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blender/source/gameengine/Ketsji/KX_GameObject.h
Benoit Bolsee 3ea1c1b4b6 BGE: new sensor object to generalize Near and Radar sensor, static-static collision capbility. 
A new type of "Sensor" physics object is available in the GE for advanced
collision management. It's called Sensor for its similarities with the
physics objects that underlie the Near and Radar sensors.
Like the Near and Radar object it is:
- static and ghost
- invisible by default
- always active to ensure correct collision detection
- capable of detecting both static and dynamic objects
- ignoring collision with their parent
- capable of broadphase filtering based on:
  * Actor option: the collisioning object must have the Actor flag set to be detected
  * property/material: as specified in the collision sensors attached to it
  Broadphase filtering is important for performance reason: the collision points
  will be computed only for the objects that pass the broahphase filter.
- automatically removed from the simulation when no collision sensor is active on it

Unlike the Near and Radar object it can:
- take any shape, including triangle mesh
- be made visible for debugging (just use the Visible actuator)
- have multiple collision sensors using it

Other than that, the sensor objects are ordinary objects. You can move them
freely or parent them. When parented to a dynamic object, they can provide
advanced collision control to this object.

The type of collision capability depends on the shape:
- box, sphere, cylinder, cone, convex hull provide volume detection.
- triangle mesh provides surface detection but you can give some volume
  to the suface by increasing the margin in the Advanced Settings panel.
  The margin applies on both sides of the surface.

Performance tip:
- Sensor objects perform better than Near and Radar: they do less synchronizations
  because of the Scenegraph optimizations and they can have multiple collision sensors
  on them (with different property filtering for example).
- Always prefer simple shape (box, sphere) to complex shape whenever possible.
- Always use broadphase filtering (avoid collision sensor with empty propery/material)
- Use collision sensor only when you need them. When no collision sensor is active
  on the sensor object, it is removed from the simulation and consume no CPU.

Known limitations:
- When running Blender in debug mode, you will see one warning line of the console:
  "warning btCollisionDispatcher::needsCollision: static-static collision!"
  In release mode this message is not printed.
- Collision margin has no effect on sphere, cone and cylinder shape.

Other performance improvements:
- Remove unnecessary interpolation for Near and Radar objects and by extension
  sensor objects.
- Use direct matrix copy instead of quaternion to synchronize orientation.

Other bug fix:
- Fix Near/Radar position error on newly activated objects. This was causing
  several detection problems in YoFrankie
- Fix margin not passed correctly to gImpact shape.
- Disable force/velocity actions on static objects
2009-05-17 12:51:51 +00:00

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/*
* $Id$
*
* ***** BEGIN GPL LICENSE BLOCK *****
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*
* The Original Code is Copyright (C) 2001-2002 by NaN Holding BV.
* All rights reserved.
*
* The Original Code is: all of this file.
*
* Contributor(s): none yet.
*
* ***** END GPL LICENSE BLOCK *****
* General KX game object.
*/
#ifndef __KX_GAMEOBJECT
#define __KX_GAMEOBJECT
#ifdef WIN32
// get rid of this stupid "warning 'this' used in initialiser list", generated by VC when including Solid/Sumo
#pragma warning (disable : 4355)
#endif
#include "ListValue.h"
#include "SCA_IObject.h"
#include "SG_Node.h"
#include "MT_Transform.h"
#include "MT_CmMatrix4x4.h"
#include "GEN_Map.h"
#include "GEN_HashedPtr.h"
#include "KX_Scene.h"
#include "KX_KetsjiEngine.h" /* for m_anim_framerate */
#include "KX_IPhysicsController.h" /* for suspend/resume */
#include "DNA_object_types.h"
#include "SCA_LogicManager.h" /* for ConvertPythonToGameObject to search object names */
#define KX_OB_DYNAMIC 1
//Forward declarations.
struct KX_ClientObjectInfo;
class KX_RayCast;
class RAS_MeshObject;
class KX_IPhysicsController;
class PHY_IGraphicController;
class PHY_IPhysicsEnvironment;
struct Object;
/* utility conversion function */
bool ConvertPythonToGameObject(PyObject * value, KX_GameObject **object, bool py_none_ok, const char *error_prefix);
/**
* KX_GameObject is the main class for dynamic objects.
*/
class KX_GameObject : public SCA_IObject
{
Py_Header;
protected:
bool m_bDyna;
KX_ClientObjectInfo* m_pClient_info;
STR_String m_name;
STR_String m_text;
int m_layer;
std::vector<RAS_MeshObject*> m_meshes;
SG_QList m_meshSlots; // head of mesh slots of this
struct Object* m_pBlenderObject;
struct Object* m_pBlenderGroupObject;
bool m_bSuspendDynamics;
bool m_bUseObjectColor;
bool m_bIsNegativeScaling;
MT_Vector4 m_objectColor;
// visible = user setting
// culled = while rendering, depending on camera
bool m_bVisible;
bool m_bCulled;
bool m_bOccluder;
KX_IPhysicsController* m_pPhysicsController1;
PHY_IGraphicController* m_pGraphicController;
// used for ray casting
PHY_IPhysicsEnvironment* m_pPhysicsEnvironment;
STR_String m_testPropName;
bool m_xray;
KX_GameObject* m_pHitObject;
SG_Node* m_pSGNode;
MT_CmMatrix4x4 m_OpenGL_4x4Matrix;
public:
bool m_isDeformable;
/**
* Helper function for modules that can't include KX_ClientObjectInfo.h
*/
static KX_GameObject* GetClientObject(KX_ClientObjectInfo* info);
// Python attributes that wont convert into CValue
//
// there are 2 places attributes can be stored, in the CValue,
// where attributes are converted into BGE's CValue types
// these can be used with property actuators
//
// For the python API, For types that cannot be converted into CValues (lists, dicts, GameObjects)
// these will be put into "m_attr_dict", logic bricks cannot access them.
//
// rules for setting attributes.
//
// * there should NEVER be a CValue and a m_attr_dict attribute with matching names. get/sets make sure of this.
// * if CValue conversion fails, use a PyObject in "m_attr_dict"
// * when assigning a value, first see if it can be a CValue, if it can remove the "m_attr_dict" and set the CValue
//
PyObject* m_attr_dict;
virtual void /* This function should be virtual - derived classed override it */
Relink(
GEN_Map<GEN_HashedPtr, void*> *map
);
/**
* Compute an OpenGl compatable 4x4 matrix. Has the
* side effect of storing the result internally. The
* memory for the matrix remains the property of this class.
*/
double*
GetOpenGLMatrix(
);
/**
* Return a pointer to a MT_CmMatrix4x4 storing the
* opengl transformation for this object. This is updated
* by a call to GetOpenGLMatrix(). This class owns the
* memory for the returned matrix.
*/
MT_CmMatrix4x4*
GetOpenGLMatrixPtr(
) {
return &m_OpenGL_4x4Matrix;
};
/**
* Get a pointer to the game object that is the parent of
* this object. Or NULL if there is no parent. The returned
* object is part of a reference counting scheme. Calling
* this function ups the reference count on the returned
* object. It is the responsibility of the caller to decrement
* the reference count when you have finished with it.
*/
KX_GameObject*
GetParent(
);
/**
* Sets the parent of this object to a game object
*/
void SetParent(KX_Scene *scene, KX_GameObject *obj);
/**
* Removes the parent of this object to a game object
*/
void RemoveParent(KX_Scene *scene);
/**
* Construct a game object. This class also inherits the
* default constructors - use those with care!
*/
KX_GameObject(
void* sgReplicationInfo,
SG_Callbacks callbacks,
PyTypeObject* T=&Type
);
virtual
~KX_GameObject(
);
/**
* @section Stuff which is here due to poor design.
* Inherited from CValue and needs an implementation.
* Do not expect these functions do to anything sensible.
*/
/**
* Inherited from CValue -- does nothing!
*/
CValue*
Calc(
VALUE_OPERATOR op,
CValue *val
);
/**
* Inherited from CValue -- does nothing!
*/
CValue*
CalcFinal(
VALUE_DATA_TYPE dtype,
VALUE_OPERATOR op,
CValue *val
);
/**
* Inherited from CValue -- does nothing!
*/
const
STR_String &
GetText(
);
/**
* Inherited from CValue -- does nothing!
*/
double
GetNumber(
);
/**
* @section Inherited from CValue. These are the useful
* part of the CValue interface that this class implements.
*/
/**
* Inherited from CValue -- returns the name of this object.
*/
STR_String&
GetName(
);
/**
* Inherited from CValue -- set the name of this object.
*/
void
SetName(
const char *name
);
/**
* Inherited from CValue -- return a new copy of this
* instance allocated on the heap. Ownership of the new
* object belongs with the caller.
*/
virtual CValue*
GetReplica(
);
/**
* Inherited from CValue -- Makes sure any internal
* data owned by this class is deep copied. Called internally
*/
virtual void
ProcessReplica();
/**
* Return the linear velocity of the game object.
*/
MT_Vector3
GetLinearVelocity(
bool local=false
);
/**
* Return the linear velocity of a given point in world coordinate
* but relative to center of object ([0,0,0]=center of object)
*/
MT_Vector3
GetVelocity(
const MT_Point3& position
);
/**
* Return the mass of the object
*/
MT_Scalar
GetMass();
/**
* Return the local inertia vector of the object
*/
MT_Vector3
GetLocalInertia();
/**
* Return the angular velocity of the game object.
*/
MT_Vector3
GetAngularVelocity(
bool local=false
);
/**
* Align the object to a given normal.
*/
void
AlignAxisToVect(
const MT_Vector3& vect,
int axis = 2,
float fac = 1.0
);
/**
* Quick'n'dirty obcolor ipo stuff
*/
void
SetObjectColor(
const MT_Vector4& rgbavec
);
void
ResolveCombinedVelocities(
const MT_Vector3 & lin_vel,
const MT_Vector3 & ang_vel,
bool lin_vel_local,
bool ang_vel_local
);
/**
* @return a pointer to the physics environment in use during the game, for rayCasting
*/
PHY_IPhysicsEnvironment* GetPhysicsEnvironment()
{
return m_pPhysicsEnvironment;
}
void SetPhysicsEnvironment(PHY_IPhysicsEnvironment* physicsEnvironment)
{
m_pPhysicsEnvironment = physicsEnvironment;
}
/**
* @return a pointer to the physics controller owned by this class.
*/
KX_IPhysicsController* GetPhysicsController() ;
void SetPhysicsController(KX_IPhysicsController* physicscontroller,bool isDynamic)
{
m_bDyna = isDynamic;
m_pPhysicsController1 = physicscontroller;
}
virtual class RAS_Deformer* GetDeformer()
{
return 0;
}
virtual void SetDeformer(class RAS_Deformer* deformer)
{
}
/**
* @return a pointer to the graphic controller owner by this class
*/
PHY_IGraphicController* GetGraphicController()
{
return m_pGraphicController;
}
void SetGraphicController(PHY_IGraphicController* graphiccontroller)
{
m_pGraphicController = graphiccontroller;
}
/*
* @add/remove the graphic controller to the physic system
*/
void ActivateGraphicController(bool recurse);
/**
* @section Coordinate system manipulation functions
*/
void NodeSetLocalPosition(const MT_Point3& trans );
void NodeSetLocalOrientation(const MT_Matrix3x3& rot );
void NodeSetLocalScale( const MT_Vector3& scale );
void NodeSetRelativeScale( const MT_Vector3& scale );
// adapt local position so that world position is set to desired position
void NodeSetWorldPosition(const MT_Point3& trans);
void
NodeUpdateGS(
double time
);
const
MT_Matrix3x3&
NodeGetWorldOrientation(
) const;
const
MT_Vector3&
NodeGetWorldScaling(
) const;
const
MT_Point3&
NodeGetWorldPosition(
) const;
/**
* @section scene graph node accessor functions.
*/
SG_Node* GetSGNode( )
{
return m_pSGNode;
}
const SG_Node* GetSGNode( ) const
{
return m_pSGNode;
}
/**
* @section blender object accessor functions.
*/
struct Object* GetBlenderObject( )
{
return m_pBlenderObject;
}
void SetBlenderObject( struct Object* obj)
{
m_pBlenderObject = obj;
}
struct Object* GetBlenderGroupObject( )
{
return m_pBlenderGroupObject;
}
void SetBlenderGroupObject( struct Object* obj)
{
m_pBlenderGroupObject = obj;
}
bool IsDupliGroup()
{
return (m_pBlenderObject &&
(m_pBlenderObject->transflag & OB_DUPLIGROUP) &&
m_pBlenderObject->dup_group != NULL) ? true : false;
}
/**
* Set the Scene graph node for this game object.
* warning - it is your responsibility to make sure
* all controllers look at this new node. You must
* also take care of the memory associated with the
* old node. This class takes ownership of the new
* node.
*/
void SetSGNode(SG_Node* node )
{
m_pSGNode = node;
}
//Is it a dynamic/physics object ?
bool IsDynamic() const
{
return m_bDyna;
}
/**
* Check if this object has a vertex parent relationship
*/
bool IsVertexParent( )
{
return (m_pSGNode && m_pSGNode->GetSGParent() && m_pSGNode->GetSGParent()->IsVertexParent());
}
bool RayHit(KX_ClientObjectInfo* client, KX_RayCast* result, void * const data);
bool NeedRayCast(KX_ClientObjectInfo* client);
/**
* @section Physics accessors for this node.
*
* All these calls get passed directly to the physics controller
* owned by this object.
* This is real interface bloat. Why not just use the physics controller
* directly? I think this is because the python interface is in the wrong
* place.
*/
void
ApplyForce(
const MT_Vector3& force, bool local
);
void
ApplyTorque(
const MT_Vector3& torque,
bool local
);
void
ApplyRotation(
const MT_Vector3& drot,
bool local
);
void
ApplyMovement(
const MT_Vector3& dloc,
bool local
);
void
addLinearVelocity(
const MT_Vector3& lin_vel,
bool local
);
void
setLinearVelocity(
const MT_Vector3& lin_vel,
bool local
);
void
setAngularVelocity(
const MT_Vector3& ang_vel,
bool local
);
/**
* Update the physics object transform based upon the current SG_Node
* position.
*/
void
UpdateTransform(
);
static void UpdateTransformFunc(SG_IObject* node, void* gameobj, void* scene);
/**
* only used for sensor objects
*/
void SynchronizeTransform();
static void SynchronizeTransformFunc(SG_IObject* node, void* gameobj, void* scene);
/**
* Function to set IPO option at start of IPO
*/
void
InitIPO(
bool ipo_as_force,
bool ipo_add,
bool ipo_local
);
/**
* Odd function to update an ipo. ???
*/
void
UpdateIPO(
float curframetime,
bool recurse
);
/**
* Updates Material Ipo data
*/
void
UpdateMaterialData(
dword matname_hash,
MT_Vector4 rgba,
MT_Vector3 specrgb,
MT_Scalar hard,
MT_Scalar spec,
MT_Scalar ref,
MT_Scalar emit,
MT_Scalar alpha
);
/**
* @section Mesh accessor functions.
*/
/**
* Update buckets to indicate that there is a new
* user of this object's meshes.
*/
void
AddMeshUser(
);
/**
* Update buckets with data about the mesh after
* creating or duplicating the object, changing
* visibility, object color, .. .
*/
void
UpdateBuckets(
bool recursive
);
/**
* Clear the meshes associated with this class
* and remove from the bucketing system.
* Don't think this actually deletes any of the meshes.
*/
void
RemoveMeshes(
);
/**
* Add a mesh to the set of meshes associated with this
* node. Meshes added in this way are not deleted by this class.
* Make sure you call RemoveMeshes() before deleting the
* mesh though,
*/
void
AddMesh(
RAS_MeshObject* mesh
){
m_meshes.push_back(mesh);
}
/**
* Pick out a mesh associated with the integer 'num'.
*/
RAS_MeshObject*
GetMesh(
int num
) const {
return m_meshes[num];
}
/**
* Return the number of meshes currently associated with this
* game object.
*/
int
GetMeshCount(
) const {
return m_meshes.size();
}
/**
* Set the debug color of the meshes associated with this
* class. Does this still work?
*/
void
SetDebugColor(
unsigned int bgra
);
/**
* Reset the debug color of meshes associated with this class.
*/
void
ResetDebugColor(
);
/**
* Was this object marked visible? (only for the explicit
* visibility system).
*/
bool
GetVisible(
void
);
/**
* Set visibility flag of this object
*/
void
SetVisible(
bool b,
bool recursive
);
/**
* Was this object culled?
*/
inline bool
GetCulled(
void
) { return m_bCulled; }
/**
* Set culled flag of this object
*/
inline void
SetCulled(
bool c
) { m_bCulled = c; }
/**
* Is this object an occluder?
*/
inline bool
GetOccluder(
void
) { return m_bOccluder; }
/**
* Set occluder flag of this object
*/
void
SetOccluder(
bool v,
bool recursive
);
/**
* Change the layer of the object (when it is added in another layer
* than the original layer)
*/
void
SetLayer(
int l
);
/**
* Get the object layer
*/
int
GetLayer(
void
);
/**
* Get the negative scaling state
*/
bool
IsNegativeScaling(
void
) { return m_bIsNegativeScaling; }
/**
* Is this a light?
*/
virtual bool
IsLight(
void
) { return false; }
/**
* @section Logic bubbling methods.
*/
/**
* Stop making progress
*/
void Suspend(void);
/**
* Resume making progress
*/
void Resume(void);
void SuspendDynamics(void) {
if (m_bSuspendDynamics)
{
return;
}
if (m_pPhysicsController1)
{
m_pPhysicsController1->SuspendDynamics();
}
m_bSuspendDynamics = true;
}
void RestoreDynamics(void) {
if (!m_bSuspendDynamics)
{
return;
}
if (m_pPhysicsController1)
{
m_pPhysicsController1->RestoreDynamics();
}
m_bSuspendDynamics = false;
}
KX_ClientObjectInfo* getClientInfo() { return m_pClient_info; }
CListValue* GetChildren();
CListValue* GetChildrenRecursive();
/**
* @section Python interface functions.
*/
virtual PyObject* py_getattro(PyObject *attr);
virtual PyObject* py_getattro_dict();
virtual int py_setattro(PyObject *attr, PyObject *value); // py_setattro method
virtual int py_delattro(PyObject *attr);
virtual PyObject* py_repr(void)
{
return PyString_FromString(GetName().ReadPtr());
}
/* quite annoying that we need these but the bloody
* py_getattro_up and py_setattro_up macro's have a returns in them! */
PyObject* py_getattro__internal(PyObject *attr);
int py_setattro__internal(PyObject *attr, PyObject *value); // py_setattro method
KX_PYMETHOD_NOARGS(KX_GameObject,GetPosition);
KX_PYMETHOD_O(KX_GameObject,SetPosition);
KX_PYMETHOD_O(KX_GameObject,SetWorldPosition);
KX_PYMETHOD_VARARGS(KX_GameObject, ApplyForce);
KX_PYMETHOD_VARARGS(KX_GameObject, ApplyTorque);
KX_PYMETHOD_VARARGS(KX_GameObject, ApplyRotation);
KX_PYMETHOD_VARARGS(KX_GameObject, ApplyMovement);
KX_PYMETHOD_VARARGS(KX_GameObject,GetLinearVelocity);
KX_PYMETHOD_VARARGS(KX_GameObject,SetLinearVelocity);
KX_PYMETHOD_VARARGS(KX_GameObject,GetAngularVelocity);
KX_PYMETHOD_VARARGS(KX_GameObject,SetAngularVelocity);
KX_PYMETHOD_VARARGS(KX_GameObject,GetVelocity);
KX_PYMETHOD_NOARGS(KX_GameObject,GetMass);
KX_PYMETHOD_NOARGS(KX_GameObject,GetReactionForce);
KX_PYMETHOD_NOARGS(KX_GameObject,GetOrientation);
KX_PYMETHOD_O(KX_GameObject,SetOrientation);
KX_PYMETHOD_NOARGS(KX_GameObject,GetVisible);
KX_PYMETHOD_VARARGS(KX_GameObject,SetVisible);
KX_PYMETHOD_VARARGS(KX_GameObject,SetOcclusion);
KX_PYMETHOD_NOARGS(KX_GameObject,GetState);
KX_PYMETHOD_O(KX_GameObject,SetState);
KX_PYMETHOD_VARARGS(KX_GameObject,AlignAxisToVect);
KX_PYMETHOD_O(KX_GameObject,GetAxisVect);
KX_PYMETHOD_NOARGS(KX_GameObject,SuspendDynamics);
KX_PYMETHOD_NOARGS(KX_GameObject,RestoreDynamics);
KX_PYMETHOD_NOARGS(KX_GameObject,EnableRigidBody);
KX_PYMETHOD_NOARGS(KX_GameObject,DisableRigidBody);
KX_PYMETHOD_VARARGS(KX_GameObject,ApplyImpulse);
KX_PYMETHOD_O(KX_GameObject,SetCollisionMargin);
KX_PYMETHOD_NOARGS(KX_GameObject,GetParent);
KX_PYMETHOD_O(KX_GameObject,SetParent);
KX_PYMETHOD_NOARGS(KX_GameObject,RemoveParent);
KX_PYMETHOD_NOARGS(KX_GameObject,GetChildren);
KX_PYMETHOD_NOARGS(KX_GameObject,GetChildrenRecursive);
KX_PYMETHOD_VARARGS(KX_GameObject,GetMesh);
KX_PYMETHOD_NOARGS(KX_GameObject,GetPhysicsId);
KX_PYMETHOD_NOARGS(KX_GameObject,GetPropertyNames);
KX_PYMETHOD_O(KX_GameObject,ReplaceMesh);
KX_PYMETHOD_NOARGS(KX_GameObject,EndObject);
KX_PYMETHOD_DOC(KX_GameObject,rayCastTo);
KX_PYMETHOD_DOC(KX_GameObject,rayCast);
KX_PYMETHOD_DOC_O(KX_GameObject,getDistanceTo);
KX_PYMETHOD_DOC_O(KX_GameObject,getVectTo);
KX_PYMETHOD_DOC_VARARGS(KX_GameObject, sendMessage);
/* attributes */
static PyObject* pyattr_get_name(void* self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static PyObject* pyattr_get_parent(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static PyObject* pyattr_get_mass(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_mass(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_lin_vel_min(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_lin_vel_min(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_lin_vel_max(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_lin_vel_max(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_visible(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_visible(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_worldPosition(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_worldPosition(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_localPosition(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_localPosition(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_localInertia(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_localInertia(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_worldOrientation(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_worldOrientation(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_localOrientation(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_localOrientation(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_worldScaling(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static PyObject* pyattr_get_localScaling(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_localScaling(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_timeOffset(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_timeOffset(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_state(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static int pyattr_set_state(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef, PyObject *value);
static PyObject* pyattr_get_meshes(void* self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static PyObject* pyattr_get_attrDict(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
/* Experemental! */
static PyObject* pyattr_get_sensors(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static PyObject* pyattr_get_controllers(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
static PyObject* pyattr_get_actuators(void *self_v, const KX_PYATTRIBUTE_DEF *attrdef);
/* getitem/setitem */
static Py_ssize_t Map_Len(PyObject* self);
static PyMappingMethods Mapping;
static PyObject* Map_GetItem(PyObject *self_v, PyObject *item);
static int Map_SetItem(PyObject *self_v, PyObject *key, PyObject *val);
private :
/**
* Random internal function to convert python function arguments
* to 2 vectors.
* @return true if conversion was possible.
*/
bool
ConvertPythonVectorArgs(
PyObject* args,
MT_Vector3& pos,
MT_Vector3& pos2
);
};
#endif //__KX_GAMEOBJECT
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