1 /* This file contains essentially all of the process and message handling.
2 * Together with "mpx.s" it forms the lowest layer of the MINIX kernel.
3 * There is one entry point from the outside:
5 * sys_call: a system call, i.e., the kernel is trapped with an INT
8 * Aug 19, 2005 rewrote scheduling code (Jorrit N. Herder)
9 * Jul 25, 2005 rewrote system call handling (Jorrit N. Herder)
10 * May 26, 2005 rewrote message passing functions (Jorrit N. Herder)
11 * May 24, 2005 new notification system call (Jorrit N. Herder)
12 * Oct 28, 2004 nonblocking send and receive calls (Jorrit N. Herder)
14 * The code here is critical to make everything work and is important for the
15 * overall performance of the system. A large fraction of the code deals with
16 * list manipulation. To make this both easy to understand and fast to execute
17 * pointer pointers are used throughout the code. Pointer pointers prevent
18 * exceptions for the head or tail of a linked list.
20 * node_t *queue, *new_node; // assume these as global variables
21 * node_t **xpp = &queue; // get pointer pointer to head of queue
22 * while (*xpp != NULL) // find last pointer of the linked list
23 * xpp = &(*xpp)->next; // get pointer to next pointer
24 * *xpp = new_node; // now replace the end (the NULL pointer)
25 * new_node->next = NULL; // and mark the new end of the list
27 * For example, when adding a new node to the end of the list, one normally
28 * makes an exception for an empty list and looks up the end of the list for
29 * nonempty lists. As shown above, this is not required with pointer pointers.
32 #include <minix/com.h>
33 #include <minix/ipcconst.h>
38 #include "kernel/kernel.h"
42 #include "arch_proto.h"
44 #include <minix/syslib.h>
46 /* Scheduling and message passing functions */
47 static void idle(void);
49 * Made public for use in clock.c (for user-space scheduling)
50 static int mini_send(struct proc *caller_ptr, endpoint_t dst_e, message
53 static int mini_receive(struct proc
*caller_ptr
, endpoint_t src
,
54 message
*m_ptr
, int flags
);
55 static int mini_senda(struct proc
*caller_ptr
, asynmsg_t
*table
, size_t
57 static int deadlock(int function
, register struct proc
*caller
,
58 endpoint_t src_dst_e
);
59 static int try_async(struct proc
*caller_ptr
);
60 static int try_one(struct proc
*src_ptr
, struct proc
*dst_ptr
);
61 static struct proc
* pick_proc(void);
62 static void enqueue_head(struct proc
*rp
);
64 /* all idles share the same idle_priv structure */
65 static struct priv idle_priv
;
67 static void set_idle_name(char * name
, int n
)
80 for (i
= 4, c
= 100; c
> 0; c
/= 10) {
86 if (p_z
|| digit
!= 0 || c
== 1) {
88 name
[i
++] = '0' + digit
;
98 #define PICK_HIGHERONLY 2
100 #define BuildNotifyMessage(m_ptr, src, dst_ptr) \
101 (m_ptr)->m_type = NOTIFY_MESSAGE; \
102 (m_ptr)->NOTIFY_TIMESTAMP = get_uptime(); \
105 (m_ptr)->NOTIFY_ARG = priv(dst_ptr)->s_int_pending; \
106 priv(dst_ptr)->s_int_pending = 0; \
109 (m_ptr)->NOTIFY_ARG = priv(dst_ptr)->s_sig_pending; \
110 priv(dst_ptr)->s_sig_pending = 0; \
120 /* Clear the process table. Anounce each slot as empty and set up
121 * mappings for proc_addr() and proc_nr() macros. Do the same for the
122 * table with privilege structures for the system processes.
124 for (rp
= BEG_PROC_ADDR
, i
= -NR_TASKS
; rp
< END_PROC_ADDR
; ++rp
, ++i
) {
125 rp
->p_rts_flags
= RTS_SLOT_FREE
;/* initialize free slot */
126 rp
->p_magic
= PMAGIC
;
127 rp
->p_nr
= i
; /* proc number from ptr */
128 rp
->p_endpoint
= _ENDPOINT(0, rp
->p_nr
); /* generation no. 0 */
129 rp
->p_scheduler
= NULL
; /* no user space scheduler */
130 rp
->p_priority
= 0; /* no priority */
131 rp
->p_quantum_size_ms
= 0; /* no quantum size */
133 /* arch-specific initialization */
136 for (sp
= BEG_PRIV_ADDR
, i
= 0; sp
< END_PRIV_ADDR
; ++sp
, ++i
) {
137 sp
->s_proc_nr
= NONE
; /* initialize as free */
138 sp
->s_id
= (sys_id_t
) i
; /* priv structure index */
139 ppriv_addr
[i
] = sp
; /* priv ptr from number */
140 sp
->s_sig_mgr
= NONE
; /* clear signal managers */
141 sp
->s_bak_sig_mgr
= NONE
;
144 idle_priv
.s_flags
= IDL_F
;
145 /* initialize IDLE structures for every CPU */
146 for (i
= 0; i
< CONFIG_MAX_CPUS
; i
++) {
147 struct proc
* ip
= get_cpu_var_ptr(i
, idle_proc
);
148 ip
->p_endpoint
= IDLE
;
149 ip
->p_priv
= &idle_priv
;
150 /* must not let idle ever get scheduled */
151 ip
->p_rts_flags
|= RTS_PROC_STOP
;
152 set_idle_name(ip
->p_name
, i
);
156 static void switch_address_space_idle(void)
160 * currently we bet that VM is always alive and its pages available so
161 * when the CPU wakes up the kernel is mapped and no surprises happen.
162 * This is only a problem if more than 1 cpus are available
164 switch_address_space(proc_addr(VM_PROC_NR
));
168 /*===========================================================================*
170 *===========================================================================*/
171 static void idle(void)
175 /* This function is called whenever there is no work to do.
176 * Halt the CPU, and measure how many timestamp counter ticks are
177 * spent not doing anything. This allows test setups to measure
178 * the CPU utiliziation of certain workloads with high precision.
181 p
= get_cpulocal_var(proc_ptr
) = get_cpulocal_var_ptr(idle_proc
);
182 if (priv(p
)->s_flags
& BILLABLE
)
183 get_cpulocal_var(bill_ptr
) = p
;
185 switch_address_space_idle();
188 get_cpulocal_var(cpu_is_idle
) = 1;
189 /* we don't need to keep time on APs as it is handled on the BSP */
190 if (cpuid
!= bsp_cpu_id
)
196 * If the timer has expired while in kernel we must
197 * rearm it before we go to sleep
199 restart_local_timer();
202 /* start accounting for the idle time */
203 context_stop(proc_addr(KERNEL
));
212 v
= get_cpulocal_var_ptr(idle_interrupted
);
216 interrupts_disable();
221 * end of accounting for the idle task does not happen here, the kernel
222 * is handling stuff for quite a while before it gets back here!
226 /*===========================================================================*
228 *===========================================================================*/
229 void switch_to_user(void)
231 /* This function is called an instant before proc_ptr is
232 * to be scheduled again.
236 int tlb_must_refresh
= 0;
239 p
= get_cpulocal_var(proc_ptr
);
241 * if the current process is still runnable check the misc flags and let
242 * it run unless it becomes not runnable in the meantime
244 if (proc_is_runnable(p
))
245 goto check_misc_flags
;
247 * if a process becomes not runnable while handling the misc flags, we
248 * need to pick a new one here and start from scratch. Also if the
249 * current process wasn' runnable, we pick a new one here
251 not_runnable_pick_new
:
252 if (proc_is_preempted(p
)) {
253 p
->p_rts_flags
&= ~RTS_PREEMPTED
;
254 if (proc_is_runnable(p
)) {
255 if (!is_zero64(p
->p_cpu_time_left
))
263 * if we have no process to run, set IDLE as the current process for
264 * time accounting and put the cpu in and idle state. After the next
265 * timer interrupt the execution resumes here and we can pick another
266 * process. If there is still nothing runnable we "schedule" IDLE again
268 while (!(p
= pick_proc())) {
272 /* update the global variable */
273 get_cpulocal_var(proc_ptr
) = p
;
276 if (p
->p_misc_flags
& MF_FLUSH_TLB
&& get_cpulocal_var(ptproc
) == p
)
277 tlb_must_refresh
= 1;
279 switch_address_space(p
);
284 assert(proc_is_runnable(p
));
285 while (p
->p_misc_flags
&
286 (MF_KCALL_RESUME
| MF_DELIVERMSG
|
287 MF_SC_DEFER
| MF_SC_TRACE
| MF_SC_ACTIVE
)) {
289 assert(proc_is_runnable(p
));
290 if (p
->p_misc_flags
& MF_KCALL_RESUME
) {
291 kernel_call_resume(p
);
293 else if (p
->p_misc_flags
& MF_DELIVERMSG
) {
294 TRACE(VF_SCHEDULING
, printf("delivering to %s / %d\n",
295 p
->p_name
, p
->p_endpoint
););
298 else if (p
->p_misc_flags
& MF_SC_DEFER
) {
299 /* Perform the system call that we deferred earlier. */
301 assert (!(p
->p_misc_flags
& MF_SC_ACTIVE
));
305 /* If the process is stopped for signal delivery, and
306 * not blocked sending a message after the system call,
309 if ((p
->p_misc_flags
& MF_SIG_DELAY
) &&
310 !RTS_ISSET(p
, RTS_SENDING
))
313 else if (p
->p_misc_flags
& MF_SC_TRACE
) {
314 /* Trigger a system call leave event if this was a
315 * system call. We must do this after processing the
316 * other flags above, both for tracing correctness and
317 * to be able to use 'break'.
319 if (!(p
->p_misc_flags
& MF_SC_ACTIVE
))
323 ~(MF_SC_TRACE
| MF_SC_ACTIVE
);
325 /* Signal the "leave system call" event.
328 cause_sig(proc_nr(p
), SIGTRAP
);
330 else if (p
->p_misc_flags
& MF_SC_ACTIVE
) {
331 /* If MF_SC_ACTIVE was set, remove it now:
332 * we're leaving the system call.
334 p
->p_misc_flags
&= ~MF_SC_ACTIVE
;
340 * the selected process might not be runnable anymore. We have
341 * to checkit and schedule another one
343 if (!proc_is_runnable(p
))
344 goto not_runnable_pick_new
;
347 * check the quantum left before it runs again. We must do it only here
348 * as we are sure that a possible out-of-quantum message to the
349 * scheduler will not collide with the regular ipc
351 if (is_zero64(p
->p_cpu_time_left
))
354 * After handling the misc flags the selected process might not be
355 * runnable anymore. We have to checkit and schedule another one
357 if (!proc_is_runnable(p
))
358 goto not_runnable_pick_new
;
360 TRACE(VF_SCHEDULING
, printf("cpu %d starting %s / %d "
362 cpuid
, p
->p_name
, p
->p_endpoint
, p
->p_reg
.pc
););
367 p
= arch_finish_switch_to_user();
368 assert(!is_zero64(p
->p_cpu_time_left
));
370 context_stop(proc_addr(KERNEL
));
372 /* If the process isn't the owner of FPU, enable the FPU exception */
373 if(get_cpulocal_var(fpu_owner
) != p
)
374 enable_fpu_exception();
376 disable_fpu_exception();
378 /* If MF_CONTEXT_SET is set, don't clobber process state within
379 * the kernel. The next kernel entry is OK again though.
381 p
->p_misc_flags
&= ~MF_CONTEXT_SET
;
383 #if defined(__i386__)
384 assert(p
->p_seg
.p_cr3
!= 0);
385 #elif defined(__arm__)
386 assert(p
->p_seg
.p_ttbr
!= 0);
389 if (p
->p_misc_flags
& MF_FLUSH_TLB
) {
390 if (tlb_must_refresh
)
392 p
->p_misc_flags
&= ~MF_FLUSH_TLB
;
396 restart_local_timer();
399 * restore_user_context() carries out the actual mode switch from kernel
400 * to userspace. This function does not return
402 restore_user_context(p
);
407 * handler for all synchronous IPC calls
409 static int do_sync_ipc(struct proc
* caller_ptr
, /* who made the call */
410 int call_nr
, /* system call number and flags */
411 endpoint_t src_dst_e
, /* src or dst of the call */
412 message
*m_ptr
) /* users pointer to a message */
414 int result
; /* the system call's result */
415 int src_dst_p
; /* Process slot number */
418 /* Check destination. RECEIVE is the only call that accepts ANY (in addition
419 * to a real endpoint). The other calls (SEND, SENDREC, and NOTIFY) require an
420 * endpoint to corresponds to a process. In addition, it is necessary to check
421 * whether a process is allowed to send to a given destination.
423 assert(call_nr
!= SENDA
);
425 /* Only allow non-negative call_nr values less than 32 */
426 if (call_nr
< 0 || call_nr
> IPCNO_HIGHEST
|| call_nr
>= 32
427 || !(callname
= ipc_call_names
[call_nr
])) {
428 #if DEBUG_ENABLE_IPC_WARNINGS
429 printf("sys_call: trap %d not allowed, caller %d, src_dst %d\n",
430 call_nr
, proc_nr(caller_ptr
), src_dst_e
);
432 return(ETRAPDENIED
); /* trap denied by mask or kernel */
435 if (src_dst_e
== ANY
)
437 if (call_nr
!= RECEIVE
)
440 printf("sys_call: %s by %d with bad endpoint %d\n",
442 proc_nr(caller_ptr
), src_dst_e
);
446 src_dst_p
= (int) src_dst_e
;
450 /* Require a valid source and/or destination process. */
451 if(!isokendpt(src_dst_e
, &src_dst_p
)) {
453 printf("sys_call: %s by %d with bad endpoint %d\n",
455 proc_nr(caller_ptr
), src_dst_e
);
460 /* If the call is to send to a process, i.e., for SEND, SENDNB,
461 * SENDREC or NOTIFY, verify that the caller is allowed to send to
462 * the given destination.
464 if (call_nr
!= RECEIVE
)
466 if (!may_send_to(caller_ptr
, src_dst_p
)) {
467 #if DEBUG_ENABLE_IPC_WARNINGS
469 "sys_call: ipc mask denied %s from %d to %d\n",
471 caller_ptr
->p_endpoint
, src_dst_e
);
473 return(ECALLDENIED
); /* call denied by ipc mask */
478 /* Check if the process has privileges for the requested call. Calls to the
479 * kernel may only be SENDREC, because tasks always reply and may not block
480 * if the caller doesn't do receive().
482 if (!(priv(caller_ptr
)->s_trap_mask
& (1 << call_nr
))) {
483 #if DEBUG_ENABLE_IPC_WARNINGS
484 printf("sys_call: %s not allowed, caller %d, src_dst %d\n",
485 callname
, proc_nr(caller_ptr
), src_dst_p
);
487 return(ETRAPDENIED
); /* trap denied by mask or kernel */
490 if (call_nr
!= SENDREC
&& call_nr
!= RECEIVE
&& iskerneln(src_dst_p
)) {
491 #if DEBUG_ENABLE_IPC_WARNINGS
492 printf("sys_call: trap %s not allowed, caller %d, src_dst %d\n",
493 callname
, proc_nr(caller_ptr
), src_dst_e
);
495 return(ETRAPDENIED
); /* trap denied by mask or kernel */
500 /* A flag is set so that notifications cannot interrupt SENDREC. */
501 caller_ptr
->p_misc_flags
|= MF_REPLY_PEND
;
504 result
= mini_send(caller_ptr
, src_dst_e
, m_ptr
, 0);
505 if (call_nr
== SEND
|| result
!= OK
)
506 break; /* done, or SEND failed */
507 /* fall through for SENDREC */
509 if (call_nr
== RECEIVE
) {
510 caller_ptr
->p_misc_flags
&= ~MF_REPLY_PEND
;
511 IPC_STATUS_CLEAR(caller_ptr
); /* clear IPC status code */
513 result
= mini_receive(caller_ptr
, src_dst_e
, m_ptr
, 0);
516 result
= mini_notify(caller_ptr
, src_dst_e
);
519 result
= mini_send(caller_ptr
, src_dst_e
, m_ptr
, NON_BLOCKING
);
522 result
= EBADCALL
; /* illegal system call */
525 /* Now, return the result of the system call to the caller. */
529 int do_ipc(reg_t r1
, reg_t r2
, reg_t r3
)
531 struct proc
*const caller_ptr
= get_cpulocal_var(proc_ptr
); /* get pointer to caller */
532 int call_nr
= (int) r1
;
534 assert(!RTS_ISSET(caller_ptr
, RTS_SLOT_FREE
));
536 /* bill kernel time to this process. */
537 kbill_ipc
= caller_ptr
;
539 /* If this process is subject to system call tracing, handle that first. */
540 if (caller_ptr
->p_misc_flags
& (MF_SC_TRACE
| MF_SC_DEFER
)) {
541 /* Are we tracing this process, and is it the first sys_call entry? */
542 if ((caller_ptr
->p_misc_flags
& (MF_SC_TRACE
| MF_SC_DEFER
)) ==
544 /* We must notify the tracer before processing the actual
545 * system call. If we don't, the tracer could not obtain the
546 * input message. Postpone the entire system call.
548 caller_ptr
->p_misc_flags
&= ~MF_SC_TRACE
;
549 assert(!(caller_ptr
->p_misc_flags
& MF_SC_DEFER
));
550 caller_ptr
->p_misc_flags
|= MF_SC_DEFER
;
551 caller_ptr
->p_defer
.r1
= r1
;
552 caller_ptr
->p_defer
.r2
= r2
;
553 caller_ptr
->p_defer
.r3
= r3
;
555 /* Signal the "enter system call" event. Block the process. */
556 cause_sig(proc_nr(caller_ptr
), SIGTRAP
);
558 /* Preserve the return register's value. */
559 return caller_ptr
->p_reg
.retreg
;
562 /* If the MF_SC_DEFER flag is set, the syscall is now being resumed. */
563 caller_ptr
->p_misc_flags
&= ~MF_SC_DEFER
;
565 assert (!(caller_ptr
->p_misc_flags
& MF_SC_ACTIVE
));
567 /* Set a flag to allow reliable tracing of leaving the system call. */
568 caller_ptr
->p_misc_flags
|= MF_SC_ACTIVE
;
571 if(caller_ptr
->p_misc_flags
& MF_DELIVERMSG
) {
572 panic("sys_call: MF_DELIVERMSG on for %s / %d\n",
573 caller_ptr
->p_name
, caller_ptr
->p_endpoint
);
576 /* Now check if the call is known and try to perform the request. The only
577 * system calls that exist in MINIX are sending and receiving messages.
578 * - SENDREC: combines SEND and RECEIVE in a single system call
579 * - SEND: sender blocks until its message has been delivered
580 * - RECEIVE: receiver blocks until an acceptable message has arrived
581 * - NOTIFY: asynchronous call; deliver notification or mark pending
582 * - SENDA: list of asynchronous send requests
591 /* Process accounting for scheduling */
592 caller_ptr
->p_accounting
.ipc_sync
++;
594 return do_sync_ipc(caller_ptr
, call_nr
, (endpoint_t
) r2
,
600 * Get and check the size of the argument in bytes as it is a
603 size_t msg_size
= (size_t) r2
;
605 /* Process accounting for scheduling */
606 caller_ptr
->p_accounting
.ipc_async
++;
608 /* Limit size to something reasonable. An arbitrary choice is 16
609 * times the number of process table entries.
611 if (msg_size
> 16*(NR_TASKS
+ NR_PROCS
))
613 return mini_senda(caller_ptr
, (asynmsg_t
*) r3
, msg_size
);
617 /* It might not be initialized yet. */
618 if(!minix_kerninfo_user
) {
622 arch_set_secondary_ipc_return(caller_ptr
, minix_kerninfo_user
);
626 return EBADCALL
; /* illegal system call */
630 /*===========================================================================*
632 *===========================================================================*/
633 static int deadlock(function
, cp
, src_dst_e
)
634 int function
; /* trap number */
635 register struct proc
*cp
; /* pointer to caller */
636 endpoint_t src_dst_e
; /* src or dst process */
638 /* Check for deadlock. This can happen if 'caller_ptr' and 'src_dst' have
639 * a cyclic dependency of blocking send and receive calls. The only cyclic
640 * depency that is not fatal is if the caller and target directly SEND(REC)
641 * and RECEIVE to each other. If a deadlock is found, the group size is
642 * returned. Otherwise zero is returned.
644 register struct proc
*xp
; /* process pointer */
645 int group_size
= 1; /* start with only caller */
646 #if DEBUG_ENABLE_IPC_WARNINGS
647 static struct proc
*processes
[NR_PROCS
+ NR_TASKS
];
651 while (src_dst_e
!= ANY
) { /* check while process nr */
653 okendpt(src_dst_e
, &src_dst_slot
);
654 xp
= proc_addr(src_dst_slot
); /* follow chain of processes */
655 assert(proc_ptr_ok(xp
));
656 assert(!RTS_ISSET(xp
, RTS_SLOT_FREE
));
657 #if DEBUG_ENABLE_IPC_WARNINGS
658 processes
[group_size
] = xp
;
660 group_size
++; /* extra process in group */
662 /* Check whether the last process in the chain has a dependency. If it
663 * has not, the cycle cannot be closed and we are done.
665 if((src_dst_e
= P_BLOCKEDON(xp
)) == NONE
)
668 /* Now check if there is a cyclic dependency. For group sizes of two,
669 * a combination of SEND(REC) and RECEIVE is not fatal. Larger groups
670 * or other combinations indicate a deadlock.
672 if (src_dst_e
== cp
->p_endpoint
) { /* possible deadlock */
673 if (group_size
== 2) { /* caller and src_dst */
674 /* The function number is magically converted to flags. */
675 if ((xp
->p_rts_flags
^ (function
<< 2)) & RTS_SENDING
) {
676 return(0); /* not a deadlock */
679 #if DEBUG_ENABLE_IPC_WARNINGS
682 printf("deadlock between these processes:\n");
683 for(i
= 0; i
< group_size
; i
++) {
684 printf(" %10s ", processes
[i
]->p_name
);
687 for(i
= 0; i
< group_size
; i
++) {
688 print_proc(processes
[i
]);
689 proc_stacktrace(processes
[i
]);
693 return(group_size
); /* deadlock found */
696 return(0); /* not a deadlock */
699 /*===========================================================================*
701 *===========================================================================*/
702 static int has_pending(sys_map_t
*map
, int src_p
, int asynm
)
704 /* Check to see if there is a pending message from the desired source
709 sys_id_t id
= NULL_PRIV_ID
;
714 /* Either check a specific bit in the mask map, or find the first bit set in
715 * it (if any), depending on whether the receive was called on a specific
719 src_id
= nr_to_id(src_p
);
720 if (get_sys_bit(*map
, src_id
)) {
722 p
= proc_addr(id_to_nr(src_id
));
723 if (asynm
&& RTS_ISSET(p
, RTS_VMINHIBIT
))
724 p
->p_misc_flags
|= MF_SENDA_VM_MISS
;
730 /* Find a source with a pending message */
731 for (src_id
= 0; src_id
< NR_SYS_PROCS
; src_id
+= BITCHUNK_BITS
) {
732 if (get_sys_bits(*map
, src_id
) != 0) {
734 while (src_id
< NR_SYS_PROCS
) {
735 while (!get_sys_bit(*map
, src_id
)) {
736 if (src_id
== NR_SYS_PROCS
)
740 p
= proc_addr(id_to_nr(src_id
));
742 * We must not let kernel fiddle with pages of a
743 * process which are currently being changed by
744 * VM. It is dangerous! So do not report such a
745 * process as having pending async messages.
748 if (asynm
&& RTS_ISSET(p
, RTS_VMINHIBIT
)) {
749 p
->p_misc_flags
|= MF_SENDA_VM_MISS
;
755 while (!get_sys_bit(*map
, src_id
)) src_id
++;
762 if (src_id
< NR_SYS_PROCS
) /* Found one */
769 /*===========================================================================*
770 * has_pending_notify *
771 *===========================================================================*/
772 int has_pending_notify(struct proc
* caller
, int src_p
)
774 sys_map_t
* map
= &priv(caller
)->s_notify_pending
;
775 return has_pending(map
, src_p
, 0);
778 /*===========================================================================*
779 * has_pending_asend *
780 *===========================================================================*/
781 int has_pending_asend(struct proc
* caller
, int src_p
)
783 sys_map_t
* map
= &priv(caller
)->s_asyn_pending
;
784 return has_pending(map
, src_p
, 1);
787 /*===========================================================================*
788 * unset_notify_pending *
789 *===========================================================================*/
790 void unset_notify_pending(struct proc
* caller
, int src_p
)
792 sys_map_t
* map
= &priv(caller
)->s_notify_pending
;
793 unset_sys_bit(*map
, src_p
);
796 /*===========================================================================*
798 *===========================================================================*/
800 register struct proc
*caller_ptr
, /* who is trying to send a message? */
801 endpoint_t dst_e
, /* to whom is message being sent? */
802 message
*m_ptr
, /* pointer to message buffer */
806 /* Send a message from 'caller_ptr' to 'dst'. If 'dst' is blocked waiting
807 * for this message, copy the message to it and unblock 'dst'. If 'dst' is
808 * not waiting at all, or is waiting for another source, queue 'caller_ptr'.
810 register struct proc
*dst_ptr
;
811 register struct proc
**xpp
;
813 dst_p
= _ENDPOINT_P(dst_e
);
814 dst_ptr
= proc_addr(dst_p
);
816 if (RTS_ISSET(dst_ptr
, RTS_NO_ENDPOINT
))
821 /* Check if 'dst' is blocked waiting for this message. The destination's
822 * RTS_SENDING flag may be set when its SENDREC call blocked while sending.
824 if (WILLRECEIVE(dst_ptr
, caller_ptr
->p_endpoint
)) {
826 /* Destination is indeed waiting for this message. */
827 assert(!(dst_ptr
->p_misc_flags
& MF_DELIVERMSG
));
829 if (!(flags
& FROM_KERNEL
)) {
830 if(copy_msg_from_user(m_ptr
, &dst_ptr
->p_delivermsg
))
833 dst_ptr
->p_delivermsg
= *m_ptr
;
834 IPC_STATUS_ADD_FLAGS(dst_ptr
, IPC_FLG_MSG_FROM_KERNEL
);
837 dst_ptr
->p_delivermsg
.m_source
= caller_ptr
->p_endpoint
;
838 dst_ptr
->p_misc_flags
|= MF_DELIVERMSG
;
840 call
= (caller_ptr
->p_misc_flags
& MF_REPLY_PEND
? SENDREC
841 : (flags
& NON_BLOCKING
? SENDNB
: SEND
));
842 IPC_STATUS_ADD_CALL(dst_ptr
, call
);
844 if (dst_ptr
->p_misc_flags
& MF_REPLY_PEND
)
845 dst_ptr
->p_misc_flags
&= ~MF_REPLY_PEND
;
847 RTS_UNSET(dst_ptr
, RTS_RECEIVING
);
850 hook_ipc_msgsend(&dst_ptr
->p_delivermsg
, caller_ptr
, dst_ptr
);
851 hook_ipc_msgrecv(&dst_ptr
->p_delivermsg
, caller_ptr
, dst_ptr
);
854 if(flags
& NON_BLOCKING
) {
858 /* Check for a possible deadlock before actually blocking. */
859 if (deadlock(SEND
, caller_ptr
, dst_e
)) {
863 /* Destination is not waiting. Block and dequeue caller. */
864 if (!(flags
& FROM_KERNEL
)) {
865 if(copy_msg_from_user(m_ptr
, &caller_ptr
->p_sendmsg
))
868 caller_ptr
->p_sendmsg
= *m_ptr
;
870 * we need to remember that this message is from kernel so we
871 * can set the delivery status flags when the message is
874 caller_ptr
->p_misc_flags
|= MF_SENDING_FROM_KERNEL
;
877 RTS_SET(caller_ptr
, RTS_SENDING
);
878 caller_ptr
->p_sendto_e
= dst_e
;
880 /* Process is now blocked. Put in on the destination's queue. */
881 assert(caller_ptr
->p_q_link
== NULL
);
882 xpp
= &dst_ptr
->p_caller_q
; /* find end of list */
883 while (*xpp
) xpp
= &(*xpp
)->p_q_link
;
884 *xpp
= caller_ptr
; /* add caller to end */
887 hook_ipc_msgsend(&caller_ptr
->p_sendmsg
, caller_ptr
, dst_ptr
);
893 /*===========================================================================*
895 *===========================================================================*/
896 static int mini_receive(struct proc
* caller_ptr
,
897 endpoint_t src_e
, /* which message source is wanted */
898 message
* m_buff_usr
, /* pointer to message buffer */
901 /* A process or task wants to get a message. If a message is already queued,
902 * acquire it and deblock the sender. If no message from the desired source
903 * is available block the caller.
905 register struct proc
**xpp
;
906 int r
, src_id
, src_proc_nr
, src_p
;
908 assert(!(caller_ptr
->p_misc_flags
& MF_DELIVERMSG
));
910 /* This is where we want our message. */
911 caller_ptr
->p_delivermsg_vir
= (vir_bytes
) m_buff_usr
;
913 if(src_e
== ANY
) src_p
= ANY
;
916 okendpt(src_e
, &src_p
);
917 if (RTS_ISSET(proc_addr(src_p
), RTS_NO_ENDPOINT
))
924 /* Check to see if a message from desired source is already available. The
925 * caller's RTS_SENDING flag may be set if SENDREC couldn't send. If it is
926 * set, the process should be blocked.
928 if (!RTS_ISSET(caller_ptr
, RTS_SENDING
)) {
930 /* Check if there are pending notifications, except for SENDREC. */
931 if (! (caller_ptr
->p_misc_flags
& MF_REPLY_PEND
)) {
933 /* Check for pending notifications */
934 if ((src_id
= has_pending_notify(caller_ptr
, src_p
)) != NULL_PRIV_ID
) {
937 src_proc_nr
= id_to_nr(src_id
); /* get source proc */
938 #if DEBUG_ENABLE_IPC_WARNINGS
939 if(src_proc_nr
== NONE
) {
940 printf("mini_receive: sending notify from NONE\n");
943 assert(src_proc_nr
!= NONE
);
944 unset_notify_pending(caller_ptr
, src_id
); /* no longer pending */
946 /* Found a suitable source, deliver the notification message. */
947 hisep
= proc_addr(src_proc_nr
)->p_endpoint
;
948 assert(!(caller_ptr
->p_misc_flags
& MF_DELIVERMSG
));
949 assert(src_e
== ANY
|| hisep
== src_e
);
951 /* assemble message */
952 BuildNotifyMessage(&caller_ptr
->p_delivermsg
, src_proc_nr
, caller_ptr
);
953 caller_ptr
->p_delivermsg
.m_source
= hisep
;
954 caller_ptr
->p_misc_flags
|= MF_DELIVERMSG
;
956 IPC_STATUS_ADD_CALL(caller_ptr
, NOTIFY
);
962 /* Check for pending asynchronous messages */
963 if (has_pending_asend(caller_ptr
, src_p
) != NULL_PRIV_ID
) {
965 r
= try_one(proc_addr(src_p
), caller_ptr
);
967 r
= try_async(caller_ptr
);
970 IPC_STATUS_ADD_CALL(caller_ptr
, SENDA
);
975 /* Check caller queue. Use pointer pointers to keep code simple. */
976 xpp
= &caller_ptr
->p_caller_q
;
978 struct proc
* sender
= *xpp
;
980 if (src_e
== ANY
|| src_p
== proc_nr(sender
)) {
982 assert(!RTS_ISSET(sender
, RTS_SLOT_FREE
));
983 assert(!RTS_ISSET(sender
, RTS_NO_ENDPOINT
));
985 /* Found acceptable message. Copy it and update status. */
986 assert(!(caller_ptr
->p_misc_flags
& MF_DELIVERMSG
));
987 caller_ptr
->p_delivermsg
= sender
->p_sendmsg
;
988 caller_ptr
->p_delivermsg
.m_source
= sender
->p_endpoint
;
989 caller_ptr
->p_misc_flags
|= MF_DELIVERMSG
;
990 RTS_UNSET(sender
, RTS_SENDING
);
992 call
= (sender
->p_misc_flags
& MF_REPLY_PEND
? SENDREC
: SEND
);
993 IPC_STATUS_ADD_CALL(caller_ptr
, call
);
996 * if the message is originaly from the kernel on behalf of this
997 * process, we must send the status flags accordingly
999 if (sender
->p_misc_flags
& MF_SENDING_FROM_KERNEL
) {
1000 IPC_STATUS_ADD_FLAGS(caller_ptr
, IPC_FLG_MSG_FROM_KERNEL
);
1001 /* we can clean the flag now, not need anymore */
1002 sender
->p_misc_flags
&= ~MF_SENDING_FROM_KERNEL
;
1004 if (sender
->p_misc_flags
& MF_SIG_DELAY
)
1005 sig_delay_done(sender
);
1008 hook_ipc_msgrecv(&caller_ptr
->p_delivermsg
, *xpp
, caller_ptr
);
1011 *xpp
= sender
->p_q_link
; /* remove from queue */
1012 sender
->p_q_link
= NULL
;
1015 xpp
= &sender
->p_q_link
; /* proceed to next */
1019 /* No suitable message is available or the caller couldn't send in SENDREC.
1020 * Block the process trying to receive, unless the flags tell otherwise.
1022 if ( ! (flags
& NON_BLOCKING
)) {
1023 /* Check for a possible deadlock before actually blocking. */
1024 if (deadlock(RECEIVE
, caller_ptr
, src_e
)) {
1028 caller_ptr
->p_getfrom_e
= src_e
;
1029 RTS_SET(caller_ptr
, RTS_RECEIVING
);
1036 if (caller_ptr
->p_misc_flags
& MF_REPLY_PEND
)
1037 caller_ptr
->p_misc_flags
&= ~MF_REPLY_PEND
;
1041 /*===========================================================================*
1043 *===========================================================================*/
1045 const struct proc
*caller_ptr
, /* sender of the notification */
1046 endpoint_t dst_e
/* which process to notify */
1049 register struct proc
*dst_ptr
;
1050 int src_id
; /* source id for late delivery */
1053 if (!isokendpt(dst_e
, &dst_p
)) {
1055 printf("mini_notify: bogus endpoint %d\n", dst_e
);
1059 dst_ptr
= proc_addr(dst_p
);
1061 /* Check to see if target is blocked waiting for this message. A process
1062 * can be both sending and receiving during a SENDREC system call.
1064 if (WILLRECEIVE(dst_ptr
, caller_ptr
->p_endpoint
) &&
1065 ! (dst_ptr
->p_misc_flags
& MF_REPLY_PEND
)) {
1066 /* Destination is indeed waiting for a message. Assemble a notification
1067 * message and deliver it. Copy from pseudo-source HARDWARE, since the
1068 * message is in the kernel's address space.
1070 assert(!(dst_ptr
->p_misc_flags
& MF_DELIVERMSG
));
1072 BuildNotifyMessage(&dst_ptr
->p_delivermsg
, proc_nr(caller_ptr
), dst_ptr
);
1073 dst_ptr
->p_delivermsg
.m_source
= caller_ptr
->p_endpoint
;
1074 dst_ptr
->p_misc_flags
|= MF_DELIVERMSG
;
1076 IPC_STATUS_ADD_CALL(dst_ptr
, NOTIFY
);
1077 RTS_UNSET(dst_ptr
, RTS_RECEIVING
);
1082 /* Destination is not ready to receive the notification. Add it to the
1083 * bit map with pending notifications. Note the indirectness: the privilege id
1084 * instead of the process number is used in the pending bit map.
1086 src_id
= priv(caller_ptr
)->s_id
;
1087 set_sys_bit(priv(dst_ptr
)->s_notify_pending
, src_id
);
1091 #define ASCOMPLAIN(caller, entry, field) \
1092 printf("kernel:%s:%d: asyn failed for %s in %s " \
1093 "(%d/%d, tab 0x%lx)\n",__FILE__,__LINE__, \
1094 field, caller->p_name, entry, priv(caller)->s_asynsize, priv(caller)->s_asyntab)
1096 #define A_RETR_FLD(entry, field) \
1097 if(data_copy(caller_ptr->p_endpoint, \
1098 table_v + (entry)*sizeof(asynmsg_t) + offsetof(struct asynmsg,field),\
1099 KERNEL, (vir_bytes) &tabent.field, \
1100 sizeof(tabent.field)) != OK) {\
1101 ASCOMPLAIN(caller_ptr, entry, #field); \
1106 #define A_RETR(entry) do { \
1108 caller_ptr->p_endpoint, table_v + (entry)*sizeof(asynmsg_t),\
1109 KERNEL, (vir_bytes) &tabent, \
1110 sizeof(tabent)) != OK) { \
1111 ASCOMPLAIN(caller_ptr, entry, "message entry"); \
1117 #define A_INSRT_FLD(entry, field) \
1118 if(data_copy(KERNEL, (vir_bytes) &tabent.field, \
1119 caller_ptr->p_endpoint, \
1120 table_v + (entry)*sizeof(asynmsg_t) + offsetof(struct asynmsg,field),\
1121 sizeof(tabent.field)) != OK) {\
1122 ASCOMPLAIN(caller_ptr, entry, #field); \
1127 #define A_INSRT(entry) do { \
1128 if (data_copy(KERNEL, (vir_bytes) &tabent, \
1129 caller_ptr->p_endpoint, table_v + (entry)*sizeof(asynmsg_t),\
1130 sizeof(tabent)) != OK) { \
1131 ASCOMPLAIN(caller_ptr, entry, "message entry"); \
1137 /*===========================================================================*
1138 * try_deliver_senda *
1139 *===========================================================================*/
1140 int try_deliver_senda(struct proc
*caller_ptr
,
1144 int r
, dst_p
, done
, do_notify
;
1148 struct proc
*dst_ptr
;
1151 const vir_bytes table_v
= (vir_bytes
) table
;
1153 privp
= priv(caller_ptr
);
1156 privp
->s_asyntab
= -1;
1157 privp
->s_asynsize
= 0;
1159 if (size
== 0) return(OK
); /* Nothing to do, just return */
1161 /* Scan the table */
1165 /* Limit size to something reasonable. An arbitrary choice is 16
1166 * times the number of process table entries.
1168 * (this check has been duplicated in sys_call but is left here
1169 * as a sanity check)
1171 if (size
> 16*(NR_TASKS
+ NR_PROCS
)) {
1176 for (i
= 0; i
< size
; i
++) {
1177 /* Process each entry in the table and store the result in the table.
1178 * If we're done handling a message, copy the result to the sender. */
1181 /* Copy message to kernel */
1183 flags
= tabent
.flags
;
1186 if (flags
== 0) continue; /* Skip empty entries */
1188 /* 'flags' field must contain only valid bits */
1189 if(flags
& ~(AMF_VALID
|AMF_DONE
|AMF_NOTIFY
|AMF_NOREPLY
|AMF_NOTIFY_ERR
)) {
1193 if (!(flags
& AMF_VALID
)) { /* Must contain message */
1197 if (flags
& AMF_DONE
) continue; /* Already done processing */
1200 if (!isokendpt(tabent
.dst
, &dst_p
))
1201 r
= EDEADSRCDST
; /* Bad destination, report the error */
1202 else if (iskerneln(dst_p
))
1203 r
= ECALLDENIED
; /* Asyn sends to the kernel are not allowed */
1204 else if (!may_send_to(caller_ptr
, dst_p
))
1205 r
= ECALLDENIED
; /* Send denied by IPC mask */
1207 dst_ptr
= proc_addr(dst_p
);
1209 /* XXX: RTS_NO_ENDPOINT should be removed */
1210 if (r
== OK
&& RTS_ISSET(dst_ptr
, RTS_NO_ENDPOINT
)) {
1214 /* Check if 'dst' is blocked waiting for this message.
1215 * If AMF_NOREPLY is set, do not satisfy the receiving part of
1218 if (r
== OK
&& WILLRECEIVE(dst_ptr
, caller_ptr
->p_endpoint
) &&
1219 (!(flags
&AMF_NOREPLY
) || !(dst_ptr
->p_misc_flags
&MF_REPLY_PEND
))) {
1220 /* Destination is indeed waiting for this message. */
1221 dst_ptr
->p_delivermsg
= tabent
.msg
;
1222 dst_ptr
->p_delivermsg
.m_source
= caller_ptr
->p_endpoint
;
1223 dst_ptr
->p_misc_flags
|= MF_DELIVERMSG
;
1224 IPC_STATUS_ADD_CALL(dst_ptr
, SENDA
);
1225 RTS_UNSET(dst_ptr
, RTS_RECEIVING
);
1226 } else if (r
== OK
) {
1227 /* Inform receiver that something is pending */
1228 set_sys_bit(priv(dst_ptr
)->s_asyn_pending
,
1229 priv(caller_ptr
)->s_id
);
1236 tabent
.flags
= flags
| AMF_DONE
;
1237 if (flags
& AMF_NOTIFY
)
1239 else if (r
!= OK
&& (flags
& AMF_NOTIFY_ERR
))
1241 A_INSRT(i
); /* Copy results to caller */
1246 printf("KERNEL senda error %d to %d\n", r
, dst
);
1248 printf("KERNEL senda error %d\n", r
);
1252 mini_notify(proc_addr(ASYNCM
), caller_ptr
->p_endpoint
);
1255 privp
->s_asyntab
= (vir_bytes
) table
;
1256 privp
->s_asynsize
= size
;
1262 /*===========================================================================*
1264 *===========================================================================*/
1265 static int mini_senda(struct proc
*caller_ptr
, asynmsg_t
*table
, size_t size
)
1269 privp
= priv(caller_ptr
);
1270 if (!(privp
->s_flags
& SYS_PROC
)) {
1271 printf( "mini_senda: warning caller has no privilege structure\n");
1275 return try_deliver_senda(caller_ptr
, table
, size
);
1279 /*===========================================================================*
1281 *===========================================================================*/
1282 static int try_async(caller_ptr
)
1283 struct proc
*caller_ptr
;
1287 struct proc
*src_ptr
;
1290 map
= &priv(caller_ptr
)->s_asyn_pending
;
1292 /* Try all privilege structures */
1293 for (privp
= BEG_PRIV_ADDR
; privp
< END_PRIV_ADDR
; ++privp
) {
1294 if (privp
->s_proc_nr
== NONE
)
1297 if (!get_sys_bit(*map
, privp
->s_id
))
1300 src_ptr
= proc_addr(privp
->s_proc_nr
);
1304 * Do not copy from a process which does not have a stable address space
1305 * due to VM fiddling with it
1307 if (RTS_ISSET(src_ptr
, RTS_VMINHIBIT
)) {
1308 src_ptr
->p_misc_flags
|= MF_SENDA_VM_MISS
;
1313 assert(!(caller_ptr
->p_misc_flags
& MF_DELIVERMSG
));
1314 if ((r
= try_one(src_ptr
, caller_ptr
)) == OK
)
1322 /*===========================================================================*
1324 *===========================================================================*/
1325 static int try_one(struct proc
*src_ptr
, struct proc
*dst_ptr
)
1327 /* Try to receive an asynchronous message from 'src_ptr' */
1328 int r
= EAGAIN
, done
, do_notify
;
1329 unsigned int flags
, i
;
1332 struct proc
*caller_ptr
;
1337 privp
= priv(src_ptr
);
1338 if (!(privp
->s_flags
& SYS_PROC
)) return(EPERM
);
1339 size
= privp
->s_asynsize
;
1340 table_v
= privp
->s_asyntab
;
1342 /* Clear table pending message flag. We're done unless we're not. */
1343 unset_sys_bit(priv(dst_ptr
)->s_asyn_pending
, privp
->s_id
);
1345 if (size
== 0) return(EAGAIN
);
1346 if (!may_send_to(src_ptr
, proc_nr(dst_ptr
))) return(ECALLDENIED
);
1348 caller_ptr
= src_ptr
; /* Needed for A_ macros later on */
1350 /* Scan the table */
1354 for (i
= 0; i
< size
; i
++) {
1355 /* Process each entry in the table and store the result in the table.
1356 * If we're done handling a message, copy the result to the sender.
1357 * Some checks done in mini_senda are duplicated here, as the sender
1358 * could've altered the contents of the table in the meantime.
1361 /* Copy message to kernel */
1363 flags
= tabent
.flags
;
1366 if (flags
== 0) continue; /* Skip empty entries */
1368 /* 'flags' field must contain only valid bits */
1369 if(flags
& ~(AMF_VALID
|AMF_DONE
|AMF_NOTIFY
|AMF_NOREPLY
|AMF_NOTIFY_ERR
))
1371 else if (!(flags
& AMF_VALID
)) /* Must contain message */
1373 else if (flags
& AMF_DONE
) continue; /* Already done processing */
1375 /* Clear done flag. The sender is done sending when all messages in the
1376 * table are marked done or empty. However, we will know that only
1377 * the next time we enter this function or when the sender decides to
1378 * send additional asynchronous messages and manages to deliver them
1386 /* Message must be directed at receiving end */
1387 if (dst
!= dst_ptr
->p_endpoint
) continue;
1389 /* If AMF_NOREPLY is set, then this message is not a reply to a
1390 * SENDREC and thus should not satisfy the receiving part of the
1391 * SENDREC. This message is to be delivered later.
1393 if ((flags
& AMF_NOREPLY
) && (dst_ptr
->p_misc_flags
& MF_REPLY_PEND
))
1396 /* Destination is ready to receive the message; deliver it */
1398 dst_ptr
->p_delivermsg
= tabent
.msg
;
1399 dst_ptr
->p_delivermsg
.m_source
= src_ptr
->p_endpoint
;
1400 dst_ptr
->p_misc_flags
|= MF_DELIVERMSG
;
1403 /* Store results for sender */
1405 tabent
.flags
= flags
| AMF_DONE
;
1406 if (flags
& AMF_NOTIFY
) do_notify
= TRUE
;
1407 else if (r
!= OK
&& (flags
& AMF_NOTIFY_ERR
)) do_notify
= TRUE
;
1408 A_INSRT(i
); /* Copy results to sender */
1414 mini_notify(proc_addr(ASYNCM
), src_ptr
->p_endpoint
);
1417 privp
->s_asyntab
= -1;
1418 privp
->s_asynsize
= 0;
1420 set_sys_bit(priv(dst_ptr
)->s_asyn_pending
, privp
->s_id
);
1427 /*===========================================================================*
1429 *===========================================================================*/
1430 int cancel_async(struct proc
*src_ptr
, struct proc
*dst_ptr
)
1432 /* Cancel asynchronous messages from src to dst, because dst is not interested
1433 * in them (e.g., dst has been restarted) */
1434 int done
, do_notify
;
1435 unsigned int flags
, i
;
1438 struct proc
*caller_ptr
;
1443 privp
= priv(src_ptr
);
1444 if (!(privp
->s_flags
& SYS_PROC
)) return(EPERM
);
1445 size
= privp
->s_asynsize
;
1446 table_v
= privp
->s_asyntab
;
1448 /* Clear table pending message flag. We're done unless we're not. */
1449 privp
->s_asyntab
= -1;
1450 privp
->s_asynsize
= 0;
1451 unset_sys_bit(priv(dst_ptr
)->s_asyn_pending
, privp
->s_id
);
1453 if (size
== 0) return(EAGAIN
);
1454 if (!may_send_to(src_ptr
, proc_nr(dst_ptr
))) return(ECALLDENIED
);
1456 caller_ptr
= src_ptr
; /* Needed for A_ macros later on */
1458 /* Scan the table */
1463 for (i
= 0; i
< size
; i
++) {
1464 /* Process each entry in the table and store the result in the table.
1465 * If we're done handling a message, copy the result to the sender.
1466 * Some checks done in mini_senda are duplicated here, as the sender
1467 * could've altered the contents of the table in the mean time.
1470 int r
= EDEADSRCDST
; /* Cancel delivery due to dead dst */
1472 /* Copy message to kernel */
1474 flags
= tabent
.flags
;
1477 if (flags
== 0) continue; /* Skip empty entries */
1479 /* 'flags' field must contain only valid bits */
1480 if(flags
& ~(AMF_VALID
|AMF_DONE
|AMF_NOTIFY
|AMF_NOREPLY
|AMF_NOTIFY_ERR
))
1482 else if (!(flags
& AMF_VALID
)) /* Must contain message */
1484 else if (flags
& AMF_DONE
) continue; /* Already done processing */
1486 /* Message must be directed at receiving end */
1487 if (dst
!= dst_ptr
->p_endpoint
) {
1492 /* Store results for sender */
1494 tabent
.flags
= flags
| AMF_DONE
;
1495 if (flags
& AMF_NOTIFY
) do_notify
= TRUE
;
1496 else if (r
!= OK
&& (flags
& AMF_NOTIFY_ERR
)) do_notify
= TRUE
;
1497 A_INSRT(i
); /* Copy results to sender */
1501 mini_notify(proc_addr(ASYNCM
), src_ptr
->p_endpoint
);
1504 privp
->s_asyntab
= table_v
;
1505 privp
->s_asynsize
= size
;
1512 /*===========================================================================*
1514 *===========================================================================*/
1516 register struct proc
*rp
/* this process is now runnable */
1519 /* Add 'rp' to one of the queues of runnable processes. This function is
1520 * responsible for inserting a process into one of the scheduling queues.
1521 * The mechanism is implemented here. The actual scheduling policy is
1522 * defined in sched() and pick_proc().
1524 * This function can be used x-cpu as it always uses the queues of the cpu the
1525 * process is assigned to.
1527 int q
= rp
->p_priority
; /* scheduling queue to use */
1528 struct proc
**rdy_head
, **rdy_tail
;
1530 assert(proc_is_runnable(rp
));
1534 rdy_head
= get_cpu_var(rp
->p_cpu
, run_q_head
);
1535 rdy_tail
= get_cpu_var(rp
->p_cpu
, run_q_tail
);
1537 /* Now add the process to the queue. */
1538 if (!rdy_head
[q
]) { /* add to empty queue */
1539 rdy_head
[q
] = rdy_tail
[q
] = rp
; /* create a new queue */
1540 rp
->p_nextready
= NULL
; /* mark new end */
1542 else { /* add to tail of queue */
1543 rdy_tail
[q
]->p_nextready
= rp
; /* chain tail of queue */
1544 rdy_tail
[q
] = rp
; /* set new queue tail */
1545 rp
->p_nextready
= NULL
; /* mark new end */
1548 if (cpuid
== rp
->p_cpu
) {
1550 * enqueueing a process with a higher priority than the current one,
1551 * it gets preempted. The current process must be preemptible. Testing
1552 * the priority also makes sure that a process does not preempt itself
1555 p
= get_cpulocal_var(proc_ptr
);
1557 if((p
->p_priority
> rp
->p_priority
) &&
1558 (priv(p
)->s_flags
& PREEMPTIBLE
))
1559 RTS_SET(p
, RTS_PREEMPTED
); /* calls dequeue() */
1563 * if the process was enqueued on a different cpu and the cpu is idle, i.e.
1564 * the time is off, we need to wake up that cpu and let it schedule this new
1567 else if (get_cpu_var(rp
->p_cpu
, cpu_is_idle
)) {
1568 smp_schedule(rp
->p_cpu
);
1572 /* Make note of when this process was added to queue */
1573 read_tsc_64(&(get_cpulocal_var(proc_ptr
)->p_accounting
.enter_queue
));
1576 #if DEBUG_SANITYCHECKS
1577 assert(runqueues_ok_local());
1581 /*===========================================================================*
1583 *===========================================================================*/
1585 * put a process at the front of its run queue. It comes handy when a process is
1586 * preempted and removed from run queue to not to have a currently not-runnable
1587 * process on a run queue. We have to put this process back at the fron to be
1590 static void enqueue_head(struct proc
*rp
)
1592 const int q
= rp
->p_priority
; /* scheduling queue to use */
1594 struct proc
**rdy_head
, **rdy_tail
;
1596 assert(proc_ptr_ok(rp
));
1597 assert(proc_is_runnable(rp
));
1600 * the process was runnable without its quantum expired when dequeued. A
1601 * process with no time left should vahe been handled else and differently
1603 assert(!is_zero64(rp
->p_cpu_time_left
));
1608 rdy_head
= get_cpu_var(rp
->p_cpu
, run_q_head
);
1609 rdy_tail
= get_cpu_var(rp
->p_cpu
, run_q_tail
);
1611 /* Now add the process to the queue. */
1612 if (!rdy_head
[q
]) { /* add to empty queue */
1613 rdy_head
[q
] = rdy_tail
[q
] = rp
; /* create a new queue */
1614 rp
->p_nextready
= NULL
; /* mark new end */
1616 else /* add to head of queue */
1617 rp
->p_nextready
= rdy_head
[q
]; /* chain head of queue */
1618 rdy_head
[q
] = rp
; /* set new queue head */
1620 /* Make note of when this process was added to queue */
1621 read_tsc_64(&(get_cpulocal_var(proc_ptr
->p_accounting
.enter_queue
)));
1624 /* Process accounting for scheduling */
1625 rp
->p_accounting
.dequeues
--;
1626 rp
->p_accounting
.preempted
++;
1628 #if DEBUG_SANITYCHECKS
1629 assert(runqueues_ok_local());
1633 /*===========================================================================*
1635 *===========================================================================*/
1636 void dequeue(struct proc
*rp
)
1637 /* this process is no longer runnable */
1639 /* A process must be removed from the scheduling queues, for example, because
1640 * it has blocked. If the currently active process is removed, a new process
1641 * is picked to run by calling pick_proc().
1643 * This function can operate x-cpu as it always removes the process from the
1644 * queue of the cpu the process is currently assigned to.
1646 int q
= rp
->p_priority
; /* queue to use */
1647 struct proc
**xpp
; /* iterate over queue */
1648 struct proc
*prev_xp
;
1649 u64_t tsc
, tsc_delta
;
1651 struct proc
**rdy_tail
;
1653 assert(proc_ptr_ok(rp
));
1654 assert(!proc_is_runnable(rp
));
1656 /* Side-effect for kernel: check if the task's stack still is ok? */
1657 assert (!iskernelp(rp
) || *priv(rp
)->s_stack_guard
== STACK_GUARD
);
1659 rdy_tail
= get_cpu_var(rp
->p_cpu
, run_q_tail
);
1661 /* Now make sure that the process is not in its ready queue. Remove the
1662 * process if it is found. A process can be made unready even if it is not
1663 * running by being sent a signal that kills it.
1666 for (xpp
= get_cpu_var_ptr(rp
->p_cpu
, run_q_head
[q
]); *xpp
;
1667 xpp
= &(*xpp
)->p_nextready
) {
1668 if (*xpp
== rp
) { /* found process to remove */
1669 *xpp
= (*xpp
)->p_nextready
; /* replace with next chain */
1670 if (rp
== rdy_tail
[q
]) { /* queue tail removed */
1671 rdy_tail
[q
] = prev_xp
; /* set new tail */
1676 prev_xp
= *xpp
; /* save previous in chain */
1680 /* Process accounting for scheduling */
1681 rp
->p_accounting
.dequeues
++;
1683 /* this is not all that accurate on virtual machines, especially with
1684 IO bound processes that only spend a short amount of time in the queue
1686 if (!is_zero64(rp
->p_accounting
.enter_queue
)) {
1688 tsc_delta
= sub64(tsc
, rp
->p_accounting
.enter_queue
);
1689 rp
->p_accounting
.time_in_queue
= add64(rp
->p_accounting
.time_in_queue
,
1691 make_zero64(rp
->p_accounting
.enter_queue
);
1695 #if DEBUG_SANITYCHECKS
1696 assert(runqueues_ok_local());
1700 /*===========================================================================*
1702 *===========================================================================*/
1703 static struct proc
* pick_proc(void)
1705 /* Decide who to run now. A new process is selected an returned.
1706 * When a billable process is selected, record it in 'bill_ptr', so that the
1707 * clock task can tell who to bill for system time.
1709 * This function always uses the run queues of the local cpu!
1711 register struct proc
*rp
; /* process to run */
1712 struct proc
**rdy_head
;
1713 int q
; /* iterate over queues */
1715 /* Check each of the scheduling queues for ready processes. The number of
1716 * queues is defined in proc.h, and priorities are set in the task table.
1717 * If there are no processes ready to run, return NULL.
1719 rdy_head
= get_cpulocal_var(run_q_head
);
1720 for (q
=0; q
< NR_SCHED_QUEUES
; q
++) {
1721 if(!(rp
= rdy_head
[q
])) {
1722 TRACE(VF_PICKPROC
, printf("cpu %d queue %d empty\n", cpuid
, q
););
1725 assert(proc_is_runnable(rp
));
1726 if (priv(rp
)->s_flags
& BILLABLE
)
1727 get_cpulocal_var(bill_ptr
) = rp
; /* bill for system time */
1733 /*===========================================================================*
1735 *===========================================================================*/
1736 struct proc
*endpoint_lookup(endpoint_t e
)
1740 if(!isokendpt(e
, &n
)) return NULL
;
1742 return proc_addr(n
);
1745 /*===========================================================================*
1747 *===========================================================================*/
1748 #if DEBUG_ENABLE_IPC_WARNINGS
1749 int isokendpt_f(file
, line
, e
, p
, fatalflag
)
1753 int isokendpt_f(e
, p
, fatalflag
)
1757 const int fatalflag
;
1760 /* Convert an endpoint number into a process number.
1761 * Return nonzero if the process is alive with the corresponding
1762 * generation number, zero otherwise.
1764 * This function is called with file and line number by the
1765 * isokendpt_d macro if DEBUG_ENABLE_IPC_WARNINGS is defined,
1766 * otherwise without. This allows us to print the where the
1767 * conversion was attempted, making the errors verbose without
1768 * adding code for that at every call.
1770 * If fatalflag is nonzero, we must panic if the conversion doesn't
1773 *p
= _ENDPOINT_P(e
);
1775 if(isokprocn(*p
) && !isemptyn(*p
) && proc_addr(*p
)->p_endpoint
== e
)
1777 if(!ok
&& fatalflag
)
1778 panic("invalid endpoint: %d", e
);
1782 static void notify_scheduler(struct proc
*p
)
1784 message m_no_quantum
;
1787 assert(!proc_kernel_scheduler(p
));
1789 /* dequeue the process */
1790 RTS_SET(p
, RTS_NO_QUANTUM
);
1792 * Notify the process's scheduler that it has run out of
1793 * quantum. This is done by sending a message to the scheduler
1794 * on the process's behalf
1796 m_no_quantum
.m_source
= p
->p_endpoint
;
1797 m_no_quantum
.m_type
= SCHEDULING_NO_QUANTUM
;
1798 m_no_quantum
.SCHEDULING_ACNT_QUEUE
= cpu_time_2_ms(p
->p_accounting
.time_in_queue
);
1799 m_no_quantum
.SCHEDULING_ACNT_DEQS
= p
->p_accounting
.dequeues
;
1800 m_no_quantum
.SCHEDULING_ACNT_IPC_SYNC
= p
->p_accounting
.ipc_sync
;
1801 m_no_quantum
.SCHEDULING_ACNT_IPC_ASYNC
= p
->p_accounting
.ipc_async
;
1802 m_no_quantum
.SCHEDULING_ACNT_PREEMPT
= p
->p_accounting
.preempted
;
1803 m_no_quantum
.SCHEDULING_ACNT_CPU
= cpuid
;
1804 m_no_quantum
.SCHEDULING_ACNT_CPU_LOAD
= cpu_load();
1806 /* Reset accounting */
1807 reset_proc_accounting(p
);
1809 if ((err
= mini_send(p
, p
->p_scheduler
->p_endpoint
,
1810 &m_no_quantum
, FROM_KERNEL
))) {
1811 panic("WARNING: Scheduling: mini_send returned %d\n", err
);
1815 void proc_no_time(struct proc
* p
)
1817 if (!proc_kernel_scheduler(p
) && priv(p
)->s_flags
& PREEMPTIBLE
) {
1818 /* this dequeues the process */
1819 notify_scheduler(p
);
1823 * non-preemptible processes only need their quantum to
1824 * be renewed. In fact, they by pass scheduling
1826 p
->p_cpu_time_left
= ms_2_cpu_time(p
->p_quantum_size_ms
);
1828 RTS_SET(p
, RTS_PREEMPTED
);
1829 RTS_UNSET(p
, RTS_PREEMPTED
);
1834 void reset_proc_accounting(struct proc
*p
)
1836 p
->p_accounting
.preempted
= 0;
1837 p
->p_accounting
.ipc_sync
= 0;
1838 p
->p_accounting
.ipc_async
= 0;
1839 p
->p_accounting
.dequeues
= 0;
1840 make_zero64(p
->p_accounting
.time_in_queue
);
1841 make_zero64(p
->p_accounting
.enter_queue
);
1844 void copr_not_available_handler(void)
1847 struct proc
** local_fpu_owner
;
1849 * Disable the FPU exception (both for the kernel and for the process
1850 * once it's scheduled), and initialize or restore the FPU state.
1853 disable_fpu_exception();
1855 p
= get_cpulocal_var(proc_ptr
);
1857 /* if FPU is not owned by anyone, do not store anything */
1858 local_fpu_owner
= get_cpulocal_var_ptr(fpu_owner
);
1859 if (*local_fpu_owner
!= NULL
) {
1860 assert(*local_fpu_owner
!= p
);
1861 save_local_fpu(*local_fpu_owner
, FALSE
/*retain*/);
1865 * restore the current process' state and let it run again, do not
1868 if (restore_fpu(p
) != OK
) {
1869 /* Restoring FPU state failed. This is always the process's own
1870 * fault. Send a signal, and schedule another process instead.
1872 *local_fpu_owner
= NULL
; /* release FPU */
1873 cause_sig(proc_nr(p
), SIGFPE
);
1877 *local_fpu_owner
= p
;
1878 context_stop(proc_addr(KERNEL
));
1879 restore_user_context(p
);
1883 void release_fpu(struct proc
* p
) {
1884 struct proc
** fpu_owner_ptr
;
1886 fpu_owner_ptr
= get_cpu_var_ptr(p
->p_cpu
, fpu_owner
);
1888 if (*fpu_owner_ptr
== p
)
1889 *fpu_owner_ptr
= NULL
;