// Copyright 2013 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // This file implements tests for various issues. package types_test import ( "fmt" "go/ast" "go/importer" "go/parser" "go/token" "internal/testenv" "regexp" "slices" "strings" "testing" . "go/types" ) func TestIssue5770(t *testing.T) { _, err := typecheck(`package p; type S struct{T}`, nil, nil) const want = "undefined: T" if err == nil || !strings.Contains(err.Error(), want) { t.Errorf("got: %v; want: %s", err, want) } } func TestIssue5849(t *testing.T) { src := ` package p var ( s uint _ = uint8(8) _ = uint16(16) << s _ = uint32(32 << s) _ = uint64(64 << s + s) _ = (interface{})("foo") _ = (interface{})(nil) )` types := make(map[ast.Expr]TypeAndValue) mustTypecheck(src, nil, &Info{Types: types}) for x, tv := range types { var want Type switch x := x.(type) { case *ast.BasicLit: switch x.Value { case `8`: want = Typ[Uint8] case `16`: want = Typ[Uint16] case `32`: want = Typ[Uint32] case `64`: want = Typ[Uint] // because of "+ s", s is of type uint case `"foo"`: want = Typ[String] } case *ast.Ident: if x.Name == "nil" { want = Typ[UntypedNil] } } if want != nil && !Identical(tv.Type, want) { t.Errorf("got %s; want %s", tv.Type, want) } } } func TestIssue6413(t *testing.T) { src := ` package p func f() int { defer f() go f() return 0 } ` types := make(map[ast.Expr]TypeAndValue) mustTypecheck(src, nil, &Info{Types: types}) want := Typ[Int] n := 0 for x, tv := range types { if _, ok := x.(*ast.CallExpr); ok { if tv.Type != want { t.Errorf("%s: got %s; want %s", fset.Position(x.Pos()), tv.Type, want) } n++ } } if n != 2 { t.Errorf("got %d CallExprs; want 2", n) } } func TestIssue7245(t *testing.T) { src := ` package p func (T) m() (res bool) { return } type T struct{} // receiver type after method declaration ` f := mustParse(fset, src) var conf Config defs := make(map[*ast.Ident]Object) _, err := conf.Check(f.Name.Name, fset, []*ast.File{f}, &Info{Defs: defs}) if err != nil { t.Fatal(err) } m := f.Decls[0].(*ast.FuncDecl) res1 := defs[m.Name].(*Func).Signature().Results().At(0) res2 := defs[m.Type.Results.List[0].Names[0]].(*Var) if res1 != res2 { t.Errorf("got %s (%p) != %s (%p)", res1, res2, res1, res2) } } // This tests that uses of existing vars on the LHS of an assignment // are Uses, not Defs; and also that the (illegal) use of a non-var on // the LHS of an assignment is a Use nonetheless. func TestIssue7827(t *testing.T) { const src = ` package p func _() { const w = 1 // defs w x, y := 2, 3 // defs x, y w, x, z := 4, 5, 6 // uses w, x, defs z; error: cannot assign to w _, _, _ = x, y, z // uses x, y, z } ` // We need a specific fileset in this test below for positions. // Cannot use typecheck helper. fset := token.NewFileSet() f := mustParse(fset, src) const want = `L3 defs func p._() L4 defs const w untyped int L5 defs var x int L5 defs var y int L6 defs var z int L6 uses const w untyped int L6 uses var x int L7 uses var x int L7 uses var y int L7 uses var z int` // don't abort at the first error conf := Config{Error: func(err error) { t.Log(err) }} defs := make(map[*ast.Ident]Object) uses := make(map[*ast.Ident]Object) _, err := conf.Check(f.Name.Name, fset, []*ast.File{f}, &Info{Defs: defs, Uses: uses}) if s := err.Error(); !strings.HasSuffix(s, "cannot assign to w") { t.Errorf("Check: unexpected error: %s", s) } var facts []string for id, obj := range defs { if obj != nil { fact := fmt.Sprintf("L%d defs %s", fset.Position(id.Pos()).Line, obj) facts = append(facts, fact) } } for id, obj := range uses { fact := fmt.Sprintf("L%d uses %s", fset.Position(id.Pos()).Line, obj) facts = append(facts, fact) } slices.Sort(facts) got := strings.Join(facts, "\n") if got != want { t.Errorf("Unexpected defs/uses\ngot:\n%s\nwant:\n%s", got, want) } } // This tests that the package associated with the types.Object.Pkg method // is the type's package independent of the order in which the imports are // listed in the sources src1, src2 below. // The actual issue is in go/internal/gcimporter which has a corresponding // test; we leave this test here to verify correct behavior at the go/types // level. func TestIssue13898(t *testing.T) { testenv.MustHaveGoBuild(t) const src0 = ` package main import "go/types" func main() { var info types.Info for _, obj := range info.Uses { _ = obj.Pkg() } } ` // like src0, but also imports go/importer const src1 = ` package main import ( "go/types" _ "go/importer" ) func main() { var info types.Info for _, obj := range info.Uses { _ = obj.Pkg() } } ` // like src1 but with different import order // (used to fail with this issue) const src2 = ` package main import ( _ "go/importer" "go/types" ) func main() { var info types.Info for _, obj := range info.Uses { _ = obj.Pkg() } } ` f := func(test, src string) { info := &Info{Uses: make(map[*ast.Ident]Object)} mustTypecheck(src, nil, info) var pkg *Package count := 0 for id, obj := range info.Uses { if id.Name == "Pkg" { pkg = obj.Pkg() count++ } } if count != 1 { t.Fatalf("%s: got %d entries named Pkg; want 1", test, count) } if pkg.Name() != "types" { t.Fatalf("%s: got %v; want package types", test, pkg) } } f("src0", src0) f("src1", src1) f("src2", src2) } func TestIssue22525(t *testing.T) { const src = `package p; func f() { var a, b, c, d, e int }` got := "\n" conf := Config{Error: func(err error) { got += err.Error() + "\n" }} typecheck(src, &conf, nil) // do not crash want := "\n" + "p:1:27: declared and not used: a\n" + "p:1:30: declared and not used: b\n" + "p:1:33: declared and not used: c\n" + "p:1:36: declared and not used: d\n" + "p:1:39: declared and not used: e\n" if got != want { t.Errorf("got: %swant: %s", got, want) } } func TestIssue25627(t *testing.T) { const prefix = `package p; import "unsafe"; type P *struct{}; type I interface{}; type T ` // The src strings (without prefix) are constructed such that the number of semicolons // plus one corresponds to the number of fields expected in the respective struct. for _, src := range []string{ `struct { x Missing }`, `struct { Missing }`, `struct { *Missing }`, `struct { unsafe.Pointer }`, `struct { P }`, `struct { *I }`, `struct { a int; b Missing; *Missing }`, } { f := mustParse(fset, prefix+src) cfg := Config{Importer: importer.Default(), Error: func(err error) {}} info := &Info{Types: make(map[ast.Expr]TypeAndValue)} _, err := cfg.Check(f.Name.Name, fset, []*ast.File{f}, info) if err != nil { if _, ok := err.(Error); !ok { t.Fatal(err) } } ast.Inspect(f, func(n ast.Node) bool { if spec, _ := n.(*ast.TypeSpec); spec != nil { if tv, ok := info.Types[spec.Type]; ok && spec.Name.Name == "T" { want := strings.Count(src, ";") + 1 if got := tv.Type.(*Struct).NumFields(); got != want { t.Errorf("%s: got %d fields; want %d", src, got, want) } } } return true }) } } func TestIssue28005(t *testing.T) { // method names must match defining interface name for this test // (see last comment in this function) sources := [...]string{ "package p; type A interface{ A() }", "package p; type B interface{ B() }", "package p; type X interface{ A; B }", } // compute original file ASTs var orig [len(sources)]*ast.File for i, src := range sources { orig[i] = mustParse(fset, src) } // run the test for all order permutations of the incoming files for _, perm := range [][len(sources)]int{ {0, 1, 2}, {0, 2, 1}, {1, 0, 2}, {1, 2, 0}, {2, 0, 1}, {2, 1, 0}, } { // create file order permutation files := make([]*ast.File, len(sources)) for i := range perm { files[i] = orig[perm[i]] } // type-check package with given file order permutation var conf Config info := &Info{Defs: make(map[*ast.Ident]Object)} _, err := conf.Check("", fset, files, info) if err != nil { t.Fatal(err) } // look for interface object X var obj Object for name, def := range info.Defs { if name.Name == "X" { obj = def break } } if obj == nil { t.Fatal("object X not found") } iface := obj.Type().Underlying().(*Interface) // object X must be an interface // Each iface method m is embedded; and m's receiver base type name // must match the method's name per the choice in the source file. for i := 0; i < iface.NumMethods(); i++ { m := iface.Method(i) recvName := m.Signature().Recv().Type().(*Named).Obj().Name() if recvName != m.Name() { t.Errorf("perm %v: got recv %s; want %s", perm, recvName, m.Name()) } } } } func TestIssue28282(t *testing.T) { // create type interface { error } et := Universe.Lookup("error").Type() it := NewInterfaceType(nil, []Type{et}) it.Complete() // verify that after completing the interface, the embedded method remains unchanged want := et.Underlying().(*Interface).Method(0) got := it.Method(0) if got != want { t.Fatalf("%s.Method(0): got %q (%p); want %q (%p)", it, got, got, want, want) } // verify that lookup finds the same method in both interfaces (redundant check) obj, _, _ := LookupFieldOrMethod(et, false, nil, "Error") if obj != want { t.Fatalf("%s.Lookup: got %q (%p); want %q (%p)", et, obj, obj, want, want) } obj, _, _ = LookupFieldOrMethod(it, false, nil, "Error") if obj != want { t.Fatalf("%s.Lookup: got %q (%p); want %q (%p)", it, obj, obj, want, want) } } func TestIssue29029(t *testing.T) { f1 := mustParse(fset, `package p; type A interface { M() }`) f2 := mustParse(fset, `package p; var B interface { A }`) // printInfo prints the *Func definitions recorded in info, one *Func per line. printInfo := func(info *Info) string { var buf strings.Builder for _, obj := range info.Defs { if fn, ok := obj.(*Func); ok { fmt.Fprintln(&buf, fn) } } return buf.String() } // The *Func (method) definitions for package p must be the same // independent on whether f1 and f2 are type-checked together, or // incrementally. // type-check together var conf Config info := &Info{Defs: make(map[*ast.Ident]Object)} check := NewChecker(&conf, fset, NewPackage("", "p"), info) if err := check.Files([]*ast.File{f1, f2}); err != nil { t.Fatal(err) } want := printInfo(info) // type-check incrementally info = &Info{Defs: make(map[*ast.Ident]Object)} check = NewChecker(&conf, fset, NewPackage("", "p"), info) if err := check.Files([]*ast.File{f1}); err != nil { t.Fatal(err) } if err := check.Files([]*ast.File{f2}); err != nil { t.Fatal(err) } got := printInfo(info) if got != want { t.Errorf("\ngot : %swant: %s", got, want) } } func TestIssue34151(t *testing.T) { const asrc = `package a; type I interface{ M() }; type T struct { F interface { I } }` const bsrc = `package b; import "a"; type T struct { F interface { a.I } }; var _ = a.T(T{})` a := mustTypecheck(asrc, nil, nil) conf := Config{Importer: importHelper{pkg: a}} mustTypecheck(bsrc, &conf, nil) } type importHelper struct { pkg *Package fallback Importer } func (h importHelper) Import(path string) (*Package, error) { if path == h.pkg.Path() { return h.pkg, nil } if h.fallback == nil { return nil, fmt.Errorf("got package path %q; want %q", path, h.pkg.Path()) } return h.fallback.Import(path) } // TestIssue34921 verifies that we don't update an imported type's underlying // type when resolving an underlying type. Specifically, when determining the // underlying type of b.T (which is the underlying type of a.T, which is int) // we must not set the underlying type of a.T again since that would lead to // a race condition if package b is imported elsewhere, in a package that is // concurrently type-checked. func TestIssue34921(t *testing.T) { defer func() { if r := recover(); r != nil { t.Error(r) } }() var sources = []string{ `package a; type T int`, `package b; import "a"; type T a.T`, } var pkg *Package for _, src := range sources { conf := Config{Importer: importHelper{pkg: pkg}} pkg = mustTypecheck(src, &conf, nil) // pkg imported by the next package in this test } } func TestIssue43088(t *testing.T) { // type T1 struct { // _ T2 // } // // type T2 struct { // _ struct { // _ T2 // } // } n1 := NewTypeName(nopos, nil, "T1", nil) T1 := NewNamed(n1, nil, nil) n2 := NewTypeName(nopos, nil, "T2", nil) T2 := NewNamed(n2, nil, nil) s1 := NewStruct([]*Var{NewField(nopos, nil, "_", T2, false)}, nil) T1.SetUnderlying(s1) s2 := NewStruct([]*Var{NewField(nopos, nil, "_", T2, false)}, nil) s3 := NewStruct([]*Var{NewField(nopos, nil, "_", s2, false)}, nil) T2.SetUnderlying(s3) // These calls must terminate (no endless recursion). Comparable(T1) Comparable(T2) } func TestIssue44515(t *testing.T) { typ := Unsafe.Scope().Lookup("Pointer").Type() got := TypeString(typ, nil) want := "unsafe.Pointer" if got != want { t.Errorf("got %q; want %q", got, want) } qf := func(pkg *Package) string { if pkg == Unsafe { return "foo" } return "" } got = TypeString(typ, qf) want = "foo.Pointer" if got != want { t.Errorf("got %q; want %q", got, want) } } func TestIssue43124(t *testing.T) { // TODO(rFindley) move this to testdata by enhancing support for importing. testenv.MustHaveGoBuild(t) // The go command is needed for the importer to determine the locations of stdlib .a files. // All involved packages have the same name (template). Error messages should // disambiguate between text/template and html/template by printing the full // path. const ( asrc = `package a; import "text/template"; func F(template.Template) {}; func G(int) {}` bsrc = ` package b import ( "a" "html/template" ) func _() { // Packages should be fully qualified when there is ambiguity within the // error string itself. a.F(template /* ERRORx "cannot use.*html/template.* as .*text/template" */ .Template{}) } ` csrc = ` package c import ( "a" "fmt" "html/template" ) // go.dev/issue/46905: make sure template is not the first package qualified. var _ fmt.Stringer = 1 // ERRORx "cannot use 1.*as fmt\\.Stringer" // Packages should be fully qualified when there is ambiguity in reachable // packages. In this case both a (and for that matter html/template) import // text/template. func _() { a.G(template /* ERRORx "cannot use .*html/template.*Template" */ .Template{}) } ` tsrc = ` package template import "text/template" type T int // Verify that the current package name also causes disambiguation. var _ T = template /* ERRORx "cannot use.*text/template.* as T value" */.Template{} ` ) a := mustTypecheck(asrc, nil, nil) imp := importHelper{pkg: a, fallback: importer.Default()} withImporter := func(cfg *Config) { cfg.Importer = imp } testFiles(t, []string{"b.go"}, [][]byte{[]byte(bsrc)}, false, withImporter) testFiles(t, []string{"c.go"}, [][]byte{[]byte(csrc)}, false, withImporter) testFiles(t, []string{"t.go"}, [][]byte{[]byte(tsrc)}, false, withImporter) } func TestIssue50646(t *testing.T) { anyType := Universe.Lookup("any").Type().Underlying() comparableType := Universe.Lookup("comparable").Type() if !Comparable(anyType) { t.Error("any is not a comparable type") } if !Comparable(comparableType) { t.Error("comparable is not a comparable type") } if Implements(anyType, comparableType.Underlying().(*Interface)) { t.Error("any implements comparable") } if !Implements(comparableType, anyType.(*Interface)) { t.Error("comparable does not implement any") } if AssignableTo(anyType, comparableType) { t.Error("any assignable to comparable") } if !AssignableTo(comparableType, anyType) { t.Error("comparable not assignable to any") } } func TestIssue55030(t *testing.T) { // makeSig makes the signature func(typ...) makeSig := func(typ Type) { par := NewVar(nopos, nil, "", typ) params := NewTuple(par) NewSignatureType(nil, nil, nil, params, nil, true) } // makeSig must not panic for the following (example) types: // []int makeSig(NewSlice(Typ[Int])) // string makeSig(Typ[String]) // P where P's core type is string { P := NewTypeName(nopos, nil, "P", nil) // [P string] makeSig(NewTypeParam(P, NewInterfaceType(nil, []Type{Typ[String]}))) } // P where P's core type is an (unnamed) slice { P := NewTypeName(nopos, nil, "P", nil) // [P []int] makeSig(NewTypeParam(P, NewInterfaceType(nil, []Type{NewSlice(Typ[Int])}))) } // P where P's core type is bytestring (i.e., string or []byte) { t1 := NewTerm(true, Typ[String]) // ~string t2 := NewTerm(false, NewSlice(Typ[Byte])) // []byte u := NewUnion([]*Term{t1, t2}) // ~string | []byte P := NewTypeName(nopos, nil, "P", nil) // [P ~string | []byte] makeSig(NewTypeParam(P, NewInterfaceType(nil, []Type{u}))) } } func TestIssue51093(t *testing.T) { // Each test stands for a conversion of the form P(val) // where P is a type parameter with typ as constraint. // The test ensures that P(val) has the correct type P // and is not a constant. var tests = []struct { typ string val string }{ {"bool", "false"}, {"int", "-1"}, {"uint", "1.0"}, {"rune", "'a'"}, {"float64", "3.5"}, {"complex64", "1.25"}, {"string", "\"foo\""}, // some more complex constraints {"~byte", "1"}, {"~int | ~float64 | complex128", "1"}, {"~uint64 | ~rune", "'X'"}, } for _, test := range tests { src := fmt.Sprintf("package p; func _[P %s]() { _ = P(%s) }", test.typ, test.val) types := make(map[ast.Expr]TypeAndValue) mustTypecheck(src, nil, &Info{Types: types}) var n int for x, tv := range types { if x, _ := x.(*ast.CallExpr); x != nil { // there must be exactly one CallExpr which is the P(val) conversion n++ tpar, _ := tv.Type.(*TypeParam) if tpar == nil { t.Fatalf("%s: got type %s, want type parameter", ExprString(x), tv.Type) } if name := tpar.Obj().Name(); name != "P" { t.Fatalf("%s: got type parameter name %s, want P", ExprString(x), name) } // P(val) must not be constant if tv.Value != nil { t.Errorf("%s: got constant value %s (%s), want no constant", ExprString(x), tv.Value, tv.Value.String()) } } } if n != 1 { t.Fatalf("%s: got %d CallExpr nodes; want 1", src, 1) } } } func TestIssue54258(t *testing.T) { tests := []struct{ main, b, want string }{ { //--------------------------------------------------------------- `package main import "b" type I0 interface { M0(w struct{ f string }) } var _ I0 = b.S{} `, `package b type S struct{} func (S) M0(struct{ f string }) {} `, `6:12: cannot use b[.]S{} [(]value of type b[.]S[)] as I0 value in variable declaration: b[.]S does not implement I0 [(]wrong type for method M0[)] .*have M0[(]struct{f string /[*] package b [*]/ }[)] .*want M0[(]struct{f string /[*] package main [*]/ }[)]`}, { //--------------------------------------------------------------- `package main import "b" type I1 interface { M1(struct{ string }) } var _ I1 = b.S{} `, `package b type S struct{} func (S) M1(struct{ string }) {} `, `6:12: cannot use b[.]S{} [(]value of type b[.]S[)] as I1 value in variable declaration: b[.]S does not implement I1 [(]wrong type for method M1[)] .*have M1[(]struct{string /[*] package b [*]/ }[)] .*want M1[(]struct{string /[*] package main [*]/ }[)]`}, { //--------------------------------------------------------------- `package main import "b" type I2 interface { M2(y struct{ f struct{ f string } }) } var _ I2 = b.S{} `, `package b type S struct{} func (S) M2(struct{ f struct{ f string } }) {} `, `6:12: cannot use b[.]S{} [(]value of type b[.]S[)] as I2 value in variable declaration: b[.]S does not implement I2 [(]wrong type for method M2[)] .*have M2[(]struct{f struct{f string} /[*] package b [*]/ }[)] .*want M2[(]struct{f struct{f string} /[*] package main [*]/ }[)]`}, { //--------------------------------------------------------------- `package main import "b" type I3 interface { M3(z struct{ F struct{ f string } }) } var _ I3 = b.S{} `, `package b type S struct{} func (S) M3(struct{ F struct{ f string } }) {} `, `6:12: cannot use b[.]S{} [(]value of type b[.]S[)] as I3 value in variable declaration: b[.]S does not implement I3 [(]wrong type for method M3[)] .*have M3[(]struct{F struct{f string /[*] package b [*]/ }}[)] .*want M3[(]struct{F struct{f string /[*] package main [*]/ }}[)]`}, { //--------------------------------------------------------------- `package main import "b" type I4 interface { M4(_ struct { *string }) } var _ I4 = b.S{} `, `package b type S struct{} func (S) M4(struct { *string }) {} `, `6:12: cannot use b[.]S{} [(]value of type b[.]S[)] as I4 value in variable declaration: b[.]S does not implement I4 [(]wrong type for method M4[)] .*have M4[(]struct{[*]string /[*] package b [*]/ }[)] .*want M4[(]struct{[*]string /[*] package main [*]/ }[)]`}, { //--------------------------------------------------------------- `package main import "b" type t struct{ A int } type I5 interface { M5(_ struct {b.S;t}) } var _ I5 = b.S{} `, `package b type S struct{} type t struct{ A int } func (S) M5(struct {S;t}) {} `, `7:12: cannot use b[.]S{} [(]value of type b[.]S[)] as I5 value in variable declaration: b[.]S does not implement I5 [(]wrong type for method M5[)] .*have M5[(]struct{b[.]S; b[.]t}[)] .*want M5[(]struct{b[.]S; t}[)]`}, } fset := token.NewFileSet() test := func(main, b, want string) { re := regexp.MustCompile(want) bpkg := mustTypecheck(b, nil, nil) mast := mustParse(fset, main) conf := Config{Importer: importHelper{pkg: bpkg}} _, err := conf.Check(mast.Name.Name, fset, []*ast.File{mast}, nil) if err == nil { t.Error("Expected failure, but it did not") } else if got := err.Error(); !re.MatchString(got) { t.Errorf("Wanted match for\n\t%s\n but got\n\t%s", want, got) } else if testing.Verbose() { t.Logf("Saw expected\n\t%s", err.Error()) } } for _, t := range tests { test(t.main, t.b, t.want) } } func TestIssue59944(t *testing.T) { testenv.MustHaveCGO(t) // The typechecker should resolve methods declared on aliases of cgo types. const src = ` package p /* struct layout { int field; }; */ import "C" type Layout = C.struct_layout func (l *Layout) Binding() {} func _() { _ = (*Layout).Binding } ` // code generated by cmd/cgo for the above source. const cgoTypes = ` // Code generated by cmd/cgo; DO NOT EDIT. package p import "unsafe" import "syscall" import _cgopackage "runtime/cgo" type _ _cgopackage.Incomplete var _ syscall.Errno func _Cgo_ptr(ptr unsafe.Pointer) unsafe.Pointer { return ptr } //go:linkname _Cgo_always_false runtime.cgoAlwaysFalse var _Cgo_always_false bool //go:linkname _Cgo_use runtime.cgoUse func _Cgo_use(interface{}) type _Ctype_int int32 type _Ctype_struct_layout struct { field _Ctype_int } type _Ctype_void [0]byte //go:linkname _cgo_runtime_cgocall runtime.cgocall func _cgo_runtime_cgocall(unsafe.Pointer, uintptr) int32 //go:linkname _cgoCheckPointer runtime.cgoCheckPointer func _cgoCheckPointer(interface{}, interface{}) //go:linkname _cgoCheckResult runtime.cgoCheckResult func _cgoCheckResult(interface{}) ` testFiles(t, []string{"p.go", "_cgo_gotypes.go"}, [][]byte{[]byte(src), []byte(cgoTypes)}, false, func(cfg *Config) { *boolFieldAddr(cfg, "go115UsesCgo") = true }) } func TestIssue61931(t *testing.T) { const src = ` package p func A(func(any), ...any) {} func B[T any](T) {} func _() { A(B, nil // syntax error: missing ',' before newline in argument list } ` fset := token.NewFileSet() f, err := parser.ParseFile(fset, pkgName(src), src, 0) if err == nil { t.Fatal("expected syntax error") } var conf Config conf.Check(f.Name.Name, fset, []*ast.File{f}, nil) // must not panic } func TestIssue61938(t *testing.T) { const src = ` package p func f[T any]() {} func _() { f() } ` // no error handler provided (this issue) var conf Config typecheck(src, &conf, nil) // must not panic // with error handler (sanity check) conf.Error = func(error) {} typecheck(src, &conf, nil) // must not panic } func TestIssue63260(t *testing.T) { const src = ` package p func _() { use(f[*string]) } func use(func()) {} func f[I *T, T any]() { var v T _ = v }` info := Info{ Defs: make(map[*ast.Ident]Object), } pkg := mustTypecheck(src, nil, &info) // get type parameter T in signature of f T := pkg.Scope().Lookup("f").Type().(*Signature).TypeParams().At(1) if T.Obj().Name() != "T" { t.Fatalf("got type parameter %s, want T", T) } // get type of variable v in body of f var v Object for name, obj := range info.Defs { if name.Name == "v" { v = obj break } } if v == nil { t.Fatal("variable v not found") } // type of v and T must be pointer-identical if v.Type() != T { t.Fatalf("types of v and T are not pointer-identical: %p != %p", v.Type().(*TypeParam), T) } } func TestIssue44410(t *testing.T) { const src = ` package p type A = []int type S struct{ A } ` t.Setenv("GODEBUG", "gotypesalias=1") pkg := mustTypecheck(src, nil, nil) S := pkg.Scope().Lookup("S") if S == nil { t.Fatal("object S not found") } got := S.String() const want = "type p.S struct{p.A}" if got != want { t.Fatalf("got %q; want %q", got, want) } } func TestIssue59831(t *testing.T) { // Package a exports a type S with an unexported method m; // the tests check the error messages when m is not found. const asrc = `package a; type S struct{}; func (S) m() {}` apkg := mustTypecheck(asrc, nil, nil) // Package b exports a type S with an exported method m; // the tests check the error messages when M is not found. const bsrc = `package b; type S struct{}; func (S) M() {}` bpkg := mustTypecheck(bsrc, nil, nil) tests := []struct { imported *Package src, err string }{ // tests importing a (or nothing) {apkg, `package a1; import "a"; var _ interface { M() } = a.S{}`, "a.S does not implement interface{M()} (missing method M) have m() want M()"}, {apkg, `package a2; import "a"; var _ interface { m() } = a.S{}`, "a.S does not implement interface{m()} (unexported method m)"}, // test for issue {nil, `package a3; type S struct{}; func (S) m(); var _ interface { M() } = S{}`, "S does not implement interface{M()} (missing method M) have m() want M()"}, {nil, `package a4; type S struct{}; func (S) m(); var _ interface { m() } = S{}`, ""}, // no error expected {nil, `package a5; type S struct{}; func (S) m(); var _ interface { n() } = S{}`, "S does not implement interface{n()} (missing method n)"}, // tests importing b (or nothing) {bpkg, `package b1; import "b"; var _ interface { m() } = b.S{}`, "b.S does not implement interface{m()} (missing method m) have M() want m()"}, {bpkg, `package b2; import "b"; var _ interface { M() } = b.S{}`, ""}, // no error expected {nil, `package b3; type S struct{}; func (S) M(); var _ interface { M() } = S{}`, ""}, // no error expected {nil, `package b4; type S struct{}; func (S) M(); var _ interface { m() } = S{}`, "S does not implement interface{m()} (missing method m) have M() want m()"}, {nil, `package b5; type S struct{}; func (S) M(); var _ interface { n() } = S{}`, "S does not implement interface{n()} (missing method n)"}, } for _, test := range tests { // typecheck test source conf := Config{Importer: importHelper{pkg: test.imported}} pkg, err := typecheck(test.src, &conf, nil) if err == nil { if test.err != "" { t.Errorf("package %s: got no error, want %q", pkg.Name(), test.err) } continue } if test.err == "" { t.Errorf("package %s: got %q, want not error", pkg.Name(), err.Error()) } // flatten reported error message errmsg := strings.ReplaceAll(err.Error(), "\n", " ") errmsg = strings.ReplaceAll(errmsg, "\t", "") // verify error message if !strings.Contains(errmsg, test.err) { t.Errorf("package %s: got %q, want %q", pkg.Name(), errmsg, test.err) } } } func TestIssue64759(t *testing.T) { const src = ` //go:build go1.18 package p func f[S ~[]E, E any](S) {} func _() { f([]string{}) } ` // Per the go:build directive, the source must typecheck // even though the (module) Go version is set to go1.17. conf := Config{GoVersion: "go1.17"} mustTypecheck(src, &conf, nil) } func TestIssue68334(t *testing.T) { const src = ` package p func f(x int) { for i, j := range x { _, _ = i, j } var a, b int for a, b = range x { _, _ = a, b } } ` got := "" conf := Config{ GoVersion: "go1.21", // #68334 requires GoVersion <= 1.21 Error: func(err error) { got += err.Error() + "\n" }, // #68334 requires Error != nil } typecheck(src, &conf, nil) // do not crash want := "p:5:20: cannot range over x (variable of type int): requires go1.22 or later\n" + "p:9:19: cannot range over x (variable of type int): requires go1.22 or later\n" if got != want { t.Errorf("got: %s want: %s", got, want) } } func TestIssue68877(t *testing.T) { const src = ` package p type ( S struct{} A = S T A )` t.Setenv("GODEBUG", "gotypesalias=1") pkg := mustTypecheck(src, nil, nil) T := pkg.Scope().Lookup("T").(*TypeName) got := T.String() // this must not panic (was issue) const want = "type p.T struct{}" if got != want { t.Errorf("got %s, want %s", got, want) } }