blender/intern/cycles/kernel/osl/nodes/node_sky_texture.osl

/*
 * Copyright 2011, Blender Foundation.
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
 */

#include "stdosl.h"

struct KernelSunSky {
	/* sun direction in spherical and cartesian */
	float theta, phi;
	vector dir;

	/* perez function parameters */
	float zenith_Y, zenith_x, zenith_y;
	float perez_Y[5], perez_x[5], perez_y[5];
};

color xyY_to_xyz(float x, float y, float Y)
{
	float X, Z;

	if(y != 0.0) X = (x / y) * Y;
	else X = 0.0;

	if(y != 0.0 && Y != 0.0) Z = ((1.0 - x - y) / y) * Y;
	else Z = 0.0;

	return color(X, Y, Z);
}

color xyz_to_rgb(float x, float y, float z)
{
	return color(3.240479 * x + -1.537150 * y + -0.498535 * z,
				 -0.969256 * x + 1.875991 * y + 0.041556 * z,
				 0.055648 * x + -0.204043 * y + 1.057311 * z);
}

float sky_angle_between(float thetav, float phiv, float theta, float phi)
{
	float cospsi = sin(thetav)*sin(theta)*cos(phi - phiv) + cos(thetav)*cos(theta);

	if(cospsi > 1.0)
		return 0.0;
	if(cospsi < -1.0)
		return M_PI;

	return acos(cospsi);
}

vector sky_spherical_coordinates(vector dir)
{
	return vector(acos(dir[2]), atan2(dir[0], dir[1]), 0);
}

float sky_perez_function(float lam[5], float theta, float gamma)
{
	float ctheta = cos(theta);
	float cgamma = cos(gamma);

	return (1.0 + lam[0]*exp(lam[1] / ctheta)) * (1.0 + lam[2]*exp(lam[3]*gamma) + lam[4]*cgamma*cgamma);
}

color sky_xyz_radiance(KernelSunSky sunsky, vector dir)
{
	/* convert vector to spherical coordinates */
	vector spherical = sky_spherical_coordinates(dir);
	float theta = spherical[0];
	float phi = spherical[1];

	/* angle between sun direction and dir */
	float gamma = sky_angle_between(theta, phi, sunsky.theta, sunsky.phi);

	/* clamp theta to horizon */
	theta = min(theta, M_PI_2 - 0.001);

	/* compute xyY color space values */
	float x = sunsky.zenith_x * sky_perez_function(sunsky.perez_x, theta, gamma);
	float y = sunsky.zenith_y * sky_perez_function(sunsky.perez_y, theta, gamma);
	float Y = sunsky.zenith_Y * sky_perez_function(sunsky.perez_Y, theta, gamma);

	/* convert to RGB */
	color xyz = xyY_to_xyz(x, y, Y);
	return xyz_to_rgb(xyz[0], xyz[1], xyz[2]);
}

void precompute_sunsky(vector dir, float turbidity, output KernelSunSky sunsky)
{
	vector spherical = sky_spherical_coordinates(dir);
	float theta = spherical[0];
	float phi = spherical[1];

	sunsky.theta = theta;
	sunsky.phi = phi;
	sunsky.dir = dir;

	float theta2 = theta*theta;
	float theta3 = theta*theta*theta;
	float T = turbidity;
	float T2 = T*T;

	float chi = (4.0/ 9.0- T / 120.0) * (M_PI - 2.0* theta);
	sunsky.zenith_Y = (4.0453*T - 4.9710) * tan(chi) - 0.2155*T + 2.4192;
	sunsky.zenith_Y *= 0.06;

	sunsky.zenith_x =
	(0.00166* theta3 - 0.00375* theta2 + 0.00209* theta)*T2 +
	(-0.02903* theta3 + 0.06377* theta2 - 0.03202* theta + 0.00394)*T +
	(0.11693* theta3 - 0.21196* theta2 + 0.06052* theta + 0.25886);

	sunsky.zenith_y =
	(0.00275* theta3 - 0.00610* theta2 + 0.00317* theta)*T2 +
	(-0.04214* theta3 + 0.08970* theta2 - 0.04153* theta + 0.00516)*T +
	(0.15346* theta3 - 0.26756* theta2 + 0.06670* theta + 0.26688);

	sunsky.perez_Y[0] = (0.1787*T - 1.4630);
	sunsky.perez_Y[1] = (-0.3554*T + 0.4275);
	sunsky.perez_Y[2] = (-0.0227*T + 5.3251);
	sunsky.perez_Y[3] = (0.1206*T - 2.5771);
	sunsky.perez_Y[4] = (-0.0670*T + 0.3703);

	sunsky.perez_x[0] = (-0.0193*T - 0.2592);
	sunsky.perez_x[1] = (-0.0665*T + 0.0008);
	sunsky.perez_x[2] = (-0.0004*T + 0.2125);
	sunsky.perez_x[3] = (-0.0641*T - 0.8989);
	sunsky.perez_x[4] = (-0.0033*T + 0.0452);

	sunsky.perez_y[0] = (-0.0167*T - 0.2608);
	sunsky.perez_y[1] = (-0.0950*T + 0.0092);
	sunsky.perez_y[2] = (-0.0079*T + 0.2102);
	sunsky.perez_y[3] = (-0.0441*T - 1.6537);
	sunsky.perez_y[4] = (-0.0109*T + 0.0529);

	sunsky.zenith_Y /= sky_perez_function(sunsky.perez_Y, 0, theta);
	sunsky.zenith_x /= sky_perez_function(sunsky.perez_x, 0, theta);
	sunsky.zenith_y /= sky_perez_function(sunsky.perez_y, 0, theta);
}

shader node_sky_texture(
	vector Vector = P,
	vector sun_direction = vector(0, 0, 1),
	float turbidity = 2.2,
	output color Color = color(0.0, 0.0, 0.0))
{
	KernelSunSky sunsky;

	precompute_sunsky(sun_direction, turbidity, sunsky);
	Color = sky_xyz_radiance(sunsky, Vector);
}
Cycles render engine, initial commit. This is the engine itself, blender modifications and build instructions will follow later. Cycles uses code from some great open source projects, many thanks them: * BVH building and traversal code from NVidia's "Understanding the Efficiency of Ray Traversal on GPUs": http://code.google.com/p/understanding-the-efficiency-of-ray-traversal-on-gpus/ * Open Shading Language for a large part of the shading system: http://code.google.com/p/openshadinglanguage/ * Blender for procedural textures and a few other nodes. * Approximate Catmull Clark subdivision from NVidia Mesh tools: http://code.google.com/p/nvidia-mesh-tools/ * Sobol direction vectors from: http://web.maths.unsw.edu.au/~fkuo/sobol/ * Film response functions from: http://www.cs.columbia.edu/CAVE/software/softlib/dorf.php 2011-04-27 11:58:34 +00:00			`/*`
			`* Copyright 2011, Blender Foundation.`
			`*`
			`* This program is free software; you can redistribute it and/or`
			`* modify it under the terms of the GNU General Public License`
			`* as published by the Free Software Foundation; either version 2`
			`* of the License, or (at your option) any later version.`
			`*`
			`* This program is distributed in the hope that it will be useful,`
			`* but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
			`* GNU General Public License for more details.`
			`*`
			`* You should have received a copy of the GNU General Public License`
			`* along with this program; if not, write to the Free Software Foundation,`
			`* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.`
			`*/`

			`#include "stdosl.h"`

			`struct KernelSunSky {`
			`/* sun direction in spherical and cartesian */`
			`float theta, phi;`
			`vector dir;`

			`/* perez function parameters */`
			`float zenith_Y, zenith_x, zenith_y;`
			`float perez_Y[5], perez_x[5], perez_y[5];`
			`};`

			`color xyY_to_xyz(float x, float y, float Y)`
			`{`
			`float X, Z;`

			`if(y != 0.0) X = (x / y) * Y;`
			`else X = 0.0;`

			`if(y != 0.0 && Y != 0.0) Z = ((1.0 - x - y) / y) * Y;`
			`else Z = 0.0;`

			`return color(X, Y, Z);`
			`}`

			`color xyz_to_rgb(float x, float y, float z)`
			`{`
			`return color(3.240479 * x + -1.537150 * y + -0.498535 * z,`
			`-0.969256 * x + 1.875991 * y + 0.041556 * z,`
			`0.055648 * x + -0.204043 * y + 1.057311 * z);`
			`}`

			`float sky_angle_between(float thetav, float phiv, float theta, float phi)`
			`{`
			`float cospsi = sin(thetav)sin(theta)cos(phi - phiv) + cos(thetav)*cos(theta);`

			`if(cospsi > 1.0)`
			`return 0.0;`
			`if(cospsi < -1.0)`
			`return M_PI;`

			`return acos(cospsi);`
			`}`

			`vector sky_spherical_coordinates(vector dir)`
			`{`
			`return vector(acos(dir[2]), atan2(dir[0], dir[1]), 0);`
			`}`

			`float sky_perez_function(float lam[5], float theta, float gamma)`
			`{`
			`float ctheta = cos(theta);`
			`float cgamma = cos(gamma);`

			`return (1.0 + lam[0]exp(lam[1] / ctheta)) (1.0 + lam[2]exp(lam[3]gamma) + lam[4]cgammacgamma);`
			`}`

			`color sky_xyz_radiance(KernelSunSky sunsky, vector dir)`
			`{`
			`/* convert vector to spherical coordinates */`
			`vector spherical = sky_spherical_coordinates(dir);`
			`float theta = spherical[0];`
			`float phi = spherical[1];`

			`/* angle between sun direction and dir */`
			`float gamma = sky_angle_between(theta, phi, sunsky.theta, sunsky.phi);`

			`/* clamp theta to horizon */`
			`theta = min(theta, M_PI_2 - 0.001);`

			`/* compute xyY color space values */`
			`float x = sunsky.zenith_x * sky_perez_function(sunsky.perez_x, theta, gamma);`
			`float y = sunsky.zenith_y * sky_perez_function(sunsky.perez_y, theta, gamma);`
			`float Y = sunsky.zenith_Y * sky_perez_function(sunsky.perez_Y, theta, gamma);`

			`/* convert to RGB */`
			`color xyz = xyY_to_xyz(x, y, Y);`
			`return xyz_to_rgb(xyz[0], xyz[1], xyz[2]);`
			`}`

			`void precompute_sunsky(vector dir, float turbidity, output KernelSunSky sunsky)`
			`{`
			`vector spherical = sky_spherical_coordinates(dir);`
			`float theta = spherical[0];`
			`float phi = spherical[1];`

			`sunsky.theta = theta;`
			`sunsky.phi = phi;`
			`sunsky.dir = dir;`

			`float theta2 = theta*theta;`
			`float theta3 = thetathetatheta;`
			`float T = turbidity;`
			`float T2 = T*T;`

			`float chi = (4.0/ 9.0- T / 120.0) * (M_PI - 2.0* theta);`
			`sunsky.zenith_Y = (4.0453T - 4.9710) tan(chi) - 0.2155*T + 2.4192;`
			`sunsky.zenith_Y *= 0.06;`

			`sunsky.zenith_x =`
			`(0.00166* theta3 - 0.00375* theta2 + 0.00209* theta)*T2 +`
			`(-0.02903* theta3 + 0.06377* theta2 - 0.03202* theta + 0.00394)*T +`
			`(0.11693* theta3 - 0.21196* theta2 + 0.06052* theta + 0.25886);`

			`sunsky.zenith_y =`
			`(0.00275* theta3 - 0.00610* theta2 + 0.00317* theta)*T2 +`
			`(-0.04214* theta3 + 0.08970* theta2 - 0.04153* theta + 0.00516)*T +`
			`(0.15346* theta3 - 0.26756* theta2 + 0.06670* theta + 0.26688);`

			`sunsky.perez_Y[0] = (0.1787*T - 1.4630);`
			`sunsky.perez_Y[1] = (-0.3554*T + 0.4275);`
			`sunsky.perez_Y[2] = (-0.0227*T + 5.3251);`
			`sunsky.perez_Y[3] = (0.1206*T - 2.5771);`
			`sunsky.perez_Y[4] = (-0.0670*T + 0.3703);`

			`sunsky.perez_x[0] = (-0.0193*T - 0.2592);`
			`sunsky.perez_x[1] = (-0.0665*T + 0.0008);`
			`sunsky.perez_x[2] = (-0.0004*T + 0.2125);`
			`sunsky.perez_x[3] = (-0.0641*T - 0.8989);`
			`sunsky.perez_x[4] = (-0.0033*T + 0.0452);`

			`sunsky.perez_y[0] = (-0.0167*T - 0.2608);`
			`sunsky.perez_y[1] = (-0.0950*T + 0.0092);`
			`sunsky.perez_y[2] = (-0.0079*T + 0.2102);`
			`sunsky.perez_y[3] = (-0.0441*T - 1.6537);`
			`sunsky.perez_y[4] = (-0.0109*T + 0.0529);`

			`sunsky.zenith_Y /= sky_perez_function(sunsky.perez_Y, 0, theta);`
			`sunsky.zenith_x /= sky_perez_function(sunsky.perez_x, 0, theta);`
			`sunsky.zenith_y /= sky_perez_function(sunsky.perez_y, 0, theta);`
			`}`

			`shader node_sky_texture(`
			`vector Vector = P,`
			`vector sun_direction = vector(0, 0, 1),`
			`float turbidity = 2.2,`
			`output color Color = color(0.0, 0.0, 0.0))`
			`{`
			`KernelSunSky sunsky;`

			`precompute_sunsky(sun_direction, turbidity, sunsky);`
			`Color = sky_xyz_radiance(sunsky, Vector);`
			`}`