#include "la_5.h"
const int TRANSMITTANCE_TEXTURE_WIDTH = 256;
const int TRANSMITTANCE_TEXTURE_HEIGHT = 64;
const int SCATTERING_TEXTURE_R_SIZE = 32;
const int SCATTERING_TEXTURE_MU_SIZE = 128;
const int SCATTERING_TEXTURE_MU_S_SIZE = 32;
const int SCATTERING_TEXTURE_NU_SIZE = 8;
const int SCATTERING_TEXTURE_WIDTH =
SCATTERING_TEXTURE_NU_SIZE * SCATTERING_TEXTURE_MU_S_SIZE;
const int SCATTERING_TEXTURE_HEIGHT = SCATTERING_TEXTURE_MU_SIZE;
const int SCATTERING_TEXTURE_DEPTH = SCATTERING_TEXTURE_R_SIZE;
const int IRRADIANCE_TEXTURE_WIDTH = 64;
const int IRRADIANCE_TEXTURE_HEIGHT = 16;
// The conversion factor between watts and lumens.
const double MAX_LUMINOUS_EFFICACY = 683.0;
// Values from "CIE (1931) 2-deg color matching functions", see
// "http://web.archive.org/web/20081228084047/
// http://www.cvrl.org/database/data/cmfs/ciexyz31.txt".
const double CIE_2_DEG_COLOR_MATCHING_FUNCTIONS[380] = {
360, 0.000129900000, 0.000003917000, 0.000606100000,
365, 0.000232100000, 0.000006965000, 0.001086000000,
370, 0.000414900000, 0.000012390000, 0.001946000000,
375, 0.000741600000, 0.000022020000, 0.003486000000,
380, 0.001368000000, 0.000039000000, 0.006450001000,
385, 0.002236000000, 0.000064000000, 0.010549990000,
390, 0.004243000000, 0.000120000000, 0.020050010000,
395, 0.007650000000, 0.000217000000, 0.036210000000,
400, 0.014310000000, 0.000396000000, 0.067850010000,
405, 0.023190000000, 0.000640000000, 0.110200000000,
410, 0.043510000000, 0.001210000000, 0.207400000000,
415, 0.077630000000, 0.002180000000, 0.371300000000,
420, 0.134380000000, 0.004000000000, 0.645600000000,
425, 0.214770000000, 0.007300000000, 1.039050100000,
430, 0.283900000000, 0.011600000000, 1.385600000000,
435, 0.328500000000, 0.016840000000, 1.622960000000,
440, 0.348280000000, 0.023000000000, 1.747060000000,
445, 0.348060000000, 0.029800000000, 1.782600000000,
450, 0.336200000000, 0.038000000000, 1.772110000000,
455, 0.318700000000, 0.048000000000, 1.744100000000,
460, 0.290800000000, 0.060000000000, 1.669200000000,
465, 0.251100000000, 0.073900000000, 1.528100000000,
470, 0.195360000000, 0.090980000000, 1.287640000000,
475, 0.142100000000, 0.112600000000, 1.041900000000,
480, 0.095640000000, 0.139020000000, 0.812950100000,
485, 0.057950010000, 0.169300000000, 0.616200000000,
490, 0.032010000000, 0.208020000000, 0.465180000000,
495, 0.014700000000, 0.258600000000, 0.353300000000,
500, 0.004900000000, 0.323000000000, 0.272000000000,
505, 0.002400000000, 0.407300000000, 0.212300000000,
510, 0.009300000000, 0.503000000000, 0.158200000000,
515, 0.029100000000, 0.608200000000, 0.111700000000,
520, 0.063270000000, 0.710000000000, 0.078249990000,
525, 0.109600000000, 0.793200000000, 0.057250010000,
530, 0.165500000000, 0.862000000000, 0.042160000000,
535, 0.225749900000, 0.914850100000, 0.029840000000,
540, 0.290400000000, 0.954000000000, 0.020300000000,
545, 0.359700000000, 0.980300000000, 0.013400000000,
550, 0.433449900000, 0.994950100000, 0.008749999000,
555, 0.512050100000, 1.000000000000, 0.005749999000,
560, 0.594500000000, 0.995000000000, 0.003900000000,
565, 0.678400000000, 0.978600000000, 0.002749999000,
570, 0.762100000000, 0.952000000000, 0.002100000000,
575, 0.842500000000, 0.915400000000, 0.001800000000,
580, 0.916300000000, 0.870000000000, 0.001650001000,
585, 0.978600000000, 0.816300000000, 0.001400000000,
590, 1.026300000000, 0.757000000000, 0.001100000000,
595, 1.056700000000, 0.694900000000, 0.001000000000,
600, 1.062200000000, 0.631000000000, 0.000800000000,
605, 1.045600000000, 0.566800000000, 0.000600000000,
610, 1.002600000000, 0.503000000000, 0.000340000000,
615, 0.938400000000, 0.441200000000, 0.000240000000,
620, 0.854449900000, 0.381000000000, 0.000190000000,
625, 0.751400000000, 0.321000000000, 0.000100000000,
630, 0.642400000000, 0.265000000000, 0.000049999990,
635, 0.541900000000, 0.217000000000, 0.000030000000,
640, 0.447900000000, 0.175000000000, 0.000020000000,
645, 0.360800000000, 0.138200000000, 0.000010000000,
650, 0.283500000000, 0.107000000000, 0.000000000000,
655, 0.218700000000, 0.081600000000, 0.000000000000,
660, 0.164900000000, 0.061000000000, 0.000000000000,
665, 0.121200000000, 0.044580000000, 0.000000000000,
670, 0.087400000000, 0.032000000000, 0.000000000000,
675, 0.063600000000, 0.023200000000, 0.000000000000,
680, 0.046770000000, 0.017000000000, 0.000000000000,
685, 0.032900000000, 0.011920000000, 0.000000000000,
690, 0.022700000000, 0.008210000000, 0.000000000000,
695, 0.015840000000, 0.005723000000, 0.000000000000,
700, 0.011359160000, 0.004102000000, 0.000000000000,
705, 0.008110916000, 0.002929000000, 0.000000000000,
710, 0.005790346000, 0.002091000000, 0.000000000000,
715, 0.004109457000, 0.001484000000, 0.000000000000,
720, 0.002899327000, 0.001047000000, 0.000000000000,
725, 0.002049190000, 0.000740000000, 0.000000000000,
730, 0.001439971000, 0.000520000000, 0.000000000000,
735, 0.000999949300, 0.000361100000, 0.000000000000,
740, 0.000690078600, 0.000249200000, 0.000000000000,
745, 0.000476021300, 0.000171900000, 0.000000000000,
750, 0.000332301100, 0.000120000000, 0.000000000000,
755, 0.000234826100, 0.000084800000, 0.000000000000,
760, 0.000166150500, 0.000060000000, 0.000000000000,
765, 0.000117413000, 0.000042400000, 0.000000000000,
770, 0.000083075270, 0.000030000000, 0.000000000000,
775, 0.000058706520, 0.000021200000, 0.000000000000,
780, 0.000041509940, 0.000014990000, 0.000000000000,
785, 0.000029353260, 0.000010600000, 0.000000000000,
790, 0.000020673830, 0.000007465700, 0.000000000000,
795, 0.000014559770, 0.000005257800, 0.000000000000,
800, 0.000010253980, 0.000003702900, 0.000000000000,
805, 0.000007221456, 0.000002607800, 0.000000000000,
810, 0.000005085868, 0.000001836600, 0.000000000000,
815, 0.000003581652, 0.000001293400, 0.000000000000,
820, 0.000002522525, 0.000000910930, 0.000000000000,
825, 0.000001776509, 0.000000641530, 0.000000000000,
830, 0.000001251141, 0.000000451810, 0.000000000000,
};
// The conversion matrix from XYZ to linear sRGB color spaces.
// Values from https://en.wikipedia.org/wiki/SRGB.
const double XYZ_TO_SRGB[9] = {
+3.2406, -1.5372, -0.4986,
-0.9689, +1.8758, +0.0415,
+0.0557, -0.2040, +1.0570
};
const char kVertexShader[] = "\n\
#version 330\n\
layout(location = 0) in vec2 vertex;\n\
void main() {\n\
gl_Position = vec4(vertex, 0.0, 1.0);\n\
}";
const char kGeometryShader[] = "\n\
#version 330\n\
layout(triangles) in;\n\
layout(triangle_strip, max_vertices = 3) out;\n\
uniform int layer;\n\
void main() {\n\
gl_Position = gl_in[0].gl_Position;\n\
gl_Layer = layer;\n\
EmitVertex();\n\
gl_Position = gl_in[1].gl_Position;\n\
gl_Layer = layer;\n\
EmitVertex();\n\
gl_Position = gl_in[2].gl_Position;\n\
gl_Layer = layer;\n\
EmitVertex();\n\
EndPrimitive();\n\
}";
const char kComputeTransmittanceShader[] = "\n\
layout(location = 0) out vec3 transmittance;\n\
void main() {\n\
transmittance = ComputeTransmittanceToTopAtmosphereBoundaryTexture(\n\
ATMOSPHERE, gl_FragCoord.xy);\n\
}";
const char kComputeDirectIrradianceShader[] = "\n\
layout(location = 0) out vec3 delta_irradiance;\n\
layout(location = 1) out vec3 irradiance;\n\
uniform sampler2D transmittance_texture;\n\
void main() {\n\
delta_irradiance = ComputeDirectIrradianceTexture(\n\
ATMOSPHERE, transmittance_texture, gl_FragCoord.xy);\n\
irradiance = vec3(0.0);\n\
}";
const char kComputeSingleScatteringShader[] = "\n\
layout(location = 0) out vec3 delta_rayleigh;\n\
layout(location = 1) out vec3 delta_mie;\n\
layout(location = 2) out vec4 scattering;\n\
layout(location = 3) out vec3 single_mie_scattering;\n\
uniform mat3 luminance_from_radiance;\n\
uniform sampler2D transmittance_texture;\n\
uniform int layer;\n\
void main() {\n\
ComputeSingleScatteringTexture(\n\
ATMOSPHERE, transmittance_texture, vec3(gl_FragCoord.xy, layer + 0.5),\n\
delta_rayleigh, delta_mie);\n\
scattering = vec4(luminance_from_radiance * delta_rayleigh.rgb,\n\
(luminance_from_radiance * delta_mie).r);\n\
single_mie_scattering = luminance_from_radiance * delta_mie;\n\
}";
const char kComputeScatteringDensityShader[] = "\n\
layout(location = 0) out vec3 scattering_density;\n\
uniform sampler2D transmittance_texture;\n\
uniform sampler3D single_rayleigh_scattering_texture;\n\
uniform sampler3D single_mie_scattering_texture;\n\
uniform sampler3D multiple_scattering_texture;\n\
uniform sampler2D irradiance_texture;\n\
uniform int scattering_order;\n\
uniform int layer;\n\
void main() {\n\
scattering_density = ComputeScatteringDensityTexture(\n\
ATMOSPHERE, transmittance_texture, single_rayleigh_scattering_texture,\n\
single_mie_scattering_texture, multiple_scattering_texture,\n\
irradiance_texture, vec3(gl_FragCoord.xy, layer + 0.5),\n\
scattering_order);\n\
}";
const char kComputeIndirectIrradianceShader[] = "\n\
layout(location = 0) out vec3 delta_irradiance;\n\
layout(location = 1) out vec3 irradiance;\n\
uniform mat3 luminance_from_radiance;\n\
uniform sampler3D single_rayleigh_scattering_texture;\n\
uniform sampler3D single_mie_scattering_texture;\n\
uniform sampler3D multiple_scattering_texture;\n\
uniform int scattering_order;\n\
void main() {\n\
delta_irradiance = ComputeIndirectIrradianceTexture(\n\
ATMOSPHERE, single_rayleigh_scattering_texture,\n\
single_mie_scattering_texture, multiple_scattering_texture,\n\
gl_FragCoord.xy, scattering_order);\n\
irradiance = luminance_from_radiance * delta_irradiance;\n\
}";
const char kComputeMultipleScatteringShader[] = "\n\
layout(location = 0) out vec3 delta_multiple_scattering;\n\
layout(location = 1) out vec4 scattering;\n\
uniform mat3 luminance_from_radiance;\n\
uniform sampler2D transmittance_texture;\n\
uniform sampler3D scattering_density_texture;\n\
uniform int layer;\n\
void main() {\n\
float nu;\n\
delta_multiple_scattering = ComputeMultipleScatteringTexture(\n\
ATMOSPHERE, transmittance_texture, scattering_density_texture,\n\
vec3(gl_FragCoord.xy, layer + 0.5), nu);\n\
scattering = vec4(\n\
luminance_from_radiance *\n\
delta_multiple_scattering.rgb / RayleighPhaseFunction(nu),\n\
0.0);\n\
}";
const char kAtmosphereShader[] = "\n\
uniform sampler2D transmittance_texture;\n\
uniform sampler3D scattering_texture;\n\
uniform sampler3D single_mie_scattering_texture;\n\
uniform sampler2D irradiance_texture;\n\
#ifdef RADIANCE_API_ENABLED\n\
RadianceSpectrum GetSolarRadiance() {\n\
return ATMOSPHERE.solar_irradiance /\n\
(PI * ATMOSPHERE.sun_angular_radius * ATMOSPHERE.sun_angular_radius);\n\
}\n\
RadianceSpectrum GetSkyRadiance(\n\
Position camera, Direction view_ray, Length shadow_length,\n\
Direction sun_direction, out DimensionlessSpectrum transmittance) {\n\
return GetSkyRadiance(ATMOSPHERE, transmittance_texture,\n\
scattering_texture, single_mie_scattering_texture,\n\
camera, view_ray, shadow_length, sun_direction, transmittance);\n\
}\n\
RadianceSpectrum GetSkyRadianceToPoint(\n\
Position camera, Position point, Length shadow_length,\n\
Direction sun_direction, out DimensionlessSpectrum transmittance) {\n\
return GetSkyRadianceToPoint(ATMOSPHERE, transmittance_texture,\n\
scattering_texture, single_mie_scattering_texture,\n\
camera, point, shadow_length, sun_direction, transmittance);\n\
}\n\
IrradianceSpectrum GetSunAndSkyIrradiance(\n\
Position p, Direction normal, Direction sun_direction,\n\
out IrradianceSpectrum sky_irradiance) {\n\
return GetSunAndSkyIrradiance(ATMOSPHERE, transmittance_texture,\n\
irradiance_texture, p, normal, sun_direction, sky_irradiance);\n\
}\n\
#endif\n\
Luminance3 GetSolarLuminance() {\n\
return ATMOSPHERE.solar_irradiance /\n\
(PI * ATMOSPHERE.sun_angular_radius * ATMOSPHERE.sun_angular_radius) *\n\
SUN_SPECTRAL_RADIANCE_TO_LUMINANCE;\n\
}\n\
Luminance3 GetSkyLuminance(\n\
Position camera, Direction view_ray, Length shadow_length,\n\
Direction sun_direction, out DimensionlessSpectrum transmittance) {\n\
return GetSkyRadiance(ATMOSPHERE, transmittance_texture,\n\
scattering_texture, single_mie_scattering_texture,\n\
camera, view_ray, shadow_length, sun_direction, transmittance) *\n\
SKY_SPECTRAL_RADIANCE_TO_LUMINANCE;\n\
}\n\
Luminance3 GetSkyLuminanceToPoint(\n\
Position camera, Position point, Length shadow_length,\n\
Direction sun_direction, out DimensionlessSpectrum transmittance) {\n\
return GetSkyRadianceToPoint(ATMOSPHERE, transmittance_texture,\n\
scattering_texture, single_mie_scattering_texture,\n\
camera, point, shadow_length, sun_direction, transmittance) *\n\
SKY_SPECTRAL_RADIANCE_TO_LUMINANCE;\n\
}\n\
Illuminance3 GetSunAndSkyIlluminance(\n\
Position p, Direction normal, Direction sun_direction,\n\
out IrradianceSpectrum sky_irradiance) {\n\
IrradianceSpectrum sun_irradiance = GetSunAndSkyIrradiance(\n\
ATMOSPHERE, transmittance_texture, irradiance_texture, p, normal,\n\
sun_direction, sky_irradiance);\n\
sky_irradiance *= SKY_SPECTRAL_RADIANCE_TO_LUMINANCE;\n\
return sun_irradiance * SUN_SPECTRAL_RADIANCE_TO_LUMINANCE;\n\
}";
const char header[]="#version 330\n\
#define IN(x) const in x\n\
#define OUT(x) out x\n\
#define TEMPLATE(x)\n\
#define TEMPLATE_ARGUMENT(x)\n\
#define assert(x)\n\
const int TRANSMITTANCE_TEXTURE_WIDTH = 256;\n\
const int TRANSMITTANCE_TEXTURE_HEIGHT = 64;\n\
const int SCATTERING_TEXTURE_R_SIZE = 32;\n\
const int SCATTERING_TEXTURE_MU_SIZE = 128;\n\
const int SCATTERING_TEXTURE_MU_S_SIZE = 32;\n\
const int SCATTERING_TEXTURE_NU_SIZE = 8;\n\
const int IRRADIANCE_TEXTURE_WIDTH = 64;\n\
const int IRRADIANCE_TEXTURE_HEIGHT = 16;\n\
#define COMBINED_SCATTERING_TEXTURES\n\
\n\
#define Length float\n\
#define Wavelength float\n\
#define Angle float\n\
#define SolidAngle float\n\
#define Power float\n\
#define LuminousPower float\n\
#define Number float\n\
#define InverseLength float\n\
#define Area float\n\
#define Volume float\n\
#define NumberDensity float\n\
#define Irradiance float\n\
#define Radiance float\n\
#define SpectralPower float\n\
#define SpectralIrradiance float\n\
#define SpectralRadiance float\n\
#define SpectralRadianceDensity float\n\
#define ScatteringCoefficient float\n\
#define InverseSolidAngle float\n\
#define LuminousIntensity float\n\
#define Luminance float\n\
#define Illuminance float\n\
#define AbstractSpectrum vec3\n\
#define DimensionlessSpectrum vec3\n\
#define PowerSpectrum vec3\n\
#define IrradianceSpectrum vec3\n\
#define RadianceSpectrum vec3\n\
#define RadianceDensitySpectrum vec3\n\
#define ScatteringSpectrum vec3\n\
#define Position vec3\n\
#define Direction vec3\n\
#define Luminance3 vec3\n\
#define Illuminance3 vec3\n\
#define TransmittanceTexture sampler2D\n\
#define AbstractScatteringTexture sampler3D\n\
#define ReducedScatteringTexture sampler3D\n\
#define ScatteringTexture sampler3D\n\
#define ScatteringDensityTexture sampler3D\n\
#define IrradianceTexture sampler2D\n\
const Length m = 1.0;\n\
const Wavelength nm = 1.0;\n\
const Angle rad = 1.0;\n\
const SolidAngle sr = 1.0;\n\
const Power watt = 1.0;\n\
const LuminousPower lm = 1.0;\n\
const float PI = 3.14159265358979323846;\n\
const Length km = 1000.0 * m;\n\
const Area m2 = m * m;\n\
const Volume m3 = m * m * m;\n\
const Angle pi = PI * rad;\n\
const Angle deg = pi / 180.0;\n\
const Irradiance watt_per_square_meter = watt / m2;\n\
const Radiance watt_per_square_meter_per_sr = watt / (m2 * sr);\n\
const SpectralIrradiance watt_per_square_meter_per_nm = watt / (m2 * nm);\n\
const SpectralRadiance watt_per_square_meter_per_sr_per_nm =\n\
watt / (m2 * sr * nm);\n\
const SpectralRadianceDensity watt_per_cubic_meter_per_sr_per_nm =\n\
watt / (m3 * sr * nm);\n\
const LuminousIntensity cd = lm / sr;\n\
const LuminousIntensity kcd = 1000.0 * cd;\n\
const Luminance cd_per_square_meter = cd / m2;\n\
const Luminance kcd_per_square_meter = kcd / m2;\n\
struct DensityProfileLayer {\n\
Length width;\n\
Number exp_term;\n\
InverseLength exp_scale;\n\
InverseLength linear_term;\n\
Number constant_term;\n\
};\n\
struct DensityProfile {\n\
DensityProfileLayer layers[2];\n\
};\n\
struct AtmosphereParameters {\n\
IrradianceSpectrum solar_irradiance;\n\
Angle sun_angular_radius;\n\
Length bottom_radius;\n\
Length top_radius;\n\
DensityProfile rayleigh_density;\n\
ScatteringSpectrum rayleigh_scattering;\n\
DensityProfile mie_density;\n\
ScatteringSpectrum mie_scattering;\n\
ScatteringSpectrum mie_extinction;\n\
Number mie_phase_function_g;\n\
DensityProfile absorption_density;\n\
ScatteringSpectrum absorption_extinction;\n\
DimensionlessSpectrum ground_albedo;\n\
Number mu_s_min;\n\
};\n\
const AtmosphereParameters ATMOSPHERE = AtmosphereParameters(\n\
vec3(1.474000,1.850400,1.911980),\n\
0.004675,\n\
6360.000000,\n\
6420.000000,\n\
DensityProfile(DensityProfileLayer[2](DensityProfileLayer(0.000000,0.000000,0.000000,0.000000,0.000000),DensityProfileLayer(0.000000,1.000000,-0.125000,0.000000,0.000000))),\n\
vec3(0.005802,0.013558,0.033100),\n\
DensityProfile(DensityProfileLayer[2](DensityProfileLayer(0.000000,0.000000,0.000000,0.000000,0.000000),DensityProfileLayer(0.000000,1.000000,-0.833333,0.000000,0.000000))),\n\
vec3(0.003996,0.003996,0.003996),\n\
vec3(0.004440,0.004440,0.004440),\n\
0.800000,\n\
DensityProfile(DensityProfileLayer[2](DensityProfileLayer(25.000000,0.000000,0.000000,0.066667,-0.666667),DensityProfileLayer(0.000000,0.000000,0.000000,-0.066667,2.666667))),\n\
vec3(0.000650,0.001881,0.000085),\n\
vec3(0.100000,0.100000,0.100000),\n\
-0.207912);\n\
const vec3 SKY_SPECTRAL_RADIANCE_TO_LUMINANCE = vec3(683.000000,683.000000,683.000000);\n\
const vec3 SUN_SPECTRAL_RADIANCE_TO_LUMINANCE = vec3(98242.786222,69954.398112,66475.012354);\n\
";
void tns_InitAtmosphere(){
laSafeString* ss=0;
tnsTexture* transmittance_texture_ = tnsCreate2DTexture(GL_RGBA32F, TRANSMITTANCE_TEXTURE_WIDTH, TRANSMITTANCE_TEXTURE_HEIGHT, 0);
tnsTexture* scattering_texture_ = tnsCreate3DTexture(GL_RGBA16F, SCATTERING_TEXTURE_WIDTH, SCATTERING_TEXTURE_HEIGHT,SCATTERING_TEXTURE_DEPTH);
tnsTexture* irradiance_texture_ = tnsCreate2DTexture(GL_RGBA32F, IRRADIANCE_TEXTURE_WIDTH, IRRADIANCE_TEXTURE_HEIGHT, 0);
tnsTexture* delta_irradiance_texture = tnsCreate2DTexture(GL_RGBA32F, IRRADIANCE_TEXTURE_WIDTH, IRRADIANCE_TEXTURE_HEIGHT, 0);
tnsTexture* delta_rayleigh_scattering_texture = tnsCreate3DTexture(GL_RGBA16F, SCATTERING_TEXTURE_WIDTH, SCATTERING_TEXTURE_HEIGHT,SCATTERING_TEXTURE_DEPTH);
tnsTexture* delta_mie_scattering_texture = tnsCreate3DTexture(GL_RGBA16F, SCATTERING_TEXTURE_WIDTH, SCATTERING_TEXTURE_HEIGHT,SCATTERING_TEXTURE_DEPTH);
tnsTexture* delta_scattering_density_texture =tnsCreate3DTexture(GL_RGBA16F, SCATTERING_TEXTURE_WIDTH, SCATTERING_TEXTURE_HEIGHT,SCATTERING_TEXTURE_DEPTH);
tnsTexture* delta_multiple_scattering_texture = delta_rayleigh_scattering_texture;
GLuint fbo;
glGenFramebuffers(1, &fbo);
glBindFramebuffer(GL_FRAMEBUFFER, fbo);
// The actual precomputations depend on whether we want to store precomputed
// irradiance or illuminance values.
//if (num_precomputed_wavelengths_ <= 3) {
// vec3 lambdas{kLambdaR, kLambdaG, kLambdaB};
// mat3 luminance_from_radiance{1.0, 0.0, 0.0, 0.0, 1.0, 0.0, 0.0, 0.0, 1.0};
// Precompute(fbo, delta_irradiance_texture, delta_rayleigh_scattering_texture,
// delta_mie_scattering_texture, delta_scattering_density_texture,
// delta_multiple_scattering_texture, lambdas, luminance_from_radiance,
// false /* blend */, num_scattering_orders);
//} else {
// constexpr double kLambdaMin = 360.0;
// constexpr double kLambdaMax = 830.0;
// int num_iterations = (num_precomputed_wavelengths_ + 2) / 3;
// double dlambda = (kLambdaMax - kLambdaMin) / (3 * num_iterations);
// for (int i = 0; i < num_iterations; ++i) {
// vec3 lambdas{
// kLambdaMin + (3 * i + 0.5) * dlambda,
// kLambdaMin + (3 * i + 1.5) * dlambda,
// kLambdaMin + (3 * i + 2.5) * dlambda
// };
// auto coeff = [dlambda](double lambda, int component) {
// // Note that we don't include MAX_LUMINOUS_EFFICACY here, to avoid
// // artefacts due to too large values when using half precision on GPU.
// // We add this term back in kAtmosphereShader, via
// // SKY_SPECTRAL_RADIANCE_TO_LUMINANCE (see also the comments in the
// // Model constructor).
// double x = CieColorMatchingFunctionTableValue(lambda, 1);
// double y = CieColorMatchingFunctionTableValue(lambda, 2);
// double z = CieColorMatchingFunctionTableValue(lambda, 3);
// return static_cast<float>((
// XYZ_TO_SRGB[component * 3] * x +
// XYZ_TO_SRGB[component * 3 + 1] * y +
// XYZ_TO_SRGB[component * 3 + 2] * z) * dlambda);
// };
// mat3 luminance_from_radiance{
// coeff(lambdas[0], 0), coeff(lambdas[1], 0), coeff(lambdas[2], 0),
// coeff(lambdas[0], 1), coeff(lambdas[1], 1), coeff(lambdas[2], 1),
// coeff(lambdas[0], 2), coeff(lambdas[1], 2), coeff(lambdas[2], 2)
// };
// Precompute(fbo, delta_irradiance_texture,
// delta_rayleigh_scattering_texture, delta_mie_scattering_texture,
// delta_scattering_density_texture, delta_multiple_scattering_texture,
// lambdas, luminance_from_radiance, i > 0 /* blend */,
// num_scattering_orders);
// }
//
// // After the above iterations, the transmittance texture contains the
// // transmittance for the 3 wavelengths used at the last iteration. But we
// // want the transmittance at kLambdaR, kLambdaG, kLambdaB instead, so we
// // must recompute it here for these 3 wavelengths:
// std::string header = glsl_header_factory_({kLambdaR, kLambdaG, kLambdaB});
// Program compute_transmittance(
// kVertexShader, header + kComputeTransmittanceShader);
// glFramebufferTexture(
// GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, transmittance_texture_, 0);
// glDrawBuffer(GL_COLOR_ATTACHMENT0);
// glViewport(0, 0, TRANSMITTANCE_TEXTURE_WIDTH, TRANSMITTANCE_TEXTURE_HEIGHT);
// compute_transmittance.Use();
// DrawQuad({}, full_screen_quad_vao_);
//}
// Delete the temporary resources allocated at the begining of this method.
glUseProgram(0);
glBindFramebuffer(GL_FRAMEBUFFER, 0);
glDeleteFramebuffers(1, &fbo);
glDeleteTextures(1, &delta_scattering_density_texture);
glDeleteTextures(1, &delta_mie_scattering_texture);
glDeleteTextures(1, &delta_rayleigh_scattering_texture);
glDeleteTextures(1, &delta_irradiance_texture);
assert(glGetError() == 0);
strSafeDestroy(&ss); strSafePrint(&ss,"%s%s",header,kComputeTransmittanceShader);
tnsShader* compute_transmittance=tnsNewShaderProgram(tnsNewVertexShader(kVertexShader),tnsNewFragmentShader(ss->Ptr),-1);
strSafeDestroy(&ss); strSafePrint(&ss,"%s%s",header,kComputeDirectIrradianceShader);
tnsShader* compute_direct_irradiance=tnsNewShaderProgram(tnsNewVertexShader(kVertexShader),tnsNewFragmentShader(ss->Ptr),-1);
strSafeDestroy(&ss); strSafePrint(&ss,"%s%s",header,kComputeSingleScatteringShader);
tnsShader* compute_single_scattering=tnsNewShaderProgram(tnsNewVertexShader(kVertexShader),tnsNewFragmentShader(ss->Ptr),tnsNewGeometryShader(kGeometryShader));
strSafeDestroy(&ss); strSafePrint(&ss,"%s%s",header,kComputeScatteringDensityShader);
tnsShader* compute_scattering_density=tnsNewShaderProgram(tnsNewVertexShader(kVertexShader),tnsNewFragmentShader(ss->Ptr),tnsNewGeometryShader(kGeometryShader));
strSafeDestroy(&ss); strSafePrint(&ss,"%s%s",header,kComputeIndirectIrradianceShader);
tnsShader* compute_indirect_irradiance=tnsNewShaderProgram(tnsNewVertexShader(kVertexShader),tnsNewFragmentShader(ss->Ptr),-1);
strSafeDestroy(&ss); strSafePrint(&ss,"%s%s",header,kComputeMultipleScatteringShader);
tnsShader* compute_multiple_scattering=tnsNewShaderProgram(tnsNewVertexShader(kVertexShader),tnsNewFragmentShader(ss->Ptr),tnsNewGeometryShader(kGeometryShader));
const GLuint kDrawBuffers[4] = {
GL_COLOR_ATTACHMENT0,
GL_COLOR_ATTACHMENT1,
GL_COLOR_ATTACHMENT2,
GL_COLOR_ATTACHMENT3
};
glBlendEquationSeparate(GL_FUNC_ADD, GL_FUNC_ADD);
glBlendFuncSeparate(GL_ONE, GL_ONE, GL_ONE, GL_ONE);;
}