/**************************************************************************** * sched/pthread/pthread_create.c * * Copyright (C) 2007-2009, 2011, 2013-2018 Gregory Nutt. All rights * reserved. * Author: Gregory Nutt * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name NuttX nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "sched/sched.h" #include "group/group.h" #include "clock/clock.h" #include "pthread/pthread.h" /**************************************************************************** * Public Data ****************************************************************************/ /* Default pthread attributes (see include/nuttx/pthread.h). When configured * to build separate kernel- and user-address spaces, this global is * duplicated in each address spaced. This copy can only be shared within * the kernel address space. */ const pthread_attr_t g_default_pthread_attr = PTHREAD_ATTR_INITIALIZER; /**************************************************************************** * Private Data ****************************************************************************/ #if CONFIG_TASK_NAME_SIZE > 0 /* This is the name for name-less pthreads */ static const char g_pthreadname[] = ""; #endif /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: pthread_argsetup * * Description: * This functions sets up parameters in the Task Control Block (TCB) in * preparation for starting a new thread. * * pthread_argsetup() is called from task_init() and task_start() to create * a new task (with arguments cloned via strdup) or pthread_create() which * has one argument passed by value (distinguished by the pthread boolean * argument). * * Input Parameters: * tcb - Address of the new task's TCB * arg - The argument to provide to the pthread on startup. * * Returned Value: * None * ****************************************************************************/ static inline void pthread_argsetup(FAR struct pthread_tcb_s *tcb, pthread_addr_t arg) { #if CONFIG_TASK_NAME_SIZE > 0 /* Copy the pthread name into the TCB */ strncpy(tcb->cmn.name, g_pthreadname, CONFIG_TASK_NAME_SIZE); tcb->cmn.name[CONFIG_TASK_NAME_SIZE] = '\0'; #endif /* CONFIG_TASK_NAME_SIZE */ /* For pthreads, args are strictly pass-by-value; that actual * type wrapped by pthread_addr_t is unknown. */ tcb->arg = arg; } /**************************************************************************** * Name: pthread_addjoininfo * * Description: * Add a join structure to the local data set. * * Input Parameters: * pjoin * * Returned Value: * None * * Assumptions: * The caller has provided protection from re-entrancy. * ****************************************************************************/ static inline void pthread_addjoininfo(FAR struct task_group_s *group, FAR struct join_s *pjoin) { pjoin->next = NULL; if (!group->tg_jointail) { group->tg_joinhead = pjoin; } else { group->tg_jointail->next = pjoin; } group->tg_jointail = pjoin; } /**************************************************************************** * Name: pthread_start * * Description: * This function is the low level entry point into the pthread * * Input Parameters: * None * ****************************************************************************/ static void pthread_start(void) { FAR struct pthread_tcb_s *ptcb = (FAR struct pthread_tcb_s *)this_task(); FAR struct task_group_s *group = ptcb->cmn.group; FAR struct join_s *pjoin = (FAR struct join_s *)ptcb->joininfo; pthread_addr_t exit_status; DEBUGASSERT(group && pjoin); /* Successfully spawned, add the pjoin to our data set. */ (void)pthread_sem_take(&group->tg_joinsem, false); pthread_addjoininfo(group, pjoin); (void)pthread_sem_give(&group->tg_joinsem); /* Report to the spawner that we successfully started. */ pjoin->started = true; (void)pthread_sem_give(&pjoin->data_sem); /* The priority of this thread may have been boosted to avoid priority * inversion problems. If that is the case, then drop to the correct * execution priority. */ if (ptcb->cmn.sched_priority > ptcb->cmn.init_priority) { DEBUGVERIFY(nxsched_setpriority(&ptcb->cmn, ptcb->cmn.init_priority)); } /* Pass control to the thread entry point. In the kernel build this has to * be handled differently if we are starting a user-space pthread; we have * to switch to user-mode before calling into the pthread. */ #if defined(CONFIG_BUILD_PROTECTED) || defined(CONFIG_BUILD_KERNEL) up_pthread_start(ptcb->cmn.entry.pthread, ptcb->arg); exit_status = NULL; #else exit_status = (*ptcb->cmn.entry.pthread)(ptcb->arg); #endif /* The thread has returned (should never happen in the kernel mode case) */ pthread_exit(exit_status); } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: pthread_create * * Description: * This function creates and activates a new thread with a specified * attributes. * * Input Parameters: * thread * attr * start_routine * arg * * Returned Value: * OK (0) on success; a (non-negated) errno value on failure. The errno * variable is not set. * ****************************************************************************/ int pthread_create(FAR pthread_t *thread, FAR const pthread_attr_t *attr, pthread_startroutine_t start_routine, pthread_addr_t arg) { FAR struct pthread_tcb_s *ptcb; FAR struct join_s *pjoin; struct sched_param param; int policy; int errcode; pid_t pid; int ret; #ifdef HAVE_TASK_GROUP bool group_joined = false; #endif /* If attributes were not supplied, use the default attributes */ if (!attr) { attr = &g_default_pthread_attr; } /* Allocate a TCB for the new task. */ ptcb = (FAR struct pthread_tcb_s *)kmm_zalloc(sizeof(struct pthread_tcb_s)); if (!ptcb) { serr("ERROR: Failed to allocate TCB\n"); return ENOMEM; } #ifdef HAVE_TASK_GROUP /* Bind the parent's group to the new TCB (we have not yet joined the * group). */ ret = group_bind(ptcb); if (ret < 0) { errcode = ENOMEM; goto errout_with_tcb; } #endif #ifdef CONFIG_ARCH_ADDRENV /* Share the address environment of the parent task group. */ ret = up_addrenv_attach(ptcb->cmn.group, this_task()); if (ret < 0) { errcode = -ret; goto errout_with_tcb; } #endif /* Allocate a detachable structure to support pthread_join logic */ pjoin = (FAR struct join_s *)kmm_zalloc(sizeof(struct join_s)); if (!pjoin) { serr("ERROR: Failed to allocate join\n"); errcode = ENOMEM; goto errout_with_tcb; } if (attr->stackaddr) { /* Use pre-allocated stack */ ret = up_use_stack((FAR struct tcb_s *)ptcb, attr->stackaddr, attr->stacksize); } else { /* Allocate the stack for the TCB */ ret = up_create_stack((FAR struct tcb_s *)ptcb, attr->stacksize, TCB_FLAG_TTYPE_PTHREAD); } if (ret != OK) { errcode = ENOMEM; goto errout_with_join; } /* Should we use the priority and scheduler specified in the pthread * attributes? Or should we use the current thread's priority and * scheduler? */ if (attr->inheritsched == PTHREAD_INHERIT_SCHED) { /* Get the priority (and any other scheduling parameters) for this * thread. */ ret = nxsched_getparam(0, ¶m); if (ret < 0) { errcode = -ret; goto errout_with_join; } /* Get the scheduler policy for this thread */ policy = nxsched_getscheduler(0); if (policy < 0) { errcode = -policy; goto errout_with_join; } } else { /* Use the scheduler policy and policy the attributes */ policy = attr->policy; param.sched_priority = attr->priority; #ifdef CONFIG_SCHED_SPORADIC param.sched_ss_low_priority = attr->low_priority; param.sched_ss_max_repl = attr->max_repl; param.sched_ss_repl_period.tv_sec = attr->repl_period.tv_sec; param.sched_ss_repl_period.tv_nsec = attr->repl_period.tv_nsec; param.sched_ss_init_budget.tv_sec = attr->budget.tv_sec; param.sched_ss_init_budget.tv_nsec = attr->budget.tv_nsec; #endif } #ifdef CONFIG_SCHED_SPORADIC if (policy == SCHED_SPORADIC) { FAR struct sporadic_s *sporadic; sclock_t repl_ticks; sclock_t budget_ticks; /* Convert timespec values to system clock ticks */ (void)clock_time2ticks(¶m.sched_ss_repl_period, &repl_ticks); (void)clock_time2ticks(¶m.sched_ss_init_budget, &budget_ticks); /* The replenishment period must be greater than or equal to the * budget period. */ if (repl_ticks < budget_ticks) { errcode = EINVAL; goto errout_with_join; } /* Initialize the sporadic policy */ ret = sched_sporadic_initialize(&ptcb->cmn); if (ret >= 0) { sporadic = ptcb->cmn.sporadic; DEBUGASSERT(sporadic != NULL); /* Save the sporadic scheduling parameters */ sporadic->hi_priority = param.sched_priority; sporadic->low_priority = param.sched_ss_low_priority; sporadic->max_repl = param.sched_ss_max_repl; sporadic->repl_period = repl_ticks; sporadic->budget = budget_ticks; /* And start the first replenishment interval */ ret = sched_sporadic_start(&ptcb->cmn); } /* Handle any failures */ if (ret < 0) { errcode = -ret; goto errout_with_join; } } #endif /* Initialize the task control block */ ret = pthread_schedsetup(ptcb, param.sched_priority, pthread_start, start_routine); if (ret != OK) { errcode = EBUSY; goto errout_with_join; } #ifdef CONFIG_SMP /* pthread_schedsetup() will set the affinity mask by inheriting the * setting from the parent task. We need to override this setting * with the value from the pthread attributes unless that value is * zero: Zero is the default value and simply means to inherit the * parent thread's affinity mask. */ if (attr->affinity != 0) { ptcb->cmn.affinity = attr->affinity; } #endif /* Configure the TCB for a pthread receiving on parameter * passed by value */ pthread_argsetup(ptcb, arg); #ifdef HAVE_TASK_GROUP /* Join the parent's task group */ ret = group_join(ptcb); if (ret < 0) { errcode = ENOMEM; goto errout_with_join; } group_joined = true; #endif /* Attach the join info to the TCB. */ ptcb->joininfo = (FAR void *)pjoin; /* Set the appropriate scheduling policy in the TCB */ ptcb->cmn.flags &= ~TCB_FLAG_POLICY_MASK; switch (policy) { default: DEBUGPANIC(); case SCHED_FIFO: ptcb->cmn.flags |= TCB_FLAG_SCHED_FIFO; break; #if CONFIG_RR_INTERVAL > 0 case SCHED_RR: ptcb->cmn.flags |= TCB_FLAG_SCHED_RR; ptcb->cmn.timeslice = MSEC2TICK(CONFIG_RR_INTERVAL); break; #endif #ifdef CONFIG_SCHED_SPORADIC case SCHED_SPORADIC: ptcb->cmn.flags |= TCB_FLAG_SCHED_SPORADIC; break; #endif #if 0 /* Not supported */ case SCHED_OTHER: ptcb->cmn.flags |= TCB_FLAG_SCHED_OTHER; break; #endif } #ifdef CONFIG_CANCELLATION_POINTS /* Set the deferred cancellation type */ ptcb->cmn.flags |= TCB_FLAG_CANCEL_DEFERRED; #endif /* Get the assigned pid before we start the task (who knows what * could happen to ptcb after this!). Copy this ID into the join structure * as well. */ pid = (int)ptcb->cmn.pid; pjoin->thread = (pthread_t)pid; /* Initialize the semaphores in the join structure to zero. */ ret = nxsem_init(&pjoin->data_sem, 0, 0); if (ret == OK) { ret = nxsem_init(&pjoin->exit_sem, 0, 0); } if (ret < 0) { ret = -ret; } /* Thse semaphores are used for signaling and, hence, should not have * priority inheritance enabled. */ if (ret == OK) { ret = nxsem_setprotocol(&pjoin->data_sem, SEM_PRIO_NONE); if (ret == OK) { ret = nxsem_setprotocol(&pjoin->exit_sem, SEM_PRIO_NONE); } if (ret < 0) { ret = -ret; } } /* If the priority of the new pthread is lower than the priority of the * parent thread, then starting the pthread could result in both the * parent and the pthread to be blocked. This is a recipe for priority * inversion issues. * * We avoid this here by boosting the priority of the (inactive) pthread * so it has the same priority as the parent thread. */ if (ret == OK) { FAR struct tcb_s *parent = this_task(); DEBUGASSERT(parent != NULL); if (ptcb->cmn.sched_priority < parent->sched_priority) { ret = nxsched_setpriority(&ptcb->cmn, parent->sched_priority); if (ret < 0) { ret = -ret; } } } /* Then activate the task */ sched_lock(); if (ret == OK) { ret = task_activate((FAR struct tcb_s *)ptcb); if (ret < 0) { ret = get_errno(); } } if (ret == OK) { /* Wait for the task to actually get running and to register * its join structure. */ (void)pthread_sem_take(&pjoin->data_sem, false); /* Return the thread information to the caller */ if (thread) { *thread = (pthread_t)pid; } if (!pjoin->started) { ret = EINVAL; } sched_unlock(); (void)nxsem_destroy(&pjoin->data_sem); } else { sched_unlock(); dq_rem((FAR dq_entry_t *)ptcb, (FAR dq_queue_t *)&g_inactivetasks); (void)nxsem_destroy(&pjoin->data_sem); (void)nxsem_destroy(&pjoin->exit_sem); errcode = EIO; goto errout_with_join; } return ret; errout_with_join: sched_kfree(pjoin); ptcb->joininfo = NULL; errout_with_tcb: #ifdef HAVE_TASK_GROUP /* Clear group binding */ if (ptcb && !group_joined) { ptcb->cmn.group = NULL; } #endif sched_releasetcb((FAR struct tcb_s *)ptcb, TCB_FLAG_TTYPE_PTHREAD); return errcode; }