sched/signal/sig_dispatch.c - nuttx - Git at Google

 /****************************************************************************
  * sched/signal/sig_dispatch.c
  *
  * Licensed to the Apache Software Foundation (ASF) under one or more
  * contributor license agreements.  See the NOTICE file distributed with
  * this work for additional information regarding copyright ownership.  The
  * ASF licenses this file to you under the Apache License, Version 2.0 (the
  * "License"); you may not use this file except in compliance with the
  * License.  You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
  * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.  See the
  * License for the specific language governing permissions and limitations
  * under the License.
  *
  ****************************************************************************/

 /****************************************************************************
  * Included Files
  ****************************************************************************/

 #include <nuttx/config.h>

 #include <inttypes.h>
 #include <string.h>
 #include <signal.h>
 #include <unistd.h>
 #include <sched.h>
 #include <assert.h>
 #include <errno.h>
 #include <debug.h>

 #include <nuttx/irq.h>
 #include <nuttx/arch.h>
 #include <nuttx/signal.h>
 #include <nuttx/queue.h>

 #include "sched/sched.h"
 #include "group/group.h"
 #include "semaphore/semaphore.h"
 #include "signal/signal.h"
 #include "mqueue/mqueue.h"

 /****************************************************************************
  * Private Functions
  ****************************************************************************/

 /****************************************************************************
  * Name: nxsig_queue_action
  *
  * Description:
  *   Queue a signal action for delivery to a task.
  *
  * Returned Value:
  *   Returns 0 (OK) on success or a negated errno value on failure.
  *
  ****************************************************************************/

 static int nxsig_queue_action(FAR struct tcb_s *stcb, siginfo_t *info)
 {
   FAR sigactq_t *sigact;
   FAR sigq_t    *sigq;
   irqstate_t     flags;
   int            ret = OK;

   sched_lock();
   DEBUGASSERT(stcb != NULL && stcb->group != NULL);

   /* Find the group sigaction associated with this signal */

   sigact = nxsig_find_action(stcb->group, info->si_signo);

   /* Check if a valid signal handler is available and if the signal is
    * unblocked. NOTE: There is no default action.
    */

   if ((sigact) && (sigact->act.sa_u._sa_sigaction))
     {
       /* Allocate a new element for the signal queue. NOTE:
        * nxsig_alloc_pendingsigaction will force a system crash if it is
        * unable to allocate memory for the signal data.
        */

       sigq = nxsig_alloc_pendingsigaction();
       if (!sigq)
         {
           ret = -ENOMEM;
         }
       else
         {
           /* Populate the new signal queue element */

           sigq->action.sighandler = sigact->act.sa_u._sa_sigaction;
           sigq->mask = sigact->act.sa_mask;
           if ((sigact->act.sa_flags & SA_NODEFER) == 0)
             {
               sigaddset(&sigq->mask, info->si_signo);
             }

           memcpy(&sigq->info, info, sizeof(siginfo_t));
           sigq->info.si_user = sigact->act.sa_user;

           /* Put it at the end of the pending signals list */

           flags = enter_critical_section();
           sq_addlast((FAR sq_entry_t *)sigq, &(stcb->sigpendactionq));

           /* Then schedule execution of the signal handling action on the
            * recipient's thread. SMP related handling will be done in
            * up_schedule_sigaction()
            */

           up_schedule_sigaction(stcb, nxsig_deliver);
           leave_critical_section(flags);
         }
     }

   sched_unlock();
   return ret;
 }

 /****************************************************************************
  * Name: nxsig_alloc_pendingsignal
  *
  * Description:
  *   Allocate a pending signal list entry
  *
  ****************************************************************************/

 static FAR sigpendq_t *nxsig_alloc_pendingsignal(void)
 {
   FAR sigpendq_t *sigpend;
   irqstate_t      flags;

   /* Check if we were called from an interrupt handler. */

   if (up_interrupt_context())
     {
       /* Try to get the pending signal structure from the free list */

       sigpend = (FAR sigpendq_t *)sq_remfirst(&g_sigpendingsignal);
       if (!sigpend)
         {
           /* If no pending signal structure is available in the free list,
            * then try the special list of structures reserved for
            * interrupt handlers
            */

           sigpend = (FAR sigpendq_t *)sq_remfirst(&g_sigpendingirqsignal);
         }
     }

   /* If we were not called from an interrupt handler, then we are
    * free to allocate pending action structures if necessary.
    */

   else
     {
       /* Try to get the pending signal structure from the free list */

       flags = enter_critical_section();
       sigpend = (FAR sigpendq_t *)sq_remfirst(&g_sigpendingsignal);
       leave_critical_section(flags);

       /* Check if we got one. */

       if (!sigpend)
         {
           /* No... Allocate the pending signal */

           sigpend = kmm_malloc(sizeof(sigpendq_t));

           /* Check if we got an allocated message */

           if (sigpend)
             {
               sigpend->type = SIG_ALLOC_DYN;
             }
         }
     }

   return sigpend;
 }

 /****************************************************************************
  * Name: nxsig_find_pendingsignal
  *
  * Description:
  *   Find a specified element in the pending signal list
  *
  ****************************************************************************/

 static FAR sigpendq_t *
 nxsig_find_pendingsignal(FAR struct task_group_s *group, int signo)
 {
   FAR sigpendq_t *sigpend = NULL;
   irqstate_t flags;

   DEBUGASSERT(group != NULL);

   /* Determining whether a signal is reliable or unreliable */

   if (SIGRTMIN <= signo && signo <= SIGRTMAX)
     {
       return sigpend;
     }

   /* Pending signals can be added from interrupt level. */

   flags = enter_critical_section();

   /* Search the list for a action pending on this signal */

   for (sigpend = (FAR sigpendq_t *)group->tg_sigpendingq.head;
        (sigpend && sigpend->info.si_signo != signo);
        sigpend = sigpend->flink);

   leave_critical_section(flags);
   return sigpend;
 }

 /****************************************************************************
  * Name: nxsig_dispatch_kernel_action
  ****************************************************************************/

 static void nxsig_dispatch_kernel_action(FAR struct tcb_s *stcb,
                                          FAR siginfo_t *info)
 {
   FAR struct task_group_s *group = stcb->group;
   FAR sigactq_t *sigact;

   sigact = nxsig_find_action(group, info->si_signo);
   if (sigact && (sigact->act.sa_flags & SA_KERNELHAND))
     {
       info->si_user = sigact->act.sa_user;
       (sigact->act.sa_sigaction)(info->si_signo, info, NULL);
     }
 }

 /****************************************************************************
  * Name: nxsig_add_pendingsignal
  *
  * Description:
  *   Add the specified signal to the signal pending list. NOTE: This
  *   function will queue only one entry for each pending signal. This
  *   was done intentionally so that a run-away sender cannot consume
  *   all of memory.
  *
  ****************************************************************************/

 static void nxsig_add_pendingsignal(FAR struct tcb_s *stcb,
                                     FAR siginfo_t *info)
 {
   FAR struct task_group_s *group;
   FAR sigpendq_t *sigpend;
   irqstate_t flags;

   DEBUGASSERT(stcb != NULL && stcb->group != NULL);
   group = stcb->group;

   /* Check if the signal is already pending for the group */

   sigpend = nxsig_find_pendingsignal(group, info->si_signo);
   if (sigpend != NULL)
     {
       /* The signal is already pending... retain only one copy */

       memcpy(&sigpend->info, info, sizeof(siginfo_t));
     }

   /* No... There is nothing pending in the group for this signo */

   else
     {
       /* Allocate a new pending signal entry */

       sigpend = nxsig_alloc_pendingsignal();
       if (sigpend != NULL)
         {
           /* Put the signal information into the allocated structure */

           memcpy(&sigpend->info, info, sizeof(siginfo_t));

           /* Add the structure to the group pending signal list */

           flags = enter_critical_section();
           sq_addlast((FAR sq_entry_t *)sigpend, &group->tg_sigpendingq);
           leave_critical_section(flags);
           nxsig_dispatch_kernel_action(stcb, &sigpend->info);
         }
     }

   DEBUGASSERT(sigpend);
 }

 /****************************************************************************
  * Public Functions
  ****************************************************************************/

 /****************************************************************************
  * Name: nxsig_tcbdispatch
  *
  * Description:
  *   All signals received the task (whatever the source) go through this
  *   function to be processed. This function is responsible for:
  *
  *   - Determining if the signal is blocked.
  *   - Queuing and dispatching signal actions
  *   - Unblocking tasks that are waiting for signals
  *   - Queuing pending signals.
  *
  *   This function will deliver the signal to the task associated with
  *   the specified TCB. This function should *not* typically be used
  *   to dispatch signals since it will *not* follow the group signal
  *   deliver algorithms.
  *
  * Returned Value:
  *   Returns 0 (OK) on success or a negated errno value on failure.
  *
  ****************************************************************************/

 int nxsig_tcbdispatch(FAR struct tcb_s *stcb, siginfo_t *info)
 {
   FAR struct tcb_s *rtcb = this_task();
   irqstate_t flags;
   int masked;
   int ret = OK;

   sinfo("TCB=%p pid=%d signo=%d code=%d value=%d masked=%s\n",
         stcb, stcb->pid, info->si_signo, info->si_code,
         info->si_value.sival_int,
         sigismember(&stcb->sigprocmask, info->si_signo) == 1 ? "YES" : "NO");

   DEBUGASSERT(stcb != NULL && info != NULL);

   /* Return ESRCH when thread was in exit processing */

   if ((stcb->flags & TCB_FLAG_EXIT_PROCESSING) != 0)
     {
       return -ESRCH;
     }

   /* Don't actually send a signal for signo 0. */

   if (info->si_signo == 0)
     {
       return OK;
     }

   /************************** MASKED SIGNAL ACTIONS *************************/

   masked = nxsig_ismember(&stcb->sigprocmask, info->si_signo);

 #ifdef CONFIG_LIB_SYSCALL
   /* Check if the signal is masked OR if the signal is received while we are
    * processing a system call -- in either case, it will be added to the
    * list of pending signals. Unmasked user signal actions will be deferred
    * while we process the system call.
    *
    * If a thread calls a blocking system call, the thread will still be
    * unblocked when the signal occurs (see OTHER SIGNAL HANDLING below), but
    * any associated user signal action will be deferred until the system
    * call returns. For example, if the application calls sem_wait(), the
    * following would occur:
    *
    *   1. System call entry logic will block user signal handling and call
    *      sem_wait() in kernel mode.
    *   2. sem_wait() will block,
    *   3. The receipt of the signal will cause any signal action to pend
    *      but will unblock sem_wait(),
    *   4. The sem_wait() system call will awaken and return EINTR,
    *   5. The pending signal action will occur after the sem_wait() system
    *      call returns to user mode.
    *
    * Syscall handlers (and logic-in-general within the OS) should not use
    * signal handlers.
    */

   if ((masked == 1) || (stcb->flags & TCB_FLAG_SYSCALL) != 0)
 #else
   /* Check if the signal is masked. In that case, it will be added to the
    * list of pending signals.
    */

   if (masked == 1)
 #endif
     {
       /* Check if the task is waiting for this pending signal. If so, then
        * unblock it. This must be performed in a critical section because
        * signals can be queued from the interrupt level.
        */

       flags = enter_critical_section();
       if (stcb->task_state == TSTATE_WAIT_SIG &&
           (masked == 0 ||
            nxsig_ismember(&stcb->sigwaitmask, info->si_signo)))
         {
           memcpy(&stcb->sigunbinfo, info, sizeof(siginfo_t));
           sigemptyset(&stcb->sigwaitmask);

           if (WDOG_ISACTIVE(&stcb->waitdog))
             {
               wd_cancel(&stcb->waitdog);
             }

           /* Remove the task from waitting list */

           dq_rem((FAR dq_entry_t *)stcb, &g_waitingforsignal);

           /* Add the task to ready-to-run task list and
            * perform the context switch if one is needed
            */

           if (nxsched_add_readytorun(stcb))
             {
               up_switch_context(stcb, rtcb);
             }

           leave_critical_section(flags);

 #ifdef CONFIG_LIB_SYSCALL
           /* Must also add signal action if in system call */

           if (masked == 0)
             {
               nxsig_add_pendingsignal(stcb, info);
             }
 #endif
         }

       /* Its not one we are waiting for... Add it to the list of pending
        * signals.
        */

       else
         {
           leave_critical_section(flags);
           nxsig_add_pendingsignal(stcb, info);
         }
     }

   /************************* UNMASKED SIGNAL ACTIONS ************************/

   else
     {
       /* Queue any sigaction's requested by this task. */

       ret = nxsig_queue_action(stcb, info);

       /* Deliver of the signal must be performed in a critical section */

       flags = enter_critical_section();

       /* Check if the task is waiting for an unmasked signal. If so, then
        * unblock it. This must be performed in a critical section because
        * signals can be queued from the interrupt level.
        */

       if (stcb->task_state == TSTATE_WAIT_SIG)
         {
           memcpy(&stcb->sigunbinfo, info, sizeof(siginfo_t));
           sigemptyset(&stcb->sigwaitmask);

           if (WDOG_ISACTIVE(&stcb->waitdog))
             {
               wd_cancel(&stcb->waitdog);
             }

           /* Remove the task from waitting list */

           dq_rem((FAR dq_entry_t *)stcb, &g_waitingforsignal);

           /* Add the task to ready-to-run task list and
            * perform the context switch if one is needed
            */

           if (nxsched_add_readytorun(stcb))
             {
               up_switch_context(stcb, rtcb);
             }
         }

       leave_critical_section(flags);

       /* If the task neither was waiting for the signal nor had a signal
        * handler attached to the signal, then the default action is
        * simply to ignore the signal
        */
     }

   /************************* OTHER SIGNAL HANDLING **************************/

   /* Performed only if the signal is unmasked. These actions also must
    * happen within a system call.
    */

   if (masked == 0)
     {
       flags = enter_critical_section();

       /* If the task is blocked waiting for a semaphore, then that task must
        * be unblocked when a signal is received.
        */

       if (stcb->task_state == TSTATE_WAIT_SEM)
         {
           nxsem_wait_irq(stcb, EINTR);
         }

 #if !defined(CONFIG_DISABLE_MQUEUE) || !defined(CONFIG_DISABLE_MQUEUE_SYSV)
       /* If the task is blocked waiting on a message queue, then that task
        * must be unblocked when a signal is received.
        */

       if (stcb->task_state == TSTATE_WAIT_MQNOTEMPTY ||
           stcb->task_state == TSTATE_WAIT_MQNOTFULL)
         {
           nxmq_wait_irq(stcb, EINTR);
         }
 #endif

 #ifdef CONFIG_SIG_SIGSTOP_ACTION
       /* If the task was stopped by SIGSTOP or SIGTSTP, then unblock the task
        * if SIGCONT is received.
        */

       if (stcb->task_state == TSTATE_TASK_STOPPED &&
           info->si_signo == SIGCONT)
         {
 #ifdef HAVE_GROUP_MEMBERS
           group_continue(stcb);
 #else
           /* Remove the task from waitting list */

           dq_rem((FAR dq_entry_t *)stcb, &g_stoppedtasks);

           /* Add the task to ready-to-run task list and
            * perform the context switch if one is needed
            */

           if (nxsched_add_readytorun(stcb))
             {
               up_switch_context(stcb, rtcb);
             }
 #endif
         }
 #endif

       leave_critical_section(flags);
     }

   /* In case nxsig_ismember failed due to an invalid signal number */

   if (masked < 0)
     {
       ret = -EINVAL;
     }

   return ret;
 }

 /****************************************************************************
  * Name: nxsig_dispatch
  *
  * Description:
  *   This is the front-end for nxsig_tcbdispatch that should be typically
  *   be used to dispatch a signal. If HAVE_GROUP_MEMBERS is defined,
  *   then function will follow the group signal delivery algorithms:
  *
  *   This front-end does the following things before calling
  *   nxsig_tcbdispatch.
  *
  *     With HAVE_GROUP_MEMBERS defined:
  *     - Get the TCB associated with the pid.
  *     - If the TCB was found, get the group from the TCB.
  *     - If the PID has already exited, lookup the group that that was
  *       started by this task.
  *     - Use the group to pick the TCB to receive the signal
  *     - Call nxsig_tcbdispatch with the TCB
  *
  *     With HAVE_GROUP_MEMBERS *not* defined
  *     - Get the TCB associated with the pid.
  *     - Call nxsig_tcbdispatch with the TCB
  *
  * Returned Value:
  *   Returns 0 (OK) on success or a negated errno value on failure.
  *
  ****************************************************************************/

 int nxsig_dispatch(pid_t pid, FAR siginfo_t *info)
 {
 #ifdef HAVE_GROUP_MEMBERS
   FAR struct tcb_s *stcb;
   FAR struct task_group_s *group;

   /* Get the TCB associated with the pid */

   stcb = nxsched_get_tcb(pid);
   if (stcb != NULL)
     {
       /* The task/thread associated with this PID is still active. Get its
        * task group.
        */

       group = stcb->group;
     }
   else
     {
       /* The task/thread associated with this PID has exited. In the normal
        * usage model, the PID should correspond to the PID of the task that
        * created the task group. Try looking it up.
        */

       group = group_findbypid(pid);
     }

   /* Did we locate the group? */

   if (group != NULL)
     {
       /* Yes.. call group_signal() to send the signal to the correct group
        * member.
        */

       return group_signal(group, info);
     }
   else
     {
       return -ESRCH;
     }

 #else
   FAR struct tcb_s *stcb;

   /* Get the TCB associated with the pid */

   stcb = nxsched_get_tcb(pid);
   if (stcb == NULL)
     {
       return -ESRCH;
     }

   return nxsig_tcbdispatch(stcb, info);

 #endif
 }
	/****************************************************************************
	* sched/signal/sig_dispatch.c
	*
	* Licensed to the Apache Software Foundation (ASF) under one or more
	* contributor license agreements. See the NOTICE file distributed with
	* this work for additional information regarding copyright ownership. The
	* ASF licenses this file to you under the Apache License, Version 2.0 (the
	* "License"); you may not use this file except in compliance with the
	* License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
	* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
	* License for the specific language governing permissions and limitations
	* under the License.
	*
	****************************************************************************/

	/****************************************************************************
	* Included Files
	****************************************************************************/

	#include <nuttx/config.h>

	#include <inttypes.h>
	#include <string.h>
	#include <signal.h>
	#include <unistd.h>
	#include <sched.h>
	#include <assert.h>
	#include <errno.h>
	#include <debug.h>

	#include <nuttx/irq.h>
	#include <nuttx/arch.h>
	#include <nuttx/signal.h>
	#include <nuttx/queue.h>

	#include "sched/sched.h"
	#include "group/group.h"
	#include "semaphore/semaphore.h"
	#include "signal/signal.h"
	#include "mqueue/mqueue.h"

	/****************************************************************************
	* Private Functions
	****************************************************************************/

	/****************************************************************************
	* Name: nxsig_queue_action
	*
	* Description:
	* Queue a signal action for delivery to a task.
	*
	* Returned Value:
	* Returns 0 (OK) on success or a negated errno value on failure.
	*
	****************************************************************************/

	static int nxsig_queue_action(FAR struct tcb_s stcb, siginfo_t info)
	{
	FAR sigactq_t *sigact;
	FAR sigq_t *sigq;
	irqstate_t flags;
	int ret = OK;

	sched_lock();
	DEBUGASSERT(stcb != NULL && stcb->group != NULL);

	/* Find the group sigaction associated with this signal */

	sigact = nxsig_find_action(stcb->group, info->si_signo);

	/* Check if a valid signal handler is available and if the signal is
	* unblocked. NOTE: There is no default action.
	*/

	if ((sigact) && (sigact->act.sa_u._sa_sigaction))
	{
	/* Allocate a new element for the signal queue. NOTE:
	* nxsig_alloc_pendingsigaction will force a system crash if it is
	* unable to allocate memory for the signal data.
	*/

	sigq = nxsig_alloc_pendingsigaction();
	if (!sigq)
	{
	ret = -ENOMEM;
	}
	else
	{
	/* Populate the new signal queue element */

	sigq->action.sighandler = sigact->act.sa_u._sa_sigaction;
	sigq->mask = sigact->act.sa_mask;
	if ((sigact->act.sa_flags & SA_NODEFER) == 0)
	{
	sigaddset(&sigq->mask, info->si_signo);
	}

	memcpy(&sigq->info, info, sizeof(siginfo_t));
	sigq->info.si_user = sigact->act.sa_user;

	/* Put it at the end of the pending signals list */

	flags = enter_critical_section();
	sq_addlast((FAR sq_entry_t *)sigq, &(stcb->sigpendactionq));

	/* Then schedule execution of the signal handling action on the
	* recipient's thread. SMP related handling will be done in
	* up_schedule_sigaction()
	*/

	up_schedule_sigaction(stcb, nxsig_deliver);
	leave_critical_section(flags);
	}
	}

	sched_unlock();
	return ret;
	}

	/****************************************************************************
	* Name: nxsig_alloc_pendingsignal
	*
	* Description:
	* Allocate a pending signal list entry
	*
	****************************************************************************/

	static FAR sigpendq_t *nxsig_alloc_pendingsignal(void)
	{
	FAR sigpendq_t *sigpend;
	irqstate_t flags;

	/* Check if we were called from an interrupt handler. */

	if (up_interrupt_context())
	{
	/* Try to get the pending signal structure from the free list */

	sigpend = (FAR sigpendq_t *)sq_remfirst(&g_sigpendingsignal);
	if (!sigpend)
	{
	/* If no pending signal structure is available in the free list,
	* then try the special list of structures reserved for
	* interrupt handlers
	*/

	sigpend = (FAR sigpendq_t *)sq_remfirst(&g_sigpendingirqsignal);
	}
	}

	/* If we were not called from an interrupt handler, then we are
	* free to allocate pending action structures if necessary.
	*/

	else
	{
	/* Try to get the pending signal structure from the free list */

	flags = enter_critical_section();
	sigpend = (FAR sigpendq_t *)sq_remfirst(&g_sigpendingsignal);
	leave_critical_section(flags);

	/* Check if we got one. */

	if (!sigpend)
	{
	/* No... Allocate the pending signal */

	sigpend = kmm_malloc(sizeof(sigpendq_t));

	/* Check if we got an allocated message */

	if (sigpend)
	{
	sigpend->type = SIG_ALLOC_DYN;
	}
	}
	}

	return sigpend;
	}

	/****************************************************************************
	* Name: nxsig_find_pendingsignal
	*
	* Description:
	* Find a specified element in the pending signal list
	*
	****************************************************************************/

	static FAR sigpendq_t *
	nxsig_find_pendingsignal(FAR struct task_group_s *group, int signo)
	{
	FAR sigpendq_t *sigpend = NULL;
	irqstate_t flags;

	DEBUGASSERT(group != NULL);

	/* Determining whether a signal is reliable or unreliable */

	if (SIGRTMIN <= signo && signo <= SIGRTMAX)
	{
	return sigpend;
	}

	/* Pending signals can be added from interrupt level. */

	flags = enter_critical_section();

	/* Search the list for a action pending on this signal */

	for (sigpend = (FAR sigpendq_t *)group->tg_sigpendingq.head;
	(sigpend && sigpend->info.si_signo != signo);
	sigpend = sigpend->flink);

	leave_critical_section(flags);
	return sigpend;
	}

	/****************************************************************************
	* Name: nxsig_dispatch_kernel_action
	****************************************************************************/

	static void nxsig_dispatch_kernel_action(FAR struct tcb_s *stcb,
	FAR siginfo_t *info)
	{
	FAR struct task_group_s *group = stcb->group;
	FAR sigactq_t *sigact;

	sigact = nxsig_find_action(group, info->si_signo);
	if (sigact && (sigact->act.sa_flags & SA_KERNELHAND))
	{
	info->si_user = sigact->act.sa_user;
	(sigact->act.sa_sigaction)(info->si_signo, info, NULL);
	}
	}

	/****************************************************************************
	* Name: nxsig_add_pendingsignal
	*
	* Description:
	* Add the specified signal to the signal pending list. NOTE: This
	* function will queue only one entry for each pending signal. This
	* was done intentionally so that a run-away sender cannot consume
	* all of memory.
	*
	****************************************************************************/

	static void nxsig_add_pendingsignal(FAR struct tcb_s *stcb,
	FAR siginfo_t *info)
	{
	FAR struct task_group_s *group;
	FAR sigpendq_t *sigpend;
	irqstate_t flags;

	DEBUGASSERT(stcb != NULL && stcb->group != NULL);
	group = stcb->group;

	/* Check if the signal is already pending for the group */

	sigpend = nxsig_find_pendingsignal(group, info->si_signo);
	if (sigpend != NULL)
	{
	/* The signal is already pending... retain only one copy */

	memcpy(&sigpend->info, info, sizeof(siginfo_t));
	}

	/* No... There is nothing pending in the group for this signo */

	else
	{
	/* Allocate a new pending signal entry */

	sigpend = nxsig_alloc_pendingsignal();
	if (sigpend != NULL)
	{
	/* Put the signal information into the allocated structure */

	memcpy(&sigpend->info, info, sizeof(siginfo_t));

	/* Add the structure to the group pending signal list */

	flags = enter_critical_section();
	sq_addlast((FAR sq_entry_t *)sigpend, &group->tg_sigpendingq);
	leave_critical_section(flags);
	nxsig_dispatch_kernel_action(stcb, &sigpend->info);
	}
	}

	DEBUGASSERT(sigpend);
	}

	/****************************************************************************
	* Public Functions
	****************************************************************************/

	/****************************************************************************
	* Name: nxsig_tcbdispatch
	*
	* Description:
	* All signals received the task (whatever the source) go through this
	* function to be processed. This function is responsible for:
	*
	* - Determining if the signal is blocked.
	* - Queuing and dispatching signal actions
	* - Unblocking tasks that are waiting for signals
	* - Queuing pending signals.
	*
	* This function will deliver the signal to the task associated with
	* the specified TCB. This function should not typically be used
	* to dispatch signals since it will not follow the group signal
	* deliver algorithms.
	*
	* Returned Value:
	* Returns 0 (OK) on success or a negated errno value on failure.
	*
	****************************************************************************/

	int nxsig_tcbdispatch(FAR struct tcb_s stcb, siginfo_t info)
	{
	FAR struct tcb_s *rtcb = this_task();
	irqstate_t flags;
	int masked;
	int ret = OK;

	sinfo("TCB=%p pid=%d signo=%d code=%d value=%d masked=%s\n",
	stcb, stcb->pid, info->si_signo, info->si_code,
	info->si_value.sival_int,
	sigismember(&stcb->sigprocmask, info->si_signo) == 1 ? "YES" : "NO");

	DEBUGASSERT(stcb != NULL && info != NULL);

	/* Return ESRCH when thread was in exit processing */

	if ((stcb->flags & TCB_FLAG_EXIT_PROCESSING) != 0)
	{
	return -ESRCH;
	}

	/* Don't actually send a signal for signo 0. */

	if (info->si_signo == 0)
	{
	return OK;
	}

	/************************ MASKED SIGNAL ACTIONS ***********************/

	masked = nxsig_ismember(&stcb->sigprocmask, info->si_signo);

	#ifdef CONFIG_LIB_SYSCALL
	/* Check if the signal is masked OR if the signal is received while we are
	* processing a system call -- in either case, it will be added to the
	* list of pending signals. Unmasked user signal actions will be deferred
	* while we process the system call.
	*
	* If a thread calls a blocking system call, the thread will still be
	* unblocked when the signal occurs (see OTHER SIGNAL HANDLING below), but
	* any associated user signal action will be deferred until the system
	* call returns. For example, if the application calls sem_wait(), the
	* following would occur:
	*
	* 1. System call entry logic will block user signal handling and call
	* sem_wait() in kernel mode.
	* 2. sem_wait() will block,
	* 3. The receipt of the signal will cause any signal action to pend
	* but will unblock sem_wait(),
	* 4. The sem_wait() system call will awaken and return EINTR,
	* 5. The pending signal action will occur after the sem_wait() system
	* call returns to user mode.
	*
	* Syscall handlers (and logic-in-general within the OS) should not use
	* signal handlers.
	*/

	if ((masked == 1) \|\| (stcb->flags & TCB_FLAG_SYSCALL) != 0)
	#else
	/* Check if the signal is masked. In that case, it will be added to the
	* list of pending signals.
	*/

	if (masked == 1)
	#endif
	{
	/* Check if the task is waiting for this pending signal. If so, then
	* unblock it. This must be performed in a critical section because
	* signals can be queued from the interrupt level.
	*/

	flags = enter_critical_section();
	if (stcb->task_state == TSTATE_WAIT_SIG &&
	(masked == 0 \|\|
	nxsig_ismember(&stcb->sigwaitmask, info->si_signo)))
	{
	memcpy(&stcb->sigunbinfo, info, sizeof(siginfo_t));
	sigemptyset(&stcb->sigwaitmask);

	if (WDOG_ISACTIVE(&stcb->waitdog))
	{
	wd_cancel(&stcb->waitdog);
	}

	/* Remove the task from waitting list */

	dq_rem((FAR dq_entry_t *)stcb, &g_waitingforsignal);

	/* Add the task to ready-to-run task list and
	* perform the context switch if one is needed
	*/

	if (nxsched_add_readytorun(stcb))
	{
	up_switch_context(stcb, rtcb);
	}

	leave_critical_section(flags);

	#ifdef CONFIG_LIB_SYSCALL
	/* Must also add signal action if in system call */

	if (masked == 0)
	{
	nxsig_add_pendingsignal(stcb, info);
	}
	#endif
	}

	/* Its not one we are waiting for... Add it to the list of pending
	* signals.
	*/

	else
	{
	leave_critical_section(flags);
	nxsig_add_pendingsignal(stcb, info);
	}
	}

	/*********************** UNMASKED SIGNAL ACTIONS **********************/

	else
	{
	/* Queue any sigaction's requested by this task. */

	ret = nxsig_queue_action(stcb, info);

	/* Deliver of the signal must be performed in a critical section */

	flags = enter_critical_section();

	/* Check if the task is waiting for an unmasked signal. If so, then
	* unblock it. This must be performed in a critical section because
	* signals can be queued from the interrupt level.
	*/

	if (stcb->task_state == TSTATE_WAIT_SIG)
	{
	memcpy(&stcb->sigunbinfo, info, sizeof(siginfo_t));
	sigemptyset(&stcb->sigwaitmask);

	if (WDOG_ISACTIVE(&stcb->waitdog))
	{
	wd_cancel(&stcb->waitdog);
	}

	/* Remove the task from waitting list */

	dq_rem((FAR dq_entry_t *)stcb, &g_waitingforsignal);

	/* Add the task to ready-to-run task list and
	* perform the context switch if one is needed
	*/

	if (nxsched_add_readytorun(stcb))
	{
	up_switch_context(stcb, rtcb);
	}
	}

	leave_critical_section(flags);

	/* If the task neither was waiting for the signal nor had a signal
	* handler attached to the signal, then the default action is
	* simply to ignore the signal
	*/
	}

	/*********************** OTHER SIGNAL HANDLING ************************/

	/* Performed only if the signal is unmasked. These actions also must
	* happen within a system call.
	*/

	if (masked == 0)
	{
	flags = enter_critical_section();

	/* If the task is blocked waiting for a semaphore, then that task must
	* be unblocked when a signal is received.
	*/

	if (stcb->task_state == TSTATE_WAIT_SEM)
	{
	nxsem_wait_irq(stcb, EINTR);
	}

	#if !defined(CONFIG_DISABLE_MQUEUE) \|\| !defined(CONFIG_DISABLE_MQUEUE_SYSV)
	/* If the task is blocked waiting on a message queue, then that task
	* must be unblocked when a signal is received.
	*/

	if (stcb->task_state == TSTATE_WAIT_MQNOTEMPTY \|\|
	stcb->task_state == TSTATE_WAIT_MQNOTFULL)
	{
	nxmq_wait_irq(stcb, EINTR);
	}
	#endif

	#ifdef CONFIG_SIG_SIGSTOP_ACTION
	/* If the task was stopped by SIGSTOP or SIGTSTP, then unblock the task
	* if SIGCONT is received.
	*/

	if (stcb->task_state == TSTATE_TASK_STOPPED &&
	info->si_signo == SIGCONT)
	{
	#ifdef HAVE_GROUP_MEMBERS
	group_continue(stcb);
	#else
	/* Remove the task from waitting list */

	dq_rem((FAR dq_entry_t *)stcb, &g_stoppedtasks);

	/* Add the task to ready-to-run task list and
	* perform the context switch if one is needed
	*/

	if (nxsched_add_readytorun(stcb))
	{
	up_switch_context(stcb, rtcb);
	}
	#endif
	}
	#endif

	leave_critical_section(flags);
	}

	/* In case nxsig_ismember failed due to an invalid signal number */

	if (masked < 0)
	{
	ret = -EINVAL;
	}

	return ret;
	}

	/****************************************************************************
	* Name: nxsig_dispatch
	*
	* Description:
	* This is the front-end for nxsig_tcbdispatch that should be typically
	* be used to dispatch a signal. If HAVE_GROUP_MEMBERS is defined,
	* then function will follow the group signal delivery algorithms:
	*
	* This front-end does the following things before calling
	* nxsig_tcbdispatch.
	*
	* With HAVE_GROUP_MEMBERS defined:
	* - Get the TCB associated with the pid.
	* - If the TCB was found, get the group from the TCB.
	* - If the PID has already exited, lookup the group that that was
	* started by this task.
	* - Use the group to pick the TCB to receive the signal
	* - Call nxsig_tcbdispatch with the TCB
	*
	* With HAVE_GROUP_MEMBERS not defined
	* - Get the TCB associated with the pid.
	* - Call nxsig_tcbdispatch with the TCB
	*
	* Returned Value:
	* Returns 0 (OK) on success or a negated errno value on failure.
	*
	****************************************************************************/

	int nxsig_dispatch(pid_t pid, FAR siginfo_t *info)
	{
	#ifdef HAVE_GROUP_MEMBERS
	FAR struct tcb_s *stcb;
	FAR struct task_group_s *group;

	/* Get the TCB associated with the pid */

	stcb = nxsched_get_tcb(pid);
	if (stcb != NULL)
	{
	/* The task/thread associated with this PID is still active. Get its
	* task group.
	*/

	group = stcb->group;
	}
	else
	{
	/* The task/thread associated with this PID has exited. In the normal
	* usage model, the PID should correspond to the PID of the task that
	* created the task group. Try looking it up.
	*/

	group = group_findbypid(pid);
	}

	/* Did we locate the group? */

	if (group != NULL)
	{
	/* Yes.. call group_signal() to send the signal to the correct group
	* member.
	*/

	return group_signal(group, info);
	}
	else
	{
	return -ESRCH;
	}

	#else
	FAR struct tcb_s *stcb;

	/* Get the TCB associated with the pid */

	stcb = nxsched_get_tcb(pid);
	if (stcb == NULL)
	{
	return -ESRCH;
	}

	return nxsig_tcbdispatch(stcb, info);

	#endif
	}