void
AdaptiveStateManagerBaseTest::testFossilCollect() {
// Create the same state queue as above.
ASMBTestClass* toCheck = dynamic_cast<ASMBTestClass*>(toTest);
toCheck->setPeriod(getSimObj1(), 3);
defaultSaveState();
// Call fossilCollect.
CPPUNIT_ASSERT(toTest->fossilCollect(getSimObj1(), IntVTime(7)) == IntVTime(5));
// Check the size of the state queue. May also want to check the entire queue.
multiset< SetObject<State> >* stateQueue = toCheck->getStateQueue();
CPPUNIT_ASSERT(stateQueue[ getSimObj1()->getObjectID()->getSimulationObjectID() ].size() == 2);
multiset< SetObject<State> >::iterator iter_begin =
stateQueue[ getSimObj1()->getObjectID()->getSimulationObjectID() ].begin();
const UnitTestState* checkState = dynamic_cast<const UnitTestState*>((*iter_begin).getElement());
IntVTime time = atoi((*iter_begin).getMainTime().toString().c_str());
CPPUNIT_ASSERT(time == 5);
CPPUNIT_ASSERT(checkState->intMember == 50);
iter_begin++;
checkState = dynamic_cast<const UnitTestState*>((*iter_begin).getElement());
time = atoi((*iter_begin).getMainTime().toString().c_str());
CPPUNIT_ASSERT(time == 9);
CPPUNIT_ASSERT(checkState->intMember == 90);
}
void
AdaptiveStateManagerBaseTest::testRestoreState() {
// Create the same state queue as above.
ASMBTestClass* toCheck = dynamic_cast<ASMBTestClass*>(toTest);
toCheck->setPeriod(getSimObj1(), 3);
defaultSaveState();
// Call restoreState.
toTest->restoreState(IntVTime(7), getSimObj1());
// Check the current state of the object
UnitTestState* testState = dynamic_cast<UnitTestState*>(getSimObj1()->getState());
CPPUNIT_ASSERT(testState->intMember == 50);
// May also want to check the state queue and see if its last element matches the current state.
// This includes checking the size.
multiset< SetObject<State> >* stateQueue = toCheck->getStateQueue();
multiset< SetObject<State> >::iterator iter_end =
stateQueue[ getSimObj1()->getObjectID()->getSimulationObjectID() ].end();
iter_end--;
const UnitTestState* checkState = dynamic_cast<const UnitTestState*>((*iter_end).getElement());
IntVTime time = atoi((*iter_end).getMainTime().toString().c_str());
CPPUNIT_ASSERT(time == 5);
CPPUNIT_ASSERT(checkState->intMember == 50);
}
void
AdaptiveStateManagerBaseTest::testSaveState() {
// There should be saved states every 4th state.
ASMBTestClass* toCheck = dynamic_cast<ASMBTestClass*>(toTest);
toCheck->setPeriod(getSimObj1(), 3);
defaultSaveState();
// Go through the state queue. The key is the object. There should then be a queue of
// pairs SetObject. The pair is (time, state). Examine the time and state. In this case
// the state should be 10*time.
multiset< SetObject<State> >* stateQueue = toCheck->getStateQueue();
multiset< SetObject<State> >::iterator iter_begin =
stateQueue[ getSimObj1()->getObjectID()->getSimulationObjectID() ].begin();
multiset< SetObject<State> >::iterator iter_end =
stateQueue[ getSimObj1()->getObjectID()->getSimulationObjectID() ].end();
int check = 1;
while (iter_begin != iter_end) {
const UnitTestState* checkState = dynamic_cast<const UnitTestState*>((*iter_begin).getElement());
CPPUNIT_ASSERT(checkState->intMember == check * 10);
IntVTime time = atoi((*iter_begin).getMainTime().toString().c_str());
CPPUNIT_ASSERT(time == check);
check += 4;
iter_begin++;
}
}
void
AdaptiveStateManagerBaseTest::defaultSaveState() {
for (int a = 1; a <= 10; a++) {
UnitTestState* testState = dynamic_cast<UnitTestState*>(getSimObj1()->getState());
testState->intMember = a * 10;
toTest->saveState(IntVTime(a), getSimObj1());
}
}
void
CostAdaptiveStateManagerTest::testSaveState() {
// The actual saving of the state is tested in AdaptiveStateManagerBaseTest.
// Just check that the forward execution length is being incremented and reset
// when the period is recalculated.
CASMTestClass* toCheck = dynamic_cast<CASMTestClass*>(toTest);
toCheck->setAdaptiveParameters(0, 30);
for (int a = 1; a <= 20; a++) {
toTest->saveState(IntVTime(a), getSimObj1());
}
CPPUNIT_ASSERT(toCheck->getForwardExecutionLength()[0] == 20);
for (int b = 21; b <= 40; b++) {
toTest->saveState(IntVTime(b), getSimObj1());
}
CPPUNIT_ASSERT(toCheck->getForwardExecutionLength()[0] == 10);
}
void
SchedulingManagerTest::testGetNextEvent( SchedulingManager *toTest ) {
CPPUNIT_ASSERT( toTest != 0 );
doDefaultInsert( getSimManager()->getEventSetManager() );
const Event *event1 = toTest->peekNextEvent();
CPPUNIT_ASSERT( event1 != 0 );
CPPUNIT_ASSERT( toTest->getLastEventScheduledTime() == IntVTime(0) );
CPPUNIT_ASSERT( event1 == getSimManager()->getEventSetManager()->getEvent( getSimObj1() ) );
const Event *event2 = toTest->peekNextEvent();
CPPUNIT_ASSERT( event2 != 0 );
CPPUNIT_ASSERT( toTest->getLastEventScheduledTime() == IntVTime(0) );
CPPUNIT_ASSERT( event2 == getSimManager()->getEventSetManager()->getEvent( getSimObj1() ) );
const Event *event3 = toTest->peekNextEvent();
CPPUNIT_ASSERT( event3 != 0 );
CPPUNIT_ASSERT( toTest->getLastEventScheduledTime() == IntVTime(0) );
CPPUNIT_ASSERT( event3 == getSimManager()->getEventSetManager()->getEvent( getSimObj1() ) );
const Event *event4 = toTest->peekNextEvent();
CPPUNIT_ASSERT( event4 != 0 );
CPPUNIT_ASSERT( toTest->getLastEventScheduledTime() == IntVTime(1) );
CPPUNIT_ASSERT( event4 == getSimManager()->getEventSetManager()->getEvent( getSimObj1() ) );
checkDefaultEvents( event1, event2, event3, event4 );
}
void
LazyOutputManagerTest::testRollback(){
CPPUNIT_ASSERT( toTest != 0 );
LOMSimMgr *simMgr = dynamic_cast<LOMSimMgr *>(getSimManager());
CPPUNIT_ASSERT( simMgr != 0 );
CPPUNIT_ASSERT( simMgr->negativeCount() == 0 );
doDefaultInsert( toTest );
toTest->rollback( getSimObj1(), IntVTime(1) );
CPPUNIT_ASSERT( simMgr->negativeCount() == 0 );
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 4 );
CPPUNIT_ASSERT( getNumLazyCancelEvents( toTest, *(getSimObj1()->getObjectID()) ) == 0 );
toTest->rollback( getSimObj1(), IntVTime(0) );
CPPUNIT_ASSERT( simMgr->negativeCount() == 0 );
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 0 );
CPPUNIT_ASSERT( getNumLazyCancelEvents( toTest, *(getSimObj1()->getObjectID()) ) == 4 );
}
void
CostAdaptiveStateManagerTest::testCalculatePeriod() {
// Case 1: The first time the period is calculated, it is increased by
// 1 because the oldCostIndex is initially 0.
// filterCostIndex becomes 4.80
CASMTestClass* toCheck = dynamic_cast<CASMTestClass*>(toTest);
toCheck->StateSaveTimeWeighted[0].update(10);
toCheck->CoastForwardTimeWeighted[0].update(10);
toCheck->calculatePeriod(getSimObj1());
CPPUNIT_ASSERT(toCheck->getObjectStatePeriod()[0] == 1);
// Case 2: Period remains the same.
// filterCostIndex becomes 4.32
toCheck->StateSaveTimeWeighted[0].update(5);
toCheck->CoastForwardTimeWeighted[0].update(5);
toCheck->calculatePeriod(getSimObj1());
CPPUNIT_ASSERT(toCheck->getObjectStatePeriod()[0] == 1);
// Case 3: Period increases by 1.
// filteredCostIndex becomes 1.78
toCheck->StateSaveTimeWeighted[0].update(0.1);
toCheck->CoastForwardTimeWeighted[0].update(0.1);
toCheck->calculatePeriod(getSimObj1());
CPPUNIT_ASSERT(toCheck->getObjectStatePeriod()[0] == 2);
// Case 4: Period decreases by 1.
// filteredCostIndex becomes 5.51
toCheck->StateSaveTimeWeighted[0].update(10);
toCheck->CoastForwardTimeWeighted[0].update(10);
toCheck->calculatePeriod(getSimObj1());
CPPUNIT_ASSERT(toCheck->getObjectStatePeriod()[0] == 1);
// Case 5: Period is at the maximum. An attempt to increase it should keep it at maximum
toCheck->setPeriod(getSimObj1(), maxDefaultInterval);
toCheck->StateSaveTimeWeighted[0].update(0.1);
toCheck->CoastForwardTimeWeighted[0].update(0.1);
toCheck->calculatePeriod(getSimObj1());
CPPUNIT_ASSERT(toCheck->getObjectStatePeriod()[0] == maxDefaultInterval - 1);
}
void
LazyOutputManagerTest::testLazyCancel(){
LazyOutputManager *toCheck = dynamic_cast<LazyOutputManager *>( toTest );
CPPUNIT_ASSERT( toTest != 0 );
LOMSimMgr *simMgr = dynamic_cast<LOMSimMgr *>(getSimManager());
CPPUNIT_ASSERT( simMgr != 0 );
CPPUNIT_ASSERT( simMgr->negativeCount() == 0 );
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 0);
//Insert events into the output manager.
toTest->insert(new UnitTestEvent( *new IntVTime( 1 ), getSimObj1ID(), *new IntVTime( 0 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 1 ), getSimObj1ID(), *new IntVTime( 0 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 1 ), getSimObj1ID(), *new IntVTime( 0 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 2 ), getSimObj1ID(), *new IntVTime( 1 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 3 ), getSimObj1ID(), *new IntVTime( 2 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 3 ), getSimObj1ID(), *new IntVTime( 2 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 5 ), getSimObj1ID(), *new IntVTime( 4 ) ));
toTest->insert(new UnitTestEvent( *new IntVTime( 6 ), getSimObj1ID(), *new IntVTime( 5 ) ));
//Rollback the output manager and check the lazy queue.
toTest->rollback( getSimObj1(), IntVTime(2) );
CPPUNIT_ASSERT( simMgr->negativeCount() == 0 );
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 4 );
CPPUNIT_ASSERT( getNumLazyCancelEvents( toTest, *(getSimObj1()->getObjectID()) ) == 7 );
//Test the case where all events are regenerated.
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 3 ), getSimObj1ID(), *new IntVTime( 2 ) )));
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 3 ), getSimObj1ID(), *new IntVTime( 2 ) )));
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) )));
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) )));
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) )));
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 5 ), getSimObj1ID(), *new IntVTime( 4 ) )));
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 6 ), getSimObj1ID(), *new IntVTime( 5 ) )));
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 11 );
CPPUNIT_ASSERT( getNumLazyCancelEvents( toTest, *(getSimObj1()->getObjectID()) ) == 0 );
CPPUNIT_ASSERT( simMgr->negativeCount() == 0 );
toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 7 ), getSimObj1ID(), *new IntVTime( 6 ) ));
//Test the case where some events are not regenerated.
toTest->rollback( getSimObj1(), IntVTime(2) );
CPPUNIT_ASSERT( toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 4 ), getSimObj1ID(), *new IntVTime( 3 ) )));
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 5 );
CPPUNIT_ASSERT( getNumLazyCancelEvents( toTest, *(getSimObj1()->getObjectID()) ) == 5 );
CPPUNIT_ASSERT( simMgr->negativeCount() == 2 );
CPPUNIT_ASSERT( !toCheck->lazyCancel(new UnitTestEvent( *new IntVTime( 8 ), getSimObj1ID(), *new IntVTime( 7 ) )));
CPPUNIT_ASSERT( getNumElements( toTest, *(getSimObj1()->getObjectID()) ) == 6 );
CPPUNIT_ASSERT( getNumLazyCancelEvents( toTest, *(getSimObj1()->getObjectID()) ) == 0 );
CPPUNIT_ASSERT( simMgr->negativeCount() == 7 );
}
