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annotate VSs.c @ 19:58a71af04cd1

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version for Tamer
author Nina Engelhardt <nengel@mailbox.tu-berlin.de>
date Mon, 17 Sep 2012 11:07:07 +0200
parents f83fff8bd4b2
children a7ca8f45c1c4
rev   line source
seanhalle@0 1 /*
seanhalle@0 2 * Copyright 2010 OpenSourceCodeStewardshipFoundation
seanhalle@0 3 *
seanhalle@0 4 * Licensed under BSD
seanhalle@0 5 */
seanhalle@0 6
seanhalle@0 7 #include <stdio.h>
seanhalle@0 8 #include <stdlib.h>
seanhalle@0 9 #include <malloc.h>
seanhalle@0 10
seanhalle@0 11 #include "Queue_impl/PrivateQueue.h"
seanhalle@0 12 #include "Hash_impl/PrivateHash.h"
seanhalle@0 13
seanhalle@2 14 #include "VSs.h"
seanhalle@3 15 #include "Measurement/VSs_Counter_Recording.h"
seanhalle@0 16
seanhalle@0 17 //==========================================================================
seanhalle@0 18
seanhalle@0 19 void
seanhalle@2 20 VSs__init();
seanhalle@0 21
seanhalle@0 22 void
seanhalle@2 23 VSs__init_Helper();
seanhalle@0 24 //==========================================================================
seanhalle@0 25
seanhalle@0 26
seanhalle@0 27
seanhalle@0 28 //===========================================================================
seanhalle@0 29
seanhalle@0 30
seanhalle@0 31 /*These are the library functions *called in the application*
seanhalle@0 32 *
seanhalle@0 33 *There's a pattern for the outside sequential code to interact with the
seanhalle@0 34 * VMS_HW code.
seanhalle@2 35 *The VMS_HW system is inside a boundary.. every VSs system is in its
seanhalle@0 36 * own directory that contains the functions for each of the processor types.
seanhalle@0 37 * One of the processor types is the "seed" processor that starts the
seanhalle@0 38 * cascade of creating all the processors that do the work.
seanhalle@0 39 *So, in the directory is a file called "EntryPoint.c" that contains the
seanhalle@0 40 * function, named appropriately to the work performed, that the outside
seanhalle@0 41 * sequential code calls. This function follows a pattern:
seanhalle@2 42 *1) it calls VSs__init()
seanhalle@0 43 *2) it creates the initial data for the seed processor, which is passed
seanhalle@0 44 * in to the function
seanhalle@2 45 *3) it creates the seed VSs processor, with the data to start it with.
seanhalle@2 46 *4) it calls startVSsThenWaitUntilWorkDone
seanhalle@0 47 *5) it gets the returnValue from the transfer struc and returns that
seanhalle@0 48 * from the function
seanhalle@0 49 *
seanhalle@2 50 *For now, a new VSs system has to be created via VSs__init every
seanhalle@0 51 * time an entry point function is called -- later, might add letting the
seanhalle@2 52 * VSs system be created once, and let all the entry points just reuse
seanhalle@0 53 * it -- want to be as simple as possible now, and see by using what makes
seanhalle@0 54 * sense for later..
seanhalle@0 55 */
seanhalle@0 56
seanhalle@0 57
seanhalle@0 58
seanhalle@0 59 //===========================================================================
seanhalle@0 60
seanhalle@0 61 /*This is the "border crossing" function -- the thing that crosses from the
seanhalle@0 62 * outside world, into the VMS_HW world. It initializes and starts up the
seanhalle@0 63 * VMS system, then creates one processor from the specified function and
seanhalle@0 64 * puts it into the readyQ. From that point, that one function is resp.
seanhalle@0 65 * for creating all the other processors, that then create others, and so
seanhalle@0 66 * forth.
seanhalle@0 67 *When all the processors, including the seed, have dissipated, then this
seanhalle@0 68 * function returns. The results will have been written by side-effect via
seanhalle@0 69 * pointers read from, or written into initData.
seanhalle@0 70 *
seanhalle@0 71 *NOTE: no Threads should exist in the outside program that might touch
seanhalle@0 72 * any of the data reachable from initData passed in to here
seanhalle@0 73 */
seanhalle@0 74 void
seanhalle@2 75 VSs__create_seed_slave_and_do_work( TopLevelFnPtr fnPtr, void *initData )
seanhalle@6 76 { VSsSemEnv *semEnv;
seanhalle@6 77 SlaveVP *seedSlv;
seanhalle@6 78 VSsSemData *semData;
seanhalle@8 79 VSsTaskStub *threadTaskStub, *parentTaskStub;
seanhalle@0 80
seanhalle@2 81 VSs__init(); //normal multi-thd
seanhalle@0 82
seanhalle@0 83 semEnv = _VMSMasterEnv->semanticEnv;
seanhalle@0 84
seanhalle@2 85 //VSs starts with one processor, which is put into initial environ,
seanhalle@0 86 // and which then calls create() to create more, thereby expanding work
seanhalle@3 87 seedSlv = VSs__create_slave_helper( fnPtr, initData,
seanhalle@6 88 semEnv, semEnv->nextCoreToGetNewSlv++ );
seanhalle@3 89
seanhalle@8 90 //seed slave is a thread slave, so make a thread's task stub for it
seanhalle@8 91 // and then make another to stand for the seed's parent task. Make
seanhalle@8 92 // the parent be already ended, and have one child (the seed). This
seanhalle@8 93 // will make the dissipate handler do the right thing when the seed
seanhalle@8 94 // is dissipated.
seanhalle@8 95 threadTaskStub = create_thread_task_stub( initData );
seanhalle@8 96 parentTaskStub = create_thread_task_stub( NULL );
seanhalle@8 97 parentTaskStub->isEnded = TRUE;
seanhalle@8 98 parentTaskStub->numLiveChildThreads = 1; //so dissipate works for seed
nengel@11 99 threadTaskStub->parentTaskStub = parentTaskStub;
nengel@16 100 threadTaskStub->slaveAssignedTo = seedSlv;
nengel@16 101
seanhalle@6 102 semData = (VSsSemData *)seedSlv->semanticData;
seanhalle@8 103 //seedVP is a thread, so has a permanent task
seanhalle@6 104 semData->needsTaskAssigned = FALSE;
seanhalle@8 105 semData->taskStub = threadTaskStub;
nengel@13 106 semData->slaveType = ThreadSlv;
seanhalle@0 107
seanhalle@6 108 resume_slaveVP( seedSlv, semEnv ); //returns right away, just queues Slv
seanhalle@0 109
seanhalle@0 110 VMS_SS__start_the_work_then_wait_until_done(); //normal multi-thd
seanhalle@0 111
seanhalle@2 112 VSs__cleanup_after_shutdown();
seanhalle@0 113 }
seanhalle@0 114
seanhalle@0 115
seanhalle@0 116 int32
seanhalle@2 117 VSs__giveMinWorkUnitCycles( float32 percentOverhead )
seanhalle@0 118 {
seanhalle@0 119 return MIN_WORK_UNIT_CYCLES;
seanhalle@0 120 }
seanhalle@0 121
seanhalle@0 122 int32
seanhalle@2 123 VSs__giveIdealNumWorkUnits()
seanhalle@0 124 {
seanhalle@0 125 return NUM_ANIM_SLOTS * NUM_CORES;
seanhalle@0 126 }
seanhalle@0 127
seanhalle@0 128 int32
seanhalle@2 129 VSs__give_number_of_cores_to_schedule_onto()
seanhalle@0 130 {
seanhalle@0 131 return NUM_CORES;
seanhalle@0 132 }
seanhalle@0 133
seanhalle@0 134 /*For now, use TSC -- later, make these two macros with assembly that first
seanhalle@0 135 * saves jump point, and second jumps back several times to get reliable time
seanhalle@0 136 */
seanhalle@0 137 void
seanhalle@2 138 VSs__start_primitive()
seanhalle@2 139 { saveLowTimeStampCountInto( ((VSsSemEnv *)(_VMSMasterEnv->semanticEnv))->
seanhalle@0 140 primitiveStartTime );
seanhalle@0 141 }
seanhalle@0 142
seanhalle@0 143 /*Just quick and dirty for now -- make reliable later
seanhalle@0 144 * will want this to jump back several times -- to be sure cache is warm
seanhalle@0 145 * because don't want comm time included in calc-time measurement -- and
seanhalle@0 146 * also to throw out any "weird" values due to OS interrupt or TSC rollover
seanhalle@0 147 */
seanhalle@0 148 int32
seanhalle@2 149 VSs__end_primitive_and_give_cycles()
seanhalle@0 150 { int32 endTime, startTime;
seanhalle@0 151 //TODO: fix by repeating time-measurement
seanhalle@0 152 saveLowTimeStampCountInto( endTime );
seanhalle@2 153 startTime =((VSsSemEnv*)(_VMSMasterEnv->semanticEnv))->primitiveStartTime;
seanhalle@0 154 return (endTime - startTime);
seanhalle@0 155 }
seanhalle@0 156
seanhalle@0 157 //===========================================================================
seanhalle@0 158
seanhalle@2 159 /*Initializes all the data-structures for a VSs system -- but doesn't
seanhalle@0 160 * start it running yet!
seanhalle@0 161 *
seanhalle@0 162 *This runs in the main thread -- before VMS starts up
seanhalle@0 163 *
seanhalle@0 164 *This sets up the semantic layer over the VMS system
seanhalle@0 165 *
seanhalle@0 166 *First, calls VMS_Setup, then creates own environment, making it ready
seanhalle@0 167 * for creating the seed processor and then starting the work.
seanhalle@0 168 */
seanhalle@0 169 void
seanhalle@2 170 VSs__init()
seanhalle@0 171 {
seanhalle@0 172 VMS_SS__init();
seanhalle@0 173 //masterEnv, a global var, now is partially set up by init_VMS
seanhalle@0 174 // after this, have VMS_int__malloc and VMS_int__free available
seanhalle@0 175
seanhalle@2 176 VSs__init_Helper();
seanhalle@0 177 }
seanhalle@0 178
seanhalle@0 179
seanhalle@0 180 void idle_fn(void* data, SlaveVP *animatingSlv){
seanhalle@0 181 while(1){
seanhalle@0 182 VMS_int__suspend_slaveVP_and_send_req(animatingSlv);
seanhalle@0 183 }
seanhalle@0 184 }
seanhalle@0 185
seanhalle@0 186 void
seanhalle@2 187 VSs__init_Helper()
seanhalle@2 188 { VSsSemEnv *semanticEnv;
seanhalle@6 189 int32 i, coreNum, slotNum;
seanhalle@10 190 VSsSemData *semData;
seanhalle@0 191
seanhalle@0 192 //Hook up the semantic layer's plug-ins to the Master virt procr
seanhalle@2 193 _VMSMasterEnv->requestHandler = &VSs__Request_Handler;
seanhalle@2 194 _VMSMasterEnv->slaveAssigner = &VSs__assign_slaveVP_to_slot;
seanhalle@0 195
seanhalle@0 196 //create the semantic layer's environment (all its data) and add to
seanhalle@0 197 // the master environment
seanhalle@2 198 semanticEnv = VMS_int__malloc( sizeof( VSsSemEnv ) );
seanhalle@0 199 _VMSMasterEnv->semanticEnv = semanticEnv;
seanhalle@0 200
seanhalle@0 201 #ifdef HOLISTIC__TURN_ON_PERF_COUNTERS
seanhalle@15 202 _VMSMasterEnv->counterHandler = &VSs__counter_handler;
seanhalle@2 203 VSs__init_counter_data_structs();
seanhalle@0 204 #endif
seanhalle@3 205
seanhalle@0 206 semanticEnv->shutdownInitiated = FALSE;
seanhalle@3 207 semanticEnv->coreIsDone = VMS_int__malloc( NUM_CORES * sizeof( bool32 ) );
seanhalle@6 208 //For each animation slot, there is an idle slave, and an initial
seanhalle@6 209 // slave assigned as the current-task-slave. Create them here.
seanhalle@10 210 SlaveVP *idleSlv, *slotTaskSlv;
seanhalle@6 211 for( coreNum = 0; coreNum < NUM_CORES; coreNum++ )
seanhalle@6 212 { semanticEnv->coreIsDone[coreNum] = FALSE; //use during shutdown
seanhalle@6 213
seanhalle@6 214 for( slotNum = 0; slotNum < NUM_ANIM_SLOTS; ++slotNum )
seanhalle@10 215 { idleSlv = VSs__create_slave_helper( &idle_fn, NULL, semanticEnv, 0);
seanhalle@6 216 idleSlv->coreAnimatedBy = coreNum;
seanhalle@9 217 idleSlv->animSlotAssignedTo =
seanhalle@9 218 _VMSMasterEnv->allAnimSlots[coreNum][slotNum];
seanhalle@6 219 semanticEnv->idleSlv[coreNum][slotNum] = idleSlv;
seanhalle@6 220
seanhalle@10 221 slotTaskSlv = VSs__create_slave_helper( &idle_fn, NULL, semanticEnv, 0);
seanhalle@10 222 slotTaskSlv->coreAnimatedBy = coreNum;
seanhalle@10 223 slotTaskSlv->animSlotAssignedTo =
seanhalle@9 224 _VMSMasterEnv->allAnimSlots[coreNum][slotNum];
seanhalle@10 225
seanhalle@10 226 semData = slotTaskSlv->semanticData;
seanhalle@10 227 semData->needsTaskAssigned = TRUE;
seanhalle@10 228 semData->slaveType = SlotTaskSlv;
seanhalle@10 229 semanticEnv->slotTaskSlvs[coreNum][slotNum] = slotTaskSlv;
seanhalle@0 230 }
seanhalle@3 231 }
seanhalle@0 232
seanhalle@6 233 //create the ready queues, hash tables used for matching and so forth
seanhalle@6 234 semanticEnv->slavesReadyToResumeQ = makeVMSQ();
seanhalle@9 235 semanticEnv->freeExtraTaskSlvQ = makeVMSQ();
seanhalle@6 236 semanticEnv->taskReadyQ = makeVMSQ();
seanhalle@0 237
seanhalle@3 238 semanticEnv->argPtrHashTbl = makeHashTable32( 16, &VMS_int__free );
seanhalle@4 239 semanticEnv->commHashTbl = makeHashTable32( 16, &VMS_int__free );
seanhalle@6 240
seanhalle@6 241 semanticEnv->nextCoreToGetNewSlv = 0;
seanhalle@6 242
nengel@18 243 #ifdef EXTERNAL_SCHEDULER
nengel@18 244 VSs__init_ext_scheduler();
nengel@18 245 #endif
seanhalle@0 246 //TODO: bug -- turn these arrays into dyn arrays to eliminate limit
seanhalle@0 247 //semanticEnv->singletonHasBeenExecutedFlags = makeDynArrayInfo( );
seanhalle@0 248 //semanticEnv->transactionStrucs = makeDynArrayInfo( );
seanhalle@0 249 for( i = 0; i < NUM_STRUCS_IN_SEM_ENV; i++ )
seanhalle@0 250 {
seanhalle@0 251 semanticEnv->fnSingletons[i].endInstrAddr = NULL;
seanhalle@0 252 semanticEnv->fnSingletons[i].hasBeenStarted = FALSE;
seanhalle@0 253 semanticEnv->fnSingletons[i].hasFinished = FALSE;
seanhalle@0 254 semanticEnv->fnSingletons[i].waitQ = makeVMSQ();
seanhalle@0 255 semanticEnv->transactionStrucs[i].waitingVPQ = makeVMSQ();
seanhalle@0 256 }
seanhalle@6 257
seanhalle@8 258 semanticEnv->numLiveExtraTaskSlvs = 0; //must be last
seanhalle@15 259 semanticEnv->numLiveThreadSlvs = 1; //must be last, counts the seed
seanhalle@6 260
seanhalle@6 261 #ifdef HOLISTIC__TURN_ON_OBSERVE_UCC
seanhalle@6 262 semanticEnv->unitList = makeListOfArrays(sizeof(Unit),128);
seanhalle@6 263 semanticEnv->ctlDependenciesList = makeListOfArrays(sizeof(Dependency),128);
seanhalle@6 264 semanticEnv->commDependenciesList = makeListOfArrays(sizeof(Dependency),128);
seanhalle@6 265 semanticEnv->dynDependenciesList = makeListOfArrays(sizeof(Dependency),128);
nengel@16 266 semanticEnv->dataDependenciesList = makeListOfArrays(sizeof(Dependency),128);
nengel@16 267 semanticEnv->singletonDependenciesList = makeListOfArrays(sizeof(Dependency),128);
nengel@17 268 semanticEnv->warDependenciesList = makeListOfArrays(sizeof(Dependency),128);
seanhalle@6 269 semanticEnv->ntonGroupsInfo = makePrivDynArrayOfSize((void***)&(semanticEnv->ntonGroups),8);
seanhalle@6 270
seanhalle@6 271 semanticEnv->hwArcs = makeListOfArrays(sizeof(Dependency),128);
seanhalle@6 272 memset(semanticEnv->last_in_slot,0,sizeof(NUM_CORES * NUM_ANIM_SLOTS * sizeof(Unit)));
seanhalle@6 273 #endif
seanhalle@0 274 }
seanhalle@0 275
seanhalle@0 276
seanhalle@2 277 /*Frees any memory allocated by VSs__init() then calls VMS_int__shutdown
seanhalle@0 278 */
seanhalle@0 279 void
seanhalle@2 280 VSs__cleanup_after_shutdown()
seanhalle@2 281 { VSsSemEnv *semanticEnv;
seanhalle@0 282
seanhalle@0 283 semanticEnv = _VMSMasterEnv->semanticEnv;
seanhalle@0 284 FILE* output;
seanhalle@0 285 int n;
nengel@18 286 char filename[255];
nengel@18 287 #ifdef HOLISTIC__TURN_ON_OBSERVE_UCC
nengel@18 288 //UCC
seanhalle@0 289 for(n=0;n<255;n++)
seanhalle@0 290 {
seanhalle@0 291 sprintf(filename, "./counters/UCC.%d",n);
seanhalle@0 292 output = fopen(filename,"r");
seanhalle@0 293 if(output)
seanhalle@0 294 {
seanhalle@0 295 fclose(output);
seanhalle@0 296 }else{
seanhalle@0 297 break;
seanhalle@0 298 }
seanhalle@0 299 }
seanhalle@0 300 if(n<255){
seanhalle@0 301 printf("Saving UCC to File: %s ...\n", filename);
seanhalle@0 302 output = fopen(filename,"w+");
seanhalle@0 303 if(output!=NULL){
seanhalle@0 304 set_dependency_file(output);
seanhalle@0 305 //fprintf(output,"digraph Dependencies {\n");
seanhalle@0 306 //set_dot_file(output);
seanhalle@0 307 //FIXME: first line still depends on counters being enabled, replace w/ unit struct!
seanhalle@0 308 //forAllInDynArrayDo(_VMSMasterEnv->counter_history_array_info, &print_dot_node_info );
seanhalle@0 309 forAllInListOfArraysDo(semanticEnv->unitList, &print_unit_to_file);
seanhalle@0 310 forAllInListOfArraysDo( semanticEnv->commDependenciesList, &print_comm_dependency_to_file );
seanhalle@0 311 forAllInListOfArraysDo( semanticEnv->ctlDependenciesList, &print_ctl_dependency_to_file );
nengel@16 312 forAllInListOfArraysDo( semanticEnv->dataDependenciesList, &print_data_dependency_to_file );
nengel@16 313 forAllInListOfArraysDo( semanticEnv->singletonDependenciesList, &print_singleton_dependency_to_file );
nengel@17 314 forAllInListOfArraysDo( semanticEnv->warDependenciesList, &print_war_dependency_to_file );
seanhalle@0 315 forAllInDynArrayDo(semanticEnv->ntonGroupsInfo,&print_nton_to_file);
seanhalle@0 316 //fprintf(output,"}\n");
seanhalle@0 317 fflush(output);
seanhalle@0 318
seanhalle@0 319 } else
seanhalle@0 320 printf("Opening UCC file failed. Please check that folder \"counters\" exists in run directory and has write permission.\n");
seanhalle@0 321 } else {
seanhalle@0 322 printf("Could not open UCC file, please clean \"counters\" folder. (Must contain less than 255 files.)\n");
seanhalle@0 323 }
seanhalle@0 324 //Loop Graph
seanhalle@0 325 for(n=0;n<255;n++)
seanhalle@0 326 {
seanhalle@0 327 sprintf(filename, "./counters/LoopGraph.%d",n);
seanhalle@0 328 output = fopen(filename,"r");
seanhalle@0 329 if(output)
seanhalle@0 330 {
seanhalle@0 331 fclose(output);
seanhalle@0 332 }else{
seanhalle@0 333 break;
seanhalle@0 334 }
seanhalle@0 335 }
seanhalle@0 336 if(n<255){
seanhalle@0 337 printf("Saving LoopGraph to File: %s ...\n", filename);
seanhalle@0 338 output = fopen(filename,"w+");
seanhalle@0 339 if(output!=NULL){
seanhalle@0 340 set_dependency_file(output);
seanhalle@0 341 //fprintf(output,"digraph Dependencies {\n");
seanhalle@0 342 //set_dot_file(output);
seanhalle@0 343 //FIXME: first line still depends on counters being enabled, replace w/ unit struct!
seanhalle@0 344 //forAllInDynArrayDo(_VMSMasterEnv->counter_history_array_info, &print_dot_node_info );
seanhalle@0 345 forAllInListOfArraysDo( semanticEnv->unitList, &print_unit_to_file );
seanhalle@0 346 forAllInListOfArraysDo( semanticEnv->commDependenciesList, &print_comm_dependency_to_file );
seanhalle@0 347 forAllInListOfArraysDo( semanticEnv->ctlDependenciesList, &print_ctl_dependency_to_file );
nengel@16 348 forAllInListOfArraysDo( semanticEnv->dataDependenciesList, &print_data_dependency_to_file );
nengel@16 349 forAllInListOfArraysDo( semanticEnv->singletonDependenciesList, &print_singleton_dependency_to_file );
seanhalle@0 350 forAllInListOfArraysDo( semanticEnv->dynDependenciesList, &print_dyn_dependency_to_file );
nengel@17 351 forAllInListOfArraysDo( semanticEnv->warDependenciesList, &print_war_dependency_to_file );
seanhalle@0 352 forAllInListOfArraysDo( semanticEnv->hwArcs, &print_hw_dependency_to_file );
seanhalle@0 353 //fprintf(output,"}\n");
seanhalle@0 354 fflush(output);
seanhalle@0 355
seanhalle@0 356 } else
seanhalle@0 357 printf("Opening LoopGraph file failed. Please check that folder \"counters\" exists in run directory and has write permission.\n");
seanhalle@0 358 } else {
seanhalle@0 359 printf("Could not open LoopGraph file, please clean \"counters\" folder. (Must contain less than 255 files.)\n");
seanhalle@0 360 }
seanhalle@0 361
seanhalle@0 362
seanhalle@0 363 freeListOfArrays(semanticEnv->unitList);
seanhalle@0 364 freeListOfArrays(semanticEnv->commDependenciesList);
seanhalle@0 365 freeListOfArrays(semanticEnv->ctlDependenciesList);
seanhalle@0 366 freeListOfArrays(semanticEnv->dynDependenciesList);
nengel@16 367 freeListOfArrays(semanticEnv->dataDependenciesList);
nengel@17 368 freeListOfArrays(semanticEnv->warDependenciesList);
nengel@17 369 freeListOfArrays(semanticEnv->singletonDependenciesList);
nengel@17 370 freeListOfArrays(semanticEnv->hwArcs);
seanhalle@0 371
seanhalle@0 372 #endif
seanhalle@0 373 #ifdef HOLISTIC__TURN_ON_PERF_COUNTERS
seanhalle@0 374 for(n=0;n<255;n++)
seanhalle@0 375 {
seanhalle@0 376 sprintf(filename, "./counters/Counters.%d.csv",n);
seanhalle@0 377 output = fopen(filename,"r");
seanhalle@0 378 if(output)
seanhalle@0 379 {
seanhalle@0 380 fclose(output);
seanhalle@0 381 }else{
seanhalle@0 382 break;
seanhalle@0 383 }
seanhalle@0 384 }
seanhalle@0 385 if(n<255){
seanhalle@0 386 printf("Saving Counter measurements to File: %s ...\n", filename);
seanhalle@0 387 output = fopen(filename,"w+");
seanhalle@0 388 if(output!=NULL){
seanhalle@0 389 set_counter_file(output);
seanhalle@0 390 int i;
seanhalle@0 391 for(i=0;i<NUM_CORES;i++){
seanhalle@0 392 forAllInListOfArraysDo( semanticEnv->counterList[i], &print_counter_events_to_file );
seanhalle@0 393 fflush(output);
seanhalle@0 394 }
seanhalle@0 395
seanhalle@0 396 } else
seanhalle@0 397 printf("Opening UCC file failed. Please check that folder \"counters\" exists in run directory and has write permission.\n");
seanhalle@0 398 } else {
seanhalle@0 399 printf("Could not open UCC file, please clean \"counters\" folder. (Must contain less than 255 files.)\n");
seanhalle@0 400 }
seanhalle@0 401
seanhalle@0 402 #endif
seanhalle@0 403 /* It's all allocated inside VMS's big chunk -- that's about to be freed, so
seanhalle@0 404 * nothing to do here
seanhalle@0 405
seanhalle@0 406
seanhalle@0 407 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
seanhalle@0 408 {
seanhalle@0 409 VMS_int__free( semanticEnv->readyVPQs[coreIdx]->startOfData );
seanhalle@0 410 VMS_int__free( semanticEnv->readyVPQs[coreIdx] );
seanhalle@0 411 }
seanhalle@0 412 VMS_int__free( semanticEnv->readyVPQs );
seanhalle@0 413
seanhalle@0 414 freeHashTable( semanticEnv->commHashTbl );
seanhalle@0 415 VMS_int__free( _VMSMasterEnv->semanticEnv );
seanhalle@0 416 */
seanhalle@0 417 VMS_SS__cleanup_at_end_of_shutdown();
seanhalle@0 418 }
seanhalle@0 419
seanhalle@0 420
seanhalle@0 421 //===========================================================================
seanhalle@0 422
seanhalle@2 423 SlaveVP *
seanhalle@7 424 VSs__create_thread( TopLevelFnPtr fnPtr, void *initData,
seanhalle@7 425 SlaveVP *creatingThd )
seanhalle@2 426 { VSsSemReq reqData;
seanhalle@0 427
seanhalle@0 428 //the semantic request data is on the stack and disappears when this
seanhalle@0 429 // call returns -- it's guaranteed to remain in the VP's stack for as
seanhalle@0 430 // long as the VP is suspended.
seanhalle@0 431 reqData.reqType = 0; //know type because in a VMS create req
seanhalle@0 432 reqData.fnPtr = fnPtr;
seanhalle@0 433 reqData.initData = initData;
seanhalle@7 434 reqData.callingSlv = creatingThd;
seanhalle@0 435
seanhalle@7 436 VMS_WL__send_create_slaveVP_req( &reqData, creatingThd );
seanhalle@0 437
seanhalle@7 438 return creatingThd->dataRetFromReq;
seanhalle@0 439 }
seanhalle@0 440
seanhalle@10 441 /*This is always the last thing done in the code animated by a thread VP.
seanhalle@7 442 * Normally, this would be the last line of the thread's top level function.
seanhalle@7 443 * But, if the thread exits from any point, it has to do so by calling
seanhalle@7 444 * this.
seanhalle@10 445 *
seanhalle@10 446 *It simply sends a dissipate request, which handles all the state cleanup.
seanhalle@7 447 */
seanhalle@2 448 void
seanhalle@7 449 VSs__end_thread( SlaveVP *thdToEnd )
seanhalle@8 450 { VSsSemData *semData;
seanhalle@8 451
seanhalle@7 452 VMS_WL__send_dissipate_req( thdToEnd );
seanhalle@0 453 }
seanhalle@0 454
seanhalle@0 455
seanhalle@10 456
seanhalle@0 457 //===========================================================================
seanhalle@0 458
seanhalle@0 459
seanhalle@4 460 //======================= task submit and end ==============================
seanhalle@4 461 /*
seanhalle@2 462 */
seanhalle@4 463 void
seanhalle@2 464 VSs__submit_task( VSsTaskType *taskType, void *args, SlaveVP *animSlv)
seanhalle@2 465 { VSsSemReq reqData;
seanhalle@0 466
seanhalle@2 467 reqData.reqType = submit_task;
seanhalle@4 468
seanhalle@2 469 reqData.taskType = taskType;
seanhalle@2 470 reqData.args = args;
seanhalle@4 471 reqData.callingSlv = animSlv;
seanhalle@2 472
seanhalle@4 473 reqData.taskID = NULL;
seanhalle@2 474
seanhalle@2 475 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 476 }
seanhalle@0 477
seanhalle@4 478 inline int32 *
seanhalle@4 479 VSs__create_taskID_of_size( int32 numInts, SlaveVP *animSlv )
seanhalle@4 480 { int32 *taskID;
seanhalle@4 481
seanhalle@4 482 taskID = VMS_WL__malloc( sizeof(int32) + numInts * sizeof(int32) );
seanhalle@4 483 taskID[0] = numInts;
seanhalle@4 484 return taskID;
seanhalle@4 485 }
seanhalle@4 486
seanhalle@4 487 void
seanhalle@4 488 VSs__submit_task_with_ID( VSsTaskType *taskType, void *args, int32 *taskID,
seanhalle@4 489 SlaveVP *animSlv)
seanhalle@4 490 { VSsSemReq reqData;
seanhalle@4 491
seanhalle@4 492 reqData.reqType = submit_task;
seanhalle@4 493
seanhalle@4 494 reqData.taskType = taskType;
seanhalle@4 495 reqData.args = args;
seanhalle@4 496 reqData.taskID = taskID;
seanhalle@4 497 reqData.callingSlv = animSlv;
seanhalle@4 498
seanhalle@4 499 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@4 500 }
seanhalle@4 501
seanhalle@4 502
seanhalle@4 503 /*This call is the last to happen in every task. It causes the slave to
seanhalle@2 504 * suspend and get the next task out of the task-queue. Notice there is no
seanhalle@2 505 * assigner here.. only one slave, no slave ReadyQ, and so on..
seanhalle@2 506 *Can either make the assigner take the next task out of the taskQ, or can
seanhalle@2 507 * leave all as it is, and make task-end take the next task.
seanhalle@2 508 *Note: this fits the case in the new VMS for no-context tasks, so will use
seanhalle@2 509 * the built-in taskQ of new VMS, and should be local and much faster.
seanhalle@2 510 *
seanhalle@2 511 *The task-stub is saved in the animSlv, so the request handler will get it
seanhalle@2 512 * from there, along with the task-type which has arg types, and so on..
seanhalle@4 513 *
seanhalle@4 514 * NOTE: if want, don't need to send the animating SlaveVP around..
seanhalle@4 515 * instead, can make a single slave per core, and coreCtrlr looks up the
seanhalle@4 516 * slave from having the core number.
seanhalle@4 517 *
seanhalle@4 518 *But, to stay compatible with all the other VMS languages, leave it in..
seanhalle@0 519 */
seanhalle@0 520 void
seanhalle@2 521 VSs__end_task( SlaveVP *animSlv )
seanhalle@2 522 { VSsSemReq reqData;
seanhalle@0 523
seanhalle@2 524 reqData.reqType = end_task;
seanhalle@2 525 reqData.callingSlv = animSlv;
seanhalle@2 526
seanhalle@2 527 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 528 }
seanhalle@0 529
seanhalle@4 530
nengel@5 531 void
nengel@5 532 VSs__taskwait(SlaveVP *animSlv)
nengel@5 533 {
nengel@5 534 VSsSemReq reqData;
nengel@5 535
nengel@5 536 reqData.reqType = taskwait;
nengel@5 537 reqData.callingSlv = animSlv;
nengel@5 538
nengel@5 539 VMS_WL__send_sem_request( &reqData, animSlv );
nengel@5 540 }
nengel@5 541
nengel@5 542
nengel@5 543
seanhalle@4 544 //========================== send and receive ============================
seanhalle@4 545 //
seanhalle@4 546
seanhalle@4 547 inline int32 *
seanhalle@4 548 VSs__give_self_taskID( SlaveVP *animSlv )
seanhalle@4 549 {
seanhalle@4 550 return ((VSsSemData*)animSlv->semanticData)->taskStub->taskID;
seanhalle@4 551 }
seanhalle@4 552
seanhalle@4 553 //================================ send ===================================
seanhalle@4 554
seanhalle@4 555 void
seanhalle@4 556 VSs__send_of_type_to( void *msg, const int32 type, int32 *receiverID,
seanhalle@4 557 SlaveVP *senderSlv )
seanhalle@4 558 { VSsSemReq reqData;
seanhalle@4 559
seanhalle@4 560 reqData.reqType = send_type_to;
seanhalle@4 561
seanhalle@4 562 reqData.msg = msg;
seanhalle@4 563 reqData.msgType = type;
seanhalle@4 564 reqData.receiverID = receiverID;
seanhalle@4 565 reqData.senderSlv = senderSlv;
seanhalle@4 566
seanhalle@4 567 reqData.nextReqInHashEntry = NULL;
seanhalle@4 568
seanhalle@4 569 VMS_WL__send_sem_request( &reqData, senderSlv );
seanhalle@4 570
seanhalle@4 571 //When come back from suspend, no longer own data reachable from msg
seanhalle@4 572 }
seanhalle@4 573
seanhalle@4 574 void
seanhalle@4 575 VSs__send_from_to( void *msg, int32 *senderID, int32 *receiverID, SlaveVP *senderSlv )
seanhalle@4 576 { VSsSemReq reqData;
seanhalle@4 577
seanhalle@4 578 reqData.reqType = send_from_to;
seanhalle@4 579
seanhalle@4 580 reqData.msg = msg;
seanhalle@4 581 reqData.senderID = senderID;
seanhalle@4 582 reqData.receiverID = receiverID;
seanhalle@4 583 reqData.senderSlv = senderSlv;
seanhalle@4 584
seanhalle@4 585 reqData.nextReqInHashEntry = NULL;
seanhalle@4 586
seanhalle@4 587 VMS_WL__send_sem_request( &reqData, senderSlv );
seanhalle@4 588 }
seanhalle@4 589
seanhalle@4 590
seanhalle@4 591 //================================ receive ================================
seanhalle@4 592
seanhalle@4 593 /*The "type" version of send and receive creates a many-to-one relationship.
seanhalle@4 594 * The sender is anonymous, and many sends can stack up, waiting to be
seanhalle@4 595 * received. The same receiver can also have send from-to's
seanhalle@4 596 * waiting for it, and those will be kept separate from the "type"
seanhalle@4 597 * messages.
seanhalle@4 598 */
seanhalle@4 599 void *
seanhalle@4 600 VSs__receive_type_to( const int32 type, int32* receiverID, SlaveVP *receiverSlv )
seanhalle@4 601 { DEBUG__printf1(dbgRqstHdlr,"WL: receive type to %d",receiverID[1] );
seanhalle@4 602 VSsSemReq reqData;
seanhalle@4 603
seanhalle@4 604 reqData.reqType = receive_type_to;
seanhalle@4 605
seanhalle@4 606 reqData.msgType = type;
seanhalle@4 607 reqData.receiverID = receiverID;
seanhalle@4 608 reqData.receiverSlv = receiverSlv;
seanhalle@4 609
seanhalle@4 610 reqData.nextReqInHashEntry = NULL;
seanhalle@4 611
seanhalle@4 612 VMS_WL__send_sem_request( &reqData, receiverSlv );
seanhalle@4 613
seanhalle@4 614 return receiverSlv->dataRetFromReq;
seanhalle@4 615 }
seanhalle@4 616
seanhalle@4 617
seanhalle@4 618
seanhalle@4 619 /*Call this at the point a receiving task wants in-coming data.
seanhalle@4 620 * Use this from-to form when know senderID -- it makes a direct channel
seanhalle@4 621 * between sender and receiver.
seanhalle@4 622 */
seanhalle@4 623 void *
seanhalle@4 624 VSs__receive_from_to( int32 *senderID, int32 *receiverID, SlaveVP *receiverSlv )
seanhalle@4 625 {
seanhalle@4 626 VSsSemReq reqData;
seanhalle@4 627
seanhalle@4 628 reqData.reqType = receive_from_to;
seanhalle@4 629
seanhalle@4 630 reqData.senderID = senderID;
seanhalle@4 631 reqData.receiverID = receiverID;
seanhalle@4 632 reqData.receiverSlv = receiverSlv;
seanhalle@4 633
seanhalle@4 634 reqData.nextReqInHashEntry = NULL;
seanhalle@4 635 DEBUG__printf2(dbgRqstHdlr,"WL: receive from %d to: %d", reqData.senderID[1], reqData.receiverID[1]);
seanhalle@4 636
seanhalle@4 637 VMS_WL__send_sem_request( &reqData, receiverSlv );
seanhalle@4 638
seanhalle@4 639 return receiverSlv->dataRetFromReq;
seanhalle@4 640 }
seanhalle@4 641
seanhalle@4 642
seanhalle@4 643
seanhalle@4 644
seanhalle@2 645 //==========================================================================
seanhalle@0 646 //
seanhalle@0 647 /*A function singleton is a function whose body executes exactly once, on a
seanhalle@0 648 * single core, no matter how many times the fuction is called and no
seanhalle@0 649 * matter how many cores or the timing of cores calling it.
seanhalle@0 650 *
seanhalle@0 651 *A data singleton is a ticket attached to data. That ticket can be used
seanhalle@0 652 * to get the data through the function exactly once, no matter how many
seanhalle@0 653 * times the data is given to the function, and no matter the timing of
seanhalle@0 654 * trying to get the data through from different cores.
seanhalle@0 655 */
seanhalle@0 656
seanhalle@0 657 /*asm function declarations*/
seanhalle@2 658 void asm_save_ret_to_singleton(VSsSingleton *singletonPtrAddr);
seanhalle@2 659 void asm_write_ret_from_singleton(VSsSingleton *singletonPtrAddr);
seanhalle@0 660
seanhalle@0 661 /*Fn singleton uses ID as index into array of singleton structs held in the
seanhalle@0 662 * semantic environment.
seanhalle@0 663 */
seanhalle@0 664 void
seanhalle@3 665 VSs__start_fn_singleton( int32 singletonID, SlaveVP *animSlv )
seanhalle@0 666 {
seanhalle@2 667 VSsSemReq reqData;
seanhalle@0 668
seanhalle@0 669 //
seanhalle@0 670 reqData.reqType = singleton_fn_start;
seanhalle@0 671 reqData.singletonID = singletonID;
seanhalle@0 672
seanhalle@3 673 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@3 674 if( animSlv->dataRetFromReq ) //will be 0 or addr of label in end singleton
seanhalle@0 675 {
seanhalle@3 676 VSsSemEnv *semEnv = VMS_int__give_sem_env_for( animSlv );
seanhalle@0 677 asm_write_ret_from_singleton(&(semEnv->fnSingletons[ singletonID]));
seanhalle@0 678 }
seanhalle@0 679 }
seanhalle@0 680
seanhalle@0 681 /*Data singleton hands addr of loc holding a pointer to a singleton struct.
seanhalle@0 682 * The start_data_singleton makes the structure and puts its addr into the
seanhalle@0 683 * location.
seanhalle@0 684 */
seanhalle@0 685 void
seanhalle@3 686 VSs__start_data_singleton( VSsSingleton **singletonAddr, SlaveVP *animSlv )
seanhalle@0 687 {
seanhalle@2 688 VSsSemReq reqData;
seanhalle@0 689
seanhalle@0 690 if( *singletonAddr && (*singletonAddr)->hasFinished )
seanhalle@0 691 goto JmpToEndSingleton;
seanhalle@0 692
seanhalle@0 693 reqData.reqType = singleton_data_start;
seanhalle@0 694 reqData.singletonPtrAddr = singletonAddr;
seanhalle@0 695
seanhalle@3 696 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@3 697 if( animSlv->dataRetFromReq ) //either 0 or end singleton's return addr
seanhalle@0 698 { //Assembly code changes the return addr on the stack to the one
seanhalle@0 699 // saved into the singleton by the end-singleton-fn
seanhalle@0 700 //The return addr is at 0x4(%%ebp)
seanhalle@0 701 JmpToEndSingleton:
seanhalle@0 702 asm_write_ret_from_singleton(*singletonAddr);
seanhalle@0 703 }
seanhalle@0 704 //now, simply return
seanhalle@0 705 //will exit either from the start singleton call or the end-singleton call
seanhalle@0 706 }
seanhalle@0 707
seanhalle@0 708 /*Uses ID as index into array of flags. If flag already set, resumes from
seanhalle@0 709 * end-label. Else, sets flag and resumes normally.
seanhalle@0 710 *
seanhalle@0 711 *Note, this call cannot be inlined because the instr addr at the label
seanhalle@0 712 * inside is shared by all invocations of a given singleton ID.
seanhalle@0 713 */
seanhalle@0 714 void
seanhalle@3 715 VSs__end_fn_singleton( int32 singletonID, SlaveVP *animSlv )
seanhalle@0 716 {
seanhalle@2 717 VSsSemReq reqData;
seanhalle@0 718
seanhalle@0 719 //don't need this addr until after at least one singleton has reached
seanhalle@0 720 // this function
seanhalle@3 721 VSsSemEnv *semEnv = VMS_int__give_sem_env_for( animSlv );
seanhalle@0 722 asm_write_ret_from_singleton(&(semEnv->fnSingletons[ singletonID]));
seanhalle@0 723
seanhalle@0 724 reqData.reqType = singleton_fn_end;
seanhalle@0 725 reqData.singletonID = singletonID;
seanhalle@0 726
seanhalle@3 727 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 728
seanhalle@0 729 EndSingletonInstrAddr:
seanhalle@0 730 return;
seanhalle@0 731 }
seanhalle@0 732
seanhalle@0 733 void
seanhalle@3 734 VSs__end_data_singleton( VSsSingleton **singletonPtrAddr, SlaveVP *animSlv )
seanhalle@0 735 {
seanhalle@2 736 VSsSemReq reqData;
seanhalle@0 737
seanhalle@0 738 //don't need this addr until after singleton struct has reached
seanhalle@0 739 // this function for first time
seanhalle@0 740 //do assembly that saves the return addr of this fn call into the
seanhalle@0 741 // data singleton -- that data-singleton can only be given to exactly
seanhalle@0 742 // one instance in the code of this function. However, can use this
seanhalle@0 743 // function in different places for different data-singletons.
seanhalle@0 744 // (*(singletonAddr))->endInstrAddr = &&EndDataSingletonInstrAddr;
seanhalle@0 745
seanhalle@0 746
seanhalle@0 747 asm_save_ret_to_singleton(*singletonPtrAddr);
seanhalle@0 748
seanhalle@0 749 reqData.reqType = singleton_data_end;
seanhalle@0 750 reqData.singletonPtrAddr = singletonPtrAddr;
seanhalle@0 751
seanhalle@3 752 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 753 }
seanhalle@0 754
seanhalle@0 755 /*This executes the function in the masterVP, so it executes in isolation
seanhalle@0 756 * from any other copies -- only one copy of the function can ever execute
seanhalle@0 757 * at a time.
seanhalle@0 758 *
seanhalle@0 759 *It suspends to the master, and the request handler takes the function
seanhalle@0 760 * pointer out of the request and calls it, then resumes the VP.
seanhalle@0 761 *Only very short functions should be called this way -- for longer-running
seanhalle@0 762 * isolation, use transaction-start and transaction-end, which run the code
seanhalle@0 763 * between as work-code.
seanhalle@0 764 */
seanhalle@0 765 void
seanhalle@2 766 VSs__animate_short_fn_in_isolation( PtrToAtomicFn ptrToFnToExecInMaster,
seanhalle@3 767 void *data, SlaveVP *animSlv )
seanhalle@0 768 {
seanhalle@2 769 VSsSemReq reqData;
seanhalle@0 770
seanhalle@0 771 //
seanhalle@0 772 reqData.reqType = atomic;
seanhalle@0 773 reqData.fnToExecInMaster = ptrToFnToExecInMaster;
seanhalle@0 774 reqData.dataForFn = data;
seanhalle@0 775
seanhalle@3 776 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 777 }
seanhalle@0 778
seanhalle@0 779
seanhalle@0 780 /*This suspends to the master.
seanhalle@0 781 *First, it looks at the VP's data, to see the highest transactionID that VP
seanhalle@0 782 * already has entered. If the current ID is not larger, it throws an
seanhalle@0 783 * exception stating a bug in the code. Otherwise it puts the current ID
seanhalle@0 784 * there, and adds the ID to a linked list of IDs entered -- the list is
seanhalle@0 785 * used to check that exits are properly ordered.
seanhalle@0 786 *Next it is uses transactionID as index into an array of transaction
seanhalle@0 787 * structures.
seanhalle@0 788 *If the "VP_currently_executing" field is non-null, then put requesting VP
seanhalle@0 789 * into queue in the struct. (At some point a holder will request
seanhalle@0 790 * end-transaction, which will take this VP from the queue and resume it.)
seanhalle@0 791 *If NULL, then write requesting into the field and resume.
seanhalle@0 792 */
seanhalle@0 793 void
seanhalle@3 794 VSs__start_transaction( int32 transactionID, SlaveVP *animSlv )
seanhalle@0 795 {
seanhalle@2 796 VSsSemReq reqData;
seanhalle@0 797
seanhalle@0 798 //
seanhalle@3 799 reqData.callingSlv = animSlv;
seanhalle@0 800 reqData.reqType = trans_start;
seanhalle@0 801 reqData.transID = transactionID;
seanhalle@0 802
seanhalle@3 803 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 804 }
seanhalle@0 805
seanhalle@0 806 /*This suspends to the master, then uses transactionID as index into an
seanhalle@0 807 * array of transaction structures.
seanhalle@0 808 *It looks at VP_currently_executing to be sure it's same as requesting VP.
seanhalle@0 809 * If different, throws an exception, stating there's a bug in the code.
seanhalle@0 810 *Next it looks at the queue in the structure.
seanhalle@0 811 *If it's empty, it sets VP_currently_executing field to NULL and resumes.
seanhalle@0 812 *If something in, gets it, sets VP_currently_executing to that VP, then
seanhalle@0 813 * resumes both.
seanhalle@0 814 */
seanhalle@0 815 void
seanhalle@3 816 VSs__end_transaction( int32 transactionID, SlaveVP *animSlv )
seanhalle@0 817 {
seanhalle@2 818 VSsSemReq reqData;
seanhalle@0 819
seanhalle@0 820 //
seanhalle@3 821 reqData.callingSlv = animSlv;
seanhalle@0 822 reqData.reqType = trans_end;
seanhalle@0 823 reqData.transID = transactionID;
seanhalle@0 824
seanhalle@3 825 VMS_WL__send_sem_request( &reqData, animSlv );
seanhalle@0 826 }
seanhalle@7 827
seanhalle@7 828 //======================== Internal ==================================
seanhalle@7 829 /*
seanhalle@7 830 */
seanhalle@7 831 SlaveVP *
seanhalle@7 832 VSs__create_slave_with( TopLevelFnPtr fnPtr, void *initData,
seanhalle@7 833 SlaveVP *creatingSlv )
seanhalle@7 834 { VSsSemReq reqData;
seanhalle@7 835
seanhalle@7 836 //the semantic request data is on the stack and disappears when this
seanhalle@7 837 // call returns -- it's guaranteed to remain in the VP's stack for as
seanhalle@7 838 // long as the VP is suspended.
seanhalle@7 839 reqData.reqType = 0; //know type because in a VMS create req
seanhalle@7 840 reqData.coreToAssignOnto = -1; //means round-robin assign
seanhalle@7 841 reqData.fnPtr = fnPtr;
seanhalle@7 842 reqData.initData = initData;
seanhalle@7 843 reqData.callingSlv = creatingSlv;
seanhalle@7 844
seanhalle@7 845 VMS_WL__send_create_slaveVP_req( &reqData, creatingSlv );
seanhalle@7 846
seanhalle@7 847 return creatingSlv->dataRetFromReq;
seanhalle@7 848 }
seanhalle@7 849
seanhalle@7 850 SlaveVP *
seanhalle@7 851 VSs__create_slave_with_affinity( TopLevelFnPtr fnPtr, void *initData,
seanhalle@7 852 SlaveVP *creatingSlv, int32 coreToAssignOnto )
seanhalle@7 853 { VSsSemReq reqData;
seanhalle@7 854
seanhalle@7 855 //the semantic request data is on the stack and disappears when this
seanhalle@7 856 // call returns -- it's guaranteed to remain in the VP's stack for as
seanhalle@7 857 // long as the VP is suspended.
seanhalle@7 858 reqData.reqType = create_slave_w_aff; //not used, May 2012
seanhalle@7 859 reqData.coreToAssignOnto = coreToAssignOnto;
seanhalle@7 860 reqData.fnPtr = fnPtr;
seanhalle@7 861 reqData.initData = initData;
seanhalle@7 862 reqData.callingSlv = creatingSlv;
seanhalle@7 863
seanhalle@7 864 VMS_WL__send_create_slaveVP_req( &reqData, creatingSlv );
seanhalle@7 865
seanhalle@7 866 return creatingSlv->dataRetFromReq;
seanhalle@7 867 }
seanhalle@7 868