public IEnumerator TestPerformanceOnLargeGraphBudget10()
{
var planGraph = PlanGraphUtility.BuildLattice(midLatticeDepth: 10);
var nodeCount = planGraph.Size;
var depthMap = new NativeHashMap <int, int>(nodeCount, Allocator.TempJob);
var queue = new NativeQueue <StateHorizonPair <int> >(Allocator.TempJob);
planGraph.GetExpandedDepthMap(0, depthMap, queue);
var selectedUnexpandedStates = new NativeList <int>(1, Allocator.Persistent);
var allExpandedStates = new NativeMultiHashMap <int, int>(1, Allocator.Persistent);
yield return(null);
// Set up performance test
Measure.Method(() =>
{
var selectJob = new SelectionJob <int, int>()
{
StateExpansionBudget = 10,
RootStateKey = 0,
StateDepthLookup = depthMap,
StateInfoLookup = planGraph.StateInfoLookup,
ActionLookup = planGraph.ActionLookup,
ActionInfoLookup = planGraph.ActionInfoLookup,
ResultingStateLookup = planGraph.ResultingStateLookup,
StateTransitionInfoLookup = planGraph.StateTransitionInfoLookup,
SelectedUnexpandedStates = selectedUnexpandedStates,
AllSelectedStates = allExpandedStates
};
selectJob.Schedule().Complete();
}).WarmupCount(1).MeasurementCount(1).IterationsPerMeasurement(1).CleanUp(() =>
{
depthMap.Clear();
queue.Clear();
planGraph.GetExpandedDepthMap(0, depthMap, queue);
selectedUnexpandedStates.Clear();
allExpandedStates.Clear();
}).Run();
queue.Dispose();
depthMap.Dispose();
planGraph.Dispose();
selectedUnexpandedStates.Dispose();
allExpandedStates.Dispose();
// Check performance times
PerformanceUtility.AssertRange(0.00, 5);
}
public void MatchManyExistingStates()
{
const int kRootState = 0;
const int kActionCount = 1000;
PlanGraph <int, StateInfo, int, ActionInfo, StateTransitionInfo> planGraph = default;
NativeMultiHashMap <int, int> binnedStateKeys = default;
NativeQueue <int> newStatesQueue = default;
NativeList <StateTransitionInfoPair <int, int, StateTransitionInfo> > statesToProcess = default;
NativeQueue <int> newStatesToDestroy = default;
Measure.Method(() =>
{
var stateTransitionInfoLookup = planGraph.StateTransitionInfoLookup;
var resultingStateLookup = planGraph.ResultingStateLookup;
var expansionJob = new GraphExpansionJob <int, int, TestStateDataContext, int>
{
BinnedStateKeys = binnedStateKeys,
NewStateTransitionInfoPairs = statesToProcess.AsDeferredJobArray(),
ActionLookup = planGraph.ActionLookup.AsParallelWriter(),
ActionInfoLookup = planGraph.ActionInfoLookup.AsParallelWriter(),
StateTransitionInfoLookup = stateTransitionInfoLookup.AsParallelWriter(),
ResultingStateLookup = resultingStateLookup.AsParallelWriter(),
NewStates = newStatesQueue.AsParallelWriter(),
PredecessorGraph = planGraph.PredecessorGraph.AsParallelWriter(),
StateDataContext = new TestStateDataContext(),
StatesToDestroy = newStatesToDestroy.AsParallelWriter(),
};
expansionJob.Schedule(statesToProcess, default).Complete();
}).SetUp(() =>
{
// One root node and all children nodes of a single depth
planGraph = PlanGraphUtility.BuildTree(kActionCount, 1, 1);
planGraph.ExpandBy(kActionCount, kActionCount);
newStatesQueue = new NativeQueue <int>(Allocator.TempJob);
newStatesToDestroy = new NativeQueue <int>(Allocator.TempJob);
// Extend graph by one depth with the same number of actions / resulting states that loop back on themselves
statesToProcess = new NativeList <StateTransitionInfoPair <int, int, StateTransitionInfo> >(kActionCount, Allocator.TempJob);
for (var i = 0; i < kActionCount; i++)
{
statesToProcess.Add(new StateTransitionInfoPair <int, int, StateTransitionInfo>(kRootState, i, i, new StateTransitionInfo()
{
Probability = 1, TransitionUtilityValue = 1
}));
}
binnedStateKeys = GetBinnedStateKeys(planGraph);
}).CleanUp(() =>
{
planGraph.Dispose();
newStatesQueue.Dispose();
statesToProcess.Dispose();
binnedStateKeys.Dispose();
newStatesToDestroy.Dispose();
}).WarmupCount(1).MeasurementCount(30).IterationsPerMeasurement(1).Run();
PerformanceUtility.AssertRange(4.3, 6.25);
}