/* GNU/Linux native-dependent code common to multiple platforms. Copyright (C) 2001-2023 Free Software Foundation, Inc. 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 "inferior.h" #include "infrun.h" #include "target.h" #include "nat/linux-nat.h" #include "nat/linux-waitpid.h" #include "gdbsupport/gdb_wait.h" #include #include #include "nat/gdb_ptrace.h" #include "linux-nat.h" #include "nat/linux-ptrace.h" #include "nat/linux-procfs.h" #include "nat/linux-personality.h" #include "linux-fork.h" #include "gdbthread.h" #include "gdbcmd.h" #include "regcache.h" #include "regset.h" #include "inf-child.h" #include "inf-ptrace.h" #include "auxv.h" #include #include "elf-bfd.h" #include "gregset.h" #include "gdbcore.h" #include #include #include #include "inf-loop.h" #include "gdbsupport/event-loop.h" #include "event-top.h" #include #include #include #include "xml-support.h" #include #include "solib.h" #include "nat/linux-osdata.h" #include "linux-tdep.h" #include "symfile.h" #include "gdbsupport/agent.h" #include "tracepoint.h" #include "target-descriptions.h" #include "gdbsupport/filestuff.h" #include "objfiles.h" #include "nat/linux-namespaces.h" #include "gdbsupport/block-signals.h" #include "gdbsupport/fileio.h" #include "gdbsupport/scope-exit.h" #include "gdbsupport/gdb-sigmask.h" #include "gdbsupport/common-debug.h" #include /* This comment documents high-level logic of this file. Waiting for events in sync mode =============================== When waiting for an event in a specific thread, we just use waitpid, passing the specific pid, and not passing WNOHANG. When waiting for an event in all threads, waitpid is not quite good: - If the thread group leader exits while other threads in the thread group still exist, waitpid(TGID, ...) hangs. That waitpid won't return an exit status until the other threads in the group are reaped. - When a non-leader thread execs, that thread just vanishes without reporting an exit (so we'd hang if we waited for it explicitly in that case). The exec event is instead reported to the TGID pid. The solution is to always use -1 and WNOHANG, together with sigsuspend. First, we use non-blocking waitpid to check for events. If nothing is found, we use sigsuspend to wait for SIGCHLD. When SIGCHLD arrives, it means something happened to a child process. As soon as we know there's an event, we get back to calling nonblocking waitpid. Note that SIGCHLD should be blocked between waitpid and sigsuspend calls, so that we don't miss a signal. If SIGCHLD arrives in between, when it's blocked, the signal becomes pending and sigsuspend immediately notices it and returns. Waiting for events in async mode (TARGET_WNOHANG) ================================================= In async mode, GDB should always be ready to handle both user input and target events, so neither blocking waitpid nor sigsuspend are viable options. Instead, we should asynchronously notify the GDB main event loop whenever there's an unprocessed event from the target. We detect asynchronous target events by handling SIGCHLD signals. To notify the event loop about target events, an event pipe is used --- the pipe is registered as waitable event source in the event loop, the event loop select/poll's on the read end of this pipe (as well on other event sources, e.g., stdin), and the SIGCHLD handler marks the event pipe to raise an event. This is more portable than relying on pselect/ppoll, since on kernels that lack those syscalls, libc emulates them with select/poll+sigprocmask, and that is racy (a.k.a. plain broken). Obviously, if we fail to notify the event loop if there's a target event, it's bad. OTOH, if we notify the event loop when there's no event from the target, linux_nat_wait will detect that there's no real event to report, and return event of type TARGET_WAITKIND_IGNORE. This is mostly harmless, but it will waste time and is better avoided. The main design point is that every time GDB is outside linux-nat.c, we have a SIGCHLD handler installed that is called when something happens to the target and notifies the GDB event loop. Whenever GDB core decides to handle the event, and calls into linux-nat.c, we process things as in sync mode, except that the we never block in sigsuspend. While processing an event, we may end up momentarily blocked in waitpid calls. Those waitpid calls, while blocking, are guarantied to return quickly. E.g., in all-stop mode, before reporting to the core that an LWP hit a breakpoint, all LWPs are stopped by sending them SIGSTOP, and synchronously waiting for the SIGSTOP to be reported. Note that this is different from blocking indefinitely waiting for the next event --- here, we're already handling an event. Use of signals ============== We stop threads by sending a SIGSTOP. The use of SIGSTOP instead of another signal is not entirely significant; we just need for a signal to be delivered, so that we can intercept it. SIGSTOP's advantage is that it can not be blocked. A disadvantage is that it is not a real-time signal, so it can only be queued once; we do not keep track of other sources of SIGSTOP. Two other signals that can't be blocked are SIGCONT and SIGKILL. But we can't use them, because they have special behavior when the signal is generated - not when it is delivered. SIGCONT resumes the entire thread group and SIGKILL kills the entire thread group. A delivered SIGSTOP would stop the entire thread group, not just the thread we tkill'd. But we never let the SIGSTOP be delivered; we always intercept and cancel it (by PTRACE_CONT without passing SIGSTOP). We could use a real-time signal instead. This would solve those problems; we could use PTRACE_GETSIGINFO to locate the specific stop signals sent by GDB. But we would still have to have some support for SIGSTOP, since PTRACE_ATTACH generates it, and there are races with trying to find a signal that is not blocked. Exec events =========== The case of a thread group (process) with 3 or more threads, and a thread other than the leader execs is worth detailing: On an exec, the Linux kernel destroys all threads except the execing one in the thread group, and resets the execing thread's tid to the tgid. No exit notification is sent for the execing thread -- from the ptracer's perspective, it appears as though the execing thread just vanishes. Until we reap all other threads except the leader and the execing thread, the leader will be zombie, and the execing thread will be in `D (disc sleep)' state. As soon as all other threads are reaped, the execing thread changes its tid to the tgid, and the previous (zombie) leader vanishes, giving place to the "new" leader. */ #ifndef O_LARGEFILE #define O_LARGEFILE 0 #endif struct linux_nat_target *linux_target; /* Does the current host support PTRACE_GETREGSET? */ enum tribool have_ptrace_getregset = TRIBOOL_UNKNOWN; /* When true, print debug messages relating to the linux native target. */ static bool debug_linux_nat; /* Implement 'show debug linux-nat'. */ static void show_debug_linux_nat (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { gdb_printf (file, _("Debugging of GNU/Linux native targets is %s.\n"), value); } /* Print a linux-nat debug statement. */ #define linux_nat_debug_printf(fmt, ...) \ debug_prefixed_printf_cond (debug_linux_nat, "linux-nat", fmt, ##__VA_ARGS__) /* Print "linux-nat" enter/exit debug statements. */ #define LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT \ scoped_debug_enter_exit (debug_linux_nat, "linux-nat") struct simple_pid_list { int pid; int status; struct simple_pid_list *next; }; static struct simple_pid_list *stopped_pids; /* Whether target_thread_events is in effect. */ static int report_thread_events; static int kill_lwp (int lwpid, int signo); static int stop_callback (struct lwp_info *lp); static void block_child_signals (sigset_t *prev_mask); static void restore_child_signals_mask (sigset_t *prev_mask); struct lwp_info; static struct lwp_info *add_lwp (ptid_t ptid); static void purge_lwp_list (int pid); static void delete_lwp (ptid_t ptid); static struct lwp_info *find_lwp_pid (ptid_t ptid); static int lwp_status_pending_p (struct lwp_info *lp); static void save_stop_reason (struct lwp_info *lp); static bool proc_mem_file_is_writable (); static void close_proc_mem_file (pid_t pid); static void open_proc_mem_file (ptid_t ptid); /* Return TRUE if LWP is the leader thread of the process. */ static bool is_leader (lwp_info *lp) { return lp->ptid.pid () == lp->ptid.lwp (); } /* Convert an LWP's pending status to a std::string. */ static std::string pending_status_str (lwp_info *lp) { gdb_assert (lwp_status_pending_p (lp)); if (lp->waitstatus.kind () != TARGET_WAITKIND_IGNORE) return lp->waitstatus.to_string (); else return status_to_str (lp->status); } /* LWP accessors. */ /* See nat/linux-nat.h. */ ptid_t ptid_of_lwp (struct lwp_info *lwp) { return lwp->ptid; } /* See nat/linux-nat.h. */ void lwp_set_arch_private_info (struct lwp_info *lwp, struct arch_lwp_info *info) { lwp->arch_private = info; } /* See nat/linux-nat.h. */ struct arch_lwp_info * lwp_arch_private_info (struct lwp_info *lwp) { return lwp->arch_private; } /* See nat/linux-nat.h. */ int lwp_is_stopped (struct lwp_info *lwp) { return lwp->stopped; } /* See nat/linux-nat.h. */ enum target_stop_reason lwp_stop_reason (struct lwp_info *lwp) { return lwp->stop_reason; } /* See nat/linux-nat.h. */ int lwp_is_stepping (struct lwp_info *lwp) { return lwp->step; } /* Trivial list manipulation functions to keep track of a list of new stopped processes. */ static void add_to_pid_list (struct simple_pid_list **listp, int pid, int status) { struct simple_pid_list *new_pid = XNEW (struct simple_pid_list); new_pid->pid = pid; new_pid->status = status; new_pid->next = *listp; *listp = new_pid; } static int pull_pid_from_list (struct simple_pid_list **listp, int pid, int *statusp) { struct simple_pid_list **p; for (p = listp; *p != NULL; p = &(*p)->next) if ((*p)->pid == pid) { struct simple_pid_list *next = (*p)->next; *statusp = (*p)->status; xfree (*p); *p = next; return 1; } return 0; } /* Return the ptrace options that we want to try to enable. */ static int linux_nat_ptrace_options (int attached) { int options = 0; if (!attached) options |= PTRACE_O_EXITKILL; options |= (PTRACE_O_TRACESYSGOOD | PTRACE_O_TRACEVFORKDONE | PTRACE_O_TRACEVFORK | PTRACE_O_TRACEFORK | PTRACE_O_TRACEEXEC); return options; } /* Initialize ptrace and procfs warnings and check for supported ptrace features given PID. ATTACHED should be nonzero iff we attached to the inferior. */ static void linux_init_ptrace_procfs (pid_t pid, int attached) { int options = linux_nat_ptrace_options (attached); linux_enable_event_reporting (pid, options); linux_ptrace_init_warnings (); linux_proc_init_warnings (); proc_mem_file_is_writable (); } linux_nat_target::~linux_nat_target () {} void linux_nat_target::post_attach (int pid) { linux_init_ptrace_procfs (pid, 1); } /* Implement the virtual inf_ptrace_target::post_startup_inferior method. */ void linux_nat_target::post_startup_inferior (ptid_t ptid) { linux_init_ptrace_procfs (ptid.pid (), 0); } /* Return the number of known LWPs in the tgid given by PID. */ static int num_lwps (int pid) { int count = 0; for (const lwp_info *lp ATTRIBUTE_UNUSED : all_lwps ()) if (lp->ptid.pid () == pid) count++; return count; } /* Deleter for lwp_info unique_ptr specialisation. */ struct lwp_deleter { void operator() (struct lwp_info *lwp) const { delete_lwp (lwp->ptid); } }; /* A unique_ptr specialisation for lwp_info. */ typedef std::unique_ptr lwp_info_up; /* Target hook for follow_fork. */ void linux_nat_target::follow_fork (inferior *child_inf, ptid_t child_ptid, target_waitkind fork_kind, bool follow_child, bool detach_fork) { inf_ptrace_target::follow_fork (child_inf, child_ptid, fork_kind, follow_child, detach_fork); if (!follow_child) { bool has_vforked = fork_kind == TARGET_WAITKIND_VFORKED; ptid_t parent_ptid = inferior_ptid; int parent_pid = parent_ptid.lwp (); int child_pid = child_ptid.lwp (); /* We're already attached to the parent, by default. */ lwp_info *child_lp = add_lwp (child_ptid); child_lp->stopped = 1; child_lp->last_resume_kind = resume_stop; /* Detach new forked process? */ if (detach_fork) { int child_stop_signal = 0; bool detach_child = true; /* Move CHILD_LP into a unique_ptr and clear the source pointer to prevent us doing anything stupid with it. */ lwp_info_up child_lp_ptr (child_lp); child_lp = nullptr; linux_target->low_prepare_to_resume (child_lp_ptr.get ()); /* When debugging an inferior in an architecture that supports hardware single stepping on a kernel without commit 6580807da14c423f0d0a708108e6df6ebc8bc83d, the vfork child process starts with the TIF_SINGLESTEP/X86_EFLAGS_TF bits set if the parent process had them set. To work around this, single step the child process once before detaching to clear the flags. */ /* Note that we consult the parent's architecture instead of the child's because there's no inferior for the child at this point. */ if (!gdbarch_software_single_step_p (target_thread_architecture (parent_ptid))) { int status; linux_disable_event_reporting (child_pid); if (ptrace (PTRACE_SINGLESTEP, child_pid, 0, 0) < 0) perror_with_name (_("Couldn't do single step")); if (my_waitpid (child_pid, &status, 0) < 0) perror_with_name (_("Couldn't wait vfork process")); else { detach_child = WIFSTOPPED (status); child_stop_signal = WSTOPSIG (status); } } if (detach_child) { int signo = child_stop_signal; if (signo != 0 && !signal_pass_state (gdb_signal_from_host (signo))) signo = 0; ptrace (PTRACE_DETACH, child_pid, 0, signo); close_proc_mem_file (child_pid); } } if (has_vforked) { lwp_info *parent_lp = find_lwp_pid (parent_ptid); linux_nat_debug_printf ("waiting for VFORK_DONE on %d", parent_pid); parent_lp->stopped = 1; /* We'll handle the VFORK_DONE event like any other event, in target_wait. */ } } else { struct lwp_info *child_lp; child_lp = add_lwp (child_ptid); child_lp->stopped = 1; child_lp->last_resume_kind = resume_stop; } } int linux_nat_target::insert_fork_catchpoint (int pid) { return 0; } int linux_nat_target::remove_fork_catchpoint (int pid) { return 0; } int linux_nat_target::insert_vfork_catchpoint (int pid) { return 0; } int linux_nat_target::remove_vfork_catchpoint (int pid) { return 0; } int linux_nat_target::insert_exec_catchpoint (int pid) { return 0; } int linux_nat_target::remove_exec_catchpoint (int pid) { return 0; } int linux_nat_target::set_syscall_catchpoint (int pid, bool needed, int any_count, gdb::array_view syscall_counts) { /* On GNU/Linux, we ignore the arguments. It means that we only enable the syscall catchpoints, but do not disable them. Also, we do not use the `syscall_counts' information because we do not filter system calls here. We let GDB do the logic for us. */ return 0; } /* List of known LWPs, keyed by LWP PID. This speeds up the common case of mapping a PID returned from the kernel to our corresponding lwp_info data structure. */ static htab_t lwp_lwpid_htab; /* Calculate a hash from a lwp_info's LWP PID. */ static hashval_t lwp_info_hash (const void *ap) { const struct lwp_info *lp = (struct lwp_info *) ap; pid_t pid = lp->ptid.lwp (); return iterative_hash_object (pid, 0); } /* Equality function for the lwp_info hash table. Compares the LWP's PID. */ static int lwp_lwpid_htab_eq (const void *a, const void *b) { const struct lwp_info *entry = (const struct lwp_info *) a; const struct lwp_info *element = (const struct lwp_info *) b; return entry->ptid.lwp () == element->ptid.lwp (); } /* Create the lwp_lwpid_htab hash table. */ static void lwp_lwpid_htab_create (void) { lwp_lwpid_htab = htab_create (100, lwp_info_hash, lwp_lwpid_htab_eq, NULL); } /* Add LP to the hash table. */ static void lwp_lwpid_htab_add_lwp (struct lwp_info *lp) { void **slot; slot = htab_find_slot (lwp_lwpid_htab, lp, INSERT); gdb_assert (slot != NULL && *slot == NULL); *slot = lp; } /* Head of doubly-linked list of known LWPs. Sorted by reverse creation order. This order is assumed in some cases. E.g., reaping status after killing alls lwps of a process: the leader LWP must be reaped last. */ static intrusive_list lwp_list; /* See linux-nat.h. */ lwp_info_range all_lwps () { return lwp_info_range (lwp_list.begin ()); } /* See linux-nat.h. */ lwp_info_safe_range all_lwps_safe () { return lwp_info_safe_range (lwp_list.begin ()); } /* Add LP to sorted-by-reverse-creation-order doubly-linked list. */ static void lwp_list_add (struct lwp_info *lp) { lwp_list.push_front (*lp); } /* Remove LP from sorted-by-reverse-creation-order doubly-linked list. */ static void lwp_list_remove (struct lwp_info *lp) { /* Remove from sorted-by-creation-order list. */ lwp_list.erase (lwp_list.iterator_to (*lp)); } /* Signal mask for use with sigsuspend in linux_nat_wait, initialized in _initialize_linux_nat. */ static sigset_t suspend_mask; /* Signals to block to make that sigsuspend work. */ static sigset_t blocked_mask; /* SIGCHLD action. */ static struct sigaction sigchld_action; /* Block child signals (SIGCHLD and linux threads signals), and store the previous mask in PREV_MASK. */ static void block_child_signals (sigset_t *prev_mask) { /* Make sure SIGCHLD is blocked. */ if (!sigismember (&blocked_mask, SIGCHLD)) sigaddset (&blocked_mask, SIGCHLD); gdb_sigmask (SIG_BLOCK, &blocked_mask, prev_mask); } /* Restore child signals mask, previously returned by block_child_signals. */ static void restore_child_signals_mask (sigset_t *prev_mask) { gdb_sigmask (SIG_SETMASK, prev_mask, NULL); } /* Mask of signals to pass directly to the inferior. */ static sigset_t pass_mask; /* Update signals to pass to the inferior. */ void linux_nat_target::pass_signals (gdb::array_view pass_signals) { int signo; sigemptyset (&pass_mask); for (signo = 1; signo < NSIG; signo++) { int target_signo = gdb_signal_from_host (signo); if (target_signo < pass_signals.size () && pass_signals[target_signo]) sigaddset (&pass_mask, signo); } } /* Prototypes for local functions. */ static int stop_wait_callback (struct lwp_info *lp); static int resume_stopped_resumed_lwps (struct lwp_info *lp, const ptid_t wait_ptid); static int check_ptrace_stopped_lwp_gone (struct lwp_info *lp); /* Destroy and free LP. */ lwp_info::~lwp_info () { /* Let the arch specific bits release arch_lwp_info. */ linux_target->low_delete_thread (this->arch_private); } /* Traversal function for purge_lwp_list. */ static int lwp_lwpid_htab_remove_pid (void **slot, void *info) { struct lwp_info *lp = (struct lwp_info *) *slot; int pid = *(int *) info; if (lp->ptid.pid () == pid) { htab_clear_slot (lwp_lwpid_htab, slot); lwp_list_remove (lp); delete lp; } return 1; } /* Remove all LWPs belong to PID from the lwp list. */ static void purge_lwp_list (int pid) { htab_traverse_noresize (lwp_lwpid_htab, lwp_lwpid_htab_remove_pid, &pid); } /* Add the LWP specified by PTID to the list. PTID is the first LWP in the process. Return a pointer to the structure describing the new LWP. This differs from add_lwp in that we don't let the arch specific bits know about this new thread. Current clients of this callback take the opportunity to install watchpoints in the new thread, and we shouldn't do that for the first thread. If we're spawning a child ("run"), the thread executes the shell wrapper first, and we shouldn't touch it until it execs the program we want to debug. For "attach", it'd be okay to call the callback, but it's not necessary, because watchpoints can't yet have been inserted into the inferior. */ static struct lwp_info * add_initial_lwp (ptid_t ptid) { gdb_assert (ptid.lwp_p ()); lwp_info *lp = new lwp_info (ptid); /* Add to sorted-by-reverse-creation-order list. */ lwp_list_add (lp); /* Add to keyed-by-pid htab. */ lwp_lwpid_htab_add_lwp (lp); return lp; } /* Add the LWP specified by PID to the list. Return a pointer to the structure describing the new LWP. The LWP should already be stopped. */ static struct lwp_info * add_lwp (ptid_t ptid) { struct lwp_info *lp; lp = add_initial_lwp (ptid); /* Let the arch specific bits know about this new thread. Current clients of this callback take the opportunity to install watchpoints in the new thread. We don't do this for the first thread though. See add_initial_lwp. */ linux_target->low_new_thread (lp); return lp; } /* Remove the LWP specified by PID from the list. */ static void delete_lwp (ptid_t ptid) { lwp_info dummy (ptid); void **slot = htab_find_slot (lwp_lwpid_htab, &dummy, NO_INSERT); if (slot == NULL) return; lwp_info *lp = *(struct lwp_info **) slot; gdb_assert (lp != NULL); htab_clear_slot (lwp_lwpid_htab, slot); /* Remove from sorted-by-creation-order list. */ lwp_list_remove (lp); /* Release. */ delete lp; } /* Return a pointer to the structure describing the LWP corresponding to PID. If no corresponding LWP could be found, return NULL. */ static struct lwp_info * find_lwp_pid (ptid_t ptid) { int lwp; if (ptid.lwp_p ()) lwp = ptid.lwp (); else lwp = ptid.pid (); lwp_info dummy (ptid_t (0, lwp)); return (struct lwp_info *) htab_find (lwp_lwpid_htab, &dummy); } /* See nat/linux-nat.h. */ struct lwp_info * iterate_over_lwps (ptid_t filter, gdb::function_view callback) { for (lwp_info *lp : all_lwps_safe ()) { if (lp->ptid.matches (filter)) { if (callback (lp) != 0) return lp; } } return NULL; } /* Update our internal state when changing from one checkpoint to another indicated by NEW_PTID. We can only switch single-threaded applications, so we only create one new LWP, and the previous list is discarded. */ void linux_nat_switch_fork (ptid_t new_ptid) { struct lwp_info *lp; purge_lwp_list (inferior_ptid.pid ()); lp = add_lwp (new_ptid); lp->stopped = 1; /* This changes the thread's ptid while preserving the gdb thread num. Also changes the inferior pid, while preserving the inferior num. */ thread_change_ptid (linux_target, inferior_ptid, new_ptid); /* We've just told GDB core that the thread changed target id, but, in fact, it really is a different thread, with different register contents. */ registers_changed (); } /* Handle the exit of a single thread LP. */ static void exit_lwp (struct lwp_info *lp) { struct thread_info *th = linux_target->find_thread (lp->ptid); if (th) delete_thread (th); delete_lwp (lp->ptid); } /* Wait for the LWP specified by LP, which we have just attached to. Returns a wait status for that LWP, to cache. */ static int linux_nat_post_attach_wait (ptid_t ptid, int *signalled) { pid_t new_pid, pid = ptid.lwp (); int status; if (linux_proc_pid_is_stopped (pid)) { linux_nat_debug_printf ("Attaching to a stopped process"); /* The process is definitely stopped. It is in a job control stop, unless the kernel predates the TASK_STOPPED / TASK_TRACED distinction, in which case it might be in a ptrace stop. Make sure it is in a ptrace stop; from there we can kill it, signal it, et cetera. First make sure there is a pending SIGSTOP. Since we are already attached, the process can not transition from stopped to running without a PTRACE_CONT; so we know this signal will go into the queue. The SIGSTOP generated by PTRACE_ATTACH is probably already in the queue (unless this kernel is old enough to use TASK_STOPPED for ptrace stops); but since SIGSTOP is not an RT signal, it can only be queued once. */ kill_lwp (pid, SIGSTOP); /* Finally, resume the stopped process. This will deliver the SIGSTOP (or a higher priority signal, just like normal PTRACE_ATTACH). */ ptrace (PTRACE_CONT, pid, 0, 0); } /* Make sure the initial process is stopped. The user-level threads layer might want to poke around in the inferior, and that won't work if things haven't stabilized yet. */ new_pid = my_waitpid (pid, &status, __WALL); gdb_assert (pid == new_pid); if (!WIFSTOPPED (status)) { /* The pid we tried to attach has apparently just exited. */ linux_nat_debug_printf ("Failed to stop %d: %s", pid, status_to_str (status).c_str ()); return status; } if (WSTOPSIG (status) != SIGSTOP) { *signalled = 1; linux_nat_debug_printf ("Received %s after attaching", status_to_str (status).c_str ()); } return status; } void linux_nat_target::create_inferior (const char *exec_file, const std::string &allargs, char **env, int from_tty) { maybe_disable_address_space_randomization restore_personality (disable_randomization); /* The fork_child mechanism is synchronous and calls target_wait, so we have to mask the async mode. */ /* Make sure we report all signals during startup. */ pass_signals ({}); inf_ptrace_target::create_inferior (exec_file, allargs, env, from_tty); open_proc_mem_file (inferior_ptid); } /* Callback for linux_proc_attach_tgid_threads. Attach to PTID if not already attached. Returns true if a new LWP is found, false otherwise. */ static int attach_proc_task_lwp_callback (ptid_t ptid) { struct lwp_info *lp; /* Ignore LWPs we're already attached to. */ lp = find_lwp_pid (ptid); if (lp == NULL) { int lwpid = ptid.lwp (); if (ptrace (PTRACE_ATTACH, lwpid, 0, 0) < 0) { int err = errno; /* Be quiet if we simply raced with the thread exiting. EPERM is returned if the thread's task still exists, and is marked as exited or zombie, as well as other conditions, so in that case, confirm the status in /proc/PID/status. */ if (err == ESRCH || (err == EPERM && linux_proc_pid_is_gone (lwpid))) { linux_nat_debug_printf ("Cannot attach to lwp %d: thread is gone (%d: %s)", lwpid, err, safe_strerror (err)); } else { std::string reason = linux_ptrace_attach_fail_reason_string (ptid, err); warning (_("Cannot attach to lwp %d: %s"), lwpid, reason.c_str ()); } } else { linux_nat_debug_printf ("PTRACE_ATTACH %s, 0, 0 (OK)", ptid.to_string ().c_str ()); lp = add_lwp (ptid); /* The next time we wait for this LWP we'll see a SIGSTOP as PTRACE_ATTACH brings it to a halt. */ lp->signalled = 1; /* We need to wait for a stop before being able to make the next ptrace call on this LWP. */ lp->must_set_ptrace_flags = 1; /* So that wait collects the SIGSTOP. */ lp->resumed = 1; /* Also add the LWP to gdb's thread list, in case a matching libthread_db is not found (or the process uses raw clone). */ add_thread (linux_target, lp->ptid); set_running (linux_target, lp->ptid, true); set_executing (linux_target, lp->ptid, true); } return 1; } return 0; } void linux_nat_target::attach (const char *args, int from_tty) { struct lwp_info *lp; int status; ptid_t ptid; /* Make sure we report all signals during attach. */ pass_signals ({}); try { inf_ptrace_target::attach (args, from_tty); } catch (const gdb_exception_error &ex) { pid_t pid = parse_pid_to_attach (args); std::string reason = linux_ptrace_attach_fail_reason (pid); if (!reason.empty ()) throw_error (ex.error, "warning: %s\n%s", reason.c_str (), ex.what ()); else throw_error (ex.error, "%s", ex.what ()); } /* The ptrace base target adds the main thread with (pid,0,0) format. Decorate it with lwp info. */ ptid = ptid_t (inferior_ptid.pid (), inferior_ptid.pid ()); thread_change_ptid (linux_target, inferior_ptid, ptid); /* Add the initial process as the first LWP to the list. */ lp = add_initial_lwp (ptid); status = linux_nat_post_attach_wait (lp->ptid, &lp->signalled); if (!WIFSTOPPED (status)) { if (WIFEXITED (status)) { int exit_code = WEXITSTATUS (status); target_terminal::ours (); target_mourn_inferior (inferior_ptid); if (exit_code == 0) error (_("Unable to attach: program exited normally.")); else error (_("Unable to attach: program exited with code %d."), exit_code); } else if (WIFSIGNALED (status)) { enum gdb_signal signo; target_terminal::ours (); target_mourn_inferior (inferior_ptid); signo = gdb_signal_from_host (WTERMSIG (status)); error (_("Unable to attach: program terminated with signal " "%s, %s."), gdb_signal_to_name (signo), gdb_signal_to_string (signo)); } internal_error (_("unexpected status %d for PID %ld"), status, (long) ptid.lwp ()); } lp->stopped = 1; open_proc_mem_file (lp->ptid); /* Save the wait status to report later. */ lp->resumed = 1; linux_nat_debug_printf ("waitpid %ld, saving status %s", (long) lp->ptid.pid (), status_to_str (status).c_str ()); lp->status = status; /* We must attach to every LWP. If /proc is mounted, use that to find them now. The inferior may be using raw clone instead of using pthreads. But even if it is using pthreads, thread_db walks structures in the inferior's address space to find the list of threads/LWPs, and those structures may well be corrupted. Note that once thread_db is loaded, we'll still use it to list threads and associate pthread info with each LWP. */ linux_proc_attach_tgid_threads (lp->ptid.pid (), attach_proc_task_lwp_callback); } /* Ptrace-detach the thread with pid PID. */ static void detach_one_pid (int pid, int signo) { if (ptrace (PTRACE_DETACH, pid, 0, signo) < 0) { int save_errno = errno; /* We know the thread exists, so ESRCH must mean the lwp is zombie. This can happen if one of the already-detached threads exits the whole thread group. In that case we're still attached, and must reap the lwp. */ if (save_errno == ESRCH) { int ret, status; ret = my_waitpid (pid, &status, __WALL); if (ret == -1) { warning (_("Couldn't reap LWP %d while detaching: %s"), pid, safe_strerror (errno)); } else if (!WIFEXITED (status) && !WIFSIGNALED (status)) { warning (_("Reaping LWP %d while detaching " "returned unexpected status 0x%x"), pid, status); } } else error (_("Can't detach %d: %s"), pid, safe_strerror (save_errno)); } else linux_nat_debug_printf ("PTRACE_DETACH (%d, %s, 0) (OK)", pid, strsignal (signo)); } /* Get pending signal of THREAD as a host signal number, for detaching purposes. This is the signal the thread last stopped for, which we need to deliver to the thread when detaching, otherwise, it'd be suppressed/lost. */ static int get_detach_signal (struct lwp_info *lp) { enum gdb_signal signo = GDB_SIGNAL_0; /* If we paused threads momentarily, we may have stored pending events in lp->status or lp->waitstatus (see stop_wait_callback), and GDB core hasn't seen any signal for those threads. Otherwise, the last signal reported to the core is found in the thread object's stop_signal. There's a corner case that isn't handled here at present. Only if the thread stopped with a TARGET_WAITKIND_STOPPED does stop_signal make sense as a real signal to pass to the inferior. Some catchpoint related events, like TARGET_WAITKIND_(V)FORK|EXEC|SYSCALL, have their stop_signal set to GDB_SIGNAL_SIGTRAP when the catchpoint triggers. But, those traps are debug API (ptrace in our case) related and induced; the inferior wouldn't see them if it wasn't being traced. Hence, we should never pass them to the inferior, even when set to pass state. Since this corner case isn't handled by infrun.c when proceeding with a signal, for consistency, neither do we handle it here (or elsewhere in the file we check for signal pass state). Normally SIGTRAP isn't set to pass state, so this is really a corner case. */ if (lp->waitstatus.kind () != TARGET_WAITKIND_IGNORE) signo = GDB_SIGNAL_0; /* a pending ptrace event, not a real signal. */ else if (lp->status) signo = gdb_signal_from_host (WSTOPSIG (lp->status)); else { thread_info *tp = linux_target->find_thread (lp->ptid); if (target_is_non_stop_p () && !tp->executing ()) { if (tp->has_pending_waitstatus ()) { /* If the thread has a pending event, and it was stopped with a signal, use that signal to resume it. If it has a pending event of another kind, it was not stopped with a signal, so resume it without a signal. */ if (tp->pending_waitstatus ().kind () == TARGET_WAITKIND_STOPPED) signo = tp->pending_waitstatus ().sig (); else signo = GDB_SIGNAL_0; } else signo = tp->stop_signal (); } else if (!target_is_non_stop_p ()) { ptid_t last_ptid; process_stratum_target *last_target; get_last_target_status (&last_target, &last_ptid, nullptr); if (last_target == linux_target && lp->ptid.lwp () == last_ptid.lwp ()) signo = tp->stop_signal (); } } if (signo == GDB_SIGNAL_0) { linux_nat_debug_printf ("lwp %s has no pending signal", lp->ptid.to_string ().c_str ()); } else if (!signal_pass_state (signo)) { linux_nat_debug_printf ("lwp %s had signal %s but it is in no pass state", lp->ptid.to_string ().c_str (), gdb_signal_to_string (signo)); } else { linux_nat_debug_printf ("lwp %s has pending signal %s", lp->ptid.to_string ().c_str (), gdb_signal_to_string (signo)); return gdb_signal_to_host (signo); } return 0; } /* Detach from LP. If SIGNO_P is non-NULL, then it points to the signal number that should be passed to the LWP when detaching. Otherwise pass any pending signal the LWP may have, if any. */ static void detach_one_lwp (struct lwp_info *lp, int *signo_p) { LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT; linux_nat_debug_printf ("lwp %s (stopped = %d)", lp->ptid.to_string ().c_str (), lp->stopped); int lwpid = lp->ptid.lwp (); int signo; gdb_assert (lp->status == 0 || WIFSTOPPED (lp->status)); /* If the lwp/thread we are about to detach has a pending fork event, there is a process GDB is attached to that the core of GDB doesn't know about. Detach from it. */ /* Check in lwp_info::status. */ if (WIFSTOPPED (lp->status) && linux_is_extended_waitstatus (lp->status)) { int event = linux_ptrace_get_extended_event (lp->status); if (event == PTRACE_EVENT_FORK || event == PTRACE_EVENT_VFORK) { unsigned long child_pid; int ret = ptrace (PTRACE_GETEVENTMSG, lp->ptid.lwp (), 0, &child_pid); if (ret == 0) detach_one_pid (child_pid, 0); else perror_warning_with_name (_("Failed to detach fork child")); } } /* Check in lwp_info::waitstatus. */ if (lp->waitstatus.kind () == TARGET_WAITKIND_VFORKED || lp->waitstatus.kind () == TARGET_WAITKIND_FORKED) detach_one_pid (lp->waitstatus.child_ptid ().pid (), 0); /* Check in thread_info::pending_waitstatus. */ thread_info *tp = linux_target->find_thread (lp->ptid); if (tp->has_pending_waitstatus ()) { const target_waitstatus &ws = tp->pending_waitstatus (); if (ws.kind () == TARGET_WAITKIND_VFORKED || ws.kind () == TARGET_WAITKIND_FORKED) detach_one_pid (ws.child_ptid ().pid (), 0); } /* Check in thread_info::pending_follow. */ if (tp->pending_follow.kind () == TARGET_WAITKIND_VFORKED || tp->pending_follow.kind () == TARGET_WAITKIND_FORKED) detach_one_pid (tp->pending_follow.child_ptid ().pid (), 0); if (lp->status != 0) linux_nat_debug_printf ("Pending %s for %s on detach.", strsignal (WSTOPSIG (lp->status)), lp->ptid.to_string ().c_str ()); /* If there is a pending SIGSTOP, get rid of it. */ if (lp->signalled) { linux_nat_debug_printf ("Sending SIGCONT to %s", lp->ptid.to_string ().c_str ()); kill_lwp (lwpid, SIGCONT); lp->signalled = 0; } if (signo_p == NULL) { /* Pass on any pending signal for this LWP. */ signo = get_detach_signal (lp); } else signo = *signo_p; linux_nat_debug_printf ("preparing to resume lwp %s (stopped = %d)", lp->ptid.to_string ().c_str (), lp->stopped); /* Preparing to resume may try to write registers, and fail if the lwp is zombie. If that happens, ignore the error. We'll handle it below, when detach fails with ESRCH. */ try { linux_target->low_prepare_to_resume (lp); } catch (const gdb_exception_error &ex) { if (!check_ptrace_stopped_lwp_gone (lp)) throw; } detach_one_pid (lwpid, signo); delete_lwp (lp->ptid); } static int detach_callback (struct lwp_info *lp) { /* We don't actually detach from the thread group leader just yet. If the thread group exits, we must reap the zombie clone lwps before we're able to reap the leader. */ if (lp->ptid.lwp () != lp->ptid.pid ()) detach_one_lwp (lp, NULL); return 0; } void linux_nat_target::detach (inferior *inf, int from_tty) { LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT; struct lwp_info *main_lwp; int pid = inf->pid; /* Don't unregister from the event loop, as there may be other inferiors running. */ /* Stop all threads before detaching. ptrace requires that the thread is stopped to successfully detach. */ iterate_over_lwps (ptid_t (pid), stop_callback); /* ... and wait until all of them have reported back that they're no longer running. */ iterate_over_lwps (ptid_t (pid), stop_wait_callback); /* We can now safely remove breakpoints. We don't this in earlier in common code because this target doesn't currently support writing memory while the inferior is running. */ remove_breakpoints_inf (current_inferior ()); iterate_over_lwps (ptid_t (pid), detach_callback); /* Only the initial process should be left right now. */ gdb_assert (num_lwps (pid) == 1); main_lwp = find_lwp_pid (ptid_t (pid)); if (forks_exist_p ()) { /* Multi-fork case. The current inferior_ptid is being detached from, but there are other viable forks to debug. Detach from the current fork, and context-switch to the first available. */ linux_fork_detach (from_tty); } else { target_announce_detach (from_tty); /* Pass on any pending signal for the last LWP. */ int signo = get_detach_signal (main_lwp); detach_one_lwp (main_lwp, &signo); detach_success (inf); } close_proc_mem_file (pid); } /* Resume execution of the inferior process. If STEP is nonzero, single-step it. If SIGNAL is nonzero, give it that signal. */ static void linux_resume_one_lwp_throw (struct lwp_info *lp, int step, enum gdb_signal signo) { lp->step = step; /* stop_pc doubles as the PC the LWP had when it was last resumed. We only presently need that if the LWP is stepped though (to handle the case of stepping a breakpoint instruction). */ if (step) { struct regcache *regcache = get_thread_regcache (linux_target, lp->ptid); lp->stop_pc = regcache_read_pc (regcache); } else lp->stop_pc = 0; linux_target->low_prepare_to_resume (lp); linux_target->low_resume (lp->ptid, step, signo); /* Successfully resumed. Clear state that no longer makes sense, and mark the LWP as running. Must not do this before resuming otherwise if that fails other code will be confused. E.g., we'd later try to stop the LWP and hang forever waiting for a stop status. Note that we must not throw after this is cleared, otherwise handle_zombie_lwp_error would get confused. */ lp->stopped = 0; lp->core = -1; lp->stop_reason = TARGET_STOPPED_BY_NO_REASON; registers_changed_ptid (linux_target, lp->ptid); } /* Called when we try to resume a stopped LWP and that errors out. If the LWP is no longer in ptrace-stopped state (meaning it's zombie, or about to become), discard the error, clear any pending status the LWP may have, and return true (we'll collect the exit status soon enough). Otherwise, return false. */ static int check_ptrace_stopped_lwp_gone (struct lwp_info *lp) { /* If we get an error after resuming the LWP successfully, we'd confuse !T state for the LWP being gone. */ gdb_assert (lp->stopped); /* We can't just check whether the LWP is in 'Z (Zombie)' state, because even if ptrace failed with ESRCH, the tracee may be "not yet fully dead", but already refusing ptrace requests. In that case the tracee has 'R (Running)' state for a little bit (observed in Linux 3.18). See also the note on ESRCH in the ptrace(2) man page. Instead, check whether the LWP has any state other than ptrace-stopped. */ /* Don't assume anything if /proc/PID/status can't be read. */ if (linux_proc_pid_is_trace_stopped_nowarn (lp->ptid.lwp ()) == 0) { lp->stop_reason = TARGET_STOPPED_BY_NO_REASON; lp->status = 0; lp->waitstatus.set_ignore (); return 1; } return 0; } /* Like linux_resume_one_lwp_throw, but no error is thrown if the LWP disappears while we try to resume it. */ static void linux_resume_one_lwp (struct lwp_info *lp, int step, enum gdb_signal signo) { try { linux_resume_one_lwp_throw (lp, step, signo); } catch (const gdb_exception_error &ex) { if (!check_ptrace_stopped_lwp_gone (lp)) throw; } } /* Resume LP. */ static void resume_lwp (struct lwp_info *lp, int step, enum gdb_signal signo) { if (lp->stopped) { struct inferior *inf = find_inferior_ptid (linux_target, lp->ptid); if (inf->vfork_child != NULL) { linux_nat_debug_printf ("Not resuming sibling %s (vfork parent)", lp->ptid.to_string ().c_str ()); } else if (!lwp_status_pending_p (lp)) { linux_nat_debug_printf ("Resuming sibling %s, %s, %s", lp->ptid.to_string ().c_str (), (signo != GDB_SIGNAL_0 ? strsignal (gdb_signal_to_host (signo)) : "0"), step ? "step" : "resume"); linux_resume_one_lwp (lp, step, signo); } else { linux_nat_debug_printf ("Not resuming sibling %s (has pending)", lp->ptid.to_string ().c_str ()); } } else linux_nat_debug_printf ("Not resuming sibling %s (not stopped)", lp->ptid.to_string ().c_str ()); } /* Callback for iterate_over_lwps. If LWP is EXCEPT, do nothing. Resume LWP with the last stop signal, if it is in pass state. */ static int linux_nat_resume_callback (struct lwp_info *lp, struct lwp_info *except) { enum gdb_signal signo = GDB_SIGNAL_0; if (lp == except) return 0; if (lp->stopped) { struct thread_info *thread; thread = linux_target->find_thread (lp->ptid); if (thread != NULL) { signo = thread->stop_signal (); thread->set_stop_signal (GDB_SIGNAL_0); } } resume_lwp (lp, 0, signo); return 0; } static int resume_clear_callback (struct lwp_info *lp) { lp->resumed = 0; lp->last_resume_kind = resume_stop; return 0; } static int resume_set_callback (struct lwp_info *lp) { lp->resumed = 1; lp->last_resume_kind = resume_continue; return 0; } void linux_nat_target::resume (ptid_t scope_ptid, int step, enum gdb_signal signo) { struct lwp_info *lp; linux_nat_debug_printf ("Preparing to %s %s, %s, inferior_ptid %s", step ? "step" : "resume", scope_ptid.to_string ().c_str (), (signo != GDB_SIGNAL_0 ? strsignal (gdb_signal_to_host (signo)) : "0"), inferior_ptid.to_string ().c_str ()); /* Mark the lwps we're resuming as resumed and update their last_resume_kind to resume_continue. */ iterate_over_lwps (scope_ptid, resume_set_callback); lp = find_lwp_pid (inferior_ptid); gdb_assert (lp != NULL); /* Remember if we're stepping. */ lp->last_resume_kind = step ? resume_step : resume_continue; /* If we have a pending wait status for this thread, there is no point in resuming the process. But first make sure that linux_nat_wait won't preemptively handle the event - we should never take this short-circuit if we are going to leave LP running, since we have skipped resuming all the other threads. This bit of code needs to be synchronized with linux_nat_wait. */ if (lp->status && WIFSTOPPED (lp->status)) { if (!lp->step && WSTOPSIG (lp->status) && sigismember (&pass_mask, WSTOPSIG (lp->status))) { linux_nat_debug_printf ("Not short circuiting for ignored status 0x%x", lp->status); /* FIXME: What should we do if we are supposed to continue this thread with a signal? */ gdb_assert (signo == GDB_SIGNAL_0); signo = gdb_signal_from_host (WSTOPSIG (lp->status)); lp->status = 0; } } if (lwp_status_pending_p (lp)) { /* FIXME: What should we do if we are supposed to continue this thread with a signal? */ gdb_assert (signo == GDB_SIGNAL_0); linux_nat_debug_printf ("Short circuiting for status %s", pending_status_str (lp).c_str ()); if (target_can_async_p ()) { target_async (true); /* Tell the event loop we have something to process. */ async_file_mark (); } return; } /* No use iterating unless we're resuming other threads. */ if (scope_ptid != lp->ptid) iterate_over_lwps (scope_ptid, [=] (struct lwp_info *info) { return linux_nat_resume_callback (info, lp); }); linux_nat_debug_printf ("%s %s, %s (resume event thread)", step ? "PTRACE_SINGLESTEP" : "PTRACE_CONT", lp->ptid.to_string ().c_str (), (signo != GDB_SIGNAL_0 ? strsignal (gdb_signal_to_host (signo)) : "0")); linux_resume_one_lwp (lp, step, signo); } /* Send a signal to an LWP. */ static int kill_lwp (int lwpid, int signo) { int ret; errno = 0; ret = syscall (__NR_tkill, lwpid, signo); if (errno == ENOSYS) { /* If tkill fails, then we are not using nptl threads, a configuration we no longer support. */ perror_with_name (("tkill")); } return ret; } /* Handle a GNU/Linux syscall trap wait response. If we see a syscall event, check if the core is interested in it: if not, ignore the event, and keep waiting; otherwise, we need to toggle the LWP's syscall entry/exit status, since the ptrace event itself doesn't indicate it, and report the trap to higher layers. */ static int linux_handle_syscall_trap (struct lwp_info *lp, int stopping) { struct target_waitstatus *ourstatus = &lp->waitstatus; struct gdbarch *gdbarch = target_thread_architecture (lp->ptid); thread_info *thread = linux_target->find_thread (lp->ptid); int syscall_number = (int) gdbarch_get_syscall_number (gdbarch, thread); if (stopping) { /* If we're stopping threads, there's a SIGSTOP pending, which makes it so that the LWP reports an immediate syscall return, followed by the SIGSTOP. Skip seeing that "return" using PTRACE_CONT directly, and let stop_wait_callback collect the SIGSTOP. Later when the thread is resumed, a new syscall entry event. If we didn't do this (and returned 0), we'd leave a syscall entry pending, and our caller, by using PTRACE_CONT to collect the SIGSTOP, skips the syscall return itself. Later, when the user re-resumes this LWP, we'd see another syscall entry event and we'd mistake it for a return. If stop_wait_callback didn't force the SIGSTOP out of the LWP (leaving immediately with LWP->signalled set, without issuing a PTRACE_CONT), it would still be problematic to leave this syscall enter pending, as later when the thread is resumed, it would then see the same syscall exit mentioned above, followed by the delayed SIGSTOP, while the syscall didn't actually get to execute. It seems it would be even more confusing to the user. */ linux_nat_debug_printf ("ignoring syscall %d for LWP %ld (stopping threads), resuming with " "PTRACE_CONT for SIGSTOP", syscall_number, lp->ptid.lwp ()); lp->syscall_state = TARGET_WAITKIND_IGNORE; ptrace (PTRACE_CONT, lp->ptid.lwp (), 0, 0); lp->stopped = 0; return 1; } /* Always update the entry/return state, even if this particular syscall isn't interesting to the core now. In async mode, the user could install a new catchpoint for this syscall between syscall enter/return, and we'll need to know to report a syscall return if that happens. */ lp->syscall_state = (lp->syscall_state == TARGET_WAITKIND_SYSCALL_ENTRY ? TARGET_WAITKIND_SYSCALL_RETURN : TARGET_WAITKIND_SYSCALL_ENTRY); if (catch_syscall_enabled ()) { if (catching_syscall_number (syscall_number)) { /* Alright, an event to report. */ if (lp->syscall_state == TARGET_WAITKIND_SYSCALL_ENTRY) ourstatus->set_syscall_entry (syscall_number); else if (lp->syscall_state == TARGET_WAITKIND_SYSCALL_RETURN) ourstatus->set_syscall_return (syscall_number); else gdb_assert_not_reached ("unexpected syscall state"); linux_nat_debug_printf ("stopping for %s of syscall %d for LWP %ld", (lp->syscall_state == TARGET_WAITKIND_SYSCALL_ENTRY ? "entry" : "return"), syscall_number, lp->ptid.lwp ()); return 0; } linux_nat_debug_printf ("ignoring %s of syscall %d for LWP %ld", (lp->syscall_state == TARGET_WAITKIND_SYSCALL_ENTRY ? "entry" : "return"), syscall_number, lp->ptid.lwp ()); } else { /* If we had been syscall tracing, and hence used PT_SYSCALL before on this LWP, it could happen that the user removes all syscall catchpoints before we get to process this event. There are two noteworthy issues here: - When stopped at a syscall entry event, resuming with PT_STEP still resumes executing the syscall and reports a syscall return. - Only PT_SYSCALL catches syscall enters. If we last single-stepped this thread, then this event can't be a syscall enter. If we last single-stepped this thread, this has to be a syscall exit. The points above mean that the next resume, be it PT_STEP or PT_CONTINUE, can not trigger a syscall trace event. */ linux_nat_debug_printf ("caught syscall event with no syscall catchpoints. %d for LWP %ld, " "ignoring", syscall_number, lp->ptid.lwp ()); lp->syscall_state = TARGET_WAITKIND_IGNORE; } /* The core isn't interested in this event. For efficiency, avoid stopping all threads only to have the core resume them all again. Since we're not stopping threads, if we're still syscall tracing and not stepping, we can't use PTRACE_CONT here, as we'd miss any subsequent syscall. Simply resume using the inf-ptrace layer, which knows when to use PT_SYSCALL or PT_CONTINUE. */ linux_resume_one_lwp (lp, lp->step, GDB_SIGNAL_0); return 1; } /* Handle a GNU/Linux extended wait response. If we see a clone event, we need to add the new LWP to our list (and not report the trap to higher layers). This function returns non-zero if the event should be ignored and we should wait again. If STOPPING is true, the new LWP remains stopped, otherwise it is continued. */ static int linux_handle_extended_wait (struct lwp_info *lp, int status) { int pid = lp->ptid.lwp (); struct target_waitstatus *ourstatus = &lp->waitstatus; int event = linux_ptrace_get_extended_event (status); /* All extended events we currently use are mid-syscall. Only PTRACE_EVENT_STOP is delivered more like a signal-stop, but you have to be using PTRACE_SEIZE to get that. */ lp->syscall_state = TARGET_WAITKIND_SYSCALL_ENTRY; if (event == PTRACE_EVENT_FORK || event == PTRACE_EVENT_VFORK || event == PTRACE_EVENT_CLONE) { unsigned long new_pid; int ret; ptrace (PTRACE_GETEVENTMSG, pid, 0, &new_pid); /* If we haven't already seen the new PID stop, wait for it now. */ if (! pull_pid_from_list (&stopped_pids, new_pid, &status)) { /* The new child has a pending SIGSTOP. We can't affect it until it hits the SIGSTOP, but we're already attached. */ ret = my_waitpid (new_pid, &status, __WALL); if (ret == -1) perror_with_name (_("waiting for new child")); else if (ret != new_pid) internal_error (_("wait returned unexpected PID %d"), ret); else if (!WIFSTOPPED (status)) internal_error (_("wait returned unexpected status 0x%x"), status); } ptid_t child_ptid (new_pid, new_pid); if (event == PTRACE_EVENT_FORK || event == PTRACE_EVENT_VFORK) { open_proc_mem_file (child_ptid); /* The arch-specific native code may need to know about new forks even if those end up never mapped to an inferior. */ linux_target->low_new_fork (lp, new_pid); } else if (event == PTRACE_EVENT_CLONE) { linux_target->low_new_clone (lp, new_pid); } if (event == PTRACE_EVENT_FORK && linux_fork_checkpointing_p (lp->ptid.pid ())) { /* Handle checkpointing by linux-fork.c here as a special case. We don't want the follow-fork-mode or 'catch fork' to interfere with this. */ /* This won't actually modify the breakpoint list, but will physically remove the breakpoints from the child. */ detach_breakpoints (ptid_t (new_pid, new_pid)); /* Retain child fork in ptrace (stopped) state. */ if (!find_fork_pid (new_pid)) add_fork (new_pid); /* Report as spurious, so that infrun doesn't want to follow this fork. We're actually doing an infcall in linux-fork.c. */ ourstatus->set_spurious (); /* Report the stop to the core. */ return 0; } if (event == PTRACE_EVENT_FORK) ourstatus->set_forked (child_ptid); else if (event == PTRACE_EVENT_VFORK) ourstatus->set_vforked (child_ptid); else if (event == PTRACE_EVENT_CLONE) { struct lwp_info *new_lp; ourstatus->set_ignore (); linux_nat_debug_printf ("Got clone event from LWP %d, new child is LWP %ld", pid, new_pid); new_lp = add_lwp (ptid_t (lp->ptid.pid (), new_pid)); new_lp->stopped = 1; new_lp->resumed = 1; /* If the thread_db layer is active, let it record the user level thread id and status, and add the thread to GDB's list. */ if (!thread_db_notice_clone (lp->ptid, new_lp->ptid)) { /* The process is not using thread_db. Add the LWP to GDB's list. */ add_thread (linux_target, new_lp->ptid); } /* Even if we're stopping the thread for some reason internal to this module, from the perspective of infrun and the user/frontend, this new thread is running until it next reports a stop. */ set_running (linux_target, new_lp->ptid, true); set_executing (linux_target, new_lp->ptid, true); if (WSTOPSIG (status) != SIGSTOP) { /* This can happen if someone starts sending signals to the new thread before it gets a chance to run, which have a lower number than SIGSTOP (e.g. SIGUSR1). This is an unlikely case, and harder to handle for fork / vfork than for clone, so we do not try - but we handle it for clone events here. */ new_lp->signalled = 1; /* We created NEW_LP so it cannot yet contain STATUS. */ gdb_assert (new_lp->status == 0); /* Save the wait status to report later. */ linux_nat_debug_printf ("waitpid of new LWP %ld, saving status %s", (long) new_lp->ptid.lwp (), status_to_str (status).c_str ()); new_lp->status = status; } else if (report_thread_events) { new_lp->waitstatus.set_thread_created (); new_lp->status = status; } return 1; } return 0; } if (event == PTRACE_EVENT_EXEC) { linux_nat_debug_printf ("Got exec event from LWP %ld", lp->ptid.lwp ()); /* Close the previous /proc/PID/mem file for this inferior, which was using the address space which is now gone. Reading/writing from this file would return 0/EOF. */ close_proc_mem_file (lp->ptid.pid ()); /* Open a new file for the new address space. */ open_proc_mem_file (lp->ptid); ourstatus->set_execd (make_unique_xstrdup (linux_proc_pid_to_exec_file (pid))); /* The thread that execed must have been resumed, but, when a thread execs, it changes its tid to the tgid, and the old tgid thread might have not been resumed. */ lp->resumed = 1; return 0; } if (event == PTRACE_EVENT_VFORK_DONE) { linux_nat_debug_printf ("Got PTRACE_EVENT_VFORK_DONE from LWP %ld", lp->ptid.lwp ()); ourstatus->set_vfork_done (); return 0; } internal_error (_("unknown ptrace event %d"), event); } /* Suspend waiting for a signal. We're mostly interested in SIGCHLD/SIGINT. */ static void wait_for_signal () { linux_nat_debug_printf ("about to sigsuspend"); sigsuspend (&suspend_mask); /* If the quit flag is set, it means that the user pressed Ctrl-C and we're debugging a process that is running on a separate terminal, so we must forward the Ctrl-C to the inferior. (If the inferior is sharing GDB's terminal, then the Ctrl-C reaches the inferior directly.) We must do this here because functions that need to block waiting for a signal loop forever until there's an event to report before returning back to the event loop. */ if (!target_terminal::is_ours ()) { if (check_quit_flag ()) target_pass_ctrlc (); } } /* Wait for LP to stop. Returns the wait status, or 0 if the LWP has exited. */ static int wait_lwp (struct lwp_info *lp) { pid_t pid; int status = 0; int thread_dead = 0; sigset_t prev_mask; gdb_assert (!lp->stopped); gdb_assert (lp->status == 0); /* Make sure SIGCHLD is blocked for sigsuspend avoiding a race below. */ block_child_signals (&prev_mask); for (;;) { pid = my_waitpid (lp->ptid.lwp (), &status, __WALL | WNOHANG); if (pid == -1 && errno == ECHILD) { /* The thread has previously exited. We need to delete it now because if this was a non-leader thread execing, we won't get an exit event. See comments on exec events at the top of the file. */ thread_dead = 1; linux_nat_debug_printf ("%s vanished.", lp->ptid.to_string ().c_str ()); } if (pid != 0) break; /* Bugs 10970, 12702. Thread group leader may have exited in which case we'll lock up in waitpid if there are other threads, even if they are all zombies too. Basically, we're not supposed to use waitpid this way. tkill(pid,0) cannot be used here as it gets ESRCH for both for zombie and running processes. As a workaround, check if we're waiting for the thread group leader and if it's a zombie, and avoid calling waitpid if it is. This is racy, what if the tgl becomes a zombie right after we check? Therefore always use WNOHANG with sigsuspend - it is equivalent to waiting waitpid but linux_proc_pid_is_zombie is safe this way. */ if (lp->ptid.pid () == lp->ptid.lwp () && linux_proc_pid_is_zombie (lp->ptid.lwp ())) { thread_dead = 1; linux_nat_debug_printf ("Thread group leader %s vanished.", lp->ptid.to_string ().c_str ()); break; } /* Wait for next SIGCHLD and try again. This may let SIGCHLD handlers get invoked despite our caller had them intentionally blocked by block_child_signals. This is sensitive only to the loop of linux_nat_wait_1 and there if we get called my_waitpid gets called again before it gets to sigsuspend so we can safely let the handlers get executed here. */ wait_for_signal (); } restore_child_signals_mask (&prev_mask); if (!thread_dead) { gdb_assert (pid == lp->ptid.lwp ()); linux_nat_debug_printf ("waitpid %s received %s", lp->ptid.to_string ().c_str (), status_to_str (status).c_str ()); /* Check if the thread has exited. */ if (WIFEXITED (status) || WIFSIGNALED (status)) { if (report_thread_events || lp->ptid.pid () == lp->ptid.lwp ()) { linux_nat_debug_printf ("LWP %d exited.", lp->ptid.pid ()); /* If this is the leader exiting, it means the whole process is gone. Store the status to report to the core. Store it in lp->waitstatus, because lp->status would be ambiguous (W_EXITCODE(0,0) == 0). */ lp->waitstatus = host_status_to_waitstatus (status); return 0; } thread_dead = 1; linux_nat_debug_printf ("%s exited.", lp->ptid.to_string ().c_str ()); } } if (thread_dead) { exit_lwp (lp); return 0; } gdb_assert (WIFSTOPPED (status)); lp->stopped = 1; if (lp->must_set_ptrace_flags) { inferior *inf = find_inferior_pid (linux_target, lp->ptid.pid ()); int options = linux_nat_ptrace_options (inf->attach_flag); linux_enable_event_reporting (lp->ptid.lwp (), options); lp->must_set_ptrace_flags = 0; } /* Handle GNU/Linux's syscall SIGTRAPs. */ if (WIFSTOPPED (status) && WSTOPSIG (status) == SYSCALL_SIGTRAP) { /* No longer need the sysgood bit. The ptrace event ends up recorded in lp->waitstatus if we care for it. We can carry on handling the event like a regular SIGTRAP from here on. */ status = W_STOPCODE (SIGTRAP); if (linux_handle_syscall_trap (lp, 1)) return wait_lwp (lp); } else { /* Almost all other ptrace-stops are known to be outside of system calls, with further exceptions in linux_handle_extended_wait. */ lp->syscall_state = TARGET_WAITKIND_IGNORE; } /* Handle GNU/Linux's extended waitstatus for trace events. */ if (WIFSTOPPED (status) && WSTOPSIG (status) == SIGTRAP && linux_is_extended_waitstatus (status)) { linux_nat_debug_printf ("Handling extended status 0x%06x", status); linux_handle_extended_wait (lp, status); return 0; } return status; } /* Send a SIGSTOP to LP. */ static int stop_callback (struct lwp_info *lp) { if (!lp->stopped && !lp->signalled) { int ret; linux_nat_debug_printf ("kill %s ****", lp->ptid.to_string ().c_str ()); errno = 0; ret = kill_lwp (lp->ptid.lwp (), SIGSTOP); linux_nat_debug_printf ("lwp kill %d %s", ret, errno ? safe_strerror (errno) : "ERRNO-OK"); lp->signalled = 1; gdb_assert (lp->status == 0); } return 0; } /* Request a stop on LWP. */ void linux_stop_lwp (struct lwp_info *lwp) { stop_callback (lwp); } /* See linux-nat.h */ void linux_stop_and_wait_all_lwps (void) { /* Stop all LWP's ... */ iterate_over_lwps (minus_one_ptid, stop_callback); /* ... and wait until all of them have reported back that they're no longer running. */ iterate_over_lwps (minus_one_ptid, stop_wait_callback); } /* See linux-nat.h */ void linux_unstop_all_lwps (void) { iterate_over_lwps (minus_one_ptid, [] (struct lwp_info *info) { return resume_stopped_resumed_lwps (info, minus_one_ptid); }); } /* Return non-zero if LWP PID has a pending SIGINT. */ static int linux_nat_has_pending_sigint (int pid) { sigset_t pending, blocked, ignored; linux_proc_pending_signals (pid, &pending, &blocked, &ignored); if (sigismember (&pending, SIGINT) && !sigismember (&ignored, SIGINT)) return 1; return 0; } /* Set a flag in LP indicating that we should ignore its next SIGINT. */ static int set_ignore_sigint (struct lwp_info *lp) { /* If a thread has a pending SIGINT, consume it; otherwise, set a flag to consume the next one. */ if (lp->stopped && lp->status != 0 && WIFSTOPPED (lp->status) && WSTOPSIG (lp->status) == SIGINT) lp->status = 0; else lp->ignore_sigint = 1; return 0; } /* If LP does not have a SIGINT pending, then clear the ignore_sigint flag. This function is called after we know the LWP has stopped; if the LWP stopped before the expected SIGINT was delivered, then it will never have arrived. Also, if the signal was delivered to a shared queue and consumed by a different thread, it will never be delivered to this LWP. */ static void maybe_clear_ignore_sigint (struct lwp_info *lp) { if (!lp->ignore_sigint) return; if (!linux_nat_has_pending_sigint (lp->ptid.lwp ())) { linux_nat_debug_printf ("Clearing bogus flag for %s", lp->ptid.to_string ().c_str ()); lp->ignore_sigint = 0; } } /* Fetch the possible triggered data watchpoint info and store it in LP. On some archs, like x86, that use debug registers to set watchpoints, it's possible that the way to know which watched address trapped, is to check the register that is used to select which address to watch. Problem is, between setting the watchpoint and reading back which data address trapped, the user may change the set of watchpoints, and, as a consequence, GDB changes the debug registers in the inferior. To avoid reading back a stale stopped-data-address when that happens, we cache in LP the fact that a watchpoint trapped, and the corresponding data address, as soon as we see LP stop with a SIGTRAP. If GDB changes the debug registers meanwhile, we have the cached data we can rely on. */ static int check_stopped_by_watchpoint (struct lwp_info *lp) { scoped_restore save_inferior_ptid = make_scoped_restore (&inferior_ptid); inferior_ptid = lp->ptid; if (linux_target->low_stopped_by_watchpoint ()) { lp->stop_reason = TARGET_STOPPED_BY_WATCHPOINT; lp->stopped_data_address_p = linux_target->low_stopped_data_address (&lp->stopped_data_address); } return lp->stop_reason == TARGET_STOPPED_BY_WATCHPOINT; } /* Returns true if the LWP had stopped for a watchpoint. */ bool linux_nat_target::stopped_by_watchpoint () { struct lwp_info *lp = find_lwp_pid (inferior_ptid); gdb_assert (lp != NULL); return lp->stop_reason == TARGET_STOPPED_BY_WATCHPOINT; } bool linux_nat_target::stopped_data_address (CORE_ADDR *addr_p) { struct lwp_info *lp = find_lwp_pid (inferior_ptid); gdb_assert (lp != NULL); *addr_p = lp->stopped_data_address; return lp->stopped_data_address_p; } /* Commonly any breakpoint / watchpoint generate only SIGTRAP. */ bool linux_nat_target::low_status_is_event (int status) { return WIFSTOPPED (status) && WSTOPSIG (status) == SIGTRAP; } /* Wait until LP is stopped. */ static int stop_wait_callback (struct lwp_info *lp) { inferior *inf = find_inferior_ptid (linux_target, lp->ptid); /* If this is a vfork parent, bail out, it is not going to report any SIGSTOP until the vfork is done with. */ if (inf->vfork_child != NULL) return 0; if (!lp->stopped) { int status; status = wait_lwp (lp); if (status == 0) return 0; if (lp->ignore_sigint && WIFSTOPPED (status) && WSTOPSIG (status) == SIGINT) { lp->ignore_sigint = 0; errno = 0; ptrace (PTRACE_CONT, lp->ptid.lwp (), 0, 0); lp->stopped = 0; linux_nat_debug_printf ("PTRACE_CONT %s, 0, 0 (%s) (discarding SIGINT)", lp->ptid.to_string ().c_str (), errno ? safe_strerror (errno) : "OK"); return stop_wait_callback (lp); } maybe_clear_ignore_sigint (lp); if (WSTOPSIG (status) != SIGSTOP) { /* The thread was stopped with a signal other than SIGSTOP. */ linux_nat_debug_printf ("Pending event %s in %s", status_to_str ((int) status).c_str (), lp->ptid.to_string ().c_str ()); /* Save the sigtrap event. */ lp->status = status; gdb_assert (lp->signalled); save_stop_reason (lp); } else { /* We caught the SIGSTOP that we intended to catch. */ linux_nat_debug_printf ("Expected SIGSTOP caught for %s.", lp->ptid.to_string ().c_str ()); lp->signalled = 0; /* If we are waiting for this stop so we can report the thread stopped then we need to record this status. Otherwise, we can now discard this stop event. */ if (lp->last_resume_kind == resume_stop) { lp->status = status; save_stop_reason (lp); } } } return 0; } /* Return non-zero if LP has a wait status pending. Discard the pending event and resume the LWP if the event that originally caused the stop became uninteresting. */ static int status_callback (struct lwp_info *lp) { /* Only report a pending wait status if we pretend that this has indeed been resumed. */ if (!lp->resumed) return 0; if (!lwp_status_pending_p (lp)) return 0; if (lp->stop_reason == TARGET_STOPPED_BY_SW_BREAKPOINT || lp->stop_reason == TARGET_STOPPED_BY_HW_BREAKPOINT) { struct regcache *regcache = get_thread_regcache (linux_target, lp->ptid); CORE_ADDR pc; int discard = 0; pc = regcache_read_pc (regcache); if (pc != lp->stop_pc) { linux_nat_debug_printf ("PC of %s changed. was=%s, now=%s", lp->ptid.to_string ().c_str (), paddress (current_inferior ()->arch (), lp->stop_pc), paddress (current_inferior ()->arch (), pc)); discard = 1; } #if !USE_SIGTRAP_SIGINFO else if (!breakpoint_inserted_here_p (regcache->aspace (), pc)) { linux_nat_debug_printf ("previous breakpoint of %s, at %s gone", lp->ptid.to_string ().c_str (), paddress (current_inferior ()->arch (), lp->stop_pc)); discard = 1; } #endif if (discard) { linux_nat_debug_printf ("pending event of %s cancelled.", lp->ptid.to_string ().c_str ()); lp->status = 0; linux_resume_one_lwp (lp, lp->step, GDB_SIGNAL_0); return 0; } } return 1; } /* Count the LWP's that have had events. */ static int count_events_callback (struct lwp_info *lp, int *count) { gdb_assert (count != NULL); /* Select only resumed LWPs that have an event pending. */ if (lp->resumed && lwp_status_pending_p (lp)) (*count)++; return 0; } /* Select the LWP (if any) that is currently being single-stepped. */ static int select_singlestep_lwp_callback (struct lwp_info *lp) { if (lp->last_resume_kind == resume_step && lp->status != 0) return 1; else return 0; } /* Returns true if LP has a status pending. */ static int lwp_status_pending_p (struct lwp_info *lp) { /* We check for lp->waitstatus in addition to lp->status, because we can have pending process exits recorded in lp->status and W_EXITCODE(0,0) happens to be 0. */ return lp->status != 0 || lp->waitstatus.kind () != TARGET_WAITKIND_IGNORE; } /* Select the Nth LWP that has had an event. */ static int select_event_lwp_callback (struct lwp_info *lp, int *selector) { gdb_assert (selector != NULL); /* Select only resumed LWPs that have an event pending. */ if (lp->resumed && lwp_status_pending_p (lp)) if ((*selector)-- == 0) return 1; return 0; } /* Called when the LWP stopped for a signal/trap. If it stopped for a trap check what caused it (breakpoint, watchpoint, trace, etc.), and save the result in the LWP's stop_reason field. If it stopped for a breakpoint, decrement the PC if necessary on the lwp's architecture. */ static void save_stop_reason (struct lwp_info *lp) { struct regcache *regcache; struct gdbarch *gdbarch; CORE_ADDR pc; CORE_ADDR sw_bp_pc; #if USE_SIGTRAP_SIGINFO siginfo_t siginfo; #endif gdb_assert (lp->stop_reason == TARGET_STOPPED_BY_NO_REASON); gdb_assert (lp->status != 0); if (!linux_target->low_status_is_event (lp->status)) return; inferior *inf = find_inferior_ptid (linux_target, lp->ptid); if (inf->starting_up) return; regcache = get_thread_regcache (linux_target, lp->ptid); gdbarch = regcache->arch (); pc = regcache_read_pc (regcache); sw_bp_pc = pc - gdbarch_decr_pc_after_break (gdbarch); #if USE_SIGTRAP_SIGINFO if (linux_nat_get_siginfo (lp->ptid, &siginfo)) { if (siginfo.si_signo == SIGTRAP) { if (GDB_ARCH_IS_TRAP_BRKPT (siginfo.si_code) && GDB_ARCH_IS_TRAP_HWBKPT (siginfo.si_code)) { /* The si_code is ambiguous on this arch -- check debug registers. */ if (!check_stopped_by_watchpoint (lp)) lp->stop_reason = TARGET_STOPPED_BY_SW_BREAKPOINT; } else if (GDB_ARCH_IS_TRAP_BRKPT (siginfo.si_code)) { /* If we determine the LWP stopped for a SW breakpoint, trust it. Particularly don't check watchpoint registers, because, at least on s390, we'd find stopped-by-watchpoint as long as there's a watchpoint set. */ lp->stop_reason = TARGET_STOPPED_BY_SW_BREAKPOINT; } else if (GDB_ARCH_IS_TRAP_HWBKPT (siginfo.si_code)) { /* This can indicate either a hardware breakpoint or hardware watchpoint. Check debug registers. */ if (!check_stopped_by_watchpoint (lp)) lp->stop_reason = TARGET_STOPPED_BY_HW_BREAKPOINT; } else if (siginfo.si_code == TRAP_TRACE) { linux_nat_debug_printf ("%s stopped by trace", lp->ptid.to_string ().c_str ()); /* We may have single stepped an instruction that triggered a watchpoint. In that case, on some architectures (such as x86), instead of TRAP_HWBKPT, si_code indicates TRAP_TRACE, and we need to check the debug registers separately. */ check_stopped_by_watchpoint (lp); } } } #else if ((!lp->step || lp->stop_pc == sw_bp_pc) && software_breakpoint_inserted_here_p (regcache->aspace (), sw_bp_pc)) { /* The LWP was either continued, or stepped a software breakpoint instruction. */ lp->stop_reason = TARGET_STOPPED_BY_SW_BREAKPOINT; } if (hardware_breakpoint_inserted_here_p (regcache->aspace (), pc)) lp->stop_reason = TARGET_STOPPED_BY_HW_BREAKPOINT; if (lp->stop_reason == TARGET_STOPPED_BY_NO_REASON) check_stopped_by_watchpoint (lp); #endif if (lp->stop_reason == TARGET_STOPPED_BY_SW_BREAKPOINT) { linux_nat_debug_printf ("%s stopped by software breakpoint", lp->ptid.to_string ().c_str ()); /* Back up the PC if necessary. */ if (pc != sw_bp_pc) regcache_write_pc (regcache, sw_bp_pc); /* Update this so we record the correct stop PC below. */ pc = sw_bp_pc; } else if (lp->stop_reason == TARGET_STOPPED_BY_HW_BREAKPOINT) { linux_nat_debug_printf ("%s stopped by hardware breakpoint", lp->ptid.to_string ().c_str ()); } else if (lp->stop_reason == TARGET_STOPPED_BY_WATCHPOINT) { linux_nat_debug_printf ("%s stopped by hardware watchpoint", lp->ptid.to_string ().c_str ()); } lp->stop_pc = pc; } /* Returns true if the LWP had stopped for a software breakpoint. */ bool linux_nat_target::stopped_by_sw_breakpoint () { struct lwp_info *lp = find_lwp_pid (inferior_ptid); gdb_assert (lp != NULL); return lp->stop_reason == TARGET_STOPPED_BY_SW_BREAKPOINT; } /* Implement the supports_stopped_by_sw_breakpoint method. */ bool linux_nat_target::supports_stopped_by_sw_breakpoint () { return USE_SIGTRAP_SIGINFO; } /* Returns true if the LWP had stopped for a hardware breakpoint/watchpoint. */ bool linux_nat_target::stopped_by_hw_breakpoint () { struct lwp_info *lp = find_lwp_pid (inferior_ptid); gdb_assert (lp != NULL); return lp->stop_reason == TARGET_STOPPED_BY_HW_BREAKPOINT; } /* Implement the supports_stopped_by_hw_breakpoint method. */ bool linux_nat_target::supports_stopped_by_hw_breakpoint () { return USE_SIGTRAP_SIGINFO; } /* Select one LWP out of those that have events pending. */ static void select_event_lwp (ptid_t filter, struct lwp_info **orig_lp, int *status) { int num_events = 0; int random_selector; struct lwp_info *event_lp = NULL; /* Record the wait status for the original LWP. */ (*orig_lp)->status = *status; /* In all-stop, give preference to the LWP that is being single-stepped. There will be at most one, and it will be the LWP that the core is most interested in. If we didn't do this, then we'd have to handle pending step SIGTRAPs somehow in case the core later continues the previously-stepped thread, as otherwise we'd report the pending SIGTRAP then, and the core, not having stepped the thread, wouldn't understand what the trap was for, and therefore would report it to the user as a random signal. */ if (!target_is_non_stop_p ()) { event_lp = iterate_over_lwps (filter, select_singlestep_lwp_callback); if (event_lp != NULL) { linux_nat_debug_printf ("Select single-step %s", event_lp->ptid.to_string ().c_str ()); } } if (event_lp == NULL) { /* Pick one at random, out of those which have had events. */ /* First see how many events we have. */ iterate_over_lwps (filter, [&] (struct lwp_info *info) { return count_events_callback (info, &num_events); }); gdb_assert (num_events > 0); /* Now randomly pick a LWP out of those that have had events. */ random_selector = (int) ((num_events * (double) rand ()) / (RAND_MAX + 1.0)); if (num_events > 1) linux_nat_debug_printf ("Found %d events, selecting #%d", num_events, random_selector); event_lp = (iterate_over_lwps (filter, [&] (struct lwp_info *info) { return select_event_lwp_callback (info, &random_selector); })); } if (event_lp != NULL) { /* Switch the event LWP. */ *orig_lp = event_lp; *status = event_lp->status; } /* Flush the wait status for the event LWP. */ (*orig_lp)->status = 0; } /* Return non-zero if LP has been resumed. */ static int resumed_callback (struct lwp_info *lp) { return lp->resumed; } /* Check if we should go on and pass this event to common code. If so, save the status to the lwp_info structure associated to LWPID. */ static void linux_nat_filter_event (int lwpid, int status) { struct lwp_info *lp; int event = linux_ptrace_get_extended_event (status); lp = find_lwp_pid (ptid_t (lwpid)); /* Check for events reported by anything not in our LWP list. */ if (lp == nullptr) { if (WIFSTOPPED (status)) { if (WSTOPSIG (status) == SIGTRAP && event == PTRACE_EVENT_EXEC) { /* A non-leader thread exec'ed after we've seen the leader zombie, and removed it from our lists (in check_zombie_leaders). The non-leader thread changes its tid to the tgid. */ linux_nat_debug_printf ("Re-adding thread group leader LWP %d after exec.", lwpid); lp = add_lwp (ptid_t (lwpid, lwpid)); lp->stopped = 1; lp->resumed = 1; add_thread (linux_target, lp->ptid); } else { /* A process we are controlling has forked and the new child's stop was reported to us by the kernel. Save its PID and go back to waiting for the fork event to be reported - the stopped process might be returned from waitpid before or after the fork event is. */ linux_nat_debug_printf ("Saving LWP %d status %s in stopped_pids list", lwpid, status_to_str (status).c_str ()); add_to_pid_list (&stopped_pids, lwpid, status); } } else { /* Don't report an event for the exit of an LWP not in our list, i.e. not part of any inferior we're debugging. This can happen if we detach from a program we originally forked and then it exits. However, note that we may have earlier deleted a leader of an inferior we're debugging, in check_zombie_leaders. Re-add it back here if so. */ for (inferior *inf : all_inferiors (linux_target)) { if (inf->pid == lwpid) { linux_nat_debug_printf ("Re-adding thread group leader LWP %d after exit.", lwpid); lp = add_lwp (ptid_t (lwpid, lwpid)); lp->resumed = 1; add_thread (linux_target, lp->ptid); break; } } } if (lp == nullptr) return; } /* This LWP is stopped now. (And if dead, this prevents it from ever being continued.) */ lp->stopped = 1; if (WIFSTOPPED (status) && lp->must_set_ptrace_flags) { inferior *inf = find_inferior_pid (linux_target, lp->ptid.pid ()); int options = linux_nat_ptrace_options (inf->attach_flag); linux_enable_event_reporting (lp->ptid.lwp (), options); lp->must_set_ptrace_flags = 0; } /* Handle GNU/Linux's syscall SIGTRAPs. */ if (WIFSTOPPED (status) && WSTOPSIG (status) == SYSCALL_SIGTRAP) { /* No longer need the sysgood bit. The ptrace event ends up recorded in lp->waitstatus if we care for it. We can carry on handling the event like a regular SIGTRAP from here on. */ status = W_STOPCODE (SIGTRAP); if (linux_handle_syscall_trap (lp, 0)) return; } else { /* Almost all other ptrace-stops are known to be outside of system calls, with further exceptions in linux_handle_extended_wait. */ lp->syscall_state = TARGET_WAITKIND_IGNORE; } /* Handle GNU/Linux's extended waitstatus for trace events. */ if (WIFSTOPPED (status) && WSTOPSIG (status) == SIGTRAP && linux_is_extended_waitstatus (status)) { linux_nat_debug_printf ("Handling extended status 0x%06x", status); if (linux_handle_extended_wait (lp, status)) return; } /* Check if the thread has exited. */ if (WIFEXITED (status) || WIFSIGNALED (status)) { if (!report_thread_events && !is_leader (lp)) { linux_nat_debug_printf ("%s exited.", lp->ptid.to_string ().c_str ()); /* If this was not the leader exiting, then the exit signal was not the end of the debugged application and should be ignored. */ exit_lwp (lp); return; } /* Note that even if the leader was ptrace-stopped, it can still exit, if e.g., some other thread brings down the whole process (calls `exit'). So don't assert that the lwp is resumed. */ linux_nat_debug_printf ("LWP %ld exited (resumed=%d)", lp->ptid.lwp (), lp->resumed); /* Dead LWP's aren't expected to reported a pending sigstop. */ lp->signalled = 0; /* Store the pending event in the waitstatus, because W_EXITCODE(0,0) == 0. */ lp->waitstatus = host_status_to_waitstatus (status); return; } /* Make sure we don't report a SIGSTOP that we sent ourselves in an attempt to stop an LWP. */ if (lp->signalled && WIFSTOPPED (status) && WSTOPSIG (status) == SIGSTOP) { lp->signalled = 0; if (lp->last_resume_kind == resume_stop) { linux_nat_debug_printf ("resume_stop SIGSTOP caught for %s.", lp->ptid.to_string ().c_str ()); } else { /* This is a delayed SIGSTOP. Filter out the event. */ linux_nat_debug_printf ("%s %s, 0, 0 (discard delayed SIGSTOP)", lp->step ? "PTRACE_SINGLESTEP" : "PTRACE_CONT", lp->ptid.to_string ().c_str ()); linux_resume_one_lwp (lp, lp->step, GDB_SIGNAL_0); gdb_assert (lp->resumed); return; } } /* Make sure we don't report a SIGINT that we have already displayed for another thread. */ if (lp->ignore_sigint && WIFSTOPPED (status) && WSTOPSIG (status) == SIGINT) { linux_nat_debug_printf ("Delayed SIGINT caught for %s.", lp->ptid.to_string ().c_str ()); /* This is a delayed SIGINT. */ lp->ignore_sigint = 0; linux_resume_one_lwp (lp, lp->step, GDB_SIGNAL_0); linux_nat_debug_printf ("%s %s, 0, 0 (discard SIGINT)", lp->step ? "PTRACE_SINGLESTEP" : "PTRACE_CONT", lp->ptid.to_string ().c_str ()); gdb_assert (lp->resumed); /* Discard the event. */ return; } /* Don't report signals that GDB isn't interested in, such as signals that are neither printed nor stopped upon. Stopping all threads can be a bit time-consuming, so if we want decent performance with heavily multi-threaded programs, especially when they're using a high frequency timer, we'd better avoid it if we can. */ if (WIFSTOPPED (status)) { enum gdb_signal signo = gdb_signal_from_host (WSTOPSIG (status)); if (!target_is_non_stop_p ()) { /* Only do the below in all-stop, as we currently use SIGSTOP to implement target_stop (see linux_nat_stop) in non-stop. */ if (signo == GDB_SIGNAL_INT && signal_pass_state (signo) == 0) { /* If ^C/BREAK is typed at the tty/console, SIGINT gets forwarded to the entire process group, that is, all LWPs will receive it - unless they're using CLONE_THREAD to share signals. Since we only want to report it once, we mark it as ignored for all LWPs except this one. */ iterate_over_lwps (ptid_t (lp->ptid.pid ()), set_ignore_sigint); lp->ignore_sigint = 0; } else maybe_clear_ignore_sigint (lp); } /* When using hardware single-step, we need to report every signal. Otherwise, signals in pass_mask may be short-circuited except signals that might be caused by a breakpoint, or SIGSTOP if we sent the SIGSTOP and are waiting for it to arrive. */ if (!lp->step && WSTOPSIG (status) && sigismember (&pass_mask, WSTOPSIG (status)) && (WSTOPSIG (status) != SIGSTOP || !linux_target->find_thread (lp->ptid)->stop_requested) && !linux_wstatus_maybe_breakpoint (status)) { linux_resume_one_lwp (lp, lp->step, signo); linux_nat_debug_printf ("%s %s, %s (preempt 'handle')", lp->step ? "PTRACE_SINGLESTEP" : "PTRACE_CONT", lp->ptid.to_string ().c_str (), (signo != GDB_SIGNAL_0 ? strsignal (gdb_signal_to_host (signo)) : "0")); return; } } /* An interesting event. */ gdb_assert (lp); lp->status = status; save_stop_reason (lp); } /* Detect zombie thread group leaders, and "exit" them. We can't reap their exits until all other threads in the group have exited. */ static void check_zombie_leaders (void) { for (inferior *inf : all_inferiors ()) { struct lwp_info *leader_lp; if (inf->pid == 0) continue; leader_lp = find_lwp_pid (ptid_t (inf->pid)); if (leader_lp != NULL /* Check if there are other threads in the group, as we may have raced with the inferior simply exiting. Note this isn't a watertight check. If the inferior is multi-threaded and is exiting, it may be we see the leader as zombie before we reap all the non-leader threads. See comments below. */ && num_lwps (inf->pid) > 1 && linux_proc_pid_is_zombie (inf->pid)) { /* A zombie leader in a multi-threaded program can mean one of three things: #1 - Only the leader exited, not the whole program, e.g., with pthread_exit. Since we can't reap the leader's exit status until all other threads are gone and reaped too, we want to delete the zombie leader right away, as it can't be debugged, we can't read its registers, etc. This is the main reason we check for zombie leaders disappearing. #2 - The whole thread-group/process exited (a group exit, via e.g. exit(3), and there is (or will be shortly) an exit reported for each thread in the process, and then finally an exit for the leader once the non-leaders are reaped. #3 - There are 3 or more threads in the group, and a thread other than the leader exec'd. See comments on exec events at the top of the file. Ideally we would never delete the leader for case #2. Instead, we want to collect the exit status of each non-leader thread, and then finally collect the exit status of the leader as normal and use its exit code as whole-process exit code. Unfortunately, there's no race-free way to distinguish cases #1 and #2. We can't assume the exit events for the non-leaders threads are already pending in the kernel, nor can we assume the non-leader threads are in zombie state already. Between the leader becoming zombie and the non-leaders exiting and becoming zombie themselves, there's a small time window, so such a check would be racy. Temporarily pausing all threads and checking to see if all threads exit or not before re-resuming them would work in the case that all threads are running right now, but it wouldn't work if some thread is currently already ptrace-stopped, e.g., due to scheduler-locking. So what we do is we delete the leader anyhow, and then later on when we see its exit status, we re-add it back. We also make sure that we only report a whole-process exit when we see the leader exiting, as opposed to when the last LWP in the LWP list exits, which can be a non-leader if we deleted the leader here. */ linux_nat_debug_printf ("Thread group leader %d zombie " "(it exited, or another thread execd), " "deleting it.", inf->pid); exit_lwp (leader_lp); } } } /* Convenience function that is called when the kernel reports an exit event. This decides whether to report the event to GDB as a process exit event, a thread exit event, or to suppress the event. */ static ptid_t filter_exit_event (struct lwp_info *event_child, struct target_waitstatus *ourstatus) { ptid_t ptid = event_child->ptid; if (!is_leader (event_child)) { if (report_thread_events) ourstatus->set_thread_exited (0); else ourstatus->set_ignore (); exit_lwp (event_child); } return ptid; } static ptid_t linux_nat_wait_1 (ptid_t ptid, struct target_waitstatus *ourstatus, target_wait_flags target_options) { LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT; sigset_t prev_mask; enum resume_kind last_resume_kind; struct lwp_info *lp; int status; /* The first time we get here after starting a new inferior, we may not have added it to the LWP list yet - this is the earliest moment at which we know its PID. */ if (ptid.is_pid () && find_lwp_pid (ptid) == nullptr) { ptid_t lwp_ptid (ptid.pid (), ptid.pid ()); /* Upgrade the main thread's ptid. */ thread_change_ptid (linux_target, ptid, lwp_ptid); lp = add_initial_lwp (lwp_ptid); lp->resumed = 1; } /* Make sure SIGCHLD is blocked until the sigsuspend below. */ block_child_signals (&prev_mask); /* First check if there is a LWP with a wait status pending. */ lp = iterate_over_lwps (ptid, status_callback); if (lp != NULL) { linux_nat_debug_printf ("Using pending wait status %s for %s.", pending_status_str (lp).c_str (), lp->ptid.to_string ().c_str ()); } /* But if we don't find a pending event, we'll have to wait. Always pull all events out of the kernel. We'll randomly select an event LWP out of all that have events, to prevent starvation. */ while (lp == NULL) { pid_t lwpid; /* Always use -1 and WNOHANG, due to couple of a kernel/ptrace quirks: - If the thread group leader exits while other threads in the thread group still exist, waitpid(TGID, ...) hangs. That waitpid won't return an exit status until the other threads in the group are reaped. - When a non-leader thread execs, that thread just vanishes without reporting an exit (so we'd hang if we waited for it explicitly in that case). The exec event is reported to the TGID pid. */ errno = 0; lwpid = my_waitpid (-1, &status, __WALL | WNOHANG); linux_nat_debug_printf ("waitpid(-1, ...) returned %d, %s", lwpid, errno ? safe_strerror (errno) : "ERRNO-OK"); if (lwpid > 0) { linux_nat_debug_printf ("waitpid %ld received %s", (long) lwpid, status_to_str (status).c_str ()); linux_nat_filter_event (lwpid, status); /* Retry until nothing comes out of waitpid. A single SIGCHLD can indicate more than one child stopped. */ continue; } /* Now that we've pulled all events out of the kernel, resume LWPs that don't have an interesting event to report. */ iterate_over_lwps (minus_one_ptid, [] (struct lwp_info *info) { return resume_stopped_resumed_lwps (info, minus_one_ptid); }); /* ... and find an LWP with a status to report to the core, if any. */ lp = iterate_over_lwps (ptid, status_callback); if (lp != NULL) break; /* Check for zombie thread group leaders. Those can't be reaped until all other threads in the thread group are. */ check_zombie_leaders (); /* If there are no resumed children left, bail. We'd be stuck forever in the sigsuspend call below otherwise. */ if (iterate_over_lwps (ptid, resumed_callback) == NULL) { linux_nat_debug_printf ("exit (no resumed LWP)"); ourstatus->set_no_resumed (); restore_child_signals_mask (&prev_mask); return minus_one_ptid; } /* No interesting event to report to the core. */ if (target_options & TARGET_WNOHANG) { linux_nat_debug_printf ("no interesting events found"); ourstatus->set_ignore (); restore_child_signals_mask (&prev_mask); return minus_one_ptid; } /* We shouldn't end up here unless we want to try again. */ gdb_assert (lp == NULL); /* Block until we get an event reported with SIGCHLD. */ wait_for_signal (); } gdb_assert (lp); status = lp->status; lp->status = 0; if (!target_is_non_stop_p ()) { /* Now stop all other LWP's ... */ iterate_over_lwps (minus_one_ptid, stop_callback); /* ... and wait until all of them have reported back that they're no longer running. */ iterate_over_lwps (minus_one_ptid, stop_wait_callback); } /* If we're not waiting for a specific LWP, choose an event LWP from among those that have had events. Giving equal priority to all LWPs that have had events helps prevent starvation. */ if (ptid == minus_one_ptid || ptid.is_pid ()) select_event_lwp (ptid, &lp, &status); gdb_assert (lp != NULL); /* Now that we've selected our final event LWP, un-adjust its PC if it was a software breakpoint, and we can't reliably support the "stopped by software breakpoint" stop reason. */ if (lp->stop_reason == TARGET_STOPPED_BY_SW_BREAKPOINT && !USE_SIGTRAP_SIGINFO) { struct regcache *regcache = get_thread_regcache (linux_target, lp->ptid); struct gdbarch *gdbarch = regcache->arch (); int decr_pc = gdbarch_decr_pc_after_break (gdbarch); if (decr_pc != 0) { CORE_ADDR pc; pc = regcache_read_pc (regcache); regcache_write_pc (regcache, pc + decr_pc); } } /* We'll need this to determine whether to report a SIGSTOP as GDB_SIGNAL_0. Need to take a copy because resume_clear_callback clears it. */ last_resume_kind = lp->last_resume_kind; if (!target_is_non_stop_p ()) { /* In all-stop, from the core's perspective, all LWPs are now stopped until a new resume action is sent over. */ iterate_over_lwps (minus_one_ptid, resume_clear_callback); } else { resume_clear_callback (lp); } if (linux_target->low_status_is_event (status)) { linux_nat_debug_printf ("trap ptid is %s.", lp->ptid.to_string ().c_str ()); } if (lp->waitstatus.kind () != TARGET_WAITKIND_IGNORE) { *ourstatus = lp->waitstatus; lp->waitstatus.set_ignore (); } else *ourstatus = host_status_to_waitstatus (status); linux_nat_debug_printf ("event found"); restore_child_signals_mask (&prev_mask); if (last_resume_kind == resume_stop && ourstatus->kind () == TARGET_WAITKIND_STOPPED && WSTOPSIG (status) == SIGSTOP) { /* A thread that has been requested to stop by GDB with target_stop, and it stopped cleanly, so report as SIG0. The use of SIGSTOP is an implementation detail. */ ourstatus->set_stopped (GDB_SIGNAL_0); } if (ourstatus->kind () == TARGET_WAITKIND_EXITED || ourstatus->kind () == TARGET_WAITKIND_SIGNALLED) lp->core = -1; else lp->core = linux_common_core_of_thread (lp->ptid); if (ourstatus->kind () == TARGET_WAITKIND_EXITED) return filter_exit_event (lp, ourstatus); return lp->ptid; } /* Resume LWPs that are currently stopped without any pending status to report, but are resumed from the core's perspective. */ static int resume_stopped_resumed_lwps (struct lwp_info *lp, const ptid_t wait_ptid) { inferior *inf = find_inferior_ptid (linux_target, lp->ptid); if (!lp->stopped) { linux_nat_debug_printf ("NOT resuming LWP %s, not stopped", lp->ptid.to_string ().c_str ()); } else if (!lp->resumed) { linux_nat_debug_printf ("NOT resuming LWP %s, not resumed", lp->ptid.to_string ().c_str ()); } else if (lwp_status_pending_p (lp)) { linux_nat_debug_printf ("NOT resuming LWP %s, has pending status", lp->ptid.to_string ().c_str ()); } else if (inf->vfork_child != nullptr) { linux_nat_debug_printf ("NOT resuming LWP %s (vfork parent)", lp->ptid.to_string ().c_str ()); } else { struct regcache *regcache = get_thread_regcache (linux_target, lp->ptid); struct gdbarch *gdbarch = regcache->arch (); try { CORE_ADDR pc = regcache_read_pc (regcache); int leave_stopped = 0; /* Don't bother if there's a breakpoint at PC that we'd hit immediately, and we're not waiting for this LWP. */ if (!lp->ptid.matches (wait_ptid)) { if (breakpoint_inserted_here_p (regcache->aspace (), pc)) leave_stopped = 1; } if (!leave_stopped) { linux_nat_debug_printf ("resuming stopped-resumed LWP %s at %s: step=%d", lp->ptid.to_string ().c_str (), paddress (gdbarch, pc), lp->step); linux_resume_one_lwp_throw (lp, lp->step, GDB_SIGNAL_0); } } catch (const gdb_exception_error &ex) { if (!check_ptrace_stopped_lwp_gone (lp)) throw; } } return 0; } ptid_t linux_nat_target::wait (ptid_t ptid, struct target_waitstatus *ourstatus, target_wait_flags target_options) { LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT; ptid_t event_ptid; linux_nat_debug_printf ("[%s], [%s]", ptid.to_string ().c_str (), target_options_to_string (target_options).c_str ()); /* Flush the async file first. */ if (target_is_async_p ()) async_file_flush (); /* Resume LWPs that are currently stopped without any pending status to report, but are resumed from the core's perspective. LWPs get in this state if we find them stopping at a time we're not interested in reporting the event (target_wait on a specific_process, for example, see linux_nat_wait_1), and meanwhile the event became uninteresting. Don't bother resuming LWPs we're not going to wait for if they'd stop immediately. */ if (target_is_non_stop_p ()) iterate_over_lwps (minus_one_ptid, [=] (struct lwp_info *info) { return resume_stopped_resumed_lwps (info, ptid); }); event_ptid = linux_nat_wait_1 (ptid, ourstatus, target_options); /* If we requested any event, and something came out, assume there may be more. If we requested a specific lwp or process, also assume there may be more. */ if (target_is_async_p () && ((ourstatus->kind () != TARGET_WAITKIND_IGNORE && ourstatus->kind () != TARGET_WAITKIND_NO_RESUMED) || ptid != minus_one_ptid)) async_file_mark (); return event_ptid; } /* Kill one LWP. */ static void kill_one_lwp (pid_t pid) { /* PTRACE_KILL may resume the inferior. Send SIGKILL first. */ errno = 0; kill_lwp (pid, SIGKILL); if (debug_linux_nat) { int save_errno = errno; linux_nat_debug_printf ("kill (SIGKILL) %ld, 0, 0 (%s)", (long) pid, save_errno != 0 ? safe_strerror (save_errno) : "OK"); } /* Some kernels ignore even SIGKILL for processes under ptrace. */ errno = 0; ptrace (PTRACE_KILL, pid, 0, 0); if (debug_linux_nat) { int save_errno = errno; linux_nat_debug_printf ("PTRACE_KILL %ld, 0, 0 (%s)", (long) pid, save_errno ? safe_strerror (save_errno) : "OK"); } } /* Wait for an LWP to die. */ static void kill_wait_one_lwp (pid_t pid) { pid_t res; /* We must make sure that there are no pending events (delayed SIGSTOPs, pending SIGTRAPs, etc.) to make sure the current program doesn't interfere with any following debugging session. */ do { res = my_waitpid (pid, NULL, __WALL); if (res != (pid_t) -1) { linux_nat_debug_printf ("wait %ld received unknown.", (long) pid); /* The Linux kernel sometimes fails to kill a thread completely after PTRACE_KILL; that goes from the stop point in do_fork out to the one in get_signal_to_deliver and waits again. So kill it again. */ kill_one_lwp (pid); } } while (res == pid); gdb_assert (res == -1 && errno == ECHILD); } /* Callback for iterate_over_lwps. */ static int kill_callback (struct lwp_info *lp) { kill_one_lwp (lp->ptid.lwp ()); return 0; } /* Callback for iterate_over_lwps. */ static int kill_wait_callback (struct lwp_info *lp) { kill_wait_one_lwp (lp->ptid.lwp ()); return 0; } /* Kill the fork children of any threads of inferior INF that are stopped at a fork event. */ static void kill_unfollowed_fork_children (struct inferior *inf) { for (thread_info *thread : inf->non_exited_threads ()) { struct target_waitstatus *ws = &thread->pending_follow; if (ws->kind () == TARGET_WAITKIND_FORKED || ws->kind () == TARGET_WAITKIND_VFORKED) { ptid_t child_ptid = ws->child_ptid (); int child_pid = child_ptid.pid (); int child_lwp = child_ptid.lwp (); kill_one_lwp (child_lwp); kill_wait_one_lwp (child_lwp); /* Let the arch-specific native code know this process is gone. */ linux_target->low_forget_process (child_pid); } } } void linux_nat_target::kill () { /* If we're stopped while forking and we haven't followed yet, kill the other task. We need to do this first because the parent will be sleeping if this is a vfork. */ kill_unfollowed_fork_children (current_inferior ()); if (forks_exist_p ()) linux_fork_killall (); else { ptid_t ptid = ptid_t (inferior_ptid.pid ()); /* Stop all threads before killing them, since ptrace requires that the thread is stopped to successfully PTRACE_KILL. */ iterate_over_lwps (ptid, stop_callback); /* ... and wait until all of them have reported back that they're no longer running. */ iterate_over_lwps (ptid, stop_wait_callback); /* Kill all LWP's ... */ iterate_over_lwps (ptid, kill_callback); /* ... and wait until we've flushed all events. */ iterate_over_lwps (ptid, kill_wait_callback); } target_mourn_inferior (inferior_ptid); } void linux_nat_target::mourn_inferior () { LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT; int pid = inferior_ptid.pid (); purge_lwp_list (pid); close_proc_mem_file (pid); if (! forks_exist_p ()) /* Normal case, no other forks available. */ inf_ptrace_target::mourn_inferior (); else /* Multi-fork case. The current inferior_ptid has exited, but there are other viable forks to debug. Delete the exiting one and context-switch to the first available. */ linux_fork_mourn_inferior (); /* Let the arch-specific native code know this process is gone. */ linux_target->low_forget_process (pid); } /* Convert a native/host siginfo object, into/from the siginfo in the layout of the inferiors' architecture. */ static void siginfo_fixup (siginfo_t *siginfo, gdb_byte *inf_siginfo, int direction) { /* If the low target didn't do anything, then just do a straight memcpy. */ if (!linux_target->low_siginfo_fixup (siginfo, inf_siginfo, direction)) { if (direction == 1) memcpy (siginfo, inf_siginfo, sizeof (siginfo_t)); else memcpy (inf_siginfo, siginfo, sizeof (siginfo_t)); } } static enum target_xfer_status linux_xfer_siginfo (ptid_t ptid, enum target_object object, const char *annex, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, ULONGEST len, ULONGEST *xfered_len) { siginfo_t siginfo; gdb_byte inf_siginfo[sizeof (siginfo_t)]; gdb_assert (object == TARGET_OBJECT_SIGNAL_INFO); gdb_assert (readbuf || writebuf); if (offset > sizeof (siginfo)) return TARGET_XFER_E_IO; if (!linux_nat_get_siginfo (ptid, &siginfo)) return TARGET_XFER_E_IO; /* When GDB is built as a 64-bit application, ptrace writes into SIGINFO an object with 64-bit layout. Since debugging a 32-bit inferior with a 64-bit GDB should look the same as debugging it with a 32-bit GDB, we need to convert it. GDB core always sees the converted layout, so any read/write will have to be done post-conversion. */ siginfo_fixup (&siginfo, inf_siginfo, 0); if (offset + len > sizeof (siginfo)) len = sizeof (siginfo) - offset; if (readbuf != NULL) memcpy (readbuf, inf_siginfo + offset, len); else { memcpy (inf_siginfo + offset, writebuf, len); /* Convert back to ptrace layout before flushing it out. */ siginfo_fixup (&siginfo, inf_siginfo, 1); int pid = get_ptrace_pid (ptid); errno = 0; ptrace (PTRACE_SETSIGINFO, pid, (PTRACE_TYPE_ARG3) 0, &siginfo); if (errno != 0) return TARGET_XFER_E_IO; } *xfered_len = len; return TARGET_XFER_OK; } static enum target_xfer_status linux_nat_xfer_osdata (enum target_object object, const char *annex, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, ULONGEST len, ULONGEST *xfered_len); static enum target_xfer_status linux_proc_xfer_memory_partial (int pid, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, LONGEST len, ULONGEST *xfered_len); enum target_xfer_status linux_nat_target::xfer_partial (enum target_object object, const char *annex, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, ULONGEST len, ULONGEST *xfered_len) { if (object == TARGET_OBJECT_SIGNAL_INFO) return linux_xfer_siginfo (inferior_ptid, object, annex, readbuf, writebuf, offset, len, xfered_len); /* The target is connected but no live inferior is selected. Pass this request down to a lower stratum (e.g., the executable file). */ if (object == TARGET_OBJECT_MEMORY && inferior_ptid == null_ptid) return TARGET_XFER_EOF; if (object == TARGET_OBJECT_AUXV) return memory_xfer_auxv (this, object, annex, readbuf, writebuf, offset, len, xfered_len); if (object == TARGET_OBJECT_OSDATA) return linux_nat_xfer_osdata (object, annex, readbuf, writebuf, offset, len, xfered_len); if (object == TARGET_OBJECT_MEMORY) { /* GDB calculates all addresses in the largest possible address width. The address width must be masked before its final use by linux_proc_xfer_partial. Compare ADDR_BIT first to avoid a compiler warning on shift overflow. */ int addr_bit = gdbarch_addr_bit (current_inferior ()->arch ()); if (addr_bit < (sizeof (ULONGEST) * HOST_CHAR_BIT)) offset &= ((ULONGEST) 1 << addr_bit) - 1; /* If /proc/pid/mem is writable, don't fallback to ptrace. If the write via /proc/pid/mem fails because the inferior execed (and we haven't seen the exec event yet), a subsequent ptrace poke would incorrectly write memory to the post-exec address space, while the core was trying to write to the pre-exec address space. */ if (proc_mem_file_is_writable ()) return linux_proc_xfer_memory_partial (inferior_ptid.pid (), readbuf, writebuf, offset, len, xfered_len); } return inf_ptrace_target::xfer_partial (object, annex, readbuf, writebuf, offset, len, xfered_len); } bool linux_nat_target::thread_alive (ptid_t ptid) { /* As long as a PTID is in lwp list, consider it alive. */ return find_lwp_pid (ptid) != NULL; } /* Implement the to_update_thread_list target method for this target. */ void linux_nat_target::update_thread_list () { /* We add/delete threads from the list as clone/exit events are processed, so just try deleting exited threads still in the thread list. */ delete_exited_threads (); /* Update the processor core that each lwp/thread was last seen running on. */ for (lwp_info *lwp : all_lwps ()) { /* Avoid accessing /proc if the thread hasn't run since we last time we fetched the thread's core. Accessing /proc becomes noticeably expensive when we have thousands of LWPs. */ if (lwp->core == -1) lwp->core = linux_common_core_of_thread (lwp->ptid); } } std::string linux_nat_target::pid_to_str (ptid_t ptid) { if (ptid.lwp_p () && (ptid.pid () != ptid.lwp () || num_lwps (ptid.pid ()) > 1)) return string_printf ("LWP %ld", ptid.lwp ()); return normal_pid_to_str (ptid); } const char * linux_nat_target::thread_name (struct thread_info *thr) { return linux_proc_tid_get_name (thr->ptid); } /* Accepts an integer PID; Returns a string representing a file that can be opened to get the symbols for the child process. */ const char * linux_nat_target::pid_to_exec_file (int pid) { return linux_proc_pid_to_exec_file (pid); } /* Object representing an /proc/PID/mem open file. We keep one such file open per inferior. It might be tempting to think about only ever opening one file at most for all inferiors, closing/reopening the file as we access memory of different inferiors, to minimize number of file descriptors open, which can otherwise run into resource limits. However, that does not work correctly -- if the inferior execs and we haven't processed the exec event yet, and, we opened a /proc/PID/mem file, we will get a mem file accessing the post-exec address space, thinking we're opening it for the pre-exec address space. That is dangerous as we can poke memory (e.g. clearing breakpoints) in the post-exec memory by mistake, corrupting the inferior. For that reason, we open the mem file as early as possible, right after spawning, forking or attaching to the inferior, when the inferior is stopped and thus before it has a chance of execing. Note that after opening the file, even if the thread we opened it for subsequently exits, the open file is still usable for accessing memory. It's only when the whole process exits or execs that the file becomes invalid, at which point reads/writes return EOF. */ class proc_mem_file { public: proc_mem_file (ptid_t ptid, int fd) : m_ptid (ptid), m_fd (fd) { gdb_assert (m_fd != -1); } ~proc_mem_file () { linux_nat_debug_printf ("closing fd %d for /proc/%d/task/%ld/mem", m_fd, m_ptid.pid (), m_ptid.lwp ()); close (m_fd); } DISABLE_COPY_AND_ASSIGN (proc_mem_file); int fd () { return m_fd; } private: /* The LWP this file was opened for. Just for debugging purposes. */ ptid_t m_ptid; /* The file descriptor. */ int m_fd = -1; }; /* The map between an inferior process id, and the open /proc/PID/mem file. This is stored in a map instead of in a per-inferior structure because we need to be able to access memory of processes which don't have a corresponding struct inferior object. E.g., with "detach-on-fork on" (the default), and "follow-fork parent" (also default), we don't create an inferior for the fork child, but we still need to remove breakpoints from the fork child's memory. */ static std::unordered_map proc_mem_file_map; /* Close the /proc/PID/mem file for PID. */ static void close_proc_mem_file (pid_t pid) { proc_mem_file_map.erase (pid); } /* Open the /proc/PID/mem file for the process (thread group) of PTID. We actually open /proc/PID/task/LWP/mem, as that's the LWP we know exists and is stopped right now. We prefer the /proc/PID/task/LWP/mem form over /proc/LWP/mem to avoid tid-reuse races, just in case this is ever called on an already-waited LWP. */ static void open_proc_mem_file (ptid_t ptid) { auto iter = proc_mem_file_map.find (ptid.pid ()); gdb_assert (iter == proc_mem_file_map.end ()); char filename[64]; xsnprintf (filename, sizeof filename, "/proc/%d/task/%ld/mem", ptid.pid (), ptid.lwp ()); int fd = gdb_open_cloexec (filename, O_RDWR | O_LARGEFILE, 0).release (); if (fd == -1) { warning (_("opening /proc/PID/mem file for lwp %d.%ld failed: %s (%d)"), ptid.pid (), ptid.lwp (), safe_strerror (errno), errno); return; } proc_mem_file_map.emplace (std::piecewise_construct, std::forward_as_tuple (ptid.pid ()), std::forward_as_tuple (ptid, fd)); linux_nat_debug_printf ("opened fd %d for lwp %d.%ld", fd, ptid.pid (), ptid.lwp ()); } /* Helper for linux_proc_xfer_memory_partial and proc_mem_file_is_writable. FD is the already opened /proc/pid/mem file, and PID is the pid of the corresponding process. The rest of the arguments are like linux_proc_xfer_memory_partial's. */ static enum target_xfer_status linux_proc_xfer_memory_partial_fd (int fd, int pid, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, LONGEST len, ULONGEST *xfered_len) { ssize_t ret; gdb_assert (fd != -1); /* Use pread64/pwrite64 if available, since they save a syscall and can handle 64-bit offsets even on 32-bit platforms (for instance, SPARC debugging a SPARC64 application). But only use them if the offset isn't so high that when cast to off_t it'd be negative, as seen on SPARC64. pread64/pwrite64 outright reject such offsets. lseek does not. */ #ifdef HAVE_PREAD64 if ((off_t) offset >= 0) ret = (readbuf != nullptr ? pread64 (fd, readbuf, len, offset) : pwrite64 (fd, writebuf, len, offset)); else #endif { ret = lseek (fd, offset, SEEK_SET); if (ret != -1) ret = (readbuf != nullptr ? read (fd, readbuf, len) : write (fd, writebuf, len)); } if (ret == -1) { linux_nat_debug_printf ("accessing fd %d for pid %d failed: %s (%d)", fd, pid, safe_strerror (errno), errno); return TARGET_XFER_E_IO; } else if (ret == 0) { /* EOF means the address space is gone, the whole process exited or execed. */ linux_nat_debug_printf ("accessing fd %d for pid %d got EOF", fd, pid); return TARGET_XFER_EOF; } else { *xfered_len = ret; return TARGET_XFER_OK; } } /* Implement the to_xfer_partial target method using /proc/PID/mem. Because we can use a single read/write call, this can be much more efficient than banging away at PTRACE_PEEKTEXT. Also, unlike PTRACE_PEEKTEXT/PTRACE_POKETEXT, this works with running threads. */ static enum target_xfer_status linux_proc_xfer_memory_partial (int pid, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, LONGEST len, ULONGEST *xfered_len) { auto iter = proc_mem_file_map.find (pid); if (iter == proc_mem_file_map.end ()) return TARGET_XFER_EOF; int fd = iter->second.fd (); return linux_proc_xfer_memory_partial_fd (fd, pid, readbuf, writebuf, offset, len, xfered_len); } /* Check whether /proc/pid/mem is writable in the current kernel, and return true if so. It wasn't writable before Linux 2.6.39, but there's no way to know whether the feature was backported to older kernels. So we check to see if it works. The result is cached, and this is guaranteed to be called once early during inferior startup, so that any warning is printed out consistently between GDB invocations. Note we don't call it during GDB startup instead though, because then we might warn with e.g. just "gdb --version" on sandboxed systems. See PR gdb/29907. */ static bool proc_mem_file_is_writable () { static gdb::optional writable; if (writable.has_value ()) return *writable; writable.emplace (false); /* We check whether /proc/pid/mem is writable by trying to write to one of our variables via /proc/self/mem. */ int fd = gdb_open_cloexec ("/proc/self/mem", O_RDWR | O_LARGEFILE, 0).release (); if (fd == -1) { warning (_("opening /proc/self/mem file failed: %s (%d)"), safe_strerror (errno), errno); return *writable; } SCOPE_EXIT { close (fd); }; /* This is the variable we try to write to. Note OFFSET below. */ volatile gdb_byte test_var = 0; gdb_byte writebuf[] = {0x55}; ULONGEST offset = (uintptr_t) &test_var; ULONGEST xfered_len; enum target_xfer_status res = linux_proc_xfer_memory_partial_fd (fd, getpid (), nullptr, writebuf, offset, 1, &xfered_len); if (res == TARGET_XFER_OK) { gdb_assert (xfered_len == 1); gdb_assert (test_var == 0x55); /* Success. */ *writable = true; } return *writable; } /* Parse LINE as a signal set and add its set bits to SIGS. */ static void add_line_to_sigset (const char *line, sigset_t *sigs) { int len = strlen (line) - 1; const char *p; int signum; if (line[len] != '\n') error (_("Could not parse signal set: %s"), line); p = line; signum = len * 4; while (len-- > 0) { int digit; if (*p >= '0' && *p <= '9') digit = *p - '0'; else if (*p >= 'a' && *p <= 'f') digit = *p - 'a' + 10; else error (_("Could not parse signal set: %s"), line); signum -= 4; if (digit & 1) sigaddset (sigs, signum + 1); if (digit & 2) sigaddset (sigs, signum + 2); if (digit & 4) sigaddset (sigs, signum + 3); if (digit & 8) sigaddset (sigs, signum + 4); p++; } } /* Find process PID's pending signals from /proc/pid/status and set SIGS to match. */ void linux_proc_pending_signals (int pid, sigset_t *pending, sigset_t *blocked, sigset_t *ignored) { char buffer[PATH_MAX], fname[PATH_MAX]; sigemptyset (pending); sigemptyset (blocked); sigemptyset (ignored); xsnprintf (fname, sizeof fname, "/proc/%d/status", pid); gdb_file_up procfile = gdb_fopen_cloexec (fname, "r"); if (procfile == NULL) error (_("Could not open %s"), fname); while (fgets (buffer, PATH_MAX, procfile.get ()) != NULL) { /* Normal queued signals are on the SigPnd line in the status file. However, 2.6 kernels also have a "shared" pending queue for delivering signals to a thread group, so check for a ShdPnd line also. Unfortunately some Red Hat kernels include the shared pending queue but not the ShdPnd status field. */ if (startswith (buffer, "SigPnd:\t")) add_line_to_sigset (buffer + 8, pending); else if (startswith (buffer, "ShdPnd:\t")) add_line_to_sigset (buffer + 8, pending); else if (startswith (buffer, "SigBlk:\t")) add_line_to_sigset (buffer + 8, blocked); else if (startswith (buffer, "SigIgn:\t")) add_line_to_sigset (buffer + 8, ignored); } } static enum target_xfer_status linux_nat_xfer_osdata (enum target_object object, const char *annex, gdb_byte *readbuf, const gdb_byte *writebuf, ULONGEST offset, ULONGEST len, ULONGEST *xfered_len) { gdb_assert (object == TARGET_OBJECT_OSDATA); *xfered_len = linux_common_xfer_osdata (annex, readbuf, offset, len); if (*xfered_len == 0) return TARGET_XFER_EOF; else return TARGET_XFER_OK; } std::vector linux_nat_target::static_tracepoint_markers_by_strid (const char *strid) { char s[IPA_CMD_BUF_SIZE]; int pid = inferior_ptid.pid (); std::vector markers; const char *p = s; ptid_t ptid = ptid_t (pid, 0); static_tracepoint_marker marker; /* Pause all */ target_stop (ptid); strcpy (s, "qTfSTM"); agent_run_command (pid, s, strlen (s) + 1); /* Unpause all. */ SCOPE_EXIT { target_continue_no_signal (ptid); }; while (*p++ == 'm') { do { parse_static_tracepoint_marker_definition (p, &p, &marker); if (strid == NULL || marker.str_id == strid) markers.push_back (std::move (marker)); } while (*p++ == ','); /* comma-separated list */ strcpy (s, "qTsSTM"); agent_run_command (pid, s, strlen (s) + 1); p = s; } return markers; } /* target_can_async_p implementation. */ bool linux_nat_target::can_async_p () { /* This flag should be checked in the common target.c code. */ gdb_assert (target_async_permitted); /* Otherwise, this targets is always able to support async mode. */ return true; } bool linux_nat_target::supports_non_stop () { return true; } /* to_always_non_stop_p implementation. */ bool linux_nat_target::always_non_stop_p () { return true; } bool linux_nat_target::supports_multi_process () { return true; } bool linux_nat_target::supports_disable_randomization () { return true; } /* SIGCHLD handler that serves two purposes: In non-stop/async mode, so we notice when any child changes state, and notify the event-loop; it allows us to use sigsuspend in linux_nat_wait_1 above to wait for the arrival of a SIGCHLD. */ static void sigchld_handler (int signo) { int old_errno = errno; if (debug_linux_nat) gdb_stdlog->write_async_safe ("sigchld\n", sizeof ("sigchld\n") - 1); if (signo == SIGCHLD) { /* Let the event loop know that there are events to handle. */ linux_nat_target::async_file_mark_if_open (); } errno = old_errno; } /* Callback registered with the target events file descriptor. */ static void handle_target_event (int error, gdb_client_data client_data) { inferior_event_handler (INF_REG_EVENT); } /* target_async implementation. */ void linux_nat_target::async (bool enable) { if (enable == is_async_p ()) return; /* Block child signals while we create/destroy the pipe, as their handler writes to it. */ gdb::block_signals blocker; if (enable) { if (!async_file_open ()) internal_error ("creating event pipe failed."); add_file_handler (async_wait_fd (), handle_target_event, NULL, "linux-nat"); /* There may be pending events to handle. Tell the event loop to poll them. */ async_file_mark (); } else { delete_file_handler (async_wait_fd ()); async_file_close (); } } /* Stop an LWP, and push a GDB_SIGNAL_0 stop status if no other event came out. */ static int linux_nat_stop_lwp (struct lwp_info *lwp) { if (!lwp->stopped) { linux_nat_debug_printf ("running -> suspending %s", lwp->ptid.to_string ().c_str ()); if (lwp->last_resume_kind == resume_stop) { linux_nat_debug_printf ("already stopping LWP %ld at GDB's request", lwp->ptid.lwp ()); return 0; } stop_callback (lwp); lwp->last_resume_kind = resume_stop; } else { /* Already known to be stopped; do nothing. */ if (debug_linux_nat) { if (linux_target->find_thread (lwp->ptid)->stop_requested) linux_nat_debug_printf ("already stopped/stop_requested %s", lwp->ptid.to_string ().c_str ()); else linux_nat_debug_printf ("already stopped/no stop_requested yet %s", lwp->ptid.to_string ().c_str ()); } } return 0; } void linux_nat_target::stop (ptid_t ptid) { LINUX_NAT_SCOPED_DEBUG_ENTER_EXIT; iterate_over_lwps (ptid, linux_nat_stop_lwp); } /* When requests are passed down from the linux-nat layer to the single threaded inf-ptrace layer, ptids of (lwpid,0,0) form are used. The address space pointer is stored in the inferior object, but the common code that is passed such ptid can't tell whether lwpid is a "main" process id or not (it assumes so). We reverse look up the "main" process id from the lwp here. */ struct address_space * linux_nat_target::thread_address_space (ptid_t ptid) { struct lwp_info *lwp; struct inferior *inf; int pid; if (ptid.lwp () == 0) { /* An (lwpid,0,0) ptid. Look up the lwp object to get at the tgid. */ lwp = find_lwp_pid (ptid); pid = lwp->ptid.pid (); } else { /* A (pid,lwpid,0) ptid. */ pid = ptid.pid (); } inf = find_inferior_pid (this, pid); gdb_assert (inf != NULL); return inf->aspace; } /* Return the cached value of the processor core for thread PTID. */ int linux_nat_target::core_of_thread (ptid_t ptid) { struct lwp_info *info = find_lwp_pid (ptid); if (info) return info->core; return -1; } /* Implementation of to_filesystem_is_local. */ bool linux_nat_target::filesystem_is_local () { struct inferior *inf = current_inferior (); if (inf->fake_pid_p || inf->pid == 0) return true; return linux_ns_same (inf->pid, LINUX_NS_MNT); } /* Convert the INF argument passed to a to_fileio_* method to a process ID suitable for passing to its corresponding linux_mntns_* function. If INF is non-NULL then the caller is requesting the filesystem seen by INF. If INF is NULL then the caller is requesting the filesystem seen by the GDB. We fall back to GDB's filesystem in the case that INF is non-NULL but its PID is unknown. */ static pid_t linux_nat_fileio_pid_of (struct inferior *inf) { if (inf == NULL || inf->fake_pid_p || inf->pid == 0) return getpid (); else return inf->pid; } /* Implementation of to_fileio_open. */ int linux_nat_target::fileio_open (struct inferior *inf, const char *filename, int flags, int mode, int warn_if_slow, fileio_error *target_errno) { int nat_flags; mode_t nat_mode; int fd; if (fileio_to_host_openflags (flags, &nat_flags) == -1 || fileio_to_host_mode (mode, &nat_mode) == -1) { *target_errno = FILEIO_EINVAL; return -1; } fd = linux_mntns_open_cloexec (linux_nat_fileio_pid_of (inf), filename, nat_flags, nat_mode); if (fd == -1) *target_errno = host_to_fileio_error (errno); return fd; } /* Implementation of to_fileio_readlink. */ gdb::optional linux_nat_target::fileio_readlink (struct inferior *inf, const char *filename, fileio_error *target_errno) { char buf[PATH_MAX]; int len; len = linux_mntns_readlink (linux_nat_fileio_pid_of (inf), filename, buf, sizeof (buf)); if (len < 0) { *target_errno = host_to_fileio_error (errno); return {}; } return std::string (buf, len); } /* Implementation of to_fileio_unlink. */ int linux_nat_target::fileio_unlink (struct inferior *inf, const char *filename, fileio_error *target_errno) { int ret; ret = linux_mntns_unlink (linux_nat_fileio_pid_of (inf), filename); if (ret == -1) *target_errno = host_to_fileio_error (errno); return ret; } /* Implementation of the to_thread_events method. */ void linux_nat_target::thread_events (int enable) { report_thread_events = enable; } linux_nat_target::linux_nat_target () { /* We don't change the stratum; this target will sit at process_stratum and thread_db will set at thread_stratum. This is a little strange, since this is a multi-threaded-capable target, but we want to be on the stack below thread_db, and we also want to be used for single-threaded processes. */ } /* See linux-nat.h. */ bool linux_nat_get_siginfo (ptid_t ptid, siginfo_t *siginfo) { int pid = get_ptrace_pid (ptid); return ptrace (PTRACE_GETSIGINFO, pid, (PTRACE_TYPE_ARG3) 0, siginfo) == 0; } /* See nat/linux-nat.h. */ ptid_t current_lwp_ptid (void) { gdb_assert (inferior_ptid.lwp_p ()); return inferior_ptid; } void _initialize_linux_nat (); void _initialize_linux_nat () { add_setshow_boolean_cmd ("linux-nat", class_maintenance, &debug_linux_nat, _("\ Set debugging of GNU/Linux native target."), _(" \ Show debugging of GNU/Linux native target."), _(" \ When on, print debug messages relating to the GNU/Linux native target."), nullptr, show_debug_linux_nat, &setdebuglist, &showdebuglist); add_setshow_boolean_cmd ("linux-namespaces", class_maintenance, &debug_linux_namespaces, _("\ Set debugging of GNU/Linux namespaces module."), _("\ Show debugging of GNU/Linux namespaces module."), _("\ Enables printf debugging output."), NULL, NULL, &setdebuglist, &showdebuglist); /* Install a SIGCHLD handler. */ sigchld_action.sa_handler = sigchld_handler; sigemptyset (&sigchld_action.sa_mask); sigchld_action.sa_flags = SA_RESTART; /* Make it the default. */ sigaction (SIGCHLD, &sigchld_action, NULL); /* Make sure we don't block SIGCHLD during a sigsuspend. */ gdb_sigmask (SIG_SETMASK, NULL, &suspend_mask); sigdelset (&suspend_mask, SIGCHLD); sigemptyset (&blocked_mask); lwp_lwpid_htab_create (); } /* FIXME: kettenis/2000-08-26: The stuff on this page is specific to the GNU/Linux Threads library and therefore doesn't really belong here. */ /* NPTL reserves the first two RT signals, but does not provide any way for the debugger to query the signal numbers - fortunately they don't change. */ static int lin_thread_signals[] = { __SIGRTMIN, __SIGRTMIN + 1 }; /* See linux-nat.h. */ unsigned int lin_thread_get_thread_signal_num (void) { return sizeof (lin_thread_signals) / sizeof (lin_thread_signals[0]); } /* See linux-nat.h. */ int lin_thread_get_thread_signal (unsigned int i) { gdb_assert (i < lin_thread_get_thread_signal_num ()); return lin_thread_signals[i]; }