SCAnalysis::SCAnalysis() {
cvmap=new HashTable<const ModelAction *, ClockVector *, uintptr_t, 4>();
+ cycleset=new HashTable<const ModelAction *, const ModelAction *, uintptr_t, 4>();
+ threadlists=new SnapVector<action_list_t>(1);
}
SCAnalysis::~SCAnalysis() {
- delete(cvmap);
+ delete cvmap;
+ delete cycleset;
+ delete threadlists;
+}
+
+void SCAnalysis::print_list(action_list_t *list) {
+ action_list_t::iterator it;
+
+ model_print("---------------------------------------------------------------------\n");
+
+ unsigned int hash = 0;
+
+ for (it = list->begin(); it != list->end(); it++) {
+ const ModelAction *act = *it;
+ if (act->get_seq_number() > 0) {
+ if (cycleset->contains(act))
+ model_print("CYC");
+ act->print();
+ }
+ hash = hash^(hash<<3)^((*it)->hash());
+ }
+ model_print("HASH %u\n", hash);
+ model_print("---------------------------------------------------------------------\n");
}
void SCAnalysis::analyze(action_list_t * actions) {
buildVectors(actions);
computeCV(actions);
+ action_list_t *list=generateSC(actions);
+ print_list(list);
+}
+
+bool SCAnalysis::merge(ClockVector * cv, const ModelAction * act, ClockVector *cv2) {
+ if (cv2->getClock(act->get_tid())>=act->get_seq_number() && act->get_seq_number() != 0) {
+ cycleset->put(act, act);
+ }
+ return cv->merge(cv2);
+}
+
+ModelAction * SCAnalysis::getNextAction() {
+ ModelAction *act=NULL;
+ for(int i=0;i<=maxthreads;i++) {
+ action_list_t * threadlist=&(*threadlists)[i];
+ if (threadlist->empty())
+ continue;
+ ModelAction *first=threadlist->front();
+ if (act==NULL) {
+ act=first;
+ continue;
+ }
+ ClockVector *cv=cvmap->get(act);
+ if (cv->synchronized_since(first)) {
+ act=first;
+ }
+ }
+ if (act==NULL)
+ return act;
+ //print cycles in a nice way to avoid confusion
+ //make sure thread starts appear after the create
+ if (act->is_thread_start()) {
+ ModelAction *createact=model->get_thread(act)->get_creation();
+ if (createact) {
+ action_list_t *threadlist=&(*threadlists)[id_to_int(createact->get_tid())];
+ if (!threadlist->empty()) {
+ ModelAction *first=threadlist->front();
+ if (first->get_seq_number() <= createact->get_seq_number())
+ act=first;
+ }
+ }
+ }
+
+ //make sure that joins appear after the thread is finished
+ if (act->is_thread_join()) {
+ int jointhread=id_to_int(act->get_thread_operand()->get_id());
+ action_list_t *threadlist=&(*threadlists)[jointhread];
+ if (!threadlist->empty()) {
+ act=threadlist->front();
+ }
+ }
+
+ return act;
+}
+
+action_list_t * SCAnalysis::generateSC(action_list_t *list) {
+ action_list_t *sclist=new action_list_t();
+ while (true) {
+ ModelAction * act=getNextAction();
+ if (act==NULL)
+ break;
+ thread_id_t tid=act->get_tid();
+ //remove action
+ (*threadlists)[id_to_int(tid)].pop_front();
+ //add ordering constraints from this choice
+ if (updateConstraints(act)) {
+ //propagate changes if we have them
+ computeCV(list);
+ }
+ //add action to end
+ sclist->push_back(act);
+ }
+ return sclist;
}
void SCAnalysis::buildVectors(action_list_t *list) {
for (action_list_t::iterator it = list->begin(); it != list->end(); it++) {
ModelAction *act = *it;
int threadid=id_to_int(act->get_tid());
- if (threadid > maxthreads)
+ if (threadid > maxthreads) {
+ threadlists->resize(threadid+1);
maxthreads=threadid;
+ }
+ (*threadlists)[threadid].push_back(act);
}
}
+bool SCAnalysis::updateConstraints(ModelAction *act) {
+ bool changed=false;
+ ClockVector *actcv = cvmap->get(act);
+ for(int i=0;i<=maxthreads;i++) {
+ thread_id_t tid=int_to_id(i);
+ if (tid==act->get_tid())
+ continue;
+
+ action_list_t * list=&(*threadlists)[id_to_int(tid)];
+ for (action_list_t::iterator rit = list->begin(); rit != list->end(); rit++) {
+ ModelAction *write = *rit;
+ if (!write->is_write())
+ continue;
+ ClockVector *writecv = cvmap->get(write);
+ if (writecv->synchronized_since(act))
+ break;
+ if (write->get_location() == act->get_location()) {
+ //write is sc after act
+ merge(writecv, write, actcv);
+ changed=true;
+ break;
+ }
+ }
+ }
+ return changed;
+}
+
bool SCAnalysis::processRead(ModelAction *read, ClockVector *cv) {
bool changed=false;
/* Merge in the clock vector from the write */
const ModelAction *write=read->get_reads_from();
ClockVector *writecv=cvmap->get(write);
- changed|= ( writecv == NULL || cv->merge(writecv) && (*read < *write));
+ changed |= writecv == NULL || (merge(cv, read, writecv) && (*read < *write));
for(int i=0;i<=maxthreads;i++) {
thread_id_t tid=int_to_id(i);
if (tid==read->get_tid())
continue;
+ if (tid==write->get_tid())
+ continue;
action_list_t * list=model->get_actions_on_obj(read->get_location(), tid);
if (list==NULL)
continue;
for (action_list_t::reverse_iterator rit = list->rbegin(); rit != list->rend(); rit++) {
ModelAction *write2 = *rit;
+ if (!write2->is_write())
+ continue;
+
ClockVector *write2cv = cvmap->get(write2);
if (write2cv == NULL)
continue;
-
+
/* write -sc-> write2 &&
write -rf-> R =>
R -sc-> write2 */
if (write2cv->synchronized_since(write)) {
- changed |= write2cv->merge(cv);
+ changed |= merge(write2cv, write2, cv);
}
-
+
//looking for earliest write2 in iteration to satisfy this
/* write2 -sc-> R &&
write -rf-> R =>
write2 -sc-> write */
if (cv->synchronized_since(write2)) {
- changed |= writecv == NULL || writecv->merge(write2cv);
+ changed |= writecv == NULL || merge(writecv, write, write2cv);
break;
}
}
cv = new ClockVector(lastcv, act);
cvmap->put(act, cv);
} else if ( lastcv != NULL ) {
- cv->merge(lastcv);
+ merge(cv, act, lastcv);
+ }
+ if (act->is_thread_join()) {
+ Thread *joinedthr = act->get_thread_operand();
+ ModelAction *finish = model->get_last_action(joinedthr->get_id());
+ ClockVector *finishcv = cvmap->get(finish);
+ changed |= (finishcv == NULL) || merge(cv, act, finishcv);
}
if (act->is_read()) {
changed|=processRead(act, cv);