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nuttx/sched/task/task_setup.c
Ville Juven 0dedbcd4ae task/pthread_cancelpt: Move cancel point handling to libc, data to TLS 
This moves task / thread cancel point logic from the NuttX kernel into
libc, while the data needed by the cancel point logic is moved to TLS.

The change is an enabler to move user-space APIs to libc as well, for
a coherent user/kernel separation.
2023-11-15 08:52:04 -08:00

761 lines
22 KiB
C
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/****************************************************************************
* sched/task/task_setup.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 <sys/types.h>
#include <ctype.h>
#include <stdint.h>
#include <sched.h>
#include <string.h>
#include <assert.h>
#include <errno.h>
#include <debug.h>
#include <nuttx/arch.h>
#include <nuttx/sched.h>
#include <nuttx/signal.h>
#include <nuttx/tls.h>
#include "sched/sched.h"
#include "pthread/pthread.h"
#include "group/group.h"
#include "task/task.h"
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
/* This is an artificial limit to detect error conditions where an argv[]
* list is not properly terminated.
*/
#define MAX_STACK_ARGS 256
/****************************************************************************
* Private Data
****************************************************************************/
/* This is the name for un-named tasks */
static const char g_noname[] = "<noname>";
/****************************************************************************
* Private Functions
****************************************************************************/
/****************************************************************************
* Name: nxtask_assign_pid
*
* Description:
* This function assigns the next unique task ID to a task.
*
* Input Parameters:
* tcb - TCB of task
*
* Returned Value:
* OK on success; ERROR on failure (errno is not set)
*
****************************************************************************/
static int nxtask_assign_pid(FAR struct tcb_s *tcb)
{
FAR struct tcb_s **pidhash;
pid_t next_pid;
int hash_ndx;
void *temp;
int i;
/* NOTE:
* ERROR means that the g_pidhash[] table is completely full.
* We cannot allow another task to be started.
*/
/* Protect the following operation with a critical section
* because g_pidhash is accessed from an interrupt context
*/
irqstate_t flags = enter_critical_section();
/* We'll try every allowable pid */
retry:
/* Get the next process ID candidate */
next_pid = g_lastpid + 1;
for (i = 0; i < g_npidhash; i++)
{
/* Verify that the next_pid is in the valid range */
if (next_pid <= 0)
{
next_pid = 1;
}
/* Get the hash_ndx associated with the next_pid */
hash_ndx = PIDHASH(next_pid);
/* Check if there is a (potential) duplicate of this pid */
if (!g_pidhash[hash_ndx])
{
/* Assign this PID to the task */
g_pidhash[hash_ndx] = tcb;
tcb->pid = next_pid;
g_lastpid = next_pid;
leave_critical_section(flags);
return OK;
}
next_pid++;
}
/* If we get here, then the g_pidhash[] table is completely full.
* We will alloc new space and copy original g_pidhash to it to
* expand space.
*/
pidhash = kmm_zalloc(g_npidhash * 2 * sizeof(*pidhash));
if (pidhash == NULL)
{
leave_critical_section(flags);
return -ENOMEM;
}
g_npidhash *= 2;
/* All original pid and hash_ndx are mismatch,
* so we need to rebuild their relationship
*/
for (i = 0; i < g_npidhash / 2; i++)
{
hash_ndx = PIDHASH(g_pidhash[i]->pid);
DEBUGASSERT(pidhash[hash_ndx] == NULL);
pidhash[hash_ndx] = g_pidhash[i];
}
/* Release resource for original g_pidhash, using new g_pidhash */
temp = g_pidhash;
g_pidhash = pidhash;
kmm_free(temp);
/* Let's try every allowable pid again */
goto retry;
}
/****************************************************************************
* Name: nxtask_inherit_affinity
*
* Description:
* exec(), task_create(), and vfork() all inherit the affinity mask from
* the parent thread. This is the default for pthread_create() as well
* but the affinity mask can be specified in the pthread attributes as
* well. pthread_setup() will have to fix up the affinity mask in this
* case.
*
* Input Parameters:
* tcb - The TCB of the new task.
*
* Returned Value:
* None
*
* Assumptions:
* The parent of the new task is the task at the head of the assigned task
* list for the current CPU.
*
****************************************************************************/
#ifdef CONFIG_SMP
static inline void nxtask_inherit_affinity(FAR struct tcb_s *tcb)
{
FAR struct tcb_s *rtcb = this_task();
tcb->affinity = rtcb->affinity;
}
#else
# define nxtask_inherit_affinity(tcb)
#endif
/****************************************************************************
* Name: nxtask_save_parent
*
* Description:
* Save the task ID of the parent task in the child task's group and
* allocate a child status structure to catch the child task's exit
* status.
*
* Input Parameters:
* tcb - The TCB of the new, child task.
* ttype - Type of the new thread: task, pthread, or kernel thread
*
* Returned Value:
* None
*
* Assumptions:
* The parent of the new task is the task at the head of the ready-to-run
* list.
*
****************************************************************************/
#ifdef CONFIG_SCHED_HAVE_PARENT
static inline void nxtask_save_parent(FAR struct tcb_s *tcb, uint8_t ttype)
{
DEBUGASSERT(tcb != NULL && tcb->group != NULL);
/* Only newly created tasks (and kernel threads) have parents. None of
* this logic applies to pthreads with reside in the same group as the
* parent and share that same child/parent relationships.
*/
#ifndef CONFIG_DISABLE_PTHREAD
if ((tcb->flags & TCB_FLAG_TTYPE_MASK) != TCB_FLAG_TTYPE_PTHREAD)
#endif
{
/* Get the TCB of the parent task. In this case, the calling task. */
FAR struct tcb_s *rtcb = this_task();
DEBUGASSERT(rtcb != NULL && rtcb->group != NULL);
/* Save the PID of the parent tasks' task group in the child's task
* group. Copy the ID from the parent's task group structure to
* child's task group.
*/
tcb->group->tg_ppid = rtcb->group->tg_pid;
#ifdef CONFIG_SCHED_CHILD_STATUS
/* Tasks can also suppress retention of their child status by applying
* the SA_NOCLDWAIT flag with sigaction().
*/
if ((rtcb->group->tg_flags & GROUP_FLAG_NOCLDWAIT) == 0)
{
FAR struct child_status_s *child;
/* Make sure that there is not already a structure for this PID in
* the parent TCB. There should not be.
*/
child = group_find_child(rtcb->group, tcb->pid);
DEBUGASSERT(child == NULL);
if (child == NULL)
{
/* Allocate a new status structure */
child = group_alloc_child();
}
/* Did we successfully find/allocate the child status structure? */
DEBUGASSERT(child != NULL);
if (child != NULL)
{
/* Yes.. Initialize the structure */
child->ch_flags = ttype;
child->ch_pid = tcb->pid;
child->ch_status = 0;
/* Add the entry into the group's list of children */
group_add_child(rtcb->group, child);
}
}
#else /* CONFIG_SCHED_CHILD_STATUS */
/* Child status is not retained. Simply keep track of the number
* child tasks created.
*/
DEBUGASSERT(rtcb->group->tg_nchildren < UINT16_MAX);
rtcb->group->tg_nchildren++;
#endif /* CONFIG_SCHED_CHILD_STATUS */
}
}
#else
# define nxtask_save_parent(tcb,ttype)
#endif
/****************************************************************************
* Name: nxtask_dup_dspace
*
* Description:
* When a new task or thread is created from a PIC module, then that
* module (probably) intends the task or thread to execute in the same
* D-Space. This function will duplicate the D-Space for that purpose.
*
* Input Parameters:
* tcb - The TCB of the new task.
*
* Returned Value:
* None
*
* Assumptions:
* The parent of the new task is the task at the head of the ready-to-run
* list.
*
****************************************************************************/
#ifdef CONFIG_PIC
static inline void nxtask_dup_dspace(FAR struct tcb_s *tcb)
{
FAR struct tcb_s *rtcb = this_task();
if (rtcb->dspace != NULL)
{
/* Copy the D-Space structure reference and increment the reference
* count on the memory. The D-Space memory will persist until the
* last thread exits (see nxsched_release_tcb()).
*/
tcb->dspace = rtcb->dspace;
tcb->dspace->crefs++;
}
}
#else
# define nxtask_dup_dspace(tcb)
#endif
/****************************************************************************
* Name: nxthread_setup_scheduler
*
* Description:
* This functions initializes the common portions of the Task Control Block
* (TCB) in preparation for starting a new thread.
*
* nxthread_setup_scheduler() is called from nxtask_setup_scheduler() and
* pthread_setup_scheduler().
*
* Input Parameters:
* tcb - Address of the new task's TCB
* priority - Priority of the new task
* start - Thread startup routine
* entry - Thread user entry point
* ttype - Type of the new thread: task, pthread, or kernel thread
*
* Returned Value:
* OK on success; ERROR on failure.
*
* This function can only failure is it is unable to assign a new, unique
* task ID to the TCB (errno is not set).
*
****************************************************************************/
static int nxthread_setup_scheduler(FAR struct tcb_s *tcb, int priority,
start_t start, CODE void *entry,
uint8_t ttype)
{
FAR struct tcb_s *rtcb = this_task();
int ret;
/* Assign a unique task ID to the task. */
ret = nxtask_assign_pid(tcb);
if (ret == OK)
{
/* Save task priority and entry point in the TCB */
tcb->sched_priority = (uint8_t)priority;
tcb->init_priority = (uint8_t)priority;
#ifdef CONFIG_PRIORITY_INHERITANCE
tcb->base_priority = (uint8_t)priority;
#endif
tcb->start = start;
tcb->entry.main = (main_t)entry;
/* Save the thread type. This setting will be needed in
* up_initial_state() is called.
*/
ttype &= TCB_FLAG_TTYPE_MASK;
tcb->flags &= ~TCB_FLAG_TTYPE_MASK;
tcb->flags |= ttype;
/* Set the appropriate scheduling policy in the TCB */
tcb->flags &= ~TCB_FLAG_POLICY_MASK;
#if CONFIG_RR_INTERVAL > 0
tcb->flags |= TCB_FLAG_SCHED_RR;
tcb->timeslice = MSEC2TICK(CONFIG_RR_INTERVAL);
#else
tcb->flags |= TCB_FLAG_SCHED_FIFO;
#endif
/* Save the task ID of the parent task in the TCB and allocate
* a child status structure.
*/
nxtask_save_parent(tcb, ttype);
#ifdef CONFIG_SMP
/* exec(), task_create(), and vfork() all inherit the affinity mask
* from the parent thread. This is the default for pthread_create()
* as well but the affinity mask can be specified in the pthread
* attributes as well. pthread_create() will have to fix up the
* affinity mask in this case.
*/
nxtask_inherit_affinity(tcb);
#endif
/* exec(), pthread_create(), task_create(), and vfork() all
* inherit the signal mask of the parent thread.
*/
tcb->sigprocmask = rtcb->sigprocmask;
/* Initialize the task state. It does not get a valid state
* until it is activated.
*/
tcb->task_state = TSTATE_TASK_INVALID;
/* Clone the parent tasks D-Space (if it was running PIC). This
* must be done before calling up_initial_state() so that the
* state setup will take the PIC address base into account.
*/
nxtask_dup_dspace(tcb);
/* Initialize the processor-specific portion of the TCB */
up_initial_state(tcb);
/* Add the task to the inactive task list */
sched_lock();
dq_addfirst((FAR dq_entry_t *)tcb, &g_inactivetasks);
tcb->task_state = TSTATE_TASK_INACTIVE;
sched_unlock();
}
return ret;
}
/****************************************************************************
* Name: nxtask_setup_name
*
* Description:
* Assign 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 void nxtask_setup_name(FAR struct task_tcb_s *tcb,
FAR const char *name)
{
FAR char *dst = tcb->cmn.name;
int i;
/* Copy the name into the TCB */
for (i = 0; i < CONFIG_TASK_NAME_SIZE; i++)
{
char c = *name++;
if (c == '\0')
{
break;
}
*dst++ = isspace(c) ? '_' : c;
}
*dst = '\0';
}
#else
# define nxtask_setup_name(t,n)
#endif /* CONFIG_TASK_NAME_SIZE */
/****************************************************************************
* Name: nxtask_setup_stackargs
*
* Description:
* This functions is called only from nxtask_setup_arguments() It will
* allocate space on the new task's stack and will copy the argv[] array
* and all strings to the task's stack where it is readily accessible to
* the task. Data on the stack, on the other hand, is guaranteed to be
* accessible no matter what privilege mode the task runs in.
*
* Input Parameters:
* tcb - Address of the new task's TCB
* argv - A pointer to an array of input parameters. The array should be
* terminated with a NULL argv[] value. If no parameters are
* required, argv may be NULL.
*
* Returned Value:
* Zero (OK) on success; a negated errno on failure.
*
****************************************************************************/
static int nxtask_setup_stackargs(FAR struct task_tcb_s *tcb,
FAR const char *name,
FAR char * const argv[])
{
FAR char **stackargv;
FAR char *str;
size_t strtablen;
size_t argvlen;
int nbytes;
int argc;
int i;
/* Get the size of the task name (including the NUL terminator) */
strtablen = (strlen(name) + 1);
/* Count the number of arguments and get the accumulated size of the
* argument strings (including the null terminators). The argument count
* does not include the task name in that will be in argv[0].
*/
argc = 0;
if (argv != NULL)
{
/* A NULL argument terminates the list */
while (argv[argc])
{
/* Add the size of this argument (with NUL terminator).
* Check each time if the accumulated size exceeds the
* size of the allocated stack.
*/
strtablen += (strlen(argv[argc]) + 1);
DEBUGASSERT(strtablen < tcb->cmn.adj_stack_size);
if (strtablen >= tcb->cmn.adj_stack_size)
{
return -ENAMETOOLONG;
}
/* Increment the number of args. Here is a sanity check to
* prevent running away with an unterminated argv[] list.
* MAX_STACK_ARGS should be sufficiently large that this never
* happens in normal usage.
*/
DEBUGASSERT(argc <= MAX_STACK_ARGS);
if (++argc > MAX_STACK_ARGS)
{
return -E2BIG;
}
}
}
/* Allocate a stack frame to hold argv[] array and the strings. NOTE
* that argc + 2 entries are needed: The number of arguments plus the
* task name plus a NULL argv[] entry to terminate the list.
*/
argvlen = (argc + 2) * sizeof(FAR char *);
stackargv = (FAR char **)up_stack_frame(&tcb->cmn, argvlen + strtablen);
DEBUGASSERT(stackargv != NULL);
if (stackargv == NULL)
{
return -ENOMEM;
}
/* Get the address of the string table that will lie immediately after
* the argv[] array and mark it as a null string.
*/
str = (FAR char *)stackargv + argvlen;
/* Copy the task name. Increment str to skip over the task name and its
* NUL terminator in the string buffer.
*/
stackargv[0] = str;
nbytes = strlen(name) + 1;
strlcpy(str, name, strtablen);
str += nbytes;
strtablen -= nbytes;
/* Copy each argument */
for (i = 0; i < argc; i++)
{
/* Save the pointer to the location in the string buffer and copy
* the argument into the buffer. Increment str to skip over the
* argument and its NUL terminator in the string buffer.
*/
stackargv[i + 1] = str;
nbytes = strlen(argv[i]) + 1;
strlcpy(str, argv[i], strtablen);
str += nbytes;
strtablen -= nbytes;
}
/* Put a terminator entry at the end of the argv[] array. Then save the
* argv[] array pointer in the TCB where it will be recovered later by
* nxtask_start().
*/
stackargv[argc + 1] = NULL;
tcb->cmn.group->tg_info->argv = stackargv;
return OK;
}
/****************************************************************************
* Public Functions
****************************************************************************/
/****************************************************************************
* Name: nxtask_setup_scheduler
*
* Description:
* This functions initializes a Task Control Block (TCB) in preparation
* for starting a new task.
*
* nxtask_setup_scheduler() is called from nxtask_init() and
* nxtask_start().
*
* Input Parameters:
* tcb - Address of the new task's TCB
* priority - Priority of the new task
* start - Start-up function (probably nxtask_start())
* main - Application start point of the new task
* ttype - Type of the new thread: task or kernel thread
*
* Returned Value:
* OK on success; ERROR on failure.
*
* This function can only failure is it is unable to assign a new, unique
* task ID to the TCB (errno is not set).
*
****************************************************************************/
int nxtask_setup_scheduler(FAR struct task_tcb_s *tcb, int priority,
start_t start, main_t main, uint8_t ttype)
{
/* Perform common thread setup */
return nxthread_setup_scheduler((FAR struct tcb_s *)tcb, priority,
start, (CODE void *)main, ttype);
}
/****************************************************************************
* Name: pthread_setup_scheduler
*
* Description:
* This functions initializes a Task Control Block (TCB) in preparation
* for starting a new pthread.
*
* pthread_setup_scheduler() is called from pthread_create(),
*
* Input Parameters:
* tcb - Address of the new task's TCB
* priority - Priority of the new task
* start - Start-up function (probably pthread_start())
* entry - Entry point of the new pthread
* ttype - Type of the new thread: task, pthread, or kernel thread
*
* Returned Value:
* OK on success; ERROR on failure.
*
* This function can only failure is it is unable to assign a new, unique
* task ID to the TCB (errno is not set).
*
****************************************************************************/
#ifndef CONFIG_DISABLE_PTHREAD
int pthread_setup_scheduler(FAR struct pthread_tcb_s *tcb, int priority,
start_t start, pthread_startroutine_t entry)
{
/* Perform common thread setup */
return nxthread_setup_scheduler((FAR struct tcb_s *)tcb, priority,
start, (CODE void *)entry,
TCB_FLAG_TTYPE_PTHREAD);
}
#endif
/****************************************************************************
* Name: nxtask_setup_arguments
*
* Description:
* This functions sets up parameters in the Task Control Block (TCB) in
* preparation for starting a new thread.
*
* nxtask_setup_arguments() is called only from nxtask_init() and
* nxtask_start() to create a new task. In the "normal" case, the argv[]
* array is a structure in the TCB, the arguments are cloned via strdup.
*
* In the kernel build case, the argv[] array and all strings are copied
* to the task's stack. This is done because the TCB (and kernel allocated
* strings) are only accessible in kernel-mode. Data on the stack, on the
* other hand, is guaranteed to be accessible no matter what mode the
* task runs in.
*
* Input Parameters:
* tcb - Address of the new task's TCB
* name - Name of the new task (not used)
* argv - A pointer to an array of input parameters. The array should be
* terminated with a NULL argv[] value. If no parameters are
* required, argv may be NULL.
*
* Returned Value:
* OK
*
****************************************************************************/
int nxtask_setup_arguments(FAR struct task_tcb_s *tcb,
FAR const char *name, FAR char * const argv[])
{
/* Give a name to the unnamed tasks */
if (!name)
{
name = (FAR char *)g_noname;
}
/* Setup the task name */
nxtask_setup_name(tcb, name);
/* Copy the argv[] array and all strings are to the task's stack. Data on
* the stack is guaranteed to be accessible by the ask no matter what
* privilege mode the task runs in.
*/
return nxtask_setup_stackargs(tcb, name, argv);
}
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