VMS/VMS_Implementations/SSR_impls/SSR__MC_shared

annotate SSR.c @ 65:51b8f15fea29

New states for sub-repos, almost works, just bug in shutdown to fix still

author	Some Random Person <seanhalle@yahoo.com>
date	Wed, 14 Mar 2012 23:22:00 -0700
parents
children	ce95c4d84fcd b5b5323b4177

rev	line source
seanhalle@64	1 /*
seanhalle@64	2 * Copyright 2010 OpenSourceCodeStewardshipFoundation
seanhalle@64	3 *
seanhalle@64	4 * Licensed under BSD
seanhalle@64	5 */
seanhalle@64	6
seanhalle@64	7 #include <stdio.h>
seanhalle@64	8 #include <stdlib.h>
seanhalle@64	9 #include <malloc.h>
seanhalle@64	10
seanhalle@64	11 #include "Queue_impl/PrivateQueue.h"
seanhalle@64	12 #include "Hash_impl/PrivateHash.h"
seanhalle@64	13
seanhalle@64	14 #include "SSR.h"
seanhalle@64	15 #include "SSR_Counter_Recording.h"
seanhalle@64	16
seanhalle@64	17 //==========================================================================
seanhalle@64	18
seanhalle@64	19 void
seanhalle@64	20 SSR__init();
seanhalle@64	21
seanhalle@64	22 void
seanhalle@64	23 SSR__init_Helper();
seanhalle@64	24 //==========================================================================
seanhalle@64	25
seanhalle@64	26
seanhalle@64	27 /*TODO: Q: dealing with library f()s and DKU vs WT vs FoR
seanhalle@64	28 * (still want to do FoR, with time-lines as syntax, could be super cool)
seanhalle@64	29 * A: thinking pin the coreCtlrs for all of BLIS -- let Master arbitrate
seanhalle@64	30 * among library, DKU, WT, FoR -- all the patterns in terms of virtual
seanhalle@64	31 * processors (or equivalently work-units), so Master picks which virt procr
seanhalle@64	32 * from which portions of app (DKU, WT, FoR) onto which sched slots
seanhalle@64	33 *Might even do hierarchy of masters -- group of sched slots for each core
seanhalle@64	34 * has its own master, that keeps generated work local
seanhalle@64	35 * single-reader-single-writer sync everywhere -- no atomic primitives
seanhalle@64	36 * Might have the different assigners talk to each other, to negotiate
seanhalle@64	37 * larger-grain sharing of resources, according to predicted critical
seanhalle@64	38 * path, and expansion of work
seanhalle@64	39 */
seanhalle@64	40
seanhalle@64	41
seanhalle@64	42
seanhalle@64	43 //===========================================================================
seanhalle@64	44
seanhalle@64	45
seanhalle@64	46 /These are the library functions called in the application*
seanhalle@64	47 *
seanhalle@64	48 *There's a pattern for the outside sequential code to interact with the
seanhalle@64	49 * VMS_HW code.
seanhalle@64	50 *The VMS_HW system is inside a boundary.. every SSR system is in its
seanhalle@64	51 * own directory that contains the functions for each of the processor types.
seanhalle@64	52 * One of the processor types is the "seed" processor that starts the
seanhalle@64	53 * cascade of creating all the processors that do the work.
seanhalle@64	54 *So, in the directory is a file called "EntryPoint.c" that contains the
seanhalle@64	55 * function, named appropriately to the work performed, that the outside
seanhalle@64	56 * sequential code calls. This function follows a pattern:
seanhalle@64	57 *1) it calls SSR__init()
seanhalle@64	58 *2) it creates the initial data for the seed processor, which is passed
seanhalle@64	59 * in to the function
seanhalle@64	60 *3) it creates the seed SSR processor, with the data to start it with.
seanhalle@64	61 *4) it calls startSSRThenWaitUntilWorkDone
seanhalle@64	62 *5) it gets the returnValue from the transfer struc and returns that
seanhalle@64	63 * from the function
seanhalle@64	64 *
seanhalle@64	65 *For now, a new SSR system has to be created via SSR__init every
seanhalle@64	66 * time an entry point function is called -- later, might add letting the
seanhalle@64	67 * SSR system be created once, and let all the entry points just reuse
seanhalle@64	68 * it -- want to be as simple as possible now, and see by using what makes
seanhalle@64	69 * sense for later..
seanhalle@64	70 */
seanhalle@64	71
seanhalle@64	72
seanhalle@64	73
seanhalle@64	74 //===========================================================================
seanhalle@64	75
seanhalle@64	76 /*This is the "border crossing" function -- the thing that crosses from the
seanhalle@64	77 * outside world, into the VMS_HW world. It initializes and starts up the
seanhalle@64	78 * VMS system, then creates one processor from the specified function and
seanhalle@64	79 * puts it into the readyQ. From that point, that one function is resp.
seanhalle@64	80 * for creating all the other processors, that then create others, and so
seanhalle@64	81 * forth.
seanhalle@64	82 *When all the processors, including the seed, have dissipated, then this
seanhalle@64	83 * function returns. The results will have been written by side-effect via
seanhalle@64	84 * pointers read from, or written into initData.
seanhalle@64	85 *
seanhalle@64	86 *NOTE: no Threads should exist in the outside program that might touch
seanhalle@64	87 * any of the data reachable from initData passed in to here
seanhalle@64	88 */
seanhalle@64	89 void
seanhalle@64	90 SSR__create_seed_procr_and_do_work( TopLevelFnPtr fnPtr, void *initData )
seanhalle@64	91 { SSRSemEnv *semEnv;
seanhalle@64	92 SlaveVP *seedPr;
seanhalle@64	93
seanhalle@64	94 SSR__init(); //normal multi-thd
seanhalle@64	95
seanhalle@64	96 semEnv = _VMSMasterEnv->semanticEnv;
seanhalle@64	97
seanhalle@64	98 //SSR starts with one processor, which is put into initial environ,
seanhalle@64	99 // and which then calls create() to create more, thereby expanding work
seanhalle@64	100 seedPr = SSR__create_procr_helper( fnPtr, initData,
seanhalle@64	101 semEnv, semEnv->nextCoreToGetNewPr++ );
seanhalle@64	102
seanhalle@64	103 resume_slaveVP( seedPr, semEnv );
seanhalle@64	104
seanhalle@64	105 VMS_SS__start_the_work_then_wait_until_done(); //normal multi-thd
seanhalle@64	106
seanhalle@64	107 SSR__cleanup_after_shutdown();
seanhalle@64	108 }
seanhalle@64	109
seanhalle@64	110
seanhalle@64	111 int32
seanhalle@64	112 SSR__giveMinWorkUnitCycles( float32 percentOverhead )
seanhalle@64	113 {
seanhalle@64	114 return MIN_WORK_UNIT_CYCLES;
seanhalle@64	115 }
seanhalle@64	116
seanhalle@64	117 int32
seanhalle@64	118 SSR__giveIdealNumWorkUnits()
seanhalle@64	119 {
seanhalle@64	120 return NUM_SCHED_SLOTS * NUM_CORES;
seanhalle@64	121 }
seanhalle@64	122
seanhalle@64	123 int32
seanhalle@64	124 SSR__give_number_of_cores_to_schedule_onto()
seanhalle@64	125 {
seanhalle@64	126 return NUM_CORES;
seanhalle@64	127 }
seanhalle@64	128
seanhalle@64	129 /*For now, use TSC -- later, make these two macros with assembly that first
seanhalle@64	130 * saves jump point, and second jumps back several times to get reliable time
seanhalle@64	131 */
seanhalle@64	132 void
seanhalle@64	133 SSR__start_primitive()
seanhalle@64	134 { saveLowTimeStampCountInto( ((SSRSemEnv *)(_VMSMasterEnv->semanticEnv))->
seanhalle@64	135 primitiveStartTime );
seanhalle@64	136 }
seanhalle@64	137
seanhalle@64	138 /*Just quick and dirty for now -- make reliable later
seanhalle@64	139 * will want this to jump back several times -- to be sure cache is warm
seanhalle@64	140 * because don't want comm time included in calc-time measurement -- and
seanhalle@64	141 * also to throw out any "weird" values due to OS interrupt or TSC rollover
seanhalle@64	142 */
seanhalle@64	143 int32
seanhalle@64	144 SSR__end_primitive_and_give_cycles()
seanhalle@64	145 { int32 endTime, startTime;
seanhalle@64	146 //TODO: fix by repeating time-measurement
seanhalle@64	147 saveLowTimeStampCountInto( endTime );
seanhalle@64	148 startTime =((SSRSemEnv*)(_VMSMasterEnv->semanticEnv))->primitiveStartTime;
seanhalle@64	149 return (endTime - startTime);
seanhalle@64	150 }
seanhalle@64	151
seanhalle@64	152 //===========================================================================
seanhalle@64	153
seanhalle@64	154 /*Initializes all the data-structures for a SSR system -- but doesn't
seanhalle@64	155 * start it running yet!
seanhalle@64	156 *
seanhalle@64	157 *This runs in the main thread -- before VMS starts up
seanhalle@64	158 *
seanhalle@64	159 *This sets up the semantic layer over the VMS system
seanhalle@64	160 *
seanhalle@64	161 *First, calls VMS_Setup, then creates own environment, making it ready
seanhalle@64	162 * for creating the seed processor and then starting the work.
seanhalle@64	163 */
seanhalle@64	164 void
seanhalle@64	165 SSR__init()
seanhalle@64	166 {
seanhalle@64	167 VMS_SS__init();
seanhalle@64	168 //masterEnv, a global var, now is partially set up by init_VMS
seanhalle@64	169 // after this, have VMS_int__malloc and VMS_int__free available
seanhalle@64	170
seanhalle@64	171 SSR__init_Helper();
seanhalle@64	172 }
seanhalle@64	173
seanhalle@64	174
seanhalle@64	175 void idle_fn(void* data, SlaveVP *animatingSlv){
seanhalle@64	176 while(1){
seanhalle@64	177 VMS_int__suspend_slaveVP_and_send_req(animatingSlv);
seanhalle@64	178 }
seanhalle@64	179 }
seanhalle@64	180
seanhalle@64	181 void
seanhalle@64	182 SSR__init_Helper()
seanhalle@64	183 { SSRSemEnv *semanticEnv;
seanhalle@64	184 PrivQueueStruc **readyVPQs;
seanhalle@64	185 int coreIdx, i, j;
seanhalle@64	186
seanhalle@64	187 //Hook up the semantic layer's plug-ins to the Master virt procr
seanhalle@64	188 _VMSMasterEnv->requestHandler = &SSR__Request_Handler;
seanhalle@64	189 _VMSMasterEnv->slaveAssigner = &SSR__assign_slaveVP;
seanhalle@64	190 #ifdef HOLISTIC__TURN_ON_PERF_COUNTERS
seanhalle@64	191 _VMSMasterEnv->counterHandler = &SSR__counter_handler;
seanhalle@64	192 #endif
seanhalle@64	193
seanhalle@64	194 //create the semantic layer's environment (all its data) and add to
seanhalle@64	195 // the master environment
seanhalle@64	196 semanticEnv = VMS_int__malloc( sizeof( SSRSemEnv ) );
seanhalle@64	197 _VMSMasterEnv->semanticEnv = semanticEnv;
seanhalle@64	198
seanhalle@64	199 #ifdef HOLISTIC__TURN_ON_PERF_COUNTERS
seanhalle@64	200 SSR__init_counter_data_structs();
seanhalle@64	201 #endif
seanhalle@64	202 for(i=0;i<NUM_CORES;++i){
seanhalle@64	203 for(j=0;j<NUM_SCHED_SLOTS;++j){
seanhalle@64	204 semanticEnv->idlePr[i][j] = VMS_int__create_slaveVP(&idle_fn,NULL);
seanhalle@64	205 semanticEnv->idlePr[i][j]->coreAnimatedBy = i;
seanhalle@64	206 }
seanhalle@64	207 }
seanhalle@64	208
seanhalle@64	209 #ifdef HOLISTIC__TURN_ON_OBSERVE_UCC
seanhalle@64	210 semanticEnv->unitList = makeListOfArrays(sizeof(Unit),128);
seanhalle@64	211 semanticEnv->ctlDependenciesList = makeListOfArrays(sizeof(Dependency),128);
seanhalle@64	212 semanticEnv->commDependenciesList = makeListOfArrays(sizeof(Dependency),128);
seanhalle@64	213 semanticEnv->dynDependenciesList = makeListOfArrays(sizeof(Dependency),128);
seanhalle@64	214 semanticEnv->ntonGroupsInfo = makePrivDynArrayOfSize((void***)&(semanticEnv->ntonGroups),8);
seanhalle@64	215
seanhalle@64	216 semanticEnv->hwArcs = makeListOfArrays(sizeof(Dependency),128);
seanhalle@64	217 memset(semanticEnv->last_in_slot,0,sizeof(NUM_CORES * NUM_SCHED_SLOTS * sizeof(Unit)));
seanhalle@64	218 #endif
seanhalle@64	219
seanhalle@64	220 //create the ready queue, hash tables used for pairing send to receive
seanhalle@64	221 // and so forth
seanhalle@64	222 //TODO: add hash tables for pairing sends with receives, and
seanhalle@64	223 // initialize the data ownership system
seanhalle@64	224 readyVPQs = VMS_int__malloc( NUM_CORES * sizeof(PrivQueueStruc *) );
seanhalle@64	225
seanhalle@64	226 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
seanhalle@64	227 {
seanhalle@64	228 readyVPQs[ coreIdx ] = makeVMSQ();
seanhalle@64	229 }
seanhalle@64	230
seanhalle@64	231 semanticEnv->readyVPQs = readyVPQs;
seanhalle@64	232
seanhalle@64	233 semanticEnv->nextCoreToGetNewPr = 0;
seanhalle@64	234 semanticEnv->numSlaveVP = 0;
seanhalle@64	235
seanhalle@64	236 semanticEnv->commHashTbl = makeHashTable( 1<<16, &VMS_int__free );//start big
seanhalle@64	237
seanhalle@64	238 //TODO: bug -- turn these arrays into dyn arrays to eliminate limit
seanhalle@64	239 //semanticEnv->singletonHasBeenExecutedFlags = makeDynArrayInfo( );
seanhalle@64	240 //semanticEnv->transactionStrucs = makeDynArrayInfo( );
seanhalle@64	241 for( i = 0; i < NUM_STRUCS_IN_SEM_ENV; i++ )
seanhalle@64	242 {
seanhalle@64	243 semanticEnv->fnSingletons[i].endInstrAddr = NULL;
seanhalle@64	244 semanticEnv->fnSingletons[i].hasBeenStarted = FALSE;
seanhalle@64	245 semanticEnv->fnSingletons[i].hasFinished = FALSE;
seanhalle@64	246 semanticEnv->fnSingletons[i].waitQ = makeVMSQ();
seanhalle@64	247 semanticEnv->transactionStrucs[i].waitingVPQ = makeVMSQ();
seanhalle@64	248 }
seanhalle@64	249 }
seanhalle@64	250
seanhalle@64	251
seanhalle@64	252 /*Frees any memory allocated by SSR__init() then calls VMS_int__shutdown
seanhalle@64	253 */
seanhalle@64	254 void
seanhalle@64	255 SSR__cleanup_after_shutdown()
seanhalle@64	256 { SSRSemEnv *semanticEnv;
seanhalle@64	257
seanhalle@64	258 semanticEnv = _VMSMasterEnv->semanticEnv;
seanhalle@64	259
seanhalle@64	260 #ifdef HOLISTIC__TURN_ON_OBSERVE_UCC
seanhalle@64	261 //UCC
seanhalle@64	262 FILE* output;
seanhalle@64	263 int n;
seanhalle@64	264 char filename[255];
seanhalle@64	265 for(n=0;n<255;n++)
seanhalle@64	266 {
seanhalle@64	267 sprintf(filename, "./counters/UCC.%d",n);
seanhalle@64	268 output = fopen(filename,"r");
seanhalle@64	269 if(output)
seanhalle@64	270 {
seanhalle@64	271 fclose(output);
seanhalle@64	272 }else{
seanhalle@64	273 break;
seanhalle@64	274 }
seanhalle@64	275 }
seanhalle@64	276 if(n<255){
seanhalle@64	277 printf("Saving UCC to File: %s ...\n", filename);
seanhalle@64	278 output = fopen(filename,"w+");
seanhalle@64	279 if(output!=NULL){
seanhalle@64	280 set_dependency_file(output);
seanhalle@64	281 //fprintf(output,"digraph Dependencies {\n");
seanhalle@64	282 //set_dot_file(output);
seanhalle@64	283 //FIXME: first line still depends on counters being enabled, replace w/ unit struct!
seanhalle@64	284 //forAllInDynArrayDo(_VMSMasterEnv->counter_history_array_info, &print_dot_node_info );
seanhalle@64	285 forAllInListOfArraysDo(semanticEnv->unitList, &print_unit_to_file);
seanhalle@64	286 forAllInListOfArraysDo( semanticEnv->commDependenciesList, &print_comm_dependency_to_file );
seanhalle@64	287 forAllInListOfArraysDo( semanticEnv->ctlDependenciesList, &print_ctl_dependency_to_file );
seanhalle@64	288 forAllInDynArrayDo(semanticEnv->ntonGroupsInfo,&print_nton_to_file);
seanhalle@64	289 //fprintf(output,"}\n");
seanhalle@64	290 fflush(output);
seanhalle@64	291
seanhalle@64	292 } else
seanhalle@64	293 printf("Opening UCC file failed. Please check that folder \"counters\" exists in run directory and has write permission.\n");
seanhalle@64	294 } else {
seanhalle@64	295 printf("Could not open UCC file, please clean \"counters\" folder. (Must contain less than 255 files.)\n");
seanhalle@64	296 }
seanhalle@64	297 //Loop Graph
seanhalle@64	298 for(n=0;n<255;n++)
seanhalle@64	299 {
seanhalle@64	300 sprintf(filename, "./counters/LoopGraph.%d",n);
seanhalle@64	301 output = fopen(filename,"r");
seanhalle@64	302 if(output)
seanhalle@64	303 {
seanhalle@64	304 fclose(output);
seanhalle@64	305 }else{
seanhalle@64	306 break;
seanhalle@64	307 }
seanhalle@64	308 }
seanhalle@64	309 if(n<255){
seanhalle@64	310 printf("Saving LoopGraph to File: %s ...\n", filename);
seanhalle@64	311 output = fopen(filename,"w+");
seanhalle@64	312 if(output!=NULL){
seanhalle@64	313 set_dependency_file(output);
seanhalle@64	314 //fprintf(output,"digraph Dependencies {\n");
seanhalle@64	315 //set_dot_file(output);
seanhalle@64	316 //FIXME: first line still depends on counters being enabled, replace w/ unit struct!
seanhalle@64	317 //forAllInDynArrayDo(_VMSMasterEnv->counter_history_array_info, &print_dot_node_info );
seanhalle@64	318 forAllInListOfArraysDo( semanticEnv->unitList, &print_unit_to_file );
seanhalle@64	319 forAllInListOfArraysDo( semanticEnv->commDependenciesList, &print_comm_dependency_to_file );
seanhalle@64	320 forAllInListOfArraysDo( semanticEnv->ctlDependenciesList, &print_ctl_dependency_to_file );
seanhalle@64	321 forAllInListOfArraysDo( semanticEnv->dynDependenciesList, &print_dyn_dependency_to_file );
seanhalle@64	322 forAllInListOfArraysDo( semanticEnv->hwArcs, &print_hw_dependency_to_file );
seanhalle@64	323 //fprintf(output,"}\n");
seanhalle@64	324 fflush(output);
seanhalle@64	325
seanhalle@64	326 } else
seanhalle@64	327 printf("Opening LoopGraph file failed. Please check that folder \"counters\" exists in run directory and has write permission.\n");
seanhalle@64	328 } else {
seanhalle@64	329 printf("Could not open LoopGraph file, please clean \"counters\" folder. (Must contain less than 255 files.)\n");
seanhalle@64	330 }
seanhalle@64	331
seanhalle@64	332
seanhalle@64	333 freeListOfArrays(semanticEnv->unitList);
seanhalle@64	334 freeListOfArrays(semanticEnv->commDependenciesList);
seanhalle@64	335 freeListOfArrays(semanticEnv->ctlDependenciesList);
seanhalle@64	336 freeListOfArrays(semanticEnv->dynDependenciesList);
seanhalle@64	337
seanhalle@64	338 #endif
seanhalle@64	339 #ifdef HOLISTIC__TURN_ON_PERF_COUNTERS
seanhalle@64	340 for(n=0;n<255;n++)
seanhalle@64	341 {
seanhalle@64	342 sprintf(filename, "./counters/Counters.%d.csv",n);
seanhalle@64	343 output = fopen(filename,"r");
seanhalle@64	344 if(output)
seanhalle@64	345 {
seanhalle@64	346 fclose(output);
seanhalle@64	347 }else{
seanhalle@64	348 break;
seanhalle@64	349 }
seanhalle@64	350 }
seanhalle@64	351 if(n<255){
seanhalle@64	352 printf("Saving Counter measurements to File: %s ...\n", filename);
seanhalle@64	353 output = fopen(filename,"w+");
seanhalle@64	354 if(output!=NULL){
seanhalle@64	355 set_counter_file(output);
seanhalle@64	356 int i;
seanhalle@64	357 for(i=0;i<NUM_CORES;i++){
seanhalle@64	358 forAllInListOfArraysDo( semanticEnv->counterList[i], &print_counter_events_to_file );
seanhalle@64	359 fflush(output);
seanhalle@64	360 }
seanhalle@64	361
seanhalle@64	362 } else
seanhalle@64	363 printf("Opening UCC file failed. Please check that folder \"counters\" exists in run directory and has write permission.\n");
seanhalle@64	364 } else {
seanhalle@64	365 printf("Could not open UCC file, please clean \"counters\" folder. (Must contain less than 255 files.)\n");
seanhalle@64	366 }
seanhalle@64	367
seanhalle@64	368 #endif
seanhalle@64	369 /* It's all allocated inside VMS's big chunk -- that's about to be freed, so
seanhalle@64	370 * nothing to do here
seanhalle@64	371
seanhalle@64	372
seanhalle@64	373 for( coreIdx = 0; coreIdx < NUM_CORES; coreIdx++ )
seanhalle@64	374 {
seanhalle@64	375 VMS_int__free( semanticEnv->readyVPQs[coreIdx]->startOfData );
seanhalle@64	376 VMS_int__free( semanticEnv->readyVPQs[coreIdx] );
seanhalle@64	377 }
seanhalle@64	378 VMS_int__free( semanticEnv->readyVPQs );
seanhalle@64	379
seanhalle@64	380 freeHashTable( semanticEnv->commHashTbl );
seanhalle@64	381 VMS_int__free( _VMSMasterEnv->semanticEnv );
seanhalle@64	382 */
seanhalle@64	383 VMS_SS__cleanup_at_end_of_shutdown();
seanhalle@64	384 }
seanhalle@64	385
seanhalle@64	386
seanhalle@64	387 //===========================================================================
seanhalle@64	388
seanhalle@64	389 /*
seanhalle@64	390 */
seanhalle@64	391 SlaveVP *
seanhalle@64	392 SSR__create_procr_with( TopLevelFnPtr fnPtr, void *initData,
seanhalle@64	393 SlaveVP *creatingPr )
seanhalle@64	394 { SSRSemReq reqData;
seanhalle@64	395
seanhalle@64	396 //the semantic request data is on the stack and disappears when this
seanhalle@64	397 // call returns -- it's guaranteed to remain in the VP's stack for as
seanhalle@64	398 // long as the VP is suspended.
seanhalle@64	399 reqData.reqType = 0; //know type because in a VMS create req
seanhalle@64	400 reqData.coreToAssignOnto = -1; //means round-robin assign
seanhalle@64	401 reqData.fnPtr = fnPtr;
seanhalle@64	402 reqData.initData = initData;
seanhalle@64	403 reqData.sendPr = creatingPr;
seanhalle@64	404
seanhalle@64	405 VMS_WL__send_create_slaveVP_req( &reqData, creatingPr );
seanhalle@64	406
seanhalle@64	407 return creatingPr->dataRetFromReq;
seanhalle@64	408 }
seanhalle@64	409
seanhalle@64	410 SlaveVP *
seanhalle@64	411 SSR__create_procr_with_affinity( TopLevelFnPtr fnPtr, void *initData,
seanhalle@64	412 SlaveVP *creatingPr, int32 coreToAssignOnto )
seanhalle@64	413 { SSRSemReq reqData;
seanhalle@64	414
seanhalle@64	415 //the semantic request data is on the stack and disappears when this
seanhalle@64	416 // call returns -- it's guaranteed to remain in the VP's stack for as
seanhalle@64	417 // long as the VP is suspended.
seanhalle@64	418 reqData.reqType = 0; //know type because in a VMS create req
seanhalle@64	419 reqData.coreToAssignOnto = coreToAssignOnto;
seanhalle@64	420 reqData.fnPtr = fnPtr;
seanhalle@64	421 reqData.initData = initData;
seanhalle@64	422 reqData.sendPr = creatingPr;
seanhalle@64	423
seanhalle@64	424 VMS_WL__send_create_slaveVP_req( &reqData, creatingPr );
seanhalle@64	425
seanhalle@64	426 return creatingPr->dataRetFromReq;
seanhalle@64	427 }
seanhalle@64	428
seanhalle@64	429
seanhalle@64	430 void
seanhalle@64	431 SSR__dissipate_procr( SlaveVP *procrToDissipate )
seanhalle@64	432 {
seanhalle@64	433 VMS_WL__send_dissipate_req( procrToDissipate );
seanhalle@64	434 }
seanhalle@64	435
seanhalle@64	436
seanhalle@64	437 //===========================================================================
seanhalle@64	438
seanhalle@64	439 void *
seanhalle@64	440 SSR__malloc_to( int32 sizeToMalloc, SlaveVP *owningPr )
seanhalle@64	441 { SSRSemReq reqData;
seanhalle@64	442
seanhalle@64	443 reqData.reqType = malloc_req;
seanhalle@64	444 reqData.sendPr = owningPr;
seanhalle@64	445 reqData.sizeToMalloc = sizeToMalloc;
seanhalle@64	446
seanhalle@64	447 VMS_WL__send_sem_request( &reqData, owningPr );
seanhalle@64	448
seanhalle@64	449 return owningPr->dataRetFromReq;
seanhalle@64	450 }
seanhalle@64	451
seanhalle@64	452
seanhalle@64	453 /*Sends request to Master, which does the work of freeing
seanhalle@64	454 */
seanhalle@64	455 void
seanhalle@64	456 SSR__free( void ptrToFree, SlaveVP owningPr )
seanhalle@64	457 { SSRSemReq reqData;
seanhalle@64	458
seanhalle@64	459 reqData.reqType = free_req;
seanhalle@64	460 reqData.sendPr = owningPr;
seanhalle@64	461 reqData.ptrToFree = ptrToFree;
seanhalle@64	462
seanhalle@64	463 VMS_WL__send_sem_request( &reqData, owningPr );
seanhalle@64	464 }
seanhalle@64	465
seanhalle@64	466
seanhalle@64	467 void
seanhalle@64	468 SSR__transfer_ownership_of_from_to( void data, SlaveVP oldOwnerSlv,
seanhalle@64	469 SlaveVP *newOwnerPr )
seanhalle@64	470 {
seanhalle@64	471 //TODO: put in the ownership system that automatically frees when no
seanhalle@64	472 // owners of data left -- will need keeper for keeping data around when
seanhalle@64	473 // future created processors might need it but don't exist yet
seanhalle@64	474 }
seanhalle@64	475
seanhalle@64	476
seanhalle@64	477 void
seanhalle@64	478 SSR__add_ownership_by_to( SlaveVP newOwnerSlv, void data )
seanhalle@64	479 {
seanhalle@64	480
seanhalle@64	481 }
seanhalle@64	482
seanhalle@64	483
seanhalle@64	484 void
seanhalle@64	485 SSR__remove_ownership_by_from( SlaveVP loserSlv, void dataLosing )
seanhalle@64	486 {
seanhalle@64	487
seanhalle@64	488 }
seanhalle@64	489
seanhalle@64	490
seanhalle@64	491 /*Causes the SSR system to remove internal ownership, so data won't be
seanhalle@64	492 * freed when SSR shuts down, and will persist in the external program.
seanhalle@64	493 *
seanhalle@64	494 *Must be called from the processor that currently owns the data.
seanhalle@64	495 *
seanhalle@64	496 *IMPL: Transferring ownership touches two different virtual processor's
seanhalle@64	497 * state -- which means it has to be done carefully -- the VMS rules for
seanhalle@64	498 * semantic layers say that a work-unit is only allowed to touch the
seanhalle@64	499 * virtual processor it is part of, and that only a single work-unit per
seanhalle@64	500 * virtual processor be assigned to a slave at a time. So, this has to
seanhalle@64	501 * modify the virtual processor that owns the work-unit that called this
seanhalle@64	502 * function, then create a request to have the other processor modified.
seanhalle@64	503 *However, in this case, the TO processor is the outside, and transfers
seanhalle@64	504 * are only allowed to be called by the giver-upper, so can mark caller of
seanhalle@64	505 * this function as no longer owner, and return -- done.
seanhalle@64	506 */
seanhalle@64	507 void
seanhalle@64	508 SSR__transfer_ownership_to_outside( void *data )
seanhalle@64	509 {
seanhalle@64	510 //TODO: removeAllOwnersFrom( data );
seanhalle@64	511 }
seanhalle@64	512
seanhalle@64	513
seanhalle@64	514 //===========================================================================
seanhalle@64	515
seanhalle@64	516 void
seanhalle@64	517 SSR__send_of_type_to( SlaveVP sendPr, void msg, const int type,
seanhalle@64	518 SlaveVP *receivePr)
seanhalle@64	519 { SSRSemReq reqData;
seanhalle@64	520
seanhalle@64	521 reqData.receivePr = receivePr;
seanhalle@64	522 reqData.sendPr = sendPr;
seanhalle@64	523 reqData.reqType = send_type;
seanhalle@64	524 reqData.msgType = type;
seanhalle@64	525 reqData.msg = msg;
seanhalle@64	526 reqData.nextReqInHashEntry = NULL;
seanhalle@64	527
seanhalle@64	528 //On ownership -- remove inside the send and let ownership sit in limbo
seanhalle@64	529 // as a potential in an entry in the hash table, when this receive msg
seanhalle@64	530 // gets paired to a send, the ownership gets added to the receivePr --
seanhalle@64	531 // the next work-unit in the receivePr's trace will have ownership.
seanhalle@64	532 VMS_WL__send_sem_request( &reqData, sendPr );
seanhalle@64	533
seanhalle@64	534 //When come back from suspend, no longer own data reachable from msg
seanhalle@64	535 //TODO: release ownership here
seanhalle@64	536 }
seanhalle@64	537
seanhalle@64	538 void
seanhalle@64	539 SSR__send_from_to( void msg, SlaveVP sendPr, SlaveVP *receivePr )
seanhalle@64	540 { SSRSemReq reqData;
seanhalle@64	541
seanhalle@64	542 //hash on the receiver, 'cause always know it, but sometimes want to
seanhalle@64	543 // receive from anonymous sender
seanhalle@64	544
seanhalle@64	545 reqData.receivePr = receivePr;
seanhalle@64	546 reqData.sendPr = sendPr;
seanhalle@64	547 reqData.reqType = send_from_to;
seanhalle@64	548 reqData.msg = msg;
seanhalle@64	549 reqData.nextReqInHashEntry = NULL;
seanhalle@64	550
seanhalle@64	551 VMS_WL__send_sem_request( &reqData, sendPr );
seanhalle@64	552 }
seanhalle@64	553
seanhalle@64	554
seanhalle@64	555 //===========================================================================
seanhalle@64	556
seanhalle@64	557 void *
seanhalle@64	558 SSR__receive_any_to( SlaveVP *receivePr )
seanhalle@64	559 {
seanhalle@64	560
seanhalle@64	561 }
seanhalle@64	562
seanhalle@64	563 void *
seanhalle@64	564 SSR__receive_type_to( const int type, SlaveVP *receivePr )
seanhalle@64	565 {
seanhalle@64	566 SSRSemReq reqData;
seanhalle@64	567
seanhalle@64	568 reqData.receivePr = receivePr;
seanhalle@64	569 reqData.reqType = receive_type;
seanhalle@64	570 reqData.msgType = type;
seanhalle@64	571 reqData.nextReqInHashEntry = NULL;
seanhalle@64	572
seanhalle@64	573 VMS_WL__send_sem_request( &reqData, receivePr );
seanhalle@64	574
seanhalle@64	575 return receivePr->dataRetFromReq;
seanhalle@64	576 }
seanhalle@64	577
seanhalle@64	578
seanhalle@64	579
seanhalle@64	580 /*Call this at point receiving virt pr wants in-coming data.
seanhalle@64	581 *
seanhalle@64	582 *The reason receivePr must call this is that it modifies the receivPr
seanhalle@64	583 * loc structure directly -- and the VMS rules state a virtual processor
seanhalle@64	584 * loc structure can only be modified by itself.
seanhalle@64	585 */
seanhalle@64	586 void *
seanhalle@64	587 SSR__receive_from_to( SlaveVP sendPr, SlaveVP receivePr )
seanhalle@64	588 { SSRSemReq reqData;
seanhalle@64	589
seanhalle@64	590 //hash on the receiver, 'cause always know it, but sometimes want to
seanhalle@64	591 // receive from anonymous sender
seanhalle@64	592
seanhalle@64	593 reqData.receivePr = receivePr;
seanhalle@64	594 reqData.sendPr = sendPr;
seanhalle@64	595 reqData.reqType = receive_from_to;
seanhalle@64	596 reqData.nextReqInHashEntry = NULL;
seanhalle@64	597
seanhalle@64	598 VMS_WL__send_sem_request( &reqData, receivePr );
seanhalle@64	599
seanhalle@64	600 return receivePr->dataRetFromReq;
seanhalle@64	601 }
seanhalle@64	602
seanhalle@64	603
seanhalle@64	604 //===========================================================================
seanhalle@64	605 //
seanhalle@64	606 /*A function singleton is a function whose body executes exactly once, on a
seanhalle@64	607 * single core, no matter how many times the fuction is called and no
seanhalle@64	608 * matter how many cores or the timing of cores calling it.
seanhalle@64	609 *
seanhalle@64	610 *A data singleton is a ticket attached to data. That ticket can be used
seanhalle@64	611 * to get the data through the function exactly once, no matter how many
seanhalle@64	612 * times the data is given to the function, and no matter the timing of
seanhalle@64	613 * trying to get the data through from different cores.
seanhalle@64	614 */
seanhalle@64	615
seanhalle@64	616 /asm function declarations/
seanhalle@64	617 void asm_save_ret_to_singleton(SSRSingleton *singletonPtrAddr);
seanhalle@64	618 void asm_write_ret_from_singleton(SSRSingleton *singletonPtrAddr);
seanhalle@64	619
seanhalle@64	620 /*Fn singleton uses ID as index into array of singleton structs held in the
seanhalle@64	621 * semantic environment.
seanhalle@64	622 */
seanhalle@64	623 void
seanhalle@64	624 SSR__start_fn_singleton( int32 singletonID, SlaveVP *animPr )
seanhalle@64	625 {
seanhalle@64	626 SSRSemReq reqData;
seanhalle@64	627
seanhalle@64	628 //
seanhalle@64	629 reqData.reqType = singleton_fn_start;
seanhalle@64	630 reqData.singletonID = singletonID;
seanhalle@64	631
seanhalle@64	632 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	633 if( animPr->dataRetFromReq ) //will be 0 or addr of label in end singleton
seanhalle@64	634 {
seanhalle@64	635 SSRSemEnv *semEnv = VMS_int__give_sem_env_for( animPr );
seanhalle@64	636 asm_write_ret_from_singleton(&(semEnv->fnSingletons[ singletonID]));
seanhalle@64	637 }
seanhalle@64	638 }
seanhalle@64	639
seanhalle@64	640 /*Data singleton hands addr of loc holding a pointer to a singleton struct.
seanhalle@64	641 * The start_data_singleton makes the structure and puts its addr into the
seanhalle@64	642 * location.
seanhalle@64	643 */
seanhalle@64	644 void
seanhalle@64	645 SSR__start_data_singleton( SSRSingleton *singletonAddr, SlaveVP animPr )
seanhalle@64	646 {
seanhalle@64	647 SSRSemReq reqData;
seanhalle@64	648
seanhalle@64	649 if( singletonAddr && (singletonAddr)->hasFinished )
seanhalle@64	650 goto JmpToEndSingleton;
seanhalle@64	651
seanhalle@64	652 reqData.reqType = singleton_data_start;
seanhalle@64	653 reqData.singletonPtrAddr = singletonAddr;
seanhalle@64	654
seanhalle@64	655 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	656 if( animPr->dataRetFromReq ) //either 0 or end singleton's return addr
seanhalle@64	657 { //Assembly code changes the return addr on the stack to the one
seanhalle@64	658 // saved into the singleton by the end-singleton-fn
seanhalle@64	659 //The return addr is at 0x4(%%ebp)
seanhalle@64	660 JmpToEndSingleton:
seanhalle@64	661 asm_write_ret_from_singleton(*singletonAddr);
seanhalle@64	662 }
seanhalle@64	663 //now, simply return
seanhalle@64	664 //will exit either from the start singleton call or the end-singleton call
seanhalle@64	665 }
seanhalle@64	666
seanhalle@64	667 /*Uses ID as index into array of flags. If flag already set, resumes from
seanhalle@64	668 * end-label. Else, sets flag and resumes normally.
seanhalle@64	669 *
seanhalle@64	670 *Note, this call cannot be inlined because the instr addr at the label
seanhalle@64	671 * inside is shared by all invocations of a given singleton ID.
seanhalle@64	672 */
seanhalle@64	673 void
seanhalle@64	674 SSR__end_fn_singleton( int32 singletonID, SlaveVP *animPr )
seanhalle@64	675 {
seanhalle@64	676 SSRSemReq reqData;
seanhalle@64	677
seanhalle@64	678 //don't need this addr until after at least one singleton has reached
seanhalle@64	679 // this function
seanhalle@64	680 SSRSemEnv *semEnv = VMS_int__give_sem_env_for( animPr );
seanhalle@64	681 asm_write_ret_from_singleton(&(semEnv->fnSingletons[ singletonID]));
seanhalle@64	682
seanhalle@64	683 reqData.reqType = singleton_fn_end;
seanhalle@64	684 reqData.singletonID = singletonID;
seanhalle@64	685
seanhalle@64	686 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	687
seanhalle@64	688 EndSingletonInstrAddr:
seanhalle@64	689 return;
seanhalle@64	690 }
seanhalle@64	691
seanhalle@64	692 void
seanhalle@64	693 SSR__end_data_singleton( SSRSingleton *singletonPtrAddr, SlaveVP animPr )
seanhalle@64	694 {
seanhalle@64	695 SSRSemReq reqData;
seanhalle@64	696
seanhalle@64	697 //don't need this addr until after singleton struct has reached
seanhalle@64	698 // this function for first time
seanhalle@64	699 //do assembly that saves the return addr of this fn call into the
seanhalle@64	700 // data singleton -- that data-singleton can only be given to exactly
seanhalle@64	701 // one instance in the code of this function. However, can use this
seanhalle@64	702 // function in different places for different data-singletons.
seanhalle@64	703 // (*(singletonAddr))->endInstrAddr = &&EndDataSingletonInstrAddr;
seanhalle@64	704
seanhalle@64	705
seanhalle@64	706 asm_save_ret_to_singleton(*singletonPtrAddr);
seanhalle@64	707
seanhalle@64	708 reqData.reqType = singleton_data_end;
seanhalle@64	709 reqData.singletonPtrAddr = singletonPtrAddr;
seanhalle@64	710
seanhalle@64	711 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	712 }
seanhalle@64	713
seanhalle@64	714 /*This executes the function in the masterVP, so it executes in isolation
seanhalle@64	715 * from any other copies -- only one copy of the function can ever execute
seanhalle@64	716 * at a time.
seanhalle@64	717 *
seanhalle@64	718 *It suspends to the master, and the request handler takes the function
seanhalle@64	719 * pointer out of the request and calls it, then resumes the VP.
seanhalle@64	720 *Only very short functions should be called this way -- for longer-running
seanhalle@64	721 * isolation, use transaction-start and transaction-end, which run the code
seanhalle@64	722 * between as work-code.
seanhalle@64	723 */
seanhalle@64	724 void
seanhalle@64	725 SSR__animate_short_fn_in_isolation( PtrToAtomicFn ptrToFnToExecInMaster,
seanhalle@64	726 void data, SlaveVP animPr )
seanhalle@64	727 {
seanhalle@64	728 SSRSemReq reqData;
seanhalle@64	729
seanhalle@64	730 //
seanhalle@64	731 reqData.reqType = atomic;
seanhalle@64	732 reqData.fnToExecInMaster = ptrToFnToExecInMaster;
seanhalle@64	733 reqData.dataForFn = data;
seanhalle@64	734
seanhalle@64	735 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	736 }
seanhalle@64	737
seanhalle@64	738
seanhalle@64	739 /*This suspends to the master.
seanhalle@64	740 *First, it looks at the VP's data, to see the highest transactionID that VP
seanhalle@64	741 * already has entered. If the current ID is not larger, it throws an
seanhalle@64	742 * exception stating a bug in the code. Otherwise it puts the current ID
seanhalle@64	743 * there, and adds the ID to a linked list of IDs entered -- the list is
seanhalle@64	744 * used to check that exits are properly ordered.
seanhalle@64	745 *Next it is uses transactionID as index into an array of transaction
seanhalle@64	746 * structures.
seanhalle@64	747 *If the "VP_currently_executing" field is non-null, then put requesting VP
seanhalle@64	748 * into queue in the struct. (At some point a holder will request
seanhalle@64	749 * end-transaction, which will take this VP from the queue and resume it.)
seanhalle@64	750 *If NULL, then write requesting into the field and resume.
seanhalle@64	751 */
seanhalle@64	752 void
seanhalle@64	753 SSR__start_transaction( int32 transactionID, SlaveVP *animPr )
seanhalle@64	754 {
seanhalle@64	755 SSRSemReq reqData;
seanhalle@64	756
seanhalle@64	757 //
seanhalle@64	758 reqData.sendPr = animPr;
seanhalle@64	759 reqData.reqType = trans_start;
seanhalle@64	760 reqData.transID = transactionID;
seanhalle@64	761
seanhalle@64	762 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	763 }
seanhalle@64	764
seanhalle@64	765 /*This suspends to the master, then uses transactionID as index into an
seanhalle@64	766 * array of transaction structures.
seanhalle@64	767 *It looks at VP_currently_executing to be sure it's same as requesting VP.
seanhalle@64	768 * If different, throws an exception, stating there's a bug in the code.
seanhalle@64	769 *Next it looks at the queue in the structure.
seanhalle@64	770 *If it's empty, it sets VP_currently_executing field to NULL and resumes.
seanhalle@64	771 *If something in, gets it, sets VP_currently_executing to that VP, then
seanhalle@64	772 * resumes both.
seanhalle@64	773 */
seanhalle@64	774 void
seanhalle@64	775 SSR__end_transaction( int32 transactionID, SlaveVP *animPr )
seanhalle@64	776 {
seanhalle@64	777 SSRSemReq reqData;
seanhalle@64	778
seanhalle@64	779 //
seanhalle@64	780 reqData.sendPr = animPr;
seanhalle@64	781 reqData.reqType = trans_end;
seanhalle@64	782 reqData.transID = transactionID;
seanhalle@64	783
seanhalle@64	784 VMS_WL__send_sem_request( &reqData, animPr );
seanhalle@64	785 }

Mercurial > cgi-bin > hgwebdir.cgi > VMS > VMS_Implementations > SSR_impls > SSR__MC_shared_impl

annotate SSR.c @ 65:51b8f15fea29