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	// Derived from Inferno utils/6l/obj.c and utils/6l/span.c
	// https://bitbucket.org/inferno-os/inferno-os/src/master/utils/6l/obj.c
	// https://bitbucket.org/inferno-os/inferno-os/src/master/utils/6l/span.c
	//
	// Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved.
	// Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net)
	// Portions Copyright © 1997-1999 Vita Nuova Limited
	// Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com)
	// Portions Copyright © 2004,2006 Bruce Ellis
	// Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net)
	// Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others
	// Portions Copyright © 2009 The Go Authors. All rights reserved.
	//
	// Permission is hereby granted, free of charge, to any person obtaining a copy
	// of this software and associated documentation files (the "Software"), to deal
	// in the Software without restriction, including without limitation the rights
	// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	// copies of the Software, and to permit persons to whom the Software is
	// furnished to do so, subject to the following conditions:
	//
	// The above copyright notice and this permission notice shall be included in
	// all copies or substantial portions of the Software.
	//
	// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	// THE SOFTWARE.

	package ld

	import (
	"bytes"
	"cmd/internal/gcprog"
	"cmd/internal/objabi"
	"cmd/internal/sys"
	"cmd/link/internal/loader"
	"cmd/link/internal/loadpe"
	"cmd/link/internal/sym"
	"compress/zlib"
	"debug/elf"
	"encoding/binary"
	"fmt"
	"internal/abi"
	"log"
	"math/rand"
	"os"
	"sort"
	"strconv"
	"strings"
	"sync"
	"sync/atomic"
	)

	// isRuntimeDepPkg reports whether pkg is the runtime package or its dependency.
	func isRuntimeDepPkg(pkg string) bool {
	return objabi.LookupPkgSpecial(pkg).Runtime
	}

	// Estimate the max size needed to hold any new trampolines created for this function. This
	// is used to determine when the section can be split if it becomes too large, to ensure that
	// the trampolines are in the same section as the function that uses them.
	func maxSizeTrampolines(ctxt Link, ldr loader.Loader, s loader.Sym, isTramp bool) uint64 {
	// If thearch.Trampoline is nil, then trampoline support is not available on this arch.
	// A trampoline does not need any dependent trampolines.
	if thearch.Trampoline == nil \|\| isTramp {
	return 0
	}

	n := uint64(0)
	relocs := ldr.Relocs(s)
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	if r.Type().IsDirectCallOrJump() {
	n++
	}
	}

	switch {
	case ctxt.IsARM():
	return n * 20 // Trampolines in ARM range from 3 to 5 instructions.
	case ctxt.IsARM64():
	return n * 12 // Trampolines in ARM64 are 3 instructions.
	case ctxt.IsLOONG64():
	return n * 12 // Trampolines in LOONG64 are 3 instructions.
	case ctxt.IsPPC64():
	return n * 16 // Trampolines in PPC64 are 4 instructions.
	case ctxt.IsRISCV64():
	return n * 8 // Trampolines in RISCV64 are 2 instructions.
	}
	panic("unreachable")
	}

	// Detect too-far jumps in function s, and add trampolines if necessary.
	// ARM, LOONG64, PPC64, PPC64LE and RISCV64 support trampoline insertion for internal
	// and external linking. On PPC64 and PPC64LE the text sections might be split
	// but will still insert trampolines where necessary.
	func trampoline(ctxt *Link, s loader.Sym) {
	if thearch.Trampoline == nil {
	return // no need or no support of trampolines on this arch
	}

	ldr := ctxt.loader
	relocs := ldr.Relocs(s)
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	rt := r.Type()
	if !rt.IsDirectCallOrJump() && !isPLTCall(ctxt.Arch, rt) {
	continue
	}
	rs := r.Sym()
	if !ldr.AttrReachable(rs) \|\| ldr.SymType(rs) == sym.Sxxx {
	continue // something is wrong. skip it here and we'll emit a better error later
	}

	if ldr.SymValue(rs) == 0 && ldr.SymType(rs) != sym.SDYNIMPORT && ldr.SymType(rs) != sym.SUNDEFEXT {
	// Symbols in the same package are laid out together (if we
	// don't randomize the function order).
	// Except that if SymPkg(s) == "", it is a host object symbol
	// which may call an external symbol via PLT.
	if ldr.SymPkg(s) != "" && ldr.SymPkg(rs) == ldr.SymPkg(s) && ldr.SymType(rs) == ldr.SymType(s) && *flagRandLayout == 0 {
	// RISC-V is only able to reach +/-1MiB via a JAL instruction.
	// We need to generate a trampoline when an address is
	// currently unknown.
	if !ctxt.Target.IsRISCV64() {
	continue
	}
	}
	// Runtime packages are laid out together.
	if isRuntimeDepPkg(ldr.SymPkg(s)) && isRuntimeDepPkg(ldr.SymPkg(rs)) && *flagRandLayout == 0 {
	continue
	}
	}
	thearch.Trampoline(ctxt, ldr, ri, rs, s)
	}
	}

	// whether rt is a (host object) relocation that will be turned into
	// a call to PLT.
	func isPLTCall(arch *sys.Arch, rt objabi.RelocType) bool {
	const pcrel = 1
	switch uint32(arch.Family) \| uint32(rt)<<8 {
	// ARM64
	case uint32(sys.ARM64) \| uint32(objabi.ElfRelocOffset+objabi.RelocType(elf.R_AARCH64_CALL26))<<8,
	uint32(sys.ARM64) \| uint32(objabi.ElfRelocOffset+objabi.RelocType(elf.R_AARCH64_JUMP26))<<8,
	uint32(sys.ARM64) \| uint32(objabi.MachoRelocOffset+MACHO_ARM64_RELOC_BRANCH26*2+pcrel)<<8:
	return true

	// ARM
	case uint32(sys.ARM) \| uint32(objabi.ElfRelocOffset+objabi.RelocType(elf.R_ARM_CALL))<<8,
	uint32(sys.ARM) \| uint32(objabi.ElfRelocOffset+objabi.RelocType(elf.R_ARM_PC24))<<8,
	uint32(sys.ARM) \| uint32(objabi.ElfRelocOffset+objabi.RelocType(elf.R_ARM_JUMP24))<<8:
	return true

	// Loong64
	case uint32(sys.Loong64) \| uint32(objabi.ElfRelocOffset+objabi.RelocType(elf.R_LARCH_B26))<<8:
	return true
	}
	// TODO: other architectures.
	return false
	}

	// FoldSubSymbolOffset computes the offset of symbol s to its top-level outer
	// symbol. Returns the top-level symbol and the offset.
	// This is used in generating external relocations.
	func FoldSubSymbolOffset(ldr *loader.Loader, s loader.Sym) (loader.Sym, int64) {
	outer := ldr.OuterSym(s)
	off := int64(0)
	if outer != 0 {
	off += ldr.SymValue(s) - ldr.SymValue(outer)
	s = outer
	}
	return s, off
	}

	// relocsym resolve relocations in "s", updating the symbol's content
	// in "P".
	// The main loop walks through the list of relocations attached to "s"
	// and resolves them where applicable. Relocations are often
	// architecture-specific, requiring calls into the 'archreloc' and/or
	// 'archrelocvariant' functions for the architecture. When external
	// linking is in effect, it may not be possible to completely resolve
	// the address/offset for a symbol, in which case the goal is to lay
	// the groundwork for turning a given relocation into an external reloc
	// (to be applied by the external linker). For more on how relocations
	// work in general, see
	//
	// "Linkers and Loaders", by John R. Levine (Morgan Kaufmann, 1999), ch. 7
	//
	// This is a performance-critical function for the linker; be careful
	// to avoid introducing unnecessary allocations in the main loop.
	func (st *relocSymState) relocsym(s loader.Sym, P []byte) {
	ldr := st.ldr
	relocs := ldr.Relocs(s)
	if relocs.Count() == 0 {
	return
	}
	target := st.target
	syms := st.syms
	nExtReloc := 0 // number of external relocations
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	off := r.Off()
	siz := int32(r.Siz())
	rs := r.Sym()
	rt := r.Type()
	weak := r.Weak()
	if off < 0 \|\| off+siz > int32(len(P)) {
	rname := ""
	if rs != 0 {
	rname = ldr.SymName(rs)
	}
	st.err.Errorf(s, "invalid relocation %s: %d+%d not in [%d,%d)", rname, off, siz, 0, len(P))
	continue
	}
	if siz == 0 { // informational relocation - no work to do
	continue
	}

	var rst sym.SymKind
	if rs != 0 {
	rst = ldr.SymType(rs)
	}

	if rs != 0 && (rst == sym.Sxxx \|\| rst == sym.SXREF) {
	// When putting the runtime but not main into a shared library
	// these symbols are undefined and that's OK.
	if target.IsShared() \|\| target.IsPlugin() {
	if ldr.SymName(rs) == "main.main" \|\| (!target.IsPlugin() && ldr.SymName(rs) == "main..inittask") {
	sb := ldr.MakeSymbolUpdater(rs)
	sb.SetType(sym.SDYNIMPORT)
	} else if strings.HasPrefix(ldr.SymName(rs), "go:info.") {
	// Skip go.info symbols. They are only needed to communicate
	// DWARF info between the compiler and linker.
	continue
	}
	} else if target.IsPPC64() && ldr.SymName(rs) == ".TOC." {
	// TOC symbol doesn't have a type but we do assign a value
	// (see the address pass) and we can resolve it.
	// TODO: give it a type.
	} else {
	st.err.errorUnresolved(ldr, s, rs)
	continue
	}
	}

	if rt >= objabi.ElfRelocOffset {
	continue
	}

	// We need to be able to reference dynimport symbols when linking against
	// shared libraries, and AIX, Darwin, OpenBSD and Solaris always need it.
	if !target.IsAIX() && !target.IsDarwin() && !target.IsSolaris() && !target.IsOpenbsd() && rs != 0 && rst == sym.SDYNIMPORT && !target.IsDynlinkingGo() && !ldr.AttrSubSymbol(rs) {
	if !(target.IsPPC64() && target.IsExternal() && ldr.SymName(rs) == ".TOC.") {
	st.err.Errorf(s, "unhandled relocation for %s (type %d (%s) rtype %d (%s))", ldr.SymName(rs), rst, rst, rt, sym.RelocName(target.Arch, rt))
	}
	}
	if rs != 0 && rst != sym.STLSBSS && !weak && rt != objabi.R_METHODOFF && !ldr.AttrReachable(rs) {
	st.err.Errorf(s, "unreachable sym in relocation: %s", ldr.SymName(rs))
	}

	var rv sym.RelocVariant
	if target.IsPPC64() \|\| target.IsS390X() {
	rv = ldr.RelocVariant(s, ri)
	}

	// TODO(mundaym): remove this special case - see issue 14218.
	if target.IsS390X() {
	switch rt {
	case objabi.R_PCRELDBL:
	rt = objabi.R_PCREL
	rv = sym.RV_390_DBL
	case objabi.R_CALL:
	rv = sym.RV_390_DBL
	}
	}

	var o int64
	switch rt {
	default:
	switch siz {
	default:
	st.err.Errorf(s, "bad reloc size %#x for %s", uint32(siz), ldr.SymName(rs))
	case 1:
	o = int64(P[off])
	case 2:
	o = int64(target.Arch.ByteOrder.Uint16(P[off:]))
	case 4:
	o = int64(target.Arch.ByteOrder.Uint32(P[off:]))
	case 8:
	o = int64(target.Arch.ByteOrder.Uint64(P[off:]))
	}
	out, n, ok := thearch.Archreloc(target, ldr, syms, r, s, o)
	if target.IsExternal() {
	nExtReloc += n
	}
	if ok {
	o = out
	} else {
	st.err.Errorf(s, "unknown reloc to %v: %d (%s)", ldr.SymName(rs), rt, sym.RelocName(target.Arch, rt))
	}
	case objabi.R_TLS_LE:
	if target.IsExternal() && target.IsElf() {
	nExtReloc++
	o = 0
	if !target.IsAMD64() {
	o = r.Add()
	}
	break
	}

	if target.IsElf() && target.IsARM() {
	// On ELF ARM, the thread pointer is 8 bytes before
	// the start of the thread-local data block, so add 8
	// to the actual TLS offset (r->sym->value).
	// This 8 seems to be a fundamental constant of
	// ELF on ARM (or maybe Glibc on ARM); it is not
	// related to the fact that our own TLS storage happens
	// to take up 8 bytes.
	o = 8 + ldr.SymValue(rs)
	} else if target.IsElf() \|\| target.IsPlan9() \|\| target.IsDarwin() {
	o = int64(syms.Tlsoffset) + r.Add()
	} else if target.IsWindows() {
	o = r.Add()
	} else {
	log.Fatalf("unexpected R_TLS_LE relocation for %v", target.HeadType)
	}
	case objabi.R_TLS_IE:
	if target.IsExternal() && target.IsElf() {
	nExtReloc++
	o = 0
	if !target.IsAMD64() {
	o = r.Add()
	}
	if target.Is386() {
	nExtReloc++ // need two ELF relocations on 386, see ../x86/asm.go:elfreloc1
	}
	break
	}
	if target.IsPIE() && target.IsElf() {
	// We are linking the final executable, so we
	// can optimize any TLS IE relocation to LE.
	if thearch.TLSIEtoLE == nil {
	log.Fatalf("internal linking of TLS IE not supported on %v", target.Arch.Family)
	}
	thearch.TLSIEtoLE(P, int(off), int(siz))
	o = int64(syms.Tlsoffset)
	} else {
	log.Fatalf("cannot handle R_TLS_IE (sym %s) when linking internally", ldr.SymName(s))
	}
	case objabi.R_ADDR, objabi.R_PEIMAGEOFF:
	if weak && !ldr.AttrReachable(rs) {
	// Redirect it to runtime.unreachableMethod, which will throw if called.
	rs = syms.unreachableMethod
	}
	if target.IsExternal() {
	nExtReloc++

	// set up addend for eventual relocation via outer symbol.
	rs := rs
	rs, off := FoldSubSymbolOffset(ldr, rs)
	xadd := r.Add() + off
	rst := ldr.SymType(rs)
	if rst != sym.SHOSTOBJ && rst != sym.SDYNIMPORT && rst != sym.SUNDEFEXT && ldr.SymSect(rs) == nil {
	st.err.Errorf(s, "missing section for relocation target %s", ldr.SymName(rs))
	}

	o = xadd
	if target.IsElf() {
	if target.IsAMD64() {
	o = 0
	}
	} else if target.IsDarwin() {
	if ldr.SymType(s).IsDWARF() {
	// We generally use symbol-targeted relocations.
	// DWARF tools seem to only handle section-targeted relocations,
	// so generate section-targeted relocations in DWARF sections.
	// See also machoreloc1.
	o += ldr.SymValue(rs)
	}
	} else if target.IsWindows() {
	// nothing to do
	} else if target.IsAIX() {
	o = ldr.SymValue(rs) + xadd
	} else {
	st.err.Errorf(s, "unhandled pcrel relocation to %s on %v", ldr.SymName(rs), target.HeadType)
	}

	break
	}

	// On AIX, a second relocation must be done by the loader,
	// as section addresses can change once loaded.
	// The "default" symbol address is still needed by the loader so
	// the current relocation can't be skipped.
	if target.IsAIX() && rst != sym.SDYNIMPORT {
	// It's not possible to make a loader relocation in a
	// symbol which is not inside .data section.
	// FIXME: It should be forbidden to have R_ADDR from a
	// symbol which isn't in .data. However, as .text has the
	// same address once loaded, this is possible.
	// TODO: .text (including rodata) to .data relocation
	// doesn't work correctly, so we should really disallow it.
	// See also aixStaticDataBase in symtab.go and in runtime.
	if ldr.SymSect(s).Seg == &Segdata {
	Xcoffadddynrel(target, ldr, syms, s, r, ri)
	}
	}

	o = ldr.SymValue(rs) + r.Add()
	if rt == objabi.R_PEIMAGEOFF {
	// The R_PEIMAGEOFF offset is a RVA, so subtract
	// the base address for the executable.
	o -= PEBASE
	}

	// On amd64, 4-byte offsets will be sign-extended, so it is impossible to
	// access more than 2GB of static data; fail at link time is better than
	// fail at runtime. See https://golang.org/issue/7980.
	// Instead of special casing only amd64, we treat this as an error on all
	// 64-bit architectures so as to be future-proof.
	if int32(o) < 0 && target.Arch.PtrSize > 4 && siz == 4 {
	st.err.Errorf(s, "non-pc-relative relocation address for %s is too big: %#x (%#x + %#x)", ldr.SymName(rs), uint64(o), ldr.SymValue(rs), r.Add())
	errorexit()
	}
	case objabi.R_DWTXTADDR_U1, objabi.R_DWTXTADDR_U2, objabi.R_DWTXTADDR_U3, objabi.R_DWTXTADDR_U4:
	unit := ldr.SymUnit(rs)
	if idx, ok := unit.Addrs[rs]; ok {
	o = int64(idx)
	} else {
	st.err.Errorf(s, "missing .debug_addr index relocation target %s", ldr.SymName(rs))
	}

	// For these relocations we write a ULEB128, but using a
	// cooked/hacked recipe that ensures the result has a
	// fixed length. That is, if we're writing a value of 1
	// with length requirement 3, we'll actually emit three
	// bytes, 0x81 0x80 0x0.
	_, leb128len := rt.DwTxtAddrRelocParams()
	if err := writeUleb128FixedLength(P[off:], uint64(o), leb128len); err != nil {
	st.err.Errorf(s, "internal error: %v applying %s to DWARF sym with reloc target %s", err, rt.String(), ldr.SymName(rs))
	}
	continue

	case objabi.R_DWARFSECREF:
	if ldr.SymSect(rs) == nil {
	st.err.Errorf(s, "missing DWARF section for relocation target %s", ldr.SymName(rs))
	}

	if target.IsExternal() {
	// On most platforms, the external linker needs to adjust DWARF references
	// as it combines DWARF sections. However, on Darwin, dsymutil does the
	// DWARF linking, and it understands how to follow section offsets.
	// Leaving in the relocation records confuses it (see
	// https://golang.org/issue/22068) so drop them for Darwin.
	if !target.IsDarwin() {
	nExtReloc++
	}

	xadd := r.Add() + ldr.SymValue(rs) - int64(ldr.SymSect(rs).Vaddr)

	o = xadd
	if target.IsElf() && target.IsAMD64() {
	o = 0
	}
	break
	}
	o = ldr.SymValue(rs) + r.Add() - int64(ldr.SymSect(rs).Vaddr)
	case objabi.R_METHODOFF:
	if !ldr.AttrReachable(rs) {
	// Set it to a sentinel value. The runtime knows this is not pointing to
	// anything valid.
	o = -1
	break
	}
	fallthrough
	case objabi.R_ADDROFF:
	if weak && !ldr.AttrReachable(rs) {
	continue
	}
	sect := ldr.SymSect(rs)
	if sect == nil {
	if rst == sym.SDYNIMPORT {
	st.err.Errorf(s, "cannot target DYNIMPORT sym in section-relative reloc: %s", ldr.SymName(rs))
	} else if rst == sym.SUNDEFEXT {
	st.err.Errorf(s, "undefined symbol in relocation: %s", ldr.SymName(rs))
	} else {
	st.err.Errorf(s, "missing section for relocation target %s", ldr.SymName(rs))
	}
	continue
	}

	// The method offset tables using this relocation expect the offset to be relative
	// to the start of the first text section, even if there are multiple.
	if sect.Name == ".text" {
	o = ldr.SymValue(rs) - int64(Segtext.Sections[0].Vaddr) + r.Add()
	if target.IsWasm() {
	// On Wasm, textoff (e.g. in the method table) is just the function index,
	// whereas the "PC" (rs's Value) is function index << 16 + block index (see
	// ../wasm/asm.go:assignAddress).
	if o&(1<<16-1) != 0 {
	st.err.Errorf(s, "textoff relocation %s does not target function entry: %s %#x", rt, ldr.SymName(rs), o)
	}
	o >>= 16
	}
	} else {
	o = ldr.SymValue(rs) - int64(ldr.SymSect(rs).Vaddr) + r.Add()
	}

	case objabi.R_ADDRCUOFF:
	// debug_range and debug_loc elements use this relocation type to get an
	// offset from the start of the compile unit.
	o = ldr.SymValue(rs) + r.Add() - ldr.SymValue(ldr.SymUnit(rs).Textp[0])

	// r.Sym() can be 0 when CALL $(constant) is transformed from absolute PC to relative PC call.
	case objabi.R_GOTPCREL:
	if target.IsDynlinkingGo() && target.IsDarwin() && rs != 0 {
	nExtReloc++
	o = r.Add()
	break
	}
	if target.Is386() && target.IsExternal() && target.IsELF {
	nExtReloc++ // need two ELF relocations on 386, see ../x86/asm.go:elfreloc1
	}
	fallthrough
	case objabi.R_CALL, objabi.R_PCREL:
	if target.IsExternal() && rs != 0 && rst == sym.SUNDEFEXT {
	// pass through to the external linker.
	nExtReloc++
	o = 0
	break
	}
	if target.IsExternal() && rs != 0 && (ldr.SymSect(rs) != ldr.SymSect(s) \|\| rt == objabi.R_GOTPCREL) {
	nExtReloc++

	// set up addend for eventual relocation via outer symbol.
	rs := rs
	rs, off := FoldSubSymbolOffset(ldr, rs)
	xadd := r.Add() + off - int64(siz) // relative to address after the relocated chunk
	rst := ldr.SymType(rs)
	if rst != sym.SHOSTOBJ && rst != sym.SDYNIMPORT && ldr.SymSect(rs) == nil {
	st.err.Errorf(s, "missing section for relocation target %s", ldr.SymName(rs))
	}

	o = xadd
	if target.IsElf() {
	if target.IsAMD64() {
	o = 0
	}
	} else if target.IsDarwin() {
	if rt == objabi.R_CALL {
	if target.IsExternal() && rst == sym.SDYNIMPORT {
	if target.IsAMD64() {
	// AMD64 dynamic relocations are relative to the end of the relocation.
	o += int64(siz)
	}
	} else {
	if rst != sym.SHOSTOBJ {
	o += int64(uint64(ldr.SymValue(rs)) - ldr.SymSect(rs).Vaddr)
	}
	o -= off // relative to section offset, not symbol
	}
	} else {
	o += int64(siz)
	}
	} else if target.IsWindows() && target.IsAMD64() { // only amd64 needs PCREL
	// PE/COFF's PC32 relocation uses the address after the relocated
	// bytes as the base. Compensate by skewing the addend.
	o += int64(siz)
	} else {
	st.err.Errorf(s, "unhandled pcrel relocation to %s on %v", ldr.SymName(rs), target.HeadType)
	}

	break
	}

	o = 0
	if rs != 0 {
	o = ldr.SymValue(rs)
	}

	o += r.Add() - (ldr.SymValue(s) + int64(off) + int64(siz))
	case objabi.R_SIZE:
	o = ldr.SymSize(rs) + r.Add()

	case objabi.R_XCOFFREF:
	if !target.IsAIX() {
	st.err.Errorf(s, "find XCOFF R_REF on non-XCOFF files")
	}
	if !target.IsExternal() {
	st.err.Errorf(s, "find XCOFF R_REF with internal linking")
	}
	nExtReloc++
	continue

	case objabi.R_CONST:
	o = r.Add()

	case objabi.R_GOTOFF:
	o = ldr.SymValue(rs) + r.Add() - ldr.SymValue(syms.GOT)
	}

	if target.IsPPC64() \|\| target.IsS390X() {
	if rv != sym.RV_NONE {
	o = thearch.Archrelocvariant(target, ldr, r, rv, s, o, P)
	}
	}

	switch siz {
	default:
	st.err.Errorf(s, "bad reloc size %#x for %s", uint32(siz), ldr.SymName(rs))
	case 1:
	P[off] = byte(int8(o))
	case 2:
	if (rt == objabi.R_PCREL \|\| rt == objabi.R_CALL) && o != int64(int16(o)) {
	st.err.Errorf(s, "pc-relative relocation %s address for %s is too big: %#x", rt, ldr.SymName(rs), o)
	} else if o != int64(int16(o)) && o != int64(uint16(o)) {
	st.err.Errorf(s, "non-pc-relative relocation %s address for %s is too big: %#x", rt, ldr.SymName(rs), uint64(o))
	}
	target.Arch.ByteOrder.PutUint16(P[off:], uint16(o))
	case 4:
	if (rt == objabi.R_PCREL \|\| rt == objabi.R_CALL) && o != int64(int32(o)) {
	st.err.Errorf(s, "pc-relative relocation %s address for %s is too big: %#x", rt, ldr.SymName(rs), o)
	} else if o != int64(int32(o)) && o != int64(uint32(o)) {
	st.err.Errorf(s, "non-pc-relative relocation %s address for %s is too big: %#x", rt, ldr.SymName(rs), uint64(o))
	}
	target.Arch.ByteOrder.PutUint32(P[off:], uint32(o))
	case 8:
	target.Arch.ByteOrder.PutUint64(P[off:], uint64(o))
	}
	}
	if target.IsExternal() {
	// We'll stream out the external relocations in asmb2 (e.g. elfrelocsect)
	// and we only need the count here.
	atomic.AddUint32(&ldr.SymSect(s).Relcount, uint32(nExtReloc))
	}
	}

	// Convert a Go relocation to an external relocation.
	func extreloc(ctxt Link, ldr loader.Loader, s loader.Sym, r loader.Reloc) (loader.ExtReloc, bool) {
	var rr loader.ExtReloc
	target := &ctxt.Target
	siz := int32(r.Siz())
	if siz == 0 { // informational relocation - no work to do
	return rr, false
	}

	rt := r.Type()
	if rt >= objabi.ElfRelocOffset {
	return rr, false
	}
	rr.Type = rt
	rr.Size = uint8(siz)

	// TODO(mundaym): remove this special case - see issue 14218.
	if target.IsS390X() {
	switch rt {
	case objabi.R_PCRELDBL:
	rt = objabi.R_PCREL
	}
	}

	switch rt {
	default:
	return thearch.Extreloc(target, ldr, r, s)

	case objabi.R_TLS_LE, objabi.R_TLS_IE:
	if target.IsElf() {
	rs := r.Sym()
	rr.Xsym = rs
	if rr.Xsym == 0 {
	rr.Xsym = ctxt.Tlsg
	}
	rr.Xadd = r.Add()
	break
	}
	return rr, false

	case objabi.R_ADDR, objabi.R_PEIMAGEOFF:
	// set up addend for eventual relocation via outer symbol.
	rs := r.Sym()
	if r.Weak() && !ldr.AttrReachable(rs) {
	rs = ctxt.ArchSyms.unreachableMethod
	}
	rs, off := FoldSubSymbolOffset(ldr, rs)
	rr.Xadd = r.Add() + off
	rr.Xsym = rs

	case objabi.R_DWARFSECREF:
	// On most platforms, the external linker needs to adjust DWARF references
	// as it combines DWARF sections. However, on Darwin, dsymutil does the
	// DWARF linking, and it understands how to follow section offsets.
	// Leaving in the relocation records confuses it (see
	// https://golang.org/issue/22068) so drop them for Darwin.
	if target.IsDarwin() {
	return rr, false
	}
	rs := r.Sym()
	rr.Xsym = ldr.SymSect(rs).Sym
	rr.Xadd = r.Add() + ldr.SymValue(rs) - int64(ldr.SymSect(rs).Vaddr)

	// r.Sym() can be 0 when CALL $(constant) is transformed from absolute PC to relative PC call.
	case objabi.R_GOTPCREL, objabi.R_CALL, objabi.R_PCREL:
	rs := r.Sym()
	if rt == objabi.R_GOTPCREL && target.IsDynlinkingGo() && target.IsDarwin() && rs != 0 {
	rr.Xadd = r.Add()
	rr.Xadd -= int64(siz) // relative to address after the relocated chunk
	rr.Xsym = rs
	break
	}
	if rs != 0 && ldr.SymType(rs) == sym.SUNDEFEXT {
	// pass through to the external linker.
	rr.Xadd = 0
	if target.IsElf() {
	rr.Xadd -= int64(siz)
	}
	rr.Xsym = rs
	break
	}
	if rs != 0 && (ldr.SymSect(rs) != ldr.SymSect(s) \|\| rt == objabi.R_GOTPCREL) {
	// set up addend for eventual relocation via outer symbol.
	rs := rs
	rs, off := FoldSubSymbolOffset(ldr, rs)
	rr.Xadd = r.Add() + off
	rr.Xadd -= int64(siz) // relative to address after the relocated chunk
	rr.Xsym = rs
	break
	}
	return rr, false

	case objabi.R_XCOFFREF:
	return ExtrelocSimple(ldr, r), true

	// These reloc types don't need external relocations.
	case objabi.R_ADDROFF, objabi.R_METHODOFF, objabi.R_ADDRCUOFF,
	objabi.R_SIZE, objabi.R_CONST, objabi.R_GOTOFF,
	objabi.R_DWTXTADDR_U1, objabi.R_DWTXTADDR_U2,
	objabi.R_DWTXTADDR_U3, objabi.R_DWTXTADDR_U4:
	return rr, false
	}
	return rr, true
	}

	// ExtrelocSimple creates a simple external relocation from r, with the same
	// symbol and addend.
	func ExtrelocSimple(ldr *loader.Loader, r loader.Reloc) loader.ExtReloc {
	var rr loader.ExtReloc
	rs := r.Sym()
	rr.Xsym = rs
	rr.Xadd = r.Add()
	rr.Type = r.Type()
	rr.Size = r.Siz()
	return rr
	}

	// ExtrelocViaOuterSym creates an external relocation from r targeting the
	// outer symbol and folding the subsymbol's offset into the addend.
	func ExtrelocViaOuterSym(ldr *loader.Loader, r loader.Reloc, s loader.Sym) loader.ExtReloc {
	// set up addend for eventual relocation via outer symbol.
	var rr loader.ExtReloc
	rs := r.Sym()
	rs, off := FoldSubSymbolOffset(ldr, rs)
	rr.Xadd = r.Add() + off
	rst := ldr.SymType(rs)
	if rst != sym.SHOSTOBJ && rst != sym.SDYNIMPORT && rst != sym.SUNDEFEXT && ldr.SymSect(rs) == nil {
	ldr.Errorf(s, "missing section for %s", ldr.SymName(rs))
	}
	rr.Xsym = rs
	rr.Type = r.Type()
	rr.Size = r.Siz()
	return rr
	}

	// relocSymState hold state information needed when making a series of
	// successive calls to relocsym(). The items here are invariant
	// (meaning that they are set up once initially and then don't change
	// during the execution of relocsym), with the exception of a slice
	// used to facilitate batch allocation of external relocations. Calls
	// to relocsym happen in parallel; the assumption is that each
	// parallel thread will have its own state object.
	type relocSymState struct {
	target *Target
	ldr *loader.Loader
	err *ErrorReporter
	syms *ArchSyms
	}

	// makeRelocSymState creates a relocSymState container object to
	// pass to relocsym(). If relocsym() calls happen in parallel,
	// each parallel thread should have its own state object.
	func (ctxt Link) makeRelocSymState() relocSymState {
	return &relocSymState{
	target: &ctxt.Target,
	ldr: ctxt.loader,
	err: &ctxt.ErrorReporter,
	syms: &ctxt.ArchSyms,
	}
	}

	// windynrelocsym examines a text symbol 's' and looks for relocations
	// from it that correspond to references to symbols defined in DLLs,
	// then fixes up those relocations as needed. A reference to a symbol
	// XYZ from some DLL will fall into one of two categories: an indirect
	// ref via "__imp_XYZ", or a direct ref to "XYZ". Here's an example of
	// an indirect ref (this is an excerpt from objdump -ldr):
	//
	// 1c1: 48 89 c6 movq %rax, %rsi
	// 1c4: ff 15 00 00 00 00 callq *(%rip)
	// 00000000000001c6: IMAGE_REL_AMD64_REL32 __imp__errno
	//
	// In the assembly above, the code loads up the value of __imp_errno
	// and then does an indirect call to that value.
	//
	// Here is what a direct reference might look like:
	//
	// 137: e9 20 06 00 00 jmp 0x75c <pow+0x75c>
	// 13c: e8 00 00 00 00 callq 0x141 <pow+0x141>
	// 000000000000013d: IMAGE_REL_AMD64_REL32 _errno
	//
	// The assembly below dispenses with the import symbol and just makes
	// a direct call to _errno.
	//
	// The code below handles indirect refs by redirecting the target of
	// the relocation from "__imp_XYZ" to "XYZ" (since the latter symbol
	// is what the Windows loader is expected to resolve). For direct refs
	// the call is redirected to a stub, where the stub first loads the
	// symbol and then direct an indirect call to that value.
	//
	// Note that for a given symbol (as above) it is perfectly legal to
	// have both direct and indirect references.
	func windynrelocsym(ctxt Link, rel loader.SymbolBuilder, s loader.Sym) error {
	var su *loader.SymbolBuilder
	relocs := ctxt.loader.Relocs(s)
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	if r.IsMarker() {
	continue // skip marker relocations
	}
	targ := r.Sym()
	if targ == 0 {
	continue
	}
	if !ctxt.loader.AttrReachable(targ) {
	if r.Weak() {
	continue
	}
	return fmt.Errorf("dynamic relocation to unreachable symbol %s",
	ctxt.loader.SymName(targ))
	}
	tgot := ctxt.loader.SymGot(targ)
	if tgot == loadpe.RedirectToDynImportGotToken {

	// Consistency check: name should be __imp_X
	sname := ctxt.loader.SymName(targ)
	if !strings.HasPrefix(sname, "__imp_") {
	return fmt.Errorf("internal error in windynrelocsym: redirect GOT token applied to non-import symbol %s", sname)
	}

	// Locate underlying symbol (which originally had type
	// SDYNIMPORT but has since been retyped to SWINDOWS).
	ds, err := loadpe.LookupBaseFromImport(targ, ctxt.loader, ctxt.Arch)
	if err != nil {
	return err
	}
	dstyp := ctxt.loader.SymType(ds)
	if dstyp != sym.SWINDOWS {
	return fmt.Errorf("internal error in windynrelocsym: underlying sym for %q has wrong type %s", sname, dstyp.String())
	}

	// Redirect relocation to the dynimport.
	r.SetSym(ds)
	continue
	}

	tplt := ctxt.loader.SymPlt(targ)
	if tplt == loadpe.CreateImportStubPltToken {

	// Consistency check: don't want to see both PLT and GOT tokens.
	if tgot != -1 {
	return fmt.Errorf("internal error in windynrelocsym: invalid GOT setting %d for reloc to %s", tgot, ctxt.loader.SymName(targ))
	}

	// make dynimport JMP table for PE object files.
	tplt := int32(rel.Size())
	ctxt.loader.SetPlt(targ, tplt)

	if su == nil {
	su = ctxt.loader.MakeSymbolUpdater(s)
	}
	r.SetSym(rel.Sym())
	r.SetAdd(int64(tplt))

	// jmp *addr
	switch ctxt.Arch.Family {
	default:
	return fmt.Errorf("internal error in windynrelocsym: unsupported arch %v", ctxt.Arch.Family)
	case sys.I386:
	rel.AddUint8(0xff)
	rel.AddUint8(0x25)
	rel.AddAddrPlus(ctxt.Arch, targ, 0)
	rel.AddUint8(0x90)
	rel.AddUint8(0x90)
	case sys.AMD64:
	// The relocation symbol might be at an absolute offset
	// higher than 32 bits, but the jump instruction can't
	// encode more than 32 bit offsets. We use a jump
	// relative to the instruction pointer to get around this
	// limitation.
	rel.AddUint8(0xff)
	rel.AddUint8(0x25)
	rel.AddPCRelPlus(ctxt.Arch, targ, 0)
	rel.AddUint8(0x90)
	rel.AddUint8(0x90)
	case sys.ARM64:
	// adrp x16, addr
	rel.AddUint32(ctxt.Arch, 0x90000010)
	r, _ := rel.AddRel(objabi.R_ARM64_PCREL)
	r.SetOff(int32(rel.Size() - 4))
	r.SetSiz(4)
	r.SetSym(targ)

	// ldr x17, [x16, <offset>]
	rel.AddUint32(ctxt.Arch, 0xf9400211)
	r, _ = rel.AddRel(objabi.R_ARM64_PCREL)
	r.SetOff(int32(rel.Size() - 4))
	r.SetSiz(4)
	r.SetSym(targ)

	// br x17
	rel.AddUint32(ctxt.Arch, 0xd61f0220)
	}
	} else if tplt >= 0 {
	if su == nil {
	su = ctxt.loader.MakeSymbolUpdater(s)
	}
	r.SetSym(rel.Sym())
	r.SetAdd(int64(tplt))
	}
	}
	return nil
	}

	// windynrelocsyms generates jump table to C library functions that will be
	// added later. windynrelocsyms writes the table into .rel symbol.
	func (ctxt *Link) windynrelocsyms() {
	if !(ctxt.IsWindows() && iscgo && ctxt.IsInternal()) {
	return
	}

	rel := ctxt.loader.CreateSymForUpdate(".rel", 0)
	rel.SetType(sym.STEXT)

	for _, s := range ctxt.Textp {
	if err := windynrelocsym(ctxt, rel, s); err != nil {
	ctxt.Errorf(s, "%v", err)
	}
	}

	ctxt.Textp = append(ctxt.Textp, rel.Sym())
	}

	func dynrelocsym(ctxt *Link, s loader.Sym) {
	target := &ctxt.Target
	ldr := ctxt.loader
	syms := &ctxt.ArchSyms
	relocs := ldr.Relocs(s)
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	if r.IsMarker() {
	continue // skip marker relocations
	}
	rSym := r.Sym()
	if r.Weak() && !ldr.AttrReachable(rSym) {
	continue
	}
	if ctxt.BuildMode == BuildModePIE && ctxt.LinkMode == LinkInternal {
	// It's expected that some relocations will be done
	// later by relocsym (R_TLS_LE, R_ADDROFF), so
	// don't worry if Adddynrel returns false.
	thearch.Adddynrel(target, ldr, syms, s, r, ri)
	continue
	}

	if rSym != 0 && ldr.SymType(rSym) == sym.SDYNIMPORT \|\| r.Type() >= objabi.ElfRelocOffset {
	if rSym != 0 && !ldr.AttrReachable(rSym) {
	ctxt.Errorf(s, "dynamic relocation to unreachable symbol %s", ldr.SymName(rSym))
	}
	if !thearch.Adddynrel(target, ldr, syms, s, r, ri) {
	ctxt.Errorf(s, "unsupported dynamic relocation for symbol %s (type=%d (%s) stype=%d (%s))", ldr.SymName(rSym), r.Type(), sym.RelocName(ctxt.Arch, r.Type()), ldr.SymType(rSym), ldr.SymType(rSym))
	}
	}
	}
	}

	func (state dodataState) dynreloc(ctxt Link) {
	if ctxt.HeadType == objabi.Hwindows {
	return
	}
	// -d suppresses dynamic loader format, so we may as well not
	// compute these sections or mark their symbols as reachable.
	if *FlagD {
	return
	}

	for _, s := range ctxt.Textp {
	dynrelocsym(ctxt, s)
	}
	for _, syms := range state.data {
	for _, s := range syms {
	dynrelocsym(ctxt, s)
	}
	}
	if ctxt.IsELF {
	elfdynhash(ctxt)
	}
	}

	func CodeblkPad(ctxt Link, out OutBuf, addr int64, size int64, pad []byte) {
	writeBlocks(ctxt, out, ctxt.outSem, ctxt.loader, ctxt.Textp, addr, size, pad)
	}

	const blockSize = 1 << 20 // 1MB chunks written at a time.

	// writeBlocks writes a specified chunk of symbols to the output buffer. It
	// breaks the write up into ≥blockSize chunks to write them out, and schedules
	// as many goroutines as necessary to accomplish this task. This call then
	// blocks, waiting on the writes to complete. Note that we use the sem parameter
	// to limit the number of concurrent writes taking place.
	func writeBlocks(ctxt Link, out OutBuf, sem chan int, ldr *loader.Loader, syms []loader.Sym, addr, size int64, pad []byte) {
	for i, s := range syms {
	if ldr.SymValue(s) >= addr && !ldr.AttrSubSymbol(s) {
	syms = syms[i:]
	break
	}
	}

	var wg sync.WaitGroup
	max, lastAddr, written := int64(blockSize), addr+size, int64(0)
	for addr < lastAddr {
	// Find the last symbol we'd write.
	idx := -1
	for i, s := range syms {
	if ldr.AttrSubSymbol(s) {
	continue
	}

	// If the next symbol's size would put us out of bounds on the total length,
	// stop looking.
	end := ldr.SymValue(s) + ldr.SymSize(s)
	if end > lastAddr {
	break
	}

	// We're gonna write this symbol.
	idx = i

	// If we cross over the max size, we've got enough symbols.
	if end > addr+max {
	break
	}
	}

	// If we didn't find any symbols to write, we're done here.
	if idx < 0 {
	break
	}

	// Compute the length to write, including padding.
	// We need to write to the end address (lastAddr), or the next symbol's
	// start address, whichever comes first. If there is no more symbols,
	// just write to lastAddr. This ensures we don't leave holes between the
	// blocks or at the end.
	length := int64(0)
	if idx+1 < len(syms) {
	// Find the next top-level symbol.
	// Skip over sub symbols so we won't split a container symbol
	// into two blocks.
	next := syms[idx+1]
	for ldr.AttrSubSymbol(next) {
	idx++
	next = syms[idx+1]
	}
	length = ldr.SymValue(next) - addr
	}
	if length == 0 \|\| length > lastAddr-addr {
	length = lastAddr - addr
	}

	// Start the block output operator.
	if ctxt.Out.isMmapped() {
	o := out.View(uint64(out.Offset() + written))
	sem <- 1
	wg.Add(1)
	go func(o OutBuf, ldr loader.Loader, syms []loader.Sym, addr, size int64, pad []byte) {
	writeBlock(ctxt, o, ldr, syms, addr, size, pad)
	wg.Done()
	<-sem
	}(o, ldr, syms, addr, length, pad)
	} else { // output not mmaped, don't parallelize.
	writeBlock(ctxt, out, ldr, syms, addr, length, pad)
	}

	// Prepare for the next loop.
	if idx != -1 {
	syms = syms[idx+1:]
	}
	written += length
	addr += length
	}
	wg.Wait()
	}

	func writeBlock(ctxt Link, out OutBuf, ldr *loader.Loader, syms []loader.Sym, addr, size int64, pad []byte) {

	st := ctxt.makeRelocSymState()

	// This doesn't distinguish the memory size from the file
	// size, and it lays out the file based on Symbol.Value, which
	// is the virtual address. DWARF compression changes file sizes,
	// so dwarfcompress will fix this up later if necessary.
	eaddr := addr + size
	var prev loader.Sym
	for _, s := range syms {
	if ldr.AttrSubSymbol(s) {
	continue
	}
	val := ldr.SymValue(s)
	if val >= eaddr {
	break
	}
	if val < addr {
	ldr.Errorf(s, "phase error: addr=%#x but val=%#x sym=%s type=%v sect=%v sect.addr=%#x prev=%s", addr, val, ldr.SymName(s), ldr.SymType(s), ldr.SymSect(s).Name, ldr.SymSect(s).Vaddr, ldr.SymName(prev))
	errorexit()
	}
	prev = s
	if addr < val {
	out.WriteStringPad("", int(val-addr), pad)
	addr = val
	}
	P := out.WriteSym(ldr, s)
	st.relocsym(s, P)
	if ldr.IsGeneratedSym(s) {
	f := ctxt.generatorSyms[s]
	f(ctxt, s)
	}
	addr += int64(len(P))
	siz := ldr.SymSize(s)
	if addr < val+siz {
	out.WriteStringPad("", int(val+siz-addr), pad)
	addr = val + siz
	}
	if addr != val+siz {
	ldr.Errorf(s, "phase error: addr=%#x value+size=%#x", addr, val+siz)
	errorexit()
	}
	if val+siz >= eaddr {
	break
	}
	}

	if addr < eaddr {
	out.WriteStringPad("", int(eaddr-addr), pad)
	}
	}

	type writeFn func(Link, OutBuf, int64, int64)

	// writeParallel handles scheduling parallel execution of data write functions.
	func writeParallel(wg sync.WaitGroup, fn writeFn, ctxt Link, seek, vaddr, length uint64) {
	if ctxt.Out.isMmapped() {
	out := ctxt.Out.View(seek)
	wg.Add(1)
	go func() {
	defer wg.Done()
	fn(ctxt, out, int64(vaddr), int64(length))
	}()
	} else {
	ctxt.Out.SeekSet(int64(seek))
	fn(ctxt, ctxt.Out, int64(vaddr), int64(length))
	}
	}

	func datblk(ctxt Link, out OutBuf, addr, size int64) {
	writeDatblkToOutBuf(ctxt, out, addr, size)
	}

	// Used only on Wasm for now.
	func DatblkBytes(ctxt *Link, addr int64, size int64) []byte {
	buf := make([]byte, size)
	out := &OutBuf{heap: buf}
	writeDatblkToOutBuf(ctxt, out, addr, size)
	return buf
	}

	func writeDatblkToOutBuf(ctxt Link, out OutBuf, addr int64, size int64) {
	writeBlocks(ctxt, out, ctxt.outSem, ctxt.loader, ctxt.datap, addr, size, zeros[:])
	}

	func dwarfblk(ctxt Link, out OutBuf, addr int64, size int64) {
	// Concatenate the section symbol lists into a single list to pass
	// to writeBlocks.
	//
	// NB: ideally we would do a separate writeBlocks call for each
	// section, but this would run the risk of undoing any file offset
	// adjustments made during layout.
	n := 0
	for i := range dwarfp {
	n += len(dwarfp[i].syms)
	}
	syms := make([]loader.Sym, 0, n)
	for i := range dwarfp {
	syms = append(syms, dwarfp[i].syms...)
	}
	writeBlocks(ctxt, out, ctxt.outSem, ctxt.loader, syms, addr, size, zeros[:])
	}

	func pdatablk(ctxt Link, out OutBuf, addr int64, size int64) {
	writeBlocks(ctxt, out, ctxt.outSem, ctxt.loader, sehp.pdata, addr, size, zeros[:])
	}

	func xdatablk(ctxt Link, out OutBuf, addr int64, size int64) {
	writeBlocks(ctxt, out, ctxt.outSem, ctxt.loader, sehp.xdata, addr, size, zeros[:])
	}

	var covCounterDataStartOff, covCounterDataLen uint64

	var zeros [512]byte

	var (
	strdata = make(map[string]string)
	strnames []string
	)

	func addstrdata1(ctxt *Link, arg string) {
	eq := strings.Index(arg, "=")
	dot := strings.LastIndex(arg[:eq+1], ".")
	if eq < 0 \|\| dot < 0 {
	Exitf("-X flag requires argument of the form importpath.name=value")
	}
	pkg := arg[:dot]
	if ctxt.BuildMode == BuildModePlugin && pkg == "main" {
	pkg = *flagPluginPath
	}
	pkg = objabi.PathToPrefix(pkg)
	name := pkg + arg[dot:eq]
	value := arg[eq+1:]
	if _, ok := strdata[name]; !ok {
	strnames = append(strnames, name)
	}
	strdata[name] = value
	}

	// addstrdata sets the initial value of the string variable name to value.
	func addstrdata(arch sys.Arch, l loader.Loader, name, value string) {
	s := l.Lookup(name, 0)
	if s == 0 {
	return
	}
	if goType := l.SymGoType(s); goType == 0 {
	return
	} else if typeName := l.SymName(goType); typeName != "type:string" {
	Errorf("%s: cannot set with -X: not a var of type string (%s)", name, typeName)
	return
	}
	if !l.AttrReachable(s) {
	return // don't bother setting unreachable variable
	}
	bld := l.MakeSymbolUpdater(s)
	if bld.Type() == sym.SBSS {
	bld.SetType(sym.SDATA)
	}

	p := fmt.Sprintf("%s.str", name)
	sbld := l.CreateSymForUpdate(p, 0)
	sbld.Addstring(value)
	sbld.SetType(sym.SRODATA)

	// Don't reset the variable's size. String variable usually has size of
	// 2*PtrSize, but in ASAN build it can be larger due to red zone.
	// (See issue 56175.)
	bld.SetData(make([]byte, arch.PtrSize*2))
	bld.SetReadOnly(false)
	bld.ResetRelocs()
	bld.SetAddrPlus(arch, 0, sbld.Sym(), 0)
	bld.SetUint(arch, int64(arch.PtrSize), uint64(len(value)))
	}

	func (ctxt *Link) dostrdata() {
	for _, name := range strnames {
	addstrdata(ctxt.Arch, ctxt.loader, name, strdata[name])
	}
	}

	// addgostring adds str, as a Go string value, to s. symname is the name of the
	// symbol used to define the string data and must be unique per linked object.
	func addgostring(ctxt Link, ldr loader.Loader, s *loader.SymbolBuilder, symname, str string) {
	sdata := ldr.CreateSymForUpdate(symname, 0)
	if sdata.Type() != sym.Sxxx {
	ctxt.Errorf(s.Sym(), "duplicate symname in addgostring: %s", symname)
	}
	sdata.SetLocal(true)
	sdata.SetType(sym.SRODATA)
	sdata.SetSize(int64(len(str)))
	sdata.SetData([]byte(str))
	s.AddAddr(ctxt.Arch, sdata.Sym())
	s.AddUint(ctxt.Arch, uint64(len(str)))
	}

	func addinitarrdata(ctxt Link, ldr loader.Loader, s loader.Sym) {
	p := ldr.SymName(s) + ".ptr"
	sp := ldr.CreateSymForUpdate(p, 0)
	sp.SetType(sym.SINITARR)
	sp.SetSize(0)
	sp.SetDuplicateOK(true)
	sp.AddAddr(ctxt.Arch, s)
	}

	// symalign returns the required alignment for the given symbol s.
	func symalign(ldr *loader.Loader, s loader.Sym) int32 {
	min := int32(thearch.Minalign)
	align := ldr.SymAlign(s)
	if align >= min {
	return align
	} else if align != 0 {
	return min
	}
	align = int32(thearch.Maxalign)
	ssz := ldr.SymSize(s)
	for int64(align) > ssz && align > min {
	align >>= 1
	}
	ldr.SetSymAlign(s, align)
	return align
	}

	func aligndatsize(state *dodataState, datsize int64, s loader.Sym) int64 {
	return Rnd(datsize, int64(symalign(state.ctxt.loader, s)))
	}

	const debugGCProg = false

	type GCProg struct {
	ctxt *Link
	sym *loader.SymbolBuilder
	w gcprog.Writer
	}

	func (p GCProg) Init(ctxt Link, name string) {
	p.ctxt = ctxt
	p.sym = ctxt.loader.CreateSymForUpdate(name, 0)
	p.w.Init(p.writeByte())
	if debugGCProg {
	fmt.Fprintf(os.Stderr, "ld: start GCProg %s\n", name)
	p.w.Debug(os.Stderr)
	}
	}

	func (p *GCProg) writeByte() func(x byte) {
	return func(x byte) {
	p.sym.AddUint8(x)
	}
	}

	func (p *GCProg) End(size int64) {
	p.w.ZeroUntil(size / int64(p.ctxt.Arch.PtrSize))
	p.w.End()
	if debugGCProg {
	fmt.Fprintf(os.Stderr, "ld: end GCProg\n")
	}
	}

	func (p *GCProg) AddSym(s loader.Sym) {
	ldr := p.ctxt.loader
	typ := ldr.SymGoType(s)

	// Things without pointers should be in sym.SNOPTRDATA or sym.SNOPTRBSS;
	// everything we see should have pointers and should therefore have a type.
	if typ == 0 {
	switch ldr.SymName(s) {
	case "runtime.data", "runtime.edata", "runtime.bss", "runtime.ebss", "runtime.gcdata", "runtime.gcbss":
	// Ignore special symbols that are sometimes laid out
	// as real symbols. See comment about dyld on darwin in
	// the address function.
	return
	}
	p.ctxt.Errorf(p.sym.Sym(), "missing Go type information for global symbol %s: size %d", ldr.SymName(s), ldr.SymSize(s))
	return
	}

	if debugGCProg {
	fmt.Fprintf(os.Stderr, "gcprog sym: %s at %d (ptr=%d)\n", ldr.SymName(s), ldr.SymValue(s), ldr.SymValue(s)/int64(p.ctxt.Arch.PtrSize))
	}

	sval := ldr.SymValue(s)
	p.AddType(sval, typ)
	}

	// Add to the gc program the ptr bits for the type typ at
	// byte offset off in the region being described.
	// The type must have a pointer in it.
	func (p *GCProg) AddType(off int64, typ loader.Sym) {
	ldr := p.ctxt.loader
	typData := ldr.Data(typ)
	ptrdata := decodetypePtrdata(p.ctxt.Arch, typData)
	if ptrdata == 0 {
	p.ctxt.Errorf(p.sym.Sym(), "has no pointers but in data section")
	// TODO: just skip these? They might occur in assembly
	// that doesn't know to use NOPTR? But there must have been
	// a Go declaration somewhere.
	}
	switch decodetypeKind(p.ctxt.Arch, typData) {
	default:
	if decodetypeGCMaskOnDemand(p.ctxt.Arch, typData) {
	p.ctxt.Errorf(p.sym.Sym(), "GC mask not available")
	}
	// Copy pointers from mask into program.
	ptrsize := int64(p.ctxt.Arch.PtrSize)
	mask := decodetypeGcmask(p.ctxt, typ)
	for i := int64(0); i < ptrdata/ptrsize; i++ {
	if (mask[i/8]>>uint(i%8))&1 != 0 {
	p.w.Ptr(off/ptrsize + i)
	}
	}
	case abi.Array:
	elem := decodetypeArrayElem(p.ctxt, p.ctxt.Arch, typ)
	n := decodetypeArrayLen(ldr, p.ctxt.Arch, typ)
	p.AddType(off, elem)
	if n > 1 {
	// Issue repeat for subsequent n-1 instances.
	elemSize := decodetypeSize(p.ctxt.Arch, ldr.Data(elem))
	ptrsize := int64(p.ctxt.Arch.PtrSize)
	p.w.ZeroUntil((off + elemSize) / ptrsize)
	p.w.Repeat(elemSize/ptrsize, n-1)
	}
	case abi.Struct:
	nField := decodetypeStructFieldCount(ldr, p.ctxt.Arch, typ)
	for i := 0; i < nField; i++ {
	fTyp := decodetypeStructFieldType(p.ctxt, p.ctxt.Arch, typ, i)
	if decodetypePtrdata(p.ctxt.Arch, ldr.Data(fTyp)) == 0 {
	continue
	}
	fOff := decodetypeStructFieldOffset(ldr, p.ctxt.Arch, typ, i)
	p.AddType(off+fOff, fTyp)
	}
	}
	}

	// cutoff is the maximum data section size permitted by the linker
	// (see issue #9862).
	const cutoff = 2e9 // 2 GB (or so; looks better in errors than 2^31)

	// check accumulated size of data sections
	func (state *dodataState) checkdatsize(symn sym.SymKind) {
	if state.datsize > cutoff {
	Errorf("too much data, last section %v (%d, over %v bytes)", symn, state.datsize, cutoff)
	}
	}

	func checkSectSize(sect *sym.Section) {
	// TODO: consider using 4 GB size limit for DWARF sections, and
	// make sure we generate unsigned offset in relocations and check
	// for overflow.
	if sect.Length > cutoff {
	Errorf("too much data in section %s (%d, over %v bytes)", sect.Name, sect.Length, cutoff)
	}
	}

	// fixZeroSizedSymbols gives a few special symbols with zero size some space.
	func fixZeroSizedSymbols(ctxt *Link) {
	// The values in moduledata are filled out by relocations
	// pointing to the addresses of these special symbols.
	// Typically these symbols have no size and are not laid
	// out with their matching section.
	//
	// However on darwin, dyld will find the special symbol
	// in the first loaded module, even though it is local.
	//
	// (An hypothesis, formed without looking in the dyld sources:
	// these special symbols have no size, so their address
	// matches a real symbol. The dynamic linker assumes we
	// want the normal symbol with the same address and finds
	// it in the other module.)
	//
	// To work around this we lay out the symbls whose
	// addresses are vital for multi-module programs to work
	// as normal symbols, and give them a little size.
	//
	// On AIX, as all DATA sections are merged together, ld might not put
	// these symbols at the beginning of their respective section if there
	// aren't real symbols, their alignment might not match the
	// first symbol alignment. Therefore, there are explicitly put at the
	// beginning of their section with the same alignment.
	if !(ctxt.DynlinkingGo() && ctxt.HeadType == objabi.Hdarwin) && !(ctxt.HeadType == objabi.Haix && ctxt.LinkMode == LinkExternal) {
	return
	}

	ldr := ctxt.loader
	bss := ldr.CreateSymForUpdate("runtime.bss", 0)
	bss.SetSize(8)
	ldr.SetAttrSpecial(bss.Sym(), false)

	ebss := ldr.CreateSymForUpdate("runtime.ebss", 0)
	ldr.SetAttrSpecial(ebss.Sym(), false)

	data := ldr.CreateSymForUpdate("runtime.data", 0)
	data.SetSize(8)
	ldr.SetAttrSpecial(data.Sym(), false)

	edata := ldr.CreateSymForUpdate("runtime.edata", 0)
	ldr.SetAttrSpecial(edata.Sym(), false)

	if ctxt.HeadType == objabi.Haix {
	// XCOFFTOC symbols are part of .data section.
	edata.SetType(sym.SXCOFFTOC)
	}

	noptrbss := ldr.CreateSymForUpdate("runtime.noptrbss", 0)
	noptrbss.SetSize(8)
	ldr.SetAttrSpecial(noptrbss.Sym(), false)

	enoptrbss := ldr.CreateSymForUpdate("runtime.enoptrbss", 0)
	ldr.SetAttrSpecial(enoptrbss.Sym(), false)

	noptrdata := ldr.CreateSymForUpdate("runtime.noptrdata", 0)
	noptrdata.SetSize(8)
	ldr.SetAttrSpecial(noptrdata.Sym(), false)

	enoptrdata := ldr.CreateSymForUpdate("runtime.enoptrdata", 0)
	ldr.SetAttrSpecial(enoptrdata.Sym(), false)

	types := ldr.CreateSymForUpdate("runtime.types", 0)
	types.SetType(sym.STYPE)
	types.SetSize(8)
	ldr.SetAttrSpecial(types.Sym(), false)

	etypes := ldr.CreateSymForUpdate("runtime.etypes", 0)
	etypes.SetType(sym.SFUNCTAB)
	ldr.SetAttrSpecial(etypes.Sym(), false)

	if ctxt.HeadType == objabi.Haix {
	rodata := ldr.CreateSymForUpdate("runtime.rodata", 0)
	rodata.SetType(sym.SSTRING)
	rodata.SetSize(8)
	ldr.SetAttrSpecial(rodata.Sym(), false)

	erodata := ldr.CreateSymForUpdate("runtime.erodata", 0)
	ldr.SetAttrSpecial(erodata.Sym(), false)
	}
	}

	// makeRelroForSharedLib creates a section of readonly data if necessary.
	func (state dodataState) makeRelroForSharedLib(target Link) {
	if !target.UseRelro() {
	return
	}

	// "read only" data with relocations needs to go in its own section
	// when building a shared library. We do this by boosting objects of
	// type SXXX with relocations to type SXXXRELRO.
	ldr := target.loader
	for _, symnro := range sym.ReadOnly {
	symnrelro := sym.RelROMap[symnro]

	ro := []loader.Sym{}
	relro := state.data[symnrelro]

	for _, s := range state.data[symnro] {
	relocs := ldr.Relocs(s)
	isRelro := relocs.Count() > 0
	switch state.symType(s) {
	case sym.STYPE, sym.STYPERELRO, sym.SGOFUNCRELRO:
	// Symbols are not sorted yet, so it is possible
	// that an Outer symbol has been changed to a
	// relro Type before it reaches here.
	isRelro = true
	case sym.SFUNCTAB:
	if ldr.SymName(s) == "runtime.etypes" {
	// runtime.etypes must be at the end of
	// the relro data.
	isRelro = true
	}
	case sym.SGOFUNC, sym.SPCLNTAB:
	// The only SGOFUNC symbols that contain relocations are .stkobj,
	// and their relocations are of type objabi.R_ADDROFF,
	// which always get resolved during linking.
	isRelro = false
	}
	if isRelro {
	if symnrelro == sym.Sxxx {
	state.ctxt.Errorf(s, "cannot contain relocations (type %v)", symnro)
	}
	state.setSymType(s, symnrelro)
	if outer := ldr.OuterSym(s); outer != 0 {
	state.setSymType(outer, symnrelro)
	}
	relro = append(relro, s)
	} else {
	ro = append(ro, s)
	}
	}

	// Check that we haven't made two symbols with the same .Outer into
	// different types (because references two symbols with non-nil Outer
	// become references to the outer symbol + offset it's vital that the
	// symbol and the outer end up in the same section).
	for _, s := range relro {
	if outer := ldr.OuterSym(s); outer != 0 {
	st := state.symType(s)
	ost := state.symType(outer)
	if st != ost {
	state.ctxt.Errorf(s, "inconsistent types for symbol and its Outer %s (%v != %v)",
	ldr.SymName(outer), st, ost)
	}
	}
	}

	state.data[symnro] = ro
	state.data[symnrelro] = relro
	}
	}

	// dodataState holds bits of state information needed by dodata() and the
	// various helpers it calls. The lifetime of these items should not extend
	// past the end of dodata().
	type dodataState struct {
	// Link context
	ctxt *Link
	// Data symbols bucketed by type.
	data [sym.SFirstUnallocated][]loader.Sym
	// Max alignment for each flavor of data symbol.
	dataMaxAlign [sym.SFirstUnallocated]int32
	// Overridden sym type
	symGroupType []sym.SymKind
	// Current data size so far.
	datsize int64
	}

	// A note on symType/setSymType below:
	//
	// In the legacy linker, the types of symbols (notably data symbols) are
	// changed during the symtab() phase so as to insure that similar symbols
	// are bucketed together, then their types are changed back again during
	// dodata. Symbol to section assignment also plays tricks along these lines
	// in the case where a relro segment is needed.
	//
	// The value returned from setType() below reflects the effects of
	// any overrides made by symtab and/or dodata.

	// symType returns the (possibly overridden) type of 's'.
	func (state *dodataState) symType(s loader.Sym) sym.SymKind {
	if int(s) < len(state.symGroupType) {
	if override := state.symGroupType[s]; override != 0 {
	return override
	}
	}
	return state.ctxt.loader.SymType(s)
	}

	// setSymType sets a new override type for 's'.
	func (state *dodataState) setSymType(s loader.Sym, kind sym.SymKind) {
	if s == 0 {
	panic("bad")
	}
	if int(s) < len(state.symGroupType) {
	state.symGroupType[s] = kind
	} else {
	su := state.ctxt.loader.MakeSymbolUpdater(s)
	su.SetType(kind)
	}
	}

	func (ctxt *Link) dodata(symGroupType []sym.SymKind) {

	// Give zeros sized symbols space if necessary.
	fixZeroSizedSymbols(ctxt)

	// Collect data symbols by type into data.
	state := dodataState{ctxt: ctxt, symGroupType: symGroupType}
	ldr := ctxt.loader
	for s := loader.Sym(1); s < loader.Sym(ldr.NSym()); s++ {
	if !ldr.AttrReachable(s) \|\| ldr.AttrSpecial(s) \|\| ldr.AttrSubSymbol(s) \|\|
	!ldr.TopLevelSym(s) {
	continue
	}

	st := state.symType(s)

	if st <= sym.STEXTEND \|\| st >= sym.SFirstUnallocated {
	continue
	}
	state.data[st] = append(state.data[st], s)

	// Similarly with checking the onlist attr.
	if ldr.AttrOnList(s) {
	log.Fatalf("symbol %s listed multiple times", ldr.SymName(s))
	}
	ldr.SetAttrOnList(s, true)
	}

	// Now that we have the data symbols, but before we start
	// to assign addresses, record all the necessary
	// dynamic relocations. These will grow the relocation
	// symbol, which is itself data.
	//
	// On darwin, we need the symbol table numbers for dynreloc.
	if ctxt.HeadType == objabi.Hdarwin {
	machosymorder(ctxt)
	}
	state.dynreloc(ctxt)

	// Move any RO data with relocations to a separate section.
	state.makeRelroForSharedLib(ctxt)

	// Set alignment for the symbol with the largest known index,
	// so as to trigger allocation of the loader's internal
	// alignment array. This will avoid data races in the parallel
	// section below.
	lastSym := loader.Sym(ldr.NSym() - 1)
	ldr.SetSymAlign(lastSym, ldr.SymAlign(lastSym))

	// Sort symbols.
	var wg sync.WaitGroup
	for symn := range state.data {
	symn := sym.SymKind(symn)
	wg.Add(1)
	go func() {
	state.data[symn], state.dataMaxAlign[symn] = state.dodataSect(ctxt, symn, state.data[symn])
	wg.Done()
	}()
	}
	wg.Wait()

	if ctxt.IsELF {
	// Make .rela and .rela.plt contiguous, the ELF ABI requires this
	// and Solaris actually cares.
	syms := state.data[sym.SELFROSECT]
	reli, plti := -1, -1
	for i, s := range syms {
	switch ldr.SymName(s) {
	case ".rel.plt", ".rela.plt":
	plti = i
	case ".rel", ".rela":
	reli = i
	}
	}
	if reli >= 0 && plti >= 0 && plti != reli+1 {
	var first, second int
	if plti > reli {
	first, second = reli, plti
	} else {
	first, second = plti, reli
	}
	rel, plt := syms[reli], syms[plti]
	copy(syms[first+2:], syms[first+1:second])
	syms[first+0] = rel
	syms[first+1] = plt

	// Make sure alignment doesn't introduce a gap.
	// Setting the alignment explicitly prevents
	// symalign from basing it on the size and
	// getting it wrong.
	ldr.SetSymAlign(rel, int32(ctxt.Arch.RegSize))
	ldr.SetSymAlign(plt, int32(ctxt.Arch.RegSize))
	}
	state.data[sym.SELFROSECT] = syms
	}

	if ctxt.HeadType == objabi.Haix && ctxt.LinkMode == LinkExternal {
	// These symbols must have the same alignment as their section.
	// Otherwise, ld might change the layout of Go sections.
	ldr.SetSymAlign(ldr.Lookup("runtime.data", 0), state.dataMaxAlign[sym.SDATA])
	ldr.SetSymAlign(ldr.Lookup("runtime.bss", 0), state.dataMaxAlign[sym.SBSS])
	}

	// Create *sym.Section objects and assign symbols to sections for
	// data/rodata (and related) symbols.
	state.allocateDataSections(ctxt)

	state.allocateSEHSections(ctxt)

	// Create *sym.Section objects and assign symbols to sections for
	// DWARF symbols.
	state.allocateDwarfSections(ctxt)

	/* number the sections */
	n := int16(1)

	for _, sect := range Segtext.Sections {
	sect.Extnum = n
	n++
	}
	for _, sect := range Segrodata.Sections {
	sect.Extnum = n
	n++
	}
	for _, sect := range Segrelrodata.Sections {
	sect.Extnum = n
	n++
	}
	for _, sect := range Segdata.Sections {
	sect.Extnum = n
	n++
	}
	for _, sect := range Segdwarf.Sections {
	sect.Extnum = n
	n++
	}
	for _, sect := range Segpdata.Sections {
	sect.Extnum = n
	n++
	}
	for _, sect := range Segxdata.Sections {
	sect.Extnum = n
	n++
	}
	}

	// allocateDataSectionForSym creates a new sym.Section into which a
	// single symbol will be placed. Here "seg" is the segment into which
	// the section will go, "s" is the symbol to be placed into the new
	// section, and "rwx" contains permissions for the section.
	func (state dodataState) allocateDataSectionForSym(seg sym.Segment, s loader.Sym, rwx int) *sym.Section {
	ldr := state.ctxt.loader
	sname := ldr.SymName(s)
	if strings.HasPrefix(sname, "go:") {
	sname = ".go." + sname[len("go:"):]
	}
	sect := addsection(ldr, state.ctxt.Arch, seg, sname, rwx)
	sect.Align = symalign(ldr, s)
	state.datsize = Rnd(state.datsize, int64(sect.Align))
	sect.Vaddr = uint64(state.datsize)
	return sect
	}

	// allocateNamedDataSection creates a new sym.Section for a category
	// of data symbols. Here "seg" is the segment into which the section
	// will go, "sName" is the name to give to the section, "types" is a
	// range of symbol types to be put into the section, and "rwx"
	// contains permissions for the section.
	func (state dodataState) allocateNamedDataSection(seg sym.Segment, sName string, types []sym.SymKind, rwx int) *sym.Section {
	sect := addsection(state.ctxt.loader, state.ctxt.Arch, seg, sName, rwx)
	if len(types) == 0 {
	sect.Align = 1
	} else if len(types) == 1 {
	sect.Align = state.dataMaxAlign[types[0]]
	} else {
	for _, symn := range types {
	align := state.dataMaxAlign[symn]
	if sect.Align < align {
	sect.Align = align
	}
	}
	}
	state.datsize = Rnd(state.datsize, int64(sect.Align))
	sect.Vaddr = uint64(state.datsize)
	return sect
	}

	// assignDsymsToSection assigns a collection of data symbols to a
	// newly created section. "sect" is the section into which to place
	// the symbols, "syms" holds the list of symbols to assign,
	// "forceType" (if non-zero) contains a new sym type to apply to each
	// sym during the assignment, and "aligner" is a hook to call to
	// handle alignment during the assignment process.
	func (state dodataState) assignDsymsToSection(sect sym.Section, syms []loader.Sym, forceType sym.SymKind, aligner func(state *dodataState, datsize int64, s loader.Sym) int64) {
	ldr := state.ctxt.loader
	for _, s := range syms {
	state.datsize = aligner(state, state.datsize, s)
	ldr.SetSymSect(s, sect)
	if forceType != sym.Sxxx {
	state.setSymType(s, forceType)
	}
	ldr.SetSymValue(s, int64(uint64(state.datsize)-sect.Vaddr))
	state.datsize += ldr.SymSize(s)
	}
	sect.Length = uint64(state.datsize) - sect.Vaddr
	}

	func (state dodataState) assignToSection(sect sym.Section, symn sym.SymKind, forceType sym.SymKind) {
	state.assignDsymsToSection(sect, state.data[symn], forceType, aligndatsize)
	state.checkdatsize(symn)
	}

	// allocateSingleSymSections walks through the bucketed data symbols
	// with type 'symn', creates a new section for each sym, and assigns
	// the sym to a newly created section. Section name is set from the
	// symbol name. "Seg" is the segment into which to place the new
	// section, "forceType" is the new sym.SymKind to assign to the symbol
	// within the section, and "rwx" holds section permissions.
	func (state dodataState) allocateSingleSymSections(seg sym.Segment, symn sym.SymKind, forceType sym.SymKind, rwx int) {
	ldr := state.ctxt.loader
	for _, s := range state.data[symn] {
	sect := state.allocateDataSectionForSym(seg, s, rwx)
	ldr.SetSymSect(s, sect)
	state.setSymType(s, forceType)
	ldr.SetSymValue(s, int64(uint64(state.datsize)-sect.Vaddr))
	state.datsize += ldr.SymSize(s)
	sect.Length = uint64(state.datsize) - sect.Vaddr
	}
	state.checkdatsize(symn)
	}

	// allocateNamedSectionAndAssignSyms creates a new section with the
	// specified name, then walks through the bucketed data symbols with
	// type 'symn' and assigns each of them to this new section. "Seg" is
	// the segment into which to place the new section, "secName" is the
	// name to give to the new section, "forceType" (if non-zero) contains
	// a new sym type to apply to each sym during the assignment, and
	// "rwx" holds section permissions.
	func (state dodataState) allocateNamedSectionAndAssignSyms(seg sym.Segment, secName string, symn sym.SymKind, forceType sym.SymKind, rwx int) *sym.Section {

	sect := state.allocateNamedDataSection(seg, secName, []sym.SymKind{symn}, rwx)
	state.assignDsymsToSection(sect, state.data[symn], forceType, aligndatsize)
	return sect
	}

	// allocateDataSections allocates sym.Section objects for data/rodata
	// (and related) symbols, and then assigns symbols to those sections.
	func (state dodataState) allocateDataSections(ctxt Link) {
	// Allocate sections.
	// Data is processed before segtext, because we need
	// to see all symbols in the .data and .bss sections in order
	// to generate garbage collection information.

	// Writable data sections that do not need any specialized handling.
	writable := []sym.SymKind{
	sym.SBUILDINFO,
	sym.SFIPSINFO,
	sym.SELFSECT,
	sym.SMACHO,
	sym.SWINDOWS,
	}
	for _, symn := range writable {
	state.allocateSingleSymSections(&Segdata, symn, sym.SDATA, 06)
	}
	ldr := ctxt.loader

	// SMODULEDATA needs to be writable, but the GC doesn't need to
	// look at it. We don't use allocateSingleSymSections because
	// the name of the section is not the name of the symbol.
	if len(state.data[sym.SMODULEDATA]) > 0 {
	if len(state.data[sym.SMODULEDATA]) != 1 {
	Errorf("internal error: more than one SMODULEDATA symbol")
	}
	s := state.data[sym.SMODULEDATA][0]
	sect := addsection(ldr, ctxt.Arch, &Segdata, ".go.module", 06)
	sect.Align = symalign(ldr, s)
	state.datsize = Rnd(state.datsize, int64(sect.Align))
	sect.Vaddr = uint64(state.datsize)
	ldr.SetSymSect(s, sect)
	state.setSymType(s, sym.SDATA)
	ldr.SetSymValue(s, int64(uint64(state.datsize)-sect.Vaddr))
	state.datsize += ldr.SymSize(s)
	sect.Length = uint64(state.datsize) - sect.Vaddr
	state.checkdatsize(sym.SMODULEDATA)
	}

	// writable .got (note that for PIE binaries .got goes in relro)
	if len(state.data[sym.SELFGOT]) > 0 {
	state.allocateNamedSectionAndAssignSyms(&Segdata, ".got", sym.SELFGOT, sym.SDATA, 06)
	}
	if len(state.data[sym.SMACHOGOT]) > 0 {
	state.allocateNamedSectionAndAssignSyms(&Segdata, ".got", sym.SMACHOGOT, sym.SDATA, 06)
	}

	/* pointer-free data */
	sect := state.allocateNamedSectionAndAssignSyms(&Segdata, ".noptrdata", sym.SNOPTRDATA, sym.SDATA, 06)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.noptrdata", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.enoptrdata", 0), sect)

	state.assignToSection(sect, sym.SNOPTRDATAFIPSSTART, sym.SDATA)
	state.assignToSection(sect, sym.SNOPTRDATAFIPS, sym.SDATA)
	state.assignToSection(sect, sym.SNOPTRDATAFIPSEND, sym.SDATA)
	state.assignToSection(sect, sym.SNOPTRDATAEND, sym.SDATA)

	hasinitarr := ctxt.linkShared

	/* shared library initializer */
	switch ctxt.BuildMode {
	case BuildModeCArchive, BuildModeCShared, BuildModeShared, BuildModePlugin:
	hasinitarr = true
	}

	if ctxt.HeadType == objabi.Haix {
	if len(state.data[sym.SINITARR]) > 0 {
	Errorf("XCOFF format doesn't allow .init_array section")
	}
	}

	if hasinitarr && len(state.data[sym.SINITARR]) > 0 {
	state.allocateNamedSectionAndAssignSyms(&Segdata, ".init_array", sym.SINITARR, sym.Sxxx, 06)
	}

	/* data */
	sect = state.allocateNamedSectionAndAssignSyms(&Segdata, ".data", sym.SDATA, sym.SDATA, 06)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.data", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.edata", 0), sect)

	state.assignToSection(sect, sym.SDATAFIPSSTART, sym.SDATA)
	state.assignToSection(sect, sym.SDATAFIPS, sym.SDATA)
	state.assignToSection(sect, sym.SDATAFIPSEND, sym.SDATA)
	state.assignToSection(sect, sym.SDATAEND, sym.SDATA)

	dataGcEnd := state.datsize - int64(sect.Vaddr)

	// On AIX, TOC entries must be the last of .data
	// These aren't part of gc as they won't change during the runtime.
	state.assignToSection(sect, sym.SXCOFFTOC, sym.SDATA)
	state.checkdatsize(sym.SDATA)
	sect.Length = uint64(state.datsize) - sect.Vaddr

	/* bss */
	sect = state.allocateNamedSectionAndAssignSyms(&Segdata, ".bss", sym.SBSS, sym.Sxxx, 06)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.bss", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.ebss", 0), sect)
	bssGcEnd := state.datsize - int64(sect.Vaddr)

	// Emit gcdata for bss symbols now that symbol values have been assigned.
	gcsToEmit := []struct {
	symName string
	symKind sym.SymKind
	gcEnd int64
	}{
	{"runtime.gcdata", sym.SDATA, dataGcEnd},
	{"runtime.gcbss", sym.SBSS, bssGcEnd},
	}
	for _, g := range gcsToEmit {
	var gc GCProg
	gc.Init(ctxt, g.symName)
	for _, s := range state.data[g.symKind] {
	gc.AddSym(s)
	}
	gc.End(g.gcEnd)
	}

	/* pointer-free bss */
	sect = state.allocateNamedSectionAndAssignSyms(&Segdata, ".noptrbss", sym.SNOPTRBSS, sym.Sxxx, 06)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.noptrbss", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.enoptrbss", 0), sect)

	// Code coverage counters are assigned to the .noptrbss section.
	// We assign them in a separate pass so that they stay aggregated
	// together in a single blob (coverage runtime depends on this).
	covCounterDataStartOff = sect.Length
	state.assignToSection(sect, sym.SCOVERAGE_COUNTER, sym.SNOPTRBSS)
	covCounterDataLen = sect.Length - covCounterDataStartOff
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.covctrs", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.ecovctrs", 0), sect)

	// Coverage instrumentation counters for libfuzzer.
	if len(state.data[sym.SLIBFUZZER_8BIT_COUNTER]) > 0 {
	sect := state.allocateNamedSectionAndAssignSyms(&Segdata, ".go.fuzzcntrs", sym.SLIBFUZZER_8BIT_COUNTER, sym.Sxxx, 06)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.__start___sancov_cntrs", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.__stop___sancov_cntrs", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("internal/fuzz._counters", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("internal/fuzz._ecounters", 0), sect)
	}

	// Assign runtime.end to the last section of data segment.
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.end", 0), Segdata.Sections[len(Segdata.Sections)-1])

	if len(state.data[sym.STLSBSS]) > 0 {
	var sect *sym.Section
	// FIXME: not clear why it is sometimes necessary to suppress .tbss section creation.
	if (ctxt.IsELF \|\| ctxt.HeadType == objabi.Haix) && (ctxt.LinkMode == LinkExternal \|\| !*FlagD) {
	sect = addsection(ldr, ctxt.Arch, &Segdata, ".tbss", 06)
	sect.Align = int32(ctxt.Arch.PtrSize)
	// FIXME: why does this need to be set to zero?
	sect.Vaddr = 0
	}
	state.datsize = 0

	for _, s := range state.data[sym.STLSBSS] {
	state.datsize = aligndatsize(state, state.datsize, s)
	if sect != nil {
	ldr.SetSymSect(s, sect)
	}
	ldr.SetSymValue(s, state.datsize)
	state.datsize += ldr.SymSize(s)
	}
	state.checkdatsize(sym.STLSBSS)

	if sect != nil {
	sect.Length = uint64(state.datsize)
	}
	}

	/*
	* We finished data, begin read-only data.
	* Not all systems support a separate read-only non-executable data section.
	* ELF and Windows PE systems do.
	* OS X and Plan 9 do not.
	* And if we're using external linking mode, the point is moot,
	* since it's not our decision; that code expects the sections in
	* segtext.
	*/
	var segro *sym.Segment
	if ctxt.IsELF && ctxt.LinkMode == LinkInternal {
	segro = &Segrodata
	} else if ctxt.HeadType == objabi.Hwindows {
	segro = &Segrodata
	} else {
	segro = &Segtext
	}

	state.datsize = 0

	/* read-only executable ELF, Mach-O sections */
	if len(state.data[sym.STEXT]) != 0 {
	culprit := ldr.SymName(state.data[sym.STEXT][0])
	Errorf("dodata found an sym.STEXT symbol: %s", culprit)
	}
	state.allocateSingleSymSections(&Segtext, sym.SELFRXSECT, sym.SRODATA, 05)
	state.allocateSingleSymSections(&Segtext, sym.SMACHOPLT, sym.SRODATA, 05)

	/* read-only data */
	sect = state.allocateNamedDataSection(segro, ".rodata", sym.ReadOnly, 04)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.rodata", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.erodata", 0), sect)
	if !ctxt.UseRelro() {
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.types", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.etypes", 0), sect)
	}
	for _, symn := range sym.ReadOnly {
	symnStartValue := state.datsize
	if len(state.data[symn]) != 0 {
	symnStartValue = aligndatsize(state, symnStartValue, state.data[symn][0])
	}
	state.assignToSection(sect, symn, sym.SRODATA)
	setCarrierSize(symn, state.datsize-symnStartValue)
	if ctxt.HeadType == objabi.Haix {
	// Read-only symbols might be wrapped inside their outer
	// symbol.
	// XCOFF symbol table needs to know the size of
	// these outer symbols.
	xcoffUpdateOuterSize(ctxt, state.datsize-symnStartValue, symn)
	}
	}

	/* gopclntab */
	sect = state.allocateNamedSectionAndAssignSyms(segro, ".gopclntab", sym.SPCLNTAB, sym.SRODATA, 04)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.pclntab", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.pcheader", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.funcnametab", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.cutab", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.filetab", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.pctab", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.functab", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("go:func.*", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.epclntab", 0), sect)
	setCarrierSize(sym.SPCLNTAB, int64(sect.Length))
	if ctxt.HeadType == objabi.Haix {
	xcoffUpdateOuterSize(ctxt, int64(sect.Length), sym.SPCLNTAB)
	}

	/* read-only ELF, Mach-O sections */
	state.allocateSingleSymSections(segro, sym.SELFROSECT, sym.SRODATA, 04)

	// There is some data that are conceptually read-only but are written to by
	// relocations. On GNU systems, we can arrange for the dynamic linker to
	// mprotect sections after relocations are applied by giving them write
	// permissions in the object file and calling them ".data.rel.ro.FOO". We
	// divide the .rodata section between actual .rodata and .data.rel.ro.rodata,
	// but for the other sections that this applies to, we just write a read-only
	// .FOO section or a read-write .data.rel.ro.FOO section depending on the
	// situation.
	// TODO(mwhudson): It would make sense to do this more widely, but it makes
	// the system linker segfault on darwin.
	const relroPerm = 06
	const fallbackPerm = 04
	relroSecPerm := fallbackPerm
	genrelrosecname := func(suffix string) string {
	if suffix == "" {
	return ".rodata"
	}
	return suffix
	}
	seg := segro

	if ctxt.UseRelro() {
	segrelro := &Segrelrodata
	if ctxt.LinkMode == LinkExternal && !ctxt.IsAIX() && !ctxt.IsDarwin() {
	// Using a separate segment with an external
	// linker results in some programs moving
	// their data sections unexpectedly, which
	// corrupts the moduledata. So we use the
	// rodata segment and let the external linker
	// sort out a rel.ro segment.
	segrelro = segro
	} else {
	// Reset datsize for new segment.
	state.datsize = 0
	}

	if !ctxt.IsDarwin() { // We don't need the special names on darwin.
	genrelrosecname = func(suffix string) string {
	return ".data.rel.ro" + suffix
	}
	}

	relroReadOnly := []sym.SymKind{}
	for _, symnro := range sym.ReadOnly {
	symn := sym.RelROMap[symnro]
	relroReadOnly = append(relroReadOnly, symn)
	}
	seg = segrelro
	relroSecPerm = relroPerm

	/* data only written by relocations */
	sect = state.allocateNamedDataSection(segrelro, genrelrosecname(""), relroReadOnly, relroSecPerm)

	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.types", 0), sect)
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.etypes", 0), sect)

	for i, symnro := range sym.ReadOnly {
	if i == 0 && symnro == sym.STYPE && ctxt.HeadType != objabi.Haix {
	// Skip forward so that no type
	// reference uses a zero offset.
	// This is unlikely but possible in small
	// programs with no other read-only data.
	state.datsize++
	}

	symn := sym.RelROMap[symnro]
	if symn == sym.Sxxx {
	continue
	}
	symnStartValue := state.datsize
	if len(state.data[symn]) != 0 {
	symnStartValue = aligndatsize(state, symnStartValue, state.data[symn][0])
	}

	for _, s := range state.data[symn] {
	outer := ldr.OuterSym(s)
	if s != 0 && ldr.SymSect(outer) != nil && ldr.SymSect(outer) != sect {
	ctxt.Errorf(s, "s.Outer (%s) in different section from s, %s != %s", ldr.SymName(outer), ldr.SymSect(outer).Name, sect.Name)
	}
	}
	state.assignToSection(sect, symn, sym.SRODATA)
	setCarrierSize(symn, state.datsize-symnStartValue)
	if ctxt.HeadType == objabi.Haix {
	// Read-only symbols might be wrapped inside their outer
	// symbol.
	// XCOFF symbol table needs to know the size of
	// these outer symbols.
	xcoffUpdateOuterSize(ctxt, state.datsize-symnStartValue, symn)
	}
	}
	sect.Length = uint64(state.datsize) - sect.Vaddr

	state.allocateSingleSymSections(segrelro, sym.SELFRELROSECT, sym.SRODATA, relroSecPerm)
	state.allocateSingleSymSections(segrelro, sym.SMACHORELROSECT, sym.SRODATA, relroSecPerm)
	}

	/* typelink */
	sect = state.allocateNamedDataSection(seg, genrelrosecname(".typelink"), []sym.SymKind{sym.STYPELINK}, relroSecPerm)

	typelink := ldr.CreateSymForUpdate("runtime.typelink", 0)
	ldr.SetSymSect(typelink.Sym(), sect)
	typelink.SetType(sym.SRODATA)
	state.datsize += typelink.Size()
	state.checkdatsize(sym.STYPELINK)
	sect.Length = uint64(state.datsize) - sect.Vaddr

	/* itablink */
	sect = state.allocateNamedDataSection(seg, genrelrosecname(".itablink"), []sym.SymKind{sym.SITABLINK}, relroSecPerm)

	itablink := ldr.CreateSymForUpdate("runtime.itablink", 0)
	ldr.SetSymSect(itablink.Sym(), sect)
	itablink.SetType(sym.SRODATA)
	state.datsize += itablink.Size()
	state.checkdatsize(sym.SITABLINK)
	sect.Length = uint64(state.datsize) - sect.Vaddr

	// 6g uses 4-byte relocation offsets, so the entire segment must fit in 32 bits.
	if state.datsize != int64(uint32(state.datsize)) {
	Errorf("read-only data segment too large: %d", state.datsize)
	}

	siz := 0
	for symn := sym.SELFRXSECT; symn < sym.SFirstUnallocated; symn++ {
	siz += len(state.data[symn])
	}
	ctxt.datap = make([]loader.Sym, 0, siz)
	for symn := sym.SELFRXSECT; symn < sym.SFirstUnallocated; symn++ {
	ctxt.datap = append(ctxt.datap, state.data[symn]...)
	}
	}

	// allocateDwarfSections allocates sym.Section objects for DWARF
	// symbols, and assigns symbols to sections.
	func (state dodataState) allocateDwarfSections(ctxt Link) {

	alignOne := func(state *dodataState, datsize int64, s loader.Sym) int64 { return datsize }

	ldr := ctxt.loader
	for i := 0; i < len(dwarfp); i++ {
	// First the section symbol.
	s := dwarfp[i].secSym()
	sect := state.allocateNamedDataSection(&Segdwarf, ldr.SymName(s), []sym.SymKind{}, 04)
	ldr.SetSymSect(s, sect)
	sect.Sym = s
	curType := ldr.SymType(s)
	state.setSymType(s, sym.SRODATA)
	ldr.SetSymValue(s, int64(uint64(state.datsize)-sect.Vaddr))
	state.datsize += ldr.SymSize(s)

	// Then any sub-symbols for the section symbol.
	subSyms := dwarfp[i].subSyms()
	state.assignDsymsToSection(sect, subSyms, sym.SRODATA, alignOne)

	for j := 0; j < len(subSyms); j++ {
	s := subSyms[j]
	if ctxt.HeadType == objabi.Haix && curType == sym.SDWARFLOC {
	// Update the size of .debug_loc for this symbol's
	// package.
	addDwsectCUSize(".debug_loc", ldr.SymPkg(s), uint64(ldr.SymSize(s)))
	}
	}
	sect.Length = uint64(state.datsize) - sect.Vaddr
	checkSectSize(sect)
	}
	}

	// allocateSEHSections allocate a sym.Section object for SEH
	// symbols, and assigns symbols to sections.
	func (state dodataState) allocateSEHSections(ctxt Link) {
	if len(sehp.pdata) > 0 {
	sect := state.allocateNamedDataSection(&Segpdata, ".pdata", []sym.SymKind{}, 04)
	state.assignDsymsToSection(sect, sehp.pdata, sym.SRODATA, aligndatsize)
	state.checkdatsize(sym.SSEHSECT)
	}
	if len(sehp.xdata) > 0 {
	sect := state.allocateNamedDataSection(&Segxdata, ".xdata", []sym.SymKind{}, 04)
	state.assignDsymsToSection(sect, sehp.xdata, sym.SRODATA, aligndatsize)
	state.checkdatsize(sym.SSEHSECT)
	}
	}

	type symNameSize struct {
	name string
	sz int64
	val int64
	sym loader.Sym
	}

	func (state dodataState) dodataSect(ctxt Link, symn sym.SymKind, syms []loader.Sym) (result []loader.Sym, maxAlign int32) {
	var head, tail, zerobase loader.Sym
	ldr := ctxt.loader
	sl := make([]symNameSize, len(syms))

	// For ppc64, we want to interleave the .got and .toc sections
	// from input files. Both are type sym.SELFGOT, so in that case
	// we skip size comparison and do the name comparison instead
	// (conveniently, .got sorts before .toc).
	sortBySize := symn != sym.SELFGOT

	for k, s := range syms {
	ss := ldr.SymSize(s)
	sl[k] = symNameSize{sz: ss, sym: s}
	if !sortBySize {
	sl[k].name = ldr.SymName(s)
	}
	ds := int64(len(ldr.Data(s)))
	switch {
	case ss < ds:
	ctxt.Errorf(s, "initialize bounds (%d < %d)", ss, ds)
	case ss < 0:
	ctxt.Errorf(s, "negative size (%d bytes)", ss)
	case ss > cutoff:
	ctxt.Errorf(s, "symbol too large (%d bytes)", ss)
	}

	// If the usually-special section-marker symbols are being laid
	// out as regular symbols, put them either at the beginning or
	// end of their section.
	if (ctxt.DynlinkingGo() && ctxt.HeadType == objabi.Hdarwin) \|\| (ctxt.HeadType == objabi.Haix && ctxt.LinkMode == LinkExternal) {
	switch ldr.SymName(s) {
	case "runtime.text", "runtime.bss", "runtime.data", "runtime.types", "runtime.rodata",
	"runtime.noptrdata", "runtime.noptrbss":
	head = s
	continue
	case "runtime.etext", "runtime.ebss", "runtime.edata", "runtime.etypes", "runtime.erodata",
	"runtime.enoptrdata", "runtime.enoptrbss":
	tail = s
	continue
	}
	}
	}
	zerobase = ldr.Lookup("runtime.zerobase", 0)

	// Perform the sort.
	if symn != sym.SPCLNTAB {
	sort.Slice(sl, func(i, j int) bool {
	si, sj := sl[i].sym, sl[j].sym
	isz, jsz := sl[i].sz, sl[j].sz
	switch {
	case si == head, sj == tail:
	return true
	case sj == head, si == tail:
	return false
	}
	if sortBySize {
	switch {
	// put zerobase right after all the zero-sized symbols,
	// so zero-sized symbols have the same address as zerobase.
	case si == zerobase:
	return jsz != 0 // zerobase < nonzero-sized, zerobase > zero-sized
	case sj == zerobase:
	return isz == 0 // 0-sized < zerobase, nonzero-sized > zerobase
	case isz != jsz:
	return isz < jsz
	}
	} else {
	iname := sl[i].name
	jname := sl[j].name
	if iname != jname {
	return iname < jname
	}
	}
	return si < sj // break ties by symbol number
	})
	} else {
	// PCLNTAB was built internally, and already has the proper order.
	}

	// Set alignment, construct result
	syms = syms[:0]
	for k := range sl {
	s := sl[k].sym
	if s != head && s != tail {
	align := symalign(ldr, s)
	if maxAlign < align {
	maxAlign = align
	}
	}
	syms = append(syms, s)
	}

	return syms, maxAlign
	}

	// Add buildid to beginning of text segment, on non-ELF systems.
	// Non-ELF binary formats are not always flexible enough to
	// give us a place to put the Go build ID. On those systems, we put it
	// at the very beginning of the text segment.
	// This “header” is read by cmd/go.
	func (ctxt *Link) textbuildid() {
	if ctxt.IsELF \|\| *flagBuildid == "" {
	return
	}

	ldr := ctxt.loader
	s := ldr.CreateSymForUpdate("go:buildid", 0)
	// The \xff is invalid UTF-8, meant to make it less likely
	// to find one of these accidentally.
	data := "\xff Go build ID: " + strconv.Quote(*flagBuildid) + "\n \xff"
	s.SetType(sym.STEXT)
	s.SetData([]byte(data))
	s.SetSize(int64(len(data)))

	ctxt.Textp = append(ctxt.Textp, 0)
	copy(ctxt.Textp[1:], ctxt.Textp)
	ctxt.Textp[0] = s.Sym()
	}

	func (ctxt *Link) buildinfo() {
	// Write the buildinfo symbol, which go version looks for.
	// The code reading this data is in package debug/buildinfo.
	ldr := ctxt.loader
	s := ldr.CreateSymForUpdate("go:buildinfo", 0)
	s.SetType(sym.SBUILDINFO)
	s.SetAlign(16)

	// The \xff is invalid UTF-8, meant to make it less likely
	// to find one of these accidentally.
	const prefix = "\xff Go buildinf:" // 14 bytes, plus 1 data byte filled in below

	// Header is always 32-bytes, a hold-over from before
	// https://go.dev/cl/369977.
	data := make([]byte, 32)
	copy(data, prefix)
	data[len(prefix)] = byte(ctxt.Arch.PtrSize)
	data[len(prefix)+1] = 0
	if ctxt.Arch.ByteOrder == binary.BigEndian {
	data[len(prefix)+1] = 1
	}
	data[len(prefix)+1] \|= 2 // signals new pointer-free format
	data = appendString(data, strdata["runtime.buildVersion"])
	data = appendString(data, strdata["runtime.modinfo"])
	// MacOS linker gets very upset if the size is not a multiple of alignment.
	for len(data)%16 != 0 {
	data = append(data, 0)
	}
	s.SetData(data)
	s.SetSize(int64(len(data)))

	// Add reference to go:buildinfo from the rodata section,
	// so that external linking with -Wl,--gc-sections does not
	// delete the build info.
	sr := ldr.CreateSymForUpdate("go:buildinfo.ref", 0)
	sr.SetType(sym.SRODATA)
	sr.SetAlign(int32(ctxt.Arch.PtrSize))
	sr.AddAddr(ctxt.Arch, s.Sym())
	}

	// appendString appends s to data, prefixed by its varint-encoded length.
	func appendString(data []byte, s string) []byte {
	var v [binary.MaxVarintLen64]byte
	n := binary.PutUvarint(v[:], uint64(len(s)))
	data = append(data, v[:n]...)
	data = append(data, s...)
	return data
	}

	// assign addresses to text
	func (ctxt *Link) textaddress() {
	addsection(ctxt.loader, ctxt.Arch, &Segtext, ".text", 05)

	// Assign PCs in text segment.
	// Could parallelize, by assigning to text
	// and then letting threads copy down, but probably not worth it.
	sect := Segtext.Sections[0]

	sect.Align = int32(Funcalign)

	ldr := ctxt.loader

	if *flagRandLayout != 0 {
	r := rand.New(rand.NewSource(*flagRandLayout))
	textp := ctxt.Textp
	i := 0
	// don't move the buildid symbol
	if len(textp) > 0 && ldr.SymName(textp[0]) == "go:buildid" {
	i++
	}
	// Skip over C symbols, as functions in a (C object) section must stay together.
	// TODO: maybe we can move a section as a whole.
	// Note: we load C symbols before Go symbols, so we can scan from the start.
	for i < len(textp) && (ldr.SubSym(textp[i]) != 0 \|\| ldr.AttrSubSymbol(textp[i])) {
	i++
	}
	textp = textp[i:]
	r.Shuffle(len(textp), func(i, j int) {
	textp[i], textp[j] = textp[j], textp[i]
	})
	}

	// Sort the text symbols by type, so that FIPS symbols are
	// gathered together, with the FIPS start and end symbols
	// bracketing them , even if we've randomized the overall order.
	sort.SliceStable(ctxt.Textp, func(i, j int) bool {
	return ldr.SymType(ctxt.Textp[i]) < ldr.SymType(ctxt.Textp[j])
	})

	text := ctxt.xdefine("runtime.text", sym.STEXT, 0)
	etext := ctxt.xdefine("runtime.etext", sym.STEXTEND, 0)
	ldr.SetSymSect(text, sect)
	if ctxt.IsAIX() && ctxt.IsExternal() {
	// Setting runtime.text has a real symbol prevents ld to
	// change its base address resulting in wrong offsets for
	// reflect methods.
	u := ldr.MakeSymbolUpdater(text)
	u.SetAlign(sect.Align)
	u.SetSize(8)
	}

	if (ctxt.DynlinkingGo() && ctxt.IsDarwin()) \|\| (ctxt.IsAIX() && ctxt.IsExternal()) {
	ldr.SetSymSect(etext, sect)
	ctxt.Textp = append(ctxt.Textp, etext, 0)
	copy(ctxt.Textp[1:], ctxt.Textp)
	ctxt.Textp[0] = text
	}

	start := uint64(Rnd(*FlagTextAddr, int64(Funcalign)))
	va := start
	n := 1
	sect.Vaddr = va

	limit := thearch.TrampLimit
	if limit == 0 {
	limit = 1 << 63 // unlimited
	}
	if *FlagDebugTextSize != 0 {
	limit = uint64(*FlagDebugTextSize)
	}
	if *FlagDebugTramp > 1 {
	limit = 1 // debug mode, force generating trampolines for everything
	}

	if ctxt.IsAIX() && ctxt.IsExternal() {
	// On AIX, normally we won't generate direct calls to external symbols,
	// except in one test, cmd/go/testdata/script/link_syso_issue33139.txt.
	// That test doesn't make much sense, and I'm not sure it ever works.
	// Just generate trampoline for now (which will turn a direct call to
	// an indirect call, which at least builds).
	limit = 1
	}

	// First pass: assign addresses assuming the program is small and will
	// not require trampoline generation.
	big := false
	for _, s := range ctxt.Textp {
	sect, n, va = assignAddress(ctxt, sect, n, s, va, false, big)
	if va-start >= limit {
	big = true
	break
	}
	}

	// Second pass: only if it is too big, insert trampolines for too-far
	// jumps and targets with unknown addresses.
	if big {
	// reset addresses
	for _, s := range ctxt.Textp {
	if s != text {
	resetAddress(ctxt, s)
	}
	}
	va = start

	ntramps := 0
	var curPkg string
	for i, s := range ctxt.Textp {
	// When we find the first symbol in a package, perform a
	// single iteration that assigns temporary addresses to all
	// of the text in the same package, using the maximum possible
	// number of trampolines. This allows for better decisions to
	// be made regarding reachability and the need for trampolines.
	if symPkg := ldr.SymPkg(s); symPkg != "" && curPkg != symPkg {
	curPkg = symPkg
	vaTmp := va
	for j := i; j < len(ctxt.Textp); j++ {
	curSym := ctxt.Textp[j]
	if symPkg := ldr.SymPkg(curSym); symPkg == "" \|\| curPkg != symPkg {
	break
	}
	// We do not pass big to assignAddress here, as this
	// can result in side effects such as section splitting.
	sect, n, vaTmp = assignAddress(ctxt, sect, n, curSym, vaTmp, false, false)
	vaTmp += maxSizeTrampolines(ctxt, ldr, curSym, false)
	}
	}

	// Reset address for current symbol.
	if s != text {
	resetAddress(ctxt, s)
	}

	// Assign actual address for current symbol.
	sect, n, va = assignAddress(ctxt, sect, n, s, va, false, big)

	// Resolve jumps, adding trampolines if they are needed.
	trampoline(ctxt, s)

	// lay down trampolines after each function
	for ; ntramps < len(ctxt.tramps); ntramps++ {
	tramp := ctxt.tramps[ntramps]
	if ctxt.IsAIX() && strings.HasPrefix(ldr.SymName(tramp), "runtime.text.") {
	// Already set in assignAddress
	continue
	}
	sect, n, va = assignAddress(ctxt, sect, n, tramp, va, true, big)
	}
	}

	// merge tramps into Textp, keeping Textp in address order
	if ntramps != 0 {
	newtextp := make([]loader.Sym, 0, len(ctxt.Textp)+ntramps)
	i := 0
	for _, s := range ctxt.Textp {
	for ; i < ntramps && ldr.SymValue(ctxt.tramps[i]) < ldr.SymValue(s); i++ {
	newtextp = append(newtextp, ctxt.tramps[i])
	}
	newtextp = append(newtextp, s)
	}
	newtextp = append(newtextp, ctxt.tramps[i:ntramps]...)

	ctxt.Textp = newtextp
	}
	}

	// Add MinLC size after etext, so it won't collide with the next symbol
	// (which may confuse some symbolizer).
	sect.Length = va - sect.Vaddr + uint64(ctxt.Arch.MinLC)
	ldr.SetSymSect(etext, sect)
	if ldr.SymValue(etext) == 0 {
	// Set the address of the start/end symbols, if not already
	// (i.e. not darwin+dynlink or AIX+external, see above).
	ldr.SetSymValue(etext, int64(va))
	ldr.SetSymValue(text, int64(Segtext.Sections[0].Vaddr))
	}
	}

	// assigns address for a text symbol, returns (possibly new) section, its number, and the address.
	func assignAddress(ctxt Link, sect sym.Section, n int, s loader.Sym, va uint64, isTramp, big bool) (*sym.Section, int, uint64) {
	ldr := ctxt.loader
	if thearch.AssignAddress != nil {
	return thearch.AssignAddress(ldr, sect, n, s, va, isTramp)
	}

	ldr.SetSymSect(s, sect)
	if ldr.AttrSubSymbol(s) {
	return sect, n, va
	}

	align := ldr.SymAlign(s)
	align = max(align, int32(Funcalign))
	va = uint64(Rnd(int64(va), int64(align)))
	if sect.Align < align {
	sect.Align = align
	}

	funcsize := uint64(abi.MINFUNC) // spacing required for findfunctab
	if ldr.SymSize(s) > abi.MINFUNC {
	funcsize = uint64(ldr.SymSize(s))
	}

	// If we need to split text sections, and this function doesn't fit in the current
	// section, then create a new one.
	//
	// Only break at outermost syms.
	if big && splitTextSections(ctxt) && ldr.OuterSym(s) == 0 {
	// For debugging purposes, allow text size limit to be cranked down,
	// so as to stress test the code that handles multiple text sections.
	var textSizelimit uint64 = thearch.TrampLimit
	if *FlagDebugTextSize != 0 {
	textSizelimit = uint64(*FlagDebugTextSize)
	}

	// Sanity check: make sure the limit is larger than any
	// individual text symbol.
	if funcsize > textSizelimit {
	panic(fmt.Sprintf("error: text size limit %d less than text symbol %s size of %d", textSizelimit, ldr.SymName(s), funcsize))
	}

	if va-sect.Vaddr+funcsize+maxSizeTrampolines(ctxt, ldr, s, isTramp) > textSizelimit {
	sectAlign := int32(thearch.Funcalign)
	if ctxt.IsPPC64() {
	// Align the next text section to the worst case function alignment likely
	// to be encountered when processing function symbols. The start address
	// is rounded against the final alignment of the text section later on in
	// (*Link).address. This may happen due to usage of PCALIGN directives
	// larger than Funcalign, or usage of ISA 3.1 prefixed instructions
	// (see ISA 3.1 Book I 1.9).
	const ppc64maxFuncalign = 64
	sectAlign = ppc64maxFuncalign
	va = uint64(Rnd(int64(va), ppc64maxFuncalign))
	}

	// Set the length for the previous text section
	sect.Length = va - sect.Vaddr

	// Create new section, set the starting Vaddr
	sect = addsection(ctxt.loader, ctxt.Arch, &Segtext, ".text", 05)

	sect.Vaddr = va
	sect.Align = sectAlign
	ldr.SetSymSect(s, sect)

	// Create a symbol for the start of the secondary text sections
	ntext := ldr.CreateSymForUpdate(fmt.Sprintf("runtime.text.%d", n), 0)
	ntext.SetSect(sect)
	if ctxt.IsAIX() {
	// runtime.text.X must be a real symbol on AIX.
	// Assign its address directly in order to be the
	// first symbol of this new section.
	ntext.SetType(sym.STEXT)
	ntext.SetSize(int64(abi.MINFUNC))
	ntext.SetOnList(true)
	ntext.SetAlign(sectAlign)
	ctxt.tramps = append(ctxt.tramps, ntext.Sym())

	ntext.SetValue(int64(va))
	va += uint64(ntext.Size())

	if align := ldr.SymAlign(s); align != 0 {
	va = uint64(Rnd(int64(va), int64(align)))
	} else {
	va = uint64(Rnd(int64(va), int64(Funcalign)))
	}
	}
	n++
	}
	}

	ldr.SetSymValue(s, 0)
	for sub := s; sub != 0; sub = ldr.SubSym(sub) {
	ldr.SetSymValue(sub, ldr.SymValue(sub)+int64(va))
	if ctxt.Debugvlog > 2 {
	fmt.Println("assign text address:", ldr.SymName(sub), ldr.SymValue(sub))
	}
	}

	va += funcsize

	return sect, n, va
	}

	func resetAddress(ctxt *Link, s loader.Sym) {
	ldr := ctxt.loader
	if ldr.OuterSym(s) != 0 {
	return
	}
	oldv := ldr.SymValue(s)
	for sub := s; sub != 0; sub = ldr.SubSym(sub) {
	ldr.SetSymValue(sub, ldr.SymValue(sub)-oldv)
	}
	}

	// Return whether we may need to split text sections.
	//
	// On PPC64x, when external linking, a text section should not be
	// larger than 2^25 bytes due to the size of call target offset field
	// in the 'bl' instruction. Splitting into smaller text sections
	// smaller than this limit allows the system linker to modify the long
	// calls appropriately. The limit allows for the space needed for
	// tables inserted by the linker.
	//
	// The same applies to Darwin/ARM64, with 2^27 byte threshold.
	//
	// Similarly for ARM, we split sections (at 2^25 bytes) to avoid
	// inconsistencies between the Go linker's reachability calculations
	// (e.g. will direct call from X to Y need a trampoline) and similar
	// machinery in the external linker; see #58425 for more on the
	// history here.
	func splitTextSections(ctxt *Link) bool {
	return (ctxt.IsARM() \|\| ctxt.IsPPC64() \|\| (ctxt.IsARM64() && ctxt.IsDarwin())) && ctxt.IsExternal()
	}

	// On Wasm, we reserve 4096 bytes for zero page, then 8192 bytes for wasm_exec.js
	// to store command line args and environment variables.
	// Data sections starts from at least address 12288.
	// Keep in sync with wasm_exec.js.
	const wasmMinDataAddr = 4096 + 8192

	// address assigns virtual addresses to all segments and sections and
	// returns all segments in file order.
	func (ctxt Link) address() []sym.Segment {
	var order []*sym.Segment // Layout order

	va := uint64(*FlagTextAddr)
	order = append(order, &Segtext)
	Segtext.Rwx = 05
	Segtext.Vaddr = va
	for i, s := range Segtext.Sections {
	va = uint64(Rnd(int64(va), int64(s.Align)))
	s.Vaddr = va
	va += s.Length

	if ctxt.IsWasm() && i == 0 && va < wasmMinDataAddr {
	va = wasmMinDataAddr
	}
	}

	Segtext.Length = va - uint64(*FlagTextAddr)

	if len(Segrodata.Sections) > 0 {
	// align to page boundary so as not to mix
	// rodata and executable text.
	//
	// Note: gold or GNU ld will reduce the size of the executable
	// file by arranging for the relro segment to end at a page
	// boundary, and overlap the end of the text segment with the
	// start of the relro segment in the file. The PT_LOAD segments
	// will be such that the last page of the text segment will be
	// mapped twice, once r-x and once starting out rw- and, after
	// relocation processing, changed to r--.
	va = uint64(Rnd(int64(va), *FlagRound))

	order = append(order, &Segrodata)
	Segrodata.Rwx = 04
	Segrodata.Vaddr = va
	for _, s := range Segrodata.Sections {
	va = uint64(Rnd(int64(va), int64(s.Align)))
	s.Vaddr = va
	va += s.Length
	}

	Segrodata.Length = va - Segrodata.Vaddr
	}
	if len(Segrelrodata.Sections) > 0 {
	// align to page boundary so as not to mix
	// rodata, rel-ro data, and executable text.
	va = uint64(Rnd(int64(va), *FlagRound))
	if ctxt.HeadType == objabi.Haix {
	// Relro data are inside data segment on AIX.
	va += uint64(XCOFFDATABASE) - uint64(XCOFFTEXTBASE)
	}

	order = append(order, &Segrelrodata)
	Segrelrodata.Rwx = 06
	Segrelrodata.Vaddr = va
	for _, s := range Segrelrodata.Sections {
	va = uint64(Rnd(int64(va), int64(s.Align)))
	s.Vaddr = va
	va += s.Length
	}

	Segrelrodata.Length = va - Segrelrodata.Vaddr
	}

	va = uint64(Rnd(int64(va), *FlagRound))
	if ctxt.HeadType == objabi.Haix && len(Segrelrodata.Sections) == 0 {
	// Data sections are moved to an unreachable segment
	// to ensure that they are position-independent.
	// Already done if relro sections exist.
	va += uint64(XCOFFDATABASE) - uint64(XCOFFTEXTBASE)
	}
	order = append(order, &Segdata)
	Segdata.Rwx = 06
	if *FlagDataAddr != -1 {
	Segdata.Vaddr = uint64(*FlagDataAddr)
	va = Segdata.Vaddr
	} else {
	Segdata.Vaddr = va
	}
	var data *sym.Section
	var noptr *sym.Section
	var bss *sym.Section
	var noptrbss *sym.Section
	var fuzzCounters *sym.Section
	for i, s := range Segdata.Sections {
	if (ctxt.IsELF \|\| ctxt.HeadType == objabi.Haix) && s.Name == ".tbss" {
	continue
	}
	vlen := int64(s.Length)
	if i+1 < len(Segdata.Sections) && !((ctxt.IsELF \|\| ctxt.HeadType == objabi.Haix) && Segdata.Sections[i+1].Name == ".tbss") {
	vlen = int64(Segdata.Sections[i+1].Vaddr - s.Vaddr)
	}
	s.Vaddr = va
	va += uint64(vlen)
	Segdata.Length = va - Segdata.Vaddr
	switch s.Name {
	case ".data":
	data = s
	case ".noptrdata":
	noptr = s
	case ".bss":
	bss = s
	case ".noptrbss":
	noptrbss = s
	case ".go.fuzzcntrs":
	fuzzCounters = s
	}
	}

	// Assign Segdata's Filelen omitting the BSS. We do this here
	// simply because right now we know where the BSS starts.
	Segdata.Filelen = bss.Vaddr - Segdata.Vaddr

	if len(Segpdata.Sections) > 0 {
	va = uint64(Rnd(int64(va), *FlagRound))
	order = append(order, &Segpdata)
	Segpdata.Rwx = 04
	Segpdata.Vaddr = va
	// Segpdata.Sections is intended to contain just one section.
	// Loop through the slice anyway for consistency.
	for _, s := range Segpdata.Sections {
	va = uint64(Rnd(int64(va), int64(s.Align)))
	s.Vaddr = va
	va += s.Length
	}
	Segpdata.Length = va - Segpdata.Vaddr
	}

	if len(Segxdata.Sections) > 0 {
	va = uint64(Rnd(int64(va), *FlagRound))
	order = append(order, &Segxdata)
	Segxdata.Rwx = 04
	Segxdata.Vaddr = va
	// Segxdata.Sections is intended to contain just one section.
	// Loop through the slice anyway for consistency.
	for _, s := range Segxdata.Sections {
	va = uint64(Rnd(int64(va), int64(s.Align)))
	s.Vaddr = va
	va += s.Length
	}
	Segxdata.Length = va - Segxdata.Vaddr
	}

	va = uint64(Rnd(int64(va), *FlagRound))
	order = append(order, &Segdwarf)
	Segdwarf.Rwx = 06
	Segdwarf.Vaddr = va
	for i, s := range Segdwarf.Sections {
	vlen := int64(s.Length)
	if i+1 < len(Segdwarf.Sections) {
	vlen = int64(Segdwarf.Sections[i+1].Vaddr - s.Vaddr)
	}
	s.Vaddr = va
	va += uint64(vlen)
	if ctxt.HeadType == objabi.Hwindows {
	va = uint64(Rnd(int64(va), PEFILEALIGN))
	}
	Segdwarf.Length = va - Segdwarf.Vaddr
	}

	ldr := ctxt.loader
	var (
	rodata = ldr.SymSect(ldr.LookupOrCreateSym("runtime.rodata", 0))
	pclntab = ldr.SymSect(ldr.LookupOrCreateSym("runtime.pclntab", 0))
	types = ldr.SymSect(ldr.LookupOrCreateSym("runtime.types", 0))
	)

	for _, s := range ctxt.datap {
	if sect := ldr.SymSect(s); sect != nil {
	ldr.AddToSymValue(s, int64(sect.Vaddr))
	}
	v := ldr.SymValue(s)
	for sub := ldr.SubSym(s); sub != 0; sub = ldr.SubSym(sub) {
	ldr.AddToSymValue(sub, v)
	}
	}

	for _, si := range dwarfp {
	for _, s := range si.syms {
	if sect := ldr.SymSect(s); sect != nil {
	ldr.AddToSymValue(s, int64(sect.Vaddr))
	}
	sub := ldr.SubSym(s)
	if sub != 0 {
	panic(fmt.Sprintf("unexpected sub-sym for %s %s", ldr.SymName(s), ldr.SymType(s).String()))
	}
	v := ldr.SymValue(s)
	for ; sub != 0; sub = ldr.SubSym(sub) {
	ldr.AddToSymValue(s, v)
	}
	}
	}

	for _, s := range sehp.pdata {
	if sect := ldr.SymSect(s); sect != nil {
	ldr.AddToSymValue(s, int64(sect.Vaddr))
	}
	}
	for _, s := range sehp.xdata {
	if sect := ldr.SymSect(s); sect != nil {
	ldr.AddToSymValue(s, int64(sect.Vaddr))
	}
	}

	if ctxt.BuildMode == BuildModeShared {
	s := ldr.LookupOrCreateSym("go:link.abihashbytes", 0)
	sect := ldr.SymSect(ldr.LookupOrCreateSym(".note.go.abihash", 0))
	ldr.SetSymSect(s, sect)
	ldr.SetSymValue(s, int64(sect.Vaddr+16))
	}

	// If there are multiple text sections, create runtime.text.n for
	// their section Vaddr, using n for index
	n := 1
	for _, sect := range Segtext.Sections[1:] {
	if sect.Name != ".text" {
	break
	}
	symname := fmt.Sprintf("runtime.text.%d", n)
	if ctxt.HeadType != objabi.Haix \|\| ctxt.LinkMode != LinkExternal {
	// Addresses are already set on AIX with external linker
	// because these symbols are part of their sections.
	ctxt.xdefine(symname, sym.STEXT, int64(sect.Vaddr))
	}
	n++
	}

	ctxt.xdefine("runtime.rodata", sym.SRODATA, int64(rodata.Vaddr))
	ctxt.xdefine("runtime.erodata", sym.SRODATA, int64(rodata.Vaddr+rodata.Length))
	ctxt.xdefine("runtime.types", sym.SRODATA, int64(types.Vaddr))
	ctxt.xdefine("runtime.etypes", sym.SRODATA, int64(types.Vaddr+types.Length))

	s := ldr.Lookup("runtime.gcdata", 0)
	ldr.SetAttrLocal(s, true)
	ctxt.xdefine("runtime.egcdata", sym.SRODATA, ldr.SymAddr(s)+ldr.SymSize(s))
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.egcdata", 0), ldr.SymSect(s))

	s = ldr.LookupOrCreateSym("runtime.gcbss", 0)
	ldr.SetAttrLocal(s, true)
	ctxt.xdefine("runtime.egcbss", sym.SRODATA, ldr.SymAddr(s)+ldr.SymSize(s))
	ldr.SetSymSect(ldr.LookupOrCreateSym("runtime.egcbss", 0), ldr.SymSect(s))

	ctxt.xdefine("runtime.pclntab", sym.SRODATA, int64(pclntab.Vaddr))
	ctxt.defineInternal("runtime.pcheader", sym.SRODATA)
	ctxt.defineInternal("runtime.funcnametab", sym.SRODATA)
	ctxt.defineInternal("runtime.cutab", sym.SRODATA)
	ctxt.defineInternal("runtime.filetab", sym.SRODATA)
	ctxt.defineInternal("runtime.pctab", sym.SRODATA)
	ctxt.defineInternal("runtime.functab", sym.SRODATA)
	ctxt.defineInternal("go:func.*", sym.SRODATA)
	ctxt.xdefine("runtime.epclntab", sym.SRODATA, int64(pclntab.Vaddr+pclntab.Length))
	ctxt.xdefine("runtime.noptrdata", sym.SNOPTRDATA, int64(noptr.Vaddr))
	ctxt.xdefine("runtime.enoptrdata", sym.SNOPTRDATAEND, int64(noptr.Vaddr+noptr.Length))
	ctxt.xdefine("runtime.bss", sym.SBSS, int64(bss.Vaddr))
	ctxt.xdefine("runtime.ebss", sym.SBSS, int64(bss.Vaddr+bss.Length))
	ctxt.xdefine("runtime.data", sym.SDATA, int64(data.Vaddr))
	ctxt.xdefine("runtime.edata", sym.SDATAEND, int64(data.Vaddr+data.Length))
	ctxt.xdefine("runtime.noptrbss", sym.SNOPTRBSS, int64(noptrbss.Vaddr))
	ctxt.xdefine("runtime.enoptrbss", sym.SNOPTRBSS, int64(noptrbss.Vaddr+noptrbss.Length))
	ctxt.xdefine("runtime.covctrs", sym.SCOVERAGE_COUNTER, int64(noptrbss.Vaddr+covCounterDataStartOff))
	ctxt.xdefine("runtime.ecovctrs", sym.SCOVERAGE_COUNTER, int64(noptrbss.Vaddr+covCounterDataStartOff+covCounterDataLen))
	ctxt.xdefine("runtime.end", sym.SBSS, int64(Segdata.Vaddr+Segdata.Length))

	if fuzzCounters != nil {
	if *flagAsan {
	// ASAN requires that the symbol marking the end
	// of the section be aligned on an 8 byte boundary.
	// See issue #66966.
	fuzzCounters.Length = uint64(Rnd(int64(fuzzCounters.Length), 8))
	}
	ctxt.xdefine("runtime.__start___sancov_cntrs", sym.SLIBFUZZER_8BIT_COUNTER, int64(fuzzCounters.Vaddr))
	ctxt.xdefine("runtime.__stop___sancov_cntrs", sym.SLIBFUZZER_8BIT_COUNTER, int64(fuzzCounters.Vaddr+fuzzCounters.Length))
	ctxt.xdefine("internal/fuzz._counters", sym.SLIBFUZZER_8BIT_COUNTER, int64(fuzzCounters.Vaddr))
	ctxt.xdefine("internal/fuzz._ecounters", sym.SLIBFUZZER_8BIT_COUNTER, int64(fuzzCounters.Vaddr+fuzzCounters.Length))
	}

	if ctxt.IsSolaris() {
	// On Solaris, in the runtime it sets the external names of the
	// end symbols. Unset them and define separate symbols, so we
	// keep both.
	etext := ldr.Lookup("runtime.etext", 0)
	edata := ldr.Lookup("runtime.edata", 0)
	end := ldr.Lookup("runtime.end", 0)
	ldr.SetSymExtname(etext, "runtime.etext")
	ldr.SetSymExtname(edata, "runtime.edata")
	ldr.SetSymExtname(end, "runtime.end")
	ctxt.xdefine("_etext", ldr.SymType(etext), ldr.SymValue(etext))
	ctxt.xdefine("_edata", ldr.SymType(edata), ldr.SymValue(edata))
	ctxt.xdefine("_end", ldr.SymType(end), ldr.SymValue(end))
	ldr.SetSymSect(ldr.Lookup("_etext", 0), ldr.SymSect(etext))
	ldr.SetSymSect(ldr.Lookup("_edata", 0), ldr.SymSect(edata))
	ldr.SetSymSect(ldr.Lookup("_end", 0), ldr.SymSect(end))
	}

	if ctxt.IsPPC64() && ctxt.IsElf() {
	// Resolve .TOC. symbols for all objects. Only one TOC region is supported. If a
	// GOT section is present, compute it as suggested by the ELFv2 ABI. Otherwise,
	// choose a similar offset from the start of the data segment.
	tocAddr := int64(Segdata.Vaddr) + 0x8000
	if gotAddr := ldr.SymValue(ctxt.GOT); gotAddr != 0 {
	tocAddr = gotAddr + 0x8000
	}
	for i := range ctxt.DotTOC {
	if i >= sym.SymVerABICount && i < sym.SymVerStatic { // these versions are not used currently
	continue
	}
	if toc := ldr.Lookup(".TOC.", i); toc != 0 {
	ldr.SetSymValue(toc, tocAddr)
	}
	}
	}

	return order
	}

	// layout assigns file offsets and lengths to the segments in order.
	// Returns the file size containing all the segments.
	func (ctxt Link) layout(order []sym.Segment) uint64 {
	var prev *sym.Segment
	for _, seg := range order {
	if prev == nil {
	seg.Fileoff = uint64(HEADR)
	} else {
	switch ctxt.HeadType {
	default:
	// Assuming the previous segment was
	// aligned, the following rounding
	// should ensure that this segment's
	// VA ≡ Fileoff mod FlagRound.
	seg.Fileoff = uint64(Rnd(int64(prev.Fileoff+prev.Filelen), *FlagRound))
	if seg.Vaddr%uint64(FlagRound) != seg.Fileoff%uint64(FlagRound) {
	Exitf("bad segment rounding (Vaddr=%#x Fileoff=%#x FlagRound=%#x)", seg.Vaddr, seg.Fileoff, *FlagRound)
	}
	case objabi.Hwindows:
	seg.Fileoff = prev.Fileoff + uint64(Rnd(int64(prev.Filelen), PEFILEALIGN))
	case objabi.Hplan9:
	seg.Fileoff = prev.Fileoff + prev.Filelen
	}
	}
	if seg != &Segdata {
	// Link.address already set Segdata.Filelen to
	// account for BSS.
	seg.Filelen = seg.Length
	}
	prev = seg
	}
	return prev.Fileoff + prev.Filelen
	}

	// add a trampoline with symbol s (to be laid down after the current function)
	func (ctxt Link) AddTramp(s loader.SymbolBuilder, typ sym.SymKind) {
	s.SetType(typ)
	s.SetReachable(true)
	s.SetOnList(true)
	ctxt.tramps = append(ctxt.tramps, s.Sym())
	if *FlagDebugTramp > 0 && ctxt.Debugvlog > 0 {
	ctxt.Logf("trampoline %s inserted\n", s.Name())
	}
	}

	// compressSyms compresses syms and returns the contents of the
	// compressed section. If the section would get larger, it returns nil.
	func compressSyms(ctxt *Link, syms []loader.Sym) []byte {
	ldr := ctxt.loader
	var total int64
	for _, sym := range syms {
	total += ldr.SymSize(sym)
	}

	var buf bytes.Buffer
	if ctxt.IsELF {
	switch ctxt.Arch.PtrSize {
	case 8:
	binary.Write(&buf, ctxt.Arch.ByteOrder, elf.Chdr64{
	Type: uint32(elf.COMPRESS_ZLIB),
	Size: uint64(total),
	Addralign: uint64(ctxt.Arch.Alignment),
	})
	case 4:
	binary.Write(&buf, ctxt.Arch.ByteOrder, elf.Chdr32{
	Type: uint32(elf.COMPRESS_ZLIB),
	Size: uint32(total),
	Addralign: uint32(ctxt.Arch.Alignment),
	})
	default:
	log.Fatalf("can't compress header size:%d", ctxt.Arch.PtrSize)
	}
	} else {
	buf.Write([]byte("ZLIB"))
	var sizeBytes [8]byte
	binary.BigEndian.PutUint64(sizeBytes[:], uint64(total))
	buf.Write(sizeBytes[:])
	}

	var relocbuf []byte // temporary buffer for applying relocations

	// Using zlib.BestSpeed achieves very nearly the same
	// compression levels of zlib.DefaultCompression, but takes
	// substantially less time. This is important because DWARF
	// compression can be a significant fraction of link time.
	z, err := zlib.NewWriterLevel(&buf, zlib.BestSpeed)
	if err != nil {
	log.Fatalf("NewWriterLevel failed: %s", err)
	}
	st := ctxt.makeRelocSymState()
	for _, s := range syms {
	// Symbol data may be read-only. Apply relocations in a
	// temporary buffer, and immediately write it out.
	P := ldr.Data(s)
	relocs := ldr.Relocs(s)
	if relocs.Count() != 0 {
	relocbuf = append(relocbuf[:0], P...)
	P = relocbuf
	st.relocsym(s, P)
	}
	if _, err := z.Write(P); err != nil {
	log.Fatalf("compression failed: %s", err)
	}
	for i := ldr.SymSize(s) - int64(len(P)); i > 0; {
	b := zeros[:]
	if i < int64(len(b)) {
	b = b[:i]
	}
	n, err := z.Write(b)
	if err != nil {
	log.Fatalf("compression failed: %s", err)
	}
	i -= int64(n)
	}
	}
	if err := z.Close(); err != nil {
	log.Fatalf("compression failed: %s", err)
	}
	if int64(buf.Len()) >= total {
	// Compression didn't save any space.
	return nil
	}
	return buf.Bytes()
	}

	// writeUleb128FixedLength writes out value v in LEB128 encoded
	// format, ensuring that the space written takes up length bytes. When
	// extra space is needed, we write initial bytes with just the
	// continuation bit set. For example, if val is 1 and length is 3,
	// we'll write 0x80 0x80 0x1 (first two bytes with zero val but
	// continuation bit set). NB: this function adapted from a similar
	// function in cmd/link/internal/wasm, they could be commoned up if
	// needed.
	func writeUleb128FixedLength(b []byte, v uint64, length int) error {
	for i := 0; i < length; i++ {
	c := uint8(v & 0x7f)
	v >>= 7
	if i < length-1 {
	c \|= 0x80
	}
	b[i] = c
	}
	if v != 0 {
	return fmt.Errorf("writeUleb128FixedLength: length too small")
	}
	return nil
	}