// Copyright 2017 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. package ld import ( "debug/dwarf" "debug/pe" "fmt" "internal/platform" "internal/testenv" "io" "os" "path/filepath" "reflect" "runtime" "sort" "strconv" "strings" "testing" intdwarf "cmd/internal/dwarf" objfilepkg "cmd/internal/objfile" // renamed to avoid conflict with objfile function "cmd/link/internal/dwtest" ) func mustHaveDWARF(t testing.TB) { if !platform.ExecutableHasDWARF(runtime.GOOS, runtime.GOARCH) { t.Helper() t.Skipf("skipping on %s/%s: no DWARF symbol table in executables", runtime.GOOS, runtime.GOARCH) } } const ( DefaultOpt = "-gcflags=" NoOpt = "-gcflags=-l -N" OptInl4 = "-gcflags=-l=4" OptAllInl4 = "-gcflags=all=-l=4" ) func TestRuntimeTypesPresent(t *testing.T) { t.Parallel() testenv.MustHaveGoBuild(t) mustHaveDWARF(t) dir := t.TempDir() f := gobuild(t, dir, `package main; func main() { }`, NoOpt) defer f.Close() dwarf, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } want := map[string]bool{ "internal/abi.Type": true, "internal/abi.ArrayType": true, "internal/abi.ChanType": true, "internal/abi.FuncType": true, "internal/abi.PtrType": true, "internal/abi.SliceType": true, "internal/abi.StructType": true, "internal/abi.InterfaceType": true, "internal/abi.ITab": true, } found := findTypes(t, dwarf, want) if len(found) != len(want) { t.Errorf("found %v, want %v", found, want) } // Must have one of OldMapType or SwissMapType. want = map[string]bool{ "internal/abi.OldMapType": true, "internal/abi.SwissMapType": true, } found = findTypes(t, dwarf, want) if len(found) != 1 { t.Errorf("map type want one of %v found %v", want, found) } } func findTypes(t *testing.T, dw *dwarf.Data, want map[string]bool) (found map[string]bool) { found = make(map[string]bool) rdr := dw.Reader() for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } switch entry.Tag { case dwarf.TagTypedef: if name, ok := entry.Val(dwarf.AttrName).(string); ok && want[name] { found[name] = true } } } return } type builtFile struct { *objfilepkg.File path string } func gobuild(t *testing.T, dir string, testfile string, gcflags string) *builtFile { src := filepath.Join(dir, "test.go") dst := filepath.Join(dir, "out.exe") if err := os.WriteFile(src, []byte(testfile), 0666); err != nil { t.Fatal(err) } cmd := testenv.Command(t, testenv.GoToolPath(t), "build", gcflags, "-o", dst, src) b, err := cmd.CombinedOutput() if len(b) != 0 { t.Logf("## build output:\n%s", b) } if err != nil { t.Fatalf("build error: %v", err) } f, err := objfilepkg.Open(dst) if err != nil { t.Fatal(err) } return &builtFile{f, dst} } // Similar to gobuild() above, but uses a main package instead of a test.go file. func gobuildTestdata(t *testing.T, pkgDir string, gcflags string) *builtFile { dst := filepath.Join(t.TempDir(), "out.exe") // Run a build with an updated GOPATH cmd := testenv.Command(t, testenv.GoToolPath(t), "build", gcflags, "-o", dst) cmd.Dir = pkgDir if b, err := cmd.CombinedOutput(); err != nil { t.Logf("build: %s\n", b) t.Fatalf("build error: %v", err) } f, err := objfilepkg.Open(dst) if err != nil { t.Fatal(err) } return &builtFile{f, dst} } // Helper to build a snippet of source for examination with dwtest.Examiner. func gobuildAndExamine(t *testing.T, source string, gcflags string) (*dwarf.Data, *dwtest.Examiner) { dir := t.TempDir() f := gobuild(t, dir, source, gcflags) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF in program %q: %v", source, err) } rdr := d.Reader() ex := &dwtest.Examiner{} if err := ex.Populate(rdr); err != nil { t.Fatalf("error populating DWARF examiner for program %q: %v", source, err) } return d, ex } func findSubprogramDIE(t *testing.T, ex *dwtest.Examiner, sym string) *dwarf.Entry { dies := ex.Named(sym) if len(dies) == 0 { t.Fatalf("unable to locate DIE for %s", sym) } if len(dies) != 1 { t.Fatalf("more than one %s DIE: %+v", sym, dies) } die := dies[0] // Vet the DIE. if die.Tag != dwarf.TagSubprogram { t.Fatalf("unexpected tag %v on %s DIE", die.Tag, sym) } return die } func TestEmbeddedStructMarker(t *testing.T) { t.Parallel() testenv.MustHaveGoBuild(t) mustHaveDWARF(t) const prog = ` package main import "fmt" type Foo struct { v int } type Bar struct { Foo name string } type Baz struct { *Foo name string } func main() { bar := Bar{ Foo: Foo{v: 123}, name: "onetwothree"} baz := Baz{ Foo: &bar.Foo, name: "123" } fmt.Println(bar, baz) }` want := map[string]map[string]bool{ "main.Foo": {"v": false}, "main.Bar": {"Foo": true, "name": false}, "main.Baz": {"Foo": true, "name": false}, } dir := t.TempDir() f := gobuild(t, dir, prog, NoOpt) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } switch entry.Tag { case dwarf.TagStructType: name, ok := entry.Val(dwarf.AttrName).(string) if !ok { continue } wantMembers := want[name] if wantMembers == nil { continue } gotMembers, err := findMembers(rdr) if err != nil { t.Fatalf("error reading DWARF: %v", err) } if !reflect.DeepEqual(gotMembers, wantMembers) { t.Errorf("type %v: got map[member]embedded = %+v, want %+v", name, wantMembers, gotMembers) } delete(want, name) } } if len(want) != 0 { t.Errorf("failed to check all expected types: missing types = %+v", want) } } func findMembers(rdr *dwarf.Reader) (map[string]bool, error) { memberEmbedded := map[string]bool{} // TODO(hyangah): define in debug/dwarf package const goEmbeddedStruct = dwarf.Attr(intdwarf.DW_AT_go_embedded_field) for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { return nil, err } switch entry.Tag { case dwarf.TagMember: name := entry.Val(dwarf.AttrName).(string) embedded := entry.Val(goEmbeddedStruct).(bool) memberEmbedded[name] = embedded case 0: return memberEmbedded, nil } } return memberEmbedded, nil } func TestSizes(t *testing.T) { mustHaveDWARF(t) // External linking may bring in C symbols with unknown size. Skip. testenv.MustInternalLink(t, false) t.Parallel() // DWARF sizes should never be -1. // See issue #21097 const prog = ` package main var x func() var y [4]func() func main() { x = nil y[0] = nil } ` dir := t.TempDir() f := gobuild(t, dir, prog, NoOpt) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } switch entry.Tag { case dwarf.TagArrayType, dwarf.TagPointerType, dwarf.TagStructType, dwarf.TagBaseType, dwarf.TagSubroutineType, dwarf.TagTypedef: default: continue } typ, err := d.Type(entry.Offset) if err != nil { t.Fatalf("can't read type: %v", err) } if typ.Size() < 0 { t.Errorf("subzero size %s %s %T", typ, entry.Tag, typ) } } } func TestFieldOverlap(t *testing.T) { mustHaveDWARF(t) t.Parallel() // This test grew out of issue 21094, where specific sudog DWARF types // had elem fields set to values instead of pointers. const prog = ` package main var c chan string func main() { c <- "foo" } ` dir := t.TempDir() f := gobuild(t, dir, prog, NoOpt) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } if entry.Tag != dwarf.TagStructType { continue } typ, err := d.Type(entry.Offset) if err != nil { t.Fatalf("can't read type: %v", err) } s := typ.(*dwarf.StructType) for i := 0; i < len(s.Field); i++ { end := s.Field[i].ByteOffset + s.Field[i].Type.Size() var limit int64 if i == len(s.Field)-1 { limit = s.Size() } else { limit = s.Field[i+1].ByteOffset } if end > limit { name := entry.Val(dwarf.AttrName).(string) t.Fatalf("field %s.%s overlaps next field", name, s.Field[i].Name) } } } } func TestSubprogramDeclFileLine(t *testing.T) { testenv.MustHaveGoBuild(t) t.Parallel() mustHaveDWARF(t) const prog = `package main %s func main() {} ` tests := []struct { name string prog string file string line int64 }{ { name: "normal", prog: fmt.Sprintf(prog, ""), file: "test.go", line: 3, }, { name: "line-directive", prog: fmt.Sprintf(prog, "//line /foobar.go:200"), file: "foobar.go", line: 200, }, } for _, tc := range tests { tc := tc t.Run(tc.name, func(t *testing.T) { t.Parallel() d, ex := gobuildAndExamine(t, tc.prog, NoOpt) maindie := findSubprogramDIE(t, ex, "main.main") mainIdx := ex.IdxFromOffset(maindie.Offset) fileIdx, fileIdxOK := maindie.Val(dwarf.AttrDeclFile).(int64) if !fileIdxOK { t.Errorf("missing or invalid DW_AT_decl_file for main") } file, err := ex.FileRef(d, mainIdx, fileIdx) if err != nil { t.Fatalf("FileRef: %v", err) } base := filepath.Base(file) if base != tc.file { t.Errorf("DW_AT_decl_file for main is %v, want %v", base, tc.file) } line, lineOK := maindie.Val(dwarf.AttrDeclLine).(int64) if !lineOK { t.Errorf("missing or invalid DW_AT_decl_line for main") } if line != tc.line { t.Errorf("DW_AT_decl_line for main is %v, want %d", line, tc.line) } }) } } func TestVarDeclLine(t *testing.T) { testenv.MustHaveGoBuild(t) t.Parallel() mustHaveDWARF(t) const prog = `package main %s func main() { var i int i = i } ` tests := []struct { name string prog string line int64 }{ { name: "normal", prog: fmt.Sprintf(prog, ""), line: 5, }, { name: "line-directive", prog: fmt.Sprintf(prog, "//line /foobar.go:200"), line: 202, }, } for _, tc := range tests { tc := tc t.Run(tc.name, func(t *testing.T) { t.Parallel() _, ex := gobuildAndExamine(t, tc.prog, NoOpt) maindie := findSubprogramDIE(t, ex, "main.main") mainIdx := ex.IdxFromOffset(maindie.Offset) childDies := ex.Children(mainIdx) var iEntry *dwarf.Entry for _, child := range childDies { if child.Tag == dwarf.TagVariable && child.Val(dwarf.AttrName).(string) == "i" { iEntry = child break } } if iEntry == nil { t.Fatalf("didn't find DW_TAG_variable for i in main.main") } // Verify line/file attributes. line, lineOK := iEntry.Val(dwarf.AttrDeclLine).(int64) if !lineOK { t.Errorf("missing or invalid DW_AT_decl_line for i") } if line != tc.line { t.Errorf("DW_AT_decl_line for i is %v, want %d", line, tc.line) } }) } } // TestInlinedRoutineCallFileLine tests the call file and line records for an // inlined subroutine. func TestInlinedRoutineCallFileLine(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() const prog = ` package main var G int //go:noinline func notinlined() int { return 42 } func inlined() int { return notinlined() } %s func main() { x := inlined() G = x } ` tests := []struct { name string prog string file string // basename line int64 }{ { name: "normal", prog: fmt.Sprintf(prog, ""), file: "test.go", line: 17, }, { name: "line-directive", prog: fmt.Sprintf(prog, "//line /foobar.go:200"), file: "foobar.go", line: 201, }, } for _, tc := range tests { tc := tc t.Run(tc.name, func(t *testing.T) { t.Parallel() // Note: this is a build with "-l=4", as opposed to "-l -N". The // test is intended to verify DWARF that is only generated when // the inliner is active. We're only going to look at the DWARF for // main.main, however, hence we build with "-gcflags=-l=4" as opposed // to "-gcflags=all=-l=4". d, ex := gobuildAndExamine(t, tc.prog, OptInl4) maindie := findSubprogramDIE(t, ex, "main.main") // Walk main's children and pick out the inlined subroutines mainIdx := ex.IdxFromOffset(maindie.Offset) childDies := ex.Children(mainIdx) found := false for _, child := range childDies { if child.Tag != dwarf.TagInlinedSubroutine { continue } // Found an inlined subroutine. if found { t.Fatalf("Found multiple inlined subroutines, expect only one") } found = true // Locate abstract origin. ooff, originOK := child.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset) if !originOK { t.Fatalf("no abstract origin attr for inlined subroutine at offset %v", child.Offset) } originDIE := ex.EntryFromOffset(ooff) if originDIE == nil { t.Fatalf("can't locate origin DIE at off %v", ooff) } // Name should check out. name, ok := originDIE.Val(dwarf.AttrName).(string) if !ok { t.Fatalf("no name attr for inlined subroutine at offset %v", child.Offset) } if name != "main.inlined" { t.Fatalf("expected inlined routine %s got %s", "main.cand", name) } // Verify that the call_file attribute for the inlined // instance is ok. In this case it should match the file // for the main routine. To do this we need to locate the // compilation unit DIE that encloses what we're looking // at; this can be done with the examiner. cf, cfOK := child.Val(dwarf.AttrCallFile).(int64) if !cfOK { t.Fatalf("no call_file attr for inlined subroutine at offset %v", child.Offset) } file, err := ex.FileRef(d, mainIdx, cf) if err != nil { t.Errorf("FileRef: %v", err) continue } base := filepath.Base(file) if base != tc.file { t.Errorf("bad call_file attribute, found '%s', want '%s'", file, tc.file) } // Verify that the call_line attribute for the inlined // instance is ok. cl, clOK := child.Val(dwarf.AttrCallLine).(int64) if !clOK { t.Fatalf("no call_line attr for inlined subroutine at offset %v", child.Offset) } if cl != tc.line { t.Errorf("bad call_line attribute, found %d, want %d", cl, tc.line) } } if !found { t.Fatalf("not enough inlined subroutines found in main.main") } }) } } // TestInlinedRoutineArgsVars tests the argument and variable records for an inlined subroutine. func TestInlinedRoutineArgsVars(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() const prog = ` package main var G int func noinline(x int) int { defer func() { G += x }() return x } func cand(x, y int) int { return noinline(x+y) ^ (y - x) } func main() { x := cand(G*G,G|7%G) G = x } ` // Note: this is a build with "-l=4", as opposed to "-l -N". The // test is intended to verify DWARF that is only generated when // the inliner is active. We're only going to look at the DWARF for // main.main, however, hence we build with "-gcflags=-l=4" as opposed // to "-gcflags=all=-l=4". _, ex := gobuildAndExamine(t, prog, OptInl4) maindie := findSubprogramDIE(t, ex, "main.main") // Walk main's children and pick out the inlined subroutines mainIdx := ex.IdxFromOffset(maindie.Offset) childDies := ex.Children(mainIdx) found := false for _, child := range childDies { if child.Tag != dwarf.TagInlinedSubroutine { continue } // Found an inlined subroutine. if found { t.Fatalf("Found multiple inlined subroutines, expect only one") } found = true // Locate abstract origin. ooff, originOK := child.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset) if !originOK { t.Fatalf("no abstract origin attr for inlined subroutine at offset %v", child.Offset) } originDIE := ex.EntryFromOffset(ooff) if originDIE == nil { t.Fatalf("can't locate origin DIE at off %v", ooff) } // Name should check out. name, ok := originDIE.Val(dwarf.AttrName).(string) if !ok { t.Fatalf("no name attr for inlined subroutine at offset %v", child.Offset) } if name != "main.cand" { t.Fatalf("expected inlined routine %s got %s", "main.cand", name) } // Walk the children of the abstract subroutine. We expect // to see child variables there, even if (perhaps due to // optimization) there are no references to them from the // inlined subroutine DIE. absFcnIdx := ex.IdxFromOffset(ooff) absFcnChildDies := ex.Children(absFcnIdx) if len(absFcnChildDies) != 2 { t.Fatalf("expected abstract function: expected 2 children, got %d children", len(absFcnChildDies)) } formalCount := 0 for _, absChild := range absFcnChildDies { if absChild.Tag == dwarf.TagFormalParameter { formalCount += 1 continue } t.Fatalf("abstract function child DIE: expected formal, got %v", absChild.Tag) } if formalCount != 2 { t.Fatalf("abstract function DIE: expected 2 formals, got %d", formalCount) } omap := make(map[dwarf.Offset]bool) // Walk the child variables of the inlined routine. Each // of them should have a distinct abstract origin-- if two // vars point to the same origin things are definitely broken. inlIdx := ex.IdxFromOffset(child.Offset) inlChildDies := ex.Children(inlIdx) for _, k := range inlChildDies { ooff, originOK := k.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset) if !originOK { t.Fatalf("no abstract origin attr for child of inlined subroutine at offset %v", k.Offset) } if _, found := omap[ooff]; found { t.Fatalf("duplicate abstract origin at child of inlined subroutine at offset %v", k.Offset) } omap[ooff] = true } } if !found { t.Fatalf("not enough inlined subroutines found in main.main") } } func abstractOriginSanity(t *testing.T, pkgDir string, flags string) { t.Parallel() // Build with inlining, to exercise DWARF inlining support. f := gobuildTestdata(t, filepath.Join(pkgDir, "main"), flags) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() ex := dwtest.Examiner{} if err := ex.Populate(rdr); err != nil { t.Fatalf("error reading DWARF: %v", err) } // Make a pass through all DIEs looking for abstract origin // references. abscount := 0 for i, die := range ex.DIEs() { // Does it have an abstract origin? ooff, originOK := die.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset) if !originOK { continue } // All abstract origin references should be resolvable. abscount += 1 originDIE := ex.EntryFromOffset(ooff) if originDIE == nil { ex.DumpEntry(i, false, 0) t.Fatalf("unresolved abstract origin ref in DIE at offset 0x%x\n", die.Offset) } // Suppose that DIE X has parameter/variable children {K1, // K2, ... KN}. If X has an abstract origin of A, then for // each KJ, the abstract origin of KJ should be a child of A. // Note that this same rule doesn't hold for non-variable DIEs. pidx := ex.IdxFromOffset(die.Offset) if pidx < 0 { t.Fatalf("can't locate DIE id") } kids := ex.Children(pidx) for _, kid := range kids { if kid.Tag != dwarf.TagVariable && kid.Tag != dwarf.TagFormalParameter { continue } kooff, originOK := kid.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset) if !originOK { continue } childOriginDIE := ex.EntryFromOffset(kooff) if childOriginDIE == nil { ex.DumpEntry(i, false, 0) t.Fatalf("unresolved abstract origin ref in DIE at offset %x", kid.Offset) } coidx := ex.IdxFromOffset(childOriginDIE.Offset) childOriginParent := ex.Parent(coidx) if childOriginParent != originDIE { ex.DumpEntry(i, false, 0) t.Fatalf("unexpected parent of abstract origin DIE at offset %v", childOriginDIE.Offset) } } } if abscount == 0 { t.Fatalf("no abstract origin refs found, something is wrong") } } func TestAbstractOriginSanity(t *testing.T) { testenv.MustHaveGoBuild(t) if testing.Short() { t.Skip("skipping test in short mode.") } mustHaveDWARF(t) abstractOriginSanity(t, "testdata/httptest", OptAllInl4) } func TestAbstractOriginSanityIssue25459(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) if runtime.GOARCH != "amd64" && runtime.GOARCH != "386" { t.Skip("skipping on not-amd64 not-386; location lists not supported") } abstractOriginSanity(t, "testdata/issue25459", DefaultOpt) } func TestAbstractOriginSanityIssue26237(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) abstractOriginSanity(t, "testdata/issue26237", DefaultOpt) } func TestRuntimeTypeAttrInternal(t *testing.T) { testenv.MustHaveGoBuild(t) testenv.MustInternalLink(t, false) mustHaveDWARF(t) testRuntimeTypeAttr(t, "-ldflags=-linkmode=internal") } // External linking requires a host linker (https://golang.org/src/cmd/cgo/doc.go l.732) func TestRuntimeTypeAttrExternal(t *testing.T) { testenv.MustHaveGoBuild(t) testenv.MustHaveCGO(t) mustHaveDWARF(t) // Explicitly test external linking, for dsymutil compatibility on Darwin. if runtime.GOARCH == "ppc64" { t.Skip("-linkmode=external not supported on ppc64") } testRuntimeTypeAttr(t, "-ldflags=-linkmode=external") } func testRuntimeTypeAttr(t *testing.T, flags string) { t.Parallel() const prog = ` package main import "unsafe" type X struct{ _ int } func main() { var x interface{} = &X{} p := *(*uintptr)(unsafe.Pointer(&x)) print(p) } ` dir := t.TempDir() f := gobuild(t, dir, prog, flags) defer f.Close() out, err := testenv.Command(t, f.path).CombinedOutput() if err != nil { t.Fatalf("could not run test program: %v", err) } addr, err := strconv.ParseUint(string(out), 10, 64) if err != nil { t.Fatalf("could not parse type address from program output %q: %v", out, err) } symbols, err := f.Symbols() if err != nil { t.Fatalf("error reading symbols: %v", err) } var types *objfilepkg.Sym for _, sym := range symbols { if sym.Name == "runtime.types" { types = &sym break } } if types == nil { t.Fatal("couldn't find runtime.types in symbols") } d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() ex := dwtest.Examiner{} if err := ex.Populate(rdr); err != nil { t.Fatalf("error reading DWARF: %v", err) } dies := ex.Named("*main.X") if len(dies) != 1 { t.Fatalf("wanted 1 DIE named *main.X, found %v", len(dies)) } rtAttr := dies[0].Val(intdwarf.DW_AT_go_runtime_type) if rtAttr == nil { t.Fatalf("*main.X DIE had no runtime type attr. DIE: %v", dies[0]) } if platform.DefaultPIE(runtime.GOOS, runtime.GOARCH, false) { return // everything is PIE, addresses are relocated } if rtAttr.(uint64)+types.Addr != addr { t.Errorf("DWARF type offset was %#x+%#x, but test program said %#x", rtAttr.(uint64), types.Addr, addr) } } func TestIssue27614(t *testing.T) { // Type references in debug_info should always use the DW_TAG_typedef_type // for the type, when that's generated. testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() dir := t.TempDir() const prog = `package main import "fmt" type astruct struct { X int } type bstruct struct { X float32 } var globalptr *astruct var globalvar astruct var bvar0, bvar1, bvar2 bstruct func main() { fmt.Println(globalptr, globalvar, bvar0, bvar1, bvar2) } ` f := gobuild(t, dir, prog, NoOpt) defer f.Close() data, err := f.DWARF() if err != nil { t.Fatal(err) } rdr := data.Reader() var astructTypeDIE, bstructTypeDIE, ptrastructTypeDIE *dwarf.Entry var globalptrDIE, globalvarDIE *dwarf.Entry var bvarDIE [3]*dwarf.Entry for { e, err := rdr.Next() if err != nil { t.Fatal(err) } if e == nil { break } name, _ := e.Val(dwarf.AttrName).(string) switch e.Tag { case dwarf.TagTypedef: switch name { case "main.astruct": astructTypeDIE = e case "main.bstruct": bstructTypeDIE = e } case dwarf.TagPointerType: if name == "*main.astruct" { ptrastructTypeDIE = e } case dwarf.TagVariable: switch name { case "main.globalptr": globalptrDIE = e case "main.globalvar": globalvarDIE = e default: const bvarprefix = "main.bvar" if strings.HasPrefix(name, bvarprefix) { i, _ := strconv.Atoi(name[len(bvarprefix):]) bvarDIE[i] = e } } } } typedieof := func(e *dwarf.Entry) dwarf.Offset { return e.Val(dwarf.AttrType).(dwarf.Offset) } if off := typedieof(ptrastructTypeDIE); off != astructTypeDIE.Offset { t.Errorf("type attribute of *main.astruct references %#x, not main.astruct DIE at %#x\n", off, astructTypeDIE.Offset) } if off := typedieof(globalptrDIE); off != ptrastructTypeDIE.Offset { t.Errorf("type attribute of main.globalptr references %#x, not *main.astruct DIE at %#x\n", off, ptrastructTypeDIE.Offset) } if off := typedieof(globalvarDIE); off != astructTypeDIE.Offset { t.Errorf("type attribute of main.globalvar1 references %#x, not main.astruct DIE at %#x\n", off, astructTypeDIE.Offset) } for i := range bvarDIE { if off := typedieof(bvarDIE[i]); off != bstructTypeDIE.Offset { t.Errorf("type attribute of main.bvar%d references %#x, not main.bstruct DIE at %#x\n", i, off, bstructTypeDIE.Offset) } } } func TestStaticTmp(t *testing.T) { // Checks that statictmp variables do not appear in debug_info or the // symbol table. // Also checks that statictmp variables do not collide with user defined // variables (issue #25113) testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() dir := t.TempDir() const prog = `package main var stmp_0 string var a []int func init() { a = []int{ 7 } } func main() { println(a[0]) } ` f := gobuild(t, dir, prog, NoOpt) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() for { e, err := rdr.Next() if err != nil { t.Fatal(err) } if e == nil { break } if e.Tag != dwarf.TagVariable { continue } name, ok := e.Val(dwarf.AttrName).(string) if !ok { continue } if strings.Contains(name, "stmp") { t.Errorf("statictmp variable found in debug_info: %s at %x", name, e.Offset) } } // When external linking, we put all symbols in the symbol table (so the // external linker can find them). Skip the symbol table check. // TODO: maybe there is some way to tell the external linker not to put // those symbols in the executable's symbol table? Prefix the symbol name // with "." or "L" to pretend it is a label? if !testenv.CanInternalLink(false) { return } syms, err := f.Symbols() if err != nil { t.Fatalf("error reading symbols: %v", err) } for _, sym := range syms { if strings.Contains(sym.Name, "stmp") { t.Errorf("statictmp variable found in symbol table: %s", sym.Name) } } } func TestPackageNameAttr(t *testing.T) { const dwarfAttrGoPackageName = dwarf.Attr(0x2905) const dwarfGoLanguage = 22 testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() dir := t.TempDir() const prog = "package main\nfunc main() {\nprintln(\"hello world\")\n}\n" f := gobuild(t, dir, prog, NoOpt) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() runtimeUnitSeen := false for { e, err := rdr.Next() if err != nil { t.Fatal(err) } if e == nil { break } if e.Tag != dwarf.TagCompileUnit { continue } if lang, _ := e.Val(dwarf.AttrLanguage).(int64); lang != dwarfGoLanguage { continue } pn, ok := e.Val(dwarfAttrGoPackageName).(string) if !ok { name, _ := e.Val(dwarf.AttrName).(string) t.Errorf("found compile unit without package name: %s", name) } if pn == "" { name, _ := e.Val(dwarf.AttrName).(string) t.Errorf("found compile unit with empty package name: %s", name) } else { if pn == "runtime" { runtimeUnitSeen = true } } } // Something is wrong if there's no runtime compilation unit. if !runtimeUnitSeen { t.Errorf("no package name for runtime unit") } } func TestMachoIssue32233(t *testing.T) { testenv.MustHaveGoBuild(t) testenv.MustHaveCGO(t) if runtime.GOOS != "darwin" { t.Skip("skipping; test only interesting on darwin") } f := gobuildTestdata(t, "testdata/issue32233/main", DefaultOpt) f.Close() } func TestWindowsIssue36495(t *testing.T) { testenv.MustHaveGoBuild(t) if runtime.GOOS != "windows" { t.Skip("skipping: test only on windows") } dir := t.TempDir() prog := ` package main import "fmt" func main() { fmt.Println("Hello World") }` f := gobuild(t, dir, prog, NoOpt) defer f.Close() exe, err := pe.Open(f.path) if err != nil { t.Fatalf("error opening pe file: %v", err) } defer exe.Close() dw, err := exe.DWARF() if err != nil { t.Fatalf("error parsing DWARF: %v", err) } rdr := dw.Reader() for { e, err := rdr.Next() if err != nil { t.Fatalf("error reading DWARF: %v", err) } if e == nil { break } if e.Tag != dwarf.TagCompileUnit { continue } lnrdr, err := dw.LineReader(e) if err != nil { t.Fatalf("error creating DWARF line reader: %v", err) } if lnrdr != nil { var lne dwarf.LineEntry for { err := lnrdr.Next(&lne) if err == io.EOF { break } if err != nil { t.Fatalf("error reading next DWARF line: %v", err) } if strings.Contains(lne.File.Name, `\`) { t.Errorf("filename should not contain backslash: %v", lne.File.Name) } } } rdr.SkipChildren() } } func TestIssue38192(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() // Build a test program that contains a translation unit whose // text (from am assembly source) contains only a single instruction. f := gobuildTestdata(t, "testdata/issue38192", DefaultOpt) defer f.Close() // Open the resulting binary and examine the DWARF it contains. // Look for the function of interest ("main.singleInstruction") // and verify that the line table has an entry not just for the // single instruction but also a dummy instruction following it, // so as to test that whoever is emitting the DWARF doesn't // emit an end-sequence op immediately after the last instruction // in the translation unit. // // NB: another way to write this test would have been to run the // resulting executable under GDB, set a breakpoint in // "main.singleInstruction", then verify that GDB displays the // correct line/file information. Given the headache and flakiness // associated with GDB-based tests these days, a direct read of // the line table seems more desirable. rows := []dwarf.LineEntry{} dw, err := f.DWARF() if err != nil { t.Fatalf("error parsing DWARF: %v", err) } rdr := dw.Reader() for { e, err := rdr.Next() if err != nil { t.Fatalf("error reading DWARF: %v", err) } if e == nil { break } if e.Tag != dwarf.TagCompileUnit { continue } // NB: there can be multiple compile units named "main". name := e.Val(dwarf.AttrName).(string) if name != "main" { continue } lnrdr, err := dw.LineReader(e) if err != nil { t.Fatalf("error creating DWARF line reader: %v", err) } if lnrdr != nil { var lne dwarf.LineEntry for { err := lnrdr.Next(&lne) if err == io.EOF { break } if err != nil { t.Fatalf("error reading next DWARF line: %v", err) } if !strings.HasSuffix(lne.File.Name, "ld/testdata/issue38192/oneline.s") { continue } rows = append(rows, lne) } } rdr.SkipChildren() } f.Close() // Make sure that: // - main.singleInstruction appears in the line table // - more than one PC value appears the line table for // that compilation unit. // - at least one row has the correct line number (8) pcs := make(map[uint64]bool) line8seen := false for _, r := range rows { pcs[r.Address] = true if r.Line == 8 { line8seen = true } } failed := false if len(pcs) < 2 { failed = true t.Errorf("not enough line table rows for main.singleInstruction (got %d, wanted > 1", len(pcs)) } if !line8seen { failed = true t.Errorf("line table does not contain correct line for main.singleInstruction") } if !failed { return } for i, r := range rows { t.Logf("row %d: A=%x F=%s L=%d\n", i, r.Address, r.File.Name, r.Line) } } func TestIssue39757(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() // In this bug the DWARF line table contents for the last couple of // instructions in a function were incorrect (bad file/line). This // test verifies that all of the line table rows for a function // of interest have the same file (no "autogenerated"). // // Note: the function in this test was written with an eye towards // ensuring that there are no inlined routines from other packages // (which could introduce other source files into the DWARF); it's // possible that at some point things could evolve in the // compiler/runtime in ways that aren't happening now, so this // might be something to check for if it does start failing. f := gobuildTestdata(t, "testdata/issue39757", DefaultOpt) defer f.Close() syms, err := f.Symbols() if err != nil { t.Fatal(err) } var addr uint64 for _, sym := range syms { if sym.Name == "main.main" { addr = sym.Addr break } } if addr == 0 { t.Fatal("cannot find main.main in symbols") } // Open the resulting binary and examine the DWARF it contains. // Look for the function of interest ("main.main") // and verify that all line table entries show the same source // file. dw, err := f.DWARF() if err != nil { t.Fatalf("error parsing DWARF: %v", err) } rdr := dw.Reader() ex := &dwtest.Examiner{} if err := ex.Populate(rdr); err != nil { t.Fatalf("error reading DWARF: %v", err) } maindie := findSubprogramDIE(t, ex, "main.main") // Collect the start/end PC for main.main lowpc := maindie.Val(dwarf.AttrLowpc).(uint64) highpc := maindie.Val(dwarf.AttrHighpc).(uint64) // Now read the line table for the 'main' compilation unit. mainIdx := ex.IdxFromOffset(maindie.Offset) cuentry := ex.Parent(mainIdx) if cuentry == nil { t.Fatalf("main.main DIE appears orphaned") } lnrdr, lerr := dw.LineReader(cuentry) if lerr != nil { t.Fatalf("error creating DWARF line reader: %v", err) } if lnrdr == nil { t.Fatalf("no line table for main.main compilation unit") } rows := []dwarf.LineEntry{} mainrows := 0 var lne dwarf.LineEntry for { err := lnrdr.Next(&lne) if err == io.EOF { break } rows = append(rows, lne) if err != nil { t.Fatalf("error reading next DWARF line: %v", err) } if lne.Address < lowpc || lne.Address > highpc { continue } if !strings.HasSuffix(lne.File.Name, "issue39757main.go") { t.Errorf("found row with file=%s (not issue39757main.go)", lne.File.Name) } mainrows++ } f.Close() // Make sure we saw a few rows. if mainrows < 3 { t.Errorf("not enough line table rows for main.main (got %d, wanted > 3", mainrows) for i, r := range rows { t.Logf("row %d: A=%x F=%s L=%d\n", i, r.Address, r.File.Name, r.Line) } } } func TestIssue42484(t *testing.T) { testenv.MustHaveGoBuild(t) testenv.MustInternalLink(t, false) // Avoid spurious failures from external linkers. mustHaveDWARF(t) t.Parallel() f := gobuildTestdata(t, "testdata/issue42484", NoOpt) var lastAddr uint64 var lastFile string var lastLine int dw, err := f.DWARF() if err != nil { t.Fatalf("error parsing DWARF: %v", err) } rdr := dw.Reader() for { e, err := rdr.Next() if err != nil { t.Fatalf("error reading DWARF: %v", err) } if e == nil { break } if e.Tag != dwarf.TagCompileUnit { continue } lnrdr, err := dw.LineReader(e) if err != nil { t.Fatalf("error creating DWARF line reader: %v", err) } if lnrdr != nil { var lne dwarf.LineEntry for { err := lnrdr.Next(&lne) if err == io.EOF { break } if err != nil { t.Fatalf("error reading next DWARF line: %v", err) } if lne.EndSequence { continue } if lne.Address == lastAddr && (lne.File.Name != lastFile || lne.Line != lastLine) { t.Errorf("address %#x is assigned to both %s:%d and %s:%d", lastAddr, lastFile, lastLine, lne.File.Name, lne.Line) } lastAddr = lne.Address lastFile = lne.File.Name lastLine = lne.Line } } rdr.SkipChildren() } f.Close() } // processParams examines the formal parameter children of subprogram // DIE "die" using the explorer "ex" and returns a string that // captures the name, order, and classification of the subprogram's // input and output parameters. For example, for the go function // // func foo(i1 int, f1 float64) (string, bool) { // // this function would return a string something like // // i1:0:1 f1:1:1 ~r0:2:2 ~r1:3:2 // // where each chunk above is of the form NAME:ORDER:INOUTCLASSIFICATION func processParams(die *dwarf.Entry, ex *dwtest.Examiner) string { // Values in the returned map are of the form : // where order is the order within the child DIE list of the // param, and is an integer: // // -1: varparm attr not found // 1: varparm found with value false // 2: varparm found with value true // foundParams := make(map[string]string) // Walk the subprogram DIE's children looking for params. pIdx := ex.IdxFromOffset(die.Offset) childDies := ex.Children(pIdx) idx := 0 for _, child := range childDies { if child.Tag == dwarf.TagFormalParameter { // NB: a setting of DW_AT_variable_parameter indicates // that the param in question is an output parameter; we // want to see this attribute set to TRUE for all Go // return params. It would be OK to have it missing for // input parameters, but for the moment we verify that the // attr is present but set to false. st := -1 if vp, ok := child.Val(dwarf.AttrVarParam).(bool); ok { if vp { st = 2 } else { st = 1 } } if name, ok := child.Val(dwarf.AttrName).(string); ok { foundParams[name] = fmt.Sprintf("%d:%d", idx, st) idx++ } } } found := make([]string, 0, len(foundParams)) for k, v := range foundParams { found = append(found, fmt.Sprintf("%s:%s", k, v)) } sort.Strings(found) return fmt.Sprintf("%+v", found) } func TestOutputParamAbbrevAndAttr(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() // This test verifies that the compiler is selecting the correct // DWARF abbreviation for output parameters, and that the // variable parameter attribute is correct for in-params and // out-params. const prog = ` package main //go:noinline func ABC(c1, c2, c3 int, d1, d2, d3, d4 string, f1, f2, f3 float32, g1 [1024]int) (r1 int, r2 int, r3 [1024]int, r4 byte, r5 string, r6 float32) { g1[0] = 6 r1, r2, r3, r4, r5, r6 = c3, c2+c1, g1, 'a', d1+d2+d3+d4, f1+f2+f3 return } func main() { a := [1024]int{} v1, v2, v3, v4, v5, v6 := ABC(1, 2, 3, "a", "b", "c", "d", 1.0, 2.0, 1.0, a) println(v1, v2, v3[0], v4, v5, v6) } ` _, ex := gobuildAndExamine(t, prog, NoOpt) abcdie := findSubprogramDIE(t, ex, "main.ABC") // Call a helper to collect param info. found := processParams(abcdie, ex) // Make sure we see all of the expected params in the proper // order, that they have the varparam attr, and the varparam is // set for the returns. expected := "[c1:0:1 c2:1:1 c3:2:1 d1:3:1 d2:4:1 d3:5:1 d4:6:1 f1:7:1 f2:8:1 f3:9:1 g1:10:1 r1:11:2 r2:12:2 r3:13:2 r4:14:2 r5:15:2 r6:16:2]" if found != expected { t.Errorf("param check failed, wanted:\n%s\ngot:\n%s\n", expected, found) } } func TestDictIndex(t *testing.T) { // Check that variables with a parametric type have a dictionary index // attribute and that types that are only referenced through dictionaries // have DIEs. testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() const prog = ` package main import "fmt" type CustomInt int func testfn[T any](arg T) { var mapvar = make(map[int]T) mapvar[0] = arg fmt.Println(arg, mapvar) } func main() { testfn(CustomInt(3)) } ` dir := t.TempDir() f := gobuild(t, dir, prog, NoOpt) defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() found := false for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } name, _ := entry.Val(dwarf.AttrName).(string) if strings.HasPrefix(name, "main.testfn") { found = true break } } if !found { t.Fatalf("could not find main.testfn") } offs := []dwarf.Offset{} for entry, err := rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } if entry.Tag == 0 { break } name, _ := entry.Val(dwarf.AttrName).(string) switch name { case "arg", "mapvar": offs = append(offs, entry.Val(dwarf.AttrType).(dwarf.Offset)) } } if len(offs) != 2 { t.Errorf("wrong number of variables found in main.testfn %d", len(offs)) } for _, off := range offs { rdr.Seek(off) entry, err := rdr.Next() if err != nil { t.Fatalf("error reading DWARF: %v", err) } if _, ok := entry.Val(intdwarf.DW_AT_go_dict_index).(int64); !ok { t.Errorf("could not find DW_AT_go_dict_index attribute offset %#x (%T)", off, entry.Val(intdwarf.DW_AT_go_dict_index)) } } rdr.Seek(0) ex := dwtest.Examiner{} if err := ex.Populate(rdr); err != nil { t.Fatalf("error reading DWARF: %v", err) } for _, typeName := range []string{"main.CustomInt", "map[int]main.CustomInt"} { dies := ex.Named(typeName) if len(dies) != 1 { t.Errorf("wanted 1 DIE named %s, found %v", typeName, len(dies)) } if dies[0].Val(intdwarf.DW_AT_go_runtime_type).(uint64) == 0 { t.Errorf("type %s does not have DW_AT_go_runtime_type", typeName) } } } func TestOptimizedOutParamHandling(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() // This test is intended to verify that the compiler emits DWARF // DIE entries for all input and output parameters, and that: // // - attributes are set correctly for output params, // - things appear in the proper order // - things work properly for both register-resident // params and params passed on the stack // - things work for both referenced and unreferenced params // - things work for named return values un-named return vals // // The scenarios below don't cover all possible permutations and // combinations, but they hit a bunch of the high points. const prog = ` package main // First testcase. All input params in registers, all params used. //go:noinline func tc1(p1, p2 int, p3 string) (int, string) { return p1 + p2, p3 + "foo" } // Second testcase. Some params in registers, some on stack. //go:noinline func tc2(p1 int, p2 [128]int, p3 string) (int, string, [128]int) { return p1 + p2[p1], p3 + "foo", [128]int{p1} } // Third testcase. Named return params. //go:noinline func tc3(p1 int, p2 [128]int, p3 string) (r1 int, r2 bool, r3 string, r4 [128]int) { if p1 == 101 { r1 = p1 + p2[p1] r2 = p3 == "foo" r4 = [128]int{p1} return } else { return p1 - p2[p1+3], false, "bar", [128]int{p1 + 2} } } // Fourth testcase. Some thing are used, some are unused. //go:noinline func tc4(p1, p1un int, p2, p2un [128]int, p3, p3un string) (r1 int, r1un int, r2 bool, r3 string, r4, r4un [128]int) { if p1 == 101 { r1 = p1 + p2[p2[0]] r2 = p3 == "foo" r4 = [128]int{p1} return } else { return p1, -1, true, "plex", [128]int{p1 + 2}, [128]int{-1} } } func main() { { r1, r2 := tc1(3, 4, "five") println(r1, r2) } { x := [128]int{9} r1, r2, r3 := tc2(3, x, "five") println(r1, r2, r3[0]) } { x := [128]int{9} r1, r2, r3, r4 := tc3(3, x, "five") println(r1, r2, r3, r4[0]) } { x := [128]int{3} y := [128]int{7} r1, r1u, r2, r3, r4, r4u := tc4(0, 1, x, y, "a", "b") println(r1, r1u, r2, r3, r4[0], r4u[1]) } } ` _, ex := gobuildAndExamine(t, prog, DefaultOpt) testcases := []struct { tag string expected string }{ { tag: "tc1", expected: "[p1:0:1 p2:1:1 p3:2:1 ~r0:3:2 ~r1:4:2]", }, { tag: "tc2", expected: "[p1:0:1 p2:1:1 p3:2:1 ~r0:3:2 ~r1:4:2 ~r2:5:2]", }, { tag: "tc3", expected: "[p1:0:1 p2:1:1 p3:2:1 r1:3:2 r2:4:2 r3:5:2 r4:6:2]", }, { tag: "tc4", expected: "[p1:0:1 p1un:1:1 p2:2:1 p2un:3:1 p3:4:1 p3un:5:1 r1:6:2 r1un:7:2 r2:8:2 r3:9:2 r4:10:2 r4un:11:2]", }, } for _, tc := range testcases { // Locate the proper DIE which := fmt.Sprintf("main.%s", tc.tag) die := findSubprogramDIE(t, ex, which) // Examine params for this subprogram. foundParams := processParams(die, ex) if foundParams != tc.expected { t.Errorf("check failed for testcase %s -- wanted:\n%s\ngot:%s\n", tc.tag, tc.expected, foundParams) } } } func TestIssue54320(t *testing.T) { // Check that when trampolines are used, the DWARF LPT is correctly // emitted in the final binary testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() const prog = ` package main import "fmt" func main() { fmt.Printf("Hello world\n"); } ` dir := t.TempDir() f := gobuild(t, dir, prog, "-ldflags=-debugtramp=2") defer f.Close() d, err := f.DWARF() if err != nil { t.Fatalf("error reading DWARF: %v", err) } rdr := d.Reader() found := false var entry *dwarf.Entry for entry, err = rdr.Next(); entry != nil; entry, err = rdr.Next() { if err != nil { t.Fatalf("error reading DWARF: %v", err) } if entry.Tag != dwarf.TagCompileUnit { continue } name, _ := entry.Val(dwarf.AttrName).(string) if name == "main" { found = true break } rdr.SkipChildren() } if !found { t.Fatalf("could not find main compile unit") } lr, err := d.LineReader(entry) if err != nil { t.Fatalf("error obtaining linereader: %v", err) } var le dwarf.LineEntry found = false for { if err := lr.Next(&le); err != nil { if err == io.EOF { break } t.Fatalf("error reading linentry: %v", err) } // check LE contains an entry to test.go if le.File == nil { continue } file := filepath.Base(le.File.Name) if file == "test.go" { found = true break } } if !found { t.Errorf("no LPT entries for test.go") } } const zeroSizedVarProg = ` package main import ( "fmt" ) func main() { zeroSizedVariable := struct{}{} fmt.Println(zeroSizedVariable) } ` func TestZeroSizedVariable(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() if testing.Short() { t.Skip("skipping test in short mode.") } // This test verifies that the compiler emits DIEs for zero sized variables // (for example variables of type 'struct {}'). // See go.dev/issues/54615. for _, opt := range []string{NoOpt, DefaultOpt} { opt := opt t.Run(opt, func(t *testing.T) { _, ex := gobuildAndExamine(t, zeroSizedVarProg, opt) // Locate the main.zeroSizedVariable DIE abcs := ex.Named("zeroSizedVariable") if len(abcs) == 0 { t.Fatalf("unable to locate DIE for zeroSizedVariable") } if len(abcs) != 1 { t.Fatalf("more than one zeroSizedVariable DIE") } }) } } func TestConsistentGoKindAndRuntimeType(t *testing.T) { testenv.MustHaveGoBuild(t) mustHaveDWARF(t) t.Parallel() if testing.Short() { t.Skip("skipping test in short mode.") } // Ensure that if we emit a "go runtime type" attr on a type DIE, // we also include the "go kind" attribute. See issue #64231. _, ex := gobuildAndExamine(t, zeroSizedVarProg, DefaultOpt) // Walk all dies. typesChecked := 0 failures := 0 for _, die := range ex.DIEs() { // For any type DIE with DW_AT_go_runtime_type set... rtt, hasRT := die.Val(intdwarf.DW_AT_go_runtime_type).(uint64) if !hasRT || rtt == 0 { continue } // ... except unsafe.Pointer... if name, _ := die.Val(intdwarf.DW_AT_name).(string); name == "unsafe.Pointer" { continue } typesChecked++ // ... we want to see a meaningful DW_AT_go_kind value. if val, ok := die.Val(intdwarf.DW_AT_go_kind).(int64); !ok || val == 0 { failures++ // dump DIEs for first 10 failures. if failures <= 10 { idx := ex.IdxFromOffset(die.Offset) t.Logf("type DIE has DW_AT_go_runtime_type but invalid DW_AT_go_kind:\n") ex.DumpEntry(idx, false, 0) } t.Errorf("bad type DIE at offset %d\n", die.Offset) } } if typesChecked == 0 { t.Fatalf("something went wrong, 0 types checked") } else { t.Logf("%d types checked\n", typesChecked) } }