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ftmemsim-valgrind/coregrind/vgdb.c
Alexandra Petlanova Hajkova 0432ce486d vgdb: implement the extended-remote protocol 
Executing vgdb --multi makes vgdb talk the gdb extended-remote
protocol. This means that the gdb run command is supported and
vgdb will start up the program under valgrind. Which means you
don't need to run gdb and valgrind from different terminals.
Also vgdb keeps being connected to gdb after valgrind exits. So
you can easily rerun the program with the same breakpoints in
place.

vgdb now implements a minimal gdbserver that just recognizes
a few extended-remote protocol packets. Once it starts up valgrind
it sets up noack and qsupported then it will forward packets
between gdb and valgrind gdbserver. After valgrind shutsdown it
resumes handling gdb packets itself.

https://bugs.kde.org/show_bug.cgi?id=434057

Co-authored-by: Mark Wielaard <mark@klomp.org>
2023-04-14 00:08:53 +02:00

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/*--------------------------------------------------------------------*/
/*--- Relay between gdb and gdbserver embedded in valgrind vgdb.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2011-2017 Philippe Waroquiers
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, see <http://www.gnu.org/licenses/>.
The GNU General Public License is contained in the file COPYING.
*/
/* For accept4. */
#define _GNU_SOURCE
#include "vgdb.h"
#include "config.h"
#include <assert.h>
#include <dirent.h>
#include <errno.h>
#include <fcntl.h>
#include <limits.h>
#include <poll.h>
#include <pthread.h>
#include <signal.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#include <netinet/in.h>
#include <sys/mman.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <sys/wait.h>
/* vgdb has two usages:
1. relay application between gdb and the gdbserver embedded in valgrind.
2. standalone to send monitor commands to a running valgrind-ified process
It is made of a main program which reads arguments. If no
arguments are given or only --pid and --vgdb-prefix, then usage 1 is
assumed.
As relay application, vgdb reads bytes from gdb on stdin and
writes these bytes to valgrind. Bytes read from valgrind are
written to gdb on stdout. Read/Write from/to valgrind is done
using FIFOs. There is one thread reading from stdin, writing to
valgrind on a FIFO. There is one thread reading from valgrind on a
FIFO, writing to gdb on stdout
As a standalone utility, vgdb builds command packets to write to valgrind,
sends it and reads the reply. The same two threads are used to write/read.
Once all the commands are sent and their replies received, vgdb will exit.
*/
int debuglevel;
Bool timestamp = False;
char timestamp_out[20];
static char *vgdb_prefix = NULL;
static char *valgrind_path = NULL;
static char **vargs;
static char cvargs = 0;
char *timestamp_str (Bool produce)
{
static char out[50];
char *ptr;
struct timeval dbgtv;
struct tm *ts_tm;
if (produce) {
gettimeofday(&dbgtv, NULL);
ts_tm = localtime(&dbgtv.tv_sec);
ptr = out + strftime(out, sizeof(out), "%H:%M:%S", ts_tm);
sprintf(ptr, ".%6.6ld ", dbgtv.tv_usec);
} else {
out[0] = 0;
}
return out;
}
/* Will be set to True when any condition indicating we have to shutdown
is encountered. */
Bool shutting_down = False;
VgdbShared32 *shared32;
VgdbShared64 *shared64;
#define VS_written_by_vgdb (shared32 != NULL ? \
shared32->written_by_vgdb \
: shared64->written_by_vgdb)
#define VS_seen_by_valgrind (shared32 != NULL ? \
shared32->seen_by_valgrind \
: shared64->seen_by_valgrind)
#define VS_vgdb_pid (shared32 != NULL ? shared32->vgdb_pid : shared64->vgdb_pid)
void *vmalloc(size_t size)
{
void * mem = malloc(size);
if (mem == NULL)
XERROR(errno, "can't allocate memory\n");
return mem;
}
void *vrealloc(void *ptr,size_t size)
{
void * mem = realloc(ptr, size);
if (mem == NULL)
XERROR(errno, "can't reallocate memory\n");
return mem;
}
/* Return the name of a directory for temporary files. */
static
const char *vgdb_tmpdir(void)
{
const char *tmpdir;
tmpdir = getenv("TMPDIR");
if (tmpdir == NULL || *tmpdir == '\0')
tmpdir = VG_TMPDIR;
if (tmpdir == NULL || *tmpdir == '\0')
tmpdir = "/tmp"; /* fallback */
return tmpdir;
}
/* Return the default path prefix for the named pipes (FIFOs) used by vgdb/gdb
to communicate with valgrind */
static
char *vgdb_prefix_default(void)
{
static HChar *prefix;
if (prefix == NULL) {
const char *tmpdir = vgdb_tmpdir();
prefix = vmalloc(strlen(tmpdir) + strlen("/vgdb-pipe") + 1);
strcpy(prefix, tmpdir);
strcat(prefix, "/vgdb-pipe");
}
return prefix;
}
/* add nrw to the written_by_vgdb field of shared32 or shared64 */
static
void add_written(int nrw)
{
if (shared32 != NULL)
shared32->written_by_vgdb += nrw;
else if (shared64 != NULL)
shared64->written_by_vgdb += nrw;
else
assert(0);
}
static int shared_mem_fd = -1;
static
void map_vgdbshared(char* shared_mem)
{
struct stat fdstat;
void **s;
int tries = 50;
int err;
/* valgrind might still be starting up, give it 5 seconds. */
do {
shared_mem_fd = open(shared_mem, O_RDWR | O_CLOEXEC);
err = errno;
if (shared_mem_fd == -1 && err == ENOENT && tries > 0)
usleep (100000); /* wait 0.1 seconds */
} while (shared_mem_fd == -1 && err == ENOENT && tries-- > 0);
/* shared_mem_fd will not be closed till vgdb exits. */
if (shared_mem_fd == -1)
XERROR(errno, "error opening %s shared memory file\n", shared_mem);
if (fstat(shared_mem_fd, &fdstat) != 0)
XERROR(errno, "fstat\n");
if (fdstat.st_size == sizeof(VgdbShared64))
s = (void*) &shared64;
else if (fdstat.st_size == sizeof(VgdbShared32))
s = (void*) &shared32;
else
#if VEX_HOST_WORDSIZE == 8
XERROR(0,
"error size shared memory file %s.\n"
"expecting size %d (64bits) or %d (32bits) got %ld.\n",
shared_mem,
(int) sizeof(VgdbShared64), (int) sizeof(VgdbShared32),
(long int)fdstat.st_size);
#elif VEX_HOST_WORDSIZE == 4
XERROR(0,
"error size shared memory file %s.\n"
"expecting size %d (32bits) got %ld.\n",
shared_mem,
(int) sizeof(VgdbShared32),
fdstat.st_size);
#else
# error "unexpected wordsize"
#endif
#if VEX_HOST_WORDSIZE == 4
if (shared64 != NULL)
XERROR(0, "cannot use 32 bits vgdb with a 64bits valgrind process\n");
/* But we can use a 64 bits vgdb with a 32 bits valgrind */
#endif
*s = (void*) mmap(NULL, fdstat.st_size,
PROT_READ|PROT_WRITE, MAP_SHARED,
shared_mem_fd, 0);
if (*s == (void *) -1)
XERROR(errno, "error mmap shared memory file %s\n", shared_mem);
}
/* This function loops till shutting_down becomes true. In this loop,
it verifies if valgrind process is reading the characters written
by vgdb. The verification is done every max_invoke_ms ms. If
valgrind is not reading characters, it will use invoker_invoke_gdbserver
to ensure that the gdbserver code is called soon by valgrind. */
static int max_invoke_ms = 100;
#define NEVER 99999999
static int cmd_time_out = NEVER;
static
void *invoke_gdbserver_in_valgrind(void *v_pid)
{
struct timeval cmd_max_end_time;
Bool cmd_started = False;
struct timeval invoke_time;
int pid = *(int *)v_pid;
int written_by_vgdb_before_sleep;
int seen_by_valgrind_before_sleep;
int invoked_written = -1;
unsigned int usecs;
pthread_cleanup_push(invoker_cleanup_restore_and_detach, v_pid);
while (!shutting_down) {
written_by_vgdb_before_sleep = VS_written_by_vgdb;
seen_by_valgrind_before_sleep = VS_seen_by_valgrind;
DEBUG(3,
"written_by_vgdb_before_sleep %d "
"seen_by_valgrind_before_sleep %d\n",
written_by_vgdb_before_sleep,
seen_by_valgrind_before_sleep);
if (cmd_time_out != NEVER
&& !cmd_started
&& written_by_vgdb_before_sleep > seen_by_valgrind_before_sleep) {
/* A command was started. Record the time at which it was started. */
DEBUG(1, "IO for command started\n");
gettimeofday(&cmd_max_end_time, NULL);
cmd_max_end_time.tv_sec += cmd_time_out;
cmd_started = True;
}
if (max_invoke_ms > 0) {
usecs = 1000 * max_invoke_ms;
gettimeofday(&invoke_time, NULL);
invoke_time.tv_sec += max_invoke_ms / 1000;
invoke_time.tv_usec += 1000 * (max_invoke_ms % 1000);
invoke_time.tv_sec += invoke_time.tv_usec / (1000 * 1000);
invoke_time.tv_usec = invoke_time.tv_usec % (1000 * 1000);
} else {
usecs = 0;
}
if (cmd_started) {
// 0 usecs here means the thread just has to check gdbserver eats
// the characters in <= cmd_time_out seconds.
// We will just wait by 1 second max at a time.
if (usecs == 0 || usecs > 1000 * 1000)
usecs = 1000 * 1000;
}
usleep(usecs);
/* If nothing happened during our sleep, let's try to wake up valgrind
or check for cmd time out. */
if (written_by_vgdb_before_sleep == VS_written_by_vgdb
&& seen_by_valgrind_before_sleep == VS_seen_by_valgrind
&& VS_written_by_vgdb > VS_seen_by_valgrind) {
struct timeval now;
gettimeofday(&now, NULL);
DEBUG(2,
"after sleep "
"written_by_vgdb %d "
"seen_by_valgrind %d "
"invoked_written %d\n",
VS_written_by_vgdb,
VS_seen_by_valgrind,
invoked_written);
/* if the pid does not exist anymore, we better stop */
if (kill(pid, 0) != 0)
XERROR(errno,
"invoke_gdbserver_in_valgrind: "
"check for pid %d existence failed\n", pid);
if (cmd_started) {
if (timercmp(&now, &cmd_max_end_time, >))
XERROR(0,
"pid %d did not handle a command in %d seconds\n",
pid, cmd_time_out);
}
if (max_invoke_ms > 0 && timercmp (&now, &invoke_time, >=)) {
/* only need to wake up if the nr written has changed since
last invoke. */
if (invoked_written != written_by_vgdb_before_sleep) {
if (invoker_invoke_gdbserver(pid)) {
/* If invoke successful, no need to invoke again
for the same value of written_by_vgdb_before_sleep. */
invoked_written = written_by_vgdb_before_sleep;
}
}
}
} else {
// Something happened => restart timer check.
if (cmd_time_out != NEVER) {
DEBUG(2, "some IO was done => restart command\n");
cmd_started = False;
}
}
}
pthread_cleanup_pop(0);
return NULL;
}
static
int open_fifo(const char* name, int flags, const char* desc)
{
int fd;
DEBUG(1, "opening %s %s\n", name, desc);
fd = open(name, flags | O_CLOEXEC);
if (fd == -1)
XERROR(errno, "error opening %s %s\n", name, desc);
DEBUG(1, "opened %s %s fd %d\n", name, desc, fd);
return fd;
}
/* acquire a lock on the first byte of the given fd. If not successful,
exits with error.
This allows to avoid having two vgdb speaking with the same Valgrind
gdbserver as this causes serious headaches to the protocol. */
static
void acquire_lock(int fd, int valgrind_pid)
{
struct flock fl;
fl.l_type = F_WRLCK;
fl.l_whence = SEEK_SET;
fl.l_start = 0;
fl.l_len = 1;
if (fcntl(fd, F_SETLK, &fl) < 0) {
if (errno == EAGAIN || errno == EACCES) {
XERROR(errno,
"Cannot acquire lock.\n"
"Probably vgdb pid %d already speaks with Valgrind pid %d\n",
VS_vgdb_pid,
valgrind_pid);
} else {
XERROR(errno, "cannot acquire lock.\n");
}
}
/* Here, we have the lock. It will be released when fd will be closed. */
/* We indicate our pid to Valgrind gdbserver */
if (shared32 != NULL)
shared32->vgdb_pid = getpid();
else if (shared64 != NULL)
shared64->vgdb_pid = getpid();
else
assert(0);
}
#define PBUFSIZ 16384 /* keep in sync with server.h */
/* read some characters from fd.
Returns the nr of characters read, -1 if error.
desc is a string used in tracing */
static
int read_buf(int fd, char* buf, const char* desc)
{
int nrread;
DEBUG(2, "reading %s\n", desc);
nrread = read(fd, buf, PBUFSIZ);
if (nrread == -1) {
ERROR(errno, "error reading %s\n", desc);
return -1;
}
buf[nrread] = '\0';
DEBUG(2, "read %s %s\n", desc, buf);
return nrread;
}
/* write size bytes from buf to fd.
desc is a description of the action for which the write is done.
If notify, then add size to the shared cntr indicating to the
valgrind process that there is new data.
Returns True if write is ok, False if there was a problem. */
static
Bool write_buf(int fd, const char* buf, int size, const char* desc, Bool notify)
{
int nrwritten;
int nrw;
DEBUG(2, "writing %s len %d %.*s notify: %d\n", desc, size,
size, buf, notify);
nrwritten = 0;
while (nrwritten < size) {
nrw = write(fd, buf+nrwritten, size - nrwritten);
if (nrw == -1) {
ERROR(errno, "error write %s\n", desc);
return False;
}
nrwritten = nrwritten + nrw;
if (notify)
add_written(nrw);
}
return True;
}
typedef enum {
FROM_GDB,
TO_GDB,
FROM_PID,
TO_PID } ConnectionKind;
static const int NumConnectionKind = TO_PID+1;
static
const char *ppConnectionKind(ConnectionKind con)
{
switch (con) {
case FROM_GDB: return "FROM_GDB";
case TO_GDB: return "TO_GDB";
case FROM_PID: return "FROM_PID";
case TO_PID: return "TO_PID";
default: return "invalid connection kind";
}
}
static char *shared_mem;
static int from_gdb = 0; /* stdin by default, changed if --port is given. */
static char *from_gdb_to_pid; /* fifo name to write gdb command to pid */
static int to_gdb = 1; /* stdout by default, changed if --port is given. */
static char *to_gdb_from_pid; /* fifo name to read pid replies */
/* Returns True in case read/write operations were done properly.
Returns False in case of error.
to_pid is the file descriptor to write to the process pid. */
static
Bool read_from_gdb_write_to_pid(int to_pid)
{
char buf[PBUFSIZ+1]; // +1 for trailing \0
int nrread;
Bool ret;
nrread = read_buf(from_gdb, buf, "from gdb on stdin");
if (nrread <= 0) {
if (nrread == 0)
DEBUG(1, "read 0 bytes from gdb => assume exit\n");
else
DEBUG(1, "error reading bytes from gdb\n");
close(from_gdb);
shutting_down = True;
return False;
}
ret = write_buf(to_pid, buf, nrread, "to_pid", /* notify */ True);
if (!ret) {
/* Let gdb know the packet couldn't be delivered. */
write_buf(to_gdb, "$E01#a6", 8, "error back to gdb", False);
}
return ret;
}
/* Returns True in case read/write operations were done properly.
Returns False in case of error.
from_pid is the file descriptor to read data from the process pid. */
static
Bool read_from_pid_write_to_gdb(int from_pid)
{
char buf[PBUFSIZ+1]; // +1 for trailing \0
int nrread;
nrread = read_buf(from_pid, buf, "from pid");
if (nrread <= 0) {
if (nrread == 0)
DEBUG(1, "read 0 bytes from pid => assume exit\n");
else
DEBUG(1, "error reading bytes from pid\n");
close(from_pid);
shutting_down = True;
return False;
}
return write_buf(to_gdb, buf, nrread, "to_gdb", /* notify */ False);
}
static
void wait_for_gdb_connect(int in_port)
{
struct sockaddr_in addr;
#ifdef SOCK_CLOEXEC
int listen_gdb = socket(PF_INET, SOCK_STREAM | SOCK_CLOEXEC, IPPROTO_TCP);
#else
int listen_gdb = socket(PF_INET, SOCK_STREAM, IPPROTO_TCP);
#endif
int gdb_connect;
if (-1 == listen_gdb) {
XERROR(errno, "cannot create socket\n");
}
/* allow address reuse to avoid "address already in use" errors */
int one = 1;
if (setsockopt(listen_gdb, SOL_SOCKET, SO_REUSEADDR,
&one, sizeof(one)) < 0) {
XERROR(errno, "cannot enable address reuse\n");
}
memset(&addr, 0, sizeof(addr));
addr.sin_family = AF_INET;
addr.sin_port = htons((unsigned short int)in_port);
addr.sin_addr.s_addr = INADDR_ANY;
if (-1 == bind(listen_gdb, (struct sockaddr *)&addr, sizeof(addr))) {
XERROR(errno, "bind failed\n");
}
TSFPRINTF(stderr, "listening on port %d ...", in_port);
if (-1 == listen(listen_gdb, 1)) {
XERROR(errno, "error listen failed\n");
}
#ifdef SOCK_CLOEXEC
gdb_connect = accept4(listen_gdb, NULL, NULL, SOCK_CLOEXEC);
#else
gdb_connect = accept(listen_gdb, NULL, NULL);
#endif
if (gdb_connect < 0) {
XERROR(errno, "accept failed\n");
}
fprintf(stderr, "connected.\n");
fflush(stderr);
close(listen_gdb);
from_gdb = gdb_connect;
to_gdb = gdb_connect;
}
/* prepares the FIFOs filenames, map the shared memory. */
static
void prepare_fifos_and_shared_mem(int pid)
{
const HChar *user, *host;
unsigned len;
user = getenv("LOGNAME");
if (user == NULL) user = getenv("USER");
if (user == NULL) user = "???";
if (strchr(user, '/')) user = "???";
host = getenv("HOST");
if (host == NULL) host = getenv("HOSTNAME");
if (host == NULL) host = "???";
if (strchr(host, '/')) host = "???";
len = strlen(vgdb_prefix) + strlen(user) + strlen(host) + 40;
from_gdb_to_pid = vmalloc(len);
to_gdb_from_pid = vmalloc(len);
shared_mem = vmalloc(len);
/* below 3 lines must match the equivalent in remote-utils.c */
sprintf(from_gdb_to_pid, "%s-from-vgdb-to-%d-by-%s-on-%s", vgdb_prefix,
pid, user, host);
sprintf(to_gdb_from_pid, "%s-to-vgdb-from-%d-by-%s-on-%s", vgdb_prefix,
pid, user, host);
sprintf(shared_mem, "%s-shared-mem-vgdb-%d-by-%s-on-%s", vgdb_prefix,
pid, user, host);
DEBUG(1, "vgdb: using %s %s %s\n",
from_gdb_to_pid, to_gdb_from_pid, shared_mem);
map_vgdbshared(shared_mem);
}
static void
cleanup_fifos_and_shared_mem(void)
{
free(from_gdb_to_pid);
free(to_gdb_from_pid);
free(shared_mem);
close(shared_mem_fd);
}
/* Convert hex digit A to a number. */
static int
fromhex(int a)
{
if (a >= '0' && a <= '9')
return a - '0';
else if (a >= 'a' && a <= 'f')
return a - 'a' + 10;
else
XERROR(0, "Reply contains invalid hex digit %c\n", a);
return 0;
}
/* Returns next char from fd. -1 if error, -2 if EOF.
NB: must always call it with the same fd */
static int
readchar(int fd)
{
static char buf[PBUFSIZ+1]; // +1 for trailing \0
static int bufcnt = 0;
static unsigned char *bufp;
// unsigned bufp to e.g. avoid having 255 converted to int -1
if (bufcnt-- > 0)
return *bufp++;
bufcnt = read_buf(fd, buf, "static buf readchar");
if (bufcnt <= 0) {
if (bufcnt == 0) {
TSFPRINTF(stderr, "readchar: Got EOF\n");
return -2;
} else {
ERROR(errno, "readchar\n");
return -1;
}
}
bufp = (unsigned char *)buf;
bufcnt--;
return *bufp++;
}
/* Read a packet from fromfd, with error checking,
and store it in BUF.
If checksum incorrect, writes a - on ackfd.
Returns length of packet, or -1 if error or -2 if EOF. */
static int
getpkt(char *buf, int fromfd, int ackfd)
{
char *bp;
unsigned char csum, c1, c2;
int c;
while (1) {
csum = 0;
while (1) {
c = readchar(fromfd);
if (c == '$')
break;
DEBUG(2, "[getpkt: discarding char '%c']\n", c);
if (c < 0)
return c;
}
bp = buf;
while (1) {
c = readchar(fromfd);
if (c < 0)
return c;
if (c == '#')
break;
if (c == '*') {
int repeat;
int r;
int prev;
prev = *(bp-1);
csum += c;
repeat = readchar(fromfd);
csum += repeat;
for (r = 0; r < repeat - 29; r ++)
*bp++ = prev;
} else {
*bp++ = c;
csum += c;
}
}
*bp = 0;
c1 = fromhex(readchar (fromfd));
c2 = fromhex(readchar (fromfd));
if (csum == (c1 << 4) + c2)
break;
TSFPRINTF(stderr, "Bad checksum, sentsum=0x%x, csum=0x%x, buf=%s\n",
(c1 << 4) + c2, csum, buf);
if (write(ackfd, "-", 1) != 1)
ERROR(0, "error when writing - (nack)\n");
else
add_written(1);
}
DEBUG(2, "getpkt (\"%s\"); [no ack] \n", buf);
return bp - buf;
}
static int sigint = 0;
static int sigterm = 0;
static int sigpipe = 0;
static int sighup = 0;
static int sigusr1 = 0;
static int sigalrm = 0;
static int sigusr1_fd = -1;
static pthread_t invoke_gdbserver_in_valgrind_thread;
static
void received_signal(int signum)
{
if (signum == SIGINT)
sigint++;
else if (signum == SIGUSR1) {
sigusr1++;
if (sigusr1_fd >= 0) {
char control_c = '\003';
write_buf(sigusr1_fd, &control_c, 1,
"write \\003 on SIGUSR1", /* notify */ True);
}
}
else if (signum == SIGTERM) {
shutting_down = True;
sigterm++;
} else if (signum == SIGHUP) {
shutting_down = True;
sighup++;
} else if (signum == SIGPIPE) {
sigpipe++;
} else if (signum == SIGALRM) {
sigalrm++;
#if defined(VGPV_arm_linux_android) \
|| defined(VGPV_x86_linux_android) \
|| defined(VGPV_mips32_linux_android) \
|| defined(VGPV_arm64_linux_android)
/* Android has no pthread_cancel. As it also does not have
an invoker implementation, there is no need for cleanup action.
So, we just do nothing. */
DEBUG(1, "sigalrm received, no action on android\n");
#else
/* Note: we cannot directly invoke restore_and_detach : this must
be done by the thread that has attached.
We have in this thread pushed a cleanup handler that will
cleanup what is needed. */
DEBUG(1, "pthread_cancel invoke_gdbserver_in_valgrind_thread\n");
pthread_cancel(invoke_gdbserver_in_valgrind_thread);
#endif
} else {
ERROR(0, "unexpected signal %d\n", signum);
}
}
/* install the signal handlers allowing e.g. vgdb to cleanup in
case of termination. */
static
void install_handlers(void)
{
struct sigaction action, oldaction;
action.sa_handler = received_signal;
sigemptyset(&action.sa_mask);
action.sa_flags = 0;
/* SIGINT: when user types C-c in gdb, this sends
a SIGINT to vgdb + causes a character to be sent to remote gdbserver.
The later is enough to wakeup the valgrind process. */
if (sigaction(SIGINT, &action, &oldaction) != 0)
XERROR(errno, "vgdb error sigaction SIGINT\n");
/* We might do something more intelligent than just
reporting this SIGINT E.g. behave similarly to the gdb: two
control-C without feedback from the debugged process would
mean to stop debugging it. */
/* SIGUSR1: this is used to facilitate automatic testing. When
vgdb receives this signal, it will simulate the user typing C-c. */
if (sigaction(SIGUSR1, &action, &oldaction) != 0)
XERROR(errno, "vgdb error sigaction SIGUSR1\n");
/* SIGTERM: can receive this signal (e.g. from gdb) to terminate vgdb
when detaching or similar. A clean shutdown will be done as both
the read and write side will detect an end of file. */
if (sigaction(SIGTERM, &action, &oldaction) != 0)
XERROR(errno, "vgdb error sigaction SIGTERM\n");
/* SIGPIPE: can receive this signal when gdb detaches or kill the
process debugged: gdb will close its pipes to vgdb. vgdb
must resist to this signal to allow a clean shutdown. */
if (sigaction(SIGPIPE, &action, &oldaction) != 0)
XERROR(errno, "vgdb error sigaction SIGPIPE\n");
/* SIGALRM: in case invoke thread is blocked, alarm is used
to cleanup. */
if (sigaction(SIGALRM, &action, &oldaction) != 0)
XERROR(errno, "vgdb error sigaction SIGALRM\n");
/* unmask all signals, in case the process that launched vgdb
masked some. */
if (sigprocmask(SIG_SETMASK, &action.sa_mask, NULL) != 0)
XERROR(errno, "vgdb error sigprocmask\n");
}
/* close the FIFOs provided connections, terminate the invoker thread. */
static
void close_connection(int to_pid, int from_pid)
{
DEBUG(1, "nr received signals: sigint %d sigterm %d sighup %d sigpipe %d\n",
sigint, sigterm, sighup, sigpipe);
/* Note that we do not forward sigterm to the valgrind process:
a sigterm signal is (probably) received from gdb if the user wants to
kill the debugged process. The kill instruction has been given to
the valgrind process, which should execute a clean exit. */
/* We first close the connection to pid. The pid will then
terminates its gdbserver work. We keep the from pid
fifo opened till the invoker thread is finished.
This allows the gdbserver to finish sending its last reply. */
if (close(to_pid) != 0)
ERROR(errno, "close to_pid\n");
/* if there is a task that was busy trying to wake up valgrind
process, we wait for it to be terminated otherwise threads
in the valgrind process can stay stopped if vgdb main
exits before the invoke thread had time to detach from
all valgrind threads. */
if (max_invoke_ms > 0 || cmd_time_out != NEVER) {
int join;
/* It is surprisingly complex to properly shutdown or exit the
valgrind process in which gdbserver has been invoked through
ptrace. In the normal case (gdb detaches from the process,
or process is continued), the valgrind process will reach the
breakpoint place. Using ptrace, vgdb will ensure the
previous activity of the process is resumed (e.g. restart a
blocking system call). The special case is when gdb asks the
valgrind process to exit (using either the "kill" command or
"monitor exit"). In such a case, the valgrind process will
call exit. But a ptraced process will be blocked in exit,
waiting for the ptracing process to detach or die. vgdb
cannot detach unconditionally as otherwise, in the normal
case, the valgrind process would stop abnormally with SIGSTOP
(as vgdb would not be there to catch it). vgdb can also not
die unconditionally otherwise again, similar problem. So, we
assume that most of the time, we arrive here in the normal
case, and so, the breakpoint has been encountered by the
valgrind process, so the invoker thread will exit and the
join will succeed. For the "kill" case, we cause an alarm
signal to be sent after a few seconds. This means that in the
normal case, the gdbserver code in valgrind process must have
returned the control in less than the alarm nr of seconds,
otherwise, valgrind will stop abnormally with SIGSTOP. */
(void) alarm(3);
DEBUG(1, "joining with invoke_gdbserver_in_valgrind_thread\n");
join = pthread_join(invoke_gdbserver_in_valgrind_thread, NULL);
if (join != 0)
XERROR
(join,
"vgdb error pthread_join invoke_gdbserver_in_valgrind_thread\n");
}
#if !defined(VGO_freebsd)
if (close(from_pid) != 0)
ERROR(errno, "close from_pid\n");
#endif
}
static
int tohex (int nib)
{
if (nib < 10)
return '0' + nib;
else
return 'a' + nib - 10;
}
/* Returns an allocated hex-decoded string from the buf starting at offset
off. Will update off to where the buf has been decoded. Stops decoding
at end of buf (zero) or when seeing the delim char. */
static
char *decode_hexstring (const char *buf, size_t prefixlen, size_t len)
{
int buflen;
char *buf_print;
if (len)
buflen = len;
else
buflen = strlen(buf) - prefixlen;
buf_print = vmalloc (buflen/2 + 1);
for (int i = 0; i < buflen; i = i + 2) {
buf_print[i/2] = ((fromhex(buf[i+prefixlen]) << 4)
+ fromhex(buf[i+prefixlen+1]));
}
buf_print[buflen/2] = '\0';
DEBUG(1, "decode_hexstring: %s\n", buf_print);
return buf_print;
}
static Bool
write_to_gdb (const char *m, int cnt)
{
int written = 0;
while (written < cnt) {
int res = write (to_gdb, m + written, cnt - written);
if (res < 0) {
perror ("write_to_gdb");
return False;
}
written += res;
}
return True;
}
static Bool
write_checksum (const char *str)
{
unsigned char csum = 0;
int i = 0;
while (str[i] != 0)
csum += str[i++];
char p[2];
p[0] = tohex ((csum >> 4) & 0x0f);
p[1] = tohex (csum & 0x0f);
return write_to_gdb (p, 2);
}
static Bool
write_reply(const char *reply)
{
write_to_gdb ("$", 1);
write_to_gdb (reply, strlen (reply));
write_to_gdb ("#", 1);
return write_checksum (reply);
}
/* Creates a packet from a string message, called needs to free. */
static char *
create_packet(const char *msg)
{
unsigned char csum = 0;
int i = 1;
char *p = vmalloc (strlen (msg) + 5); /* $ + msg + # + hexhex + 0 */
strcpy (&p[1], msg);
p[0] = '$';
while (p[i] != 0)
csum += p[i++];
p[i++] = '#';
p[i++] = tohex ((csum >> 4) & 0x0f);
p[i++] = tohex (csum & 0x0f);
p[i] = '\0';
return p;
}
static int read_one_char (char *c)
{
int i;
do
i = read (from_gdb, c, 1);
while (i == -1 && errno == EINTR);
return i;
}
static Bool
send_packet(const char *reply, int noackmode)
{
int ret;
char c;
send_packet_start:
if (!write_reply(reply))
return False;
if (!noackmode) {
// Look for '+' or '-'.
// We must wait for "+" if !noackmode.
do {
ret = read_one_char(&c);
if (ret <= 0)
return False;
// And if in !noackmode if we get "-" we should resent the packet.
if (c == '-')
goto send_packet_start;
} while (c != '+');
DEBUG(1, "sent packet to gdb got: %c\n",c);
}
return True;
}
// Reads one packet from_gdb starting with $ into buf.
// Skipping any other characters.
// Returns the size of the packet, 0 for end of input,
// or -1 if no packet could be read.
static int receive_packet(char *buf, int noackmode)
{
int bufcnt = 0, ret;
char c, c1, c2;
unsigned char csum = 0;
// Look for first '$' (start of packet) or error.
receive_packet_start:
do {
ret = read_one_char(&c);
if (ret <= 0)
return ret;
} while (c != '$');
// Found start of packet ('$')
while (bufcnt < (PBUFSIZ+1)) {
ret = read_one_char(&c);
if (ret <= 0)
return ret;
if (c == '#') {
if ((ret = read_one_char(&c1)) <= 0
|| (ret = read_one_char(&c2)) <= 0) {
return ret;
}
c1 = fromhex(c1);
c2 = fromhex(c2);
break;
}
buf[bufcnt] = c;
csum += buf[bufcnt];
bufcnt++;
}
// Packet complete, add terminator.
buf[bufcnt] ='\0';
if (!(csum == (c1 << 4) + c2)) {
TSFPRINTF(stderr, "Bad checksum, sentsum=0x%x, csum=0x%x, buf=%s\n",
(c1 << 4) + c2, csum, buf);
if (!noackmode)
if (!write_to_gdb ("-", 1))
return -1;
/* Try again, gdb should resend the packet. */
bufcnt = 0;
csum = 0;
goto receive_packet_start;
}
if (!noackmode)
if (!write_to_gdb ("+", 1))
return -1;
return bufcnt;
}
// Returns a pointer to the char after the next delim char.
static const char *next_delim_string (const char *buf, char delim)
{
while (*buf) {
if (*buf++ == delim)
break;
}
return buf;
}
// Throws away the packet name and decodes the hex string, which is placed in
// decoded_string (the caller owns this and is responsible for freeing it).
static int split_hexdecode(const char *buf, const char *string,
const char *delim, char **decoded_string)
{
const char *next_str = next_delim_string(buf, *delim);
if (next_str) {
*decoded_string = decode_hexstring (next_str, 0, 0);
DEBUG(1, "split_hexdecode decoded %s\n", *decoded_string);
return 1;
} else {
TSFPRINTF(stderr, "%s decoding error: finding the hex string in %s failed!\n", string, buf);
return 0;
}
}
static int count_delims(char delim, char *buf)
{
size_t count = 0;
char *ptr = buf;
while (*ptr)
count += *ptr++ == delim;
return count;
}
// Determine the length of the arguments.
// This depends on the len array being initialized to -1 for each element.
// We first skip the command (e.g. vRun;arg0;arg1)
static void count_len(char delim, char *buf, size_t *len)
{
int i = 0;
char *ptr = buf;
// Skip the command
while (*ptr && *ptr != delim)
ptr++;
// Delimiter counts towards the first arg0
if (*ptr == delim) {
ptr++;
len[i]++;
}
// For each arg0... count chars (delim counts towards next arg)
while (*ptr) {
i += *ptr++ == delim;
len[i]++;
}
}
/* Declare here, will be used early, implementation follows later. */
static void gdb_relay(int pid, int send_noack_mode, char *q_buf);
/* Returns zero on success (and the pid of the valgrind process),
or the errno from the child on failure. */
static
int fork_and_exec_valgrind (int argc, char **argv, const char *working_dir,
pid_t *pid)
{
int err = 0;
// We will use a pipe to track what the child does,
// so we can report failure.
int pipefd[2];
if (pipe2 (pipefd, O_CLOEXEC) == -1) {
err = errno;
perror ("pipe2 failed");
return err;
}
pid_t p = fork ();
if (p < 0) {
err = errno;
perror ("fork failed");
return err;
} else if (p > 0) {
// I am the parent (vgdb), p is the pid of the child (valgrind)
// We only read from the child to see if everything is OK.
// If the pipe closes, we get zero back, which is good.
// An error reading the pipe is bad (and really shouldn't happen).
// Otherwise the child sent us an errno code about what went wrong.
close (pipefd[1]);
while (err == 0) {
int r = read (pipefd[0], &err, sizeof (int));
if (r == 0) // end of file, good pipe closed after execve
break;
if (r == -1) {
if (errno == EINTR)
continue;
else {
err = errno;
perror ("pipe read");
}
}
}
close (pipefd[0]);
if (err != 0)
return err;
else {
*pid = p;
return 0;
}
} else {
// p == 0, I am the child (will start valgrind)
// We write success to the pipe, no need to read from it.
close (pipefd[0]);
if (working_dir != NULL && working_dir[0] != '\0') {
if (chdir (working_dir) != 0) {
err = errno;
perror("chdir");
write (pipefd[1], &err, sizeof (int));
_exit (-1);
}
}
/* Try to launch valgrind. Add --vgdb-error=0 to stop immediately so we
can attach and --launched-with-multi to let valgrind know it doesn't
need to show a banner how to connect to gdb, we will do that
automagically. And add --vgdb-shadow-registers=yes to make shadow
registers available by default. Add any other valgrind arguments the
user gave with --vargs. Then the rest of the arguments to valgrind are
the program to exec plus its arguments. */
const int extra_vargs = 3;
/* vargv[0] == "valgrind",
vargv[1..extra_vargs] == static valgrind arguments vgdb needs,
vargv[extra_vargs+1..extra_vargs+1+cvargs] == user valgrind arguments,
vargv[extra_vargs+1+cvargs..extra_vargs+1+cvargs+args] == prog + args,
vargs[arguments - 1] = NULL */
int arguments = 1 + extra_vargs + cvargs + argc + 1;
// We combine const and non-const char[]. This is mildly annoying
// since we then need a char *const * for execvp. So we strdup the
// const char*. Not pretty :{
char **vargv = vmalloc (arguments * sizeof (char *));
vargv[0] = strdup ("valgrind");
vargv[1] = strdup ("--vgdb-error=0");
vargv[2] = strdup ("--launched-with-multi=yes");
vargv[3] = strdup ("--vgdb-shadow-registers=yes");
// Add --vargs
for (int i = 0; i < cvargs; i++) {
vargv[i + extra_vargs + 1] = vargs[i];
}
// Add command and args
for (int i = 0; i < argc; i++) {
vargv[i + extra_vargs + 1 + cvargs] = argv[i];
}
vargv[arguments - 1] = NULL;
if (!valgrind_path) {
// TODO use execvpe (or something else if not on GNU/Linux
/* We want to make a copy of the environ on start. When we
get a QEnvironmentReset we copy that back. If we get an
EvironSet/Add/Remove we update the copy. */
execvp ("valgrind", vargv);
}
else {
vargv[0] = valgrind_path;
execvp (vargv[0], vargv);
}
// We really shouldn't get here...
err = errno;
/* Note we are after fork and exec failed, we cannot really call
perror or printf in this situation since they aren't async-safe. */
// perror ("execvp valgrind");
// printf ("execve returned??? confusing: %d\n", res);
write (pipefd[1], &err, sizeof (int));
_exit (-1);
}
abort (); // Impossible
}
/* Do multi stuff. */
static
void do_multi_mode(void)
{
char *buf = vmalloc(PBUFSIZ+1);
char *q_buf = vmalloc(PBUFSIZ+1); //save the qSupported packet sent by gdb
//to send it to the valgrind gdbserver later
q_buf[0] = '\0';
int noackmode = 0, pkt_size = 0, bad_unknown_packets = 0;
char *string = NULL;
char *working_dir = NULL;
DEBUG(1, "doing multi stuff...\n");
while (1){
/* We get zero if the pipe was closed (EOF), or -1 on error reading from
the pipe to gdb. */
pkt_size = receive_packet(buf, noackmode);
if (pkt_size <= 0) {
DEBUG(1, "receive_packet: %d\n", pkt_size);
break;
}
DEBUG(1, "packet recieved: '%s'\n", buf);
#define QSUPPORTED "qSupported:"
#define STARTNOACKMODE "QStartNoAckMode"
#define QRCMD "qRcmd" // This is the monitor command in gdb
#define VRUN "vRun"
#define XFER "qXfer"
#define QATTACHED "qAttached"
#define QENVIRONMENTHEXENCODED "QEnvironmentHexEncoded"
#define QENVIRONMENTRESET "QEnvironmentReset"
#define QENVIRONMENTUNSET "QEnvironmentUnset"
#define QSETWORKINGDIR "QSetWorkingDir"
#define QTSTATUS "qTStatus"
if (strncmp(QSUPPORTED, buf, strlen(QSUPPORTED)) == 0) {
DEBUG(1, "CASE %s\n", QSUPPORTED);
// And here is our reply.
// XXX error handling? We don't check the arguments.
char *reply;
strcpy(q_buf, buf);
// Keep this in sync with coregrind/m_gdbserver/server.c
asprintf (&reply,
"PacketSize=%x;"
"QStartNoAckMode+;"
"QPassSignals+;"
"QCatchSyscalls+;"
/* Just report support always. */
"qXfer:auxv:read+;"
/* We'll force --vgdb-shadow-registers=yes */
"qXfer:features:read+;"
"qXfer:exec-file:read+;"
"qXfer:siginfo:read+;"
/* Some extra's vgdb support before valgrind starts up. */
"QEnvironmentHexEncoded+;"
"QEnvironmentReset+;"
"QEnvironmentUnset+;"
"QSetWorkingDir+", (UInt)PBUFSIZ - 1);
send_packet(reply, noackmode);
free (reply);
}
else if (strncmp(STARTNOACKMODE, buf, strlen(STARTNOACKMODE)) == 0) {
// We have to ack this one
send_packet("OK", 0);
noackmode = 1;
}
else if (buf[0] == '!') {
send_packet("OK", noackmode);
}
else if (buf[0] == '?') {
send_packet("W00", noackmode);
}
else if (strncmp("H", buf, strlen("H")) == 0) {
// Set thread packet, but we are not running yet.
send_packet("E01", noackmode);
}
else if (strncmp("vMustReplyEmpty", buf, strlen("vMustReplyEmpty")) == 0) {
send_packet ("", noackmode);
}
else if (strncmp(QRCMD, buf, strlen(QRCMD)) == 0) {
send_packet ("No running target, monitor commands not available yet.", noackmode);
char *decoded_string = decode_hexstring (buf, strlen (QRCMD) + 1, 0);
DEBUG(1, "qRcmd decoded: %s\n", decoded_string);
free (decoded_string);
}
else if (strncmp(VRUN, buf, strlen(VRUN)) == 0) {
// vRun;filename[;argument]*
// vRun, filename and arguments are split on ';',
// no ';' at the end.
// If there are no arguments count is one (just the filename).
// Otherwise it is the number of arguments plus one (the filename).
// The filename must be there and starts after the first ';'.
// TODO: Handle vRun;[;argument]*
// https://www.sourceware.org/gdb/onlinedocs/gdb/Packets.html#Packets
// If filename is an empty string, the stub may use a default program
// (e.g. the last program run).
size_t count = count_delims(';', buf);
size_t *len = vmalloc(count * sizeof(count));
const char *delim = ";";
const char *next_str = next_delim_string(buf, *delim);
char **decoded_string = vmalloc(count * sizeof (char *));
// Count the lenghts of each substring, init to -1 to compensate for
// each substring starting with a delim char.
for (int i = 0; i < count; i++)
len[i] = -1;
count_len(';', buf, len);
if (next_str) {
DEBUG(1, "vRun: next_str %s\n", next_str);
for (int i = 0; i < count; i++) {
/* Handle the case when the arguments
* was specified to gdb's run command
* but no remote exec-file was set,
* so the first vRun argument is missing.
* For example vRun;;6c. */
if (*next_str == *delim) {
next_str++;
/* empty string that can be freed. */
decoded_string[i] = strdup("");
}
else {
decoded_string[i] = decode_hexstring (next_str, 0, len[i]);
if (i < count - 1)
next_str = next_delim_string(next_str, *delim);
}
DEBUG(1, "vRun decoded: %s, next_str %s, len[%d] %d\n", decoded_string[i], next_str, i, len[i]);
}
/* If we didn't get any arguments or the filename is an empty
string, valgrind won't know which program to run. */
DEBUG (1, "count: %d, len[0]: %d\n", count, len[0]);
if (! count || len[0] == 0) {
free(len);
for (int i = 0; i < count; i++)
free (decoded_string[i]);
free (decoded_string);
send_packet ("E01", noackmode);
continue;
}
/* We have collected the decoded strings so we can use them to
launch valgrind with the correct arguments... We then use the
valgrind pid to start relaying packets. */
pid_t valgrind_pid = -1;
int res = fork_and_exec_valgrind (count,
decoded_string,
working_dir,
&valgrind_pid);
if (res == 0) {
// Lets report we Stopped with SIGTRAP (05).
send_packet ("S05", noackmode);
prepare_fifos_and_shared_mem(valgrind_pid);
DEBUG(1, "from_gdb_to_pid %s, to_gdb_from_pid %s\n", from_gdb_to_pid, to_gdb_from_pid);
// gdb_rely is an endless loop till valgrind quits.
shutting_down = False;
gdb_relay (valgrind_pid, 1, q_buf);
cleanup_fifos_and_shared_mem();
DEBUG(1, "valgrind relay done\n");
int status;
pid_t p = waitpid (valgrind_pid, &status, 0);
DEBUG(2, "waitpid: %d\n", (int) p);
if (p == -1)
DEBUG(1, "waitpid error %s\n", strerror (errno));
else {
if (WIFEXITED(status))
DEBUG(1, "valgrind exited with %d\n",
WEXITSTATUS(status));
else if (WIFSIGNALED(status))
DEBUG(1, "valgrind kill by signal %d\n",
WTERMSIG(status));
else
DEBUG(1, "valgind unexpectedly stopped or continued");
}
} else {
send_packet ("E01", noackmode);
DEBUG(1, "OOPS! couldn't launch valgrind %s\n",
strerror (res));
}
free(len);
for (int i = 0; i < count; i++)
free (decoded_string[i]);
free (decoded_string);
} else {
free(len);
send_packet ("E01", noackmode);
DEBUG(1, "vRun decoding error: no next_string!\n");
continue;
}
} else if (strncmp(QATTACHED, buf, strlen(QATTACHED)) == 0) {
send_packet ("1", noackmode);
DEBUG(1, "qAttached sent: '1'\n");
const char *next_str = next_delim_string(buf, ':');
if (next_str) {
char *decoded_string = decode_hexstring (next_str, 0, 0);
DEBUG(1, "qAttached decoded: %s, next_str %s\n", decoded_string, next_str);
free (decoded_string);
} else {
DEBUG(1, "qAttached decoding error: strdup of %s failed!\n", buf);
continue;
}
} /* Reset the state of environment variables in the remote target before starting
the inferior. In this context, reset means unsetting all environment variables
that were previously set by the user (i.e., were not initially present in the environment). */
else if (strncmp(QENVIRONMENTRESET, buf,
strlen(QENVIRONMENTRESET)) == 0) {
send_packet ("OK", noackmode);
// TODO clear all environment strings. We're not using
// environment strings now. But we should.
} else if (strncmp(QENVIRONMENTHEXENCODED, buf,
strlen(QENVIRONMENTHEXENCODED)) == 0) {
send_packet ("OK", noackmode);
if (!split_hexdecode(buf, QENVIRONMENTHEXENCODED, ":", &string))
break;
// TODO Collect all environment strings and add them to environ
// before launcing valgrind.
free (string);
string = NULL;
} else if (strncmp(QENVIRONMENTUNSET, buf,
strlen(QENVIRONMENTUNSET)) == 0) {
send_packet ("OK", noackmode);
if (!split_hexdecode(buf, QENVIRONMENTUNSET, ":", &string))
break;
// TODO Remove this environment string from the collection.
free (string);
string = NULL;
} else if (strncmp(QSETWORKINGDIR, buf,
strlen(QSETWORKINGDIR)) == 0) {
// Silly, but we can only reply OK, even if the working directory is
// bad. Errors will be reported when we try to execute the actual
// process.
send_packet ("OK", noackmode);
// Free any previously set working_dir
free (working_dir);
working_dir = NULL;
if (!split_hexdecode(buf, QSETWORKINGDIR, ":", &working_dir)) {
continue; // We cannot report the error to gdb...
}
DEBUG(1, "set working dir to: %s\n", working_dir);
} else if (strncmp(XFER, buf, strlen(XFER)) == 0) {
char *buf_dup = strdup(buf);
DEBUG(1, "strdup: buf_dup %s\n", buf_dup);
if (buf_dup) {
const char *delim = ":";
size_t count = count_delims(delim[0], buf);
if (count < 4) {
strsep(&buf_dup, delim);
strsep(&buf_dup, delim);
strsep(&buf_dup, delim);
char *decoded_string = decode_hexstring (buf_dup, 0, 0);
DEBUG(1, "qXfer decoded: %s, buf_dup %s\n", decoded_string, buf_dup);
free (decoded_string);
}
free (buf_dup);
} else {
DEBUG(1, "qXfer decoding error: strdup of %s failed!\n", buf);
free (buf_dup);
continue;
}
// Whether we could decode it or not, we cannot handle it now. We
// need valgrind gdbserver to properly reply. So error out here.
send_packet ("E00", noackmode);
} else if (strncmp(QTSTATUS, buf, strlen(QTSTATUS)) == 0) {
// We don't support trace experiments
DEBUG(1, "Got QTSTATUS\n");
send_packet ("", noackmode);
} else if (strcmp("qfThreadInfo", buf) == 0) {
DEBUG(1, "Got qfThreadInfo\n");
/* There are no threads yet, reply 'l' end of list. */
send_packet ("l", noackmode);
} else if (buf[0] != '\0') {
// We didn't understand.
DEBUG(1, "Unknown packet received: '%s'\n", buf);
bad_unknown_packets++;
if (bad_unknown_packets > 10) {
DEBUG(1, "Too many bad/unknown packets received\n");
break;
}
send_packet ("", noackmode);
}
}
DEBUG(1, "done doing multi stuff...\n");
free(working_dir);
free(buf);
free(q_buf);
shutting_down = True;
close (to_gdb);
close (from_gdb);
}
/* Relay data between gdb and Valgrind gdbserver, till EOF or an error is
encountered. q_buf is the qSupported packet received from gdb. */
static
void gdb_relay(int pid, int send_noack_mode, char *q_buf)
{
int from_pid = -1; /* fd to read from pid */
int to_pid = -1; /* fd to write to pid */
int shutdown_loop = 0;
TSFPRINTF(stderr, "relaying data between gdb and process %d\n", pid);
if (max_invoke_ms > 0)
pthread_create(&invoke_gdbserver_in_valgrind_thread, NULL,
invoke_gdbserver_in_valgrind, (void *) &pid);
to_pid = open_fifo(from_gdb_to_pid, O_WRONLY, "write to pid");
acquire_lock(shared_mem_fd, pid);
from_pid = open_fifo(to_gdb_from_pid, O_RDONLY|O_NONBLOCK,
"read mode from pid");
sigusr1_fd = to_pid; /* allow simulating user typing control-c */
Bool waiting_for_noack_mode = False;
Bool waiting_for_qsupported = False;
if(send_noack_mode) {
DEBUG(1, "gdb_relay: to_pid %d, from_pid: %d\n", to_pid, from_pid);
write_buf(to_pid, "$QStartNoAckMode#b0", 19,
"write start no ack mode",
/* notify */ True);
waiting_for_noack_mode = True;
}
while (1) {
ConnectionKind ck;
int ret;
struct pollfd pollfds[NumConnectionKind];
/* watch data written by gdb, watch POLLERR on both gdb fd */
pollfds[FROM_GDB].fd = from_gdb;
pollfds[FROM_GDB].events = POLLIN;
pollfds[FROM_GDB].revents = 0;
pollfds[TO_GDB].fd = to_gdb;
pollfds[TO_GDB].events = 0;
pollfds[TO_GDB].revents = 0;
/* watch data written by pid, watch POLLERR on both pid fd */
pollfds[FROM_PID].fd = from_pid;
pollfds[FROM_PID].events = POLLIN;
pollfds[FROM_PID].revents = 0;
pollfds[TO_PID].fd = to_pid;
pollfds[TO_PID].events = 0;
pollfds[TO_PID].revents = 0;
ret = poll(pollfds,
NumConnectionKind,
(shutting_down ?
1 /* one second */
: -1 /* infinite */));
DEBUG(2, "poll ret %d errno %d\n", ret, errno);
/* check for unexpected error */
if (ret <= 0 && errno != EINTR) {
ERROR(errno, "unexpected poll ret %d\n", ret);
shutting_down = True;
break;
}
/* check for data to read */
for (ck = 0; ck < NumConnectionKind; ck ++) {
if (pollfds[ck].revents & POLLIN) {
switch (ck) {
case FROM_GDB:
if (waiting_for_noack_mode || waiting_for_qsupported)
break; /* Don't add any messages while vgdb is talking. */
if (!read_from_gdb_write_to_pid(to_pid))
shutting_down = True;
break;
case FROM_PID:
// First handle any messages from vgdb
if (waiting_for_noack_mode) {
char buf[PBUFSIZ+1]; // +1 for trailing \0
size_t buflen;
buflen = getpkt(buf, from_pid, to_pid);
if (buflen != 2 || strcmp(buf, "OK") != 0) {
if (buflen != 2)
ERROR(0, "no ack mode: unexpected buflen %d, buf %s\n",
buflen, buf);
else
ERROR(0, "no ack mode: unexpected packet %s\n", buf);
}
waiting_for_noack_mode = False;
/* Propagate qSupported to valgrind, we already replied. */
if (q_buf != NULL && q_buf[0] != '\0') {
char *pkt = create_packet (q_buf);
write_buf(to_pid, pkt, strlen(pkt),
"write qSupported", /* notify */ True);
free(pkt);
waiting_for_qsupported = True;
}
} else if (waiting_for_qsupported) {
char buf[PBUFSIZ+1]; // +1 for trailing \0
size_t buflen;
buflen = getpkt(buf, from_pid, to_pid);
/* Should we sanity check the result? */
if (buflen > 0) {
waiting_for_qsupported = False;
} else {
ERROR(0, "Unexpected getpkt for qSupported reply: %d\n",
buflen);
}
} else if (!read_from_pid_write_to_gdb(from_pid))
shutting_down = True;
break;
default: XERROR(0, "unexpected POLLIN on %s\n",
ppConnectionKind(ck));
}
}
}
/* check for an fd being in error condition */
for (ck = 0; ck < NumConnectionKind; ck ++) {
if (pollfds[ck].revents & POLLERR) {
DEBUG(1, "connection %s fd %d POLLERR error condition\n",
ppConnectionKind(ck), pollfds[ck].fd);
invoker_valgrind_dying();
shutting_down = True;
}
if (pollfds[ck].revents & POLLHUP) {
DEBUG(1, "connection %s fd %d POLLHUP error condition\n",
ppConnectionKind(ck), pollfds[ck].fd);
invoker_valgrind_dying();
shutting_down = True;
}
if (pollfds[ck].revents & POLLNVAL) {
DEBUG(1, "connection %s fd %d POLLNVAL error condition\n",
ppConnectionKind(ck), pollfds[ck].fd);
invoker_valgrind_dying();
shutting_down = True;
}
}
if (shutting_down) {
/* we let some time to the final packets to be transferred */
shutdown_loop++;
if (shutdown_loop > 3)
break;
}
}
close_connection(to_pid, from_pid);
}
static int packet_len_for_command(char *cmd)
{
/* cmd will be send as a packet $qRcmd,xxxx....................xx#cc */
return 7+ 2*strlen(cmd) +3 + 1;
}
/* hyper-minimal protocol implementation that
sends the provided commands (using qRcmd packets)
and read and display their replies. */
static
void standalone_send_commands(int pid,
int last_command,
char *commands[] )
{
int from_pid = -1; /* fd to read from pid */
int to_pid = -1; /* fd to write to pid */
int i;
int hi;
char hex[3];
unsigned char cksum;
char *hexcommand;
char buf[PBUFSIZ+1]; // +1 for trailing \0
int buflen;
int nc;
if (max_invoke_ms > 0 || cmd_time_out != NEVER)
pthread_create(&invoke_gdbserver_in_valgrind_thread, NULL,
invoke_gdbserver_in_valgrind, (void *) &pid);
to_pid = open_fifo(from_gdb_to_pid, O_WRONLY, "write to pid");
acquire_lock(shared_mem_fd, pid);
/* first send a C-c \003 to pid, so that it wakes up the process
After that, we can open the fifo from the pid in read mode
We then start to wait for packets (normally first a resume reply)
At that point, we send our command and expect replies */
buf[0] = '\003';
i = 0;
while (!write_buf(to_pid, buf, 1,
"write \\003 to wake up", /* notify */ True)) {
/* If write fails, retries up to 10 times every 0.5 seconds
This aims at solving the race condition described in
remote-utils.c remote_finish function. */
usleep(500*1000);
i++;
if (i >= 10)
XERROR(errno, "failed to send wake up char after 10 trials\n");
}
from_pid = open_fifo(to_gdb_from_pid, O_RDONLY,
"read cmd result from pid");
/* Enable no ack mode. */
write_buf(to_pid, "$QStartNoAckMode#b0", 19, "write start no ack mode",
/* notify */ True);
buflen = getpkt(buf, from_pid, to_pid);
if (buflen != 2 || strcmp(buf, "OK") != 0) {
if (buflen != 2)
ERROR(0, "no ack mode: unexpected buflen %d\n", buflen);
else
ERROR(0, "no ack mode: unexpected packet %s\n", buf);
}
for (nc = 0; nc <= last_command; nc++) {
TSFPRINTF(stderr, "sending command %s to pid %d\n", commands[nc], pid);
/* prepare hexcommand $qRcmd,xxxx....................xx#cc */
hexcommand = vmalloc(packet_len_for_command(commands[nc]));
hexcommand[0] = 0;
strcat(hexcommand, "$qRcmd,");
for (i = 0; i < strlen(commands[nc]); i++) {
sprintf(hex, "%02x", (unsigned char) commands[nc][i]);
// Need to use unsigned char, to avoid sign extension.
strcat(hexcommand, hex);
}
/* checksum (but without the $) */
cksum = 0;
for (hi = 1; hi < strlen(hexcommand); hi++)
cksum+=hexcommand[hi];
strcat(hexcommand, "#");
sprintf(hex, "%02x", cksum);
strcat(hexcommand, hex);
write_buf(to_pid, hexcommand, strlen(hexcommand),
"writing hex command to pid", /* notify */ True);
/* we exit of the below loop explicitly when the command has
been handled or because a signal handler will set
shutting_down. */
while (!shutting_down) {
buflen = getpkt(buf, from_pid, to_pid);
if (buflen < 0) {
ERROR(0, "error reading packet\n");
if (buflen == -2)
invoker_valgrind_dying();
break;
}
if (strlen(buf) == 0) {
DEBUG(0, "empty packet rcvd (packet qRcmd not recognised?)\n");
break;
}
if (strcmp(buf, "OK") == 0) {
DEBUG(1, "OK packet rcvd\n");
break;
}
if (buf[0] == 'E') {
DEBUG(0,
"E NN error packet rcvd: %s (unknown monitor command?)\n",
buf);
break;
}
if (buf[0] == 'W') {
DEBUG(0, "W stopped packet rcvd: %s\n", buf);
break;
}
if (buf[0] == 'T') {
DEBUG(1, "T resume reply packet received: %s\n", buf);
continue;
}
/* must be here an O packet with hex encoded string reply
=> decode and print it */
if (buf[0] != 'O') {
DEBUG(0, "expecting O packet, received: %s\n", buf);
continue;
}
{
char buf_print[buflen/2 + 1];
for (i = 1; i < buflen; i = i + 2)
buf_print[i/2] = (fromhex(*(buf+i)) << 4)
+ fromhex(*(buf+i+1));
buf_print[buflen/2] = 0;
printf("%s", buf_print);
fflush(stdout);
}
}
free(hexcommand);
}
shutting_down = True;
close_connection(to_pid, from_pid);
}
/* report to user the existence of a vgdb-able valgrind process
with given pid.
Note: this function does not use XERROR if an error is encountered
while producing the command line for pid, as this is not critical
and at least on MacOS, reading cmdline is not available. */
static
void report_pid(int pid, Bool on_stdout)
{
char cmdline_file[50]; // large enough
int fd, i;
FILE *out = on_stdout ? stdout : stderr;
TSFPRINTF(out, "use --pid=%d for ", pid);
sprintf(cmdline_file, "/proc/%d/cmdline", pid);
fd = open(cmdline_file, O_RDONLY | O_CLOEXEC);
if (fd == -1) {
DEBUG(1, "error opening cmdline file %s %s\n",
cmdline_file, strerror(errno));
fprintf(out, "(could not open process command line)\n");
} else {
char cmdline[100];
ssize_t sz;
while ((sz = read(fd, cmdline, sizeof cmdline - 1)) > 0) {
for (i = 0; i < sz; i++)
if (cmdline[i] == 0)
cmdline[i] = ' ';
cmdline[sz] = 0;
fprintf(out, "%s", cmdline);
}
if (sz == -1) {
DEBUG(1, "error reading cmdline file %s %s\n",
cmdline_file, strerror(errno));
fprintf(out, "(error reading process command line)");
}
fprintf(out, "\n");
close(fd);
}
fflush(out);
}
static
void usage(void)
{
fprintf(stderr,
"Usage: vgdb [OPTION]... [[-c] COMMAND]...\n"
"vgdb (valgrind gdb) has two usages\n"
" 1. standalone to send monitor commands to a Valgrind gdbserver.\n"
" The OPTION(s) must be followed by the command to send\n"
" To send more than one command, separate the commands with -c\n"
" 2. relay application between gdb and a Valgrind gdbserver.\n"
" Only OPTION(s) can be given.\n"
"\n"
" OPTIONS are [--pid=<number>] [--vgdb-prefix=<prefix>]\n"
" [--wait=<number>] [--max-invoke-ms=<number>]\n"
" [--port=<portnr>\n"
" [--cmd-time-out=<number>] [-l] [-T] [-D] [-d]\n"
" [--multi]\n"
" \n"
" --pid arg must be given if multiple Valgrind gdbservers are found.\n"
" --vgdb-prefix arg must be given to both Valgrind and vgdb utility\n"
" if you want to change the prefix (default %s) for the FIFOs communication\n"
" between the Valgrind gdbserver and vgdb.\n"
" --wait (default 0) tells vgdb to check during the specified number\n"
" of seconds if a Valgrind gdbserver can be found.\n"
" --max-invoke-ms (default 100) gives the nr of milli-seconds after which vgdb\n"
" will force the invocation of the Valgrind gdbserver (if the Valgrind\n"
" process is blocked in a system call).\n"
" --port instructs vgdb to listen for gdb on the specified port nr.\n"
" --cmd-time-out (default 99999999) tells vgdb to exit if the found Valgrind\n"
" gdbserver has not processed a command after number seconds\n"
" --multi start in extended-remote mode, wait for gdb to tell us what to run\n"
" --valgrind, pass the path to valgrind to use. If not specified, the system valgrind will be launched.\n"
" --vargs everything that follows is an argument for valgrind."
" -l arg tells to show the list of running Valgrind gdbserver and then exit.\n"
" -T arg tells to add timestamps to vgdb information messages.\n"
" -D arg tells to show shared mem status and then exit.\n"
" -d arg tells to show debug info. Multiple -d args for more debug info\n"
"\n"
" -h --help shows this message\n"
" The GDB python code defining GDB front end valgrind commands is:\n %s\n"
" To get help from the Valgrind gdbserver, use vgdb help\n"
"\n", vgdb_prefix_default(), VG_LIBDIR "/valgrind-monitor.py"
);
invoker_restrictions_msg();
}
/* If show_list, outputs on stdout the list of Valgrind processes with gdbserver activated.
and then exits.
else if arg_pid == -1, waits maximum check_trials seconds to discover
a valgrind pid appearing.
Otherwise verify arg_pid is valid and corresponds to a Valgrind process
with gdbserver activated.
Returns the pid to work with
or exits in case of error (e.g. no pid found corresponding to arg_pid */
static
int search_arg_pid(int arg_pid, int check_trials, Bool show_list)
{
int i;
int pid = -1;
if (arg_pid == 0 || arg_pid < -1) {
TSFPRINTF(stderr, "vgdb error: invalid pid %d given\n", arg_pid);
exit(1);
} else {
/* search for a matching named fifo.
If we have been given a pid, we will check that the matching FIFO is
there (or wait the nr of check_trials for this to appear).
If no pid has been given, then if we find only one FIFO,
we will use this to build the pid to use.
If we find multiple processes with valid FIFO, we report them and will
exit with an error. */
DIR *vgdb_dir;
char *vgdb_dir_name = vmalloc(strlen (vgdb_prefix) + 3);
struct dirent *f;
int is;
int nr_valid_pid = 0;
const char *suffix = "-from-vgdb-to-"; /* followed by pid */
char *vgdb_format = vmalloc(strlen(vgdb_prefix) + strlen(suffix) + 1);
strcpy(vgdb_format, vgdb_prefix);
strcat(vgdb_format, suffix);
if (strchr(vgdb_prefix, '/') != NULL) {
strcpy(vgdb_dir_name, vgdb_prefix);
for (is = strlen(vgdb_prefix) - 1; is >= 0; is--)
if (vgdb_dir_name[is] == '/') {
vgdb_dir_name[is+1] = '\0';
break;
}
} else {
strcpy(vgdb_dir_name, "");
}
DEBUG(1, "searching pid in directory %s format %s\n",
vgdb_dir_name, vgdb_format);
/* try to find FIFOs with valid pid.
On exit of the loop, pid is set to:
the last pid found if show_list (or -1 if no process was listed)
-1 if no FIFOs matching a running process is found
-2 if multiple FIFOs of running processes are found
otherwise it is set to the (only) pid found that can be debugged
*/
for (i = 0; i < check_trials; i++) {
DEBUG(1, "check_trial %d \n", i);
if (i > 0)
/* wait one second before checking again */
sleep(1);
vgdb_dir = opendir(strlen(vgdb_dir_name) ? vgdb_dir_name : "./");
if (vgdb_dir == NULL)
XERROR(errno,
"vgdb error: opening directory %s searching vgdb fifo\n",
vgdb_dir_name);
errno = 0; /* avoid complain if vgdb_dir is empty */
while ((f = readdir(vgdb_dir))) {
struct stat st;
char pathname[strlen(vgdb_dir_name) + strlen(f->d_name) + 1];
char *wrongpid;
int newpid;
strcpy(pathname, vgdb_dir_name);
strcat(pathname, f->d_name);
DEBUG(3, "checking pathname is FIFO %s\n", pathname);
if (stat(pathname, &st) != 0) {
if (debuglevel >= 3)
ERROR(errno, "vgdb error: stat %s searching vgdb fifo\n",
pathname);
} else if (S_ISFIFO(st.st_mode)) {
DEBUG(3, "trying FIFO %s\n", pathname);
if (strncmp(pathname, vgdb_format,
strlen(vgdb_format)) == 0) {
newpid = strtol(pathname + strlen(vgdb_format),
&wrongpid, 10);
if (*wrongpid == '-' && newpid > 0
&& kill(newpid, 0) == 0) {
nr_valid_pid++;
if (show_list) {
report_pid(newpid, /*on_stdout*/ True);
pid = newpid;
} else if (arg_pid != -1) {
if (arg_pid == newpid) {
pid = newpid;
}
} else if (nr_valid_pid > 1) {
if (nr_valid_pid == 2) {
TSFPRINTF
(stderr,
"no --pid= arg given"
" and multiple valgrind pids found:\n");
report_pid(pid, /*on_stdout*/ False);
}
pid = -2;
report_pid(newpid, /*on_stdout*/ False);
} else {
pid = newpid;
}
}
}
}
errno = 0; /* avoid complain if at the end of vgdb_dir */
}
if (f == NULL && errno != 0)
XERROR(errno, "vgdb error: reading directory %s for vgdb fifo\n",
vgdb_dir_name);
closedir(vgdb_dir);
if (pid != -1)
break;
}
free(vgdb_dir_name);
free(vgdb_format);
}
if (show_list) {
exit(1);
} else if (pid == -1) {
if (arg_pid == -1)
TSFPRINTF(stderr, "vgdb error: no FIFO found and no pid given\n");
else
TSFPRINTF(stderr, "vgdb error: no FIFO found matching pid %d\n",
arg_pid);
exit(1);
}
else if (pid == -2) {
/* no arg_pid given, multiple FIFOs found */
exit(1);
}
else {
return pid;
}
}
/* return true if the numeric value of an option of the
form --xxxxxxxxx=<number> could properly be extracted
from arg. If True is returned, *value contains the
extracted value.*/
static
Bool numeric_val(char* arg, int *value)
{
const char *eq_pos = strchr(arg, '=');
char *wrong;
long long int long_value;
if (eq_pos == NULL)
return False;
long_value = strtoll(eq_pos+1, &wrong, 10);
if (long_value < 0 || long_value > INT_MAX)
return False;
if (*wrong)
return False;
*value = (int) long_value;
return True;
}
/* true if arg matches the provided option */
static
Bool is_opt(char* arg, const char *option)
{
int option_len = strlen(option);
if (option[option_len-1] == '=')
return (0 == strncmp(option, arg, option_len));
else
return (0 == strcmp(option, arg));
}
/* Parse command lines options. If error(s), exits.
Otherwise returns the options in *p_... args.
commands must be big enough for the commands extracted from argv.
On return, *p_last_command gives the position in commands where
the last command has been allocated (using vmalloc). */
static
void parse_options(int argc, char** argv,
Bool *p_show_shared_mem,
Bool *p_show_list,
Bool *p_multi_mode,
int *p_arg_pid,
int *p_check_trials,
int *p_port,
int *p_last_command,
char *commands[])
{
Bool show_shared_mem = False;
Bool show_list = False;
Bool multi_mode = False;
int arg_pid = -1;
int check_trials = 1;
int last_command = -1;
int int_port = 0;
int i;
int arg_errors = 0;
for (i = 1; i < argc; i++) {
if (is_opt(argv[i], "--help") || is_opt(argv[i], "-h")) {
usage();
exit(0);
} else if (is_opt(argv[i], "-d")) {
debuglevel++;
} else if (is_opt(argv[i], "-D")) {
show_shared_mem = True;
} else if (is_opt(argv[i], "-l")) {
show_list = True;
} else if (is_opt(argv[i], "--multi")) {
multi_mode = True;
} else if (is_opt(argv[i], "-T")) {
timestamp = True;
} else if (is_opt(argv[i], "--pid=")) {
int newpid;
if (!numeric_val(argv[i], &newpid)) {
TSFPRINTF(stderr, "invalid --pid argument %s\n", argv[i]);
arg_errors++;
} else if (arg_pid != -1) {
TSFPRINTF(stderr, "multiple --pid arguments given\n");
arg_errors++;
} else {
arg_pid = newpid;
}
} else if (is_opt(argv[i], "--wait=")) {
if (!numeric_val(argv[i], &check_trials)) {
TSFPRINTF(stderr, "invalid --wait argument %s\n", argv[i]);
arg_errors++;
}
} else if (is_opt(argv[i], "--max-invoke-ms=")) {
if (!numeric_val(argv[i], &max_invoke_ms)) {
TSFPRINTF(stderr, "invalid --max-invoke-ms argument %s\n", argv[i]);
arg_errors++;
}
} else if (is_opt(argv[i], "--cmd-time-out=")) {
if (!numeric_val(argv[i], &cmd_time_out)) {
TSFPRINTF(stderr, "invalid --cmd-time-out argument %s\n", argv[i]);
arg_errors++;
}
} else if (is_opt(argv[i], "--port=")) {
if (!numeric_val(argv[i], &int_port)) {
TSFPRINTF(stderr, "invalid --port argument %s\n", argv[i]);
arg_errors++;
}
} else if (is_opt(argv[i], "--vgdb-prefix=")) {
vgdb_prefix = strdup (argv[i] + 14);
} else if (is_opt(argv[i], "--valgrind=")) {
char *path = argv[i] + 11;
/* Compute the absolute path. */
valgrind_path = realpath(path, NULL);
if (!valgrind_path) {
TSFPRINTF(stderr, "%s is not a correct path. %s, exiting.\n", path, strerror (errno));
exit(1);
}
DEBUG(2, "valgrind's real path: %s\n", valgrind_path);
} else if (is_opt(argv[i], "--vargs")) {
// Everything that follows now is an argument for valgrind
// No other options (or commands) can follow
// argc - i is the number of left over arguments
// allocate enough space, but all args in it.
cvargs = argc - i - 1;
vargs = vmalloc (cvargs * sizeof(vargs));
i++;
for (int j = 0; i < argc; i++) {
vargs[j] = argv[i];
j++;
}
} else if (is_opt(argv[i], "-c")) {
last_command++;
commands[last_command] = vmalloc(1);
commands[last_command][0] = '\0';
} else if (0 == strncmp(argv[i], "-", 1)) {
TSFPRINTF(stderr, "unknown or invalid argument %s\n", argv[i]);
arg_errors++;
} else {
int len;
if (last_command == -1) {
/* only one command, no -c command indicator */
last_command++;
commands[last_command] = vmalloc(1);
commands[last_command][0] = '\0';
}
len = strlen(commands[last_command]);
commands[last_command] = vrealloc(commands[last_command],
len + 1 + strlen(argv[i]) + 1);
if (len > 0)
strcat(commands[last_command], " ");
strcat(commands[last_command], argv[i]);
if (packet_len_for_command(commands[last_command]) > PBUFSIZ) {
TSFPRINTF(stderr, "command %s too long\n", commands[last_command]);
arg_errors++;
}
}
}
if (vgdb_prefix == NULL)
vgdb_prefix = vgdb_prefix_default();
if (multi_mode
&& (show_shared_mem
|| show_list
|| last_command != -1)) {
arg_errors++;
TSFPRINTF(stderr,
"Cannot use -D, -l or COMMANDs when using --multi mode\n");
}
if (isatty(0)
&& !show_shared_mem
&& !show_list
&& int_port == 0
&& last_command == -1) {
arg_errors++;
TSFPRINTF(stderr,
"Using vgdb standalone implies to give -D or -l or a COMMAND\n");
}
if (show_shared_mem && show_list) {
arg_errors++;
TSFPRINTF(stderr,
"Can't use both -D and -l options\n");
}
if (max_invoke_ms > 0
&& cmd_time_out != NEVER
&& (cmd_time_out * 1000) <= max_invoke_ms) {
arg_errors++;
TSFPRINTF(stderr,
"--max-invoke-ms must be < --cmd-time-out * 1000\n");
}
if (show_list && arg_pid != -1) {
arg_errors++;
TSFPRINTF(stderr,
"Can't use both --pid and -l options\n");
}
if (int_port > 0 && last_command != -1) {
arg_errors++;
TSFPRINTF(stderr,
"Can't use --port to send commands\n");
}
if (arg_errors > 0) {
TSFPRINTF(stderr, "args error. Try `vgdb --help` for more information\n");
exit(1);
}
*p_show_shared_mem = show_shared_mem;
*p_show_list = show_list;
*p_multi_mode = multi_mode;
*p_arg_pid = arg_pid;
*p_check_trials = check_trials;
*p_port = int_port;
*p_last_command = last_command;
}
int main(int argc, char** argv)
{
int i;
int pid;
Bool show_shared_mem;
Bool show_list;
Bool multi_mode;
int arg_pid;
int check_trials;
int in_port;
int last_command;
char *commands[argc]; // we will never have more commands than args.
parse_options(argc, argv,
&show_shared_mem,
&show_list,
&multi_mode,
&arg_pid,
&check_trials,
&in_port,
&last_command,
commands);
/* when we are working as a relay for gdb, handle some signals by
only reporting them (according to debug level). Also handle these
when ptrace will be used: vgdb must clean up the ptrace effect before
dying. */
if (max_invoke_ms > 0 || last_command == -1)
install_handlers();
if (!multi_mode) {
pid = search_arg_pid(arg_pid, check_trials, show_list);
prepare_fifos_and_shared_mem(pid);
} else {
pid = 0;
}
if (in_port > 0)
wait_for_gdb_connect(in_port);
if (show_shared_mem) {
TSFPRINTF(stderr,
"vgdb %d "
"written_by_vgdb %d "
"seen_by_valgrind %d\n",
VS_vgdb_pid,
VS_written_by_vgdb,
VS_seen_by_valgrind);
TSFPRINTF(stderr, "vgdb pid %d\n", VS_vgdb_pid);
exit(0);
}
if (multi_mode) {
do_multi_mode ();
} else if (last_command >= 0) {
standalone_send_commands(pid, last_command, commands);
} else {
gdb_relay(pid, 0, NULL);
}
free(vgdb_prefix);
free(valgrind_path);
if (!multi_mode)
cleanup_fifos_and_shared_mem();
for (i = 0; i <= last_command; i++)
free(commands[i]);
return 0;
}
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