VMS/VMS_Implementations/VMS_impls/VMS__MC_shared

annotate VMS.c @ 206:a262abf4b8d5

brch file for new WestmereEx 4x10 HW Branch

author	Merten Sach <msach@mailbox.tu-berlin.de>
date	Fri, 17 Feb 2012 18:43:52 +0100
parents	de5e7c522f1f
children

rev	line source
Me@0	1 /*
Me@38	2 * Copyright 2010 OpenSourceStewardshipFoundation
Me@0	3 *
Me@0	4 * Licensed under BSD
Me@0	5 */
Me@0	6
Me@0	7 #include <stdio.h>
Me@0	8 #include <stdlib.h>
Me@50	9 #include <string.h>
Me@0	10 #include <malloc.h>
msach@76	11 #include <inttypes.h>
Me@50	12 #include <sys/time.h>
Me@0	13
Me@0	14 #include "VMS.h"
msach@77	15 #include "ProcrContext.h"
msach@201	16 #include "C_Libraries/Queue_impl/BlockingQueue.h"
msach@201	17 #include "C_Libraries/Histogram/Histogram.h"
Me@0	18
Me@0	19
Me@26	20 #define thdAttrs NULL
Me@26	21
Me@22	22 //===========================================================================
Me@22	23 void
Me@22	24 shutdownFn( void dummy, VirtProcr dummy2 );
Me@22	25
Me@31	26 SchedSlot **
Me@31	27 create_sched_slots();
Me@22	28
Me@28	29 void
Me@28	30 create_masterEnv();
Me@28	31
Me@28	32 void
Me@28	33 create_the_coreLoop_OS_threads();
Me@28	34
Me@50	35 MallocProlog *
Me@50	36 create_free_list();
Me@50	37
Me@53	38 void
Me@53	39 endOSThreadFn( void initData, VirtProcr animatingPr );
Me@50	40
Me@26	41 pthread_mutex_t suspendLock = PTHREAD_MUTEX_INITIALIZER;
Me@26	42 pthread_cond_t suspend_cond = PTHREAD_COND_INITIALIZER;
Me@26	43
Me@22	44 //===========================================================================
Me@22	45
Me@0	46 /*Setup has two phases:
Me@0	47 * 1) Semantic layer first calls init_VMS, which creates masterEnv, and puts
Me@8	48 * the master virt procr into the work-queue, ready for first "call"
Me@8	49 * 2) Semantic layer then does its own init, which creates the seed virt
Me@8	50 * procr inside the semantic layer, ready to schedule it when
Me@0	51 * asked by the first run of the masterLoop.
Me@0	52 *
Me@0	53 *This part is bit weird because VMS really wants to be "always there", and
Me@0	54 * have applications attach and detach.. for now, this VMS is part of
Me@0	55 * the app, so the VMS system starts up as part of running the app.
Me@0	56 *
Me@8	57 *The semantic layer is isolated from the VMS internals by making the
Me@8	58 * semantic layer do setup to a state that it's ready with its
Me@8	59 * initial virt procrs, ready to schedule them to slots when the masterLoop
Me@0	60 * asks. Without this pattern, the semantic layer's setup would
Me@8	61 * have to modify slots directly to assign the initial virt-procrs, and put
Me@31	62 * them into the readyToAnimateQ itself, breaking the isolation completely.
Me@0	63 *
Me@0	64 *
Me@8	65 *The semantic layer creates the initial virt procr(s), and adds its
Me@8	66 * own environment to masterEnv, and fills in the pointers to
Me@0	67 * the requestHandler and slaveScheduler plug-in functions
Me@8	68 */
Me@8	69
Me@8	70 /*This allocates VMS data structures, populates the master VMSProc,
Me@0	71 * and master environment, and returns the master environment to the semantic
Me@0	72 * layer.
Me@0	73 */
Me@8	74 void
Me@8	75 VMS__init()
Me@28	76 {
Me@28	77 create_masterEnv();
Me@28	78 create_the_coreLoop_OS_threads();
Me@28	79 }
Me@28	80
msach@71	81 #ifdef SEQUENTIAL
msach@71	82
Me@28	83 /*To initialize the sequential version, just don't create the threads
Me@28	84 */
Me@28	85 void
Me@28	86 VMS__init_Seq()
Me@28	87 {
Me@28	88 create_masterEnv();
Me@28	89 }
Me@28	90
msach@71	91 #endif
msach@71	92
Me@28	93 void
Me@28	94 create_masterEnv()
Me@31	95 { MasterEnv *masterEnv;
Me@55	96 VMSQueueStruc **readyToAnimateQs;
Me@31	97 int coreIdx;
Me@31	98 VirtProcr **masterVPs;
Me@31	99 SchedSlot ***allSchedSlots; //ptr to array of ptrs
Me@53	100
Me@53	101
Me@31	102 //Make the master env, which holds everything else
msach@173	103 posix_memalign((void*)&_VMSMasterEnv, CACHELINE_SIZE, sizeof(MasterEnv) );
msach@169	104 memset( _VMSMasterEnv, 0, sizeof(MasterEnv) );
Me@53	105
Me@53	106 //Very first thing put into the master env is the free-list, seeded
Me@53	107 // with a massive initial chunk of memory.
msach@201	108 //After this, all other mallocs are VMS_int__malloc.
msach@101	109 _VMSMasterEnv->freeLists = VMS_ext__create_free_list();
Me@53	110
Me@65	111
Me@65	112 //============================= MEASUREMENT STUFF ========================
Me@65	113 #ifdef MEAS__TIME_MALLOC
msach@162	114 _VMSMasterEnv->mallocTimeHist = makeFixedBinHistExt( 100, 0, 30,
msach@79	115 "malloc_time_hist");
msach@162	116 _VMSMasterEnv->freeTimeHist = makeFixedBinHistExt( 100, 0, 30,
msach@79	117 "free_time_hist");
Me@65	118 #endif
Me@68	119 #ifdef MEAS__TIME_PLUGIN
msach@162	120 _VMSMasterEnv->reqHdlrLowTimeHist = makeFixedBinHistExt( 100, 0, 200,
msach@79	121 "plugin_low_time_hist");
msach@162	122 _VMSMasterEnv->reqHdlrHighTimeHist = makeFixedBinHistExt( 100, 0, 200,
msach@79	123 "plugin_high_time_hist");
Me@68	124 #endif
Me@65	125 //========================================================================
Me@65	126
msach@201	127 //===================== Only VMS_int__malloc after this ====================
msach@69	128 masterEnv = (MasterEnv*)_VMSMasterEnv;
Me@31	129
Me@31	130 //Make a readyToAnimateQ for each core loop
msach@201	131 readyToAnimateQs = VMS_int__malloc( NUM_CORES * sizeof(VMSQueueStruc *) );
msach@201	132 masterVPs = VMS_int__malloc( NUM_CORES * sizeof(VirtProcr *) );
Me@0	133
Me@31	134 //One array for each core, 3 in array, core's masterVP scheds all
msach@201	135 allSchedSlots = VMS_int__malloc( NUM_CORES * sizeof(SchedSlot *) );
Me@0	136
Me@53	137 _VMSMasterEnv->numProcrsCreated = 0; //used by create procr
Me@31	138 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
Me@53	139 {
Me@55	140 readyToAnimateQs[ coreIdx ] = makeVMSQ();
Me@31	141
Me@50	142 //Q: should give masterVP core-specific info as its init data?
msach@76	143 masterVPs[ coreIdx ] = VMS__create_procr( (VirtProcrFnPtr)&masterLoop, (void*)masterEnv );
Me@31	144 masterVPs[ coreIdx ]->coreAnimatedBy = coreIdx;
Me@31	145 allSchedSlots[ coreIdx ] = create_sched_slots(); //makes for one core
msach@173	146 //_VMSMasterEnv->numMasterInARow[ coreIdx ] = 0; //moved to coreLoops stack, reason: avoid false sharing
Me@55	147 _VMSMasterEnv->workStealingGates[ coreIdx ] = NULL;
Me@31	148 }
Me@31	149 _VMSMasterEnv->readyToAnimateQs = readyToAnimateQs;
Me@31	150 _VMSMasterEnv->masterVPs = masterVPs;
msach@173	151 _VMSMasterEnv->masterLockUnion.masterLock = UNLOCKED;
Me@31	152 _VMSMasterEnv->allSchedSlots = allSchedSlots;
Me@55	153 _VMSMasterEnv->workStealingLock = UNLOCKED;
Me@28	154
Me@12	155
Me@31	156 //Aug 19, 2010: no longer need to place initial masterVP into queue
Me@31	157 // because coreLoop now controls -- animates its masterVP when no work
Me@31	158
Me@30	159
Me@50	160 //============================= MEASUREMENT STUFF ========================
Me@50	161 #ifdef STATS__TURN_ON_PROBES
Me@50	162 _VMSMasterEnv->dynIntervalProbesInfo =
msach@69	163 makePrivDynArrayOfSize( (void***)&(_VMSMasterEnv->intervalProbes), 200);
Me@30	164
msach@201	165 _VMSMasterEnv->probeNameHashTbl = makeHashTable( 1000, &VMS_int__free );
Me@53	166
Me@53	167 //put creation time directly into master env, for fast retrieval
Me@50	168 struct timeval timeStamp;
Me@50	169 gettimeofday( &(timeStamp), NULL);
Me@50	170 _VMSMasterEnv->createPtInSecs =
Me@50	171 timeStamp.tv_sec +(timeStamp.tv_usec/1000000.0);
Me@50	172 #endif
Me@65	173 #ifdef MEAS__TIME_MASTER_LOCK
Me@65	174 _VMSMasterEnv->masterLockLowTimeHist = makeFixedBinHist( 50, 0, 2,
Me@65	175 "master lock low time hist");
Me@68	176 _VMSMasterEnv->masterLockHighTimeHist = makeFixedBinHist( 50, 0, 100,
Me@65	177 "master lock high time hist");
Me@65	178 #endif
Me@68	179
msach@76	180 MakeTheMeasHists();
Me@50	181 //========================================================================
Me@38	182
Me@0	183 }
Me@0	184
Me@31	185 SchedSlot **
Me@31	186 create_sched_slots()
Me@31	187 { SchedSlot **schedSlots;
Me@0	188 int i;
Me@0	189
msach@201	190 //schedSlots = VMS_int__malloc( NUM_SCHED_SLOTS * sizeof(SchedSlot *) );
msach@174	191 posix_memalign(&schedSlots, CACHELINE_SIZE, NUM_SCHED_SLOTS * sizeof(SchedSlot *));
Me@8	192
Me@1	193 for( i = 0; i < NUM_SCHED_SLOTS; i++ )
Me@0	194 {
msach@201	195 //schedSlots[i] = VMS_int__malloc( sizeof(SchedSlot) );
msach@175	196 posix_memalign(&schedSlots[i], CACHELINE_SIZE, CACHELINE_SIZE );
Me@8	197
Me@1	198 //Set state to mean "handling requests done, slot needs filling"
Me@8	199 schedSlots[i]->workIsDone = FALSE;
Me@8	200 schedSlots[i]->needsProcrAssigned = TRUE;
Me@0	201 }
Me@31	202 return schedSlots;
Me@31	203 }
Me@31	204
Me@31	205
Me@31	206 void
Me@31	207 freeSchedSlots( SchedSlot **schedSlots )
Me@31	208 { int i;
Me@31	209 for( i = 0; i < NUM_SCHED_SLOTS; i++ )
Me@31	210 {
msach@201	211 VMS_int__free( schedSlots[i] );
Me@31	212 }
msach@201	213 VMS_int__free( schedSlots );
Me@0	214 }
Me@0	215
Me@8	216
Me@28	217 void
Me@28	218 create_the_coreLoop_OS_threads()
Me@28	219 {
Me@28	220 //========================================================================
Me@28	221 // Create the Threads
Me@28	222 int coreIdx, retCode;
Me@28	223
Me@28	224 //Need the threads to be created suspended, and wait for a signal
Me@28	225 // before proceeding -- gives time after creating to initialize other
Me@28	226 // stuff before the coreLoops set off.
Me@28	227 _VMSMasterEnv->setupComplete = 0;
Me@28	228
Me@28	229 //Make the threads that animate the core loops
Me@28	230 for( coreIdx=0; coreIdx < NUM_CORES; coreIdx++ )
msach@201	231 { coreLoopThdParams[coreIdx] = VMS_int__malloc( sizeof(ThdParams) );
Me@28	232 coreLoopThdParams[coreIdx]->coreNum = coreIdx;
Me@28	233
Me@28	234 retCode =
Me@28	235 pthread_create( &(coreLoopThdHandles[coreIdx]),
Me@28	236 thdAttrs,
Me@28	237 &coreLoop,
Me@28	238 (void *)(coreLoopThdParams[coreIdx]) );
Me@50	239 if(retCode){printf("ERROR creating thread: %d\n", retCode); exit(1);}
Me@28	240 }
Me@28	241 }
Me@28	242
Me@0	243 /*Semantic layer calls this when it want the system to start running..
Me@0	244 *
Me@24	245 *This starts the core loops running then waits for them to exit.
Me@0	246 */
Me@12	247 void
Me@24	248 VMS__start_the_work_then_wait_until_done()
Me@12	249 { int coreIdx;
Me@24	250 //Start the core loops running
Me@25	251
Me@25	252 //tell the core loop threads that setup is complete
Me@25	253 //get lock, to lock out any threads still starting up -- they'll see
Me@25	254 // that setupComplete is true before entering while loop, and so never
Me@25	255 // wait on the condition
Me@26	256 pthread_mutex_lock( &suspendLock );
Me@25	257 _VMSMasterEnv->setupComplete = 1;
Me@26	258 pthread_mutex_unlock( &suspendLock );
Me@26	259 pthread_cond_broadcast( &suspend_cond );
Me@25	260
Me@25	261
Me@24	262 //wait for all to complete
Me@8	263 for( coreIdx=0; coreIdx < NUM_CORES; coreIdx++ )
Me@8	264 {
Me@25	265 pthread_join( coreLoopThdHandles[coreIdx], NULL );
Me@24	266 }
Me@25	267
Me@24	268 //NOTE: do not clean up VMS env here -- semantic layer has to have
Me@24	269 // a chance to clean up its environment first, then do a call to free
Me@24	270 // the Master env and rest of VMS locations
Me@8	271 }
Me@0	272
msach@71	273 #ifdef SEQUENTIAL
Me@28	274 /*Only difference between version with an OS thread pinned to each core and
Me@28	275 * the sequential version of VMS is VMS__init_Seq, this, and coreLoop_Seq.
Me@28	276 */
Me@28	277 void
Me@28	278 VMS__start_the_work_then_wait_until_done_Seq()
Me@28	279 {
Me@28	280 //Instead of un-suspending threads, just call the one and only
Me@28	281 // core loop (sequential version), in the main thread.
Me@28	282 coreLoop_Seq( NULL );
msach@75	283 flushRegisters();
Me@28	284
Me@28	285 }
msach@71	286 #endif
Me@0	287
Me@50	288 inline VirtProcr *
Me@50	289 VMS__create_procr( VirtProcrFnPtr fnPtr, void *initialData )
Me@50	290 { VirtProcr *newPr;
msach@76	291 void *stackLocs;
Me@50	292
msach@173	293 posix_memalign((void*)&newPr, CACHELINE_SIZE, sizeof(VirtProcr) ); //align to cacheline
msach@173	294 posix_memalign(&stackLocs, CACHELINE_SIZE, VIRT_PROCR_STACK_SIZE ); //align to cacheline
Me@50	295 if( stackLocs == 0 )
msach@201	296 { perror("VMS_int__malloc stack"); exit(1); }
Me@50	297
Me@50	298 return create_procr_helper( newPr, fnPtr, initialData, stackLocs );
Me@50	299 }
Me@50	300
Me@50	301 /* "ext" designates that it's for use outside the VMS system -- should only
Me@50	302 * be called from main thread or other thread -- never from code animated by
Me@50	303 * a VMS virtual processor.
Me@50	304 */
Me@50	305 inline VirtProcr *
Me@50	306 VMS_ext__create_procr( VirtProcrFnPtr fnPtr, void *initialData )
Me@50	307 { VirtProcr *newPr;
Me@50	308 char *stackLocs;
Me@50	309
Me@50	310 newPr = malloc( sizeof(VirtProcr) );
Me@50	311 stackLocs = malloc( VIRT_PROCR_STACK_SIZE );
Me@50	312 if( stackLocs == 0 )
Me@50	313 { perror("malloc stack"); exit(1); }
Me@50	314
Me@50	315 return create_procr_helper( newPr, fnPtr, initialData, stackLocs );
Me@50	316 }
Me@50	317
Me@8	318
Me@64	319 /*Anticipating multi-tasking
Me@64	320 */
Me@64	321 void *
Me@64	322 VMS__give_sem_env_for( VirtProcr *animPr )
Me@64	323 {
Me@64	324 return _VMSMasterEnv->semanticEnv;
Me@64	325 }
Me@64	326 //===========================================================================
Me@26	327 /*there is a label inside this function -- save the addr of this label in
Me@0	328 * the callingPr struc, as the pick-up point from which to start the next
Me@0	329 * work-unit for that procr. If turns out have to save registers, then
Me@0	330 * save them in the procr struc too. Then do assembly jump to the CoreLoop's
Me@0	331 * "done with work-unit" label. The procr struc is in the request in the
Me@0	332 * slave that animated the just-ended work-unit, so all the state is saved
Me@0	333 * there, and will get passed along, inside the request handler, to the
Me@0	334 * next work-unit for that procr.
Me@0	335 */
Me@8	336 void
Me@38	337 VMS__suspend_procr( VirtProcr *animatingPr )
Me@55	338 {
Me@0	339
Me@14	340 //The request to master will cause this suspended virt procr to get
Me@14	341 // scheduled again at some future point -- to resume, core loop jumps
Me@14	342 // to the resume point (below), which causes restore of saved regs and
Me@14	343 // "return" from this call.
msach@71	344 //animatingPr->nextInstrPt = &&ResumePt;
Me@1	345
Me@1	346 //return ownership of the virt procr and sched slot to Master virt pr
Me@38	347 animatingPr->schedSlot->workIsDone = TRUE;
Me@1	348
Me@41	349 //=========================== Measurement stuff ========================
Me@38	350 #ifdef MEAS__TIME_STAMP_SUSP
Me@41	351 //record time stamp: compare to time-stamp recorded below
Me@38	352 saveLowTimeStampCountInto( animatingPr->preSuspTSCLow );
Me@38	353 #endif
Me@41	354 //=======================================================================
Me@38	355
msach@71	356 switchToCoreLoop(animatingPr);
msach@71	357 flushRegisters();
Me@55	358
Me@55	359 //=======================================================================
msach@71	360
Me@38	361 #ifdef MEAS__TIME_STAMP_SUSP
Me@41	362 //NOTE: only take low part of count -- do sanity check when take diff
Me@38	363 saveLowTimeStampCountInto( animatingPr->postSuspTSCLow );
Me@38	364 #endif
Me@38	365
Me@0	366 return;
Me@0	367 }
Me@0	368
Me@22	369
Me@22	370
Me@50	371 /*For this implementation of VMS, it may not make much sense to have the
Me@50	372 * system of requests for creating a new processor done this way.. but over
Me@50	373 * the scope of single-master, multi-master, mult-tasking, OS-implementing,
Me@50	374 * distributed-memory, and so on, this gives VMS implementation a chance to
Me@50	375 * do stuff before suspend, in the AppVP, and in the Master before the plugin
Me@50	376 * is called, as well as in the lang-lib before this is called, and in the
Me@50	377 * plugin. So, this gives both VMS and language implementations a chance to
Me@50	378 * intercept at various points and do order-dependent stuff.
Me@50	379 *Having a standard VMSNewPrReqData struc allows the language to create and
Me@50	380 * free the struc, while VMS knows how to get the newPr if it wants it, and
Me@50	381 * it lets the lang have lang-specific data related to creation transported
Me@50	382 * to the plugin.
Me@50	383 */
Me@50	384 void
Me@50	385 VMS__send_create_procr_req( void semReqData, VirtProcr reqstingPr )
Me@50	386 { VMSReqst req;
Me@50	387
Me@50	388 req.reqType = createReq;
Me@50	389 req.semReqData = semReqData;
Me@50	390 req.nextReqst = reqstingPr->requests;
Me@50	391 reqstingPr->requests = &req;
Me@50	392
Me@50	393 VMS__suspend_procr( reqstingPr );
Me@50	394 }
Me@50	395
Me@22	396
Me@38	397 /*
Me@22	398 *This adds a request to dissipate, then suspends the processor so that the
Me@22	399 * request handler will receive the request. The request handler is what
Me@22	400 * does the work of freeing memory and removing the processor from the
Me@22	401 * semantic environment's data structures.
Me@22	402 *The request handler also is what figures out when to shutdown the VMS
Me@22	403 * system -- which causes all the core loop threads to die, and returns from
Me@22	404 * the call that started up VMS to perform the work.
Me@22	405 *
Me@22	406 *This form is a bit misleading to understand if one is trying to figure out
Me@22	407 * how VMS works -- it looks like a normal function call, but inside it
Me@22	408 * sends a request to the request handler and suspends the processor, which
Me@22	409 * jumps out of the VMS__dissipate_procr function, and out of all nestings
Me@22	410 * above it, transferring the work of dissipating to the request handler,
Me@22	411 * which then does the actual work -- causing the processor that animated
Me@22	412 * the call of this function to disappear and the "hanging" state of this
Me@22	413 * function to just poof into thin air -- the virtual processor's trace
Me@22	414 * never returns from this call, but instead the virtual processor's trace
Me@22	415 * gets suspended in this call and all the virt processor's state disap-
Me@22	416 * pears -- making that suspend the last thing in the virt procr's trace.
Me@8	417 */
Me@8	418 void
Me@53	419 VMS__send_dissipate_req( VirtProcr *procrToDissipate )
Me@50	420 { VMSReqst req;
Me@22	421
Me@50	422 req.reqType = dissipate;
Me@50	423 req.nextReqst = procrToDissipate->requests;
Me@50	424 procrToDissipate->requests = &req;
Me@50	425
Me@22	426 VMS__suspend_procr( procrToDissipate );
Me@50	427 }
Me@50	428
Me@50	429
Me@50	430 /* "ext" designates that it's for use outside the VMS system -- should only
Me@50	431 * be called from main thread or other thread -- never from code animated by
Me@50	432 * a VMS virtual processor.
Me@50	433 *
Me@50	434 *Use this version to dissipate VPs created outside the VMS system.
Me@50	435 */
Me@50	436 void
Me@50	437 VMS_ext__dissipate_procr( VirtProcr *procrToDissipate )
Me@50	438 {
Me@50	439 //NOTE: initialData was given to the processor, so should either have
msach@201	440 // been alloc'd with VMS_int__malloc, or freed by the level above animPr.
Me@50	441 //So, all that's left to free here is the stack and the VirtProcr struc
Me@50	442 // itself
Me@50	443 //Note, should not stack-allocate initial data -- no guarantee, in
Me@50	444 // general that creating processor will outlive ones it creates.
Me@50	445 free( procrToDissipate->startOfStack );
Me@50	446 free( procrToDissipate );
Me@50	447 }
Me@50	448
Me@22	449
Me@22	450
Me@53	451 /*This call's name indicates that request is malloc'd -- so req handler
Me@53	452 * has to free any extra requests tacked on before a send, using this.
Me@53	453 *
Me@53	454 * This inserts the semantic-layer's request data into standard VMS carrier
Me@53	455 * request data-struct that is mallocd. The sem request doesn't need to
Me@53	456 * be malloc'd if this is called inside the same call chain before the
Me@53	457 * send of the last request is called.
Me@53	458 *
msach@201	459 *The request handler has to call VMS_int__free_VMSReq for any of these
Me@22	460 */
Me@22	461 inline void
Me@53	462 VMS__add_sem_request_in_mallocd_VMSReqst( void *semReqData,
Me@53	463 VirtProcr *callingPr )
Me@53	464 { VMSReqst *req;
Me@22	465
msach@201	466 req = VMS_int__malloc( sizeof(VMSReqst) );
Me@53	467 req->reqType = semantic;
Me@53	468 req->semReqData = semReqData;
Me@53	469 req->nextReqst = callingPr->requests;
Me@53	470 callingPr->requests = req;
Me@22	471 }
Me@22	472
Me@50	473 /*This inserts the semantic-layer's request data into standard VMS carrier
Me@50	474 * request data-struct is allocated on stack of this call & ptr to it sent
Me@50	475 * to plugin
Me@50	476 *Then it does suspend, to cause request to be sent.
Me@50	477 */
Me@50	478 inline void
Me@50	479 VMS__send_sem_request( void semReqData, VirtProcr callingPr )
Me@50	480 { VMSReqst req;
Me@22	481
Me@50	482 req.reqType = semantic;
Me@50	483 req.semReqData = semReqData;
Me@50	484 req.nextReqst = callingPr->requests;
Me@50	485 callingPr->requests = &req;
Me@50	486
Me@50	487 VMS__suspend_procr( callingPr );
Me@50	488 }
Me@50	489
Me@50	490
Me@50	491 inline void
Me@50	492 VMS__send_VMSSem_request( void semReqData, VirtProcr callingPr )
Me@50	493 { VMSReqst req;
Me@50	494
Me@50	495 req.reqType = VMSSemantic;
Me@50	496 req.semReqData = semReqData;
Me@50	497 req.nextReqst = callingPr->requests; //gab any other preceeding
Me@50	498 callingPr->requests = &req;
Me@50	499
Me@50	500 VMS__suspend_procr( callingPr );
Me@50	501 }
Me@50	502
Me@50	503
Me@50	504 /*
Me@38	505 */
Me@24	506 VMSReqst *
Me@50	507 VMS__take_next_request_out_of( VirtProcr *procrWithReq )
Me@31	508 { VMSReqst *req;
Me@31	509
Me@31	510 req = procrWithReq->requests;
Me@38	511 if( req == NULL ) return NULL;
Me@31	512
Me@31	513 procrWithReq->requests = procrWithReq->requests->nextReqst;
Me@50	514 return req;
Me@24	515 }
Me@22	516
Me@24	517
Me@24	518 inline void *
Me@24	519 VMS__take_sem_reqst_from( VMSReqst *req )
Me@24	520 {
Me@24	521 return req->semReqData;
Me@24	522 }
Me@24	523
Me@24	524
Me@24	525
Me@50	526 /* This is for OS requests and VMS infrastructure requests, such as to create
Me@50	527 * a probe -- a probe is inside the heart of VMS-core, it's not part of any
Me@50	528 * language -- but it's also a semantic thing that's triggered from and used
Me@50	529 * in the application.. so it crosses abstractions.. so, need some special
Me@50	530 * pattern here for handling such requests.
Me@52	531 * Doing this just like it were a second language sharing VMS-core.
Me@52	532 *
Me@50	533 * This is called from the language's request handler when it sees a request
Me@50	534 * of type VMSSemReq
Me@52	535 *
Me@52	536 * TODO: Later change this, to give probes their own separate plugin & have
Me@52	537 * VMS-core steer the request to appropriate plugin
Me@52	538 * Do the same for OS calls -- look later at it..
Me@50	539 */
Me@50	540 void inline
Me@50	541 VMS__handle_VMSSemReq( VMSReqst req, VirtProcr requestingPr, void *semEnv,
Me@50	542 ResumePrFnPtr resumePrFnPtr )
Me@50	543 { VMSSemReq *semReq;
Me@50	544 IntervalProbe *newProbe;
Me@24	545
Me@50	546 semReq = req->semReqData;
Me@24	547
msach@201	548 newProbe = VMS_int__malloc( sizeof(IntervalProbe) );
msach@201	549 newProbe->nameStr = VMS_int__strDup( semReq->nameStr );
Me@50	550 newProbe->hist = NULL;
Me@50	551 newProbe->schedChoiceWasRecorded = FALSE;
Me@53	552
Me@53	553 //This runs in masterVP, so no race-condition worries
Me@50	554 newProbe->probeID =
Me@50	555 addToDynArray( newProbe, _VMSMasterEnv->dynIntervalProbesInfo );
Me@50	556
Me@53	557 requestingPr->dataRetFromReq = newProbe;
Me@50	558
Me@50	559 (*resumePrFnPtr)( requestingPr, semEnv );
Me@22	560 }
Me@22	561
Me@22	562
Me@22	563
Me@24	564 /*This must be called by the request handler plugin -- it cannot be called
Me@24	565 * from the semantic library "dissipate processor" function -- instead, the
Me@50	566 * semantic layer has to generate a request, and the plug-in calls this
Me@24	567 * function.
Me@24	568 *The reason is that this frees the virtual processor's stack -- which is
Me@24	569 * still in use inside semantic library calls!
Me@24	570 *
Me@24	571 *This frees or recycles all the state owned by and comprising the VMS
Me@24	572 * portion of the animating virtual procr. The request handler must first
Me@24	573 * free any semantic data created for the processor that didn't use the
Me@24	574 * VMS_malloc mechanism. Then it calls this, which first asks the malloc
Me@24	575 * system to disown any state that did use VMS_malloc, and then frees the
Me@24	576 * statck and the processor-struct itself.
msach@201	577 *If the dissipated processor is the sole (remaining) owner of VMS_int__malloc'd
Me@24	578 * state, then that state gets freed (or sent to recycling) as a side-effect
Me@24	579 * of dis-owning it.
Me@24	580 */
Me@24	581 void
Me@53	582 VMS__dissipate_procr( VirtProcr *animatingPr )
Me@24	583 {
Me@24	584 //dis-own all locations owned by this processor, causing to be freed
Me@24	585 // any locations that it is (was) sole owner of
msach@201	586 //TODO: implement VMS_int__malloc system, including "give up ownership"
Me@24	587
Me@24	588
Me@24	589 //NOTE: initialData was given to the processor, so should either have
msach@201	590 // been alloc'd with VMS_int__malloc, or freed by the level above animPr.
Me@24	591 //So, all that's left to free here is the stack and the VirtProcr struc
Me@24	592 // itself
Me@50	593 //Note, should not stack-allocate initial data -- no guarantee, in
Me@50	594 // general that creating processor will outlive ones it creates.
msach@174	595 free( animatingPr->startOfStack );
msach@174	596 free( animatingPr );
Me@24	597 }
Me@24	598
Me@24	599
Me@53	600 //TODO: look at architecting cleanest separation between request handler
Me@29	601 // and master loop, for dissipate, create, shutdown, and other non-semantic
Me@29	602 // requests. Issue is chain: one removes requests from AppVP, one dispatches
Me@29	603 // on type of request, and one handles each type.. but some types require
Me@29	604 // action from both request handler and master loop -- maybe just give the
Me@29	605 // request handler calls like: VMS__handle_X_request_type
Me@24	606
Me@29	607
Me@29	608 /*This is called by the semantic layer's request handler when it decides its
Me@29	609 * time to shut down the VMS system. Calling this causes the core loop OS
Me@29	610 * threads to exit, which unblocks the entry-point function that started up
Me@29	611 * VMS, and allows it to grab the result and return to the original single-
Me@29	612 * threaded application.
Me@22	613 *
Me@29	614 *The _VMSMasterEnv is needed by this shut down function, so the create-seed-
Me@29	615 * and-wait function has to free a bunch of stuff after it detects the
Me@29	616 * threads have all died: the masterEnv, the thread-related locations,
Me@29	617 * masterVP any AppVPs that might still be allocated and sitting in the
Me@29	618 * semantic environment, or have been orphaned in the _VMSWorkQ.
Me@29	619 *
msach@201	620 *NOTE: the semantic plug-in is expected to use VMS_int__malloc to get all the
Me@29	621 * locations it needs, and give ownership to masterVP. Then, they will be
Me@53	622 * automatically freed.
Me@22	623 *
Me@29	624 *In here,create one core-loop shut-down processor for each core loop and put
Me@31	625 * them all directly into the readyToAnimateQ.
Me@29	626 *Note, this function can ONLY be called after the semantic environment no
Me@29	627 * longer cares if AppVPs get animated after the point this is called. In
Me@29	628 * other words, this can be used as an abort, or else it should only be
Me@29	629 * called when all AppVPs have finished dissipate requests -- only at that
Me@29	630 * point is it sure that all results have completed.
Me@22	631 */
Me@22	632 void
Me@53	633 VMS__shutdown()
Me@8	634 { int coreIdx;
Me@14	635 VirtProcr *shutDownPr;
Me@22	636
Me@29	637 //create the shutdown processors, one for each core loop -- put them
Me@31	638 // directly into the Q -- each core will die when gets one
Me@8	639 for( coreIdx=0; coreIdx < NUM_CORES; coreIdx++ )
Me@50	640 { //Note, this is running in the master
Me@29	641 shutDownPr = VMS__create_procr( &endOSThreadFn, NULL );
Me@55	642 writeVMSQ( shutDownPr, _VMSMasterEnv->readyToAnimateQs[coreIdx] );
Me@8	643 }
Me@22	644
Me@12	645 }
Me@12	646
Me@12	647
Me@29	648 /*Am trying to be cute, avoiding IF statement in coreLoop that checks for
Me@29	649 * a special shutdown procr. Ended up with extra-complex shutdown sequence.
Me@29	650 *This function has the sole purpose of setting the stack and framePtr
Me@29	651 * to the coreLoop's stack and framePtr.. it does that then jumps to the
Me@29	652 * core loop's shutdown point -- might be able to just call Pthread_exit
Me@30	653 * from here, but am going back to the pthread's stack and setting everything
Me@29	654 * up just as if it never jumped out, before calling pthread_exit.
Me@29	655 *The end-point of core loop will free the stack and so forth of the
Me@29	656 * processor that animates this function, (this fn is transfering the
Me@29	657 * animator of the AppVP that is in turn animating this function over
Me@29	658 * to core loop function -- note that this slices out a level of virtual
Me@29	659 * processors).
Me@29	660 */
Me@29	661 void
Me@29	662 endOSThreadFn( void initData, VirtProcr animatingPr )
msach@71	663 {
msach@75	664 #ifdef SEQUENTIAL
msach@75	665 asmTerminateCoreLoopSeq(animatingPr);
msach@75	666 #else
msach@71	667 asmTerminateCoreLoop(animatingPr);
msach@75	668 #endif
Me@29	669 }
Me@29	670
Me@29	671
Me@53	672 /*This is called from the startup & shutdown
Me@24	673 */
Me@24	674 void
Me@53	675 VMS__cleanup_at_end_of_shutdown()
Me@31	676 {
msach@78	677 //unused
msach@78	678 //VMSQueueStruc **readyToAnimateQs;
msach@78	679 //int coreIdx;
msach@78	680 //VirtProcr **masterVPs;
msach@78	681 //SchedSlot ***allSchedSlots; //ptr to array of ptrs
Me@31	682
Me@65	683 //Before getting rid of everything, print out any measurements made
msach@102	684 //forAllInDynArrayDo( _VMSMasterEnv->measHistsInfo, (DynArrayFnPtr)&printHist );
msach@102	685 //forAllInDynArrayDo( _VMSMasterEnv->measHistsInfo, (DynArrayFnPtr)&saveHistToFile);
Me@68	686 //forAllInDynArrayDo( _VMSMasterEnv->measHistsInfo, &freeHistExt );
msach@169	687 /*
Me@65	688 #ifdef MEAS__TIME_PLUGIN
Me@68	689 printHist( _VMSMasterEnv->reqHdlrLowTimeHist );
msach@84	690 saveHistToFile( _VMSMasterEnv->reqHdlrLowTimeHist );
Me@68	691 printHist( _VMSMasterEnv->reqHdlrHighTimeHist );
msach@79	692 saveHistToFile( _VMSMasterEnv->reqHdlrHighTimeHist );
Me@68	693 freeHistExt( _VMSMasterEnv->reqHdlrLowTimeHist );
Me@68	694 freeHistExt( _VMSMasterEnv->reqHdlrHighTimeHist );
Me@65	695 #endif
Me@65	696 #ifdef MEAS__TIME_MALLOC
Me@65	697 printHist( _VMSMasterEnv->mallocTimeHist );
msach@79	698 saveHistToFile( _VMSMasterEnv->mallocTimeHist );
Me@65	699 printHist( _VMSMasterEnv->freeTimeHist );
msach@79	700 saveHistToFile( _VMSMasterEnv->freeTimeHist );
Me@65	701 freeHistExt( _VMSMasterEnv->mallocTimeHist );
Me@65	702 freeHistExt( _VMSMasterEnv->freeTimeHist );
Me@65	703 #endif
Me@65	704 #ifdef MEAS__TIME_MASTER_LOCK
Me@65	705 printHist( _VMSMasterEnv->masterLockLowTimeHist );
Me@65	706 printHist( _VMSMasterEnv->masterLockHighTimeHist );
Me@65	707 #endif
Me@65	708 #ifdef MEAS__TIME_MASTER
Me@65	709 printHist( _VMSMasterEnv->pluginTimeHist );
Me@65	710 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
Me@65	711 {
Me@65	712 freeVMSQ( readyToAnimateQs[ coreIdx ] );
Me@65	713 //master VPs were created external to VMS, so use external free
Me@65	714 VMS__dissipate_procr( masterVPs[ coreIdx ] );
Me@65	715
Me@65	716 freeSchedSlots( allSchedSlots[ coreIdx ] );
Me@65	717 }
Me@65	718 #endif
msach@169	719 */
Me@65	720 #ifdef MEAS__TIME_STAMP_SUSP
Me@65	721 printHist( _VMSMasterEnv->pluginTimeHist );
Me@65	722 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
Me@65	723 {
Me@65	724 freeVMSQ( readyToAnimateQs[ coreIdx ] );
Me@65	725 //master VPs were created external to VMS, so use external free
Me@65	726 VMS__dissipate_procr( masterVPs[ coreIdx ] );
Me@65	727
Me@65	728 freeSchedSlots( allSchedSlots[ coreIdx ] );
Me@65	729 }
Me@65	730 #endif
Me@65	731
msach@201	732 //All the environment data has been allocated with VMS_int__malloc, so just
Me@53	733 // free its internal big-chunk and all inside it disappear.
Me@53	734 /*
Me@31	735 readyToAnimateQs = _VMSMasterEnv->readyToAnimateQs;
Me@31	736 masterVPs = _VMSMasterEnv->masterVPs;
Me@31	737 allSchedSlots = _VMSMasterEnv->allSchedSlots;
Me@31	738
Me@31	739 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
Me@24	740 {
Me@55	741 freeVMSQ( readyToAnimateQs[ coreIdx ] );
Me@50	742 //master VPs were created external to VMS, so use external free
Me@53	743 VMS__dissipate_procr( masterVPs[ coreIdx ] );
Me@31	744
Me@31	745 freeSchedSlots( allSchedSlots[ coreIdx ] );
Me@24	746 }
Me@31	747
msach@201	748 VMS_int__free( _VMSMasterEnv->readyToAnimateQs );
msach@201	749 VMS_int__free( _VMSMasterEnv->masterVPs );
msach@201	750 VMS_int__free( _VMSMasterEnv->allSchedSlots );
Me@50	751
Me@50	752 //============================= MEASUREMENT STUFF ========================
Me@50	753 #ifdef STATS__TURN_ON_PROBES
msach@201	754 freeDynArrayDeep( _VMSMasterEnv->dynIntervalProbesInfo, &VMS_int__free_probe);
Me@50	755 #endif
Me@50	756 //========================================================================
Me@53	757 */
Me@53	758 //These are the only two that use system free
msach@101	759 VMS_ext__free_free_list( _VMSMasterEnv->freeLists );
Me@53	760 free( (void *)_VMSMasterEnv );
Me@24	761 }
Me@24	762
Me@54	763
Me@54	764 //================================
Me@54	765
Me@54	766
Me@54	767 /*Later, improve this -- for now, just exits the application after printing
Me@54	768 * the error message.
Me@54	769 */
Me@54	770 void
Me@54	771 VMS__throw_exception( char msgStr, VirtProcr reqstPr, VMSExcp *excpData )
Me@54	772 {
msach@69	773 printf("%s",msgStr);
Me@54	774 fflush(stdin);
Me@54	775 exit(1);
Me@54	776 }
Me@54	777
msach@169	778 //======================= Measurement =======================
msach@169	779 #ifdef MEAS__TIME_2011_SYS
msach@169	780 uint64
msach@169	781 VMS__give_num_plugin_cycles()
msach@169	782 { return _VMSMasterEnv->totalPluginCycles;
msach@169	783 }
msach@169	784
msach@169	785 uint32
msach@169	786 VMS__give_num_plugin_animations()
msach@169	787 { return _VMSMasterEnv->numPluginAnimations;
msach@169	788 }
msach@169	789 #endif

Mercurial > cgi-bin > hgwebdir.cgi > VMS > VMS_Implementations > VMS_impls > VMS__MC_shared_impl

annotate VMS.c @ 206:a262abf4b8d5