/*
* Project: S.Ha.R.K.
*
* Coordinators:
* Giorgio Buttazzo <giorgio@sssup.it>
* Paolo Gai <pj@gandalf.sssup.it>
*
* Authors :
* Paolo Gai <pj@gandalf.sssup.it>
* (see the web pages for full authors list)
*
* ReTiS Lab (Scuola Superiore S.Anna - Pisa - Italy)
*
* http://www.sssup.it
* http://retis.sssup.it
* http://shark.sssup.it
*/
/**
------------
CVS : $Id: edfact.c,v 1.1.1.1 2002-09-02 09:37:41 pj Exp $
File: $File$
Revision: $Revision: 1.1.1.1 $
Last update: $Date: 2002-09-02 09:37:41 $
------------
**/
/*
* Copyright (C) 2001 Paolo Gai
*
* 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, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#include "edfact.h"
#include <ll/stdio.h>
#include <ll/string.h>
#include <kernel/model.h>
#include <kernel/descr.h>
#include <kernel/var.h>
#include <kernel/func.h>
#include <kernel/trace.h>
//#define edfact_printf kern_printf
#define edfact_printf printk
/*+ Status used in the level +*/
#define EDFACT_READY MODULE_STATUS_BASE /*+ - Ready status +*/
#define EDFACT_IDLE MODULE_STATUS_BASE+4 /*+ to wait the deadline +*/
/*+ flags +*/
#define EDFACT_FLAG_NORAISEEXC 2
/*+ the level redefinition for the Earliest Deadline First level +*/
typedef struct {
level_des l
; /*+ the standard level descriptor +*/
TIME period
[MAX_PROC
]; /*+ The task periods; the deadlines are
stored in the priority field +*/
int deadline_timer
[MAX_PROC
];
/*+ The task deadline timers +*/
struct timespec deadline_timespec
[MAX_PROC
];
int dline_miss
[MAX_PROC
]; /*+ Deadline miss counter +*/
int wcet_miss
[MAX_PROC
]; /*+ Wcet miss counter +*/
int nact
[MAX_PROC
]; /*+ Wcet miss counter +*/
int flag
[MAX_PROC
];
/*+ used to manage the JOB_TASK_MODEL and the
periodicity +*/
QUEUE ready
; /*+ the ready queue +*/
int flags
; /*+ the init flags... +*/
bandwidth_t U
; /*+ the used bandwidth +*/
} EDFACT_level_des
;
static void EDFACT_timer_deadline
(void *par
);
static void EDFACT_internal_activate
(EDFACT_level_des
*lev
, PID p
)
{
TIMESPEC_ASSIGN
(&proc_table
[p
].
timespec_priority,
&proc_table
[p
].
request_time);
ADDUSEC2TIMESPEC
(lev
->period
[p
], &proc_table
[p
].
timespec_priority);
TIMESPEC_ASSIGN
(&lev
->deadline_timespec
[p
],
&proc_table
[p
].
timespec_priority);
/* Insert task in the correct position */
proc_table
[p
].
status = EDFACT_READY
;
q_timespec_insert
(p
,&lev
->ready
);
/* needed because when there is a wcet miss I disable CONTROL_CAP */
proc_table
[p
].
control |= CONTROL_CAP
;
}
static char *EDFACT_status_to_a
(WORD status
)
{
if (status
< MODULE_STATUS_BASE
)
return status_to_a
(status
);
switch (status
) {
case EDFACT_READY
: return "EDFACT_Ready";
case EDFACT_IDLE
: return "EDFACT_Idle";
default : return "EDFACT_Unknown";
}
}
static void EDFACT_timer_deadline
(void *par
)
{
PID p
= (PID
) par
;
EDFACT_level_des
*lev
;
lev
= (EDFACT_level_des
*)level_table
[proc_table
[p
].
task_level];
switch (proc_table
[p
].
status) {
case EDFACT_IDLE
:
edfact_printf
("I%d",p
);
TIMESPEC_ASSIGN
(&proc_table
[p
].
request_time,
&proc_table
[p
].
timespec_priority);
EDFACT_internal_activate
(lev
,p
);
event_need_reschedule
();
break;
default:
edfact_printf
("D%d",p
);
/* else, a deadline miss occurred!!! */
lev
->dline_miss
[p
]++;
/* the task is into another state */
lev
->nact
[p
]++;
/* Set the deadline timer */
ADDUSEC2TIMESPEC
(lev
->period
[p
], &lev
->deadline_timespec
[p
]);
}
/* Set the deadline timer */
lev
->deadline_timer
[p
] = kern_event_post
(&lev
->deadline_timespec
[p
],
EDFACT_timer_deadline
,
(void *)p
);
}
static void EDFACT_timer_guest_deadline
(void *par
)
{
PID p
= (PID
) par
;
edfact_printf
("AAARRRGGGHHH!!!");
kern_raise
(XDEADLINE_MISS
,p
);
}
static int EDFACT_level_accept_task_model
(LEVEL l
, TASK_MODEL
*m
)
{
if (m
->pclass
== HARD_PCLASS
|| m
->pclass
== (HARD_PCLASS
| l
)) {
HARD_TASK_MODEL
*h
= (HARD_TASK_MODEL
*)m
;
if (h
->wcet
&& h
->mit
&& h
->periodicity
== PERIODIC
)
return 0;
}
return -1;
}
static int EDFACT_level_accept_guest_model
(LEVEL l
, TASK_MODEL
*m
)
{
if (m
->pclass
== JOB_PCLASS
|| m
->pclass
== (JOB_PCLASS
| l
))
return 0;
else
return -1;
}
static char *onoff
(int i
)
{
if (i
)
return "On ";
else
return "Off";
}
static void EDFACT_level_status
(LEVEL l
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
PID p
= lev
->ready
;
kern_printf
("On-line guarantee : %s\n",
onoff
(lev
->flags
& EDFACT_ENABLE_GUARANTEE
));
kern_printf
("Used Bandwidth : %u/%u\n",
lev
->U
, MAX_BANDWIDTH
);
while (p
!= NIL
) {
if ((proc_table
[p
].
pclass) == JOB_PCLASS
)
kern_printf
("Pid: %2d (GUEST)\n", p
);
else
kern_printf
("Pid: %2d Name: %10s %s: %9d Dline: %9d.%6d Stat: %s\n",
p
,
proc_table
[p
].
name,
"Period ",
lev
->period
[p
],
proc_table
[p
].
timespec_priority.
tv_sec,
proc_table
[p
].
timespec_priority.
tv_nsec/1000,
EDFACT_status_to_a
(proc_table
[p
].
status));
p
= proc_table
[p
].
next;
}
for (p
=0; p
<MAX_PROC
; p
++)
if (proc_table
[p
].
task_level == l
&& proc_table
[p
].
status != EDFACT_READY
&& proc_table
[p
].
status != FREE
)
kern_printf
("Pid: %2d Name: %10s %s: %9d Dline: %9d.%6d Stat: %s\n",
p
,
proc_table
[p
].
name,
"Period ",
lev
->period
[p
],
proc_table
[p
].
timespec_priority.
tv_sec,
proc_table
[p
].
timespec_priority.
tv_nsec/1000,
EDFACT_status_to_a
(proc_table
[p
].
status));
}
/* The scheduler only gets the first task in the queue */
static PID EDFACT_level_scheduler
(LEVEL l
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* { // print 4 dbg the ready queue
PID p= lev->ready;
kern_printf("(s");
while (p != NIL) {
kern_printf("%d ",p);
p = proc_table[p].next;
}
kern_printf(") ");
}
*/
return (PID
)lev
->ready
;
}
/* The on-line guarantee is enabled only if the appropriate flag is set... */
static int EDFACT_level_guarantee
(LEVEL l
, bandwidth_t
*freebandwidth
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->flags
& EDFACT_FAILED_GUARANTEE
) {
*freebandwidth
= 0;
return 0;
}
else
if (*freebandwidth
>= lev
->U
) {
*freebandwidth
-= lev
->U
;
return 1;
}
else
return 0;
}
static int EDFACT_task_create
(LEVEL l
, PID p
, TASK_MODEL
*m
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* if the EDFACT_task_create is called, then the pclass must be a
valid pclass. */
HARD_TASK_MODEL
*h
= (HARD_TASK_MODEL
*)m
;
lev
->period
[p
] = h
->mit
;
lev
->flag
[p
] = 0;
lev
->deadline_timer
[p
] = -1;
lev
->dline_miss
[p
] = 0;
lev
->wcet_miss
[p
] = 0;
lev
->nact
[p
] = 0;
/* Enable wcet check */
proc_table
[p
].
avail_time = h
->wcet
;
proc_table
[p
].
wcet = h
->wcet
;
proc_table
[p
].
control |= CONTROL_CAP
;
/* update the bandwidth... */
if (lev
->flags
& EDFACT_ENABLE_GUARANTEE
) {
bandwidth_t b
;
b
= (MAX_BANDWIDTH
/ h
->mit
) * h
->wcet
;
/* really update lev->U, checking an overflow... */
if (MAX_BANDWIDTH
- lev
->U
> b
)
lev
->U
+= b
;
else
/* The task can NOT be guaranteed (U>MAX_BANDWIDTH)...
in this case, we don't raise an exception... in fact, after the
EDFACT_task_create the task_create will call level_guarantee that return
-1... return -1 in EDFACT_task_create isn't correct, because:
. generally, the guarantee must be done when also the resources
are registered
. returning -1 will cause the task_create to return with an errno
ETASK_CREATE instead of ENO_GUARANTEE!!!
Why I use the flag??? because if the lev->U overflows, if i.e. I set
it to MAX_BANDWIDTH, I lose the correct allocated bandwidth...
*/
lev
->flags
|= EDFACT_FAILED_GUARANTEE
;
}
return 0; /* OK, also if the task cannot be guaranteed... */
}
static void EDFACT_task_detach
(LEVEL l
, PID p
)
{
/* the EDFACT level doesn't introduce any dinamic allocated new field.
we have only to reset the NO_GUARANTEE FIELD and decrement the allocated
bandwidth */
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->flags
& EDFACT_FAILED_GUARANTEE
)
lev
->flags
&= ~EDFACT_FAILED_GUARANTEE
;
else
lev
->U
-= (MAX_BANDWIDTH
/ lev
->period
[p
]) * proc_table
[p
].
wcet;
}
static int EDFACT_task_eligible
(LEVEL l
, PID p
)
{
return 0; /* if the task p is chosen, it is always eligible */
}
static void EDFACT_task_dispatch
(LEVEL l
, PID p
, int nostop
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* the task state is set EXE by the scheduler()
we extract the task from the ready queue
NB: we can't assume that p is the first task in the queue!!! */
q_extract
(p
, &lev
->ready
);
}
static void EDFACT_task_epilogue
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* check if the wcet is finished... */
if (proc_table
[p
].
avail_time <= 0 && proc_table
[p
].
control&CONTROL_CAP
) {
/* wcet finished: disable wcet event and count wcet miss */
edfact_printf
("W%d",p
);
proc_table
[p
].
control &= ~CONTROL_CAP
;
lev
->wcet_miss
[p
]++;
}
/* the task it returns into the ready queue... */
q_timespec_insert
(p
,&lev
->ready
);
proc_table
[p
].
status = EDFACT_READY
;
}
static void EDFACT_task_activate
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* Test if we are trying to activate a non sleeping task */
/* save activation (only if needed... */
if (proc_table
[p
].
status != SLEEP
) {
/* a periodic task cannot be activated when it is already active */
kern_raise
(XACTIVATION
,p
);
return;
}
ll_gettime
(TIME_EXACT
, &proc_table
[p
].
request_time);
EDFACT_internal_activate
(lev
,p
);
/* Set the deadline timer */
lev
->deadline_timer
[p
] = kern_event_post
(&lev
->deadline_timespec
[p
],
EDFACT_timer_deadline
,
(void *)p
);
}
static void EDFACT_task_insert
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* Insert task in the coEDFect position */
proc_table
[p
].
status = EDFACT_READY
;
q_timespec_insert
(p
,&lev
->ready
);
}
static void EDFACT_task_extract
(LEVEL l
, PID p
)
{
}
static void EDFACT_task_endcycle
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* we reset the capacity counters... */
proc_table
[p
].
avail_time = proc_table
[p
].
wcet;
if (lev
->nact
[p
] > 0) {
edfact_printf
("E%d",p
);
/* Pending activation: reactivate the thread!!! */
lev
->nact
[p
]--;
/* see also EDFACT_timer_deadline */
ll_gettime
(TIME_EXACT
, &proc_table
[p
].
request_time);
EDFACT_internal_activate
(lev
,p
);
/* check if the deadline has already expired */
if (TIMESPEC_A_LT_B
(&proc_table
[p
].
timespec_priority, &schedule_time
)) {
/* count the deadline miss */
lev
->dline_miss
[p
]++;
event_delete
(lev
->deadline_timer
[p
]);
}
}
else {
edfact_printf
("e%d",p
);
/* the task has terminated his job before it consume the wcet. All OK! */
proc_table
[p
].
status = EDFACT_IDLE
;
/* when the deadline timer fire, it recognize the situation and set
correctly all the stuffs (like reactivation, request_time, etc... ) */
}
}
static void EDFACT_task_end
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
edfact_printf
("Û%d",p
);
/* we finally put the task in the ready queue */
proc_table
[p
].
status = FREE
;
q_insertfirst
(p
,&freedesc
);
/* and free the allocated bandwidth */
lev
->U
-= (MAX_BANDWIDTH
/lev
->period
[p
]) * proc_table
[p
].
wcet;
if (lev
->deadline_timer
[p
] != -1) {
edfact_printf
("²%d",p
);
event_delete
(lev
->deadline_timer
[p
]);
}
}
static void EDFACT_task_sleep
(LEVEL l
, PID p
)
{ kern_raise
(XUNVALID_TASK
,exec_shadow
); }
static void EDFACT_task_delay
(LEVEL l
, PID p
, TIME usdelay
)
{ kern_raise
(XUNVALID_TASK
,exec_shadow
); }
/* Guest Functions
These functions manages a JOB_TASK_MODEL, that is used to put
a guest task in the EDFACT ready queue. */
static int EDFACT_guest_create
(LEVEL l
, PID p
, TASK_MODEL
*m
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
JOB_TASK_MODEL
*job
= (JOB_TASK_MODEL
*)m
;
/* if the EDFACT_guest_create is called, then the pclass must be a
valid pclass. */
TIMESPEC_ASSIGN
(&proc_table
[p
].
timespec_priority, &job
->deadline
);
lev
->deadline_timer
[p
] = -1;
lev
->dline_miss
[p
] = 0;
lev
->wcet_miss
[p
] = 0;
lev
->nact
[p
] = 0;
if (job
->noraiseexc
)
lev
->flag
[p
] = EDFACT_FLAG_NORAISEEXC
;
else
lev
->flag
[p
] = 0;
lev
->period
[p
] = job
->period
;
/* there is no bandwidth guarantee at this level, it is performed
by the level that inserts guest tasks... */
return 0; /* OK, also if the task cannot be guaranteed... */
}
static void EDFACT_guest_detach
(LEVEL l
, PID p
)
{
/* the EDFACT level doesn't introduce any dinamic allocated new field.
No guarantee is performed on guest tasks... so we don't have to reset
the NO_GUARANTEE FIELD */
}
static void EDFACT_guest_dispatch
(LEVEL l
, PID p
, int nostop
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* the task state is set to EXE by the scheduler()
we extract the task from the ready queue
NB: we can't assume that p is the first task in the queue!!! */
q_extract
(p
, &lev
->ready
);
}
static void EDFACT_guest_epilogue
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* the task has been preempted. it returns into the ready queue... */
q_timespec_insert
(p
,&lev
->ready
);
proc_table
[p
].
status = EDFACT_READY
;
}
static void EDFACT_guest_activate
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* Insert task in the correct position */
q_timespec_insert
(p
,&lev
->ready
);
proc_table
[p
].
status = EDFACT_READY
;
/* Set the deadline timer */
if (!(lev
->flag
[p
] & EDFACT_FLAG_NORAISEEXC
))
lev
->deadline_timer
[p
] = kern_event_post
(&proc_table
[p
].
timespec_priority,
EDFACT_timer_guest_deadline
,
(void *)p
);
}
static void EDFACT_guest_insert
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
/* Insert task in the correct position */
q_timespec_insert
(p
,&lev
->ready
);
proc_table
[p
].
status = EDFACT_READY
;
}
static void EDFACT_guest_extract
(LEVEL l
, PID p
)
{
}
static void EDFACT_guest_endcycle
(LEVEL l
, PID p
)
{ kern_raise
(XUNVALID_GUEST
,exec_shadow
); }
static void EDFACT_guest_end
(LEVEL l
, PID p
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
//kern_printf("EDFACT_guest_end: dline timer %d\n",lev->deadline_timer[p]);
if (proc_table
[p
].
status == EDFACT_READY
)
{
q_extract
(p
, &lev
->ready
);
//kern_printf("(g_end rdy extr)");
}
/* we remove the deadline timer, because the slice is finished */
if (lev
->deadline_timer
[p
] != NIL
) {
// kern_printf("EDFACT_guest_end: dline timer %d\n",lev->deadline_timer[p]);
event_delete
(lev
->deadline_timer
[p
]);
lev
->deadline_timer
[p
] = NIL
;
}
}
static void EDFACT_guest_sleep
(LEVEL l
, PID p
)
{ kern_raise
(XUNVALID_GUEST
,exec_shadow
); }
static void EDFACT_guest_delay
(LEVEL l
, PID p
, TIME usdelay
)
{ kern_raise
(XUNVALID_GUEST
,exec_shadow
); }
/* Registration functions */
/*+ Registration function:
int flags the init flags ... see EDFACT.h +*/
void EDFACT_register_level
(int flags
)
{
LEVEL l
; /* the level that we register */
EDFACT_level_des
*lev
; /* for readableness only */
PID i
; /* a counter */
printk
("EDFACT_register_level\n");
/* request an entry in the level_table */
l
= level_alloc_descriptor
();
printk
(" alloco descrittore %d %d\n",l
,(int)sizeof(EDFACT_level_des
));
/* alloc the space needed for the EDFACT_level_des */
lev
= (EDFACT_level_des
*)kern_alloc
(sizeof(EDFACT_level_des
));
printk
(" lev=%d\n",(int)lev
);
/* update the level_table with the new entry */
level_table
[l
] = (level_des
*)lev
;
/* fill the standard descriptor */
strncpy(lev
->l.
level_name, EDFACT_LEVELNAME
, MAX_LEVELNAME
);
lev
->l.
level_code = EDFACT_LEVEL_CODE
;
lev
->l.
level_version = EDFACT_LEVEL_VERSION
;
lev
->l.
level_accept_task_model = EDFACT_level_accept_task_model
;
lev
->l.
level_accept_guest_model = EDFACT_level_accept_guest_model
;
lev
->l.
level_status = EDFACT_level_status
;
lev
->l.
level_scheduler = EDFACT_level_scheduler
;
if (flags
& EDFACT_ENABLE_GUARANTEE
)
lev
->l.
level_guarantee = EDFACT_level_guarantee
;
else
lev
->l.
level_guarantee = NULL
;
lev
->l.
task_create = EDFACT_task_create
;
lev
->l.
task_detach = EDFACT_task_detach
;
lev
->l.
task_eligible = EDFACT_task_eligible
;
lev
->l.
task_dispatch = EDFACT_task_dispatch
;
lev
->l.
task_epilogue = EDFACT_task_epilogue
;
lev
->l.
task_activate = EDFACT_task_activate
;
lev
->l.
task_insert = EDFACT_task_insert
;
lev
->l.
task_extract = EDFACT_task_extract
;
lev
->l.
task_endcycle = EDFACT_task_endcycle
;
lev
->l.
task_end = EDFACT_task_end
;
lev
->l.
task_sleep = EDFACT_task_sleep
;
lev
->l.
task_delay = EDFACT_task_delay
;
lev
->l.
guest_create = EDFACT_guest_create
;
lev
->l.
guest_detach = EDFACT_guest_detach
;
lev
->l.
guest_dispatch = EDFACT_guest_dispatch
;
lev
->l.
guest_epilogue = EDFACT_guest_epilogue
;
lev
->l.
guest_activate = EDFACT_guest_activate
;
lev
->l.
guest_insert = EDFACT_guest_insert
;
lev
->l.
guest_extract = EDFACT_guest_extract
;
lev
->l.
guest_endcycle = EDFACT_guest_endcycle
;
lev
->l.
guest_end = EDFACT_guest_end
;
lev
->l.
guest_sleep = EDFACT_guest_sleep
;
lev
->l.
guest_delay = EDFACT_guest_delay
;
/* fill the EDFACT descriptor part */
for(i
=0; i
<MAX_PROC
; i
++) {
lev
->period
[i
] = 0;
lev
->deadline_timer
[i
] = -1;
lev
->flag
[i
] = 0;
lev
->dline_miss
[i
] = 0;
lev
->wcet_miss
[i
] = 0;
lev
->nact
[i
] = 0;
}
lev
->ready
= NIL
;
lev
->flags
= flags
& 0x07;
lev
->U
= 0;
}
bandwidth_t EDFACT_usedbandwidth
(LEVEL l
)
{
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->l.
level_code == EDFACT_LEVEL_CODE
&&
lev
->l.
level_version == EDFACT_LEVEL_VERSION
)
return lev
->U
;
else
return 0;
}
int EDFACT_get_dline_miss
(PID p
)
{
LEVEL l
= proc_table
[p
].
task_level;
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->l.
level_code == EDFACT_LEVEL_CODE
&&
lev
->l.
level_version == EDFACT_LEVEL_VERSION
)
return lev
->dline_miss
[p
];
else
return -1;
}
int EDFACT_get_wcet_miss
(PID p
)
{
LEVEL l
= proc_table
[p
].
task_level;
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->l.
level_code == EDFACT_LEVEL_CODE
&&
lev
->l.
level_version == EDFACT_LEVEL_VERSION
)
return lev
->wcet_miss
[p
];
else
return -1;
}
int EDFACT_get_nact
(PID p
)
{
LEVEL l
= proc_table
[p
].
task_level;
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->l.
level_code == EDFACT_LEVEL_CODE
&&
lev
->l.
level_version == EDFACT_LEVEL_VERSION
)
return lev
->nact
[p
];
else
return -1;
}
int EDFACT_reset_dline_miss
(PID p
)
{
LEVEL l
= proc_table
[p
].
task_level;
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->l.
level_code == EDFACT_LEVEL_CODE
&&
lev
->l.
level_version == EDFACT_LEVEL_VERSION
)
{
lev
->dline_miss
[p
] = 0;
return 0;
}
else
return -1;
}
int EDFACT_reset_wcet_miss
(PID p
)
{
LEVEL l
= proc_table
[p
].
task_level;
EDFACT_level_des
*lev
= (EDFACT_level_des
*)(level_table
[l
]);
if (lev
->l.
level_code == EDFACT_LEVEL_CODE
&&
lev
->l.
level_version == EDFACT_LEVEL_VERSION
)
{
lev
->wcet_miss
[p
] = 0;
return 0;
}
else
return -1;
}