blender-archive/source/blender/python/api2_2x/sceneRender.c

/* 
 * $Id$
 *
 * ***** BEGIN GPL/BL DUAL 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. The Blender
 * Foundation also sells licenses for use in proprietary software under
 * the Blender License.  See http://www.blender.org/BL/ for information
 * about this.
 *
 * 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.
 *
 * This is a new part of Blender.
 *
 * Contributor(s): Joseph Gilbert
 *
 * ***** END GPL/BL DUAL LICENSE BLOCK *****
*/

#include <BIF_renderwin.h>
#include <BKE_utildefines.h>
#include <BKE_global.h>
#include <DNA_image_types.h>
#include <BIF_drawscene.h>
#include <BLI_blenlib.h>
#include <BKE_image.h>
#include <BIF_space.h>
#include <DNA_scene_types.h>
#include <DNA_space_types.h>
#include <mydevice.h>
#include <butspace.h>
#include <BKE_bad_level_calls.h>
#include <render.h> /* RE_animrender() */
#include "sceneRender.h"
#include "blendef.h"
#include "Scene.h"
#include "gen_utils.h"


#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

//local defines
#define PY_NONE		0
#define PY_LOW		1
#define PY_MEDIUM	2
#define PY_HIGH		3
#define PY_HIGHER	4
#define PY_BEST		5
#define PY_SKYDOME	1
#define PY_FULL	 2

extern RE_Render R;

//---------------------------------------Render prototypes-------------
static PyObject *M_Render_CloseRenderWindow( PyObject * self );
static PyObject *M_Render_EnableDispView( PyObject * self );
static PyObject *M_Render_EnableDispWin( PyObject * self );
static PyObject *M_Render_SetRenderWinPos( PyObject * self, PyObject * args );
static PyObject *M_Render_EnableEdgeShift( PyObject * self, PyObject * args );
static PyObject *M_Render_EnableEdgeAll( PyObject * self, PyObject * args );
//----------------------------------------------Render doc strings------
static char M_Render_doc[] = "The Blender Render module";
//----------------------------------------------Render method def-------
struct PyMethodDef M_Render_methods[] = {
	{"CloseRenderWindow", ( PyCFunction ) M_Render_CloseRenderWindow,
	 METH_NOARGS,
	 "() - close the rendering window\n"},
	{"EnableDispView", ( PyCFunction ) M_Render_EnableDispView,
	 METH_NOARGS,
	 "(bool) - enable Sceneing in view\n"},
	{"EnableDispWin", ( PyCFunction ) M_Render_EnableDispWin, METH_NOARGS,
	 "(bool) - enable Sceneing in new window\n"},
	{"SetRenderWinPos", ( PyCFunction ) M_Render_SetRenderWinPos,
	 METH_VARARGS,
	 "([string list]) - position the rendering window in around the edge of the screen\n"},
	{"EnableEdgeShift", ( PyCFunction ) M_Render_EnableEdgeShift,
	 METH_VARARGS,
	 "(bool) - with the unified renderer the outlines are shifted a bit.\n"},
	{"EnableEdgeAll", ( PyCFunction ) M_Render_EnableEdgeAll, METH_VARARGS,
	 "(bool) - also consider transparent faces for edge-rendering with the unified renderer\n"},
	{NULL, NULL, 0, NULL}
};
//------------------------------------BPy_RenderData methods/callbacks--
static PyObject *RenderData_Render( BPy_RenderData * self );
static PyObject *RenderData_RenderAnim( BPy_RenderData * self );
static PyObject *RenderData_Play( BPy_RenderData * self );
static PyObject *RenderData_SetRenderPath( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_GetRenderPath( BPy_RenderData * self );
static PyObject *RenderData_SetBackbufPath( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_GetBackbufPath( BPy_RenderData * self );
static PyObject *RenderData_EnableBackbuf( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_SetFtypePath( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_GetFtypePath( BPy_RenderData * self );
static PyObject *RenderData_EnableExtensions( BPy_RenderData * self,
					      PyObject * args );
static PyObject *RenderData_EnableSequencer( BPy_RenderData * self,
					     PyObject * args );
static PyObject *RenderData_EnableRenderDaemon( BPy_RenderData * self,
						PyObject * args );
static PyObject *RenderData_EnableToonShading( BPy_RenderData * self,
					       PyObject * args );
static PyObject *RenderData_EdgeIntensity( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_SetEdgeColor( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_GetEdgeColor( BPy_RenderData * self );
static PyObject *RenderData_EdgeAntiShift( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_EnableOversampling( BPy_RenderData * self,
						PyObject * args );
static PyObject *RenderData_SetOversamplingLevel( BPy_RenderData * self,
						  PyObject * args );
static PyObject *RenderData_EnableMotionBlur( BPy_RenderData * self,
					      PyObject * args );
static PyObject *RenderData_MotionBlurLevel( BPy_RenderData * self,
					     PyObject * args );
static PyObject *RenderData_PartsX( BPy_RenderData * self, PyObject * args );
static PyObject *RenderData_PartsY( BPy_RenderData * self, PyObject * args );
static PyObject *RenderData_EnableSky( BPy_RenderData * self );
static PyObject *RenderData_EnablePremultiply( BPy_RenderData * self );
static PyObject *RenderData_EnableKey( BPy_RenderData * self );
static PyObject *RenderData_EnableShadow( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_EnablePanorama( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_EnableEnvironmentMap( BPy_RenderData * self,
						  PyObject * args );
static PyObject *RenderData_EnableRayTracing( BPy_RenderData * self,
					      PyObject * args );
static PyObject *RenderData_EnableRadiosityRender( BPy_RenderData * self,
						   PyObject * args );
static PyObject *RenderData_SetRenderWinSize( BPy_RenderData * self,
					      PyObject * args );
static PyObject *RenderData_EnableFieldRendering( BPy_RenderData * self,
						  PyObject * args );
static PyObject *RenderData_EnableOddFieldFirst( BPy_RenderData * self,
						 PyObject * args );
static PyObject *RenderData_EnableFieldTimeDisable( BPy_RenderData * self,
						    PyObject * args );
static PyObject *RenderData_EnableGaussFilter( BPy_RenderData * self,
					       PyObject * args );
static PyObject *RenderData_EnableBorderRender( BPy_RenderData * self,
						PyObject * args );
static PyObject *RenderData_SetBorder( BPy_RenderData * self,
				       PyObject * args );
static PyObject *RenderData_EnableGammaCorrection( BPy_RenderData * self,
						   PyObject * args );
static PyObject *RenderData_GaussFilterSize( BPy_RenderData * self,
					     PyObject * args );
static PyObject *RenderData_StartFrame( BPy_RenderData * self,
					PyObject * args );
static PyObject *RenderData_CurrentFrame( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_EndFrame( BPy_RenderData * self, PyObject * args );
static PyObject *RenderData_ImageSizeX( BPy_RenderData * self,
					PyObject * args );
static PyObject *RenderData_ImageSizeY( BPy_RenderData * self,
					PyObject * args );
static PyObject *RenderData_AspectRatioX( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_AspectRatioY( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_SetRenderer( BPy_RenderData * self,
					 PyObject * args );
static PyObject *RenderData_EnableCropping( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_SetImageType( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_Quality( BPy_RenderData * self, PyObject * args );
static PyObject *RenderData_FramesPerSec( BPy_RenderData * self,
					  PyObject * args );
static PyObject *RenderData_EnableGrayscale( BPy_RenderData * self );
static PyObject *RenderData_EnableRGBColor( BPy_RenderData * self );
static PyObject *RenderData_EnableRGBAColor( BPy_RenderData * self );
static PyObject *RenderData_SizePreset( BPy_RenderData * self,
					PyObject * args );
static PyObject *RenderData_EnableUnifiedRenderer( BPy_RenderData * self,
						   PyObject * args );
static PyObject *RenderData_SetYafrayGIQuality( BPy_RenderData * self,
						PyObject * args );
static PyObject *RenderData_SetYafrayGIMethod( BPy_RenderData * self,
					       PyObject * args );
static PyObject *RenderData_YafrayGIPower( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_YafrayGIDepth( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_YafrayGICDepth( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_EnableYafrayGICache( BPy_RenderData * self,
						 PyObject * args );
static PyObject *RenderData_EnableYafrayGIPhotons( BPy_RenderData * self,
						   PyObject * args );
static PyObject *RenderData_YafrayGIPhotonCount( BPy_RenderData * self,
						 PyObject * args );
static PyObject *RenderData_YafrayGIPhotonRadius( BPy_RenderData * self,
						  PyObject * args );
static PyObject *RenderData_YafrayGIPhotonMixCount( BPy_RenderData * self,
						    PyObject * args );
static PyObject *RenderData_EnableYafrayGITunePhotons( BPy_RenderData * self,
						       PyObject * args );
static PyObject *RenderData_YafrayGIShadowQuality( BPy_RenderData * self,
						   PyObject * args );
static PyObject *RenderData_YafrayGIPixelsPerSample( BPy_RenderData * self,
						     PyObject * args );
static PyObject *RenderData_YafrayGIRefinement( BPy_RenderData * self,
						PyObject * args );
static PyObject *RenderData_YafrayRayBias( BPy_RenderData * self,
					   PyObject * args );
static PyObject *RenderData_YafrayRayDepth( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_YafrayGamma( BPy_RenderData * self,
					 PyObject * args );
static PyObject *RenderData_YafrayExposure( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_YafrayProcessorCount( BPy_RenderData * self,
						  PyObject * args );
static PyObject *RenderData_EnableGameFrameStretch( BPy_RenderData * self );
static PyObject *RenderData_EnableGameFrameExpose( BPy_RenderData * self );
static PyObject *RenderData_EnableGameFrameBars( BPy_RenderData * self );
static PyObject *RenderData_SetGameFrameColor( BPy_RenderData * self,
					       PyObject * args );
static PyObject *RenderData_GetGameFrameColor( BPy_RenderData * self );
static PyObject *RenderData_GammaLevel( BPy_RenderData * self,
					PyObject * args );
static PyObject *RenderData_PostProcessAdd( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_PostProcessMultiply( BPy_RenderData * self,
						 PyObject * args );
static PyObject *RenderData_PostProcessGamma( BPy_RenderData * self,
					      PyObject * args );
static PyObject *RenderData_SGIMaxsize( BPy_RenderData * self,
					PyObject * args );
static PyObject *RenderData_EnableSGICosmo( BPy_RenderData * self,
					    PyObject * args );
static PyObject *RenderData_OldMapValue( BPy_RenderData * self,
					 PyObject * args );
static PyObject *RenderData_NewMapValue( BPy_RenderData * self,
					 PyObject * args );

static void RenderData_dealloc( BPy_RenderData * self );
static PyObject *RenderData_getAttr( BPy_RenderData * self, char *name );
static PyObject *RenderData_repr( BPy_RenderData * self );
//------------------------------------BPy_RenderData  method def--------
static PyMethodDef BPy_RenderData_methods[] = {
	{"render", ( PyCFunction ) RenderData_Render, METH_NOARGS,
	 "() - render the scene\n"},
	{"renderAnim", ( PyCFunction ) RenderData_RenderAnim, METH_NOARGS,
	 "() - render a sequence from start frame to end frame\n"},
	{"play", ( PyCFunction ) RenderData_Play, METH_NOARGS,
	 "() - play animation of rendered images/avi (searches Pics: field)\n"},
	{"setRenderPath", ( PyCFunction ) RenderData_SetRenderPath,
	 METH_VARARGS,
	 "(string) - get/set the path to output the rendered images to\n"},
	{"getRenderPath", ( PyCFunction ) RenderData_GetRenderPath,
	 METH_NOARGS,
	 "() - get the path to directory where rendered images will go\n"},
	{"setBackbufPath", ( PyCFunction ) RenderData_SetBackbufPath,
	 METH_VARARGS,
	 "(string) - get/set the path to a background image and load it\n"},
	{"getBackbufPath", ( PyCFunction ) RenderData_GetBackbufPath,
	 METH_NOARGS,
	 "() - get the path to background image file\n"},
	{"enableBackbuf", ( PyCFunction ) RenderData_EnableBackbuf,
	 METH_VARARGS,
	 "(bool) - enable/disable the backbuf image\n"},
	{"setFtypePath", ( PyCFunction ) RenderData_SetFtypePath, METH_VARARGS,
	 "(string) - get/set the path to output the Ftype file\n"},
	{"getFtypePath", ( PyCFunction ) RenderData_GetFtypePath, METH_NOARGS,
	 "() - get the path to Ftype file\n"},
	{"enableExtensions", ( PyCFunction ) RenderData_EnableExtensions,
	 METH_VARARGS,
	 "(bool) - enable/disable windows extensions for output files\n"},
	{"enableSequencer", ( PyCFunction ) RenderData_EnableSequencer,
	 METH_VARARGS,
	 "(bool) - enable/disable Do Sequence\n"},
	{"enableRenderDaemon", ( PyCFunction ) RenderData_EnableRenderDaemon,
	 METH_VARARGS,
	 "(bool) - enable/disable Scene daemon\n"},
	{"enableToonShading", ( PyCFunction ) RenderData_EnableToonShading,
	 METH_VARARGS,
	 "(bool) - enable/disable Edge rendering\n"},
	{"edgeIntensity", ( PyCFunction ) RenderData_EdgeIntensity,
	 METH_VARARGS,
	 "(int) - get/set edge intensity for toon shading\n"},
	{"setEdgeColor", ( PyCFunction ) RenderData_SetEdgeColor, METH_VARARGS,
	 "(f,f,f) - set the edge color for toon shading - Red,Green,Blue expected.\n"},
	{"getEdgeColor", ( PyCFunction ) RenderData_GetEdgeColor, METH_VARARGS,
	 "() - get the edge color for toon shading - Red,Green,Blue expected.\n"},
	{"edgeAntiShift", ( PyCFunction ) RenderData_EdgeAntiShift,
	 METH_VARARGS,
	 "(int) - with the unified renderer to reduce intensity on boundaries.\n"},
	{"enableOversampling", ( PyCFunction ) RenderData_EnableOversampling,
	 METH_VARARGS,
	 "(bool) - enable/disable oversampling (anit-aliasing).\n"},
	{"setOversamplingLevel",
	 ( PyCFunction ) RenderData_SetOversamplingLevel, METH_VARARGS,
	 "(enum) - get/set the level of oversampling (anit-aliasing).\n"},
	{"enableMotionBlur", ( PyCFunction ) RenderData_EnableMotionBlur,
	 METH_VARARGS,
	 "(bool) - enable/disable MBlur.\n"},
	{"motionBlurLevel", ( PyCFunction ) RenderData_MotionBlurLevel,
	 METH_VARARGS,
	 "(float) - get/set the length of shutter time for motion blur.\n"},
	{"partsX", ( PyCFunction ) RenderData_PartsX, METH_VARARGS,
	 "(int) - get/set the number of parts to divide the render in the X direction\n"},
	{"partsY", ( PyCFunction ) RenderData_PartsY, METH_VARARGS,
	 "(int) - get/set the number of parts to divide the render in the Y direction\n"},
	{"enableSky", ( PyCFunction ) RenderData_EnableSky, METH_NOARGS,
	 "() - enable render background with sky\n"},
	{"enablePremultiply", ( PyCFunction ) RenderData_EnablePremultiply,
	 METH_NOARGS,
	 "() - enable premultiply alpha\n"},
	{"enableKey", ( PyCFunction ) RenderData_EnableKey, METH_NOARGS,
	 "() - enable alpha and colour values remain unchanged\n"},
	{"enableShadow", ( PyCFunction ) RenderData_EnableShadow, METH_VARARGS,
	 "(bool) - enable/disable shadow calculation\n"},
	{"enablePanorama", ( PyCFunction ) RenderData_EnablePanorama,
	 METH_VARARGS,
	 "(bool) - enable/disable panorama rendering (output width is multiplied by Xparts)\n"},
	{"enableEnvironmentMap",
	 ( PyCFunction ) RenderData_EnableEnvironmentMap, METH_VARARGS,
	 "(bool) - enable/disable environment map rendering\n"},
	{"enableRayTracing", ( PyCFunction ) RenderData_EnableRayTracing,
	 METH_VARARGS,
	 "(bool) - enable/disable ray tracing\n"},
	{"enableRadiosityRender",
	 ( PyCFunction ) RenderData_EnableRadiosityRender, METH_VARARGS,
	 "(bool) - enable/disable radiosity rendering\n"},
	{"setRenderWinSize", ( PyCFunction ) RenderData_SetRenderWinSize,
	 METH_VARARGS,
	 "(enum) - get/set the size of the render window\n"},
	{"enableFieldRendering",
	 ( PyCFunction ) RenderData_EnableFieldRendering, METH_VARARGS,
	 "(bool) - enable/disable field rendering\n"},
	{"enableOddFieldFirst", ( PyCFunction ) RenderData_EnableOddFieldFirst,
	 METH_VARARGS,
	 "(bool) - enable/disable Odd field first rendering (Default: Even field)\n"},
	{"enableFieldTimeDisable",
	 ( PyCFunction ) RenderData_EnableFieldTimeDisable, METH_VARARGS,
	 "(bool) - enable/disable time difference in field calculations\n"},
	{"enableGaussFilter", ( PyCFunction ) RenderData_EnableGaussFilter,
	 METH_VARARGS,
	 "(bool) - enable/disable Gauss sampling filter for antialiasing\n"},
	{"enableBorderRender", ( PyCFunction ) RenderData_EnableBorderRender,
	 METH_VARARGS,
	 "(bool) - enable/disable small cut-out rendering\n"},
	{"setBorder", ( PyCFunction ) RenderData_SetBorder, METH_VARARGS,
	 "(f,f,f,f) - set the border for border rendering\n"},
	{"enableGammaCorrection",
	 ( PyCFunction ) RenderData_EnableGammaCorrection, METH_VARARGS,
	 "(bool) - enable/disable gamma correction\n"},
	{"gaussFilterSize", ( PyCFunction ) RenderData_GaussFilterSize,
	 METH_VARARGS,
	 "(float) - get/sets the Gauss filter size\n"},
	{"startFrame", ( PyCFunction ) RenderData_StartFrame, METH_VARARGS,
	 "(int) - get/set the starting frame for rendering\n"},
	{"currentFrame", ( PyCFunction ) RenderData_CurrentFrame, METH_VARARGS,
	 "(int) - get/set the current frame for rendering\n"},
	{"endFrame", ( PyCFunction ) RenderData_EndFrame, METH_VARARGS,
	 "(int) - get/set the ending frame for rendering\n"},
	{"imageSizeX", ( PyCFunction ) RenderData_ImageSizeX, METH_VARARGS,
	 "(int) - get/set the image width in pixels\n"},
	{"imageSizeY", ( PyCFunction ) RenderData_ImageSizeY, METH_VARARGS,
	 "(int) - get/set the image height in pixels\n"},
	{"aspectRatioX", ( PyCFunction ) RenderData_AspectRatioX, METH_VARARGS,
	 "(int) - get/set the horizontal aspect ratio\n"},
	{"aspectRatioY", ( PyCFunction ) RenderData_AspectRatioY, METH_VARARGS,
	 "(int) - get/set the vertical aspect ratio\n"},
	{"setRenderer", ( PyCFunction ) RenderData_SetRenderer, METH_VARARGS,
	 "(enum) - get/set which renderer to render the output\n"},
	{"enableCropping", ( PyCFunction ) RenderData_EnableCropping,
	 METH_VARARGS,
	 "(bool) - enable/disable exclusion of border rendering from total image\n"},
	{"setImageType", ( PyCFunction ) RenderData_SetImageType, METH_VARARGS,
	 "(enum) - get/set the type of image to output from the render\n"},
	{"quality", ( PyCFunction ) RenderData_Quality, METH_VARARGS,
	 "(int) - get/set quality get/setting for JPEG images, AVI Jpeg and SGI movies\n"},
	{"framesPerSec", ( PyCFunction ) RenderData_FramesPerSec, METH_VARARGS,
	 "(int) - get/set frames per second\n"},
	{"enableGrayscale", ( PyCFunction ) RenderData_EnableGrayscale,
	 METH_NOARGS,
	 "() - images are saved with BW (grayscale) data\n"},
	{"enableRGBColor", ( PyCFunction ) RenderData_EnableRGBColor,
	 METH_NOARGS,
	 "() - images are saved with RGB (color) data\n"},
	{"enableRGBAColor", ( PyCFunction ) RenderData_EnableRGBAColor,
	 METH_NOARGS,
	 "() - images are saved with RGB and Alpha data (if supported)\n"},
	{"sizePreset", ( PyCFunction ) RenderData_SizePreset, METH_VARARGS,
	 "(enum) - get/set the render to one of a few preget/sets\n"},
	{"enableUnifiedRenderer",
	 ( PyCFunction ) RenderData_EnableUnifiedRenderer, METH_VARARGS,
	 "(bool) - use the unified renderer\n"},
	{"setYafrayGIQuality", ( PyCFunction ) RenderData_SetYafrayGIQuality,
	 METH_VARARGS,
	 "(enum) - get/set yafray global Illumination quality\n"},
	{"setYafrayGIMethod", ( PyCFunction ) RenderData_SetYafrayGIMethod,
	 METH_VARARGS,
	 "(enum) - get/set yafray global Illumination method\n"},
	{"yafrayGIPower", ( PyCFunction ) RenderData_YafrayGIPower,
	 METH_VARARGS,
	 "(float) - get/set GI lighting intensity scale\n"},
	{"yafrayGIDepth", ( PyCFunction ) RenderData_YafrayGIDepth,
	 METH_VARARGS,
	 "(int) - get/set number of bounces of the indirect light\n"},
	{"yafrayGICDepth", ( PyCFunction ) RenderData_YafrayGICDepth,
	 METH_VARARGS,
	 "(int) - get/set number of bounces inside objects (for caustics)\n"},
	{"enableYafrayGICache", ( PyCFunction ) RenderData_EnableYafrayGICache,
	 METH_VARARGS,
	 "(bool) - enable/disable cache irradiance samples (faster)\n"},
	{"enableYafrayGIPhotons",
	 ( PyCFunction ) RenderData_EnableYafrayGIPhotons, METH_VARARGS,
	 "(bool) - enable/disable use global photons to help in GI\n"},
	{"yafrayGIPhotonCount", ( PyCFunction ) RenderData_YafrayGIPhotonCount,
	 METH_VARARGS,
	 "(int) - get/set number of photons to shoot\n"},
	{"yafrayGIPhotonRadius",
	 ( PyCFunction ) RenderData_YafrayGIPhotonRadius, METH_VARARGS,
	 "(float) - get/set radius to search for photons to mix (blur)\n"},
	{"yafrayGIPhotonMixCount",
	 ( PyCFunction ) RenderData_YafrayGIPhotonMixCount, METH_VARARGS,
	 "(int) - get/set number of photons to shoot\n"},
	{"enableYafrayGITunePhotons",
	 ( PyCFunction ) RenderData_EnableYafrayGITunePhotons, METH_VARARGS,
	 "(bool) - enable/disable show the photonmap directly in the render for tuning\n"},
	{"yafrayGIShadowQuality",
	 ( PyCFunction ) RenderData_YafrayGIShadowQuality, METH_VARARGS,
	 "(float) - get/set the shadow quality, keep it under 0.95\n"},
	{"yafrayGIPixelsPerSample",
	 ( PyCFunction ) RenderData_YafrayGIPixelsPerSample, METH_VARARGS,
	 "(int) - get/set maximum number of pixels without samples, the lower the better and slower\n"},
	{"yafrayGIRefinement", ( PyCFunction ) RenderData_YafrayGIRefinement,
	 METH_VARARGS,
	 "(float) - get/setthreshold to refine shadows EXPERIMENTAL. 1 = no refinement\n"},
	{"yafrayRayBias", ( PyCFunction ) RenderData_YafrayRayBias,
	 METH_VARARGS,
	 "(float) - get/set shadow ray bias to avoid self shadowing\n"},
	{"yafrayRayDepth", ( PyCFunction ) RenderData_YafrayRayDepth,
	 METH_VARARGS,
	 "(int) - get/set maximum render ray depth from the camera\n"},
	{"yafrayGamma", ( PyCFunction ) RenderData_YafrayGamma, METH_VARARGS,
	 "(float) - get/set gamma correction, 1 is off\n"},
	{"yafrayExposure", ( PyCFunction ) RenderData_YafrayExposure,
	 METH_VARARGS,
	 "(float) - get/set exposure adjustment, 0 is off\n"},
	{"yafrayProcessorCount",
	 ( PyCFunction ) RenderData_YafrayProcessorCount, METH_VARARGS,
	 "(int) - get/set number of processors to use\n"},
	{"enableGameFrameStretch",
	 ( PyCFunction ) RenderData_EnableGameFrameStretch, METH_NOARGS,
	 "(l) - enble stretch or squeeze the viewport to fill the display window\n"},
	{"enableGameFrameExpose",
	 ( PyCFunction ) RenderData_EnableGameFrameExpose, METH_NOARGS,
	 "(l) - enable show the entire viewport in the display window, viewing more horizontally or vertically\n"},
	{"enableGameFrameBars", ( PyCFunction ) RenderData_EnableGameFrameBars,
	 METH_NOARGS,
	 "() - enable show the entire viewport in the display window, using bar horizontally or vertically\n"},
	{"setGameFrameColor", ( PyCFunction ) RenderData_SetGameFrameColor,
	 METH_VARARGS,
	 "(f,f,f) - set the red, green, blue component of the bars\n"},
	{"getGameFrameColor", ( PyCFunction ) RenderData_GetGameFrameColor,
	 METH_VARARGS,
	 "() - get the red, green, blue component of the bars\n"},
	{"gammaLevel", ( PyCFunction ) RenderData_GammaLevel, METH_VARARGS,
	 "(float) - get/set the gamma value for blending oversampled images (1.0 = no correction\n"},
	{"postProcessAdd", ( PyCFunction ) RenderData_PostProcessAdd,
	 METH_VARARGS,
	 "(float) - get/set post processing add\n"},
	{"postProcessMultiply", ( PyCFunction ) RenderData_PostProcessMultiply,
	 METH_VARARGS,
	 "(float) - get/set post processing multiply\n"},
	{"postProcessGamma", ( PyCFunction ) RenderData_PostProcessGamma,
	 METH_VARARGS,
	 "(float) - get/set post processing gamma\n"},
	{"SGIMaxsize", ( PyCFunction ) RenderData_SGIMaxsize, METH_VARARGS,
	 "(int) - get/set maximum size per frame to save in an SGI movie\n"},
	{"enableSGICosmo", ( PyCFunction ) RenderData_EnableSGICosmo,
	 METH_VARARGS,
	 "(bool) - enable/disable attempt to save SGI movies using Cosmo hardware\n"},
	{"oldMapValue", ( PyCFunction ) RenderData_OldMapValue, METH_VARARGS,
	 "(int) - get/set specify old map value in frames\n"},
	{"newMapValue", ( PyCFunction ) RenderData_NewMapValue, METH_VARARGS,
	 "(int) - get/set specify new map value in frames\n"},
	{NULL, NULL, 0, NULL}
};
//------------------------------------BPy_RenderData Type defintion------
PyTypeObject RenderData_Type = {
	PyObject_HEAD_INIT( NULL ) 0,	/* ob_size */
	"Blender RenderData",	/* tp_name */
	sizeof( BPy_RenderData ),	/* tp_basicsize */
	0,			/* tp_itemsize */
	/* methods */
	( destructor ) RenderData_dealloc,	/* tp_dealloc */
	0,			/* tp_print */
	( getattrfunc ) RenderData_getAttr,	/* tp_getattr */
	0,			/* tp_setattr */
	0,			/* tp_compare */
	( reprfunc ) RenderData_repr,	/* tp_repr */
	0,			/* tp_as_number */
	0,			/* tp_as_sequence */
	0,			/* tp_as_mapping */
	0,			/* tp_as_hash */
	0, 0, 0, 0, 0, 0,
	0,			/* tp_doc */
	0, 0, 0, 0, 0, 0,
	BPy_RenderData_methods,	/* tp_methods */
	0,			/* tp_members */
	0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
};
//---------------------------------------------------Render Module Init--
PyObject *Render_Init( void )
{
	PyObject *submodule;

	RenderData_Type.ob_type = &PyType_Type;

	submodule = Py_InitModule3( "Blender.Scene.Render",
				    M_Render_methods, M_Render_doc );

	PyModule_AddIntConstant( submodule, "INTERNAL", R_INTERN );
	PyModule_AddIntConstant( submodule, "YAFRAY", R_YAFRAY );
	PyModule_AddIntConstant( submodule, "AVIRAW", R_AVIRAW );
	PyModule_AddIntConstant( submodule, "AVIJPEG", R_AVIJPEG );
	PyModule_AddIntConstant( submodule, "AVICODEC", R_AVICODEC );
	PyModule_AddIntConstant( submodule, "QUICKTIME", R_QUICKTIME );
	PyModule_AddIntConstant( submodule, "TARGA", R_TARGA );
	PyModule_AddIntConstant( submodule, "RAWTGA", R_RAWTGA );
	PyModule_AddIntConstant( submodule, "PNG", R_PNG );
	PyModule_AddIntConstant( submodule, "BMP", R_BMP );
	PyModule_AddIntConstant( submodule, "JPEG", R_JPEG90 );
	PyModule_AddIntConstant( submodule, "HAMX", R_HAMX );
	PyModule_AddIntConstant( submodule, "IRIS", R_IRIS );
	PyModule_AddIntConstant( submodule, "IRISZ", R_IRIZ );
	PyModule_AddIntConstant( submodule, "FTYPE", R_FTYPE );
	PyModule_AddIntConstant( submodule, "PAL", B_PR_PAL );
	PyModule_AddIntConstant( submodule, "NTSC", B_PR_NTSC );
	PyModule_AddIntConstant( submodule, "DEFAULT", B_PR_PRESET );
	PyModule_AddIntConstant( submodule, "PREVIEW", B_PR_PRV );
	PyModule_AddIntConstant( submodule, "PC", B_PR_PC );
	PyModule_AddIntConstant( submodule, "PAL169", B_PR_PAL169 );
	PyModule_AddIntConstant( submodule, "PANO", B_PR_PANO );
	PyModule_AddIntConstant( submodule, "FULL", B_PR_FULL );
	PyModule_AddIntConstant( submodule, "NONE", PY_NONE );
	PyModule_AddIntConstant( submodule, "LOW", PY_LOW );
	PyModule_AddIntConstant( submodule, "MEDIUM", PY_MEDIUM );
	PyModule_AddIntConstant( submodule, "HIGH", PY_HIGH );
	PyModule_AddIntConstant( submodule, "HIGHER", PY_HIGHER );
	PyModule_AddIntConstant( submodule, "BEST", PY_BEST );
	PyModule_AddIntConstant( submodule, "SKYDOME", PY_SKYDOME );
	PyModule_AddIntConstant( submodule, "GIFULL", PY_FULL );

	return ( submodule );
}

//-----------------------------------BPy_RenderData Internal Protocols---
//-------------------------------------------------dealloc---------------
static void RenderData_dealloc( BPy_RenderData * self )
{
	PyObject_DEL( self );
}

//-------------------------------------------------getAttr---------------
static PyObject *RenderData_getAttr( BPy_RenderData * self, char *name )
{
	return Py_FindMethod( BPy_RenderData_methods, ( PyObject * ) self,
			      name );
}

//-------------------------------------------------repr------------------
static PyObject *RenderData_repr( BPy_RenderData * self )
{
	if( self->renderContext )
		return PyString_FromFormat( "[RenderData \"%s\"]",
					    self->scene->id.name + 2 );
	else
		return PyString_FromString( "NULL" );
}

//------------------------------BPy_RenderData Callbacks-----------------
//--------------------------------------CreatePyObject-------------------
PyObject *RenderData_CreatePyObject( struct Scene * scene )
{
	BPy_RenderData *py_renderdata;

	py_renderdata =
		( BPy_RenderData * ) PyObject_NEW( BPy_RenderData,
						   &RenderData_Type );

	if( py_renderdata == NULL ) {
		return ( NULL );
	}
	py_renderdata->renderContext = &scene->r;
	py_renderdata->scene = scene;

	return ( ( PyObject * ) py_renderdata );
}

//------------------------------CheckPyObject----------------------------
int RenderData_CheckPyObject( PyObject * py_obj )
{
	return ( py_obj->ob_type == &RenderData_Type );
}

//------------------------------------BitToggleInt-----------------------
static PyObject *M_Render_BitToggleInt( PyObject * args, int setting,
					int *structure )
{
	int flag;

	if( !PyArg_ParseTuple( args, "i", &flag ) )
		return ( EXPP_ReturnPyObjError
			 ( PyExc_AttributeError,
			   "expected TRUE or FALSE (1 or 0)" ) );

	if( flag < 0 || flag > 1 )
		return ( EXPP_ReturnPyObjError
			 ( PyExc_AttributeError,
			   "expected TRUE or FALSE (1 or 0)" ) );

	if( flag )
		*structure |= setting;
	else
		*structure &= ~setting;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );

}

//------------------------------------BitToggleShort---------------------
static PyObject *M_Render_BitToggleShort( PyObject * args, short setting,
					  short *structure )
{
	int flag;

	if( !PyArg_ParseTuple( args, "i", &flag ) )
		return ( EXPP_ReturnPyObjError
			 ( PyExc_AttributeError,
			   "expected TRUE or FALSE (1 or 0)" ) );

	if( flag < 0 || flag > 1 )
		return ( EXPP_ReturnPyObjError
			 ( PyExc_AttributeError,
			   "expected TRUE or FALSE (1 or 0)" ) );

	if( flag )
		*structure |= setting;
	else
		*structure &= ~setting;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );

}

//------------------------------------GetSetAttributeFloat---------------
static PyObject *M_Render_GetSetAttributeFloat( PyObject * args,
						float *structure, float min,
						float max )
{
	float property = -10.0f;
	char error[48];

	if( !PyArg_ParseTuple( args, "|f", &property ) )
		return ( EXPP_ReturnPyObjError
			 ( PyExc_AttributeError, "expected float" ) );

	if( property != -10.0f ) {
		if( property < min || property > max ) {
			sprintf( error, "out of range - expected %f to %f",
				 min, max );
			return ( EXPP_ReturnPyObjError
				 ( PyExc_AttributeError, error ) );
		}

		*structure = property;
		EXPP_allqueue( REDRAWBUTSSCENE, 0 );
		return EXPP_incr_ret( Py_None );
	} else
		return Py_BuildValue( "f", *structure );
}

//------------------------------------GetSetAttributeShort---------------
static PyObject *M_Render_GetSetAttributeShort( PyObject * args,
						short *structure, int min,
						int max )
{
	short property = -10;
	char error[48];

	if( !PyArg_ParseTuple( args, "|h", &property ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected int" ) );

	if( property != -10 ) {
		if( property < min || property > max ) {
			sprintf( error, "out of range - expected %d to %d",
				 min, max );
			return ( EXPP_ReturnPyObjError
				 ( PyExc_AttributeError, error ) );
		}

		*structure = property;
		EXPP_allqueue( REDRAWBUTSSCENE, 0 );
		return EXPP_incr_ret( Py_None );
	} else
		return Py_BuildValue( "h", *structure );
}

//------------------------------------GetSetAttributeInt-----------------
static PyObject *M_Render_GetSetAttributeInt( PyObject * args, int *structure,
					      int min, int max )
{
	int property = -10;
	char error[48];

	if( !PyArg_ParseTuple( args, "|i", &property ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected int" ) );

	if( property != -10 ) {
		if( property < min || property > max ) {
			sprintf( error, "out of range - expected %d to %d",
				 min, max );
			return ( EXPP_ReturnPyObjError
				 ( PyExc_AttributeError, error ) );
		}

		*structure = property;
		EXPP_allqueue( REDRAWBUTSSCENE, 0 );
		return EXPP_incr_ret( Py_None );
	} else
		return Py_BuildValue( "i", *structure );
}

//------------------------------------DoSizePrese -----------------------
static void M_Render_DoSizePreset( BPy_RenderData * self, short xsch,
				   short ysch, short xasp, short yasp,
				   short size, short xparts, short yparts,
				   short frames, float a, float b, float c,
				   float d )
{
	self->renderContext->xsch = xsch;
	self->renderContext->ysch = ysch;
	self->renderContext->xasp = xasp;
	self->renderContext->yasp = yasp;
	self->renderContext->size = size;
	self->renderContext->frs_sec = frames;
	self->renderContext->xparts = xparts;
	self->renderContext->yparts = yparts;

	BLI_init_rctf( &self->renderContext->safety, a, b, c, d );
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );
	EXPP_allqueue( REDRAWVIEWCAM, 0 );
}

//------------------------------------Render Module Function Definitions-
//------------------------------------Render.CloseRenderWindow() --------
PyObject *M_Render_CloseRenderWindow( PyObject * self )
{
	BIF_close_render_display(  );
	return EXPP_incr_ret( Py_None );
}

//------------------------------------Render.SetRenderWinPos() ----------
PyObject *M_Render_SetRenderWinPos( PyObject * self, PyObject * args )
{
	PyObject *list = NULL;
	char *loc = NULL;
	int x;

	if( !PyArg_ParseTuple( args, "O!", &PyList_Type, &list ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected a list" ) );

	G.winpos = 0;
	for( x = 0; x < PyList_Size( list ); x++ ) {
		if( !PyArg_Parse( PyList_GetItem( list, x ), "s", &loc ) ) {
			return EXPP_ReturnPyObjError( PyExc_TypeError,
						      "python list not parseable\n" );
		}
		if( strcmp( loc, "SW" ) == 0 || strcmp( loc, "sw" ) == 0 )
			G.winpos |= 1;
		else if( strcmp( loc, "S" ) == 0 || strcmp( loc, "s" ) == 0 )
			G.winpos |= 2;
		else if( strcmp( loc, "SE" ) == 0 || strcmp( loc, "se" ) == 0 )
			G.winpos |= 4;
		else if( strcmp( loc, "W" ) == 0 || strcmp( loc, "w" ) == 0 )
			G.winpos |= 8;
		else if( strcmp( loc, "C" ) == 0 || strcmp( loc, "c" ) == 0 )
			G.winpos |= 16;
		else if( strcmp( loc, "E" ) == 0 || strcmp( loc, "e" ) == 0 )
			G.winpos |= 32;
		else if( strcmp( loc, "NW" ) == 0 || strcmp( loc, "nw" ) == 0 )
			G.winpos |= 64;
		else if( strcmp( loc, "N" ) == 0 || strcmp( loc, "n" ) == 0 )
			G.winpos |= 128;
		else if( strcmp( loc, "NE" ) == 0 || strcmp( loc, "ne" ) == 0 )
			G.winpos |= 256;
		else
			return EXPP_ReturnPyObjError( PyExc_AttributeError,
						      "list contains unknown string\n" );
	}
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------Render.EnableDispView() -----------
PyObject *M_Render_EnableDispView( PyObject * self )
{
	G.displaymode = R_DISPLAYVIEW;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------Render.EnableDispWin() ------------
PyObject *M_Render_EnableDispWin( PyObject * self )
{
	G.displaymode = R_DISPLAYWIN;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------Render.EnableEdgeShift() ----------
PyObject *M_Render_EnableEdgeShift( PyObject * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, 1, &G.compat );
}

//------------------------------------Render.EnableEdgeAll() ------------
PyObject *M_Render_EnableEdgeAll( PyObject * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, 1, &G.notonlysolid );
}

//----------------------------BPy_RenderData Function Definitions--------

//------------------------------------RenderData.Render() ---------------
PyObject *RenderData_Render( BPy_RenderData * self )
{
	Scene *oldsce;

	if (!G.background) {
		oldsce = G.scene;
		set_scene( self->scene );
		BIF_do_render( 0 );
		set_scene( oldsce );
	}

	else { /* background mode (blender -b file.blend -P script) */

		int end_frame = G.scene->r.efra; /* is of type short currently */

		if (G.scene != self->scene)
			return EXPP_ReturnPyObjError (PyExc_RuntimeError,
				"scene to render in bg mode must be the active scene");

		G.scene->r.efra = G.scene->r.sfra;

		RE_animrender(NULL);

		G.scene->r.efra = end_frame;
	}

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.RenderAnim() -----------
PyObject *RenderData_RenderAnim( BPy_RenderData * self )
{
	Scene *oldsce;

	if (!G.background) {
		oldsce = G.scene;
		set_scene( self->scene );
		BIF_do_render( 1 );
		set_scene( oldsce );
	}
	else { /* background mode (blender -b file.blend -P script) */
		if (G.scene != self->scene)
			return EXPP_ReturnPyObjError (PyExc_RuntimeError,
				"scene to render in bg mode must be the active scene");

		if (G.scene->r.sfra > G.scene->r.efra)
			return EXPP_ReturnPyObjError (PyExc_RuntimeError,
				"start frame must be less or equal to end frame");
		RE_animrender(NULL);
	}
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.Play() -----------------
PyObject *RenderData_Play( BPy_RenderData * self )
{
	char file[FILE_MAXDIR + FILE_MAXFILE];
	extern char bprogname[];
	char str[FILE_MAXDIR + FILE_MAXFILE];
	int pos[2], size[2];
	char txt[64];

#ifdef WITH_QUICKTIME
	if( self->renderContext->imtype == R_QUICKTIME ) {

		strcpy( file, self->renderContext->pic );
		BLI_convertstringcode( file, (char *) self->scene,
				       self->renderContext->cfra );
		RE_make_existing_file( file );
		if( BLI_strcasecmp( file + strlen( file ) - 4, ".mov" ) ) {
			sprintf( txt, "%04d_%04d.mov",
				 ( self->renderContext->sfra ),
				 ( self->renderContext->efra ) );
			strcat( file, txt );
		}
	} else
#endif
	{

		strcpy( file, self->renderContext->pic );
		BLI_convertstringcode( file, G.sce,
				       self->renderContext->cfra );
		RE_make_existing_file( file );
		if( BLI_strcasecmp( file + strlen( file ) - 4, ".avi" ) ) {
			sprintf( txt, "%04d_%04d.avi",
				 ( self->renderContext->sfra ),
				 ( self->renderContext->efra ) );
			strcat( file, txt );
		}
	}
	if( BLI_exist( file ) ) {
		calc_renderwin_rectangle( G.winpos, pos, size );
		sprintf( str, "%s -a -p %d %d \"%s\"", bprogname, pos[0],
			 pos[1], file );
		system( str );
	} else {
		makepicstring( file, self->renderContext->sfra );
		if( BLI_exist( file ) ) {
			calc_renderwin_rectangle( G.winpos, pos, size );
			sprintf( str, "%s -a -p %d %d \"%s\"", bprogname,
				 pos[0], pos[1], file );
			system( str );
		} else
			sprintf( "Can't find image: %s", file );
	}

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.StRenderPath() ---------
PyObject *RenderData_SetRenderPath( BPy_RenderData * self, PyObject * args )
{
	char *name;

	if( !PyArg_ParseTuple( args, "s", &name ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected a string" ) );

	if( strlen( name ) > 160 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"path is too long (SetRenderPath)" ) );

	strcpy( self->renderContext->pic, name );
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.GetRenderPath() --------
PyObject *RenderData_GetRenderPath( BPy_RenderData * self )
{
	return Py_BuildValue( "s", self->renderContext->pic );
}

//------------------------------------RenderData.SetBackbufPath() -------
PyObject *RenderData_SetBackbufPath( BPy_RenderData * self, PyObject * args )
{
	char *name;
	Image *ima;

	if( !PyArg_ParseTuple( args, "s", &name ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected a string" ) );

	if( strlen( name ) > 160 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"path is too long (SetBackbufPath)" ) );

	strcpy( self->renderContext->backbuf, name );
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	ima = add_image( name );
	if( ima ) {
		free_image_buffers( ima );
		ima->ok = 1;
	}

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.GetBackbufPath() -------
PyObject *RenderData_GetBackbufPath( BPy_RenderData * self )
{
	return Py_BuildValue( "s", self->renderContext->backbuf );
}

//------------------------------------RenderData.EnableBackbuf() --------
PyObject *RenderData_EnableBackbuf( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleShort( args, 1,
					&self->renderContext->bufflag );
}

//------------------------------------RenderData.SetFtypePath() ---------
PyObject *RenderData_SetFtypePath( BPy_RenderData * self, PyObject * args )
{
	char *name;

	if( !PyArg_ParseTuple( args, "s", &name ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected a string" ) );

	if( strlen( name ) > 160 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"path is too long (SetFtypePath)" ) );

	strcpy( self->renderContext->ftype, name );
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.GetFtypePath() ---------
PyObject *RenderData_GetFtypePath( BPy_RenderData * self )
{
	return Py_BuildValue( "s", self->renderContext->ftype );
}

//------------------------------------RenderData.EnableExtensions() -----
PyObject *RenderData_EnableExtensions( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleShort( args, R_EXTENSION,
					&self->renderContext->scemode );
}

//------------------------------------RenderData.EnableSequencer() ------
PyObject *RenderData_EnableSequencer( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleShort( args, R_DOSEQ,
					&self->renderContext->scemode );
}

//------------------------------------RenderData.EnableRenderDaemon() ---
PyObject *RenderData_EnableRenderDaemon( BPy_RenderData * self,
					 PyObject * args )
{
	return M_Render_BitToggleShort( args, R_BG_RENDER,
					&self->renderContext->scemode );
}

//------------------------------------RenderData.EnableToonShading() ----
PyObject *RenderData_EnableToonShading( BPy_RenderData * self,
					PyObject * args )
{
	return M_Render_BitToggleInt( args, R_EDGE,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EdgeIntensity() --------
PyObject *RenderData_EdgeIntensity( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->edgeint, 0,
					      255 );
}

//------------------------------------RenderData.SetEdgeColor() ---------
PyObject *RenderData_SetEdgeColor( BPy_RenderData * self, PyObject * args )
{
	float red = 0.0f;
	float green = 0.0f;
	float blue = 0.0f;

	if( !PyArg_ParseTuple( args, "fff", &red, &green, &blue ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected three floats" ) );

	if( red < 0 || red > 1 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"value out of range 0.000 - 1.000 (red)" ) );
	if( green < 0 || green > 1 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"value out of range 0.000 - 1.000 (green)" ) );
	if( blue < 0 || blue > 1 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"value out of range 0.000 - 1.000 (blue)" ) );

	self->renderContext->edgeR = red;
	self->renderContext->edgeG = green;
	self->renderContext->edgeB = blue;

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.GetEdgeColor() ---------
PyObject *RenderData_GetEdgeColor( BPy_RenderData * self )
{
	char rgb[24];

	sprintf( rgb, "[%.3f,%.3f,%.3f]\n", self->renderContext->edgeR,
		 self->renderContext->edgeG, self->renderContext->edgeB );
	return PyString_FromString( rgb );
}

//------------------------------------RenderData.EdgeAntiShift() --------
PyObject *RenderData_EdgeAntiShift( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->
					      same_mat_redux, 0, 255 );
}

//------------------------------------RenderData.EnableOversampling() ---
PyObject *RenderData_EnableOversampling( BPy_RenderData * self,
					 PyObject * args )
{
	return M_Render_BitToggleInt( args, R_OSA,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.SetOversamplingLevel() -
PyObject *RenderData_SetOversamplingLevel( BPy_RenderData * self,
					   PyObject * args )
{
	int level;

	if( !PyArg_ParseTuple( args, "i", &level ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected int" ) );

	if( level != 5 && level != 8 && level != 11 && level != 16 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected 5,8,11, or 16" ) );

	self->renderContext->osa = level;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableMotionBlur() -----
PyObject *RenderData_EnableMotionBlur( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, R_MBLUR,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.MotionBlurLevel() ------
PyObject *RenderData_MotionBlurLevel( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeFloat( args,
					      &self->renderContext->blurfac,
					      0.01f, 5.0f );
}

//------------------------------------RenderData.PartsX() ---------------
PyObject *RenderData_PartsX( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->xparts, 1,
					      64 );
}

//------------------------------------RenderData.PartsY() ---------------
PyObject *RenderData_PartsY( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->yparts, 1,
					      64 );
}

//------------------------------------RenderData.EnableSky() ------------
PyObject *RenderData_EnableSky( BPy_RenderData * self )
{
	self->renderContext->alphamode = R_ADDSKY;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnablePremultiply() ----
PyObject *RenderData_EnablePremultiply( BPy_RenderData * self )
{
	self->renderContext->alphamode = R_ALPHAPREMUL;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableKey() ------------
PyObject *RenderData_EnableKey( BPy_RenderData * self )
{
	self->renderContext->alphamode = R_ALPHAKEY;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableShadow() ---------
PyObject *RenderData_EnableShadow( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, R_SHADOW,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnvironmentMap() -------
PyObject *RenderData_EnableEnvironmentMap( BPy_RenderData * self,
					   PyObject * args )
{
	return M_Render_BitToggleInt( args, R_ENVMAP,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnablePanorama() -------
PyObject *RenderData_EnablePanorama( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, R_PANORAMA,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnableRayTracing() -----
PyObject *RenderData_EnableRayTracing( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, R_RAYTRACE,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnableRadiosityRender() 
PyObject *RenderData_EnableRadiosityRender( BPy_RenderData * self,
					    PyObject * args )
{
	return M_Render_BitToggleInt( args, R_RADIO,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.SetRenderWinSize() -----
PyObject *RenderData_SetRenderWinSize( BPy_RenderData * self, PyObject * args )
{
	int size;

	if( !PyArg_ParseTuple( args, "i", &size ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected int" ) );

	if( size != 25 && size != 50 && size != 75 && size != 100 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected 25, 50, 75, or 100" ) );

	self->renderContext->size = size;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableFieldRendering() -
PyObject *RenderData_EnableFieldRendering( BPy_RenderData * self,
					   PyObject * args )
{
	return M_Render_BitToggleInt( args, R_FIELDS,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnableOddFieldFirst() --
PyObject *RenderData_EnableOddFieldFirst( BPy_RenderData * self,
					  PyObject * args )
{
	return M_Render_BitToggleInt( args, R_ODDFIELD,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnableFieldTimeDisable()
PyObject *RenderData_EnableFieldTimeDisable( BPy_RenderData * self,
					     PyObject * args )
{
	return M_Render_BitToggleInt( args, R_FIELDSTILL,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnableGaussFilter() ----
PyObject *RenderData_EnableGaussFilter( BPy_RenderData * self,
					PyObject * args )
{
	return M_Render_BitToggleInt( args, R_GAUSS,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.EnableBorderRender() ---
PyObject *RenderData_EnableBorderRender( BPy_RenderData * self,
					 PyObject * args )
{
	return M_Render_BitToggleInt( args, R_BORDER,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.SetBorder() ------------
PyObject *RenderData_SetBorder( BPy_RenderData * self, PyObject * args )
{
	float xmin, ymin, xmax, ymax;
	int status = 0;
	PyObject *ob_args;

	//left,botton | right,top coords - in that order
	if( PyObject_Length( args ) == 4 ) {
		status = PyArg_ParseTuple( args, "ffff", &xmin, &ymin, &xmax,
					   &ymax );
	} else {
		if( PyArg_ParseTuple( args, "O", &ob_args ) ) {
			if( PyList_Check( ob_args ) )
				status = PyArg_ParseTuple( args, "(ffff)",
							   &xmin, &ymin, &xmax,
							   &ymax );
			else {
				status = 0;
			}
		} else {
			status = 0;
		}
	}
	if( !status )		/* parsing args failed */
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected four floats" ) );
	if( xmin > 1.0 || xmin < 0.0 || ymin > 1.0 || ymin < 0.0 ||
	    xmax > 1.0 || xmax < 0.0 || ymax > 1.0 || ymax < 0.0 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"all values must be between 0.0 and 1.0" ) );

	self->renderContext->border.xmin = xmin;
	self->renderContext->border.ymin = ymin;
	self->renderContext->border.xmax = xmax;
	self->renderContext->border.ymax = ymax;

	EXPP_allqueue( REDRAWVIEWCAM, 1 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableGammaCorrection() 
PyObject *RenderData_EnableGammaCorrection( BPy_RenderData * self,
					    PyObject * args )
{
	return M_Render_BitToggleInt( args, R_GAMMA,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.GaussFilterSize() ------
PyObject *RenderData_GaussFilterSize( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeFloat( args,
					      &self->renderContext->gauss,
					      0.5f, 1.5f );
}

//------------------------------------RenderData.StartFrame() -----------
PyObject *RenderData_StartFrame( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->sfra,
					      1, MAXFRAME );
}

//------------------------------------RenderData.CurrentFrame() ---------
PyObject *RenderData_CurrentFrame( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->cfra,
					      1, MAXFRAME );
}

//------------------------------------RenderData.EndFrame() -------------
PyObject *RenderData_EndFrame( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->efra,
					      1, MAXFRAME );
}

 //------------------------------------RenderData.ImageSizeX() ----------
PyObject *RenderData_ImageSizeX( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->xsch,
					      4, 10000 );
}

//------------------------------------RenderData.ImageSizeY() -----------
PyObject *RenderData_ImageSizeY( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->ysch,
					      4, 10000 );
}

//------------------------------------RenderData.AspectRatioX() ---------
PyObject *RenderData_AspectRatioX( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->xasp,
					      1, 200 );
}

//------------------------------------RenderData.AspectRatioY() ---------
PyObject *RenderData_AspectRatioY( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args, &self->renderContext->yasp,
					      1, 200 );
}

//------------------------------------RenderData.SetRenderer() ----------
PyObject *RenderData_SetRenderer( BPy_RenderData * self, PyObject * args )
{
	int type;

	if( !PyArg_ParseTuple( args, "i", &type ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected constant INTERN or YAFRAY" ) );

	if( type == R_INTERN )
		self->renderContext->renderer = R_INTERN;
	else if( type == R_YAFRAY )
		self->renderContext->renderer = R_YAFRAY;
	else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected INTERN or YAFRAY" ) );

	EXPP_allqueue( REDRAWBUTSSCENE, 0 );
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableCropping() -------
PyObject *RenderData_EnableCropping( BPy_RenderData * self, PyObject * args )
{
	return M_Render_BitToggleInt( args, R_MOVIECROP,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.SetImageType() ---------
PyObject *RenderData_SetImageType( BPy_RenderData * self, PyObject * args )
{
	int type;

	if( !PyArg_ParseTuple( args, "i", &type ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected constant" ) );

	if( type == R_AVIRAW )
		self->renderContext->imtype = R_AVIRAW;
	else if( type == R_AVIJPEG )
		self->renderContext->imtype = R_AVIJPEG;
#ifdef _WIN32
	else if( type == R_AVICODEC )
		self->renderContext->imtype = R_AVICODEC;
#endif
	else if( type == R_QUICKTIME && G.have_quicktime )
		self->renderContext->imtype = R_QUICKTIME;
	else if( type == R_TARGA )
		self->renderContext->imtype = R_TARGA;
	else if( type == R_RAWTGA )
		self->renderContext->imtype = R_RAWTGA;
	else if( type == R_PNG )
		self->renderContext->imtype = R_PNG;
	else if( type == R_BMP )
		self->renderContext->imtype = R_BMP;
	else if( type == R_JPEG90 )
		self->renderContext->imtype = R_JPEG90;
	else if( type == R_HAMX )
		self->renderContext->imtype = R_HAMX;
	else if( type == R_IRIS )
		self->renderContext->imtype = R_IRIS;
	else if( type == R_IRIZ )
		self->renderContext->imtype = R_IRIZ;
	else if( type == R_FTYPE )
		self->renderContext->imtype = R_FTYPE;
	else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"unknown constant - see modules dict for help" ) );

	EXPP_allqueue( REDRAWBUTSSCENE, 0 );
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.Quality() --------------
PyObject *RenderData_Quality( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->quality,
					      10, 100 );
}

//------------------------------------RenderData.FramesPerSec() ---------
PyObject *RenderData_FramesPerSec( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->frs_sec, 1,
					      120 );
}

//------------------------------------RenderData.EnableGrayscale() ------
PyObject *RenderData_EnableGrayscale( BPy_RenderData * self )
{
	self->renderContext->planes = R_PLANESBW;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableRGBColor() -------
PyObject *RenderData_EnableRGBColor( BPy_RenderData * self )
{
	self->renderContext->planes = R_PLANES24;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableRGBAColor() ------
PyObject *RenderData_EnableRGBAColor( BPy_RenderData * self )
{
	self->renderContext->planes = R_PLANES32;
	EXPP_allqueue( REDRAWBUTSSCENE, 0 );

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.SizePreset() -----------
PyObject *RenderData_SizePreset( BPy_RenderData * self, PyObject * args )
{
	int type;

	if( !PyArg_ParseTuple( args, "i", &type ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected constant" ) );

	if( type == B_PR_PAL ) {
		M_Render_DoSizePreset( self, 720, 576, 54, 51, 100,
				       self->renderContext->xparts,
				       self->renderContext->yparts, 25, 0.1,
				       0.9, 0.1, 0.9 );
		self->renderContext->mode &= ~R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else if( type == B_PR_NTSC ) {
		M_Render_DoSizePreset( self, 720, 480, 10, 11, 100, 1, 1,
				       30, 0.1, 0.9, 0.1, 0.9 );
		self->renderContext->mode &= ~R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else if( type == B_PR_PRESET ) {
		M_Render_DoSizePreset( self, 720, 576, 54, 51, 100, 1, 1,
				       self->renderContext->frs_sec, 0.1, 0.9,
				       0.1, 0.9 );
		self->renderContext->mode = R_OSA + R_SHADOW + R_FIELDS;
		self->renderContext->imtype = R_TARGA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else if( type == B_PR_PRV ) {
		M_Render_DoSizePreset( self, 640, 512, 1, 1, 50, 1, 1,
				       self->renderContext->frs_sec, 0.1, 0.9,
				       0.1, 0.9 );
		self->renderContext->mode &= ~R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else if( type == B_PR_PC ) {
		M_Render_DoSizePreset( self, 640, 480, 100, 100, 100, 1, 1,
				       self->renderContext->frs_sec, 0.0, 1.0,
				       0.0, 1.0 );
		self->renderContext->mode &= ~R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.0, 1.0, 0.0,
			       1.0 );
	} else if( type == B_PR_PAL169 ) {
		M_Render_DoSizePreset( self, 720, 576, 64, 45, 100, 1, 1,
				       25, 0.1, 0.9, 0.1, 0.9 );
		self->renderContext->mode &= ~R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else if( type == B_PR_PANO ) {
		M_Render_DoSizePreset( self, 36, 176, 115, 100, 100, 16, 1,
				       self->renderContext->frs_sec, 0.1, 0.9,
				       0.1, 0.9 );
		self->renderContext->mode |= R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else if( type == B_PR_FULL ) {
		M_Render_DoSizePreset( self, 1280, 1024, 1, 1, 100, 1, 1,
				       self->renderContext->frs_sec, 0.1, 0.9,
				       0.1, 0.9 );
		self->renderContext->mode &= ~R_PANORAMA;
		BLI_init_rctf( &self->renderContext->safety, 0.1, 0.9, 0.1,
			       0.9 );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"unknown constant - see modules dict for help" ) );

	EXPP_allqueue( REDRAWBUTSSCENE, 0 );
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableUnifiedRenderer() 
PyObject *RenderData_EnableUnifiedRenderer( BPy_RenderData * self,
					    PyObject * args )
{
	return M_Render_BitToggleInt( args, R_UNIFIED,
				      &self->renderContext->mode );
}

//------------------------------------RenderData.SetYafrayGIQuality() ---
PyObject *RenderData_SetYafrayGIQuality( BPy_RenderData * self,
					 PyObject * args )
{
	int type;

	if( !PyArg_ParseTuple( args, "i", &type ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected constant" ) );

	if( type == PY_NONE || type == PY_LOW ||
	    type == PY_MEDIUM || type == PY_HIGH ||
	    type == PY_HIGHER || type == PY_BEST ) {
		self->renderContext->GIquality = type;
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"unknown constant - see modules dict for help" ) );

	EXPP_allqueue( REDRAWBUTSSCENE, 0 );
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.SetYafrayGIMethod() ----
PyObject *RenderData_SetYafrayGIMethod( BPy_RenderData * self,
					PyObject * args )
{
	int type;

	if( !PyArg_ParseTuple( args, "i", &type ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected constant" ) );

	if( type == PY_NONE || type == PY_SKYDOME || type == PY_FULL ) {
		self->renderContext->GImethod = type;
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"unknown constant - see modules dict for help" ) );

	EXPP_allqueue( REDRAWBUTSSCENE, 0 );
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.YafrayGIPower() --------
PyObject *RenderData_YafrayGIPower( BPy_RenderData * self, PyObject * args )
{
	if( self->renderContext->GImethod > 0 ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      GIpower, 0.01f,
						      100.00f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'SKYDOME' or 'FULL'" ) );
}

//------------------------------------RenderData.YafrayGIDepth() --------
PyObject *RenderData_YafrayGIDepth( BPy_RenderData * self, PyObject * args )
{
	if( self->renderContext->GImethod == 2 ) {
		return M_Render_GetSetAttributeInt( args,
						    &self->renderContext->
						    GIdepth, 1, 8 );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL'" ) );
}

//------------------------------------RenderData.afrayGICDepth() --------
PyObject *RenderData_YafrayGICDepth( BPy_RenderData * self, PyObject * args )
{
	if( self->renderContext->GImethod == 2 ) {
		return M_Render_GetSetAttributeInt( args,
						    &self->renderContext->
						    GIcausdepth, 1, 8 );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL'" ) );
}

//------------------------------------RenderData.EnableYafrayGICache() --
PyObject *RenderData_EnableYafrayGICache( BPy_RenderData * self,
					  PyObject * args )
{
	if( self->renderContext->GImethod == 2 ) {
		return M_Render_BitToggleShort( args, 1,
						&self->renderContext->
						GIcache );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL'" ) );
}

//------------------------------------RenderData.EnableYafrayGIPhotons() 
PyObject *RenderData_EnableYafrayGIPhotons( BPy_RenderData * self,
					    PyObject * args )
{
	if( self->renderContext->GImethod == 2 ) {
		return M_Render_BitToggleShort( args, 1,
						&self->renderContext->
						GIphotons );;
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL'" ) );
}

//------------------------------------RenderData.YafrayGIPhotonCount() --
PyObject *RenderData_YafrayGIPhotonCount( BPy_RenderData * self,
					  PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIphotons == 1 ) {
		return M_Render_GetSetAttributeInt( args,
						    &self->renderContext->
						    GIphotoncount, 0,
						    10000000 );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GIPhotons must be enabled\n" ) );
}

//------------------------------------RenderData.YafrayGIPhotonRadius() -
PyObject *RenderData_YafrayGIPhotonRadius( BPy_RenderData * self,
					   PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIphotons == 1 ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      GIphotonradius, 0.00001f,
						      100.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GIPhotons must be enabled\n" ) );
}

//------------------------------------RenderData.YafrayGIPhotonMixCount()
PyObject *RenderData_YafrayGIPhotonMixCount( BPy_RenderData * self,
					     PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIphotons == 1 ) {
		return M_Render_GetSetAttributeInt( args,
						    &self->renderContext->
						    GImixphotons, 0, 1000 );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GIPhotons must be enabled\n" ) );
}

//--------------------------RenderData.EnableYafrayGITunePhotons() ------
PyObject *RenderData_EnableYafrayGITunePhotons( BPy_RenderData * self,
						PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIphotons == 1 ) {
		return M_Render_BitToggleShort( args, 1,
						&self->renderContext->
						GIdirect );;
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GIPhotons must be enabled" ) );
}

//------------------------------------RenderData.YafrayGIShadowQuality() 
PyObject *RenderData_YafrayGIShadowQuality( BPy_RenderData * self,
					    PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIcache == 1 ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      GIshadowquality, 0.01f,
						      1.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GICache must be enabled\n" ) );
}

//------------------------------------RenderData.YafrayGIPixelsPerSample()
PyObject *RenderData_YafrayGIPixelsPerSample( BPy_RenderData * self,
					      PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIcache == 1 ) {
		return M_Render_GetSetAttributeInt( args,
						    &self->renderContext->
						    GIpixelspersample, 1, 50 );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GICache must be enabled\n" ) );
}

//------------------------------------RenderData.YafrayGIRefinement() ----
PyObject *RenderData_YafrayGIRefinement( BPy_RenderData * self,
					 PyObject * args )
{
	if( self->renderContext->GImethod == 2
	    && self->renderContext->GIcache == 1 ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      GIrefinement, 0.001f,
						      1.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_StandardError,
						"YafrayGIMethod must be set to 'FULL' and GICache must be enabled\n" ) );
}

//------------------------------------RenderData.YafrayRayBias() ---------
PyObject *RenderData_YafrayRayBias( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeFloat( args,
					      &self->renderContext->YF_raybias,
					      0.0f, 10.0f );
}

//------------------------------------RenderData.YafrayRayDepth() --------
PyObject *RenderData_YafrayRayDepth( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeInt( args,
					    &self->renderContext->YF_raydepth,
					    1, 80 );
}

//------------------------------------RenderData.YafrayGamma() -----------
PyObject *RenderData_YafrayGamma( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeFloat( args,
					      &self->renderContext->YF_gamma,
					      0.001f, 5.0f );
}

//------------------------------------RenderData.YafrayExposure() --------
PyObject *RenderData_YafrayExposure( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeFloat( args,
					      &self->renderContext->
					      YF_exposure, 0.0f, 10.0f );
}

//------------------------------------RenderData.YafrayProcessorCount() --
PyObject *RenderData_YafrayProcessorCount( BPy_RenderData * self,
					   PyObject * args )
{
	return M_Render_GetSetAttributeInt( args,
					    &self->renderContext->YF_numprocs,
					    1, 8 );
}

//------------------------------------RenderData.EnableGameFrameStretch() -----------------------------------------------------------
PyObject *RenderData_EnableGameFrameStretch( BPy_RenderData * self )
{
	self->scene->framing.type = SCE_GAMEFRAMING_SCALE;
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableGameFrameExpose() -
PyObject *RenderData_EnableGameFrameExpose( BPy_RenderData * self )
{
	self->scene->framing.type = SCE_GAMEFRAMING_EXTEND;
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.EnableGameFrameBars() ---
PyObject *RenderData_EnableGameFrameBars( BPy_RenderData * self )
{
	self->scene->framing.type = SCE_GAMEFRAMING_BARS;
	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.SetGameFrameColor() -----
PyObject *RenderData_SetGameFrameColor( BPy_RenderData * self,
					PyObject * args )
{
	float red = 0.0f;
	float green = 0.0f;
	float blue = 0.0f;

	if( !PyArg_ParseTuple( args, "fff", &red, &green, &blue ) )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"expected three floats" ) );

	if( red < 0 || red > 1 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"value out of range 0.000 - 1.000 (red)" ) );
	if( green < 0 || green > 1 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"value out of range 0.000 - 1.000 (green)" ) );
	if( blue < 0 || blue > 1 )
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"value out of range 0.000 - 1.000 (blue)" ) );

	self->scene->framing.col[0] = red;
	self->scene->framing.col[1] = green;
	self->scene->framing.col[2] = blue;

	return EXPP_incr_ret( Py_None );
}

//------------------------------------RenderData.GetGameFrameColor() -----
PyObject *RenderData_GetGameFrameColor( BPy_RenderData * self )
{
	char rgb[24];

	sprintf( rgb, "[%.3f,%.3f,%.3f]\n", self->scene->framing.col[0],
		 self->scene->framing.col[1], self->scene->framing.col[2] );
	return PyString_FromString( rgb );
}

//------------------------------------RenderData.GammaLevel() ------------
PyObject *RenderData_GammaLevel( BPy_RenderData * self, PyObject * args )
{
	if( self->renderContext->mode & R_UNIFIED ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      gamma, 0.2f, 5.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"Unified Render must be enabled" ) );
}

//------------------------------------RenderData.PostProcessAdd() --------
PyObject *RenderData_PostProcessAdd( BPy_RenderData * self, PyObject * args )
{
	if( self->renderContext->mode & R_UNIFIED ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      postadd, -1.0f, 1.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"Unified Render must be enabled" ) );
}

//------------------------------------RenderData.PostProcessMultiply() ---
PyObject *RenderData_PostProcessMultiply( BPy_RenderData * self,
					  PyObject * args )
{
	if( self->renderContext->mode & R_UNIFIED ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      postmul, 0.01f, 4.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"Unified Render must be enabled" ) );
}

//------------------------------------RenderData.PostProcessGamma() ------
PyObject *RenderData_PostProcessGamma( BPy_RenderData * self, PyObject * args )
{
	if( self->renderContext->mode & R_UNIFIED ) {
		return M_Render_GetSetAttributeFloat( args,
						      &self->renderContext->
						      postgamma, 0.2f, 2.0f );
	} else
		return ( EXPP_ReturnPyObjError( PyExc_AttributeError,
						"Unified Render must be enabled" ) );
}

//------------------------------------RenderData.SGIMaxsize() ------------
PyObject *RenderData_SGIMaxsize( BPy_RenderData * self, PyObject * args )
{
#ifdef __sgi
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->maximsize,
					      0, 500 );
#else
	return ( EXPP_ReturnPyObjError( PyExc_StandardError,
					"SGI is not defined on this machine" ) );
#endif
}

//------------------------------------RenderData.EnableSGICosmo() --------
PyObject *RenderData_EnableSGICosmo( BPy_RenderData * self, PyObject * args )
{
#ifdef __sgi
	return M_Render_BitToggleInt( args, R_COSMO,
				      &self->renderContext->mode );
#else
	return ( EXPP_ReturnPyObjError( PyExc_StandardError,
					"SGI is not defined on this machine" ) );
#endif
}

//------------------------------------RenderData.OldMapValue() -----------
PyObject *RenderData_OldMapValue( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->framapto,
					      1, 900 );
}

//------------------------------------RenderData.NewMapValue() -----------
PyObject *RenderData_NewMapValue( BPy_RenderData * self, PyObject * args )
{
	return M_Render_GetSetAttributeShort( args,
					      &self->renderContext->images, 1,
					      900 );
}