170 lines
4.9 KiB
C++
170 lines
4.9 KiB
C++
//========= Copyright Valve Corporation, All rights reserved. ============//
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//
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// Purpose:
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//
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//===========================================================================//
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#include "tier0/platform.h"
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#include <stdio.h>
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#include "bitmap/float_bm.h"
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#include "mathlib/mathlib.h"
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#include "tier2/tier2.h"
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#define BRIGHT_THRESH 0.90 // pixels within this % of average are "bright"
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#define GROUND_IMPORTANCE 0.2 // weight for downward pointing skymap pixels
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float Importance(Vector const &direction)
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{
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// this returns a scale factor which can be used to recurd the importance of certain
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// directions. in particular, this version makes the ground a lot less important than the sky
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if (direction.z>.2)
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return 1.0;
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if (direction.z>0)
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return FLerp(1.0,GROUND_IMPORTANCE,.2,0,direction.z);
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else
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return GROUND_IMPORTANCE;
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}
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void main(int argc,char **argv)
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{
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InitCommandLineProgram(argc, argv);
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if (argc!=2)
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{
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printf("format is %s basename\n",argv[0]);
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}
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else
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{
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FloatCubeMap_t cmap(argv[1]);
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// find the brightest pixel. We will consider the pixels neat this to be the
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// ones contrinbuting to the light source
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float max_color=cmap.BrightestColor();
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float threshhold=max_color*.90;
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// now, find average color of non-bright pixels
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float sumweights=0.0;
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Vector AverageColor(0,0,0);
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for(int f=0;f<6;f++)
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for(int y=0;y<cmap.face_maps[f].Height;y++)
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for(int x=0;x<cmap.face_maps[f].Width;x++)
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{
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Vector clr(
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cmap.face_maps[f].Pixel(x,y,0),
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cmap.face_maps[f].Pixel(x,y,1),
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cmap.face_maps[f].Pixel(x,y,2));
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float mag=clr.Length();
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if (mag<threshhold)
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{
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float weight=Importance(cmap.PixelDirection(f,x,y));
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sumweights+=weight;
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AverageColor+=weight*clr;
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}
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}
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AverageColor*=(1.0/sumweights);
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Vector avg_light_dir(0,0,0);
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Vector AverageHue(0,0,0);
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// now, find average direction and color of bright pixels
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for(int f=0;f<6;f++)
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for(int y=0;y<cmap.face_maps[f].Height;y++)
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for(int x=0;x<cmap.face_maps[f].Width;x++)
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{
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Vector clr(
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cmap.face_maps[f].Pixel(x,y,0),
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cmap.face_maps[f].Pixel(x,y,1),
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cmap.face_maps[f].Pixel(x,y,2));
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float mag=clr.Length();
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if (mag>threshhold)
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{
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clr-=AverageColor;
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AverageHue+=clr;
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Vector pdir=cmap.PixelDirection(f,x,y);
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pdir*=clr.Length();
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avg_light_dir+=pdir;
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}
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}
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VectorNormalize(AverageHue);
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VectorNormalize(avg_light_dir);
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printf("Point light dir=%f %f %f\n",avg_light_dir.x,avg_light_dir.y,avg_light_dir.z);
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// printf("Point light color=%f %f %f\n",AverageHue.x,AverageHue.y,AverageHue.z);
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printf("Point light color=%d %d %d 255\n",
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( int )( 255 * pow( AverageHue.x, 1.0f / 2.2f ) ),
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( int )( 255 * pow( AverageHue.y, 1.0f / 2.2f ) ),
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( int )( 255 * pow( AverageHue.z, 1.0f / 2.2f ) ) );
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// now, output ambient cube maps for image-based lighting. During this pass, we will also
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// correct the ambient color
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FloatCubeMap_t conv(32,32);
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Vector AmbientColor(0,0,0);
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float sumweights_amb=0;
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for(int f=0;f<6;f++)
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for(int y=0;y<conv.face_maps[f].Height;y++)
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for(int x=0;x<conv.face_maps[f].Width;x++)
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{
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Vector pdir=conv.PixelDirection(f,x,y);
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float dot=pdir.Dot(avg_light_dir);
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if (dot<0) dot=0;
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float sumdot=0;
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Vector sumlight(0,0,0);
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for(int f1=0;f1<6;f1++)
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for(int y1=0;y1<cmap.face_maps[f].Height;y1+=20)
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for(int x1=0;x1<cmap.face_maps[f].Width;x1+=20)
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{
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Vector sdir=cmap.PixelDirection(f1,x1,y1);
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float dot_sphere=sdir.Dot(pdir);
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if (dot_sphere>0)
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{
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sumdot+=dot_sphere;
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for(int comp=0;comp<3;comp++)
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sumlight[comp]+=
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dot_sphere*cmap.face_maps[f1].Pixel(x1,y1,comp);
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}
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}
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sumlight*=1.0/sumdot;
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// sumlight is the desired lighting
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// use our calculated point light source to find the error
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float weight=Importance(pdir);
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sumweights_amb+=weight;
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for(int comp=0;comp<3;comp++)
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{
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conv.face_maps[f].Pixel(x,y,comp)=sumlight[comp];
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AmbientColor[comp]+=weight*(sumlight[comp]-dot*AverageHue[comp]);
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}
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}
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AmbientColor*=1.0/sumweights_amb;
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conv.WritePFMs("ambient_cube_");
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// printf("Ambient color=%f %f %f\n",AmbientColor.x,AmbientColor.y,AmbientColor.z);
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// convert to gamma space. . .
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printf("Ambient color=%d %d %d 255\n",
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( int )( 255 * pow( AmbientColor.x, 1.0f/2.2f ) ),
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( int )( 255 * pow( AmbientColor.y, 1.0f/2.2f ) ),
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( int )( 255 * pow( AmbientColor.z, 1.0f/2.2f ) ) );
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for(int f=0;f<6;f++)
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for(int y=0;y<cmap.face_maps[f].Height;y++)
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for(int x=0;x<cmap.face_maps[f].Width;x++)
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{
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Vector pdir=cmap.PixelDirection(f,x,y);
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float dot=pdir.Dot(avg_light_dir);
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if (dot<0) dot=0;
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dot=pow(dot,7);
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for(int comp=0;comp<3;comp++)
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cmap.face_maps[f].Pixel(x,y,comp)=AmbientColor[comp]+dot*AverageHue[comp];
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}
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cmap.WritePFMs("directional_plus_ambient_");
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}
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}
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