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// 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 loader
import (
"bytes"
"cmd/internal/bio"
"cmd/internal/goobj2"
"cmd/internal/obj"
"cmd/internal/objabi"
"cmd/internal/sys"
"cmd/link/internal/sym"
"debug/elf"
"fmt"
"log"
"math/bits"
"os"
"sort"
"strconv"
"strings"
)
var _ = fmt.Print
// Sym encapsulates a global symbol index, used to identify a specific
// Go symbol. The 0-valued Sym is corresponds to an invalid symbol.
type Sym int
// Relocs encapsulates the set of relocations on a given symbol; an
// instance of this type is returned by the Loader Relocs() method.
type Relocs struct {
rs []goobj2.Reloc
li int // local index of symbol whose relocs we're examining
r *oReader // object reader for containing package
l *Loader // loader
}
// Reloc contains the payload for a specific relocation.
// TODO: replace this with sym.Reloc, once we change the
// relocation target from "*sym.Symbol" to "loader.Sym" in sym.Reloc.
type Reloc struct {
Off int32 // offset to rewrite
Size uint8 // number of bytes to rewrite: 0, 1, 2, or 4
Type objabi.RelocType // the relocation type
Add int64 // addend
Sym Sym // global index of symbol the reloc addresses
}
// ExtReloc contains the payload for an external relocation.
type ExtReloc struct {
Idx int // index of the original relocation
Xsym Sym
Xadd int64
}
// ExtRelocView is a view of an external relocation.
// It is intended to be constructed on the fly, such as ExtRelocs.At.
// It is not the data structure used to store the payload internally.
type ExtRelocView struct {
Reloc2
*ExtReloc
}
// Reloc2 holds a "handle" to access a relocation record from an
// object file.
type Reloc2 struct {
*goobj2.Reloc
r *oReader
l *Loader
// External reloc types may not fit into a uint8 which the Go object file uses.
// Store it here, instead of in the byte of goobj2.Reloc2.
// For Go symbols this will always be zero.
// goobj2.Reloc2.Type() + typ is always the right type, for both Go and external
// symbols.
typ objabi.RelocType
}
func (rel Reloc2) Type() objabi.RelocType { return objabi.RelocType(rel.Reloc.Type()) + rel.typ }
func (rel Reloc2) Sym() Sym { return rel.l.resolve(rel.r, rel.Reloc.Sym()) }
func (rel Reloc2) SetSym(s Sym) { rel.Reloc.SetSym(goobj2.SymRef{PkgIdx: 0, SymIdx: uint32(s)}) }
func (rel Reloc2) SetType(t objabi.RelocType) {
if t != objabi.RelocType(uint8(t)) {
panic("SetType: type doesn't fit into Reloc2")
}
rel.Reloc.SetType(uint8(t))
if rel.typ != 0 {
// should use SymbolBuilder.SetRelocType
panic("wrong method to set reloc type")
}
}
// Aux2 holds a "handle" to access an aux symbol record from an
// object file.
type Aux2 struct {
*goobj2.Aux
r *oReader
l *Loader
}
func (a Aux2) Sym() Sym { return a.l.resolve(a.r, a.Aux.Sym()) }
// oReader is a wrapper type of obj.Reader, along with some
// extra information.
// TODO: rename to objReader once the old one is gone?
type oReader struct {
*goobj2.Reader
unit *sym.CompilationUnit
version int // version of static symbol
flags uint32 // read from object file
pkgprefix string
syms []Sym // Sym's global index, indexed by local index
ndef int // cache goobj2.Reader.NSym()
objidx uint32 // index of this reader in the objs slice
}
type objIdx struct {
r *oReader
i Sym // start index
}
// objSym represents a symbol in an object file. It is a tuple of
// the object and the symbol's local index.
// For external symbols, r is l.extReader, s is its index into the
// payload array.
// {nil, 0} represents the nil symbol.
type objSym struct {
r *oReader
s int // local index
}
type nameVer struct {
name string
v int
}
type Bitmap []uint32
// set the i-th bit.
func (bm Bitmap) Set(i Sym) {
n, r := uint(i)/32, uint(i)%32
bm[n] |= 1 << r
}
// unset the i-th bit.
func (bm Bitmap) Unset(i Sym) {
n, r := uint(i)/32, uint(i)%32
bm[n] &^= (1 << r)
}
// whether the i-th bit is set.
func (bm Bitmap) Has(i Sym) bool {
n, r := uint(i)/32, uint(i)%32
return bm[n]&(1<<r) != 0
}
// return current length of bitmap in bits.
func (bm Bitmap) Len() int {
return len(bm) * 32
}
// return the number of bits set.
func (bm Bitmap) Count() int {
s := 0
for _, x := range bm {
s += bits.OnesCount32(x)
}
return s
}
func MakeBitmap(n int) Bitmap {
return make(Bitmap, (n+31)/32)
}
// growBitmap insures that the specified bitmap has enough capacity,
// reallocating (doubling the size) if needed.
func growBitmap(reqLen int, b Bitmap) Bitmap {
curLen := b.Len()
if reqLen > curLen {
b = append(b, MakeBitmap(reqLen+1-curLen)...)
}
return b
}
// A Loader loads new object files and resolves indexed symbol references.
//
// Notes on the layout of global symbol index space:
//
// - Go object files are read before host object files; each Go object
// read adds its defined package symbols to the global index space.
// Nonpackage symbols are not yet added.
//
// - In loader.LoadNonpkgSyms, add non-package defined symbols and
// references in all object files to the global index space.
//
// - Host object file loading happens; the host object loader does a
// name/version lookup for each symbol it finds; this can wind up
// extending the external symbol index space range. The host object
// loader stores symbol payloads in loader.payloads using SymbolBuilder.
//
// - For now, in loader.LoadFull we convert all symbols (Go + external)
// to sym.Symbols.
//
// - At some point (when the wayfront is pushed through all of the
// linker), all external symbols will be payload-based, and we can
// get rid of the loader.Syms array.
//
// - Each symbol gets a unique global index. For duplicated and
// overwriting/overwritten symbols, the second (or later) appearance
// of the symbol gets the same global index as the first appearance.
type Loader struct {
start map[*oReader]Sym // map from object file to its start index
objs []objIdx // sorted by start index (i.e. objIdx.i)
extStart Sym // from this index on, the symbols are externally defined
builtinSyms []Sym // global index of builtin symbols
objSyms []objSym // global index mapping to local index
symsByName [2]map[string]Sym // map symbol name to index, two maps are for ABI0 and ABIInternal
extStaticSyms map[nameVer]Sym // externally defined static symbols, keyed by name
extReader *oReader // a dummy oReader, for external symbols
payloadBatch []extSymPayload
payloads []*extSymPayload // contents of linker-materialized external syms
values []int64 // symbol values, indexed by global sym index
sects []*sym.Section // sections
symSects []uint16 // symbol's section, index to sects array
align []uint8 // symbol 2^N alignment, indexed by global index
outdata [][]byte // symbol's data in the output buffer
extRelocs [][]ExtReloc // symbol's external relocations
itablink map[Sym]struct{} // itablink[j] defined if j is go.itablink.*
deferReturnTramp map[Sym]bool // whether the symbol is a trampoline of a deferreturn call
objByPkg map[string]*oReader // map package path to its Go object reader
Syms []*sym.Symbol // indexed symbols. XXX we still make sym.Symbol for now.
symBatch []sym.Symbol // batch of symbols.
anonVersion int // most recently assigned ext static sym pseudo-version
// Bitmaps and other side structures used to store data used to store
// symbol flags/attributes; these are to be accessed via the
// corresponding loader "AttrXXX" and "SetAttrXXX" methods. Please
// visit the comments on these methods for more details on the
// semantics / interpretation of the specific flags or attribute.
attrReachable Bitmap // reachable symbols, indexed by global index
attrOnList Bitmap // "on list" symbols, indexed by global index
attrLocal Bitmap // "local" symbols, indexed by global index
attrNotInSymbolTable Bitmap // "not in symtab" symbols, indexed by glob idx
attrVisibilityHidden Bitmap // hidden symbols, indexed by ext sym index
attrDuplicateOK Bitmap // dupOK symbols, indexed by ext sym index
attrShared Bitmap // shared symbols, indexed by ext sym index
attrExternal Bitmap // external symbols, indexed by ext sym index
attrReadOnly map[Sym]bool // readonly data for this sym
attrTopFrame map[Sym]struct{} // top frame symbols
attrSpecial map[Sym]struct{} // "special" frame symbols
attrCgoExportDynamic map[Sym]struct{} // "cgo_export_dynamic" symbols
attrCgoExportStatic map[Sym]struct{} // "cgo_export_static" symbols
// Outer and Sub relations for symbols.
// TODO: figure out whether it's more efficient to just have these
// as fields on extSymPayload (note that this won't be a viable
// strategy if somewhere in the linker we set sub/outer for a
// non-external sym).
outer map[Sym]Sym
sub map[Sym]Sym
dynimplib map[Sym]string // stores Dynimplib symbol attribute
dynimpvers map[Sym]string // stores Dynimpvers symbol attribute
localentry map[Sym]uint8 // stores Localentry symbol attribute
extname map[Sym]string // stores Extname symbol attribute
elfType map[Sym]elf.SymType // stores elf type symbol property
elfSym map[Sym]int32 // stores elf sym symbol property
localElfSym map[Sym]int32 // stores "local" elf sym symbol property
symPkg map[Sym]string // stores package for symbol, or library for shlib-derived syms
plt map[Sym]int32 // stores dynimport for pe objects
got map[Sym]int32 // stores got for pe objects
dynid map[Sym]int32 // stores Dynid for symbol
relocVariant map[relocId]sym.RelocVariant // stores variant relocs
// Used to implement field tracking; created during deadcode if
// field tracking is enabled. Reachparent[K] contains the index of
// the symbol that triggered the marking of symbol K as live.
Reachparent []Sym
relocBatch []sym.Reloc // for bulk allocation of relocations
relocExtBatch []sym.RelocExt // for bulk allocation of relocations
flags uint32
strictDupMsgs int // number of strict-dup warning/errors, when FlagStrictDups is enabled
elfsetstring elfsetstringFunc
errorReporter *ErrorReporter
SymLookup func(name string, ver int) *sym.Symbol
}
const (
pkgDef = iota
nonPkgDef
nonPkgRef
)
type elfsetstringFunc func(s *sym.Symbol, str string, off int)
// extSymPayload holds the payload (data + relocations) for linker-synthesized
// external symbols (note that symbol value is stored in a separate slice).
type extSymPayload struct {
name string // TODO: would this be better as offset into str table?
size int64
ver int
kind sym.SymKind
objidx uint32 // index of original object if sym made by cloneToExternal
gotype Sym // Gotype (0 if not present)
relocs []goobj2.Reloc
reltypes []objabi.RelocType // relocation types
data []byte
auxs []goobj2.Aux
}
const (
// Loader.flags
FlagStrictDups = 1 << iota
)
func NewLoader(flags uint32, elfsetstring elfsetstringFunc, reporter *ErrorReporter) *Loader {
nbuiltin := goobj2.NBuiltin()
ldr := &Loader{
start: make(map[*oReader]Sym),
objs: []objIdx{{}}, // reserve index 0 for nil symbol
objSyms: []objSym{{}}, // reserve index 0 for nil symbol
extReader: &oReader{},
symsByName: [2]map[string]Sym{make(map[string]Sym, 100000), make(map[string]Sym, 50000)}, // preallocate ~2MB for ABI0 and ~1MB for ABI1 symbols
objByPkg: make(map[string]*oReader),
outer: make(map[Sym]Sym),
sub: make(map[Sym]Sym),
dynimplib: make(map[Sym]string),
dynimpvers: make(map[Sym]string),
localentry: make(map[Sym]uint8),
extname: make(map[Sym]string),
attrReadOnly: make(map[Sym]bool),
elfType: make(map[Sym]elf.SymType),
elfSym: make(map[Sym]int32),
localElfSym: make(map[Sym]int32),
symPkg: make(map[Sym]string),
plt: make(map[Sym]int32),
got: make(map[Sym]int32),
dynid: make(map[Sym]int32),
attrTopFrame: make(map[Sym]struct{}),
attrSpecial: make(map[Sym]struct{}),
attrCgoExportDynamic: make(map[Sym]struct{}),
attrCgoExportStatic: make(map[Sym]struct{}),
itablink: make(map[Sym]struct{}),
deferReturnTramp: make(map[Sym]bool),
extStaticSyms: make(map[nameVer]Sym),
builtinSyms: make([]Sym, nbuiltin),
flags: flags,
elfsetstring: elfsetstring,
errorReporter: reporter,
sects: []*sym.Section{nil}, // reserve index 0 for nil section
}
reporter.ldr = ldr
return ldr
}
// Add object file r, return the start index.
func (l *Loader) addObj(pkg string, r *oReader) Sym {
if _, ok := l.start[r]; ok {
panic("already added")
}
pkg = objabi.PathToPrefix(pkg) // the object file contains escaped package path
if _, ok := l.objByPkg[pkg]; !ok {
l.objByPkg[pkg] = r
}
i := Sym(len(l.objSyms))
l.start[r] = i
l.objs = append(l.objs, objIdx{r, i})
return i
}
// Add a symbol from an object file, return the global index and whether it is added.
// If the symbol already exist, it returns the index of that symbol.
func (l *Loader) AddSym(name string, ver int, r *oReader, li int, kind int, dupok bool, typ sym.SymKind) (Sym, bool) {
if l.extStart != 0 {
panic("AddSym called after external symbol is created")
}
i := Sym(len(l.objSyms))
addToGlobal := func() {
l.objSyms = append(l.objSyms, objSym{r, li})
}
if name == "" {
addToGlobal()
return i, true // unnamed aux symbol
}
if ver == r.version {
// Static symbol. Add its global index but don't
// add to name lookup table, as it cannot be
// referenced by name.
addToGlobal()
return i, true
}
if kind == pkgDef {
// Defined package symbols cannot be dup to each other.
// We load all the package symbols first, so we don't need
// to check dup here.
// We still add it to the lookup table, as it may still be
// referenced by name (e.g. through linkname).
l.symsByName[ver][name] = i
addToGlobal()
return i, true
}
// Non-package (named) symbol. Check if it already exists.
oldi, existed := l.symsByName[ver][name]
if !existed {
l.symsByName[ver][name] = i
addToGlobal()
return i, true
}
// symbol already exists
if dupok {
if l.flags&FlagStrictDups != 0 {
l.checkdup(name, r, li, oldi)
}
return oldi, false
}
oldr, oldli := l.toLocal(oldi)
oldsym := oldr.Sym(oldli)
if oldsym.Dupok() {
return oldi, false
}
overwrite := r.DataSize(li) != 0
if overwrite {
// new symbol overwrites old symbol.
oldtyp := sym.AbiSymKindToSymKind[objabi.SymKind(oldsym.Type())]
if !(oldtyp.IsData() && oldr.DataSize(oldli) == 0) {
log.Fatalf("duplicated definition of symbol " + name)
}
l.objSyms[oldi] = objSym{r, li}
} else {
// old symbol overwrites new symbol.
if !typ.IsData() { // only allow overwriting data symbol
log.Fatalf("duplicated definition of symbol " + name)
}
}
return oldi, true
}
// newExtSym creates a new external sym with the specified
// name/version.
func (l *Loader) newExtSym(name string, ver int) Sym {
i := Sym(len(l.objSyms))
if l.extStart == 0 {
l.extStart = i
}
l.growSyms(int(i))
pi := l.newPayload(name, ver)
l.objSyms = append(l.objSyms, objSym{l.extReader, int(pi)})
l.extReader.syms = append(l.extReader.syms, i)
return i
}
// LookupOrCreateSym looks up the symbol with the specified name/version,
// returning its Sym index if found. If the lookup fails, a new external
// Sym will be created, entered into the lookup tables, and returned.
func (l *Loader) LookupOrCreateSym(name string, ver int) Sym {
i := l.Lookup(name, ver)
if i != 0 {
return i
}
i = l.newExtSym(name, ver)
static := ver >= sym.SymVerStatic || ver < 0
if static {
l.extStaticSyms[nameVer{name, ver}] = i
} else {
l.symsByName[ver][name] = i
}
return i
}
func (l *Loader) IsExternal(i Sym) bool {
r, _ := l.toLocal(i)
return l.isExtReader(r)
}
func (l *Loader) isExtReader(r *oReader) bool {
return r == l.extReader
}
// For external symbol, return its index in the payloads array.
// XXX result is actually not a global index. We (ab)use the Sym type
// so we don't need conversion for accessing bitmaps.
func (l *Loader) extIndex(i Sym) Sym {
_, li := l.toLocal(i)
return Sym(li)
}
// Get a new payload for external symbol, return its index in
// the payloads array.
func (l *Loader) newPayload(name string, ver int) int {
pi := len(l.payloads)
pp := l.allocPayload()
pp.name = name
pp.ver = ver
l.payloads = append(l.payloads, pp)
l.growExtAttrBitmaps()
return pi
}
// getPayload returns a pointer to the extSymPayload struct for an
// external symbol if the symbol has a payload. Will panic if the
// symbol in question is bogus (zero or not an external sym).
func (l *Loader) getPayload(i Sym) *extSymPayload {
if !l.IsExternal(i) {
panic(fmt.Sprintf("bogus symbol index %d in getPayload", i))
}
pi := l.extIndex(i)
return l.payloads[pi]
}
// allocPayload allocates a new payload.
func (l *Loader) allocPayload() *extSymPayload {
batch := l.payloadBatch
if len(batch) == 0 {
batch = make([]extSymPayload, 1000)
}
p := &batch[0]
l.payloadBatch = batch[1:]
return p
}
func (ms *extSymPayload) Grow(siz int64) {
if int64(int(siz)) != siz {
log.Fatalf("symgrow size %d too long", siz)
}
if int64(len(ms.data)) >= siz {
return
}
if cap(ms.data) < int(siz) {
cl := len(ms.data)
ms.data = append(ms.data, make([]byte, int(siz)+1-cl)...)
ms.data = ms.data[0:cl]
}
ms.data = ms.data[:siz]
}
// Ensure Syms slice has enough space.
func (l *Loader) growSyms(i int) {
n := len(l.Syms)
if n > i {
return
}
l.Syms = append(l.Syms, make([]*sym.Symbol, i+1-n)...)
l.growValues(int(i) + 1)
l.growAttrBitmaps(int(i) + 1)
}
// Convert a local index to a global index.
func (l *Loader) toGlobal(r *oReader, i int) Sym {
return r.syms[i]
}
// Convert a global index to a local index.
func (l *Loader) toLocal(i Sym) (*oReader, int) {
return l.objSyms[i].r, int(l.objSyms[i].s)
}
// Resolve a local symbol reference. Return global index.
func (l *Loader) resolve(r *oReader, s goobj2.SymRef) Sym {
var rr *oReader
switch p := s.PkgIdx; p {
case goobj2.PkgIdxInvalid:
// {0, X} with non-zero X is never a valid sym reference from a Go object.
// We steal this space for symbol references from external objects.
// In this case, X is just the global index.
if l.isExtReader(r) {
return Sym(s.SymIdx)
}
if s.SymIdx != 0 {
panic("bad sym ref")
}
return 0
case goobj2.PkgIdxNone:
i := int(s.SymIdx) + r.ndef
return r.syms[i]
case goobj2.PkgIdxBuiltin:
return l.builtinSyms[s.SymIdx]
case goobj2.PkgIdxSelf:
rr = r
default:
pkg := r.Pkg(int(p))
var ok bool
rr, ok = l.objByPkg[pkg]
if !ok {
log.Fatalf("reference of nonexisted package %s, from %v", pkg, r.unit.Lib)
}
}
return l.toGlobal(rr, int(s.SymIdx))
}
// Look up a symbol by name, return global index, or 0 if not found.
// This is more like Syms.ROLookup than Lookup -- it doesn't create
// new symbol.
func (l *Loader) Lookup(name string, ver int) Sym {
if ver >= sym.SymVerStatic || ver < 0 {
return l.extStaticSyms[nameVer{name, ver}]
}
return l.symsByName[ver][name]
}
// Check that duplicate symbols have same contents.
func (l *Loader) checkdup(name string, r *oReader, li int, dup Sym) {
p := r.Data(li)
rdup, ldup := l.toLocal(dup)
pdup := rdup.Data(ldup)
if bytes.Equal(p, pdup) {
return
}
reason := "same length but different contents"
if len(p) != len(pdup) {
reason = fmt.Sprintf("new length %d != old length %d", len(p), len(pdup))
}
fmt.Fprintf(os.Stderr, "cmd/link: while reading object for '%v': duplicate symbol '%s', previous def at '%v', with mismatched payload: %s\n", r.unit.Lib, name, rdup.unit.Lib, reason)
// For the moment, allowlist DWARF subprogram DIEs for
// auto-generated wrapper functions. What seems to happen
// here is that we get different line numbers on formal
// params; I am guessing that the pos is being inherited
// from the spot where the wrapper is needed.
allowlist := strings.HasPrefix(name, "go.info.go.interface") ||
strings.HasPrefix(name, "go.info.go.builtin") ||
strings.HasPrefix(name, "go.debuglines")
if !allowlist {
l.strictDupMsgs++
}
}
func (l *Loader) NStrictDupMsgs() int { return l.strictDupMsgs }
// Number of total symbols.
func (l *Loader) NSym() int {
return len(l.objSyms)
}
// Number of defined Go symbols.
func (l *Loader) NDef() int {
return int(l.extStart)
}
// Number of reachable symbols.
func (l *Loader) NReachableSym() int {
return l.attrReachable.Count()
}
// Returns the raw (unpatched) name of the i-th symbol.
func (l *Loader) RawSymName(i Sym) string {
if l.IsExternal(i) {
pp := l.getPayload(i)
return pp.name
}
r, li := l.toLocal(i)
return r.Sym(li).Name(r.Reader)
}
// Returns the (patched) name of the i-th symbol.
func (l *Loader) SymName(i Sym) string {
if l.IsExternal(i) {
pp := l.getPayload(i)
return pp.name
}
r, li := l.toLocal(i)
return strings.Replace(r.Sym(li).Name(r.Reader), "\"\".", r.pkgprefix, -1)
}
// Returns the version of the i-th symbol.
func (l *Loader) SymVersion(i Sym) int {
if l.IsExternal(i) {
pp := l.getPayload(i)
return pp.ver
}
r, li := l.toLocal(i)
return int(abiToVer(r.Sym(li).ABI(), r.version))
}
// Returns the type of the i-th symbol.
func (l *Loader) SymType(i Sym) sym.SymKind {
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp != nil {
return pp.kind
}
return 0
}
r, li := l.toLocal(i)
return sym.AbiSymKindToSymKind[objabi.SymKind(r.Sym(li).Type())]
}
// Returns the attributes of the i-th symbol.
func (l *Loader) SymAttr(i Sym) uint8 {
if l.IsExternal(i) {
// TODO: do something? External symbols have different representation of attributes.
// For now, ReflectMethod, NoSplit, GoType, and Typelink are used and they cannot be
// set by external symbol.
return 0
}
r, li := l.toLocal(i)
return r.Sym(li).Flag()
}
// Returns the size of the i-th symbol.
func (l *Loader) SymSize(i Sym) int64 {
if l.IsExternal(i) {
pp := l.getPayload(i)
return pp.size
}
r, li := l.toLocal(i)
return int64(r.Sym(li).Siz())
}
// AttrReachable returns true for symbols that are transitively
// referenced from the entry points. Unreachable symbols are not
// written to the output.
func (l *Loader) AttrReachable(i Sym) bool {
return l.attrReachable.Has(i)
}
// SetAttrReachable sets the reachability property for a symbol (see
// AttrReachable).
func (l *Loader) SetAttrReachable(i Sym, v bool) {
if v {
l.attrReachable.Set(i)
} else {
l.attrReachable.Unset(i)
}
}
// AttrOnList returns true for symbols that are on some list (such as
// the list of all text symbols, or one of the lists of data symbols)
// and is consulted to avoid bugs where a symbol is put on a list
// twice.
func (l *Loader) AttrOnList(i Sym) bool {
return l.attrOnList.Has(i)
}
// SetAttrOnList sets the "on list" property for a symbol (see
// AttrOnList).
func (l *Loader) SetAttrOnList(i Sym, v bool) {
if v {
l.attrOnList.Set(i)
} else {
l.attrOnList.Unset(i)
}
}
// AttrLocal returns true for symbols that are only visible within the
// module (executable or shared library) being linked. This attribute
// is applied to thunks and certain other linker-generated symbols.
func (l *Loader) AttrLocal(i Sym) bool {
return l.attrLocal.Has(i)
}
// SetAttrLocal the "local" property for a symbol (see AttrLocal above).
func (l *Loader) SetAttrLocal(i Sym, v bool) {
if v {
l.attrLocal.Set(i)
} else {
l.attrLocal.Unset(i)
}
}
// SymAddr checks that a symbol is reachable, and returns its value.
func (l *Loader) SymAddr(i Sym) int64 {
if !l.AttrReachable(i) {
panic("unreachable symbol in symaddr")
}
return l.values[i]
}
// AttrNotInSymbolTable returns true for symbols that should not be
// added to the symbol table of the final generated load module.
func (l *Loader) AttrNotInSymbolTable(i Sym) bool {
return l.attrNotInSymbolTable.Has(i)
}
// SetAttrNotInSymbolTable the "not in symtab" property for a symbol
// (see AttrNotInSymbolTable above).
func (l *Loader) SetAttrNotInSymbolTable(i Sym, v bool) {
if v {
l.attrNotInSymbolTable.Set(i)
} else {
l.attrNotInSymbolTable.Unset(i)
}
}
// AttrVisibilityHidden symbols returns true for ELF symbols with
// visibility set to STV_HIDDEN. They become local symbols in
// the final executable. Only relevant when internally linking
// on an ELF platform.
func (l *Loader) AttrVisibilityHidden(i Sym) bool {
if !l.IsExternal(i) {
return false
}
return l.attrVisibilityHidden.Has(l.extIndex(i))
}
// SetAttrVisibilityHidden sets the "hidden visibility" property for a
// symbol (see AttrVisibilityHidden).
func (l *Loader) SetAttrVisibilityHidden(i Sym, v bool) {
if !l.IsExternal(i) {
panic("tried to set visibility attr on non-external symbol")
}
if v {
l.attrVisibilityHidden.Set(l.extIndex(i))
} else {
l.attrVisibilityHidden.Unset(l.extIndex(i))
}
}
// AttrDuplicateOK returns true for a symbol that can be present in
// multiple object files.
func (l *Loader) AttrDuplicateOK(i Sym) bool {
if !l.IsExternal(i) {
// TODO: if this path winds up being taken frequently, it
// might make more sense to copy the flag value out of the object
// into a larger bitmap during preload.
r, li := l.toLocal(i)
return r.Sym(li).Dupok()
}
return l.attrDuplicateOK.Has(l.extIndex(i))
}
// SetAttrDuplicateOK sets the "duplicate OK" property for an external
// symbol (see AttrDuplicateOK).
func (l *Loader) SetAttrDuplicateOK(i Sym, v bool) {
if !l.IsExternal(i) {
panic("tried to set dupok attr on non-external symbol")
}
if v {
l.attrDuplicateOK.Set(l.extIndex(i))
} else {
l.attrDuplicateOK.Unset(l.extIndex(i))
}
}
// AttrShared returns true for symbols compiled with the -shared option.
func (l *Loader) AttrShared(i Sym) bool {
if !l.IsExternal(i) {
// TODO: if this path winds up being taken frequently, it
// might make more sense to copy the flag value out of the
// object into a larger bitmap during preload.
r, _ := l.toLocal(i)
return (r.Flags() & goobj2.ObjFlagShared) != 0
}
return l.attrShared.Has(l.extIndex(i))
}
// SetAttrShared sets the "shared" property for an external
// symbol (see AttrShared).
func (l *Loader) SetAttrShared(i Sym, v bool) {
if !l.IsExternal(i) {
panic(fmt.Sprintf("tried to set shared attr on non-external symbol %d %s", i, l.SymName(i)))
}
if v {
l.attrShared.Set(l.extIndex(i))
} else {
l.attrShared.Unset(l.extIndex(i))
}
}
// AttrExternal returns true for function symbols loaded from host
// object files.
func (l *Loader) AttrExternal(i Sym) bool {
if !l.IsExternal(i) {
return false
}
return l.attrExternal.Has(l.extIndex(i))
}
// SetAttrExternal sets the "external" property for an host object
// symbol (see AttrExternal).
func (l *Loader) SetAttrExternal(i Sym, v bool) {
if !l.IsExternal(i) {
panic(fmt.Sprintf("tried to set external attr on non-external symbol %q", l.RawSymName(i)))
}
if v {
l.attrExternal.Set(l.extIndex(i))
} else {
l.attrExternal.Unset(l.extIndex(i))
}
}
// AttrTopFrame returns true for a function symbol that is an entry
// point, meaning that unwinders should stop when they hit this
// function.
func (l *Loader) AttrTopFrame(i Sym) bool {
_, ok := l.attrTopFrame[i]
return ok
}
// SetAttrTopFrame sets the "top frame" property for a symbol (see
// AttrTopFrame).
func (l *Loader) SetAttrTopFrame(i Sym, v bool) {
if v {
l.attrTopFrame[i] = struct{}{}
} else {
delete(l.attrTopFrame, i)
}
}
// AttrSpecial returns true for a symbols that do not have their
// address (i.e. Value) computed by the usual mechanism of
// data.go:dodata() & data.go:address().
func (l *Loader) AttrSpecial(i Sym) bool {
_, ok := l.attrSpecial[i]
return ok
}
// SetAttrSpecial sets the "special" property for a symbol (see
// AttrSpecial).
func (l *Loader) SetAttrSpecial(i Sym, v bool) {
if v {
l.attrSpecial[i] = struct{}{}
} else {
delete(l.attrSpecial, i)
}
}
// AttrCgoExportDynamic returns true for a symbol that has been
// specially marked via the "cgo_export_dynamic" compiler directive
// written by cgo (in response to //export directives in the source).
func (l *Loader) AttrCgoExportDynamic(i Sym) bool {
_, ok := l.attrCgoExportDynamic[i]
return ok
}
// SetAttrCgoExportDynamic sets the "cgo_export_dynamic" for a symbol
// (see AttrCgoExportDynamic).
func (l *Loader) SetAttrCgoExportDynamic(i Sym, v bool) {
if v {
l.attrCgoExportDynamic[i] = struct{}{}
} else {
delete(l.attrCgoExportDynamic, i)
}
}
// AttrCgoExportStatic returns true for a symbol that has been
// specially marked via the "cgo_export_static" directive
// written by cgo.
func (l *Loader) AttrCgoExportStatic(i Sym) bool {
_, ok := l.attrCgoExportStatic[i]
return ok
}
// SetAttrCgoExportStatic sets the "cgo_export_static" for a symbol
// (see AttrCgoExportStatic).
func (l *Loader) SetAttrCgoExportStatic(i Sym, v bool) {
if v {
l.attrCgoExportStatic[i] = struct{}{}
} else {
delete(l.attrCgoExportStatic, i)
}
}
func (l *Loader) AttrCgoExport(i Sym) bool {
return l.AttrCgoExportDynamic(i) || l.AttrCgoExportStatic(i)
}
// AttrReadOnly returns true for a symbol whose underlying data
// is stored via a read-only mmap.
func (l *Loader) AttrReadOnly(i Sym) bool {
if v, ok := l.attrReadOnly[i]; ok {
return v
}
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp.objidx != 0 {
return l.objs[pp.objidx].r.ReadOnly()
}
return false
}
r, _ := l.toLocal(i)
return r.ReadOnly()
}
// SetAttrReadOnly sets the "data is read only" property for a symbol
// (see AttrReadOnly).
func (l *Loader) SetAttrReadOnly(i Sym, v bool) {
l.attrReadOnly[i] = v
}
// AttrSubSymbol returns true for symbols that are listed as a
// sub-symbol of some other outer symbol. The sub/outer mechanism is
// used when loading host objects (sections from the host object
// become regular linker symbols and symbols go on the Sub list of
// their section) and for constructing the global offset table when
// internally linking a dynamic executable.
//
// Note that in later stages of the linker, we set Outer(S) to some
// container symbol C, but don't set Sub(C). Thus we have two
// distinct scenarios:
//
// - Outer symbol covers the address ranges of its sub-symbols.
// Outer.Sub is set in this case.
// - Outer symbol doesn't conver the address ranges. It is zero-sized
// and doesn't have sub-symbols. In the case, the inner symbol is
// not actually a "SubSymbol". (Tricky!)
//
// This method returns TRUE only for sub-symbols in the first scenario.
//
// FIXME: would be better to do away with this and have a better way
// to represent container symbols.
func (l *Loader) AttrSubSymbol(i Sym) bool {
// we don't explicitly store this attribute any more -- return
// a value based on the sub-symbol setting.
o := l.OuterSym(i)
if o == 0 {
return false
}
return l.SubSym(o) != 0
}
// Note that we don't have a 'SetAttrSubSymbol' method in the loader;
// clients should instead use the PrependSub method to establish
// outer/sub relationships for host object symbols.
// Returns whether the i-th symbol has ReflectMethod attribute set.
func (l *Loader) IsReflectMethod(i Sym) bool {
return l.SymAttr(i)&goobj2.SymFlagReflectMethod != 0
}
// Returns whether the i-th symbol is nosplit.
func (l *Loader) IsNoSplit(i Sym) bool {
return l.SymAttr(i)&goobj2.SymFlagNoSplit != 0
}
// Returns whether this is a Go type symbol.
func (l *Loader) IsGoType(i Sym) bool {
return l.SymAttr(i)&goobj2.SymFlagGoType != 0
}
// Returns whether this symbol should be included in typelink.
func (l *Loader) IsTypelink(i Sym) bool {
return l.SymAttr(i)&goobj2.SymFlagTypelink != 0
}
// Returns whether this is a "go.itablink.*" symbol.
func (l *Loader) IsItabLink(i Sym) bool {
if _, ok := l.itablink[i]; ok {
return true
}
return false
}
// Return whether this is a trampoline of a deferreturn call.
func (l *Loader) IsDeferReturnTramp(i Sym) bool {
return l.deferReturnTramp[i]
}
// Set that i is a trampoline of a deferreturn call.
func (l *Loader) SetIsDeferReturnTramp(i Sym, v bool) {
l.deferReturnTramp[i] = v
}
// growValues grows the slice used to store symbol values.
func (l *Loader) growValues(reqLen int) {
curLen := len(l.values)
if reqLen > curLen {
l.values = append(l.values, make([]int64, reqLen+1-curLen)...)
}
}
// SymValue returns the value of the i-th symbol. i is global index.
func (l *Loader) SymValue(i Sym) int64 {
return l.values[i]
}
// SetSymValue sets the value of the i-th symbol. i is global index.
func (l *Loader) SetSymValue(i Sym, val int64) {
l.values[i] = val
}
// AddToSymValue adds to the value of the i-th symbol. i is the global index.
func (l *Loader) AddToSymValue(i Sym, val int64) {
l.values[i] += val
}
// Returns the symbol content of the i-th symbol. i is global index.
func (l *Loader) Data(i Sym) []byte {
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp != nil {
return pp.data
}
return nil
}
r, li := l.toLocal(i)
return r.Data(li)
}
// Returns the data of the i-th symbol in the output buffer.
func (l *Loader) OutData(i Sym) []byte {
if int(i) < len(l.outdata) && l.outdata[i] != nil {
return l.outdata[i]
}
return l.Data(i)
}
// SetOutData sets the position of the data of the i-th symbol in the output buffer.
// i is global index.
func (l *Loader) SetOutData(i Sym, data []byte) {
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp != nil {
pp.data = data
return
}
}
l.outdata[i] = data
}
// InitOutData initializes the slice used to store symbol output data.
func (l *Loader) InitOutData() {
l.outdata = make([][]byte, l.extStart)
}
// SetExtRelocs sets the external relocations of the i-th symbol. i is global index.
func (l *Loader) SetExtRelocs(i Sym, relocs []ExtReloc) {
l.extRelocs[i] = relocs
}
// InitExtRelocs initialize the slice used to store external relocations.
func (l *Loader) InitExtRelocs() {
l.extRelocs = make([][]ExtReloc, l.NSym())
}
// SymAlign returns the alignment for a symbol.
func (l *Loader) SymAlign(i Sym) int32 {
if int(i) >= len(l.align) {
// align is extended lazily -- it the sym in question is
// outside the range of the existing slice, then we assume its
// alignment has not yet been set.
return 0
}
// TODO: would it make sense to return an arch-specific
// alignment depending on section type? E.g. STEXT => 32,
// SDATA => 1, etc?
abits := l.align[i]
if abits == 0 {
return 0
}
return int32(1 << (abits - 1))
}
// SetSymAlign sets the alignment for a symbol.
func (l *Loader) SetSymAlign(i Sym, align int32) {
// Reject nonsense alignments.
if align < 0 || align&(align-1) != 0 {
panic("bad alignment value")
}
if int(i) >= len(l.align) {
l.align = append(l.align, make([]uint8, l.NSym()-len(l.align))...)
}
if align == 0 {
l.align[i] = 0
}
l.align[i] = uint8(bits.Len32(uint32(align)))
}
// SymValue returns the section of the i-th symbol. i is global index.
func (l *Loader) SymSect(i Sym) *sym.Section {
if int(i) >= len(l.symSects) {
// symSects is extended lazily -- it the sym in question is
// outside the range of the existing slice, then we assume its
// section has not yet been set.
return nil
}
return l.sects[l.symSects[i]]
}
// SetSymValue sets the section of the i-th symbol. i is global index.
func (l *Loader) SetSymSect(i Sym, sect *sym.Section) {
if int(i) >= len(l.symSects) {
l.symSects = append(l.symSects, make([]uint16, l.NSym()-len(l.symSects))...)
}
l.symSects[i] = sect.Index
}
// growSects grows the slice used to store symbol sections.
func (l *Loader) growSects(reqLen int) {
curLen := len(l.symSects)
if reqLen > curLen {
l.symSects = append(l.symSects, make([]uint16, reqLen+1-curLen)...)
}
}
// NewSection creates a new (output) section.
func (l *Loader) NewSection() *sym.Section {
sect := new(sym.Section)
idx := len(l.sects)
if idx != int(uint16(idx)) {
panic("too many sections created")
}
sect.Index = uint16(idx)
l.sects = append(l.sects, sect)
return sect
}
// SymDynImplib returns the "dynimplib" attribute for the specified
// symbol, making up a portion of the info for a symbol specified
// on a "cgo_import_dynamic" compiler directive.
func (l *Loader) SymDynimplib(i Sym) string {
return l.dynimplib[i]
}
// SetSymDynimplib sets the "dynimplib" attribute for a symbol.
func (l *Loader) SetSymDynimplib(i Sym, value string) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetDynimplib")
}
if value == "" {
delete(l.dynimplib, i)
} else {
l.dynimplib[i] = value
}
}
// SymDynimpvers returns the "dynimpvers" attribute for the specified
// symbol, making up a portion of the info for a symbol specified
// on a "cgo_import_dynamic" compiler directive.
func (l *Loader) SymDynimpvers(i Sym) string {
return l.dynimpvers[i]
}
// SetSymDynimpvers sets the "dynimpvers" attribute for a symbol.
func (l *Loader) SetSymDynimpvers(i Sym, value string) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetDynimpvers")
}
if value == "" {
delete(l.dynimpvers, i)
} else {
l.dynimpvers[i] = value
}
}
// SymExtname returns the "extname" value for the specified
// symbol.
func (l *Loader) SymExtname(i Sym) string {
if s, ok := l.extname[i]; ok {
return s
}
return l.SymName(i)
}
// SetSymExtname sets the "extname" attribute for a symbol.
func (l *Loader) SetSymExtname(i Sym, value string) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetExtname")
}
if value == "" {
delete(l.extname, i)
} else {
l.extname[i] = value
}
}
// SymElfType returns the previously recorded ELF type for a symbol
// (used only for symbols read from shared libraries by ldshlibsyms).
// It is not set for symbols defined by the packages being linked or
// by symbols read by ldelf (and so is left as elf.STT_NOTYPE).
func (l *Loader) SymElfType(i Sym) elf.SymType {
if et, ok := l.elfType[i]; ok {
return et
}
return elf.STT_NOTYPE
}
// SetSymElfType sets the elf type attribute for a symbol.
func (l *Loader) SetSymElfType(i Sym, et elf.SymType) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetSymElfType")
}
if et == elf.STT_NOTYPE {
delete(l.elfType, i)
} else {
l.elfType[i] = et
}
}
// SymElfSym returns the ELF symbol index for a given loader
// symbol, assigned during ELF symtab generation.
func (l *Loader) SymElfSym(i Sym) int32 {
return l.elfSym[i]
}
// SetSymElfSym sets the elf symbol index for a symbol.
func (l *Loader) SetSymElfSym(i Sym, es int32) {
if i == 0 {
panic("bad sym index")
}
if es == 0 {
delete(l.elfSym, i)
} else {
l.elfSym[i] = es
}
}
// SymLocalElfSym returns the "local" ELF symbol index for a given loader
// symbol, assigned during ELF symtab generation.
func (l *Loader) SymLocalElfSym(i Sym) int32 {
return l.localElfSym[i]
}
// SetSymLocalElfSym sets the "local" elf symbol index for a symbol.
func (l *Loader) SetSymLocalElfSym(i Sym, es int32) {
if i == 0 {
panic("bad sym index")
}
if es == 0 {
delete(l.localElfSym, i)
} else {
l.localElfSym[i] = es
}
}
// SymPlt returns the plt value for pe symbols.
func (l *Loader) SymPlt(s Sym) int32 {
if v, ok := l.plt[s]; ok {
return v
}
return -1
}
// SetPlt sets the plt value for pe symbols.
func (l *Loader) SetPlt(i Sym, v int32) {
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol for SetPlt")
}
if v == -1 {
delete(l.plt, i)
} else {
l.plt[i] = v
}
}
// SymGot returns the got value for pe symbols.
func (l *Loader) SymGot(s Sym) int32 {
if v, ok := l.got[s]; ok {
return v
}
return -1
}
// SetGot sets the got value for pe symbols.
func (l *Loader) SetGot(i Sym, v int32) {
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol for SetGot")
}
if v == -1 {
delete(l.got, i)
} else {
l.got[i] = v
}
}
// SymDynid returns the "dynid" property for the specified symbol.
func (l *Loader) SymDynid(i Sym) int32 {
if s, ok := l.dynid[i]; ok {
return s
}
return -1
}
// SetSymDynid sets the "dynid" property for a symbol.
func (l *Loader) SetSymDynid(i Sym, val int32) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetSymDynid")
}
if val == -1 {
delete(l.dynid, i)
} else {
l.dynid[i] = val
}
}
// DynIdSyms returns the set of symbols for which dynID is set to an
// interesting (non-default) value. This is expected to be a fairly
// small set.
func (l *Loader) DynidSyms() []Sym {
sl := make([]Sym, 0, len(l.dynid))
for s := range l.dynid {
sl = append(sl, s)
}
sort.Slice(sl, func(i, j int) bool { return sl[i] < sl[j] })
return sl
}
// SymGoType returns the 'Gotype' property for a given symbol (set by
// the Go compiler for variable symbols). This version relies on
// reading aux symbols for the target sym -- it could be that a faster
// approach would be to check for gotype during preload and copy the
// results in to a map (might want to try this at some point and see
// if it helps speed things up).
func (l *Loader) SymGoType(i Sym) Sym {
if l.IsExternal(i) {
pp := l.getPayload(i)
return pp.gotype
}
r, li := l.toLocal(i)
auxs := r.Auxs(li)
for j := range auxs {
a := &auxs[j]
switch a.Type() {
case goobj2.AuxGotype:
return l.resolve(r, a.Sym())
}
}
return 0
}
// SymUnit returns the compilation unit for a given symbol (which will
// typically be nil for external or linker-manufactured symbols).
func (l *Loader) SymUnit(i Sym) *sym.CompilationUnit {
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp.objidx != 0 {
r := l.objs[pp.objidx].r
return r.unit
}
return nil
}
r, _ := l.toLocal(i)
return r.unit
}
// SymPkg returns the package where the symbol came from (for
// regular compiler-generated Go symbols), but in the case of
// building with "-linkshared" (when a symbol is read from a
// shared library), will hold the library name.
// NOTE: this correspondes to sym.Symbol.File field.
func (l *Loader) SymPkg(i Sym) string {
if f, ok := l.symPkg[i]; ok {
return f
}
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp.objidx != 0 {
r := l.objs[pp.objidx].r
return r.unit.Lib.Pkg
}
return ""
}
r, _ := l.toLocal(i)
return r.unit.Lib.Pkg
}
// SetSymPkg sets the package/library for a symbol. This is
// needed mainly for external symbols, specifically those imported
// from shared libraries.
func (l *Loader) SetSymPkg(i Sym, pkg string) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetSymPkg")
}
l.symPkg[i] = pkg
}
// SymLocalentry returns the "local entry" value for the specified
// symbol.
func (l *Loader) SymLocalentry(i Sym) uint8 {
return l.localentry[i]
}
// SetSymLocalentry sets the "local entry" attribute for a symbol.
func (l *Loader) SetSymLocalentry(i Sym, value uint8) {
// reject bad symbols
if i >= Sym(len(l.objSyms)) || i == 0 {
panic("bad symbol index in SetSymLocalentry")
}
if value == 0 {
delete(l.localentry, i)
} else {
l.localentry[i] = value
}
}
// Returns the number of aux symbols given a global index.
func (l *Loader) NAux(i Sym) int {
if l.IsExternal(i) {
return 0
}
r, li := l.toLocal(i)
return r.NAux(li)
}
// Returns the "handle" to the j-th aux symbol of the i-th symbol.
func (l *Loader) Aux2(i Sym, j int) Aux2 {
if l.IsExternal(i) {
return Aux2{}
}
r, li := l.toLocal(i)
if j >= r.NAux(li) {
return Aux2{}
}
return Aux2{r.Aux(li, j), r, l}
}
// GetFuncDwarfAuxSyms collects and returns the auxiliary DWARF
// symbols associated with a given function symbol. Prior to the
// introduction of the loader, this was done purely using name
// lookups, e.f. for function with name XYZ we would then look up
// go.info.XYZ, etc.
// FIXME: once all of dwarfgen is converted over to the loader,
// it would save some space to make these aux symbols nameless.
func (l *Loader) GetFuncDwarfAuxSyms(fnSymIdx Sym) (auxDwarfInfo, auxDwarfLoc, auxDwarfRanges, auxDwarfLines Sym) {
if l.SymType(fnSymIdx) != sym.STEXT {
log.Fatalf("error: non-function sym %d/%s t=%s passed to GetFuncDwarfAuxSyms", fnSymIdx, l.SymName(fnSymIdx), l.SymType(fnSymIdx).String())
}
if l.IsExternal(fnSymIdx) {
// Current expectation is that any external function will
// not have auxsyms.
return
}
r, li := l.toLocal(fnSymIdx)
auxs := r.Auxs(li)
for i := range auxs {
a := &auxs[i]
switch a.Type() {
case goobj2.AuxDwarfInfo:
auxDwarfInfo = l.resolve(r, a.Sym())
if l.SymType(auxDwarfInfo) != sym.SDWARFINFO {
panic("aux dwarf info sym with wrong type")
}
case goobj2.AuxDwarfLoc:
auxDwarfLoc = l.resolve(r, a.Sym())
if l.SymType(auxDwarfLoc) != sym.SDWARFLOC {
panic("aux dwarf loc sym with wrong type")
}
case goobj2.AuxDwarfRanges:
auxDwarfRanges = l.resolve(r, a.Sym())
if l.SymType(auxDwarfRanges) != sym.SDWARFRANGE {
panic("aux dwarf ranges sym with wrong type")
}
case goobj2.AuxDwarfLines:
auxDwarfLines = l.resolve(r, a.Sym())
if l.SymType(auxDwarfLines) != sym.SDWARFLINES {
panic("aux dwarf lines sym with wrong type")
}
}
}
return
}
// PrependSub prepends 'sub' onto the sub list for outer symbol 'outer'.
// Will panic if 'sub' already has an outer sym or sub sym.
// FIXME: should this be instead a method on SymbolBuilder?
func (l *Loader) PrependSub(outer Sym, sub Sym) {
// NB: this presupposes that an outer sym can't be a sub symbol of
// some other outer-outer sym (I'm assuming this is true, but I
// haven't tested exhaustively).
if l.OuterSym(outer) != 0 {
panic("outer has outer itself")
}
if l.SubSym(sub) != 0 {
panic("sub set for subsym")
}
if l.OuterSym(sub) != 0 {
panic("outer already set for subsym")
}
l.sub[sub] = l.sub[outer]
l.sub[outer] = sub
l.outer[sub] = outer
}
// OuterSym gets the outer symbol for host object loaded symbols.
func (l *Loader) OuterSym(i Sym) Sym {
// FIXME: add check for isExternal?
return l.outer[i]
}
// SubSym gets the subsymbol for host object loaded symbols.
func (l *Loader) SubSym(i Sym) Sym {
// NB: note -- no check for l.isExternal(), since I am pretty sure
// that later phases in the linker set subsym for "type." syms
return l.sub[i]
}
// SetOuterSym sets the outer symbol of i to o (without setting
// sub symbols).
func (l *Loader) SetOuterSym(i Sym, o Sym) {
if o != 0 {
l.outer[i] = o
} else {
delete(l.outer, i)
}
}
// Initialize Reachable bitmap and its siblings for running deadcode pass.
func (l *Loader) InitReachable() {
l.growAttrBitmaps(l.NSym() + 1)
}
type symWithVal struct {
s Sym
v int64
}
type bySymValue []symWithVal
func (s bySymValue) Len() int { return len(s) }
func (s bySymValue) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
func (s bySymValue) Less(i, j int) bool { return s[i].v < s[j].v }
// SortSub walks through the sub-symbols for 's' and sorts them
// in place by increasing value. Return value is the new
// sub symbol for the specified outer symbol.
func (l *Loader) SortSub(s Sym) Sym {
if s == 0 || l.sub[s] == 0 {
return s
}
// Sort symbols using a slice first. Use a stable sort on the off
// chance that there's more than once symbol with the same value,
// so as to preserve reproducible builds.
sl := []symWithVal{}
for ss := l.sub[s]; ss != 0; ss = l.sub[ss] {
sl = append(sl, symWithVal{s: ss, v: l.SymValue(ss)})
}
sort.Stable(bySymValue(sl))
// Then apply any changes needed to the sub map.
ns := Sym(0)
for i := len(sl) - 1; i >= 0; i-- {
s := sl[i].s
l.sub[s] = ns
ns = s
}
// Update sub for outer symbol, then return
l.sub[s] = sl[0].s
return sl[0].s
}
// Insure that reachable bitmap and its siblings have enough size.
func (l *Loader) growAttrBitmaps(reqLen int) {
if reqLen > l.attrReachable.Len() {
// These are indexed by global symbol
l.attrReachable = growBitmap(reqLen, l.attrReachable)
l.attrOnList = growBitmap(reqLen, l.attrOnList)
l.attrLocal = growBitmap(reqLen, l.attrLocal)
l.attrNotInSymbolTable = growBitmap(reqLen, l.attrNotInSymbolTable)
}
l.growExtAttrBitmaps()
}
func (l *Loader) growExtAttrBitmaps() {
// These are indexed by external symbol index (e.g. l.extIndex(i))
extReqLen := len(l.payloads)
if extReqLen > l.attrVisibilityHidden.Len() {
l.attrVisibilityHidden = growBitmap(extReqLen, l.attrVisibilityHidden)
l.attrDuplicateOK = growBitmap(extReqLen, l.attrDuplicateOK)
l.attrShared = growBitmap(extReqLen, l.attrShared)
l.attrExternal = growBitmap(extReqLen, l.attrExternal)
}
}
func (relocs *Relocs) Count() int { return len(relocs.rs) }
// At2 returns the j-th reloc for a global symbol.
func (relocs *Relocs) At2(j int) Reloc2 {
if relocs.l.isExtReader(relocs.r) {
pp := relocs.l.payloads[relocs.li]
return Reloc2{&relocs.rs[j], relocs.r, relocs.l, pp.reltypes[j]}
}
return Reloc2{&relocs.rs[j], relocs.r, relocs.l, 0}
}
// Relocs returns a Relocs object for the given global sym.
func (l *Loader) Relocs(i Sym) Relocs {
r, li := l.toLocal(i)
if r == nil {
panic(fmt.Sprintf("trying to get oreader for invalid sym %d\n\n", i))
}
return l.relocs(r, li)
}
// Relocs returns a Relocs object given a local sym index and reader.
func (l *Loader) relocs(r *oReader, li int) Relocs {
var rs []goobj2.Reloc
if l.isExtReader(r) {
pp := l.payloads[li]
rs = pp.relocs
} else {
rs = r.Relocs(li)
}
return Relocs{
rs: rs,
li: li,
r: r,
l: l,
}
}
// ExtRelocs returns the external relocations of the i-th symbol.
func (l *Loader) ExtRelocs(i Sym) ExtRelocs {
return ExtRelocs{l.Relocs(i), l.extRelocs[i]}
}
// ExtRelocs represents the set of external relocations of a symbol.
type ExtRelocs struct {
rs Relocs
es []ExtReloc
}
func (ers ExtRelocs) Count() int { return len(ers.es) }
func (ers ExtRelocs) At(j int) ExtRelocView {
i := ers.es[j].Idx
return ExtRelocView{ers.rs.At2(i), &ers.es[j]}
}
// RelocByOff implements sort.Interface for sorting relocations by offset.
type RelocByOff []Reloc
func (x RelocByOff) Len() int { return len(x) }
func (x RelocByOff) Swap(i, j int) { x[i], x[j] = x[j], x[i] }
func (x RelocByOff) Less(i, j int) bool { return x[i].Off < x[j].Off }
// FuncInfo provides hooks to access goobj2.FuncInfo in the objects.
type FuncInfo struct {
l *Loader
r *oReader
data []byte
auxs []goobj2.Aux
lengths goobj2.FuncInfoLengths
}
func (fi *FuncInfo) Valid() bool { return fi.r != nil }
func (fi *FuncInfo) Args() int {
return int((*goobj2.FuncInfo)(nil).ReadArgs(fi.data))
}
func (fi *FuncInfo) Locals() int {
return int((*goobj2.FuncInfo)(nil).ReadLocals(fi.data))
}
func (fi *FuncInfo) Pcsp() []byte {
pcsp, end := (*goobj2.FuncInfo)(nil).ReadPcsp(fi.data)
return fi.r.BytesAt(fi.r.PcdataBase()+pcsp, int(end-pcsp))
}
func (fi *FuncInfo) Pcfile() []byte {
pcf, end := (*goobj2.FuncInfo)(nil).ReadPcfile(fi.data)
return fi.r.BytesAt(fi.r.PcdataBase()+pcf, int(end-pcf))
}
func (fi *FuncInfo) Pcline() []byte {
pcln, end := (*goobj2.FuncInfo)(nil).ReadPcline(fi.data)
return fi.r.BytesAt(fi.r.PcdataBase()+pcln, int(end-pcln))
}
// Preload has to be called prior to invoking the various methods
// below related to pcdata, funcdataoff, files, and inltree nodes.
func (fi *FuncInfo) Preload() {
fi.lengths = (*goobj2.FuncInfo)(nil).ReadFuncInfoLengths(fi.data)
}
func (fi *FuncInfo) Pcinline() []byte {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
pcinl, end := (*goobj2.FuncInfo)(nil).ReadPcinline(fi.data, fi.lengths.PcdataOff)
return fi.r.BytesAt(fi.r.PcdataBase()+pcinl, int(end-pcinl))
}
func (fi *FuncInfo) NumPcdata() uint32 {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
return fi.lengths.NumPcdata
}
func (fi *FuncInfo) Pcdata(k int) []byte {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
pcdat, end := (*goobj2.FuncInfo)(nil).ReadPcdata(fi.data, fi.lengths.PcdataOff, uint32(k))
return fi.r.BytesAt(fi.r.PcdataBase()+pcdat, int(end-pcdat))
}
func (fi *FuncInfo) NumFuncdataoff() uint32 {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
return fi.lengths.NumFuncdataoff
}
func (fi *FuncInfo) Funcdataoff(k int) int64 {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
return (*goobj2.FuncInfo)(nil).ReadFuncdataoff(fi.data, fi.lengths.FuncdataoffOff, uint32(k))
}
func (fi *FuncInfo) Funcdata(syms []Sym) []Sym {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
if int(fi.lengths.NumFuncdataoff) > cap(syms) {
syms = make([]Sym, 0, fi.lengths.NumFuncdataoff)
} else {
syms = syms[:0]
}
for j := range fi.auxs {
a := &fi.auxs[j]
if a.Type() == goobj2.AuxFuncdata {
syms = append(syms, fi.l.resolve(fi.r, a.Sym()))
}
}
return syms
}
func (fi *FuncInfo) NumFile() uint32 {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
return fi.lengths.NumFile
}
func (fi *FuncInfo) File(k int) Sym {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
sr := (*goobj2.FuncInfo)(nil).ReadFile(fi.data, fi.lengths.FileOff, uint32(k))
return fi.l.resolve(fi.r, sr)
}
type InlTreeNode struct {
Parent int32
File Sym
Line int32
Func Sym
ParentPC int32
}
func (fi *FuncInfo) NumInlTree() uint32 {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
return fi.lengths.NumInlTree
}
func (fi *FuncInfo) InlTree(k int) InlTreeNode {
if !fi.lengths.Initialized {
panic("need to call Preload first")
}
node := (*goobj2.FuncInfo)(nil).ReadInlTree(fi.data, fi.lengths.InlTreeOff, uint32(k))
return InlTreeNode{
Parent: node.Parent,
File: fi.l.resolve(fi.r, node.File),
Line: node.Line,
Func: fi.l.resolve(fi.r, node.Func),
ParentPC: node.ParentPC,
}
}
func (l *Loader) FuncInfo(i Sym) FuncInfo {
var r *oReader
var auxs []goobj2.Aux
if l.IsExternal(i) {
pp := l.getPayload(i)
if pp.objidx == 0 {
return FuncInfo{}
}
r = l.objs[pp.objidx].r
auxs = pp.auxs
} else {
var li int
r, li = l.toLocal(i)
auxs = r.Auxs(li)
}
for j := range auxs {
a := &auxs[j]
if a.Type() == goobj2.AuxFuncInfo {
b := r.Data(int(a.Sym().SymIdx))
return FuncInfo{l, r, b, auxs, goobj2.FuncInfoLengths{}}
}
}
return FuncInfo{}
}
// Preload a package: add autolibs, add defined package symbols to the symbol table.
// Does not add non-package symbols yet, which will be done in LoadNonpkgSyms.
// Does not read symbol data.
// Returns the fingerprint of the object.
func (l *Loader) Preload(syms *sym.Symbols, f *bio.Reader, lib *sym.Library, unit *sym.CompilationUnit, length int64) goobj2.FingerprintType {
roObject, readonly, err := f.Slice(uint64(length)) // TODO: no need to map blocks that are for tools only (e.g. RefName)
if err != nil {
log.Fatal("cannot read object file:", err)
}
r := goobj2.NewReaderFromBytes(roObject, readonly)
if r == nil {
if len(roObject) >= 8 && bytes.Equal(roObject[:8], []byte("\x00go114ld")) {
log.Fatalf("found object file %s in old format, but -go115newobj is true\nset -go115newobj consistently in all -gcflags, -asmflags, and -ldflags", f.File().Name())
}
panic("cannot read object file")
}
localSymVersion := syms.IncVersion()
pkgprefix := objabi.PathToPrefix(lib.Pkg) + "."
ndef := r.NSym()
nnonpkgdef := r.NNonpkgdef()
or := &oReader{r, unit, localSymVersion, r.Flags(), pkgprefix, make([]Sym, ndef+nnonpkgdef+r.NNonpkgref()), ndef, uint32(len(l.objs))}
// Autolib
lib.Autolib = append(lib.Autolib, r.Autolib()...)
// DWARF file table
nfile := r.NDwarfFile()
unit.DWARFFileTable = make([]string, nfile)
for i := range unit.DWARFFileTable {
unit.DWARFFileTable[i] = r.DwarfFile(i)
}
l.addObj(lib.Pkg, or)
l.preloadSyms(or, pkgDef)
// The caller expects us consuming all the data
f.MustSeek(length, os.SEEK_CUR)
return r.Fingerprint()
}
// Preload symbols of given kind from an object.
func (l *Loader) preloadSyms(r *oReader, kind int) {
ndef := r.NSym()
nnonpkgdef := r.NNonpkgdef()
var start, end int
switch kind {
case pkgDef:
start = 0
end = ndef
case nonPkgDef:
start = ndef
end = ndef + nnonpkgdef
default:
panic("preloadSyms: bad kind")
}
l.growSyms(len(l.objSyms) + end - start)
l.growAttrBitmaps(len(l.objSyms) + end - start)
for i := start; i < end; i++ {
osym := r.Sym(i)
name := strings.Replace(osym.Name(r.Reader), "\"\".", r.pkgprefix, -1)
v := abiToVer(osym.ABI(), r.version)
dupok := osym.Dupok()
gi, added := l.AddSym(name, v, r, i, kind, dupok, sym.AbiSymKindToSymKind[objabi.SymKind(osym.Type())])
r.syms[i] = gi
if !added {
continue
}
if osym.TopFrame() {
l.SetAttrTopFrame(gi, true)
}
if osym.Local() {
l.SetAttrLocal(gi, true)
}
if strings.HasPrefix(name, "go.itablink.") {
l.itablink[gi] = struct{}{}
}
if strings.HasPrefix(name, "runtime.") {
if bi := goobj2.BuiltinIdx(name, v); bi != -1 {
// This is a definition of a builtin symbol. Record where it is.
l.builtinSyms[bi] = gi
}
}
if strings.HasPrefix(name, "go.string.") ||
strings.HasPrefix(name, "gclocals·") ||
strings.HasPrefix(name, "runtime.gcbits.") {
l.SetAttrNotInSymbolTable(gi, true)
}
if a := osym.Align(); a != 0 {
l.SetSymAlign(gi, int32(a))
}
}
}
// Add non-package symbols and references to external symbols (which are always
// named).
func (l *Loader) LoadNonpkgSyms(arch *sys.Arch) {
for _, o := range l.objs[1:] {
l.preloadSyms(o.r, nonPkgDef)
}
for _, o := range l.objs[1:] {
loadObjRefs(l, o.r, arch)
}
}
func loadObjRefs(l *Loader, r *oReader, arch *sys.Arch) {
ndef := r.NSym() + r.NNonpkgdef()
for i, n := 0, r.NNonpkgref(); i < n; i++ {
osym := r.Sym(ndef + i)
name := strings.Replace(osym.Name(r.Reader), "\"\".", r.pkgprefix, -1)
v := abiToVer(osym.ABI(), r.version)
r.syms[ndef+i] = l.LookupOrCreateSym(name, v)
gi := r.syms[ndef+i]
if osym.Local() {
l.SetAttrLocal(gi, true)
}
l.preprocess(arch, gi, name)
}
}
func abiToVer(abi uint16, localSymVersion int) int {
var v int
if abi == goobj2.SymABIstatic {
// Static
v = localSymVersion
} else if abiver := sym.ABIToVersion(obj.ABI(abi)); abiver != -1 {
// Note that data symbols are "ABI0", which maps to version 0.
v = abiver
} else {
log.Fatalf("invalid symbol ABI: %d", abi)
}
return v
}
// preprocess looks for integer/floating point constant symbols whose
// content is encoded into the symbol name, and promotes them into
// real symbols with RODATA type and a payload that matches the
// encoded content.
func (l *Loader) preprocess(arch *sys.Arch, s Sym, name string) {
if name != "" && name[0] == '$' && len(name) > 5 && l.SymType(s) == 0 && len(l.Data(s)) == 0 {
x, err := strconv.ParseUint(name[5:], 16, 64)
if err != nil {
log.Panicf("failed to parse $-symbol %s: %v", name, err)
}
su := l.MakeSymbolUpdater(s)
su.SetType(sym.SRODATA)
su.SetLocal(true)
switch name[:5] {
case "$f32.":
if uint64(uint32(x)) != x {
log.Panicf("$-symbol %s too large: %d", name, x)
}
su.AddUint32(arch, uint32(x))
case "$f64.", "$i64.":
su.AddUint64(arch, x)
default:
log.Panicf("unrecognized $-symbol: %s", name)
}
}
}
// Load full contents.
func (l *Loader) LoadFull(arch *sys.Arch, syms *sym.Symbols, needReloc, needExtReloc bool) {
// create all Symbols first.
l.growSyms(l.NSym())
l.growSects(l.NSym())
if needReloc && len(l.extRelocs) != 0 {
// If needReloc is true, we are going to convert the loader's
// "internal" relocations to sym.Relocs. In this case, external
// relocations shouldn't be used.
panic("phase error")
}
nr := 0 // total number of sym.Reloc's we'll need
for _, o := range l.objs[1:] {
nr += loadObjSyms(l, syms, o.r, needReloc, needExtReloc)
}
// Make a first pass through the external symbols, making
// sure that each external symbol has a non-nil entry in
// l.Syms (note that relocations and symbol content will
// be copied in a later loop).
toConvert := make([]Sym, 0, len(l.payloads))
for _, i := range l.extReader.syms {
if !l.attrReachable.Has(i) {
continue
}
pp := l.getPayload(i)
if needReloc {
nr += len(pp.relocs)
}
if needExtReloc && int(i) < len(l.extRelocs) {
nr += len(l.extRelocs[i])
}
// create and install the sym.Symbol here so that l.Syms will
// be fully populated when we do relocation processing and
// outer/sub processing below. Note that once we do this,
// we'll need to get at the payload for a symbol with direct
// reference to l.payloads[] as opposed to calling l.getPayload().
s := l.allocSym(pp.name, 0)
l.installSym(i, s)
toConvert = append(toConvert, i)
}
// allocate a single large slab of relocations for all live symbols
if nr != 0 {
l.relocBatch = make([]sym.Reloc, nr)
if needExtReloc {
l.relocExtBatch = make([]sym.RelocExt, nr)
}
}
// convert payload-based external symbols into sym.Symbol-based
for _, i := range toConvert {
// Copy kind/size/value etc.
pp := l.payloads[l.extIndex(i)]
s := l.Syms[i]
s.Version = int16(pp.ver)
s.Type = pp.kind
s.Size = pp.size
// Copy relocations
if needReloc {
batch := l.relocBatch
s.R = batch[:len(pp.relocs):len(pp.relocs)]
l.relocBatch = batch[len(pp.relocs):]
relocs := l.Relocs(i)
l.convertRelocations(i, &relocs, s, false)
}
if needExtReloc {
l.convertExtRelocs(s, i)
}
// Copy data
s.P = pp.data
// Transfer over attributes.
l.migrateAttributes(i, s)
}
// load contents of defined symbols
for _, o := range l.objs[1:] {
loadObjFull(l, o.r, needReloc, needExtReloc)
}
// Sanity check: we should have consumed all batched allocations.
if len(l.relocBatch) != 0 || len(l.relocExtBatch) != 0 {
panic("batch allocation mismatch")
}
// Note: resolution of ABI aliases is now also handled in
// loader.convertRelocations, so once the host object loaders move
// completely to loader.Sym, we can remove the code below.
// Resolve ABI aliases for external symbols. This is only
// needed for internal cgo linking.
if needReloc {
for _, i := range l.extReader.syms {
if s := l.Syms[i]; s != nil && s.Attr.Reachable() {
for ri := range s.R {
r := &s.R[ri]
if r.Sym != nil && r.Sym.Type == sym.SABIALIAS {
r.Sym = r.Sym.R[0].Sym
}
}
}
}
}
// Free some memory.
// At this point we still need basic index mapping, and some fields of
// external symbol payloads, but not much else.
l.values = nil
l.symSects = nil
l.outdata = nil
l.itablink = nil
l.attrOnList = nil
l.attrLocal = nil
l.attrNotInSymbolTable = nil
l.attrVisibilityHidden = nil
l.attrDuplicateOK = nil
l.attrShared = nil
l.attrExternal = nil
l.attrReadOnly = nil
l.attrTopFrame = nil
l.attrSpecial = nil
l.attrCgoExportDynamic = nil
l.attrCgoExportStatic = nil
l.outer = nil
l.align = nil
l.dynimplib = nil
l.dynimpvers = nil
l.localentry = nil
l.extname = nil
l.elfType = nil
l.plt = nil
l.got = nil
l.dynid = nil
if needExtReloc { // converted to sym.Relocs, drop loader references
l.relocVariant = nil
l.extRelocs = nil
}
// Drop fields that are no longer needed.
for _, i := range l.extReader.syms {
pp := l.getPayload(i)
pp.name = ""
pp.auxs = nil
pp.data = nil
if needExtReloc {
pp.relocs = nil
pp.reltypes = nil
}
}
}
// ResolveABIAlias given a symbol returns the ABI alias target of that
// symbol. If the sym in question is not an alias, the sym itself is
// returned.
func (l *Loader) ResolveABIAlias(s Sym) Sym {
if s == 0 {
return 0
}
if l.SymType(s) != sym.SABIALIAS {
return s
}
relocs := l.Relocs(s)
target := relocs.At2(0).Sym()
if l.SymType(target) == sym.SABIALIAS {
panic(fmt.Sprintf("ABI alias %s references another ABI alias %s", l.SymName(s), l.SymName(target)))
}
return target
}
// PropagateSymbolChangesBackToLoader is a temporary shim function
// that copies over a given sym.Symbol into the equivalent representation
// in the loader world. The intent is to enable converting a given
// linker phase/pass from dealing with sym.Symbol's to a modernized
// pass that works with loader.Sym, in cases where the "loader.Sym
// wavefront" has not yet reached the pass in question. For such work
// the recipe is to first call PropagateSymbolChangesBackToLoader(),
// then exexute the pass working with the loader, then call
// PropagateLoaderChangesToSymbols to copy the changes made by the
// pass back to the sym.Symbol world.
func (l *Loader) PropagateSymbolChangesBackToLoader() {
// For the moment we only copy symbol values, and we don't touch
// any new sym.Symbols created since loadlibfull() was run. This
// seems to be what's needed for DWARF gen.
for i := Sym(1); i < Sym(len(l.objSyms)); i++ {
s := l.Syms[i]
if s != nil {
if s.Value != l.SymValue(i) {
l.SetSymValue(i, s.Value)
}
}
}
}
// PropagateLoaderChangesToSymbols is a temporary shim function that
// takes a list of loader.Sym symbols and works to copy their contents
// and attributes over to a corresponding sym.Symbol. The parameter
// anonVerReplacement specifies a version number for any new anonymous
// symbols encountered on the list, when creating sym.Symbols for them
// (or zero if we don't expect to encounter any new anon symbols). See
// the PropagateSymbolChangesBackToLoader header comment for more
// info.
//
// WARNING: this function is brittle and depends heavily on loader
// implementation. A key problem with doing this is that as things
// stand at the moment, some sym.Symbol contents/attributes are
// populated only when converting from loader.Sym to sym.Symbol in
// loadlibfull, meaning we may wipe out some information when copying
// back.
func (l *Loader) PropagateLoaderChangesToSymbols(toconvert []Sym, anonVerReplacement int) []*sym.Symbol {
result := []*sym.Symbol{}
relocfixup := []Sym{}
// Note: this loop needs to allow for the possibility that we may
// see "new" symbols on the 'toconvert' list that come from object
// files (for example, DWARF location lists), as opposed to just
// newly manufactured symbols (ex: DWARF section symbols such as
// ".debug_info"). This means that we have to be careful not to
// stomp on sym.Symbol attributes/content that was set up in
// in loadlibfull().
// Also note that in order for the relocation fixup to work, we
// have to do this in two passes -- one pass to create the symbols,
// and then a second fix up the relocations once all necessary
// sym.Symbols are created.
// First pass, symbol creation and symbol data fixup.
for _, cand := range toconvert {
sn := l.SymName(cand)
sv := l.SymVersion(cand)
st := l.SymType(cand)
if sv < 0 {
if anonVerReplacement == 0 {
panic("expected valid anon version replacement")
}
sv = anonVerReplacement
}
s := l.Syms[cand]
isnew := false
if sn == "" {
// Don't install anonymous symbols in the lookup tab.
if s == nil {
s = l.allocSym(sn, sv)
l.installSym(cand, s)
}
isnew = true
} else {
if s != nil {
// Already have a symbol for this -- it must be
// something that was previously processed by
// loadObjFull. Note that the symbol in question may
// or may not be in the name lookup map.
} else {
isnew = true
s = l.SymLookup(sn, sv)
}
}
result = append(result, s)
// Always copy these from new to old.
s.Value = l.SymValue(cand)
s.Type = st
// If the data for a symbol has increased in size, make sure
// we bring the new content across.
relfix := isnew
if isnew || len(l.Data(cand)) > len(s.P) {
s.P = l.Data(cand)
s.Size = int64(len(s.P))
relfix = true
}
// For 'new' symbols, copy other content.
if relfix {
relocfixup = append(relocfixup, cand)
}
// If new symbol, call a helper to migrate attributes.
// Otherwise touch only not-in-symbol-table, since there are
// some attrs that are only set up at the point where we
// convert loader.Sym to sym.Symbol.
if isnew {
l.migrateAttributes(cand, s)
} else {
if l.AttrNotInSymbolTable(cand) {
s.Attr.Set(sym.AttrNotInSymbolTable, true)
}
}
}
// Second pass to fix up relocations.
for _, cand := range relocfixup {
s := l.Syms[cand]
relocs := l.Relocs(cand)
if len(s.R) != relocs.Count() {
s.R = make([]sym.Reloc, relocs.Count())
}
l.convertRelocations(cand, &relocs, s, true)
}
return result
}
// ExtractSymbols grabs the symbols out of the loader for work that hasn't been
// ported to the new symbol type.
func (l *Loader) ExtractSymbols(syms *sym.Symbols) {
// Add symbols to the ctxt.Syms lookup table. This explicitly skips things
// created via loader.Create (marked with versions less than zero), since
// if we tried to add these we'd wind up with collisions. We do, however,
// add these symbols to the list of global symbols so that other future
// steps (like pclntab generation) can find these symbols if neceassary.
// Along the way, update the version from the negative anon version to
// something larger than sym.SymVerStatic (needed so that
// sym.symbol.IsFileLocal() works properly).
anonVerReplacement := syms.IncVersion()
for _, s := range l.Syms {
if s == nil {
continue
}
if s.Version < 0 {
s.Version = int16(anonVerReplacement)
}
}
// Provide lookup functions for sym.Symbols.
l.SymLookup = func(name string, ver int) *sym.Symbol {
i := l.LookupOrCreateSym(name, ver)
if s := l.Syms[i]; s != nil {
return s
}
s := l.allocSym(name, ver)
l.installSym(i, s)
return s
}
syms.Lookup = l.SymLookup
syms.ROLookup = func(name string, ver int) *sym.Symbol {
i := l.Lookup(name, ver)
return l.Syms[i]
}
}
// allocSym allocates a new symbol backing.
func (l *Loader) allocSym(name string, version int) *sym.Symbol {
batch := l.symBatch
if len(batch) == 0 {
batch = make([]sym.Symbol, 1000)
}
s := &batch[0]
l.symBatch = batch[1:]
s.Dynid = -1
s.Name = name
s.Version = int16(version)
return s
}
// installSym sets the underlying sym.Symbol for the specified sym index.
func (l *Loader) installSym(i Sym, s *sym.Symbol) {
if s == nil {
panic("installSym nil symbol")
}
if l.Syms[i] != nil {
panic("sym already present in installSym")
}
l.Syms[i] = s
s.SymIdx = sym.LoaderSym(i)
}
// addNewSym adds a new sym.Symbol to the i-th index in the list of symbols.
func (l *Loader) addNewSym(i Sym, name string, ver int, unit *sym.CompilationUnit, t sym.SymKind) *sym.Symbol {
s := l.allocSym(name, ver)
if s.Type != 0 && s.Type != sym.SXREF {
fmt.Println("symbol already processed:", unit.Lib, i, s)
panic("symbol already processed")
}
if t == sym.SBSS && (s.Type == sym.SRODATA || s.Type == sym.SNOPTRBSS) {
t = s.Type
}
s.Type = t
l.growSyms(int(i))
l.installSym(i, s)
return s
}
// TopLevelSym tests a symbol (by name and kind) to determine whether
// the symbol first class sym (participating in the link) or is an
// anonymous aux or sub-symbol containing some sub-part or payload of
// another symbol.
func (l *Loader) TopLevelSym(s Sym) bool {
return topLevelSym(l.RawSymName(s), l.SymType(s))
}
// topLevelSym tests a symbol name and kind to determine whether
// the symbol first class sym (participating in the link) or is an
// anonymous aux or sub-symbol containing some sub-part or payload of
// another symbol.
func topLevelSym(sname string, skind sym.SymKind) bool {
if sname != "" {
return true
}
switch skind {
case sym.SDWARFINFO, sym.SDWARFRANGE, sym.SDWARFLOC, sym.SDWARFLINES, sym.SGOFUNC:
return true
default:
return false
}
}
// loadObjSyms creates sym.Symbol objects for the live Syms in the
// object corresponding to object reader "r". Return value is the
// number of sym.Reloc entries required for all the new symbols.
func loadObjSyms(l *Loader, syms *sym.Symbols, r *oReader, needReloc, needExtReloc bool) int {
nr := 0
for i, n := 0, r.NSym()+r.NNonpkgdef(); i < n; i++ {
gi := r.syms[i]
if r2, i2 := l.toLocal(gi); r2 != r || i2 != i {
continue // come from a different object
}
osym := r.Sym(i)
name := strings.Replace(osym.Name(r.Reader), "\"\".", r.pkgprefix, -1)
t := sym.AbiSymKindToSymKind[objabi.SymKind(osym.Type())]
// Skip non-dwarf anonymous symbols (e.g. funcdata),
// since they will never be turned into sym.Symbols.
if !topLevelSym(name, t) {
continue
}
ver := abiToVer(osym.ABI(), r.version)
if t == sym.SXREF {
log.Fatalf("bad sxref")
}
if t == 0 {
log.Fatalf("missing type for %s in %s", name, r.unit.Lib)
}
if !l.attrReachable.Has(gi) && name != "runtime.addmoduledata" && name != "runtime.lastmoduledatap" {
// No need to load unreachable symbols.
// XXX reference to runtime.addmoduledata may be generated later by the linker in plugin mode.
continue
}
l.addNewSym(gi, name, ver, r.unit, t)
if needReloc {
nr += r.NReloc(i)
}
if needExtReloc && int(gi) < len(l.extRelocs) {
nr += len(l.extRelocs[gi])
}
}
return nr
}
// cloneToExternal takes the existing object file symbol (symIdx)
// and creates a new external symbol payload that is a clone with
// respect to name, version, type, relocations, etc. The idea here
// is that if the linker decides it wants to update the contents of
// a symbol originally discovered as part of an object file, it's
// easier to do this if we make the updates to an external symbol
// payload.
// XXX maybe rename? makeExtPayload?
func (l *Loader) cloneToExternal(symIdx Sym) {
if l.IsExternal(symIdx) {
panic("sym is already external, no need for clone")
}
l.growSyms(int(symIdx))
// Read the particulars from object.
r, li := l.toLocal(symIdx)
osym := r.Sym(li)
sname := strings.Replace(osym.Name(r.Reader), "\"\".", r.pkgprefix, -1)
sver := abiToVer(osym.ABI(), r.version)
skind := sym.AbiSymKindToSymKind[objabi.SymKind(osym.Type())]
// Create new symbol, update version and kind.
pi := l.newPayload(sname, sver)
pp := l.payloads[pi]
pp.kind = skind
pp.ver = sver
pp.size = int64(osym.Siz())
pp.objidx = r.objidx
// If this is a def, then copy the guts. We expect this case
// to be very rare (one case it may come up is with -X).
if li < (r.NSym() + r.NNonpkgdef()) {
// Copy relocations
relocs := l.Relocs(symIdx)
pp.relocs = make([]goobj2.Reloc, relocs.Count())
pp.reltypes = make([]objabi.RelocType, relocs.Count())
for i := range pp.relocs {
// Copy the relocs slice.
// Convert local reference to global reference.
rel := relocs.At2(i)
pp.relocs[i].Set(rel.Off(), rel.Siz(), 0, rel.Add(), goobj2.SymRef{PkgIdx: 0, SymIdx: uint32(rel.Sym())})
pp.reltypes[i] = rel.Type()
}
// Copy data
pp.data = r.Data(li)
}
// If we're overriding a data symbol, collect the associated
// Gotype, so as to propagate it to the new symbol.
auxs := r.Auxs(li)
pp.auxs = auxs
loop:
for j := range auxs {
a := &auxs[j]
switch a.Type() {
case goobj2.AuxGotype:
pp.gotype = l.resolve(r, a.Sym())
break loop
default:
// nothing to do
}
}
// Install new payload to global index space.
// (This needs to happen at the end, as the accessors above
// need to access the old symbol content.)
l.objSyms[symIdx] = objSym{l.extReader, pi}
l.extReader.syms = append(l.extReader.syms, symIdx)
}
// Copy the payload of symbol src to dst. Both src and dst must be external
// symbols.
// The intended use case is that when building/linking against a shared library,
// where we do symbol name mangling, the Go object file may have reference to
// the original symbol name whereas the shared library provides a symbol with
// the mangled name. When we do mangling, we copy payload of mangled to original.
func (l *Loader) CopySym(src, dst Sym) {
if !l.IsExternal(dst) {
panic("dst is not external") //l.newExtSym(l.SymName(dst), l.SymVersion(dst))
}
if !l.IsExternal(src) {
panic("src is not external") //l.cloneToExternal(src)
}
l.payloads[l.extIndex(dst)] = l.payloads[l.extIndex(src)]
l.SetSymPkg(dst, l.SymPkg(src))
// TODO: other attributes?
}
// CopyAttributes copies over all of the attributes of symbol 'src' to
// symbol 'dst'.
func (l *Loader) CopyAttributes(src Sym, dst Sym) {
l.SetAttrReachable(dst, l.AttrReachable(src))
l.SetAttrOnList(dst, l.AttrOnList(src))
l.SetAttrLocal(dst, l.AttrLocal(src))
l.SetAttrNotInSymbolTable(dst, l.AttrNotInSymbolTable(src))
if l.IsExternal(dst) {
l.SetAttrVisibilityHidden(dst, l.AttrVisibilityHidden(src))
l.SetAttrDuplicateOK(dst, l.AttrDuplicateOK(src))
l.SetAttrShared(dst, l.AttrShared(src))
l.SetAttrExternal(dst, l.AttrExternal(src))
} else {
// Some attributes are modifiable only for external symbols.
// In such cases, don't try to transfer over the attribute
// from the source even if there is a clash. This comes up
// when copying attributes from a dupOK ABI wrapper symbol to
// the real target symbol (which may not be marked dupOK).
}
l.SetAttrTopFrame(dst, l.AttrTopFrame(src))
l.SetAttrSpecial(dst, l.AttrSpecial(src))
l.SetAttrCgoExportDynamic(dst, l.AttrCgoExportDynamic(src))
l.SetAttrCgoExportStatic(dst, l.AttrCgoExportStatic(src))
l.SetAttrReadOnly(dst, l.AttrReadOnly(src))
}
// migrateAttributes copies over all of the attributes of symbol 'src' to
// sym.Symbol 'dst'.
func (l *Loader) migrateAttributes(src Sym, dst *sym.Symbol) {
dst.Value = l.SymValue(src)
dst.Align = l.SymAlign(src)
dst.Sect = l.SymSect(src)
dst.Attr.Set(sym.AttrReachable, l.AttrReachable(src))
dst.Attr.Set(sym.AttrOnList, l.AttrOnList(src))
dst.Attr.Set(sym.AttrLocal, l.AttrLocal(src))
dst.Attr.Set(sym.AttrNotInSymbolTable, l.AttrNotInSymbolTable(src))
dst.Attr.Set(sym.AttrNoSplit, l.IsNoSplit(src))
dst.Attr.Set(sym.AttrVisibilityHidden, l.AttrVisibilityHidden(src))
dst.Attr.Set(sym.AttrDuplicateOK, l.AttrDuplicateOK(src))
dst.Attr.Set(sym.AttrShared, l.AttrShared(src))
dst.Attr.Set(sym.AttrExternal, l.AttrExternal(src))
dst.Attr.Set(sym.AttrTopFrame, l.AttrTopFrame(src))
dst.Attr.Set(sym.AttrSpecial, l.AttrSpecial(src))
dst.Attr.Set(sym.AttrCgoExportDynamic, l.AttrCgoExportDynamic(src))
dst.Attr.Set(sym.AttrCgoExportStatic, l.AttrCgoExportStatic(src))
dst.Attr.Set(sym.AttrReadOnly, l.AttrReadOnly(src))
// Convert outer relationship
if outer, ok := l.outer[src]; ok {
dst.Outer = l.Syms[outer]
}
// Set sub-symbol attribute. See the comment on the AttrSubSymbol
// method for more on this, there is some tricky stuff here.
dst.Attr.Set(sym.AttrSubSymbol, l.outer[src] != 0 && l.sub[l.outer[src]] != 0)
// Copy over dynimplib, dynimpvers, extname.
if name, ok := l.extname[src]; ok {
dst.SetExtname(name)
}
if l.SymDynimplib(src) != "" {
dst.SetDynimplib(l.SymDynimplib(src))
}
if l.SymDynimpvers(src) != "" {
dst.SetDynimpvers(l.SymDynimpvers(src))
}
// Copy ELF type if set.
if et, ok := l.elfType[src]; ok {
dst.SetElfType(et)
}
// Copy pe objects values if set.
if plt, ok := l.plt[src]; ok {
dst.SetPlt(plt)
}
if got, ok := l.got[src]; ok {
dst.SetGot(got)
}
// Copy dynid
if dynid, ok := l.dynid[src]; ok {
dst.Dynid = dynid
}
}
// CreateExtSym creates a new external symbol with the specified name
// without adding it to any lookup tables, returning a Sym index for it.
func (l *Loader) CreateExtSym(name string, ver int) Sym {
return l.newExtSym(name, ver)
}
// CreateStaticSym creates a new static symbol with the specified name
// without adding it to any lookup tables, returning a Sym index for it.
func (l *Loader) CreateStaticSym(name string) Sym {
// Assign a new unique negative version -- this is to mark the
// symbol so that it can be skipped when ExtractSymbols is adding
// ext syms to the sym.Symbols hash.
l.anonVersion--
return l.newExtSym(name, l.anonVersion)
}
func (l *Loader) FreeSym(i Sym) {
if l.IsExternal(i) {
pp := l.getPayload(i)
*pp = extSymPayload{}
}
}
func loadObjFull(l *Loader, r *oReader, needReloc, needExtReloc bool) {
for i, n := 0, r.NSym()+r.NNonpkgdef(); i < n; i++ {
// A symbol may be a dup or overwritten. In this case, its
// content will actually be provided by a different object
// (to which its global index points). Skip those symbols.
gi := l.toGlobal(r, i)
if r2, i2 := l.toLocal(gi); r2 != r || i2 != i {
continue
}
s := l.Syms[gi]
if s == nil {
continue
}
l.migrateAttributes(gi, s)
// Be careful not to overwrite attributes set by the linker.
// Don't use the attributes from the object file.
osym := r.Sym(i)
size := osym.Siz()
// Symbol data
s.P = l.OutData(gi)
// Relocs
if needReloc {
relocs := l.relocs(r, i)
batch := l.relocBatch
s.R = batch[:relocs.Count():relocs.Count()]
l.relocBatch = batch[relocs.Count():]
l.convertRelocations(gi, &relocs, s, false)
}
if needExtReloc {
l.convertExtRelocs(s, gi)
}
// Aux symbol info
auxs := r.Auxs(i)
for j := range auxs {
a := &auxs[j]
switch a.Type() {
case goobj2.AuxFuncInfo, goobj2.AuxFuncdata, goobj2.AuxGotype:
// already handled
case goobj2.AuxDwarfInfo, goobj2.AuxDwarfLoc, goobj2.AuxDwarfRanges, goobj2.AuxDwarfLines:
// ignored for now
default:
panic("unknown aux type")
}
}
if s.Size < int64(size) {
s.Size = int64(size)
}
}
}
// convertRelocations takes a vector of loader.Reloc relocations and
// translates them into an equivalent set of sym.Reloc relocations on
// the symbol "dst", performing fixups along the way for ABI aliases,
// etc. It is assumed that the caller has pre-allocated the dst symbol
// relocations slice. If 'strict' is set, then this method will
// panic if it finds a relocation targeting a nil symbol.
func (l *Loader) convertRelocations(symIdx Sym, src *Relocs, dst *sym.Symbol, strict bool) {
for j := range dst.R {
r := src.At2(j)
rs := r.Sym()
sz := r.Siz()
rt := r.Type()
if rt == objabi.R_METHODOFF {
if l.attrReachable.Has(rs) {
rt = objabi.R_ADDROFF
} else {
sz = 0
rs = 0
}
}
if rt == objabi.R_WEAKADDROFF && !l.attrReachable.Has(rs) {
rs = 0
sz = 0
}
if rs != 0 && l.Syms[rs] != nil && l.Syms[rs].Type == sym.SABIALIAS {
rsrelocs := l.Relocs(rs)
rs = rsrelocs.At2(0).Sym()
}
if strict && rs != 0 && l.Syms[rs] == nil && rt != objabi.R_USETYPE {
panic("nil reloc target in convertRelocations")
}
dst.R[j] = sym.Reloc{
Off: r.Off(),
Siz: sz,
Type: rt,
Add: r.Add(),
Sym: l.Syms[rs],
}
if rv := l.RelocVariant(symIdx, j); rv != 0 {
dst.R[j].InitExt()
dst.R[j].Variant = rv
}
}
}
// Convert external relocations to sym.Relocs on symbol dst.
func (l *Loader) convertExtRelocs(dst *sym.Symbol, src Sym) {
if int(src) >= len(l.extRelocs) {
return
}
extRelocs := l.extRelocs[src]
if len(extRelocs) == 0 {
return
}
if len(dst.R) != 0 {
panic("bad")
}
n := len(extRelocs)
batch := l.relocBatch
dst.R = batch[:n:n]
l.relocBatch = batch[n:]
relocs := l.Relocs(src)
for i := range dst.R {
er := &extRelocs[i]
sr := relocs.At2(er.Idx)
r := &dst.R[i]
r.RelocExt = &l.relocExtBatch[0]
l.relocExtBatch = l.relocExtBatch[1:]
r.Off = sr.Off()
r.Siz = sr.Siz()
r.Type = sr.Type()
r.Sym = l.Syms[l.ResolveABIAlias(sr.Sym())]
r.Add = sr.Add()
r.Xsym = l.Syms[er.Xsym]
r.Xadd = er.Xadd
if rv := l.RelocVariant(src, er.Idx); rv != 0 {
r.Variant = rv
}
}
}
// relocId is essentially a <S,R> tuple identifying the Rth
// relocation of symbol S.
type relocId struct {
sym Sym
ridx int
}
// SetRelocVariant sets the 'variant' property of a relocation on
// some specific symbol.
func (l *Loader) SetRelocVariant(s Sym, ri int, v sym.RelocVariant) {
// sanity check
if relocs := l.Relocs(s); ri >= relocs.Count() {
panic("invalid relocation ID")
}
if l.relocVariant == nil {
l.relocVariant = make(map[relocId]sym.RelocVariant)
}
if v != 0 {
l.relocVariant[relocId{s, ri}] = v
} else {
delete(l.relocVariant, relocId{s, ri})
}
}
// RelocVariant returns the 'variant' property of a relocation on
// some specific symbol.
func (l *Loader) RelocVariant(s Sym, ri int) sym.RelocVariant {
return l.relocVariant[relocId{s, ri}]
}
// UndefinedRelocTargets iterates through the global symbol index
// space, looking for symbols with relocations targeting undefined
// references. The linker's loadlib method uses this to determine if
// there are unresolved references to functions in system libraries
// (for example, libgcc.a), presumably due to CGO code. Return
// value is a list of loader.Sym's corresponding to the undefined
// cross-refs. The "limit" param controls the maximum number of
// results returned; if "limit" is -1, then all undefs are returned.
func (l *Loader) UndefinedRelocTargets(limit int) []Sym {
result := []Sym{}
for si := Sym(1); si < Sym(len(l.objSyms)); si++ {
relocs := l.Relocs(si)
for ri := 0; ri < relocs.Count(); ri++ {
r := relocs.At2(ri)
rs := r.Sym()
if rs != 0 && l.SymType(rs) == sym.SXREF && l.RawSymName(rs) != ".got" {
result = append(result, rs)
if limit != -1 && len(result) >= limit {
break
}
}
}
}
return result
}
// AssignTextSymbolOrder populates the Textp2 slices within each
// library and compilation unit, insuring that packages are laid down
// in dependency order (internal first, then everything else). Return value
// is a slice of all text syms.
func (l *Loader) AssignTextSymbolOrder(libs []*sym.Library, intlibs []bool, extsyms []Sym) []Sym {
// Library Textp2 lists should be empty at this point.
for _, lib := range libs {
if len(lib.Textp2) != 0 {
panic("expected empty Textp2 slice for library")
}
if len(lib.DupTextSyms2) != 0 {
panic("expected empty DupTextSyms2 slice for library")
}
}
// Used to record which dupok symbol we've assigned to a unit.
// Can't use the onlist attribute here because it will need to
// clear for the later assignment of the sym.Symbol to a unit.
// NB: we can convert to using onList once we no longer have to
// call the regular addToTextp.
assignedToUnit := MakeBitmap(l.NSym() + 1)
// Start off textp2 with reachable external syms.
textp2 := []Sym{}
for _, sym := range extsyms {
if !l.attrReachable.Has(sym) {
continue
}
textp2 = append(textp2, sym)
}
// Walk through all text symbols from Go object files and append
// them to their corresponding library's textp2 list.
for _, o := range l.objs[1:] {
r := o.r
lib := r.unit.Lib
for i, n := 0, r.NSym()+r.NNonpkgdef(); i < n; i++ {
gi := l.toGlobal(r, i)
if !l.attrReachable.Has(gi) {
continue
}
osym := r.Sym(i)
st := sym.AbiSymKindToSymKind[objabi.SymKind(osym.Type())]
if st != sym.STEXT {
continue
}
dupok := osym.Dupok()
if r2, i2 := l.toLocal(gi); r2 != r || i2 != i {
// A dupok text symbol is resolved to another package.
// We still need to record its presence in the current
// package, as the trampoline pass expects packages
// are laid out in dependency order.
lib.DupTextSyms2 = append(lib.DupTextSyms2, sym.LoaderSym(gi))
continue // symbol in different object
}
if dupok {
lib.DupTextSyms2 = append(lib.DupTextSyms2, sym.LoaderSym(gi))
continue
}
lib.Textp2 = append(lib.Textp2, sym.LoaderSym(gi))
}
}
// Now assemble global textp, and assign text symbols to units.
for _, doInternal := range [2]bool{true, false} {
for idx, lib := range libs {
if intlibs[idx] != doInternal {
continue
}
lists := [2][]sym.LoaderSym{lib.Textp2, lib.DupTextSyms2}
for i, list := range lists {
for _, s := range list {
sym := Sym(s)
if l.attrReachable.Has(sym) && !assignedToUnit.Has(sym) {
textp2 = append(textp2, sym)
unit := l.SymUnit(sym)
if unit != nil {
unit.Textp2 = append(unit.Textp2, s)
assignedToUnit.Set(sym)
}
// Dupok symbols may be defined in multiple packages; the
// associated package for a dupok sym is chosen sort of
// arbitrarily (the first containing package that the linker
// loads). Canonicalizes its Pkg to the package with which
// it will be laid down in text.
if i == 1 /* DupTextSyms2 */ && l.SymPkg(sym) != lib.Pkg {
l.SetSymPkg(sym, lib.Pkg)
}
}
}
}
lib.Textp2 = nil
lib.DupTextSyms2 = nil
}
}
return textp2
}
// ErrorReporter is a helper class for reporting errors.
type ErrorReporter struct {
ldr *Loader
AfterErrorAction func()
}
// Errorf method logs an error message.
//
// After each error, the error actions function will be invoked; this
// will either terminate the link immediately (if -h option given)
// or it will keep a count and exit if more than 20 errors have been printed.
//
// Logging an error means that on exit cmd/link will delete any
// output file and return a non-zero error code.
//
func (reporter *ErrorReporter) Errorf(s Sym, format string, args ...interface{}) {
if s != 0 && reporter.ldr.SymName(s) != "" {
format = reporter.ldr.SymName(s) + ": " + format
} else {
format = fmt.Sprintf("sym %d: %s", s, format)
}
format += "\n"
fmt.Fprintf(os.Stderr, format, args...)
reporter.AfterErrorAction()
}
// GetErrorReporter returns the loader's associated error reporter.
func (l *Loader) GetErrorReporter() *ErrorReporter {
return l.errorReporter
}
// Errorf method logs an error message. See ErrorReporter.Errorf for details.
func (l *Loader) Errorf(s Sym, format string, args ...interface{}) {
l.errorReporter.Errorf(s, format, args...)
}
// For debugging.
func (l *Loader) Dump() {
fmt.Println("objs")
for _, obj := range l.objs {
if obj.r != nil {
fmt.Println(obj.i, obj.r.unit.Lib)
}
}
fmt.Println("extStart:", l.extStart)
fmt.Println("Nsyms:", len(l.objSyms))
fmt.Println("syms")
for i := Sym(1); i < Sym(len(l.objSyms)); i++ {
pi := interface{}("")
if l.IsExternal(i) {
pi = fmt.Sprintf("<ext %d>", l.extIndex(i))
}
var s *sym.Symbol
if int(i) < len(l.Syms) {
s = l.Syms[i]
}
if s != nil {
fmt.Println(i, s, s.Type, pi)
} else {
fmt.Println(i, l.SymName(i), "<not loaded>", pi)
}
}
fmt.Println("symsByName")
for name, i := range l.symsByName[0] {
fmt.Println(i, name, 0)
}
for name, i := range l.symsByName[1] {
fmt.Println(i, name, 1)
}
fmt.Println("payloads:")
for i := range l.payloads {
pp := l.payloads[i]
fmt.Println(i, pp.name, pp.ver, pp.kind)
}
}