// Schedule all the jobs for the simulation step. // Enqueued callbacks can choose to inject additional jobs at defined sync points. public unsafe void ScheduleStepJobs(SimulationStepInput input, JobHandle inputDeps) { if (input.TimeStep < 0) { throw new ArgumentOutOfRangeException(); } if (input.ThreadCountHint <= 0) { throw new ArgumentOutOfRangeException(); } if (input.NumSolverIterations <= 0) { throw new ArgumentOutOfRangeException(); } // Dispose event streams from previous frame JobHandle handle = DisposeEventStreams(inputDeps); // Allocate storage for input velocities m_Storage.InputVelocityCount = input.World.NumDynamicBodies; m_Context = new Context { TimeStep = input.TimeStep, InputVelocities = m_Storage.InputVelocities }; if (input.World.NumDynamicBodies == 0) { // No need to do anything, since nothing can move FinalSimulationJobHandle = handle; FinalJobHandle = handle; return; } SimulationCallbacks callbacks = input.Callbacks ?? new SimulationCallbacks(); // Find all body pairs that overlap in the broadphase handle = input.World.CollisionWorld.Broadphase.ScheduleFindOverlapsJobs( out BlockStream dynamicVsDynamicBodyPairs, out BlockStream dynamicVsStaticBodyPairs, ref m_Context, handle); var postOverlapsHandle = handle; // Sort all overlapping and jointed body pairs into phases handle = m_Scheduler.ScheduleCreatePhasedDispatchPairsJob( ref input.World, ref dynamicVsDynamicBodyPairs, ref dynamicVsStaticBodyPairs, ref m_Context, handle); // Apply gravity and copy input velocities at this point (in parallel with the scheduler, but before the callbacks) var applyGravityAndCopyInputVelocitiesHandle = Solver.ScheduleApplyGravityAndCopyInputVelocitiesJob( ref input.World.DynamicsWorld, m_Storage.InputVelocities, input.TimeStep * input.Gravity, postOverlapsHandle); handle = JobHandle.CombineDependencies(handle, applyGravityAndCopyInputVelocitiesHandle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateDispatchPairs, this, ref input.World, handle); // Create contact points & joint Jacobians handle = NarrowPhase.ScheduleProcessBodyPairsJobs(ref input.World, input.TimeStep, input.NumSolverIterations, ref m_Context, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateContacts, this, ref input.World, handle); // Create contact Jacobians handle = Solver.ScheduleBuildContactJacobiansJobs(ref input.World.DynamicsWorld, input.TimeStep, math.length(input.Gravity), ref m_Context, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateContactJacobians, this, ref input.World, handle); // Solve all Jacobians handle = Solver.ScheduleSolveJacobiansJobs(ref input.World.DynamicsWorld, input.TimeStep, input.NumSolverIterations, ref m_Context, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostSolveJacobians, this, ref input.World, handle); // Integrate motions handle = Integrator.ScheduleIntegrateJobs(ref input.World.DynamicsWorld, input.TimeStep, handle); // Synchronize the collision world if (input.SynchronizeCollisionWorld) { handle = input.World.CollisionWorld.ScheduleUpdateDynamicLayer(ref input.World, input.TimeStep, input.Gravity, input.ThreadCountHint, handle); // TODO: timeStep = 0? } // Return the final simulation handle FinalSimulationJobHandle = handle; // Return the final handle, which includes disposing temporary arrays JobHandle *deps = stackalloc JobHandle[11] { FinalSimulationJobHandle, m_Context.DisposeOverlapPairs0, m_Context.DisposeOverlapPairs1, m_Context.DisposeBroadphasePairs0, m_Context.DisposeBroadphasePairs1, m_Context.DisposeContacts, m_Context.DisposeJacobians, m_Context.DisposeJointJacobians, m_Context.DisposeSolverSchedulerData, m_Context.DisposeProcessBodyPairs, m_Context.DisposePhasedDispatchPairs }; FinalJobHandle = JobHandleUnsafeUtility.CombineDependencies(deps, 11); }
// Steps the simulation immediately on a single thread without spawning any jobs. public static void StepImmediate(SimulationStepInput input, ref SimulationContext simulationContext) { if (input.TimeStep < 0) { throw new ArgumentOutOfRangeException(); } if (input.NumSolverIterations <= 0) { throw new ArgumentOutOfRangeException(); } if (input.World.NumDynamicBodies == 0) { // No need to do anything, since nothing can move return; } // Inform the context of the timeStep simulationContext.TimeStep = input.TimeStep; // Find all body pairs that overlap in the broadphase var dynamicVsDynamicBodyPairs = new NativeStream(1, Allocator.Temp); var dynamicVsStaticBodyPairs = new NativeStream(1, Allocator.Temp); { var dynamicVsDynamicBodyPairsWriter = dynamicVsDynamicBodyPairs.AsWriter(); var dynamicVsStaticBodyPairsWriter = dynamicVsStaticBodyPairs.AsWriter(); input.World.CollisionWorld.FindOverlaps(ref dynamicVsDynamicBodyPairsWriter, ref dynamicVsStaticBodyPairsWriter); } // Create dispatch pairs var dispatchPairs = new NativeList <DispatchPairSequencer.DispatchPair>(Allocator.Temp); DispatchPairSequencer.CreateDispatchPairs(ref dynamicVsDynamicBodyPairs, ref dynamicVsStaticBodyPairs, input.World.NumDynamicBodies, input.World.Joints, ref dispatchPairs); // Apply gravity and copy input velocities Solver.ApplyGravityAndCopyInputVelocities(input.World.DynamicsWorld.MotionDatas, input.World.DynamicsWorld.MotionVelocities, simulationContext.InputVelocities, input.TimeStep * input.Gravity); // Narrow phase var contacts = new NativeStream(1, Allocator.Temp); { var contactsWriter = contacts.AsWriter(); NarrowPhase.CreateContacts(ref input.World, dispatchPairs.AsArray(), input.TimeStep, ref contactsWriter); } // Build Jacobians var jacobians = new NativeStream(1, Allocator.Temp); { var contactsReader = contacts.AsReader(); var jacobiansWriter = jacobians.AsWriter(); Solver.BuildJacobians(ref input.World, input.TimeStep, input.Gravity, input.NumSolverIterations, dispatchPairs.AsArray(), ref contactsReader, ref jacobiansWriter); } // Solve Jacobians { var jacobiansReader = jacobians.AsReader(); var collisionEventsWriter = simulationContext.CollisionEventDataStream.AsWriter(); var triggerEventsWriter = simulationContext.TriggerEventDataStream.AsWriter(); Solver.SolveJacobians(ref jacobiansReader, input.World.DynamicsWorld.MotionVelocities, input.TimeStep, input.NumSolverIterations, ref collisionEventsWriter, ref triggerEventsWriter); } // Integrate motions Integrator.Integrate(input.World.DynamicsWorld.MotionDatas, input.World.DynamicsWorld.MotionVelocities, input.TimeStep); // Synchronize the collision world if asked for if (input.SynchronizeCollisionWorld) { input.World.CollisionWorld.UpdateDynamicTree(ref input.World, input.TimeStep, input.Gravity); } }
// Schedule all the jobs for the simulation step. // Enqueued callbacks can choose to inject additional jobs at defined sync points. // threadCountHint defines which simulation type will be called: // - threadCountHint > 0 will result in default multithreaded simulation // - threadCountHint <=0 will result in a very small number of jobs (1 per physics step phase) that are scheduled sequentially // Behavior doesn't change regardless of the threadCountHint provided. public unsafe SimulationJobHandles ScheduleStepJobs(SimulationStepInput input, SimulationCallbacks callbacksIn, JobHandle inputDeps, int threadCountHint = 0) { if (input.TimeStep < 0) { throw new ArgumentOutOfRangeException(); } if (input.NumSolverIterations <= 0) { throw new ArgumentOutOfRangeException(); } bool singleThreadedSim = (threadCountHint <= 0); // Dispose and reallocate input velocity buffer, if dynamic body count has increased. // Dispose previous collision and trigger event data streams. // New event streams are reallocated later when the work item count is known. JobHandle handle = SimulationContext.ScheduleReset(ref input.World, inputDeps, false); SimulationContext.TimeStep = input.TimeStep; StepContext = new StepContext(); if (input.World.NumDynamicBodies == 0) { // No need to do anything, since nothing can move m_StepHandles = new SimulationJobHandles(handle); return(m_StepHandles); } SimulationCallbacks callbacks = callbacksIn ?? new SimulationCallbacks(); // Find all body pairs that overlap in the broadphase var handles = input.World.CollisionWorld.ScheduleFindOverlapsJobs( out NativeStream dynamicVsDynamicBodyPairs, out NativeStream dynamicVsStaticBodyPairs, handle, threadCountHint); handle = handles.FinalExecutionHandle; var disposeHandle1 = handles.FinalDisposeHandle; var postOverlapsHandle = handle; // Sort all overlapping and jointed body pairs into phases handles = m_Scheduler.ScheduleCreatePhasedDispatchPairsJob( ref input.World, ref dynamicVsDynamicBodyPairs, ref dynamicVsStaticBodyPairs, handle, ref StepContext.PhasedDispatchPairs, out StepContext.SolverSchedulerInfo, threadCountHint); handle = handles.FinalExecutionHandle; var disposeHandle2 = handles.FinalDisposeHandle; // Apply gravity and copy input velocities at this point (in parallel with the scheduler, but before the callbacks) var applyGravityAndCopyInputVelocitiesHandle = Solver.ScheduleApplyGravityAndCopyInputVelocitiesJob( ref input.World.DynamicsWorld, SimulationContext.InputVelocities, input.TimeStep * input.Gravity, singleThreadedSim ? handle : postOverlapsHandle, threadCountHint); handle = JobHandle.CombineDependencies(handle, applyGravityAndCopyInputVelocitiesHandle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateDispatchPairs, this, ref input.World, handle); // Create contact points & joint Jacobians handles = NarrowPhase.ScheduleCreateContactsJobs(ref input.World, input.TimeStep, ref StepContext.Contacts, ref StepContext.Jacobians, ref StepContext.PhasedDispatchPairs, handle, ref StepContext.SolverSchedulerInfo, threadCountHint); handle = handles.FinalExecutionHandle; var disposeHandle3 = handles.FinalDisposeHandle; handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateContacts, this, ref input.World, handle); // Create contact Jacobians handles = Solver.ScheduleBuildJacobiansJobs(ref input.World, input.TimeStep, input.Gravity, input.NumSolverIterations, handle, ref StepContext.PhasedDispatchPairs, ref StepContext.SolverSchedulerInfo, ref StepContext.Contacts, ref StepContext.Jacobians, threadCountHint); handle = handles.FinalExecutionHandle; var disposeHandle4 = handles.FinalDisposeHandle; handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateContactJacobians, this, ref input.World, handle); // Solve all Jacobians handles = Solver.ScheduleSolveJacobiansJobs(ref input.World.DynamicsWorld, input.TimeStep, input.NumSolverIterations, ref StepContext.Jacobians, ref SimulationContext.CollisionEventDataStream, ref SimulationContext.TriggerEventDataStream, ref StepContext.SolverSchedulerInfo, handle, threadCountHint); handle = handles.FinalExecutionHandle; var disposeHandle5 = handles.FinalDisposeHandle; handle = callbacks.Execute(SimulationCallbacks.Phase.PostSolveJacobians, this, ref input.World, handle); // Integrate motions handle = Integrator.ScheduleIntegrateJobs(ref input.World.DynamicsWorld, input.TimeStep, handle, threadCountHint); // Synchronize the collision world if (input.SynchronizeCollisionWorld) { handle = input.World.CollisionWorld.ScheduleUpdateDynamicTree(ref input.World, input.TimeStep, input.Gravity, handle, threadCountHint); // TODO: timeStep = 0? } // Return the final simulation handle m_StepHandles.FinalExecutionHandle = handle; // Different dispose logic for single threaded simulation compared to "standard" threading (multi threaded) if (singleThreadedSim) { handle = dynamicVsDynamicBodyPairs.Dispose(handle); handle = dynamicVsStaticBodyPairs.Dispose(handle); handle = StepContext.PhasedDispatchPairs.Dispose(handle); handle = StepContext.Contacts.Dispose(handle); handle = StepContext.Jacobians.Dispose(handle); handle = StepContext.SolverSchedulerInfo.ScheduleDisposeJob(handle); m_StepHandles.FinalDisposeHandle = handle; } else { // Return the final handle, which includes disposing temporary arrays JobHandle *deps = stackalloc JobHandle[5] { disposeHandle1, disposeHandle2, disposeHandle3, disposeHandle4, disposeHandle5 }; m_StepHandles.FinalDisposeHandle = JobHandleUnsafeUtility.CombineDependencies(deps, 5); } return(m_StepHandles); }
// Schedule all the jobs for the simulation step. // Enqueued callbacks can choose to inject additional jobs at defined sync points. public void ScheduleStepJobs(SimulationStepInput input, JobHandle inputDeps, out JobHandle finalSimulationJobHandle, out JobHandle finalJobHandle) { // Dispose event streams from previous frame DisposeEventStreams(); m_Context = new Context(); if (input.World.NumDynamicBodies == 0) { // No need to do anything, since nothing can move finalSimulationJobHandle = new JobHandle(); finalJobHandle = new JobHandle(); return; } SimulationCallbacks callbacks = input.Callbacks ?? new SimulationCallbacks(); JobHandle handle = inputDeps; // We need to make sure that broadphase tree building is done before we schedule FindOverlapsJobs. handle.Complete(); // Find all body pairs that overlap in the broadphase handle = input.World.CollisionWorld.Broadphase.ScheduleFindOverlapsJobs( out BlockStream dynamicVsDynamicBroadphasePairsStream, out BlockStream staticVsDynamicBroadphasePairsStream, handle); handle.Complete(); // Need to know the total number of pairs before continuing // Create phased dispatch pairs for all interacting body pairs handle = m_Scheduler.ScheduleCreatePhasedDispatchPairsJob( ref input.World, ref dynamicVsDynamicBroadphasePairsStream, ref staticVsDynamicBroadphasePairsStream, ref m_Context, handle); handle.Complete(); // Need to know the total number of work items before continuing handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateDispatchPairs, this, handle); m_Context.CreateBodyPairsHandle = handle; // Create contact points & joint Jacobians handle = NarrowPhase.ScheduleProcessBodyPairsJobs(ref input.World, input.TimeStep, input.NumSolverIterations, ref m_Context, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateContacts, this, handle); m_Context.CreateContactsHandle = handle; // Create contact Jacobians handle = Solver.ScheduleBuildContactJacobiansJobs(ref input.World.DynamicsWorld, input.TimeStep, ref m_Context, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostCreateContactJacobians, this, handle); m_Context.CreateContactJacobiansHandle = handle; // Solve all Jacobians int numIterations = input.NumSolverIterations > 0 ? input.NumSolverIterations : 4; handle = Solver.ScheduleSolveJacobiansJobs(ref input.World.DynamicsWorld, input.TimeStep, input.Gravity, numIterations, ref m_Context, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostSolveJacobians, this, handle); m_Context.SolveContactJacobiansHandle = handle; // Integration motions handle = Integrator.ScheduleIntegrateJobs(ref input.World.DynamicsWorld, input.TimeStep, input.Gravity, handle); handle = callbacks.Execute(SimulationCallbacks.Phase.PostIntegrateMotions, this, handle); m_Context.IntegrateMotionsHandle = handle; // Synchronize the collision world if (input.SynchronizeCollisionWorld) { handle = input.World.CollisionWorld.ScheduleUpdateDynamicLayer(ref input.World, input.TimeStep, input.ThreadCountHint, handle); // TODO: timeStep = 0? } // Return the final simulation handle finalSimulationJobHandle = handle; // Return the final handle, which includes disposing temporary arrays finalJobHandle = JobHandle.CombineDependencies(finalSimulationJobHandle, m_Context.DisposeBroadphasePairs, m_Context.DisposeContacts); finalJobHandle = JobHandle.CombineDependencies(finalJobHandle, m_Context.DisposeJacobians, m_Context.DisposeJointJacobians); finalJobHandle = JobHandle.CombineDependencies(finalJobHandle, m_Context.DisposeSolverSchedulerData); }