OpenSimMirror/addon-modules/BulletSPlugin/BSPrim.cs

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2011-05-19 19:50:29 +00:00
/*
* Copyright (c) Intel Corporation
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the Intel Corporation nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE DEVELOPERS ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE CONTRIBUTORS BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
using System;
using System.Reflection;
using System.Collections.Generic;
using System.Xml;
using log4net;
using OMV = OpenMetaverse;
using OpenSim.Framework;
using OpenSim.Region.Physics.Manager;
using OpenSim.Region.Physics.ConvexDecompositionDotNet;
namespace OpenSim.Region.Physics.BulletSPlugin
{
[Serializable]
public sealed class BSPrim : PhysicsActor
{
private static readonly ILog m_log = LogManager.GetLogger(MethodBase.GetCurrentMethod().DeclaringType);
private static readonly string LogHeader = "[BULLETS PRIM]";
private IMesh _mesh;
private PrimitiveBaseShape _pbs;
private ShapeData.PhysicsShapeType _shapeType;
private ulong _hullKey;
private List<ConvexResult> _hulls;
private BSScene _scene;
private String _avName;
private uint _localID = 0;
private OMV.Vector3 _size;
private OMV.Vector3 _scale;
private bool _stopped;
private bool _grabbed;
private bool _isSelected;
private OMV.Vector3 _position;
private float _mass;
private float _density;
private OMV.Vector3 _force;
private OMV.Vector3 _velocity;
private OMV.Vector3 _torque;
private float _collisionScore;
private OMV.Vector3 _acceleration;
private OMV.Quaternion _orientation;
private int _physicsActorType;
private bool _isPhysical;
private bool _flying;
private float _friction;
private bool _setAlwaysRun;
private bool _throttleUpdates;
private bool _isColliding;
private bool _collidingGround;
private bool _collidingObj;
private bool _floatOnWater;
private OMV.Vector3 _rotationalVelocity;
private bool _kinematic;
private float _buoyancy;
private List<BSPrim> _childrenPrims;
private BSPrim _parentPrim;
private int _subscribedEventsMs = 0;
long _collidingStep;
long _collidingGroundStep;
private OMV.Vector3 _PIDTarget;
private bool _usePID;
private float _PIDTau;
private bool _useHoverPID;
private float _PIDHoverHeight;
private PIDHoverType _PIDHoverType;
private float _PIDHoverTao;
public BSPrim(uint localID, String primName, BSScene parent_scene, OMV.Vector3 pos, OMV.Vector3 size,
OMV.Quaternion rotation, IMesh mesh, PrimitiveBaseShape pbs, bool pisPhysical)
{
m_log.DebugFormat("{0}: BSPrim creation of {1}, id={2}", LogHeader, primName, localID);
_localID = localID;
_avName = primName;
_scene = parent_scene;
_position = pos;
_size = size;
_scale = new OMV.Vector3(1f, 1f, 1f); // the scale will be set by CreateGeom depending on object type
_orientation = rotation;
_mesh = mesh;
_hullKey = 0;
_pbs = pbs;
_isPhysical = pisPhysical;
_subscribedEventsMs = 0;
_friction = _scene.DefaultFriction; // TODO: compute based on object material
_density = _scene.DefaultDensity; // TODO: compute based on object material
_parentPrim = null; // not a child or a parent
_childrenPrims = new List<BSPrim>();
if (_isPhysical)
_mass = CalculateMass();
else
_mass = 0f;
// do the actual object creation at taint time
_scene.TaintedObject(delegate()
{
CreateGeom();
CreateObject();
});
}
// called when this prim is being destroyed and we should free all the resources
public void Destroy()
{
// m_log.DebugFormat("{0}: Destroy", LogHeader);
_scene.TaintedObject(delegate()
{
BulletSimAPI.DestroyObject(_scene.WorldID, _localID);
});
}
public override bool Stopped {
get { return _stopped; }
}
public override OMV.Vector3 Size {
get { return _size; }
set {
_size = value;
m_log.DebugFormat("{0}: Size={1}", LogHeader, _size);
_scene.TaintedObject(delegate()
{
if (_isPhysical) _mass = CalculateMass(); // changing size changes the mass
BulletSimAPI.SetObjectScaleMass(_scene.WorldID, _localID, _scale, _mass, _isPhysical);
RecreateGeomAndObject();
// SyncUpdated = true;
});
}
}
public override PrimitiveBaseShape Shape {
set {
_pbs = value;
m_log.DebugFormat("{0}: set Shape", LogHeader);
_scene.TaintedObject(delegate()
{
if (_isPhysical) _mass = CalculateMass(); // changing the shape changes the mass
RecreateGeomAndObject();
// SyncUpdated = true;
});
}
}
public override uint LocalID {
set { _localID = value; }
get { return _localID; }
}
public override bool Grabbed {
set { _grabbed = value;
m_log.DebugFormat("{0}: Grabbed={1}", LogHeader, _grabbed);
}
}
public override bool Selected {
set {
_isSelected = value;
_scene.TaintedObject(delegate()
{
m_log.DebugFormat("{0}: Selected={1}, localID={2}", LogHeader, _isSelected, _localID);
SetObjectDynamic();
// SyncUpdated = true;
});
}
}
public override void CrossingFailure() { return; }
// link me to the specified parent
public override void link(PhysicsActor obj) {
BSPrim parent = (BSPrim)obj;
m_log.DebugFormat("{0}: link {1} to {2}", LogHeader, _localID, obj.LocalID);
// TODO: decide if this parent checking needs to happen at taint time
if (_parentPrim == null)
{
if (parent != null)
{
// I don't have a parent so I am joining a linkset
parent.AddChildToLinkset(this);
}
}
else
{
// I already have a parent, is parenting changing?
if (parent != _parentPrim)
{
if (parent == null)
{
// we are being removed from a linkset
_parentPrim.RemoveChildFromLinkset(this);
}
else
{
// asking to reparent a prim should not happen
m_log.ErrorFormat("{0}: Reparenting a prim. ", LogHeader);
}
}
}
return;
}
// delink me from my linkset
public override void delink() {
// TODO: decide if this parent checking needs to happen at taint time
m_log.DebugFormat("{0}: delink {1}", LogHeader, _localID);
if (_parentPrim != null)
{
_parentPrim.RemoveChildFromLinkset(this);
}
return;
}
public void AddChildToLinkset(BSPrim pchild)
{
BSPrim child = pchild;
_scene.TaintedObject(delegate()
{
if (!_childrenPrims.Contains(child))
{
_childrenPrims.Add(child);
child.ParentPrim = this; // the child has gained a parent
RecreateGeomAndObject(); // rebuild my shape with the new child added
}
});
return;
}
public void RemoveChildFromLinkset(BSPrim pchild)
{
BSPrim child = pchild;
_scene.TaintedObject(delegate()
{
if (_childrenPrims.Contains(child))
{
_childrenPrims.Remove(child);
child.ParentPrim = null; // the child has lost its parent
RecreateGeomAndObject(); // rebuild my shape with the child removed
}
else
{
m_log.ErrorFormat("{0}: Asked to remove child from linkset that was not in linkset");
}
});
return;
}
public BSPrim ParentPrim
{
set { _parentPrim = value; }
}
public ulong HullKey
{
get { return _hullKey; }
}
// return true if we are the root of a linkset (there are children to manage)
public bool IsRootOfLinkset
{
get { return (_parentPrim == null && _childrenPrims.Count != 0); }
}
public override void LockAngularMotion(OMV.Vector3 axis) { return; }
public override OMV.Vector3 Position {
get {
// _position = BulletSimAPI.GetObjectPosition(_scene.WorldID, _localID);
return _position;
}
set {
_position = value;
_scene.TaintedObject(delegate()
{
BulletSimAPI.SetObjectTranslation(_scene.WorldID, _localID, _position, _orientation);
// SyncUpdated = true;
});
}
}
public override float Mass {
get { return _mass; }
}
public override OMV.Vector3 Force {
get { return _force; }
set {
_force = value;
m_log.DebugFormat("{0}: set Force. f={1}", LogHeader, _force);
_scene.TaintedObject(delegate()
{
BulletSimAPI.SetObjectForce(_scene.WorldID, _localID, _force);
// SyncUpdated = true;
});
}
}
public override int VehicleType {
get { return 0; }
set { return; }
}
public override void VehicleFloatParam(int param, float value) { }
public override void VehicleVectorParam(int param, OMV.Vector3 value) {}
public override void VehicleRotationParam(int param, OMV.Quaternion rotation) { }
public override void VehicleFlags(int param, bool remove) { }
// Allows the detection of collisions with inherently non-physical prims. see llVolumeDetect for more
public override void SetVolumeDetect(int param) { return; }
public override OMV.Vector3 GeometricCenter { get { return OMV.Vector3.Zero; } }
public override OMV.Vector3 CenterOfMass { get { return OMV.Vector3.Zero; } }
public override OMV.Vector3 Velocity {
get { return _velocity; }
set { _velocity = value;
// SyncUpdated = true;
}
}
public override OMV.Vector3 Torque {
get { return _torque; }
set { _torque = value;
// SyncUpdated = true;
}
}
public override float CollisionScore {
get { return _collisionScore; }
set { _collisionScore = value;
// SyncUpdated = true;
}
}
public override OMV.Vector3 Acceleration {
get { return _acceleration; }
}
public override OMV.Quaternion Orientation {
get { return _orientation; }
set {
_orientation = value;
_scene.TaintedObject(delegate()
{
_position = BulletSimAPI.GetObjectPosition(_scene.WorldID, _localID);
BulletSimAPI.SetObjectTranslation(_scene.WorldID, _localID, _position, _orientation);
// m_log.DebugFormat("{0}: set orientation: {1}", LogHeader, _orientation);
// SyncUpdated = true;
});
}
}
public override int PhysicsActorType {
get { return _physicsActorType; }
set { _physicsActorType = value;
// SyncUpdated = true;
}
}
public override bool IsPhysical {
get { return _isPhysical; }
set {
_isPhysical = value;
_scene.TaintedObject(delegate()
{
SetObjectDynamic();
m_log.DebugFormat("{0}: ID={1}, IsPhysical={2}, IsSelected={3}, mass={4}", LogHeader, _localID, _isPhysical, _isSelected, _mass);
// SyncUpdated = true;
});
}
}
// make gravity work if the object is physical and not selected
// no locking here because only called when it is safe
private void SetObjectDynamic()
{
// a selected object is not physical
if (_isSelected || !_isPhysical)
{
_mass = 0f; // non-physical things work best with a mass of zero
BulletSimAPI.SetObjectDynamic(_scene.WorldID, _localID, false, _mass);
}
else
{
_mass = CalculateMass();
BulletSimAPI.SetObjectDynamic(_scene.WorldID, _localID, true, _mass);
}
}
public override bool Flying {
get { return _flying; }
set {
_flying = value;
_scene.TaintedObject(delegate()
{
BulletSimAPI.SetObjectFlying(_scene.WorldID, LocalID, _flying);
// SyncUpdated = true;
});
}
}
public override bool
SetAlwaysRun {
get { return _setAlwaysRun; }
set { _setAlwaysRun = value; }
}
public override bool ThrottleUpdates {
get { return _throttleUpdates; }
set { _throttleUpdates = value; }
}
public override bool IsColliding {
get { return _isColliding; }
set { _isColliding = value; }
}
public override bool CollidingGround {
get { return _collidingGround; }
set { _collidingGround = value; }
}
public override bool CollidingObj {
get { return _collidingObj; }
set { _collidingObj = value; }
}
public bool IsPhantom {
get {
// SceneObjectPart removes phantom objects from the physics scene
// so, although we could implement touching and such, we never
// are invoked as a phantom object
return false;
}
}
public override bool FloatOnWater {
set { _floatOnWater = value; }
}
public override OMV.Vector3 RotationalVelocity {
get { return _rotationalVelocity; }
set { _rotationalVelocity = value;
m_log.DebugFormat("{0}: RotationalVelocity={1}", LogHeader, _rotationalVelocity);
}
}
public override bool Kinematic {
get { return _kinematic; }
set { _kinematic = value;
m_log.DebugFormat("{0}: Kinematic={1}", LogHeader, _kinematic);
}
}
public override float Buoyancy {
get { return _buoyancy; }
set { _buoyancy = value; }
}
// Used for MoveTo
public override OMV.Vector3 PIDTarget {
set { _PIDTarget = value; }
}
public override bool PIDActive {
set { _usePID = value; }
}
public override float PIDTau {
set { _PIDTau = value; }
}
// Used for llSetHoverHeight and maybe vehicle height
// Hover Height will override MoveTo target's Z
public override bool PIDHoverActive {
set { _useHoverPID = value; }
}
public override float PIDHoverHeight {
set { _PIDHoverHeight = value; }
}
public override PIDHoverType PIDHoverType {
set { _PIDHoverType = value; }
}
public override float PIDHoverTau {
set { _PIDHoverTao = value; }
}
// For RotLookAt
public override OMV.Quaternion APIDTarget { set { return; } }
public override bool APIDActive { set { return; } }
public override float APIDStrength { set { return; } }
public override float APIDDamping { set { return; } }
public override void AddForce(OMV.Vector3 force, bool pushforce) {
if (force.IsFinite())
{
_force.X += force.X;
_force.Y += force.Y;
_force.Z += force.Z;
}
else
{
m_log.WarnFormat("{0}: Got a NaN force applied to a Character", LogHeader);
}
_scene.TaintedObject(delegate()
{
BulletSimAPI.SetObjectForce(_scene.WorldID, _localID, _force);
});
}
public override void AddAngularForce(OMV.Vector3 force, bool pushforce) {
m_log.DebugFormat("{0}: AddAngularForce. f={1}, push={2}", LogHeader, force, pushforce);
}
public override void SetMomentum(OMV.Vector3 momentum) {
}
public override void SubscribeEvents(int ms) {
_subscribedEventsMs = ms;
}
public override void UnSubscribeEvents() {
_subscribedEventsMs = 0;
}
public override bool SubscribedEvents() {
return (_subscribedEventsMs > 0);
}
#region Mass Calculation
private float CalculateMass()
{
float volume = _size.X * _size.Y * _size.Z; // default
float tmp;
float returnMass = 0;
float hollowAmount = (float)_pbs.ProfileHollow * 2.0e-5f;
float hollowVolume = hollowAmount * hollowAmount;
switch (_pbs.ProfileShape)
{
case ProfileShape.Square:
// default box
if (_pbs.PathCurve == (byte)Extrusion.Straight)
{
if (hollowAmount > 0.0)
{
switch (_pbs.HollowShape)
{
case HollowShape.Square:
case HollowShape.Same:
break;
case HollowShape.Circle:
hollowVolume *= 0.78539816339f;
break;
case HollowShape.Triangle:
hollowVolume *= (0.5f * .5f);
break;
default:
hollowVolume = 0;
break;
}
volume *= (1.0f - hollowVolume);
}
}
else if (_pbs.PathCurve == (byte)Extrusion.Curve1)
{
//a tube
volume *= 0.78539816339e-2f * (float)(200 - _pbs.PathScaleX);
tmp= 1.0f -2.0e-2f * (float)(200 - _pbs.PathScaleY);
volume -= volume*tmp*tmp;
if (hollowAmount > 0.0)
{
hollowVolume *= hollowAmount;
switch (_pbs.HollowShape)
{
case HollowShape.Square:
case HollowShape.Same:
break;
case HollowShape.Circle:
hollowVolume *= 0.78539816339f;;
break;
case HollowShape.Triangle:
hollowVolume *= 0.5f * 0.5f;
break;
default:
hollowVolume = 0;
break;
}
volume *= (1.0f - hollowVolume);
}
}
break;
case ProfileShape.Circle:
if (_pbs.PathCurve == (byte)Extrusion.Straight)
{
volume *= 0.78539816339f; // elipse base
if (hollowAmount > 0.0)
{
switch (_pbs.HollowShape)
{
case HollowShape.Same:
case HollowShape.Circle:
break;
case HollowShape.Square:
hollowVolume *= 0.5f * 2.5984480504799f;
break;
case HollowShape.Triangle:
hollowVolume *= .5f * 1.27323954473516f;
break;
default:
hollowVolume = 0;
break;
}
volume *= (1.0f - hollowVolume);
}
}
else if (_pbs.PathCurve == (byte)Extrusion.Curve1)
{
volume *= 0.61685027506808491367715568749226e-2f * (float)(200 - _pbs.PathScaleX);
tmp = 1.0f - .02f * (float)(200 - _pbs.PathScaleY);
volume *= (1.0f - tmp * tmp);
if (hollowAmount > 0.0)
{
// calculate the hollow volume by it's shape compared to the prim shape
hollowVolume *= hollowAmount;
switch (_pbs.HollowShape)
{
case HollowShape.Same:
case HollowShape.Circle:
break;
case HollowShape.Square:
hollowVolume *= 0.5f * 2.5984480504799f;
break;
case HollowShape.Triangle:
hollowVolume *= .5f * 1.27323954473516f;
break;
default:
hollowVolume = 0;
break;
}
volume *= (1.0f - hollowVolume);
}
}
break;
case ProfileShape.HalfCircle:
if (_pbs.PathCurve == (byte)Extrusion.Curve1)
{
volume *= 0.52359877559829887307710723054658f;
}
break;
case ProfileShape.EquilateralTriangle:
if (_pbs.PathCurve == (byte)Extrusion.Straight)
{
volume *= 0.32475953f;
if (hollowAmount > 0.0)
{
// calculate the hollow volume by it's shape compared to the prim shape
switch (_pbs.HollowShape)
{
case HollowShape.Same:
case HollowShape.Triangle:
hollowVolume *= .25f;
break;
case HollowShape.Square:
hollowVolume *= 0.499849f * 3.07920140172638f;
break;
case HollowShape.Circle:
// Hollow shape is a perfect cyllinder in respect to the cube's scale
// Cyllinder hollow volume calculation
hollowVolume *= 0.1963495f * 3.07920140172638f;
break;
default:
hollowVolume = 0;
break;
}
volume *= (1.0f - hollowVolume);
}
}
else if (_pbs.PathCurve == (byte)Extrusion.Curve1)
{
volume *= 0.32475953f;
volume *= 0.01f * (float)(200 - _pbs.PathScaleX);
tmp = 1.0f - .02f * (float)(200 - _pbs.PathScaleY);
volume *= (1.0f - tmp * tmp);
if (hollowAmount > 0.0)
{
hollowVolume *= hollowAmount;
switch (_pbs.HollowShape)
{
case HollowShape.Same:
case HollowShape.Triangle:
hollowVolume *= .25f;
break;
case HollowShape.Square:
hollowVolume *= 0.499849f * 3.07920140172638f;
break;
case HollowShape.Circle:
hollowVolume *= 0.1963495f * 3.07920140172638f;
break;
default:
hollowVolume = 0;
break;
}
volume *= (1.0f - hollowVolume);
}
}
break;
default:
break;
}
float taperX1;
float taperY1;
float taperX;
float taperY;
float pathBegin;
float pathEnd;
float profileBegin;
float profileEnd;
if (_pbs.PathCurve == (byte)Extrusion.Straight || _pbs.PathCurve == (byte)Extrusion.Flexible)
{
taperX1 = _pbs.PathScaleX * 0.01f;
if (taperX1 > 1.0f)
taperX1 = 2.0f - taperX1;
taperX = 1.0f - taperX1;
taperY1 = _pbs.PathScaleY * 0.01f;
if (taperY1 > 1.0f)
taperY1 = 2.0f - taperY1;
taperY = 1.0f - taperY1;
}
else
{
taperX = _pbs.PathTaperX * 0.01f;
if (taperX < 0.0f)
taperX = -taperX;
taperX1 = 1.0f - taperX;
taperY = _pbs.PathTaperY * 0.01f;
if (taperY < 0.0f)
taperY = -taperY;
taperY1 = 1.0f - taperY;
}
volume *= (taperX1 * taperY1 + 0.5f * (taperX1 * taperY + taperX * taperY1) + 0.3333333333f * taperX * taperY);
pathBegin = (float)_pbs.PathBegin * 2.0e-5f;
pathEnd = 1.0f - (float)_pbs.PathEnd * 2.0e-5f;
volume *= (pathEnd - pathBegin);
// this is crude aproximation
profileBegin = (float)_pbs.ProfileBegin * 2.0e-5f;
profileEnd = 1.0f - (float)_pbs.ProfileEnd * 2.0e-5f;
volume *= (profileEnd - profileBegin);
returnMass = _density * volume;
if (returnMass <= 0)
returnMass = 0.0001f;//ckrinke: Mass must be greater then zero.
if (IsRootOfLinkset)
{
foreach (BSPrim prim in _childrenPrims)
{
returnMass += prim.CalculateMass();
}
}
if (returnMass > _scene.maximumMassObject)
returnMass = _scene.maximumMassObject;
return returnMass;
}// end CalculateMass
#endregion Mass Calculation
// Create the geometry information in Bullet for later use
// No locking here because this is done when we know physics is not simulating
private void CreateGeom()
{
if (_mesh == null)
{
// the mesher thought this was too simple to mesh. Use a native Bullet collision shape.
if (_pbs.ProfileShape == ProfileShape.HalfCircle && _pbs.PathCurve == (byte)Extrusion.Curve1)
{
if (_size.X == _size.Y && _size.Y == _size.Z && _size.X == _size.Z)
{
m_log.DebugFormat("{0}: CreateGeom: mesh null. Defaulting to sphere of size {1}", LogHeader, _size);
_shapeType = ShapeData.PhysicsShapeType.SHAPE_SPHERE;
// Bullet native objects are scaled by the Bullet engine so pass the size in
_scale = _size;
}
}
else
{
m_log.DebugFormat("{0}: CreateGeom: mesh null. Defaulting to box of size {1}", LogHeader, _size);
_shapeType = ShapeData.PhysicsShapeType.SHAPE_BOX;
_scale = _size;
}
}
else
{
if (_hullKey != 0)
{
m_log.DebugFormat("{0}: CreateGeom: deleting old hull. Key={1}", LogHeader, _hullKey);
BulletSimAPI.DestroyHull(_scene.WorldID, _hullKey);
_hullKey = 0;
_hulls.Clear();
}
int[] indices = _mesh.getIndexListAsInt();
List<OMV.Vector3> vertices = _mesh.getVertexList();
//format conversion from IMesh format to DecompDesc format
List<int> convIndices = new List<int>();
List<float3> convVertices = new List<float3>();
for (int ii = 0; ii < indices.GetLength(0); ii++)
{
convIndices.Add(indices[ii]);
}
foreach (OMV.Vector3 vv in vertices)
{
convVertices.Add(new float3(vv.X, vv.Y, vv.Z));
}
// setup and do convex hull conversion
_hulls = new List<ConvexResult>();
DecompDesc dcomp = new DecompDesc();
dcomp.mIndices = convIndices;
dcomp.mVertices = convVertices;
ConvexBuilder convexBuilder = new ConvexBuilder(HullReturn);
// create the hull into the _hulls variable
convexBuilder.process(dcomp);
// Convert the vertices and indices for passing to unmanaged
// The hull information is passed as a large floating point array.
// The format is:
// convHulls[0] = number of hulls
// convHulls[1] = number of vertices in first hull
// convHulls[2] = hull centroid X coordinate
// convHulls[3] = hull centroid Y coordinate
// convHulls[4] = hull centroid Z coordinate
// convHulls[5] = first hull vertex X
// convHulls[6] = first hull vertex Y
// convHulls[7] = first hull vertex Z
// convHulls[8] = second hull vertex X
// ...
// convHulls[n] = number of vertices in second hull
// convHulls[n+1] = second hull centroid X coordinate
// ...
//
// TODO: is is very inefficient. Someday change the convex hull generator to return
// data structures that do not need to be converted in order to pass to Bullet.
// And maybe put the values directly into pinned memory rather than marshaling.
int hullCount = _hulls.Count;
int totalVertices = 1; // include one for the count of the hulls
foreach (ConvexResult cr in _hulls)
{
totalVertices += 4; // add four for the vertex count and centroid
totalVertices += cr.HullIndices.Count * 3; // we pass just triangles
}
float[] convHulls = new float[totalVertices];
convHulls[0] = (float)hullCount;
int jj = 1;
foreach (ConvexResult cr in _hulls)
{
// copy vertices for index access
float3[] verts = new float3[cr.HullVertices.Count];
int kk = 0;
foreach (float3 ff in cr.HullVertices)
{
verts[kk++] = ff;
}
// add to the array one hull's worth of data
convHulls[jj++] = cr.HullIndices.Count;
convHulls[jj++] = 0f; // centroid x,y,z
convHulls[jj++] = 0f;
convHulls[jj++] = 0f;
foreach (int ind in cr.HullIndices)
{
convHulls[jj++] = verts[ind].x;
convHulls[jj++] = verts[ind].y;
convHulls[jj++] = verts[ind].z;
}
}
// create the hull definition in Bullet
_hullKey = (ulong)_pbs.GetHashCode();
// m_log.DebugFormat("{0}: CreateGeom: calling CreateHull. key={1}, hulls={2}", LogHeader, _hullKey, hullCount);
BulletSimAPI.CreateHull(_scene.WorldID, _hullKey, hullCount, convHulls);
_shapeType = ShapeData.PhysicsShapeType.SHAPE_HULL;
// meshes are already scaled by the meshmerizer
_scale = new OMV.Vector3(1f, 1f, 1f);
}
return;
}
private void HullReturn(ConvexResult result)
{
_hulls.Add(result);
return;
}
// Create an object in Bullet
// No locking here because this is done when the physics engine is not simulating
private void CreateObject()
{
if (IsRootOfLinkset)
{
// Create a linkset around this object
// If I am the root prim of a linkset, replace my physical shape with all the
// pieces of the children.
// All of the children should have called CreateGeom so they have a hull
// in the physics engine already. Here we pull together all of those hulls
// into one shape.
m_log.DebugFormat("{0}: CreateLinkset", LogHeader);
int totalPrimsInLinkset = _childrenPrims.Count + 1;
ShapeData[] shapes = new ShapeData[totalPrimsInLinkset];
FillShapeInfo(out shapes[0]);
int ii = 1;
foreach (BSPrim prim in _childrenPrims)
{
m_log.DebugFormat("{0}: CreateLinkset: adding prim {1}", LogHeader, prim.LocalID);
prim.FillShapeInfo(out shapes[ii]);
ii++;
}
BulletSimAPI.CreateLinkset(_scene.WorldID, totalPrimsInLinkset, shapes);
}
else
{
// simple object
ShapeData shape;
FillShapeInfo(out shape);
BulletSimAPI.CreateObject(_scene.WorldID, shape);
}
}
// Copy prim's info into the BulletSim shape description structure
public void FillShapeInfo(out ShapeData shape)
{
shape.ID = _localID;
shape.Type = _shapeType;
shape.Position = _position;
shape.Rotation = _orientation;
shape.Velocity = _velocity;
shape.Scale = _scale;
shape.Mass = _isPhysical ? _mass : 0f;
shape.MeshKey = _hullKey;
shape.Collidable = (!IsPhantom) ? ShapeData.numericTrue : ShapeData.numericFalse;
shape.Flying = _flying ? ShapeData.numericTrue : ShapeData.numericFalse;
shape.Friction = _friction;
shape.Dynamic = _isPhysical ? ShapeData.numericTrue : ShapeData.numericFalse;
}
// Rebuild the geometry and object.
// This is called when the shape changes so we need to recreate the mesh/hull.
// No locking here because this is done when the physics engine is not simulating
private void RecreateGeomAndObject()
{
if (_hullKey != 0)
{
// if a hull already exists, delete the old one
BulletSimAPI.DestroyHull(_scene.WorldID, _hullKey);
_hullKey = 0;
}
// If this object is complex or we are the root of a linkset, build a mesh.
// The root of a linkset must be a mesh so we can create the linked compound object.
if (_scene.NeedsMeshing(_pbs) || IsRootOfLinkset )
{
m_log.DebugFormat("{0}: RecreateGeomAndObject: creating mesh", LogHeader);
_mesh = _scene.mesher.CreateMesh(_avName, _pbs, _size, _scene.meshLOD, _isPhysical);
}
else
{
// it's a BulletSim native shape.
_mesh = null;
}
CreateGeom(); // create the geometry for this prim
CreateObject();
return;
}
// The physics engine says that properties have updated. Update same and inform
// the world that things have changed.
// TODO: do we really need to check for changed? Maybe just copy values and call RequestPhysicsterseUpdate()
public void UpdateProperties(EntityProperties entprop)
{
bool changed = false;
// we assign to the local variables so the normal set action does not happen
if (_position != entprop.Position)
{
_position = entprop.Position;
// m_log.DebugFormat("{0}: UpdateProperties: position = {1}", LogHeader, _position);
changed = true;
}
if (_orientation != entprop.Rotation)
{
_orientation = entprop.Rotation;
// m_log.DebugFormat("{0}: UpdateProperties: rotation = {1}", LogHeader, _orientation);
changed = true;
}
if (_velocity != entprop.Velocity)
{
_velocity = entprop.Velocity;
// m_log.DebugFormat("{0}: UpdateProperties: velocity = {1}", LogHeader, _velocity);
changed = true;
}
if (_acceleration != entprop.Acceleration)
{
_acceleration = entprop.Acceleration;
// m_log.DebugFormat("{0}: UpdateProperties: acceleration = {1}", LogHeader, _acceleration);
changed = true;
}
if (_rotationalVelocity != entprop.AngularVelocity)
{
_rotationalVelocity = entprop.AngularVelocity;
// m_log.DebugFormat("{0}: UpdateProperties: rotationalVelocity = {1}", LogHeader, _rotationalVelocity);
changed = true;
}
if (changed)
{
base.RequestPhysicsterseUpdate();
}
}
// I've collided with something
public void Collide(uint collidingWith, ActorTypes type, OMV.Vector3 contactPoint, OMV.Vector3 contactNormal, float pentrationDepth)
{
// m_log.DebugFormat("{0}: Collide: ms={1}, id={2}, with={3}", LogHeader, _subscribedEventsMs, LocalID, collidingWith);
if (_subscribedEventsMs == 0) return; // nothing in the object is waiting for collision events
// The following makes it so we can sense we're colliding this simulation step
_collidingStep = _scene.SimulationStep;
if (collidingWith == BSScene.TERRAIN_ID || collidingWith == BSScene.GROUNDPLANE_ID)
{
_collidingGroundStep = _scene.SimulationStep;
}
// create the event for the collision
Dictionary<uint, ContactPoint> contactPoints = new Dictionary<uint, ContactPoint>();
contactPoints.Add(collidingWith, new ContactPoint(contactPoint, contactNormal, pentrationDepth));
CollisionEventUpdate args = new CollisionEventUpdate(LocalID, (int)type, 1, contactPoints);
base.SendCollisionUpdate(args);
}
}
}