fish-shell/src/proc.cpp

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// Utilities for keeping track of jobs, processes and subshells, as well as signal handling
// functions for tracking children. These functions do not themselves launch new processes, the exec
// library will call proc to create representations of the running jobs as needed.
//
// Some of the code in this file is based on code from the Glibc manual.
// IWYU pragma: no_include <__bit_reference>
#include "config.h"
#include <errno.h>
#include <signal.h>
#include <stdio.h>
#include <sys/wait.h>
#include <unistd.h>
#include <wchar.h>
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#include <wctype.h>
#if HAVE_TERM_H
#include <curses.h>
#include <term.h>
#elif HAVE_NCURSES_TERM_H
#include <ncurses/term.h>
#endif
#include <termios.h>
#ifdef HAVE_SIGINFO_H
#include <siginfo.h>
#endif
#ifdef HAVE_SYS_SELECT_H
#include <sys/select.h>
#endif
#include <sys/time.h> // IWYU pragma: keep
#include <sys/types.h>
#include <algorithm> // IWYU pragma: keep
#include <memory>
#include <utility>
#include <vector>
#include "common.h"
#include "event.h"
#include "fallback.h" // IWYU pragma: keep
#include "io.h"
#include "output.h"
#include "parse_tree.h"
#include "parser.h"
#include "proc.h"
#include "reader.h"
#include "sanity.h"
#include "signal.h"
#include "util.h"
#include "wutil.h" // IWYU pragma: keep
/// Size of buffer for reading buffered output.
#define BUFFER_SIZE 4096
/// Status of last process to exit.
static int last_status = 0;
/// The signals that signify crashes to us.
static const int crashsignals[] = {SIGABRT, SIGBUS, SIGFPE, SIGILL, SIGSEGV, SIGSYS};
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bool job_list_is_empty() {
ASSERT_IS_MAIN_THREAD();
return parser_t::principal_parser().job_list().empty();
}
void job_iterator_t::reset() {
this->current = job_list->begin();
this->end = job_list->end();
}
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job_iterator_t::job_iterator_t(job_list_t &jobs) : job_list(&jobs) { this->reset(); }
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job_iterator_t::job_iterator_t() : job_list(&parser_t::principal_parser().job_list()) {
ASSERT_IS_MAIN_THREAD();
this->reset();
}
size_t job_iterator_t::count() const { return this->job_list->size(); }
bool is_interactive_session = false;
bool is_subshell = false;
bool is_block = false;
bool is_breakpoint = false;
bool is_login = false;
int is_event = false;
int job_control_mode = JOB_CONTROL_INTERACTIVE;
int no_exec = 0;
static int is_interactive = -1;
static bool proc_had_barrier = false;
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bool shell_is_interactive() {
ASSERT_IS_MAIN_THREAD();
// is_interactive is statically initialized to -1. Ensure it has been dynamically set
// before we're called.
assert(is_interactive != -1);
return is_interactive > 0;
}
bool get_proc_had_barrier() {
ASSERT_IS_MAIN_THREAD();
return proc_had_barrier;
}
void set_proc_had_barrier(bool flag) {
ASSERT_IS_MAIN_THREAD();
proc_had_barrier = flag;
}
/// The event variable used to send all process event.
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static event_t event(0);
/// A stack containing the values of is_interactive. Used by proc_push_interactive and
/// proc_pop_interactive.
static std::vector<int> interactive_stack;
void proc_init() { proc_push_interactive(0); }
/// Remove job from list of jobs.
static int job_remove(job_t *j) {
ASSERT_IS_MAIN_THREAD();
return parser_t::principal_parser().job_remove(j);
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}
void job_t::promote() {
ASSERT_IS_MAIN_THREAD();
parser_t::principal_parser().job_promote(this);
}
void proc_destroy() {
job_list_t &jobs = parser_t::principal_parser().job_list();
while (!jobs.empty()) {
job_t *job = jobs.front().get();
debug(2, L"freeing leaked job %ls", job->command_wcstr());
job_remove(job);
}
}
void proc_set_last_status(int s) {
ASSERT_IS_MAIN_THREAD();
last_status = s;
}
int proc_get_last_status() { return last_status; }
// Basic thread safe job IDs. The vector consumed_job_ids has a true value wherever the job ID
// corresponding to that slot is in use. The job ID corresponding to slot 0 is 1.
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static owning_lock<std::vector<bool>> locked_consumed_job_ids;
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job_id_t acquire_job_id() {
auto consumed_job_ids = locked_consumed_job_ids.acquire();
// Find the index of the first 0 slot.
auto slot = std::find(consumed_job_ids->begin(), consumed_job_ids->end(), false);
if (slot != consumed_job_ids->end()) {
// We found a slot. Note that slot 0 corresponds to job ID 1.
*slot = true;
return (job_id_t)(slot - consumed_job_ids->begin() + 1);
}
// We did not find a slot; create a new slot. The size of the vector is now the job ID
// (since it is one larger than the slot).
consumed_job_ids->push_back(true);
return (job_id_t)consumed_job_ids->size();
}
void release_job_id(job_id_t jid) {
assert(jid > 0);
auto consumed_job_ids = locked_consumed_job_ids.acquire();
size_t slot = (size_t)(jid - 1), count = consumed_job_ids->size();
// Make sure this slot is within our vector and is currently set to consumed.
assert(slot < count);
assert(consumed_job_ids->at(slot) == true);
// Clear it and then resize the vector to eliminate unused trailing job IDs.
consumed_job_ids->at(slot) = false;
while (count--) {
if (consumed_job_ids->at(count)) break;
}
consumed_job_ids->resize(count + 1);
}
job_t *job_t::from_job_id(job_id_t id) {
ASSERT_IS_MAIN_THREAD();
return parser_t::principal_parser().job_get(id);
}
job_t *job_t::from_pid(pid_t pid) {
ASSERT_IS_MAIN_THREAD();
return parser_t::principal_parser().job_get_from_pid(pid);
}
/// Return true if all processes in the job have stopped or completed.
bool job_t::is_stopped() const {
for (const process_ptr_t &p : processes) {
if (!p->completed && !p->stopped) {
return false;
}
}
return true;
}
/// Return true if the last processes in the job has completed.
bool job_t::is_completed() const {
assert(!processes.empty());
for (const process_ptr_t &p : processes) {
if (!p->completed) {
return false;
}
}
return true;
}
bool job_t::job_chain_is_fully_constructed() const {
const job_t *cursor = this;
while (cursor) {
if (!cursor->is_constructed()) return false;
cursor = cursor->get_parent().get();
}
return true;
}
void job_t::set_flag(job_flag_t flag, bool set) { this->flags.set(flag, set); }
bool job_t::get_flag(job_flag_t flag) const { return this->flags.get(flag); }
bool job_t::signal(int signal) {
// Presumably we are distinguishing between the two cases below because we do
// not want to send ourselves the signal in question in case the job shares
// a pgid with the shell.
if (pgid != getpgrp()) {
if (killpg(pgid, signal) == -1) {
char buffer[512];
sprintf(buffer, "killpg(%d, %s)", pgid, strsignal(signal));
wperror(str2wcstring(buffer).c_str());
return false;
}
} else {
for (const auto &p : processes) {
if (!p->completed && p->pid && kill(p->pid, signal) == -1) {
return false;
}
}
}
return true;
}
static void mark_job_complete(const job_t *j) {
for (auto &p : j->processes) {
p->completed = 1;
}
}
/// Store the status of the process pid that was returned by waitpid.
static void mark_process_status(process_t *p, int status) {
// debug( 0, L"Process %ls %ls", p->argv[0], WIFSTOPPED (status)?L"stopped":(WIFEXITED( status
// )?L"exited":(WIFSIGNALED( status )?L"signaled to exit":L"BLARGH")) );
p->status = status;
if (WIFSTOPPED(status)) {
p->stopped = 1;
} else if (WIFSIGNALED(status) || WIFEXITED(status)) {
p->completed = 1;
} else {
// This should never be reached.
p->completed = 1;
debug(1, "Process %ld exited abnormally", (long)p->pid);
}
}
void job_mark_process_as_failed(const std::shared_ptr<job_t> &job, const process_t *failed_proc) {
// The given process failed to even lift off (e.g. posix_spawn failed) and so doesn't have a
// valid pid. Mark it and everything after it as dead.
bool found = false;
for (process_ptr_t &p : job->processes) {
found = found || (p.get() == failed_proc);
if (found) {
p->completed = true;
}
}
}
/// Handle status update for child \c pid.
///
/// \param pid the pid of the process whose status changes
/// \param status the status as returned by wait
static void handle_child_status(pid_t pid, int status) {
job_t *j = NULL;
const process_t *found_proc = NULL;
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job_iterator_t jobs;
while (!found_proc && (j = jobs.next())) {
process_t *prev = NULL;
for (process_ptr_t &p : j->processes) {
if (pid == p->pid) {
mark_process_status(p.get(), status);
found_proc = p.get();
break;
}
prev = p.get();
}
}
// If the child process was not killed by a signal or other than SIGINT or SIGQUIT we're done.
if (!WIFSIGNALED(status) || (WTERMSIG(status) != SIGINT && WTERMSIG(status) != SIGQUIT)) {
return;
}
if (is_interactive_session) {
// In an interactive session, tell the principal parser to skip all blocks we're executing
// so control-C returns control to the user.
if (found_proc) parser_t::skip_all_blocks();
} else {
// Deliver the SIGINT or SIGQUIT signal to ourself since we're not interactive.
struct sigaction act;
sigemptyset(&act.sa_mask);
act.sa_flags = 0;
act.sa_handler = SIG_DFL;
sigaction(SIGINT, &act, 0);
sigaction(SIGQUIT, &act, 0);
kill(getpid(), WTERMSIG(status));
}
}
process_t::process_t() {}
job_t::job_t(job_id_t jobid, io_chain_t bio, std::shared_ptr<job_t> parent)
: block_io(std::move(bio)),
parent_job(std::move(parent)),
pgid(INVALID_PID),
tmodes(),
job_id(jobid),
flags{} {}
job_t::~job_t() { release_job_id(job_id); }
/// Return all the IO redirections. Start with the block IO, then walk over the processes.
io_chain_t job_t::all_io_redirections() const {
io_chain_t result = this->block_io;
for (const process_ptr_t &p : this->processes) {
result.append(p->io_chain());
}
return result;
}
typedef unsigned int process_generation_count_t;
/// A list of pids/pgids that have been disowned. They are kept around until either they exit or
/// we exit. Poll these from time-to-time to prevent zombie processes from happening (#5342).
static std::vector<pid_t> s_disowned_pids;
void add_disowned_pgid(pid_t pgid) {
// NEVER add our own (or an invalid) pgid as they are not unique to only
// one job, and may result in a deadlock if we attempt the wait.
if (pgid != getpgrp() && pgid > 0) {
// waitpid(2) is signalled to wait on a process group rather than a
// process id by using the negative of its value.
s_disowned_pids.push_back(pgid * -1);
}
}
/// A static value tracking how many SIGCHLDs we have seen, which is used in a heurstic to
/// determine if we should call waitpid() at all in `process_mark_finished_children`.
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static volatile process_generation_count_t s_sigchld_generation_cnt = 0;
/// See if any children of a fully constructed job have exited or been killed, and mark them
/// accordingly. We cannot reap just any child that's exited, (as in, `waitpid(-1,…`) since
/// that may reap a pgrp leader that has exited but in a job with another process that has yet to
/// launch and join its pgrp (#5219).
/// \param block_on_fg when true, blocks waiting for the foreground job to finish.
/// \return whether the operation completed without incident
static bool process_mark_finished_children(bool block_on_fg) {
ASSERT_IS_MAIN_THREAD();
// We can't always use SIGCHLD to determine if waitpid() should be called since it is not
// strictly one-SIGCHLD-per-one-child-exited (i.e. multiple exits can share a SIGCHLD call) and
// we a) return immediately the first time a dead child is reaped, b) explicitly skip over jobs
// that aren't yet fully constructed, so it's possible that we can get SIGCHLD and even find a
// killed child in the jobs we are reaping, but also have an exited child process in a job that
// hasn't been fully constructed yet - which means we can end up never knowing about the exited
// child process in that job if we use SIGCHLD count as the only metric for whether or not
// waitpid() is called.
// Without this optimization, the slowdown caused by calling waitpid() even just once each time
// `process_mark_finished_children()` is called is rather obvious (see the performance-related
// discussion in #5219), making it worth the complexity of this heuristic.
/// Tracks whether or not we received SIGCHLD without checking all jobs (due to jobs under
/// construction), forcing a full waitpid loop.
static bool dirty_state = true;
static process_generation_count_t last_sigchld_count = -1;
// If the last time that we received a SIGCHLD we did not waitpid all jobs, we cannot early out.
if (!dirty_state && last_sigchld_count == s_sigchld_generation_cnt) {
// If we have foreground jobs, we need to block on them below
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if (!block_on_fg) {
// We can assume that no children have exited and that all waitpid calls with
// WNOHANG below will confirm that.
return true;
}
}
last_sigchld_count = s_sigchld_generation_cnt;
bool jobs_skipped = false;
bool has_error = false;
job_t *job_fg = nullptr;
// Reap only processes belonging to fully-constructed jobs to prevent reaping of processes
// before others in the same process group have a chance to join their pgrp.
job_iterator_t jobs;
while (auto j = jobs.next()) {
// (A job can have pgrp INVALID_PID if it consists solely of builtins that perform no IO)
if (j->pgid == INVALID_PID || !j->is_constructed()) {
debug(5, "Skipping wait on incomplete job %d (%ls)", j->job_id, j->preview().c_str());
jobs_skipped = true;
continue;
}
if (j != job_fg && j->is_foreground() && !j->is_stopped() && !j->is_completed()) {
// Ensure that we don't have multiple fully constructed foreground jobs.
assert((!job_fg || !job_fg->job_chain_is_fully_constructed() ||
!j->job_chain_is_fully_constructed()) &&
"More than one active, fully-constructed foreground job!");
job_fg = j;
}
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// Whether we will wait for uncompleted processes depends on the combination of
// `block_on_fg` and the nature of the process. Default is WNOHANG, but if foreground,
// constructed, not stopped, *and* block_on_fg is true, then no WNOHANG (i.e. "HANG").
int options = WUNTRACED | WNOHANG;
// We should never block twice in the same go, as `waitpid()' returning could mean one
// process completed or many, and there is a race condition when calling `waitpid()` after
// the process group exits having reaped all children and terminated the process group and
// when a subsequent call to `waitpid()` for the same process group returns immediately if
// that process group no longer exists. i.e. it's possible for all processes to have exited
// but the process group to remain momentarily valid, in which case calling `waitpid()`
// without WNOHANG can cause an infinite wait. Additionally, only wait on external jobs that
// spawned new process groups (i.e. JOB_CONTROL). We do not break or return on error as we
// wait on only one pgrp at a time and we need to check all pgrps before returning, but we
// never wait/block on fg processes after an error has been encountered to give ourselves
// (elsewhere) a chance to handle the fallout from process termination, etc.
if (!has_error && block_on_fg && j == job_fg) {
debug(4, "Waiting on processes from foreground job %d", job_fg->pgid);
options &= ~WNOHANG;
}
// If the pgid is 0, we need to wait by process because that's invalid.
// This happens in firejail for reasons not entirely clear to me.
bool wait_by_process = !j->job_chain_is_fully_constructed() || j->pgid == 0;
// When waiting on processes individually in a pipeline, we need to enumerate in reverse
// order so that the first process we actually wait on (i.e. ~WNOHANG) is the last process
// in the IO chain, because that's the one that controls the lifetime of the foreground job
// - as long as it is still running, we are in the background and once it exits or is
// killed, all previous jobs in the IO pipeline must necessarily terminate as well.
auto process = j->processes.rbegin();
// waitpid(2) returns 1 process each time, we need to keep calling it until we've reaped all
// children of the pgrp in question or else we can't reset the dirty_state flag. In all
// cases, calling waitpid(2) is faster than potentially calling select_try() on a process
// that has exited, which will force us to wait the full timeout before coming back here and
// calling waitpid() again.
while (true) {
int status;
pid_t pid;
if (wait_by_process) {
// If the evaluation of a function resulted in the sharing of a pgroup between the
// real job and the job that shouldn't have been created as a separate job AND the
// parent job is still under construction (which is the case when continue_job() is
// first called on the child job during the recursive call to exec_job() before the
// parent job has been fully constructed), we need to call waitpid(2) on the
// individual processes of the child job instead of using a catch-all waitpid(2)
// call on the job's process group.
if (process == j->processes.rend()) {
break;
}
assert((*process)->pid != INVALID_PID && "Waiting by process on an invalid PID!");
if ((options & WNOHANG) == 0) {
debug(4, "Waiting on individual process %d", (*process)->pid);
} else {
debug(4, "waitpid with WNOHANG on individual process %d", (*process)->pid);
}
pid = waitpid((*process)->pid, &status, options);
process++;
} else {
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// A negative PID passed in to `waitpid()` means wait on any child in that process
// group
pid = waitpid(-1 * j->pgid, &status, options);
}
// Never make two calls to waitpid(2) without WNOHANG (i.e. with "HANG") in a row,
// because we might wait on a non-stopped job that becomes stopped, but we don't refresh
// our view of the process state before calling waitpid(2) again here.
options |= WNOHANG;
if (pid > 0) {
// A child process has been reaped
handle_child_status(pid, status);
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} else if (pid == 0 || errno == ECHILD) {
// No killed/dead children in this particular process group
if (!wait_by_process) {
break;
}
} else {
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// pid < 0 indicates an error. One likely failure is ECHILD (no children), which is
// not an error and is ignored. The other likely failure is EINTR, which means we
// got a signal, which is considered an error. We absolutely do not break or return
// on error, as we need to iterate over all constructed jobs but we only call
// waitpid for one pgrp at a time. We do bypass future waits in case of error,
// however.
has_error = true;
// Do not audibly complain on interrupt (see #5293)
if (errno != EINTR) {
wperror(L"waitpid in process_mark_finished_children");
}
break;
}
}
}
// Poll disowned processes/process groups, but do nothing with the result. Only used to avoid
// zombie processes. Entries have already been converted to negative for process groups.
int status;
s_disowned_pids.erase(std::remove_if(s_disowned_pids.begin(), s_disowned_pids.end(),
[&status](pid_t pid) { return waitpid(pid, &status, WNOHANG) > 0; }),
s_disowned_pids.end());
// Yes, the below can be collapsed to a single line, but it's worth being explicit about it with
// the comments. Fret not, the compiler will optimize it. (It better!)
if (jobs_skipped) {
// We received SIGCHLD but were not able to definitely say whether or not all children were
// reaped.
dirty_state = true;
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} else {
// We can safely assume that no SIGCHLD means we can just return next time around
dirty_state = false;
}
return !has_error;
}
/// This is called from a signal handler. The signal is always SIGCHLD.
void job_handle_signal(int signal, siginfo_t *info, void *context) {
UNUSED(signal);
UNUSED(info);
UNUSED(context);
// This is the only place that this generation count is modified. It's OK if it overflows.
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s_sigchld_generation_cnt += 1;
}
/// Given a command like "cat file", truncate it to a reasonable length.
static wcstring truncate_command(const wcstring &cmd) {
const size_t max_len = 32;
if (cmd.size() <= max_len) {
// No truncation necessary.
return cmd;
}
// Truncation required.
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const size_t ellipsis_length = wcslen(ellipsis_str); // no need for wcwidth
size_t trunc_length = max_len - ellipsis_length;
// Eat trailing whitespace.
while (trunc_length > 0 && iswspace(cmd.at(trunc_length - 1))) {
trunc_length -= 1;
}
wcstring result = wcstring(cmd, 0, trunc_length);
// Append ellipsis.
result.append(ellipsis_str);
return result;
}
/// Format information about job status for the user to look at.
typedef enum { JOB_STOPPED, JOB_ENDED } job_status_t;
static void format_job_info(const job_t *j, job_status_t status) {
const wchar_t *msg = L"Job %d, '%ls' has ended"; // this is the most common status msg
if (status == JOB_STOPPED) msg = L"Job %d, '%ls' has stopped";
fwprintf(stdout, L"\r");
fwprintf(stdout, _(msg), j->job_id, truncate_command(j->command()).c_str());
fflush(stdout);
if (clr_eol) tputs(clr_eol, 1, &writeb);
fwprintf(stdout, L"\n");
}
void proc_fire_event(const wchar_t *msg, int type, pid_t pid, int status) {
event.type = type;
event.param1.pid = pid;
event.arguments.push_back(msg);
event.arguments.push_back(to_string<int>(pid));
event.arguments.push_back(to_string<int>(status));
event_fire(&event);
event.arguments.resize(0);
}
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static int process_clean_after_marking(bool allow_interactive) {
ASSERT_IS_MAIN_THREAD();
job_t *jnext;
int found = 0;
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// this function may fire an event handler, we do not want to call ourselves recursively (to
// avoid infinite recursion).
static bool locked = false;
if (locked) {
return 0;
}
locked = true;
// this may be invoked in an exit handler, after the TERM has been torn down
// don't try to print in that case (#3222)
const bool interactive = allow_interactive && cur_term != NULL;
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job_iterator_t jobs;
const size_t job_count = jobs.count();
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jnext = jobs.next();
while (jnext) {
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job_t *j = jnext;
jnext = jobs.next();
// If we are reaping only jobs who do not need status messages sent to the console, do not
// consider reaping jobs that need status messages.
if ((!j->get_flag(job_flag_t::SKIP_NOTIFICATION)) && (!interactive) &&
(!j->is_foreground())) {
continue;
}
for (const process_ptr_t &p : j->processes) {
int s;
if (!p->completed) continue;
if (!p->pid) continue;
s = p->status;
// TODO: The generic process-exit event is useless and unused.
// Remove this in future.
// Update: This event is used for cleaning up the psub temporary files and folders.
// Removing it breaks the psub tests as a result.
proc_fire_event(L"PROCESS_EXIT", EVENT_EXIT, p->pid,
(WIFSIGNALED(s) ? -1 : WEXITSTATUS(s)));
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// Ignore signal SIGPIPE.We issue it ourselves to the pipe writer when the pipe reader
// dies.
if (!WIFSIGNALED(s) || WTERMSIG(s) == SIGPIPE) {
continue;
}
// Handle signals other than SIGPIPE.
int proc_is_job = (p->is_first_in_job && p->is_last_in_job);
if (proc_is_job) j->set_flag(job_flag_t::NOTIFIED, true);
// Always report crashes.
if (j->get_flag(job_flag_t::SKIP_NOTIFICATION) &&
!contains(crashsignals, WTERMSIG(p->status))) {
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continue;
}
// Print nothing if we get SIGINT in the foreground process group, to avoid spamming
// obvious stuff on the console (#1119). If we get SIGINT for the foreground
// process, assume the user typed ^C and can see it working. It's possible they
// didn't, and the signal was delivered via pkill, etc., but the SIGINT/SIGTERM
// distinction is precisely to allow INT to be from a UI
// and TERM to be programmatic, so this assumption is keeping with the design of
// signals. If echoctl is on, then the terminal will have written ^C to the console.
// If off, it won't have. We don't echo ^C either way, so as to respect the user's
// preference.
if (WTERMSIG(p->status) != SIGINT || !j->is_foreground()) {
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if (proc_is_job) {
// We want to report the job number, unless it's the only job, in which case
// we don't need to.
const wcstring job_number_desc =
(job_count == 1) ? wcstring() : format_string(_(L"Job %d, "), j->job_id);
fwprintf(stdout, _(L"%ls: %ls\'%ls\' terminated by signal %ls (%ls)"),
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program_name, job_number_desc.c_str(),
truncate_command(j->command()).c_str(), sig2wcs(WTERMSIG(p->status)),
signal_get_desc(WTERMSIG(p->status)));
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} else {
const wcstring job_number_desc =
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(job_count == 1) ? wcstring() : format_string(L"from job %d, ", j->job_id);
const wchar_t *fmt =
_(L"%ls: Process %d, \'%ls\' %ls\'%ls\' terminated by signal %ls (%ls)");
fwprintf(stdout, fmt, program_name, p->pid, p->argv0(), job_number_desc.c_str(),
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truncate_command(j->command()).c_str(), sig2wcs(WTERMSIG(p->status)),
signal_get_desc(WTERMSIG(p->status)));
}
if (clr_eol) tputs(clr_eol, 1, &writeb);
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fwprintf(stdout, L"\n");
}
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found = 1;
p->status = 0; // clear status so it is not reported more than once
}
// If all processes have completed, tell the user the job has completed and delete it from
// the active job list.
if (j->is_completed()) {
if (!j->is_foreground() && !j->get_flag(job_flag_t::NOTIFIED) &&
!j->get_flag(job_flag_t::SKIP_NOTIFICATION)) {
format_job_info(j, JOB_ENDED);
found = 1;
}
// TODO: The generic process-exit event is useless and unused.
// Remove this in future.
2018-10-02 03:55:18 +00:00
// Don't fire the exit-event for jobs with pgid INVALID_PID.
// That's our "sentinel" pgid, for jobs that don't (yet) have a pgid,
// or jobs that consist entirely of builtins (and hence don't have a process).
// This causes issues if fish is PID 2, which is quite common on WSL. See #4582.
2018-10-02 03:55:18 +00:00
if (j->pgid != INVALID_PID) {
proc_fire_event(L"JOB_EXIT", EVENT_EXIT, -j->pgid, 0);
}
proc_fire_event(L"JOB_EXIT", EVENT_JOB_ID, j->job_id, 0);
job_remove(j);
} else if (j->is_stopped() && !j->get_flag(job_flag_t::NOTIFIED)) {
// Notify the user about newly stopped jobs.
if (!j->get_flag(job_flag_t::SKIP_NOTIFICATION)) {
format_job_info(j, JOB_STOPPED);
found = 1;
}
j->set_flag(job_flag_t::NOTIFIED, true);
}
}
if (found) fflush(stdout);
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locked = false;
return found;
}
int job_reap(bool allow_interactive) {
ASSERT_IS_MAIN_THREAD();
int found = 0;
process_mark_finished_children(false);
// Preserve the exit status.
const int saved_status = proc_get_last_status();
found = process_clean_after_marking(allow_interactive);
// Restore the exit status.
proc_set_last_status(saved_status);
return found;
}
#ifdef HAVE__PROC_SELF_STAT
/// Maximum length of a /proc/[PID]/stat filename.
#define FN_SIZE 256
/// Get the CPU time for the specified process.
unsigned long proc_get_jiffies(process_t *p) {
if (p->pid <= 0) return 0;
wchar_t fn[FN_SIZE];
char state;
int pid, ppid, pgrp, session, tty_nr, tpgid, exit_signal, processor;
long int cutime, cstime, priority, nice, placeholder, itrealvalue, rss;
unsigned long int flags, minflt, cminflt, majflt, cmajflt, utime, stime, starttime, vsize, rlim,
startcode, endcode, startstack, kstkesp, kstkeip, signal, blocked, sigignore, sigcatch,
wchan, nswap, cnswap;
char comm[1024];
swprintf(fn, FN_SIZE, L"/proc/%d/stat", p->pid);
FILE *f = wfopen(fn, "r");
if (!f) return 0;
// TODO: replace the use of fscanf() as it is brittle and should never be used.
int count = fscanf(f,
"%9d %1023s %c %9d %9d %9d %9d %9d %9lu "
"%9lu %9lu %9lu %9lu %9lu %9lu %9ld %9ld %9ld "
"%9ld %9ld %9ld %9lu %9lu %9ld %9lu %9lu %9lu "
"%9lu %9lu %9lu %9lu %9lu %9lu %9lu %9lu %9lu "
"%9lu %9d %9d ",
&pid, comm, &state, &ppid, &pgrp, &session, &tty_nr, &tpgid, &flags, &minflt,
&cminflt, &majflt, &cmajflt, &utime, &stime, &cutime, &cstime, &priority,
&nice, &placeholder, &itrealvalue, &starttime, &vsize, &rss, &rlim,
&startcode, &endcode, &startstack, &kstkesp, &kstkeip, &signal, &blocked,
&sigignore, &sigcatch, &wchan, &nswap, &cnswap, &exit_signal, &processor);
fclose(f);
if (count < 17) return 0;
return utime + stime + cutime + cstime;
}
/// Update the CPU time for all jobs.
void proc_update_jiffies() {
job_t *job;
job_iterator_t j;
for (job = j.next(); job; job = j.next()) {
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for (process_ptr_t &p : job->processes) {
gettimeofday(&p->last_time, 0);
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p->last_jiffies = proc_get_jiffies(p.get());
}
}
}
#endif
/// The return value of select_try(), indicating IO readiness or an error
enum class select_try_t {
/// One or more fds have data ready for read
DATA_READY,
/// The timeout elapsed without any data becoming available for read
TIMEOUT,
/// There were no FDs in the io chain for which to select on.
IOCHAIN_EMPTY,
};
/// Check if there are buffers associated with the job, and select on them for a while if available.
///
/// \param j the job to test
/// \return the status of the select operation
static select_try_t select_try(job_t *j) {
fd_set fds;
int maxfd = -1;
FD_ZERO(&fds);
const io_chain_t chain = j->all_io_redirections();
for (const auto &io : chain) {
if (io->io_mode == IO_BUFFER) {
auto io_pipe = static_cast<const io_pipe_t *>(io.get());
int fd = io_pipe->pipe_fd[0];
FD_SET(fd, &fds);
maxfd = std::max(maxfd, fd);
debug(4, L"select_try on fd %d", fd);
}
}
if (maxfd >= 0) {
struct timeval timeout;
timeout.tv_sec = 0;
timeout.tv_usec = 10000;
int retval = select(maxfd + 1, &fds, 0, 0, &timeout);
if (retval == 0) {
debug(4, L"select_try hit timeout");
return select_try_t::TIMEOUT;
}
return select_try_t::DATA_READY;
}
return select_try_t::IOCHAIN_EMPTY;
}
/// Read from descriptors until they are empty.
///
/// \param j the job to test
static void read_try(job_t *j) {
io_buffer_t *buff = NULL;
// Find the last buffer, which is the one we want to read from.
const io_chain_t chain = j->all_io_redirections();
for (size_t idx = 0; idx < chain.size(); idx++) {
io_data_t *d = chain.at(idx).get();
if (d->io_mode == IO_BUFFER) {
buff = static_cast<io_buffer_t *>(d);
}
}
if (buff) {
debug(4, L"proc::read_try('%ls')", j->command_wcstr());
while (1) {
char b[BUFFER_SIZE];
long len = read_blocked(buff->pipe_fd[0], b, BUFFER_SIZE);
if (len == 0) {
break;
} else if (len < 0) {
if (errno != EAGAIN) {
debug(1, _(L"An error occured while reading output from code block"));
wperror(L"read_try");
}
break;
} else {
buff->append(b, len);
}
}
}
}
// Return control of the terminal to a job's process group. restore_attrs is true if we are restoring
// a previously-stopped job, in which case we need to restore terminal attributes.
bool terminal_give_to_job(const job_t *j, bool restore_attrs) {
if (j->pgid == 0) {
debug(2, "terminal_give_to_job() returning early due to no process group");
return true;
}
// RAII wrappers must have a name so that their scope is tied to the function as it is legal for
// the compiler to construct and then immediately deconstruct unnamed objects otherwise.
signal_block_t signal_block;
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// It may not be safe to call tcsetpgrp if we've already done so, as at that point we are no
// longer the controlling process group for the terminal and no longer have permission to set
// the process group that is in control, causing tcsetpgrp to return EPERM, even though that's
// not the documented behavior in tcsetpgrp(3), which instead says other bad things will happen
// (it says SIGTTOU will be sent to all members of the background *calling* process group, but
// it's more complicated than that, SIGTTOU may or may not be sent depending on the TTY
// configuration and whether or not signal handlers for SIGTTOU are installed. Read:
// http://curiousthing.org/sigttin-sigttou-deep-dive-linux In all cases, our goal here was just
// to hand over control of the terminal to this process group, which is a no-op if it's already
// been done.
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if (j->pgid == INVALID_PID || tcgetpgrp(STDIN_FILENO) == j->pgid) {
debug(4, L"Process group %d already has control of terminal\n", j->pgid);
} else {
debug(4,
L"Attempting to bring process group to foreground via tcsetpgrp for job->pgid %d\n",
j->pgid);
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// The tcsetpgrp(2) man page says that EPERM is thrown if "pgrp has a supported value, but
// is not the process group ID of a process in the same session as the calling process."
// Since we _guarantee_ that this isn't the case (the child calls setpgid before it calls
// SIGSTOP, and the child was created in the same session as us), it seems that EPERM is
// being thrown because of an caching issue - the call to tcsetpgrp isn't seeing the
// newly-created process group just yet. On this developer's test machine (WSL running Linux
// 4.4.0), EPERM does indeed disappear on retry. The important thing is that we can
// guarantee the process isn't going to exit while we wait (which would cause us to possibly
// block indefinitely).
while (tcsetpgrp(STDIN_FILENO, j->pgid) != 0) {
debug(3, "tcsetpgrp failed: %d", errno);
bool pgroup_terminated = false;
// No need to test for EINTR as we are blocking signals
if (errno == EINVAL) {
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// OS X returns EINVAL if the process group no longer lives. Probably other OSes,
// too. Unlike EPERM below, EINVAL can only happen if the process group has
// terminated.
pgroup_terminated = true;
} else if (errno == EPERM) {
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// Retry so long as this isn't because the process group is dead.
int wait_result = waitpid(-1 * j->pgid, &wait_result, WNOHANG);
if (wait_result == -1) {
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// Note that -1 is technically an "error" for waitpid in the sense that an
// invalid argument was specified because no such process group exists any
// longer. This is the observed behavior on Linux 4.4.0. a "success" result
// would mean processes from the group still exist but is still running in some
// state or the other.
pgroup_terminated = true;
} else {
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// Debug the original tcsetpgrp error (not the waitpid errno) to the log, and
// then retry until not EPERM or the process group has exited.
debug(2, L"terminal_give_to_job(): EPERM.\n", j->pgid);
continue;
}
} else {
if (errno == ENOTTY) {
redirect_tty_output();
}
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debug(1, _(L"Could not send job %d ('%ls') with pgid %d to foreground"), j->job_id,
j->command_wcstr(), j->pgid);
wperror(L"tcsetpgrp");
return false;
}
if (pgroup_terminated) {
// All processes in the process group has exited.
// Since we delay reaping any processes in a process group until all members of that
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// job/group have been started, the only way this can happen is if the very last
// process in the group terminated and didn't need to access the terminal, otherwise
// it would have hung waiting for terminal IO (SIGTTIN). We can safely ignore this.
debug(3, L"tcsetpgrp called but process group %d has terminated.\n", j->pgid);
mark_job_complete(j);
return true;
}
break;
}
}
if (restore_attrs) {
auto result = tcsetattr(STDIN_FILENO, TCSADRAIN, &j->tmodes);
if (result == -1) {
// No need to test for EINTR and retry since we have blocked all signals
if (errno == ENOTTY) {
redirect_tty_output();
}
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debug(1, _(L"Could not send job %d ('%ls') to foreground"), j->job_id,
j->preview().c_str());
wperror(L"tcsetattr");
return false;
}
}
return true;
}
pid_t terminal_acquire_before_builtin(int job_pgid) {
pid_t selfpgid = getpgrp();
pid_t current_owner = tcgetpgrp(STDIN_FILENO);
if (current_owner >= 0 && current_owner != selfpgid && current_owner == job_pgid) {
if (tcsetpgrp(STDIN_FILENO, selfpgid) == 0) {
return current_owner;
}
}
return -1;
}
/// Returns control of the terminal to the shell, and saves the terminal attribute state to the job,
/// so that we can restore the terminal ownership to the job at a later time.
static bool terminal_return_from_job(job_t *j) {
errno = 0;
if (j->pgid == 0) {
debug(2, "terminal_return_from_job() returning early due to no process group");
return true;
}
signal_block();
if (tcsetpgrp(STDIN_FILENO, getpgrp()) == -1) {
if (errno == ENOTTY) redirect_tty_output();
debug(1, _(L"Could not return shell to foreground"));
wperror(L"tcsetpgrp");
signal_unblock();
return false;
}
// Save jobs terminal modes.
if (tcgetattr(STDIN_FILENO, &j->tmodes)) {
if (errno == EIO) redirect_tty_output();
debug(1, _(L"Could not return shell to foreground"));
wperror(L"tcgetattr");
signal_unblock();
return false;
}
// Disabling this per
// https://github.com/adityagodbole/fish-shell/commit/9d229cd18c3e5c25a8bd37e9ddd3b67ddc2d1b72 On
// Linux, 'cd . ; ftp' prevents you from typing into the ftp prompt. See
// https://github.com/fish-shell/fish-shell/issues/121
#if 0
2018-10-29 00:09:57 +00:00
// Restore the shell's terminal modes.
if (tcsetattr(STDIN_FILENO, TCSADRAIN, &shell_modes) == -1) {
if (errno == EIO) redirect_tty_output();
debug(1, _(L"Could not return shell to foreground"));
wperror(L"tcsetattr");
return false;
}
#endif
signal_unblock();
return true;
}
void job_t::continue_job(bool send_sigcont) {
// Put job first in the job list.
promote();
set_flag(job_flag_t::NOTIFIED, false);
debug(4, L"%ls job %d, gid %d (%ls), %ls, %ls", send_sigcont ? L"Continue" : L"Start", job_id,
pgid, command_wcstr(), is_completed() ? L"COMPLETED" : L"UNCOMPLETED",
is_interactive ? L"INTERACTIVE" : L"NON-INTERACTIVE");
// Make sure we retake control of the terminal before leaving this function.
bool term_transferred = false;
cleanup_t take_term_back([&]() {
2018-10-29 00:09:57 +00:00
if (term_transferred) {
terminal_return_from_job(this);
}
});
bool read_attempted = false;
if (!is_completed()) {
if (get_flag(job_flag_t::TERMINAL) && is_foreground()) {
// Put the job into the foreground and give it control of the terminal.
// Hack: ensure that stdin is marked as blocking first (issue #176).
make_fd_blocking(STDIN_FILENO);
if (!terminal_give_to_job(this, send_sigcont)) {
2018-10-29 00:09:57 +00:00
// This scenario has always returned without any error handling. Presumably that is
// OK.
return;
}
term_transferred = true;
}
// If both requested and necessary, send the job a continue signal.
if (send_sigcont) {
// This code used to check for JOB_CONTROL to decide between using killpg to signal all
// processes in the group or iterating over each process in the group and sending the
// signal individually. job_t::signal() does the same, but uses the shell's own pgroup
// to make that distinction.
if (!signal(SIGCONT)) {
debug(2, "Failed to send SIGCONT to any processes in pgroup %d!", pgid);
// This returns without bubbling up the error. Presumably that is OK.
return;
}
// reset the status of each process instance
for (auto &p : processes) {
p->stopped = false;
}
}
if (is_foreground()) {
// This is an optimization to not call select_try() in case a process has exited. While
// it may seem silly, unless there is IO (and there usually isn't in terms of total CPU
// time), select_try() will wait for 10ms (our timeout) before returning. If during
// these 10ms a process exited, the shell will basically hang until the timeout happens
// and we are free to call `process_mark_finished_children()` to discover that fact. By
// calling it here before calling `select_try()` below, shell responsiveness can be
// dramatically improved (noticably so, not just "theoretically speaking" per the
// discussion in #5219).
process_mark_finished_children(false);
// If this is a child job and the parent job is still under construction (i.e. job1 |
// some_func), we can't block on execution of the nested job for `some_func`. Doing
// so can cause hangs if job1 emits more data than fits in the OS pipe buffer.
// The solution is to to not block on fg from the initial call in exec_job(), which
// is also the only place that send_sigcont is false. parent_job.is_constructed()
// must also be true, which coincides with WAIT_BY_PROCESS (which will have to do
// since we don't store a reference to the parent job in the job_t structure).
bool block_on_fg = send_sigcont && job_chain_is_fully_constructed();
// Wait for data to become available or the status of our own job to change
while (!reader_exit_forced() && !is_stopped() && !is_completed()) {
auto result = select_try(this);
read_attempted = true;
switch (result) {
case select_try_t::DATA_READY:
// Read the data that we know is now available, then scan for finished processes
// but do not block. We don't block so long as we have IO to process, once the
// fd buffers are empty we'll block in the second case below.
read_try(this);
process_mark_finished_children(false);
break;
case select_try_t::TIMEOUT:
// No FDs are ready. Look for finished processes instead.
debug(4, L"select_try: no fds returned valid data within the timeout" );
process_mark_finished_children(block_on_fg);
break;
case select_try_t::IOCHAIN_EMPTY:
// There were no IO fds to select on.
debug(4, L"select_try: no IO fds" );
process_mark_finished_children(true);
// If it turns out that we encountered this because the file descriptor we were
// reading from has died, process_mark_finished_children() should take care of
// changing the status of our is_completed() (assuming it is appropriate to do
// so), in which case we will break out of this loop.
break;
}
}
}
}
if (is_foreground()) {
if (is_completed()) {
// It's possible that the job will produce output and exit before we've even read from
// it. In that case, make sure we read that output now, before we've executed any
// subsequent calls. This is why prompt colors were getting screwed up - the builtin
// `echo` calls were sometimes having their output combined with the `set_color` calls
// in the wrong order!
if (!read_attempted) {
read_try(this);
}
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// Set $status only if we are in the foreground and the last process in the job has
// finished and is not a short-circuited builtin.
auto &p = processes.back();
if ((WIFEXITED(p->status) || WIFSIGNALED(p->status)) && p->pid) {
int status = proc_format_status(p->status);
proc_set_last_status(get_flag(job_flag_t::NEGATE) ? !status : status);
}
}
}
}
int proc_format_status(int status) {
if (WIFSIGNALED(status)) {
return 128 + WTERMSIG(status);
} else if (WIFEXITED(status)) {
return WEXITSTATUS(status);
}
return status;
}
void proc_sanity_check() {
const job_t *fg_job = NULL;
2012-01-30 00:36:21 +00:00
job_iterator_t jobs;
while (const job_t *j = jobs.next()) {
if (!j->is_constructed()) continue;
// More than one foreground job?
if (j->is_foreground() && !(j->is_stopped() || j->is_completed())) {
2017-01-24 23:14:56 +00:00
if (fg_job) {
debug(0, _(L"More than one job in foreground: job 1: '%ls' job 2: '%ls'"),
fg_job->command_wcstr(), j->command_wcstr());
sanity_lose();
}
fg_job = j;
}
for (const process_ptr_t &p : j->processes) {
// Internal block nodes do not have argv - see issue #1545.
bool null_ok = (p->type == INTERNAL_BLOCK_NODE);
validate_pointer(p->get_argv(), _(L"Process argument list"), null_ok);
validate_pointer(p->argv0(), _(L"Process name"), null_ok);
if ((p->stopped & (~0x00000001)) != 0) {
debug(0, _(L"Job '%ls', process '%ls' has inconsistent state \'stopped\'=%d"),
j->command_wcstr(), p->argv0(), p->stopped);
sanity_lose();
}
if ((p->completed & (~0x00000001)) != 0) {
debug(0, _(L"Job '%ls', process '%ls' has inconsistent state \'completed\'=%d"),
j->command_wcstr(), p->argv0(), p->completed);
sanity_lose();
}
}
}
}
void proc_push_interactive(int value) {
ASSERT_IS_MAIN_THREAD();
int old = is_interactive;
interactive_stack.push_back(is_interactive);
is_interactive = value;
if (old != value) signal_set_handlers();
}
void proc_pop_interactive() {
ASSERT_IS_MAIN_THREAD();
int old = is_interactive;
is_interactive = interactive_stack.back();
interactive_stack.pop_back();
if (is_interactive != old) signal_set_handlers();
}
2017-10-22 07:10:23 +00:00
pid_t proc_wait_any() {
int pid_status;
pid_t pid = waitpid(-1, &pid_status, WUNTRACED);
if (pid == -1) return -1;
handle_child_status(pid, pid_status);
process_clean_after_marking(is_interactive);
return pid;
}
void hup_background_jobs() {
job_iterator_t jobs;
while (job_t *j = jobs.next()) {
// Make sure we don't try to SIGHUP the calling builtin
if (j->pgid == INVALID_PID || !j->get_flag(job_flag_t::JOB_CONTROL)) {
continue;
}
if (!j->is_completed()) {
if (j->is_stopped()) {
j->signal(SIGCONT);
}
j->signal(SIGHUP);
}
}
}