/**************************************************************************** * sched/task/task_vfork * * 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 #include #include #include #include #include #include #include #include #include #include "sched/sched.h" #include "group/group.h" #include "task/task.h" /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /* vfork() requires architecture-specific support as well as waipid(). */ #if defined(CONFIG_ARCH_HAVE_VFORK) && defined(CONFIG_SCHED_WAITPID) /* This is an artificial limit to detect error conditions where an argv[] * list is not properly terminated. */ #define MAX_VFORK_ARGS 256 /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: nxvfork_setup_name * * Description: * Copy the task name. * * Input Parameters: * tcb - Address of the new task's TCB * name - Name of the new task * * Returned Value: * None * ****************************************************************************/ #if CONFIG_TASK_NAME_SIZE > 0 static inline void nxvfork_setup_name(FAR struct tcb_s *parent, FAR struct task_tcb_s *child) { /* Copy the name from the parent into the child TCB */ strncpy(child->cmn.name, parent->name, CONFIG_TASK_NAME_SIZE); } #else # define nxvfork_setup_name(p,c) #endif /* CONFIG_TASK_NAME_SIZE */ /**************************************************************************** * Name: nxvfork_setup_stackargs * * Description: * Clone the task arguments in the same relative positions on the child's * stack. * * Input Parameters: * parent - Address of the parent task's TCB * child - Address of the child task's TCB * * Returned Value: * Zero (OK) on success; a negated errno on failure. * ****************************************************************************/ static inline int nxvfork_setup_stackargs(FAR struct tcb_s *parent, FAR struct task_tcb_s *child) { /* Is the parent a task? or a pthread? Only tasks (and kernel threads) * have command line arguments. */ child->argv = NULL; if ((parent->flags & TCB_FLAG_TTYPE_MASK) != TCB_FLAG_TTYPE_PTHREAD) { FAR struct task_tcb_s *ptcb = (FAR struct task_tcb_s *)parent; uintptr_t offset; int argc; /* Get the address correction */ offset = (uintptr_t)child->cmn.adj_stack_ptr - (uintptr_t)parent->adj_stack_ptr; /* Change the child argv[] to point into its stack (instead of its * parent's stack). */ child->argv = (FAR char **)((uintptr_t)ptcb->argv + offset); /* Copy the adjusted address for each argument */ argc = 0; while (ptcb->argv[argc]) { uintptr_t newaddr = (uintptr_t)ptcb->argv[argc] + offset; child->argv[argc] = (FAR char *)newaddr; /* Increment the number of args. Here is a sanity check to * prevent running away with an unterminated argv[] list. * MAX_VFORK_ARGS should be sufficiently large that this never * happens in normal usage. */ if (++argc > MAX_VFORK_ARGS) { return -E2BIG; } } /* Put a terminator entry at the end of the child argv[] array. */ child->argv[argc] = NULL; } return OK; } /**************************************************************************** * Name: nxvfork_setup_arguments * * Description: * Clone the argument list from the parent to the child. * * Input Parameters: * parent - Address of the parent task's TCB * child - Address of the child task's TCB * * Returned Value: * Zero (OK) on success; a negated errno on failure. * ****************************************************************************/ static inline int nxvfork_setup_arguments(FAR struct tcb_s *parent, FAR struct task_tcb_s *child) { /* Clone the task name */ nxvfork_setup_name(parent, child); /* Adjust and copy the argv[] array. */ return nxvfork_setup_stackargs(parent, child); } /**************************************************************************** * Name: nxvfork_sizeof_arguments * * Description: * Get the parent's argument size. * * Input Parameters: * parent - Address of the parent task's TCB * * Return Value: * The parent's argument size. * ****************************************************************************/ static inline size_t nxvfork_sizeof_arguments(FAR struct tcb_s *parent) { if ((parent->flags & TCB_FLAG_TTYPE_MASK) != TCB_FLAG_TTYPE_PTHREAD) { FAR struct task_tcb_s *ptcb = (FAR struct task_tcb_s *)parent; size_t strtablen = 0; int argc = 0; while (ptcb->argv[argc]) { /* Add the size of this argument (with NUL terminator) */ strtablen += strlen(ptcb->argv[argc++]) + 1; } /* Return the size to hold argv[] array and the strings. */ return (argc + 1) * sizeof(FAR char *) + strtablen; } else { return 0; } } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: nxtask_setup_vfork * * Description: * The vfork() function has the same effect as fork(), except that the * behavior is undefined if the process created by vfork() either modifies * any data other than a variable of type pid_t used to store the return * value from vfork(), or returns from the function in which vfork() was * called, or calls any other function before successfully calling _exit() * or one of the exec family of functions. * * This function provides one step in the overall vfork() sequence: It * Allocates and initializes the child task's TCB. The overall sequence * is: * * 1) User code calls vfork(). vfork() is provided in * architecture-specific code. * 2) vfork()and calls nxtask_setup_vfork(). * 3) nxtask_setup_vfork() allocates and configures the child task's TCB. * This consists of: * - Allocation of the child task's TCB. * - Initialization of file descriptors and streams * - Configuration of environment variables * - Setup the input parameters for the task. * - Initialization of the TCB (including call to up_initial_state() * 4) up_vfork() provides any additional operating context. up_vfork must: * - Allocate and initialize the stack * - Initialize special values in any CPU registers that were not * already configured by up_initial_state() * 5) up_vfork() then calls nxtask_start_vfork() * 6) nxtask_start_vfork() then executes the child thread. * * Input Parameters: * retaddr - Return address * argsize - Location to return the argument size * * Returned Value: * Upon successful completion, nxtask_setup_vfork() returns a pointer to * newly allocated and initialized child task's TCB. NULL is returned * on any failure and the errno is set appropriately. * ****************************************************************************/ FAR struct task_tcb_s *nxtask_setup_vfork(start_t retaddr, size_t *argsize) { FAR struct tcb_s *parent = this_task(); FAR struct task_tcb_s *child; uint8_t ttype; int priority; int ret; DEBUGASSERT(retaddr != NULL && argsize != NULL); /* Get the type of the fork'ed task (kernel or user) */ if ((parent->flags & TCB_FLAG_TTYPE_MASK) == TCB_FLAG_TTYPE_KERNEL) { /* Fork'ed from a kernel thread */ ttype = TCB_FLAG_TTYPE_KERNEL; } else { /* Fork'ed from a user task or pthread */ ttype = TCB_FLAG_TTYPE_TASK; } /* Allocate a TCB for the child task. */ child = (FAR struct task_tcb_s *)kmm_zalloc(sizeof(struct task_tcb_s)); if (!child) { serr("ERROR: Failed to allocate TCB\n"); set_errno(ENOMEM); return NULL; } /* Allocate a new task group with the same privileges as the parent */ ret = group_allocate(child, parent->flags); if (ret < 0) { goto errout_with_tcb; } /* Associate file descriptors with the new task */ ret = group_setuptaskfiles(child); if (ret < OK) { goto errout_with_tcb; } /* Get the priority of the parent task */ #ifdef CONFIG_PRIORITY_INHERITANCE priority = parent->base_priority; /* "Normal," unboosted priority */ #else priority = parent->sched_priority; /* Current priority */ #endif /* Initialize the task control block. This calls up_initial_state() */ sinfo("Child priority=%d start=%p\n", priority, retaddr); ret = nxtask_setup_scheduler(child, priority, retaddr, parent->entry.main, ttype); if (ret < OK) { goto errout_with_tcb; } /* Return the argument size */ *argsize = nxvfork_sizeof_arguments(parent); sinfo("parent=%p, returning child=%p\n", parent, child); return child; errout_with_tcb: nxsched_release_tcb((FAR struct tcb_s *)child, ttype); set_errno(-ret); return NULL; } /**************************************************************************** * Name: nxtask_start_vfork * * Description: * The vfork() function has the same effect as fork(), except that the * behavior is undefined if the process created by vfork() either modifies * any data other than a variable of type pid_t used to store the return * value from vfork(), or returns from the function in which vfork() was * called, or calls any other function before successfully calling _exit() * or one of the exec family of functions. * * This function provides one step in the overall vfork() sequence: It * starts execution of the previously initialized TCB. The overall * sequence is: * * 1) User code calls vfork() * 2) Architecture-specific code provides vfork()and calls * nxtask_setup_vfork(). * 3) nxtask_setup_vfork() allocates and configures the child task's TCB. * This consists of: * - Allocation of the child task's TCB. * - Initialization of file descriptors and streams * - Configuration of environment variables * - Setup the input parameters for the task. * - Initialization of the TCB (including call to up_initial_state() * 4) vfork() provides any additional operating context. vfork must: * - Allocate and initialize the stack * - Initialize special values in any CPU registers that were not * already configured by up_initial_state() * 5) vfork() then calls nxtask_start_vfork() * 6) nxtask_start_vfork() then executes the child thread. * * Input Parameters: * retaddr - The return address from vfork() where the child task * will be started. * * Returned Value: * Upon successful completion, vfork() returns 0 to the child process and * returns the process ID of the child process to the parent process. * Otherwise, -1 is returned to the parent, no child process is created, * and errno is set to indicate the error. * ****************************************************************************/ pid_t nxtask_start_vfork(FAR struct task_tcb_s *child) { FAR struct tcb_s *parent = this_task(); pid_t pid; int rc; int ret; sinfo("Starting Child TCB=%p, parent=%p\n", child, this_task()); DEBUGASSERT(child); /* Duplicate the original argument list in the forked child TCB */ ret = nxvfork_setup_arguments(parent, child); if (ret < 0) { nxtask_abort_vfork(child, -ret); return ERROR; } /* Now we have enough in place that we can join the group */ ret = group_initialize(child); if (ret < 0) { nxtask_abort_vfork(child, -ret); return ERROR; } /* Get the assigned pid before we start the task */ pid = (int)child->cmn.pid; /* Eliminate a race condition by disabling pre-emption. The child task * can be instantiated, but cannot run until we call waitpid(). This * assures us that we cannot miss the death-of-child signal (only * needed in the SMP case). */ sched_lock(); /* Activate the task */ nxtask_activate((FAR struct tcb_s *)child); /* The child task has not yet ran because pre-emption is disabled. * The child task has the same priority as the parent task, so that * would typically be the case anyway. However, in the SMP * configuration, the child thread might have already ran on * another CPU if pre-emption were not disabled. * * It is a requirement that the parent environment be stable while * vfork runs; the child thread is still dependent on things in the * parent thread... like the pointers into parent thread's stack * which will still appear in the child's registers and environment. * * We assure that by waiting for the child thread to exit before * returning to the parent thread. NOTE that pre-emption will be * re-enabled while we are waiting, giving the child thread the * opportunity to run. */ rc = 0; #ifdef CONFIG_DEBUG_FEATURES ret = waitpid(pid, &rc, 0); if (ret < 0) { serr("ERROR: waitpid failed: %d\n", errno); } #else waitpid(pid, &rc, 0); #endif sched_unlock(); return pid; } /**************************************************************************** * Name: nxtask_abort_vfork * * Description: * Recover from any errors after nxtask_setup_vfork() was called. * * Returned Value: * None * ****************************************************************************/ void nxtask_abort_vfork(FAR struct task_tcb_s *child, int errcode) { /* The TCB was added to the active task list by nxtask_setup_scheduler() */ dq_rem((FAR dq_entry_t *)child, (FAR dq_queue_t *)&g_inactivetasks); /* Release the TCB */ nxsched_release_tcb((FAR struct tcb_s *)child, child->cmn.flags & TCB_FLAG_TTYPE_MASK); set_errno(errcode); } #endif /* CONFIG_ARCH_HAVE_VFORK && CONFIG_SCHED_WAITPID */