toaruos/kernel/sys/signal.c

268 lines
6.3 KiB
C

/**
* @file kernel/sys/signal.c
* @brief Signal handling.
*
* Provides signal entry and delivery; also handles suspending
* and resuming jobs (SIGTSTP, SIGCONT).
*
* Signal delivery in ToaruOS is a bit odd; we save a lot of the
* kernel context from before the signal, including the entire
* kernel stack, so that we can resume userspace in a new context;
* essentially we build a whole new kernel thread for the signal
* handler to run in, and then restore the original when the signal
* handler exits. Signal handler exits are generally handled by
* a page fault at a magic known address.
*
* @copyright
* This file is part of ToaruOS and is released under the terms
* of the NCSA / University of Illinois License - see LICENSE.md
* Copyright (C) 2012-2021 K. Lange
*/
#include <errno.h>
#include <stdint.h>
#include <sys/signal.h>
#include <sys/signal_defs.h>
#include <kernel/printf.h>
#include <kernel/string.h>
#include <kernel/process.h>
#include <kernel/signal.h>
#include <kernel/spinlock.h>
static spin_lock_t sig_lock;
static spin_lock_t sig_lock_b;
char isdeadly[] = {
0, /* 0? */
[SIGHUP ] = 1,
[SIGINT ] = 1,
[SIGQUIT ] = 2,
[SIGILL ] = 2,
[SIGTRAP ] = 2,
[SIGABRT ] = 2,
[SIGEMT ] = 2,
[SIGFPE ] = 2,
[SIGKILL ] = 1,
[SIGBUS ] = 2,
[SIGSEGV ] = 2,
[SIGSYS ] = 2,
[SIGPIPE ] = 1,
[SIGALRM ] = 1,
[SIGTERM ] = 1,
[SIGUSR1 ] = 1,
[SIGUSR2 ] = 1,
[SIGCHLD ] = 0,
[SIGPWR ] = 0,
[SIGWINCH ] = 0,
[SIGURG ] = 0,
[SIGPOLL ] = 0,
[SIGSTOP ] = 3,
[SIGTSTP ] = 3,
[SIGCONT ] = 4,
[SIGTTIN ] = 3,
[SIGTTOUT ] = 3,
[SIGVTALRM ] = 1,
[SIGPROF ] = 1,
[SIGXCPU ] = 2,
[SIGXFSZ ] = 2,
[SIGWAITING ] = 0,
[SIGDIAF ] = 1,
[SIGHATE ] = 0,
[SIGWINEVENT] = 0,
[SIGCAT ] = 0,
};
void handle_signal(process_t * proc, signal_t * sig) {
uintptr_t handler = sig->handler;
uintptr_t signum = sig->signum;
free(sig);
if (proc->flags & PROC_FLAG_FINISHED) {
return;
}
if (signum == 0 || signum >= NUMSIGNALS) {
/* Ignore */
return;
}
if (!handler) {
char dowhat = isdeadly[signum];
if (dowhat == 1 || dowhat == 2) {
task_exit(((128 + signum) << 8) | signum);
__builtin_unreachable();
} else if (dowhat == 3) {
__sync_or_and_fetch(&this_core->current_process->flags, PROC_FLAG_SUSPENDED);
this_core->current_process->status = 0x7F;
process_t * parent = process_get_parent((process_t *)this_core->current_process);
if (parent && !(parent->flags & PROC_FLAG_FINISHED)) {
wakeup_queue(parent->wait_queue);
}
switch_task(0);
} else if (dowhat == 4) {
switch_task(1);
return;
}
/* XXX dowhat == 2: should dump core */
/* XXX dowhat == 3: stop */
return;
}
if (handler == 1) /* Ignore */ {
return;
}
arch_enter_signal_handler(handler, signum);
}
list_t * rets_from_sig;
void return_from_signal_handler(void) {
if (__builtin_expect(!rets_from_sig, 0)) {
rets_from_sig = list_create("global return-from-signal queue",NULL);
}
spin_lock(sig_lock);
list_insert(rets_from_sig, (process_t *)this_core->current_process);
spin_unlock(sig_lock);
switch_next();
}
void fix_signal_stacks(void) {
uint8_t redo_me = 0;
if (rets_from_sig) {
spin_lock(sig_lock_b);
while (rets_from_sig->head) {
spin_lock(sig_lock);
node_t * n = list_dequeue(rets_from_sig);
spin_unlock(sig_lock);
if (!n) {
continue;
}
process_t * p = n->value;
free(n);
if (p == this_core->current_process) {
redo_me = 1;
continue;
}
memcpy(&p->thread, &p->signal_state, sizeof(thread_t));
if (!p->signal_kstack) {
printf("Cannot restore signal stack for pid=%d - unset?\n", p->id);
} else {
memcpy((char *)(p->image.stack - KERNEL_STACK_SIZE + 0x1000), p->signal_kstack + 0x1000, KERNEL_STACK_SIZE - 0x1000);
free(p->signal_kstack);
p->signal_kstack = NULL;
}
make_process_ready(p);
}
spin_unlock(sig_lock_b);
}
if (redo_me) {
spin_lock(sig_lock);
list_insert(rets_from_sig, (process_t *)this_core->current_process);
spin_unlock(sig_lock);
switch_next();
}
}
int send_signal(pid_t process, int signal, int force_root) {
process_t * receiver = process_from_pid(process);
if (!receiver) {
/* Invalid pid */
return -ESRCH;
}
if (!force_root && receiver->user != this_core->current_process->user && this_core->current_process->user != USER_ROOT_UID) {
if (!(signal == SIGCONT && receiver->session == this_core->current_process->session)) {
return -EPERM;
}
}
if (receiver->flags & PROC_FLAG_IS_TASKLET) {
/* Can not send signals to kernel tasklets */
return -EINVAL;
}
if (signal > NUMSIGNALS) {
/* Invalid signal */
return -EINVAL;
}
if (receiver->flags & PROC_FLAG_FINISHED) {
/* Can't send signals to finished processes */
return -EINVAL;
}
if (!receiver->signals[signal] && !isdeadly[signal]) {
/* If we're blocking a signal and it's not going to kill us, don't deliver it */
return 0;
}
if (isdeadly[signal] == 4) {
if (!(receiver->flags & PROC_FLAG_SUSPENDED)) {
return -EINVAL;
} else {
__sync_and_and_fetch(&receiver->flags, ~(PROC_FLAG_SUSPENDED));
receiver->status = 0;
}
}
/* Append signal to list */
signal_t * sig = malloc(sizeof(signal_t));
sig->handler = (uintptr_t)receiver->signals[signal];
sig->signum = signal;
memset(&sig->registers_before, 0x00, sizeof(struct regs));
process_awaken_signal(receiver);
if (!process_is_ready(receiver) || receiver == this_core->current_process) {
make_process_ready(receiver);
}
list_insert(receiver->signal_queue, sig);
if (receiver == this_core->current_process) {
/* Forces us to be rescheduled and enter signal handler */
if (receiver->signal_kstack) {
switch_next();
} else {
switch_task(0);
}
}
return 0;
}
int group_send_signal(pid_t group, int signal, int force_root) {
int kill_self = 0;
int killed_something = 0;
foreach(node, process_list) {
process_t * proc = node->value;
if (proc->group == proc->id && proc->job == group) {
/* Only thread group leaders */
if (proc->group == this_core->current_process->group) {
kill_self = 1;
} else {
if (send_signal(proc->group, signal, force_root) == 0) {
killed_something = 1;
}
}
}
}
if (kill_self) {
if (send_signal(this_core->current_process->group, signal, force_root) == 0) {
killed_something = 1;
}
}
return !!killed_something;
}