Echtzeitdatenverarbeitung/include/rtai_sched.h

529 lines
14 KiB
C
Raw Normal View History

2020-10-26 10:38:48 +01:00
/*
* Copyright (C) 1999-2017 Paolo Mantegazza <mantegazza@aero.polimi.it>
* Copyright (C) 2019 Alec Ari <neotheuser@ymail.com>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
*/
#ifndef _RTAI_SCHED_H
#define _RTAI_SCHED_H
#include <rtai.h>
#ifndef __KERNEL__
#include <sys/time.h>
#include <time.h>
#include <errno.h>
#include <rtai_types.h>
#endif /* __KERNEL__ */
#define RT_SCHED_UP 1
#define RT_SCHED_SMP 2
#define RT_SCHED_MUP 3
#define RT_SCHED_HIGHEST_PRIORITY 0
#define RT_SCHED_LOWEST_PRIORITY 0x3fffFfff
#define RT_SCHED_LINUX_PRIORITY 0x7fffFfff
#define RT_RESEM_SUSPDEL (-0x7fffFfff)
#define RT_SCHED_READY 1
#define RT_SCHED_SUSPENDED 2
#define RT_SCHED_DELAYED 4
#define RT_SCHED_SEMAPHORE 8
#define RT_SCHED_SEND 16
#define RT_SCHED_RECEIVE 32
#define RT_SCHED_RPC 64
#define RT_SCHED_RETURN 128
#define RT_SCHED_MBXSUSP 256
#define RT_SCHED_SFTRDY 512
#define RT_SCHED_POLL 1024
#define RT_SCHED_SIGSUSP (1 << 15)
#define RT_RWLINV (11) // keep this the highest
#define RT_CHGPORTERR (10)
#define RT_CHGPORTOK (9)
#define RT_NETIMOUT (8)
#define RT_DEADLOK (7)
#define RT_PERM (6)
#define RT_OBJINV (5)
#define RT_OBJREM (4)
#define RT_TIMOUT (3)
#define RT_UNBLKD (2)
#define RT_TMROVRN (1) // keep this the lowest, must be 1
#define RTP_RWLINV ((void *)RT_RWLINV)
#define RTP_CHGPORTERR ((void *)RT_CHGPORTERR)
#define RTP_CHGPORTOK ((void *)RT_CHGPORTOK)
#define RTP_NETIMOUT ((void *)RT_NETIMOUT)
#define RTP_DEADLOK ((void *)RT_DEADLOK)
#define RTP_PERM ((void *)RT_PERM)
#define RTP_OBJINV ((void *)RT_OBJINV)
#define RTP_OBJREM ((void *)RT_OBJREM)
#define RTP_TIMOUT ((void *)RT_TIMOUT)
#define RTP_UNBLKD ((void *)RT_UNBLKD)
#define RTP_TMROVRN ((void *)RT_TMROVRN)
#define RTP_HIGERR (RTP_RWLINV)
#define RTP_LOWERR (RTP_TMROVRN)
#if CONFIG_RTAI_USE_NEWERR
#define RTE_BASE (0x3FFFFF00)
#define RTE_RWLINV (RTE_BASE + RT_RWLINV)
#define RTE_CHGPORTERR (RTE_BASE + RT_CHGPORTERR)
#define RTE_CHGPORTOK (RTE_BASE + RT_CHGPORTOK)
#define RTE_NETIMOUT (RTE_BASE + RT_NETIMOUT)
#define RTE_DEADLOK (RTE_BASE + RT_DEADLOK)
#define RTE_PERM (RTE_BASE + RT_PERM)
#define RTE_OBJINV (RTE_BASE + RT_OBJINV)
#define RTE_OBJREM (RTE_BASE + RT_OBJREM)
#define RTE_TIMOUT (RTE_BASE + RT_TIMOUT)
#define RTE_UNBLKD (RTE_BASE + RT_UNBLKD)
#define RTE_TMROVRN (RTE_BASE + RT_TMROVRN)
#define RTE_HIGERR (RTE_RWLINV)
#define RTE_LOWERR (RTE_TMROVRN)
#else
#define RTE_BASE (0xFFFB)
#define RTE_RWLINV (RTE_BASE + RT_RWLINV)
#define RTE_CHGPORTERR (RTE_BASE + RT_CHGPORTERR)
#define RTE_CHGPORTOK (RTE_BASE + RT_CHGPORTOK)
#define RTE_NETIMOUT (RTE_BASE + RT_NETIMOUT)
#define RTE_DEADLOK (RTE_BASE + RT_DEADLOK)
#define RTE_PERM (RTE_BASE + RT_PERM)
#define RTE_OBJINV (RTE_BASE + RT_OBJREM)
#define RTE_OBJREM (RTE_BASE + RT_OBJREM)
#define RTE_TIMOUT (RTE_BASE + RT_TIMOUT)
#define RTE_UNBLKD (RTE_BASE + RT_UNBLKD)
#define RTE_TMROVRN (RTE_BASE + RT_TMROVRN)
#define RTE_HIGERR (RTE_RWLINV)
#define RTE_LOWERR (RTE_TMROVRN)
#endif
#define RT_EINTR (RTE_UNBLKD)
#define rt_is_reterr(i) (i >= RTE_LOWERR)
#define RT_IRQ_TASK 0
#define RT_IRQ_TASKLET 1
#define RT_IRQ_TASK_ERR 0x7FFFFFFF
struct rt_task_struct;
typedef struct rt_task_info {
RTIME period; long base_priority, priority;
} RT_TASK_INFO;
#ifdef __KERNEL__
#include <linux/time.h>
#include <linux/errno.h>
#if defined(CONFIG_RTAI_LONG_TIMED_LIST)
#include <linux/rbtree.h>
typedef struct rb_node rb_node_t;
typedef struct rb_root rb_root_t;
#endif
#define RT_TASK_MAGIC 0x9ad25f6f // nam2num("rttask")
#ifndef __cplusplus
#include <linux/sched.h>
typedef struct rt_queue {
struct rt_queue *prev;
struct rt_queue *next;
struct rt_task_struct *task;
} QUEUE;
struct mcb_t {
void *sbuf;
int sbytes;
void *rbuf;
int rbytes;
};
/*Exit handler functions are called like C++ destructors in rt_task_delete().*/
typedef struct rt_ExitHandler {
struct rt_ExitHandler *nxt;
void (*fun) (void *arg1, int arg2);
void *arg1;
int arg2;
} XHDL;
struct rt_heap_t { void *heap, *kadr, *uadr; };
#define RTAI_MAX_NAME_LENGTH 32
typedef struct rt_task_struct {
long *stack __attribute__ ((__aligned__ (L1_CACHE_BYTES)));
int uses_fpu;
int magic;
volatile int state, running;
unsigned long runnable_on_cpus;
long *stack_bottom;
volatile int priority;
int base_priority;
int policy;
int sched_lock_priority;
struct rt_task_struct *prio_passed_to;
RTIME period;
RTIME resume_time;
RTIME periodic_resume_time;
RTIME yield_time;
int rr_quantum, rr_remaining;
int suspdepth;
struct rt_queue queue;
int owndres;
struct rt_queue *blocked_on;
struct rt_queue msg_queue;
int tid; /* trace ID */
unsigned long msg;
struct rt_queue ret_queue;
void (*signal)(void);
FPU_ENV fpu_reg __attribute__ ((__aligned__ (L1_CACHE_BYTES)));
struct rt_task_struct *prev, *next;
struct rt_task_struct *tprev, *tnext;
struct rt_task_struct *rprev, *rnext;
/* For calls from LINUX. */
long *fun_args;
long *bstack;
struct task_struct *lnxtsk;
long long retval;
char *msg_buf[2];
long max_msg_size[2];
char task_name[RTAI_MAX_NAME_LENGTH];
void *system_data_ptr;
struct rt_task_struct *nextp, *prevp;
RT_TRAP_HANDLER task_trap_handler[RTAI_NR_TRAPS];
long unblocked;
void *rt_signals;
volatile unsigned long pstate;
unsigned long usp_flags;
unsigned long usp_flags_mask;
unsigned long force_soft;
volatile int is_hard;
int kerrno;
long busy_time_align;
void *linux_syscall_server;
/* For use by watchdog. */
int resync_frame;
/* For use by exit handler functions. */
XHDL *ExitHook;
RTIME exectime[2];
struct mcb_t mcb;
/* Real time heaps. */
struct rt_heap_t heap[2];
long scheduler;
#ifdef CONFIG_RTAI_LONG_TIMED_LIST
rb_root_t rbr;
rb_node_t rbn;
#endif
struct rt_queue resq;
unsigned long resumsg;
int schedlat;
} RT_TASK __attribute__ ((__aligned__ (L1_CACHE_BYTES)));
#else /* __cplusplus */
extern "C" {
#endif /* !__cplusplus */
int set_rtext(RT_TASK *task, int priority, int uses_fpu, void(*signal)(void), unsigned int cpuid);
int rt_task_init(struct rt_task_struct *task,
void (*rt_thread)(long),
long data,
int stack_size,
int priority,
int uses_fpu,
void(*signal)(void));
int rt_task_init_cpuid(struct rt_task_struct *task,
void (*rt_thread)(long),
long data,
int stack_size,
int priority,
int uses_fpu,
void(*signal)(void),
unsigned run_on_cpu);
void rt_thread_create(void *fun, void *args, struct task_struct **thread);
RT_TASK *rt_thread_init(unsigned long name, int priority, int make_hard, int policy, int cpus_allowed);
int rt_thread_delete(RT_TASK *rt_task);
int rt_kthread_init(struct rt_task_struct *task,
void (*rt_thread)(long),
long data,
int stack_size,
int priority,
int uses_fpu,
void(*signal)(void));
int rt_kthread_init_cpuid(struct rt_task_struct *task,
void (*rt_thread)(long),
long data,
int stack_size,
int priority,
int uses_fpu,
void(*signal)(void),
unsigned run_on_cpu);
RTAI_SYSCALL_MODE void rt_set_runnable_on_cpus(struct rt_task_struct *task,
unsigned long cpu_mask);
RTAI_SYSCALL_MODE void rt_set_runnable_on_cpuid(struct rt_task_struct *task,
unsigned cpuid);
RTAI_SYSCALL_MODE void rt_set_sched_policy(struct rt_task_struct *task,
int policy,
int rr_quantum_ns);
int rt_task_delete(struct rt_task_struct *task);
int rt_get_task_state(struct rt_task_struct *task);
void rt_gettimeorig(RTIME time_orig[]);
int rt_get_timer_cpu(void);
int rt_is_hard_timer_running(void);
void rt_set_periodic_mode(void);
void rt_set_oneshot_mode(void);
RTAI_SYSCALL_MODE RTIME start_rt_timer(int period);
#define start_rt_timer_ns(period) start_rt_timer(nano2count((period)))
RTAI_SYSCALL_MODE void start_rt_apic_timers(struct apic_timer_setup_data *setup_mode,
unsigned rcvr_jiffies_cpuid);
void stop_rt_timer(void);
struct rt_task_struct *rt_whoami(void);
int rt_sched_type(void);
RTAI_SYSCALL_MODE int rt_task_signal_handler(struct rt_task_struct *task,
void (*handler)(void));
RTAI_SYSCALL_MODE int rt_task_use_fpu(struct rt_task_struct *task,
int use_fpu_flag);
void rt_linux_use_fpu(int use_fpu_flag);
RTAI_SYSCALL_MODE int rt_hard_timer_tick_count(void);
RTAI_SYSCALL_MODE int rt_hard_timer_tick_count_cpuid(int cpuid);
RTAI_SYSCALL_MODE RTIME count2nano(RTIME timercounts);
RTAI_SYSCALL_MODE RTIME nano2count(RTIME nanosecs);
RTAI_SYSCALL_MODE RTIME count2nano_cpuid(RTIME timercounts, unsigned cpuid);
RTAI_SYSCALL_MODE RTIME nano2count_cpuid(RTIME nanosecs, unsigned cpuid);
RTIME rt_get_time(void);
RTAI_SYSCALL_MODE RTIME rt_get_time_cpuid(unsigned cpuid);
RTIME rt_get_time_ns(void);
RTAI_SYSCALL_MODE RTIME rt_get_time_ns_cpuid(unsigned cpuid);
RTIME rt_get_cpu_time_ns(void);
RTIME rt_get_real_time(void);
RTIME rt_get_real_time_ns(void);
int rt_get_prio(struct rt_task_struct *task);
int rt_get_inher_prio(struct rt_task_struct *task);
RTAI_SYSCALL_MODE int rt_task_get_info(RT_TASK *task, RT_TASK_INFO *task_info);
RTAI_SYSCALL_MODE int rt_get_priorities(struct rt_task_struct *task, int *priority, int *base_priority);
RTAI_SYSCALL_MODE void rt_spv_RMS(int cpuid);
RTAI_SYSCALL_MODE int rt_change_prio(struct rt_task_struct *task,
int priority);
void rt_sched_lock(void);
void rt_sched_unlock(void);
void rt_task_yield(void);
RTAI_SYSCALL_MODE int rt_task_suspend(struct rt_task_struct *task);
RTAI_SYSCALL_MODE int rt_task_suspend_if(struct rt_task_struct *task);
RTAI_SYSCALL_MODE int rt_task_suspend_until(struct rt_task_struct *task, RTIME until);
RTAI_SYSCALL_MODE int rt_task_suspend_timed(struct rt_task_struct *task, RTIME delay);
RTAI_SYSCALL_MODE int rt_task_resume(struct rt_task_struct *task);
RTAI_SYSCALL_MODE int rt_set_linux_syscall_mode(long sync_async, void (*callback_fun)(long, long));
struct linux_syscalls_list;
void rt_exec_linux_syscall(RT_TASK *rt_current, struct linux_syscalls_list *syscalls, struct pt_regs *regs);
RTAI_SYSCALL_MODE void rt_return_linux_syscall(RT_TASK *task, unsigned long retval);
RTAI_SYSCALL_MODE int rt_irq_wait(unsigned irq);
RTAI_SYSCALL_MODE int rt_irq_wait_if(unsigned irq);
RTAI_SYSCALL_MODE int rt_irq_wait_until(unsigned irq, RTIME until);
RTAI_SYSCALL_MODE int rt_irq_wait_timed(unsigned irq, RTIME delay);
RTAI_SYSCALL_MODE void rt_irq_signal(unsigned irq);
RTAI_SYSCALL_MODE int rt_request_irq_task (unsigned irq, void *handler, int type, int affine2task);
RTAI_SYSCALL_MODE int rt_release_irq_task (unsigned irq);
RTAI_SYSCALL_MODE int rt_task_make_periodic_relative_ns(struct rt_task_struct *task,
RTIME start_delay,
RTIME period);
RTAI_SYSCALL_MODE int rt_task_make_periodic(struct rt_task_struct *task,
RTIME start_time,
RTIME period);
RTAI_SYSCALL_MODE void rt_task_set_resume_end_times(RTIME resume,
RTIME end);
RTAI_SYSCALL_MODE int rt_set_resume_time(struct rt_task_struct *task,
RTIME new_resume_time);
RTAI_SYSCALL_MODE int rt_set_period(struct rt_task_struct *task,
RTIME new_period);
int rt_task_wait_period(void);
void rt_schedule(void);
RTIME next_period(void);
RTAI_SYSCALL_MODE void rt_busy_sleep(int nanosecs);
RTAI_SYSCALL_MODE int rt_sleep(RTIME delay);
RTAI_SYSCALL_MODE int rt_sleep_until(RTIME time);
RTAI_SYSCALL_MODE int rt_task_masked_unblock(struct rt_task_struct *task, unsigned long mask);
#define rt_task_wakeup_sleeping(t) rt_task_masked_unblock(t, RT_SCHED_DELAYED)
RTAI_SYSCALL_MODE struct rt_task_struct *rt_named_task_init(const char *task_name,
void (*thread)(long),
long data,
int stack_size,
int prio,
int uses_fpu,
void(*signal)(void));
RTAI_SYSCALL_MODE struct rt_task_struct *rt_named_task_init_cpuid(const char *task_name,
void (*thread)(long),
long data,
int stack_size,
int prio,
int uses_fpu,
void(*signal)(void),
unsigned run_on_cpu);
RTAI_SYSCALL_MODE int rt_named_task_delete(struct rt_task_struct *task);
RT_TRAP_HANDLER rt_set_task_trap_handler(struct rt_task_struct *task,
unsigned vec,
RT_TRAP_HANDLER handler);
static inline RTIME timeval2count(struct timeval *t)
{
return nano2count(t->tv_sec*1000000000LL + t->tv_usec*1000);
}
static inline void count2timeval(RTIME rt, struct timeval *t)
{
t->tv_sec = rtai_ulldiv(count2nano(rt), 1000000000, (unsigned long *)&t->tv_usec);
t->tv_usec /= 1000;
}
static inline RTIME timespec2count(const struct timespec *t)
{
return nano2count(t->tv_sec*1000000000LL + t->tv_nsec);
}
static inline void count2timespec(RTIME rt, struct timespec *t)
{
t->tv_sec = rtai_ulldiv(count2nano(rt), 1000000000, (unsigned long *)&t->tv_nsec);
}
static inline RTIME timespec2nanos(const struct timespec *t)
{
return t->tv_sec*1000000000LL + t->tv_nsec;
}
static inline void nanos2timespec(RTIME rt, struct timespec *t)
{
t->tv_sec = rtai_ulldiv(rt, 1000000000, (unsigned long *)&t->tv_nsec);
}
void rt_make_hard_real_time(RT_TASK *task);
void rt_make_soft_real_time(RT_TASK *task);
#ifdef __cplusplus
}
#else /* !__cplusplus */
#endif /* __cplusplus */
#endif /* __KERNEL__ */
#if !defined(__KERNEL__) || defined(__cplusplus)
typedef struct rt_task_struct {
int opaque;
} RT_TASK;
typedef struct QueueBlock {
int opaque;
} QBLK;
typedef struct QueueHook {
int opaque;
} QHOOK;
#endif /* !__KERNEL__ || __cplusplus */
#endif /* !_RTAI_SCHED_H */