IObject[] wl_OnCreateIObject(IWorld world, GraphicFactory factory, GraphicInfo ginfo, ObjectInformation[] mi)
{
IModelo model = new CustomModel(factory, mi);
IPhysicObject po = new TriangleMeshObject(model, Vector3.Zero, Matrix.Identity, Vector3.One, MaterialDescription.DefaultBepuMaterial());
IShader shader = new ForwardXNABasicShader();
ForwardMaterial dm = new ForwardMaterial(shader);
return new IObject[] {new IObject(dm, model, po)};
}
IObject[] wl_OnCreateIObject(IWorld world, GraphicFactory factory, GraphicInfo ginfo, ObjectInformation[] oi)
{
IObject[] objs = new IObject[oi.Count()];
int i = 0;
foreach (var mi in oi)
{
mi.batchInformation.ModelLocalTransformation = Matrix.Identity;
IModelo model = new CustomModel(factory, mi.modelName, mi.batchInformation, mi.textureInformation, mi.meshIndex, mi.meshPartIndex);
//IPhysicObject po = new TriangleMeshObject(model, Vector3.Zero, Matrix.Identity, Vector3.One, MaterialDescription.DefaultBepuMaterial());
GhostObject po = new GhostObject(mi.position, Matrix.CreateFromQuaternion(mi.rotation), mi.scale);
IShader shader = new ForwardXNABasicShader();
ForwardMaterial dm = new ForwardMaterial(shader);
IObject obj = new IObject(dm, model, po);
objs[i++] = obj;
}
return objs;
}
/// <summary>
/// Called when an object is found
/// </summary>
/// <param name="world">The world.</param>
/// <param name="factory">The factory.</param>
/// <param name="ginfo">The ginfo.</param>
/// <param name="mi">The mi.</param>
/// <returns></returns>
IObject[] wl_OnCreateIObject(IWorld world, GraphicFactory factory, GraphicInfo ginfo, ObjectInformation[] mi)
{
IObject[] objs = new IObject[mi.Length];
for (int i = 0; i < mi.Length; i++)
{
IModelo model = new CustomModel(factory, mi[i].modelName, mi[i].batchInformation, mi[i].textureInformation);
IPhysicObject po = new TriangleMeshObject(model, Vector3.Zero, Matrix.Identity, Vector3.One, MaterialDescription.DefaultBepuMaterial());
DeferredCustomShader shader = new DeferredCustomShader(mi[i].HasTexture(TextureType.GLOW), mi[i].HasTexture(TextureType.BUMP), mi[i].HasTexture(TextureType.SPECULAR), mi[i].HasTexture(TextureType.PARALAX));
DeferredMaterial dm = new DeferredMaterial(shader);
IObject obj = new IObject(dm, model, po);
if (mi[i].HasTexture(TextureType.BUMP))
{
withBump.Add(obj);
}
if (mi[i].HasTexture(TextureType.SPECULAR))
{
shader.SpecularPowerMapScale = 2f;
shader.SpecularIntensityMapScale = 0.1f;
withSpecular.Add(obj);
}
objs[i] = obj;
}
return objs;
}
public static IObject[] CreateOBJ(IWorld world, GraphicFactory factory, GraphicInfo ginfo, ObjectInformation[] mi)
{
IModelo model = new CustomModel(factory, mi);
MaterialDescription material;
if (mi[0].staticfriction == -1 || mi[0].dinamicfriction == -1 || mi[0].ellasticity == -1)
{
material = MaterialDescription.DefaultBepuMaterial();
}
else
{
material = new MaterialDescription(mi[0].staticfriction, mi[0].dinamicfriction, mi[0].ellasticity);
}
IPhysicObject po;
bool massflag = false;
if (mi[0].mass == 0)
{
massflag = true;
mi[0].mass = 0.5f;
}
BatchInformation binf = model.GetBatchInformation(0)[0];
BoundingBox bb;
switch (mi[0].collisionType)
{
case "Ghost":
po = new GhostObject(mi[0].position,Matrix.CreateFromQuaternion(mi[0].rotation), mi[0].scale);
break;
case "Cylinder":
binf.ModelLocalTransformation = Matrix.Identity;
bb = ModelBuilderHelper.CreateBoundingBoxFromModel(binf);
Vector3 len = bb.Max - bb.Min;
po = new CylinderObject(mi[0].position, len.Y, len.X / 2,Vector3.Up ,mi[0].mass, Matrix.CreateFromQuaternion(mi[0].rotation), material);
break;
case "Sphere":
binf.ModelLocalTransformation = Matrix.Identity;
po = new SphereObject(mi[0].position, model.GetModelRadius(), mi[0].mass, mi[0].scale.X, material);
po.Rotation = Matrix.CreateFromQuaternion(mi[0].rotation);
break;
case "Box":
bb = ModelBuilderHelper.CreateBoundingBoxFromModel(binf);
len = bb.Max - bb.Min;
po = new BoxObject(mi[0].position, len.X, len.Y, len.Z, mi[0].mass, mi[0].scale, Matrix.CreateFromQuaternion(mi[0].rotation), material);
break;
case "Water":
po = new GhostObject(mi[0].position, Matrix.CreateFromQuaternion(mi[0].rotation), mi[0].scale);
break;
case "TriangleMesh":
default:
po = new TriangleMeshObject(model, Vector3.Zero, Matrix.Identity, new Vector3(1), material);
break;
}
po.isMotionLess = massflag;
IShader shader = null;
#if !REACH && !WINDOWS_PHONE
if (mi[0].HasTexture(TextureType.ENVIRONMENT))
{
shader = new DeferredEMReflectiveShader();
(shader as DeferredEMReflectiveShader).TextureCube = mi[0].textureInformation.getCubeTexture(TextureType.ENVIRONMENT);
}
else if (mi[0].collisionType != null && mi[0].collisionType.Contains("Water"))
{
Vector3 position = (Vector3)(mi[0].extra["position"]);
var width = (mi[0].extra["width"]);
var height = (mi[0].extra["length"]);
shader = new DeferredWaterCompleteShader((int)width,(int)height, new Plane(position.X, position.Y, position.Z, 1),10.0f);
}
else
{
shader = new DeferredCustomShader(mi[0].HasTexture(TextureType.GLOW), mi[0].HasTexture(TextureType.BUMP), mi[0].HasTexture(TextureType.SPECULAR), mi[0].HasTexture(TextureType.PARALAX));
}
DeferredMaterial dm = new DeferredMaterial(shader);
#else
shader = new ForwardXNABasicShader();
ForwardMaterial dm = new ForwardMaterial(shader);
#endif
IObject ob = new IObject(dm, model, po);
ob.Name = mi[0].modelName;
return new IObject[] { ob };
}
