ViewVC Help
View File | Revision Log | Show Annotations | Download File | Root Listing
root/radiance/ray/src/cv/bsdfrep.h
(Generate patch)

Comparing ray/src/cv/bsdfrep.h (file contents):
Revision 2.1 by greg, Fri Oct 19 04:14:29 2012 UTC vs.
Revision 2.22 by greg, Fri Aug 22 05:38:44 2014 UTC

# Line 5 | Line 5
5   *      G. Ward
6   */
7  
8 + #ifndef _BSDFREP_H_
9 + #define _BSDFREP_H_
10 +
11   #include "bsdf.h"
12  
13 < #define DEBUG           1
13 > #ifdef __cplusplus
14 > extern "C" {
15 > #endif
16  
17   #ifndef GRIDRES
18 < #define GRIDRES         200             /* grid resolution per side */
18 > #define GRIDRES         (1<<8)          /* grid resolution per side */
19   #endif
20                                          /* convert to/from coded radians */
21   #define ANG2R(r)        (int)((r)*((1<<16)/M_PI))
22   #define R2ANG(c)        (((c)+.5)*(M_PI/(1<<16)))
23  
24 < typedef struct {
25 <        float           vsum;           /* DSF sum */
26 <        unsigned short  nval;           /* number of values in sum */
27 <        unsigned short  crad;           /* radius (coded angle) */
24 >                                        /* moderated cosine factor */
25 > #define COSF(z)         (fabs(z)*0.98 + 0.02)
26 >
27 > typedef union {
28 >        struct {
29 >                float           v;              /* DSF sum */
30 >                unsigned int    n;              /* number of values in sum */
31 >        }       sum;                    /* sum for averaging */
32 >        float   val[2];                 /* comparison values */
33   } GRIDVAL;                      /* grid value */
34  
35   typedef struct {
# Line 57 | Line 67 | typedef struct s_rbfnode {
67   #define INP_QUAD3       4               /* 180-270 degree quadrant */
68   #define INP_QUAD4       8               /* 270-360 degree quadrant */
69  
70 +                                /* name and manufacturer if known */
71 + extern char             bsdf_name[];
72 + extern char             bsdf_manuf[];
73 +                                /* active grid resolution */
74 + extern int              grid_res;
75 +                                /* coverage/symmetry using INP_QUAD? flags */
76   extern int              inp_coverage;
77  
78                                  /* all incident angles in-plane so far? */
# Line 66 | Line 82 | extern int             single_plane_incident;
82   extern int              input_orient;
83   extern int              output_orient;
84  
85 +                                /* log BSDF histogram */
86 + #define HISTLEN         256
87 + #define BSDF2BIG        (1./M_PI)
88 + #define BSDF2SML        1e-8
89 + #define HISTLNR         17.2759509              /* log(BSDF2BIG/BSDF2SML) */
90 + extern unsigned long    bsdf_hist[HISTLEN];
91 + #define histndx(v)      (int)(log((v)*(1./BSDF2SML))*(HISTLEN/HISTLNR))
92 + #define histval(i)      (exp(((i)+.5)*(HISTLNR/HISTLEN))*BSDF2SML)
93 +
94 +                                /* BSDF value for boundary regions */
95 + extern double           bsdf_min;
96 + extern double           bsdf_spec_peak;
97 + extern double           bsdf_spec_rad;
98 +
99                                  /* processed incident DSF measurements */
100   extern RBFNODE          *dsf_list;
101  
102                                  /* RBF-linking matrices (edges) */
103   extern MIGRATION        *mig_list;
104  
105 <                                /* migration edges drawn in raster fashion */
106 < extern MIGRATION        *mig_grid[GRIDRES][GRIDRES];
107 <
78 < #define mtx_nrows(m)    ((m)->rbfv[0]->nrbf)
79 < #define mtx_ncols(m)    ((m)->rbfv[1]->nrbf)
80 < #define mtx_ndx(m,i,j)  ((i)*mtx_ncols(m) + (j))
105 > #define mtx_nrows(m)    (m)->rbfv[0]->nrbf
106 > #define mtx_ncols(m)    (m)->rbfv[1]->nrbf
107 > #define mtx_coef(m,i,j) (m)->mtx[(i)*mtx_ncols(m) + (j)]
108   #define is_src(rbf,m)   ((rbf) == (m)->rbfv[0])
109   #define is_dest(rbf,m)  ((rbf) == (m)->rbfv[1])
110   #define nextedge(rbf,m) (m)->enxt[is_dest(rbf,m)]
# Line 85 | Line 112 | extern MIGRATION       *mig_grid[GRIDRES][GRIDRES];
112  
113   #define round(v)        (int)((v) + .5 - ((v) < -.5))
114  
115 < #define BSDFREP_FMT     "binary_RBF_BSDF_mesh"
115 > #define BSDFREP_FMT     "BSDF_RBFmesh"
116  
117                                  /* global argv[0] */
118   extern char             *progname;
119  
120                                  /* get theta value in degrees [0,180) range */
121 < #define get_theta180(v) (180./M_PI)*acos((v)[2])
121 > #define get_theta180(v) ((180./M_PI)*Acos((v)[2]))
122                                  /* get phi value in degrees, [0,360) range */
123 < #define get_phi360(v)   ((180./M_PI)*atan2((v)[1],(v)[0]) + 180.)
123 > #define get_phi360(v)   ((180./M_PI)*atan2((v)[1],(v)[0]) + 360.*((v)[1]<0))
124  
125                                  /* our loaded grid for this incident angle */
126   extern double           theta_in_deg, phi_in_deg;
# Line 114 | Line 141 | extern void            rev_symmetry(FVECT vec, int sym);
141   /* Reverse symmetry for an RBF distribution */
142   extern void             rev_rbf_symmetry(RBFNODE *rbf, int sym);
143  
144 + /* Rotate RBF to correspond to given incident vector */
145 + extern void             rotate_rbf(RBFNODE *rbf, const FVECT invec);
146 +
147   /* Compute volume associated with Gaussian lobe */
148   extern double           rbf_volume(const RBFVAL *rbfp);
149  
# Line 123 | Line 153 | extern void            ovec_from_pos(FVECT vec, int xpos, int yp
153   /* Compute grid position from normalized input/output vector */
154   extern void             pos_from_vec(int pos[2], const FVECT vec);
155  
156 < /* Evaluate RBF for DSF at the given normalized outgoing direction */
156 > /* Evaluate BSDF at the given normalized outgoing direction */
157   extern double           eval_rbfrep(const RBFNODE *rp, const FVECT outvec);
158  
159   /* Insert a new directional scattering function in our global list */
# Line 143 | Line 173 | extern int             is_rev_tri(const FVECT v1,
173   /* Find vertices completing triangles on either side of the given edge */
174   extern int              get_triangles(RBFNODE *rbfv[2], const MIGRATION *mig);
175  
176 + /* Clear our BSDF representation and free memory */
177 + extern void             clear_bsdf_rep(void);
178 +
179   /* Write our BSDF mesh interpolant out to the given binary stream */
180   extern void             save_bsdf_rep(FILE *ofp);
181  
# Line 162 | Line 195 | extern RBFNODE *       make_rbfrep(void);
195   /* Build our triangle mesh from recorded RBFs */
196   extern void             build_mesh(void);
197  
165 /* Draw edge list into mig_grid array */
166 extern void             draw_edges(void);
167
198   /* Find edge(s) for interpolating the given vector, applying symmetry */
199   extern int              get_interp(MIGRATION *miga[3], FVECT invec);
200  
201 + /* Return single-lobe specular RBF for the given incident direction */
202 + extern RBFNODE *        def_rbf_spec(const FVECT invec);
203 +
204 + /* Advect and allocate new RBF along edge (internal call) */
205 + extern RBFNODE *        e_advect_rbf(const MIGRATION *mig,
206 +                                        const FVECT invec, int lobe_lim);
207 +
208 + /* Compute distance between two RBF lobes (internal call) */
209 + extern double           lobe_distance(RBFVAL *rbf1, RBFVAL *rbf2);
210 +
211 + /* Compute mass transport plan (internal call) */
212 + extern void             plan_transport(MIGRATION *mig);
213 +
214   /* Partially advect between recorded incident angles and allocate new RBF */
215 < extern RBFNODE *        advect_rbf(const FVECT invec);
215 > extern RBFNODE *        advect_rbf(const FVECT invec, int lobe_lim);
216 >
217 > #ifdef __cplusplus
218 > }
219 > #endif
220 > #endif  /* _BSDFREP_H_ */

Diff Legend

Removed lines
+ Added lines
< Changed lines
> Changed lines