/* Machine independent support for QNX Neutrino /proc (process file system) for GDB. Written by Colin Burgess at QNX Software Systems Limited. Copyright (C) 2003-2018 Free Software Foundation, Inc. Contributed by QNX Software Systems Ltd. This file is part of GDB. 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 3 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 . */ #include "defs.h" #include #include #include #include #include #include #include #include #include #include "gdbcore.h" #include "inferior.h" #include "target.h" #include "objfiles.h" #include "gdbthread.h" #include "nto-tdep.h" #include "command.h" #include "regcache.h" #include "solib.h" #include "inf-child.h" #include "common/filestuff.h" #include "common/scoped_fd.h" #define NULL_PID 0 #define _DEBUG_FLAG_TRACE (_DEBUG_FLAG_TRACE_EXEC|_DEBUG_FLAG_TRACE_RD|\ _DEBUG_FLAG_TRACE_WR|_DEBUG_FLAG_TRACE_MODIFY) int ctl_fd; static sighandler_t ofunc; static procfs_run run; /* Create the "native" and "procfs" targets. */ struct nto_procfs_target : public inf_child_target { void open (const char *arg, int from_tty) override; void attach (const char *, int) override = 0; void post_attach (int); void detach (inferior *, int) override; void resume (ptid_t, int, enum gdb_signal) override; ptid_t wait (ptid_t, struct target_waitstatus *, int) override; void fetch_registers (struct regcache *, int) override; void store_registers (struct regcache *, int) override; enum target_xfer_status xfer_partial (enum target_object object, const char *annex, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, ULONGEST len, ULONGEST *xfered_len) override; void files_info () override; int insert_breakpoint (struct gdbarch *, struct bp_target_info *) override; int remove_breakpoint (struct gdbarch *, struct bp_target_info *, enum remove_bp_reason) override; int can_use_hw_breakpoint (enum bptype, int, int) override; int insert_hw_breakpoint (struct gdbarch *, struct bp_target_info *) override; int remove_hw_breakpoint (struct gdbarch *, struct bp_target_info *) override; int insert_watchpoint (CORE_ADDR, int, enum target_hw_bp_type, struct expression *) override; int remove_watchpoint (CORE_ADDR, int, enum target_hw_bp_type, struct expression *) override; bool stopped_by_watchpoint () override; void kill () override; void create_inferior (const char *, const std::string &, char **, int) override; void mourn_inferior () override; void pass_signals (int, unsigned char *) override; bool thread_alive (ptid_t ptid) override; void update_thread_list () override; const char *pid_to_str (ptid_t) override; void interrupt () override; const char *extra_thread_info (struct thread_info *) override; char *pid_to_exec_file (int pid) override; }; /* For "target native". */ static const target_info nto_native_target_info = { "native", N_("QNX Neutrino local process"), N_("QNX Neutrino local process (started by the \"run\" command).") }; class nto_procfs_target_native final : public nto_procfs_target { const target_info &info () const override { return nto_native_target_info; } }; /* For "target procfs ". */ static const target_info nto_procfs_target_info = { "procfs", N_("QNX Neutrino local or remote process"), N_("QNX Neutrino process. target procfs ") }; struct nto_procfs_target_procfs final : public nto_procfs_target { const target_info &info () const override { return nto_procfs_target_info; } }; static ptid_t do_attach (ptid_t ptid); /* These two globals are only ever set in procfs_open_1, but are referenced elsewhere. 'nto_procfs_node' is a flag used to say whether we are local, or we should get the current node descriptor for the remote QNX node. */ static char *nodestr; static unsigned nto_procfs_node = ND_LOCAL_NODE; /* Return the current QNX Node, or error out. This is a simple wrapper for the netmgr_strtond() function. The reason this is required is because QNX node descriptors are transient so we have to re-acquire them every time. */ static unsigned nto_node (void) { unsigned node; if (ND_NODE_CMP (nto_procfs_node, ND_LOCAL_NODE) == 0 || nodestr == NULL) return ND_LOCAL_NODE; node = netmgr_strtond (nodestr, 0); if (node == -1) error (_("Lost the QNX node. Debug session probably over.")); return (node); } static enum gdb_osabi procfs_is_nto_target (bfd *abfd) { return GDB_OSABI_QNXNTO; } /* This is called when we call 'target native' or 'target procfs ' from the (gdb) prompt. For QNX6 (nto), the only valid arg will be a QNX node string, eg: "/net/some_node". If arg is not a valid QNX node, we will default to local. */ void nto_procfs_target::open (const char *arg, int from_tty) { char *endstr; char buffer[50]; int total_size; procfs_sysinfo *sysinfo; char nto_procfs_path[PATH_MAX]; /* Offer to kill previous inferiors before opening this target. */ target_preopen (from_tty); nto_is_nto_target = procfs_is_nto_target; /* Set the default node used for spawning to this one, and only override it if there is a valid arg. */ xfree (nodestr); nodestr = NULL; nto_procfs_node = ND_LOCAL_NODE; nodestr = (arg != NULL) ? xstrdup (arg) : NULL; init_thread_list (); if (nodestr) { nto_procfs_node = netmgr_strtond (nodestr, &endstr); if (nto_procfs_node == -1) { if (errno == ENOTSUP) printf_filtered ("QNX Net Manager not found.\n"); printf_filtered ("Invalid QNX node %s: error %d (%s).\n", nodestr, errno, safe_strerror (errno)); xfree (nodestr); nodestr = NULL; nto_procfs_node = ND_LOCAL_NODE; } else if (*endstr) { if (*(endstr - 1) == '/') *(endstr - 1) = 0; else *endstr = 0; } } snprintf (nto_procfs_path, PATH_MAX - 1, "%s%s", (nodestr != NULL) ? nodestr : "", "/proc"); scoped_fd fd (open (nto_procfs_path, O_RDONLY)); if (fd.get () == -1) { printf_filtered ("Error opening %s : %d (%s)\n", nto_procfs_path, errno, safe_strerror (errno)); error (_("Invalid procfs arg")); } sysinfo = (void *) buffer; if (devctl (fd.get (), DCMD_PROC_SYSINFO, sysinfo, sizeof buffer, 0) != EOK) { printf_filtered ("Error getting size: %d (%s)\n", errno, safe_strerror (errno)); error (_("Devctl failed.")); } else { total_size = sysinfo->total_size; sysinfo = alloca (total_size); if (sysinfo == NULL) { printf_filtered ("Memory error: %d (%s)\n", errno, safe_strerror (errno)); error (_("alloca failed.")); } else { if (devctl (fd.get (), DCMD_PROC_SYSINFO, sysinfo, total_size, 0) != EOK) { printf_filtered ("Error getting sysinfo: %d (%s)\n", errno, safe_strerror (errno)); error (_("Devctl failed.")); } else { if (sysinfo->type != nto_map_arch_to_cputype (gdbarch_bfd_arch_info (target_gdbarch ())->arch_name)) error (_("Invalid target CPU.")); } } } inf_child_target::open (arg, from_tty); printf_filtered ("Debugging using %s\n", nto_procfs_path); } static void procfs_set_thread (ptid_t ptid) { pid_t tid; tid = ptid.tid (); devctl (ctl_fd, DCMD_PROC_CURTHREAD, &tid, sizeof (tid), 0); } /* Return true if the thread TH is still alive. */ bool nto_procfs_target::thread_alive (ptid_t ptid) { pid_t tid; pid_t pid; procfs_status status; int err; tid = ptid.tid (); pid = ptid.pid (); if (kill (pid, 0) == -1) return false; status.tid = tid; if ((err = devctl (ctl_fd, DCMD_PROC_TIDSTATUS, &status, sizeof (status), 0)) != EOK) return false; /* Thread is alive or dead but not yet joined, or dead and there is an alive (or dead unjoined) thread with higher tid. If the tid is not the same as requested, requested tid is dead. */ return (status.tid == tid) && (status.state != STATE_DEAD); } static void update_thread_private_data_name (struct thread_info *new_thread, const char *newname) { nto_thread_info *pti = get_nto_thread_info (new_thread); gdb_assert (newname != NULL); gdb_assert (new_thread != NULL); if (pti) { pti = new nto_thread_info; new_thread->priv.reset (pti); } pti->name = newname; } static void update_thread_private_data (struct thread_info *new_thread, pthread_t tid, int state, int flags) { procfs_info pidinfo; struct _thread_name *tn; procfs_threadctl tctl; #if _NTO_VERSION > 630 gdb_assert (new_thread != NULL); if (devctl (ctl_fd, DCMD_PROC_INFO, &pidinfo, sizeof(pidinfo), 0) != EOK) return; memset (&tctl, 0, sizeof (tctl)); tctl.cmd = _NTO_TCTL_NAME; tn = (struct _thread_name *) (&tctl.data); /* Fetch name for the given thread. */ tctl.tid = tid; tn->name_buf_len = sizeof (tctl.data) - sizeof (*tn); tn->new_name_len = -1; /* Getting, not setting. */ if (devctl (ctl_fd, DCMD_PROC_THREADCTL, &tctl, sizeof (tctl), NULL) != EOK) tn->name_buf[0] = '\0'; tn->name_buf[_NTO_THREAD_NAME_MAX] = '\0'; update_thread_private_data_name (new_thread, tn->name_buf); nto_thread_info *pti = get_nto_thread_info (new_thread); pti->tid = tid; pti->state = state; pti->flags = flags; #endif /* _NTO_VERSION */ } void nto_procfs_target::update_thread_list () { procfs_status status; pid_t pid; ptid_t ptid; pthread_t tid; struct thread_info *new_thread; if (ctl_fd == -1) return; prune_threads (); pid = inferior_ptid.pid (); status.tid = 1; for (tid = 1;; ++tid) { if (status.tid == tid && (devctl (ctl_fd, DCMD_PROC_TIDSTATUS, &status, sizeof (status), 0) != EOK)) break; if (status.tid != tid) /* The reason why this would not be equal is that devctl might have returned different tid, meaning the requested tid no longer exists (e.g. thread exited). */ continue; ptid = ptid_t (pid, 0, tid); new_thread = find_thread_ptid (ptid); if (!new_thread) new_thread = add_thread (ptid); update_thread_private_data (new_thread, tid, status.state, 0); status.tid++; } return; } static void procfs_pidlist (const char *args, int from_tty) { struct dirent *dirp = NULL; char buf[PATH_MAX]; procfs_info *pidinfo = NULL; procfs_debuginfo *info = NULL; procfs_status *status = NULL; pid_t num_threads = 0; pid_t pid; char name[512]; char procfs_dir[PATH_MAX]; snprintf (procfs_dir, sizeof (procfs_dir), "%s%s", (nodestr != NULL) ? nodestr : "", "/proc"); gdb_dir_up dp (opendir (procfs_dir)); if (dp == NULL) { fprintf_unfiltered (gdb_stderr, "failed to opendir \"%s\" - %d (%s)", procfs_dir, errno, safe_strerror (errno)); return; } /* Start scan at first pid. */ rewinddir (dp.get ()); do { /* Get the right pid and procfs path for the pid. */ do { dirp = readdir (dp.get ()); if (dirp == NULL) return; snprintf (buf, sizeof (buf), "%s%s/%s/as", (nodestr != NULL) ? nodestr : "", "/proc", dirp->d_name); pid = atoi (dirp->d_name); } while (pid == 0); /* Open the procfs path. */ scoped_fd fd (open (buf, O_RDONLY)); if (fd.get () == -1) { fprintf_unfiltered (gdb_stderr, "failed to open %s - %d (%s)\n", buf, errno, safe_strerror (errno)); continue; } pidinfo = (procfs_info *) buf; if (devctl (fd.get (), DCMD_PROC_INFO, pidinfo, sizeof (buf), 0) != EOK) { fprintf_unfiltered (gdb_stderr, "devctl DCMD_PROC_INFO failed - %d (%s)\n", errno, safe_strerror (errno)); break; } num_threads = pidinfo->num_threads; info = (procfs_debuginfo *) buf; if (devctl (fd.get (), DCMD_PROC_MAPDEBUG_BASE, info, sizeof (buf), 0) != EOK) strcpy (name, "unavailable"); else strcpy (name, info->path); /* Collect state info on all the threads. */ status = (procfs_status *) buf; for (status->tid = 1; status->tid <= num_threads; status->tid++) { const int err = devctl (fd.get (), DCMD_PROC_TIDSTATUS, status, sizeof (buf), 0); printf_filtered ("%s - %d", name, pid); if (err == EOK && status->tid != 0) printf_filtered ("/%d\n", status->tid); else { printf_filtered ("\n"); break; } } } while (dirp != NULL); } static void procfs_meminfo (const char *args, int from_tty) { procfs_mapinfo *mapinfos = NULL; static int num_mapinfos = 0; procfs_mapinfo *mapinfo_p, *mapinfo_p2; int flags = ~0, err, num, i, j; struct { procfs_debuginfo info; char buff[_POSIX_PATH_MAX]; } map; struct info { unsigned addr; unsigned size; unsigned flags; unsigned debug_vaddr; unsigned long long offset; }; struct printinfo { unsigned long long ino; unsigned dev; struct info text; struct info data; char name[256]; } printme; /* Get the number of map entrys. */ err = devctl (ctl_fd, DCMD_PROC_MAPINFO, NULL, 0, &num); if (err != EOK) { printf ("failed devctl num mapinfos - %d (%s)\n", err, safe_strerror (err)); return; } mapinfos = XNEWVEC (procfs_mapinfo, num); num_mapinfos = num; mapinfo_p = mapinfos; /* Fill the map entrys. */ err = devctl (ctl_fd, DCMD_PROC_MAPINFO, mapinfo_p, num * sizeof (procfs_mapinfo), &num); if (err != EOK) { printf ("failed devctl mapinfos - %d (%s)\n", err, safe_strerror (err)); xfree (mapinfos); return; } num = std::min (num, num_mapinfos); /* Run through the list of mapinfos, and store the data and text info so we can print it at the bottom of the loop. */ for (mapinfo_p = mapinfos, i = 0; i < num; i++, mapinfo_p++) { if (!(mapinfo_p->flags & flags)) mapinfo_p->ino = 0; if (mapinfo_p->ino == 0) /* Already visited. */ continue; map.info.vaddr = mapinfo_p->vaddr; err = devctl (ctl_fd, DCMD_PROC_MAPDEBUG, &map, sizeof (map), 0); if (err != EOK) continue; memset (&printme, 0, sizeof printme); printme.dev = mapinfo_p->dev; printme.ino = mapinfo_p->ino; printme.text.addr = mapinfo_p->vaddr; printme.text.size = mapinfo_p->size; printme.text.flags = mapinfo_p->flags; printme.text.offset = mapinfo_p->offset; printme.text.debug_vaddr = map.info.vaddr; strcpy (printme.name, map.info.path); /* Check for matching data. */ for (mapinfo_p2 = mapinfos, j = 0; j < num; j++, mapinfo_p2++) { if (mapinfo_p2->vaddr != mapinfo_p->vaddr && mapinfo_p2->ino == mapinfo_p->ino && mapinfo_p2->dev == mapinfo_p->dev) { map.info.vaddr = mapinfo_p2->vaddr; err = devctl (ctl_fd, DCMD_PROC_MAPDEBUG, &map, sizeof (map), 0); if (err != EOK) continue; if (strcmp (map.info.path, printme.name)) continue; /* Lower debug_vaddr is always text, if nessessary, swap. */ if ((int) map.info.vaddr < (int) printme.text.debug_vaddr) { memcpy (&(printme.data), &(printme.text), sizeof (printme.data)); printme.text.addr = mapinfo_p2->vaddr; printme.text.size = mapinfo_p2->size; printme.text.flags = mapinfo_p2->flags; printme.text.offset = mapinfo_p2->offset; printme.text.debug_vaddr = map.info.vaddr; } else { printme.data.addr = mapinfo_p2->vaddr; printme.data.size = mapinfo_p2->size; printme.data.flags = mapinfo_p2->flags; printme.data.offset = mapinfo_p2->offset; printme.data.debug_vaddr = map.info.vaddr; } mapinfo_p2->ino = 0; } } mapinfo_p->ino = 0; printf_filtered ("%s\n", printme.name); printf_filtered ("\ttext=%08x bytes @ 0x%08x\n", printme.text.size, printme.text.addr); printf_filtered ("\t\tflags=%08x\n", printme.text.flags); printf_filtered ("\t\tdebug=%08x\n", printme.text.debug_vaddr); printf_filtered ("\t\toffset=%s\n", phex (printme.text.offset, 8)); if (printme.data.size) { printf_filtered ("\tdata=%08x bytes @ 0x%08x\n", printme.data.size, printme.data.addr); printf_filtered ("\t\tflags=%08x\n", printme.data.flags); printf_filtered ("\t\tdebug=%08x\n", printme.data.debug_vaddr); printf_filtered ("\t\toffset=%s\n", phex (printme.data.offset, 8)); } printf_filtered ("\tdev=0x%x\n", printme.dev); printf_filtered ("\tino=0x%x\n", (unsigned int) printme.ino); } xfree (mapinfos); return; } /* Print status information about what we're accessing. */ void nto_procfs_target::files_info () { struct inferior *inf = current_inferior (); printf_unfiltered ("\tUsing the running image of %s %s via %s.\n", inf->attach_flag ? "attached" : "child", target_pid_to_str (inferior_ptid), (nodestr != NULL) ? nodestr : "local node"); } /* Target to_pid_to_exec_file implementation. */ char * nto_procfs_target::pid_to_exec_file (const int pid) { int proc_fd; static char proc_path[PATH_MAX]; ssize_t rd; /* Read exe file name. */ snprintf (proc_path, sizeof (proc_path), "%s/proc/%d/exefile", (nodestr != NULL) ? nodestr : "", pid); proc_fd = open (proc_path, O_RDONLY); if (proc_fd == -1) return NULL; rd = read (proc_fd, proc_path, sizeof (proc_path) - 1); close (proc_fd); if (rd <= 0) { proc_path[0] = '\0'; return NULL; } proc_path[rd] = '\0'; return proc_path; } /* Attach to process PID, then initialize for debugging it. */ void nto_procfs_target::attach (const char *args, int from_tty) { char *exec_file; int pid; struct inferior *inf; pid = parse_pid_to_attach (args); if (pid == getpid ()) error (_("Attaching GDB to itself is not a good idea...")); if (from_tty) { exec_file = (char *) get_exec_file (0); if (exec_file) printf_unfiltered ("Attaching to program `%s', %s\n", exec_file, target_pid_to_str (ptid_t (pid))); else printf_unfiltered ("Attaching to %s\n", target_pid_to_str (ptid_t (pid))); gdb_flush (gdb_stdout); } inferior_ptid = do_attach (ptid_t (pid)); inf = current_inferior (); inferior_appeared (inf, pid); inf->attach_flag = 1; if (!target_is_pushed (ops)) push_target (ops); procfs_update_thread_list (ops); } void nto_procfs_target::post_attach (pid_t pid) { if (exec_bfd) solib_create_inferior_hook (0); } static ptid_t do_attach (ptid_t ptid) { procfs_status status; struct sigevent event; char path[PATH_MAX]; snprintf (path, PATH_MAX - 1, "%s%s/%d/as", (nodestr != NULL) ? nodestr : "", "/proc", ptid.pid ()); ctl_fd = open (path, O_RDWR); if (ctl_fd == -1) error (_("Couldn't open proc file %s, error %d (%s)"), path, errno, safe_strerror (errno)); if (devctl (ctl_fd, DCMD_PROC_STOP, &status, sizeof (status), 0) != EOK) error (_("Couldn't stop process")); /* Define a sigevent for process stopped notification. */ event.sigev_notify = SIGEV_SIGNAL_THREAD; event.sigev_signo = SIGUSR1; event.sigev_code = 0; event.sigev_value.sival_ptr = NULL; event.sigev_priority = -1; devctl (ctl_fd, DCMD_PROC_EVENT, &event, sizeof (event), 0); if (devctl (ctl_fd, DCMD_PROC_STATUS, &status, sizeof (status), 0) == EOK && status.flags & _DEBUG_FLAG_STOPPED) SignalKill (nto_node (), ptid.pid (), 0, SIGCONT, 0, 0); nto_init_solib_absolute_prefix (); return ptid_t (ptid.pid (), 0, status.tid); } /* Ask the user what to do when an interrupt is received. */ static void interrupt_query (void) { if (query (_("Interrupted while waiting for the program.\n\ Give up (and stop debugging it)? "))) { target_mourn_inferior (inferior_ptid); quit (); } } /* The user typed ^C twice. */ static void nto_handle_sigint_twice (int signo) { signal (signo, ofunc); interrupt_query (); signal (signo, nto_handle_sigint_twice); } static void nto_handle_sigint (int signo) { /* If this doesn't work, try more severe steps. */ signal (signo, nto_handle_sigint_twice); target_interrupt (); } sptid_t nto_procfs_target::wait (ptid_t ptid, struct target_waitstatus *ourstatus, int options) { sigset_t set; siginfo_t info; procfs_status status; static int exit_signo = 0; /* To track signals that cause termination. */ ourstatus->kind = TARGET_WAITKIND_SPURIOUS; if (inferior_ptid == null_ptid) { ourstatus->kind = TARGET_WAITKIND_STOPPED; ourstatus->value.sig = GDB_SIGNAL_0; exit_signo = 0; return null_ptid; } sigemptyset (&set); sigaddset (&set, SIGUSR1); devctl (ctl_fd, DCMD_PROC_STATUS, &status, sizeof (status), 0); while (!(status.flags & _DEBUG_FLAG_ISTOP)) { ofunc = signal (SIGINT, nto_handle_sigint); sigwaitinfo (&set, &info); signal (SIGINT, ofunc); devctl (ctl_fd, DCMD_PROC_STATUS, &status, sizeof (status), 0); } nto_inferior_data (NULL)->stopped_flags = status.flags; nto_inferior_data (NULL)->stopped_pc = status.ip; if (status.flags & _DEBUG_FLAG_SSTEP) { ourstatus->kind = TARGET_WAITKIND_STOPPED; ourstatus->value.sig = GDB_SIGNAL_TRAP; } /* Was it a breakpoint? */ else if (status.flags & _DEBUG_FLAG_TRACE) { ourstatus->kind = TARGET_WAITKIND_STOPPED; ourstatus->value.sig = GDB_SIGNAL_TRAP; } else if (status.flags & _DEBUG_FLAG_ISTOP) { switch (status.why) { case _DEBUG_WHY_SIGNALLED: ourstatus->kind = TARGET_WAITKIND_STOPPED; ourstatus->value.sig = gdb_signal_from_host (status.info.si_signo); exit_signo = 0; break; case _DEBUG_WHY_FAULTED: ourstatus->kind = TARGET_WAITKIND_STOPPED; if (status.info.si_signo == SIGTRAP) { ourstatus->value.sig = 0; exit_signo = 0; } else { ourstatus->value.sig = gdb_signal_from_host (status.info.si_signo); exit_signo = ourstatus->value.sig; } break; case _DEBUG_WHY_TERMINATED: { int waitval = 0; waitpid (inferior_ptid.pid (), &waitval, WNOHANG); if (exit_signo) { /* Abnormal death. */ ourstatus->kind = TARGET_WAITKIND_SIGNALLED; ourstatus->value.sig = exit_signo; } else { /* Normal death. */ ourstatus->kind = TARGET_WAITKIND_EXITED; ourstatus->value.integer = WEXITSTATUS (waitval); } exit_signo = 0; break; } case _DEBUG_WHY_REQUESTED: /* We are assuming a requested stop is due to a SIGINT. */ ourstatus->kind = TARGET_WAITKIND_STOPPED; ourstatus->value.sig = GDB_SIGNAL_INT; exit_signo = 0; break; } } return ptid_t (status.pid, 0, status.tid); } /* Read the current values of the inferior's registers, both the general register set and floating point registers (if supported) and update gdb's idea of their current values. */ void nto_procfs_target::fetch_registers (struct regcache *regcache, int regno) { union { procfs_greg greg; procfs_fpreg fpreg; procfs_altreg altreg; } reg; int regsize; procfs_set_thread (regcache->ptid ()); if (devctl (ctl_fd, DCMD_PROC_GETGREG, ®, sizeof (reg), ®size) == EOK) nto_supply_gregset (regcache, (char *) ®.greg); if (devctl (ctl_fd, DCMD_PROC_GETFPREG, ®, sizeof (reg), ®size) == EOK) nto_supply_fpregset (regcache, (char *) ®.fpreg); if (devctl (ctl_fd, DCMD_PROC_GETALTREG, ®, sizeof (reg), ®size) == EOK) nto_supply_altregset (regcache, (char *) ®.altreg); } /* Helper for procfs_xfer_partial that handles memory transfers. Arguments are like target_xfer_partial. */ static enum target_xfer_status procfs_xfer_memory (gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST memaddr, ULONGEST len, ULONGEST *xfered_len) { int nbytes; if (lseek (ctl_fd, (off_t) memaddr, SEEK_SET) != (off_t) memaddr) return TARGET_XFER_E_IO; if (writebuf != NULL) nbytes = write (ctl_fd, writebuf, len); else nbytes = read (ctl_fd, readbuf, len); if (nbytes <= 0) return TARGET_XFER_E_IO; *xfered_len = nbytes; return TARGET_XFER_OK; } /* Target to_xfer_partial implementation. */ enum target_xfer_status nto_procfs_target::xfer_partial (enum target_object object, const char *annex, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, ULONGEST len, ULONGEST *xfered_len) { switch (object) { case TARGET_OBJECT_MEMORY: return procfs_xfer_memory (readbuf, writebuf, offset, len, xfered_len); case TARGET_OBJECT_AUXV: if (readbuf != NULL) { int err; CORE_ADDR initial_stack; debug_process_t procinfo; /* For 32-bit architecture, size of auxv_t is 8 bytes. */ const unsigned int sizeof_auxv_t = sizeof (auxv_t); const unsigned int sizeof_tempbuf = 20 * sizeof_auxv_t; int tempread; gdb_byte *const tempbuf = alloca (sizeof_tempbuf); if (tempbuf == NULL) return TARGET_XFER_E_IO; err = devctl (ctl_fd, DCMD_PROC_INFO, &procinfo, sizeof procinfo, 0); if (err != EOK) return TARGET_XFER_E_IO; initial_stack = procinfo.initial_stack; /* procfs is always 'self-hosted', no byte-order manipulation. */ tempread = nto_read_auxv_from_initial_stack (initial_stack, tempbuf, sizeof_tempbuf, sizeof (auxv_t)); tempread = std::min (tempread, len) - offset; memcpy (readbuf, tempbuf + offset, tempread); *xfered_len = tempread; return tempread ? TARGET_XFER_OK : TARGET_XFER_EOF; } /* Fallthru */ default: return this->beneath ()->xfer_partial (object, annex, readbuf, writebuf, offset, len, xfered_len); } } /* Take a program previously attached to and detaches it. The program resumes execution and will no longer stop on signals, etc. We'd better not have left any breakpoints in the program or it'll die when it hits one. */ void nto_procfs_target::detach (inferior *inf, int from_tty) { int pid; target_announce_detach (); if (siggnal) SignalKill (nto_node (), inferior_ptid.pid (), 0, 0, 0, 0); close (ctl_fd); ctl_fd = -1; pid = inferior_ptid.pid (); inferior_ptid = null_ptid; detach_inferior (pid); init_thread_list (); inf_child_maybe_unpush_target (ops); } static int procfs_breakpoint (CORE_ADDR addr, int type, int size) { procfs_break brk; brk.type = type; brk.addr = addr; brk.size = size; errno = devctl (ctl_fd, DCMD_PROC_BREAK, &brk, sizeof (brk), 0); if (errno != EOK) return 1; return 0; } int nto_procfs_target::insert_breakpoint (struct gdbarch *gdbarch, struct bp_target_info *bp_tgt) { bp_tgt->placed_address = bp_tgt->reqstd_address; return procfs_breakpoint (bp_tgt->placed_address, _DEBUG_BREAK_EXEC, 0); } int nto_procfs_target::remove_breakpoint (struct gdbarch *gdbarch, struct bp_target_info *bp_tgt, enum remove_bp_reason reason) { return procfs_breakpoint (bp_tgt->placed_address, _DEBUG_BREAK_EXEC, -1); } int nto_procfs_target::insert_hw_breakpoint (struct gdbarch *gdbarch, struct bp_target_info *bp_tgt) { bp_tgt->placed_address = bp_tgt->reqstd_address; return procfs_breakpoint (bp_tgt->placed_address, _DEBUG_BREAK_EXEC | _DEBUG_BREAK_HW, 0); } int nto_procfs_target::remove_hw_breakpoint (struct gdbarch *gdbarch, struct bp_target_info *bp_tgt) { return procfs_breakpoint (bp_tgt->placed_address, _DEBUG_BREAK_EXEC | _DEBUG_BREAK_HW, -1); } void nto_procfs_target::resume (ptid_t ptid, int step, enum gdb_signal signo) { int signal_to_pass; procfs_status status; sigset_t *run_fault = (sigset_t *) (void *) &run.fault; if (inferior_ptid == null_ptid) return; procfs_set_thread (ptid == minus_one_ptid ? inferior_ptid : ptid); run.flags = _DEBUG_RUN_FAULT | _DEBUG_RUN_TRACE; if (step) run.flags |= _DEBUG_RUN_STEP; sigemptyset (run_fault); sigaddset (run_fault, FLTBPT); sigaddset (run_fault, FLTTRACE); sigaddset (run_fault, FLTILL); sigaddset (run_fault, FLTPRIV); sigaddset (run_fault, FLTBOUNDS); sigaddset (run_fault, FLTIOVF); sigaddset (run_fault, FLTIZDIV); sigaddset (run_fault, FLTFPE); /* Peter V will be changing this at some point. */ sigaddset (run_fault, FLTPAGE); run.flags |= _DEBUG_RUN_ARM; signal_to_pass = gdb_signal_to_host (signo); if (signal_to_pass) { devctl (ctl_fd, DCMD_PROC_STATUS, &status, sizeof (status), 0); signal_to_pass = gdb_signal_to_host (signo); if (status.why & (_DEBUG_WHY_SIGNALLED | _DEBUG_WHY_FAULTED)) { if (signal_to_pass != status.info.si_signo) { SignalKill (nto_node (), inferior_ptid.pid (), 0, signal_to_pass, 0, 0); run.flags |= _DEBUG_RUN_CLRFLT | _DEBUG_RUN_CLRSIG; } else /* Let it kill the program without telling us. */ sigdelset (&run.trace, signal_to_pass); } } else run.flags |= _DEBUG_RUN_CLRSIG | _DEBUG_RUN_CLRFLT; errno = devctl (ctl_fd, DCMD_PROC_RUN, &run, sizeof (run), 0); if (errno != EOK) { perror (_("run error!\n")); return; } } void nto_procfs_target::mourn_inferior () { if (inferior_ptid != null_ptid) { SignalKill (nto_node (), inferior_ptid.pid (), 0, SIGKILL, 0, 0); close (ctl_fd); } inferior_ptid = null_ptid; init_thread_list (); inf_child_mourn_inferior (ops); } /* This function breaks up an argument string into an argument vector suitable for passing to execvp(). E.g., on "run a b c d" this routine would get as input the string "a b c d", and as output it would fill in argv with the four arguments "a", "b", "c", "d". The only additional functionality is simple quoting. The gdb command: run a "b c d" f will fill in argv with the three args "a", "b c d", "e". */ static void breakup_args (char *scratch, char **argv) { char *pp, *cp = scratch; char quoting = 0; for (;;) { /* Scan past leading separators. */ quoting = 0; while (*cp == ' ' || *cp == '\t' || *cp == '\n') cp++; /* Break if at end of string. */ if (*cp == '\0') break; /* Take an arg. */ if (*cp == '"') { cp++; quoting = strchr (cp, '"') ? 1 : 0; } *argv++ = cp; /* Scan for next arg separator. */ pp = cp; if (quoting) cp = strchr (pp, '"'); if ((cp == NULL) || (!quoting)) cp = strchr (pp, ' '); if (cp == NULL) cp = strchr (pp, '\t'); if (cp == NULL) cp = strchr (pp, '\n'); /* No separators => end of string => break. */ if (cp == NULL) { pp = cp; break; } /* Replace the separator with a terminator. */ *cp++ = '\0'; } /* Execv requires a null-terminated arg vector. */ *argv = NULL; } void nto_procfs_target::create_inferior (const char *exec_file, const std::string &allargs, char **env, int from_tty) { struct inheritance inherit; pid_t pid; int flags, errn; char **argv, *args; const char *in = "", *out = "", *err = ""; int fd, fds[3]; sigset_t set; const char *inferior_io_terminal = get_inferior_io_terminal (); struct inferior *inf; argv = xmalloc ((allargs.size () / (unsigned) 2 + 2) * sizeof (*argv)); argv[0] = get_exec_file (1); if (!argv[0]) { if (exec_file) argv[0] = exec_file; else return; } args = xstrdup (allargs.c_str ()); breakup_args (args, (exec_file != NULL) ? &argv[1] : &argv[0]); argv = nto_parse_redirection (argv, &in, &out, &err); fds[0] = STDIN_FILENO; fds[1] = STDOUT_FILENO; fds[2] = STDERR_FILENO; /* If the user specified I/O via gdb's --tty= arg, use it, but only if the i/o is not also being specified via redirection. */ if (inferior_io_terminal) { if (!in[0]) in = inferior_io_terminal; if (!out[0]) out = inferior_io_terminal; if (!err[0]) err = inferior_io_terminal; } if (in[0]) { fd = open (in, O_RDONLY); if (fd == -1) perror (in); else fds[0] = fd; } if (out[0]) { fd = open (out, O_WRONLY); if (fd == -1) perror (out); else fds[1] = fd; } if (err[0]) { fd = open (err, O_WRONLY); if (fd == -1) perror (err); else fds[2] = fd; } /* Clear any pending SIGUSR1's but keep the behavior the same. */ signal (SIGUSR1, signal (SIGUSR1, SIG_IGN)); sigemptyset (&set); sigaddset (&set, SIGUSR1); sigprocmask (SIG_UNBLOCK, &set, NULL); memset (&inherit, 0, sizeof (inherit)); if (ND_NODE_CMP (nto_procfs_node, ND_LOCAL_NODE) != 0) { inherit.nd = nto_node (); inherit.flags |= SPAWN_SETND; inherit.flags &= ~SPAWN_EXEC; } inherit.flags |= SPAWN_SETGROUP | SPAWN_HOLD; inherit.pgroup = SPAWN_NEWPGROUP; pid = spawnp (argv[0], 3, fds, &inherit, argv, ND_NODE_CMP (nto_procfs_node, ND_LOCAL_NODE) == 0 ? env : 0); xfree (args); sigprocmask (SIG_BLOCK, &set, NULL); if (pid == -1) error (_("Error spawning %s: %d (%s)"), argv[0], errno, safe_strerror (errno)); if (fds[0] != STDIN_FILENO) close (fds[0]); if (fds[1] != STDOUT_FILENO) close (fds[1]); if (fds[2] != STDERR_FILENO) close (fds[2]); inferior_ptid = do_attach (ptid_t (pid)); procfs_update_thread_list (ops); inf = current_inferior (); inferior_appeared (inf, pid); inf->attach_flag = 0; flags = _DEBUG_FLAG_KLC; /* Kill-on-Last-Close flag. */ errn = devctl (ctl_fd, DCMD_PROC_SET_FLAG, &flags, sizeof (flags), 0); if (errn != EOK) { /* FIXME: expected warning? */ /* warning( "Failed to set Kill-on-Last-Close flag: errno = %d(%s)\n", errn, strerror(errn) ); */ } if (!target_is_pushed (ops)) push_target (ops); target_terminal::init (); if (exec_bfd != NULL || (symfile_objfile != NULL && symfile_objfile->obfd != NULL)) solib_create_inferior_hook (0); } void nto_procfs_target::interrupt () { devctl (ctl_fd, DCMD_PROC_STOP, NULL, 0, 0); } void nto_procfs_target::kill () { target_mourn_inferior (inferior_ptid); } /* Fill buf with regset and return devctl cmd to do the setting. Return -1 if we fail to get the regset. Store size of regset in regsize. */ static int get_regset (int regset, char *buf, int bufsize, int *regsize) { int dev_get, dev_set; switch (regset) { case NTO_REG_GENERAL: dev_get = DCMD_PROC_GETGREG; dev_set = DCMD_PROC_SETGREG; break; case NTO_REG_FLOAT: dev_get = DCMD_PROC_GETFPREG; dev_set = DCMD_PROC_SETFPREG; break; case NTO_REG_ALT: dev_get = DCMD_PROC_GETALTREG; dev_set = DCMD_PROC_SETALTREG; break; case NTO_REG_SYSTEM: default: return -1; } if (devctl (ctl_fd, dev_get, buf, bufsize, regsize) != EOK) return -1; return dev_set; } void nto_procfs_target::store_registers (struct regcache *regcache, int regno) { union { procfs_greg greg; procfs_fpreg fpreg; procfs_altreg altreg; } reg; unsigned off; int len, regset, regsize, dev_set, err; char *data; ptid_t ptid = regcache->ptid (); if (ptid == null_ptid) return; procfs_set_thread (ptid); if (regno == -1) { for (regset = NTO_REG_GENERAL; regset < NTO_REG_END; regset++) { dev_set = get_regset (regset, (char *) ®, sizeof (reg), ®size); if (dev_set == -1) continue; if (nto_regset_fill (regcache, regset, (char *) ®) == -1) continue; err = devctl (ctl_fd, dev_set, ®, regsize, 0); if (err != EOK) fprintf_unfiltered (gdb_stderr, "Warning unable to write regset %d: %s\n", regno, safe_strerror (err)); } } else { regset = nto_regset_id (regno); if (regset == -1) return; dev_set = get_regset (regset, (char *) ®, sizeof (reg), ®size); if (dev_set == -1) return; len = nto_register_area (regcache->arch (), regno, regset, &off); if (len < 1) return; regcache->raw_collect (regno, (char *) ® + off); err = devctl (ctl_fd, dev_set, ®, regsize, 0); if (err != EOK) fprintf_unfiltered (gdb_stderr, "Warning unable to write regset %d: %s\n", regno, safe_strerror (err)); } } /* Set list of signals to be handled in the target. */ void nto_procfs_target::pass_signals (int numsigs, unsigned char *pass_signals) { int signo; sigfillset (&run.trace); for (signo = 1; signo < NSIG; signo++) { int target_signo = gdb_signal_from_host (signo); if (target_signo < numsigs && pass_signals[target_signo]) sigdelset (&run.trace, signo); } } char * nto_procfs_target::pid_to_str (ptid_t ptid) { static char buf[1024]; int pid, tid, n; struct tidinfo *tip; pid = ptid.pid (); tid = ptid.tid (); n = snprintf (buf, 1023, "process %d", pid); #if 0 /* NYI */ tip = procfs_thread_info (pid, tid); if (tip != NULL) snprintf (&buf[n], 1023, " (state = 0x%02x)", tip->state); #endif return buf; } /* to_can_run implementation for "target procfs". Note this really means "can this target be the default run target", which there can be only one, and we make it be "target native" like other ports. "target procfs " wouldn't make sense as default run target, as it needs . */ int nto_procfs_target::can_run () { return 0; } /* "target procfs". */ static nto_procfs_target_procfs nto_procfs_ops; /* "target native". */ static nto_procfs_target_native nto_native_ops; /* Create the "native" and "procfs" targets. */ static void init_procfs_targets (void) { /* Register "target native". This is the default run target. */ add_target (nto_native_target_info, inf_child_open_target); set_native_target (&nto_native_ops); /* Register "target procfs ". */ add_target (nto_procfs_target_info, inf_child_open_target); } #define OSTYPE_NTO 1 void _initialize_procfs (void) { sigset_t set; init_procfs_targets (); /* We use SIGUSR1 to gain control after we block waiting for a process. We use sigwaitevent to wait. */ sigemptyset (&set); sigaddset (&set, SIGUSR1); sigprocmask (SIG_BLOCK, &set, NULL); /* Initially, make sure all signals are reported. */ sigfillset (&run.trace); /* Stuff some information. */ nto_cpuinfo_flags = SYSPAGE_ENTRY (cpuinfo)->flags; nto_cpuinfo_valid = 1; add_info ("pidlist", procfs_pidlist, _("pidlist")); add_info ("meminfo", procfs_meminfo, _("memory information")); nto_is_nto_target = procfs_is_nto_target; } static int procfs_hw_watchpoint (int addr, int len, enum target_hw_bp_type type) { procfs_break brk; switch (type) { case hw_read: brk.type = _DEBUG_BREAK_RD; break; case hw_access: brk.type = _DEBUG_BREAK_RW; break; default: /* Modify. */ /* FIXME: brk.type = _DEBUG_BREAK_RWM gives EINVAL for some reason. */ brk.type = _DEBUG_BREAK_RW; } brk.type |= _DEBUG_BREAK_HW; /* Always ask for HW. */ brk.addr = addr; brk.size = len; errno = devctl (ctl_fd, DCMD_PROC_BREAK, &brk, sizeof (brk), 0); if (errno != EOK) { perror (_("Failed to set hardware watchpoint")); return -1; } return 0; } bool nto_procfs_target::can_use_hw_breakpoint (enum bptype type, int cnt, int othertype) { return 1; } int nto_procfs_target::remove_hw_watchpoint (CORE_ADDR addr, int len, enum target_hw_bp_type type, struct expression *cond) { return procfs_hw_watchpoint (addr, -1, type); } int nto_procfs_target::insert_hw_watchpoint (CORE_ADDR addr, int len, enum target_hw_bp_type type, struct expression *cond) { return procfs_hw_watchpoint (addr, len, type); } bool nto_procfs_target::stopped_by_watchpoint () { /* NOTE: nto_stopped_by_watchpoint will be called ONLY while we are stopped due to a SIGTRAP. This assumes gdb works in 'all-stop' mode; future gdb versions will likely run in 'non-stop' mode in which case we will have to store/examine statuses per thread in question. Until then, this will work fine. */ struct inferior *inf = current_inferior (); struct nto_inferior_data *inf_data; gdb_assert (inf != NULL); inf_data = nto_inferior_data (inf); return inf_data->stopped_flags & (_DEBUG_FLAG_TRACE_RD | _DEBUG_FLAG_TRACE_WR | _DEBUG_FLAG_TRACE_MODIFY); }