src/cmd/internal/obj/objfile.go - go - Git at Google

 // 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.

 // Writing of Go object files.
 //
 // Originally, Go object files were Plan 9 object files, but no longer.
 // Now they are more like standard object files, in that each symbol is defined
 // by an associated memory image (bytes) and a list of relocations to apply
 // during linking. We do not (yet?) use a standard file format, however.
 // For now, the format is chosen to be as simple as possible to read and write.
 // It may change for reasons of efficiency, or we may even switch to a
 // standard file format if there are compelling benefits to doing so.
 // See golang.org/s/go13linker for more background.
 //
 // The file format is:
 //
 //	- magic header: "\x00\x00go17ld"
 //	- byte 1 - version number
 //	- sequence of strings giving dependencies (imported packages)
 //	- empty string (marks end of sequence)
 //	- sequence of symbol references used by the defined symbols
 //	- byte 0xff (marks end of sequence)
 //	- sequence of integer lengths:
 //		- total data length
 //		- total number of relocations
 //		- total number of pcdata
 //		- total number of automatics
 //		- total number of funcdata
 //		- total number of files
 //	- data, the content of the defined symbols
 //	- sequence of defined symbols
 //	- byte 0xff (marks end of sequence)
 //	- magic footer: "\xff\xffgo17ld"
 //
 // All integers are stored in a zigzag varint format.
 // See golang.org/s/go12symtab for a definition.
 //
 // Data blocks and strings are both stored as an integer
 // followed by that many bytes.
 //
 // A symbol reference is a string name followed by a version.
 //
 // A symbol points to other symbols using an index into the symbol
 // reference sequence. Index 0 corresponds to a nil LSym* pointer.
 // In the symbol layout described below "symref index" stands for this
 // index.
 //
 // Each symbol is laid out as the following fields (taken from LSym*):
 //
 //	- byte 0xfe (sanity check for synchronization)
 //	- type [int]
 //	- name & version [symref index]
 //	- flags [int]
 //		1<<0 dupok
 //		1<<1 local
 //		1<<2 add to typelink table
 //	- size [int]
 //	- gotype [symref index]
 //	- p [data block]
 //	- nr [int]
 //	- r [nr relocations, sorted by off]
 //
 // If type == STEXT, there are a few more fields:
 //
 //	- args [int]
 //	- locals [int]
 //	- nosplit [int]
 //	- flags [int]
 //		1<<0 leaf
 //		1<<1 C function
 //		1<<2 function may call reflect.Type.Method
 //	- nlocal [int]
 //	- local [nlocal automatics]
 //	- pcln [pcln table]
 //
 // Each relocation has the encoding:
 //
 //	- off [int]
 //	- siz [int]
 //	- type [int]
 //	- add [int]
 //	- sym [symref index]
 //
 // Each local has the encoding:
 //
 //	- asym [symref index]
 //	- offset [int]
 //	- type [int]
 //	- gotype [symref index]
 //
 // The pcln table has the encoding:
 //
 //	- pcsp [data block]
 //	- pcfile [data block]
 //	- pcline [data block]
 //	- npcdata [int]
 //	- pcdata [npcdata data blocks]
 //	- nfuncdata [int]
 //	- funcdata [nfuncdata symref index]
 //	- funcdatasym [nfuncdata ints]
 //	- nfile [int]
 //	- file [nfile symref index]
 //
 // The file layout and meaning of type integers are architecture-independent.
 //
 // TODO(rsc): The file format is good for a first pass but needs work.
 //	- There are SymID in the object file that should really just be strings.

 package obj

 import (
 	"bufio"
 	"cmd/internal/dwarf"
 	"cmd/internal/sys"
 	"fmt"
 	"log"
 	"path/filepath"
 	"sort"
 )

 // The Go and C compilers, and the assembler, call writeobj to write
 // out a Go object file. The linker does not call this; the linker
 // does not write out object files.
 func Writeobjdirect(ctxt *Link, b *bufio.Writer) {
 	Flushplist(ctxt)
 	WriteObjFile(ctxt, b)
 }

 // objWriter writes Go object files.
 type objWriter struct {
 	wr   *bufio.Writer
 	ctxt *Link
 	// Temporary buffer for zigzag int writing.
 	varintbuf [10]uint8

 	// Provide the the index of a symbol reference by symbol name.
 	// One map for versioned symbols and one for unversioned symbols.
 	// Used for deduplicating the symbol reference list.
 	refIdx  map[string]int
 	vrefIdx map[string]int

 	// Number of objects written of each type.
 	nRefs     int
 	nData     int
 	nReloc    int
 	nPcdata   int
 	nAutom    int
 	nFuncdata int
 	nFile     int
 }

 func (w *objWriter) addLengths(s *LSym) {
 	w.nData += len(s.P)
 	w.nReloc += len(s.R)

 	if s.Type != STEXT {
 		return
 	}

 	pc := s.Pcln

 	data := 0
 	data += len(pc.Pcsp.P)
 	data += len(pc.Pcfile.P)
 	data += len(pc.Pcline.P)
 	for i := 0; i < len(pc.Pcdata); i++ {
 		data += len(pc.Pcdata[i].P)
 	}

 	w.nData += data
 	w.nPcdata += len(pc.Pcdata)

 	autom := 0
 	for a := s.Autom; a != nil; a = a.Link {
 		autom++
 	}
 	w.nAutom += autom
 	w.nFuncdata += len(pc.Funcdataoff)
 	w.nFile += len(pc.File)
 }

 func (w *objWriter) writeLengths() {
 	w.writeInt(int64(w.nData))
 	w.writeInt(int64(w.nReloc))
 	w.writeInt(int64(w.nPcdata))
 	w.writeInt(int64(w.nAutom))
 	w.writeInt(int64(w.nFuncdata))
 	w.writeInt(int64(w.nFile))
 }

 func newObjWriter(ctxt *Link, b *bufio.Writer) *objWriter {
 	return &objWriter{
 		ctxt:    ctxt,
 		wr:      b,
 		vrefIdx: make(map[string]int),
 		refIdx:  make(map[string]int),
 	}
 }

 func WriteObjFile(ctxt *Link, b *bufio.Writer) {
 	w := newObjWriter(ctxt, b)

 	// Magic header
 	w.wr.WriteString("\x00\x00go17ld")

 	// Version
 	w.wr.WriteByte(1)

 	// Autolib
 	for _, pkg := range ctxt.Imports {
 		w.writeString(pkg)
 	}
 	w.writeString("")

 	// Symbol references
 	for _, s := range ctxt.Text {
 		w.writeRefs(s)
 		w.addLengths(s)
 	}
 	for _, s := range ctxt.Data {
 		w.writeRefs(s)
 		w.addLengths(s)
 	}
 	// End symbol references
 	w.wr.WriteByte(0xff)

 	// Lengths
 	w.writeLengths()

 	// Data block
 	for _, s := range ctxt.Text {
 		w.wr.Write(s.P)
 		pc := s.Pcln
 		w.wr.Write(pc.Pcsp.P)
 		w.wr.Write(pc.Pcfile.P)
 		w.wr.Write(pc.Pcline.P)
 		for i := 0; i < len(pc.Pcdata); i++ {
 			w.wr.Write(pc.Pcdata[i].P)
 		}
 	}
 	for _, s := range ctxt.Data {
 		w.wr.Write(s.P)
 	}

 	// Symbols
 	for _, s := range ctxt.Text {
 		w.writeSym(s)
 	}
 	for _, s := range ctxt.Data {
 		w.writeSym(s)
 	}

 	// Magic footer
 	w.wr.WriteString("\xff\xffgo17ld")
 }

 // Symbols are prefixed so their content doesn't get confused with the magic footer.
 const symPrefix = 0xfe

 func (w *objWriter) writeRef(s *LSym, isPath bool) {
 	if s == nil || s.RefIdx != 0 {
 		return
 	}
 	var m map[string]int
 	switch s.Version {
 	case 0:
 		m = w.refIdx
 	case 1:
 		m = w.vrefIdx
 	default:
 		log.Fatalf("%s: invalid version number %d", s.Name, s.Version)
 	}

 	idx := m[s.Name]
 	if idx != 0 {
 		s.RefIdx = idx
 		return
 	}
 	w.wr.WriteByte(symPrefix)
 	if isPath {
 		w.writeString(filepath.ToSlash(s.Name))
 	} else {
 		w.writeString(s.Name)
 	}
 	w.writeInt(int64(s.Version))
 	w.nRefs++
 	s.RefIdx = w.nRefs
 	m[s.Name] = w.nRefs
 }

 func (w *objWriter) writeRefs(s *LSym) {
 	w.writeRef(s, false)
 	w.writeRef(s.Gotype, false)
 	for i := range s.R {
 		w.writeRef(s.R[i].Sym, false)
 	}

 	if s.Type == STEXT {
 		for a := s.Autom; a != nil; a = a.Link {
 			w.writeRef(a.Asym, false)
 			w.writeRef(a.Gotype, false)
 		}
 		pc := s.Pcln
 		for _, d := range pc.Funcdata {
 			w.writeRef(d, false)
 		}
 		for _, f := range pc.File {
 			w.writeRef(f, true)
 		}
 	}
 }

 func (w *objWriter) writeSymDebug(s *LSym) {
 	ctxt := w.ctxt
 	fmt.Fprintf(ctxt.Bso, "%s ", s.Name)
 	if s.Version != 0 {
 		fmt.Fprintf(ctxt.Bso, "v=%d ", s.Version)
 	}
 	if s.Type != 0 {
 		fmt.Fprintf(ctxt.Bso, "t=%d ", s.Type)
 	}
 	if s.DuplicateOK() {
 		fmt.Fprintf(ctxt.Bso, "dupok ")
 	}
 	if s.CFunc() {
 		fmt.Fprintf(ctxt.Bso, "cfunc ")
 	}
 	if s.NoSplit() {
 		fmt.Fprintf(ctxt.Bso, "nosplit ")
 	}
 	fmt.Fprintf(ctxt.Bso, "size=%d", s.Size)
 	if s.Type == STEXT {
 		fmt.Fprintf(ctxt.Bso, " args=%#x locals=%#x", uint64(s.Args), uint64(s.Locals))
 		if s.Leaf() {
 			fmt.Fprintf(ctxt.Bso, " leaf")
 		}
 	}

 	fmt.Fprintf(ctxt.Bso, "\n")
 	for p := s.Text; p != nil; p = p.Link {
 		fmt.Fprintf(ctxt.Bso, "\t%#04x %v\n", uint(int(p.Pc)), p)
 	}
 	var c int
 	var j int
 	for i := 0; i < len(s.P); {
 		fmt.Fprintf(ctxt.Bso, "\t%#04x", uint(i))
 		for j = i; j < i+16 && j < len(s.P); j++ {
 			fmt.Fprintf(ctxt.Bso, " %02x", s.P[j])
 		}
 		for ; j < i+16; j++ {
 			fmt.Fprintf(ctxt.Bso, "   ")
 		}
 		fmt.Fprintf(ctxt.Bso, "  ")
 		for j = i; j < i+16 && j < len(s.P); j++ {
 			c = int(s.P[j])
 			if ' ' <= c && c <= 0x7e {
 				fmt.Fprintf(ctxt.Bso, "%c", c)
 			} else {
 				fmt.Fprintf(ctxt.Bso, ".")
 			}
 		}

 		fmt.Fprintf(ctxt.Bso, "\n")
 		i += 16
 	}

 	sort.Sort(relocByOff(s.R)) // generate stable output
 	for _, r := range s.R {
 		name := ""
 		if r.Sym != nil {
 			name = r.Sym.Name
 		} else if r.Type == R_TLS_LE {
 			name = "TLS"
 		}
 		if ctxt.Arch.InFamily(sys.ARM, sys.PPC64) {
 			fmt.Fprintf(ctxt.Bso, "\trel %d+%d t=%d %s+%x\n", int(r.Off), r.Siz, r.Type, name, uint64(r.Add))
 		} else {
 			fmt.Fprintf(ctxt.Bso, "\trel %d+%d t=%d %s+%d\n", int(r.Off), r.Siz, r.Type, name, r.Add)
 		}
 	}
 }

 func (w *objWriter) writeSym(s *LSym) {
 	ctxt := w.ctxt
 	if ctxt.Debugasm != 0 {
 		w.writeSymDebug(s)
 	}

 	w.wr.WriteByte(symPrefix)
 	w.writeInt(int64(s.Type))
 	w.writeRefIndex(s)
 	flags := int64(0)
 	if s.DuplicateOK() {
 		flags |= 1
 	}
 	if s.Local() {
 		flags |= 1 << 1
 	}
 	if s.MakeTypelink() {
 		flags |= 1 << 2
 	}
 	w.writeInt(flags)
 	w.writeInt(s.Size)
 	w.writeRefIndex(s.Gotype)
 	w.writeInt(int64(len(s.P)))

 	w.writeInt(int64(len(s.R)))
 	var r *Reloc
 	for i := 0; i < len(s.R); i++ {
 		r = &s.R[i]
 		w.writeInt(int64(r.Off))
 		w.writeInt(int64(r.Siz))
 		w.writeInt(int64(r.Type))
 		w.writeInt(r.Add)
 		w.writeRefIndex(r.Sym)
 	}

 	if s.Type != STEXT {
 		return
 	}

 	w.writeInt(int64(s.Args))
 	w.writeInt(int64(s.Locals))
 	if s.NoSplit() {
 		w.writeInt(1)
 	} else {
 		w.writeInt(0)
 	}
 	flags = int64(0)
 	if s.Leaf() {
 		flags |= 1
 	}
 	if s.CFunc() {
 		flags |= 1 << 1
 	}
 	if s.ReflectMethod() {
 		flags |= 1 << 2
 	}
 	w.writeInt(flags)
 	n := 0
 	for a := s.Autom; a != nil; a = a.Link {
 		n++
 	}
 	w.writeInt(int64(n))
 	for a := s.Autom; a != nil; a = a.Link {
 		w.writeRefIndex(a.Asym)
 		w.writeInt(int64(a.Aoffset))
 		if a.Name == NAME_AUTO {
 			w.writeInt(A_AUTO)
 		} else if a.Name == NAME_PARAM {
 			w.writeInt(A_PARAM)
 		} else {
 			log.Fatalf("%s: invalid local variable type %d", s.Name, a.Name)
 		}
 		w.writeRefIndex(a.Gotype)
 	}

 	pc := s.Pcln
 	w.writeInt(int64(len(pc.Pcsp.P)))
 	w.writeInt(int64(len(pc.Pcfile.P)))
 	w.writeInt(int64(len(pc.Pcline.P)))
 	w.writeInt(int64(len(pc.Pcdata)))
 	for i := 0; i < len(pc.Pcdata); i++ {
 		w.writeInt(int64(len(pc.Pcdata[i].P)))
 	}
 	w.writeInt(int64(len(pc.Funcdataoff)))
 	for i := 0; i < len(pc.Funcdataoff); i++ {
 		w.writeRefIndex(pc.Funcdata[i])
 	}
 	for i := 0; i < len(pc.Funcdataoff); i++ {
 		w.writeInt(pc.Funcdataoff[i])
 	}
 	w.writeInt(int64(len(pc.File)))
 	for _, f := range pc.File {
 		w.writeRefIndex(f)
 	}
 }

 func (w *objWriter) writeInt(sval int64) {
 	var v uint64
 	uv := (uint64(sval) << 1) ^ uint64(sval>>63)
 	p := w.varintbuf[:]
 	for v = uv; v >= 0x80; v >>= 7 {
 		p[0] = uint8(v | 0x80)
 		p = p[1:]
 	}
 	p[0] = uint8(v)
 	p = p[1:]
 	w.wr.Write(w.varintbuf[:len(w.varintbuf)-len(p)])
 }

 func (w *objWriter) writeString(s string) {
 	w.writeInt(int64(len(s)))
 	w.wr.WriteString(s)
 }

 func (w *objWriter) writeRefIndex(s *LSym) {
 	if s == nil {
 		w.writeInt(0)
 		return
 	}
 	if s.RefIdx == 0 {
 		log.Fatalln("writing an unreferenced symbol", s.Name)
 	}
 	w.writeInt(int64(s.RefIdx))
 }

 // relocByOff sorts relocations by their offsets.
 type relocByOff []Reloc

 func (x relocByOff) Len() int           { return len(x) }
 func (x relocByOff) Less(i, j int) bool { return x[i].Off < x[j].Off }
 func (x relocByOff) Swap(i, j int)      { x[i], x[j] = x[j], x[i] }

 // implement dwarf.Context
 type dwCtxt struct{ *Link }

 func (c dwCtxt) PtrSize() int {
 	return c.Arch.PtrSize
 }
 func (c dwCtxt) AddInt(s dwarf.Sym, size int, i int64) {
 	ls := s.(*LSym)
 	ls.WriteInt(c.Link, ls.Size, size, i)
 }
 func (c dwCtxt) AddBytes(s dwarf.Sym, b []byte) {
 	ls := s.(*LSym)
 	ls.WriteBytes(c.Link, ls.Size, b)
 }
 func (c dwCtxt) AddString(s dwarf.Sym, v string) {
 	ls := s.(*LSym)
 	ls.WriteString(c.Link, ls.Size, len(v), v)
 	ls.WriteInt(c.Link, ls.Size, 1, 0)
 }
 func (c dwCtxt) SymValue(s dwarf.Sym) int64 {
 	return 0
 }
 func (c dwCtxt) AddAddress(s dwarf.Sym, data interface{}, value int64) {
 	rsym := data.(*LSym)
 	ls := s.(*LSym)
 	size := c.PtrSize()
 	ls.WriteAddr(c.Link, ls.Size, size, rsym, value)
 }
 func (c dwCtxt) AddSectionOffset(s dwarf.Sym, size int, t interface{}, ofs int64) {
 	ls := s.(*LSym)
 	rsym := t.(*LSym)
 	ls.WriteAddr(c.Link, ls.Size, size, rsym, ofs)
 	r := &ls.R[len(ls.R)-1]
 	r.Type = R_DWARFREF
 }

 func gendwarf(ctxt *Link, text []*LSym) []*LSym {
 	dctxt := dwCtxt{ctxt}
 	var dw []*LSym

 	for _, s := range text {
 		dsym := Linklookup(ctxt, dwarf.InfoPrefix+s.Name, int(s.Version))
 		if dsym.Size != 0 {
 			continue
 		}
 		dw = append(dw, dsym)
 		dsym.Type = SDWARFINFO
 		dsym.Set(AttrDuplicateOK, s.DuplicateOK())
 		var vars dwarf.Var
 		var abbrev int
 		var offs int32
 		for a := s.Autom; a != nil; a = a.Link {
 			switch a.Name {
 			case NAME_AUTO:
 				abbrev = dwarf.DW_ABRV_AUTO
 				offs = a.Aoffset
 				if ctxt.FixedFrameSize() == 0 {
 					offs -= int32(ctxt.Arch.PtrSize)
 				}
 				if Framepointer_enabled(GOOS, GOARCH) {
 					offs -= int32(ctxt.Arch.PtrSize)
 				}

 			case NAME_PARAM:
 				abbrev = dwarf.DW_ABRV_PARAM
 				offs = a.Aoffset + int32(ctxt.FixedFrameSize())

 			default:
 				continue
 			}
 			typename := dwarf.InfoPrefix + a.Gotype.Name[len("type."):]
 			dwvar := &dwarf.Var{
 				Name:   a.Asym.Name,
 				Abbrev: abbrev,
 				Offset: int32(offs),
 				Type:   Linklookup(ctxt, typename, 0),
 			}
 			dws := &vars.Link
 			for ; *dws != nil; dws = &(*dws).Link {
 				if offs <= (*dws).Offset {
 					break
 				}
 			}
 			dwvar.Link = *dws
 			*dws = dwvar
 		}
 		dwarf.PutFunc(dctxt, dsym, s.Name, s.Version == 0, s, s.Size, vars.Link)
 	}
 	return dw
 }
	// 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.

	// Writing of Go object files.
	//
	// Originally, Go object files were Plan 9 object files, but no longer.
	// Now they are more like standard object files, in that each symbol is defined
	// by an associated memory image (bytes) and a list of relocations to apply
	// during linking. We do not (yet?) use a standard file format, however.
	// For now, the format is chosen to be as simple as possible to read and write.
	// It may change for reasons of efficiency, or we may even switch to a
	// standard file format if there are compelling benefits to doing so.
	// See golang.org/s/go13linker for more background.
	//
	// The file format is:
	//
	// - magic header: "\x00\x00go17ld"
	// - byte 1 - version number
	// - sequence of strings giving dependencies (imported packages)
	// - empty string (marks end of sequence)
	// - sequence of symbol references used by the defined symbols
	// - byte 0xff (marks end of sequence)
	// - sequence of integer lengths:
	// - total data length
	// - total number of relocations
	// - total number of pcdata
	// - total number of automatics
	// - total number of funcdata
	// - total number of files
	// - data, the content of the defined symbols
	// - sequence of defined symbols
	// - byte 0xff (marks end of sequence)
	// - magic footer: "\xff\xffgo17ld"
	//
	// All integers are stored in a zigzag varint format.
	// See golang.org/s/go12symtab for a definition.
	//
	// Data blocks and strings are both stored as an integer
	// followed by that many bytes.
	//
	// A symbol reference is a string name followed by a version.
	//
	// A symbol points to other symbols using an index into the symbol
	// reference sequence. Index 0 corresponds to a nil LSym* pointer.
	// In the symbol layout described below "symref index" stands for this
	// index.
	//
	// Each symbol is laid out as the following fields (taken from LSym*):
	//
	// - byte 0xfe (sanity check for synchronization)
	// - type [int]
	// - name & version [symref index]
	// - flags [int]
	// 1<<0 dupok
	// 1<<1 local
	// 1<<2 add to typelink table
	// - size [int]
	// - gotype [symref index]
	// - p [data block]
	// - nr [int]
	// - r [nr relocations, sorted by off]
	//
	// If type == STEXT, there are a few more fields:
	//
	// - args [int]
	// - locals [int]
	// - nosplit [int]
	// - flags [int]
	// 1<<0 leaf
	// 1<<1 C function
	// 1<<2 function may call reflect.Type.Method
	// - nlocal [int]
	// - local [nlocal automatics]
	// - pcln [pcln table]
	//
	// Each relocation has the encoding:
	//
	// - off [int]
	// - siz [int]
	// - type [int]
	// - add [int]
	// - sym [symref index]
	//
	// Each local has the encoding:
	//
	// - asym [symref index]
	// - offset [int]
	// - type [int]
	// - gotype [symref index]
	//
	// The pcln table has the encoding:
	//
	// - pcsp [data block]
	// - pcfile [data block]
	// - pcline [data block]
	// - npcdata [int]
	// - pcdata [npcdata data blocks]
	// - nfuncdata [int]
	// - funcdata [nfuncdata symref index]
	// - funcdatasym [nfuncdata ints]
	// - nfile [int]
	// - file [nfile symref index]
	//
	// The file layout and meaning of type integers are architecture-independent.
	//
	// TODO(rsc): The file format is good for a first pass but needs work.
	// - There are SymID in the object file that should really just be strings.

	package obj

	import (
	"bufio"
	"cmd/internal/dwarf"
	"cmd/internal/sys"
	"fmt"
	"log"
	"path/filepath"
	"sort"
	)

	// The Go and C compilers, and the assembler, call writeobj to write
	// out a Go object file. The linker does not call this; the linker
	// does not write out object files.
	func Writeobjdirect(ctxt Link, b bufio.Writer) {
	Flushplist(ctxt)
	WriteObjFile(ctxt, b)
	}

	// objWriter writes Go object files.
	type objWriter struct {
	wr *bufio.Writer
	ctxt *Link
	// Temporary buffer for zigzag int writing.
	varintbuf [10]uint8

	// Provide the the index of a symbol reference by symbol name.
	// One map for versioned symbols and one for unversioned symbols.
	// Used for deduplicating the symbol reference list.
	refIdx map[string]int
	vrefIdx map[string]int

	// Number of objects written of each type.
	nRefs int
	nData int
	nReloc int
	nPcdata int
	nAutom int
	nFuncdata int
	nFile int
	}

	func (w objWriter) addLengths(s LSym) {
	w.nData += len(s.P)
	w.nReloc += len(s.R)

	if s.Type != STEXT {
	return
	}

	pc := s.Pcln

	data := 0
	data += len(pc.Pcsp.P)
	data += len(pc.Pcfile.P)
	data += len(pc.Pcline.P)
	for i := 0; i < len(pc.Pcdata); i++ {
	data += len(pc.Pcdata[i].P)
	}

	w.nData += data
	w.nPcdata += len(pc.Pcdata)

	autom := 0
	for a := s.Autom; a != nil; a = a.Link {
	autom++
	}
	w.nAutom += autom
	w.nFuncdata += len(pc.Funcdataoff)
	w.nFile += len(pc.File)
	}

	func (w *objWriter) writeLengths() {
	w.writeInt(int64(w.nData))
	w.writeInt(int64(w.nReloc))
	w.writeInt(int64(w.nPcdata))
	w.writeInt(int64(w.nAutom))
	w.writeInt(int64(w.nFuncdata))
	w.writeInt(int64(w.nFile))
	}

	func newObjWriter(ctxt Link, b bufio.Writer) *objWriter {
	return &objWriter{
	ctxt: ctxt,
	wr: b,
	vrefIdx: make(map[string]int),
	refIdx: make(map[string]int),
	}
	}

	func WriteObjFile(ctxt Link, b bufio.Writer) {
	w := newObjWriter(ctxt, b)

	// Magic header
	w.wr.WriteString("\x00\x00go17ld")

	// Version
	w.wr.WriteByte(1)

	// Autolib
	for _, pkg := range ctxt.Imports {
	w.writeString(pkg)
	}
	w.writeString("")

	// Symbol references
	for _, s := range ctxt.Text {
	w.writeRefs(s)
	w.addLengths(s)
	}
	for _, s := range ctxt.Data {
	w.writeRefs(s)
	w.addLengths(s)
	}
	// End symbol references
	w.wr.WriteByte(0xff)

	// Lengths
	w.writeLengths()

	// Data block
	for _, s := range ctxt.Text {
	w.wr.Write(s.P)
	pc := s.Pcln
	w.wr.Write(pc.Pcsp.P)
	w.wr.Write(pc.Pcfile.P)
	w.wr.Write(pc.Pcline.P)
	for i := 0; i < len(pc.Pcdata); i++ {
	w.wr.Write(pc.Pcdata[i].P)
	}
	}
	for _, s := range ctxt.Data {
	w.wr.Write(s.P)
	}

	// Symbols
	for _, s := range ctxt.Text {
	w.writeSym(s)
	}
	for _, s := range ctxt.Data {
	w.writeSym(s)
	}

	// Magic footer
	w.wr.WriteString("\xff\xffgo17ld")
	}

	// Symbols are prefixed so their content doesn't get confused with the magic footer.
	const symPrefix = 0xfe

	func (w objWriter) writeRef(s LSym, isPath bool) {
	if s == nil \|\| s.RefIdx != 0 {
	return
	}
	var m map[string]int
	switch s.Version {
	case 0:
	m = w.refIdx
	case 1:
	m = w.vrefIdx
	default:
	log.Fatalf("%s: invalid version number %d", s.Name, s.Version)
	}

	idx := m[s.Name]
	if idx != 0 {
	s.RefIdx = idx
	return
	}
	w.wr.WriteByte(symPrefix)
	if isPath {
	w.writeString(filepath.ToSlash(s.Name))
	} else {
	w.writeString(s.Name)
	}
	w.writeInt(int64(s.Version))
	w.nRefs++
	s.RefIdx = w.nRefs
	m[s.Name] = w.nRefs
	}

	func (w objWriter) writeRefs(s LSym) {
	w.writeRef(s, false)
	w.writeRef(s.Gotype, false)
	for i := range s.R {
	w.writeRef(s.R[i].Sym, false)
	}

	if s.Type == STEXT {
	for a := s.Autom; a != nil; a = a.Link {
	w.writeRef(a.Asym, false)
	w.writeRef(a.Gotype, false)
	}
	pc := s.Pcln
	for _, d := range pc.Funcdata {
	w.writeRef(d, false)
	}
	for _, f := range pc.File {
	w.writeRef(f, true)
	}
	}
	}

	func (w objWriter) writeSymDebug(s LSym) {
	ctxt := w.ctxt
	fmt.Fprintf(ctxt.Bso, "%s ", s.Name)
	if s.Version != 0 {
	fmt.Fprintf(ctxt.Bso, "v=%d ", s.Version)
	}
	if s.Type != 0 {
	fmt.Fprintf(ctxt.Bso, "t=%d ", s.Type)
	}
	if s.DuplicateOK() {
	fmt.Fprintf(ctxt.Bso, "dupok ")
	}
	if s.CFunc() {
	fmt.Fprintf(ctxt.Bso, "cfunc ")
	}
	if s.NoSplit() {
	fmt.Fprintf(ctxt.Bso, "nosplit ")
	}
	fmt.Fprintf(ctxt.Bso, "size=%d", s.Size)
	if s.Type == STEXT {
	fmt.Fprintf(ctxt.Bso, " args=%#x locals=%#x", uint64(s.Args), uint64(s.Locals))
	if s.Leaf() {
	fmt.Fprintf(ctxt.Bso, " leaf")
	}
	}

	fmt.Fprintf(ctxt.Bso, "\n")
	for p := s.Text; p != nil; p = p.Link {
	fmt.Fprintf(ctxt.Bso, "\t%#04x %v\n", uint(int(p.Pc)), p)
	}
	var c int
	var j int
	for i := 0; i < len(s.P); {
	fmt.Fprintf(ctxt.Bso, "\t%#04x", uint(i))
	for j = i; j < i+16 && j < len(s.P); j++ {
	fmt.Fprintf(ctxt.Bso, " %02x", s.P[j])
	}
	for ; j < i+16; j++ {
	fmt.Fprintf(ctxt.Bso, " ")
	}
	fmt.Fprintf(ctxt.Bso, " ")
	for j = i; j < i+16 && j < len(s.P); j++ {
	c = int(s.P[j])
	if ' ' <= c && c <= 0x7e {
	fmt.Fprintf(ctxt.Bso, "%c", c)
	} else {
	fmt.Fprintf(ctxt.Bso, ".")
	}
	}

	fmt.Fprintf(ctxt.Bso, "\n")
	i += 16
	}

	sort.Sort(relocByOff(s.R)) // generate stable output
	for _, r := range s.R {
	name := ""
	if r.Sym != nil {
	name = r.Sym.Name
	} else if r.Type == R_TLS_LE {
	name = "TLS"
	}
	if ctxt.Arch.InFamily(sys.ARM, sys.PPC64) {
	fmt.Fprintf(ctxt.Bso, "\trel %d+%d t=%d %s+%x\n", int(r.Off), r.Siz, r.Type, name, uint64(r.Add))
	} else {
	fmt.Fprintf(ctxt.Bso, "\trel %d+%d t=%d %s+%d\n", int(r.Off), r.Siz, r.Type, name, r.Add)
	}
	}
	}

	func (w objWriter) writeSym(s LSym) {
	ctxt := w.ctxt
	if ctxt.Debugasm != 0 {
	w.writeSymDebug(s)
	}

	w.wr.WriteByte(symPrefix)
	w.writeInt(int64(s.Type))
	w.writeRefIndex(s)
	flags := int64(0)
	if s.DuplicateOK() {
	flags \|= 1
	}
	if s.Local() {
	flags \|= 1 << 1
	}
	if s.MakeTypelink() {
	flags \|= 1 << 2
	}
	w.writeInt(flags)
	w.writeInt(s.Size)
	w.writeRefIndex(s.Gotype)
	w.writeInt(int64(len(s.P)))

	w.writeInt(int64(len(s.R)))
	var r *Reloc
	for i := 0; i < len(s.R); i++ {
	r = &s.R[i]
	w.writeInt(int64(r.Off))
	w.writeInt(int64(r.Siz))
	w.writeInt(int64(r.Type))
	w.writeInt(r.Add)
	w.writeRefIndex(r.Sym)
	}

	if s.Type != STEXT {
	return
	}

	w.writeInt(int64(s.Args))
	w.writeInt(int64(s.Locals))
	if s.NoSplit() {
	w.writeInt(1)
	} else {
	w.writeInt(0)
	}
	flags = int64(0)
	if s.Leaf() {
	flags \|= 1
	}
	if s.CFunc() {
	flags \|= 1 << 1
	}
	if s.ReflectMethod() {
	flags \|= 1 << 2
	}
	w.writeInt(flags)
	n := 0
	for a := s.Autom; a != nil; a = a.Link {
	n++
	}
	w.writeInt(int64(n))
	for a := s.Autom; a != nil; a = a.Link {
	w.writeRefIndex(a.Asym)
	w.writeInt(int64(a.Aoffset))
	if a.Name == NAME_AUTO {
	w.writeInt(A_AUTO)
	} else if a.Name == NAME_PARAM {
	w.writeInt(A_PARAM)
	} else {
	log.Fatalf("%s: invalid local variable type %d", s.Name, a.Name)
	}
	w.writeRefIndex(a.Gotype)
	}

	pc := s.Pcln
	w.writeInt(int64(len(pc.Pcsp.P)))
	w.writeInt(int64(len(pc.Pcfile.P)))
	w.writeInt(int64(len(pc.Pcline.P)))
	w.writeInt(int64(len(pc.Pcdata)))
	for i := 0; i < len(pc.Pcdata); i++ {
	w.writeInt(int64(len(pc.Pcdata[i].P)))
	}
	w.writeInt(int64(len(pc.Funcdataoff)))
	for i := 0; i < len(pc.Funcdataoff); i++ {
	w.writeRefIndex(pc.Funcdata[i])
	}
	for i := 0; i < len(pc.Funcdataoff); i++ {
	w.writeInt(pc.Funcdataoff[i])
	}
	w.writeInt(int64(len(pc.File)))
	for _, f := range pc.File {
	w.writeRefIndex(f)
	}
	}

	func (w *objWriter) writeInt(sval int64) {
	var v uint64
	uv := (uint64(sval) << 1) ^ uint64(sval>>63)
	p := w.varintbuf[:]
	for v = uv; v >= 0x80; v >>= 7 {
	p[0] = uint8(v \| 0x80)
	p = p[1:]
	}
	p[0] = uint8(v)
	p = p[1:]
	w.wr.Write(w.varintbuf[:len(w.varintbuf)-len(p)])
	}

	func (w *objWriter) writeString(s string) {
	w.writeInt(int64(len(s)))
	w.wr.WriteString(s)
	}

	func (w objWriter) writeRefIndex(s LSym) {
	if s == nil {
	w.writeInt(0)
	return
	}
	if s.RefIdx == 0 {
	log.Fatalln("writing an unreferenced symbol", s.Name)
	}
	w.writeInt(int64(s.RefIdx))
	}

	// relocByOff sorts relocations by their offsets.
	type relocByOff []Reloc

	func (x relocByOff) Len() int { return len(x) }
	func (x relocByOff) Less(i, j int) bool { return x[i].Off < x[j].Off }
	func (x relocByOff) Swap(i, j int) { x[i], x[j] = x[j], x[i] }

	// implement dwarf.Context
	type dwCtxt struct{ *Link }

	func (c dwCtxt) PtrSize() int {
	return c.Arch.PtrSize
	}
	func (c dwCtxt) AddInt(s dwarf.Sym, size int, i int64) {
	ls := s.(*LSym)
	ls.WriteInt(c.Link, ls.Size, size, i)
	}
	func (c dwCtxt) AddBytes(s dwarf.Sym, b []byte) {
	ls := s.(*LSym)
	ls.WriteBytes(c.Link, ls.Size, b)
	}
	func (c dwCtxt) AddString(s dwarf.Sym, v string) {
	ls := s.(*LSym)
	ls.WriteString(c.Link, ls.Size, len(v), v)
	ls.WriteInt(c.Link, ls.Size, 1, 0)
	}
	func (c dwCtxt) SymValue(s dwarf.Sym) int64 {
	return 0
	}
	func (c dwCtxt) AddAddress(s dwarf.Sym, data interface{}, value int64) {
	rsym := data.(*LSym)
	ls := s.(*LSym)
	size := c.PtrSize()
	ls.WriteAddr(c.Link, ls.Size, size, rsym, value)
	}
	func (c dwCtxt) AddSectionOffset(s dwarf.Sym, size int, t interface{}, ofs int64) {
	ls := s.(*LSym)
	rsym := t.(*LSym)
	ls.WriteAddr(c.Link, ls.Size, size, rsym, ofs)
	r := &ls.R[len(ls.R)-1]
	r.Type = R_DWARFREF
	}

	func gendwarf(ctxt Link, text []LSym) []*LSym {
	dctxt := dwCtxt{ctxt}
	var dw []*LSym

	for _, s := range text {
	dsym := Linklookup(ctxt, dwarf.InfoPrefix+s.Name, int(s.Version))
	if dsym.Size != 0 {
	continue
	}
	dw = append(dw, dsym)
	dsym.Type = SDWARFINFO
	dsym.Set(AttrDuplicateOK, s.DuplicateOK())
	var vars dwarf.Var
	var abbrev int
	var offs int32
	for a := s.Autom; a != nil; a = a.Link {
	switch a.Name {
	case NAME_AUTO:
	abbrev = dwarf.DW_ABRV_AUTO
	offs = a.Aoffset
	if ctxt.FixedFrameSize() == 0 {
	offs -= int32(ctxt.Arch.PtrSize)
	}
	if Framepointer_enabled(GOOS, GOARCH) {
	offs -= int32(ctxt.Arch.PtrSize)
	}

	case NAME_PARAM:
	abbrev = dwarf.DW_ABRV_PARAM
	offs = a.Aoffset + int32(ctxt.FixedFrameSize())

	default:
	continue
	}
	typename := dwarf.InfoPrefix + a.Gotype.Name[len("type."):]
	dwvar := &dwarf.Var{
	Name: a.Asym.Name,
	Abbrev: abbrev,
	Offset: int32(offs),
	Type: Linklookup(ctxt, typename, 0),
	}
	dws := &vars.Link
	for ; dws != nil; dws = &(dws).Link {
	if offs <= (*dws).Offset {
	break
	}
	}
	dwvar.Link = *dws
	*dws = dwvar
	}
	dwarf.PutFunc(dctxt, dsym, s.Name, s.Version == 0, s, s.Size, vars.Link)
	}
	return dw
	}