Exemple #1
0
	virtual CMatrix3D GetInterpolatedTransform(float frameOffset, bool forceFloating)
	{
		if (!m_InWorld)
		{
			LOGERROR(L"CCmpPosition::GetInterpolatedTransform called on entity when IsInWorld is false");
			CMatrix3D m;
			m.SetIdentity();
			return m;
		}

		float x, z, rotY;
		GetInterpolatedPosition2D(frameOffset, x, z, rotY);

		float baseY = 0;
		if (m_RelativeToGround)
		{
			CmpPtr<ICmpTerrain> cmpTerrain(GetSimContext(), SYSTEM_ENTITY);
			if (cmpTerrain)
				baseY = cmpTerrain->GetExactGroundLevel(x, z);

			if (m_Floating || forceFloating)
			{
				CmpPtr<ICmpWaterManager> cmpWaterManager(GetSimContext(), SYSTEM_ENTITY);
				if (cmpWaterManager)
					baseY = std::max(baseY, cmpWaterManager->GetExactWaterLevel(x, z));
			}
		}

		float y = baseY + m_YOffset.ToFloat();

		// TODO: do something with m_AnchorType

		CMatrix3D m;
		CMatrix3D mXZ;
		float Cos = cosf(rotY);
		float Sin = sinf(rotY);

		m.SetIdentity();
		m._11 = -Cos;
		m._13 = -Sin;
		m._31 = Sin;
		m._33 = -Cos;

		mXZ.SetIdentity();
		mXZ.SetXRotation(m_RotX.ToFloat());
		mXZ.RotateZ(m_RotZ.ToFloat());
		// TODO: is this all done in the correct order?
		mXZ = m * mXZ;
		mXZ.Translate(CVector3D(x, y, z));

		return mXZ;
	}
Exemple #2
0
	virtual void HandleMessage(const CMessage& msg, bool UNUSED(global))
	{
		switch (msg.GetType())
		{
		case MT_Interpolate:
		{
			const CMessageInterpolate& msgData = static_cast<const CMessageInterpolate&> (msg);

			float rotY = m_RotY.ToFloat();
			float delta = rotY - m_InterpolatedRotY;
			// Wrap delta to -M_PI..M_PI
			delta = fmodf(delta + (float)M_PI, 2*(float)M_PI); // range -2PI..2PI
			if (delta < 0) delta += 2*(float)M_PI; // range 0..2PI
			delta -= (float)M_PI; // range -M_PI..M_PI
			// Clamp to max rate
			float deltaClamped = clamp(delta, -m_RotYSpeed*msgData.deltaSimTime, +m_RotYSpeed*msgData.deltaSimTime);
			// Calculate new orientation, in a peculiar way in order to make sure the
			// result gets close to m_orientation (rather than being n*2*M_PI out)
			m_InterpolatedRotY = rotY + deltaClamped - delta;

			break;
		}
		case MT_TurnStart:
		{
			// Store the positions from the turn before
			m_PrevX = m_LastX;
			m_PrevZ = m_LastZ;
			
			m_LastX = m_X;
			m_LastZ = m_Z;

			break;
		}
		}
	}
Exemple #3
0
	virtual void SetYRotation(entity_angle_t y)
	{
		m_RotY = y;
		m_InterpolatedRotY = m_RotY.ToFloat();

		AdvertisePositionChanges();
	}
Exemple #4
0
	virtual void SetYRotation(entity_angle_t y)
	{
		m_RotY = y;
		m_InterpolatedRotY = m_RotY.ToFloat();

		if (m_InWorld)
		{
			UpdateXZRotation();

			m_LastInterpolatedRotX = m_InterpolatedRotX;
			m_LastInterpolatedRotZ = m_InterpolatedRotZ;
		}

		AdvertisePositionChanges();
	}
Exemple #5
0
	virtual void Deserialize(const CParamNode& paramNode, IDeserializer& deserialize)
	{
		Init(paramNode);

		deserialize.Bool("in world", m_InWorld);
		if (m_InWorld)
		{
			deserialize.NumberFixed_Unbounded("x", m_X);
			deserialize.NumberFixed_Unbounded("z", m_Z);
			deserialize.NumberFixed_Unbounded("last x", m_LastX);
			deserialize.NumberFixed_Unbounded("last z", m_LastZ);
		}
		deserialize.NumberFixed_Unbounded("rot x", m_RotX);
		deserialize.NumberFixed_Unbounded("rot y", m_RotY);
		deserialize.NumberFixed_Unbounded("rot z", m_RotZ);
		deserialize.NumberFixed_Unbounded("altitude", m_YOffset);
		deserialize.Bool("relative", m_RelativeToGround);
		// TODO: should there be range checks on all these values?

		m_InterpolatedRotY = m_RotY.ToFloat();
	}
Exemple #6
0
	virtual void SetYRotation(entity_angle_t y)
	{
		if (m_TurretParent != INVALID_ENTITY)
		{
			CmpPtr<ICmpPosition> cmpPosition(GetSimContext(), m_TurretParent);
			if (cmpPosition)
				y -= cmpPosition->GetRotation().Y;
		}
		m_RotY = y;
		m_InterpolatedRotY = m_RotY.ToFloat();

		if (m_InWorld)
		{
			UpdateXZRotation();

			m_LastInterpolatedRotX = m_InterpolatedRotX;
			m_LastInterpolatedRotZ = m_InterpolatedRotZ;
		}

		AdvertisePositionChanges();
		UpdateMessageSubscriptions();
	}
Exemple #7
0
	virtual void Deserialize(const CParamNode& paramNode, IDeserializer& deserialize)
	{
		Init(paramNode);

		deserialize.Bool("in world", m_InWorld);
		if (m_InWorld)
		{
			deserialize.NumberFixed_Unbounded("x", m_X);
			deserialize.NumberFixed_Unbounded("y", m_Y);
			deserialize.NumberFixed_Unbounded("z", m_Z);
			deserialize.NumberFixed_Unbounded("last x", m_LastX);
			deserialize.NumberFixed_Unbounded("last y diff", m_LastYDifference);
			deserialize.NumberFixed_Unbounded("last z", m_LastZ);
		}
		deserialize.NumberI32_Unbounded("territory", m_Territory);
		deserialize.NumberFixed_Unbounded("rot x", m_RotX);
		deserialize.NumberFixed_Unbounded("rot y", m_RotY);
		deserialize.NumberFixed_Unbounded("rot z", m_RotZ);
		deserialize.NumberFixed_Unbounded("altitude", m_Y);
		deserialize.Bool("relative", m_RelativeToGround);
		deserialize.Bool("floating", m_Floating);
		deserialize.NumberFixed_Unbounded("constructionprogress", m_ConstructionProgress);
		// TODO: should there be range checks on all these values?

		m_InterpolatedRotY = m_RotY.ToFloat();

		deserialize.NumberU32_Unbounded("turret parent", m_TurretParent);
		if (m_TurretParent != INVALID_ENTITY)
		{
			deserialize.NumberFixed_Unbounded("x", m_TurretPosition.X);
			deserialize.NumberFixed_Unbounded("y", m_TurretPosition.Y);
			deserialize.NumberFixed_Unbounded("z", m_TurretPosition.Z);
		}

		if (m_InWorld)
			UpdateXZRotation();

		UpdateMessageSubscriptions();
	}
Exemple #8
0
	virtual void HandleMessage(const CMessage& msg, bool UNUSED(global))
	{
		switch (msg.GetType())
		{
		case MT_Interpolate:
		{
			PROFILE("Position::Interpolate");

			const CMessageInterpolate& msgData = static_cast<const CMessageInterpolate&> (msg);

			float rotY = m_RotY.ToFloat();

			if (rotY != m_InterpolatedRotY)
			{
				float delta = rotY - m_InterpolatedRotY;
				// Wrap delta to -M_PI..M_PI
				delta = fmodf(delta + (float)M_PI, 2*(float)M_PI); // range -2PI..2PI
				if (delta < 0) delta += 2*(float)M_PI; // range 0..2PI
				delta -= (float)M_PI; // range -M_PI..M_PI
				// Clamp to max rate
				float deltaClamped = clamp(delta, -m_RotYSpeed*msgData.deltaSimTime, +m_RotYSpeed*msgData.deltaSimTime);
				// Calculate new orientation, in a peculiar way in order to make sure the
				// result gets close to m_orientation (rather than being n*2*M_PI out)
				m_InterpolatedRotY = rotY + deltaClamped - delta;

				// update the visual XZ rotation
				if (m_InWorld)
				{
					m_LastInterpolatedRotX = m_InterpolatedRotX;
					m_LastInterpolatedRotZ = m_InterpolatedRotZ;

					UpdateXZRotation();
				}

				UpdateMessageSubscriptions();
			}

			break;
		}
		case MT_TurnStart:
		{

			m_LastInterpolatedRotX = m_InterpolatedRotX;
			m_LastInterpolatedRotZ = m_InterpolatedRotZ;

			if (m_InWorld && (m_LastX != m_X || m_LastZ != m_Z))
				UpdateXZRotation();

			// Store the positions from the turn before
			m_PrevX = m_LastX;
			m_PrevZ = m_LastZ;

			m_LastX = m_X;
			m_LastZ = m_Z;
			m_LastYDifference = entity_pos_t::Zero();


			// warn when a position change also causes a territory change under the entity
			if (m_InWorld)
			{
				player_id_t newTerritory;
				CmpPtr<ICmpTerritoryManager> cmpTerritoryManager(GetSystemEntity());
				if (cmpTerritoryManager)
					newTerritory = cmpTerritoryManager->GetOwner(m_X, m_Z);
				else
					newTerritory = INVALID_PLAYER;
				if (newTerritory != m_Territory)
				{
					m_Territory = newTerritory;
					CMessageTerritoryPositionChanged msg(GetEntityId(), m_Territory);
					GetSimContext().GetComponentManager().PostMessage(GetEntityId(), msg);
				}
			}
			else if (m_Territory != INVALID_PLAYER)
			{
				m_Territory = INVALID_PLAYER;
				CMessageTerritoryPositionChanged msg(GetEntityId(), m_Territory);
				GetSimContext().GetComponentManager().PostMessage(GetEntityId(), msg);
			}
			break;
		}
		case MT_TerrainChanged:
		case MT_WaterChanged:
		{
			AdvertiseInterpolatedPositionChanges();
			break;
		}
		case MT_Deserialized:
		{
			Deserialized();
			break;
		}
		}
	}
Exemple #9
0
	virtual void HandleMessage(const CMessage& msg, bool UNUSED(global))
	{
		switch (msg.GetType())
		{
		case MT_Interpolate:
		{
			const CMessageInterpolate& msgData = static_cast<const CMessageInterpolate&> (msg);

			float rotY = m_RotY.ToFloat();

			if (rotY != m_InterpolatedRotY)
			{
				float delta = rotY - m_InterpolatedRotY;
				// Wrap delta to -M_PI..M_PI
				delta = fmodf(delta + (float)M_PI, 2*(float)M_PI); // range -2PI..2PI
				if (delta < 0) delta += 2*(float)M_PI; // range 0..2PI
				delta -= (float)M_PI; // range -M_PI..M_PI
				// Clamp to max rate
				float deltaClamped = clamp(delta, -m_RotYSpeed*msgData.deltaSimTime, +m_RotYSpeed*msgData.deltaSimTime);
				// Calculate new orientation, in a peculiar way in order to make sure the
				// result gets close to m_orientation (rather than being n*2*M_PI out)
				m_InterpolatedRotY = rotY + deltaClamped - delta;
				
				// update the visual XZ rotation
				if (m_InWorld)
				{
					m_LastInterpolatedRotX = m_InterpolatedRotX;
					m_LastInterpolatedRotZ = m_InterpolatedRotZ;

					UpdateXZRotation();
				}
			}
			
			if (m_InWorld && m_NeedInitialXZRotation)
			{
				// the terrain probably wasn't loaded last time we tried, so update the XZ rotation without interpolation
				UpdateXZRotation();

				m_LastInterpolatedRotX = m_InterpolatedRotX;
				m_LastInterpolatedRotZ = m_InterpolatedRotZ;
			}

			break;
		}
		case MT_TurnStart:
		{
			m_LastInterpolatedRotX = m_InterpolatedRotX;
			m_LastInterpolatedRotZ = m_InterpolatedRotZ;

			if (m_InWorld && (m_LastX != m_X || m_LastZ != m_Z))
				UpdateXZRotation();

			// Store the positions from the turn before
			m_PrevX = m_LastX;
			m_PrevZ = m_LastZ;

			m_LastX = m_X;
			m_LastZ = m_Z;

			break;
		}
	}
};