/** {@inheritDoc} */
@Override
public void onCollision(
Collection<GridCollisionJobContext> waitJobs,
Collection<GridCollisionJobContext> activeJobs) {
assert waitJobs != null;
assert activeJobs != null;
int activeSize = F.size(activeJobs, RUNNING_JOBS);
waitingCnt.set(waitJobs.size());
runningCnt.set(activeSize);
heldCnt.set(activeJobs.size() - activeSize);
int waitSize = waitJobs.size();
int activateCnt = parallelJobsNum - activeSize;
if (activateCnt > 0 && !waitJobs.isEmpty()) {
if (waitJobs.size() <= activateCnt) {
for (GridCollisionJobContext waitJob : waitJobs) {
waitJob.activate();
waitSize--;
}
} else {
List<GridCollisionJobContext> passiveList =
new ArrayList<GridCollisionJobContext>(waitJobs);
Collections.sort(
passiveList,
new Comparator<GridCollisionJobContext>() {
/** {@inheritDoc} */
@Override
public int compare(GridCollisionJobContext o1, GridCollisionJobContext o2) {
int p1 = getJobPriority(o1);
int p2 = getJobPriority(o2);
return p1 < p2 ? 1 : p1 == p2 ? 0 : -1;
}
});
if (preventStarvation) bumpPriority(waitJobs, passiveList);
for (int i = 0; i < activateCnt; i++) {
passiveList.get(i).activate();
waitSize--;
}
}
}
if (waitSize > waitJobsNum) {
List<GridCollisionJobContext> waitList = new ArrayList<GridCollisionJobContext>(waitJobs);
// Put jobs with highest priority first.
Collections.sort(
waitList,
new Comparator<GridCollisionJobContext>() {
/** {@inheritDoc} */
@Override
public int compare(GridCollisionJobContext o1, GridCollisionJobContext o2) {
int p1 = getJobPriority(o1);
int p2 = getJobPriority(o2);
return p1 < p2 ? 1 : p1 == p2 ? 0 : -1;
}
});
int skip = waitJobs.size() - waitSize;
int i = 0;
for (GridCollisionJobContext waitCtx : waitList) {
if (++i >= skip) {
waitCtx.cancel();
if (--waitSize <= waitJobsNum) break;
}
}
}
}
/** {@inheritDoc} */
@Override
protected List<String> getConsistentAttributeNames() {
return Collections.singletonList(createSpiAttributeName(PRIORITY_ATTRIBUTE_KEY));
}
/** @throws Exception If failed. */
public void testEmptyProjections() throws Exception {
final GridClientCompute dflt = client.compute();
Collection<? extends GridClientNode> nodes = dflt.nodes();
assertEquals(NODES_CNT, nodes.size());
Iterator<? extends GridClientNode> iter = nodes.iterator();
final GridClientCompute singleNodePrj = dflt.projection(Collections.singletonList(iter.next()));
final GridClientNode second = iter.next();
final GridClientPredicate<GridClientNode> noneFilter =
new GridClientPredicate<GridClientNode>() {
@Override
public boolean apply(GridClientNode node) {
return false;
}
};
final GridClientPredicate<GridClientNode> targetFilter =
new GridClientPredicate<GridClientNode>() {
@Override
public boolean apply(GridClientNode node) {
return node.nodeId().equals(second.nodeId());
}
};
GridTestUtils.assertThrows(
log(),
new Callable<Object>() {
@Override
public Object call() throws Exception {
return dflt.projection(noneFilter).log(-1, -1);
}
},
GridServerUnreachableException.class,
null);
GridTestUtils.assertThrows(
log(),
new Callable<Object>() {
@Override
public Object call() throws Exception {
return singleNodePrj.projection(second);
}
},
GridClientException.class,
null);
GridTestUtils.assertThrows(
log(),
new Callable<Object>() {
@Override
public Object call() throws Exception {
return singleNodePrj.projection(targetFilter);
}
},
GridClientException.class,
null);
}
