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bee/vendor/github.com/derekparker/delve/pkg/proc/proc.go

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2017-03-19 22:45:54 +00:00
package proc
import (
"debug/gosym"
"encoding/binary"
"errors"
"fmt"
"go/ast"
"go/constant"
"go/token"
"os"
"path/filepath"
"runtime"
"strconv"
"strings"
"sync"
"time"
"github.com/derekparker/delve/pkg/dwarf/frame"
"github.com/derekparker/delve/pkg/dwarf/line"
"github.com/derekparker/delve/pkg/dwarf/reader"
"golang.org/x/debug/dwarf"
)
// Process represents all of the information the debugger
// is holding onto regarding the process we are debugging.
type Process struct {
pid int // Process Pid
Process *os.Process // Pointer to process struct for the actual process we are debugging
lastModified time.Time // Time the executable of this process was last modified
// Breakpoint table, holds information on breakpoints.
// Maps instruction address to Breakpoint struct.
breakpoints map[uint64]*Breakpoint
// List of threads mapped as such: pid -> *Thread
threads map[int]*Thread
// Active thread
currentThread *Thread
// Goroutine that will be used by default to set breakpoint, eval variables, etc...
// Normally selectedGoroutine is currentThread.GetG, it will not be only if SwitchGoroutine is called with a goroutine that isn't attached to a thread
selectedGoroutine *G
// Maps package names to package paths, needed to lookup types inside DWARF info
packageMap map[string]string
allGCache []*G
dwarf *dwarf.Data
goSymTable *gosym.Table
frameEntries frame.FrameDescriptionEntries
lineInfo line.DebugLines
os *OSProcessDetails
arch Arch
breakpointIDCounter int
internalBreakpointIDCounter int
firstStart bool
halt bool
exited bool
ptraceChan chan func()
ptraceDoneChan chan interface{}
types map[string]dwarf.Offset
functions []functionDebugInfo
loadModuleDataOnce sync.Once
moduleData []moduleData
nameOfRuntimeType map[uintptr]nameOfRuntimeTypeEntry
}
type functionDebugInfo struct {
lowpc, highpc uint64
offset dwarf.Offset
}
var NotExecutableErr = errors.New("not an executable file")
// New returns an initialized Process struct. Before returning,
// it will also launch a goroutine in order to handle ptrace(2)
// functions. For more information, see the documentation on
// `handlePtraceFuncs`.
func New(pid int) *Process {
dbp := &Process{
pid: pid,
threads: make(map[int]*Thread),
breakpoints: make(map[uint64]*Breakpoint),
firstStart: true,
os: new(OSProcessDetails),
ptraceChan: make(chan func()),
ptraceDoneChan: make(chan interface{}),
nameOfRuntimeType: make(map[uintptr]nameOfRuntimeTypeEntry),
}
// TODO: find better way to determine proc arch (perhaps use executable file info)
switch runtime.GOARCH {
case "amd64":
dbp.arch = AMD64Arch()
}
go dbp.handlePtraceFuncs()
return dbp
}
// ProcessExitedError indicates that the process has exited and contains both
// process id and exit status.
type ProcessExitedError struct {
Pid int
Status int
}
func (pe ProcessExitedError) Error() string {
return fmt.Sprintf("Process %d has exited with status %d", pe.Pid, pe.Status)
}
// Detach from the process being debugged, optionally killing it.
func (dbp *Process) Detach(kill bool) (err error) {
if dbp.exited {
return nil
}
if dbp.Running() {
if err = dbp.Halt(); err != nil {
return
}
}
if !kill {
// Clean up any breakpoints we've set.
for _, bp := range dbp.breakpoints {
if bp != nil {
_, err := dbp.ClearBreakpoint(bp.Addr)
if err != nil {
return err
}
}
}
}
dbp.execPtraceFunc(func() {
err = PtraceDetach(dbp.pid, 0)
if err != nil {
return
}
if kill {
err = killProcess(dbp.pid)
}
})
return
}
// Exited returns whether the debugged
// process has exited.
func (dbp *Process) Exited() bool {
return dbp.exited
}
// Running returns whether the debugged
// process is currently executing.
func (dbp *Process) Running() bool {
for _, th := range dbp.threads {
if th.running {
return true
}
}
return false
}
func (dbp *Process) LastModified() time.Time {
return dbp.lastModified
}
func (dbp *Process) Pid() int {
return dbp.pid
}
func (dbp *Process) SelectedGoroutine() *G {
return dbp.selectedGoroutine
}
func (dbp *Process) Threads() map[int]*Thread {
return dbp.threads
}
func (dbp *Process) CurrentThread() *Thread {
return dbp.currentThread
}
func (dbp *Process) Breakpoints() map[uint64]*Breakpoint {
return dbp.breakpoints
}
// LoadInformation finds the executable and then uses it
// to parse the following information:
// * Dwarf .debug_frame section
// * Dwarf .debug_line section
// * Go symbol table.
func (dbp *Process) LoadInformation(path string) error {
var wg sync.WaitGroup
exe, path, err := dbp.findExecutable(path)
if err != nil {
return err
}
fi, err := os.Stat(path)
if err == nil {
dbp.lastModified = fi.ModTime()
}
wg.Add(5)
go dbp.loadProcessInformation(&wg)
go dbp.parseDebugFrame(exe, &wg)
go dbp.obtainGoSymbols(exe, &wg)
go dbp.parseDebugLineInfo(exe, &wg)
go dbp.loadDebugInfoMaps(&wg)
wg.Wait()
return nil
}
// FindFileLocation returns the PC for a given file:line.
// Assumes that `file` is normailzed to lower case and '/' on Windows.
func (dbp *Process) FindFileLocation(fileName string, lineno int) (uint64, error) {
pc, fn, err := dbp.goSymTable.LineToPC(fileName, lineno)
if err != nil {
return 0, err
}
if fn.Entry == pc {
pc, _ = dbp.FirstPCAfterPrologue(fn, true)
}
return pc, nil
}
// FindFunctionLocation finds address of a function's line
// If firstLine == true is passed FindFunctionLocation will attempt to find the first line of the function
// If lineOffset is passed FindFunctionLocation will return the address of that line
// Pass lineOffset == 0 and firstLine == false if you want the address for the function's entry point
// Note that setting breakpoints at that address will cause surprising behavior:
// https://github.com/derekparker/delve/issues/170
func (dbp *Process) FindFunctionLocation(funcName string, firstLine bool, lineOffset int) (uint64, error) {
origfn := dbp.goSymTable.LookupFunc(funcName)
if origfn == nil {
return 0, fmt.Errorf("Could not find function %s\n", funcName)
}
if firstLine {
return dbp.FirstPCAfterPrologue(origfn, false)
} else if lineOffset > 0 {
filename, lineno, _ := dbp.goSymTable.PCToLine(origfn.Entry)
breakAddr, _, err := dbp.goSymTable.LineToPC(filename, lineno+lineOffset)
return breakAddr, err
}
return origfn.Entry, nil
}
// CurrentLocation returns the location of the current thread.
func (dbp *Process) CurrentLocation() (*Location, error) {
return dbp.currentThread.Location()
}
// RequestManualStop sets the `halt` flag and
// sends SIGSTOP to all threads.
func (dbp *Process) RequestManualStop() error {
if dbp.exited {
return &ProcessExitedError{}
}
dbp.halt = true
return dbp.requestManualStop()
}
// SetBreakpoint sets a breakpoint at addr, and stores it in the process wide
// break point table. Setting a break point must be thread specific due to
// ptrace actions needing the thread to be in a signal-delivery-stop.
func (dbp *Process) SetBreakpoint(addr uint64, kind BreakpointKind, cond ast.Expr) (*Breakpoint, error) {
tid := dbp.currentThread.ID
if bp, ok := dbp.FindBreakpoint(addr); ok {
return nil, BreakpointExistsError{bp.File, bp.Line, bp.Addr}
}
f, l, fn := dbp.goSymTable.PCToLine(uint64(addr))
if fn == nil {
return nil, InvalidAddressError{address: addr}
}
newBreakpoint := &Breakpoint{
FunctionName: fn.Name,
File: f,
Line: l,
Addr: addr,
Kind: kind,
Cond: cond,
HitCount: map[int]uint64{},
}
if kind != UserBreakpoint {
dbp.internalBreakpointIDCounter++
newBreakpoint.ID = dbp.internalBreakpointIDCounter
} else {
dbp.breakpointIDCounter++
newBreakpoint.ID = dbp.breakpointIDCounter
}
thread := dbp.threads[tid]
originalData, err := thread.readMemory(uintptr(addr), dbp.arch.BreakpointSize())
if err != nil {
return nil, err
}
if err := dbp.writeSoftwareBreakpoint(thread, addr); err != nil {
return nil, err
}
newBreakpoint.OriginalData = originalData
dbp.breakpoints[addr] = newBreakpoint
return newBreakpoint, nil
}
// ClearBreakpoint clears the breakpoint at addr.
func (dbp *Process) ClearBreakpoint(addr uint64) (*Breakpoint, error) {
if dbp.exited {
return nil, &ProcessExitedError{}
}
bp, ok := dbp.FindBreakpoint(addr)
if !ok {
return nil, NoBreakpointError{addr: addr}
}
if _, err := bp.Clear(dbp.currentThread); err != nil {
return nil, err
}
delete(dbp.breakpoints, addr)
return bp, nil
}
// Status returns the status of the current main thread context.
func (dbp *Process) Status() *WaitStatus {
return dbp.currentThread.Status
}
// Next continues execution until the next source line.
func (dbp *Process) Next() (err error) {
if dbp.exited {
return &ProcessExitedError{}
}
for i := range dbp.breakpoints {
if dbp.breakpoints[i].Internal() {
return fmt.Errorf("next while nexting")
}
}
if err = dbp.next(false); err != nil {
switch err.(type) {
case ThreadBlockedError, NoReturnAddr: // Noop
default:
dbp.ClearInternalBreakpoints()
return
}
}
return dbp.Continue()
}
// Continue continues execution of the debugged
// process. It will continue until it hits a breakpoint
// or is otherwise stopped.
func (dbp *Process) Continue() error {
if dbp.exited {
return &ProcessExitedError{}
}
for {
if err := dbp.resume(); err != nil {
return err
}
dbp.allGCache = nil
for _, th := range dbp.threads {
th.clearBreakpointState()
}
trapthread, err := dbp.trapWait(-1)
if err != nil {
return err
}
if err := dbp.Halt(); err != nil {
return dbp.exitGuard(err)
}
if err := dbp.setCurrentBreakpoints(trapthread); err != nil {
return err
}
if err := dbp.pickCurrentThread(trapthread); err != nil {
return err
}
switch {
case dbp.currentThread.CurrentBreakpoint == nil:
// runtime.Breakpoint or manual stop
if dbp.currentThread.onRuntimeBreakpoint() {
// Single-step current thread until we exit runtime.breakpoint and
// runtime.Breakpoint.
// On go < 1.8 it was sufficient to single-step twice on go1.8 a change
// to the compiler requires 4 steps.
for {
if err = dbp.currentThread.StepInstruction(); err != nil {
return err
}
loc, err := dbp.currentThread.Location()
if err != nil || loc.Fn == nil || (loc.Fn.Name != "runtime.breakpoint" && loc.Fn.Name != "runtime.Breakpoint") {
break
}
}
}
return dbp.conditionErrors()
case dbp.currentThread.onTriggeredInternalBreakpoint():
if dbp.currentThread.CurrentBreakpoint.Kind == StepBreakpoint {
// See description of proc.(*Process).next for the meaning of StepBreakpoints
if err := dbp.conditionErrors(); err != nil {
return err
}
pc, err := dbp.currentThread.PC()
if err != nil {
return err
}
text, err := dbp.currentThread.Disassemble(pc, pc+maxInstructionLength, true)
if err != nil {
return err
}
// here we either set a breakpoint into the destination of the CALL
// instruction or we determined that the called function is hidden,
// either way we need to resume execution
if err = dbp.setStepIntoBreakpoint(text, sameGoroutineCondition(dbp.selectedGoroutine)); err != nil {
return err
}
} else {
if err := dbp.ClearInternalBreakpoints(); err != nil {
return err
}
return dbp.conditionErrors()
}
case dbp.currentThread.onTriggeredBreakpoint():
onNextGoroutine, err := dbp.currentThread.onNextGoroutine()
if err != nil {
return err
}
if onNextGoroutine {
err := dbp.ClearInternalBreakpoints()
if err != nil {
return err
}
}
return dbp.conditionErrors()
default:
// not a manual stop, not on runtime.Breakpoint, not on a breakpoint, just repeat
}
}
}
func (dbp *Process) conditionErrors() error {
var condErr error
for _, th := range dbp.threads {
if th.CurrentBreakpoint != nil && th.BreakpointConditionError != nil {
if condErr == nil {
condErr = th.BreakpointConditionError
} else {
return fmt.Errorf("multiple errors evaluating conditions")
}
}
}
return condErr
}
// pick a new dbp.currentThread, with the following priority:
// - a thread with onTriggeredInternalBreakpoint() == true
// - a thread with onTriggeredBreakpoint() == true (prioritizing trapthread)
// - trapthread
func (dbp *Process) pickCurrentThread(trapthread *Thread) error {
for _, th := range dbp.threads {
if th.onTriggeredInternalBreakpoint() {
return dbp.SwitchThread(th.ID)
}
}
if trapthread.onTriggeredBreakpoint() {
return dbp.SwitchThread(trapthread.ID)
}
for _, th := range dbp.threads {
if th.onTriggeredBreakpoint() {
return dbp.SwitchThread(th.ID)
}
}
return dbp.SwitchThread(trapthread.ID)
}
// Step will continue until another source line is reached.
// Will step into functions.
func (dbp *Process) Step() (err error) {
if dbp.exited {
return &ProcessExitedError{}
}
for i := range dbp.breakpoints {
if dbp.breakpoints[i].Internal() {
return fmt.Errorf("next while nexting")
}
}
if err = dbp.next(true); err != nil {
switch err.(type) {
case ThreadBlockedError, NoReturnAddr: // Noop
default:
dbp.ClearInternalBreakpoints()
return
}
}
return dbp.Continue()
}
// Returns an expression that evaluates to true when the current goroutine is g
func sameGoroutineCondition(g *G) ast.Expr {
if g == nil {
return nil
}
return &ast.BinaryExpr{
Op: token.EQL,
X: &ast.SelectorExpr{
X: &ast.SelectorExpr{
X: &ast.Ident{Name: "runtime"},
Sel: &ast.Ident{Name: "curg"},
},
Sel: &ast.Ident{Name: "goid"},
},
Y: &ast.BasicLit{Kind: token.INT, Value: strconv.Itoa(g.ID)},
}
}
// StepInstruction will continue the current thread for exactly
// one instruction. This method affects only the thread
// asssociated with the selected goroutine. All other
// threads will remain stopped.
func (dbp *Process) StepInstruction() (err error) {
if dbp.selectedGoroutine == nil {
return errors.New("cannot single step: no selected goroutine")
}
if dbp.selectedGoroutine.thread == nil {
// Step called on parked goroutine
if _, err := dbp.SetBreakpoint(dbp.selectedGoroutine.PC, NextBreakpoint, sameGoroutineCondition(dbp.selectedGoroutine)); err != nil {
return err
}
return dbp.Continue()
}
dbp.allGCache = nil
if dbp.exited {
return &ProcessExitedError{}
}
dbp.selectedGoroutine.thread.clearBreakpointState()
err = dbp.selectedGoroutine.thread.StepInstruction()
if err != nil {
return err
}
return dbp.selectedGoroutine.thread.SetCurrentBreakpoint()
}
// StepOut will continue until the current goroutine exits the
// function currently being executed or a deferred function is executed
func (dbp *Process) StepOut() error {
cond := sameGoroutineCondition(dbp.selectedGoroutine)
topframe, err := topframe(dbp.selectedGoroutine, dbp.currentThread)
if err != nil {
return err
}
pcs := []uint64{}
var deferpc uint64 = 0
if filepath.Ext(topframe.Current.File) == ".go" {
if dbp.selectedGoroutine != nil {
deferPCEntry := dbp.selectedGoroutine.DeferPC()
if deferPCEntry != 0 {
_, _, deferfn := dbp.goSymTable.PCToLine(deferPCEntry)
deferpc, err = dbp.FirstPCAfterPrologue(deferfn, false)
if err != nil {
return err
}
pcs = append(pcs, deferpc)
}
}
}
if topframe.Ret == 0 && deferpc == 0 {
return errors.New("nothing to stepout to")
}
if deferpc != 0 && deferpc != topframe.Current.PC {
bp, err := dbp.SetBreakpoint(deferpc, NextDeferBreakpoint, cond)
if err != nil {
if _, ok := err.(BreakpointExistsError); !ok {
dbp.ClearInternalBreakpoints()
return err
}
}
if bp != nil {
// For StepOut we do not want to step into the deferred function
// when it's called by runtime.deferreturn so we do not populate
// DeferReturns.
bp.DeferReturns = []uint64{}
}
}
if topframe.Ret != 0 {
if err := dbp.setInternalBreakpoints(topframe.Current.PC, []uint64{topframe.Ret}, NextBreakpoint, cond); err != nil {
return err
}
}
return dbp.Continue()
}
// SwitchThread changes from current thread to the thread specified by `tid`.
func (dbp *Process) SwitchThread(tid int) error {
if dbp.exited {
return &ProcessExitedError{}
}
if th, ok := dbp.threads[tid]; ok {
dbp.currentThread = th
dbp.selectedGoroutine, _ = dbp.currentThread.GetG()
return nil
}
return fmt.Errorf("thread %d does not exist", tid)
}
// SwitchGoroutine changes from current thread to the thread
// running the specified goroutine.
func (dbp *Process) SwitchGoroutine(gid int) error {
if dbp.exited {
return &ProcessExitedError{}
}
g, err := dbp.FindGoroutine(gid)
if err != nil {
return err
}
if g == nil {
// user specified -1 and selectedGoroutine is nil
return nil
}
if g.thread != nil {
return dbp.SwitchThread(g.thread.ID)
}
dbp.selectedGoroutine = g
return nil
}
// GoroutinesInfo returns an array of G structures representing the information
// Delve cares about from the internal runtime G structure.
func (dbp *Process) GoroutinesInfo() ([]*G, error) {
if dbp.exited {
return nil, &ProcessExitedError{}
}
if dbp.allGCache != nil {
return dbp.allGCache, nil
}
var (
threadg = map[int]*Thread{}
allg []*G
rdr = dbp.DwarfReader()
)
for i := range dbp.threads {
if dbp.threads[i].blocked() {
continue
}
g, _ := dbp.threads[i].GetG()
if g != nil {
threadg[g.ID] = dbp.threads[i]
}
}
addr, err := rdr.AddrFor("runtime.allglen")
if err != nil {
return nil, err
}
allglenBytes, err := dbp.currentThread.readMemory(uintptr(addr), 8)
if err != nil {
return nil, err
}
allglen := binary.LittleEndian.Uint64(allglenBytes)
rdr.Seek(0)
allgentryaddr, err := rdr.AddrFor("runtime.allgs")
if err != nil {
// try old name (pre Go 1.6)
allgentryaddr, err = rdr.AddrFor("runtime.allg")
if err != nil {
return nil, err
}
}
faddr, err := dbp.currentThread.readMemory(uintptr(allgentryaddr), dbp.arch.PtrSize())
allgptr := binary.LittleEndian.Uint64(faddr)
for i := uint64(0); i < allglen; i++ {
gvar, err := dbp.currentThread.newGVariable(uintptr(allgptr+(i*uint64(dbp.arch.PtrSize()))), true)
if err != nil {
return nil, err
}
g, err := gvar.parseG()
if err != nil {
return nil, err
}
if thread, allocated := threadg[g.ID]; allocated {
loc, err := thread.Location()
if err != nil {
return nil, err
}
g.thread = thread
// Prefer actual thread location information.
g.CurrentLoc = *loc
}
if g.Status != Gdead {
allg = append(allg, g)
}
}
dbp.allGCache = allg
return allg, nil
}
func (g *G) Thread() *Thread {
return g.thread
}
// Halt stops all threads.
func (dbp *Process) Halt() (err error) {
if dbp.exited {
return &ProcessExitedError{}
}
for _, th := range dbp.threads {
if err := th.Halt(); err != nil {
return err
}
}
return nil
}
// Registers obtains register values from the
// "current" thread of the traced process.
func (dbp *Process) Registers() (Registers, error) {
return dbp.currentThread.Registers(false)
}
// PC returns the PC of the current thread.
func (dbp *Process) PC() (uint64, error) {
return dbp.currentThread.PC()
}
// CurrentBreakpoint returns the breakpoint the current thread
// is stopped at.
func (dbp *Process) CurrentBreakpoint() *Breakpoint {
return dbp.currentThread.CurrentBreakpoint
}
// DwarfReader returns a reader for the dwarf data
func (dbp *Process) DwarfReader() *reader.Reader {
return reader.New(dbp.dwarf)
}
// Sources returns list of source files that comprise the debugged binary.
func (dbp *Process) Sources() map[string]*gosym.Obj {
return dbp.goSymTable.Files
}
// Funcs returns list of functions present in the debugged program.
func (dbp *Process) Funcs() []gosym.Func {
return dbp.goSymTable.Funcs
}
// Types returns list of types present in the debugged program.
func (dbp *Process) Types() ([]string, error) {
types := make([]string, 0, len(dbp.types))
for k := range dbp.types {
types = append(types, k)
}
return types, nil
}
// PCToLine converts an instruction address to a file/line/function.
func (dbp *Process) PCToLine(pc uint64) (string, int, *gosym.Func) {
return dbp.goSymTable.PCToLine(pc)
}
// FindBreakpointByID finds the breakpoint for the given ID.
func (dbp *Process) FindBreakpointByID(id int) (*Breakpoint, bool) {
for _, bp := range dbp.breakpoints {
if bp.ID == id {
return bp, true
}
}
return nil, false
}
// FindBreakpoint finds the breakpoint for the given pc.
func (dbp *Process) FindBreakpoint(pc uint64) (*Breakpoint, bool) {
// Check to see if address is past the breakpoint, (i.e. breakpoint was hit).
if bp, ok := dbp.breakpoints[pc-uint64(dbp.arch.BreakpointSize())]; ok {
return bp, true
}
// Directly use addr to lookup breakpoint.
if bp, ok := dbp.breakpoints[pc]; ok {
return bp, true
}
return nil, false
}
// Returns a new Process struct.
func initializeDebugProcess(dbp *Process, path string, attach bool) (*Process, error) {
if attach {
var err error
dbp.execPtraceFunc(func() { err = PtraceAttach(dbp.pid) })
if err != nil {
return nil, err
}
_, _, err = dbp.wait(dbp.pid, 0)
if err != nil {
return nil, err
}
}
proc, err := os.FindProcess(dbp.pid)
if err != nil {
return nil, err
}
dbp.Process = proc
err = dbp.LoadInformation(path)
if err != nil {
return nil, err
}
if err := dbp.updateThreadList(); err != nil {
return nil, err
}
ver, isextld, err := dbp.getGoInformation()
if err != nil {
return nil, err
}
dbp.arch.SetGStructOffset(ver, isextld)
// selectedGoroutine can not be set correctly by the call to updateThreadList
// because without calling SetGStructOffset we can not read the G struct of currentThread
// but without calling updateThreadList we can not examine memory to determine
// the offset of g struct inside TLS
dbp.selectedGoroutine, _ = dbp.currentThread.GetG()
panicpc, err := dbp.FindFunctionLocation("runtime.startpanic", true, 0)
if err == nil {
bp, err := dbp.SetBreakpoint(panicpc, UserBreakpoint, nil)
if err == nil {
bp.Name = "unrecovered-panic"
bp.ID = -1
dbp.breakpointIDCounter--
}
}
return dbp, nil
}
func (dbp *Process) ClearInternalBreakpoints() error {
for _, bp := range dbp.breakpoints {
if !bp.Internal() {
continue
}
if _, err := dbp.ClearBreakpoint(bp.Addr); err != nil {
return err
}
}
for i := range dbp.threads {
if dbp.threads[i].CurrentBreakpoint != nil && dbp.threads[i].CurrentBreakpoint.Internal() {
dbp.threads[i].CurrentBreakpoint = nil
}
}
return nil
}
func (dbp *Process) handlePtraceFuncs() {
// We must ensure here that we are running on the same thread during
// while invoking the ptrace(2) syscall. This is due to the fact that ptrace(2) expects
// all commands after PTRACE_ATTACH to come from the same thread.
runtime.LockOSThread()
for fn := range dbp.ptraceChan {
fn()
dbp.ptraceDoneChan <- nil
}
}
func (dbp *Process) execPtraceFunc(fn func()) {
dbp.ptraceChan <- fn
<-dbp.ptraceDoneChan
}
func (dbp *Process) getGoInformation() (ver GoVersion, isextld bool, err error) {
vv, err := dbp.EvalPackageVariable("runtime.buildVersion", LoadConfig{true, 0, 64, 0, 0})
if err != nil {
err = fmt.Errorf("Could not determine version number: %v\n", err)
return
}
if vv.Unreadable != nil {
err = fmt.Errorf("Unreadable version number: %v\n", vv.Unreadable)
return
}
ver, ok := ParseVersionString(constant.StringVal(vv.Value))
if !ok {
err = fmt.Errorf("Could not parse version number: %v\n", vv.Value)
return
}
rdr := dbp.DwarfReader()
rdr.Seek(0)
for entry, err := rdr.NextCompileUnit(); entry != nil; entry, err = rdr.NextCompileUnit() {
if err != nil {
return ver, isextld, err
}
if prod, ok := entry.Val(dwarf.AttrProducer).(string); ok && (strings.HasPrefix(prod, "GNU AS")) {
isextld = true
break
}
}
return
}
// FindGoroutine returns a G struct representing the goroutine
// specified by `gid`.
func (dbp *Process) FindGoroutine(gid int) (*G, error) {
if gid == -1 {
return dbp.selectedGoroutine, nil
}
gs, err := dbp.GoroutinesInfo()
if err != nil {
return nil, err
}
for i := range gs {
if gs[i].ID == gid {
return gs[i], nil
}
}
return nil, fmt.Errorf("Unknown goroutine %d", gid)
}
// ConvertEvalScope returns a new EvalScope in the context of the
// specified goroutine ID and stack frame.
func (dbp *Process) ConvertEvalScope(gid, frame int) (*EvalScope, error) {
if dbp.exited {
return nil, &ProcessExitedError{}
}
g, err := dbp.FindGoroutine(gid)
if err != nil {
return nil, err
}
if g == nil {
return dbp.currentThread.Scope()
}
var out EvalScope
if g.thread == nil {
out.Thread = dbp.currentThread
} else {
out.Thread = g.thread
}
locs, err := g.Stacktrace(frame)
if err != nil {
return nil, err
}
if frame >= len(locs) {
return nil, fmt.Errorf("Frame %d does not exist in goroutine %d", frame, gid)
}
out.PC, out.CFA = locs[frame].Current.PC, locs[frame].CFA
return &out, nil
}
func (dbp *Process) postExit() {
dbp.exited = true
close(dbp.ptraceChan)
close(dbp.ptraceDoneChan)
}