added Python binding for material.h classes
added raytracermodule.h header file for declarations
updated car.py demo
added texture.py demo (based on spheres_glass.py)
all remaining 'centre' changed to more common 'center'
added some more const's to material.h
/*
* scene.cc: screen sample generation and image reconstruction
*
* This file is part of Pyrit Ray Tracer.
*
* Copyright 2008 Radek Brich
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include <math.h>
#include "common.h"
#include "scene.h"
/* grid oversampling look up tables */
static const int gridsamples[] = {1,4,9,16};
static const Float osa4x[] = { -0.25f, +0.25f, +0.25f, -0.25f };
static const Float osa4y[] = { -0.25f, -0.25f, +0.25f, +0.25f };
static const Float osa9x[] =
{
-0.34f, 0.00f, +0.34f,
-0.34f, 0.00f, +0.34f,
-0.34f, 0.00f, +0.34f
};
static const Float osa9y[] =
{
-0.34f, -0.34f, -0.34f,
0.00f, 0.00f, 0.00f,
+0.34f, +0.34f, +0.34f
};
static const Float osa16x[] =
{
-0.375f, -0.125f, +0.125f, +0.375f,
-0.375f, -0.125f, +0.125f, +0.375f,
-0.375f, -0.125f, +0.125f, +0.375f,
-0.375f, -0.125f, +0.125f, +0.375f
};
static const Float osa16y[] =
{
-0.375f, -0.375f, -0.375f, -0.375f,
-0.125f, -0.125f, -0.125f, -0.125f,
+0.125f, +0.125f, +0.125f, +0.125f,
+0.375f, +0.375f, +0.375f, +0.375f
};
static const Float *osaSx[] = {NULL, osa4x, osa9x, osa16x};
static const Float *osaSy[] = {NULL, osa4y, osa9y, osa16y};
void DefaultSampler::init()
{
phase = 0;
packetable = (subsample <= 1);
}
int DefaultSampler::initSampleSet()
{
const int samples = gridsamples[oversample];
const int &w = pixmap.getWidth(), &h = pixmap.getHeight();
Float *&buffer = pixmap.getFloatData();
if ( phase == 0 )
{
if (subsample > 1)
{
phase = 1;
sx = -1;
return (w/subsample+1)*(h/subsample+1);
}
else
{
phase = 2;
sx = -1;
return w*h*samples;
}
}
if ( phase == 1 )
{
// finalize subsampling
const Float subsample2 = 1.0f / (subsample*subsample);
int num_samples = 0;
Colour ic;
phase = 2;
sx = -1;
for (int y = 0; y < h/subsample; y++)
for (int x = 0; x < w/subsample; x++)
{
int x1 = x*subsample;
int y1 = y*subsample;
int x2 = (x+1)*subsample;
int y2 = (y+1)*subsample;
if (x2 > w-1) x2 = w-1;
if (y2 > h-1) y2 = h-1;
if (x1 == x2 || y1 == y2)
continue;
Float *p;
p = buffer + 3*(y1*w + x1);
Colour c1(*p, *(p+1), *(p+2));
p = buffer + 3*(y1*w + x2);
Colour c2(*p, *(p+1), *(p+2));
p = buffer + 3*(y2*w + x1);
Colour c3(*p, *(p+1), *(p+2));
p = buffer + 3*(y2*w + x2);
Colour c4(*p, *(p+1), *(p+2));
Float m = (c1-c2).mag2();
m = max(m, (c2-c3).mag2());
m = max(m, (c3-c4).mag2());
m = max(m, (c4-c1).mag2());
if (m < 0.002)
{
// interpolate
for (int i = 0; i < subsample; i++)
for (int j = 0; j < subsample; j++)
{
ic = c1*(Float)((subsample-i)*(subsample-j)*subsample2)
+ c2*(Float)((i)*(subsample-j)*subsample2)
+ c3*(Float)((subsample-i)*(j)*subsample2)
+ c4*(Float)((i)*(j)*subsample2);
p = buffer + 3*((y1+j)*w + x1+i);
*(p + 0) = ic.r;
*(p + 1) = oversample ? -ic.g : ic.g;
*(p + 2) = ic.b;
}
}
else
{
// mark as to be computed
num_samples += subsample * subsample;
for (int i = 0; i < subsample; i++)
for (int j = 0; j < subsample; j++)
if (oversample || i != 0 || j != 0)
*(buffer + 3*((y1+j)*w + x1+i)) = -1.;
}
}
return num_samples;
}
if ( phase == 2 && oversample )
{
// finalize oversampling
Float *buf;
if (subsample > 1)
for (buf = buffer; buf != buffer + w*h*3; buf += 3)
if (*(buf+1) < 0)
{
// interpolated
*(buf+1) = -*(buf+1);
}
else
{
*buf = *buf * (1.0f/samples);
*(buf+1) = *(buf+1) * (1.0f/samples);
*(buf+2) = *(buf+2) * (1.0f/samples);
}
else
for (buf = buffer; buf != buffer + w*h*3; buf++)
*buf = *buf * (1.0f/samples);
}
phase = -1;
return 0;
}
bool DefaultSampler::nextSample(Sample* s)
{
const int &w = pixmap.getWidth(), &h = pixmap.getHeight();
Float *&buffer = pixmap.getFloatData();
if (phase == 1)
{
// subsampling
if (sx < 0)
{
// first sample
s->x = -(Float)w/h/2.0f;
s->y = -0.5f;
sx = 0;
sy = 0;
osa_samp = 0;
}
else
{
if (sx == w-1)
{
if (sy == h-1)
return false;
sy += subsample;
if (sy > h-1)
sy = h-1;
sx = 0;
}
else
{
sx += subsample;
if (sx > w-1)
sx = w-1;
}
s->x = (Float)sx/h - (Float)w/h/2.0f;
s->y = (Float)sy/h - 0.5f;
}
}
else if (phase == 2)
{
/* grid oversampling */
const int samples = gridsamples[oversample];
const Float *osax = osaSx[oversample];
const Float *osay = osaSy[oversample];
if (sx < 0)
{
// first sample
s->x = -(Float)w/h/2.0f;
s->y = -0.5f;
sx = 0;
sy = 0;
osa_samp = 0;
}
else
{
osa_samp++;
if (oversample && oversample <= 3 && osa_samp < samples)
{
s->x = osax[osa_samp]/h + (Float)sx/h - (Float)w/h/2.0f;
s->y = osay[osa_samp]/h + (Float)sy/h - 0.5f;
}
else
{
if (subsample > 1)
{
// find next not interpolated pixel
do
{
sx++;
if (sx >= w)
{
sx = 0;
sy++;
}
if (sy >= h)
return false;
}
while ( *(buffer + 3*(sy*w + sx)) >= 0. );
}
else if (!oversample && !(w&1) && !(h&1))
{
// generate good raster for packet tracing
const int j = ((sy&1)<<1) + (sx&1);
switch (j)
{
case 0:
case 2:
sx++;
break;
case 1:
sx--;
sy++;
break;
case 3:
sx++;
if (sx >= w)
{
sx = 0;
sy++;
}
else
sy--;
if (sy >= h)
return false;
break;
}
}
else
{
sx++;
if (sx >= w)
{
sx = 0;
sy++;
}
if (sy >= h)
return false;
}
s->x = (Float)sx/h - (Float)w/h/2.0f;
s->y = (Float)sy/h - 0.5f;
osa_samp = 0;
}
}
if (osa_samp == 0 && oversample && oversample <= 3)
{
s->x += osax[0]/h;
s->y += osay[0]/h;
Float *buf = buffer + 3*(sy*w + sx);
*(buf++) = 0;
*(buf++) = 0;
*(buf++) = 0;
}
}
s->sx = sx;
s->sy = sy;
s->osa_samp = osa_samp;
return true;
}
void DefaultSampler::saveSample(const Sample &samp, const Colour &col)
{
Float *buf = pixmap.getFloatData()
+ 3*(samp.sy * pixmap.getWidth() + samp.sx);
if (phase == 2 && oversample)
{
*(buf+0) += col.r;
*(buf+1) += col.g;
*(buf+2) += col.b;
}
else
{
*(buf++) = col.r;
*(buf++) = col.g;
*(buf++) = col.b;
}
}