// Copyright 2018 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 xcoff implements access to XCOFF (Extended Common Object File Format) files. package xcoff import ( "debug/dwarf" "encoding/binary" "fmt" "internal/saferio" "io" "os" "strings" ) // SectionHeader holds information about an XCOFF section header. type SectionHeader struct { Name string VirtualAddress uint64 Size uint64 Type uint32 Relptr uint64 Nreloc uint32 } type Section struct { SectionHeader Relocs []Reloc io.ReaderAt sr *io.SectionReader } // AuxiliaryCSect holds information about an XCOFF symbol in an AUX_CSECT entry. type AuxiliaryCSect struct { Length int64 StorageMappingClass int SymbolType int } // AuxiliaryFcn holds information about an XCOFF symbol in an AUX_FCN entry. type AuxiliaryFcn struct { Size int64 } type Symbol struct { Name string Value uint64 SectionNumber int StorageClass int AuxFcn AuxiliaryFcn AuxCSect AuxiliaryCSect } type Reloc struct { VirtualAddress uint64 Symbol *Symbol Signed bool InstructionFixed bool Length uint8 Type uint8 } // ImportedSymbol holds information about an imported XCOFF symbol. type ImportedSymbol struct { Name string Library string } // FileHeader holds information about an XCOFF file header. type FileHeader struct { TargetMachine uint16 } // A File represents an open XCOFF file. type File struct { FileHeader Sections []*Section Symbols []*Symbol StringTable []byte LibraryPaths []string closer io.Closer } // Open opens the named file using os.Open and prepares it for use as an XCOFF binary. func Open(name string) (*File, error) { f, err := os.Open(name) if err != nil { return nil, err } ff, err := NewFile(f) if err != nil { f.Close() return nil, err } ff.closer = f return ff, nil } // Close closes the File. // If the File was created using NewFile directly instead of Open, // Close has no effect. func (f *File) Close() error { var err error if f.closer != nil { err = f.closer.Close() f.closer = nil } return err } // Section returns the first section with the given name, or nil if no such // section exists. // Xcoff have section's name limited to 8 bytes. Some sections like .gosymtab // can be trunked but this method will still find them. func (f *File) Section(name string) *Section { for _, s := range f.Sections { if s.Name == name || (len(name) > 8 && s.Name == name[:8]) { return s } } return nil } // SectionByType returns the first section in f with the // given type, or nil if there is no such section. func (f *File) SectionByType(typ uint32) *Section { for _, s := range f.Sections { if s.Type == typ { return s } } return nil } // cstring converts ASCII byte sequence b to string. // It stops once it finds 0 or reaches end of b. func cstring(b []byte) string { var i int for i = 0; i < len(b) && b[i] != 0; i++ { } return string(b[:i]) } // getString extracts a string from an XCOFF string table. func getString(st []byte, offset uint32) (string, bool) { if offset < 4 || int(offset) >= len(st) { return "", false } return cstring(st[offset:]), true } // NewFile creates a new File for accessing an XCOFF binary in an underlying reader. func NewFile(r io.ReaderAt) (*File, error) { sr := io.NewSectionReader(r, 0, 1<<63-1) // Read XCOFF target machine var magic uint16 if err := binary.Read(sr, binary.BigEndian, &magic); err != nil { return nil, err } if magic != U802TOCMAGIC && magic != U64_TOCMAGIC { return nil, fmt.Errorf("unrecognised XCOFF magic: 0x%x", magic) } f := new(File) f.TargetMachine = magic // Read XCOFF file header if _, err := sr.Seek(0, io.SeekStart); err != nil { return nil, err } var nscns uint16 var symptr uint64 var nsyms uint32 var opthdr uint16 var hdrsz int switch f.TargetMachine { case U802TOCMAGIC: fhdr := new(FileHeader32) if err := binary.Read(sr, binary.BigEndian, fhdr); err != nil { return nil, err } nscns = fhdr.Fnscns symptr = uint64(fhdr.Fsymptr) nsyms = fhdr.Fnsyms opthdr = fhdr.Fopthdr hdrsz = FILHSZ_32 case U64_TOCMAGIC: fhdr := new(FileHeader64) if err := binary.Read(sr, binary.BigEndian, fhdr); err != nil { return nil, err } nscns = fhdr.Fnscns symptr = fhdr.Fsymptr nsyms = fhdr.Fnsyms opthdr = fhdr.Fopthdr hdrsz = FILHSZ_64 } if symptr == 0 || nsyms <= 0 { return nil, fmt.Errorf("no symbol table") } // Read string table (located right after symbol table). offset := symptr + uint64(nsyms)*SYMESZ if _, err := sr.Seek(int64(offset), io.SeekStart); err != nil { return nil, err } // The first 4 bytes contain the length (in bytes). var l uint32 if err := binary.Read(sr, binary.BigEndian, &l); err != nil { return nil, err } if l > 4 { st, err := saferio.ReadDataAt(sr, uint64(l), int64(offset)) if err != nil { return nil, err } f.StringTable = st } // Read section headers if _, err := sr.Seek(int64(hdrsz)+int64(opthdr), io.SeekStart); err != nil { return nil, err } c := saferio.SliceCap((**Section)(nil), uint64(nscns)) if c < 0 { return nil, fmt.Errorf("too many XCOFF sections (%d)", nscns) } f.Sections = make([]*Section, 0, c) for i := 0; i < int(nscns); i++ { var scnptr uint64 s := new(Section) switch f.TargetMachine { case U802TOCMAGIC: shdr := new(SectionHeader32) if err := binary.Read(sr, binary.BigEndian, shdr); err != nil { return nil, err } s.Name = cstring(shdr.Sname[:]) s.VirtualAddress = uint64(shdr.Svaddr) s.Size = uint64(shdr.Ssize) scnptr = uint64(shdr.Sscnptr) s.Type = shdr.Sflags s.Relptr = uint64(shdr.Srelptr) s.Nreloc = uint32(shdr.Snreloc) case U64_TOCMAGIC: shdr := new(SectionHeader64) if err := binary.Read(sr, binary.BigEndian, shdr); err != nil { return nil, err } s.Name = cstring(shdr.Sname[:]) s.VirtualAddress = shdr.Svaddr s.Size = shdr.Ssize scnptr = shdr.Sscnptr s.Type = shdr.Sflags s.Relptr = shdr.Srelptr s.Nreloc = shdr.Snreloc } r2 := r if scnptr == 0 { // .bss must have all 0s r2 = zeroReaderAt{} } s.sr = io.NewSectionReader(r2, int64(scnptr), int64(s.Size)) s.ReaderAt = s.sr f.Sections = append(f.Sections, s) } // Symbol map needed by relocation var idxToSym = make(map[int]*Symbol) // Read symbol table if _, err := sr.Seek(int64(symptr), io.SeekStart); err != nil { return nil, err } f.Symbols = make([]*Symbol, 0) for i := 0; i < int(nsyms); i++ { var numaux int var ok, needAuxFcn bool sym := new(Symbol) switch f.TargetMachine { case U802TOCMAGIC: se := new(SymEnt32) if err := binary.Read(sr, binary.BigEndian, se); err != nil { return nil, err } numaux = int(se.Nnumaux) sym.SectionNumber = int(se.Nscnum) sym.StorageClass = int(se.Nsclass) sym.Value = uint64(se.Nvalue) needAuxFcn = se.Ntype&SYM_TYPE_FUNC != 0 && numaux > 1 zeroes := binary.BigEndian.Uint32(se.Nname[:4]) if zeroes != 0 { sym.Name = cstring(se.Nname[:]) } else { offset := binary.BigEndian.Uint32(se.Nname[4:]) sym.Name, ok = getString(f.StringTable, offset) if !ok { goto skip } } case U64_TOCMAGIC: se := new(SymEnt64) if err := binary.Read(sr, binary.BigEndian, se); err != nil { return nil, err } numaux = int(se.Nnumaux) sym.SectionNumber = int(se.Nscnum) sym.StorageClass = int(se.Nsclass) sym.Value = se.Nvalue needAuxFcn = se.Ntype&SYM_TYPE_FUNC != 0 && numaux > 1 sym.Name, ok = getString(f.StringTable, se.Noffset) if !ok { goto skip } } if sym.StorageClass != C_EXT && sym.StorageClass != C_WEAKEXT && sym.StorageClass != C_HIDEXT { goto skip } // Must have at least one csect auxiliary entry. if numaux < 1 || i+numaux >= int(nsyms) { goto skip } if sym.SectionNumber > int(nscns) { goto skip } if sym.SectionNumber == 0 { sym.Value = 0 } else { sym.Value -= f.Sections[sym.SectionNumber-1].VirtualAddress } idxToSym[i] = sym // If this symbol is a function, it must retrieve its size from // its AUX_FCN entry. // It can happen that a function symbol doesn't have any AUX_FCN. // In this case, needAuxFcn is false and their size will be set to 0. if needAuxFcn { switch f.TargetMachine { case U802TOCMAGIC: aux := new(AuxFcn32) if err := binary.Read(sr, binary.BigEndian, aux); err != nil { return nil, err } sym.AuxFcn.Size = int64(aux.Xfsize) case U64_TOCMAGIC: aux := new(AuxFcn64) if err := binary.Read(sr, binary.BigEndian, aux); err != nil { return nil, err } sym.AuxFcn.Size = int64(aux.Xfsize) } } // Read csect auxiliary entry (by convention, it is the last). if !needAuxFcn { if _, err := sr.Seek(int64(numaux-1)*SYMESZ, io.SeekCurrent); err != nil { return nil, err } } i += numaux numaux = 0 switch f.TargetMachine { case U802TOCMAGIC: aux := new(AuxCSect32) if err := binary.Read(sr, binary.BigEndian, aux); err != nil { return nil, err } sym.AuxCSect.SymbolType = int(aux.Xsmtyp & 0x7) sym.AuxCSect.StorageMappingClass = int(aux.Xsmclas) sym.AuxCSect.Length = int64(aux.Xscnlen) case U64_TOCMAGIC: aux := new(AuxCSect64) if err := binary.Read(sr, binary.BigEndian, aux); err != nil { return nil, err } sym.AuxCSect.SymbolType = int(aux.Xsmtyp & 0x7) sym.AuxCSect.StorageMappingClass = int(aux.Xsmclas) sym.AuxCSect.Length = int64(aux.Xscnlenhi)<<32 | int64(aux.Xscnlenlo) } f.Symbols = append(f.Symbols, sym) skip: i += numaux // Skip auxiliary entries if _, err := sr.Seek(int64(numaux)*SYMESZ, io.SeekCurrent); err != nil { return nil, err } } // Read relocations // Only for .data or .text section for sectNum, sect := range f.Sections { if sect.Type != STYP_TEXT && sect.Type != STYP_DATA { continue } if sect.Relptr == 0 { continue } c := saferio.SliceCap((*Reloc)(nil), uint64(sect.Nreloc)) if c < 0 { return nil, fmt.Errorf("too many relocs (%d) for section %d", sect.Nreloc, sectNum) } sect.Relocs = make([]Reloc, 0, c) if _, err := sr.Seek(int64(sect.Relptr), io.SeekStart); err != nil { return nil, err } for i := uint32(0); i < sect.Nreloc; i++ { var reloc Reloc switch f.TargetMachine { case U802TOCMAGIC: rel := new(Reloc32) if err := binary.Read(sr, binary.BigEndian, rel); err != nil { return nil, err } reloc.VirtualAddress = uint64(rel.Rvaddr) reloc.Symbol = idxToSym[int(rel.Rsymndx)] reloc.Type = rel.Rtype reloc.Length = rel.Rsize&0x3F + 1 if rel.Rsize&0x80 != 0 { reloc.Signed = true } if rel.Rsize&0x40 != 0 { reloc.InstructionFixed = true } case U64_TOCMAGIC: rel := new(Reloc64) if err := binary.Read(sr, binary.BigEndian, rel); err != nil { return nil, err } reloc.VirtualAddress = rel.Rvaddr reloc.Symbol = idxToSym[int(rel.Rsymndx)] reloc.Type = rel.Rtype reloc.Length = rel.Rsize&0x3F + 1 if rel.Rsize&0x80 != 0 { reloc.Signed = true } if rel.Rsize&0x40 != 0 { reloc.InstructionFixed = true } } sect.Relocs = append(sect.Relocs, reloc) } } return f, nil } // zeroReaderAt is ReaderAt that reads 0s. type zeroReaderAt struct{} // ReadAt writes len(p) 0s into p. func (w zeroReaderAt) ReadAt(p []byte, off int64) (n int, err error) { for i := range p { p[i] = 0 } return len(p), nil } // Data reads and returns the contents of the XCOFF section s. func (s *Section) Data() ([]byte, error) { dat := make([]byte, s.sr.Size()) n, err := s.sr.ReadAt(dat, 0) if n == len(dat) { err = nil } return dat[:n], err } // CSect reads and returns the contents of a csect. func (f *File) CSect(name string) []byte { for _, sym := range f.Symbols { if sym.Name == name && sym.AuxCSect.SymbolType == XTY_SD { if i := sym.SectionNumber - 1; 0 <= i && i < len(f.Sections) { s := f.Sections[i] if sym.Value+uint64(sym.AuxCSect.Length) <= s.Size { dat := make([]byte, sym.AuxCSect.Length) _, err := s.sr.ReadAt(dat, int64(sym.Value)) if err != nil { return nil } return dat } } break } } return nil } func (f *File) DWARF() (*dwarf.Data, error) { // There are many other DWARF sections, but these // are the ones the debug/dwarf package uses. // Don't bother loading others. var subtypes = [...]uint32{SSUBTYP_DWABREV, SSUBTYP_DWINFO, SSUBTYP_DWLINE, SSUBTYP_DWRNGES, SSUBTYP_DWSTR} var dat [len(subtypes)][]byte for i, subtype := range subtypes { s := f.SectionByType(STYP_DWARF | subtype) if s != nil { b, err := s.Data() if err != nil && uint64(len(b)) < s.Size { return nil, err } dat[i] = b } } abbrev, info, line, ranges, str := dat[0], dat[1], dat[2], dat[3], dat[4] return dwarf.New(abbrev, nil, nil, info, line, nil, ranges, str) } // readImportID returns the import file IDs stored inside the .loader section. // Library name pattern is either path/base/member or base/member func (f *File) readImportIDs(s *Section) ([]string, error) { // Read loader header if _, err := s.sr.Seek(0, io.SeekStart); err != nil { return nil, err } var istlen uint32 var nimpid uint32 var impoff uint64 switch f.TargetMachine { case U802TOCMAGIC: lhdr := new(LoaderHeader32) if err := binary.Read(s.sr, binary.BigEndian, lhdr); err != nil { return nil, err } istlen = lhdr.Listlen nimpid = lhdr.Lnimpid impoff = uint64(lhdr.Limpoff) case U64_TOCMAGIC: lhdr := new(LoaderHeader64) if err := binary.Read(s.sr, binary.BigEndian, lhdr); err != nil { return nil, err } istlen = lhdr.Listlen nimpid = lhdr.Lnimpid impoff = lhdr.Limpoff } // Read loader import file ID table if _, err := s.sr.Seek(int64(impoff), io.SeekStart); err != nil { return nil, err } table := make([]byte, istlen) if _, err := io.ReadFull(s.sr, table); err != nil { return nil, err } offset := 0 // First import file ID is the default LIBPATH value libpath := cstring(table[offset:]) f.LibraryPaths = strings.Split(libpath, ":") offset += len(libpath) + 3 // 3 null bytes all := make([]string, 0) for i := 1; i < int(nimpid); i++ { impidpath := cstring(table[offset:]) offset += len(impidpath) + 1 impidbase := cstring(table[offset:]) offset += len(impidbase) + 1 impidmem := cstring(table[offset:]) offset += len(impidmem) + 1 var path string if len(impidpath) > 0 { path = impidpath + "/" + impidbase + "/" + impidmem } else { path = impidbase + "/" + impidmem } all = append(all, path) } return all, nil } // ImportedSymbols returns the names of all symbols // referred to by the binary f that are expected to be // satisfied by other libraries at dynamic load time. // It does not return weak symbols. func (f *File) ImportedSymbols() ([]ImportedSymbol, error) { s := f.SectionByType(STYP_LOADER) if s == nil { return nil, nil } // Read loader header if _, err := s.sr.Seek(0, io.SeekStart); err != nil { return nil, err } var stlen uint32 var stoff uint64 var nsyms uint32 var symoff uint64 switch f.TargetMachine { case U802TOCMAGIC: lhdr := new(LoaderHeader32) if err := binary.Read(s.sr, binary.BigEndian, lhdr); err != nil { return nil, err } stlen = lhdr.Lstlen stoff = uint64(lhdr.Lstoff) nsyms = lhdr.Lnsyms symoff = LDHDRSZ_32 case U64_TOCMAGIC: lhdr := new(LoaderHeader64) if err := binary.Read(s.sr, binary.BigEndian, lhdr); err != nil { return nil, err } stlen = lhdr.Lstlen stoff = lhdr.Lstoff nsyms = lhdr.Lnsyms symoff = lhdr.Lsymoff } // Read loader section string table if _, err := s.sr.Seek(int64(stoff), io.SeekStart); err != nil { return nil, err } st := make([]byte, stlen) if _, err := io.ReadFull(s.sr, st); err != nil { return nil, err } // Read imported libraries libs, err := f.readImportIDs(s) if err != nil { return nil, err } // Read loader symbol table if _, err := s.sr.Seek(int64(symoff), io.SeekStart); err != nil { return nil, err } all := make([]ImportedSymbol, 0) for i := 0; i < int(nsyms); i++ { var name string var ifile uint32 var ok bool switch f.TargetMachine { case U802TOCMAGIC: ldsym := new(LoaderSymbol32) if err := binary.Read(s.sr, binary.BigEndian, ldsym); err != nil { return nil, err } if ldsym.Lsmtype&0x40 == 0 { continue // Imported symbols only } zeroes := binary.BigEndian.Uint32(ldsym.Lname[:4]) if zeroes != 0 { name = cstring(ldsym.Lname[:]) } else { offset := binary.BigEndian.Uint32(ldsym.Lname[4:]) name, ok = getString(st, offset) if !ok { continue } } ifile = ldsym.Lifile case U64_TOCMAGIC: ldsym := new(LoaderSymbol64) if err := binary.Read(s.sr, binary.BigEndian, ldsym); err != nil { return nil, err } if ldsym.Lsmtype&0x40 == 0 { continue // Imported symbols only } name, ok = getString(st, ldsym.Loffset) if !ok { continue } ifile = ldsym.Lifile } var sym ImportedSymbol sym.Name = name if ifile >= 1 && int(ifile) <= len(libs) { sym.Library = libs[ifile-1] } all = append(all, sym) } return all, nil } // ImportedLibraries returns the names of all libraries // referred to by the binary f that are expected to be // linked with the binary at dynamic link time. func (f *File) ImportedLibraries() ([]string, error) { s := f.SectionByType(STYP_LOADER) if s == nil { return nil, nil } all, err := f.readImportIDs(s) return all, err }