DPDK  20.05.0
examples/performance-thread/common/lthread.c
/*
* SPDX-License-Identifier: BSD-3-Clause
* Copyright 2015 Intel Corporation.
* Copyright 2012 Hasan Alayli <halayli@gmail.com>
*/
#define RTE_MEM 1
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <stddef.h>
#include <limits.h>
#include <inttypes.h>
#include <unistd.h>
#include <pthread.h>
#include <fcntl.h>
#include <sys/time.h>
#include <sys/mman.h>
#include <rte_log.h>
#include <ctx.h>
#include <stack.h>
#include "lthread_api.h"
#include "lthread.h"
#include "lthread_timer.h"
#include "lthread_tls.h"
#include "lthread_objcache.h"
#include "lthread_diag.h"
/*
* This function gets called after an lthread function has returned.
*/
void _lthread_exit_handler(struct lthread *lt)
{
lt->state |= BIT(ST_LT_EXITED);
if (!(lt->state & BIT(ST_LT_DETACH))) {
/* thread is this not explicitly detached
* it must be joinable, so we call lthread_exit().
*/
lthread_exit(NULL);
}
/* if we get here the thread is detached so we can reschedule it,
* allowing the scheduler to free it
*/
_reschedule();
}
/*
* Free resources allocated to an lthread
*/
void _lthread_free(struct lthread *lt)
{
DIAG_EVENT(lt, LT_DIAG_LTHREAD_FREE, lt, 0);
/* invoke any user TLS destructor functions */
_lthread_tls_destroy(lt);
/* free memory allocated for TLS defined using RTE_PER_LTHREAD macros */
if (sizeof(void *) < (uint64_t)RTE_PER_LTHREAD_SECTION_SIZE)
_lthread_objcache_free(lt->tls->root_sched->per_lthread_cache,
lt->per_lthread_data);
/* free pthread style TLS memory */
_lthread_objcache_free(lt->tls->root_sched->tls_cache, lt->tls);
/* free the stack */
_lthread_objcache_free(lt->stack_container->root_sched->stack_cache,
lt->stack_container);
/* now free the thread */
_lthread_objcache_free(lt->root_sched->lthread_cache, lt);
}
/*
* Allocate a stack and maintain a cache of stacks
*/
struct lthread_stack *_stack_alloc(void)
{
struct lthread_stack *s;
s = _lthread_objcache_alloc((THIS_SCHED)->stack_cache);
RTE_ASSERT(s != NULL);
s->root_sched = THIS_SCHED;
s->stack_size = LTHREAD_MAX_STACK_SIZE;
return s;
}
/*
* Execute a ctx by invoking the start function
* On return call an exit handler if the user has provided one
*/
static void _lthread_exec(void *arg)
{
struct lthread *lt = (struct lthread *)arg;
/* invoke the contexts function */
lt->fun(lt->arg);
/* do exit handling */
if (lt->exit_handler != NULL)
lt->exit_handler(lt);
}
/*
* Initialize an lthread
* Set its function, args, and exit handler
*/
void
_lthread_init(struct lthread *lt,
lthread_func_t fun, void *arg, lthread_exit_func exit_handler)
{
/* set ctx func and args */
lt->fun = fun;
lt->arg = arg;
lt->exit_handler = exit_handler;
/* set initial state */
lt->birth = _sched_now();
lt->state = BIT(ST_LT_INIT);
lt->join = LT_JOIN_INITIAL;
}
/*
* set the lthread stack
*/
void _lthread_set_stack(struct lthread *lt, void *stack, size_t stack_size)
{
/* set stack */
lt->stack = stack;
lt->stack_size = stack_size;
arch_set_stack(lt, _lthread_exec);
}
/*
* Create an lthread on the current scheduler
* If there is no current scheduler on this pthread then first create one
*/
int
lthread_create(struct lthread **new_lt, int lcore_id,
lthread_func_t fun, void *arg)
{
if ((new_lt == NULL) || (fun == NULL))
return POSIX_ERRNO(EINVAL);
if (lcore_id < 0)
lcore_id = rte_lcore_id();
else if (lcore_id > LTHREAD_MAX_LCORES)
return POSIX_ERRNO(EINVAL);
struct lthread *lt = NULL;
if (THIS_SCHED == NULL) {
THIS_SCHED = _lthread_sched_create(0);
if (THIS_SCHED == NULL) {
perror("Failed to create scheduler");
return POSIX_ERRNO(EAGAIN);
}
}
/* allocate a thread structure */
lt = _lthread_objcache_alloc((THIS_SCHED)->lthread_cache);
if (lt == NULL)
return POSIX_ERRNO(EAGAIN);
bzero(lt, sizeof(struct lthread));
lt->root_sched = THIS_SCHED;
/* set the function args and exit handlder */
_lthread_init(lt, fun, arg, _lthread_exit_handler);
/* put it in the ready queue */
*new_lt = lt;
if (lcore_id < 0)
lcore_id = rte_lcore_id();
DIAG_CREATE_EVENT(lt, LT_DIAG_LTHREAD_CREATE);
rte_wmb();
_ready_queue_insert(_lthread_sched_get(lcore_id), lt);
return 0;
}
/*
* Schedules lthread to sleep for `nsecs`
* setting the lthread state to LT_ST_SLEEPING.
* lthread state is cleared upon resumption or expiry.
*/
static inline void _lthread_sched_sleep(struct lthread *lt, uint64_t nsecs)
{
uint64_t state = lt->state;
uint64_t clks = _ns_to_clks(nsecs);
if (clks) {
_timer_start(lt, clks);
lt->state = state | BIT(ST_LT_SLEEPING);
}
DIAG_EVENT(lt, LT_DIAG_LTHREAD_SLEEP, clks, 0);
_suspend();
}
/*
* Cancels any running timer.
* This can be called multiple times on the same lthread regardless if it was
* sleeping or not.
*/
int _lthread_desched_sleep(struct lthread *lt)
{
uint64_t state = lt->state;
if (state & BIT(ST_LT_SLEEPING)) {
_timer_stop(lt);
state &= (CLEARBIT(ST_LT_SLEEPING) & CLEARBIT(ST_LT_EXPIRED));
lt->state = state | BIT(ST_LT_READY);
return 1;
}
return 0;
}
/*
* set user data pointer in an lthread
*/
void lthread_set_data(void *data)
{
if (sizeof(void *) == RTE_PER_LTHREAD_SECTION_SIZE)
THIS_LTHREAD->per_lthread_data = data;
}
/*
* Retrieve user data pointer from an lthread
*/
void *lthread_get_data(void)
{
return THIS_LTHREAD->per_lthread_data;
}
/*
* Return the current lthread handle
*/
struct lthread *lthread_current(void)
{
struct lthread_sched *sched = THIS_SCHED;
if (sched)
return sched->current_lthread;
return NULL;
}
/*
* Tasklet to cancel a thread
*/
static void *
_cancel(void *arg)
{
struct lthread *lt = (struct lthread *) arg;
lt->state |= BIT(ST_LT_CANCELLED);
lthread_detach();
return NULL;
}
/*
* Mark the specified as canceled
*/
int lthread_cancel(struct lthread *cancel_lt)
{
struct lthread *lt;
if ((cancel_lt == NULL) || (cancel_lt == THIS_LTHREAD))
return POSIX_ERRNO(EINVAL);
DIAG_EVENT(cancel_lt, LT_DIAG_LTHREAD_CANCEL, cancel_lt, 0);
if (cancel_lt->sched != THIS_SCHED) {
/* spawn task-let to cancel the thread */
lthread_create(&lt,
cancel_lt->sched->lcore_id,
_cancel,
cancel_lt);
return 0;
}
cancel_lt->state |= BIT(ST_LT_CANCELLED);
return 0;
}
/*
* Suspend the current lthread for specified time
*/
void lthread_sleep(uint64_t nsecs)
{
struct lthread *lt = THIS_LTHREAD;
_lthread_sched_sleep(lt, nsecs);
}
/*
* Suspend the current lthread for specified time
*/
void lthread_sleep_clks(uint64_t clks)
{
struct lthread *lt = THIS_LTHREAD;
uint64_t state = lt->state;
if (clks) {
_timer_start(lt, clks);
lt->state = state | BIT(ST_LT_SLEEPING);
}
DIAG_EVENT(lt, LT_DIAG_LTHREAD_SLEEP, clks, 0);
_suspend();
}
/*
* Requeue the current thread to the back of the ready queue
*/
void lthread_yield(void)
{
struct lthread *lt = THIS_LTHREAD;
DIAG_EVENT(lt, LT_DIAG_LTHREAD_YIELD, 0, 0);
_ready_queue_insert(THIS_SCHED, lt);
ctx_switch(&(THIS_SCHED)->ctx, &lt->ctx);
}
/*
* Exit the current lthread
* If a thread is joining pass the user pointer to it
*/
void lthread_exit(void *ptr)
{
struct lthread *lt = THIS_LTHREAD;
/* if thread is detached (this is not valid) just exit */
if (lt->state & BIT(ST_LT_DETACH))
return;
/* There is a race between lthread_join() and lthread_exit()
* - if exit before join then we suspend and resume on join
* - if join before exit then we resume the joining thread
*/
if ((lt->join == LT_JOIN_INITIAL)
&& rte_atomic64_cmpset(&lt->join, LT_JOIN_INITIAL,
LT_JOIN_EXITING)) {
DIAG_EVENT(lt, LT_DIAG_LTHREAD_EXIT, 1, 0);
_suspend();
/* set the exit value */
if ((ptr != NULL) && (lt->lt_join->lt_exit_ptr != NULL))
*(lt->lt_join->lt_exit_ptr) = ptr;
/* let the joining thread know we have set the exit value */
lt->join = LT_JOIN_EXIT_VAL_SET;
} else {
DIAG_EVENT(lt, LT_DIAG_LTHREAD_EXIT, 0, 0);
/* set the exit value */
if ((ptr != NULL) && (lt->lt_join->lt_exit_ptr != NULL))
*(lt->lt_join->lt_exit_ptr) = ptr;
/* let the joining thread know we have set the exit value */
lt->join = LT_JOIN_EXIT_VAL_SET;
_ready_queue_insert(lt->lt_join->sched,
(struct lthread *)lt->lt_join);
}
/* wait until the joinging thread has collected the exit value */
while (lt->join != LT_JOIN_EXIT_VAL_READ)
_reschedule();
/* reset join state */
lt->join = LT_JOIN_INITIAL;
/* detach it so its resources can be released */
lt->state |= (BIT(ST_LT_DETACH) | BIT(ST_LT_EXITED));
}
/*
* Join an lthread
* Suspend until the joined thread returns
*/
int lthread_join(struct lthread *lt, void **ptr)
{
if (lt == NULL)
return POSIX_ERRNO(EINVAL);
struct lthread *current = THIS_LTHREAD;
uint64_t lt_state = lt->state;
/* invalid to join a detached thread, or a thread that is joined */
if ((lt_state & BIT(ST_LT_DETACH)) || (lt->join == LT_JOIN_THREAD_SET))
return POSIX_ERRNO(EINVAL);
/* pointer to the joining thread and a poingter to return a value */
lt->lt_join = current;
current->lt_exit_ptr = ptr;
/* There is a race between lthread_join() and lthread_exit()
* - if join before exit we suspend and will resume when exit is called
* - if exit before join we resume the exiting thread
*/
if ((lt->join == LT_JOIN_INITIAL)
&& rte_atomic64_cmpset(&lt->join, LT_JOIN_INITIAL,
LT_JOIN_THREAD_SET)) {
DIAG_EVENT(current, LT_DIAG_LTHREAD_JOIN, lt, 1);
_suspend();
} else {
DIAG_EVENT(current, LT_DIAG_LTHREAD_JOIN, lt, 0);
_ready_queue_insert(lt->sched, lt);
}
/* wait for exiting thread to set return value */
while (lt->join != LT_JOIN_EXIT_VAL_SET)
_reschedule();
/* collect the return value */
if (ptr != NULL)
*ptr = *current->lt_exit_ptr;
/* let the exiting thread proceed to exit */
lt->join = LT_JOIN_EXIT_VAL_READ;
return 0;
}
/*
* Detach current lthread
* A detached thread cannot be joined
*/
void lthread_detach(void)
{
struct lthread *lt = THIS_LTHREAD;
DIAG_EVENT(lt, LT_DIAG_LTHREAD_DETACH, 0, 0);
uint64_t state = lt->state;
lt->state = state | BIT(ST_LT_DETACH);
}
/*
* Set function name of an lthread
* this is a debug aid
*/
void lthread_set_funcname(const char *f)
{
struct lthread *lt = THIS_LTHREAD;
strncpy(lt->funcname, f, sizeof(lt->funcname));
lt->funcname[sizeof(lt->funcname)-1] = 0;
}
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