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blender/source/gameengine/Ketsji/KX_PolyProxy.cpp
Benoit Bolsee 386122ada6 BGE performance, 4th round: logic 
This commit extends the technique of dynamic linked list to the logic
system to eliminate as much as possible temporaries, map lookup or 
full scan. The logic engine is now free of memory allocation, which is
an important stability factor. 

The overhead of the logic system is reduced by a factor between 3 and 6
depending on the logic setup. This is the speed-up you can expect on 
a logic setup using simple bricks. Heavy bricks like python controllers
and ray sensors will still take about the same time to execute so the
speed up will be less important.

The core of the logic engine has been much reworked but the functionality
is still the same except for one thing: the priority system on the 
execution of controllers. The exact same remark applies to actuators but
I'll explain for controllers only:

Previously, it was possible, with the "executePriority" attribute to set
a controller to run before any other controllers in the game. Other than
that, the sequential execution of controllers, as defined in Blender was
guaranteed by default.

With the new system, the sequential execution of controllers is still 
guaranteed but only within the controllers of one object. the user can
no longer set a controller to run before any other controllers in the
game. The "executePriority" attribute controls the execution of controllers
within one object. The priority is a small number starting from 0 for the
first controller and incrementing for each controller.

If this missing feature is a must, a special method can be implemented
to set a controller to run before all other controllers.

Other improvements:
- Systematic use of reference in parameter passing to avoid unnecessary data copy
- Use pre increment in iterator instead of post increment to avoid temporary allocation
- Use const char* instead of STR_String whenever possible to avoid temporary allocation
- Fix reference counting bugs (memory leak)
- Fix a crash in certain cases of state switching and object deletion
- Minor speed up in property sensor
- Removal of objects during the game is a lot faster
2009-05-10 20:53:58 +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 *****
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include "KX_PolyProxy.h"
#include "KX_MeshProxy.h"
#include "RAS_MeshObject.h"
#include "KX_BlenderMaterial.h"
#include "KX_PolygonMaterial.h"
#include "KX_PyMath.h"
PyTypeObject KX_PolyProxy::Type = {
#if (PY_VERSION_HEX >= 0x02060000)
PyVarObject_HEAD_INIT(NULL, 0)
#else
/* python 2.5 and below */
PyObject_HEAD_INIT( NULL ) /* required py macro */
0, /* ob_size */
#endif
"KX_PolyProxy",
sizeof(PyObjectPlus_Proxy),
0,
py_base_dealloc,
0,
0,
0,
0,
py_base_repr,
0,0,0,0,0,0,
py_base_getattro,
py_base_setattro,
0,0,0,0,0,0,0,0,0,
Methods
};
PyParentObject KX_PolyProxy::Parents[] = {
&KX_PolyProxy::Type,
&CValue::Type,
&PyObjectPlus::Type,
NULL
};
PyMethodDef KX_PolyProxy::Methods[] = {
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,getMaterialIndex),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,getNumVertex),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,isVisible),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,isCollider),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,getMaterialName),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,getTextureName),
KX_PYMETHODTABLE(KX_PolyProxy,getVertexIndex),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,getMesh),
KX_PYMETHODTABLE_NOARGS(KX_PolyProxy,getMaterial),
{NULL,NULL} //Sentinel
};
PyAttributeDef KX_PolyProxy::Attributes[] = {
/* All dummy's so they come up in a dir() */
//KX_PYATTRIBUTE_TODO("DummyProps"),
KX_PYATTRIBUTE_DUMMY("matname"),
KX_PYATTRIBUTE_DUMMY("texture"),
KX_PYATTRIBUTE_DUMMY("material"),
KX_PYATTRIBUTE_DUMMY("matid"),
KX_PYATTRIBUTE_DUMMY("v1"),
KX_PYATTRIBUTE_DUMMY("v2"),
KX_PYATTRIBUTE_DUMMY("v3"),
KX_PYATTRIBUTE_DUMMY("v4"),
KX_PYATTRIBUTE_DUMMY("visible"),
KX_PYATTRIBUTE_DUMMY("collide"),
{ NULL } //Sentinel
};
PyObject* KX_PolyProxy::py_getattro(PyObject *attr)
{
char *attr_str= PyString_AsString(attr);
if (!strcmp(attr_str, "matname"))
{
return PyString_FromString(m_polygon->GetMaterial()->GetPolyMaterial()->GetMaterialName());
}
if (!strcmp(attr_str, "texture"))
{
return PyString_FromString(m_polygon->GetMaterial()->GetPolyMaterial()->GetTextureName());
}
if (!strcmp(attr_str, "material"))
{
RAS_IPolyMaterial *polymat = m_polygon->GetMaterial()->GetPolyMaterial();
if(polymat->GetFlag() & RAS_BLENDERMAT)
{
KX_BlenderMaterial* mat = static_cast<KX_BlenderMaterial*>(polymat);
return mat->GetProxy();
}
else
{
KX_PolygonMaterial* mat = static_cast<KX_PolygonMaterial*>(polymat);
return mat->GetProxy();
}
}
if (!strcmp(attr_str, "matid"))
{
// we'll have to scan through the material bucket of the mes and compare with
// the one of the polygon
RAS_MaterialBucket* polyBucket = m_polygon->GetMaterial();
unsigned int matid;
for (matid=0; matid<(unsigned int)m_mesh->NumMaterials(); matid++)
{
RAS_MeshMaterial* meshMat = m_mesh->GetMeshMaterial(matid);
if (meshMat->m_bucket == polyBucket)
// found it
break;
}
return PyInt_FromLong(matid);
}
if (!strcmp(attr_str, "v1"))
{
return PyInt_FromLong(m_polygon->GetVertexOffset(0));
}
if (!strcmp(attr_str, "v2"))
{
return PyInt_FromLong(m_polygon->GetVertexOffset(1));
}
if (!strcmp(attr_str, "v3"))
{
return PyInt_FromLong(m_polygon->GetVertexOffset(2));
}
if (!strcmp(attr_str, "v4"))
{
return PyInt_FromLong(((m_polygon->VertexCount()>3)?m_polygon->GetVertexOffset(3):0));
}
if (!strcmp(attr_str, "visible"))
{
return PyInt_FromLong(m_polygon->IsVisible());
}
if (!strcmp(attr_str, "collide"))
{
return PyInt_FromLong(m_polygon->IsCollider());
}
py_getattro_up(CValue);
}
PyObject* KX_PolyProxy::py_getattro_dict() {
py_getattro_dict_up(CValue);
}
KX_PolyProxy::KX_PolyProxy(const RAS_MeshObject*mesh, RAS_Polygon* polygon)
: m_polygon(polygon),
m_mesh((RAS_MeshObject*)mesh)
{
}
KX_PolyProxy::~KX_PolyProxy()
{
}
// stuff for cvalue related things
CValue* KX_PolyProxy::Calc(VALUE_OPERATOR, CValue *) { return NULL;}
CValue* KX_PolyProxy::CalcFinal(VALUE_DATA_TYPE, VALUE_OPERATOR, CValue *) { return NULL;}
STR_String sPolyName="polygone";
const STR_String & KX_PolyProxy::GetText() {return sPolyName;};
double KX_PolyProxy::GetNumber() { return -1;}
STR_String& KX_PolyProxy::GetName() { return sPolyName;}
void KX_PolyProxy::SetName(const char *) { };
CValue* KX_PolyProxy::GetReplica() { return NULL;}
// stuff for python integration
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, getMaterialIndex,
"getMaterialIndex() : return the material index of the polygon in the mesh\n")
{
RAS_MaterialBucket* polyBucket = m_polygon->GetMaterial();
unsigned int matid;
for (matid=0; matid<(unsigned int)m_mesh->NumMaterials(); matid++)
{
RAS_MeshMaterial* meshMat = m_mesh->GetMeshMaterial(matid);
if (meshMat->m_bucket == polyBucket)
// found it
break;
}
return PyInt_FromLong(matid);
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, getNumVertex,
"getNumVertex() : returns the number of vertex of the polygon, 3 or 4\n")
{
return PyInt_FromLong(m_polygon->VertexCount());
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, isVisible,
"isVisible() : returns whether the polygon is visible or not\n")
{
return PyInt_FromLong(m_polygon->IsVisible());
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, isCollider,
"isCollider() : returns whether the polygon is receives collision or not\n")
{
return PyInt_FromLong(m_polygon->IsCollider());
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, getMaterialName,
"getMaterialName() : returns the polygon material name, \"NoMaterial\" if no material\n")
{
return PyString_FromString(m_polygon->GetMaterial()->GetPolyMaterial()->GetMaterialName());
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, getTextureName,
"getTexturelName() : returns the polygon texture name, \"NULL\" if no texture\n")
{
return PyString_FromString(m_polygon->GetMaterial()->GetPolyMaterial()->GetTextureName());
}
KX_PYMETHODDEF_DOC(KX_PolyProxy, getVertexIndex,
"getVertexIndex(vertex) : returns the mesh vertex index of a polygon vertex\n"
"vertex: index of the vertex in the polygon: 0->3\n"
"return value can be used to retrieve the vertex details through mesh proxy\n"
"Note: getVertexIndex(3) on a triangle polygon returns 0\n")
{
int index;
if (!PyArg_ParseTuple(args,"i:getVertexIndex",&index))
{
return NULL;
}
if (index < 0 || index > 3)
{
PyErr_SetString(PyExc_AttributeError, "poly.getVertexIndex(int): KX_PolyProxy, expected an index between 0-3");
return NULL;
}
if (index < m_polygon->VertexCount())
{
return PyInt_FromLong(m_polygon->GetVertexOffset(index));
}
return PyInt_FromLong(0);
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, getMesh,
"getMesh() : returns a mesh proxy\n")
{
KX_MeshProxy* meshproxy = new KX_MeshProxy((RAS_MeshObject*)m_mesh);
return meshproxy->NewProxy(true);
}
KX_PYMETHODDEF_DOC_NOARGS(KX_PolyProxy, getMaterial,
"getMaterial() : returns a material\n")
{
RAS_IPolyMaterial *polymat = m_polygon->GetMaterial()->GetPolyMaterial();
if(polymat->GetFlag() & RAS_BLENDERMAT)
{
KX_BlenderMaterial* mat = static_cast<KX_BlenderMaterial*>(polymat);
return mat->GetProxy();
}
else
{
KX_PolygonMaterial* mat = static_cast<KX_PolygonMaterial*>(polymat);
return mat->GetProxy();
}
}
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