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4e7b689e1a
delve/pkg/proc/bininfo.go
aarzilli 4e7b689e1a proc: rewrite FindFileLocation to support generics 
With generics a single function can have multiple concrete
instantiations, the old version of FindFileLocation supported at most
one concrete instantiation per function and any number of inlined
calls, this supports any number of inlined calls and concrete
functions.
2021-10-02 15:44:30 +02:00

2341 lines
70 KiB
Go
Raw Blame History

package proc
import (
"bytes"
"debug/dwarf"
"debug/elf"
"debug/macho"
"debug/pe"
"encoding/binary"
"encoding/hex"
"errors"
"fmt"
"go/ast"
"go/token"
"io"
"os"
"os/exec"
"path/filepath"
"sort"
"strconv"
"strings"
"sync"
"time"
"github.com/go-delve/delve/pkg/dwarf/frame"
"github.com/go-delve/delve/pkg/dwarf/godwarf"
"github.com/go-delve/delve/pkg/dwarf/line"
"github.com/go-delve/delve/pkg/dwarf/loclist"
"github.com/go-delve/delve/pkg/dwarf/op"
"github.com/go-delve/delve/pkg/dwarf/reader"
"github.com/go-delve/delve/pkg/dwarf/util"
"github.com/go-delve/delve/pkg/goversion"
"github.com/go-delve/delve/pkg/logflags"
"github.com/hashicorp/golang-lru/simplelru"
"github.com/sirupsen/logrus"
)
const (
dwarfGoLanguage = 22 // DW_LANG_Go (from DWARF v5, section 7.12, page 231)
dwarfAttrAddrBase = 0x74 // debug/dwarf.AttrAddrBase in Go 1.14, defined here for compatibility with Go < 1.14
dwarfTreeCacheSize = 512 // size of the dwarfTree cache of each image
)
// BinaryInfo holds information on the binaries being executed (this
// includes both the executable and also any loaded libraries).
type BinaryInfo struct {
// Architecture of this binary.
Arch *Arch
// GOOS operating system this binary is executing on.
GOOS string
debugInfoDirectories []string
// Functions is a list of all DW_TAG_subprogram entries in debug_info, sorted by entry point
Functions []Function
// Sources is a list of all source files found in debug_line.
Sources []string
// LookupFunc maps function names to a description of the function.
LookupFunc map[string]*Function
// SymNames maps addr to a description *elf.Symbol of this addr.
SymNames map[uint64]*elf.Symbol
// Images is a list of loaded shared libraries (also known as
// shared objects on linux or DLLs on windows).
Images []*Image
ElfDynamicSection ElfDynamicSection
lastModified time.Time // Time the executable of this process was last modified
// PackageMap maps package names to package paths, needed to lookup types inside DWARF info.
// On Go1.12 this mapping is determined by using the last element of a package path, for example:
// github.com/go-delve/delve
// will map to 'delve' because it ends in '/delve'.
// Starting with Go1.13 debug_info will contain a special attribute
// (godwarf.AttrGoPackageName) containing the canonical package name for
// each package.
// If multiple packages have the same name the map entry will have more
// than one item in the slice.
PackageMap map[string][]string
frameEntries frame.FrameDescriptionEntries
types map[string]dwarfRef
packageVars []packageVar // packageVars is a list of all global/package variables in debug_info, sorted by address
gStructOffset uint64
// nameOfRuntimeType maps an address of a runtime._type struct to its
// decoded name. Used with versions of Go <= 1.10 to figure out the DIE of
// the concrete type of interfaces.
nameOfRuntimeType map[uint64]nameOfRuntimeTypeEntry
// consts[off] lists all the constants with the type defined at offset off.
consts constantsMap
// inlinedCallLines maps a file:line pair, corresponding to the header line
// of a function to a list of PC addresses where an inlined call to that
// function starts.
inlinedCallLines map[fileLine][]uint64
// dwrapUnwrapCache caches unwrapping of defer wrapper functions (dwrap)
dwrapUnwrapCache map[uint64]*Function
// Go 1.17 register ABI is enabled.
regabi bool
logger *logrus.Entry
}
var (
// ErrCouldNotDetermineRelocation is an error returned when Delve could not determine the base address of a
// position independent executable.
ErrCouldNotDetermineRelocation = errors.New("could not determine the base address of a PIE")
// ErrNoDebugInfoFound is returned when Delve cannot open the debug_info
// section or find an external debug info file.
ErrNoDebugInfoFound = errors.New("could not open debug info")
)
var (
supportedLinuxArch = map[elf.Machine]bool{
elf.EM_X86_64: true,
elf.EM_AARCH64: true,
elf.EM_386: true,
}
supportedWindowsArch = map[_PEMachine]bool{
_IMAGE_FILE_MACHINE_AMD64: true,
}
supportedDarwinArch = map[macho.Cpu]bool{
macho.CpuAmd64: true,
macho.CpuArm64: true,
}
)
// ErrFunctionNotFound is returned when failing to find the
// function named 'FuncName' within the binary.
type ErrFunctionNotFound struct {
FuncName string
}
func (err *ErrFunctionNotFound) Error() string {
return fmt.Sprintf("could not find function %s\n", err.FuncName)
}
// FindFileLocation returns the PC for a given file:line.
// Assumes that `file` is normalized to lower case and '/' on Windows.
func FindFileLocation(p Process, filename string, lineno int) ([]uint64, error) {
// A single file:line can appear in multiple concrete functions, because of
// generics instantiation as well as multiple inlined calls into other
// concrete functions.
// 1. Find all instructions assigned in debug_line to filename:lineno.
bi := p.BinInfo()
fileFound := false
pcs := []line.PCStmt{}
for _, image := range bi.Images {
for _, cu := range image.compileUnits {
if cu.lineInfo == nil || cu.lineInfo.Lookup[filename] == nil {
continue
}
fileFound = true
pcs = append(pcs, cu.lineInfo.LineToPCs(filename, lineno)...)
}
}
if len(pcs) == 0 {
// Check if the line contained a call to a function that was inlined, in
// that case it's possible for the line itself to not appear in debug_line
// at all, but it will still be in debug_info as the call site for an
// inlined subroutine entry.
for _, pc := range bi.inlinedCallLines[fileLine{filename, lineno}] {
pcs = append(pcs, line.PCStmt{PC: pc, Stmt: true})
}
}
if len(pcs) == 0 {
return nil, &ErrCouldNotFindLine{fileFound, filename, lineno}
}
// 2. assign all occurences of filename:lineno to their containing function
pcByFunc := map[*Function][]line.PCStmt{}
sort.Slice(pcs, func(i, j int) bool { return pcs[i].PC < pcs[j].PC })
var fn *Function
for _, pcstmt := range pcs {
if fn == nil || (pcstmt.PC < fn.Entry) || (pcstmt.PC >= fn.End) {
fn = p.BinInfo().PCToFunc(pcstmt.PC)
}
if fn != nil {
pcByFunc[fn] = append(pcByFunc[fn], pcstmt)
}
}
selectedPCs := []uint64{}
for fn, pcs := range pcByFunc {
// 3. for each concrete function split instruction between the inlined functions it contains
if strings.Contains(fn.Name, "·dwrap·") || fn.trampoline {
// skip autogenerated functions
continue
}
dwtree, err := fn.cu.image.getDwarfTree(fn.offset)
if err != nil {
return nil, fmt.Errorf("loading DWARF for %s@%#x: %v", fn.Name, fn.offset, err)
}
inlrngs := allInlineCallRanges(dwtree)
// findInlRng returns the DWARF offset of the inlined call containing pc.
// If multiple nested inlined calls contain pc the deepest one is returned
// (since allInlineCallRanges returns inlined call by decreasing depth
// this is the first matching entry of the slice).
findInlRng := func(pc uint64) dwarf.Offset {
for _, inlrng := range inlrngs {
if inlrng.rng[0] <= pc && pc < inlrng.rng[1] {
return inlrng.off
}
}
return fn.offset
}
pcsByOff := map[dwarf.Offset][]line.PCStmt{}
for _, pc := range pcs {
off := findInlRng(pc.PC)
pcsByOff[off] = append(pcsByOff[off], pc)
}
// 4. pick the first instruction with stmt set for each inlined call as
// well as the main body of the concrete function. If nothing has
// is_stmt set pick the first instruction instead.
for off, pcs := range pcsByOff {
sort.Slice(pcs, func(i, j int) bool { return pcs[i].PC < pcs[j].PC })
var selectedPC uint64
for _, pc := range pcs {
if pc.Stmt {
selectedPC = pc.PC
break
}
}
if selectedPC == 0 && len(pcs) > 0 {
selectedPC = pcs[0].PC
}
if selectedPC == 0 {
continue
}
// 5. if we picked the entry point of the function, skip it
if off == fn.offset && fn.Entry == selectedPC {
selectedPC, _ = FirstPCAfterPrologue(p, fn, true)
}
selectedPCs = append(selectedPCs, selectedPC)
}
}
return selectedPCs, nil
}
// inlRnage is the range of an inlined call
type inlRange struct {
off dwarf.Offset
depth uint32
rng [2]uint64
}
// allInlineCallRanges returns all inlined calls contained inside 'tree' in
// reverse nesting order (i.e. the most nested calls are returned first).
// Note that a single inlined call might not have a continuous range of
// addresses and therefore appear multiple times in the returned slice.
func allInlineCallRanges(tree *godwarf.Tree) []inlRange {
r := []inlRange{}
var visit func(*godwarf.Tree, uint32)
visit = func(n *godwarf.Tree, depth uint32) {
if n.Tag == dwarf.TagInlinedSubroutine {
for _, rng := range n.Ranges {
r = append(r, inlRange{off: n.Offset, depth: depth, rng: rng})
}
}
for _, child := range n.Children {
visit(child, depth+1)
}
}
visit(tree, 0)
sort.SliceStable(r, func(i, j int) bool { return r[i].depth > r[j].depth })
return r
}
// FindFunctionLocation finds address of a function's line
// If lineOffset is passed FindFunctionLocation will return the address of that line
func FindFunctionLocation(p Process, funcName string, lineOffset int) ([]uint64, error) {
bi := p.BinInfo()
origfn := bi.LookupFunc[funcName]
if origfn == nil {
return nil, &ErrFunctionNotFound{funcName}
}
if lineOffset > 0 {
filename, lineno := origfn.cu.lineInfo.PCToLine(origfn.Entry, origfn.Entry)
return FindFileLocation(p, filename, lineno+lineOffset)
}
r := make([]uint64, 0, len(origfn.InlinedCalls)+1)
if origfn.Entry > 0 {
// add concrete implementation of the function
pc, err := FirstPCAfterPrologue(p, origfn, false)
if err != nil {
return nil, err
}
r = append(r, pc)
}
// add inlined calls to the function
for _, call := range origfn.InlinedCalls {
r = append(r, call.LowPC)
}
if len(r) == 0 {
return nil, &ErrFunctionNotFound{funcName}
}
return r, nil
}
// FirstPCAfterPrologue returns the address of the first
// instruction after the prologue for function fn.
// If sameline is set FirstPCAfterPrologue will always return an
// address associated with the same line as fn.Entry.
func FirstPCAfterPrologue(p Process, fn *Function, sameline bool) (uint64, error) {
pc, _, line, ok := fn.cu.lineInfo.PrologueEndPC(fn.Entry, fn.End)
if ok {
if !sameline {
return pc, nil
}
_, entryLine := fn.cu.lineInfo.PCToLine(fn.Entry, fn.Entry)
if entryLine == line {
return pc, nil
}
}
pc, err := firstPCAfterPrologueDisassembly(p, fn, sameline)
if err != nil {
return fn.Entry, err
}
if pc == fn.Entry {
// Look for the first instruction with the stmt flag set, so that setting a
// breakpoint with file:line and with the function name always result on
// the same instruction being selected.
if pc2, _, _, ok := fn.cu.lineInfo.FirstStmtForLine(fn.Entry, fn.End); ok {
return pc2, nil
}
}
return pc, nil
}
// cpuArch is a stringer interface representing CPU architectures.
type cpuArch interface {
String() string
}
// ErrUnsupportedArch is returned when attempting to debug a binary compiled for an unsupported architecture.
type ErrUnsupportedArch struct {
os string
cpuArch cpuArch
}
func (e *ErrUnsupportedArch) Error() string {
var supportArchs []cpuArch
switch e.os {
case "linux":
for linuxArch := range supportedLinuxArch {
supportArchs = append(supportArchs, linuxArch)
}
case "windows":
for windowArch := range supportedWindowsArch {
supportArchs = append(supportArchs, windowArch)
}
case "darwin":
for darwinArch := range supportedDarwinArch {
supportArchs = append(supportArchs, darwinArch)
}
}
errStr := "unsupported architecture of " + e.os + "/" + e.cpuArch.String()
errStr += " - only"
for _, arch := range supportArchs {
errStr += " " + e.os + "/" + arch.String() + " "
}
if len(supportArchs) == 1 {
errStr += "is supported"
} else {
errStr += "are supported"
}
return errStr
}
type compileUnit struct {
name string // univocal name for non-go compile units
Version uint8 // DWARF version of this compile unit
lowPC uint64
ranges [][2]uint64
entry *dwarf.Entry // debug_info entry describing this compile unit
isgo bool // true if this is the go compile unit
lineInfo *line.DebugLineInfo // debug_line segment associated with this compile unit
optimized bool // this compile unit is optimized
producer string // producer attribute
offset dwarf.Offset // offset of the entry describing the compile unit
image *Image // parent image of this compilation unit.
}
type fileLine struct {
file string
line int
}
// dwarfRef is a reference to a Debug Info Entry inside a shared object.
type dwarfRef struct {
imageIndex int
offset dwarf.Offset
}
// InlinedCall represents a concrete inlined call to a function.
type InlinedCall struct {
cu *compileUnit
LowPC, HighPC uint64 // Address range of the generated inlined instructions
}
// Function describes a function in the target program.
type Function struct {
Name string
Entry, End uint64 // same as DW_AT_lowpc and DW_AT_highpc
offset dwarf.Offset
cu *compileUnit
trampoline bool // DW_AT_trampoline attribute set to true
// InlinedCalls lists all inlined calls to this function
InlinedCalls []InlinedCall
}
// PackageName returns the package part of the symbol name,
// or the empty string if there is none.
// Borrowed from $GOROOT/debug/gosym/symtab.go
func (fn *Function) PackageName() string {
return packageName(fn.Name)
}
func packageName(name string) string {
pathend := strings.LastIndex(name, "/")
if pathend < 0 {
pathend = 0
}
if i := strings.Index(name[pathend:], "."); i != -1 {
return name[:pathend+i]
}
return ""
}
// ReceiverName returns the receiver type name of this symbol,
// or the empty string if there is none.
// Borrowed from $GOROOT/debug/gosym/symtab.go
func (fn *Function) ReceiverName() string {
pathend := strings.LastIndex(fn.Name, "/")
if pathend < 0 {
pathend = 0
}
l := strings.Index(fn.Name[pathend:], ".")
r := strings.LastIndex(fn.Name[pathend:], ".")
if l == -1 || r == -1 || l == r {
return ""
}
return fn.Name[pathend+l+1 : pathend+r]
}
// BaseName returns the symbol name without the package or receiver name.
// Borrowed from $GOROOT/debug/gosym/symtab.go
func (fn *Function) BaseName() string {
if i := strings.LastIndex(fn.Name, "."); i != -1 {
return fn.Name[i+1:]
}
return fn.Name
}
// Optimized returns true if the function was optimized by the compiler.
func (fn *Function) Optimized() bool {
return fn.cu.optimized
}
// PrologueEndPC returns the PC just after the function prologue
func (fn *Function) PrologueEndPC() uint64 {
pc, _, _, ok := fn.cu.lineInfo.PrologueEndPC(fn.Entry, fn.End)
if !ok {
return fn.Entry
}
return pc
}
// From $GOROOT/src/runtime/traceback.go:597
// exportedRuntime reports whether the function is an exported runtime function.
// It is only for runtime functions, so ASCII A-Z is fine.
func (fn *Function) exportedRuntime() bool {
name := fn.Name
const n = len("runtime.")
return len(name) > n && name[:n] == "runtime." && 'A' <= name[n] && name[n] <= 'Z'
}
// unexportedRuntime reports whether the function is a private runtime function.
func (fn *Function) privateRuntime() bool {
name := fn.Name
const n = len("runtime.")
return len(name) > n && name[:n] == "runtime." && !('A' <= name[n] && name[n] <= 'Z')
}
type constantsMap map[dwarfRef]*constantType
type constantType struct {
initialized bool
values []constantValue
}
type constantValue struct {
name string
fullName string
value int64
singleBit bool
}
// packageVar represents a package-level variable (or a C global variable).
// If a global variable does not have an address (for example it's stored in
// a register, or non-contiguously) addr will be 0.
type packageVar struct {
name string
cu *compileUnit
offset dwarf.Offset
addr uint64
}
type buildIDHeader struct {
Namesz uint32
Descsz uint32
Type uint32
}
// ElfDynamicSection describes the .dynamic section of an ELF executable.
type ElfDynamicSection struct {
Addr uint64 // relocated address of where the .dynamic section is mapped in memory
Size uint64 // size of the .dynamic section of the executable
}
// NewBinaryInfo returns an initialized but unloaded BinaryInfo struct.
func NewBinaryInfo(goos, goarch string) *BinaryInfo {
r := &BinaryInfo{GOOS: goos, nameOfRuntimeType: make(map[uint64]nameOfRuntimeTypeEntry), logger: logflags.DebuggerLogger()}
// TODO: find better way to determine proc arch (perhaps use executable file info).
switch goarch {
case "386":
r.Arch = I386Arch(goos)
case "amd64":
r.Arch = AMD64Arch(goos)
case "arm64":
r.Arch = ARM64Arch(goos)
}
return r
}
// LoadBinaryInfo will load and store the information from the binary at 'path'.
func (bi *BinaryInfo) LoadBinaryInfo(path string, entryPoint uint64, debugInfoDirs []string) error {
fi, err := os.Stat(path)
if err == nil {
bi.lastModified = fi.ModTime()
}
bi.debugInfoDirectories = debugInfoDirs
return bi.AddImage(path, entryPoint)
}
func loadBinaryInfo(bi *BinaryInfo, image *Image, path string, entryPoint uint64) error {
var wg sync.WaitGroup
defer wg.Wait()
switch bi.GOOS {
case "linux", "freebsd":
return loadBinaryInfoElf(bi, image, path, entryPoint, &wg)
case "windows":
return loadBinaryInfoPE(bi, image, path, entryPoint, &wg)
case "darwin":
return loadBinaryInfoMacho(bi, image, path, entryPoint, &wg)
}
return errors.New("unsupported operating system")
}
// GStructOffset returns the offset of the G
// struct in thread local storage.
func (bi *BinaryInfo) GStructOffset() uint64 {
return bi.gStructOffset
}
// LastModified returns the last modified time of the binary.
func (bi *BinaryInfo) LastModified() time.Time {
return bi.lastModified
}
// DwarfReader returns a reader for the dwarf data
func (so *Image) DwarfReader() *reader.Reader {
return reader.New(so.dwarf)
}
// Types returns list of types present in the debugged program.
func (bi *BinaryInfo) Types() ([]string, error) {
types := make([]string, 0, len(bi.types))
for k := range bi.types {
types = append(types, k)
}
return types, nil
}
// PCToLine converts an instruction address to a file/line/function.
func (bi *BinaryInfo) PCToLine(pc uint64) (string, int, *Function) {
fn := bi.PCToFunc(pc)
if fn == nil {
return "", 0, nil
}
f, ln := fn.cu.lineInfo.PCToLine(fn.Entry, pc)
return f, ln, fn
}
type ErrCouldNotFindLine struct {
fileFound bool
filename string
lineno int
}
func (err *ErrCouldNotFindLine) Error() string {
if err.fileFound {
return fmt.Sprintf("could not find statement at %s:%d, please use a line with a statement", err.filename, err.lineno)
}
return fmt.Sprintf("could not find file %s", err.filename)
}
// AllPCsForFileLines returns a map providing all PC addresses for filename and each line in linenos
func (bi *BinaryInfo) AllPCsForFileLines(filename string, linenos []int) map[int][]uint64 {
r := make(map[int][]uint64)
for _, line := range linenos {
r[line] = make([]uint64, 0, 1)
}
for _, image := range bi.Images {
for _, cu := range image.compileUnits {
if cu.lineInfo != nil && cu.lineInfo.Lookup[filename] != nil {
cu.lineInfo.AllPCsForFileLines(filename, r)
}
}
}
return r
}
// PCToFunc returns the concrete function containing the given PC address.
// If the PC address belongs to an inlined call it will return the containing function.
func (bi *BinaryInfo) PCToFunc(pc uint64) *Function {
i := sort.Search(len(bi.Functions), func(i int) bool {
fn := bi.Functions[i]
return pc <= fn.Entry || (fn.Entry <= pc && pc < fn.End)
})
if i != len(bi.Functions) {
fn := &bi.Functions[i]
if fn.Entry <= pc && pc < fn.End {
return fn
}
}
return nil
}
// PCToImage returns the image containing the given PC address.
func (bi *BinaryInfo) PCToImage(pc uint64) *Image {
fn := bi.PCToFunc(pc)
return bi.funcToImage(fn)
}
// Image represents a loaded library file (shared object on linux, DLL on windows).
type Image struct {
Path string
StaticBase uint64
addr uint64
index int // index of this object in BinaryInfo.SharedObjects
closer io.Closer
sepDebugCloser io.Closer
dwarf *dwarf.Data
dwarfReader *dwarf.Reader
loclist2 *loclist.Dwarf2Reader
loclist5 *loclist.Dwarf5Reader
debugAddr *godwarf.DebugAddrSection
debugLineStr []byte
typeCache map[dwarf.Offset]godwarf.Type
compileUnits []*compileUnit // compileUnits is sorted by increasing DWARF offset
dwarfTreeCache *simplelru.LRU
runtimeMallocgcTree *godwarf.Tree // patched version of runtime.mallocgc's DIE
// runtimeTypeToDIE maps between the offset of a runtime._type in
// runtime.moduledata.types and the offset of the DIE in debug_info. This
// map is filled by using the extended attribute godwarf.AttrGoRuntimeType
// which was added in go 1.11.
runtimeTypeToDIE map[uint64]runtimeTypeDIE
loadErrMu sync.Mutex
loadErr error
}
func (image *Image) registerRuntimeTypeToDIE(entry *dwarf.Entry, ardr *reader.Reader) {
if off, ok := entry.Val(godwarf.AttrGoRuntimeType).(uint64); ok {
if _, ok := image.runtimeTypeToDIE[off]; !ok {
image.runtimeTypeToDIE[off] = runtimeTypeDIE{entry.Offset, -1}
}
}
}
// AddImage adds the specified image to bi, loading data asynchronously.
// Addr is the relocated entry point for the executable and staticBase (i.e.
// the relocation offset) for all other images.
// The first image added must be the executable file.
func (bi *BinaryInfo) AddImage(path string, addr uint64) error {
// Check if the image is already present.
if len(bi.Images) > 0 && !strings.HasPrefix(path, "/") {
return nil
}
for _, image := range bi.Images {
if image.Path == path && image.addr == addr {
return nil
}
}
// Actually add the image.
image := &Image{Path: path, addr: addr, typeCache: make(map[dwarf.Offset]godwarf.Type)}
image.dwarfTreeCache, _ = simplelru.NewLRU(dwarfTreeCacheSize, nil)
// add Image regardless of error so that we don't attempt to re-add it every time we stop
image.index = len(bi.Images)
bi.Images = append(bi.Images, image)
err := loadBinaryInfo(bi, image, path, addr)
if err != nil {
bi.Images[len(bi.Images)-1].loadErr = err
}
bi.macOSDebugFrameBugWorkaround()
return err
}
// moduleDataToImage finds the image corresponding to the given module data object.
func (bi *BinaryInfo) moduleDataToImage(md *moduleData) *Image {
fn := bi.PCToFunc(uint64(md.text))
if fn != nil {
return bi.funcToImage(fn)
}
// Try searching for the image with the closest address preceding md.text
var so *Image
for i := range bi.Images {
if int64(bi.Images[i].StaticBase) > int64(md.text) {
continue
}
if so == nil || int64(bi.Images[i].StaticBase) > int64(so.StaticBase) {
so = bi.Images[i]
}
}
return so
}
// imageToModuleData finds the module data in mds corresponding to the given image.
func (bi *BinaryInfo) imageToModuleData(image *Image, mds []moduleData) *moduleData {
for _, md := range mds {
im2 := bi.moduleDataToImage(&md)
if im2 != nil && im2.index == image.index {
return &md
}
}
return nil
}
// typeToImage returns the image containing the give type.
func (bi *BinaryInfo) typeToImage(typ godwarf.Type) *Image {
return bi.Images[typ.Common().Index]
}
var errBinaryInfoClose = errors.New("multiple errors closing executable files")
// Close closes all internal readers.
func (bi *BinaryInfo) Close() error {
var errs []error
for _, image := range bi.Images {
if err := image.Close(); err != nil {
errs = append(errs, err)
}
}
switch len(errs) {
case 0:
return nil
case 1:
return errs[0]
default:
return errBinaryInfoClose
}
}
func (image *Image) Close() error {
var err1, err2 error
if image.sepDebugCloser != nil {
err := image.sepDebugCloser.Close()
if err != nil {
err1 = fmt.Errorf("closing shared object %q (split dwarf): %v", image.Path, err)
}
}
if image.closer != nil {
err := image.closer.Close()
if err != nil {
err2 = fmt.Errorf("closing shared object %q: %v", image.Path, err)
}
}
if err1 != nil && err2 != nil {
return errBinaryInfoClose
}
if err1 != nil {
return err1
}
return err2
}
func (image *Image) setLoadError(fmtstr string, args ...interface{}) {
image.loadErrMu.Lock()
image.loadErr = fmt.Errorf(fmtstr, args...)
image.loadErrMu.Unlock()
}
// LoadError returns any error incurred while loading this image.
func (image *Image) LoadError() error {
return image.loadErr
}
func (image *Image) getDwarfTree(off dwarf.Offset) (*godwarf.Tree, error) {
if image.runtimeMallocgcTree != nil && off == image.runtimeMallocgcTree.Offset {
return image.runtimeMallocgcTree, nil
}
if r, ok := image.dwarfTreeCache.Get(off); ok {
return r.(*godwarf.Tree), nil
}
r, err := godwarf.LoadTree(off, image.dwarf, image.StaticBase)
if err != nil {
return nil, err
}
image.dwarfTreeCache.Add(off, r)
return r, nil
}
type nilCloser struct{}
func (c *nilCloser) Close() error { return nil }
// LoadImageFromData creates a new Image, using the specified data, and adds it to bi.
// This is used for debugging BinaryInfo, you should use LoadBinary instead.
func (bi *BinaryInfo) LoadImageFromData(dwdata *dwarf.Data, debugFrameBytes, debugLineBytes, debugLocBytes []byte) {
image := &Image{}
image.closer = (*nilCloser)(nil)
image.sepDebugCloser = (*nilCloser)(nil)
image.dwarf = dwdata
image.typeCache = make(map[dwarf.Offset]godwarf.Type)
image.dwarfTreeCache, _ = simplelru.NewLRU(dwarfTreeCacheSize, nil)
if debugFrameBytes != nil {
bi.frameEntries, _ = frame.Parse(debugFrameBytes, frame.DwarfEndian(debugFrameBytes), 0, bi.Arch.PtrSize(), 0)
}
image.loclist2 = loclist.NewDwarf2Reader(debugLocBytes, bi.Arch.PtrSize())
bi.loadDebugInfoMaps(image, nil, debugLineBytes, nil, nil)
bi.Images = append(bi.Images, image)
}
func (bi *BinaryInfo) locationExpr(entry godwarf.Entry, attr dwarf.Attr, pc uint64) ([]byte, *locationExpr, error) {
//TODO(aarzilli): handle DW_FORM_loclistx attribute form new in DWARFv5
a := entry.Val(attr)
if a == nil {
return nil, nil, fmt.Errorf("no location attribute %s", attr)
}
if instr, ok := a.([]byte); ok {
return instr, &locationExpr{isBlock: true, instr: instr}, nil
}
off, ok := a.(int64)
if !ok {
return nil, nil, fmt.Errorf("could not interpret location attribute %s", attr)
}
instr := bi.loclistEntry(off, pc)
if instr == nil {
return nil, nil, fmt.Errorf("could not find loclist entry at %#x for address %#x", off, pc)
}
return instr, &locationExpr{pc: pc, off: off, instr: instr}, nil
}
type locationExpr struct {
isBlock bool
isEscaped bool
off int64
pc uint64
instr []byte
}
func (le *locationExpr) String() string {
if le == nil {
return ""
}
var descr bytes.Buffer
if le.isBlock {
fmt.Fprintf(&descr, "[block] ")
op.PrettyPrint(&descr, le.instr)
} else {
fmt.Fprintf(&descr, "[%#x:%#x] ", le.off, le.pc)
op.PrettyPrint(&descr, le.instr)
}
if le.isEscaped {
fmt.Fprintf(&descr, " (escaped)")
}
return descr.String()
}
// LocationCovers returns the list of PC addresses that is covered by the
// location attribute 'attr' of entry 'entry'.
func (bi *BinaryInfo) LocationCovers(entry *dwarf.Entry, attr dwarf.Attr) ([][2]uint64, error) {
a := entry.Val(attr)
if a == nil {
return nil, fmt.Errorf("attribute %s not found", attr)
}
if _, isblock := a.([]byte); isblock {
return [][2]uint64{[2]uint64{0, ^uint64(0)}}, nil
}
off, ok := a.(int64)
if !ok {
return nil, fmt.Errorf("attribute %s of unsupported type %T", attr, a)
}
cu := bi.Images[0].findCompileUnitForOffset(entry.Offset)
if cu == nil {
return nil, errors.New("could not find compile unit")
}
if cu.Version >= 5 && cu.image.loclist5 != nil {
return nil, errors.New("LocationCovers does not support DWARFv5")
}
image := cu.image
base := cu.lowPC
if image == nil || image.loclist2.Empty() {
return nil, errors.New("malformed executable")
}
r := [][2]uint64{}
var e loclist.Entry
image.loclist2.Seek(int(off))
for image.loclist2.Next(&e) {
if e.BaseAddressSelection() {
base = e.HighPC
continue
}
r = append(r, [2]uint64{e.LowPC + base, e.HighPC + base})
}
return r, nil
}
// Location returns the location described by attribute attr of entry.
// This will either be an int64 address or a slice of Pieces for locations
// that don't correspond to a single memory address (registers, composite
// locations).
func (bi *BinaryInfo) Location(entry godwarf.Entry, attr dwarf.Attr, pc uint64, regs op.DwarfRegisters, mem MemoryReadWriter) (int64, []op.Piece, *locationExpr, error) {
instr, descr, err := bi.locationExpr(entry, attr, pc)
if err != nil {
return 0, nil, nil, err
}
readMemory := op.ReadMemoryFunc(nil)
if mem != nil {
readMemory = mem.ReadMemory
}
addr, pieces, err := op.ExecuteStackProgram(regs, instr, bi.Arch.PtrSize(), readMemory)
return addr, pieces, descr, err
}
// loclistEntry returns the loclist entry in the loclist starting at off,
// for address pc.
func (bi *BinaryInfo) loclistEntry(off int64, pc uint64) []byte {
var base uint64
image := bi.Images[0]
cu := bi.findCompileUnit(pc)
if cu != nil {
base = cu.lowPC
image = cu.image
}
if image == nil {
return nil
}
var loclist loclist.Reader = image.loclist2
var debugAddr *godwarf.DebugAddr
if cu != nil && cu.Version >= 5 && image.loclist5 != nil {
loclist = image.loclist5
if addrBase, ok := cu.entry.Val(dwarfAttrAddrBase).(int64); ok {
debugAddr = image.debugAddr.GetSubsection(uint64(addrBase))
}
}
if loclist.Empty() {
return nil
}
e, err := loclist.Find(int(off), image.StaticBase, base, pc, debugAddr)
if err != nil {
bi.logger.Errorf("error reading loclist section: %v", err)
return nil
}
if e != nil {
return e.Instr
}
return nil
}
// findCompileUnit returns the compile unit containing address pc.
func (bi *BinaryInfo) findCompileUnit(pc uint64) *compileUnit {
for _, image := range bi.Images {
for _, cu := range image.compileUnits {
for _, rng := range cu.ranges {
if pc >= rng[0] && pc < rng[1] {
return cu
}
}
}
}
return nil
}
func (bi *Image) findCompileUnitForOffset(off dwarf.Offset) *compileUnit {
i := sort.Search(len(bi.compileUnits), func(i int) bool {
return bi.compileUnits[i].offset >= off
})
if i > 0 {
i--
}
return bi.compileUnits[i]
}
// Producer returns the value of DW_AT_producer.
func (bi *BinaryInfo) Producer() string {
for _, cu := range bi.Images[0].compileUnits {
if cu.isgo && cu.producer != "" {
return cu.producer
}
}
return ""
}
// Type returns the Dwarf type entry at `offset`.
func (image *Image) Type(offset dwarf.Offset) (godwarf.Type, error) {
return godwarf.ReadType(image.dwarf, image.index, offset, image.typeCache)
}
// funcToImage returns the Image containing function fn, or the
// executable file as a fallback.
func (bi *BinaryInfo) funcToImage(fn *Function) *Image {
if fn == nil {
return bi.Images[0]
}
return fn.cu.image
}
// parseDebugFrameGeneral parses a debug_frame and a eh_frame section.
// At least one of the two must be present and parsed correctly, if
// debug_frame is present it must be parsable correctly.
func (bi *BinaryInfo) parseDebugFrameGeneral(image *Image, debugFrameBytes []byte, debugFrameName string, debugFrameErr error, ehFrameBytes []byte, ehFrameAddr uint64, ehFrameName string, byteOrder binary.ByteOrder) {
if debugFrameBytes == nil && ehFrameBytes == nil {
image.setLoadError("could not get %s section: %v", debugFrameName, debugFrameErr)
return
}
if debugFrameBytes != nil {
fe, err := frame.Parse(debugFrameBytes, byteOrder, image.StaticBase, bi.Arch.PtrSize(), 0)
if err != nil {
image.setLoadError("could not parse %s section: %v", debugFrameName, err)
return
}
bi.frameEntries = bi.frameEntries.Append(fe)
}
if ehFrameBytes != nil && ehFrameAddr > 0 {
fe, err := frame.Parse(ehFrameBytes, byteOrder, image.StaticBase, bi.Arch.PtrSize(), ehFrameAddr)
if err != nil {
if debugFrameBytes == nil {
image.setLoadError("could not parse %s section: %v", ehFrameName, err)
return
}
bi.logger.Warnf("could not parse %s section: %v", ehFrameName, err)
return
}
bi.frameEntries = bi.frameEntries.Append(fe)
}
}
// ELF ///////////////////////////////////////////////////////////////
// ErrNoBuildIDNote is used in openSeparateDebugInfo to signal there's no
// build-id note on the binary, so LoadBinaryInfoElf will return
// the error message coming from elfFile.DWARF() instead.
type ErrNoBuildIDNote struct{}
func (e *ErrNoBuildIDNote) Error() string {
return "can't find build-id note on binary"
}
// openSeparateDebugInfo searches for a file containing the separate
// debug info for the binary using the "build ID" method as described
// in GDB's documentation [1], and if found returns two handles, one
// for the bare file, and another for its corresponding elf.File.
// [1] https://sourceware.org/gdb/onlinedocs/gdb/Separate-Debug-Files.html
//
// Alternatively, if the debug file cannot be found be the build-id, Delve
// will look in directories specified by the debug-info-directories config value.
func (bi *BinaryInfo) openSeparateDebugInfo(image *Image, exe *elf.File, debugInfoDirectories []string) (*os.File, *elf.File, error) {
var debugFilePath string
desc1, desc2, _ := parseBuildID(exe)
for _, dir := range debugInfoDirectories {
var potentialDebugFilePath string
if strings.Contains(dir, "build-id") {
potentialDebugFilePath = fmt.Sprintf("%s/%s/%s.debug", dir, desc1, desc2)
} else if strings.HasPrefix(image.Path, "/proc") {
path, err := filepath.EvalSymlinks(image.Path)
if err == nil {
potentialDebugFilePath = fmt.Sprintf("%s/%s.debug", dir, filepath.Base(path))
}
} else {
potentialDebugFilePath = fmt.Sprintf("%s/%s.debug", dir, filepath.Base(image.Path))
}
_, err := os.Stat(potentialDebugFilePath)
if err == nil {
debugFilePath = potentialDebugFilePath
break
}
}
// We cannot find the debug information locally on the system. Try and see if we're on a system that
// has debuginfod so that we can use that in order to find any relevant debug information.
if debugFilePath == "" {
const debuginfodFind = "debuginfod-find"
if _, err := exec.LookPath(debuginfodFind); err == nil {
cmd := exec.Command(debuginfodFind, "debuginfo", desc1+desc2)
out, err := cmd.CombinedOutput()
if err != nil {
return nil, nil, ErrNoDebugInfoFound
}
debugFilePath = string(out)
} else {
return nil, nil, ErrNoDebugInfoFound
}
}
sepFile, err := os.OpenFile(debugFilePath, 0, os.ModePerm)
if err != nil {
return nil, nil, errors.New("can't open separate debug file: " + err.Error())
}
elfFile, err := elf.NewFile(sepFile)
if err != nil {
sepFile.Close()
return nil, nil, fmt.Errorf("can't open separate debug file %q: %v", debugFilePath, err.Error())
}
if !supportedLinuxArch[elfFile.Machine] {
sepFile.Close()
return nil, nil, fmt.Errorf("can't open separate debug file %q: %v", debugFilePath, &ErrUnsupportedArch{os: "linux", cpuArch: elfFile.Machine})
}
return sepFile, elfFile, nil
}
func parseBuildID(exe *elf.File) (string, string, error) {
buildid := exe.Section(".note.gnu.build-id")
if buildid == nil {
return "", "", &ErrNoBuildIDNote{}
}
br := buildid.Open()
bh := new(buildIDHeader)
if err := binary.Read(br, binary.LittleEndian, bh); err != nil {
return "", "", errors.New("can't read build-id header: " + err.Error())
}
name := make([]byte, bh.Namesz)
if err := binary.Read(br, binary.LittleEndian, name); err != nil {
return "", "", errors.New("can't read build-id name: " + err.Error())
}
if strings.TrimSpace(string(name)) != "GNU\x00" {
return "", "", errors.New("invalid build-id signature")
}
descBinary := make([]byte, bh.Descsz)
if err := binary.Read(br, binary.LittleEndian, descBinary); err != nil {
return "", "", errors.New("can't read build-id desc: " + err.Error())
}
desc := hex.EncodeToString(descBinary)
return desc[:2], desc[2:], nil
}
// loadBinaryInfoElf specifically loads information from an ELF binary.
func loadBinaryInfoElf(bi *BinaryInfo, image *Image, path string, addr uint64, wg *sync.WaitGroup) error {
exe, err := os.OpenFile(path, 0, os.ModePerm)
if err != nil {
return err
}
image.closer = exe
elfFile, err := elf.NewFile(exe)
if err != nil {
return err
}
if !supportedLinuxArch[elfFile.Machine] {
return &ErrUnsupportedArch{os: "linux", cpuArch: elfFile.Machine}
}
if image.index == 0 {
// adding executable file:
// - addr is entryPoint therefore staticBase needs to be calculated by
// subtracting the entry point specified in the executable file from addr.
// - memory address of the .dynamic section needs to be recorded in
// BinaryInfo so that we can find loaded libraries.
if addr != 0 {
image.StaticBase = addr - elfFile.Entry
} else if elfFile.Type == elf.ET_DYN {
return ErrCouldNotDetermineRelocation
}
if dynsec := elfFile.Section(".dynamic"); dynsec != nil {
bi.ElfDynamicSection.Addr = dynsec.Addr + image.StaticBase
bi.ElfDynamicSection.Size = dynsec.Size
}
} else {
image.StaticBase = addr
}
dwarfFile := elfFile
var debugInfoBytes []byte
image.dwarf, err = elfFile.DWARF()
if err != nil {
var sepFile *os.File
var serr error
sepFile, dwarfFile, serr = bi.openSeparateDebugInfo(image, elfFile, bi.debugInfoDirectories)
if serr != nil {
return serr
}
image.sepDebugCloser = sepFile
image.dwarf, err = dwarfFile.DWARF()
if err != nil {
return err
}
}
debugInfoBytes, err = godwarf.GetDebugSectionElf(dwarfFile, "info")
if err != nil {
return err
}
image.dwarfReader = image.dwarf.Reader()
debugLineBytes, err := godwarf.GetDebugSectionElf(dwarfFile, "line")
if err != nil {
return err
}
debugLocBytes, _ := godwarf.GetDebugSectionElf(dwarfFile, "loc")
image.loclist2 = loclist.NewDwarf2Reader(debugLocBytes, bi.Arch.PtrSize())
debugLoclistBytes, _ := godwarf.GetDebugSectionElf(dwarfFile, "loclists")
image.loclist5 = loclist.NewDwarf5Reader(debugLoclistBytes)
debugAddrBytes, _ := godwarf.GetDebugSectionElf(dwarfFile, "addr")
image.debugAddr = godwarf.ParseAddr(debugAddrBytes)
debugLineStrBytes, _ := godwarf.GetDebugSectionElf(dwarfFile, "line_str")
image.debugLineStr = debugLineStrBytes
wg.Add(3)
go bi.parseDebugFrameElf(image, dwarfFile, debugInfoBytes, wg)
go bi.loadDebugInfoMaps(image, debugInfoBytes, debugLineBytes, wg, nil)
go bi.loadSymbolName(image, elfFile, wg)
if image.index == 0 {
// determine g struct offset only when loading the executable file
wg.Add(1)
go bi.setGStructOffsetElf(image, dwarfFile, wg)
}
return nil
}
// _STT_FUNC is a code object, see /usr/include/elf.h for a full definition.
const _STT_FUNC = 2
func (bi *BinaryInfo) loadSymbolName(image *Image, file *elf.File, wg *sync.WaitGroup) {
defer wg.Done()
if bi.SymNames == nil {
bi.SymNames = make(map[uint64]*elf.Symbol)
}
symSecs, _ := file.Symbols()
for _, symSec := range symSecs {
if symSec.Info == _STT_FUNC { // TODO(chainhelen), need to parse others types.
s := symSec
bi.SymNames[symSec.Value+image.StaticBase] = &s
}
}
}
func (bi *BinaryInfo) parseDebugFrameElf(image *Image, exe *elf.File, debugInfoBytes []byte, wg *sync.WaitGroup) {
defer wg.Done()
debugFrameData, debugFrameErr := godwarf.GetDebugSectionElf(exe, "frame")
ehFrameSection := exe.Section(".eh_frame")
var ehFrameData []byte
var ehFrameAddr uint64
if ehFrameSection != nil {
ehFrameAddr = ehFrameSection.Addr
ehFrameData, _ = ehFrameSection.Data()
}
bi.parseDebugFrameGeneral(image, debugFrameData, ".debug_frame", debugFrameErr, ehFrameData, ehFrameAddr, ".eh_frame", frame.DwarfEndian(debugInfoBytes))
}
func (bi *BinaryInfo) setGStructOffsetElf(image *Image, exe *elf.File, wg *sync.WaitGroup) {
defer wg.Done()
// This is a bit arcane. Essentially:
// - If the program is pure Go, it can do whatever it wants, and puts the G
// pointer at %fs-8 on 64 bit.
// - %Gs is the index of private storage in GDT on 32 bit, and puts the G
// pointer at -4(tls).
// - Otherwise, Go asks the external linker to place the G pointer by
// emitting runtime.tlsg, a TLS symbol, which is relocated to the chosen
// offset in libc's TLS block.
// - On ARM64 (but really, any architecture other than i386 and 86x64) the
// offset is calculate using runtime.tls_g and the formula is different.
var tls *elf.Prog
for _, prog := range exe.Progs {
if prog.Type == elf.PT_TLS {
tls = prog
break
}
}
switch exe.Machine {
case elf.EM_X86_64, elf.EM_386:
tlsg := getSymbol(image, exe, "runtime.tlsg")
if tlsg == nil || tls == nil {
bi.gStructOffset = ^uint64(bi.Arch.PtrSize()) + 1 //-ptrSize
return
}
// According to https://reviews.llvm.org/D61824, linkers must pad the actual
// size of the TLS segment to ensure that (tlsoffset%align) == (vaddr%align).
// This formula, copied from the lld code, matches that.
// https://github.com/llvm-mirror/lld/blob/9aef969544981d76bea8e4d1961d3a6980980ef9/ELF/InputSection.cpp#L643
memsz := tls.Memsz + (-tls.Vaddr-tls.Memsz)&(tls.Align-1)
// The TLS register points to the end of the TLS block, which is
// tls.Memsz long. runtime.tlsg is an offset from the beginning of that block.
bi.gStructOffset = ^(memsz) + 1 + tlsg.Value // -tls.Memsz + tlsg.Value
case elf.EM_AARCH64:
tlsg := getSymbol(image, exe, "runtime.tls_g")
if tlsg == nil || tls == nil {
bi.gStructOffset = 2 * uint64(bi.Arch.PtrSize())
return
}
bi.gStructOffset = tlsg.Value + uint64(bi.Arch.PtrSize()*2) + ((tls.Vaddr - uint64(bi.Arch.PtrSize()*2)) & (tls.Align - 1))
default:
// we should never get here
panic("architecture not supported")
}
}
func getSymbol(image *Image, exe *elf.File, name string) *elf.Symbol {
symbols, err := exe.Symbols()
if err != nil {
image.setLoadError("could not parse ELF symbols: %v", err)
return nil
}
for _, symbol := range symbols {
if symbol.Name == name {
s := symbol
return &s
}
}
return nil
}
// PE ////////////////////////////////////////////////////////////////
const _IMAGE_DLLCHARACTERISTICS_DYNAMIC_BASE = 0x0040
// loadBinaryInfoPE specifically loads information from a PE binary.
func loadBinaryInfoPE(bi *BinaryInfo, image *Image, path string, entryPoint uint64, wg *sync.WaitGroup) error {
peFile, closer, err := openExecutablePathPE(path)
if err != nil {
return err
}
image.closer = closer
cpuArch := _PEMachine(peFile.Machine)
if !supportedWindowsArch[cpuArch] {
return &ErrUnsupportedArch{os: "windows", cpuArch: cpuArch}
}
image.dwarf, err = peFile.DWARF()
if err != nil {
return err
}
debugInfoBytes, err := godwarf.GetDebugSectionPE(peFile, "info")
if err != nil {
return err
}
//TODO(aarzilli): actually test this when Go supports PIE buildmode on Windows.
opth := peFile.OptionalHeader.(*pe.OptionalHeader64)
if entryPoint != 0 {
image.StaticBase = entryPoint - opth.ImageBase
} else {
if opth.DllCharacteristics&_IMAGE_DLLCHARACTERISTICS_DYNAMIC_BASE != 0 {
return ErrCouldNotDetermineRelocation
}
}
image.dwarfReader = image.dwarf.Reader()
debugLineBytes, err := godwarf.GetDebugSectionPE(peFile, "line")
if err != nil {
return err
}
debugLocBytes, _ := godwarf.GetDebugSectionPE(peFile, "loc")
image.loclist2 = loclist.NewDwarf2Reader(debugLocBytes, bi.Arch.PtrSize())
debugLoclistBytes, _ := godwarf.GetDebugSectionPE(peFile, "loclists")
image.loclist5 = loclist.NewDwarf5Reader(debugLoclistBytes)
debugAddrBytes, _ := godwarf.GetDebugSectionPE(peFile, "addr")
image.debugAddr = godwarf.ParseAddr(debugAddrBytes)
wg.Add(2)
go bi.parseDebugFramePE(image, peFile, debugInfoBytes, wg)
go bi.loadDebugInfoMaps(image, debugInfoBytes, debugLineBytes, wg, nil)
// Use ArbitraryUserPointer (0x28) as pointer to pointer
// to G struct per:
// https://golang.org/src/runtime/cgo/gcc_windows_amd64.c
bi.gStructOffset = 0x28
return nil
}
func openExecutablePathPE(path string) (*pe.File, io.Closer, error) {
f, err := os.OpenFile(path, 0, os.ModePerm)
if err != nil {
return nil, nil, err
}
peFile, err := pe.NewFile(f)
if err != nil {
f.Close()
return nil, nil, err
}
return peFile, f, nil
}
func (bi *BinaryInfo) parseDebugFramePE(image *Image, exe *pe.File, debugInfoBytes []byte, wg *sync.WaitGroup) {
defer wg.Done()
debugFrameBytes, err := godwarf.GetDebugSectionPE(exe, "frame")
bi.parseDebugFrameGeneral(image, debugFrameBytes, ".debug_frame", err, nil, 0, "", frame.DwarfEndian(debugInfoBytes))
}
// MACH-O ////////////////////////////////////////////////////////////
// loadBinaryInfoMacho specifically loads information from a Mach-O binary.
func loadBinaryInfoMacho(bi *BinaryInfo, image *Image, path string, entryPoint uint64, wg *sync.WaitGroup) error {
exe, err := macho.Open(path)
if err != nil {
return err
}
if entryPoint != 0 {
// This is a little bit hacky. We use the entryPoint variable, but it
// actually holds the address of the mach-o header. We can use this
// to calculate the offset to the non-aslr location of the mach-o header
// (which is 0x100000000)
image.StaticBase = entryPoint - 0x100000000
}
image.closer = exe
if !supportedDarwinArch[exe.Cpu] {
return &ErrUnsupportedArch{os: "darwin", cpuArch: exe.Cpu}
}
image.dwarf, err = exe.DWARF()
if err != nil {
return err
}
debugInfoBytes, err := godwarf.GetDebugSectionMacho(exe, "info")
if err != nil {
return err
}
image.dwarfReader = image.dwarf.Reader()
debugLineBytes, err := godwarf.GetDebugSectionMacho(exe, "line")
if err != nil {
return err
}
debugLocBytes, _ := godwarf.GetDebugSectionMacho(exe, "loc")
image.loclist2 = loclist.NewDwarf2Reader(debugLocBytes, bi.Arch.PtrSize())
debugLoclistBytes, _ := godwarf.GetDebugSectionMacho(exe, "loclists")
image.loclist5 = loclist.NewDwarf5Reader(debugLoclistBytes)
debugAddrBytes, _ := godwarf.GetDebugSectionMacho(exe, "addr")
image.debugAddr = godwarf.ParseAddr(debugAddrBytes)
wg.Add(2)
go bi.parseDebugFrameMacho(image, exe, debugInfoBytes, wg)
go bi.loadDebugInfoMaps(image, debugInfoBytes, debugLineBytes, wg, bi.setGStructOffsetMacho)
return nil
}
func (bi *BinaryInfo) setGStructOffsetMacho() {
// In go1.11 it's 0x30, before 0x8a0, see:
// https://github.com/golang/go/issues/23617
// and go commit b3a854c733257c5249c3435ffcee194f8439676a
producer := bi.Producer()
if producer != "" && goversion.ProducerAfterOrEqual(producer, 1, 11) {
bi.gStructOffset = 0x30
return
}
bi.gStructOffset = 0x8a0
}
func (bi *BinaryInfo) parseDebugFrameMacho(image *Image, exe *macho.File, debugInfoBytes []byte, wg *sync.WaitGroup) {
defer wg.Done()
debugFrameBytes, debugFrameErr := godwarf.GetDebugSectionMacho(exe, "frame")
ehFrameSection := exe.Section("__eh_frame")
var ehFrameBytes []byte
var ehFrameAddr uint64
if ehFrameSection != nil {
ehFrameAddr = ehFrameSection.Addr
ehFrameBytes, _ = ehFrameSection.Data()
}
bi.parseDebugFrameGeneral(image, debugFrameBytes, "__debug_frame", debugFrameErr, ehFrameBytes, ehFrameAddr, "__eh_frame", frame.DwarfEndian(debugInfoBytes))
}
// macOSDebugFrameBugWorkaround applies a workaround for:
// https://github.com/golang/go/issues/25841
// It finds the Go function with the lowest entry point and the first
// debug_frame FDE, calculates the difference between the start of the
// function and the start of the FDE and sums it to all debug_frame FDEs.
// A number of additional checks are performed to make sure we don't ruin
// executables unaffected by this bug.
func (bi *BinaryInfo) macOSDebugFrameBugWorkaround() {
//TODO: log extensively because of bugs in the field
if bi.GOOS != "darwin" || bi.Arch.Name != "arm64" {
return
}
if len(bi.Images) > 1 {
// Only do this for the first executable, but it might work for plugins as
// well if we had a way to distinguish where entries in bi.frameEntries
// come from
return
}
exe, ok := bi.Images[0].closer.(*macho.File)
if !ok {
return
}
if exe.Flags&macho.FlagPIE == 0 {
bi.logger.Infof("debug_frame workaround not needed: not a PIE (%#x)", exe.Flags)
return
}
// Find first Go function (first = lowest entry point)
var fn *Function
for i := range bi.Functions {
if bi.Functions[i].cu.isgo && bi.Functions[i].Entry > 0 {
fn = &bi.Functions[i]
break
}
}
if fn == nil {
bi.logger.Warn("debug_frame workaround not applied: could not find a Go function")
return
}
if fde, _ := bi.frameEntries.FDEForPC(fn.Entry); fde != nil {
// Function is covered, no need to apply workaround
bi.logger.Warnf("debug_frame workaround not applied: function %s (at %#x) covered by %#x-%#x", fn.Name, fn.Entry, fde.Begin(), fde.End())
return
}
// Find lowest FDE in debug_frame
var fde *frame.FrameDescriptionEntry
for i := range bi.frameEntries {
if bi.frameEntries[i].CIE.CIE_id == ^uint32(0) {
fde = bi.frameEntries[i]
break
}
}
if fde == nil {
bi.logger.Warnf("debug_frame workaround not applied because there are no debug_frame entries (%d)", len(bi.frameEntries))
return
}
fnsize := fn.End - fn.Entry
if fde.End()-fde.Begin() != fnsize || fde.Begin() > fn.Entry {
bi.logger.Warnf("debug_frame workaround not applied: function %s (at %#x-%#x) has a different size than the first FDE (%#x-%#x) (or the FDE starts after the function)", fn.Name, fn.Entry, fn.End, fde.Begin(), fde.End())
return
}
delta := fn.Entry - fde.Begin()
bi.logger.Infof("applying debug_frame workaround +%#x: function %s (at %#x-%#x) and FDE %#x-%#x", delta, fn.Name, fn.Entry, fn.End, fde.Begin(), fde.End())
for i := range bi.frameEntries {
if bi.frameEntries[i].CIE.CIE_id == ^uint32(0) {
bi.frameEntries[i].Translate(delta)
}
}
}
// Do not call this function directly it isn't able to deal correctly with package paths
func (bi *BinaryInfo) findType(name string) (godwarf.Type, error) {
ref, found := bi.types[name]
if !found {
return nil, reader.ErrTypeNotFound
}
image := bi.Images[ref.imageIndex]
return godwarf.ReadType(image.dwarf, ref.imageIndex, ref.offset, image.typeCache)
}
func (bi *BinaryInfo) findTypeExpr(expr ast.Expr) (godwarf.Type, error) {
if lit, islit := expr.(*ast.BasicLit); islit && lit.Kind == token.STRING {
// Allow users to specify type names verbatim as quoted
// string. Useful as a catch-all workaround for cases where we don't
// parse/serialize types correctly or can not resolve package paths.
typn, _ := strconv.Unquote(lit.Value)
// Check if the type in question is an array type, in which case we try to
// fake it.
if len(typn) > 0 && typn[0] == '[' {
closedBrace := strings.Index(typn, "]")
if closedBrace > 1 {
n, err := strconv.Atoi(typn[1:closedBrace])
if err == nil {
return bi.findArrayType(n, typn[closedBrace+1:])
}
}
}
return bi.findType(typn)
}
bi.expandPackagesInType(expr)
if snode, ok := expr.(*ast.StarExpr); ok {
// Pointer types only appear in the dwarf informations when
// a pointer to the type is used in the target program, here
// we create a pointer type on the fly so that the user can
// specify a pointer to any variable used in the target program
ptyp, err := bi.findTypeExpr(snode.X)
if err != nil {
return nil, err
}
return pointerTo(ptyp, bi.Arch), nil
}
if anode, ok := expr.(*ast.ArrayType); ok {
// Array types (for example [N]byte) are only present in DWARF if they are
// used by the program, but it's convenient to make all of them available
// to the user for two reasons:
// 1. to allow reading arbitrary memory byte-by-byte (by casting an
// address to an array of bytes).
// 2. to read the contents of a channel's buffer (we create fake array
// types for them)
alen, litlen := anode.Len.(*ast.BasicLit)
if litlen && alen.Kind == token.INT {
n, _ := strconv.Atoi(alen.Value)
return bi.findArrayType(n, exprToString(anode.Elt))
}
}
return bi.findType(exprToString(expr))
}
func (bi *BinaryInfo) findArrayType(n int, etyp string) (godwarf.Type, error) {
switch etyp {
case "byte", "uint8":
etyp = "uint8"
fallthrough
default:
btyp, err := bi.findType(etyp)
if err != nil {
return nil, err
}
return fakeArrayType(uint64(n), btyp), nil
}
}
func complexType(typename string) bool {
for _, ch := range typename {
switch ch {
case '*', '[', '<', '{', '(', ' ':
return true
}
}
return false
}
func (bi *BinaryInfo) registerTypeToPackageMap(entry *dwarf.Entry) {
if entry.Tag != dwarf.TagTypedef && entry.Tag != dwarf.TagBaseType && entry.Tag != dwarf.TagClassType && entry.Tag != dwarf.TagStructType {
return
}
typename, ok := entry.Val(dwarf.AttrName).(string)
if !ok || complexType(typename) {
return
}
dot := strings.LastIndex(typename, ".")
if dot < 0 {
return
}
path := typename[:dot]
slash := strings.LastIndex(path, "/")
if slash < 0 || slash+1 >= len(path) {
return
}
name := path[slash+1:]
bi.PackageMap[name] = []string{path}
}
func (bi *BinaryInfo) loadDebugInfoMaps(image *Image, debugInfoBytes, debugLineBytes []byte, wg *sync.WaitGroup, cont func()) {
if wg != nil {
defer wg.Done()
}
if bi.types == nil {
bi.types = make(map[string]dwarfRef)
}
if bi.consts == nil {
bi.consts = make(map[dwarfRef]*constantType)
}
if bi.PackageMap == nil {
bi.PackageMap = make(map[string][]string)
}
if bi.inlinedCallLines == nil {
bi.inlinedCallLines = make(map[fileLine][]uint64)
}
if bi.dwrapUnwrapCache == nil {
bi.dwrapUnwrapCache = make(map[uint64]*Function)
}
image.runtimeTypeToDIE = make(map[uint64]runtimeTypeDIE)
ctxt := newLoadDebugInfoMapsContext(bi, image, util.ReadUnitVersions(debugInfoBytes))
reader := image.DwarfReader()
for entry, err := reader.Next(); entry != nil; entry, err = reader.Next() {
if err != nil {
image.setLoadError("error reading debug_info: %v", err)
break
}
switch entry.Tag {
case dwarf.TagCompileUnit:
cu := &compileUnit{}
cu.image = image
cu.entry = entry
cu.offset = entry.Offset
cu.Version = ctxt.offsetToVersion[cu.offset]
if lang, _ := entry.Val(dwarf.AttrLanguage).(int64); lang == dwarfGoLanguage {
cu.isgo = true
}
cu.name, _ = entry.Val(dwarf.AttrName).(string)
compdir, _ := entry.Val(dwarf.AttrCompDir).(string)
if compdir != "" {
cu.name = filepath.Join(compdir, cu.name)
}
cu.ranges, _ = image.dwarf.Ranges(entry)
for i := range cu.ranges {
cu.ranges[i][0] += image.StaticBase
cu.ranges[i][1] += image.StaticBase
}
if len(cu.ranges) >= 1 {
cu.lowPC = cu.ranges[0][0]
}
lineInfoOffset, hasLineInfo := entry.Val(dwarf.AttrStmtList).(int64)
if hasLineInfo && lineInfoOffset >= 0 && lineInfoOffset < int64(len(debugLineBytes)) {
var logfn func(string, ...interface{})
if logflags.DebugLineErrors() {
logger := logrus.New().WithFields(logrus.Fields{"layer": "dwarf-line"})
logger.Logger.Level = logrus.DebugLevel
logfn = func(fmt string, args ...interface{}) {
logger.Printf(fmt, args)
}
}
cu.lineInfo = line.Parse(compdir, bytes.NewBuffer(debugLineBytes[lineInfoOffset:]), image.debugLineStr, logfn, image.StaticBase, bi.GOOS == "windows", bi.Arch.PtrSize())
}
cu.producer, _ = entry.Val(dwarf.AttrProducer).(string)
if cu.isgo && cu.producer != "" {
semicolon := strings.Index(cu.producer, ";")
if semicolon < 0 {
cu.optimized = goversion.ProducerAfterOrEqual(cu.producer, 1, 10)
} else {
cu.optimized = !strings.Contains(cu.producer[semicolon:], "-N") || !strings.Contains(cu.producer[semicolon:], "-l")
const regabi = " regabi"
if i := strings.Index(cu.producer[semicolon:], regabi); i > 0 {
i += semicolon
if i+len(regabi) >= len(cu.producer) || cu.producer[i+len(regabi)] == ' ' {
bi.regabi = true
}
}
cu.producer = cu.producer[:semicolon]
}
}
gopkg, _ := entry.Val(godwarf.AttrGoPackageName).(string)
if cu.isgo && gopkg != "" {
bi.PackageMap[gopkg] = append(bi.PackageMap[gopkg], escapePackagePath(strings.Replace(cu.name, "\\", "/", -1)))
}
image.compileUnits = append(image.compileUnits, cu)
if entry.Children {
bi.loadDebugInfoMapsCompileUnit(ctxt, image, reader, cu)
}
case dwarf.TagPartialUnit:
reader.SkipChildren()
default:
// ignore unknown tags
reader.SkipChildren()
}
}
sort.Sort(compileUnitsByOffset(image.compileUnits))
sort.Sort(functionsDebugInfoByEntry(bi.Functions))
sort.Sort(packageVarsByAddr(bi.packageVars))
bi.LookupFunc = make(map[string]*Function)
for i := range bi.Functions {
bi.LookupFunc[bi.Functions[i].Name] = &bi.Functions[i]
}
for _, cu := range image.compileUnits {
if cu.lineInfo != nil {
for _, fileEntry := range cu.lineInfo.FileNames {
bi.Sources = append(bi.Sources, fileEntry.Path)
}
}
}
sort.Strings(bi.Sources)
bi.Sources = uniq(bi.Sources)
if bi.regabi {
// prepare patch for runtime.mallocgc's DIE
fn := bi.LookupFunc["runtime.mallocgc"]
if fn != nil && fn.cu.image == image {
tree, err := image.getDwarfTree(fn.offset)
if err == nil {
tree.Children, err = regabiMallocgcWorkaround(bi)
if err != nil {
bi.logger.Errorf("could not patch runtime.mallogc: %v", err)
} else {
image.runtimeMallocgcTree = tree
}
}
}
}
if cont != nil {
cont()
}
}
// loadDebugInfoMapsCompileUnit loads entry from a single compile unit.
func (bi *BinaryInfo) loadDebugInfoMapsCompileUnit(ctxt *loadDebugInfoMapsContext, image *Image, reader *reader.Reader, cu *compileUnit) {
hasAttrGoPkgName := goversion.ProducerAfterOrEqual(cu.producer, 1, 13)
depth := 0
for entry, err := reader.Next(); entry != nil; entry, err = reader.Next() {
if err != nil {
image.setLoadError("error reading debug_info: %v", err)
return
}
switch entry.Tag {
case 0:
if depth == 0 {
return
} else {
depth--
}
case dwarf.TagImportedUnit:
bi.loadDebugInfoMapsImportedUnit(entry, ctxt, image, cu)
reader.SkipChildren()
case dwarf.TagArrayType, dwarf.TagBaseType, dwarf.TagClassType, dwarf.TagStructType, dwarf.TagUnionType, dwarf.TagConstType, dwarf.TagVolatileType, dwarf.TagRestrictType, dwarf.TagEnumerationType, dwarf.TagPointerType, dwarf.TagSubroutineType, dwarf.TagTypedef, dwarf.TagUnspecifiedType:
if name, ok := entry.Val(dwarf.AttrName).(string); ok {
if !cu.isgo {
name = "C." + name
}
if _, exists := bi.types[name]; !exists {
bi.types[name] = dwarfRef{image.index, entry.Offset}
}
}
if cu != nil && cu.isgo && !hasAttrGoPkgName {
bi.registerTypeToPackageMap(entry)
}
image.registerRuntimeTypeToDIE(entry, ctxt.ardr)
reader.SkipChildren()
case dwarf.TagVariable:
if n, ok := entry.Val(dwarf.AttrName).(string); ok {
var addr uint64
if loc, ok := entry.Val(dwarf.AttrLocation).([]byte); ok {
if len(loc) == bi.Arch.PtrSize()+1 && op.Opcode(loc[0]) == op.DW_OP_addr {
addr, _ = util.ReadUintRaw(bytes.NewReader(loc[1:]), binary.LittleEndian, bi.Arch.PtrSize())
}
}
if !cu.isgo {
n = "C." + n
}
if _, known := ctxt.knownPackageVars[n]; !known {
bi.packageVars = append(bi.packageVars, packageVar{n, cu, entry.Offset, addr + image.StaticBase})
}
}
reader.SkipChildren()
case dwarf.TagConstant:
name, okName := entry.Val(dwarf.AttrName).(string)
typ, okType := entry.Val(dwarf.AttrType).(dwarf.Offset)
val, okVal := entry.Val(dwarf.AttrConstValue).(int64)
if okName && okType && okVal {
if !cu.isgo {
name = "C." + name
}
ct := bi.consts[dwarfRef{image.index, typ}]
if ct == nil {
ct = &constantType{}
bi.consts[dwarfRef{image.index, typ}] = ct
}
ct.values = append(ct.values, constantValue{name: name, fullName: name, value: val})
}
reader.SkipChildren()
case dwarf.TagSubprogram:
inlined := false
if inval, ok := entry.Val(dwarf.AttrInline).(int64); ok {
inlined = inval == 1
}
if inlined {
bi.addAbstractSubprogram(entry, ctxt, reader, image, cu)
} else {
originOffset, hasAbstractOrigin := entry.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset)
if hasAbstractOrigin {
bi.addConcreteInlinedSubprogram(entry, originOffset, ctxt, reader, cu)
} else {
bi.addConcreteSubprogram(entry, ctxt, reader, cu)
}
}
default:
if entry.Children {
depth++
}
}
}
}
// loadDebugInfoMapsImportedUnit loads entries into cu from the partial unit
// referenced in a DW_TAG_imported_unit entry.
func (bi *BinaryInfo) loadDebugInfoMapsImportedUnit(entry *dwarf.Entry, ctxt *loadDebugInfoMapsContext, image *Image, cu *compileUnit) {
off, ok := entry.Val(dwarf.AttrImport).(dwarf.Offset)
if !ok {
return
}
reader := image.DwarfReader()
reader.Seek(off)
imentry, err := reader.Next()
if err != nil {
return
}
if imentry.Tag != dwarf.TagPartialUnit {
return
}
bi.loadDebugInfoMapsCompileUnit(ctxt, image, reader, cu)
}
// addAbstractSubprogram adds the abstract entry for an inlined function.
func (bi *BinaryInfo) addAbstractSubprogram(entry *dwarf.Entry, ctxt *loadDebugInfoMapsContext, reader *reader.Reader, image *Image, cu *compileUnit) {
name, ok := subprogramEntryName(entry, cu)
if !ok {
bi.logger.Warnf("reading debug_info: abstract subprogram without name at %#x", entry.Offset)
// In some cases clang produces abstract subprograms that do not have a
// name, but we should process them anyway.
}
if entry.Children {
bi.loadDebugInfoMapsInlinedCalls(ctxt, reader, cu)
}
originIdx := ctxt.lookupAbstractOrigin(bi, entry.Offset)
fn := &bi.Functions[originIdx]
fn.Name = name
fn.offset = entry.Offset
fn.cu = cu
}
// addConcreteInlinedSubprogram adds the concrete entry of a subprogram that was also inlined.
func (bi *BinaryInfo) addConcreteInlinedSubprogram(entry *dwarf.Entry, originOffset dwarf.Offset, ctxt *loadDebugInfoMapsContext, reader *reader.Reader, cu *compileUnit) {
lowpc, highpc, ok := subprogramEntryRange(entry, cu.image)
if !ok {
bi.logger.Warnf("reading debug_info: concrete inlined subprogram without address range at %#x", entry.Offset)
if entry.Children {
reader.SkipChildren()
}
return
}
originIdx := ctxt.lookupAbstractOrigin(bi, originOffset)
fn := &bi.Functions[originIdx]
fn.offset = entry.Offset
fn.Entry = lowpc
fn.End = highpc
fn.cu = cu
if entry.Children {
bi.loadDebugInfoMapsInlinedCalls(ctxt, reader, cu)
}
}
// addConcreteSubprogram adds a concrete subprogram (a normal subprogram
// that doesn't have abstract or inlined entries)
func (bi *BinaryInfo) addConcreteSubprogram(entry *dwarf.Entry, ctxt *loadDebugInfoMapsContext, reader *reader.Reader, cu *compileUnit) {
lowpc, highpc, ok := subprogramEntryRange(entry, cu.image)
if !ok {
bi.logger.Warnf("reading debug_info: concrete subprogram without address range at %#x", entry.Offset)
// When clang inlines a function, in some cases, it produces a concrete
// subprogram without address range and then inlined calls that reference
// it, instead of producing an abstract subprogram.
// It is unclear if this behavior is standard.
}
name, ok := subprogramEntryName(entry, cu)
if !ok {
bi.logger.Warnf("reading debug_info: concrete subprogram without name at %#x", entry.Offset)
}
trampoline, _ := entry.Val(dwarf.AttrTrampoline).(bool)
originIdx := ctxt.lookupAbstractOrigin(bi, entry.Offset)
fn := &bi.Functions[originIdx]
fn.Name = name
fn.Entry = lowpc
fn.End = highpc
fn.offset = entry.Offset
fn.cu = cu
fn.trampoline = trampoline
if entry.Children {
bi.loadDebugInfoMapsInlinedCalls(ctxt, reader, cu)
}
}
func subprogramEntryName(entry *dwarf.Entry, cu *compileUnit) (string, bool) {
name, ok := entry.Val(dwarf.AttrName).(string)
if !ok {
return "", false
}
if !cu.isgo {
name = "C." + name
}
return name, true
}
func subprogramEntryRange(entry *dwarf.Entry, image *Image) (lowpc, highpc uint64, ok bool) {
ok = false
if ranges, _ := image.dwarf.Ranges(entry); len(ranges) >= 1 {
ok = true
lowpc = ranges[0][0] + image.StaticBase
highpc = ranges[0][1] + image.StaticBase
}
return lowpc, highpc, ok
}
func (bi *BinaryInfo) loadDebugInfoMapsInlinedCalls(ctxt *loadDebugInfoMapsContext, reader *reader.Reader, cu *compileUnit) {
for {
entry, err := reader.Next()
if err != nil {
cu.image.setLoadError("error reading debug_info: %v", err)
return
}
switch entry.Tag {
case 0:
return
case dwarf.TagInlinedSubroutine:
originOffset, ok := entry.Val(dwarf.AttrAbstractOrigin).(dwarf.Offset)
if !ok {
bi.logger.Warnf("reading debug_info: inlined call without origin offset at %#x", entry.Offset)
reader.SkipChildren()
continue
}
lowpc, highpc, ok := subprogramEntryRange(entry, cu.image)
if !ok {
bi.logger.Warnf("reading debug_info: inlined call without address range at %#x", entry.Offset)
reader.SkipChildren()
continue
}
callfileidx, ok1 := entry.Val(dwarf.AttrCallFile).(int64)
callline, ok2 := entry.Val(dwarf.AttrCallLine).(int64)
if !ok1 || !ok2 {
bi.logger.Warnf("reading debug_info: inlined call without CallFile/CallLine at %#x", entry.Offset)
reader.SkipChildren()
continue
}
callfile, cferr := cu.filePath(int(callfileidx), entry)
if cferr != nil {
bi.logger.Warnf("%v", cferr)
reader.SkipChildren()
continue
}
originIdx := ctxt.lookupAbstractOrigin(bi, originOffset)
fn := &bi.Functions[originIdx]
fn.InlinedCalls = append(fn.InlinedCalls, InlinedCall{
cu: cu,
LowPC: lowpc,
HighPC: highpc,
})
if fn.cu == nil {
fn.cu = cu
}
fl := fileLine{callfile, int(callline)}
bi.inlinedCallLines[fl] = append(bi.inlinedCallLines[fl], lowpc)
}
reader.SkipChildren()
}
}
func uniq(s []string) []string {
if len(s) <= 0 {
return s
}
src, dst := 1, 1
for src < len(s) {
if s[src] != s[dst-1] {
s[dst] = s[src]
dst++
}
src++
}
return s[:dst]
}
func (bi *BinaryInfo) expandPackagesInType(expr ast.Expr) {
switch e := expr.(type) {
case *ast.ArrayType:
bi.expandPackagesInType(e.Elt)
case *ast.ChanType:
bi.expandPackagesInType(e.Value)
case *ast.FuncType:
for i := range e.Params.List {
bi.expandPackagesInType(e.Params.List[i].Type)
}
if e.Results != nil {
for i := range e.Results.List {
bi.expandPackagesInType(e.Results.List[i].Type)
}
}
case *ast.MapType:
bi.expandPackagesInType(e.Key)
bi.expandPackagesInType(e.Value)
case *ast.ParenExpr:
bi.expandPackagesInType(e.X)
case *ast.SelectorExpr:
switch x := e.X.(type) {
case *ast.Ident:
if len(bi.PackageMap[x.Name]) > 0 {
// There's no particular reason to expect the first entry to be the
// correct one if the package name is ambiguous, but trying all possible
// expansions of all types mentioned in the expression is complicated
// and, besides type assertions, users can always specify the type they
// want exactly, using a string.
x.Name = bi.PackageMap[x.Name][0]
}
default:
bi.expandPackagesInType(e.X)
}
case *ast.StarExpr:
bi.expandPackagesInType(e.X)
default:
// nothing to do
}
}
// escapePackagePath returns pkg with '.' replaced with '%2e' (in all
// elements of the path except the first one) like Go does in variable and
// type names.
func escapePackagePath(pkg string) string {
slash := strings.Index(pkg, "/")
if slash < 0 {
slash = 0
}
return pkg[:slash] + strings.Replace(pkg[slash:], ".", "%2e", -1)
}
// Looks up symbol (either functions or global variables) at address addr.
// Used by disassembly formatter.
func (bi *BinaryInfo) symLookup(addr uint64) (string, uint64) {
fn := bi.PCToFunc(addr)
if fn != nil {
if fn.Entry == addr {
// only report the function name if it's the exact address because it's
// easier to read the absolute address than function_name+offset.
return fn.Name, fn.Entry
}
return "", 0
}
if sym, ok := bi.SymNames[addr]; ok {
return sym.Name, addr
}
i := sort.Search(len(bi.packageVars), func(i int) bool {
return bi.packageVars[i].addr >= addr
})
if i >= len(bi.packageVars) {
return "", 0
}
if bi.packageVars[i].addr > addr {
// report previous variable + offset if i-th variable starts after addr
i--
}
if i >= 0 && bi.packageVars[i].addr != 0 {
return bi.packageVars[i].name, bi.packageVars[i].addr
}
return "", 0
}
type PackageBuildInfo struct {
ImportPath string
DirectoryPath string
Files map[string]struct{}
}
// ListPackagesBuildInfo returns the list of packages used by the program along with
// the directory where each package was compiled and optionally the list of
// files constituting the package.
func (bi *BinaryInfo) ListPackagesBuildInfo(includeFiles bool) []*PackageBuildInfo {
m := make(map[string]*PackageBuildInfo)
for _, cu := range bi.Images[0].compileUnits {
if cu.image != bi.Images[0] || !cu.isgo || cu.lineInfo == nil {
//TODO(aarzilli): what's the correct thing to do for plugins?
continue
}
ip := strings.Replace(cu.name, "\\", "/", -1)
if _, ok := m[ip]; !ok {
path := cu.lineInfo.FirstFile()
if ext := filepath.Ext(path); ext != ".go" && ext != ".s" {
continue
}
dp := filepath.Dir(path)
m[ip] = &PackageBuildInfo{
ImportPath: ip,
DirectoryPath: dp,
Files: make(map[string]struct{}),
}
}
if includeFiles {
pbi := m[ip]
for _, file := range cu.lineInfo.FileNames {
pbi.Files[file.Path] = struct{}{}
}
}
}
r := make([]*PackageBuildInfo, 0, len(m))
for _, pbi := range m {
r = append(r, pbi)
}
sort.Slice(r, func(i, j int) bool { return r[i].ImportPath < r[j].ImportPath })
return r
}
// cuFilePath takes a compilation unit "cu" and a file index reference
// "fileidx" and returns the corresponding file name entry from the
// DWARF line table associated with the unit; "entry" is the offset of
// the attribute where the file reference originated, for logging
// purposes. Return value is the file string and an error value; error
// will be non-nil if the file could not be recovered, perhaps due to
// malformed DWARF.
func (cu *compileUnit) filePath(fileidx int, entry *dwarf.Entry) (string, error) {
if cu.lineInfo == nil {
return "", fmt.Errorf("reading debug_info: file reference within a compilation unit without debug_line section at %#x", entry.Offset)
}
// File numbering is slightly different before and after DWARF 5;
// account for this here. See section 6.2.4 of the DWARF 5 spec.
if cu.Version < 5 {
fileidx--
}
if fileidx < 0 || fileidx >= len(cu.lineInfo.FileNames) {
return "", fmt.Errorf("reading debug_info: file index (%d) out of range in compile unit file table at %#x", fileidx, entry.Offset)
}
return cu.lineInfo.FileNames[fileidx].Path, nil
}
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