [160; 162) 's3': S [165; 188) '() -> Self [165; 190) ' { fn make() -> T; } struct S; impl Trait for S {} struct G; impl Trait for G {} fn test() { let a = S::make(); let b = G::::make(); let c: f64 = G::make(); } "#), @r###" [127; 211) '{ ...e(); }': () [137; 138) 'a': u32 [141; 148) 'S::make': fn make() -> T [141; 150) 'S::make()': u32 [160; 161) 'b': u64 [164; 178) 'G::::make': fn make, u64>() -> T [164; 180) 'G::, f64>() -> T [199; 208) 'G::make()': f64 "### ); } #[test] fn infer_trait_assoc_method_generics_2() { assert_snapshot!( infer(r#" trait Trait { fn make() -> (T, U); } struct S; impl Trait for S {} struct G; impl Trait for G {} fn test() { let a = S::make::(); let b: (_, i64) = S::make(); let c = G::::make::(); let d: (u32, _) = G::make::(); let e: (u32, i64) = G::make(); } "#), @r###" [135; 313) '{ ...e(); }': () [145; 146) 'a': (u32, i64) [149; 163) 'S::make::': fn make() -> (T, U) [149; 165) 'S::mak...i64>()': (u32, i64) [175; 176) 'b': (u32, i64) [189; 196) 'S::make': fn make() -> (T, U) [189; 198) 'S::make()': (u32, i64) [208; 209) 'c': (u32, i64) [212; 233) 'G::': fn make, u32, i64>() -> (T, U) [212; 235) 'G::()': (u32, i64) [245; 246) 'd': (u32, i64) [259; 273) 'G::make::': fn make, u32, i64>() -> (T, U) [259; 275) 'G::mak...i64>()': (u32, i64) [285; 286) 'e': (u32, i64) [301; 308) 'G::make': fn make, u32, i64>() -> (T, U) [301; 310) 'G::make()': (u32, i64) "### ); } #[test] fn infer_trait_assoc_method_generics_3() { assert_snapshot!( infer(r#" trait Trait { fn make() -> (Self, T); } struct S; impl Trait for S {} fn test() { let a = S::make(); } "#), @r###" [101; 127) '{ ...e(); }': () [111; 112) 'a': (S, i64) [115; 122) 'S::make': fn make, i64>() -> (Self, T) [115; 124) 'S::make()': (S, i64) "### ); } #[test] fn infer_trait_assoc_method_generics_4() { assert_snapshot!( infer(r#" trait Trait { fn make() -> (Self, T); } struct S; impl Trait for S {} impl Trait for S {} fn test() { let a: (S, _) = S::make(); let b: (_, i32) = S::make(); } "#), @r###" [131; 203) '{ ...e(); }': () [141; 142) 'a': (S, i64) [158; 165) 'S::make': fn make, i64>() -> (Self, T) [158; 167) 'S::make()': (S, i64) [177; 178) 'b': (S, i32) [191; 198) 'S::make': fn make, i32>() -> (Self, T) [191; 200) 'S::make()': (S, i32) "### ); } #[test] fn infer_trait_assoc_method_generics_5() { assert_snapshot!( infer(r#" trait Trait { fn make() -> (Self, T, U); } struct S; impl Trait for S {} fn test() { let a = >::make::(); let b: (S, _, _) = Trait::::make::(); } "#), @r###" [107; 211) '{ ...>(); }': () [117; 118) 'a': (S, i64, u8) [121; 150) '': fn make, i64, u8>() -> (Self, T, U) [121; 152) '()': (S, i64, u8) [162; 163) 'b': (S, i64, u8) [182; 206) 'Trait:...::': fn make, i64, u8>() -> (Self, T, U) [182; 208) 'Trait:...()': (S, i64, u8) "### ); } #[test] fn infer_from_bound_1() { assert_snapshot!( infer(r#" trait Trait {} struct S(T); impl Trait for S {} fn foo>(t: T) {} fn test() { let s = S(unknown); foo(s); } "#), @r###" [86; 87) 't': T [92; 94) '{}': () [105; 144) '{ ...(s); }': () [115; 116) 's': S [119; 120) 'S': S(T) -> S [119; 129) 'S(unknown)': S [121; 128) 'unknown': u32 [135; 138) 'foo': fn foo>(T) -> () [135; 141) 'foo(s)': () [139; 140) 's': S "### ); } #[test] fn infer_from_bound_2() { assert_snapshot!( infer(r#" trait Trait {} struct S(T); impl Trait for S {} fn foo>(t: T) -> U {} fn test() { let s = S(unknown); let x: u32 = foo(s); } "#), @r###" [87; 88) 't': T [98; 100) '{}': () [111; 163) '{ ...(s); }': () [121; 122) 's': S [125; 126) 'S': S(T) -> S [125; 135) 'S(unknown)': S [127; 134) 'unknown': u32 [145; 146) 'x': u32 [154; 157) 'foo': fn foo>(T) -> U [154; 160) 'foo(s)': u32 [158; 159) 's': S "### ); } #[test] fn infer_call_trait_method_on_generic_param_1() { assert_snapshot!( infer(r#" trait Trait { fn method(&self) -> u32; } fn test(t: T) { t.method(); } "#), @r###" [30; 34) 'self': &Self [64; 65) 't': T [70; 89) '{ ...d(); }': () [76; 77) 't': T [76; 86) 't.method()': u32 "### ); } #[test] fn infer_call_trait_method_on_generic_param_2() { assert_snapshot!( infer(r#" trait Trait { fn method(&self) -> T; } fn test>(t: T) { t.method(); } "#), @r###" [33; 37) 'self': &Self [71; 72) 't': T [77; 96) '{ ...d(); }': () [83; 84) 't': T [83; 93) 't.method()': [missing name] "### ); } #[test] fn infer_with_multiple_trait_impls() { assert_snapshot!( infer(r#" trait Into { fn into(self) -> T; } struct S; impl Into for S {} impl Into for S {} fn test() { let x: u32 = S.into(); let y: u64 = S.into(); let z = Into::::into(S); } "#), @r###" [29; 33) 'self': Self [111; 202) '{ ...(S); }': () [121; 122) 'x': u32 [130; 131) 'S': S [130; 138) 'S.into()': u32 [148; 149) 'y': u64 [157; 158) 'S': S [157; 165) 'S.into()': u64 [175; 176) 'z': u64 [179; 196) 'Into::...::into': fn into(Self) -> T [179; 199) 'Into::...nto(S)': u64 [197; 198) 'S': S "### ); } #[test] fn infer_project_associated_type() { // y, z, a don't yet work because of https://github.com/rust-lang/chalk/issues/234 assert_snapshot!( infer(r#" trait Iterable { type Item; } struct S; impl Iterable for S { type Item = u32; } fn test() { let x: ::Item = 1; let y: ::Item = no_matter; let z: T::Item = no_matter; let a: ::Item = no_matter; } "#), @r###" [108; 261) '{ ...ter; }': () [118; 119) 'x': u32 [145; 146) '1': u32 [156; 157) 'y': {unknown} [183; 192) 'no_matter': {unknown} [202; 203) 'z': {unknown} [215; 224) 'no_matter': {unknown} [234; 235) 'a': {unknown} [249; 258) 'no_matter': {unknown} "### ); } #[test] fn infer_return_associated_type() { assert_snapshot!( infer(r#" trait Iterable { type Item; } struct S; impl Iterable for S { type Item = u32; } fn foo1(t: T) -> T::Item {} fn foo2(t: T) -> ::Item {} fn foo3(t: T) -> ::Item {} fn test() { let x = foo1(S); let y = foo2(S); let z = foo3(S); } "#), @r###" [106; 107) 't': T [123; 125) '{}': () [147; 148) 't': T [178; 180) '{}': () [202; 203) 't': T [221; 223) '{}': () [234; 300) '{ ...(S); }': () [244; 245) 'x': u32 [248; 252) 'foo1': fn foo1(T) -> ::Item [248; 255) 'foo1(S)': u32 [253; 254) 'S': S [265; 266) 'y': u32 [269; 273) 'foo2': fn foo2(T) -> ::Item [269; 276) 'foo2(S)': u32 [274; 275) 'S': S [286; 287) 'z': u32 [290; 294) 'foo3': fn foo3(T) -> ::Item [290; 297) 'foo3(S)': u32 [295; 296) 'S': S "### ); } #[test] fn infer_associated_type_bound() { assert_snapshot!( infer(r#" trait Iterable { type Item; } fn test>() { let y: T::Item = unknown; } "#), @r###" [67; 100) '{ ...own; }': () [77; 78) 'y': {unknown} [90; 97) 'unknown': {unknown} "### ); } #[test] fn infer_const_body() { assert_snapshot!( infer(r#" const A: u32 = 1 + 1; static B: u64 = { let x = 1; x }; "#), @r###" [16; 17) '1': u32 [16; 21) '1 + 1': u32 [20; 21) '1': u32 [39; 55) '{ let ...1; x }': u64 [45; 46) 'x': u64 [49; 50) '1': u64 [52; 53) 'x': u64 "### ); } #[test] fn tuple_struct_fields() { assert_snapshot!( infer(r#" struct S(i32, u64); fn test() -> u64 { let a = S(4, 6); let b = a.0; a.1 } "#), @r###" [38; 87) '{ ... a.1 }': u64 [48; 49) 'a': S [52; 53) 'S': S(i32, u64) -> S [52; 59) 'S(4, 6)': S [54; 55) '4': i32 [57; 58) '6': u64 [69; 70) 'b': i32 [73; 74) 'a': S [73; 76) 'a.0': i32 [82; 83) 'a': S [82; 85) 'a.1': u64 "### ); } #[test] fn tuple_struct_with_fn() { assert_snapshot!( infer(r#" struct S(fn(u32) -> u64); fn test() -> u64 { let a = S(|i| 2*i); let b = a.0(4); a.0(2) } "#), @r###" [44; 102) '{ ...0(2) }': u64 [54; 55) 'a': S [58; 59) 'S': S(fn(u32) -> u64) -> S [58; 68) 'S(|i| 2*i)': S [60; 67) '|i| 2*i': |i32| -> i32 [61; 62) 'i': i32 [64; 65) '2': i32 [64; 67) '2*i': i32 [66; 67) 'i': i32 [78; 79) 'b': u64 [82; 83) 'a': S [82; 85) 'a.0': fn(u32) -> u64 [82; 88) 'a.0(4)': u64 [86; 87) '4': u32 [94; 95) 'a': S [94; 97) 'a.0': fn(u32) -> u64 [94; 100) 'a.0(2)': u64 [98; 99) '2': u32 "### ); } #[test] fn indexing_arrays() { assert_snapshot!( infer("fn main() { &mut [9][2]; }"), @r###" [10; 26) '{ &mut...[2]; }': () [12; 23) '&mut [9][2]': &mut {unknown} [17; 20) '[9]': [i32;_] [17; 23) '[9][2]': {unknown} [18; 19) '9': i32 [21; 22) '2': i32 "### ) } #[test] fn infer_macros_expanded() { assert_snapshot!( infer(r#" struct Foo(Vec); macro_rules! foo { ($($item:expr),*) => { { Foo(vec![$($item,)*]) } }; } fn main() { let x = foo!(1,2); } "#), @r###" ![0; 17) '{Foo(v...,2,])}': Foo ![1; 4) 'Foo': Foo({unknown}) -> Foo ![1; 16) 'Foo(vec![1,2,])': Foo ![5; 15) 'vec![1,2,]': {unknown} [156; 182) '{ ...,2); }': () [166; 167) 'x': Foo "### ); } #[test] fn infer_legacy_textual_scoped_macros_expanded() { assert_snapshot!( infer(r#" struct Foo(Vec); #[macro_use] mod m { macro_rules! foo { ($($item:expr),*) => { { Foo(vec![$($item,)*]) } }; } } fn main() { let x = foo!(1,2); let y = crate::foo!(1,2); } "#), @r###" ![0; 17) '{Foo(v...,2,])}': Foo ![1; 4) 'Foo': Foo({unknown}) -> Foo ![1; 16) 'Foo(vec![1,2,])': Foo ![5; 15) 'vec![1,2,]': {unknown} [195; 251) '{ ...,2); }': () [205; 206) 'x': Foo [228; 229) 'y': {unknown} [232; 248) 'crate:...!(1,2)': {unknown} "### ); } #[test] fn infer_path_qualified_macros_expanded() { assert_snapshot!( infer(r#" #[macro_export] macro_rules! foo { () => { 42i32 } } mod m { pub use super::foo as bar; } fn main() { let x = crate::foo!(); let y = m::bar!(); } "#), @r###" ![0; 5) '42i32': i32 ![0; 5) '42i32': i32 [111; 164) '{ ...!(); }': () [121; 122) 'x': i32 [148; 149) 'y': i32 "### ); } #[test] fn infer_type_value_macro_having_same_name() { assert_snapshot!( infer(r#" #[macro_export] macro_rules! foo { () => { mod foo { pub use super::foo; } }; ($x:tt) => { $x }; } foo!(); fn foo() { let foo = foo::foo!(42i32); } "#), @r###" ![0; 5) '42i32': i32 [171; 206) '{ ...32); }': () [181; 184) 'foo': i32 "### ); } #[test] fn processes_impls_generated_by_macros() { let t = type_at( r#" //- /main.rs macro_rules! m { ($ident:ident) => (impl Trait for $ident {}) } trait Trait { fn foo(self) -> u128 {} } struct S; m!(S); fn test() { S.foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[test] fn infer_macro_with_dollar_crate_is_correct_in_expr() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:foo fn test() { let x = (foo::foo!(1), foo::foo!(2)); x<|>; } //- /lib.rs crate:foo #[macro_export] macro_rules! foo { (1) => { $crate::bar!() }; (2) => { 1 + $crate::baz() }; } #[macro_export] macro_rules! bar { () => { 42 } } pub fn baz() -> usize { 31usize } "#, ); assert_eq!("(i32, usize)", type_at_pos(&db, pos)); } #[ignore] #[test] fn method_resolution_trait_before_autoref() { let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl S { fn foo(&self) -> i8 { 0 } } impl Trait for S { fn foo(self) -> u128 { 0 } } fn test() { S.foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[ignore] #[test] fn method_resolution_by_value_before_autoref() { let t = type_at( r#" //- /main.rs trait Clone { fn clone(&self) -> Self; } struct S; impl Clone for S {} impl Clone for &S {} fn test() { (S.clone(), (&S).clone(), (&&S).clone())<|>; } "#, ); assert_eq!(t, "(S, S, &S)"); } #[test] fn method_resolution_trait_before_autoderef() { let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl S { fn foo(self) -> i8 { 0 } } impl Trait for &S { fn foo(self) -> u128 { 0 } } fn test() { (&S).foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[test] fn method_resolution_impl_before_trait() { let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl S { fn foo(self) -> i8 { 0 } } impl Trait for S { fn foo(self) -> u128 { 0 } } fn test() { S.foo()<|>; } "#, ); assert_eq!(t, "i8"); } #[test] fn method_resolution_trait_autoderef() { let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl Trait for S { fn foo(self) -> u128 { 0 } } fn test() { (&S).foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[test] fn method_resolution_trait_from_prelude() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:other_crate struct S; impl Clone for S {} fn test() { S.clone()<|>; } //- /lib.rs crate:other_crate #[prelude_import] use foo::*; mod foo { trait Clone { fn clone(&self) -> Self; } } "#, ); assert_eq!("S", type_at_pos(&db, pos)); } #[test] fn method_resolution_where_clause_for_unknown_trait() { // The blanket impl shouldn't apply because we can't even resolve UnknownTrait let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl Trait for T where T: UnknownTrait {} fn test() { (&S).foo()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn method_resolution_where_clause_not_met() { // The blanket impl shouldn't apply because we can't prove S: Clone let t = type_at( r#" //- /main.rs trait Clone {} trait Trait { fn foo(self) -> u128; } struct S; impl Trait for T where T: Clone {} fn test() { (&S).foo()<|>; } "#, ); // This is also to make sure that we don't resolve to the foo method just // because that's the only method named foo we can find, which would make // the below tests not work assert_eq!(t, "{unknown}"); } #[test] fn method_resolution_where_clause_inline_not_met() { // The blanket impl shouldn't apply because we can't prove S: Clone let t = type_at( r#" //- /main.rs trait Clone {} trait Trait { fn foo(self) -> u128; } struct S; impl Trait for T {} fn test() { (&S).foo()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn method_resolution_where_clause_1() { let t = type_at( r#" //- /main.rs trait Clone {} trait Trait { fn foo(self) -> u128; } struct S; impl Clone for S {} impl Trait for T where T: Clone {} fn test() { S.foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[test] fn method_resolution_where_clause_2() { let t = type_at( r#" //- /main.rs trait Into { fn into(self) -> T; } trait From { fn from(other: T) -> Self; } struct S1; struct S2; impl From for S1 {} impl Into for T where U: From {} fn test() { S2.into()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn method_resolution_where_clause_inline() { let t = type_at( r#" //- /main.rs trait Into { fn into(self) -> T; } trait From { fn from(other: T) -> Self; } struct S1; struct S2; impl From for S1 {} impl> Into for T {} fn test() { S2.into()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn method_resolution_encountering_fn_type() { type_at( r#" //- /main.rs fn foo() {} trait FnOnce { fn call(self); } fn test() { foo.call()<|>; } "#, ); } #[test] fn method_resolution_slow() { // this can get quite slow if we set the solver size limit too high let t = type_at( r#" //- /main.rs trait SendX {} struct S1; impl SendX for S1 {} struct S2; impl SendX for S2 {} struct U1; trait Trait { fn method(self); } struct X1 {} impl SendX for X1 where A: SendX, B: SendX {} struct S {} trait FnX {} impl Trait for S where C: FnX, B: SendX {} fn test() { (S {}).method()<|>; } "#, ); assert_eq!(t, "()"); } #[test] fn shadowing_primitive() { let t = type_at( r#" //- /main.rs struct i32; struct Foo; impl i32 { fn foo(&self) -> Foo { Foo } } fn main() { let x: i32 = i32; x.foo()<|>; }"#, ); assert_eq!(t, "Foo"); } #[test] fn deref_trait() { let t = type_at( r#" //- /main.rs #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct Arc; impl Deref for Arc { type Target = T; } struct S; impl S { fn foo(&self) -> u128 {} } fn test(s: Arc) { (*s, s.foo())<|>; } "#, ); assert_eq!(t, "(S, u128)"); } #[test] fn deref_trait_with_inference_var() { let t = type_at( r#" //- /main.rs #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct Arc; fn new_arc() -> Arc {} impl Deref for Arc { type Target = T; } struct S; fn foo(a: Arc) {} fn test() { let a = new_arc(); let b = (*a)<|>; foo(a); } "#, ); assert_eq!(t, "S"); } #[test] fn deref_trait_infinite_recursion() { let t = type_at( r#" //- /main.rs #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct S; impl Deref for S { type Target = S; } fn test(s: S) { s.foo()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn deref_trait_with_question_mark_size() { let t = type_at( r#" //- /main.rs #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct Arc; impl Deref for Arc { type Target = T; } struct S; impl S { fn foo(&self) -> u128 {} } fn test(s: Arc) { (*s, s.foo())<|>; } "#, ); assert_eq!(t, "(S, u128)"); } #[test] fn obligation_from_function_clause() { let t = type_at( r#" //- /main.rs struct S; trait Trait {} impl Trait for S {} fn foo, U>(t: T) -> U {} fn test(s: S) { foo(s)<|>; } "#, ); assert_eq!(t, "u32"); } #[test] fn obligation_from_method_clause() { let t = type_at( r#" //- /main.rs struct S; trait Trait {} impl Trait for S {} struct O; impl O { fn foo, U>(&self, t: T) -> U {} } fn test() { O.foo(S)<|>; } "#, ); assert_eq!(t, "isize"); } #[test] fn obligation_from_self_method_clause() { let t = type_at( r#" //- /main.rs struct S; trait Trait {} impl Trait for S {} impl S { fn foo(&self) -> U where Self: Trait {} } fn test() { S.foo()<|>; } "#, ); assert_eq!(t, "i64"); } #[test] fn obligation_from_impl_clause() { let t = type_at( r#" //- /main.rs struct S; trait Trait {} impl Trait<&str> for S {} struct O; impl> O { fn foo(&self) -> U {} } fn test(o: O) { o.foo()<|>; } "#, ); assert_eq!(t, "&str"); } #[test] fn generic_param_env_1() { let t = type_at( r#" //- /main.rs trait Clone {} trait Trait { fn foo(self) -> u128; } struct S; impl Clone for S {} impl Trait for T where T: Clone {} fn test(t: T) { t.foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[test] fn generic_param_env_1_not_met() { let t = type_at( r#" //- /main.rs trait Clone {} trait Trait { fn foo(self) -> u128; } struct S; impl Clone for S {} impl Trait for T where T: Clone {} fn test(t: T) { t.foo()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn generic_param_env_2() { let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl Trait for S {} fn test(t: T) { t.foo()<|>; } "#, ); assert_eq!(t, "u128"); } #[test] fn generic_param_env_2_not_met() { let t = type_at( r#" //- /main.rs trait Trait { fn foo(self) -> u128; } struct S; impl Trait for S {} fn test(t: T) { t.foo()<|>; } "#, ); assert_eq!(t, "{unknown}"); } #[test] fn generic_param_env_deref() { let t = type_at( r#" //- /main.rs #[lang = "deref"] trait Deref { type Target; } trait Trait {} impl Deref for T where T: Trait { type Target = i128; } fn test(t: T) { (*t)<|>; } "#, ); assert_eq!(t, "i128"); } #[test] fn associated_type_placeholder() { let t = type_at( r#" //- /main.rs pub trait ApplyL { type Out; } pub struct RefMutL; impl ApplyL for RefMutL { type Out = ::Out; } fn test() { let y: as ApplyL>::Out = no_matter; y<|>; } "#, ); // inside the generic function, the associated type gets normalized to a placeholder `ApplL::Out` [https://rust-lang.github.io/rustc-guide/traits/associated-types.html#placeholder-associated-types]. // FIXME: fix type parameter names going missing when going through Chalk assert_eq!(t, "ApplyL::Out<[missing name]>"); } #[test] fn associated_type_placeholder_2() { let t = type_at( r#" //- /main.rs pub trait ApplyL { type Out; } fn foo(t: T) -> ::Out; fn test(t: T) { let y = foo(t); y<|>; } "#, ); // FIXME here Chalk doesn't normalize the type to a placeholder. I think we // need to add a rule like Normalize(::Out -> ApplyL::Out) // to the trait env ourselves here; probably Chalk can't do this by itself. // assert_eq!(t, "ApplyL::Out<[missing name]>"); assert_eq!(t, "{unknown}"); } #[test] fn impl_trait() { assert_snapshot!( infer(r#" trait Trait { fn foo(&self) -> T; fn foo2(&self) -> i64; } fn bar() -> impl Trait {} fn test(x: impl Trait, y: &impl Trait) { x; y; let z = bar(); x.foo(); y.foo(); z.foo(); x.foo2(); y.foo2(); z.foo2(); } "#), @r###" [30; 34) 'self': &Self [55; 59) 'self': &Self [99; 101) '{}': () [111; 112) 'x': impl Trait [131; 132) 'y': &impl Trait [152; 269) '{ ...2(); }': () [158; 159) 'x': impl Trait [165; 166) 'y': &impl Trait [176; 177) 'z': impl Trait [180; 183) 'bar': fn bar() -> impl Trait [180; 185) 'bar()': impl Trait [191; 192) 'x': impl Trait [191; 198) 'x.foo()': u64 [204; 205) 'y': &impl Trait [204; 211) 'y.foo()': u64 [217; 218) 'z': impl Trait [217; 224) 'z.foo()': u64 [230; 231) 'x': impl Trait [230; 238) 'x.foo2()': i64 [244; 245) 'y': &impl Trait [244; 252) 'y.foo2()': i64 [258; 259) 'z': impl Trait [258; 266) 'z.foo2()': i64 "### ); } #[test] fn dyn_trait() { assert_snapshot!( infer(r#" trait Trait { fn foo(&self) -> T; fn foo2(&self) -> i64; } fn bar() -> dyn Trait {} fn test(x: dyn Trait, y: &dyn Trait) { x; y; let z = bar(); x.foo(); y.foo(); z.foo(); x.foo2(); y.foo2(); z.foo2(); } "#), @r###" [30; 34) 'self': &Self [55; 59) 'self': &Self [98; 100) '{}': () [110; 111) 'x': dyn Trait [129; 130) 'y': &dyn Trait [149; 266) '{ ...2(); }': () [155; 156) 'x': dyn Trait [162; 163) 'y': &dyn Trait [173; 174) 'z': dyn Trait [177; 180) 'bar': fn bar() -> dyn Trait [177; 182) 'bar()': dyn Trait [188; 189) 'x': dyn Trait [188; 195) 'x.foo()': u64 [201; 202) 'y': &dyn Trait [201; 208) 'y.foo()': u64 [214; 215) 'z': dyn Trait [214; 221) 'z.foo()': u64 [227; 228) 'x': dyn Trait [227; 235) 'x.foo2()': i64 [241; 242) 'y': &dyn Trait [241; 249) 'y.foo2()': i64 [255; 256) 'z': dyn Trait [255; 263) 'z.foo2()': i64 "### ); } #[test] fn dyn_trait_bare() { assert_snapshot!( infer(r#" trait Trait { fn foo(&self) -> u64; } fn bar() -> Trait {} fn test(x: Trait, y: &Trait) -> u64 { x; y; let z = bar(); x.foo(); y.foo(); z.foo(); } "#), @r###" [27; 31) 'self': &Self [61; 63) '{}': () [73; 74) 'x': dyn Trait [83; 84) 'y': &dyn Trait [101; 176) '{ ...o(); }': () [107; 108) 'x': dyn Trait [114; 115) 'y': &dyn Trait [125; 126) 'z': dyn Trait [129; 132) 'bar': fn bar() -> dyn Trait [129; 134) 'bar()': dyn Trait [140; 141) 'x': dyn Trait [140; 147) 'x.foo()': u64 [153; 154) 'y': &dyn Trait [153; 160) 'y.foo()': u64 [166; 167) 'z': dyn Trait [166; 173) 'z.foo()': u64 "### ); } #[test] fn weird_bounds() { assert_snapshot!( infer(r#" trait Trait {} fn test() { let a: impl Trait + 'lifetime = foo; let b: impl 'lifetime = foo; let b: impl (Trait) = foo; let b: impl ('lifetime) = foo; let d: impl ?Sized = foo; let e: impl Trait + ?Sized = foo; } "#), @r###" [26; 237) '{ ...foo; }': () [36; 37) 'a': impl Trait + {error} [64; 67) 'foo': impl Trait + {error} [77; 78) 'b': impl {error} [97; 100) 'foo': impl {error} [110; 111) 'b': impl Trait [128; 131) 'foo': impl Trait [141; 142) 'b': impl {error} [163; 166) 'foo': impl {error} [176; 177) 'd': impl {error} [193; 196) 'foo': impl {error} [206; 207) 'e': impl Trait + {error} [231; 234) 'foo': impl Trait + {error} "### ); } #[test] fn assoc_type_bindings() { assert_snapshot!( infer(r#" trait Trait { type Type; } fn get(t: T) -> ::Type {} fn get2>(t: T) -> U {} fn set>(t: T) -> T {t} struct S; impl Trait for S { type Type = T; } fn test>(x: T, y: impl Trait) { get(x); get2(x); get(y); get2(y); get(set(S)); get2(set(S)); get2(S::); } "#), @r###" [50; 51) 't': T [78; 80) '{}': () [112; 113) 't': T [123; 125) '{}': () [155; 156) 't': T [166; 169) '{t}': T [167; 168) 't': T [257; 258) 'x': T [263; 264) 'y': impl Trait [290; 398) '{ ...r>); }': () [296; 299) 'get': fn get(T) -> ::Type [296; 302) 'get(x)': {unknown} [300; 301) 'x': T [308; 312) 'get2': fn get2<{unknown}, T>(T) -> U [308; 315) 'get2(x)': {unknown} [313; 314) 'x': T [321; 324) 'get': fn get>(T) -> ::Type [321; 327) 'get(y)': {unknown} [325; 326) 'y': impl Trait [333; 337) 'get2': fn get2<{unknown}, impl Trait>(T) -> U [333; 340) 'get2(y)': {unknown} [338; 339) 'y': impl Trait [346; 349) 'get': fn get>(T) -> ::Type [346; 357) 'get(set(S))': u64 [350; 353) 'set': fn set>(T) -> T [350; 356) 'set(S)': S [354; 355) 'S': S [363; 367) 'get2': fn get2>(T) -> U [363; 375) 'get2(set(S))': u64 [368; 371) 'set': fn set>(T) -> T [368; 374) 'set(S)': S [372; 373) 'S': S [381; 385) 'get2': fn get2>(T) -> U [381; 395) 'get2(S::)': str [386; 394) 'S::': S "### ); } #[test] fn impl_trait_assoc_binding_projection_bug() { let (db, pos) = TestDB::with_position( r#" //- /main.rs crate:main deps:std pub trait Language { type Kind; } pub enum RustLanguage {} impl Language for RustLanguage { type Kind = SyntaxKind; } struct SyntaxNode {} fn foo() -> impl Iterator> {} trait Clone { fn clone(&self) -> Self; } fn api_walkthrough() { for node in foo() { node.clone()<|>; } } //- /std.rs crate:std #[prelude_import] use iter::*; mod iter { trait IntoIterator { type Item; } trait Iterator { type Item; } impl IntoIterator for T { type Item = ::Item; } } "#, ); assert_eq!("{unknown}", type_at_pos(&db, pos)); } #[test] fn projection_eq_within_chalk() { // std::env::set_var("CHALK_DEBUG", "1"); assert_snapshot!( infer(r#" trait Trait1 { type Type; } trait Trait2 { fn foo(self) -> T; } impl Trait2 for U where U: Trait1 {} fn test>(x: T) { x.foo(); } "#), @r###" [62; 66) 'self': Self [164; 165) 'x': T [170; 186) '{ ...o(); }': () [176; 177) 'x': T [176; 183) 'x.foo()': {unknown} "### ); } #[test] fn where_clause_trait_in_scope_for_method_resolution() { let t = type_at( r#" //- /main.rs mod foo { trait Trait { fn foo(&self) -> u32 {} } } fn test(x: T) { x.foo()<|>; } "#, ); assert_eq!(t, "u32"); } #[test] fn super_trait_method_resolution() { assert_snapshot!( infer(r#" mod foo { trait SuperTrait { fn foo(&self) -> u32 {} } } trait Trait1: foo::SuperTrait {} trait Trait2 where Self: foo::SuperTrait {} fn test(x: T, y: U) { x.foo(); y.foo(); } "#), @r###" [50; 54) 'self': &Self [63; 65) '{}': () [182; 183) 'x': T [188; 189) 'y': U [194; 223) '{ ...o(); }': () [200; 201) 'x': T [200; 207) 'x.foo()': u32 [213; 214) 'y': U [213; 220) 'y.foo()': u32 "### ); } #[test] fn super_trait_cycle() { // This just needs to not crash assert_snapshot!( infer(r#" trait A: B {} trait B: A {} fn test(x: T) { x.foo(); } "#), @r###" [44; 45) 'x': T [50; 66) '{ ...o(); }': () [56; 57) 'x': T [56; 63) 'x.foo()': {unknown} "### ); } #[test] fn super_trait_assoc_type_bounds() { assert_snapshot!( infer(r#" trait SuperTrait { type Type; } trait Trait where Self: SuperTrait {} fn get2>(t: T) -> U {} fn set>(t: T) -> T {t} struct S; impl SuperTrait for S { type Type = T; } impl Trait for S {} fn test() { get2(set(S)); } "#), @r###" [103; 104) 't': T [114; 116) '{}': () [146; 147) 't': T [157; 160) '{t}': T [158; 159) 't': T [259; 280) '{ ...S)); }': () [265; 269) 'get2': fn get2>(T) -> U [265; 277) 'get2(set(S))': u64 [270; 273) 'set': fn set>(T) -> T [270; 276) 'set(S)': S [274; 275) 'S': S "### ); } #[test] fn fn_trait() { assert_snapshot!( infer(r#" trait FnOnce { type Output; fn call_once(self, args: Args) -> >::Output; } fn test u128>(f: F) { f.call_once((1, 2)); } "#), @r###" [57; 61) 'self': Self [63; 67) 'args': Args [150; 151) 'f': F [156; 184) '{ ...2)); }': () [162; 163) 'f': F [162; 181) 'f.call...1, 2))': {unknown} [174; 180) '(1, 2)': (u32, u64) [175; 176) '1': u32 [178; 179) '2': u64 "### ); } #[test] fn closure_1() { assert_snapshot!( infer(r#" #[lang = "fn_once"] trait FnOnce { type Output; } enum Option { Some(T), None } impl Option { fn map U>(self, f: F) -> Option {} } fn test() { let x = Option::Some(1u32); x.map(|v| v + 1); x.map(|_v| 1u64); let y: Option = x.map(|_v| 1); } "#), @r###" [148; 152) 'self': Option [154; 155) 'f': F [173; 175) '{}': () [189; 308) '{ ... 1); }': () [199; 200) 'x': Option [203; 215) 'Option::Some': Some(T) -> Option [203; 221) 'Option...(1u32)': Option [216; 220) '1u32': u32 [227; 228) 'x': Option [227; 243) 'x.map(...v + 1)': Option [233; 242) '|v| v + 1': |u32| -> u32 [234; 235) 'v': u32 [237; 238) 'v': u32 [237; 242) 'v + 1': u32 [241; 242) '1': u32 [249; 250) 'x': Option [249; 265) 'x.map(... 1u64)': Option [255; 264) '|_v| 1u64': |u32| -> u64 [256; 258) '_v': u32 [260; 264) '1u64': u64 [275; 276) 'y': Option [292; 293) 'x': Option [292; 305) 'x.map(|_v| 1)': Option [298; 304) '|_v| 1': |u32| -> i64 [299; 301) '_v': u32 [303; 304) '1': i64 "### ); } #[test] fn closure_2() { assert_snapshot!( infer(r#" trait FnOnce { type Output; } fn test u64>(f: F) { f(1); let g = |v| v + 1; g(1u64); let h = |v| 1u128 + v; } "#), @r###" [73; 74) 'f': F [79; 155) '{ ...+ v; }': () [85; 86) 'f': F [85; 89) 'f(1)': {unknown} [87; 88) '1': i32 [99; 100) 'g': |u64| -> i32 [103; 112) '|v| v + 1': |u64| -> i32 [104; 105) 'v': u64 [107; 108) 'v': u64 [107; 112) 'v + 1': i32 [111; 112) '1': i32 [118; 119) 'g': |u64| -> i32 [118; 125) 'g(1u64)': i32 [120; 124) '1u64': u64 [135; 136) 'h': |u128| -> u128 [139; 152) '|v| 1u128 + v': |u128| -> u128 [140; 141) 'v': u128 [143; 148) '1u128': u128 [143; 152) '1u128 + v': u128 [151; 152) 'v': u128 "### ); } #[test] fn closure_as_argument_inference_order() { assert_snapshot!( infer(r#" #[lang = "fn_once"] trait FnOnce { type Output; } fn foo1 U>(x: T, f: F) -> U {} fn foo2 U>(f: F, x: T) -> U {} struct S; impl S { fn method(self) -> u64; fn foo1 U>(self, x: T, f: F) -> U {} fn foo2 U>(self, f: F, x: T) -> U {} } fn test() { let x1 = foo1(S, |s| s.method()); let x2 = foo2(|s| s.method(), S); let x3 = S.foo1(S, |s| s.method()); let x4 = S.foo2(|s| s.method(), S); } "#), @r###" [95; 96) 'x': T [101; 102) 'f': F [112; 114) '{}': () [148; 149) 'f': F [154; 155) 'x': T [165; 167) '{}': () [202; 206) 'self': S [254; 258) 'self': S [260; 261) 'x': T [266; 267) 'f': F [277; 279) '{}': () [317; 321) 'self': S [323; 324) 'f': F [329; 330) 'x': T [340; 342) '{}': () [356; 515) '{ ... S); }': () [366; 368) 'x1': u64 [371; 375) 'foo1': fn foo1 u64>(T, F) -> U [371; 394) 'foo1(S...hod())': u64 [376; 377) 'S': S [379; 393) '|s| s.method()': |S| -> u64 [380; 381) 's': S [383; 384) 's': S [383; 393) 's.method()': u64 [404; 406) 'x2': u64 [409; 413) 'foo2': fn foo2 u64>(F, T) -> U [409; 432) 'foo2(|...(), S)': u64 [414; 428) '|s| s.method()': |S| -> u64 [415; 416) 's': S [418; 419) 's': S [418; 428) 's.method()': u64 [430; 431) 'S': S [442; 444) 'x3': u64 [447; 448) 'S': S [447; 472) 'S.foo1...hod())': u64 [454; 455) 'S': S [457; 471) '|s| s.method()': |S| -> u64 [458; 459) 's': S [461; 462) 's': S [461; 471) 's.method()': u64 [482; 484) 'x4': u64 [487; 488) 'S': S [487; 512) 'S.foo2...(), S)': u64 [494; 508) '|s| s.method()': |S| -> u64 [495; 496) 's': S [498; 499) 's': S [498; 508) 's.method()': u64 [510; 511) 'S': S "### ); } #[test] fn unselected_projection_in_trait_env_1() { let t = type_at( r#" //- /main.rs trait Trait { type Item; } trait Trait2 { fn foo(&self) -> u32; } fn test() where T::Item: Trait2 { let x: T::Item = no_matter; x.foo()<|>; } "#, ); assert_eq!(t, "u32"); } #[test] fn unselected_projection_in_trait_env_2() { let t = type_at( r#" //- /main.rs trait Trait { type Item; } trait Trait2 { fn foo(&self) -> u32; } fn test() where T::Item: Trait2, T: Trait, U: Trait<()> { let x: T::Item = no_matter; x.foo()<|>; } "#, ); assert_eq!(t, "u32"); } #[test] // FIXME this is currently a Salsa panic; it would be nicer if it just returned // in Unknown, and we should be able to do that once Salsa allows us to handle // the cycle. But at least it doesn't overflow for now. #[should_panic] fn unselected_projection_in_trait_env_cycle_1() { let t = type_at( r#" //- /main.rs trait Trait { type Item; } trait Trait2 {} fn test() where T: Trait2 { let x: T::Item = no_matter<|>; } "#, ); // this is a legitimate cycle assert_eq!(t, "{unknown}"); } #[test] // FIXME this is currently a Salsa panic; it would be nicer if it just returned // in Unknown, and we should be able to do that once Salsa allows us to handle // the cycle. But at least it doesn't overflow for now. #[should_panic] fn unselected_projection_in_trait_env_cycle_2() { let t = type_at( r#" //- /main.rs trait Trait { type Item; } fn test() where T: Trait, U: Trait { let x: T::Item = no_matter<|>; } "#, ); // this is a legitimate cycle assert_eq!(t, "{unknown}"); } fn type_at_pos(db: &TestDB, pos: FilePosition) -> String { let file = db.parse(pos.file_id).ok().unwrap(); let expr = algo::find_node_at_offset::(file.syntax(), pos.offset).unwrap(); let module = db.module_for_file(pos.file_id); let crate_def_map = db.crate_def_map(module.krate); for decl in crate_def_map[module.local_id].scope.declarations() { if let ModuleDefId::FunctionId(func) = decl { let (_body, source_map) = db.body_with_source_map(func.into()); if let Some(expr_id) = source_map.node_expr(Source::new(pos.file_id.into(), &expr)) { let infer = db.infer(func.into()); let ty = &infer[expr_id]; return ty.display(db).to_string(); } } } panic!("Can't find expression") } fn type_at(content: &str) -> String { let (db, file_pos) = TestDB::with_position(content); type_at_pos(&db, file_pos) } fn infer(content: &str) -> String { let (db, file_id) = TestDB::with_single_file(content); let mut acc = String::new(); let mut infer_def = |inference_result: Arc, body_source_map: Arc| { let mut types = Vec::new(); for (pat, ty) in inference_result.type_of_pat.iter() { let syntax_ptr = match body_source_map.pat_syntax(pat) { Some(sp) => { sp.map(|ast| ast.either(|it| it.syntax_node_ptr(), |it| it.syntax_node_ptr())) } None => continue, }; types.push((syntax_ptr, ty)); } for (expr, ty) in inference_result.type_of_expr.iter() { let syntax_ptr = match body_source_map.expr_syntax(expr) { Some(sp) => { sp.map(|ast| ast.either(|it| it.syntax_node_ptr(), |it| it.syntax_node_ptr())) } None => continue, }; types.push((syntax_ptr, ty)); } // sort ranges for consistency types.sort_by_key(|(src_ptr, _)| { (src_ptr.value.range().start(), src_ptr.value.range().end()) }); for (src_ptr, ty) in &types { let node = src_ptr.value.to_node(&src_ptr.file_syntax(&db)); let (range, text) = if let Some(self_param) = ast::SelfParam::cast(node.clone()) { (self_param.self_kw_token().text_range(), "self".to_string()) } else { (src_ptr.value.range(), node.text().to_string().replace("\n", " ")) }; let macro_prefix = if src_ptr.file_id != file_id.into() { "!" } else { "" }; write!( acc, "{}{} '{}': {}\n", macro_prefix, range, ellipsize(text, 15), ty.display(&db) ) .unwrap(); } }; let module = db.module_for_file(file_id); let crate_def_map = db.crate_def_map(module.krate); let mut defs: Vec = Vec::new(); visit_module(&db, &crate_def_map, module.local_id, &mut |it| defs.push(it)); defs.sort_by_key(|def| match def { DefWithBodyId::FunctionId(it) => { it.lookup(&db).ast_id.to_node(&db).syntax().text_range().start() } DefWithBodyId::ConstId(it) => { it.lookup(&db).ast_id.to_node(&db).syntax().text_range().start() } DefWithBodyId::StaticId(it) => { it.lookup(&db).ast_id.to_node(&db).syntax().text_range().start() } }); for def in defs { let (_body, source_map) = db.body_with_source_map(def); let infer = db.infer(def); infer_def(infer, source_map); } acc.truncate(acc.trim_end().len()); acc } fn visit_module( db: &TestDB, crate_def_map: &CrateDefMap, module_id: LocalModuleId, cb: &mut dyn FnMut(DefWithBodyId), ) { for decl in crate_def_map[module_id].scope.declarations() { match decl { ModuleDefId::FunctionId(it) => cb(it.into()), ModuleDefId::ConstId(it) => cb(it.into()), ModuleDefId::StaticId(it) => cb(it.into()), ModuleDefId::TraitId(it) => { let trait_data = db.trait_data(it); for &(_, item) in trait_data.items.iter() { match item { AssocItemId::FunctionId(it) => cb(it.into()), AssocItemId::ConstId(it) => cb(it.into()), AssocItemId::TypeAliasId(_) => (), } } } ModuleDefId::ModuleId(it) => visit_module(db, crate_def_map, it.local_id, cb), _ => (), } } for &impl_id in crate_def_map[module_id].impls.iter() { let impl_data = db.impl_data(impl_id); for &item in impl_data.items.iter() { match item { AssocItemId::FunctionId(it) => cb(it.into()), AssocItemId::ConstId(it) => cb(it.into()), AssocItemId::TypeAliasId(_) => (), } } } } fn ellipsize(mut text: String, max_len: usize) -> String { if text.len() <= max_len { return text; } let ellipsis = "..."; let e_len = ellipsis.len(); let mut prefix_len = (max_len - e_len) / 2; while !text.is_char_boundary(prefix_len) { prefix_len += 1; } let mut suffix_len = max_len - e_len - prefix_len; while !text.is_char_boundary(text.len() - suffix_len) { suffix_len += 1; } text.replace_range(prefix_len..text.len() - suffix_len, ellipsis); text } #[test] fn typing_whitespace_inside_a_function_should_not_invalidate_types() { let (mut db, pos) = TestDB::with_position( " //- /lib.rs fn foo() -> i32 { <|>1 + 1 } ", ); { let events = db.log_executed(|| { let module = db.module_for_file(pos.file_id); let crate_def_map = db.crate_def_map(module.krate); visit_module(&db, &crate_def_map, module.local_id, &mut |def| { db.infer(def); }); }); assert!(format!("{:?}", events).contains("infer")) } let new_text = " fn foo() -> i32 { 1 + 1 } " .to_string(); db.query_mut(ra_db::FileTextQuery).set(pos.file_id, Arc::new(new_text)); { let events = db.log_executed(|| { let module = db.module_for_file(pos.file_id); let crate_def_map = db.crate_def_map(module.krate); visit_module(&db, &crate_def_map, module.local_id, &mut |def| { db.infer(def); }); }); assert!(!format!("{:?}", events).contains("infer"), "{:#?}", events) } } #[test] fn no_such_field_diagnostics() { let diagnostics = TestDB::with_files( r" //- /lib.rs struct S { foo: i32, bar: () } impl S { fn new() -> S { S { foo: 92, baz: 62, } } } ", ) .diagnostics(); assert_snapshot!(diagnostics, @r###" "baz: 62": no such field "{\n foo: 92,\n baz: 62,\n }": Missing structure fields: - bar "### ); } #[test] fn infer_builtin_macros_line() { assert_snapshot!( infer(r#" #[rustc_builtin_macro] macro_rules! line {() => {}} fn main() { let x = line!(); } "#), @r###" ![0; 1) '6': i32 [64; 88) '{ ...!(); }': () [74; 75) 'x': i32 "### ); } #[test] fn infer_builtin_macros_file() { assert_snapshot!( infer(r#" #[rustc_builtin_macro] macro_rules! file {() => {}} fn main() { let x = file!(); } "#), @r###" ![0; 2) '""': &str [64; 88) '{ ...!(); }': () [74; 75) 'x': &str "### ); } #[test] fn infer_builtin_macros_column() { assert_snapshot!( infer(r#" #[rustc_builtin_macro] macro_rules! column {() => {}} fn main() { let x = column!(); } "#), @r###" ![0; 2) '13': i32 [66; 92) '{ ...!(); }': () [76; 77) 'x': i32 "### ); }