// Copyright 2009 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. // go-specific code shared across loaders (5l, 6l, 8l). package ld import ( "cmd/internal/bio" "cmd/internal/obj" "cmd/internal/objabi" "cmd/internal/sys" "cmd/link/internal/loader" "cmd/link/internal/sym" "debug/elf" "encoding/json" "fmt" "io" "os" "sort" "strconv" "strings" ) // go-specific code shared across loaders (5l, 6l, 8l). // TODO: // generate debugging section in binary. // once the dust settles, try to move some code to // libmach, so that other linkers and ar can share. func ldpkg(ctxt *Link, f *bio.Reader, lib *sym.Library, length int64, filename string) { if *flagG { return } if int64(int(length)) != length { fmt.Fprintf(os.Stderr, "%s: too much pkg data in %s\n", os.Args[0], filename) return } bdata := make([]byte, length) if _, err := io.ReadFull(f, bdata); err != nil { fmt.Fprintf(os.Stderr, "%s: short pkg read %s\n", os.Args[0], filename) return } data := string(bdata) // process header lines for data != "" { var line string line, data, _ = strings.Cut(data, "\n") if line == "main" { lib.Main = true } if line == "" { break } } // look for cgo section p0 := strings.Index(data, "\n$$ // cgo") var p1 int if p0 >= 0 { p0 += p1 i := strings.IndexByte(data[p0+1:], '\n') if i < 0 { fmt.Fprintf(os.Stderr, "%s: found $$ // cgo but no newline in %s\n", os.Args[0], filename) return } p0 += 1 + i p1 = strings.Index(data[p0:], "\n$$") if p1 < 0 { p1 = strings.Index(data[p0:], "\n!\n") } if p1 < 0 { fmt.Fprintf(os.Stderr, "%s: cannot find end of // cgo section in %s\n", os.Args[0], filename) return } p1 += p0 loadcgo(ctxt, filename, objabi.PathToPrefix(lib.Pkg), data[p0:p1]) } } func loadcgo(ctxt *Link, file string, pkg string, p string) { var directives [][]string if err := json.NewDecoder(strings.NewReader(p)).Decode(&directives); err != nil { fmt.Fprintf(os.Stderr, "%s: %s: failed decoding cgo directives: %v\n", os.Args[0], file, err) nerrors++ return } // Record the directives. We'll process them later after Symbols are created. ctxt.cgodata = append(ctxt.cgodata, cgodata{file, pkg, directives}) } // Set symbol attributes or flags based on cgo directives. // Any newly discovered HOSTOBJ syms are added to 'hostObjSyms'. func setCgoAttr(ctxt *Link, file string, pkg string, directives [][]string, hostObjSyms map[loader.Sym]struct{}) { l := ctxt.loader for _, f := range directives { switch f[0] { case "cgo_import_dynamic": if len(f) < 2 || len(f) > 4 { break } local := f[1] remote := local if len(f) > 2 { remote = f[2] } lib := "" if len(f) > 3 { lib = f[3] } if *FlagD { fmt.Fprintf(os.Stderr, "%s: %s: cannot use dynamic imports with -d flag\n", os.Args[0], file) nerrors++ return } if local == "_" && remote == "_" { // allow #pragma dynimport _ _ "foo.so" // to force a link of foo.so. havedynamic = 1 if ctxt.HeadType == objabi.Hdarwin { machoadddynlib(lib, ctxt.LinkMode) } else { dynlib = append(dynlib, lib) } continue } q := "" if before, after, found := strings.Cut(remote, "#"); found { remote, q = before, after } s := l.LookupOrCreateSym(local, 0) st := l.SymType(s) if st == 0 || st == sym.SXREF || st == sym.SBSS || st == sym.SNOPTRBSS || st == sym.SHOSTOBJ { l.SetSymDynimplib(s, lib) l.SetSymExtname(s, remote) l.SetSymDynimpvers(s, q) if st != sym.SHOSTOBJ { su := l.MakeSymbolUpdater(s) su.SetType(sym.SDYNIMPORT) } else { hostObjSyms[s] = struct{}{} } havedynamic = 1 if lib != "" && ctxt.IsDarwin() { machoadddynlib(lib, ctxt.LinkMode) } } continue case "cgo_import_static": if len(f) != 2 { break } local := f[1] s := l.LookupOrCreateSym(local, 0) su := l.MakeSymbolUpdater(s) su.SetType(sym.SHOSTOBJ) su.SetSize(0) hostObjSyms[s] = struct{}{} continue case "cgo_export_static", "cgo_export_dynamic": if len(f) < 2 || len(f) > 4 { break } local := f[1] remote := local if len(f) > 2 { remote = f[2] } // The compiler adds a fourth argument giving // the definition ABI of function symbols. abi := obj.ABI0 if len(f) > 3 { var ok bool abi, ok = obj.ParseABI(f[3]) if !ok { fmt.Fprintf(os.Stderr, "%s: bad ABI in cgo_export directive %s\n", os.Args[0], f) nerrors++ return } } s := l.LookupOrCreateSym(local, sym.ABIToVersion(abi)) if l.SymType(s) == sym.SHOSTOBJ { hostObjSyms[s] = struct{}{} } switch ctxt.BuildMode { case BuildModeCShared, BuildModeCArchive, BuildModePlugin: if s == l.Lookup("main", 0) { continue } } // export overrides import, for openbsd/cgo. // see issue 4878. if l.SymDynimplib(s) != "" { l.SetSymDynimplib(s, "") l.SetSymDynimpvers(s, "") l.SetSymExtname(s, "") var su *loader.SymbolBuilder su = l.MakeSymbolUpdater(s) su.SetType(0) } if !(l.AttrCgoExportStatic(s) || l.AttrCgoExportDynamic(s)) { l.SetSymExtname(s, remote) } else if l.SymExtname(s) != remote { fmt.Fprintf(os.Stderr, "%s: conflicting cgo_export directives: %s as %s and %s\n", os.Args[0], l.SymName(s), l.SymExtname(s), remote) nerrors++ return } // Mark exported symbols and also add them to // the lists used for roots in the deadcode pass. if f[0] == "cgo_export_static" { if ctxt.LinkMode == LinkExternal && !l.AttrCgoExportStatic(s) { // Static cgo exports appear // in the exported symbol table. ctxt.dynexp = append(ctxt.dynexp, s) } if ctxt.LinkMode == LinkInternal { // For internal linking, we're // responsible for resolving // relocations from host objects. // Record the right Go symbol // version to use. l.AddCgoExport(s) } l.SetAttrCgoExportStatic(s, true) } else { if ctxt.LinkMode == LinkInternal && !l.AttrCgoExportDynamic(s) { // Dynamic cgo exports appear // in the exported symbol table. ctxt.dynexp = append(ctxt.dynexp, s) } l.SetAttrCgoExportDynamic(s, true) } continue case "cgo_dynamic_linker": if len(f) != 2 { break } if *flagInterpreter == "" { if interpreter != "" && interpreter != f[1] { fmt.Fprintf(os.Stderr, "%s: conflict dynlinker: %s and %s\n", os.Args[0], interpreter, f[1]) nerrors++ return } interpreter = f[1] } continue case "cgo_ldflag": if len(f) != 2 { break } ldflag = append(ldflag, f[1]) continue } fmt.Fprintf(os.Stderr, "%s: %s: invalid cgo directive: %q\n", os.Args[0], file, f) nerrors++ } return } // openbsdTrimLibVersion indicates whether a shared library is // versioned and if it is, returns the unversioned name. The // OpenBSD library naming scheme is lib.so.. func openbsdTrimLibVersion(lib string) (string, bool) { parts := strings.Split(lib, ".") if len(parts) != 4 { return "", false } if parts[1] != "so" { return "", false } if _, err := strconv.Atoi(parts[2]); err != nil { return "", false } if _, err := strconv.Atoi(parts[3]); err != nil { return "", false } return fmt.Sprintf("%s.%s", parts[0], parts[1]), true } // dedupLibrariesOpenBSD dedups a list of shared libraries, treating versioned // and unversioned libraries as equivalents. Versioned libraries are preferred // and retained over unversioned libraries. This avoids the situation where // the use of cgo results in a DT_NEEDED for a versioned library (for example, // libc.so.96.1), while a dynamic import specifies an unversioned library (for // example, libc.so) - this would otherwise result in two DT_NEEDED entries // for the same library, resulting in a failure when ld.so attempts to load // the Go binary. func dedupLibrariesOpenBSD(ctxt *Link, libs []string) []string { libraries := make(map[string]string) for _, lib := range libs { if name, ok := openbsdTrimLibVersion(lib); ok { // Record unversioned name as seen. seenlib[name] = true libraries[name] = lib } else if _, ok := libraries[lib]; !ok { libraries[lib] = lib } } libs = nil for _, lib := range libraries { libs = append(libs, lib) } sort.Strings(libs) return libs } func dedupLibraries(ctxt *Link, libs []string) []string { if ctxt.Target.IsOpenbsd() { return dedupLibrariesOpenBSD(ctxt, libs) } return libs } var seenlib = make(map[string]bool) func adddynlib(ctxt *Link, lib string) { if seenlib[lib] || ctxt.LinkMode == LinkExternal { return } seenlib[lib] = true if ctxt.IsELF { dsu := ctxt.loader.MakeSymbolUpdater(ctxt.DynStr) if dsu.Size() == 0 { dsu.Addstring("") } du := ctxt.loader.MakeSymbolUpdater(ctxt.Dynamic) Elfwritedynent(ctxt.Arch, du, elf.DT_NEEDED, uint64(dsu.Addstring(lib))) } else { Errorf("adddynlib: unsupported binary format") } } func Adddynsym(ldr *loader.Loader, target *Target, syms *ArchSyms, s loader.Sym) { if ldr.SymDynid(s) >= 0 || target.LinkMode == LinkExternal { return } if target.IsELF { elfadddynsym(ldr, target, syms, s) } else if target.HeadType == objabi.Hdarwin { ldr.Errorf(s, "adddynsym: missed symbol (Extname=%s)", ldr.SymExtname(s)) } else if target.HeadType == objabi.Hwindows { // already taken care of } else { ldr.Errorf(s, "adddynsym: unsupported binary format") } } func fieldtrack(arch *sys.Arch, l *loader.Loader) { var buf strings.Builder for i := loader.Sym(1); i < loader.Sym(l.NSym()); i++ { if name := l.SymName(i); strings.HasPrefix(name, "go:track.") { if l.AttrReachable(i) { l.SetAttrSpecial(i, true) l.SetAttrNotInSymbolTable(i, true) buf.WriteString(name[9:]) for p := l.Reachparent[i]; p != 0; p = l.Reachparent[p] { buf.WriteString("\t") buf.WriteString(l.SymName(p)) } buf.WriteString("\n") } } } l.Reachparent = nil // we are done with it if *flagFieldTrack == "" { return } s := l.Lookup(*flagFieldTrack, 0) if s == 0 || !l.AttrReachable(s) { return } bld := l.MakeSymbolUpdater(s) bld.SetType(sym.SDATA) addstrdata(arch, l, *flagFieldTrack, buf.String()) } func (ctxt *Link) addexport() { // Track undefined external symbols during external link. if ctxt.LinkMode == LinkExternal { for _, s := range ctxt.Textp { if ctxt.loader.AttrSpecial(s) || ctxt.loader.AttrSubSymbol(s) { continue } relocs := ctxt.loader.Relocs(s) for i := 0; i < relocs.Count(); i++ { if rs := relocs.At(i).Sym(); rs != 0 { if ctxt.loader.SymType(rs) == sym.Sxxx && !ctxt.loader.AttrLocal(rs) { // sanity check if len(ctxt.loader.Data(rs)) != 0 { panic("expected no data on undef symbol") } su := ctxt.loader.MakeSymbolUpdater(rs) su.SetType(sym.SUNDEFEXT) } } } } } // TODO(aix) if ctxt.HeadType == objabi.Hdarwin || ctxt.HeadType == objabi.Haix { return } // Add dynamic symbols. for _, s := range ctxt.dynexp { // Consistency check. if !ctxt.loader.AttrReachable(s) { panic("dynexp entry not reachable") } Adddynsym(ctxt.loader, &ctxt.Target, &ctxt.ArchSyms, s) } for _, lib := range dedupLibraries(ctxt, dynlib) { adddynlib(ctxt, lib) } }