Exemplo n.º 1
0
bool UPrimitiveComponent::WeldToImplementation(USceneComponent * InParent, FName ParentSocketName /* = Name_None */, bool bWeldSimulatedChild /* = false */)
{
	//WeldToInternal assumes attachment is already done
	if (AttachParent != InParent || AttachSocketName != ParentSocketName)
	{
		return false;
	}

	//Check that we can actually our own socket name
	FBodyInstance* BI = GetBodyInstance(NAME_None, false);
	if (BI == NULL)
	{
		return false;
	}

	if (BI->ShouldInstanceSimulatingPhysics() && bWeldSimulatedChild == false)
	{
		return false;
	}

	UnWeldFromParent();	//make sure to unweld from wherever we currently are

	FName SocketName;
	UPrimitiveComponent * RootComponent = GetRootWelded(this, ParentSocketName, &SocketName, true);

	if (RootComponent)
	{
		if (FBodyInstance* RootBI = RootComponent->GetBodyInstance(SocketName, false))
		{
			if (BI->WeldParent == RootBI)	//already welded so stop
			{
				return true;
			}

			BI->bWelded = true;
			//There are multiple cases to handle:
			//Root is kinematic, simulated
			//Child is kinematic, simulated
			//Child always inherits from root

			//if root is kinematic simply set child to be kinematic and we're done
			if (RootComponent->IsSimulatingPhysics(SocketName) == false)
			{
				BI->WeldParent = NULL;
				SetSimulatePhysics(false);
				return false;	//return false because we need to continue with regular body initialization
			}

			//root is simulated so we actually weld the body
			FTransform RelativeTM = RootComponent == AttachParent ? GetRelativeTransform() : GetComponentToWorld().GetRelativeTransform(RootComponent->GetComponentToWorld());	//if direct parent we already have relative. Otherwise compute it
			RootBI->Weld(BI, GetComponentToWorld());
			BI->WeldParent = RootBI;

			return true;
		}
	}

	return false;
}
FBodyInstance* UPhysicsConstraintComponent::GetBodyInstance(EConstraintFrame::Type Frame) const
{
	FBodyInstance* Instance = NULL;
	UPrimitiveComponent* PrimComp = GetComponentInternal(Frame);
	if(PrimComp != NULL)
	{
		if(Frame == EConstraintFrame::Frame1)
		{
			Instance = PrimComp->GetBodyInstance(ConstraintInstance.ConstraintBone1);
		}
		else
		{
			Instance = PrimComp->GetBodyInstance(ConstraintInstance.ConstraintBone2);
		}
	}
	return Instance;
}
bool UGripMotionControllerComponent::TeleportMoveGrippedActor(AActor * GrippedActorToMove)
{
	if (!GrippedActorToMove || !GrippedActors.Num())
		return false;

	FTransform WorldTransform;
	FTransform InverseTransform = this->GetComponentTransform().Inverse();
	for (int i = GrippedActors.Num() - 1; i >= 0; --i)
	{
		if (GrippedActors[i].Actor == GrippedActorToMove)
		{
			// GetRelativeTransformReverse had some serious f*****g floating point errors associated with it that was f*****g everything up
			// Not sure whats wrong with the function but I might want to push a patch out eventually
			WorldTransform = GrippedActors[i].RelativeTransform.GetRelativeTransform(InverseTransform);

			// Need to use WITH teleport for this function so that the velocity isn't updated and without sweep so that they don't collide
			GrippedActors[i].Actor->SetActorTransform(WorldTransform, false, NULL, ETeleportType::TeleportPhysics);
			
			FBPActorPhysicsHandleInformation * Handle = GetPhysicsGrip(GrippedActors[i]);
			if (Handle && Handle->KinActorData)
			{

				{
					PxScene* PScene = GetPhysXSceneFromIndex(Handle->SceneIndex);
					if (PScene)
					{
						SCOPED_SCENE_WRITE_LOCK(PScene);
						Handle->KinActorData->setKinematicTarget(PxTransform(U2PVector(WorldTransform.GetLocation()), Handle->KinActorData->getGlobalPose().q));
						Handle->KinActorData->setGlobalPose(PxTransform(U2PVector(WorldTransform.GetLocation()), Handle->KinActorData->getGlobalPose().q));
					}
				}
				//Handle->KinActorData->setGlobalPose(PxTransform(U2PVector(WorldTransform.GetLocation()), Handle->KinActorData->getGlobalPose().q));

				UPrimitiveComponent *root = Cast<UPrimitiveComponent>(GrippedActors[i].Actor->GetRootComponent());
				if (root)
				{
					FBodyInstance * body = root->GetBodyInstance();
					if (body)
					{
						body->SetBodyTransform(WorldTransform, ETeleportType::TeleportPhysics);
					}
				}
			}
			
			return true;
		}
	}

	return false;
}
Exemplo n.º 4
0
UPrimitiveComponent * GetRootWelded(const UPrimitiveComponent* PrimComponent, FName ParentSocketName = NAME_None, FName* OutSocketName = NULL, bool bAboutToWeld = false)
{
	UPrimitiveComponent * Result = NULL;
	UPrimitiveComponent * RootComponent = Cast<UPrimitiveComponent>(PrimComponent->AttachParent);	//we must find the root component along hierarchy that has bWelded set to true

	//check that body itself is welded
	if (FBodyInstance* BI = PrimComponent->GetBodyInstance(ParentSocketName, false))
	{
		if (bAboutToWeld == false && BI->bWelded == false && BI->bAutoWeld == false)	//we're not welded and we aren't trying to become welded
		{
			return NULL;
		}
	}

	FName PrevSocketName = ParentSocketName;
	FName SocketName = NAME_None; //because of skeletal mesh it's important that we check along the bones that we attached
	FBodyInstance* RootBI = NULL;
	for (; RootComponent; RootComponent = Cast<UPrimitiveComponent>(RootComponent->AttachParent))
	{
		Result = RootComponent;
		SocketName = PrevSocketName;
		PrevSocketName = RootComponent->AttachSocketName;

		RootBI = RootComponent->GetBodyInstance(SocketName, false);
		if (RootBI && RootBI->bWelded)
		{
			continue;
		}

		break;
	}

	if (OutSocketName)
	{
		*OutSocketName = SocketName;
	}

	return Result;
}
Exemplo n.º 5
0
void UPrimitiveComponent::UnWeldFromParent()
{
	FBodyInstance* NewRootBI = GetBodyInstance(NAME_None, false);
	UWorld* CurrentWorld = GetWorld();
	if (NewRootBI == NULL || NewRootBI->bWelded == false || CurrentWorld == nullptr || IsPendingKill())
	{
		return;
	}

	FName SocketName;
	UPrimitiveComponent * RootComponent = GetRootWelded(this, AttachSocketName, &SocketName);

	if (RootComponent)
	{
		if (FBodyInstance* RootBI = RootComponent->GetBodyInstance(SocketName, false))
		{
			bool bRootIsBeingDeleted = RootComponent->HasAnyFlags(RF_PendingKill) || RootComponent->HasAnyFlags(RF_Unreachable);
			if (!bRootIsBeingDeleted)
			{
				//create new root
				RootBI->UnWeld(NewRootBI);	//don't bother fixing up shapes if RootComponent is about to be deleted
			}

			NewRootBI->bWelded = false;
			const FBodyInstance* PrevWeldParent = NewRootBI->WeldParent;
			NewRootBI->WeldParent = nullptr;

			bool bHasBodySetup = GetBodySetup() != nullptr;

			//if BodyInstance hasn't already been created we need to initialize it
			if (bHasBodySetup && NewRootBI->IsValidBodyInstance() == false)
			{
				bool bPrevAutoWeld = NewRootBI->bAutoWeld;
				NewRootBI->bAutoWeld = false;
				NewRootBI->InitBody(GetBodySetup(), GetComponentToWorld(), this, CurrentWorld->GetPhysicsScene());
				NewRootBI->bAutoWeld = bPrevAutoWeld;
			}

			if(PrevWeldParent == nullptr)	//our parent is kinematic so no need to do any unwelding/rewelding of children
			{
				return;
			}

			//now weld its children to it
			TArray<FBodyInstance*> ChildrenBodies;
			TArray<FName> ChildrenLabels;
			GetWeldedBodies(ChildrenBodies, ChildrenLabels);

			for (int32 ChildIdx = 0; ChildIdx < ChildrenBodies.Num(); ++ChildIdx)
			{
				FBodyInstance* ChildBI = ChildrenBodies[ChildIdx];
				if (ChildBI != NewRootBI)
				{
					if (!bRootIsBeingDeleted)
					{
						RootBI->UnWeld(ChildBI);
					}

					//At this point, NewRootBI must be kinematic because it's being unwelded. It's up to the code that simulates to call Weld on the children as needed
					ChildBI->WeldParent = nullptr;	//null because we are currently kinematic
				}
			}
		}
	}
}
void UGripMotionControllerComponent::PostTeleportMoveGrippedActors()
{
	if (!GrippedActors.Num())
		return;

	FTransform WorldTransform;
	FTransform InverseTransform = this->GetComponentTransform().Inverse();
	for (int i = GrippedActors.Num() - 1; i >= 0; --i)
	{
		// GetRelativeTransformReverse had some serious f*****g floating point errors associated with it that was f*****g everything up
		// Not sure whats wrong with the function but I might want to push a patch out eventually
		WorldTransform = GrippedActors[i].RelativeTransform.GetRelativeTransform(InverseTransform);

		if (GrippedActors[i].Actor)
		{
			// Need to use WITH teleport for this function so that the velocity isn't updated and without sweep so that they don't collide
			GrippedActors[i].Actor->SetActorTransform(WorldTransform, false, NULL, ETeleportType::TeleportPhysics);
		}
		else if (GrippedActors[i].Component)
		{
			// Need to use WITH teleport for this function so that the velocity isn't updated and without sweep so that they don't collide
			GrippedActors[i].Component->SetWorldTransform(WorldTransform, false, NULL, ETeleportType::TeleportPhysics);
		}

		FBPActorPhysicsHandleInformation * Handle = GetPhysicsGrip(GrippedActors[i]);
		if (Handle && Handle->KinActorData)
		{
			{
				PxScene* PScene = GetPhysXSceneFromIndex(Handle->SceneIndex);
				if (PScene)
				{
					SCOPED_SCENE_WRITE_LOCK(PScene);
					Handle->KinActorData->setKinematicTarget(PxTransform(U2PVector(WorldTransform.GetLocation()), Handle->KinActorData->getGlobalPose().q));
					Handle->KinActorData->setGlobalPose(PxTransform(U2PVector(WorldTransform.GetLocation()), Handle->KinActorData->getGlobalPose().q));
				}
			}
			//Handle->KinActorData->setGlobalPose(PxTransform(U2PVector(WorldTransform.GetLocation()), Handle->KinActorData->getGlobalPose().q));

			if (GrippedActors[i].Actor)
			{
				UPrimitiveComponent *root = Cast<UPrimitiveComponent>(GrippedActors[i].Actor->GetRootComponent());
				if (root)
				{
					FBodyInstance * body = root->GetBodyInstance();
					if (body)
					{
						body->SetBodyTransform(WorldTransform, ETeleportType::TeleportPhysics);
					}
				}
			}
			else if (GrippedActors[i].Component)
			{
				FBodyInstance * body = GrippedActors[i].Component->GetBodyInstance();
				if (body)
				{
					body->SetBodyTransform(WorldTransform, ETeleportType::TeleportPhysics);
				}
			}
		}
		/*else
		{
			if (bIsServer)
			{
				DestroyPhysicsHandle(GrippedActors[i]);
				GrippedActors.RemoveAt(i); // If it got garbage collected then just remove the pointer, won't happen with new uproperty use, but keeping it here anyway
			}
		}*/
	}
}
bool UGripMotionControllerComponent::SetUpPhysicsHandle(const FBPActorGripInformation &NewGrip)
{
	UPrimitiveComponent *root = NewGrip.Component;
	if(!root)
		root = Cast<UPrimitiveComponent>(NewGrip.Actor->GetRootComponent());
	
	if (!root)
		return false;

	// Needs to be simulating in order to run physics
	root->SetSimulatePhysics(true);
	root->SetEnableGravity(false);

	FBPActorPhysicsHandleInformation * HandleInfo = CreatePhysicsGrip(NewGrip);

#if WITH_PHYSX
	// Get the PxRigidDynamic that we want to grab.
	FBodyInstance* BodyInstance = root->GetBodyInstance(NAME_None/*InBoneName*/);
	if (!BodyInstance)
	{
		return false;
	}

	ExecuteOnPxRigidDynamicReadWrite(BodyInstance, [&](PxRigidDynamic* Actor)
	{
		PxScene* Scene = Actor->getScene();
	
		// Get transform of actor we are grabbing

		FTransform WorldTransform;
		FTransform InverseTransform = this->GetComponentTransform().Inverse();
		WorldTransform = NewGrip.RelativeTransform.GetRelativeTransform(InverseTransform);

		PxVec3 KinLocation = U2PVector(WorldTransform.GetLocation() - (WorldTransform.GetLocation() - root->GetComponentLocation()));
		PxTransform GrabbedActorPose = Actor->getGlobalPose();
		PxTransform KinPose(KinLocation, GrabbedActorPose.q);

		// set target and current, so we don't need another "Tick" call to have it right
		//TargetTransform = CurrentTransform = P2UTransform(KinPose);

		// If we don't already have a handle - make one now.
		if (!HandleInfo->HandleData)
		{
			// Create kinematic actor we are going to create joint with. This will be moved around with calls to SetLocation/SetRotation.
			PxRigidDynamic* KinActor = Scene->getPhysics().createRigidDynamic(KinPose);
			KinActor->setRigidDynamicFlag(PxRigidDynamicFlag::eKINEMATIC, true);
			KinActor->setMass(0.0f); // 1.0f;
			KinActor->setMassSpaceInertiaTensor(PxVec3(0.0f, 0.0f, 0.0f));// PxVec3(1.0f, 1.0f, 1.0f));
			KinActor->setMaxDepenetrationVelocity(PX_MAX_F32);

			// No bodyinstance
			KinActor->userData = NULL;
			
			// Add to Scene
			Scene->addActor(*KinActor);

			// Save reference to the kinematic actor.
			HandleInfo->KinActorData = KinActor;

			// Create the joint
			PxVec3 LocalHandlePos = GrabbedActorPose.transformInv(KinLocation);
			PxD6Joint* NewJoint = PxD6JointCreate(Scene->getPhysics(), KinActor, PxTransform::createIdentity(), Actor, PxTransform(LocalHandlePos));
			
			if (!NewJoint)
			{
				HandleInfo->HandleData = 0;
			}
			else
			{
				// No constraint instance
				NewJoint->userData = NULL;
				HandleInfo->HandleData = NewJoint;

				// Remember the scene index that the handle joint/actor are in.
				FPhysScene* RBScene = FPhysxUserData::Get<FPhysScene>(Scene->userData);
				const uint32 SceneType = root->BodyInstance.UseAsyncScene(RBScene) ? PST_Async : PST_Sync;
				HandleInfo->SceneIndex = RBScene->PhysXSceneIndex[SceneType];
				
				// Setting up the joint
				NewJoint->setMotion(PxD6Axis::eX, PxD6Motion::eFREE);
				NewJoint->setMotion(PxD6Axis::eY, PxD6Motion::eFREE);
				NewJoint->setMotion(PxD6Axis::eZ, PxD6Motion::eFREE);
				NewJoint->setDrivePosition(PxTransform(PxVec3(0, 0, 0)));

				NewJoint->setMotion(PxD6Axis::eTWIST, PxD6Motion::eFREE);
				NewJoint->setMotion(PxD6Axis::eSWING1, PxD6Motion::eFREE);
				NewJoint->setMotion(PxD6Axis::eSWING2, PxD6Motion::eFREE);

				//UpdateDriveSettings();
				if (HandleInfo->HandleData != nullptr)
				{
					HandleInfo->HandleData->setDrive(PxD6Drive::eX, PxD6JointDrive(NewGrip.Stiffness, NewGrip.Damping, PX_MAX_F32, PxD6JointDriveFlag::eACCELERATION));
					HandleInfo->HandleData->setDrive(PxD6Drive::eY, PxD6JointDrive(NewGrip.Stiffness, NewGrip.Damping, PX_MAX_F32, PxD6JointDriveFlag::eACCELERATION));
					HandleInfo->HandleData->setDrive(PxD6Drive::eZ, PxD6JointDrive(NewGrip.Stiffness, NewGrip.Damping, PX_MAX_F32, PxD6JointDriveFlag::eACCELERATION));

					HandleInfo->HandleData->setDrive(PxD6Drive::eSLERP, PxD6JointDrive(NewGrip.Stiffness, NewGrip.Damping, PX_MAX_F32, PxD6JointDriveFlag::eACCELERATION));

						//HandleData->setDrive(PxD6Drive::eTWIST, PxD6JointDrive(Stiffness, Damping, PX_MAX_F32, PxD6JointDriveFlag::eACCELERATION));
						//HandleData->setDrive(PxD6Drive::eSWING, PxD6JointDrive(Stiffness, Damping, PX_MAX_F32, PxD6JointDriveFlag::eACCELERATION));
				}
			}
		}
	});
#else
	return false;
#endif // WITH_PHYSX

	return true;
}