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Commit dd87082a authored by Russ Cox's avatar Russ Cox
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import debug/proc from usr/austin/ptrace 

R=austin
DELTA=1892  (1892 added, 0 deleted, 0 changed)
OCL=34183
CL=34197
parent d80a177a
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src/pkg/debug/proc/Makefile 0 → 100644
View file @ dd87082a
# Copyright 2009 The Go Authors. All rights reserved.
# Use of this source code is governed by a BSD-style
# license that can be found in the LICENSE file.
include $(GOROOT)/src/Make.$(GOARCH)
TARG=ptrace
GOFILES=\
proc.go\
proc_linux.go\
regs_$(GOOS)_$(GOARCH).go\
include $(GOROOT)/src/Make.pkg
src/pkg/debug/proc/proc.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Package ptrace provides a platform-independent interface for
// tracing and controlling running processes. It supports
// multi-threaded processes and provides typical low-level debugging
// controls such as breakpoints, single stepping, and manipulating
// memory and registers.
package proc
import (
"os";
"strconv";
)
type Word uint64
// A Cause explains why a thread is stopped.
type Cause interface {
String() string;
}
// Regs is a set of named machine registers, including a program
// counter, link register, and stack pointer.
//
// TODO(austin) There's quite a proliferation of methods here. We
// could make a Reg interface with Get and Set and make this just PC,
// Link, SP, Names, and Reg. We could also put Index in Reg and that
// makes it easy to get the index of things like the PC (currently
// there's just no way to know that). This would also let us include
// other per-register information like how to print it.
type Regs interface {
// PC returns the value of the program counter.
PC() Word;
// SetPC sets the program counter to val.
SetPC(val Word) os.Error;
// Link returns the link register, if any.
Link() Word;
// SetLink sets the link register to val.
SetLink(val Word) os.Error;
// SP returns the value of the stack pointer.
SP() Word;
// SetSP sets the stack pointer register to val.
SetSP(val Word) os.Error;
// Names returns the names of all of the registers.
Names() []string;
// Get returns the value of a register, where i corresponds to
// the index of the register's name in the array returned by
// Names.
Get(i int) Word;
// Set sets the value of a register.
Set(i int, val Word) os.Error;
}
// Thread is a thread in the process being traced.
type Thread interface {
// Step steps this thread by a single instruction. The thread
// must be stopped. If the thread is currently stopped on a
// breakpoint, this will step over the breakpoint.
//
// XXX What if it's stopped because of a signal?
Step() os.Error;
// Stopped returns the reason that this thread is stopped. It
// is an error is the thread not stopped.
Stopped() (Cause, os.Error);
// Regs retrieves the current register values from this
// thread. The thread must be stopped.
Regs() (Regs, os.Error);
// Peek reads len(out) bytes from the address addr in this
// thread into out. The thread must be stopped. It returns
// the number of bytes successfully read. If an error occurs,
// such as attempting to read unmapped memory, this count
// could be short and an error will be returned. If this does
// encounter unmapped memory, it will read up to the byte
// preceding the unmapped area.
Peek(addr Word, out []byte) (int, os.Error);
// Poke writes b to the address addr in this thread. The
// thread must be stopped. It returns the number of bytes
// successfully written. If an error occurs, such as
// attempting to write to unmapped memory, this count could be
// short and an error will be returned. If this does
// encounter unmapped memory, it will write up to the byte
// preceding the unmapped area.
Poke(addr Word, b []byte) (int, os.Error);
}
// Process is a process being traced. It consists of a set of
// threads. A process can be running, stopped, or terminated. The
// process's state extends to all of its threads.
type Process interface {
// Threads returns an array of all threads in this process.
Threads() []Thread;
// AddBreakpoint creates a new breakpoint at program counter
// pc. Breakpoints can only be created when the process is
// stopped. It is an error if a breakpoint already exists at
// pc.
AddBreakpoint(pc Word) os.Error;
// RemoveBreakpoint removes the breakpoint at the program
// counter pc. It is an error if no breakpoint exists at pc.
RemoveBreakpoint(pc Word) os.Error;
// Stop stops all running threads in this process before
// returning.
Stop() os.Error;
// Continue resumes execution of all threads in this process.
// Any thread that is stopped on a breakpoint will be stepped
// over that breakpoint. Any thread that is stopped because
// of a signal (other than SIGSTOP or SIGTRAP) will receive
// the pending signal.
Continue() os.Error;
// WaitStop waits until all threads in process p are stopped
// as a result of some thread hitting a breakpoint, receiving
// a signal, creating a new thread, or exiting.
WaitStop() os.Error;
// Detach detaches from this process. All stopped threads
// will be resumed.
Detach() os.Error;
}
// Stopped is a stop cause used for threads that are stopped either by
// user request (e.g., from the Stop method or after single stepping),
// or that are stopped because some other thread caused the program to
// stop.
type Stopped struct {}
func (c Stopped) String() string {
return "stopped";
}
// Breakpoint is a stop cause resulting from a thread reaching a set
// breakpoint.
type Breakpoint Word
// PC returns the program counter that the program is stopped at.
func (c Breakpoint) PC() Word {
return Word(c);
}
func (c Breakpoint) String() string {
return "breakpoint at 0x" + strconv.Uitob64(uint64(c.PC()), 16);
}
// Signal is a stop cause resulting from a thread receiving a signal.
// When the process is continued, the signal will be delivered.
type Signal string
// Signal returns the signal being delivered to the thread.
func (c Signal) Name() string {
return string(c);
}
func (c Signal) String() string {
return c.Name();
}
// ThreadCreate is a stop cause returned from an existing thread when
// it creates a new thread. The new thread exists in a primordial
// form at this point and will begin executing in earnest when the
// process is continued.
type ThreadCreate struct {
thread Thread;
}
func (c *ThreadCreate) NewThread() Thread {
return c.thread;
}
func (c *ThreadCreate) String() string {
return "thread create";
}
// ThreadExit is a stop cause resulting from a thread exiting. When
// this cause first arises, the thread will still be in the list of
// process threads and its registers and memory will still be
// accessible.
type ThreadExit struct {
exitStatus int;
signal string;
}
// Exited returns true if the thread exited normally.
func (c *ThreadExit) Exited() bool {
return c.exitStatus != -1;
}
// ExitStatus returns the exit status of the thread if it exited
// normally or -1 otherwise.
func (c *ThreadExit) ExitStatus() int {
return c.exitStatus;
}
// Signaled returns true if the thread was terminated by a signal.
func (c *ThreadExit) Signaled() bool {
return c.exitStatus == -1;
}
// StopSignal returns the signal that terminated the thread, or "" if
// it was not terminated by a signal.
func (c *ThreadExit) StopSignal() string {
return c.signal;
}
func (c *ThreadExit) String() string {
res := "thread exited ";
switch {
case c.Exited():
res += "with status " + strconv.Itoa(c.ExitStatus());
case c.Signaled():
res += "from signal " + c.StopSignal();
default:
res += "from unknown cause";
}
return res;
}
src/pkg/debug/proc/proc_darwin.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package proc
import "os"
// Process tracing is not supported on OS X yet.
func Attach(pid int) (Process, os.Error) {
return nil, os.NewError("debug/proc not implemented on OS X");
}
func ForkExec(argv0 string, argv []string, envv []string, dir string, fd []*os.File) (Process, os.Error) {
return Attach(0);
}
src/pkg/debug/proc/proc_linux.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package proc
import (
"container/vector";
"fmt";
"io";
"os";
"runtime";
"strconv";
"strings";
"sync";
"syscall";
)
// This is an implementation of the process tracing interface using
// Linux's ptrace(2) interface. The implementation is multi-threaded.
// Each attached process has an associated monitor thread, and each
// running attached thread has an associated "wait" thread. The wait
// thread calls wait4 on the thread's TID and reports any wait events
// or errors via "debug events". The monitor thread consumes these
// wait events and updates the internally maintained state of each
// thread. All ptrace calls must run in the monitor thread, so the
// monitor executes closures received on the debugReq channel.
//
// As ptrace's documentation is somewhat light, this is heavily based
// on information gleaned from the implementation of ptrace found at
// http://lxr.linux.no/linux+v2.6.30/kernel/ptrace.c
// http://lxr.linux.no/linux+v2.6.30/arch/x86/kernel/ptrace.c#L854
// as well as experimentation and examination of gdb's behavior.
const (
trace = false;
traceIP = false;
traceMem = false;
)
/*
* Thread state
*/
// Each thread can be in one of the following set of states.
// Each state satisfies
// isRunning() || isStopped() || isZombie() || isTerminal().
//
// Running threads can be sent signals and must be waited on, but they
// cannot be inspected using ptrace.
//
// Stopped threads can be inspected and continued, but cannot be
// meaningfully waited on. They can be sent signals, but the signals
// will be queued until they are running again.
//
// Zombie threads cannot be inspected, continued, or sent signals (and
// therefore they cannot be stopped), but they must be waited on.
//
// Terminal threads no longer exist in the OS and thus you can't do
// anything with them.
type threadState string;
const (
running threadState = "Running";
singleStepping threadState = "SingleStepping"; // Transient
stopping threadState = "Stopping"; // Transient
stopped threadState = "Stopped";
stoppedBreakpoint threadState = "StoppedBreakpoint";
stoppedSignal threadState = "StoppedSignal";
stoppedThreadCreate threadState = "StoppedThreadCreate";
stoppedExiting threadState = "StoppedExiting";
exiting threadState = "Exiting"; // Transient (except main thread)
exited threadState = "Exited";
detached threadState = "Detached";
)
func (ts threadState) isRunning() bool {
return ts == running || ts == singleStepping || ts == stopping;
}
func (ts threadState) isStopped() bool {
return ts == stopped || ts == stoppedBreakpoint || ts == stoppedSignal || ts == stoppedThreadCreate || ts == stoppedExiting;
}
func (ts threadState) isZombie() bool {
return ts == exiting;
}
func (ts threadState) isTerminal() bool {
return ts == exited || ts == detached;
}
func (ts threadState) String() string {
return string(ts);
}
/*
* Basic types
*/
// A breakpoint stores information about a single breakpoint,
// including its program counter, the overwritten text if the
// breakpoint is installed.
type breakpoint struct {
pc uintptr;
olddata []byte;
}
func (bp *breakpoint) String() string {
if bp == nil {
return "<nil>";
}
return fmt.Sprintf("%#x", bp.pc);
}
// bpinst386 is the breakpoint instruction used on 386 and amd64.
var bpinst386 = []byte{0xcc};
// A debugEvent represents a reason a thread stopped or a wait error.
type debugEvent struct {
*os.Waitmsg;
t *thread;
err os.Error;
}
// A debugReq is a request to execute a closure in the monitor thread.
type debugReq struct {
f func () os.Error;
res chan os.Error;
}
// A transitionHandler specifies a function to be called when a thread
// changes state and a function to be called when an error occurs in
// the monitor. Both run in the monitor thread. Before the monitor
// invokes a handler, it removes the handler from the handler queue.
// The handler should re-add itself if needed.
type transitionHandler struct {
handle func (*thread, threadState, threadState);
onErr func (os.Error);
}
// A process is a Linux process, which consists of a set of threads.
// Each running process has one monitor thread, which processes
// messages from the debugEvents, debugReqs, and stopReq channels and
// calls transition handlers.
type process struct {
pid int;
threads map[int] *thread;
breakpoints map[uintptr] *breakpoint;
debugEvents chan *debugEvent;
debugReqs chan *debugReq;
stopReq chan os.Error;
transitionHandlers *vector.Vector;
}
// A thread represents a Linux thread in another process that is being
// debugged. Each running thread has an associated goroutine that
// waits for thread updates and sends them to the process monitor.
type thread struct {
tid int;
proc *process;
// Whether to ignore the next SIGSTOP received by wait.
ignoreNextSigstop bool;
// Thread state. Only modified via setState.
state threadState;
// If state == StoppedBreakpoint
breakpoint *breakpoint;
// If state == StoppedSignal or state == Exited
signal int;
// If state == StoppedThreadCreate
newThread *thread;
// If state == Exited
exitStatus int;
}
/*
* Errors
*/
type badState struct {
thread *thread;
message string;
state threadState;
}
func (e *badState) String() string {
return fmt.Sprintf("Thread %d %s from state %v", e.thread.tid, e.message, e.state);
}
type breakpointExistsError Word
func (e breakpointExistsError) String() string {
return fmt.Sprintf("breakpoint already exists at PC %#x", e);
}
type noBreakpointError Word
func (e noBreakpointError) String() string {
return fmt.Sprintf("no breakpoint at PC %#x", e);
}
type newThreadError struct {
*os.Waitmsg;
wantPid int;
wantSig int;
}
func (e *newThreadError) String() string {
return fmt.Sprintf("newThread wait wanted pid %v and signal %v, got %v and %v", e.Pid, e.StopSignal(), e.wantPid, e.wantSig);
}
/*
* Ptrace wrappers
*/
func (t *thread) ptracePeekText(addr uintptr, out []byte) (int, os.Error) {
c, err := syscall.PtracePeekText(t.tid, addr, out);
if traceMem {
fmt.Printf("peek(%#x) => %v, %v\n", addr, out, err);
}
return c, os.NewSyscallError("ptrace(PEEKTEXT)", err);
}
func (t *thread) ptracePokeText(addr uintptr, out []byte) (int, os.Error) {
c, err := syscall.PtracePokeText(t.tid, addr, out);
if traceMem {
fmt.Printf("poke(%#x, %v) => %v\n", addr, out, err);
}
return c, os.NewSyscallError("ptrace(POKETEXT)", err);
}
func (t *thread) ptraceGetRegs(regs *syscall.PtraceRegs) os.Error {
err := syscall.PtraceGetRegs(t.tid, regs);
return os.NewSyscallError("ptrace(GETREGS)", err);
}
func (t *thread) ptraceSetRegs(regs *syscall.PtraceRegs) os.Error {
err := syscall.PtraceSetRegs(t.tid, regs);
return os.NewSyscallError("ptrace(SETREGS)", err);
}
func (t *thread) ptraceSetOptions(options int) os.Error {
err := syscall.PtraceSetOptions(t.tid, options);
return os.NewSyscallError("ptrace(SETOPTIONS)", err);
}
func (t *thread) ptraceGetEventMsg() (uint, os.Error) {
msg, err := syscall.PtraceGetEventMsg(t.tid);
return msg, os.NewSyscallError("ptrace(GETEVENTMSG)", err);
}
func (t *thread) ptraceCont() os.Error {
err := syscall.PtraceCont(t.tid, 0);
return os.NewSyscallError("ptrace(CONT)", err);
}
func (t *thread) ptraceContWithSignal(sig int) os.Error {
err := syscall.PtraceCont(t.tid, sig);
return os.NewSyscallError("ptrace(CONT)", err);
}
func (t *thread) ptraceStep() os.Error {
err := syscall.PtraceSingleStep(t.tid);
return os.NewSyscallError("ptrace(SINGLESTEP)", err);
}
func (t *thread) ptraceDetach() os.Error {
err := syscall.PtraceDetach(t.tid);
return os.NewSyscallError("ptrace(DETACH)", err);
}
/*
* Logging utilties
*/
var logLock sync.Mutex
func (t *thread) logTrace(format string, args ...) {
if !trace {
return;
}
logLock.Lock();
defer logLock.Unlock();
fmt.Fprintf(os.Stderr, "Thread %d", t.tid);
if traceIP {
var regs syscall.PtraceRegs;
err := t.ptraceGetRegs(&regs);
if err == nil {
fmt.Fprintf(os.Stderr, "@%x", regs.Rip);
}
}
fmt.Fprint(os.Stderr, ": ");
fmt.Fprintf(os.Stderr, format, args);
fmt.Fprint(os.Stderr, "\n");
}
func (t *thread) warn(format string, args ...) {
logLock.Lock();
defer logLock.Unlock();
fmt.Fprintf(os.Stderr, "Thread %d: WARNING ", t.tid);
fmt.Fprintf(os.Stderr, format, args);
fmt.Fprint(os.Stderr, "\n");
}
func (p *process) logTrace(format string, args ...) {
if !trace {
return;
}
logLock.Lock();
defer logLock.Unlock();
fmt.Fprintf(os.Stderr, "Process %d: ", p.pid);
fmt.Fprintf(os.Stderr, format, args);
fmt.Fprint(os.Stderr, "\n");
}
/*
* State utilities
*/
// someStoppedThread returns a stopped thread from the process.
// Returns nil if no threads are stopped.
//
// Must be called from the monitor thread.
func (p *process) someStoppedThread() *thread {
for _, t := range p.threads {
if t.state.isStopped() {
return t;
}
}
return nil;
}
// someRunningThread returns a running thread from the process.
// Returns nil if no threads are running.
//
// Must be called from the monitor thread.
func (p *process) someRunningThread() *thread {
for _, t := range p.threads {
if t.state.isRunning() {
return t;
}
}
return nil;
}
/*
* Breakpoint utilities
*/
// installBreakpoints adds breakpoints to the attached process.
//
// Must be called from the monitor thread.
func (p *process) installBreakpoints() os.Error {
n := 0;
main := p.someStoppedThread();
for _, b := range p.breakpoints {
if b.olddata != nil {
continue;
}
b.olddata = make([]byte, len(bpinst386));
_, err := main.ptracePeekText(uintptr(b.pc), b.olddata);
if err != nil {
b.olddata = nil;
return err;
}
_, err = main.ptracePokeText(uintptr(b.pc), bpinst386);
if err != nil {
b.olddata = nil;
return err;
}
n++;
}
if n > 0 {
p.logTrace("installed %d/%d breakpoints", n, len(p.breakpoints));
}
return nil;
}
// uninstallBreakpoints removes the installed breakpoints from p.
//
// Must be called from the monitor thread.
func (p *process) uninstallBreakpoints() os.Error {
n := 0;
main := p.someStoppedThread();
for _, b := range p.breakpoints {
if b.olddata == nil {
continue;
}
_, err := main.ptracePokeText(uintptr(b.pc), b.olddata);
if err != nil {
return err;
}
b.olddata = nil;
n++;
}
if n > 0 {
p.logTrace("uninstalled %d/%d breakpoints", n, len(p.breakpoints));
}
return nil;
}
/*
* Debug event handling
*/
// wait waits for a wait event from this thread and sends it on the
// debug events channel for this thread's process. This should be
// started in its own goroutine when the attached thread enters a
// running state. The goroutine will exit as soon as it sends a debug
// event.
func (t *thread) wait() {
for {
var err os.Error;
var ev debugEvent;
ev.t = t;
t.logTrace("beginning wait");
ev.Waitmsg, ev.err = os.Wait(t.tid, syscall.WALL);
if ev.err == nil && ev.Pid != t.tid {
panic("Wait returned pid ", ev.Pid, " wanted ", t.tid);
}
if ev.StopSignal() == syscall.SIGSTOP && t.ignoreNextSigstop {
// Spurious SIGSTOP. See Thread.Stop().
t.ignoreNextSigstop = false;
err := t.ptraceCont();
if err == nil {
continue;
}
// If we failed to continue, just let
// the stop go through so we can
// update the thread's state.
}
t.proc.debugEvents <- &ev;
break;
}
}
// setState sets this thread's state, starts a wait thread if
// necessary, and invokes state transition handlers.
//
// Must be called from the monitor thread.
func (t *thread) setState(new threadState) {
old := t.state;
t.state = new;
t.logTrace("state %v -> %v", old, new);
if !old.isRunning() && (new.isRunning() || new.isZombie()) {
// Start waiting on this thread
go t.wait();
}
// Invoke state change handlers
handlers := t.proc.transitionHandlers;
if handlers.Len() == 0 {
return;
}
t.proc.transitionHandlers = vector.New(0);
for _, h := range handlers.Data() {
h := h.(*transitionHandler);
h.handle(t, old, new);
}
}
// sendSigstop sends a SIGSTOP to this thread.
func (t *thread) sendSigstop() os.Error {
t.logTrace("sending SIGSTOP");
err := syscall.Tgkill(t.proc.pid, t.tid, syscall.SIGSTOP);
return os.NewSyscallError("tgkill", err);
}
// stopAsync sends SIGSTOP to all threads in state 'running'.
//
// Must be called from the monitor thread.
func (p *process) stopAsync() os.Error {
for _, t := range p.threads {
if t.state == running {
err := t.sendSigstop();
if err != nil {
return err;
}
t.setState(stopping);
}
}
return nil;
}
// doTrap handles SIGTRAP debug events with a cause of 0. These can
// be caused either by an installed breakpoint, a breakpoint in the
// program text, or by single stepping.
//
// TODO(austin) I think we also get this on an execve syscall.
func (ev *debugEvent) doTrap() (threadState, os.Error) {
t := ev.t;
if t.state == singleStepping {
return stopped, nil;
}
// Hit a breakpoint. Linux leaves the program counter after
// the breakpoint. If this is an installed breakpoint, we
// need to back the PC up to the breakpoint PC.
var regs syscall.PtraceRegs;
err := t.ptraceGetRegs(&regs);
if err != nil {
return stopped, err;
}
b, ok := t.proc.breakpoints[uintptr(regs.Rip)-uintptr(len(bpinst386))];
if !ok {
// We must have hit a breakpoint that was actually in
// the program. Leave the IP where it is so we don't
// re-execute the breakpoint instruction. Expose the
// fact that we stopped with a SIGTRAP.
return stoppedSignal, nil;
}
t.breakpoint = b;
t.logTrace("at breakpoint %v, backing up PC from %#x", b, regs.Rip);
regs.Rip = uint64(b.pc);
err = t.ptraceSetRegs(&regs);
if err != nil {
return stopped, err;
}
return stoppedBreakpoint, nil;
}
// doPtraceClone handles SIGTRAP debug events with a PTRACE_EVENT_CLONE
// cause. It initializes the new thread, adds it to the process, and
// returns the appropriate thread state for the existing thread.
func (ev *debugEvent) doPtraceClone() (threadState, os.Error) {
t := ev.t;
// Get the TID of the new thread
tid, err := t.ptraceGetEventMsg();
if err != nil {
return stopped, err;
}
nt, err := t.proc.newThread(int(tid), syscall.SIGSTOP, true);
if err != nil {
return stopped, err;
}
// Remember the thread
t.newThread = nt;
return stoppedThreadCreate, nil;
}
// doPtraceExit handles SIGTRAP debug events with a PTRACE_EVENT_EXIT
// cause. It sets up the thread's state, but does not remove it from
// the process. A later WIFEXITED debug event will remove it from the
// process.
func (ev *debugEvent) doPtraceExit() (threadState, os.Error) {
t := ev.t;
// Get exit status
exitStatus, err := t.ptraceGetEventMsg();
if err != nil {
return stopped, err;
}
ws := syscall.WaitStatus(exitStatus);
t.logTrace("exited with %v", ws);
switch {
case ws.Exited():
t.exitStatus = ws.ExitStatus();
case ws.Signaled():
t.signal = ws.Signal();
}
// We still need to continue this thread and wait on this
// thread's WIFEXITED event. We'll delete it then.
return stoppedExiting, nil;
}
// process handles a debug event. It modifies any thread or process
// state as necessary, uninstalls breakpoints if necessary, and stops
// any running threads.
func (ev *debugEvent) process() os.Error {
if ev.err != nil {
return ev.err;
}
t := ev.t;
t.exitStatus = -1;
t.signal = -1;
// Decode wait status.
var state threadState;
switch {
case ev.Stopped():
state = stoppedSignal;
t.signal = ev.StopSignal();
t.logTrace("stopped with %v", ev);
if ev.StopSignal() == syscall.SIGTRAP {
// What caused the debug trap?
var err os.Error;
switch cause := ev.TrapCause(); cause {
case 0:
// Breakpoint or single stepping
state, err = ev.doTrap();
case syscall.PTRACE_EVENT_CLONE:
state, err = ev.doPtraceClone();
case syscall.PTRACE_EVENT_EXIT:
state, err = ev.doPtraceExit();
default:
t.warn("Unknown trap cause %d", cause);
}
if err != nil {
t.setState(stopped);
t.warn("failed to handle trap %v: %v", ev, err);
}
}
case ev.Exited():
state = exited;
t.proc.threads[t.tid] = nil, false;
t.logTrace("exited %v", ev);
// We should have gotten the exit status in
// PTRACE_EVENT_EXIT, but just in case.
t.exitStatus = ev.ExitStatus();
case ev.Signaled():
state = exited;
t.proc.threads[t.tid] = nil, false;
t.logTrace("signaled %v", ev);
// Again, this should be redundant.
t.signal = ev.Signal();
default:
panic(fmt.Sprintf("Unexpected wait status %v", ev.Waitmsg));
}
// If we sent a SIGSTOP to the thread (indicated by state
// Stopping), we might have raced with a different type of
// stop. If we didn't get the stop we expected, then the
// SIGSTOP we sent is now queued up, so we should ignore the
// next one we get.
if t.state == stopping && ev.StopSignal() != syscall.SIGSTOP {
t.ignoreNextSigstop = true;
}
// TODO(austin) If we're in state stopping and get a SIGSTOP,
// set state stopped instead of stoppedSignal.
t.setState(state);
if t.proc.someRunningThread() == nil {
// Nothing is running, uninstall breakpoints
return t.proc.uninstallBreakpoints();
}
// Stop any other running threads
return t.proc.stopAsync();
}
// onStop adds a handler for state transitions from running to
// non-running states. The handler will be called from the monitor
// thread.
//
// Must be called from the monitor thread.
func (t *thread) onStop(handle func (), onErr func (os.Error)) {
// TODO(austin) This is rather inefficient for things like
// stepping all threads during a continue. Maybe move
// transitionHandlers to the thread, or have both per-thread
// and per-process transition handlers.
h := &transitionHandler{nil, onErr};
h.handle = func (st *thread, old, new threadState) {
if t == st && old.isRunning() && !new.isRunning() {
handle();
} else {
t.proc.transitionHandlers.Push(h);
}
};
t.proc.transitionHandlers.Push(h);
}
/*
* Event monitor
*/
// monitor handles debug events and debug requests for p, exiting when
// there are no threads left in p.
//
// TODO(austin) When an unrecoverable error occurs, abort the monitor
// and record this error so all future calls to do will return it
// immediately.
func (p *process) monitor() {
var err os.Error;
// Linux requires that all ptrace calls come from the thread
// that originally attached. Prevent the Go scheduler from
// migrating us to other OS threads.
runtime.LockOSThread();
defer runtime.UnlockOSThread();
hadThreads := false;
for {
select {
case event := <-p.debugEvents:
err = event.process();
if err != nil {
break;
}
case req := <-p.debugReqs:
req.res <- req.f();
case err = <-p.stopReq:
break;
}
if len(p.threads) == 0 {
if hadThreads {
p.logTrace("no more threads; monitor exiting");
// TODO(austin) Use a real error do
// future operations will fail
err = nil;
break;
}
} else {
hadThreads = true;
}
}
// Abort waiting handlers
for _, h := range p.transitionHandlers.Data() {
h := h.(*transitionHandler);
h.onErr(err);
}
// TODO(austin) How do I stop the wait threads?
if err != nil {
panic(err.String());
}
}
// do executes f in the monitor thread (and, thus, atomically with
// respect to thread state changes). f must not block.
//
// Must NOT be called from the monitor thread.
func (p *process) do(f func () os.Error) os.Error {
// TODO(austin) If monitor is stopped, return error.
req := &debugReq{f, make(chan os.Error)};
p.debugReqs <- req;
return <-req.res;
}
// stopMonitor stops the monitor with the given error. If the monitor
// is already stopped, does nothing.
func (p *process) stopMonitor(err os.Error) {
doNotBlock := p.stopReq <- err;
// TODO(austin) Wait until monitor has exited?
}
/*
* Public thread interface
*/
func (t *thread) Regs() (Regs, os.Error) {
var regs syscall.PtraceRegs;
err := t.proc.do(func () os.Error {
if !t.state.isStopped() {
return &badState{t, "cannot get registers", t.state};
}
return t.ptraceGetRegs(&regs);
});
if err != nil {
return nil, err;
}
setter := func (r *syscall.PtraceRegs) os.Error {
return t.proc.do(func () os.Error {
if !t.state.isStopped() {
return &badState{t, "cannot get registers", t.state};
}
return t.ptraceSetRegs(r);
});
};
return newRegs(&regs, setter), nil;
}
func (t *thread) Peek(addr Word, out []byte) (int, os.Error) {
var c int;
err := t.proc.do(func () os.Error {
if !t.state.isStopped() {
return &badState{t, "cannot peek text", t.state};
}
var err os.Error;
c, err = t.ptracePeekText(uintptr(addr), out);
return err;
});
return c, err;
}
func (t *thread) Poke(addr Word, out []byte) (int, os.Error) {
var c int;
err := t.proc.do(func () os.Error {
if !t.state.isStopped() {
return &badState{t, "cannot poke text", t.state};
}
var err os.Error;
c, err = t.ptracePokeText(uintptr(addr), out);
return err;
});
return c, err;
}
// stepAsync starts this thread single stepping. When the single step
// is complete, it will send nil on the given channel. If an error
// occurs while setting up the single step, it returns that error. If
// an error occurs while waiting for the single step to complete, it
// sends that error on the channel.
func (t *thread) stepAsync(ready chan os.Error) os.Error {
if err := t.ptraceStep(); err != nil {
return err;
}
t.setState(singleStepping);
t.onStop(func () {
ready <- nil;
},
func (err os.Error) {
ready <- err;
});
return nil;
}
func (t *thread) Step() os.Error {
t.logTrace("Step {");
defer t.logTrace("}");
ready := make(chan os.Error);
err := t.proc.do(func () os.Error {
if !t.state.isStopped() {
return &badState{t, "cannot single step", t.state};
}
return t.stepAsync(ready);
});
if err != nil {
return err;
}
err = <-ready;
return err;
}
// TODO(austin) We should probably get this via C's strsignal.
var sigNames = [...]string {
"SIGEXIT", "SIGHUP", "SIGINT", "SIGQUIT", "SIGILL",
"SIGTRAP", "SIGABRT", "SIGBUS", "SIGFPE", "SIGKILL",
"SIGUSR1", "SIGSEGV", "SIGUSR2", "SIGPIPE", "SIGALRM",
"SIGTERM", "SIGSTKFLT", "SIGCHLD", "SIGCONT", "SIGSTOP",
"SIGTSTP", "SIGTTIN", "SIGTTOU", "SIGURG", "SIGXCPU",
"SIGXFSZ", "SIGVTALRM", "SIGPROF", "SIGWINCH", "SIGPOLL",
"SIGPWR", "SIGSYS"
}
// sigName returns the symbolic name for the given signal number. If
// the signal number is invalid, returns "<invalid>".
func sigName(signal int) string {
if signal < 0 || signal >= len(sigNames) {
return "<invalid>";
}
return sigNames[signal];
}
func (t *thread) Stopped() (Cause, os.Error) {
var c Cause;
err := t.proc.do(func() os.Error {
switch t.state {
case stopped:
c = Stopped{};
case stoppedBreakpoint:
c = Breakpoint(t.breakpoint.pc);
case stoppedSignal:
c = Signal(sigName(t.signal));
case stoppedThreadCreate:
c = &ThreadCreate{t.newThread};
case stoppedExiting, exiting, exited:
if t.signal == -1 {
c = &ThreadExit{t.exitStatus, ""};
} else {
c = &ThreadExit{t.exitStatus, sigName(t.signal)};
}
default:
return &badState{t, "cannot get stop cause", t.state};
}
return nil;
});
if err != nil {
return nil, err;
}
return c, nil;
}
func (p *process) Threads() []Thread {
var res []Thread;
p.do(func () os.Error {
res = make([]Thread, len(p.threads));
i := 0;
for _, t := range p.threads {
// Exclude zombie threads.
st := t.state;
if st == exiting || st == exited || st == detached {
continue;
}
res[i] = t;
i++;
}
res = res[0:i];
return nil;
});
return res;
}
func (p *process) AddBreakpoint(pc Word) os.Error {
return p.do(func () os.Error {
if t := p.someRunningThread(); t != nil {
return &badState{t, "cannot add breakpoint", t.state};
}
if _, ok := p.breakpoints[uintptr(pc)]; ok {
return breakpointExistsError(pc);
}
p.breakpoints[uintptr(pc)] = &breakpoint{pc: uintptr(pc)};
return nil;
});
}
func (p *process) RemoveBreakpoint(pc Word) os.Error {
return p.do(func () os.Error {
if t := p.someRunningThread(); t != nil {
return &badState{t, "cannot remove breakpoint", t.state};
}
if _, ok := p.breakpoints[uintptr(pc)]; !ok {
return noBreakpointError(pc);
}
p.breakpoints[uintptr(pc)] = nil, false;
return nil;
});
}
func (p *process) Continue() os.Error {
// Single step any threads that are stopped at breakpoints so
// we can reinstall breakpoints.
var ready chan os.Error;
count := 0;
err := p.do(func () os.Error {
// We make the ready channel big enough to hold all
// ready message so we don't jam up the monitor if we
// stop listening (e.g., if there's an error).
ready = make(chan os.Error, len(p.threads));
for _, t := range p.threads {
if !t.state.isStopped() {
continue;
}
// We use the breakpoint map directly here
// instead of checking the stop cause because
// it could have been stopped at a breakpoint
// for some other reason, or the breakpoint
// could have been added since it was stopped.
var regs syscall.PtraceRegs;
err := t.ptraceGetRegs(&regs);
if err != nil {
return err;
}
if b, ok := p.breakpoints[uintptr(regs.Rip)]; ok {
t.logTrace("stepping over breakpoint %v", b);
if err := t.stepAsync(ready); err != nil {
return err;
}
count++;
}
}
return nil;
});
if err != nil {
p.stopMonitor(err);
return err;
}
// Wait for single stepping threads
for count > 0 {
err = <-ready;
if err != nil {
p.stopMonitor(err);
return err;
}
count--;
}
// Continue all threads
err = p.do(func () os.Error {
if err := p.installBreakpoints(); err != nil {
return err;
}
for _, t := range p.threads {
var err os.Error;
switch {
case !t.state.isStopped():
continue;
case t.state == stoppedSignal && t.signal != syscall.SIGSTOP && t.signal != syscall.SIGTRAP:
t.logTrace("continuing with signal %d", t.signal);
err = t.ptraceContWithSignal(t.signal);
default:
t.logTrace("continuing");
err = t.ptraceCont();
}
if err != nil {
return err;
}
if t.state == stoppedExiting {
t.setState(exiting);
} else {
t.setState(running);
}
}
return nil;
});
if err != nil {
// TODO(austin) Do we need to stop the monitor with
// this error atomically with the do-routine above?
p.stopMonitor(err);
return err;
}
return nil;
}
func (p *process) WaitStop() os.Error {
// We need a non-blocking ready channel for the case where all
// threads are already stopped.
ready := make(chan os.Error, 1);
err := p.do(func () os.Error {
// Are all of the threads already stopped?
if p.someRunningThread() == nil {
ready <- nil;
return nil;
}
// Monitor state transitions
h := &transitionHandler{};
h.handle = func (st *thread, old, new threadState) {
if !new.isRunning() {
if p.someRunningThread() == nil {
ready <- nil;
return;
}
}
p.transitionHandlers.Push(h);
};
h.onErr = func (err os.Error) {
ready <- err;
};
p.transitionHandlers.Push(h);
return nil;
});
if err != nil {
return err;
}
return <-ready;
}
func (p *process) Stop() os.Error {
err := p.do(func () os.Error {
return p.stopAsync();
});
if err != nil {
return err;
}
return p.WaitStop();
}
func (p *process) Detach() os.Error {
if err := p.Stop(); err != nil {
return err;
}
err := p.do(func () os.Error {
if err := p.uninstallBreakpoints(); err != nil {
return err;
}
for pid, t := range p.threads {
if t.state.isStopped() {
// We can't detach from zombies.
if err := t.ptraceDetach(); err != nil {
return err;
}
}
t.setState(detached);
p.threads[pid] = nil, false;
}
return nil;
});
// TODO(austin) Wait for monitor thread to exit?
return err;
}
// newThread creates a new thread object and waits for its initial
// signal. If cloned is true, this thread was cloned from a thread we
// are already attached to.
//
// Must be run from the monitor thread.
func (p *process) newThread(tid int, signal int, cloned bool) (*thread, os.Error) {
t := &thread{tid: tid, proc: p, state: stopped};
// Get the signal from the thread
// TODO(austin) Thread might already be stopped if we're attaching.
w, err := os.Wait(tid, syscall.WALL);
if err != nil {
return nil, err;
}
if w.Pid != tid || w.StopSignal() != signal {
return nil, &newThreadError{w, tid, signal};
}
if !cloned {
err = t.ptraceSetOptions(syscall.PTRACE_O_TRACECLONE | syscall.PTRACE_O_TRACEEXIT);
if err != nil {
return nil, err;
}
}
p.threads[tid] = t;
return t, nil;
}
// attachThread attaches a running thread to the process.
//
// Must NOT be run from the monitor thread.
func (p *process) attachThread(tid int) (*thread, os.Error) {
p.logTrace("attaching to thread %d", tid);
var thr *thread;
err := p.do(func () os.Error {
errno := syscall.PtraceAttach(tid);
if errno != 0 {
return os.NewSyscallError("ptrace(ATTACH)", errno);
}
var err os.Error;
thr, err = p.newThread(tid, syscall.SIGSTOP, false);
return err;
});
return thr, err;
}
// attachAllThreads attaches to all threads in a process.
func (p *process) attachAllThreads() os.Error {
taskPath := "/proc/" + strconv.Itoa(p.pid) + "/task";
taskDir, err := os.Open(taskPath, os.O_RDONLY, 0);
if err != nil {
return err;
}
defer taskDir.Close();
// We stop threads as we attach to them; however, because new
// threads can appear while we're looping over all of them, we
// have to repeatly scan until we know we're attached to all
// of them.
for again := true; again; {
again = false;
tids, err := taskDir.Readdirnames(-1);
if err != nil {
return err;
}
for _, tidStr := range tids {
tid, err := strconv.Atoi(tidStr);
if err != nil {
return err;
}
if _, ok := p.threads[tid]; ok {
continue;
}
t, err := p.attachThread(tid);
if err != nil {
// There could have been a race, or
// this process could be a zobmie.
statFile, err2 := io.ReadFile(taskPath + "/" + tidStr + "/stat");
if err2 != nil {
switch err2 := err2.(type) {
case *os.PathError:
if err2.Error == os.ENOENT {
// Raced with thread exit
p.logTrace("raced with thread %d exit", tid);
continue;
}
}
// Return the original error
return err;
}
statParts := strings.Split(string(statFile), " ", 4);
if len(statParts) > 2 && statParts[2] == "Z" {
// tid is a zombie
p.logTrace("thread %d is a zombie", tid);
continue;
}
// Return the original error
return err;
}
again = true;
}
}
return nil;
}
// newProcess creates a new process object and starts its monitor thread.
func newProcess(pid int) *process {
p := &process{
pid: pid,
threads: make(map[int] *thread),
breakpoints: make(map[uintptr] *breakpoint),
debugEvents: make(chan *debugEvent),
debugReqs: make(chan *debugReq),
stopReq: make(chan os.Error),
transitionHandlers: vector.New(0)
};
go p.monitor();
return p;
}
// Attach attaches to process pid and stops all of its threads.
func Attach(pid int) (Process, os.Error) {
p := newProcess(pid);
// Attach to all threads
err := p.attachAllThreads();
if err != nil {
p.Detach();
// TODO(austin) Detach stopped the monitor already
//p.stopMonitor(err);
return nil, err;
}
return p, nil;
}
// ForkExec forks the current process and execs argv0, stopping the
// new process after the exec syscall. See os.ForkExec for additional
// details.
func ForkExec(argv0 string, argv []string, envv []string, dir string, fd []*os.File) (Process, os.Error)
{
p := newProcess(-1);
// Create array of integer (system) fds.
intfd := make([]int, len(fd));
for i, f := range fd {
if f == nil {
intfd[i] = -1;
} else {
intfd[i] = f.Fd();
}
}
// Fork from the monitor thread so we get the right tracer pid.
err := p.do(func () os.Error {
pid, errno := syscall.PtraceForkExec(argv0, argv, envv, dir, intfd);
if errno != 0 {
return &os.PathError{"fork/exec", argv0, os.Errno(errno)};
}
p.pid = pid;
// The process will raise SIGTRAP when it reaches execve.
t, err := p.newThread(pid, syscall.SIGTRAP, false);
return err;
});
if err != nil {
p.stopMonitor(err);
return nil, err;
}
return p, nil;
}
src/pkg/debug/proc/ptrace-nptl.txt 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
ptrace and NTPL, the missing manpage
== Signals ==
A signal sent to a ptrace'd process or thread causes only the thread
that receives it to stop and report to the attached process.
Use tgkill to target a signal (for example, SIGSTOP) at a particular
thread. If you use kill, the signal could be delivered to another
thread in the same process.
Note that SIGSTOP differs from its usual behavior when a process is
being traced. Usually, a SIGSTOP sent to any thread in a thread group
will stop all threads in the thread group. When a thread is traced,
however, a SIGSTOP affects only the receiving thread (and any other
threads in the thread group that are not traced).
SIGKILL behaves like it does for non-traced processes. It affects all
threads in the process and terminates them without the WSTOPSIG event
generated by other signals. However, if PTRACE_O_TRACEEXIT is set,
the attached process will still receive PTRACE_EVENT_EXIT events
before receiving WIFSIGNALED events.
See "Following thread death" for a caveat regarding signal delivery to
zombie threads.
== Waiting on threads ==
Cloned threads in ptrace'd processes are treated similarly to cloned
threads in your own process. Thus, you must use the __WALL option in
order to receive notifications from threads created by the child
process. Similarly, the __WCLONE option will wait only on
notifications from threads created by the child process and *not* on
notifications from the initial child thread.
Even when waiting on a specific thread's PID using waitpid or similar,
__WALL or __WCLONE is necessary or waitpid will return ECHILD.
== Attaching to existing threads ==
libthread_db (which gdb uses), attaches to existing threads by pulling
the pthread data structures out of the traced process. The much
easier way is to traverse the /proc/PID/task directory, though it's
unclear how the semantics of these two approaches differ.
Unfortunately, if the main thread has exited (but the overall process
has not), it sticks around as a zombie process. This zombie will
appear in the /proc/PID/task directory, but trying to attach to it
will yield EPERM. In this case, the third field of the
/proc/PID/task/PID/stat file will be "Z". Attempting to open the stat
file is also a convenient way to detect races between listing the task
directory and the thread exiting. Coincidentally, gdb will simply
fail to attach to a process whose main thread is a zombie.
Because new threads may be created while the debugger is in the
process of attaching to existing threads, the debugger must repeatedly
re-list the task directory until it has attached to (and thus stopped)
every thread listed.
In order to follow new threads created by existing threads,
PTRACE_O_TRACECLONE must be set on each thread attached to.
== Following new threads ==
With the child process stopped, use PTRACE_SETOPTIONS to set the
PTRACE_O_TRACECLONE option. This option is per-thread, and thus must
be set on each existing thread individually. When an existing thread
with PTRACE_O_TRACECLONE set spawns a new thread, the existing thread
will stop with (SIGTRAP | PTRACE_EVENT_CLONE << 8) and the PID of the
new thread can be retrieved with PTRACE_GETEVENTMSG on the creating
thread. At this time, the new thread will exist, but will initially
be stopped with a SIGSTOP. The new thread will automatically be
traced and will inherit the PTRACE_O_TRACECLONE option from its
parent. The attached process should wait on the new thread to receive
the SIGSTOP notification.
When using waitpid(-1, ...), don't rely on the parent thread reporting
a SIGTRAP before receiving the SIGSTOP from the new child thread.
Without PTRACE_O_TRACECLONE, newly cloned threads will not be
ptrace'd. As a result, signals received by new threads will be
handled in the usual way, which may affect the parent and in turn
appear to the attached process, but attributed to the parent (possibly
in unexpected ways).
== Following thread death ==
If any thread with the PTRACE_O_TRACEEXIT option set exits (either by
returning or pthread_exit'ing), the tracing process will receive an
immediate PTRACE_EVENT_EXIT. At this point, the thread will still
exist. The exit status, encoded as for wait, can be queried using
PTRACE_GETEVENTMSG on the exiting thread's PID. The thread should be
continued so it can actually exit, after which its wait behavior is
the same as for a thread without the PTRACE_O_TRACEEXIT option.
If a non-main thread exits (either by returning or pthread_exit'ing),
its corresponding process will also exit, producing a WIFEXITED event
(after the process is continued from a possible PTRACE_EVENT_EXIT
event). It is *not* necessary for another thread to ptrace_join for
this to happen.
If the main thread exits by returning, then all threads will exit,
first generating a PTRACE_EVENT_EXIT event for each thread if
appropriate, then producing a WIFEXITED event for each thread.
If the main thread exits using pthread_exit, then it enters a
non-waitable zombie state. It will still produce an immediate
PTRACE_O_TRACEEXIT event, but the WIFEXITED event will be delayed
until the entire process exits. This state exists so that shells
don't think the process is done until all of the threads have exited.
Unfortunately, signals cannot be delivered to non-waitable zombies.
Most notably, SIGSTOP cannot be delivered; as a result, when you
broadcast SIGSTOP to all of the threads, you must not wait for
non-waitable zombies to stop. Furthermore, any ptrace command on a
non-waitable zombie, including PTRACE_DETACH, will return ESRCH.
== Multi-threaded debuggers ==
If the debugger itself is multi-threaded, ptrace calls must come from
the same thread that originally attached to the remote thread. The
kernel simply compares the PID of the caller of ptrace against the
tracer PID of the process passed to ptrace. Because each debugger
thread has a different PID, calling ptrace from a different thread
might as well be calling it from a different process and the kernel
will return ESRCH.
wait, on the other hand, does not have this restriction. Any debugger
thread can wait on any thread in the attached process.
src/pkg/debug/proc/regs_darwin_386.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package proc
import "syscall"
func newRegs(regs *syscall.PtraceRegs, setter func (*syscall.PtraceRegs) os.Error) Regs {
panic("newRegs unimplemented on darwin/386");
}
src/pkg/debug/proc/regs_darwin_amd64.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package proc
import "syscall"
func newRegs(regs *syscall.PtraceRegs, setter func (*syscall.PtraceRegs) os.Error) Regs {
panic("newRegs unimplemented on darwin/amd64");
}
src/pkg/debug/proc/regs_linux_386.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package proc
import "syscall"
func newRegs(regs *syscall.PtraceRegs, setter func (*syscall.PtraceRegs) os.Error) Regs {
panic("newRegs unimplemented on linux/386");
}
src/pkg/debug/proc/regs_linux_amd64.go 0 → 100644
View file @ dd87082a
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package proc
import (
"os";
"strconv";
"syscall";
)
type amd64Regs struct {
syscall.PtraceRegs;
setter func (*syscall.PtraceRegs) os.Error;
}
var names = [...]string {
"rax",
"rbx",
"rcx",
"rdx",
"rsi",
"rdi",
"rbp",
"rsp",
"r8",
"r9",
"r10",
"r11",
"r12",
"r13",
"r14",
"r15",
"rip",
"eflags",
"cs",
"ss",
"ds",
"es",
"fs",
"gs",
// PtraceRegs contains these registers, but I don't think
// they're actually meaningful.
//"orig_rax",
//"fs_base",
//"gs_base",
}
func (r *amd64Regs) PC() Word {
return Word(r.Rip);
}
func (r *amd64Regs) SetPC(val Word) os.Error {
r.Rip = uint64(val);
return r.setter(&r.PtraceRegs);
}
func (r *amd64Regs) Link() Word {
// TODO(austin)
panic("No link register");
}
func (r *amd64Regs) SetLink(val Word) os.Error {
panic("No link register");
}
func (r *amd64Regs) SP() Word {
return Word(r.Rsp);
}
func (r *amd64Regs) SetSP(val Word) os.Error {
r.Rsp = uint64(val);
return r.setter(&r.PtraceRegs);
}
func (r *amd64Regs) Names() []string {
return &names;
}
func (r *amd64Regs) Get(i int) Word {
switch i {
case 0: return Word(r.Rax);
case 1: return Word(r.Rbx);
case 2: return Word(r.Rcx);
case 3: return Word(r.Rdx);
case 4: return Word(r.Rsi);
case 5: return Word(r.Rdi);
case 6: return Word(r.Rbp);
case 7: return Word(r.Rsp);
case 8: return Word(r.R8);
case 9: return Word(r.R9);
case 10: return Word(r.R10);
case 11: return Word(r.R11);
case 12: return Word(r.R12);
case 13: return Word(r.R13);
case 14: return Word(r.R14);
case 15: return Word(r.R15);
case 16: return Word(r.Rip);
case 17: return Word(r.Eflags);
case 18: return Word(r.Cs);
case 19: return Word(r.Ss);
case 20: return Word(r.Ds);
case 21: return Word(r.Es);
case 22: return Word(r.Fs);
case 23: return Word(r.Gs);
}
panic("invalid register index ", strconv.Itoa(i));
}
func (r *amd64Regs) Set(i int, val Word) os.Error {
switch i {
case 0: r.Rax = uint64(val);
case 1: r.Rbx = uint64(val);
case 2: r.Rcx = uint64(val);
case 3: r.Rdx = uint64(val);
case 4: r.Rsi = uint64(val);
case 5: r.Rdi = uint64(val);
case 6: r.Rbp = uint64(val);
case 7: r.Rsp = uint64(val);
case 8: r.R8 = uint64(val);
case 9: r.R9 = uint64(val);
case 10: r.R10 = uint64(val);
case 11: r.R11 = uint64(val);
case 12: r.R12 = uint64(val);
case 13: r.R13 = uint64(val);
case 14: r.R14 = uint64(val);
case 15: r.R15 = uint64(val);
case 16: r.Rip = uint64(val);
case 17: r.Eflags = uint64(val);
case 18: r.Cs = uint64(val);
case 19: r.Ss = uint64(val);
case 20: r.Ds = uint64(val);
case 21: r.Es = uint64(val);
case 22: r.Fs = uint64(val);
case 23: r.Gs = uint64(val);
default:
panic("invalid register index ", strconv.Itoa(i));
}
return r.setter(&r.PtraceRegs);
}
func newRegs(regs *syscall.PtraceRegs, setter func (*syscall.PtraceRegs) os.Error) Regs {
res := amd64Regs{};
res.PtraceRegs = *regs;
res.setter = setter;
return &res;
}
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