src/rt/pmapmat.h

/* RCSid $Id: pmapmat.h,v 2.8 2015/08/18 18:45:55 greg Exp $ */
/* 
   ==================================================================
   Photon map support routines for scattering by materials. 
   
   Roland Schregle (roland.schregle@{hslu.ch, gmail.com})
   (c) Fraunhofer Institute for Solar Energy Systems,
   (c) Lucerne University of Applied Sciences and Arts,
   supported by the Swiss National Science Foundation (SNSF, #147053)
   ==================================================================
   
*/


#ifndef PMAPMAT_H
   #define PMAPMAT_H

   #include "pmap.h"

   /* 
      Check for paths already accounted for in photon map to avoid
      double-counting during backward raytracing.
    
      shadowRayInPmap():   Check for DIFFUSE -> SPECULAR -> LIGHT
                           subpaths. These occur during the backward pass 
                           when a shadow ray is transferred through a
                           transparent material. These subpaths are already
                           accounted for by caustic photons in the global,
                           contrib, or dedicated caustic photon map.
   */
/*
   #define ambRayInPmap(r)    ((r) -> crtype & AMBIENT && \
                               ((photonMapping && \
                                 (ambounce < 0 || (r) -> rlvl > 1)) || \
                                 causticPhotonMapping || contribPhotonMapping))
*/
   #define ambRayInPmap(r)    0
   #define shadowRayInPmap(r) ((r) -> crtype & SHADOW && \
                                (ambounce < 0 || ((r) -> crtype & AMBIENT ? \
                                        photonMapping : causticPhotonMapping)))
   
   /* Check if scattered ray spawns a caustic photon */
   #define PMAP_CAUSTICRAY(r) ((r) -> rtype & SPECULAR)


   /* Scattered photon ray types for photonRay() */
   #define  PMAP_DIFFREFL        (REFLECTED | AMBIENT)
   #define  PMAP_DIFFTRANS       (REFLECTED | AMBIENT | TRANS)
   #define  PMAP_SPECREFL        (REFLECTED | SPECULAR)
   #define  PMAP_SPECTRANS       (REFLECTED | SPECULAR | TRANS)
   #define  PMAP_REFRACT         (REFRACTED | SPECULAR)
   #define  PMAP_XFER            (TRANS)


   /* Dispatch table for photon scattering functions */
   extern int (*photonScatter []) (OBJREC*, RAY*);
   
   /* List of antimatter sensor modifier names */
   extern char *photonSensorList [MAXSET + 1];


   /* Spawn a new photon ray from a previous one; this is effectively a
    * customised rayorigin(). */
   void photonRay (const RAY *rayIn, RAY *rayOut, int rayOutType, 
                   COLOR fluxAtten);

   /* Init photonScatter[] dispatch table with material specific scattering
      routines */
   void initPhotonScatterFuncs ();

   /* Find antimatter geometry declared as photon sensors */   
   void getPhotonSensors (char **sensorList);
   
#endif
Revision:	2.9
Committed:	Tue Sep 1 16:27:52 2015 UTC (10 years, 2 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.8:	+1 -2 lines
Log Message:	Removed redundant $Id: in file
#	User	Rev	Content
1	greg	2.9	/* RCSid $Id: pmapmat.h,v 2.8 2015/08/18 18:45:55 greg Exp $ */
2	greg	2.1	/*
3			==================================================================
4			Photon map support routines for scattering by materials.
5
6			Roland Schregle (roland.schregle@{hslu.ch, gmail.com})
7			(c) Fraunhofer Institute for Solar Energy Systems,
8	rschregle	2.2	(c) Lucerne University of Applied Sciences and Arts,
9			supported by the Swiss National Science Foundation (SNSF, #147053)
10	greg	2.1	==================================================================
11
12			*/
13
14
15			#ifndef PMAPMAT_H
16			#define PMAPMAT_H
17
18			#include "pmap.h"
19
20			/*
21	greg	2.5	Check for paths already accounted for in photon map to avoid
22	greg	2.1	double-counting during backward raytracing.
23
24			shadowRayInPmap(): Check for DIFFUSE -> SPECULAR -> LIGHT
25			subpaths. These occur during the backward pass
26			when a shadow ray is transferred through a
27			transparent material. These subpaths are already
28			accounted for by caustic photons in the global,
29			contrib, or dedicated caustic photon map.
30			*/
31	rschregle	2.7	/*
32			#define ambRayInPmap(r) ((r) -> crtype & AMBIENT && \
33			((photonMapping && \
34			(ambounce < 0 \|\| (r) -> rlvl > 1)) \|\| \
35			causticPhotonMapping \|\| contribPhotonMapping))
36			*/
37			#define ambRayInPmap(r) 0
38	greg	2.1	#define shadowRayInPmap(r) ((r) -> crtype & SHADOW && \
39	greg	2.6	(ambounce < 0 \|\| ((r) -> crtype & AMBIENT ? \
40			photonMapping : causticPhotonMapping)))
41	greg	2.1
42			/* Check if scattered ray spawns a caustic photon */
43			#define PMAP_CAUSTICRAY(r) ((r) -> rtype & SPECULAR)
44
45
46			/* Scattered photon ray types for photonRay() */
47			#define PMAP_DIFFREFL (REFLECTED \| AMBIENT)
48			#define PMAP_DIFFTRANS (REFLECTED \| AMBIENT \| TRANS)
49			#define PMAP_SPECREFL (REFLECTED \| SPECULAR)
50			#define PMAP_SPECTRANS (REFLECTED \| SPECULAR \| TRANS)
51			#define PMAP_REFRACT (REFRACTED \| SPECULAR)
52			#define PMAP_XFER (TRANS)
53
54
55
56			/* Dispatch table for photon scattering functions */
57			extern int (photonScatter []) (OBJREC, RAY*);
58
59			/* List of antimatter sensor modifier names */
60			extern char *photonSensorList [MAXSET + 1];
61
62
63
64			/* Spawn a new photon ray from a previous one; this is effectively a
65			* customised rayorigin(). */
66			void photonRay (const RAY rayIn, RAY rayOut, int rayOutType,
67			COLOR fluxAtten);
68
69			/* Init photonScatter[] dispatch table with material specific scattering
70			routines */
71			void initPhotonScatterFuncs ();
72
73			/* Find antimatter geometry declared as photon sensors */
74			void getPhotonSensors (char **sensorList);
75
76			#endif