Google Git
Sign in
rust / rust-lang / llvm-project / 7ade8dc4b84142abd3e6d1fb8a0f4111b0bbd571 / . / lldb / tools / debugserver / source / debugserver.cpp
blob: 42205dedf4bb8d44ff76ba6fbece4533c5070b5f [file] [log] [blame]
//===-- debugserver.cpp -----------------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include <arpa/inet.h>
#include <asl.h>
#include <crt_externs.h>
#include <errno.h>
#include <getopt.h>
#include <netdb.h>
#include <netinet/in.h>
#include <netinet/tcp.h>
#include <string>
#include <sys/select.h>
#include <sys/socket.h>
#include <sys/sysctl.h>
#include <sys/types.h>
#include <sys/un.h>
#include <memory>
#include <vector>
#if defined(__APPLE__)
#include <sched.h>
extern "C" int proc_set_wakemon_params(pid_t, int,
int); // <libproc_internal.h> SPI
#endif
#include "CFString.h"
#include "DNB.h"
#include "DNBLog.h"
#include "DNBTimer.h"
#include "OsLogger.h"
#include "PseudoTerminal.h"
#include "RNBContext.h"
#include "RNBRemote.h"
#include "RNBServices.h"
#include "RNBSocket.h"
#include "SysSignal.h"
// Global PID in case we get a signal and need to stop the process...
nub_process_t g_pid = INVALID_NUB_PROCESS;
// Run loop modes which determine which run loop function will be called
enum RNBRunLoopMode {
eRNBRunLoopModeInvalid = 0,
eRNBRunLoopModeGetStartModeFromRemoteProtocol,
eRNBRunLoopModeInferiorAttaching,
eRNBRunLoopModeInferiorLaunching,
eRNBRunLoopModeInferiorExecuting,
eRNBRunLoopModePlatformMode,
eRNBRunLoopModeExit
};
// Global Variables
RNBRemoteSP g_remoteSP;
static int g_lockdown_opt = 0;
static int g_applist_opt = 0;
static nub_launch_flavor_t g_launch_flavor = eLaunchFlavorDefault;
int g_disable_aslr = 0;
int g_isatty = 0;
bool g_detach_on_error = true;
#define RNBLogSTDOUT(fmt, ...) \
do { \
if (g_isatty) { \
fprintf(stdout, fmt, ##__VA_ARGS__); \
} else { \
_DNBLog(0, fmt, ##__VA_ARGS__); \
} \
} while (0)
#define RNBLogSTDERR(fmt, ...) \
do { \
if (g_isatty) { \
fprintf(stderr, fmt, ##__VA_ARGS__); \
} else { \
_DNBLog(0, fmt, ##__VA_ARGS__); \
} \
} while (0)
// Get our program path and arguments from the remote connection.
// We will need to start up the remote connection without a PID, get the
// arguments, wait for the new process to finish launching and hit its
// entry point, and then return the run loop mode that should come next.
RNBRunLoopMode RNBRunLoopGetStartModeFromRemote(RNBRemote *remote) {
std::string packet;
if (remote) {
RNBContext &ctx = remote->Context();
uint32_t event_mask = RNBContext::event_read_packet_available |
RNBContext::event_read_thread_exiting;
// Spin waiting to get the A packet.
while (true) {
DNBLogThreadedIf(LOG_RNB_MAX,
"%s ctx.Events().WaitForSetEvents( 0x%08x ) ...",
__FUNCTION__, event_mask);
nub_event_t set_events = ctx.Events().WaitForSetEvents(event_mask);
DNBLogThreadedIf(LOG_RNB_MAX,
"%s ctx.Events().WaitForSetEvents( 0x%08x ) => 0x%08x",
__FUNCTION__, event_mask, set_events);
if (set_events & RNBContext::event_read_thread_exiting) {
RNBLogSTDERR("error: packet read thread exited.\n");
return eRNBRunLoopModeExit;
}
if (set_events & RNBContext::event_read_packet_available) {
rnb_err_t err = rnb_err;
RNBRemote::PacketEnum type;
err = remote->HandleReceivedPacket(&type);
// check if we tried to attach to a process
if (type == RNBRemote::vattach || type == RNBRemote::vattachwait ||
type == RNBRemote::vattachorwait) {
if (err == rnb_success) {
RNBLogSTDOUT("Attach succeeded, ready to debug.\n");
return eRNBRunLoopModeInferiorExecuting;
} else {
RNBLogSTDERR("error: attach failed.\n");
return eRNBRunLoopModeExit;
}
}
if (err == rnb_success) {
// If we got our arguments we are ready to launch using the arguments
// and any environment variables we received.
if (type == RNBRemote::set_argv) {
return eRNBRunLoopModeInferiorLaunching;
}
} else if (err == rnb_not_connected) {
RNBLogSTDERR("error: connection lost.\n");
return eRNBRunLoopModeExit;
} else {
// a catch all for any other gdb remote packets that failed
DNBLogThreadedIf(LOG_RNB_MINIMAL, "%s Error getting packet.",
__FUNCTION__);
continue;
}
DNBLogThreadedIf(LOG_RNB_MINIMAL, "#### %s", __FUNCTION__);
} else {
DNBLogThreadedIf(LOG_RNB_MINIMAL,
"%s Connection closed before getting \"A\" packet.",
__FUNCTION__);
return eRNBRunLoopModeExit;
}
}
}
return eRNBRunLoopModeExit;
}
// This run loop mode will wait for the process to launch and hit its
// entry point. It will currently ignore all events except for the
// process state changed event, where it watches for the process stopped
// or crash process state.
RNBRunLoopMode RNBRunLoopLaunchInferior(RNBRemote *remote,
const char *stdin_path,
const char *stdout_path,
const char *stderr_path,
bool no_stdio) {
RNBContext &ctx = remote->Context();
// The Process stuff takes a c array, the RNBContext has a vector...
// So make up a c array.
DNBLogThreadedIf(LOG_RNB_MINIMAL, "%s Launching '%s'...", __FUNCTION__,
ctx.ArgumentAtIndex(0));
size_t inferior_argc = ctx.ArgumentCount();
// Initialize inferior_argv with inferior_argc + 1 NULLs
std::vector<const char *> inferior_argv(inferior_argc + 1, NULL);
size_t i;
for (i = 0; i < inferior_argc; i++)
inferior_argv[i] = ctx.ArgumentAtIndex(i);
// Pass the environment array the same way:
size_t inferior_envc = ctx.EnvironmentCount();
// Initialize inferior_argv with inferior_argc + 1 NULLs
std::vector<const char *> inferior_envp(inferior_envc + 1, NULL);
for (i = 0; i < inferior_envc; i++)
inferior_envp[i] = ctx.EnvironmentAtIndex(i);
// Our launch type hasn't been set to anything concrete, so we need to
// figure our how we are going to launch automatically.
nub_launch_flavor_t launch_flavor = g_launch_flavor;
if (launch_flavor == eLaunchFlavorDefault) {
// Our default launch method is posix spawn
launch_flavor = eLaunchFlavorPosixSpawn;
#if defined WITH_FBS
// Check if we have an app bundle, if so launch using BackBoard Services.
if (strstr(inferior_argv[0], ".app")) {
launch_flavor = eLaunchFlavorFBS;
}
#elif defined WITH_BKS
// Check if we have an app bundle, if so launch using BackBoard Services.
if (strstr(inferior_argv[0], ".app")) {
launch_flavor = eLaunchFlavorBKS;
}
#elif defined WITH_SPRINGBOARD
// Check if we have an app bundle, if so launch using SpringBoard.
if (strstr(inferior_argv[0], ".app")) {
launch_flavor = eLaunchFlavorSpringBoard;
}
#endif
}
ctx.SetLaunchFlavor(launch_flavor);
char resolved_path[PATH_MAX];
// If we fail to resolve the path to our executable, then just use what we
// were given and hope for the best
if (!DNBResolveExecutablePath(inferior_argv[0], resolved_path,
sizeof(resolved_path)))
::strlcpy(resolved_path, inferior_argv[0], sizeof(resolved_path));
char launch_err_str[PATH_MAX];
launch_err_str[0] = '\0';
const char *cwd =
(ctx.GetWorkingDirPath() != NULL ? ctx.GetWorkingDirPath()
: ctx.GetWorkingDirectory());
const char *process_event = ctx.GetProcessEvent();
nub_process_t pid = DNBProcessLaunch(
resolved_path, &inferior_argv[0], &inferior_envp[0], cwd, stdin_path,
stdout_path, stderr_path, no_stdio, launch_flavor, g_disable_aslr,
process_event, launch_err_str, sizeof(launch_err_str));
g_pid = pid;
if (pid == INVALID_NUB_PROCESS && strlen(launch_err_str) > 0) {
DNBLogThreaded("%s DNBProcessLaunch() returned error: '%s'", __FUNCTION__,
launch_err_str);
ctx.LaunchStatus().SetError(-1, DNBError::Generic);
ctx.LaunchStatus().SetErrorString(launch_err_str);
} else if (pid == INVALID_NUB_PROCESS) {
DNBLogThreaded(
"%s DNBProcessLaunch() failed to launch process, unknown failure",
__FUNCTION__);
ctx.LaunchStatus().SetError(-1, DNBError::Generic);
ctx.LaunchStatus().SetErrorString("<unknown failure>");
} else {
ctx.LaunchStatus().Clear();
}
if (remote->Comm().IsConnected()) {
// It we are connected already, the next thing gdb will do is ask
// whether the launch succeeded, and if not, whether there is an
// error code. So we need to fetch one packet from gdb before we wait
// on the stop from the target.
uint32_t event_mask = RNBContext::event_read_packet_available;
nub_event_t set_events = ctx.Events().WaitForSetEvents(event_mask);
if (set_events & RNBContext::event_read_packet_available) {
rnb_err_t err = rnb_err;
RNBRemote::PacketEnum type;
err = remote->HandleReceivedPacket(&type);
if (err != rnb_success) {
DNBLogThreadedIf(LOG_RNB_MINIMAL, "%s Error getting packet.",
__FUNCTION__);
return eRNBRunLoopModeExit;
}
if (type != RNBRemote::query_launch_success) {
DNBLogThreadedIf(LOG_RNB_MINIMAL,
"%s Didn't get the expected qLaunchSuccess packet.",
__FUNCTION__);
}
}
}
while (pid != INVALID_NUB_PROCESS) {
// Wait for process to start up and hit entry point
DNBLogThreadedIf(LOG_RNB_EVENTS, "%s DNBProcessWaitForEvent (%4.4x, "
"eEventProcessRunningStateChanged | "
"eEventProcessStoppedStateChanged, true, "
"INFINITE)...",
__FUNCTION__, pid);
nub_event_t set_events =
DNBProcessWaitForEvents(pid, eEventProcessRunningStateChanged |
eEventProcessStoppedStateChanged,
true, NULL);
DNBLogThreadedIf(LOG_RNB_EVENTS, "%s DNBProcessWaitForEvent (%4.4x, "
"eEventProcessRunningStateChanged | "
"eEventProcessStoppedStateChanged, true, "
"INFINITE) => 0x%8.8x",
__FUNCTION__, pid, set_events);
if (set_events == 0) {
pid = INVALID_NUB_PROCESS;
g_pid = pid;
} else {
if (set_events & (eEventProcessRunningStateChanged |
eEventProcessStoppedStateChanged)) {
nub_state_t pid_state = DNBProcessGetState(pid);
DNBLogThreadedIf(
LOG_RNB_EVENTS,
"%s process %4.4x state changed (eEventProcessStateChanged): %s",
__FUNCTION__, pid, DNBStateAsString(pid_state));
switch (pid_state) {
case eStateInvalid:
case eStateUnloaded:
case eStateAttaching:
case eStateLaunching:
case eStateSuspended:
break; // Ignore
case eStateRunning:
case eStateStepping:
// Still waiting to stop at entry point...
break;
case eStateStopped:
case eStateCrashed:
ctx.SetProcessID(pid);
return eRNBRunLoopModeInferiorExecuting;
case eStateDetached:
case eStateExited:
pid = INVALID_NUB_PROCESS;
g_pid = pid;
return eRNBRunLoopModeExit;
}
}
DNBProcessResetEvents(pid, set_events);
}
}
return eRNBRunLoopModeExit;
}
// This run loop mode will wait for the process to launch and hit its
// entry point. It will currently ignore all events except for the
// process state changed event, where it watches for the process stopped
// or crash process state.
RNBRunLoopMode RNBRunLoopLaunchAttaching(RNBRemote *remote,
nub_process_t attach_pid,
nub_process_t &pid) {
RNBContext &ctx = remote->Context();
DNBLogThreadedIf(LOG_RNB_MINIMAL, "%s Attaching to pid %i...", __FUNCTION__,
attach_pid);
char err_str[1024];
pid = DNBProcessAttach(attach_pid, NULL, err_str, sizeof(err_str));
g_pid = pid;
if (pid == INVALID_NUB_PROCESS) {
ctx.LaunchStatus().SetError(-1, DNBError::Generic);
if (err_str[0])
ctx.LaunchStatus().SetErrorString(err_str);
return eRNBRunLoopModeExit;
} else {
ctx.SetProcessID(pid);
return eRNBRunLoopModeInferiorExecuting;
}
}
// Watch for signals:
// SIGINT: so we can halt our inferior. (disabled for now)
// SIGPIPE: in case our child process dies
int g_sigint_received = 0;
int g_sigpipe_received = 0;
void signal_handler(int signo) {
DNBLogThreadedIf(LOG_RNB_MINIMAL, "%s (%s)", __FUNCTION__,
SysSignal::Name(signo));
switch (signo) {
case SIGINT:
g_sigint_received++;
if (g_pid != INVALID_NUB_PROCESS) {
// Only send a SIGINT once...
if (g_sigint_received == 1) {
switch (DNBProcessGetState(g_pid)) {
case eStateRunning:
case eStateStepping:
DNBProcessSignal(g_pid, SIGSTOP);
return;
default:
break;
}
}
}
exit(SIGINT);
break;
case SIGPIPE:
g_sigpipe_received = 1;
break;
}
}
// Return the new run loop mode based off of the current process state
RNBRunLoopMode HandleProcessStateChange(RNBRemote *remote, bool initialize) {
RNBContext &ctx = remote->Context();
nub_process_t pid = ctx.ProcessID();
if (pid == INVALID_NUB_PROCESS) {
DNBLogThreadedIf(LOG_RNB_MINIMAL, "#### %s error: pid invalid, exiting...",
__FUNCTION__);
return eRNBRunLoopModeExit;
}
nub_state_t pid_state = DNBProcessGetState(pid);
DNBLogThreadedIf(LOG_RNB_MINIMAL,
"%s (&remote, initialize=%i) pid_state = %s", __FUNCTION__,
(int)initialize, DNBStateAsString(pid_state));
switch (pid_state) {
case eStateInvalid:
case eStateUnloaded:
// Something bad happened
return eRNBRunLoopModeExit;
break;
case eStateAttaching:
case eStateLaunching:
return eRNBRunLoopModeInferiorExecuting;
case eStateSuspended:
case eStateCrashed:
case eStateStopped:
// If we stop due to a signal, so clear the fact that we got a SIGINT
// so we can stop ourselves again (but only while our inferior
// process is running..)
g_sigint_received = 0;
if (initialize == false) {
// Compare the last stop count to our current notion of a stop count
// to make sure we don't notify more than once for a given stop.
nub_size_t prev_pid_stop_count = ctx.GetProcessStopCount();
bool pid_stop_count_changed =
ctx.SetProcessStopCount(DNBProcessGetStopCount(pid));
if (pid_stop_count_changed) {
remote->FlushSTDIO();
if (ctx.GetProcessStopCount() == 1) {
DNBLogThreadedIf(
LOG_RNB_MINIMAL, "%s (&remote, initialize=%i) pid_state = %s "
"pid_stop_count %llu (old %llu)) Notify??? no, "
"first stop...",
__FUNCTION__, (int)initialize, DNBStateAsString(pid_state),
(uint64_t)ctx.GetProcessStopCount(),
(uint64_t)prev_pid_stop_count);
} else {
DNBLogThreadedIf(LOG_RNB_MINIMAL, "%s (&remote, initialize=%i) "
"pid_state = %s pid_stop_count "
"%llu (old %llu)) Notify??? YES!!!",
__FUNCTION__, (int)initialize,
DNBStateAsString(pid_state),
(uint64_t)ctx.GetProcessStopCount(),
(uint64_t)prev_pid_stop_count);
remote->NotifyThatProcessStopped();
}
} else {
DNBLogThreadedIf(
LOG_RNB_MINIMAL, "%s (&remote, initialize=%i) pid_state = %s "
"pid_stop_count %llu (old %llu)) Notify??? "
"skipping...",
__FUNCTION__, (int)initialize, DNBStateAsString(pid_state),
(uint64_t)ctx.GetProcessStopCount(), (uint64_t)prev_pid_stop_count);
}
}
return eRNBRunLoopModeInferiorExecuting;
case eStateStepping:
case eStateRunning:
return eRNBRunLoopModeInferiorExecuting;
case eStateExited:
remote->HandlePacket_last_signal(NULL);
return eRNBRunLoopModeExit;
case eStateDetached:
return eRNBRunLoopModeExit;
}
// Catch all...
return eRNBRunLoopModeExit;
}
// This function handles the case where our inferior program is stopped and
// we are waiting for gdb remote protocol packets. When a packet occurs that
// makes the inferior run, we need to leave this function with a new state
// as the return code.
RNBRunLoopMode RNBRunLoopInferiorExecuting(RNBRemote *remote) {
DNBLogThreadedIf(LOG_RNB_MINIMAL, "#### %s", __FUNCTION__);
RNBContext &ctx = remote->Context();
// Init our mode and set 'is_running' based on the current process state
RNBRunLoopMode mode = HandleProcessStateChange(remote, true);
while (ctx.ProcessID() != INVALID_NUB_PROCESS) {
std::string set_events_str;
uint32_t event_mask = ctx.NormalEventBits();
if (!ctx.ProcessStateRunning()) {
// Clear some bits if we are not running so we don't send any async
// packets
event_mask &= ~RNBContext::event_proc_stdio_available;
event_mask &= ~RNBContext::event_proc_profile_data;
// When we enable async structured data packets over another logical
// channel,
// this can be relaxed.
event_mask &= ~RNBContext::event_darwin_log_data_available;
}
// We want to make sure we consume all process state changes and have
// whomever is notifying us to wait for us to reset the event bit before
// continuing.
// ctx.Events().SetResetAckMask (RNBContext::event_proc_state_changed);
DNBLogThreadedIf(LOG_RNB_EVENTS,
"%s ctx.Events().WaitForSetEvents(0x%08x) ...",
__FUNCTION__, event_mask);
nub_event_t set_events = ctx.Events().WaitForSetEvents(event_mask);
DNBLogThreadedIf(LOG_RNB_EVENTS,
"%s ctx.Events().WaitForSetEvents(0x%08x) => 0x%08x (%s)",
__FUNCTION__, event_mask, set_events,
ctx.EventsAsString(set_events, set_events_str));
if (set_events) {
if ((set_events & RNBContext::event_proc_thread_exiting) ||
(set_events & RNBContext::event_proc_stdio_available)) {
remote->FlushSTDIO();
}
if (set_events & RNBContext::event_proc_profile_data) {
remote->SendAsyncProfileData();
}
if (set_events & RNBContext::event_darwin_log_data_available) {
remote->SendAsyncDarwinLogData();
}
if (set_events & RNBContext::event_read_packet_available) {
// handleReceivedPacket will take care of resetting the
// event_read_packet_available events when there are no more...
set_events ^= RNBContext::event_read_packet_available;
if (ctx.ProcessStateRunning()) {
if (remote->HandleAsyncPacket() == rnb_not_connected) {
// TODO: connect again? Exit?
}
} else {
if (remote->HandleReceivedPacket() == rnb_not_connected) {
// TODO: connect again? Exit?
}
}
}
if (set_events & RNBContext::event_proc_state_changed) {
mode = HandleProcessStateChange(remote, false);
ctx.Events().ResetEvents(RNBContext::event_proc_state_changed);
set_events ^= RNBContext::event_proc_state_changed;
}
if (set_events & RNBContext::event_proc_thread_exiting) {
mode = eRNBRunLoopModeExit;
}
if (set_events & RNBContext::event_read_thread_exiting) {
// Out remote packet receiving thread exited, exit for now.
if (ctx.HasValidProcessID()) {
// TODO: We should add code that will leave the current process
// in its current state and listen for another connection...
if (ctx.ProcessStateRunning()) {
if (ctx.GetDetachOnError()) {
DNBLog("debugserver's event read thread is exiting, detaching "
"from the inferior process.");
DNBProcessDetach(ctx.ProcessID());
} else {
DNBLog("debugserver's event read thread is exiting, killing the "
"inferior process.");
DNBProcessKill(ctx.ProcessID());
}
} else {
if (ctx.GetDetachOnError()) {
DNBLog("debugserver's event read thread is exiting, detaching "
"from the inferior process.");
DNBProcessDetach(ctx.ProcessID());
}
}
}
mode = eRNBRunLoopModeExit;
}
}
// Reset all event bits that weren't reset for now...
if (set_events != 0)
ctx.Events().ResetEvents(set_events);
if (mode != eRNBRunLoopModeInferiorExecuting)
break;
}
return mode;
}
RNBRunLoopMode RNBRunLoopPlatform(RNBRemote *remote) {
RNBRunLoopMode mode = eRNBRunLoopModePlatformMode;
RNBContext &ctx = remote->Context();
while (mode == eRNBRunLoopModePlatformMode) {
std::string set_events_str;
const uint32_t event_mask = RNBContext::event_read_packet_available |
RNBContext::event_read_thread_exiting;
DNBLogThreadedIf(LOG_RNB_EVENTS,
"%s ctx.Events().WaitForSetEvents(0x%08x) ...",
__FUNCTION__, event_mask);
nub_event_t set_events = ctx.Events().WaitForSetEvents(event_mask);
DNBLogThreadedIf(LOG_RNB_EVENTS,
"%s ctx.Events().WaitForSetEvents(0x%08x) => 0x%08x (%s)",
__FUNCTION__, event_mask, set_events,
ctx.EventsAsString(set_events, set_events_str));
if (set_events) {
if (set_events & RNBContext::event_read_packet_available) {
if (remote->HandleReceivedPacket() == rnb_not_connected)
mode = eRNBRunLoopModeExit;
}
if (set_events & RNBContext::event_read_thread_exiting) {
mode = eRNBRunLoopModeExit;
}
ctx.Events().ResetEvents(set_events);
}
}
return eRNBRunLoopModeExit;
}
// Convenience function to set up the remote listening port
// Returns 1 for success 0 for failure.
static void PortWasBoundCallbackUnixSocket(const void *baton, in_port_t port) {
//::printf ("PortWasBoundCallbackUnixSocket (baton = %p, port = %u)\n", baton,
//port);
const char *unix_socket_name = (const char *)baton;
if (unix_socket_name && unix_socket_name[0]) {
// We were given a unix socket name to use to communicate the port
// that we ended up binding to back to our parent process
struct sockaddr_un saddr_un;
int s = ::socket(AF_UNIX, SOCK_STREAM, 0);
if (s < 0) {
perror("error: socket (AF_UNIX, SOCK_STREAM, 0)");
exit(1);
}
saddr_un.sun_family = AF_UNIX;
::strlcpy(saddr_un.sun_path, unix_socket_name,
sizeof(saddr_un.sun_path) - 1);
saddr_un.sun_path[sizeof(saddr_un.sun_path) - 1] = '\0';
saddr_un.sun_len = SUN_LEN(&saddr_un);
if (::connect(s, (struct sockaddr *)&saddr_un,
static_cast<socklen_t>(SUN_LEN(&saddr_un))) < 0) {
perror("error: connect (socket, &saddr_un, saddr_un_len)");
exit(1);
}
//::printf ("connect () sucess!!\n");
// We were able to connect to the socket, now write our PID so whomever
// launched us will know this process's ID
RNBLogSTDOUT("Listening to port %i...\n", port);
char pid_str[64];
const int pid_str_len = ::snprintf(pid_str, sizeof(pid_str), "%u", port);
const ssize_t bytes_sent = ::send(s, pid_str, pid_str_len, 0);
if (pid_str_len != bytes_sent) {
perror("error: send (s, pid_str, pid_str_len, 0)");
exit(1);
}
//::printf ("send () sucess!!\n");
// We are done with the socket
close(s);
}
}
static void PortWasBoundCallbackNamedPipe(const void *baton, uint16_t port) {
const char *named_pipe = (const char *)baton;
if (named_pipe && named_pipe[0]) {
int fd = ::open(named_pipe, O_WRONLY);
if (fd > -1) {
char port_str[64];
const ssize_t port_str_len =
::snprintf(port_str, sizeof(port_str), "%u", port);
// Write the port number as a C string with the NULL terminator
::write(fd, port_str, port_str_len + 1);
close(fd);
}
}
}
static int ConnectRemote(RNBRemote *remote, const char *host, int port,
bool reverse_connect, const char *named_pipe_path,
const char *unix_socket_name) {
if (!remote->Comm().IsConnected()) {
if (reverse_connect) {
if (port == 0) {
DNBLogThreaded(
"error: invalid port supplied for reverse connection: %i.\n", port);
return 0;
}
if (remote->Comm().Connect(host, port) != rnb_success) {
DNBLogThreaded("Failed to reverse connect to %s:%i.\n", host, port);
return 0;
}
} else {
if (port != 0)
RNBLogSTDOUT("Listening to port %i for a connection from %s...\n", port,
host ? host : "127.0.0.1");
if (unix_socket_name && unix_socket_name[0]) {
if (remote->Comm().Listen(host, port, PortWasBoundCallbackUnixSocket,
unix_socket_name) != rnb_success) {
RNBLogSTDERR("Failed to get connection from a remote gdb process.\n");
return 0;
}
} else {
if (remote->Comm().Listen(host, port, PortWasBoundCallbackNamedPipe,
named_pipe_path) != rnb_success) {
RNBLogSTDERR("Failed to get connection from a remote gdb process.\n");
return 0;
}
}
}
remote->StartReadRemoteDataThread();
}
return 1;
}
// ASL Logging callback that can be registered with DNBLogSetLogCallback
void ASLLogCallback(void *baton, uint32_t flags, const char *format,
va_list args) {
if (format == NULL)
return;
static aslmsg g_aslmsg = NULL;
if (g_aslmsg == NULL) {
g_aslmsg = ::asl_new(ASL_TYPE_MSG);
char asl_key_sender[PATH_MAX];
snprintf(asl_key_sender, sizeof(asl_key_sender), "com.apple.%s-%s",
DEBUGSERVER_PROGRAM_NAME, DEBUGSERVER_VERSION_STR);
::asl_set(g_aslmsg, ASL_KEY_SENDER, asl_key_sender);
}
int asl_level;
if (flags & DNBLOG_FLAG_FATAL)
asl_level = ASL_LEVEL_CRIT;
else if (flags & DNBLOG_FLAG_ERROR)
asl_level = ASL_LEVEL_ERR;
else if (flags & DNBLOG_FLAG_WARNING)
asl_level = ASL_LEVEL_WARNING;
else if (flags & DNBLOG_FLAG_VERBOSE)
asl_level = ASL_LEVEL_WARNING; // ASL_LEVEL_INFO;
else
asl_level = ASL_LEVEL_WARNING; // ASL_LEVEL_DEBUG;
::asl_vlog(NULL, g_aslmsg, asl_level, format, args);
}
// FILE based Logging callback that can be registered with
// DNBLogSetLogCallback
void FileLogCallback(void *baton, uint32_t flags, const char *format,
va_list args) {
if (baton == NULL || format == NULL)
return;
::vfprintf((FILE *)baton, format, args);
::fprintf((FILE *)baton, "\n");
::fflush((FILE *)baton);
}
void show_version_and_exit(int exit_code) {
printf("%s-%s for %s.\n", DEBUGSERVER_PROGRAM_NAME, DEBUGSERVER_VERSION_STR,
RNB_ARCH);
exit(exit_code);
}
void show_usage_and_exit(int exit_code) {
RNBLogSTDERR(
"Usage:\n %s host:port [program-name program-arg1 program-arg2 ...]\n",
DEBUGSERVER_PROGRAM_NAME);
RNBLogSTDERR(" %s /path/file [program-name program-arg1 program-arg2 ...]\n",
DEBUGSERVER_PROGRAM_NAME);
RNBLogSTDERR(" %s host:port --attach=<pid>\n", DEBUGSERVER_PROGRAM_NAME);
RNBLogSTDERR(" %s /path/file --attach=<pid>\n", DEBUGSERVER_PROGRAM_NAME);
RNBLogSTDERR(" %s host:port --attach=<process_name>\n",
DEBUGSERVER_PROGRAM_NAME);
RNBLogSTDERR(" %s /path/file --attach=<process_name>\n",
DEBUGSERVER_PROGRAM_NAME);
exit(exit_code);
}
// option descriptors for getopt_long_only()
static struct option g_long_options[] = {
{"attach", required_argument, NULL, 'a'},
{"arch", required_argument, NULL, 'A'},
{"debug", no_argument, NULL, 'g'},
{"kill-on-error", no_argument, NULL, 'K'},
{"verbose", no_argument, NULL, 'v'},
{"version", no_argument, NULL, 'V'},
{"lockdown", no_argument, &g_lockdown_opt, 1}, // short option "-k"
{"applist", no_argument, &g_applist_opt, 1}, // short option "-t"
{"log-file", required_argument, NULL, 'l'},
{"log-flags", required_argument, NULL, 'f'},
{"launch", required_argument, NULL, 'x'}, // Valid values are "auto",
// "posix-spawn", "fork-exec",
// "springboard" (arm only)
{"waitfor", required_argument, NULL,
'w'}, // Wait for a process whose name starts with ARG
{"waitfor-interval", required_argument, NULL,
'i'}, // Time in usecs to wait between sampling the pid list when waiting
// for a process by name
{"waitfor-duration", required_argument, NULL,
'd'}, // The time in seconds to wait for a process to show up by name
{"native-regs", no_argument, NULL, 'r'}, // Specify to use the native
// registers instead of the gdb
// defaults for the architecture.
{"stdio-path", required_argument, NULL,
's'}, // Set the STDIO path to be used when launching applications (STDIN,
// STDOUT and STDERR) (only if debugserver launches the process)
{"stdin-path", required_argument, NULL,
'I'}, // Set the STDIN path to be used when launching applications (only if
// debugserver launches the process)
{"stdout-path", required_argument, NULL,
'O'}, // Set the STDOUT path to be used when launching applications (only
// if debugserver launches the process)
{"stderr-path", required_argument, NULL,
'E'}, // Set the STDERR path to be used when launching applications (only
// if debugserver launches the process)
{"no-stdio", no_argument, NULL,
'n'}, // Do not set up any stdio (perhaps the program is a GUI program)
// (only if debugserver launches the process)
{"setsid", no_argument, NULL,
'S'}, // call setsid() to make debugserver run in its own session
{"disable-aslr", no_argument, NULL, 'D'}, // Use _POSIX_SPAWN_DISABLE_ASLR
// to avoid shared library
// randomization
{"working-dir", required_argument, NULL,
'W'}, // The working directory that the inferior process should have (only
// if debugserver launches the process)
{"platform", required_argument, NULL,
'p'}, // Put this executable into a remote platform mode
{"unix-socket", required_argument, NULL,
'u'}, // If we need to handshake with our parent process, an option will be
// passed down that specifies a unix socket name to use
{"fd", required_argument, NULL,
'2'}, // A file descriptor was passed to this process when spawned that
// is already open and ready for communication
{"named-pipe", required_argument, NULL, 'P'},
{"reverse-connect", no_argument, NULL, 'R'},
{"env", required_argument, NULL,
'e'}, // When debugserver launches the process, set a single environment
// entry as specified by the option value ("./debugserver -e FOO=1 -e
// BAR=2 localhost:1234 -- /bin/ls")
{"forward-env", no_argument, NULL,
'F'}, // When debugserver launches the process, forward debugserver's
// current environment variables to the child process ("./debugserver
// -F localhost:1234 -- /bin/ls"
{NULL, 0, NULL, 0}};
// main
int main(int argc, char *argv[]) {
// If debugserver is launched with DYLD_INSERT_LIBRARIES, unset it so we
// don't spawn child processes with this enabled.
unsetenv("DYLD_INSERT_LIBRARIES");
const char *argv_sub_zero =
argv[0]; // save a copy of argv[0] for error reporting post-launch
#if defined(__APPLE__)
pthread_setname_np("main thread");
#if defined(__arm__) || defined(__arm64__) || defined(__aarch64__)
struct sched_param thread_param;
int thread_sched_policy;
if (pthread_getschedparam(pthread_self(), &thread_sched_policy,
&thread_param) == 0) {
thread_param.sched_priority = 47;
pthread_setschedparam(pthread_self(), thread_sched_policy, &thread_param);
}
::proc_set_wakemon_params(
getpid(), 500,
0); // Allow up to 500 wakeups/sec to avoid EXC_RESOURCE for normal use.
#endif
#endif
g_isatty = ::isatty(STDIN_FILENO);
// ::printf ("uid=%u euid=%u gid=%u egid=%u\n",
// getuid(),
// geteuid(),
// getgid(),
// getegid());
// signal (SIGINT, signal_handler);
signal(SIGPIPE, signal_handler);
signal(SIGHUP, signal_handler);
// We're always sitting in waitpid or kevent waiting on our target process'
// death,
// we don't need no stinking SIGCHLD's...
sigset_t sigset;
sigemptyset(&sigset);
sigaddset(&sigset, SIGCHLD);
sigprocmask(SIG_BLOCK, &sigset, NULL);
g_remoteSP = std::make_shared<RNBRemote>();
RNBRemote *remote = g_remoteSP.get();
if (remote == NULL) {
RNBLogSTDERR("error: failed to create a remote connection class\n");
return -1;
}
RNBContext &ctx = remote->Context();
int i;
int attach_pid = INVALID_NUB_PROCESS;
FILE *log_file = NULL;
uint32_t log_flags = 0;
// Parse our options
int ch;
int long_option_index = 0;
int debug = 0;
int communication_fd = -1;
std::string compile_options;
std::string waitfor_pid_name; // Wait for a process that starts with this name
std::string attach_pid_name;
std::string arch_name;
std::string working_dir; // The new working directory to use for the inferior
std::string unix_socket_name; // If we need to handshake with our parent
// process, an option will be passed down that
// specifies a unix socket name to use
std::string named_pipe_path; // If we need to handshake with our parent
// process, an option will be passed down that
// specifies a named pipe to use
useconds_t waitfor_interval = 1000; // Time in usecs between process lists
// polls when waiting for a process by
// name, default 1 msec.
useconds_t waitfor_duration =
0; // Time in seconds to wait for a process by name, 0 means wait forever.
bool no_stdio = false;
bool reverse_connect = false; // Set to true by an option to indicate we
// should reverse connect to the host:port
// supplied as the first debugserver argument
#if !defined(DNBLOG_ENABLED)
compile_options += "(no-logging) ";
#endif
RNBRunLoopMode start_mode = eRNBRunLoopModeExit;
char short_options[512];
uint32_t short_options_idx = 0;
// Handle the two case that don't have short options in g_long_options
short_options[short_options_idx++] = 'k';
short_options[short_options_idx++] = 't';
for (i = 0; g_long_options[i].name != NULL; ++i) {
if (isalpha(g_long_options[i].val)) {
short_options[short_options_idx++] = g_long_options[i].val;
switch (g_long_options[i].has_arg) {
default:
case no_argument:
break;
case optional_argument:
short_options[short_options_idx++] = ':';
short_options[short_options_idx++] = ':';
break;
case required_argument:
short_options[short_options_idx++] = ':';
break;
}
}
}
// NULL terminate the short option string.
short_options[short_options_idx++] = '\0';
#if __GLIBC__
optind = 0;
#else
optreset = 1;
optind = 1;
#endif
bool forward_env = false;
while ((ch = getopt_long_only(argc, argv, short_options, g_long_options,
&long_option_index)) != -1) {
DNBLogDebug("option: ch == %c (0x%2.2x) --%s%c%s\n", ch, (uint8_t)ch,
g_long_options[long_option_index].name,
g_long_options[long_option_index].has_arg ? '=' : ' ',
optarg ? optarg : "");
switch (ch) {
case 0: // Any optional that auto set themselves will return 0
break;
case 'A':
if (optarg && optarg[0])
arch_name.assign(optarg);
break;
case 'a':
if (optarg && optarg[0]) {
if (isdigit(optarg[0])) {
char *end = NULL;
attach_pid = static_cast<int>(strtoul(optarg, &end, 0));
if (end == NULL || *end != '\0') {
RNBLogSTDERR("error: invalid pid option '%s'\n", optarg);
exit(4);
}
} else {
attach_pid_name = optarg;
}
start_mode = eRNBRunLoopModeInferiorAttaching;
}
break;
// --waitfor=NAME
case 'w':
if (optarg && optarg[0]) {
waitfor_pid_name = optarg;
start_mode = eRNBRunLoopModeInferiorAttaching;
}
break;
// --waitfor-interval=USEC
case 'i':
if (optarg && optarg[0]) {
char *end = NULL;
waitfor_interval = static_cast<useconds_t>(strtoul(optarg, &end, 0));
if (end == NULL || *end != '\0') {
RNBLogSTDERR("error: invalid waitfor-interval option value '%s'.\n",
optarg);
exit(6);
}
}
break;
// --waitfor-duration=SEC
case 'd':
if (optarg && optarg[0]) {
char *end = NULL;
waitfor_duration = static_cast<useconds_t>(strtoul(optarg, &end, 0));
if (end == NULL || *end != '\0') {
RNBLogSTDERR("error: invalid waitfor-duration option value '%s'.\n",
optarg);
exit(7);
}
}
break;
case 'K':
g_detach_on_error = false;
break;
case 'W':
if (optarg && optarg[0])
working_dir.assign(optarg);
break;
case 'x':
if (optarg && optarg[0]) {
if (strcasecmp(optarg, "auto") == 0)
g_launch_flavor = eLaunchFlavorDefault;
else if (strcasestr(optarg, "posix") == optarg)
g_launch_flavor = eLaunchFlavorPosixSpawn;
else if (strcasestr(optarg, "fork") == optarg)
g_launch_flavor = eLaunchFlavorForkExec;
#ifdef WITH_SPRINGBOARD
else if (strcasestr(optarg, "spring") == optarg)
g_launch_flavor = eLaunchFlavorSpringBoard;
#endif
#ifdef WITH_BKS
else if (strcasestr(optarg, "backboard") == optarg)
g_launch_flavor = eLaunchFlavorBKS;
#endif
#ifdef WITH_FBS
else if (strcasestr(optarg, "frontboard") == optarg)
g_launch_flavor = eLaunchFlavorFBS;
#endif
else {
RNBLogSTDERR("error: invalid TYPE for the --launch=TYPE (-x TYPE) "
"option: '%s'\n",
optarg);
RNBLogSTDERR("Valid values TYPE are:\n");
RNBLogSTDERR(
" auto Auto-detect the best launch method to use.\n");
RNBLogSTDERR(
" posix Launch the executable using posix_spawn.\n");
RNBLogSTDERR(
" fork Launch the executable using fork and exec.\n");
#ifdef WITH_SPRINGBOARD
RNBLogSTDERR(
" spring Launch the executable through Springboard.\n");
#endif
#ifdef WITH_BKS
RNBLogSTDERR(" backboard Launch the executable through BackBoard "
"Services.\n");
#endif
#ifdef WITH_FBS
RNBLogSTDERR(" frontboard Launch the executable through FrontBoard "
"Services.\n");
#endif
exit(5);
}
}
break;
case 'l': // Set Log File
if (optarg && optarg[0]) {
if (strcasecmp(optarg, "stdout") == 0)
log_file = stdout;
else if (strcasecmp(optarg, "stderr") == 0)
log_file = stderr;
else {
log_file = fopen(optarg, "w");
if (log_file != NULL)
setlinebuf(log_file);
}
if (log_file == NULL) {
const char *errno_str = strerror(errno);
RNBLogSTDERR(
"Failed to open log file '%s' for writing: errno = %i (%s)",
optarg, errno, errno_str ? errno_str : "unknown error");
}
}
break;
case 'f': // Log Flags
if (optarg && optarg[0])
log_flags = static_cast<uint32_t>(strtoul(optarg, NULL, 0));
break;
case 'g':
debug = 1;
DNBLogSetDebug(debug);
break;
case 't':
g_applist_opt = 1;
break;
case 'k':
g_lockdown_opt = 1;
break;
case 'r':
// Do nothing, native regs is the default these days
break;
case 'R':
reverse_connect = true;
break;
case 'v':
DNBLogSetVerbose(1);
break;
case 'V':
show_version_and_exit(0);
break;
case 's':
ctx.GetSTDIN().assign(optarg);
ctx.GetSTDOUT().assign(optarg);
ctx.GetSTDERR().assign(optarg);
break;
case 'I':
ctx.GetSTDIN().assign(optarg);
break;
case 'O':
ctx.GetSTDOUT().assign(optarg);
break;
case 'E':
ctx.GetSTDERR().assign(optarg);
break;
case 'n':
no_stdio = true;
break;
case 'S':
// Put debugserver into a new session. Terminals group processes
// into sessions and when a special terminal key sequences
// (like control+c) are typed they can cause signals to go out to
// all processes in a session. Using this --setsid (-S) option
// will cause debugserver to run in its own sessions and be free
// from such issues.
//
// This is useful when debugserver is spawned from a command
// line application that uses debugserver to do the debugging,
// yet that application doesn't want debugserver receiving the
// signals sent to the session (i.e. dying when anyone hits ^C).
setsid();
break;
case 'D':
g_disable_aslr = 1;
break;
case 'p':
start_mode = eRNBRunLoopModePlatformMode;
break;
case 'u':
unix_socket_name.assign(optarg);
break;
case 'P':
named_pipe_path.assign(optarg);
break;
case 'e':
// Pass a single specified environment variable down to the process that
// gets launched
remote->Context().PushEnvironment(optarg);
break;
case 'F':
forward_env = true;
break;
case '2':
// File descriptor passed to this process during fork/exec and is already
// open and ready for communication.
communication_fd = atoi(optarg);
break;
}
}
if (arch_name.empty()) {
#if defined(__arm__)
arch_name.assign("arm");
#endif
} else {
DNBSetArchitecture(arch_name.c_str());
}
// if (arch_name.empty())
// {
// fprintf(stderr, "error: no architecture was specified\n");
// exit (8);
// }
// Skip any options we consumed with getopt_long_only
argc -= optind;
argv += optind;
if (!working_dir.empty()) {
if (remote->Context().SetWorkingDirectory(working_dir.c_str()) == false) {
RNBLogSTDERR("error: working directory doesn't exist '%s'.\n",
working_dir.c_str());
exit(8);
}
}
remote->Context().SetDetachOnError(g_detach_on_error);
remote->Initialize();
// It is ok for us to set NULL as the logfile (this will disable any logging)
if (log_file != NULL) {
DNBLogSetLogCallback(FileLogCallback, log_file);
// If our log file was set, yet we have no log flags, log everything!
if (log_flags == 0)
log_flags = LOG_ALL | LOG_RNB_ALL;
DNBLogSetLogMask(log_flags);
} else {
// Enable DNB logging
// if os_log() support is available, log through that.
auto log_callback = OsLogger::GetLogFunction();
if (log_callback) {
DNBLogSetLogCallback(log_callback, nullptr);
DNBLog("debugserver will use os_log for internal logging.");
} else {
// Fall back to ASL support.
DNBLogSetLogCallback(ASLLogCallback, NULL);
DNBLog("debugserver will use ASL for internal logging.");
}
DNBLogSetLogMask(log_flags);
}
if (DNBLogEnabled()) {
for (i = 0; i < argc; i++)
DNBLogDebug("argv[%i] = %s", i, argv[i]);
}
// as long as we're dropping remotenub in as a replacement for gdbserver,
// explicitly note that this is not gdbserver.
RNBLogSTDOUT("%s-%s %sfor %s.\n", DEBUGSERVER_PROGRAM_NAME,
DEBUGSERVER_VERSION_STR, compile_options.c_str(), RNB_ARCH);
std::string host;
int port = INT32_MAX;
char str[PATH_MAX];
str[0] = '\0';
if (g_lockdown_opt == 0 && g_applist_opt == 0 && communication_fd == -1) {
// Make sure we at least have port
if (argc < 1) {
show_usage_and_exit(1);
}
// accept 'localhost:' prefix on port number
std::string host_specifier = argv[0];
auto colon_location = host_specifier.rfind(':');
if (colon_location != std::string::npos) {
host = host_specifier.substr(0, colon_location);
std::string port_str =
host_specifier.substr(colon_location + 1, std::string::npos);
char *end_ptr;
port = strtoul(port_str.c_str(), &end_ptr, 0);
if (end_ptr < port_str.c_str() + port_str.size())
show_usage_and_exit(2);
if (host.front() == '[' && host.back() == ']')
host = host.substr(1, host.size() - 2);
DNBLogDebug("host = '%s' port = %i", host.c_str(), port);
} else {
// No hostname means "localhost"
int items_scanned = ::sscanf(argv[0], "%i", &port);
if (items_scanned == 1) {
host = "127.0.0.1";
DNBLogDebug("host = '%s' port = %i", host.c_str(), port);
} else if (argv[0][0] == '/') {
port = INT32_MAX;
strlcpy(str, argv[0], sizeof(str));
} else {
show_usage_and_exit(2);
}
}
// We just used the 'host:port' or the '/path/file' arg...
argc--;
argv++;
}
// If we know we're waiting to attach, we don't need any of this other info.
if (start_mode != eRNBRunLoopModeInferiorAttaching &&
start_mode != eRNBRunLoopModePlatformMode) {
if (argc == 0 || g_lockdown_opt) {
if (g_lockdown_opt != 0) {
// Work around for SIGPIPE crashes due to posix_spawn issue.
// We have to close STDOUT and STDERR, else the first time we
// try and do any, we get SIGPIPE and die as posix_spawn is
// doing bad things with our file descriptors at the moment.
int null = open("/dev/null", O_RDWR);
dup2(null, STDOUT_FILENO);
dup2(null, STDERR_FILENO);
} else if (g_applist_opt != 0) {
// List all applications we are able to see
std::string applist_plist;
int err = ListApplications(applist_plist, false, false);
if (err == 0) {
fputs(applist_plist.c_str(), stdout);
} else {
RNBLogSTDERR("error: ListApplications returned error %i\n", err);
}
// Exit with appropriate error if we were asked to list the applications
// with no other args were given (and we weren't trying to do this over
// lockdown)
return err;
}
DNBLogDebug("Get args from remote protocol...");
start_mode = eRNBRunLoopModeGetStartModeFromRemoteProtocol;
} else {
start_mode = eRNBRunLoopModeInferiorLaunching;
// Fill in the argv array in the context from the rest of our args.
// Skip the name of this executable and the port number
for (int i = 0; i < argc; i++) {
DNBLogDebug("inferior_argv[%i] = '%s'", i, argv[i]);
ctx.PushArgument(argv[i]);
}
}
}
if (start_mode == eRNBRunLoopModeExit)
return -1;
if (forward_env || start_mode == eRNBRunLoopModeInferiorLaunching) {
// Pass the current environment down to the process that gets launched
// This happens automatically in the "launching" mode. For the rest, we
// only do that if the user explicitly requested this via --forward-env
// argument.
char **host_env = *_NSGetEnviron();
char *env_entry;
size_t i;
for (i = 0; (env_entry = host_env[i]) != NULL; ++i)
remote->Context().PushEnvironmentIfNeeded(env_entry);
}
RNBRunLoopMode mode = start_mode;
char err_str[1024] = {'\0'};
while (mode != eRNBRunLoopModeExit) {
switch (mode) {
case eRNBRunLoopModeGetStartModeFromRemoteProtocol:
#ifdef WITH_LOCKDOWN
if (g_lockdown_opt) {
if (!remote->Comm().IsConnected()) {
if (remote->Comm().ConnectToService() != rnb_success) {
RNBLogSTDERR(
"Failed to get connection from a remote gdb process.\n");
mode = eRNBRunLoopModeExit;
} else if (g_applist_opt != 0) {
// List all applications we are able to see
std::string applist_plist;
if (ListApplications(applist_plist, false, false) == 0) {
DNBLogDebug("Task list: %s", applist_plist.c_str());
remote->Comm().Write(applist_plist.c_str(), applist_plist.size());
// Issue a read that will never yield any data until the other
// side
// closes the socket so this process doesn't just exit and cause
// the
// socket to close prematurely on the other end and cause data
// loss.
std::string buf;
remote->Comm().Read(buf);
}
remote->Comm().Disconnect(false);
mode = eRNBRunLoopModeExit;
break;
} else {
// Start watching for remote packets
remote->StartReadRemoteDataThread();
}
}
} else
#endif
if (port != INT32_MAX) {
if (!ConnectRemote(remote, host.c_str(), port, reverse_connect,
named_pipe_path.c_str(), unix_socket_name.c_str()))
mode = eRNBRunLoopModeExit;
} else if (str[0] == '/') {
if (remote->Comm().OpenFile(str))
mode = eRNBRunLoopModeExit;
} else if (communication_fd >= 0) {
// We were passed a file descriptor to use during fork/exec that is
// already open
// in our process, so lets just use it!
if (remote->Comm().useFD(communication_fd))
mode = eRNBRunLoopModeExit;
else
remote->StartReadRemoteDataThread();
}
if (mode != eRNBRunLoopModeExit) {
RNBLogSTDOUT("Got a connection, waiting for process information for "
"launching or attaching.\n");
mode = RNBRunLoopGetStartModeFromRemote(remote);
}
break;
case eRNBRunLoopModeInferiorAttaching:
if (!waitfor_pid_name.empty()) {
// Set our end wait time if we are using a waitfor-duration
// option that may have been specified
struct timespec attach_timeout_abstime, *timeout_ptr = NULL;
if (waitfor_duration != 0) {
DNBTimer::OffsetTimeOfDay(&attach_timeout_abstime, waitfor_duration,
0);
timeout_ptr = &attach_timeout_abstime;
}
nub_launch_flavor_t launch_flavor = g_launch_flavor;
if (launch_flavor == eLaunchFlavorDefault) {
// Our default launch method is posix spawn
launch_flavor = eLaunchFlavorPosixSpawn;
#if defined WITH_FBS
// Check if we have an app bundle, if so launch using SpringBoard.
if (waitfor_pid_name.find(".app") != std::string::npos) {
launch_flavor = eLaunchFlavorFBS;
}
#elif defined WITH_BKS
// Check if we have an app bundle, if so launch using SpringBoard.
if (waitfor_pid_name.find(".app") != std::string::npos) {
launch_flavor = eLaunchFlavorBKS;
}
#elif defined WITH_SPRINGBOARD
// Check if we have an app bundle, if so launch using SpringBoard.
if (waitfor_pid_name.find(".app") != std::string::npos) {
launch_flavor = eLaunchFlavorSpringBoard;
}
#endif
}
ctx.SetLaunchFlavor(launch_flavor);
bool ignore_existing = false;
RNBLogSTDOUT("Waiting to attach to process %s...\n",
waitfor_pid_name.c_str());
nub_process_t pid = DNBProcessAttachWait(
waitfor_pid_name.c_str(), launch_flavor, ignore_existing,
timeout_ptr, waitfor_interval, err_str, sizeof(err_str));
g_pid = pid;
if (pid == INVALID_NUB_PROCESS) {
ctx.LaunchStatus().SetError(-1, DNBError::Generic);
if (err_str[0])
ctx.LaunchStatus().SetErrorString(err_str);
RNBLogSTDERR("error: failed to attach to process named: \"%s\" %s\n",
waitfor_pid_name.c_str(), err_str);
mode = eRNBRunLoopModeExit;
} else {
ctx.SetProcessID(pid);
mode = eRNBRunLoopModeInferiorExecuting;
}
} else if (attach_pid != INVALID_NUB_PROCESS) {
RNBLogSTDOUT("Attaching to process %i...\n", attach_pid);
nub_process_t attached_pid;
mode = RNBRunLoopLaunchAttaching(remote, attach_pid, attached_pid);
if (mode != eRNBRunLoopModeInferiorExecuting) {
const char *error_str = remote->Context().LaunchStatus().AsString();
RNBLogSTDERR("error: failed to attach process %i: %s\n", attach_pid,
error_str ? error_str : "unknown error.");
mode = eRNBRunLoopModeExit;
}
} else if (!attach_pid_name.empty()) {
struct timespec attach_timeout_abstime, *timeout_ptr = NULL;
if (waitfor_duration != 0) {
DNBTimer::OffsetTimeOfDay(&attach_timeout_abstime, waitfor_duration,
0);
timeout_ptr = &attach_timeout_abstime;
}
RNBLogSTDOUT("Attaching to process %s...\n", attach_pid_name.c_str());
nub_process_t pid = DNBProcessAttachByName(
attach_pid_name.c_str(), timeout_ptr, err_str, sizeof(err_str));
g_pid = pid;
if (pid == INVALID_NUB_PROCESS) {
ctx.LaunchStatus().SetError(-1, DNBError::Generic);
if (err_str[0])
ctx.LaunchStatus().SetErrorString(err_str);
RNBLogSTDERR("error: failed to attach to process named: \"%s\" %s\n",
waitfor_pid_name.c_str(), err_str);
mode = eRNBRunLoopModeExit;
} else {
ctx.SetProcessID(pid);
mode = eRNBRunLoopModeInferiorExecuting;
}
} else {
RNBLogSTDERR(
"error: asked to attach with empty name and invalid PID.\n");
mode = eRNBRunLoopModeExit;
}
if (mode != eRNBRunLoopModeExit) {
if (port != INT32_MAX) {
if (!ConnectRemote(remote, host.c_str(), port, reverse_connect,
named_pipe_path.c_str(), unix_socket_name.c_str()))
mode = eRNBRunLoopModeExit;
} else if (str[0] == '/') {
if (remote->Comm().OpenFile(str))
mode = eRNBRunLoopModeExit;
} else if (communication_fd >= 0) {
// We were passed a file descriptor to use during fork/exec that is
// already open
// in our process, so lets just use it!
if (remote->Comm().useFD(communication_fd))
mode = eRNBRunLoopModeExit;
else
remote->StartReadRemoteDataThread();
}
if (mode != eRNBRunLoopModeExit)
RNBLogSTDOUT("Waiting for debugger instructions for process %d.\n",
attach_pid);
}
break;
case eRNBRunLoopModeInferiorLaunching: {
mode = RNBRunLoopLaunchInferior(remote, ctx.GetSTDINPath(),
ctx.GetSTDOUTPath(), ctx.GetSTDERRPath(),
no_stdio);
if (mode == eRNBRunLoopModeInferiorExecuting) {
if (port != INT32_MAX) {
if (!ConnectRemote(remote, host.c_str(), port, reverse_connect,
named_pipe_path.c_str(), unix_socket_name.c_str()))
mode = eRNBRunLoopModeExit;
} else if (str[0] == '/') {
if (remote->Comm().OpenFile(str))
mode = eRNBRunLoopModeExit;
} else if (communication_fd >= 0) {
// We were passed a file descriptor to use during fork/exec that is
// already open
// in our process, so lets just use it!
if (remote->Comm().useFD(communication_fd))
mode = eRNBRunLoopModeExit;
else
remote->StartReadRemoteDataThread();
}
if (mode != eRNBRunLoopModeExit) {
const char *proc_name = "<unknown>";
if (ctx.ArgumentCount() > 0)
proc_name = ctx.ArgumentAtIndex(0);
RNBLogSTDOUT("Got a connection, launched process %s (pid = %d).\n",
proc_name, ctx.ProcessID());
}
} else {
const char *error_str = remote->Context().LaunchStatus().AsString();
RNBLogSTDERR("error: failed to launch process %s: %s\n", argv_sub_zero,
error_str ? error_str : "unknown error.");
}
} break;
case eRNBRunLoopModeInferiorExecuting:
mode = RNBRunLoopInferiorExecuting(remote);
break;
case eRNBRunLoopModePlatformMode:
if (port != INT32_MAX) {
if (!ConnectRemote(remote, host.c_str(), port, reverse_connect,
named_pipe_path.c_str(), unix_socket_name.c_str()))
mode = eRNBRunLoopModeExit;
} else if (str[0] == '/') {
if (remote->Comm().OpenFile(str))
mode = eRNBRunLoopModeExit;
} else if (communication_fd >= 0) {
// We were passed a file descriptor to use during fork/exec that is
// already open
// in our process, so lets just use it!
if (remote->Comm().useFD(communication_fd))
mode = eRNBRunLoopModeExit;
else
remote->StartReadRemoteDataThread();
}
if (mode != eRNBRunLoopModeExit)
mode = RNBRunLoopPlatform(remote);
break;
default:
mode = eRNBRunLoopModeExit;
break;
case eRNBRunLoopModeExit:
break;
}
}
remote->StopReadRemoteDataThread();
remote->Context().SetProcessID(INVALID_NUB_PROCESS);
RNBLogSTDOUT("Exiting.\n");
return 0;
}