src/cmd/link/internal/ld/deadcode.go - go - Git at Google

 // Copyright 2019 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package ld

 import (
 	"cmd/internal/goobj"
 	"cmd/internal/objabi"
 	"cmd/internal/sys"
 	"cmd/link/internal/loader"
 	"cmd/link/internal/sym"
 	"fmt"
 	"internal/buildcfg"
 	"unicode"
 )

 var _ = fmt.Print

 type deadcodePass struct {
 	ctxt *Link
 	ldr  *loader.Loader
 	wq   heap // work queue, using min-heap for better locality

 	ifaceMethod     map[methodsig]bool // methods declared in reached interfaces
 	markableMethods []methodref        // methods of reached types
 	reflectSeen     bool               // whether we have seen a reflect method call
 	dynlink         bool

 	methodsigstmp []methodsig // scratch buffer for decoding method signatures
 }

 func (d *deadcodePass) init() {
 	d.ldr.InitReachable()
 	d.ifaceMethod = make(map[methodsig]bool)
 	if buildcfg.Experiment.FieldTrack {
 		d.ldr.Reachparent = make([]loader.Sym, d.ldr.NSym())
 	}
 	d.dynlink = d.ctxt.DynlinkingGo()

 	if d.ctxt.BuildMode == BuildModeShared {
 		// Mark all symbols defined in this library as reachable when
 		// building a shared library.
 		n := d.ldr.NDef()
 		for i := 1; i < n; i++ {
 			s := loader.Sym(i)
 			d.mark(s, 0)
 		}
 		return
 	}

 	var names []string

 	// In a normal binary, start at main.main and the init
 	// functions and mark what is reachable from there.
 	if d.ctxt.linkShared && (d.ctxt.BuildMode == BuildModeExe || d.ctxt.BuildMode == BuildModePIE) {
 		names = append(names, "main.main", "main..inittask")
 	} else {
 		// The external linker refers main symbol directly.
 		if d.ctxt.LinkMode == LinkExternal && (d.ctxt.BuildMode == BuildModeExe || d.ctxt.BuildMode == BuildModePIE) {
 			if d.ctxt.HeadType == objabi.Hwindows && d.ctxt.Arch.Family == sys.I386 {
 				*flagEntrySymbol = "_main"
 			} else {
 				*flagEntrySymbol = "main"
 			}
 		}
 		names = append(names, *flagEntrySymbol)
 	}
 	// runtime.unreachableMethod is a function that will throw if called.
 	// We redirect unreachable methods to it.
 	names = append(names, "runtime.unreachableMethod")
 	if !d.ctxt.linkShared && d.ctxt.BuildMode != BuildModePlugin {
 		// runtime.buildVersion and runtime.modinfo are referenced in .go.buildinfo section
 		// (see function buildinfo in data.go). They should normally be reachable from the
 		// runtime. Just make it explicit, in case.
 		names = append(names, "runtime.buildVersion", "runtime.modinfo")
 	}
 	if d.ctxt.BuildMode == BuildModePlugin {
 		names = append(names, objabi.PathToPrefix(*flagPluginPath)+"..inittask", objabi.PathToPrefix(*flagPluginPath)+".main", "go.plugin.tabs")

 		// We don't keep the go.plugin.exports symbol,
 		// but we do keep the symbols it refers to.
 		exportsIdx := d.ldr.Lookup("go.plugin.exports", 0)
 		if exportsIdx != 0 {
 			relocs := d.ldr.Relocs(exportsIdx)
 			for i := 0; i < relocs.Count(); i++ {
 				d.mark(relocs.At(i).Sym(), 0)
 			}
 		}
 	}

 	if d.ctxt.Debugvlog > 1 {
 		d.ctxt.Logf("deadcode start names: %v\n", names)
 	}

 	for _, name := range names {
 		// Mark symbol as a data/ABI0 symbol.
 		d.mark(d.ldr.Lookup(name, 0), 0)
 		// Also mark any Go functions (internal ABI).
 		d.mark(d.ldr.Lookup(name, sym.SymVerABIInternal), 0)
 	}

 	// All dynamic exports are roots.
 	for _, s := range d.ctxt.dynexp {
 		if d.ctxt.Debugvlog > 1 {
 			d.ctxt.Logf("deadcode start dynexp: %s<%d>\n", d.ldr.SymName(s), d.ldr.SymVersion(s))
 		}
 		d.mark(s, 0)
 	}
 }

 func (d *deadcodePass) flood() {
 	var methods []methodref
 	for !d.wq.empty() {
 		symIdx := d.wq.pop()

 		d.reflectSeen = d.reflectSeen || d.ldr.IsReflectMethod(symIdx)

 		isgotype := d.ldr.IsGoType(symIdx)
 		relocs := d.ldr.Relocs(symIdx)
 		var usedInIface bool

 		if isgotype {
 			if d.dynlink {
 				// When dynamic linking, a type may be passed across DSO
 				// boundary and get converted to interface at the other side.
 				d.ldr.SetAttrUsedInIface(symIdx, true)
 			}
 			usedInIface = d.ldr.AttrUsedInIface(symIdx)
 		}

 		methods = methods[:0]
 		for i := 0; i < relocs.Count(); i++ {
 			r := relocs.At(i)
 			if r.Weak() {
 				continue
 			}
 			t := r.Type()
 			switch t {
 			case objabi.R_METHODOFF:
 				if i+2 >= relocs.Count() {
 					panic("expect three consecutive R_METHODOFF relocs")
 				}
 				if usedInIface {
 					methods = append(methods, methodref{src: symIdx, r: i})
 					// The method descriptor is itself a type descriptor, and
 					// it can be used to reach other types, e.g. by using
 					// reflect.Type.Method(i).Type.In(j). We need to traverse
 					// its child types with UsedInIface set. (See also the
 					// comment below.)
 					rs := r.Sym()
 					if !d.ldr.AttrUsedInIface(rs) {
 						d.ldr.SetAttrUsedInIface(rs, true)
 						if d.ldr.AttrReachable(rs) {
 							d.ldr.SetAttrReachable(rs, false)
 							d.mark(rs, symIdx)
 						}
 					}
 				}
 				i += 2
 				continue
 			case objabi.R_USETYPE:
 				// type symbol used for DWARF. we need to load the symbol but it may not
 				// be otherwise reachable in the program.
 				// do nothing for now as we still load all type symbols.
 				continue
 			case objabi.R_USEIFACE:
 				// R_USEIFACE is a marker relocation that tells the linker the type is
 				// converted to an interface, i.e. should have UsedInIface set. See the
 				// comment below for why we need to unset the Reachable bit and re-mark it.
 				rs := r.Sym()
 				if !d.ldr.AttrUsedInIface(rs) {
 					d.ldr.SetAttrUsedInIface(rs, true)
 					if d.ldr.AttrReachable(rs) {
 						d.ldr.SetAttrReachable(rs, false)
 						d.mark(rs, symIdx)
 					}
 				}
 				continue
 			case objabi.R_USEIFACEMETHOD:
 				// R_USEIFACEMETHOD is a marker relocation that marks an interface
 				// method as used.
 				rs := r.Sym()
 				if d.ctxt.linkShared && (d.ldr.SymType(rs) == sym.SDYNIMPORT || d.ldr.SymType(rs) == sym.Sxxx) {
 					// Don't decode symbol from shared library (we'll mark all exported methods anyway).
 					// We check for both SDYNIMPORT and Sxxx because name-mangled symbols haven't
 					// been resolved at this point.
 					continue
 				}
 				m := d.decodeIfaceMethod(d.ldr, d.ctxt.Arch, rs, r.Add())
 				if d.ctxt.Debugvlog > 1 {
 					d.ctxt.Logf("reached iface method: %v\n", m)
 				}
 				d.ifaceMethod[m] = true
 				continue
 			}
 			rs := r.Sym()
 			if isgotype && usedInIface && d.ldr.IsGoType(rs) && !d.ldr.AttrUsedInIface(rs) {
 				// If a type is converted to an interface, it is possible to obtain an
 				// interface with a "child" type of it using reflection (e.g. obtain an
 				// interface of T from []chan T). We need to traverse its "child" types
 				// with UsedInIface attribute set.
 				// When visiting the child type (chan T in the example above), it will
 				// have UsedInIface set, so it in turn will mark and (re)visit its children
 				// (e.g. T above).
 				// We unset the reachable bit here, so if the child type is already visited,
 				// it will be visited again.
 				// Note that a type symbol can be visited at most twice, one without
 				// UsedInIface and one with. So termination is still guaranteed.
 				d.ldr.SetAttrUsedInIface(rs, true)
 				d.ldr.SetAttrReachable(rs, false)
 			}
 			d.mark(rs, symIdx)
 		}
 		naux := d.ldr.NAux(symIdx)
 		for i := 0; i < naux; i++ {
 			a := d.ldr.Aux(symIdx, i)
 			if a.Type() == goobj.AuxGotype {
 				// A symbol being reachable doesn't imply we need its
 				// type descriptor. Don't mark it.
 				continue
 			}
 			d.mark(a.Sym(), symIdx)
 		}
 		// Some host object symbols have an outer object, which acts like a
 		// "carrier" symbol, or it holds all the symbols for a particular
 		// section. We need to mark all "referenced" symbols from that carrier,
 		// so we make sure we're pulling in all outer symbols, and their sub
 		// symbols. This is not ideal, and these carrier/section symbols could
 		// be removed.
 		if d.ldr.IsExternal(symIdx) {
 			d.mark(d.ldr.OuterSym(symIdx), symIdx)
 			d.mark(d.ldr.SubSym(symIdx), symIdx)
 		}

 		if len(methods) != 0 {
 			if !isgotype {
 				panic("method found on non-type symbol")
 			}
 			// Decode runtime type information for type methods
 			// to help work out which methods can be called
 			// dynamically via interfaces.
 			methodsigs := d.decodetypeMethods(d.ldr, d.ctxt.Arch, symIdx, &relocs)
 			if len(methods) != len(methodsigs) {
 				panic(fmt.Sprintf("%q has %d method relocations for %d methods", d.ldr.SymName(symIdx), len(methods), len(methodsigs)))
 			}
 			for i, m := range methodsigs {
 				methods[i].m = m
 				if d.ctxt.Debugvlog > 1 {
 					d.ctxt.Logf("markable method: %v of sym %v %s\n", m, symIdx, d.ldr.SymName(symIdx))
 				}
 			}
 			d.markableMethods = append(d.markableMethods, methods...)
 		}
 	}
 }

 func (d *deadcodePass) mark(symIdx, parent loader.Sym) {
 	if symIdx != 0 && !d.ldr.AttrReachable(symIdx) {
 		d.wq.push(symIdx)
 		d.ldr.SetAttrReachable(symIdx, true)
 		if buildcfg.Experiment.FieldTrack && d.ldr.Reachparent[symIdx] == 0 {
 			d.ldr.Reachparent[symIdx] = parent
 		}
 		if *flagDumpDep {
 			to := d.ldr.SymName(symIdx)
 			if to != "" {
 				if d.ldr.AttrUsedInIface(symIdx) {
 					to += " <UsedInIface>"
 				}
 				from := "_"
 				if parent != 0 {
 					from = d.ldr.SymName(parent)
 					if d.ldr.AttrUsedInIface(parent) {
 						from += " <UsedInIface>"
 					}
 				}
 				fmt.Printf("%s -> %s\n", from, to)
 			}
 		}
 	}
 }

 func (d *deadcodePass) markMethod(m methodref) {
 	relocs := d.ldr.Relocs(m.src)
 	d.mark(relocs.At(m.r).Sym(), m.src)
 	d.mark(relocs.At(m.r+1).Sym(), m.src)
 	d.mark(relocs.At(m.r+2).Sym(), m.src)
 }

 // deadcode marks all reachable symbols.
 //
 // The basis of the dead code elimination is a flood fill of symbols,
 // following their relocations, beginning at *flagEntrySymbol.
 //
 // This flood fill is wrapped in logic for pruning unused methods.
 // All methods are mentioned by relocations on their receiver's *rtype.
 // These relocations are specially defined as R_METHODOFF by the compiler
 // so we can detect and manipulated them here.
 //
 // There are three ways a method of a reachable type can be invoked:
 //
 //	1. direct call
 //	2. through a reachable interface type
 //	3. reflect.Value.Method (or MethodByName), or reflect.Type.Method
 //	   (or MethodByName)
 //
 // The first case is handled by the flood fill, a directly called method
 // is marked as reachable.
 //
 // The second case is handled by decomposing all reachable interface
 // types into method signatures. Each encountered method is compared
 // against the interface method signatures, if it matches it is marked
 // as reachable. This is extremely conservative, but easy and correct.
 //
 // The third case is handled by looking to see if any of:
 //	- reflect.Value.Method or MethodByName is reachable
 // 	- reflect.Type.Method or MethodByName is called (through the
 // 	  REFLECTMETHOD attribute marked by the compiler).
 // If any of these happen, all bets are off and all exported methods
 // of reachable types are marked reachable.
 //
 // Any unreached text symbols are removed from ctxt.Textp.
 func deadcode(ctxt *Link) {
 	ldr := ctxt.loader
 	d := deadcodePass{ctxt: ctxt, ldr: ldr}
 	d.init()
 	d.flood()

 	methSym := ldr.Lookup("reflect.Value.Method", sym.SymVerABIInternal)
 	methByNameSym := ldr.Lookup("reflect.Value.MethodByName", sym.SymVerABIInternal)

 	if ctxt.DynlinkingGo() {
 		// Exported methods may satisfy interfaces we don't know
 		// about yet when dynamically linking.
 		d.reflectSeen = true
 	}

 	for {
 		// Methods might be called via reflection. Give up on
 		// static analysis, mark all exported methods of
 		// all reachable types as reachable.
 		d.reflectSeen = d.reflectSeen || (methSym != 0 && ldr.AttrReachable(methSym)) || (methByNameSym != 0 && ldr.AttrReachable(methByNameSym))

 		// Mark all methods that could satisfy a discovered
 		// interface as reachable. We recheck old marked interfaces
 		// as new types (with new methods) may have been discovered
 		// in the last pass.
 		rem := d.markableMethods[:0]
 		for _, m := range d.markableMethods {
 			if (d.reflectSeen && m.isExported()) || d.ifaceMethod[m.m] {
 				d.markMethod(m)
 			} else {
 				rem = append(rem, m)
 			}
 		}
 		d.markableMethods = rem

 		if d.wq.empty() {
 			// No new work was discovered. Done.
 			break
 		}
 		d.flood()
 	}
 }

 // methodsig is a typed method signature (name + type).
 type methodsig struct {
 	name string
 	typ  loader.Sym // type descriptor symbol of the function
 }

 // methodref holds the relocations from a receiver type symbol to its
 // method. There are three relocations, one for each of the fields in
 // the reflect.method struct: mtyp, ifn, and tfn.
 type methodref struct {
 	m   methodsig
 	src loader.Sym // receiver type symbol
 	r   int        // the index of R_METHODOFF relocations
 }

 func (m methodref) isExported() bool {
 	for _, r := range m.m.name {
 		return unicode.IsUpper(r)
 	}
 	panic("methodref has no signature")
 }

 // decodeMethodSig decodes an array of method signature information.
 // Each element of the array is size bytes. The first 4 bytes is a
 // nameOff for the method name, and the next 4 bytes is a typeOff for
 // the function type.
 //
 // Conveniently this is the layout of both runtime.method and runtime.imethod.
 func (d *deadcodePass) decodeMethodSig(ldr *loader.Loader, arch *sys.Arch, symIdx loader.Sym, relocs *loader.Relocs, off, size, count int) []methodsig {
 	if cap(d.methodsigstmp) < count {
 		d.methodsigstmp = append(d.methodsigstmp[:0], make([]methodsig, count)...)
 	}
 	var methods = d.methodsigstmp[:count]
 	for i := 0; i < count; i++ {
 		methods[i].name = decodetypeName(ldr, symIdx, relocs, off)
 		methods[i].typ = decodeRelocSym(ldr, symIdx, relocs, int32(off+4))
 		off += size
 	}
 	return methods
 }

 // Decode the method of interface type symbol symIdx at offset off.
 func (d *deadcodePass) decodeIfaceMethod(ldr *loader.Loader, arch *sys.Arch, symIdx loader.Sym, off int64) methodsig {
 	p := ldr.Data(symIdx)
 	if decodetypeKind(arch, p)&kindMask != kindInterface {
 		panic(fmt.Sprintf("symbol %q is not an interface", ldr.SymName(symIdx)))
 	}
 	relocs := ldr.Relocs(symIdx)
 	var m methodsig
 	m.name = decodetypeName(ldr, symIdx, &relocs, int(off))
 	m.typ = decodeRelocSym(ldr, symIdx, &relocs, int32(off+4))
 	return m
 }

 func (d *deadcodePass) decodetypeMethods(ldr *loader.Loader, arch *sys.Arch, symIdx loader.Sym, relocs *loader.Relocs) []methodsig {
 	p := ldr.Data(symIdx)
 	if !decodetypeHasUncommon(arch, p) {
 		panic(fmt.Sprintf("no methods on %q", ldr.SymName(symIdx)))
 	}
 	off := commonsize(arch) // reflect.rtype
 	switch decodetypeKind(arch, p) & kindMask {
 	case kindStruct: // reflect.structType
 		off += 4 * arch.PtrSize
 	case kindPtr: // reflect.ptrType
 		off += arch.PtrSize
 	case kindFunc: // reflect.funcType
 		off += arch.PtrSize // 4 bytes, pointer aligned
 	case kindSlice: // reflect.sliceType
 		off += arch.PtrSize
 	case kindArray: // reflect.arrayType
 		off += 3 * arch.PtrSize
 	case kindChan: // reflect.chanType
 		off += 2 * arch.PtrSize
 	case kindMap: // reflect.mapType
 		off += 4*arch.PtrSize + 8
 	case kindInterface: // reflect.interfaceType
 		off += 3 * arch.PtrSize
 	default:
 		// just Sizeof(rtype)
 	}

 	mcount := int(decodeInuxi(arch, p[off+4:], 2))
 	moff := int(decodeInuxi(arch, p[off+4+2+2:], 4))
 	off += moff                // offset to array of reflect.method values
 	const sizeofMethod = 4 * 4 // sizeof reflect.method in program
 	return d.decodeMethodSig(ldr, arch, symIdx, relocs, off, sizeofMethod, mcount)
 }
	// Copyright 2019 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package ld

	import (
	"cmd/internal/goobj"
	"cmd/internal/objabi"
	"cmd/internal/sys"
	"cmd/link/internal/loader"
	"cmd/link/internal/sym"
	"fmt"
	"internal/buildcfg"
	"unicode"
	)

	var _ = fmt.Print

	type deadcodePass struct {
	ctxt *Link
	ldr *loader.Loader
	wq heap // work queue, using min-heap for better locality

	ifaceMethod map[methodsig]bool // methods declared in reached interfaces
	markableMethods []methodref // methods of reached types
	reflectSeen bool // whether we have seen a reflect method call
	dynlink bool

	methodsigstmp []methodsig // scratch buffer for decoding method signatures
	}

	func (d *deadcodePass) init() {
	d.ldr.InitReachable()
	d.ifaceMethod = make(map[methodsig]bool)
	if buildcfg.Experiment.FieldTrack {
	d.ldr.Reachparent = make([]loader.Sym, d.ldr.NSym())
	}
	d.dynlink = d.ctxt.DynlinkingGo()

	if d.ctxt.BuildMode == BuildModeShared {
	// Mark all symbols defined in this library as reachable when
	// building a shared library.
	n := d.ldr.NDef()
	for i := 1; i < n; i++ {
	s := loader.Sym(i)
	d.mark(s, 0)
	}
	return
	}

	var names []string

	// In a normal binary, start at main.main and the init
	// functions and mark what is reachable from there.
	if d.ctxt.linkShared && (d.ctxt.BuildMode == BuildModeExe \|\| d.ctxt.BuildMode == BuildModePIE) {
	names = append(names, "main.main", "main..inittask")
	} else {
	// The external linker refers main symbol directly.
	if d.ctxt.LinkMode == LinkExternal && (d.ctxt.BuildMode == BuildModeExe \|\| d.ctxt.BuildMode == BuildModePIE) {
	if d.ctxt.HeadType == objabi.Hwindows && d.ctxt.Arch.Family == sys.I386 {
	*flagEntrySymbol = "_main"
	} else {
	*flagEntrySymbol = "main"
	}
	}
	names = append(names, *flagEntrySymbol)
	}
	// runtime.unreachableMethod is a function that will throw if called.
	// We redirect unreachable methods to it.
	names = append(names, "runtime.unreachableMethod")
	if !d.ctxt.linkShared && d.ctxt.BuildMode != BuildModePlugin {
	// runtime.buildVersion and runtime.modinfo are referenced in .go.buildinfo section
	// (see function buildinfo in data.go). They should normally be reachable from the
	// runtime. Just make it explicit, in case.
	names = append(names, "runtime.buildVersion", "runtime.modinfo")
	}
	if d.ctxt.BuildMode == BuildModePlugin {
	names = append(names, objabi.PathToPrefix(flagPluginPath)+"..inittask", objabi.PathToPrefix(flagPluginPath)+".main", "go.plugin.tabs")

	// We don't keep the go.plugin.exports symbol,
	// but we do keep the symbols it refers to.
	exportsIdx := d.ldr.Lookup("go.plugin.exports", 0)
	if exportsIdx != 0 {
	relocs := d.ldr.Relocs(exportsIdx)
	for i := 0; i < relocs.Count(); i++ {
	d.mark(relocs.At(i).Sym(), 0)
	}
	}
	}

	if d.ctxt.Debugvlog > 1 {
	d.ctxt.Logf("deadcode start names: %v\n", names)
	}

	for _, name := range names {
	// Mark symbol as a data/ABI0 symbol.
	d.mark(d.ldr.Lookup(name, 0), 0)
	// Also mark any Go functions (internal ABI).
	d.mark(d.ldr.Lookup(name, sym.SymVerABIInternal), 0)
	}

	// All dynamic exports are roots.
	for _, s := range d.ctxt.dynexp {
	if d.ctxt.Debugvlog > 1 {
	d.ctxt.Logf("deadcode start dynexp: %s<%d>\n", d.ldr.SymName(s), d.ldr.SymVersion(s))
	}
	d.mark(s, 0)
	}
	}

	func (d *deadcodePass) flood() {
	var methods []methodref
	for !d.wq.empty() {
	symIdx := d.wq.pop()

	d.reflectSeen = d.reflectSeen \|\| d.ldr.IsReflectMethod(symIdx)

	isgotype := d.ldr.IsGoType(symIdx)
	relocs := d.ldr.Relocs(symIdx)
	var usedInIface bool

	if isgotype {
	if d.dynlink {
	// When dynamic linking, a type may be passed across DSO
	// boundary and get converted to interface at the other side.
	d.ldr.SetAttrUsedInIface(symIdx, true)
	}
	usedInIface = d.ldr.AttrUsedInIface(symIdx)
	}

	methods = methods[:0]
	for i := 0; i < relocs.Count(); i++ {
	r := relocs.At(i)
	if r.Weak() {
	continue
	}
	t := r.Type()
	switch t {
	case objabi.R_METHODOFF:
	if i+2 >= relocs.Count() {
	panic("expect three consecutive R_METHODOFF relocs")
	}
	if usedInIface {
	methods = append(methods, methodref{src: symIdx, r: i})
	// The method descriptor is itself a type descriptor, and
	// it can be used to reach other types, e.g. by using
	// reflect.Type.Method(i).Type.In(j). We need to traverse
	// its child types with UsedInIface set. (See also the
	// comment below.)
	rs := r.Sym()
	if !d.ldr.AttrUsedInIface(rs) {
	d.ldr.SetAttrUsedInIface(rs, true)
	if d.ldr.AttrReachable(rs) {
	d.ldr.SetAttrReachable(rs, false)
	d.mark(rs, symIdx)
	}
	}
	}
	i += 2
	continue
	case objabi.R_USETYPE:
	// type symbol used for DWARF. we need to load the symbol but it may not
	// be otherwise reachable in the program.
	// do nothing for now as we still load all type symbols.
	continue
	case objabi.R_USEIFACE:
	// R_USEIFACE is a marker relocation that tells the linker the type is
	// converted to an interface, i.e. should have UsedInIface set. See the
	// comment below for why we need to unset the Reachable bit and re-mark it.
	rs := r.Sym()
	if !d.ldr.AttrUsedInIface(rs) {
	d.ldr.SetAttrUsedInIface(rs, true)
	if d.ldr.AttrReachable(rs) {
	d.ldr.SetAttrReachable(rs, false)
	d.mark(rs, symIdx)
	}
	}
	continue
	case objabi.R_USEIFACEMETHOD:
	// R_USEIFACEMETHOD is a marker relocation that marks an interface
	// method as used.
	rs := r.Sym()
	if d.ctxt.linkShared && (d.ldr.SymType(rs) == sym.SDYNIMPORT \|\| d.ldr.SymType(rs) == sym.Sxxx) {
	// Don't decode symbol from shared library (we'll mark all exported methods anyway).
	// We check for both SDYNIMPORT and Sxxx because name-mangled symbols haven't
	// been resolved at this point.
	continue
	}
	m := d.decodeIfaceMethod(d.ldr, d.ctxt.Arch, rs, r.Add())
	if d.ctxt.Debugvlog > 1 {
	d.ctxt.Logf("reached iface method: %v\n", m)
	}
	d.ifaceMethod[m] = true
	continue
	}
	rs := r.Sym()
	if isgotype && usedInIface && d.ldr.IsGoType(rs) && !d.ldr.AttrUsedInIface(rs) {
	// If a type is converted to an interface, it is possible to obtain an
	// interface with a "child" type of it using reflection (e.g. obtain an
	// interface of T from []chan T). We need to traverse its "child" types
	// with UsedInIface attribute set.
	// When visiting the child type (chan T in the example above), it will
	// have UsedInIface set, so it in turn will mark and (re)visit its children
	// (e.g. T above).
	// We unset the reachable bit here, so if the child type is already visited,
	// it will be visited again.
	// Note that a type symbol can be visited at most twice, one without
	// UsedInIface and one with. So termination is still guaranteed.
	d.ldr.SetAttrUsedInIface(rs, true)
	d.ldr.SetAttrReachable(rs, false)
	}
	d.mark(rs, symIdx)
	}
	naux := d.ldr.NAux(symIdx)
	for i := 0; i < naux; i++ {
	a := d.ldr.Aux(symIdx, i)
	if a.Type() == goobj.AuxGotype {
	// A symbol being reachable doesn't imply we need its
	// type descriptor. Don't mark it.
	continue
	}
	d.mark(a.Sym(), symIdx)
	}
	// Some host object symbols have an outer object, which acts like a
	// "carrier" symbol, or it holds all the symbols for a particular
	// section. We need to mark all "referenced" symbols from that carrier,
	// so we make sure we're pulling in all outer symbols, and their sub
	// symbols. This is not ideal, and these carrier/section symbols could
	// be removed.
	if d.ldr.IsExternal(symIdx) {
	d.mark(d.ldr.OuterSym(symIdx), symIdx)
	d.mark(d.ldr.SubSym(symIdx), symIdx)
	}

	if len(methods) != 0 {
	if !isgotype {
	panic("method found on non-type symbol")
	}
	// Decode runtime type information for type methods
	// to help work out which methods can be called
	// dynamically via interfaces.
	methodsigs := d.decodetypeMethods(d.ldr, d.ctxt.Arch, symIdx, &relocs)
	if len(methods) != len(methodsigs) {
	panic(fmt.Sprintf("%q has %d method relocations for %d methods", d.ldr.SymName(symIdx), len(methods), len(methodsigs)))
	}
	for i, m := range methodsigs {
	methods[i].m = m
	if d.ctxt.Debugvlog > 1 {
	d.ctxt.Logf("markable method: %v of sym %v %s\n", m, symIdx, d.ldr.SymName(symIdx))
	}
	}
	d.markableMethods = append(d.markableMethods, methods...)
	}
	}
	}

	func (d *deadcodePass) mark(symIdx, parent loader.Sym) {
	if symIdx != 0 && !d.ldr.AttrReachable(symIdx) {
	d.wq.push(symIdx)
	d.ldr.SetAttrReachable(symIdx, true)
	if buildcfg.Experiment.FieldTrack && d.ldr.Reachparent[symIdx] == 0 {
	d.ldr.Reachparent[symIdx] = parent
	}
	if *flagDumpDep {
	to := d.ldr.SymName(symIdx)
	if to != "" {
	if d.ldr.AttrUsedInIface(symIdx) {
	to += " <UsedInIface>"
	}
	from := "_"
	if parent != 0 {
	from = d.ldr.SymName(parent)
	if d.ldr.AttrUsedInIface(parent) {
	from += " <UsedInIface>"
	}
	}
	fmt.Printf("%s -> %s\n", from, to)
	}
	}
	}
	}

	func (d *deadcodePass) markMethod(m methodref) {
	relocs := d.ldr.Relocs(m.src)
	d.mark(relocs.At(m.r).Sym(), m.src)
	d.mark(relocs.At(m.r+1).Sym(), m.src)
	d.mark(relocs.At(m.r+2).Sym(), m.src)
	}

	// deadcode marks all reachable symbols.
	//
	// The basis of the dead code elimination is a flood fill of symbols,
	// following their relocations, beginning at *flagEntrySymbol.
	//
	// This flood fill is wrapped in logic for pruning unused methods.
	// All methods are mentioned by relocations on their receiver's *rtype.
	// These relocations are specially defined as R_METHODOFF by the compiler
	// so we can detect and manipulated them here.
	//
	// There are three ways a method of a reachable type can be invoked:
	//
	// 1. direct call
	// 2. through a reachable interface type
	// 3. reflect.Value.Method (or MethodByName), or reflect.Type.Method
	// (or MethodByName)
	//
	// The first case is handled by the flood fill, a directly called method
	// is marked as reachable.
	//
	// The second case is handled by decomposing all reachable interface
	// types into method signatures. Each encountered method is compared
	// against the interface method signatures, if it matches it is marked
	// as reachable. This is extremely conservative, but easy and correct.
	//
	// The third case is handled by looking to see if any of:
	// - reflect.Value.Method or MethodByName is reachable
	// - reflect.Type.Method or MethodByName is called (through the
	// REFLECTMETHOD attribute marked by the compiler).
	// If any of these happen, all bets are off and all exported methods
	// of reachable types are marked reachable.
	//
	// Any unreached text symbols are removed from ctxt.Textp.
	func deadcode(ctxt *Link) {
	ldr := ctxt.loader
	d := deadcodePass{ctxt: ctxt, ldr: ldr}
	d.init()
	d.flood()

	methSym := ldr.Lookup("reflect.Value.Method", sym.SymVerABIInternal)
	methByNameSym := ldr.Lookup("reflect.Value.MethodByName", sym.SymVerABIInternal)

	if ctxt.DynlinkingGo() {
	// Exported methods may satisfy interfaces we don't know
	// about yet when dynamically linking.
	d.reflectSeen = true
	}

	for {
	// Methods might be called via reflection. Give up on
	// static analysis, mark all exported methods of
	// all reachable types as reachable.
	d.reflectSeen = d.reflectSeen \|\| (methSym != 0 && ldr.AttrReachable(methSym)) \|\| (methByNameSym != 0 && ldr.AttrReachable(methByNameSym))

	// Mark all methods that could satisfy a discovered
	// interface as reachable. We recheck old marked interfaces
	// as new types (with new methods) may have been discovered
	// in the last pass.
	rem := d.markableMethods[:0]
	for _, m := range d.markableMethods {
	if (d.reflectSeen && m.isExported()) \|\| d.ifaceMethod[m.m] {
	d.markMethod(m)
	} else {
	rem = append(rem, m)
	}
	}
	d.markableMethods = rem

	if d.wq.empty() {
	// No new work was discovered. Done.
	break
	}
	d.flood()
	}
	}

	// methodsig is a typed method signature (name + type).
	type methodsig struct {
	name string
	typ loader.Sym // type descriptor symbol of the function
	}

	// methodref holds the relocations from a receiver type symbol to its
	// method. There are three relocations, one for each of the fields in
	// the reflect.method struct: mtyp, ifn, and tfn.
	type methodref struct {
	m methodsig
	src loader.Sym // receiver type symbol
	r int // the index of R_METHODOFF relocations
	}

	func (m methodref) isExported() bool {
	for _, r := range m.m.name {
	return unicode.IsUpper(r)
	}
	panic("methodref has no signature")
	}

	// decodeMethodSig decodes an array of method signature information.
	// Each element of the array is size bytes. The first 4 bytes is a
	// nameOff for the method name, and the next 4 bytes is a typeOff for
	// the function type.
	//
	// Conveniently this is the layout of both runtime.method and runtime.imethod.
	func (d deadcodePass) decodeMethodSig(ldr loader.Loader, arch sys.Arch, symIdx loader.Sym, relocs loader.Relocs, off, size, count int) []methodsig {
	if cap(d.methodsigstmp) < count {
	d.methodsigstmp = append(d.methodsigstmp[:0], make([]methodsig, count)...)
	}
	var methods = d.methodsigstmp[:count]
	for i := 0; i < count; i++ {
	methods[i].name = decodetypeName(ldr, symIdx, relocs, off)
	methods[i].typ = decodeRelocSym(ldr, symIdx, relocs, int32(off+4))
	off += size
	}
	return methods
	}

	// Decode the method of interface type symbol symIdx at offset off.
	func (d deadcodePass) decodeIfaceMethod(ldr loader.Loader, arch *sys.Arch, symIdx loader.Sym, off int64) methodsig {
	p := ldr.Data(symIdx)
	if decodetypeKind(arch, p)&kindMask != kindInterface {
	panic(fmt.Sprintf("symbol %q is not an interface", ldr.SymName(symIdx)))
	}
	relocs := ldr.Relocs(symIdx)
	var m methodsig
	m.name = decodetypeName(ldr, symIdx, &relocs, int(off))
	m.typ = decodeRelocSym(ldr, symIdx, &relocs, int32(off+4))
	return m
	}

	func (d deadcodePass) decodetypeMethods(ldr loader.Loader, arch sys.Arch, symIdx loader.Sym, relocs loader.Relocs) []methodsig {
	p := ldr.Data(symIdx)
	if !decodetypeHasUncommon(arch, p) {
	panic(fmt.Sprintf("no methods on %q", ldr.SymName(symIdx)))
	}
	off := commonsize(arch) // reflect.rtype
	switch decodetypeKind(arch, p) & kindMask {
	case kindStruct: // reflect.structType
	off += 4 * arch.PtrSize
	case kindPtr: // reflect.ptrType
	off += arch.PtrSize
	case kindFunc: // reflect.funcType
	off += arch.PtrSize // 4 bytes, pointer aligned
	case kindSlice: // reflect.sliceType
	off += arch.PtrSize
	case kindArray: // reflect.arrayType
	off += 3 * arch.PtrSize
	case kindChan: // reflect.chanType
	off += 2 * arch.PtrSize
	case kindMap: // reflect.mapType
	off += 4*arch.PtrSize + 8
	case kindInterface: // reflect.interfaceType
	off += 3 * arch.PtrSize
	default:
	// just Sizeof(rtype)
	}

	mcount := int(decodeInuxi(arch, p[off+4:], 2))
	moff := int(decodeInuxi(arch, p[off+4+2+2:], 4))
	off += moff // offset to array of reflect.method values
	const sizeofMethod = 4 * 4 // sizeof reflect.method in program
	return d.decodeMethodSig(ldr, arch, symIdx, relocs, off, sizeofMethod, mcount)
	}