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bee/vendor/github.com/derekparker/delve/pkg/proc/gdbserial/gdbserver.go
2018-10-13 21:45:53 +08:00

1878 lines
49 KiB
Go

// This file and its companion gdbserver_conn implement a target.Interface
// backed by a connection to a debugger speaking the "Gdb Remote Serial
// Protocol".
//
// The "Gdb Remote Serial Protocol" is a low level debugging protocol
// originally designed so that gdb could be used to debug programs running
// in embedded environments but it was later extended to support programs
// running on any environment and a variety of debuggers support it:
// gdbserver, lldb-server, macOS's debugserver and rr.
//
// The protocol is specified at:
// https://sourceware.org/gdb/onlinedocs/gdb/Remote-Protocol.html
// with additional documentation for lldb specific extensions described at:
// https://github.com/llvm-mirror/lldb/blob/master/docs/lldb-gdb-remote.txt
//
// Terminology:
// * inferior: the program we are trying to debug
// * stub: the debugger on the other side of the protocol's connection (for
// example lldb-server)
// * gdbserver: stub version of gdb
// * lldb-server: stub version of lldb
// * debugserver: a different stub version of lldb, installed with lldb on
// macOS.
// * mozilla rr: a stub that records the full execution of a program
// and can then play it back.
//
// Implementations of the protocol vary wildly between stubs, while there is
// a command to query the stub about supported features (qSupported) this
// only covers *some* of the more recent additions to the protocol and most
// of the older packets are optional and *not* implemented by all stubs.
// For example gdbserver implements 'g' (read all registers) but not 'p'
// (read single register) while lldb-server implements 'p' but not 'g'.
//
// The protocol is also underspecified with regards to how the stub should
// handle a multithreaded inferior. Its default mode of operation is
// "all-stop mode", when a thread hits a breakpoint all other threads are
// also stopped. But the protocol doesn't say what happens if a second
// thread hits a breakpoint while the stub is in the process of stopping all
// other threads.
//
// In practice the stub is allowed to swallow the second breakpoint hit or
// to return it at a later time. If the stub chooses the latter behavior
// (like gdbserver does) it is allowed to return delayed events on *any*
// vCont packet. This is incredibly inconvenient since if we get notified
// about a delayed breakpoint while we are trying to singlestep another
// thread it's impossible to know when the singlestep we requested ended.
//
// What this means is that gdbserver can only be supported for multithreaded
// inferiors by selecting non-stop mode, which behaves in a markedly
// different way from all-stop mode and isn't supported by anything except
// gdbserver.
//
// lldb-server/debugserver takes a different approach, only the first stop
// event is reported, if any other event happens "simultaneously" they are
// suppressed by the stub and the debugger can query for them using
// qThreadStopInfo. This is much easier for us to implement and the
// implementation gracefully degrades to the case where qThreadStopInfo is
// unavailable but the inferior is run in single threaded mode.
//
// Therefore the following code will assume lldb-server-like behavior.
package gdbserial
import (
"bytes"
"debug/macho"
"encoding/binary"
"errors"
"fmt"
"go/ast"
"io/ioutil"
"net"
"os"
"os/exec"
"runtime"
"strconv"
"strings"
"sync"
"time"
"golang.org/x/arch/x86/x86asm"
"github.com/derekparker/delve/pkg/logflags"
"github.com/derekparker/delve/pkg/proc"
"github.com/derekparker/delve/pkg/proc/linutil"
"github.com/mattn/go-isatty"
"github.com/sirupsen/logrus"
)
const (
gdbWireFullStopPacket = false
gdbWireMaxLen = 120
maxTransmitAttempts = 3 // number of retransmission attempts on failed checksum
initialInputBufferSize = 2048 // size of the input buffer for gdbConn
)
const heartbeatInterval = 10 * time.Second
// ErrDirChange is returned when trying to change execution direction
// while there are still internal breakpoints set.
var ErrDirChange = errors.New("direction change with internal breakpoints")
// Process implements proc.Process using a connection to a debugger stub
// that understands Gdb Remote Serial Protocol.
type Process struct {
bi *proc.BinaryInfo
conn gdbConn
threads map[int]*Thread
currentThread *Thread
selectedGoroutine *proc.G
exited, detached bool
ctrlC bool // ctrl-c was sent to stop inferior
manualStopRequested bool
breakpoints proc.BreakpointMap
gcmdok bool // true if the stub supports g and G commands
threadStopInfo bool // true if the stub supports qThreadStopInfo
tracedir string // if attached to rr the path to the trace directory
loadGInstrAddr uint64 // address of the g loading instruction, zero if we couldn't allocate it
process *os.Process
waitChan chan *os.ProcessState
common proc.CommonProcess
}
// Thread is a thread.
type Thread struct {
ID int
strID string
regs gdbRegisters
CurrentBreakpoint proc.BreakpointState
p *Process
setbp bool // thread was stopped because of a breakpoint
common proc.CommonThread
}
// ErrBackendUnavailable is returned when the stub program can not be found.
type ErrBackendUnavailable struct {
}
func (err *ErrBackendUnavailable) Error() string {
return "backend unavailable"
}
// gdbRegisters represents the current value of the registers of a thread.
// The storage space for all the registers is allocated as a single memory
// block in buf, the value field inside an individual gdbRegister will be a
// slice of the global buf field.
type gdbRegisters struct {
regs map[string]gdbRegister
regsInfo []gdbRegisterInfo
tls uint64
gaddr uint64
hasgaddr bool
buf []byte
}
type gdbRegister struct {
value []byte
regnum int
}
// New creates a new Process instance.
// If process is not nil it is the stub's process and will be killed after
// Detach.
// Use Listen, Dial or Connect to complete connection.
func New(process *os.Process) *Process {
logger := logrus.New().WithFields(logrus.Fields{"layer": "gdbconn"})
logger.Logger.Level = logrus.DebugLevel
if !logflags.GdbWire() {
logger.Logger.Out = ioutil.Discard
}
p := &Process{
conn: gdbConn{
maxTransmitAttempts: maxTransmitAttempts,
inbuf: make([]byte, 0, initialInputBufferSize),
direction: proc.Forward,
log: logger,
},
threads: make(map[int]*Thread),
bi: proc.NewBinaryInfo(runtime.GOOS, runtime.GOARCH),
breakpoints: proc.NewBreakpointMap(),
gcmdok: true,
threadStopInfo: true,
process: process,
common: proc.NewCommonProcess(true),
}
if process != nil {
p.waitChan = make(chan *os.ProcessState)
go func() {
state, _ := process.Wait()
p.waitChan <- state
}()
}
return p
}
// Listen waits for a connection from the stub.
func (p *Process) Listen(listener net.Listener, path string, pid int) error {
acceptChan := make(chan net.Conn)
go func() {
conn, _ := listener.Accept()
acceptChan <- conn
}()
select {
case conn := <-acceptChan:
listener.Close()
if conn == nil {
return errors.New("could not connect")
}
return p.Connect(conn, path, pid)
case status := <-p.waitChan:
listener.Close()
return fmt.Errorf("stub exited while waiting for connection: %v", status)
}
}
// Dial attempts to connect to the stub.
func (p *Process) Dial(addr string, path string, pid int) error {
for {
conn, err := net.Dial("tcp", addr)
if err == nil {
return p.Connect(conn, path, pid)
}
select {
case status := <-p.waitChan:
return fmt.Errorf("stub exited while attempting to connect: %v", status)
default:
}
time.Sleep(time.Second)
}
}
// Connect connects to a stub and performs a handshake.
//
// Path and pid are, respectively, the path to the executable of the target
// program and the PID of the target process, both are optional, however
// some stubs do not provide ways to determine path and pid automatically
// and Connect will be unable to function without knowing them.
func (p *Process) Connect(conn net.Conn, path string, pid int) error {
p.conn.conn = conn
p.conn.pid = pid
err := p.conn.handshake()
if err != nil {
conn.Close()
return err
}
if verbuf, err := p.conn.exec([]byte("$qGDBServerVersion"), "init"); err == nil {
for _, v := range strings.Split(string(verbuf), ";") {
if strings.HasPrefix(v, "version:") {
if v[len("version:"):] == "902" {
// Workaround for https://bugs.llvm.org/show_bug.cgi?id=36968, 'g' command crashes a version of debugserver on some systems (?)
p.gcmdok = false
break
}
}
}
}
if path == "" {
// If we are attaching to a running process and the user didn't specify
// the executable file manually we must ask the stub for it.
// We support both qXfer:exec-file:read:: (the gdb way) and calling
// qProcessInfo (the lldb way).
// Unfortunately debugserver on macOS supports neither.
path, err = p.conn.readExecFile()
if err != nil {
if isProtocolErrorUnsupported(err) {
_, path, err = p.loadProcessInfo(pid)
if err != nil {
conn.Close()
return err
}
} else {
conn.Close()
return fmt.Errorf("could not determine executable path: %v", err)
}
}
}
if path == "" {
// try using jGetLoadedDynamicLibrariesInfos which is the only way to do
// this supported on debugserver (but only on macOS >= 12.10)
images, _ := p.conn.getLoadedDynamicLibraries()
for _, image := range images {
if image.MachHeader.FileType == macho.TypeExec {
path = image.Pathname
break
}
}
}
var entryPoint uint64
if auxv, err := p.conn.readAuxv(); err == nil {
// If we can't read the auxiliary vector it just means it's not supported
// by the OS or by the stub. If we are debugging a PIE and the entry point
// is needed proc.LoadBinaryInfo will complain about it.
entryPoint = linutil.EntryPointFromAuxvAMD64(auxv)
}
var wg sync.WaitGroup
err = p.bi.LoadBinaryInfo(path, entryPoint, &wg)
wg.Wait()
if err == nil {
err = p.bi.LoadError()
}
if err != nil {
conn.Close()
return err
}
// None of the stubs we support returns the value of fs_base or gs_base
// along with the registers, therefore we have to resort to executing a MOV
// instruction on the inferior to find out where the G struct of a given
// thread is located.
// Here we try to allocate some memory on the inferior which we will use to
// store the MOV instruction.
// If the stub doesn't support memory allocation reloadRegisters will
// overwrite some existing memory to store the MOV.
if addr, err := p.conn.allocMemory(256); err == nil {
if _, err := p.conn.writeMemory(uintptr(addr), p.loadGInstr()); err == nil {
p.loadGInstrAddr = addr
}
}
err = p.updateThreadList(&threadUpdater{p: p})
if err != nil {
conn.Close()
p.bi.Close()
return err
}
if p.conn.pid <= 0 {
p.conn.pid, _, err = p.loadProcessInfo(0)
if err != nil && !isProtocolErrorUnsupported(err) {
conn.Close()
p.bi.Close()
return err
}
}
p.selectedGoroutine, _ = proc.GetG(p.CurrentThread())
proc.CreateUnrecoveredPanicBreakpoint(p, p.writeBreakpoint, &p.breakpoints)
panicpc, err := proc.FindFunctionLocation(p, "runtime.startpanic", true, 0)
if err == nil {
bp, err := p.breakpoints.SetWithID(-1, panicpc, p.writeBreakpoint)
if err == nil {
bp.Name = proc.UnrecoveredPanic
bp.Variables = []string{"runtime.curg._panic.arg"}
}
}
return nil
}
// unusedPort returns an unused tcp port
// This is a hack and subject to a race condition with other running
// programs, but most (all?) OS will cycle through all ephemeral ports
// before reassigning one port they just assigned, unless there's heavy
// churn in the ephemeral range this should work.
func unusedPort() string {
listener, err := net.Listen("tcp", "localhost:0")
if err != nil {
return ":8081"
}
port := listener.Addr().(*net.TCPAddr).Port
listener.Close()
return fmt.Sprintf(":%d", port)
}
const debugserverExecutable = "/Library/Developer/CommandLineTools/Library/PrivateFrameworks/LLDB.framework/Versions/A/Resources/debugserver"
// ErrUnsupportedOS is returned when trying to use the lldb backend on Windows.
var ErrUnsupportedOS = errors.New("lldb backend not supported on Windows")
func getLdEnvVars() []string {
var result []string
environ := os.Environ()
for i := 0; i < len(environ); i++ {
if strings.HasPrefix(environ[i], "LD_") ||
strings.HasPrefix(environ[i], "DYLD_") {
result = append(result, "-e", environ[i])
}
}
return result
}
// LLDBLaunch starts an instance of lldb-server and connects to it, asking
// it to launch the specified target program with the specified arguments
// (cmd) on the specified directory wd.
func LLDBLaunch(cmd []string, wd string, foreground bool) (*Process, error) {
switch runtime.GOOS {
case "windows":
return nil, ErrUnsupportedOS
default:
// check that the argument to Launch is an executable file
if fi, staterr := os.Stat(cmd[0]); staterr == nil && (fi.Mode()&0111) == 0 {
return nil, proc.ErrNotExecutable
}
}
if foreground {
// Disable foregrounding if we can't open /dev/tty or debugserver will
// crash. See issue #1215.
if !isatty.IsTerminal(os.Stdin.Fd()) {
foreground = false
}
}
isDebugserver := false
var listener net.Listener
var port string
var proc *exec.Cmd
if _, err := os.Stat(debugserverExecutable); err == nil {
listener, err = net.Listen("tcp", "localhost:0")
if err != nil {
return nil, err
}
ldEnvVars := getLdEnvVars()
args := make([]string, 0, len(cmd)+4+len(ldEnvVars))
args = append(args, ldEnvVars...)
if foreground {
args = append(args, "--stdio-path", "/dev/tty")
}
args = append(args, "-F", "-R", fmt.Sprintf("127.0.0.1:%d", listener.Addr().(*net.TCPAddr).Port), "--")
args = append(args, cmd...)
isDebugserver = true
proc = exec.Command(debugserverExecutable, args...)
} else {
if _, err := exec.LookPath("lldb-server"); err != nil {
return nil, &ErrBackendUnavailable{}
}
port = unusedPort()
args := make([]string, 0, len(cmd)+3)
args = append(args, "gdbserver")
args = append(args, port, "--")
args = append(args, cmd...)
proc = exec.Command("lldb-server", args...)
}
if logflags.LLDBServerOutput() || logflags.GdbWire() || foreground {
proc.Stdout = os.Stdout
proc.Stderr = os.Stderr
}
if foreground {
foregroundSignalsIgnore()
proc.Stdin = os.Stdin
}
if wd != "" {
proc.Dir = wd
}
proc.SysProcAttr = sysProcAttr(foreground)
err := proc.Start()
if err != nil {
return nil, err
}
p := New(proc.Process)
p.conn.isDebugserver = isDebugserver
if listener != nil {
err = p.Listen(listener, cmd[0], 0)
} else {
err = p.Dial(port, cmd[0], 0)
}
if err != nil {
return nil, err
}
return p, nil
}
// LLDBAttach starts an instance of lldb-server and connects to it, asking
// it to attach to the specified pid.
// Path is path to the target's executable, path only needs to be specified
// for some stubs that do not provide an automated way of determining it
// (for example debugserver).
func LLDBAttach(pid int, path string) (*Process, error) {
if runtime.GOOS == "windows" {
return nil, ErrUnsupportedOS
}
isDebugserver := false
var proc *exec.Cmd
var listener net.Listener
var port string
if _, err := os.Stat(debugserverExecutable); err == nil {
isDebugserver = true
listener, err = net.Listen("tcp", "localhost:0")
if err != nil {
return nil, err
}
proc = exec.Command(debugserverExecutable, "-R", fmt.Sprintf("127.0.0.1:%d", listener.Addr().(*net.TCPAddr).Port), "--attach="+strconv.Itoa(pid))
} else {
if _, err := exec.LookPath("lldb-server"); err != nil {
return nil, &ErrBackendUnavailable{}
}
port = unusedPort()
proc = exec.Command("lldb-server", "gdbserver", "--attach", strconv.Itoa(pid), port)
}
proc.Stdout = os.Stdout
proc.Stderr = os.Stderr
proc.SysProcAttr = sysProcAttr(false)
err := proc.Start()
if err != nil {
return nil, err
}
p := New(proc.Process)
p.conn.isDebugserver = isDebugserver
if listener != nil {
err = p.Listen(listener, path, pid)
} else {
err = p.Dial(port, path, pid)
}
if err != nil {
return nil, err
}
return p, nil
}
// loadProcessInfo uses qProcessInfo to load the inferior's PID and
// executable path. This command is not supported by all stubs and not all
// stubs will report both the PID and executable path.
func (p *Process) loadProcessInfo(pid int) (int, string, error) {
pi, err := p.conn.queryProcessInfo(pid)
if err != nil {
return 0, "", err
}
if pid == 0 {
n, _ := strconv.ParseUint(pi["pid"], 16, 64)
pid = int(n)
}
return pid, pi["name"], nil
}
// BinInfo returns information on the binary.
func (p *Process) BinInfo() *proc.BinaryInfo {
return p.bi
}
// Recorded returns whether or not we are debugging
// a recorded "traced" program.
func (p *Process) Recorded() (bool, string) {
return p.tracedir != "", p.tracedir
}
// Pid returns the process ID.
func (p *Process) Pid() int {
return int(p.conn.pid)
}
// Valid returns true if we are not detached
// and the process has not exited.
func (p *Process) Valid() (bool, error) {
if p.detached {
return false, &proc.ProcessDetachedError{}
}
if p.exited {
return false, &proc.ErrProcessExited{Pid: p.Pid()}
}
return true, nil
}
// ResumeNotify specifies a channel that will be closed the next time
// ContinueOnce finishes resuming the target.
func (p *Process) ResumeNotify(ch chan<- struct{}) {
p.conn.resumeChan = ch
}
// FindThread returns the thread with the given ID.
func (p *Process) FindThread(threadID int) (proc.Thread, bool) {
thread, ok := p.threads[threadID]
return thread, ok
}
// ThreadList returns all threads in the process.
func (p *Process) ThreadList() []proc.Thread {
r := make([]proc.Thread, 0, len(p.threads))
for _, thread := range p.threads {
r = append(r, thread)
}
return r
}
// CurrentThread returns the current active
// selected thread.
func (p *Process) CurrentThread() proc.Thread {
return p.currentThread
}
// Common returns common information across Process implementations.
func (p *Process) Common() *proc.CommonProcess {
return &p.common
}
// SelectedGoroutine returns the current actuve selected goroutine.
func (p *Process) SelectedGoroutine() *proc.G {
return p.selectedGoroutine
}
const (
interruptSignal = 0x2
breakpointSignal = 0x5
childSignal = 0x11
stopSignal = 0x13
)
// ContinueOnce will continue execution of the process until
// a breakpoint is hit or signal is received.
func (p *Process) ContinueOnce() (proc.Thread, error) {
if p.exited {
return nil, &proc.ErrProcessExited{Pid: p.conn.pid}
}
if p.conn.direction == proc.Forward {
// step threads stopped at any breakpoint over their breakpoint
for _, thread := range p.threads {
if thread.CurrentBreakpoint.Breakpoint != nil {
if err := thread.stepInstruction(&threadUpdater{p: p}); err != nil {
return nil, err
}
}
}
}
p.common.ClearAllGCache()
for _, th := range p.threads {
th.clearBreakpointState()
}
p.setCtrlC(false)
// resume all threads
var threadID string
var sig uint8 = 0
var tu = threadUpdater{p: p}
var err error
continueLoop:
for {
tu.Reset()
threadID, sig, err = p.conn.resume(sig, &tu)
if err != nil {
if _, exited := err.(proc.ErrProcessExited); exited {
p.exited = true
}
return nil, err
}
// 0x5 is always a breakpoint, a manual stop either manifests as 0x13
// (lldb), 0x11 (debugserver) or 0x2 (gdbserver).
// Since 0x2 could also be produced by the user
// pressing ^C (in which case it should be passed to the inferior) we need
// the ctrlC flag to know that we are the originators.
switch sig {
case interruptSignal: // interrupt
if p.getCtrlC() {
break continueLoop
}
case breakpointSignal: // breakpoint
break continueLoop
case childSignal: // stop on debugserver but SIGCHLD on lldb-server/linux
if p.conn.isDebugserver {
break continueLoop
}
case stopSignal: // stop
break continueLoop
// The following are fake BSD-style signals sent by debugserver
// Unfortunately debugserver can not convert them into signals for the
// process so we must stop here.
case 0x91, 0x92, 0x93, 0x94, 0x95, 0x96: /* TARGET_EXC_BAD_ACCESS */
break continueLoop
default:
// any other signal is always propagated to inferior
}
}
if err := p.updateThreadList(&tu); err != nil {
return nil, err
}
if err := p.setCurrentBreakpoints(); err != nil {
return nil, err
}
for _, thread := range p.threads {
if thread.strID == threadID {
var err error = nil
switch sig {
case 0x91:
err = errors.New("bad access")
case 0x92:
err = errors.New("bad instruction")
case 0x93:
err = errors.New("arithmetic exception")
case 0x94:
err = errors.New("emulation exception")
case 0x95:
err = errors.New("software exception")
case 0x96:
err = errors.New("breakpoint exception")
}
return thread, err
}
}
return nil, fmt.Errorf("could not find thread %s", threadID)
}
// StepInstruction will step exactly one CPU instruction.
func (p *Process) StepInstruction() error {
thread := p.currentThread
if p.selectedGoroutine != nil {
if p.selectedGoroutine.Thread == nil {
if _, err := p.SetBreakpoint(p.selectedGoroutine.PC, proc.NextBreakpoint, proc.SameGoroutineCondition(p.selectedGoroutine)); err != nil {
return err
}
return proc.Continue(p)
}
thread = p.selectedGoroutine.Thread.(*Thread)
}
p.common.ClearAllGCache()
if p.exited {
return &proc.ErrProcessExited{Pid: p.conn.pid}
}
thread.clearBreakpointState()
err := thread.StepInstruction()
if err != nil {
return err
}
err = thread.SetCurrentBreakpoint()
if err != nil {
return err
}
if g, _ := proc.GetG(thread); g != nil {
p.selectedGoroutine = g
}
return nil
}
// SwitchThread will change the internal selected thread.
func (p *Process) SwitchThread(tid int) error {
if p.exited {
return proc.ErrProcessExited{Pid: p.conn.pid}
}
if th, ok := p.threads[tid]; ok {
p.currentThread = th
p.selectedGoroutine, _ = proc.GetG(p.CurrentThread())
return nil
}
return fmt.Errorf("thread %d does not exist", tid)
}
// SwitchGoroutine will change the internal selected goroutine.
func (p *Process) SwitchGoroutine(gid int) error {
g, err := proc.FindGoroutine(p, gid)
if err != nil {
return err
}
if g == nil {
// user specified -1 and selectedGoroutine is nil
return nil
}
if g.Thread != nil {
return p.SwitchThread(g.Thread.ThreadID())
}
p.selectedGoroutine = g
return nil
}
// RequestManualStop will attempt to stop the process
// without a breakpoint or signal having been recieved.
func (p *Process) RequestManualStop() error {
p.conn.manualStopMutex.Lock()
p.manualStopRequested = true
if !p.conn.running {
p.conn.manualStopMutex.Unlock()
return nil
}
p.ctrlC = true
p.conn.manualStopMutex.Unlock()
return p.conn.sendCtrlC()
}
// CheckAndClearManualStopRequest will check for a manual
// stop and then clear that state.
func (p *Process) CheckAndClearManualStopRequest() bool {
p.conn.manualStopMutex.Lock()
msr := p.manualStopRequested
p.manualStopRequested = false
p.conn.manualStopMutex.Unlock()
return msr
}
func (p *Process) setCtrlC(v bool) {
p.conn.manualStopMutex.Lock()
p.ctrlC = v
p.conn.manualStopMutex.Unlock()
}
func (p *Process) getCtrlC() bool {
p.conn.manualStopMutex.Lock()
defer p.conn.manualStopMutex.Unlock()
return p.ctrlC
}
// Detach will detach from the target process,
// if 'kill' is true it will also kill the process.
func (p *Process) Detach(kill bool) error {
if kill && !p.exited {
err := p.conn.kill()
if err != nil {
if _, exited := err.(proc.ErrProcessExited); !exited {
return err
}
p.exited = true
}
}
if !p.exited {
if err := p.conn.detach(); err != nil {
return err
}
}
if p.process != nil {
p.process.Kill()
<-p.waitChan
p.process = nil
}
p.detached = true
return p.bi.Close()
}
// Restart will restart the process from the given position.
func (p *Process) Restart(pos string) error {
if p.tracedir == "" {
return proc.ErrNotRecorded
}
p.exited = false
p.common.ClearAllGCache()
for _, th := range p.threads {
th.clearBreakpointState()
}
p.setCtrlC(false)
err := p.conn.restart(pos)
if err != nil {
return err
}
// for some reason we have to send a vCont;c after a vRun to make rr behave
// properly, because that's what gdb does.
_, _, err = p.conn.resume(0, nil)
if err != nil {
return err
}
err = p.updateThreadList(&threadUpdater{p: p})
if err != nil {
return err
}
p.selectedGoroutine, _ = proc.GetG(p.CurrentThread())
for addr := range p.breakpoints.M {
p.conn.setBreakpoint(addr)
}
return p.setCurrentBreakpoints()
}
// When executes the 'when' command for the Mozilla RR backend.
// This command will return rr's internal event number.
func (p *Process) When() (string, error) {
if p.tracedir == "" {
return "", proc.ErrNotRecorded
}
event, err := p.conn.qRRCmd("when")
if err != nil {
return "", err
}
return strings.TrimSpace(event), nil
}
const (
checkpointPrefix = "Checkpoint "
)
// Checkpoint creates a checkpoint from which you can restart the program.
func (p *Process) Checkpoint(where string) (int, error) {
if p.tracedir == "" {
return -1, proc.ErrNotRecorded
}
resp, err := p.conn.qRRCmd("checkpoint", where)
if err != nil {
return -1, err
}
if !strings.HasPrefix(resp, checkpointPrefix) {
return -1, fmt.Errorf("can not parse checkpoint response %q", resp)
}
idstr := resp[len(checkpointPrefix):]
space := strings.Index(idstr, " ")
if space < 0 {
return -1, fmt.Errorf("can not parse checkpoint response %q", resp)
}
idstr = idstr[:space]
cpid, err := strconv.Atoi(idstr)
if err != nil {
return -1, err
}
return cpid, nil
}
// Checkpoints returns a list of all checkpoints set.
func (p *Process) Checkpoints() ([]proc.Checkpoint, error) {
if p.tracedir == "" {
return nil, proc.ErrNotRecorded
}
resp, err := p.conn.qRRCmd("info checkpoints")
if err != nil {
return nil, err
}
lines := strings.Split(resp, "\n")
r := make([]proc.Checkpoint, 0, len(lines)-1)
for _, line := range lines[1:] {
if line == "" {
continue
}
fields := strings.Split(line, "\t")
if len(fields) != 3 {
return nil, fmt.Errorf("can not parse \"info checkpoints\" output line %q", line)
}
cpid, err := strconv.Atoi(fields[0])
if err != nil {
return nil, fmt.Errorf("can not parse \"info checkpoints\" output line %q: %v", line, err)
}
r = append(r, proc.Checkpoint{cpid, fields[1], fields[2]})
}
return r, nil
}
const deleteCheckpointPrefix = "Deleted checkpoint "
// ClearCheckpoint clears the checkpoint for the given ID.
func (p *Process) ClearCheckpoint(id int) error {
if p.tracedir == "" {
return proc.ErrNotRecorded
}
resp, err := p.conn.qRRCmd("delete checkpoint", strconv.Itoa(id))
if err != nil {
return err
}
if !strings.HasPrefix(resp, deleteCheckpointPrefix) {
return errors.New(resp)
}
return nil
}
// Direction sets whether to run the program forwards or in reverse execution.
func (p *Process) Direction(dir proc.Direction) error {
if p.tracedir == "" {
return proc.ErrNotRecorded
}
if p.conn.conn == nil {
return proc.ErrProcessExited{Pid: p.conn.pid}
}
if p.conn.direction == dir {
return nil
}
if p.Breakpoints().HasInternalBreakpoints() {
return ErrDirChange
}
p.conn.direction = dir
return nil
}
// Breakpoints returns the list of breakpoints currently set.
func (p *Process) Breakpoints() *proc.BreakpointMap {
return &p.breakpoints
}
// FindBreakpoint returns the breakpoint at the given address.
func (p *Process) FindBreakpoint(pc uint64) (*proc.Breakpoint, bool) {
// Check to see if address is past the breakpoint, (i.e. breakpoint was hit).
if bp, ok := p.breakpoints.M[pc-uint64(p.bi.Arch.BreakpointSize())]; ok {
return bp, true
}
// Directly use addr to lookup breakpoint.
if bp, ok := p.breakpoints.M[pc]; ok {
return bp, true
}
return nil, false
}
func (p *Process) writeBreakpoint(addr uint64) (string, int, *proc.Function, []byte, error) {
f, l, fn := p.bi.PCToLine(uint64(addr))
if fn == nil {
return "", 0, nil, nil, proc.InvalidAddressError{Address: addr}
}
if err := p.conn.setBreakpoint(addr); err != nil {
return "", 0, nil, nil, err
}
return f, l, fn, nil, nil
}
// SetBreakpoint creates a new breakpoint.
func (p *Process) SetBreakpoint(addr uint64, kind proc.BreakpointKind, cond ast.Expr) (*proc.Breakpoint, error) {
if p.exited {
return nil, &proc.ErrProcessExited{Pid: p.conn.pid}
}
return p.breakpoints.Set(addr, kind, cond, p.writeBreakpoint)
}
// ClearBreakpoint clears a breakpoint at the given address.
func (p *Process) ClearBreakpoint(addr uint64) (*proc.Breakpoint, error) {
if p.exited {
return nil, &proc.ErrProcessExited{Pid: p.conn.pid}
}
return p.breakpoints.Clear(addr, func(bp *proc.Breakpoint) error {
return p.conn.clearBreakpoint(bp.Addr)
})
}
// ClearInternalBreakpoints clear all internal use breakpoints like those set by 'next'.
func (p *Process) ClearInternalBreakpoints() error {
return p.breakpoints.ClearInternalBreakpoints(func(bp *proc.Breakpoint) error {
if err := p.conn.clearBreakpoint(bp.Addr); err != nil {
return err
}
for _, thread := range p.threads {
if thread.CurrentBreakpoint.Breakpoint == bp {
thread.clearBreakpointState()
}
}
return nil
})
}
type threadUpdater struct {
p *Process
seen map[int]bool
done bool
}
func (tu *threadUpdater) Reset() {
tu.done = false
tu.seen = nil
}
func (tu *threadUpdater) Add(threads []string) error {
if tu.done {
panic("threadUpdater: Add after Finish")
}
if tu.seen == nil {
tu.seen = map[int]bool{}
}
for _, threadID := range threads {
b := threadID
if period := strings.Index(b, "."); period >= 0 {
b = b[period+1:]
}
n, err := strconv.ParseUint(b, 16, 32)
if err != nil {
return &GdbMalformedThreadIDError{threadID}
}
tid := int(n)
tu.seen[tid] = true
if _, found := tu.p.threads[tid]; !found {
tu.p.threads[tid] = &Thread{ID: tid, strID: threadID, p: tu.p}
}
}
return nil
}
func (tu *threadUpdater) Finish() {
tu.done = true
for threadID := range tu.p.threads {
_, threadSeen := tu.seen[threadID]
if threadSeen {
continue
}
delete(tu.p.threads, threadID)
if tu.p.currentThread.ID == threadID {
tu.p.currentThread = nil
}
}
if tu.p.currentThread != nil {
if _, exists := tu.p.threads[tu.p.currentThread.ID]; !exists {
// current thread was removed
tu.p.currentThread = nil
}
}
if tu.p.currentThread == nil {
for _, thread := range tu.p.threads {
tu.p.currentThread = thread
break
}
}
}
// updateThreadsList retrieves the list of inferior threads from the stub
// and passes it to the threadUpdater.
// Then it reloads the register information for all running threads.
// Some stubs will return the list of running threads in the stop packet, if
// this happens the threadUpdater will know that we have already updated the
// thread list and the first step of updateThreadList will be skipped.
// Registers are always reloaded.
func (p *Process) updateThreadList(tu *threadUpdater) error {
if !tu.done {
first := true
for {
threads, err := p.conn.queryThreads(first)
if err != nil {
return err
}
if len(threads) == 0 {
break
}
first = false
if err := tu.Add(threads); err != nil {
return err
}
}
tu.Finish()
}
if p.threadStopInfo {
for _, th := range p.threads {
sig, reason, err := p.conn.threadStopInfo(th.strID)
if err != nil {
if isProtocolErrorUnsupported(err) {
p.threadStopInfo = false
break
}
return err
}
th.setbp = (reason == "breakpoint" || (reason == "" && sig == breakpointSignal))
}
}
for _, thread := range p.threads {
if err := thread.reloadRegisters(); err != nil {
return err
}
}
return nil
}
func (p *Process) setCurrentBreakpoints() error {
if p.threadStopInfo {
for _, th := range p.threads {
if th.setbp {
err := th.SetCurrentBreakpoint()
if err != nil {
return err
}
}
}
}
if !p.threadStopInfo {
for _, th := range p.threads {
if th.CurrentBreakpoint.Breakpoint == nil {
err := th.SetCurrentBreakpoint()
if err != nil {
return err
}
}
}
}
return nil
}
// ReadMemory will read into 'data' memory at the address provided.
func (t *Thread) ReadMemory(data []byte, addr uintptr) (n int, err error) {
err = t.p.conn.readMemory(data, addr)
if err != nil {
return 0, err
}
return len(data), nil
}
// WriteMemory will write into the memory at 'addr' the data provided.
func (t *Thread) WriteMemory(addr uintptr, data []byte) (written int, err error) {
return t.p.conn.writeMemory(addr, data)
}
// Location returns the current location of this thread.
func (t *Thread) Location() (*proc.Location, error) {
regs, err := t.Registers(false)
if err != nil {
return nil, err
}
pc := regs.PC()
f, l, fn := t.p.bi.PCToLine(pc)
return &proc.Location{PC: pc, File: f, Line: l, Fn: fn}, nil
}
// Breakpoint returns the current active breakpoint for this thread.
func (t *Thread) Breakpoint() proc.BreakpointState {
return t.CurrentBreakpoint
}
// ThreadID returns this threads ID.
func (t *Thread) ThreadID() int {
return t.ID
}
// Registers returns the CPU registers for this thread.
func (t *Thread) Registers(floatingPoint bool) (proc.Registers, error) {
return &t.regs, nil
}
// RestoreRegisters will set the CPU registers the value of those provided.
func (t *Thread) RestoreRegisters(savedRegs proc.Registers) error {
copy(t.regs.buf, savedRegs.(*gdbRegisters).buf)
return t.writeRegisters()
}
// Arch will return the CPU architecture for the target.
func (t *Thread) Arch() proc.Arch {
return t.p.bi.Arch
}
// BinInfo will return information on the binary being debugged.
func (t *Thread) BinInfo() *proc.BinaryInfo {
return t.p.bi
}
// Common returns common information across Process implementations.
func (t *Thread) Common() *proc.CommonThread {
return &t.common
}
func (t *Thread) stepInstruction(tu *threadUpdater) error {
pc := t.regs.PC()
if _, atbp := t.p.breakpoints.M[pc]; atbp {
err := t.p.conn.clearBreakpoint(pc)
if err != nil {
return err
}
defer t.p.conn.setBreakpoint(pc)
}
_, _, err := t.p.conn.step(t.strID, tu)
return err
}
// StepInstruction will step exactly 1 CPU instruction.
func (t *Thread) StepInstruction() error {
if err := t.stepInstruction(&threadUpdater{p: t.p}); err != nil {
return err
}
return t.reloadRegisters()
}
// Blocked returns true if the thread is blocked in runtime or kernel code.
func (t *Thread) Blocked() bool {
regs, err := t.Registers(false)
if err != nil {
return false
}
pc := regs.PC()
f, ln, fn := t.BinInfo().PCToLine(pc)
if fn == nil {
if f == "" && ln == 0 {
return true
}
return false
}
switch fn.Name {
case "runtime.futex", "runtime.usleep", "runtime.clone":
return true
case "runtime.kevent":
return true
case "runtime.mach_semaphore_wait", "runtime.mach_semaphore_timedwait":
return true
default:
return strings.HasPrefix(fn.Name, "syscall.Syscall") || strings.HasPrefix(fn.Name, "syscall.RawSyscall")
}
return false
}
// loadGInstr returns the correct MOV instruction for the current
// OS/architecture that can be executed to load the address of G from an
// inferior's thread.
func (p *Process) loadGInstr() []byte {
var op []byte
switch p.bi.GOOS {
case "windows":
// mov rcx, QWORD PTR gs:{uint32(off)}
op = []byte{0x65, 0x48, 0x8b, 0x0c, 0x25}
case "linux":
// mov rcx,QWORD PTR fs:{uint32(off)}
op = []byte{0x64, 0x48, 0x8B, 0x0C, 0x25}
case "darwin":
// mov rcx,QWORD PTR gs:{uint32(off)}
op = []byte{0x65, 0x48, 0x8B, 0x0C, 0x25}
default:
panic("unsupported operating system attempting to find Goroutine on Thread")
}
buf := &bytes.Buffer{}
buf.Write(op)
binary.Write(buf, binary.LittleEndian, uint32(p.bi.GStructOffset()))
return buf.Bytes()
}
func (regs *gdbRegisters) init(regsInfo []gdbRegisterInfo) {
regs.regs = make(map[string]gdbRegister)
regs.regsInfo = regsInfo
regsz := 0
for _, reginfo := range regsInfo {
if endoff := reginfo.Offset + (reginfo.Bitsize / 8); endoff > regsz {
regsz = endoff
}
}
regs.buf = make([]byte, regsz)
for _, reginfo := range regsInfo {
regs.regs[reginfo.Name] = gdbRegister{regnum: reginfo.Regnum, value: regs.buf[reginfo.Offset : reginfo.Offset+reginfo.Bitsize/8]}
}
}
// reloadRegisters loads the current value of the thread's registers.
// It will also load the address of the thread's G.
// Loading the address of G can be done in one of two ways reloadGAlloc, if
// the stub can allocate memory, or reloadGAtPC, if the stub can't.
func (t *Thread) reloadRegisters() error {
if t.regs.regs == nil {
t.regs.init(t.p.conn.regsInfo)
}
if t.p.gcmdok {
if err := t.p.conn.readRegisters(t.strID, t.regs.buf); err != nil {
if isProtocolErrorUnsupported(err) {
t.p.gcmdok = false
} else {
return err
}
}
}
if !t.p.gcmdok {
for _, reginfo := range t.p.conn.regsInfo {
if err := t.p.conn.readRegister(t.strID, reginfo.Regnum, t.regs.regs[reginfo.Name].value); err != nil {
return err
}
}
}
switch t.p.bi.GOOS {
case "linux":
if reg, hasFsBase := t.regs.regs[regnameFsBase]; hasFsBase {
t.regs.gaddr = 0
t.regs.tls = binary.LittleEndian.Uint64(reg.value)
t.regs.hasgaddr = false
return nil
}
}
if t.p.loadGInstrAddr > 0 {
return t.reloadGAlloc()
}
return t.reloadGAtPC()
}
func (t *Thread) writeSomeRegisters(regNames ...string) error {
if t.p.gcmdok {
return t.p.conn.writeRegisters(t.strID, t.regs.buf)
}
for _, regName := range regNames {
if err := t.p.conn.writeRegister(t.strID, t.regs.regs[regName].regnum, t.regs.regs[regName].value); err != nil {
return err
}
}
return nil
}
func (t *Thread) writeRegisters() error {
if t.p.gcmdok {
return t.p.conn.writeRegisters(t.strID, t.regs.buf)
}
for _, r := range t.regs.regs {
if err := t.p.conn.writeRegister(t.strID, r.regnum, r.value); err != nil {
return err
}
}
return nil
}
func (t *Thread) readSomeRegisters(regNames ...string) error {
if t.p.gcmdok {
return t.p.conn.readRegisters(t.strID, t.regs.buf)
}
for _, regName := range regNames {
err := t.p.conn.readRegister(t.strID, t.regs.regs[regName].regnum, t.regs.regs[regName].value)
if err != nil {
return err
}
}
return nil
}
// reloadGAtPC overwrites the instruction that the thread is stopped at with
// the MOV instruction used to load current G, executes this single
// instruction and then puts everything back the way it was.
func (t *Thread) reloadGAtPC() error {
movinstr := t.p.loadGInstr()
if t.Blocked() {
t.regs.tls = 0
t.regs.gaddr = 0
t.regs.hasgaddr = true
return nil
}
cx := t.regs.CX()
pc := t.regs.PC()
// We are partially replicating the code of GdbserverThread.stepInstruction
// here.
// The reason is that lldb-server has a bug with writing to memory and
// setting/clearing breakpoints to that same memory which we must work
// around by clearing and re-setting the breakpoint in a specific sequence
// with the memory writes.
// Additionally all breakpoints in [pc, pc+len(movinstr)] need to be removed
for addr := range t.p.breakpoints.M {
if addr >= pc && addr <= pc+uint64(len(movinstr)) {
err := t.p.conn.clearBreakpoint(addr)
if err != nil {
return err
}
defer t.p.conn.setBreakpoint(addr)
}
}
savedcode := make([]byte, len(movinstr))
_, err := t.ReadMemory(savedcode, uintptr(pc))
if err != nil {
return err
}
_, err = t.WriteMemory(uintptr(pc), movinstr)
if err != nil {
return err
}
defer func() {
_, err0 := t.WriteMemory(uintptr(pc), savedcode)
if err == nil {
err = err0
}
t.regs.setPC(pc)
t.regs.setCX(cx)
err1 := t.writeSomeRegisters(regnamePC, regnameCX)
if err == nil {
err = err1
}
}()
_, _, err = t.p.conn.step(t.strID, nil)
if err != nil {
if err == threadBlockedError {
t.regs.tls = 0
t.regs.gaddr = 0
t.regs.hasgaddr = true
return nil
}
return err
}
if err := t.readSomeRegisters(regnamePC, regnameCX); err != nil {
return err
}
t.regs.gaddr = t.regs.CX()
t.regs.hasgaddr = true
return err
}
// reloadGAlloc makes the specified thread execute one instruction stored at
// t.p.loadGInstrAddr then restores the value of the thread's registers.
// t.p.loadGInstrAddr must point to valid memory on the inferior, containing
// a MOV instruction that loads the address of the current G in the RCX
// register.
func (t *Thread) reloadGAlloc() error {
if t.Blocked() {
t.regs.tls = 0
t.regs.gaddr = 0
t.regs.hasgaddr = true
return nil
}
cx := t.regs.CX()
pc := t.regs.PC()
t.regs.setPC(t.p.loadGInstrAddr)
if err := t.writeSomeRegisters(regnamePC); err != nil {
return err
}
var err error
defer func() {
t.regs.setPC(pc)
t.regs.setCX(cx)
err1 := t.writeSomeRegisters(regnamePC, regnameCX)
if err == nil {
err = err1
}
}()
_, _, err = t.p.conn.step(t.strID, nil)
if err != nil {
if err == threadBlockedError {
t.regs.tls = 0
t.regs.gaddr = 0
t.regs.hasgaddr = true
return nil
}
return err
}
if err := t.readSomeRegisters(regnameCX); err != nil {
return err
}
t.regs.gaddr = t.regs.CX()
t.regs.hasgaddr = true
return err
}
func (t *Thread) clearBreakpointState() {
t.setbp = false
t.CurrentBreakpoint.Clear()
}
// SetCurrentBreakpoint will find and set the threads current breakpoint.
func (thread *Thread) SetCurrentBreakpoint() error {
thread.clearBreakpointState()
regs, err := thread.Registers(false)
if err != nil {
return err
}
pc := regs.PC()
if bp, ok := thread.p.FindBreakpoint(pc); ok {
if thread.regs.PC() != bp.Addr {
if err := thread.SetPC(bp.Addr); err != nil {
return err
}
}
thread.CurrentBreakpoint = bp.CheckCondition(thread)
if thread.CurrentBreakpoint.Breakpoint != nil && thread.CurrentBreakpoint.Active {
if g, err := proc.GetG(thread); err == nil {
thread.CurrentBreakpoint.HitCount[g.ID]++
}
thread.CurrentBreakpoint.TotalHitCount++
}
}
return nil
}
func (regs *gdbRegisters) PC() uint64 {
return binary.LittleEndian.Uint64(regs.regs[regnamePC].value)
}
func (regs *gdbRegisters) setPC(value uint64) {
binary.LittleEndian.PutUint64(regs.regs[regnamePC].value, value)
}
func (regs *gdbRegisters) SP() uint64 {
return binary.LittleEndian.Uint64(regs.regs[regnameSP].value)
}
func (regs *gdbRegisters) setSP(value uint64) {
binary.LittleEndian.PutUint64(regs.regs[regnameSP].value, value)
}
func (regs *gdbRegisters) setDX(value uint64) {
binary.LittleEndian.PutUint64(regs.regs[regnameDX].value, value)
}
func (regs *gdbRegisters) BP() uint64 {
return binary.LittleEndian.Uint64(regs.regs[regnameBP].value)
}
func (regs *gdbRegisters) CX() uint64 {
return binary.LittleEndian.Uint64(regs.regs[regnameCX].value)
}
func (regs *gdbRegisters) setCX(value uint64) {
binary.LittleEndian.PutUint64(regs.regs[regnameCX].value, value)
}
func (regs *gdbRegisters) TLS() uint64 {
return regs.tls
}
func (regs *gdbRegisters) GAddr() (uint64, bool) {
return regs.gaddr, regs.hasgaddr
}
func (regs *gdbRegisters) byName(name string) uint64 {
reg, ok := regs.regs[name]
if !ok {
return 0
}
return binary.LittleEndian.Uint64(reg.value)
}
func (regs *gdbRegisters) Get(n int) (uint64, error) {
reg := x86asm.Reg(n)
const (
mask8 = 0x000f
mask16 = 0x00ff
mask32 = 0xffff
)
switch reg {
// 8-bit
case x86asm.AL:
return regs.byName("rax") & mask8, nil
case x86asm.CL:
return regs.byName("rcx") & mask8, nil
case x86asm.DL:
return regs.byName("rdx") & mask8, nil
case x86asm.BL:
return regs.byName("rbx") & mask8, nil
case x86asm.AH:
return (regs.byName("rax") >> 8) & mask8, nil
case x86asm.CH:
return (regs.byName("rcx") >> 8) & mask8, nil
case x86asm.DH:
return (regs.byName("rdx") >> 8) & mask8, nil
case x86asm.BH:
return (regs.byName("rbx") >> 8) & mask8, nil
case x86asm.SPB:
return regs.byName("rsp") & mask8, nil
case x86asm.BPB:
return regs.byName("rbp") & mask8, nil
case x86asm.SIB:
return regs.byName("rsi") & mask8, nil
case x86asm.DIB:
return regs.byName("rdi") & mask8, nil
case x86asm.R8B:
return regs.byName("r8") & mask8, nil
case x86asm.R9B:
return regs.byName("r9") & mask8, nil
case x86asm.R10B:
return regs.byName("r10") & mask8, nil
case x86asm.R11B:
return regs.byName("r11") & mask8, nil
case x86asm.R12B:
return regs.byName("r12") & mask8, nil
case x86asm.R13B:
return regs.byName("r13") & mask8, nil
case x86asm.R14B:
return regs.byName("r14") & mask8, nil
case x86asm.R15B:
return regs.byName("r15") & mask8, nil
// 16-bit
case x86asm.AX:
return regs.byName("rax") & mask16, nil
case x86asm.CX:
return regs.byName("rcx") & mask16, nil
case x86asm.DX:
return regs.byName("rdx") & mask16, nil
case x86asm.BX:
return regs.byName("rbx") & mask16, nil
case x86asm.SP:
return regs.byName("rsp") & mask16, nil
case x86asm.BP:
return regs.byName("rbp") & mask16, nil
case x86asm.SI:
return regs.byName("rsi") & mask16, nil
case x86asm.DI:
return regs.byName("rdi") & mask16, nil
case x86asm.R8W:
return regs.byName("r8") & mask16, nil
case x86asm.R9W:
return regs.byName("r9") & mask16, nil
case x86asm.R10W:
return regs.byName("r10") & mask16, nil
case x86asm.R11W:
return regs.byName("r11") & mask16, nil
case x86asm.R12W:
return regs.byName("r12") & mask16, nil
case x86asm.R13W:
return regs.byName("r13") & mask16, nil
case x86asm.R14W:
return regs.byName("r14") & mask16, nil
case x86asm.R15W:
return regs.byName("r15") & mask16, nil
// 32-bit
case x86asm.EAX:
return regs.byName("rax") & mask32, nil
case x86asm.ECX:
return regs.byName("rcx") & mask32, nil
case x86asm.EDX:
return regs.byName("rdx") & mask32, nil
case x86asm.EBX:
return regs.byName("rbx") & mask32, nil
case x86asm.ESP:
return regs.byName("rsp") & mask32, nil
case x86asm.EBP:
return regs.byName("rbp") & mask32, nil
case x86asm.ESI:
return regs.byName("rsi") & mask32, nil
case x86asm.EDI:
return regs.byName("rdi") & mask32, nil
case x86asm.R8L:
return regs.byName("r8") & mask32, nil
case x86asm.R9L:
return regs.byName("r9") & mask32, nil
case x86asm.R10L:
return regs.byName("r10") & mask32, nil
case x86asm.R11L:
return regs.byName("r11") & mask32, nil
case x86asm.R12L:
return regs.byName("r12") & mask32, nil
case x86asm.R13L:
return regs.byName("r13") & mask32, nil
case x86asm.R14L:
return regs.byName("r14") & mask32, nil
case x86asm.R15L:
return regs.byName("r15") & mask32, nil
// 64-bit
case x86asm.RAX:
return regs.byName("rax"), nil
case x86asm.RCX:
return regs.byName("rcx"), nil
case x86asm.RDX:
return regs.byName("rdx"), nil
case x86asm.RBX:
return regs.byName("rbx"), nil
case x86asm.RSP:
return regs.byName("rsp"), nil
case x86asm.RBP:
return regs.byName("rbp"), nil
case x86asm.RSI:
return regs.byName("rsi"), nil
case x86asm.RDI:
return regs.byName("rdi"), nil
case x86asm.R8:
return regs.byName("r8"), nil
case x86asm.R9:
return regs.byName("r9"), nil
case x86asm.R10:
return regs.byName("r10"), nil
case x86asm.R11:
return regs.byName("r11"), nil
case x86asm.R12:
return regs.byName("r12"), nil
case x86asm.R13:
return regs.byName("r13"), nil
case x86asm.R14:
return regs.byName("r14"), nil
case x86asm.R15:
return regs.byName("r15"), nil
}
return 0, proc.ErrUnknownRegister
}
// SetPC will set the value of the PC register to the given value.
func (t *Thread) SetPC(pc uint64) error {
t.regs.setPC(pc)
if t.p.gcmdok {
return t.p.conn.writeRegisters(t.strID, t.regs.buf)
}
reg := t.regs.regs[regnamePC]
return t.p.conn.writeRegister(t.strID, reg.regnum, reg.value)
}
// SetSP will set the value of the SP register to the given value.
func (t *Thread) SetSP(sp uint64) error {
t.regs.setSP(sp)
if t.p.gcmdok {
return t.p.conn.writeRegisters(t.strID, t.regs.buf)
}
reg := t.regs.regs[regnameSP]
return t.p.conn.writeRegister(t.strID, reg.regnum, reg.value)
}
// SetDX will set the value of the DX register to the given value.
func (t *Thread) SetDX(dx uint64) error {
t.regs.setDX(dx)
if t.p.gcmdok {
return t.p.conn.writeRegisters(t.strID, t.regs.buf)
}
reg := t.regs.regs[regnameDX]
return t.p.conn.writeRegister(t.strID, reg.regnum, reg.value)
}
func (regs *gdbRegisters) Slice() []proc.Register {
r := make([]proc.Register, 0, len(regs.regsInfo))
for _, reginfo := range regs.regsInfo {
switch {
case reginfo.Name == "eflags":
r = proc.AppendEflagReg(r, reginfo.Name, uint64(binary.LittleEndian.Uint32(regs.regs[reginfo.Name].value)))
case reginfo.Name == "mxcsr":
r = proc.AppendMxcsrReg(r, reginfo.Name, uint64(binary.LittleEndian.Uint32(regs.regs[reginfo.Name].value)))
case reginfo.Bitsize == 16:
r = proc.AppendWordReg(r, reginfo.Name, binary.LittleEndian.Uint16(regs.regs[reginfo.Name].value))
case reginfo.Bitsize == 32:
r = proc.AppendDwordReg(r, reginfo.Name, binary.LittleEndian.Uint32(regs.regs[reginfo.Name].value))
case reginfo.Bitsize == 64:
r = proc.AppendQwordReg(r, reginfo.Name, binary.LittleEndian.Uint64(regs.regs[reginfo.Name].value))
case reginfo.Bitsize == 80:
idx := 0
for _, stprefix := range []string{"stmm", "st"} {
if strings.HasPrefix(reginfo.Name, stprefix) {
idx, _ = strconv.Atoi(reginfo.Name[len(stprefix):])
break
}
}
value := regs.regs[reginfo.Name].value
r = proc.AppendX87Reg(r, idx, binary.LittleEndian.Uint16(value[8:]), binary.LittleEndian.Uint64(value[:8]))
case reginfo.Bitsize == 128:
r = proc.AppendSSEReg(r, strings.ToUpper(reginfo.Name), regs.regs[reginfo.Name].value)
case reginfo.Bitsize == 256:
if !strings.HasPrefix(strings.ToLower(reginfo.Name), "ymm") {
continue
}
value := regs.regs[reginfo.Name].value
xmmName := "x" + reginfo.Name[1:]
r = proc.AppendSSEReg(r, strings.ToUpper(xmmName), value[:16])
r = proc.AppendSSEReg(r, strings.ToUpper(reginfo.Name), value[16:])
}
}
return r
}
func (regs *gdbRegisters) Copy() proc.Registers {
savedRegs := &gdbRegisters{}
savedRegs.init(regs.regsInfo)
copy(savedRegs.buf, regs.buf)
return savedRegs
}