src/cmd/oldlink/internal/ld/pcln.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.

 package ld

 import (
 	"cmd/internal/obj"
 	"cmd/internal/objabi"
 	"cmd/internal/src"
 	"cmd/internal/sys"
 	"cmd/oldlink/internal/sym"
 	"encoding/binary"
 	"fmt"
 	"log"
 	"os"
 	"path/filepath"
 	"strings"
 )

 func ftabaddstring(ftab *sym.Symbol, s string) int32 {
 	start := len(ftab.P)
 	ftab.Grow(int64(start + len(s) + 1)) // make room for s plus trailing NUL
 	copy(ftab.P[start:], s)
 	return int32(start)
 }

 // numberfile assigns a file number to the file if it hasn't been assigned already.
 func numberfile(ctxt *Link, file *sym.Symbol) {
 	if file.Type != sym.SFILEPATH {
 		ctxt.Filesyms = append(ctxt.Filesyms, file)
 		file.Value = int64(len(ctxt.Filesyms))
 		file.Type = sym.SFILEPATH
 		path := file.Name[len(src.FileSymPrefix):]
 		file.Name = expandGoroot(path)
 	}
 }

 func renumberfiles(ctxt *Link, files []*sym.Symbol, d *sym.Pcdata) {
 	// Give files numbers.
 	for _, f := range files {
 		numberfile(ctxt, f)
 	}

 	buf := make([]byte, binary.MaxVarintLen32)
 	newval := int32(-1)
 	var out sym.Pcdata
 	it := obj.NewPCIter(uint32(ctxt.Arch.MinLC))
 	for it.Init(d.P); !it.Done; it.Next() {
 		// value delta
 		oldval := it.Value

 		var val int32
 		if oldval == -1 {
 			val = -1
 		} else {
 			if oldval < 0 || oldval >= int32(len(files)) {
 				log.Fatalf("bad pcdata %d", oldval)
 			}
 			val = int32(files[oldval].Value)
 		}

 		dv := val - newval
 		newval = val

 		// value
 		n := binary.PutVarint(buf, int64(dv))
 		out.P = append(out.P, buf[:n]...)

 		// pc delta
 		pc := (it.NextPC - it.PC) / it.PCScale
 		n = binary.PutUvarint(buf, uint64(pc))
 		out.P = append(out.P, buf[:n]...)
 	}

 	// terminating value delta
 	// we want to write varint-encoded 0, which is just 0
 	out.P = append(out.P, 0)

 	*d = out
 }

 // onlycsymbol reports whether this is a symbol that is referenced by C code.
 func onlycsymbol(s *sym.Symbol) bool {
 	switch s.Name {
 	case "_cgo_topofstack", "__cgo_topofstack", "_cgo_panic", "crosscall2":
 		return true
 	}
 	if strings.HasPrefix(s.Name, "_cgoexp_") {
 		return true
 	}
 	return false
 }

 func emitPcln(ctxt *Link, s *sym.Symbol) bool {
 	if s == nil {
 		return true
 	}
 	if ctxt.BuildMode == BuildModePlugin && ctxt.HeadType == objabi.Hdarwin && onlycsymbol(s) {
 		return false
 	}
 	// We want to generate func table entries only for the "lowest level" symbols,
 	// not containers of subsymbols.
 	return !s.Attr.Container()
 }

 // pclntab initializes the pclntab symbol with
 // runtime function and file name information.

 var pclntabZpcln sym.FuncInfo

 // These variables are used to initialize runtime.firstmoduledata, see symtab.go:symtab.
 var pclntabNfunc int32
 var pclntabFiletabOffset int32
 var pclntabPclntabOffset int32
 var pclntabFirstFunc *sym.Symbol
 var pclntabLastFunc *sym.Symbol

 func (ctxt *Link) pclntab() {
 	funcdataBytes := int64(0)
 	ftab := ctxt.Syms.Lookup("runtime.pclntab", 0)
 	ftab.Type = sym.SPCLNTAB
 	ftab.Attr |= sym.AttrReachable

 	// See golang.org/s/go12symtab for the format. Briefly:
 	//	8-byte header
 	//	nfunc [thearch.ptrsize bytes]
 	//	function table, alternating PC and offset to func struct [each entry thearch.ptrsize bytes]
 	//	end PC [thearch.ptrsize bytes]
 	//	offset to file table [4 bytes]

 	// Find container symbols and mark them as such.
 	for _, s := range ctxt.Textp {
 		if s.Outer != nil {
 			s.Outer.Attr |= sym.AttrContainer
 		}
 	}

 	// Gather some basic stats and info.
 	var nfunc int32
 	prevSect := ctxt.Textp[0].Sect
 	for _, s := range ctxt.Textp {
 		if !emitPcln(ctxt, s) {
 			continue
 		}
 		nfunc++
 		if pclntabFirstFunc == nil {
 			pclntabFirstFunc = s
 		}
 		if s.Sect != prevSect {
 			// With multiple text sections, the external linker may insert functions
 			// between the sections, which are not known by Go. This leaves holes in
 			// the PC range covered by the func table. We need to generate an entry
 			// to mark the hole.
 			nfunc++
 			prevSect = s.Sect
 		}
 	}

 	pclntabNfunc = nfunc
 	ftab.Grow(8 + int64(ctxt.Arch.PtrSize) + int64(nfunc)*2*int64(ctxt.Arch.PtrSize) + int64(ctxt.Arch.PtrSize) + 4)
 	ftab.SetUint32(ctxt.Arch, 0, 0xfffffffb)
 	ftab.SetUint8(ctxt.Arch, 6, uint8(ctxt.Arch.MinLC))
 	ftab.SetUint8(ctxt.Arch, 7, uint8(ctxt.Arch.PtrSize))
 	ftab.SetUint(ctxt.Arch, 8, uint64(nfunc))
 	pclntabPclntabOffset = int32(8 + ctxt.Arch.PtrSize)

 	funcnameoff := make(map[string]int32)
 	nameToOffset := func(name string) int32 {
 		nameoff, ok := funcnameoff[name]
 		if !ok {
 			nameoff = ftabaddstring(ftab, name)
 			funcnameoff[name] = nameoff
 		}
 		return nameoff
 	}

 	pctaboff := make(map[string]uint32)
 	writepctab := func(off int32, p []byte) int32 {
 		start, ok := pctaboff[string(p)]
 		if !ok {
 			if len(p) > 0 {
 				start = uint32(len(ftab.P))
 				ftab.AddBytes(p)
 			}
 			pctaboff[string(p)] = start
 		}
 		newoff := int32(ftab.SetUint32(ctxt.Arch, int64(off), start))
 		return newoff
 	}

 	nfunc = 0 // repurpose nfunc as a running index
 	prevFunc := ctxt.Textp[0]
 	for _, s := range ctxt.Textp {
 		if !emitPcln(ctxt, s) {
 			continue
 		}

 		if s.Sect != prevFunc.Sect {
 			// With multiple text sections, there may be a hole here in the address
 			// space (see the comment above). We use an invalid funcoff value to
 			// mark the hole.
 			// See also runtime/symtab.go:findfunc
 			ftab.SetAddrPlus(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)*2*int64(ctxt.Arch.PtrSize), prevFunc, prevFunc.Size)
 			ftab.SetUint(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)*2*int64(ctxt.Arch.PtrSize)+int64(ctxt.Arch.PtrSize), ^uint64(0))
 			nfunc++
 		}
 		prevFunc = s

 		pcln := s.FuncInfo
 		if pcln == nil {
 			pcln = &pclntabZpcln
 		}

 		if len(pcln.InlTree) > 0 {
 			if len(pcln.Pcdata) <= objabi.PCDATA_InlTreeIndex {
 				// Create inlining pcdata table.
 				pcdata := make([]sym.Pcdata, objabi.PCDATA_InlTreeIndex+1)
 				copy(pcdata, pcln.Pcdata)
 				pcln.Pcdata = pcdata
 			}

 			if len(pcln.Funcdataoff) <= objabi.FUNCDATA_InlTree {
 				// Create inline tree funcdata.
 				funcdata := make([]*sym.Symbol, objabi.FUNCDATA_InlTree+1)
 				funcdataoff := make([]int64, objabi.FUNCDATA_InlTree+1)
 				copy(funcdata, pcln.Funcdata)
 				copy(funcdataoff, pcln.Funcdataoff)
 				pcln.Funcdata = funcdata
 				pcln.Funcdataoff = funcdataoff
 			}
 		}

 		funcstart := int32(len(ftab.P))
 		funcstart += int32(-len(ftab.P)) & (int32(ctxt.Arch.PtrSize) - 1) // align to ptrsize

 		ftab.SetAddr(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)*2*int64(ctxt.Arch.PtrSize), s)
 		ftab.SetUint(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)*2*int64(ctxt.Arch.PtrSize)+int64(ctxt.Arch.PtrSize), uint64(funcstart))

 		// Write runtime._func. Keep in sync with ../../../../runtime/runtime2.go:/_func
 		// and package debug/gosym.

 		// fixed size of struct, checked below
 		off := funcstart

 		end := funcstart + int32(ctxt.Arch.PtrSize) + 3*4 + 5*4 + int32(len(pcln.Pcdata))*4 + int32(len(pcln.Funcdata))*int32(ctxt.Arch.PtrSize)
 		if len(pcln.Funcdata) > 0 && (end&int32(ctxt.Arch.PtrSize-1) != 0) {
 			end += 4
 		}
 		ftab.Grow(int64(end))

 		// entry uintptr
 		off = int32(ftab.SetAddr(ctxt.Arch, int64(off), s))

 		// name int32
 		nameoff := nameToOffset(s.Name)
 		off = int32(ftab.SetUint32(ctxt.Arch, int64(off), uint32(nameoff)))

 		// args int32
 		// TODO: Move into funcinfo.
 		args := uint32(0)
 		if s.FuncInfo != nil {
 			args = uint32(s.FuncInfo.Args)
 		}
 		off = int32(ftab.SetUint32(ctxt.Arch, int64(off), args))

 		// deferreturn
 		deferreturn := uint32(0)
 		lastWasmAddr := uint32(0)
 		for _, r := range s.R {
 			if ctxt.Arch.Family == sys.Wasm && r.Type == objabi.R_ADDR {
 				// Wasm does not have a live variable set at the deferreturn
 				// call itself. Instead it has one identified by the
 				// resumption point immediately preceding the deferreturn.
 				// The wasm code has a R_ADDR relocation which is used to
 				// set the resumption point to PC_B.
 				lastWasmAddr = uint32(r.Add)
 			}
 			if r.Type.IsDirectCall() && r.Sym != nil && (r.Sym.Name == "runtime.deferreturn" || r.Sym.Attr.DeferReturnTramp()) {
 				if ctxt.Arch.Family == sys.Wasm {
 					deferreturn = lastWasmAddr - 1
 				} else {
 					// Note: the relocation target is in the call instruction, but
 					// is not necessarily the whole instruction (for instance, on
 					// x86 the relocation applies to bytes [1:5] of the 5 byte call
 					// instruction).
 					deferreturn = uint32(r.Off)
 					switch ctxt.Arch.Family {
 					case sys.AMD64, sys.I386:
 						deferreturn--
 					case sys.PPC64, sys.ARM, sys.ARM64, sys.MIPS, sys.MIPS64:
 						// no change
 					case sys.RISCV64:
 						// TODO(jsing): The JALR instruction is marked with
 						// R_CALLRISCV, whereas the actual reloc is currently
 						// one instruction earlier starting with the AUIPC.
 						deferreturn -= 4
 					case sys.S390X:
 						deferreturn -= 2
 					default:
 						panic(fmt.Sprint("Unhandled architecture:", ctxt.Arch.Family))
 					}
 				}
 				break // only need one
 			}
 		}
 		off = int32(ftab.SetUint32(ctxt.Arch, int64(off), deferreturn))

 		if pcln != &pclntabZpcln {
 			renumberfiles(ctxt, pcln.File, &pcln.Pcfile)
 			if false {
 				// Sanity check the new numbering
 				it := obj.NewPCIter(uint32(ctxt.Arch.MinLC))
 				for it.Init(pcln.Pcfile.P); !it.Done; it.Next() {
 					if it.Value < 1 || it.Value > int32(len(ctxt.Filesyms)) {
 						Errorf(s, "bad file number in pcfile: %d not in range [1, %d]\n", it.Value, len(ctxt.Filesyms))
 						errorexit()
 					}
 				}
 			}
 		}

 		if len(pcln.InlTree) > 0 {
 			inlTreeSym := ctxt.Syms.Lookup("inltree."+s.Name, 0)
 			inlTreeSym.Type = sym.SRODATA
 			inlTreeSym.Attr |= sym.AttrReachable | sym.AttrDuplicateOK

 			for i, call := range pcln.InlTree {
 				// Usually, call.File is already numbered since the file
 				// shows up in the Pcfile table. However, two inlined calls
 				// might overlap exactly so that only the innermost file
 				// appears in the Pcfile table. In that case, this assigns
 				// the outer file a number.
 				numberfile(ctxt, call.File)
 				nameoff := nameToOffset(call.Func)

 				inlTreeSym.SetUint16(ctxt.Arch, int64(i*20+0), uint16(call.Parent))
 				inlTreeSym.SetUint8(ctxt.Arch, int64(i*20+2), uint8(objabi.GetFuncID(call.Func, "")))
 				// byte 3 is unused
 				inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+4), uint32(call.File.Value))
 				inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+8), uint32(call.Line))
 				inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+12), uint32(nameoff))
 				inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+16), uint32(call.ParentPC))
 			}

 			pcln.Funcdata[objabi.FUNCDATA_InlTree] = inlTreeSym
 			pcln.Pcdata[objabi.PCDATA_InlTreeIndex] = pcln.Pcinline
 		}

 		// pcdata
 		off = writepctab(off, pcln.Pcsp.P)
 		off = writepctab(off, pcln.Pcfile.P)
 		off = writepctab(off, pcln.Pcline.P)
 		off = int32(ftab.SetUint32(ctxt.Arch, int64(off), uint32(len(pcln.Pcdata))))

 		// funcID uint8
 		var file string
 		if s.FuncInfo != nil && len(s.FuncInfo.File) > 0 {
 			file = s.FuncInfo.File[0].Name
 		}
 		funcID := objabi.GetFuncID(s.Name, file)

 		off = int32(ftab.SetUint8(ctxt.Arch, int64(off), uint8(funcID)))

 		// unused
 		off += 2

 		// nfuncdata must be the final entry.
 		off = int32(ftab.SetUint8(ctxt.Arch, int64(off), uint8(len(pcln.Funcdata))))
 		for i := range pcln.Pcdata {
 			off = writepctab(off, pcln.Pcdata[i].P)
 		}

 		// funcdata, must be pointer-aligned and we're only int32-aligned.
 		// Missing funcdata will be 0 (nil pointer).
 		if len(pcln.Funcdata) > 0 {
 			if off&int32(ctxt.Arch.PtrSize-1) != 0 {
 				off += 4
 			}
 			for i := range pcln.Funcdata {
 				dataoff := int64(off) + int64(ctxt.Arch.PtrSize)*int64(i)
 				if pcln.Funcdata[i] == nil {
 					ftab.SetUint(ctxt.Arch, dataoff, uint64(pcln.Funcdataoff[i]))
 					continue
 				}
 				// TODO: Dedup.
 				funcdataBytes += pcln.Funcdata[i].Size
 				ftab.SetAddrPlus(ctxt.Arch, dataoff, pcln.Funcdata[i], pcln.Funcdataoff[i])
 			}
 			off += int32(len(pcln.Funcdata)) * int32(ctxt.Arch.PtrSize)
 		}

 		if off != end {
 			Errorf(s, "bad math in functab: funcstart=%d off=%d but end=%d (npcdata=%d nfuncdata=%d ptrsize=%d)", funcstart, off, end, len(pcln.Pcdata), len(pcln.Funcdata), ctxt.Arch.PtrSize)
 			errorexit()
 		}

 		nfunc++
 	}

 	last := ctxt.Textp[len(ctxt.Textp)-1]
 	pclntabLastFunc = last
 	// Final entry of table is just end pc.
 	ftab.SetAddrPlus(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)*2*int64(ctxt.Arch.PtrSize), last, last.Size)

 	// Start file table.
 	start := int32(len(ftab.P))

 	start += int32(-len(ftab.P)) & (int32(ctxt.Arch.PtrSize) - 1)
 	pclntabFiletabOffset = start
 	ftab.SetUint32(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)*2*int64(ctxt.Arch.PtrSize)+int64(ctxt.Arch.PtrSize), uint32(start))

 	ftab.Grow(int64(start) + (int64(len(ctxt.Filesyms))+1)*4)
 	ftab.SetUint32(ctxt.Arch, int64(start), uint32(len(ctxt.Filesyms)+1))
 	for i := len(ctxt.Filesyms) - 1; i >= 0; i-- {
 		s := ctxt.Filesyms[i]
 		ftab.SetUint32(ctxt.Arch, int64(start)+s.Value*4, uint32(ftabaddstring(ftab, s.Name)))
 	}

 	ftab.Size = int64(len(ftab.P))

 	if ctxt.Debugvlog != 0 {
 		ctxt.Logf("pclntab=%d bytes, funcdata total %d bytes\n", ftab.Size, funcdataBytes)
 	}
 }

 func gorootFinal() string {
 	root := objabi.GOROOT
 	if final := os.Getenv("GOROOT_FINAL"); final != "" {
 		root = final
 	}
 	return root
 }

 func expandGoroot(s string) string {
 	const n = len("$GOROOT")
 	if len(s) >= n+1 && s[:n] == "$GOROOT" && (s[n] == '/' || s[n] == '\\') {
 		return filepath.ToSlash(filepath.Join(gorootFinal(), s[n:]))
 	}
 	return s
 }

 const (
 	BUCKETSIZE    = 256 * MINFUNC
 	SUBBUCKETS    = 16
 	SUBBUCKETSIZE = BUCKETSIZE / SUBBUCKETS
 	NOIDX         = 0x7fffffff
 )

 // findfunctab generates a lookup table to quickly find the containing
 // function for a pc. See src/runtime/symtab.go:findfunc for details.
 func (ctxt *Link) findfunctab() {
 	t := ctxt.Syms.Lookup("runtime.findfunctab", 0)
 	t.Type = sym.SRODATA
 	t.Attr |= sym.AttrReachable
 	t.Attr |= sym.AttrLocal

 	// find min and max address
 	min := ctxt.Textp[0].Value
 	lastp := ctxt.Textp[len(ctxt.Textp)-1]
 	max := lastp.Value + lastp.Size

 	// for each subbucket, compute the minimum of all symbol indexes
 	// that map to that subbucket.
 	n := int32((max - min + SUBBUCKETSIZE - 1) / SUBBUCKETSIZE)

 	indexes := make([]int32, n)
 	for i := int32(0); i < n; i++ {
 		indexes[i] = NOIDX
 	}
 	idx := int32(0)
 	for i, s := range ctxt.Textp {
 		if !emitPcln(ctxt, s) {
 			continue
 		}
 		p := s.Value
 		var e *sym.Symbol
 		i++
 		if i < len(ctxt.Textp) {
 			e = ctxt.Textp[i]
 		}
 		for !emitPcln(ctxt, e) && i < len(ctxt.Textp) {
 			e = ctxt.Textp[i]
 			i++
 		}
 		q := max
 		if e != nil {
 			q = e.Value
 		}

 		//print("%d: [%lld %lld] %s\n", idx, p, q, s->name);
 		for ; p < q; p += SUBBUCKETSIZE {
 			i = int((p - min) / SUBBUCKETSIZE)
 			if indexes[i] > idx {
 				indexes[i] = idx
 			}
 		}

 		i = int((q - 1 - min) / SUBBUCKETSIZE)
 		if indexes[i] > idx {
 			indexes[i] = idx
 		}
 		idx++
 	}

 	// allocate table
 	nbuckets := int32((max - min + BUCKETSIZE - 1) / BUCKETSIZE)

 	t.Grow(4*int64(nbuckets) + int64(n))

 	// fill in table
 	for i := int32(0); i < nbuckets; i++ {
 		base := indexes[i*SUBBUCKETS]
 		if base == NOIDX {
 			Errorf(nil, "hole in findfunctab")
 		}
 		t.SetUint32(ctxt.Arch, int64(i)*(4+SUBBUCKETS), uint32(base))
 		for j := int32(0); j < SUBBUCKETS && i*SUBBUCKETS+j < n; j++ {
 			idx = indexes[i*SUBBUCKETS+j]
 			if idx == NOIDX {
 				Errorf(nil, "hole in findfunctab")
 			}
 			if idx-base >= 256 {
 				Errorf(nil, "too many functions in a findfunc bucket! %d/%d %d %d", i, nbuckets, j, idx-base)
 			}

 			t.SetUint8(ctxt.Arch, int64(i)*(4+SUBBUCKETS)+4+int64(j), uint8(idx-base))
 		}
 	}
 }
	// 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.

	package ld

	import (
	"cmd/internal/obj"
	"cmd/internal/objabi"
	"cmd/internal/src"
	"cmd/internal/sys"
	"cmd/oldlink/internal/sym"
	"encoding/binary"
	"fmt"
	"log"
	"os"
	"path/filepath"
	"strings"
	)

	func ftabaddstring(ftab *sym.Symbol, s string) int32 {
	start := len(ftab.P)
	ftab.Grow(int64(start + len(s) + 1)) // make room for s plus trailing NUL
	copy(ftab.P[start:], s)
	return int32(start)
	}

	// numberfile assigns a file number to the file if it hasn't been assigned already.
	func numberfile(ctxt Link, file sym.Symbol) {
	if file.Type != sym.SFILEPATH {
	ctxt.Filesyms = append(ctxt.Filesyms, file)
	file.Value = int64(len(ctxt.Filesyms))
	file.Type = sym.SFILEPATH
	path := file.Name[len(src.FileSymPrefix):]
	file.Name = expandGoroot(path)
	}
	}

	func renumberfiles(ctxt Link, files []sym.Symbol, d *sym.Pcdata) {
	// Give files numbers.
	for _, f := range files {
	numberfile(ctxt, f)
	}

	buf := make([]byte, binary.MaxVarintLen32)
	newval := int32(-1)
	var out sym.Pcdata
	it := obj.NewPCIter(uint32(ctxt.Arch.MinLC))
	for it.Init(d.P); !it.Done; it.Next() {
	// value delta
	oldval := it.Value

	var val int32
	if oldval == -1 {
	val = -1
	} else {
	if oldval < 0 \|\| oldval >= int32(len(files)) {
	log.Fatalf("bad pcdata %d", oldval)
	}
	val = int32(files[oldval].Value)
	}

	dv := val - newval
	newval = val

	// value
	n := binary.PutVarint(buf, int64(dv))
	out.P = append(out.P, buf[:n]...)

	// pc delta
	pc := (it.NextPC - it.PC) / it.PCScale
	n = binary.PutUvarint(buf, uint64(pc))
	out.P = append(out.P, buf[:n]...)
	}

	// terminating value delta
	// we want to write varint-encoded 0, which is just 0
	out.P = append(out.P, 0)

	*d = out
	}

	// onlycsymbol reports whether this is a symbol that is referenced by C code.
	func onlycsymbol(s *sym.Symbol) bool {
	switch s.Name {
	case "_cgo_topofstack", "__cgo_topofstack", "_cgo_panic", "crosscall2":
	return true
	}
	if strings.HasPrefix(s.Name, "_cgoexp_") {
	return true
	}
	return false
	}

	func emitPcln(ctxt Link, s sym.Symbol) bool {
	if s == nil {
	return true
	}
	if ctxt.BuildMode == BuildModePlugin && ctxt.HeadType == objabi.Hdarwin && onlycsymbol(s) {
	return false
	}
	// We want to generate func table entries only for the "lowest level" symbols,
	// not containers of subsymbols.
	return !s.Attr.Container()
	}

	// pclntab initializes the pclntab symbol with
	// runtime function and file name information.

	var pclntabZpcln sym.FuncInfo

	// These variables are used to initialize runtime.firstmoduledata, see symtab.go:symtab.
	var pclntabNfunc int32
	var pclntabFiletabOffset int32
	var pclntabPclntabOffset int32
	var pclntabFirstFunc *sym.Symbol
	var pclntabLastFunc *sym.Symbol

	func (ctxt *Link) pclntab() {
	funcdataBytes := int64(0)
	ftab := ctxt.Syms.Lookup("runtime.pclntab", 0)
	ftab.Type = sym.SPCLNTAB
	ftab.Attr \|= sym.AttrReachable

	// See golang.org/s/go12symtab for the format. Briefly:
	// 8-byte header
	// nfunc [thearch.ptrsize bytes]
	// function table, alternating PC and offset to func struct [each entry thearch.ptrsize bytes]
	// end PC [thearch.ptrsize bytes]
	// offset to file table [4 bytes]

	// Find container symbols and mark them as such.
	for _, s := range ctxt.Textp {
	if s.Outer != nil {
	s.Outer.Attr \|= sym.AttrContainer
	}
	}

	// Gather some basic stats and info.
	var nfunc int32
	prevSect := ctxt.Textp[0].Sect
	for _, s := range ctxt.Textp {
	if !emitPcln(ctxt, s) {
	continue
	}
	nfunc++
	if pclntabFirstFunc == nil {
	pclntabFirstFunc = s
	}
	if s.Sect != prevSect {
	// With multiple text sections, the external linker may insert functions
	// between the sections, which are not known by Go. This leaves holes in
	// the PC range covered by the func table. We need to generate an entry
	// to mark the hole.
	nfunc++
	prevSect = s.Sect
	}
	}

	pclntabNfunc = nfunc
	ftab.Grow(8 + int64(ctxt.Arch.PtrSize) + int64(nfunc)2int64(ctxt.Arch.PtrSize) + int64(ctxt.Arch.PtrSize) + 4)
	ftab.SetUint32(ctxt.Arch, 0, 0xfffffffb)
	ftab.SetUint8(ctxt.Arch, 6, uint8(ctxt.Arch.MinLC))
	ftab.SetUint8(ctxt.Arch, 7, uint8(ctxt.Arch.PtrSize))
	ftab.SetUint(ctxt.Arch, 8, uint64(nfunc))
	pclntabPclntabOffset = int32(8 + ctxt.Arch.PtrSize)

	funcnameoff := make(map[string]int32)
	nameToOffset := func(name string) int32 {
	nameoff, ok := funcnameoff[name]
	if !ok {
	nameoff = ftabaddstring(ftab, name)
	funcnameoff[name] = nameoff
	}
	return nameoff
	}

	pctaboff := make(map[string]uint32)
	writepctab := func(off int32, p []byte) int32 {
	start, ok := pctaboff[string(p)]
	if !ok {
	if len(p) > 0 {
	start = uint32(len(ftab.P))
	ftab.AddBytes(p)
	}
	pctaboff[string(p)] = start
	}
	newoff := int32(ftab.SetUint32(ctxt.Arch, int64(off), start))
	return newoff
	}

	nfunc = 0 // repurpose nfunc as a running index
	prevFunc := ctxt.Textp[0]
	for _, s := range ctxt.Textp {
	if !emitPcln(ctxt, s) {
	continue
	}

	if s.Sect != prevFunc.Sect {
	// With multiple text sections, there may be a hole here in the address
	// space (see the comment above). We use an invalid funcoff value to
	// mark the hole.
	// See also runtime/symtab.go:findfunc
	ftab.SetAddrPlus(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)2int64(ctxt.Arch.PtrSize), prevFunc, prevFunc.Size)
	ftab.SetUint(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)2int64(ctxt.Arch.PtrSize)+int64(ctxt.Arch.PtrSize), ^uint64(0))
	nfunc++
	}
	prevFunc = s

	pcln := s.FuncInfo
	if pcln == nil {
	pcln = &pclntabZpcln
	}

	if len(pcln.InlTree) > 0 {
	if len(pcln.Pcdata) <= objabi.PCDATA_InlTreeIndex {
	// Create inlining pcdata table.
	pcdata := make([]sym.Pcdata, objabi.PCDATA_InlTreeIndex+1)
	copy(pcdata, pcln.Pcdata)
	pcln.Pcdata = pcdata
	}

	if len(pcln.Funcdataoff) <= objabi.FUNCDATA_InlTree {
	// Create inline tree funcdata.
	funcdata := make([]*sym.Symbol, objabi.FUNCDATA_InlTree+1)
	funcdataoff := make([]int64, objabi.FUNCDATA_InlTree+1)
	copy(funcdata, pcln.Funcdata)
	copy(funcdataoff, pcln.Funcdataoff)
	pcln.Funcdata = funcdata
	pcln.Funcdataoff = funcdataoff
	}
	}

	funcstart := int32(len(ftab.P))
	funcstart += int32(-len(ftab.P)) & (int32(ctxt.Arch.PtrSize) - 1) // align to ptrsize

	ftab.SetAddr(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)2int64(ctxt.Arch.PtrSize), s)
	ftab.SetUint(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)2int64(ctxt.Arch.PtrSize)+int64(ctxt.Arch.PtrSize), uint64(funcstart))

	// Write runtime._func. Keep in sync with ../../../../runtime/runtime2.go:/_func
	// and package debug/gosym.

	// fixed size of struct, checked below
	off := funcstart

	end := funcstart + int32(ctxt.Arch.PtrSize) + 34 + 54 + int32(len(pcln.Pcdata))4 + int32(len(pcln.Funcdata))int32(ctxt.Arch.PtrSize)
	if len(pcln.Funcdata) > 0 && (end&int32(ctxt.Arch.PtrSize-1) != 0) {
	end += 4
	}
	ftab.Grow(int64(end))

	// entry uintptr
	off = int32(ftab.SetAddr(ctxt.Arch, int64(off), s))

	// name int32
	nameoff := nameToOffset(s.Name)
	off = int32(ftab.SetUint32(ctxt.Arch, int64(off), uint32(nameoff)))

	// args int32
	// TODO: Move into funcinfo.
	args := uint32(0)
	if s.FuncInfo != nil {
	args = uint32(s.FuncInfo.Args)
	}
	off = int32(ftab.SetUint32(ctxt.Arch, int64(off), args))

	// deferreturn
	deferreturn := uint32(0)
	lastWasmAddr := uint32(0)
	for _, r := range s.R {
	if ctxt.Arch.Family == sys.Wasm && r.Type == objabi.R_ADDR {
	// Wasm does not have a live variable set at the deferreturn
	// call itself. Instead it has one identified by the
	// resumption point immediately preceding the deferreturn.
	// The wasm code has a R_ADDR relocation which is used to
	// set the resumption point to PC_B.
	lastWasmAddr = uint32(r.Add)
	}
	if r.Type.IsDirectCall() && r.Sym != nil && (r.Sym.Name == "runtime.deferreturn" \|\| r.Sym.Attr.DeferReturnTramp()) {
	if ctxt.Arch.Family == sys.Wasm {
	deferreturn = lastWasmAddr - 1
	} else {
	// Note: the relocation target is in the call instruction, but
	// is not necessarily the whole instruction (for instance, on
	// x86 the relocation applies to bytes [1:5] of the 5 byte call
	// instruction).
	deferreturn = uint32(r.Off)
	switch ctxt.Arch.Family {
	case sys.AMD64, sys.I386:
	deferreturn--
	case sys.PPC64, sys.ARM, sys.ARM64, sys.MIPS, sys.MIPS64:
	// no change
	case sys.RISCV64:
	// TODO(jsing): The JALR instruction is marked with
	// R_CALLRISCV, whereas the actual reloc is currently
	// one instruction earlier starting with the AUIPC.
	deferreturn -= 4
	case sys.S390X:
	deferreturn -= 2
	default:
	panic(fmt.Sprint("Unhandled architecture:", ctxt.Arch.Family))
	}
	}
	break // only need one
	}
	}
	off = int32(ftab.SetUint32(ctxt.Arch, int64(off), deferreturn))

	if pcln != &pclntabZpcln {
	renumberfiles(ctxt, pcln.File, &pcln.Pcfile)
	if false {
	// Sanity check the new numbering
	it := obj.NewPCIter(uint32(ctxt.Arch.MinLC))
	for it.Init(pcln.Pcfile.P); !it.Done; it.Next() {
	if it.Value < 1 \|\| it.Value > int32(len(ctxt.Filesyms)) {
	Errorf(s, "bad file number in pcfile: %d not in range [1, %d]\n", it.Value, len(ctxt.Filesyms))
	errorexit()
	}
	}
	}
	}

	if len(pcln.InlTree) > 0 {
	inlTreeSym := ctxt.Syms.Lookup("inltree."+s.Name, 0)
	inlTreeSym.Type = sym.SRODATA
	inlTreeSym.Attr \|= sym.AttrReachable \| sym.AttrDuplicateOK

	for i, call := range pcln.InlTree {
	// Usually, call.File is already numbered since the file
	// shows up in the Pcfile table. However, two inlined calls
	// might overlap exactly so that only the innermost file
	// appears in the Pcfile table. In that case, this assigns
	// the outer file a number.
	numberfile(ctxt, call.File)
	nameoff := nameToOffset(call.Func)

	inlTreeSym.SetUint16(ctxt.Arch, int64(i*20+0), uint16(call.Parent))
	inlTreeSym.SetUint8(ctxt.Arch, int64(i*20+2), uint8(objabi.GetFuncID(call.Func, "")))
	// byte 3 is unused
	inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+4), uint32(call.File.Value))
	inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+8), uint32(call.Line))
	inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+12), uint32(nameoff))
	inlTreeSym.SetUint32(ctxt.Arch, int64(i*20+16), uint32(call.ParentPC))
	}

	pcln.Funcdata[objabi.FUNCDATA_InlTree] = inlTreeSym
	pcln.Pcdata[objabi.PCDATA_InlTreeIndex] = pcln.Pcinline
	}

	// pcdata
	off = writepctab(off, pcln.Pcsp.P)
	off = writepctab(off, pcln.Pcfile.P)
	off = writepctab(off, pcln.Pcline.P)
	off = int32(ftab.SetUint32(ctxt.Arch, int64(off), uint32(len(pcln.Pcdata))))

	// funcID uint8
	var file string
	if s.FuncInfo != nil && len(s.FuncInfo.File) > 0 {
	file = s.FuncInfo.File[0].Name
	}
	funcID := objabi.GetFuncID(s.Name, file)

	off = int32(ftab.SetUint8(ctxt.Arch, int64(off), uint8(funcID)))

	// unused
	off += 2

	// nfuncdata must be the final entry.
	off = int32(ftab.SetUint8(ctxt.Arch, int64(off), uint8(len(pcln.Funcdata))))
	for i := range pcln.Pcdata {
	off = writepctab(off, pcln.Pcdata[i].P)
	}

	// funcdata, must be pointer-aligned and we're only int32-aligned.
	// Missing funcdata will be 0 (nil pointer).
	if len(pcln.Funcdata) > 0 {
	if off&int32(ctxt.Arch.PtrSize-1) != 0 {
	off += 4
	}
	for i := range pcln.Funcdata {
	dataoff := int64(off) + int64(ctxt.Arch.PtrSize)*int64(i)
	if pcln.Funcdata[i] == nil {
	ftab.SetUint(ctxt.Arch, dataoff, uint64(pcln.Funcdataoff[i]))
	continue
	}
	// TODO: Dedup.
	funcdataBytes += pcln.Funcdata[i].Size
	ftab.SetAddrPlus(ctxt.Arch, dataoff, pcln.Funcdata[i], pcln.Funcdataoff[i])
	}
	off += int32(len(pcln.Funcdata)) * int32(ctxt.Arch.PtrSize)
	}

	if off != end {
	Errorf(s, "bad math in functab: funcstart=%d off=%d but end=%d (npcdata=%d nfuncdata=%d ptrsize=%d)", funcstart, off, end, len(pcln.Pcdata), len(pcln.Funcdata), ctxt.Arch.PtrSize)
	errorexit()
	}

	nfunc++
	}

	last := ctxt.Textp[len(ctxt.Textp)-1]
	pclntabLastFunc = last
	// Final entry of table is just end pc.
	ftab.SetAddrPlus(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)2int64(ctxt.Arch.PtrSize), last, last.Size)

	// Start file table.
	start := int32(len(ftab.P))

	start += int32(-len(ftab.P)) & (int32(ctxt.Arch.PtrSize) - 1)
	pclntabFiletabOffset = start
	ftab.SetUint32(ctxt.Arch, 8+int64(ctxt.Arch.PtrSize)+int64(nfunc)2int64(ctxt.Arch.PtrSize)+int64(ctxt.Arch.PtrSize), uint32(start))

	ftab.Grow(int64(start) + (int64(len(ctxt.Filesyms))+1)*4)
	ftab.SetUint32(ctxt.Arch, int64(start), uint32(len(ctxt.Filesyms)+1))
	for i := len(ctxt.Filesyms) - 1; i >= 0; i-- {
	s := ctxt.Filesyms[i]
	ftab.SetUint32(ctxt.Arch, int64(start)+s.Value*4, uint32(ftabaddstring(ftab, s.Name)))
	}

	ftab.Size = int64(len(ftab.P))

	if ctxt.Debugvlog != 0 {
	ctxt.Logf("pclntab=%d bytes, funcdata total %d bytes\n", ftab.Size, funcdataBytes)
	}
	}

	func gorootFinal() string {
	root := objabi.GOROOT
	if final := os.Getenv("GOROOT_FINAL"); final != "" {
	root = final
	}
	return root
	}

	func expandGoroot(s string) string {
	const n = len("$GOROOT")
	if len(s) >= n+1 && s[:n] == "$GOROOT" && (s[n] == '/' \|\| s[n] == '\\') {
	return filepath.ToSlash(filepath.Join(gorootFinal(), s[n:]))
	}
	return s
	}

	const (
	BUCKETSIZE = 256 * MINFUNC
	SUBBUCKETS = 16
	SUBBUCKETSIZE = BUCKETSIZE / SUBBUCKETS
	NOIDX = 0x7fffffff
	)

	// findfunctab generates a lookup table to quickly find the containing
	// function for a pc. See src/runtime/symtab.go:findfunc for details.
	func (ctxt *Link) findfunctab() {
	t := ctxt.Syms.Lookup("runtime.findfunctab", 0)
	t.Type = sym.SRODATA
	t.Attr \|= sym.AttrReachable
	t.Attr \|= sym.AttrLocal

	// find min and max address
	min := ctxt.Textp[0].Value
	lastp := ctxt.Textp[len(ctxt.Textp)-1]
	max := lastp.Value + lastp.Size

	// for each subbucket, compute the minimum of all symbol indexes
	// that map to that subbucket.
	n := int32((max - min + SUBBUCKETSIZE - 1) / SUBBUCKETSIZE)

	indexes := make([]int32, n)
	for i := int32(0); i < n; i++ {
	indexes[i] = NOIDX
	}
	idx := int32(0)
	for i, s := range ctxt.Textp {
	if !emitPcln(ctxt, s) {
	continue
	}
	p := s.Value
	var e *sym.Symbol
	i++
	if i < len(ctxt.Textp) {
	e = ctxt.Textp[i]
	}
	for !emitPcln(ctxt, e) && i < len(ctxt.Textp) {
	e = ctxt.Textp[i]
	i++
	}
	q := max
	if e != nil {
	q = e.Value
	}

	//print("%d: [%lld %lld] %s\n", idx, p, q, s->name);
	for ; p < q; p += SUBBUCKETSIZE {
	i = int((p - min) / SUBBUCKETSIZE)
	if indexes[i] > idx {
	indexes[i] = idx
	}
	}

	i = int((q - 1 - min) / SUBBUCKETSIZE)
	if indexes[i] > idx {
	indexes[i] = idx
	}
	idx++
	}

	// allocate table
	nbuckets := int32((max - min + BUCKETSIZE - 1) / BUCKETSIZE)

	t.Grow(4*int64(nbuckets) + int64(n))

	// fill in table
	for i := int32(0); i < nbuckets; i++ {
	base := indexes[i*SUBBUCKETS]
	if base == NOIDX {
	Errorf(nil, "hole in findfunctab")
	}
	t.SetUint32(ctxt.Arch, int64(i)*(4+SUBBUCKETS), uint32(base))
	for j := int32(0); j < SUBBUCKETS && i*SUBBUCKETS+j < n; j++ {
	idx = indexes[i*SUBBUCKETS+j]
	if idx == NOIDX {
	Errorf(nil, "hole in findfunctab")
	}
	if idx-base >= 256 {
	Errorf(nil, "too many functions in a findfunc bucket! %d/%d %d %d", i, nbuckets, j, idx-base)
	}

	t.SetUint8(ctxt.Arch, int64(i)*(4+SUBBUCKETS)+4+int64(j), uint8(idx-base))
	}
	}
	}