group_bot/assets/voxygen/shaders/include/light.glsl

#ifndef LIGHT_GLSL
#define LIGHT_GLSL

#include <srgb.glsl>
#include <shadows.glsl>

struct Light {
    vec4 light_pos;
    vec4 light_col;
    // mat4 light_proj;
};

layout (std140, set = 0, binding = 3)
uniform u_lights {
    // TODO: insert light max count constant here when loading the shaders
    Light lights[20];
};

struct Shadow {
    vec4 shadow_pos_radius;
};

layout (std140, set = 0, binding = 4)
uniform u_shadows {
    Shadow shadows[24];
};

float attenuation_strength(vec3 rpos) {
    // This is not how light attenuation works at all, but it produces visually pleasing and mechanically useful properties
    float d2 = rpos.x * rpos.x + rpos.y * rpos.y + rpos.z * rpos.z;
    return max(2.0 / pow(d2 + 10, 0.35) - pow(d2 / 50000.0, 0.8), 0.0);
}

float attenuation_strength_real(vec3 rpos) {
    float d2 = rpos.x * rpos.x + rpos.y * rpos.y + rpos.z * rpos.z;
    return 1.0 / (0.025 + d2);
}

// // Compute attenuation due to light passing through a substance that fills an area below a horizontal plane
// // (e.g. in most cases, water below the water surface depth).
// //
// // wpos is the position of the point being hit.
// // ray_dir is the reversed direction of the ray (going "out" of the point being hit).
// // surface_alt is the estimated altitude of the horizontal surface separating the substance from air.
// // defaultpos is the position to use in computing the distance along material at this point if there was a failure.
// //
// // Ideally, defaultpos is set so we can avoid branching on error.
// float compute_attenuation_beam(vec3 wpos, vec3 ray_dir, float surface_alt, vec3 defaultpos, float attenuation_depth) {
//     vec3 water_intersection_surface_camera = vec3(cam_pos);
//     bool _water_intersects_surface_camera = IntersectRayPlane(f_pos, view_dir, vec3(0.0, 0.0, /*f_alt*/f_pos.z + f_light), cam_surface_dir, water_intersection_surface_camera);
//     // Should work because we set it up so that if IntersectRayPlane returns false for camera, its default intersection point is cam_pos.
//     float water_depth_to_camera = length(water_intersection_surface_camera - f_pos);
//
//     vec3 water_intersection_surface_light = f_pos;
//     bool _light_intersects_surface_water = IntersectRayPlane(f_pos, sun_dir.z <= 0.0 ? sun_dir : moon_dir, vec3(0.0, 0.0, /*f_alt*/f_pos.z + f_light), vec3(0.0, 0.0, 1.0), water_intersection_surface_light);
//     // Should work because we set it up so that if IntersectRayPlane returns false for light, its default intersection point is f_pos--
//     // i.e. if a light ray can't hit the water, it shouldn't contribute to coloring at all.
//     float water_depth_to_light = length(water_intersection_surface_light - f_pos);
//
//     // For ambient color, we just take the distance to the surface out of laziness.
//     float water_depth_to_vertical = max(/*f_alt - f_pos.z*/f_light, 0.0);
//
//     // Color goes down with distance...
//     // See https://en.wikipedia.org/wiki/Beer%E2%80%93Lambert_law.
//     vec3 water_color_direct = exp(-water_attenuation * (water_depth_to_light + water_depth_to_camera));
//     vec3 water_color_ambient = exp(-water_attenuation * (water_depth_to_vertical + water_depth_to_camera));
//
// }

vec3 light_at(vec3 wpos, vec3 wnorm) {
    const float LIGHT_AMBIANCE = 0.025;

    vec3 light = vec3(0);

    for (uint i = 0u; i < light_shadow_count.x; i ++) {

        // Only access the array once
        Light L = lights[i];

        vec3 light_pos = L.light_pos.xyz - focus_off.xyz;

        // Pre-calculate difference between light and fragment
        vec3 difference = light_pos - wpos;

        float strength = attenuation_strength(difference);

        vec3 color = L.light_col.rgb * strength;

        light += color * (max(0, max(dot(normalize(difference), wnorm), 0.15)) + LIGHT_AMBIANCE);
    }
    return light;
}

float shadow_at(vec3 wpos, vec3 wnorm) {
    float shadow = 1.0;

#if (SHADOW_MODE == SHADOW_MODE_CHEAP || (SHADOW_MODE == SHADOW_MODE_MAP && defined(EXPERIMENTAL_POINTSHADOWSWITHSHADOWMAPPING)))
    for (uint i = 0u; i < light_shadow_count.y; i ++) {

        // Only access the array once
        Shadow S = shadows[i];

        vec3 shadow_pos = S.shadow_pos_radius.xyz - focus_off.xyz;
        float radius = S.shadow_pos_radius.w;

        vec3 diff = shadow_pos - wpos;
        #if (SHADOW_MODE == SHADOW_MODE_CHEAP)
            if (diff.z >= 0.0) {
                diff.z = -sign(diff.z) * diff.z * 0.1;
            }
        #endif

        float shade = max(pow(diff.x * diff.x + diff.y * diff.y + diff.z * diff.z, 0.3) / pow(radius * radius * 0.5, 0.5), 0.5);
        // float shade = max(pow(dot(diff, diff) / (radius * radius * 0.5), 0.25), 0.5);
        // float shade = dot(diff, diff) / (radius * radius * 0.5);

        shadow = min(shadow, shade);
    }
    // NOTE: Squared to compenate for prior saturation.
    return min(shadow, 1.0);
    // return min(shadow * shadow, 1.0);
#else
    return shadow;
#endif
}

// Returns computed maximum intensity.
//
// mu is the attenuation coefficient for any substance on a horizontal plane.
// cam_attenuation is the total light attenuation due to the substance for beams between the point and the camera.
// surface_alt is the altitude of the attenuating surface.
float lights_at(vec3 wpos, vec3 wnorm, vec3 /*cam_to_frag*/view_dir, vec3 mu, vec3 cam_attenuation, float surface_alt, vec3 k_a, vec3 k_d, vec3 k_s, float alpha, vec3 voxel_norm, float voxel_lighting, inout vec3 emitted_light, inout vec3 reflected_light/*, out float shadow*/) {
    // return 0.0;
    // shadow = 0.0;
    // vec3 ambient_light = vec3(0.0);
    vec3 directed_light = vec3(0.0);
    vec3 max_light = vec3(0.0);

    const float LIGHT_AMBIANCE = 0.0;//0.015625;

    for (uint i = 0u; i < /*light_shadow_count.x*//*0u*/light_shadow_count.x/*32u*/; i ++) {

        // Only access the array once
        Light L = lights[i];

        vec3 light_pos = L.light_pos.xyz - focus_off.xyz;

        // Pre-calculate difference between light and fragment
        vec3 difference = light_pos - wpos;
        float distance_2 = dot(difference, difference);

        if (distance_2 > 10000.0) {
            continue;
        }

        // float strength = attenuation_strength(difference);// pow(attenuation_strength(difference), 0.6);
        // NOTE: This normalizes strength to 0.25 at the center of the point source.
        float strength = 3.0 / (5 + distance_2);

        // Multiply the vec3 only once
        const float PI = 3.1415926535897932384626433832795;
        const float PI_2 = 2 * PI;
        vec3 color = /*srgb_to_linear*/L.light_col.rgb;

        // // Only access the array once
        // Shadow S = shadows[i];

        // vec3 shadow_pos = S.shadow_pos_radius.xyz;
        // float radius = S.shadow_pos_radius.w;

        // vec3 diff = shadow_pos - wpos;
        // if (diff.z >= 0.0) {
        //  diff.z = -sign(diff.z) * diff.z * 0.1;
        // }

        // float shade = max(pow(diff.x * diff.x + diff.y * diff.y + diff.z * diff.z, 0.25) / pow(radius * radius * 0.5, 0.25), /*0.5*/0.0);

        // shadow = min(shadow, shade);

        // Compute reflectance.
        float light_distance = sqrt(distance_2);
        vec3 light_dir = -difference / light_distance; // normalize(-difference);
        // light_dir = faceforward(light_dir, wnorm, light_dir);
        bool is_direct = dot(difference, wnorm) > 0.0;
        // reflected_light += color * (distance_2 == 0.0 ? vec3(1.0) : light_reflection_factor(wnorm, cam_to_frag, light_dir, k_d, k_s, alpha));
        vec3 direct_light_dir = is_direct ? light_dir : -light_dir;
        // vec3 direct_norm_dir = is_direct ? wnorm : -wnorm;
        // Compute attenuation due to fluid.
        // Default is light_pos, so we take the whole segment length for this beam if it never intersects the surface, unlesss the beam itself
        // is above the surface, in which case we take zero (wpos).
        color *= cam_attenuation * compute_attenuation_point(wpos, -direct_light_dir, mu, surface_alt, light_pos.z < surface_alt ? light_pos : wpos);

#if (LIGHTING_TYPE & LIGHTING_TYPE_TRANSMISSION) != 0
        is_direct = true;
#endif
        vec3 lrf = light_reflection_factor(/*direct_norm_dir*/wnorm, /*cam_to_frag*/view_dir, direct_light_dir, k_d, k_s, alpha, voxel_norm, voxel_lighting);
        vec3 direct_light = PI * color * strength * lrf;
        /* is_direct = true; */
        float computed_shadow = ShadowCalculationPoint(i, -difference, wnorm, wpos/*, light_distance*/);
        // directed_light += is_direct ? max(computed_shadow, /*LIGHT_AMBIANCE*/0.0) * direct_light : vec3(0.0);
        float ambiance = 0.0;
        #ifndef EXPERIMENTAL_PHOTOREALISTIC
            // Non-physically emulate ambient light nearby
            ambiance = mix(0.05, 0.5, (dot(wnorm, direct_light_dir) + 1.0) * 0.5) * strength;
            #ifdef FIGURE_SHADER
                // Non-physical hack. Subtle, but allows lanterns to glow nicely
                // TODO: Make lanterns use glowing cells instead
                ambiance += 0.1 / distance_2;
            #endif
        #endif
        directed_light += (is_direct ? mix(LIGHT_AMBIANCE, 1.0, computed_shadow) * direct_light : vec3(0.0)) + ambiance * color;
        // directed_light += (is_direct ? 1.0 : LIGHT_AMBIANCE) * max(computed_shadow, /*LIGHT_AMBIANCE*/0.0) * direct_light;// : vec3(0.0);
        // directed_light += mix(LIGHT_AMBIANCE, 1.0, computed_shadow) * direct_light;
        // ambient_light += is_direct ? vec3(0.0) : vec3(0.0); // direct_light * LIGHT_AMBIANCE;
        // ambient_light += is_direct ? direct_light * (1.0 - LIGHT_AMBIANCE) : vec3(0.0);

        vec3 cam_light_diff = light_pos - focus_pos.xyz;
        float cam_distance_2 = dot(cam_light_diff, cam_light_diff);// + 0.0001;
        float cam_strength = 1.0 / (/*4.0 * *//*PI * *//*1.0 + */cam_distance_2);

        // vec3 cam_pos_diff  = cam_to_frag.xyz - wpos;
        // float pos_distance_2 = dot(cam_pos_diff, cam_pos_diff);// + 0.0001;

        // float cam_distance = sqrt(cam_distance_2);
        // float distance = sqrt(distance_2);
        float both_strength = cam_distance_2 == 0.0 ? distance_2 == 0.0 ? 0.0 : strength/* * strength*//*1.0*/ : distance_2 == 0.0 ? cam_strength/* * cam_strength*//*1.0*/ :
            // 1.0 / (cam_distance * distance);
            // sqrt(cam_strength * strength);
            cam_strength + strength;
            // (cam_strength * strength);
            // max(cam_strength, strength);
            // mix(cam_strength, strength, distance_2 / (cam_distance_2 + distance_2));
            // mix(cam_strength, strength, cam_distance_2 / (cam_distance_2 + distance_2));
            // max(cam_strength, strength);//mix(cam_strength, strength, clamp(distance_2 / /*pos_distance_2*/cam_distance_2, 0.0, 1.0));
        // float both_strength = mix(cam_strength, strength, cam_distance_2 / sqrt(cam_distance_2 + distance_2));
        max_light += /*max(1.0, cam_strength)*//*min(cam_strength, 1.0)*//*max*//*max(both_strength, 1.0) * *//*cam_strength*/computed_shadow * both_strength * PI * color;
        // max_light += /*max(1.0, cam_strength)*//*min(cam_strength, 1.0)*//*max*/max(cam_strength, 1.0/*, strength*//*1.0*/) * PI * color;
        // light += color * (max(0, max(dot(normalize(difference), wnorm), 0.15)) + LIGHT_AMBIANCE);
        // Compute emiittance.
        // float ambient_sides = clamp(mix(0.15, 0.0, abs(dot(wnorm, light_dir)) * 10000.0), 0.0, 0.15);
        // float ambient_sides = 0.0;// max(dot(wnorm, light_dir) - 0.15, 0.15);
        // // float ambient_sides = 0.0;
        // ambient_light += color * (ambient_sides + LIGHT_AMBIANCE);
    }

    // shadow = shadow_at(wpos, wnorm);
    // float shadow = shadow_at(wpos, wnorm);
    reflected_light += directed_light;
    // emitted_light += k_a * ambient_light/* * shadow*/;// min(shadow, 1.0);
    return /*rel_luminance(ambient_light + directed_light)*/rel_luminance(max_light);//ambient_light;
}

// Same as lights_at, but with no assumed attenuation due to fluid.
float lights_at(vec3 wpos, vec3 wnorm, vec3 view_dir, vec3 k_a, vec3 k_d, vec3 k_s, float alpha, inout vec3 emitted_light, inout vec3 reflected_light) {
    return lights_at(wpos, wnorm, view_dir, vec3(0.0), vec3(1.0), 0.0, k_a, k_d, k_s, alpha, wnorm, 1.0, emitted_light, reflected_light);
}

#endif
Update assets; Tick faster 2024-06-13 23:16:24 +00:00			`#ifndef LIGHT_GLSL`
			`#define LIGHT_GLSL`

			`#include <srgb.glsl>`
			`#include <shadows.glsl>`

			`struct Light {`
			`vec4 light_pos;`
			`vec4 light_col;`
			`// mat4 light_proj;`
			`};`

			`layout (std140, set = 0, binding = 3)`
			`uniform u_lights {`
			`// TODO: insert light max count constant here when loading the shaders`
			`Light lights[20];`
			`};`

			`struct Shadow {`
			`vec4 shadow_pos_radius;`
			`};`

			`layout (std140, set = 0, binding = 4)`
			`uniform u_shadows {`
			`Shadow shadows[24];`
			`};`

			`float attenuation_strength(vec3 rpos) {`
			`// This is not how light attenuation works at all, but it produces visually pleasing and mechanically useful properties`
			`float d2 = rpos.x * rpos.x + rpos.y * rpos.y + rpos.z * rpos.z;`
			`return max(2.0 / pow(d2 + 10, 0.35) - pow(d2 / 50000.0, 0.8), 0.0);`
			`}`

			`float attenuation_strength_real(vec3 rpos) {`
			`float d2 = rpos.x * rpos.x + rpos.y * rpos.y + rpos.z * rpos.z;`
			`return 1.0 / (0.025 + d2);`
			`}`

			`// // Compute attenuation due to light passing through a substance that fills an area below a horizontal plane`
			`// // (e.g. in most cases, water below the water surface depth).`
			`// //`
			`// // wpos is the position of the point being hit.`
			`// // ray_dir is the reversed direction of the ray (going "out" of the point being hit).`
			`// // surface_alt is the estimated altitude of the horizontal surface separating the substance from air.`
			`// // defaultpos is the position to use in computing the distance along material at this point if there was a failure.`
			`// //`
			`// // Ideally, defaultpos is set so we can avoid branching on error.`
			`// float compute_attenuation_beam(vec3 wpos, vec3 ray_dir, float surface_alt, vec3 defaultpos, float attenuation_depth) {`
			`// vec3 water_intersection_surface_camera = vec3(cam_pos);`
			`// bool _water_intersects_surface_camera = IntersectRayPlane(f_pos, view_dir, vec3(0.0, 0.0, /f_alt/f_pos.z + f_light), cam_surface_dir, water_intersection_surface_camera);`
			`// // Should work because we set it up so that if IntersectRayPlane returns false for camera, its default intersection point is cam_pos.`
			`// float water_depth_to_camera = length(water_intersection_surface_camera - f_pos);`
			`//`
			`// vec3 water_intersection_surface_light = f_pos;`
			`// bool _light_intersects_surface_water = IntersectRayPlane(f_pos, sun_dir.z <= 0.0 ? sun_dir : moon_dir, vec3(0.0, 0.0, /f_alt/f_pos.z + f_light), vec3(0.0, 0.0, 1.0), water_intersection_surface_light);`
			`// // Should work because we set it up so that if IntersectRayPlane returns false for light, its default intersection point is f_pos--`
			`// // i.e. if a light ray can't hit the water, it shouldn't contribute to coloring at all.`
			`// float water_depth_to_light = length(water_intersection_surface_light - f_pos);`
			`//`
			`// // For ambient color, we just take the distance to the surface out of laziness.`
			`// float water_depth_to_vertical = max(/f_alt - f_pos.z/f_light, 0.0);`
			`//`
			`// // Color goes down with distance...`
			`// // See https://en.wikipedia.org/wiki/Beer%E2%80%93Lambert_law.`
			`// vec3 water_color_direct = exp(-water_attenuation * (water_depth_to_light + water_depth_to_camera));`
			`// vec3 water_color_ambient = exp(-water_attenuation * (water_depth_to_vertical + water_depth_to_camera));`
			`//`
			`// }`

			`vec3 light_at(vec3 wpos, vec3 wnorm) {`
			`const float LIGHT_AMBIANCE = 0.025;`

			`vec3 light = vec3(0);`

			`for (uint i = 0u; i < light_shadow_count.x; i ++) {`

			`// Only access the array once`
			`Light L = lights[i];`

			`vec3 light_pos = L.light_pos.xyz - focus_off.xyz;`

			`// Pre-calculate difference between light and fragment`
			`vec3 difference = light_pos - wpos;`

			`float strength = attenuation_strength(difference);`

			`vec3 color = L.light_col.rgb * strength;`

			`light += color * (max(0, max(dot(normalize(difference), wnorm), 0.15)) + LIGHT_AMBIANCE);`
			`}`
			`return light;`
			`}`

			`float shadow_at(vec3 wpos, vec3 wnorm) {`
			`float shadow = 1.0;`

			`#if (SHADOW_MODE == SHADOW_MODE_CHEAP \|\| (SHADOW_MODE == SHADOW_MODE_MAP && defined(EXPERIMENTAL_POINTSHADOWSWITHSHADOWMAPPING)))`
			`for (uint i = 0u; i < light_shadow_count.y; i ++) {`

			`// Only access the array once`
			`Shadow S = shadows[i];`

			`vec3 shadow_pos = S.shadow_pos_radius.xyz - focus_off.xyz;`
			`float radius = S.shadow_pos_radius.w;`

			`vec3 diff = shadow_pos - wpos;`
			`#if (SHADOW_MODE == SHADOW_MODE_CHEAP)`
			`if (diff.z >= 0.0) {`
			`diff.z = -sign(diff.z) * diff.z * 0.1;`
			`}`
			`#endif`

			`float shade = max(pow(diff.x * diff.x + diff.y * diff.y + diff.z * diff.z, 0.3) / pow(radius * radius * 0.5, 0.5), 0.5);`
			`// float shade = max(pow(dot(diff, diff) / (radius * radius * 0.5), 0.25), 0.5);`
			`// float shade = dot(diff, diff) / (radius * radius * 0.5);`

			`shadow = min(shadow, shade);`
			`}`
			`// NOTE: Squared to compenate for prior saturation.`
			`return min(shadow, 1.0);`
			`// return min(shadow * shadow, 1.0);`
			`#else`
			`return shadow;`
			`#endif`
			`}`

			`// Returns computed maximum intensity.`
			`//`
			`// mu is the attenuation coefficient for any substance on a horizontal plane.`
			`// cam_attenuation is the total light attenuation due to the substance for beams between the point and the camera.`
			`// surface_alt is the altitude of the attenuating surface.`
			`float lights_at(vec3 wpos, vec3 wnorm, vec3 /cam_to_frag/view_dir, vec3 mu, vec3 cam_attenuation, float surface_alt, vec3 k_a, vec3 k_d, vec3 k_s, float alpha, vec3 voxel_norm, float voxel_lighting, inout vec3 emitted_light, inout vec3 reflected_light/, out float shadow/) {`
			`// return 0.0;`
			`// shadow = 0.0;`
			`// vec3 ambient_light = vec3(0.0);`
			`vec3 directed_light = vec3(0.0);`
			`vec3 max_light = vec3(0.0);`

			`const float LIGHT_AMBIANCE = 0.0;//0.015625;`

			`for (uint i = 0u; i < /light_shadow_count.x//0u/light_shadow_count.x/32u/; i ++) {`

			`// Only access the array once`
			`Light L = lights[i];`

			`vec3 light_pos = L.light_pos.xyz - focus_off.xyz;`

			`// Pre-calculate difference between light and fragment`
			`vec3 difference = light_pos - wpos;`
			`float distance_2 = dot(difference, difference);`

			`if (distance_2 > 10000.0) {`
			`continue;`
			`}`

			`// float strength = attenuation_strength(difference);// pow(attenuation_strength(difference), 0.6);`
			`// NOTE: This normalizes strength to 0.25 at the center of the point source.`
			`float strength = 3.0 / (5 + distance_2);`

			`// Multiply the vec3 only once`
			`const float PI = 3.1415926535897932384626433832795;`
			`const float PI_2 = 2 * PI;`
			`vec3 color = /srgb_to_linear/L.light_col.rgb;`

			`// // Only access the array once`
			`// Shadow S = shadows[i];`

			`// vec3 shadow_pos = S.shadow_pos_radius.xyz;`
			`// float radius = S.shadow_pos_radius.w;`

			`// vec3 diff = shadow_pos - wpos;`
			`// if (diff.z >= 0.0) {`
			`// diff.z = -sign(diff.z) * diff.z * 0.1;`
			`// }`

			`// float shade = max(pow(diff.x * diff.x + diff.y * diff.y + diff.z * diff.z, 0.25) / pow(radius * radius * 0.5, 0.25), /0.5/0.0);`

			`// shadow = min(shadow, shade);`

			`// Compute reflectance.`
			`float light_distance = sqrt(distance_2);`
			`vec3 light_dir = -difference / light_distance; // normalize(-difference);`
			`// light_dir = faceforward(light_dir, wnorm, light_dir);`
			`bool is_direct = dot(difference, wnorm) > 0.0;`
			`// reflected_light += color * (distance_2 == 0.0 ? vec3(1.0) : light_reflection_factor(wnorm, cam_to_frag, light_dir, k_d, k_s, alpha));`
			`vec3 direct_light_dir = is_direct ? light_dir : -light_dir;`
			`// vec3 direct_norm_dir = is_direct ? wnorm : -wnorm;`
			`// Compute attenuation due to fluid.`
			`// Default is light_pos, so we take the whole segment length for this beam if it never intersects the surface, unlesss the beam itself`
			`// is above the surface, in which case we take zero (wpos).`
			`color = cam_attenuation compute_attenuation_point(wpos, -direct_light_dir, mu, surface_alt, light_pos.z < surface_alt ? light_pos : wpos);`

			`#if (LIGHTING_TYPE & LIGHTING_TYPE_TRANSMISSION) != 0`
			`is_direct = true;`
			`#endif`
			`vec3 lrf = light_reflection_factor(/direct_norm_dir/wnorm, /cam_to_frag/view_dir, direct_light_dir, k_d, k_s, alpha, voxel_norm, voxel_lighting);`
			`vec3 direct_light = PI * color * strength * lrf;`
			`/* is_direct = true; */`
			`float computed_shadow = ShadowCalculationPoint(i, -difference, wnorm, wpos/, light_distance/);`
			`// directed_light += is_direct ? max(computed_shadow, /LIGHT_AMBIANCE/0.0) * direct_light : vec3(0.0);`
			`float ambiance = 0.0;`
			`#ifndef EXPERIMENTAL_PHOTOREALISTIC`
			`// Non-physically emulate ambient light nearby`
			`ambiance = mix(0.05, 0.5, (dot(wnorm, direct_light_dir) + 1.0) * 0.5) * strength;`
			`#ifdef FIGURE_SHADER`
			`// Non-physical hack. Subtle, but allows lanterns to glow nicely`
			`// TODO: Make lanterns use glowing cells instead`
			`ambiance += 0.1 / distance_2;`
			`#endif`
			`#endif`
			`directed_light += (is_direct ? mix(LIGHT_AMBIANCE, 1.0, computed_shadow) * direct_light : vec3(0.0)) + ambiance * color;`
			`// directed_light += (is_direct ? 1.0 : LIGHT_AMBIANCE) * max(computed_shadow, /LIGHT_AMBIANCE/0.0) * direct_light;// : vec3(0.0);`
			`// directed_light += mix(LIGHT_AMBIANCE, 1.0, computed_shadow) * direct_light;`
			`// ambient_light += is_direct ? vec3(0.0) : vec3(0.0); // direct_light * LIGHT_AMBIANCE;`
			`// ambient_light += is_direct ? direct_light * (1.0 - LIGHT_AMBIANCE) : vec3(0.0);`

			`vec3 cam_light_diff = light_pos - focus_pos.xyz;`
			`float cam_distance_2 = dot(cam_light_diff, cam_light_diff);// + 0.0001;`
			`float cam_strength = 1.0 / (/4.0 //PI * //1.0 + */cam_distance_2);`

			`// vec3 cam_pos_diff = cam_to_frag.xyz - wpos;`
			`// float pos_distance_2 = dot(cam_pos_diff, cam_pos_diff);// + 0.0001;`

			`// float cam_distance = sqrt(cam_distance_2);`
			`// float distance = sqrt(distance_2);`
			`float both_strength = cam_distance_2 == 0.0 ? distance_2 == 0.0 ? 0.0 : strength/* * strength//1.0/ : distance_2 == 0.0 ? cam_strength/ * cam_strength//1.0*/ :`
			`// 1.0 / (cam_distance * distance);`
			`// sqrt(cam_strength * strength);`
			`cam_strength + strength;`
			`// (cam_strength * strength);`
			`// max(cam_strength, strength);`
			`// mix(cam_strength, strength, distance_2 / (cam_distance_2 + distance_2));`
			`// mix(cam_strength, strength, cam_distance_2 / (cam_distance_2 + distance_2));`
			`// max(cam_strength, strength);//mix(cam_strength, strength, clamp(distance_2 / /pos_distance_2/cam_distance_2, 0.0, 1.0));`
			`// float both_strength = mix(cam_strength, strength, cam_distance_2 / sqrt(cam_distance_2 + distance_2));`
			`max_light += /max(1.0, cam_strength)//min(cam_strength, 1.0)//max//max(both_strength, 1.0) //cam_strength/computed_shadow both_strength * PI * color;`
			`// max_light += /max(1.0, cam_strength)//min(cam_strength, 1.0)//max/max(cam_strength, 1.0/, strength//1.0/) * PI * color;`
			`// light += color * (max(0, max(dot(normalize(difference), wnorm), 0.15)) + LIGHT_AMBIANCE);`
			`// Compute emiittance.`
			`// float ambient_sides = clamp(mix(0.15, 0.0, abs(dot(wnorm, light_dir)) * 10000.0), 0.0, 0.15);`
			`// float ambient_sides = 0.0;// max(dot(wnorm, light_dir) - 0.15, 0.15);`
			`// // float ambient_sides = 0.0;`
			`// ambient_light += color * (ambient_sides + LIGHT_AMBIANCE);`
			`}`

			`// shadow = shadow_at(wpos, wnorm);`
			`// float shadow = shadow_at(wpos, wnorm);`
			`reflected_light += directed_light;`
			`// emitted_light += k_a * ambient_light/* * shadow*/;// min(shadow, 1.0);`
			`return /rel_luminance(ambient_light + directed_light)/rel_luminance(max_light);//ambient_light;`
			`}`

			`// Same as lights_at, but with no assumed attenuation due to fluid.`
			`float lights_at(vec3 wpos, vec3 wnorm, vec3 view_dir, vec3 k_a, vec3 k_d, vec3 k_s, float alpha, inout vec3 emitted_light, inout vec3 reflected_light) {`
			`return lights_at(wpos, wnorm, view_dir, vec3(0.0), vec3(1.0), 0.0, k_a, k_d, k_s, alpha, wnorm, 1.0, emitted_light, reflected_light);`
			`}`

			`#endif`