/* * A simple demo/test program using criu's --inherit-fd command line * option to restore a process with an external unix socket. * Extending inherit's logic to unix sockets created by socketpair(..) syscall. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include typedef void (*sighandler_t)(int); typedef unsigned long ulong; /* colors */ #define CS_PARENT "\033[00;32m" #define CS_CHILD "\033[00;33m" #define CS_DUMP "\033[00;34m" #define CS_RESTORE "\033[00;35m" #define CE "\033[0m" #define die(fmt, ...) do { \ fprintf(stderr, fmt ": %m\n", __VA_ARGS__); \ if (getpid() == parent_pid) { \ (void)kill(0, 9); \ exit(1); \ } \ _exit(1); \ } while (0) #define READ_FD 0 /* pipe read fd */ #define WRITE_FD 1 /* pipe write fd */ #define CLASH_FD 3 /* force inherit fd clash */ #define MAX_FORKS 3 /* child, checkpoint, restore */ #define CRIU_BINARY "../../criu" #define IMG_DIR "images" #define DUMP_LOG_FILE "dump.log" #define RESTORE_LOG_FILE "restore.log" #define RESTORE_PID_FILE "restore.pid" #define INHERIT_FD_OPTION "--inherit-fd" #define OLD_LOG_FILE "/tmp/oldlog" #define NEW_LOG_FILE "/tmp/newlog" /* * Command line options (see usage()). */ char *cli_flags = "hm:nv"; int max_msgs = 10; int vflag; int nflag; char pid_number[8]; char inh_unixsk_opt[16]; char inh_unixsk_arg[64]; char external_sk_ino[32]; char *dump_argv[] = { "criu", "dump", "-D", IMG_DIR, "-o", DUMP_LOG_FILE, "-v4", external_sk_ino, "-t", pid_number, NULL }; char *restore_argv[] = { "criu", "restore", "-d", "-D", IMG_DIR, "-o", RESTORE_LOG_FILE, "--pidfile", RESTORE_PID_FILE, "-v4", "-x", inh_unixsk_opt, inh_unixsk_arg, NULL }; int max_forks; int parent_pid; int child_pid; int criu_dump_pid; int criu_restore_pid; /* prototypes */ void chld_handler(int signum); int parent(int *socketfd, const char *ino_child_sk); int child(int *socketfd, int dupfd, int newfd); void checkpoint_child(int child_pid, int *old_socket_namefd); void restore_child(int *new_socketfd, const char *old_socket_name); void write_to_fd(int fd, char *name, int i, int newline); void ls_proc_fd(int fd); char *socket_name(int fd); ino_t socket_inode(int fd); char *who(pid_t pid); void socketpair_safe(int socketfd[2]); pid_t fork_safe(void); void signal_safe(int signum, sighandler_t handler); int open_safe(char *pathname, int flags); void close_safe(int fd); void write_safe(int fd, char *buf, int count); int read_safe(int fd, char *buf, int count); int dup_safe(int oldfd); void move_fd(int oldfd, int newfd); void mkdir_safe(char *dirname, int mode); void unlink_safe(char *pathname); void execv_safe(char *path, char *argv[], int ls); pid_t waitpid_safe(pid_t pid, int *status, int options, int id); void prctl_safe(int option, ulong arg2, ulong arg3, ulong arg4, ulong arg5); int dup2_safe(int oldfd, int newfd); void usage(char *cmd) { printf("Usage: %s [%s]\n", cmd, cli_flags); printf("-h\tprint this help and exit\n"); printf("-m\tcount of send messages (by default 10 will send from child) \n"); printf("-n\tdo not use the %s option\n", INHERIT_FD_OPTION); printf("-v\tverbose mode (list contents of /proc//fd)\n"); } int main(int argc, char *argv[]) { int ret; int opt; int socketfd[2]; while ((opt = getopt(argc, argv, cli_flags)) != -1) { switch (opt) { case 'h': usage(argv[0]); return 0; case 'm': max_msgs = atoi(optarg); break; case 'n': nflag++; break; case 'v': vflag++; break; case '?': if ('m' == optopt) fprintf (stderr, "Option -%c requires an argument.\n", optopt); else fprintf ( stderr, "Unknown option character `\\x%x'.\n", optopt); return 1; default: usage(argv[0]); return 1; } } setbuf(stdout, NULL); setbuf(stderr, NULL); mkdir_safe(IMG_DIR, 0700); socketpair_safe(socketfd); child_pid = fork_safe(); if (child_pid > 0) { parent_pid = getpid(); signal_safe(SIGCHLD, chld_handler); prctl_safe(PR_SET_CHILD_SUBREAPER, 1, 0, 0, 0); snprintf(external_sk_ino, sizeof(external_sk_ino), "--ext-unix-sk=%u", (unsigned int)socket_inode(socketfd[WRITE_FD])); char unix_sk_ino[32] = {0}; strcpy(unix_sk_ino, socket_name(socketfd[WRITE_FD])); close_safe(socketfd[WRITE_FD]); ret = parent(socketfd, unix_sk_ino); } else { /* child */ int dupfd = -1; int openfd = -1; int logfd; child_pid = getpid(); close_safe(socketfd[READ_FD]); setsid(); logfd = open_safe(OLD_LOG_FILE, O_WRONLY | O_APPEND | O_CREAT); dup2_safe(logfd, 1); dup2_safe(logfd, 2); close(logfd); close(0); ret = child(socketfd, dupfd, openfd); } return ret; } /* * Parent reads message from its pipe with the child. * After a couple of messages, it checkpoints the child * which causes the child to exit. Parent then creates * a new pipe and restores the child. */ int parent(int *socketfd, const char *ino_child_sk) { char buf[32]; int nread; nread = 0; while (max_forks <= MAX_FORKS) { if (read_safe(socketfd[READ_FD], buf, sizeof buf) == 0) continue; nread++; if (vflag && nread == 1) ls_proc_fd(-1); printf( "%s read %s from %s\n", who(0), buf, socket_name(socketfd[READ_FD])); if (nread == (max_msgs / 2)) { checkpoint_child(child_pid, socketfd); if (!nflag) { close_safe(socketfd[READ_FD]); /* create a new one */ printf("%s creating a new socket\n", who(0)); socketpair_safe(socketfd); } restore_child(socketfd, ino_child_sk); } } return 0; } /* * Child sends a total of max_messages messages to its * parent, half before checkpoint and half after restore. */ int child(int *socketfd, int dupfd, int openfd) { int i; int fd; int num_wfds; struct timespec req = { 1, 0 }; /* * Count the number of pipe descriptors we'll be * writing to. At least 1 (for socketfd[WRITE_FD]) * and at most 3. */ num_wfds = 1; if (dupfd >= 0) num_wfds++; if (openfd >= 0) num_wfds++; for (i = 0; i < max_msgs; i++) { /* print first time and after checkpoint */ if (vflag && (i == 0 || i == (max_msgs / 2))) ls_proc_fd(-1); switch (i % num_wfds) { case 0: fd = socketfd[WRITE_FD]; break; case 1: fd = openfd; break; case 2: fd = openfd; break; } write_to_fd(fd, socket_name(socketfd[WRITE_FD]), i+1, 0); /* * Since sleep will be interrupted by C/R, make sure * to sleep an entire second to minimize the chance of * writing before criu restore has exited. If criu is * still around and we write to a broken pipe, we'll be * killed but SIGCHLD will be delivered to criu instead * of parent. */ while (nanosleep(&req, NULL)) ; printf("\n"); } return 0; } void chld_handler(int signum) { int status; pid_t pid; pid = waitpid_safe(-1, &status, WNOHANG, 1); if (WIFEXITED(status)) status = WEXITSTATUS(status); if (pid == child_pid) { printf("%s %s exited with status %d\n", who(0), who(pid), status); /* if child exited successfully, we're done */ if (status == 0) exit(0); /* checkpoint kills the child */ if (status != 9) exit(status); } } void checkpoint_child(int child_pid, int *socketfd) { /* prepare -t */ snprintf(pid_number, sizeof pid_number, "%d", child_pid); criu_dump_pid = fork_safe(); if (criu_dump_pid > 0) { int status; pid_t pid; pid = waitpid_safe(criu_dump_pid, &status, 0, 2); if (WIFEXITED(status)) status = WEXITSTATUS(status); printf("%s %s exited with status %d\n", who(0), who(pid), status); if (status) exit(status); } else { close(socketfd[READ_FD]); criu_dump_pid = getpid(); execv_safe(CRIU_BINARY, dump_argv, 0); } } void restore_child(int *new_socketfd, const char *old_sock_name) { char buf[64]; criu_restore_pid = fork_safe(); if (criu_restore_pid > 0) { int status; pid_t pid; if (!nflag) close_safe(new_socketfd[WRITE_FD]); pid = waitpid_safe(criu_restore_pid, &status, 0, 3); if (WIFEXITED(status)) status = WEXITSTATUS(status); printf("%s %s exited with status %d\n", who(0), who(pid), status); if (status) exit(status); } else { criu_restore_pid = getpid(); if (!nflag) { close_safe(new_socketfd[READ_FD]); move_fd(new_socketfd[WRITE_FD], CLASH_FD); /* --inherit-fd fd[CLASH_FD]:socket[xxxxxx] */ snprintf(inh_unixsk_opt, sizeof inh_unixsk_opt, "%s", INHERIT_FD_OPTION); snprintf(inh_unixsk_arg, sizeof inh_unixsk_arg, "fd[%d]:%s", CLASH_FD, old_sock_name); restore_argv[11] = inh_unixsk_opt; restore_argv[13] = NULL; } else restore_argv[11] = NULL; snprintf(buf, sizeof buf, "%s/%s", IMG_DIR, RESTORE_PID_FILE); unlink_safe(buf); execv_safe(CRIU_BINARY, restore_argv, 1); } } void write_to_fd(int fd, char *name, int i, int newline) { int n; char buf[16]; /* fit "hello d\n" for small d */ n = snprintf(buf, sizeof buf, "hello %d", i); printf("%s writing %s to %s via fd %d\n", who(0), buf, name, fd); if (newline) { buf[n++] = '\n'; buf[n] = '\0'; } write_safe(fd, buf, strlen(buf)); } void ls_proc_fd(int fd) { char cmd[128]; if (fd == -1) snprintf(cmd, sizeof cmd, "ls -l /proc/%d/fd", getpid()); else snprintf(cmd, sizeof cmd, "ls -l /proc/%d/fd/%d", getpid(), fd); printf("%s %s\n", who(0), cmd); system(cmd); } char *socket_name(int fd) { static char sock_name[64]; char path[64]; snprintf(path, sizeof path, "/proc/self/fd/%d", fd); if (readlink(path, sock_name, sizeof sock_name) == -1) die("readlink: path=%s", path); return sock_name; } ino_t socket_inode(int fd) { struct stat sbuf; if (fstat(fd, &sbuf) == -1) die("fstat: fd=%i", fd); return sbuf.st_ino; } /* * Use two buffers to support two calls to * this function in a printf argument list. */ char *who(pid_t pid) { static char pidstr1[64]; static char pidstr2[64]; static char *cp; char *np; char *ep; int p; p = pid ? pid : getpid(); if (p == parent_pid) { np = "parent"; ep = CS_PARENT; } else if (p == child_pid) { np = "child"; ep = CS_CHILD; } else if (p == criu_dump_pid) { np = "dump"; ep = CS_DUMP; } else if (p == criu_restore_pid) { np = "restore"; ep = CS_RESTORE; } else np = "???"; cp = (cp == pidstr1) ? pidstr2 : pidstr1; snprintf(cp, sizeof pidstr1, "%s[%s %d]", pid ? "" : ep, np, p); return cp; } void socketpair_safe(int socketfd[2]) { if (socketpair(AF_UNIX, SOCK_STREAM, 0, socketfd) == -1) die("socketpair %p", socketfd); } pid_t fork_safe(void) { pid_t pid; if ((pid = fork()) == -1) die("fork: pid=%d", pid); max_forks++; return pid; } void signal_safe(int signum, sighandler_t handler) { if (signal(signum, handler) == SIG_ERR) die("signal: signum=%d", signum); } int open_safe(char *pathname, int flags) { int fd; if ((fd = open(pathname, flags, 0777)) == -1) die("open: pathname=%s", pathname); return fd; } void close_safe(int fd) { if (close(fd) == -1) die("close: fd=%d", fd); } void write_safe(int fd, char *buf, int count) { if (write(fd, buf, count) != count) { die("write: fd=%d buf=\"%s\" count=%d errno=%d", fd, buf, count, errno); } } int read_safe(int fd, char *buf, int count) { int n; if ((n = read(fd, buf, count)) < 0) die("read: fd=%d count=%d", fd, count); buf[n] = '\0'; return n; } int dup_safe(int oldfd) { int newfd; if ((newfd = dup(oldfd)) == -1) die("dup: oldfd=%d", oldfd); return newfd; } int dup2_safe(int oldfd, int newfd) { if (dup2(oldfd, newfd) != newfd) die("dup2: oldfd=%d newfd=%d", oldfd, newfd); return newfd; } void move_fd(int oldfd, int newfd) { if (oldfd != newfd) { dup2_safe(oldfd, newfd); close_safe(oldfd); } } void mkdir_safe(char *dirname, int mode) { if (mkdir(dirname, mode) == -1 && errno != EEXIST) die("mkdir dirname=%s mode=0x%x\n", dirname, mode); } void unlink_safe(char *pathname) { if (unlink(pathname) == -1 && errno != ENOENT) { die("unlink: pathname=%s\n", pathname); } } void execv_safe(char *path, char *argv[], int ls) { int i; struct timespec req = { 0, 1000000 }; printf("\n%s ", who(0)); for (i = 0; argv[i] != NULL; i++) printf("%s ", argv[i]); printf("\n"); /* give parent a chance to wait for us */ while (nanosleep(&req, NULL)) ; if (vflag && ls) ls_proc_fd(-1); execv(path, argv); die("execv: path=%s", path); } pid_t waitpid_safe(pid_t pid, int *status, int options, int id) { pid_t p; p = waitpid(pid, status, options); if (p == -1) fprintf(stderr, "waitpid pid=%d id=%d %m\n", pid, id); return p; } void prctl_safe(int option, ulong arg2, ulong arg3, ulong arg4, ulong arg5) { if (prctl(option, arg2, arg3, arg4, arg5) == -1) die("prctl: option=0x%x", option); }