src/rt/pmapbias.c

#ifndef lint
static const char RCSid[] = "$Id$";
#endif
/* 
   ==================================================================
   Bias compensation for photon density estimates
   
   For background see:
      R. Schregle, "Bias Compensation for Photon Maps",
      Computer Graphics Forum, v22:n4, pp. 729-742, Dec. 2003.

   Roland Schregle ([email protected])
   (c) Fraunhofer Institute for Solar Energy Systems
   ==================================================================
   
   $Id: pmapbias.c,v 2.2 2015/05/08 13:20:23 rschregle Exp $    
*/


#include "pmapbias.h"
#include "pmap.h"
#include "pmaprand.h"


void squeuePartition (PhotonSQNode* squeue, unsigned lo, 
                      unsigned mid, unsigned hi)
/* REVERSE Partition squeue such that all photons in 
   squeue-hi+1..squeue-mid are farther than the median at squeue-mid+1, 
   and those in squeue-mid+2..squeue-lo+1 are closer than the median. 
   This means that squeue points to the END of the queue, and the (1-based) 
   indices are offsets relative to it. This convoluted scheme is adopted 
   since the queue is initially a maxheap, so reverse sorting is expected 
   to be faster. */
{
   unsigned l, h, p;
   PhotonSQNode *lp, *hp, *pp;
   float pivot, dist;
   Photon* photon;

   while (hi > lo) {
      /* Grab pivot node in middle as an educated guess, since our
         queue is sorta sorted. */
      l = lo;
      h = hi;
      p = mid;
      lp = squeue - lo + 1;
      hp = squeue - hi + 1;
      pp = squeue - p + 1;
      pivot = pp -> dist;
      
      /* l & h converge, swapping elements out of order with respect to 
         pivot node. */
      while (l < h) {
         while (lp -> dist <= pivot && l <= h && l < hi)
            ++l, --lp;
         while (hp -> dist >= pivot && h >= l && h > lo)
            --h, ++hp;
            
         if (l < h) {
            /* Swap */
            photon = lp -> photon;
            dist = lp -> dist;
            lp -> photon = hp -> photon;
            lp -> dist = hp -> dist;
            hp -> photon = photon;
            hp -> dist = dist;
         }
      }
      
      /* Swap convergence and pivot node */
      if (p > h) {
         /* Need this otherwise shit happens! 
            Since lp -> dist > hp -> dist, we swap either l or p depending 
            on whether we're above or below p */
         h = l;
         hp = lp;
      }
      
      photon = hp -> photon;
      dist = hp -> dist;
      hp -> photon = pp -> photon;
      hp -> dist = pivot;
      pp -> photon = photon;
      pp -> dist = dist; 
      if (h >= mid) 
         hi = h - 1; 
      if (h <= mid) 
         lo = h + 1; 
   }
   
   /* Once lo & hi have converged, we have found the median! */
}


void biasComp (PhotonMap* pmap, COLOR irrad)
/* Photon density estimate with bias compensation -- czech dis shit out! */
{
   unsigned i, numLo, numHi, numMid;
   PhotonSQNode *sq;
   PhotonBCNode *hist;
   float r, totalWeight = 0;
   PhotonSQNode *squeueEnd;
   PhotonBCNode *histEnd;
   COLOR fluxLo, fluxMid, irradVar, irradAvg, p, d;
   
   if (!pmap -> biasCompHist) {
      /* Allocate bias compensation history */
      numHi = pmap -> maxGather - pmap -> minGather; 
      for (i = pmap -> minGather + 1; numHi > 1; numHi >>= 1, ++i);
      pmap -> biasCompHist = (PhotonBCNode*)malloc(i * sizeof(PhotonBCNode));      
      if (!pmap -> biasCompHist)
         error(USER, "can't allocate bias compensation history");
   }
   
   numLo = min(pmap -> minGather, pmap -> squeueEnd - 1);
   numHi = min(pmap -> maxGather, pmap -> squeueEnd - 1);
   sq = squeueEnd = pmap -> squeue + pmap -> squeueEnd - 1;
   histEnd = pmap -> biasCompHist;
   setcolor(fluxLo, 0, 0, 0);
   
   /* Partition to get numLo closest photons starting from END of queue */
   squeuePartition(squeueEnd, 1, numLo + 1, numHi);
   
   /* Get irradiance estimates (ignoring 1 / PI) using 1..numLo photons 
      and chuck in history. Queue is traversed BACKWARDS. */
   for (i = 1; i <= numLo; i++, sq--) {
      /* Make sure furthest two photons are consecutive wrt distance */
      squeuePartition(squeueEnd, i, i + 1, numLo + 1);
      getPhotonFlux(sq -> photon, irrad);
      addcolor(fluxLo, irrad);
      /* Average radius between furthest two photons to improve accuracy */
      r = 0.25 * (sq -> dist + (sq - 1) -> dist +
                  2 * sqrt(sq -> dist * (sq - 1) -> dist));
      /* Add irradiance and weight to history. Weights should increase
         monotonically based on number of photons used for the estimate. */
      histEnd -> irrad [0] = fluxLo [0] / r;
      histEnd -> irrad [1] = fluxLo [1] / r;
      histEnd -> irrad [2] = fluxLo [2] / r;
      totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)i);
   }
   
   /* Compute expected value (average) and variance of irradiance based on 
      history for numLo photons. */
   setcolor(irradAvg, 0, 0, 0);
   setcolor(irradVar, 0, 0, 0);
   
   for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
      for (i = 0; i <= 2; ++i) {
         irradAvg [i] += r = hist -> weight * hist -> irrad [i];
         irradVar [i] += r * hist -> irrad [i];
      }
      
   for (i = 0; i <= 2; ++i) {
      r = irradAvg [i] /= totalWeight;
      irradVar [i] = irradVar [i] / totalWeight - r * r;
   }
   
   /* Do binary search within interval [numLo, numHi]. numLo is towards
      the END of the queue. */
   while (numHi - numLo > 1) {
      numMid = (numLo + numHi) >> 1;
      /* Split interval to get numMid closest photons starting from the 
         END of the queue */
      squeuePartition(squeueEnd, numLo, numMid, numHi);
      /* Make sure furthest two photons are consecutive wrt distance */
      squeuePartition(squeueEnd, numMid, numMid + 1, numHi);
      copycolor(fluxMid, fluxLo);
      sq = squeueEnd - numLo;
      
      /* Get irradiance for numMid photons (ignoring 1 / PI) */
      for (i = numLo; i < numMid; i++, sq--) {
         getPhotonFlux(sq -> photon, irrad);
         addcolor(fluxMid, irrad);
      }
      
      /* Average radius between furthest two photons to improve accuracy */
      r = 0.25 * (sq -> dist + (sq + 1) -> dist +
                  2 * sqrt(sq -> dist * (sq + 1) -> dist));
                  
      /* Get deviation from current average, and probability that it's due
         to noise from gaussian distribution based on current variance. Since
         we are doing this for each colour channel we can also detect
         chromatic bias. */
      for (i = 0; i <= 2; ++i) {
         d [i] = irradAvg [i] - (irrad [i] = fluxMid [i] / r);
         p [i] = exp(-0.5 * d [i] * d [i] / irradVar [i]);
      }
      
      if (pmapRandom(pmap -> randState) < colorAvg(p)) {
         /* Deviation is probably noise, so add mid irradiance to history */
         copycolor(histEnd -> irrad, irrad);
         totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)numMid);
         setcolor(irradAvg, 0, 0, 0);
         setcolor(irradVar, 0, 0, 0);
         
         /* Update average and variance */
         for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
            for (i = 0; i <= 2; i++) {
               r = hist -> irrad [i];
               irradAvg [i] += hist -> weight * r;
               irradVar [i] += hist -> weight * r * r;
            }
            
         for (i = 0; i <= 2; i++) {
            r = irradAvg [i] /= totalWeight;
            irradVar [i] = irradVar [i] / totalWeight - r * r;
         }
         
         /* Need more photons -- recurse on [numMid, numHi] */
         numLo = numMid;
         copycolor(fluxLo, fluxMid);
      }
      else 
         /* Deviation is probably bias -- need fewer photons, 
            so recurse on [numLo, numMid] */
         numHi = numMid;
   }   

   --histEnd;
   for (i = 0; i <= 2; i++) {
      /* Estimated relative error */
      d [i] = histEnd -> irrad [i] / irradAvg [i] - 1;
      
#ifdef BIASCOMP_BWIDTH
      /* Return bandwidth instead of irradiance */
      irrad [i] = numHi / PI;
#else
      /* 1 / PI required as ambient normalisation factor */
      irrad [i] = histEnd -> irrad [i] / (PI * PI);
#endif
   }
   
   /* Update statistix */
   r = colorAvg(d);
   if (r < pmap -> minError) 
      pmap -> minError = r;
   if (r > pmap -> maxError) 
      pmap -> maxError = r;
   pmap -> rmsError += r * r;
   
   if (numHi < pmap -> minGathered) 
      pmap -> minGathered = numHi;
   if (numHi > pmap -> maxGathered) 
      pmap -> maxGathered = numHi;
      
   pmap -> totalGathered += numHi;
   ++pmap -> numDensity;
}


void volumeBiasComp (PhotonMap* pmap, const RAY* ray, COLOR irrad)
/* Photon volume density estimate with bias compensation -- czech dis 
   shit out! */
{
   unsigned i, numLo, numHi, numMid = 0;
   PhotonSQNode *sq;
   PhotonBCNode *hist;
   const float gecc2 = ray -> gecc * ray -> gecc;
   float r, totalWeight = 0;
   PhotonSQNode *squeueEnd;
   PhotonBCNode *histEnd;
   COLOR fluxLo, fluxMid, irradVar, irradAvg, p, d;

   if (!pmap -> biasCompHist) {
      /* Allocate bias compensation history */
      numHi = pmap -> maxGather - pmap -> minGather; 
      for (i = pmap -> minGather + 1; numHi > 1; numHi >>= 1, ++i);
      pmap -> biasCompHist = (PhotonBCNode*)malloc(i * sizeof(PhotonBCNode));
      if (!pmap -> biasCompHist)
         error(USER, "can't allocate bias compensation history");
   }
   
   numLo = min(pmap -> minGather, pmap -> squeueEnd - 1);
   numHi = min(pmap -> maxGather, pmap -> squeueEnd - 1);
   sq = squeueEnd = pmap -> squeue + pmap -> squeueEnd - 1;
   histEnd = pmap -> biasCompHist;
   setcolor(fluxLo, 0, 0, 0);
   /* Partition to get numLo closest photons starting from END of queue */
   squeuePartition(squeueEnd, 1, numLo, numHi);
   
   /* Get irradiance estimates (ignoring constants) using 1..numLo photons 
      and chuck in history. Queue is traversed BACKWARDS. */
   for (i = 1; i <= numLo; i++, sq--) {
      /* Make sure furthest two photons are consecutive wrt distance */
      squeuePartition(squeueEnd, i, i + 1, numHi);
      
      /* Compute phase function for inscattering from photon */
      if (gecc2 <= FTINY) 
         r = 1;
      else {
         r = DOT(ray -> rdir, sq -> photon -> norm) / 127;
         r = 1 + gecc2 - 2 * ray -> gecc * r;
         r = (1 - gecc2) / (r * sqrt(r));
      }
      
      getPhotonFlux(sq -> photon, irrad);
      scalecolor(irrad, r);
      addcolor(fluxLo, irrad);
      /* Average radius between furthest two photons to improve accuracy */
      r = 0.25 * (sq -> dist + (sq - 1) -> dist +
                  2 * sqrt(sq -> dist * (sq - 1) -> dist));  
      r *= sqrt(r);
      /* Add irradiance and weight to history. Weights should increase
         monotonically based on number of photons used for the estimate. */     
      histEnd -> irrad [0] = fluxLo [0] / r;
      histEnd -> irrad [1] = fluxLo [1] / r;
      histEnd -> irrad [2] = fluxLo [2] / r;
      totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)i);
   }
   
   /* Compute expected value (average) and variance of irradiance based on 
      history for numLo photons. */
   setcolor(irradAvg, 0, 0, 0);
   setcolor(irradVar, 0, 0, 0);
   
   for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
      for (i = 0; i <= 2; ++i) {
         irradAvg [i] += r = hist -> weight * hist -> irrad [i];
         irradVar [i] += r * hist -> irrad [i];
      }
      
   for (i = 0; i <= 2; ++i) {
      r = irradAvg [i] /= totalWeight;
      irradVar [i] = irradVar [i] / totalWeight - r * r;
   }
   
   /* Do binary search within interval [numLo, numHi]. numLo is towards
      the END of the queue. */
   while (numHi - numLo > 1) {
      numMid = (numLo + numHi) >> 1;
      /* Split interval to get numMid closest photons starting from the 
         END of the queue */
      squeuePartition(squeueEnd, numLo, numMid, numHi);
      /* Make sure furthest two photons are consecutive wrt distance */
      squeuePartition(squeueEnd, numMid, numMid + 1, numHi);
      copycolor(fluxMid, fluxLo);
      sq = squeueEnd - numLo;
      
      /* Get irradiance for numMid photons (ignoring constants) */
      for (i = numLo; i < numMid; i++, sq--) {
         /* Compute phase function for inscattering from photon */
         if (gecc2 <= FTINY) 
            r = 1;
         else {
            r = DOT(ray -> rdir, sq -> photon -> norm) / 127;
            r = 1 + gecc2 - 2 * ray -> gecc * r;
            r = (1 - gecc2) / (r * sqrt(r));
         }
         
         getPhotonFlux(sq -> photon, irrad);
         scalecolor(irrad, r);
         addcolor(fluxMid, irrad);
      }
      
      /* Average radius between furthest two photons to improve accuracy */
      r = 0.25 * (sq -> dist + (sq + 1) -> dist +
                  2 * sqrt(sq -> dist * (sq + 1) -> dist));
      r *= sqrt(r);
      
      /* Get deviation from current average, and probability that it's due
         to noise from gaussian distribution based on current variance. Since
         we are doing this for each colour channel we can also detect
         chromatic bias. */
      for (i = 0; i <= 2; ++i) {
         d [i] = irradAvg [i] - (irrad [i] = fluxMid [i] / r);
         p [i] = exp(-0.5 * d [i] * d [i] / irradVar [i]);
      }
      
      if (pmapRandom(pmap -> randState) < colorAvg(p)) {
         /* Deviation is probably noise, so add mid irradiance to history */
         copycolor(histEnd -> irrad, irrad);
         totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)numMid);
         setcolor(irradAvg, 0, 0, 0);
         setcolor(irradVar, 0, 0, 0);
         
         /* Update average and variance */
         for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
            for (i = 0; i <= 2; i++) {
               r = hist -> irrad [i];
               irradAvg [i] += hist -> weight * r;
               irradVar [i] += hist -> weight * r * r;
            }
         for (i = 0; i <= 2; i++) {
            r = irradAvg [i] /= totalWeight;
            irradVar [i] = irradVar [i] / totalWeight - r * r;
         }
         
         /* Need more photons -- recurse on [numMid, numHi] */
         numLo = numMid;
         copycolor(fluxLo, fluxMid);
      }
      else 
         /* Deviation is probably bias -- need fewer photons, 
            so recurse on [numLo, numMid] */
         numHi = numMid;
   }   
   
   --histEnd;
   for (i = 0; i <= 2; i++) {
      /* Estimated relative error */
      d [i] = histEnd -> irrad [i] / irradAvg [i] - 1;
      /* Divide by 4 / 3 * PI for search volume (r^3 already accounted
         for) and phase function normalization factor 1 / (4 * PI) */
      irrad [i] = histEnd -> irrad [i] * 3 / (16 * PI * PI);
   }
   
   /* Update statistix */
   r = colorAvg(d);
   if (r < pmap -> minError) 
      pmap -> minError = r;
   if (r > pmap -> maxError) 
      pmap -> maxError = r;
   pmap -> rmsError += r * r;
   
   if (numMid < pmap -> minGathered) 
      pmap -> minGathered = numMid;
   if (numMid > pmap -> maxGathered) 
      pmap -> maxGathered = numMid;
      
   pmap -> totalGathered += numMid;
   ++pmap -> numDensity;
}
                                 
Revision:	2.3
Committed:	Tue Aug 18 18:45:55 2015 UTC (10 years, 2 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.2:	+5 -2 lines
Log Message:	Added missing RCSid forgotten during initial check-in
#	User	Rev	Content
1	greg	2.3	#ifndef lint
2			static const char RCSid[] = "$Id$";
3			#endif
4	greg	2.1	/*
5			==================================================================
6			Bias compensation for photon density estimates
7
8			For background see:
9			R. Schregle, "Bias Compensation for Photon Maps",
10			Computer Graphics Forum, v22:n4, pp. 729-742, Dec. 2003.
11
12	rschregle	2.2	Roland Schregle ([email protected])
13			(c) Fraunhofer Institute for Solar Energy Systems
14	greg	2.1	==================================================================
15
16	greg	2.3	$Id: pmapbias.c,v 2.2 2015/05/08 13:20:23 rschregle Exp $
17	greg	2.1	*/
18
19
20
21			#include "pmapbias.h"
22			#include "pmap.h"
23			#include "pmaprand.h"
24
25
26
27			void squeuePartition (PhotonSQNode* squeue, unsigned lo,
28			unsigned mid, unsigned hi)
29			/* REVERSE Partition squeue such that all photons in
30			squeue-hi+1..squeue-mid are farther than the median at squeue-mid+1,
31			and those in squeue-mid+2..squeue-lo+1 are closer than the median.
32			This means that squeue points to the END of the queue, and the (1-based)
33			indices are offsets relative to it. This convoluted scheme is adopted
34			since the queue is initially a maxheap, so reverse sorting is expected
35			to be faster. */
36			{
37			unsigned l, h, p;
38			PhotonSQNode lp, hp, *pp;
39			float pivot, dist;
40			Photon* photon;
41
42			while (hi > lo) {
43			/* Grab pivot node in middle as an educated guess, since our
44			queue is sorta sorted. */
45			l = lo;
46			h = hi;
47			p = mid;
48			lp = squeue - lo + 1;
49			hp = squeue - hi + 1;
50			pp = squeue - p + 1;
51			pivot = pp -> dist;
52
53			/* l & h converge, swapping elements out of order with respect to
54			pivot node. */
55			while (l < h) {
56			while (lp -> dist <= pivot && l <= h && l < hi)
57			++l, --lp;
58			while (hp -> dist >= pivot && h >= l && h > lo)
59			--h, ++hp;
60
61			if (l < h) {
62			/* Swap */
63			photon = lp -> photon;
64			dist = lp -> dist;
65			lp -> photon = hp -> photon;
66			lp -> dist = hp -> dist;
67			hp -> photon = photon;
68			hp -> dist = dist;
69			}
70			}
71
72			/* Swap convergence and pivot node */
73			if (p > h) {
74			/* Need this otherwise shit happens!
75			Since lp -> dist > hp -> dist, we swap either l or p depending
76			on whether we're above or below p */
77			h = l;
78			hp = lp;
79			}
80
81			photon = hp -> photon;
82			dist = hp -> dist;
83			hp -> photon = pp -> photon;
84			hp -> dist = pivot;
85			pp -> photon = photon;
86			pp -> dist = dist;
87			if (h >= mid)
88			hi = h - 1;
89			if (h <= mid)
90			lo = h + 1;
91			}
92
93			/* Once lo & hi have converged, we have found the median! */
94			}
95
96
97
98			void biasComp (PhotonMap* pmap, COLOR irrad)
99			/* Photon density estimate with bias compensation -- czech dis shit out! */
100			{
101			unsigned i, numLo, numHi, numMid;
102			PhotonSQNode *sq;
103			PhotonBCNode *hist;
104			float r, totalWeight = 0;
105			PhotonSQNode *squeueEnd;
106			PhotonBCNode *histEnd;
107			COLOR fluxLo, fluxMid, irradVar, irradAvg, p, d;
108
109			if (!pmap -> biasCompHist) {
110			/* Allocate bias compensation history */
111			numHi = pmap -> maxGather - pmap -> minGather;
112			for (i = pmap -> minGather + 1; numHi > 1; numHi >>= 1, ++i);
113			pmap -> biasCompHist = (PhotonBCNode)malloc(i sizeof(PhotonBCNode));
114			if (!pmap -> biasCompHist)
115			error(USER, "can't allocate bias compensation history");
116			}
117
118			numLo = min(pmap -> minGather, pmap -> squeueEnd - 1);
119			numHi = min(pmap -> maxGather, pmap -> squeueEnd - 1);
120			sq = squeueEnd = pmap -> squeue + pmap -> squeueEnd - 1;
121			histEnd = pmap -> biasCompHist;
122			setcolor(fluxLo, 0, 0, 0);
123
124			/* Partition to get numLo closest photons starting from END of queue */
125			squeuePartition(squeueEnd, 1, numLo + 1, numHi);
126
127			/* Get irradiance estimates (ignoring 1 / PI) using 1..numLo photons
128			and chuck in history. Queue is traversed BACKWARDS. */
129			for (i = 1; i <= numLo; i++, sq--) {
130			/* Make sure furthest two photons are consecutive wrt distance */
131			squeuePartition(squeueEnd, i, i + 1, numLo + 1);
132			getPhotonFlux(sq -> photon, irrad);
133			addcolor(fluxLo, irrad);
134			/* Average radius between furthest two photons to improve accuracy */
135			r = 0.25 * (sq -> dist + (sq - 1) -> dist +
136			2 * sqrt(sq -> dist * (sq - 1) -> dist));
137			/* Add irradiance and weight to history. Weights should increase
138			monotonically based on number of photons used for the estimate. */
139			histEnd -> irrad [0] = fluxLo [0] / r;
140			histEnd -> irrad [1] = fluxLo [1] / r;
141			histEnd -> irrad [2] = fluxLo [2] / r;
142			totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)i);
143			}
144
145			/* Compute expected value (average) and variance of irradiance based on
146			history for numLo photons. */
147			setcolor(irradAvg, 0, 0, 0);
148			setcolor(irradVar, 0, 0, 0);
149
150			for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
151			for (i = 0; i <= 2; ++i) {
152			irradAvg [i] += r = hist -> weight * hist -> irrad [i];
153			irradVar [i] += r * hist -> irrad [i];
154			}
155
156			for (i = 0; i <= 2; ++i) {
157			r = irradAvg [i] /= totalWeight;
158			irradVar [i] = irradVar [i] / totalWeight - r * r;
159			}
160
161			/* Do binary search within interval [numLo, numHi]. numLo is towards
162			the END of the queue. */
163			while (numHi - numLo > 1) {
164			numMid = (numLo + numHi) >> 1;
165			/* Split interval to get numMid closest photons starting from the
166			END of the queue */
167			squeuePartition(squeueEnd, numLo, numMid, numHi);
168			/* Make sure furthest two photons are consecutive wrt distance */
169			squeuePartition(squeueEnd, numMid, numMid + 1, numHi);
170			copycolor(fluxMid, fluxLo);
171			sq = squeueEnd - numLo;
172
173			/* Get irradiance for numMid photons (ignoring 1 / PI) */
174			for (i = numLo; i < numMid; i++, sq--) {
175			getPhotonFlux(sq -> photon, irrad);
176			addcolor(fluxMid, irrad);
177			}
178
179			/* Average radius between furthest two photons to improve accuracy */
180			r = 0.25 * (sq -> dist + (sq + 1) -> dist +
181			2 * sqrt(sq -> dist * (sq + 1) -> dist));
182
183			/* Get deviation from current average, and probability that it's due
184			to noise from gaussian distribution based on current variance. Since
185			we are doing this for each colour channel we can also detect
186			chromatic bias. */
187			for (i = 0; i <= 2; ++i) {
188			d [i] = irradAvg [i] - (irrad [i] = fluxMid [i] / r);
189			p [i] = exp(-0.5 * d [i] * d [i] / irradVar [i]);
190			}
191
192			if (pmapRandom(pmap -> randState) < colorAvg(p)) {
193			/* Deviation is probably noise, so add mid irradiance to history */
194			copycolor(histEnd -> irrad, irrad);
195			totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)numMid);
196			setcolor(irradAvg, 0, 0, 0);
197			setcolor(irradVar, 0, 0, 0);
198
199			/* Update average and variance */
200			for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
201			for (i = 0; i <= 2; i++) {
202			r = hist -> irrad [i];
203			irradAvg [i] += hist -> weight * r;
204			irradVar [i] += hist -> weight * r * r;
205			}
206
207			for (i = 0; i <= 2; i++) {
208			r = irradAvg [i] /= totalWeight;
209			irradVar [i] = irradVar [i] / totalWeight - r * r;
210			}
211
212			/* Need more photons -- recurse on [numMid, numHi] */
213			numLo = numMid;
214			copycolor(fluxLo, fluxMid);
215			}
216			else
217			/* Deviation is probably bias -- need fewer photons,
218			so recurse on [numLo, numMid] */
219			numHi = numMid;
220			}
221
222			--histEnd;
223			for (i = 0; i <= 2; i++) {
224			/* Estimated relative error */
225			d [i] = histEnd -> irrad [i] / irradAvg [i] - 1;
226
227			#ifdef BIASCOMP_BWIDTH
228			/* Return bandwidth instead of irradiance */
229			irrad [i] = numHi / PI;
230			#else
231			/* 1 / PI required as ambient normalisation factor */
232			irrad [i] = histEnd -> irrad [i] / (PI * PI);
233			#endif
234			}
235
236			/* Update statistix */
237			r = colorAvg(d);
238			if (r < pmap -> minError)
239			pmap -> minError = r;
240			if (r > pmap -> maxError)
241			pmap -> maxError = r;
242			pmap -> rmsError += r * r;
243
244			if (numHi < pmap -> minGathered)
245			pmap -> minGathered = numHi;
246			if (numHi > pmap -> maxGathered)
247			pmap -> maxGathered = numHi;
248
249			pmap -> totalGathered += numHi;
250			++pmap -> numDensity;
251			}
252
253
254
255			void volumeBiasComp (PhotonMap* pmap, const RAY* ray, COLOR irrad)
256			/* Photon volume density estimate with bias compensation -- czech dis
257			shit out! */
258			{
259			unsigned i, numLo, numHi, numMid = 0;
260			PhotonSQNode *sq;
261			PhotonBCNode *hist;
262			const float gecc2 = ray -> gecc * ray -> gecc;
263			float r, totalWeight = 0;
264			PhotonSQNode *squeueEnd;
265			PhotonBCNode *histEnd;
266			COLOR fluxLo, fluxMid, irradVar, irradAvg, p, d;
267
268			if (!pmap -> biasCompHist) {
269			/* Allocate bias compensation history */
270			numHi = pmap -> maxGather - pmap -> minGather;
271			for (i = pmap -> minGather + 1; numHi > 1; numHi >>= 1, ++i);
272			pmap -> biasCompHist = (PhotonBCNode)malloc(i sizeof(PhotonBCNode));
273			if (!pmap -> biasCompHist)
274			error(USER, "can't allocate bias compensation history");
275			}
276
277			numLo = min(pmap -> minGather, pmap -> squeueEnd - 1);
278			numHi = min(pmap -> maxGather, pmap -> squeueEnd - 1);
279			sq = squeueEnd = pmap -> squeue + pmap -> squeueEnd - 1;
280			histEnd = pmap -> biasCompHist;
281			setcolor(fluxLo, 0, 0, 0);
282			/* Partition to get numLo closest photons starting from END of queue */
283			squeuePartition(squeueEnd, 1, numLo, numHi);
284
285			/* Get irradiance estimates (ignoring constants) using 1..numLo photons
286			and chuck in history. Queue is traversed BACKWARDS. */
287			for (i = 1; i <= numLo; i++, sq--) {
288			/* Make sure furthest two photons are consecutive wrt distance */
289			squeuePartition(squeueEnd, i, i + 1, numHi);
290
291			/* Compute phase function for inscattering from photon */
292			if (gecc2 <= FTINY)
293			r = 1;
294			else {
295			r = DOT(ray -> rdir, sq -> photon -> norm) / 127;
296			r = 1 + gecc2 - 2 * ray -> gecc * r;
297			r = (1 - gecc2) / (r * sqrt(r));
298			}
299
300			getPhotonFlux(sq -> photon, irrad);
301			scalecolor(irrad, r);
302			addcolor(fluxLo, irrad);
303			/* Average radius between furthest two photons to improve accuracy */
304			r = 0.25 * (sq -> dist + (sq - 1) -> dist +
305			2 * sqrt(sq -> dist * (sq - 1) -> dist));
306			r *= sqrt(r);
307			/* Add irradiance and weight to history. Weights should increase
308			monotonically based on number of photons used for the estimate. */
309			histEnd -> irrad [0] = fluxLo [0] / r;
310			histEnd -> irrad [1] = fluxLo [1] / r;
311			histEnd -> irrad [2] = fluxLo [2] / r;
312			totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)i);
313			}
314
315			/* Compute expected value (average) and variance of irradiance based on
316			history for numLo photons. */
317			setcolor(irradAvg, 0, 0, 0);
318			setcolor(irradVar, 0, 0, 0);
319
320			for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
321			for (i = 0; i <= 2; ++i) {
322			irradAvg [i] += r = hist -> weight * hist -> irrad [i];
323			irradVar [i] += r * hist -> irrad [i];
324			}
325
326			for (i = 0; i <= 2; ++i) {
327			r = irradAvg [i] /= totalWeight;
328			irradVar [i] = irradVar [i] / totalWeight - r * r;
329			}
330
331			/* Do binary search within interval [numLo, numHi]. numLo is towards
332			the END of the queue. */
333			while (numHi - numLo > 1) {
334			numMid = (numLo + numHi) >> 1;
335			/* Split interval to get numMid closest photons starting from the
336			END of the queue */
337			squeuePartition(squeueEnd, numLo, numMid, numHi);
338			/* Make sure furthest two photons are consecutive wrt distance */
339			squeuePartition(squeueEnd, numMid, numMid + 1, numHi);
340			copycolor(fluxMid, fluxLo);
341			sq = squeueEnd - numLo;
342
343			/* Get irradiance for numMid photons (ignoring constants) */
344			for (i = numLo; i < numMid; i++, sq--) {
345			/* Compute phase function for inscattering from photon */
346			if (gecc2 <= FTINY)
347			r = 1;
348			else {
349			r = DOT(ray -> rdir, sq -> photon -> norm) / 127;
350			r = 1 + gecc2 - 2 * ray -> gecc * r;
351			r = (1 - gecc2) / (r * sqrt(r));
352			}
353
354			getPhotonFlux(sq -> photon, irrad);
355			scalecolor(irrad, r);
356			addcolor(fluxMid, irrad);
357			}
358
359			/* Average radius between furthest two photons to improve accuracy */
360			r = 0.25 * (sq -> dist + (sq + 1) -> dist +
361			2 * sqrt(sq -> dist * (sq + 1) -> dist));
362			r *= sqrt(r);
363
364			/* Get deviation from current average, and probability that it's due
365			to noise from gaussian distribution based on current variance. Since
366			we are doing this for each colour channel we can also detect
367			chromatic bias. */
368			for (i = 0; i <= 2; ++i) {
369			d [i] = irradAvg [i] - (irrad [i] = fluxMid [i] / r);
370			p [i] = exp(-0.5 * d [i] * d [i] / irradVar [i]);
371			}
372
373			if (pmapRandom(pmap -> randState) < colorAvg(p)) {
374			/* Deviation is probably noise, so add mid irradiance to history */
375			copycolor(histEnd -> irrad, irrad);
376			totalWeight += histEnd++ -> weight = BIASCOMP_WGT((float)numMid);
377			setcolor(irradAvg, 0, 0, 0);
378			setcolor(irradVar, 0, 0, 0);
379
380			/* Update average and variance */
381			for (hist = pmap -> biasCompHist; hist < histEnd; ++hist)
382			for (i = 0; i <= 2; i++) {
383			r = hist -> irrad [i];
384			irradAvg [i] += hist -> weight * r;
385			irradVar [i] += hist -> weight * r * r;
386			}
387			for (i = 0; i <= 2; i++) {
388			r = irradAvg [i] /= totalWeight;
389			irradVar [i] = irradVar [i] / totalWeight - r * r;
390			}
391
392			/* Need more photons -- recurse on [numMid, numHi] */
393			numLo = numMid;
394			copycolor(fluxLo, fluxMid);
395			}
396			else
397			/* Deviation is probably bias -- need fewer photons,
398			so recurse on [numLo, numMid] */
399			numHi = numMid;
400			}
401
402			--histEnd;
403			for (i = 0; i <= 2; i++) {
404			/* Estimated relative error */
405			d [i] = histEnd -> irrad [i] / irradAvg [i] - 1;
406			/* Divide by 4 / 3 * PI for search volume (r^3 already accounted
407			for) and phase function normalization factor 1 / (4 * PI) */
408			irrad [i] = histEnd -> irrad [i] * 3 / (16 * PI * PI);
409			}
410
411			/* Update statistix */
412			r = colorAvg(d);
413			if (r < pmap -> minError)
414			pmap -> minError = r;
415			if (r > pmap -> maxError)
416			pmap -> maxError = r;
417			pmap -> rmsError += r * r;
418
419			if (numMid < pmap -> minGathered)
420			pmap -> minGathered = numMid;
421			if (numMid > pmap -> maxGathered)
422			pmap -> maxGathered = numMid;
423
424			pmap -> totalGathered += numMid;
425			++pmap -> numDensity;
426			}
427	greg	2.3