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/* ---------------------------------------------------------------------------
*
* (c) The GHC Team, 2010
*
* Inter-Capability message passing
*
* --------------------------------------------------------------------------*/
#include "Rts.h"
#include "Messages.h"
#include "Trace.h"
#include "Capability.h"
#include "Schedule.h"
#include "Threads.h"
#include "RaiseAsync.h"
#include "sm/Storage.h"
/* ----------------------------------------------------------------------------
Send a message to another Capability
------------------------------------------------------------------------- */
#ifdef THREADED_RTS
void sendMessage(Capability *from_cap, Capability *to_cap, Message *msg)
{
ACQUIRE_LOCK(&to_cap->lock);
#ifdef DEBUG
{
const StgInfoTable *i = msg->header.info;
if (i != &stg_MSG_THROWTO_info &&
i != &stg_MSG_BLACKHOLE_info &&
i != &stg_MSG_TRY_WAKEUP_info &&
i != &stg_IND_info && // can happen if a MSG_BLACKHOLE is revoked
i != &stg_WHITEHOLE_info) {
barf("sendMessage: %p", i);
}
}
#endif
msg->link = to_cap->inbox;
to_cap->inbox = msg;
recordClosureMutated(from_cap,(StgClosure*)msg);
if (to_cap->running_task == NULL) {
to_cap->running_task = myTask();
// precond for releaseCapability_()
releaseCapability_(to_cap,rtsFalse);
} else {
interruptCapability(to_cap);
}
RELEASE_LOCK(&to_cap->lock);
}
#endif /* THREADED_RTS */
/* ----------------------------------------------------------------------------
Handle a message
------------------------------------------------------------------------- */
#ifdef THREADED_RTS
void
executeMessage (Capability *cap, Message *m)
{
const StgInfoTable *i;
loop:
write_barrier(); // allow m->header to be modified by another thread
i = m->header.info;
if (i == &stg_MSG_TRY_WAKEUP_info)
{
StgTSO *tso = ((MessageWakeup *)m)->tso;
debugTraceCap(DEBUG_sched, cap, "message: try wakeup thread %ld",
(W_)tso->id);
tryWakeupThread(cap, tso);
}
else if (i == &stg_MSG_THROWTO_info)
{
MessageThrowTo *t = (MessageThrowTo *)m;
nat r;
const StgInfoTable *i;
i = lockClosure((StgClosure*)m);
if (i != &stg_MSG_THROWTO_info) {
unlockClosure((StgClosure*)m, i);
goto loop;
}
debugTraceCap(DEBUG_sched, cap, "message: throwTo %ld -> %ld",
(W_)t->source->id, (W_)t->target->id);
ASSERT(t->source->why_blocked == BlockedOnMsgThrowTo);
ASSERT(t->source->block_info.closure == (StgClosure *)m);
r = throwToMsg(cap, t);
switch (r) {
case THROWTO_SUCCESS: {
// this message is done
StgTSO *source = t->source;
doneWithMsgThrowTo(t);
tryWakeupThread(cap, source);
break;
}
case THROWTO_BLOCKED:
// unlock the message
unlockClosure((StgClosure*)m, &stg_MSG_THROWTO_info);
break;
}
}
else if (i == &stg_MSG_BLACKHOLE_info)
{
nat r;
MessageBlackHole *b = (MessageBlackHole*)m;
r = messageBlackHole(cap, b);
if (r == 0) {
tryWakeupThread(cap, b->tso);
}
return;
}
else if (i == &stg_IND_info || i == &stg_MSG_NULL_info)
{
// message was revoked
return;
}
else if (i == &stg_WHITEHOLE_info)
{
goto loop;
}
else
{
barf("executeMessage: %p", i);
}
}
#endif
/* ----------------------------------------------------------------------------
Handle a MSG_BLACKHOLE message
This is called from two places: either we just entered a BLACKHOLE
(stg_BLACKHOLE_info), or we received a MSG_BLACKHOLE in our
cap->inbox.
We need to establish whether the BLACKHOLE belongs to
this Capability, and
- if so, arrange to block the current thread on it
- otherwise, forward the message to the right place
Returns:
- 0 if the blocked thread can be woken up by the caller
- 1 if the thread is still blocked, and we promise to send a MSG_TRY_WAKEUP
at some point in the future.
------------------------------------------------------------------------- */
nat messageBlackHole(Capability *cap, MessageBlackHole *msg)
{
const StgInfoTable *info;
StgClosure *p;
StgBlockingQueue *bq;
StgClosure *bh = UNTAG_CLOSURE(msg->bh);
StgTSO *owner;
debugTraceCap(DEBUG_sched, cap, "message: thread %d blocking on "
"blackhole %p", (W_)msg->tso->id, msg->bh);
info = bh->header.info;
// If we got this message in our inbox, it might be that the
// BLACKHOLE has already been updated, and GC has shorted out the
// indirection, so the pointer no longer points to a BLACKHOLE at
// all.
if (info != &stg_BLACKHOLE_info &&
info != &stg_CAF_BLACKHOLE_info &&
info != &__stg_EAGER_BLACKHOLE_info &&
info != &stg_WHITEHOLE_info) {
// if it is a WHITEHOLE, then a thread is in the process of
// trying to BLACKHOLE it. But we know that it was once a
// BLACKHOLE, so there is at least a valid pointer in the
// payload, so we can carry on.
return 0;
}
// The blackhole must indirect to a TSO, a BLOCKING_QUEUE, an IND,
// or a value.
loop:
// NB. VOLATILE_LOAD(), because otherwise gcc hoists the load
// and turns this into an infinite loop.
p = UNTAG_CLOSURE((StgClosure*)VOLATILE_LOAD(&((StgInd*)bh)->indirectee));
info = p->header.info;
if (info == &stg_IND_info)
{
// This could happen, if e.g. we got a BLOCKING_QUEUE that has
// just been replaced with an IND by another thread in
// updateThunk(). In which case, if we read the indirectee
// again we should get the value.
goto loop;
}
else if (info == &stg_TSO_info)
{
owner = (StgTSO*)p;
#ifdef THREADED_RTS
if (owner->cap != cap) {
sendMessage(cap, owner->cap, (Message*)msg);
debugTraceCap(DEBUG_sched, cap, "forwarding message to cap %d",
owner->cap->no);
return 1;
}
#endif
// owner is the owner of the BLACKHOLE, and resides on this
// Capability. msg->tso is the first thread to block on this
// BLACKHOLE, so we first create a BLOCKING_QUEUE object.
bq = (StgBlockingQueue*)allocate(cap, sizeofW(StgBlockingQueue));
// initialise the BLOCKING_QUEUE object
SET_HDR(bq, &stg_BLOCKING_QUEUE_DIRTY_info, CCS_SYSTEM);
bq->bh = bh;
bq->queue = msg;
bq->owner = owner;
msg->link = (MessageBlackHole*)END_TSO_QUEUE;
// All BLOCKING_QUEUES are linked in a list on owner->bq, so
// that we can search through them in the event that there is
// a collision to update a BLACKHOLE and a BLOCKING_QUEUE
// becomes orphaned (see updateThunk()).
bq->link = owner->bq;
owner->bq = bq;
dirty_TSO(cap, owner); // we modified owner->bq
// If the owner of the blackhole is currently runnable, then
// bump it to the front of the run queue. This gives the
// blocked-on thread a little boost which should help unblock
// this thread, and may avoid a pile-up of other threads
// becoming blocked on the same BLACKHOLE (#3838).
//
// NB. we check to make sure that the owner is not the same as
// the current thread, since in that case it will not be on
// the run queue.
if (owner->why_blocked == NotBlocked && owner->id != msg->tso->id) {
promoteInRunQueue(cap, owner);
}
// point to the BLOCKING_QUEUE from the BLACKHOLE
write_barrier(); // make the BQ visible
((StgInd*)bh)->indirectee = (StgClosure *)bq;
recordClosureMutated(cap,bh); // bh was mutated
debugTraceCap(DEBUG_sched, cap, "thread %d blocked on thread %d",
(W_)msg->tso->id, (W_)owner->id);
return 1; // blocked
}
else if (info == &stg_BLOCKING_QUEUE_CLEAN_info ||
info == &stg_BLOCKING_QUEUE_DIRTY_info)
{
StgBlockingQueue *bq = (StgBlockingQueue *)p;
ASSERT(bq->bh == bh);
owner = bq->owner;
ASSERT(owner != END_TSO_QUEUE);
#ifdef THREADED_RTS
if (owner->cap != cap) {
sendMessage(cap, owner->cap, (Message*)msg);
debugTraceCap(DEBUG_sched, cap, "forwarding message to cap %d",
owner->cap->no);
return 1;
}
#endif
msg->link = bq->queue;
bq->queue = msg;
recordClosureMutated(cap,(StgClosure*)msg);
if (info == &stg_BLOCKING_QUEUE_CLEAN_info) {
bq->header.info = &stg_BLOCKING_QUEUE_DIRTY_info;
recordClosureMutated(cap,(StgClosure*)bq);
}
debugTraceCap(DEBUG_sched, cap, "thread %d blocked on thread %d",
(W_)msg->tso->id, (W_)owner->id);
// See above, #3838
if (owner->why_blocked == NotBlocked && owner->id != msg->tso->id) {
promoteInRunQueue(cap, owner);
}
return 1; // blocked
}
return 0; // not blocked
}
// A shorter version of messageBlackHole(), that just returns the
// owner (or NULL if the owner cannot be found, because the blackhole
// has been updated in the meantime).
StgTSO * blackHoleOwner (StgClosure *bh)
{
const StgInfoTable *info;
StgClosure *p;
info = bh->header.info;
if (info != &stg_BLACKHOLE_info &&
info != &stg_CAF_BLACKHOLE_info &&
info != &__stg_EAGER_BLACKHOLE_info &&
info != &stg_WHITEHOLE_info) {
return NULL;
}
// The blackhole must indirect to a TSO, a BLOCKING_QUEUE, an IND,
// or a value.
loop:
// NB. VOLATILE_LOAD(), because otherwise gcc hoists the load
// and turns this into an infinite loop.
p = UNTAG_CLOSURE((StgClosure*)VOLATILE_LOAD(&((StgInd*)bh)->indirectee));
info = p->header.info;
if (info == &stg_IND_info) goto loop;
else if (info == &stg_TSO_info)
{
return (StgTSO*)p;
}
else if (info == &stg_BLOCKING_QUEUE_CLEAN_info ||
info == &stg_BLOCKING_QUEUE_DIRTY_info)
{
StgBlockingQueue *bq = (StgBlockingQueue *)p;
return bq->owner;
}
return NULL; // not blocked
}
|