group_bot/assets/voxygen/shaders/particle-vert.glsl
2024-06-13 19:16:24 -04:00

1099 lines
46 KiB
GLSL

#version 440 core
#include <constants.glsl>
#define LIGHTING_TYPE LIGHTING_TYPE_REFLECTION
#define LIGHTING_REFLECTION_KIND LIGHTING_REFLECTION_KIND_GLOSSY
#define LIGHTING_TRANSPORT_MODE LIGHTING_TRANSPORT_MODE_IMPORTANCE
#define LIGHTING_DISTRIBUTION_SCHEME LIGHTING_DISTRIBUTION_SCHEME_MICROFACET
#define LIGHTING_DISTRIBUTION LIGHTING_DISTRIBUTION_BECKMANN
#include <globals.glsl>
#include <srgb.glsl>
#include <random.glsl>
#include <lod.glsl>
layout(location = 0) in vec3 v_pos;
// in uint v_col;
layout(location = 1) in uint v_norm_ao;
layout(location = 2) in float inst_time;
layout(location = 3) in float inst_lifespan;
layout(location = 4) in float inst_entropy;
layout(location = 5) in int inst_mode;
layout(location = 6) in vec3 inst_dir;
layout(location = 7) in vec3 inst_pos;
layout(location = 0) out vec3 f_pos;
layout(location = 1) flat out vec3 f_norm;
layout(location = 2) out vec4 f_col;
//layout(location = x) out float f_ao;
//layout(location = x) out float f_light;
layout(location = 3) out float f_reflect;
const float SCALE = 1.0 / 11.0;
// Modes
const int SMOKE = 0;
const int FIRE = 1;
const int GUN_POWDER_SPARK = 2;
const int SHRAPNEL = 3;
const int FIREWORK_BLUE = 4;
const int FIREWORK_GREEN = 5;
const int FIREWORK_PURPLE = 6;
const int FIREWORK_RED = 7;
const int FIREWORK_WHITE = 8;
const int FIREWORK_YELLOW = 9;
const int LEAF = 10;
const int FIREFLY = 11;
const int BEE = 12;
const int GROUND_SHOCKWAVE = 13;
const int ENERGY_HEALING = 14;
const int ENERGY_NATURE = 15;
const int FLAMETHROWER = 16;
const int FIRE_SHOCKWAVE = 17;
const int FIRE_BOWL = 18;
const int SNOW = 19;
const int EXPLOSION = 20;
const int ICE = 21;
const int LIFESTEAL_BEAM = 22;
const int CULTIST_FLAME = 23;
const int STATIC_SMOKE = 24;
const int BLOOD = 25;
const int ENRAGED = 26;
const int BIG_SHRAPNEL = 27;
const int LASER = 28;
const int BUBBLES = 29;
const int WATER = 30;
const int ICE_SPIKES = 31;
const int DRIP = 32;
const int TORNADO = 33;
const int DEATH = 34;
const int ENERGY_BUFFING = 35;
const int WEB_STRAND = 36;
const int BLACK_SMOKE = 37;
const int LIGHTNING = 38;
const int STEAM = 39;
const int BARRELORGAN = 40;
const int POTION_SICKNESS = 41;
const int GIGA_SNOW = 42;
const int CYCLOPS_CHARGE = 43;
const int PORTAL_FIZZ = 45;
const int INK = 46;
const int WHIRLWIND = 47;
const int FIERY_BURST = 48;
const int FIERY_BURST_VORTEX = 49;
const int FIERY_BURST_SPARKS = 50;
const int FIERY_BURST_ASH = 51;
const int FIERY_TORNADO = 52;
const int PHOENIX_CLOUD = 53;
const int FIERY_DROPLET_TRACE = 54;
const int ENERGY_PHOENIX = 55;
const int PHOENIX_BEAM = 56;
const int PHOENIX_BUILD_UP_AIM = 57;
const int CLAY_SHRAPNEL = 58;
const int AIRFLOW = 59;
const int SPORE = 60;
const int SURPRISE_EGG = 61;
const int FLAME_TORNADO = 62;
// meters per second squared (acceleration)
const float earth_gravity = 9.807;
struct Attr {
vec3 offs;
vec3 scale;
vec4 col;
mat4 rot;
};
float lifetime = time_since(inst_time);
// Retrieves inst_time, repeating over a period. This will be consistent
// over a time overflow.
float loop_inst_time(float period, float scale) {
if (tick.x < inst_time) {
return mod(mod(tick_overflow * scale, period) + inst_time * scale, period);
} else {
return mod(inst_time * scale, period);
}
}
vec3 linear_motion(vec3 init_offs, vec3 vel) {
return init_offs + vel * lifetime;
}
vec3 quadratic_bezier_motion(vec3 start, vec3 ctrl0, vec3 end) {
float t = lifetime;
float u = 1 - lifetime;
return u*u*start + t*u*ctrl0 + t*t*end;
}
vec3 grav_vel(float grav) {
return vec3(0, 0, -grav * lifetime);
}
float exp_scale(float factor) {
return 1 / (1 - lifetime * factor);
}
float linear_scale(float factor) {
return lifetime * factor;
}
float percent() {
return lifetime / inst_lifespan;
}
float slow_end(float factor) {
return (1 + factor) * percent() / (percent() + factor);
}
float slow_start(float factor) {
return 1-(1 + factor) * (1-percent()) / ((1-percent()) + factor);
}
float start_end(float from, float to) {
return mix(from, to, lifetime / inst_lifespan);
}
mat4 spin_in_axis(vec3 axis, float angle)
{
axis = normalize(axis);
float s = sin(angle);
float c = cos(angle);
float oc = 1.0 - c;
return mat4(
oc * axis.x * axis.x + c,
oc * axis.x * axis.y - axis.z * s,
oc * axis.z * axis.x + axis.y * s,
0,
oc * axis.x * axis.y + axis.z * s,
oc * axis.y * axis.y + c,
oc * axis.y * axis.z - axis.x * s,
0,
oc * axis.z * axis.x - axis.y * s,
oc * axis.y * axis.z + axis.x * s,
oc * axis.z * axis.z + c,
0,
0, 0, 0, 1
);
}
mat4 identity() {
return mat4(
1, 0, 0, 0,
0, 1, 0, 0,
0, 0, 1, 0,
0, 0, 0, 1
);
}
vec3 perp_axis1(vec3 axis) {
return normalize(vec3(axis.y + axis.z, -axis.x + axis.z, -axis.x - axis.y));
}
vec3 perp_axis2(vec3 axis1, vec3 axis2) {
return normalize(vec3(axis1.y * axis2.z - axis1.z * axis2.y, axis1.z * axis2.x - axis1.x * axis2.z, axis1.x * axis2.y - axis1.y * axis2.x));
}
// Line is the axis of the spiral, it goes from the start position to the end position
// Radius is the distance from the axis the particle is
// Time function is some value that ideally goes from 0 to 1. When it is 0, it is as
// the point (0, 0, 0), when it is 1, it is at the point provided by the coordinates of line
// Frequency increases the frequency of rotation
// Offset is an offset to the angle of the rotation
vec3 spiral_motion(vec3 line, float radius, float time_function, float frequency, float offset) {
vec3 axis2 = perp_axis1(line);
vec3 axis3 = perp_axis2(line, axis2);
return line * time_function + vec3(
radius * cos(frequency * time_function - offset) * axis2.x + radius * sin(frequency * time_function - offset) * axis3.x,
radius * cos(frequency * time_function - offset) * axis2.y + radius * sin(frequency * time_function - offset) * axis3.y,
radius * cos(frequency * time_function - offset) * axis2.z + radius * sin(frequency * time_function - offset) * axis3.z);
}
void main() {
float rand0 = hash(vec4(inst_entropy + 0));
float rand1 = hash(vec4(inst_entropy + 1));
float rand2 = hash(vec4(inst_entropy + 2));
float rand3 = hash(vec4(inst_entropy + 3));
float rand4 = hash(vec4(inst_entropy + 4));
float rand5 = hash(vec4(inst_entropy + 5));
float rand6 = hash(vec4(inst_entropy + 6));
float rand7 = hash(vec4(inst_entropy + 7));
float rand8 = hash(vec4(inst_entropy + 8));
float rand9 = hash(vec4(inst_entropy + 9));
vec3 start_pos = inst_pos - focus_off.xyz;
Attr attr;
f_reflect = 1.0;
switch(inst_mode) {
case SMOKE:
attr = Attr(
linear_motion(
vec3(0),
vec3(rand2 * 0.02, rand3 * 0.02, 1.0 + rand4 * 0.1)
),
vec3(linear_scale(0.5)),
vec4(vec3(0.8, 0.8, 1) * 0.125 * (3.8 + rand0), start_end(1.0, 0.0)),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 0.5)
);
break;
case BLACK_SMOKE:
attr = Attr(
linear_motion(
vec3(0),
vec3(rand2 * 0.02, rand3 * 0.02, 1.0 + rand4 * 0.1)
),
vec3(linear_scale(0.5)),
vec4(vec3(0.8, 0.8, 1) * 0.125 * (1.8 + rand0), start_end(1.0, 0.0)),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 0.5)
);
break;
case FIRE:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0.0),
vec3(rand2 * 0.1, rand3 * 0.1, 2.0 + rand4 * 1.0)
),
vec3(1.0),
vec4(6, 3 + rand5 * 0.3 - 0.8 * percent(), 0.4, 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3)
);
break;
case FIRE_BOWL:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(normalize(vec2(rand0, rand1)) * 0.1, 0.6),
vec3(rand2 * 0.2, rand3 * 0.5, 0.8 + rand4 * 0.5)
),
vec3(0.2), // Size
vec4(2, 1.5 + rand5 * 0.5, 0, start_end(1.0, 0.0)), // Colour
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3)
);
break;
case GUN_POWDER_SPARK:
attr = Attr(
linear_motion(
normalize(vec3(rand0, rand1, rand3)) * 0.3,
normalize(vec3(rand4, rand5, rand6)) * 4.0 + grav_vel(earth_gravity)
),
vec3(1.0),
vec4(3.5, 3 + rand7, 0, 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case SHRAPNEL:
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand4, rand5, rand6)) * 20.0 + grav_vel(earth_gravity)
),
vec3(1),
vec4(vec3(0.25), 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case BIG_SHRAPNEL:
float brown_color = 0.05 + 0.1 * rand1;
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand4, rand5, rand6)) * 15.0 + grav_vel(earth_gravity)
),
vec3(5 * (1 - percent())),
vec4(vec3(brown_color, brown_color / 2, 0), 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case FIREWORK_BLUE:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand1, rand2, rand3)) * 40.0 + grav_vel(earth_gravity)
),
vec3(3.0 + rand0),
vec4(vec3(0, 0, 2), 1),
identity()
);
break;
case FIREWORK_GREEN:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand1, rand2, rand3)) * 40.0 + grav_vel(earth_gravity)
),
vec3(3.0 + rand0),
vec4(vec3(0, 2, 0), 1),
identity()
);
break;
case FIREWORK_PURPLE:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand1, rand2, rand3)) * 40.0 + grav_vel(earth_gravity)
),
vec3(3.0 + rand0),
vec4(vec3(2, 0, 2), 1),
identity()
);
break;
case FIREWORK_RED:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand1, rand2, rand3)) * 40.0 + grav_vel(earth_gravity)
),
vec3(3.0 + rand0),
vec4(vec3(2, 0, 0), 1),
identity()
);
break;
case FIREWORK_WHITE:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand1, rand2, rand3)) * 40.0 + grav_vel(earth_gravity)
),
vec3(3.0 + rand0),
vec4(vec3(2, 2, 2), 1),
identity()
);
break;
case FIREWORK_YELLOW:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand1, rand2, rand3)) * 40.0 + grav_vel(earth_gravity)
),
vec3(3.0 + rand0),
vec4(vec3(2, 2, 0), 1),
identity()
);
break;
case LEAF:
attr = Attr(
linear_motion(
vec3(0),
vec3(0, 0, -2)
) + vec3(sin(lifetime), sin(lifetime + 0.7), sin(lifetime * 0.5)) * 2.0,
vec3(4),
vec4(vec3(0.2 + rand7 * 0.2, 0.2 + (0.25 + rand6 * 0.5) * 0.3, 0) * (0.75 + rand1 * 0.5), 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 5)
);
break;
case SNOW:
float height = mix(-4, 60, pow(start_end(1, 0), 3));
float wind_speed = (inst_pos.z - 2000) * 0.025;
vec3 offset = linear_motion(vec3(0), vec3(1, 1, 0) * wind_speed);
float end_alt = alt_at(start_pos.xy + offset.xy);
attr = Attr(
offset + vec3(0, 0, end_alt - start_pos.z + height) + vec3(sin(lifetime), sin(lifetime + 0.7), sin(lifetime * 0.5)) * 3,
vec3(mix(4, 0, pow(start_end(1, 0), 4))),
vec4(1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 5)
);
break;
case FIREFLY:
float raise = pow(sin(3.1416 * lifetime / inst_lifespan), 0.2);
attr = Attr(
vec3(0, 0, raise * 5.0) + vec3(
sin(lifetime * 1.0 + rand0) + sin(lifetime * 7.0 + rand3) * 0.3,
sin(lifetime * 3.0 + rand1) + sin(lifetime * 8.0 + rand4) * 0.3,
sin(lifetime * 2.0 + rand2) + sin(lifetime * 9.0 + rand5) * 0.3
),
vec3(raise),
vec4(vec3(10.3, 9, 1.5), 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 5)
);
break;
case BEE:
float lower = pow(sin(3.1416 * lifetime / inst_lifespan), 0.2);
attr = Attr(
vec3(0, 0, lower * -0.5) + vec3(
sin(lifetime * 2.0 + rand0) + sin(lifetime * 9.0 + rand3) * 0.3,
sin(lifetime * 3.0 + rand1) + sin(lifetime * 10.0 + rand4) * 0.3,
sin(lifetime * 4.0 + rand2) + sin(lifetime * 11.0 + rand5) * 0.3
) * 0.5,
vec3(lower),
vec4(vec3(1, 0.7, 0), 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 5)
);
break;
case GROUND_SHOCKWAVE:
attr = Attr(
vec3(0.0),
vec3(11.0, 11.0, (33.0 * rand0 * sin(2.0 * lifetime * 3.14 * 2.0))) / 3,
vec4(vec3(0.32 + (rand0 * 0.04), 0.22 + (rand1 * 0.03), 0.05 + (rand2 * 0.01)), 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case ENERGY_HEALING:
f_reflect = 0.0;
float spiral_radius = start_end(1 - pow(abs(rand5), 5), 1) * length(inst_dir);
attr = Attr(
spiral_motion(vec3(0, 0, rand3 + 1), spiral_radius, lifetime, abs(rand0), rand1 * 2 * PI) + vec3(0, 0, rand2),
vec3(6 * abs(rand4) * (1 - slow_start(2)) * pow(spiral_radius / length(inst_dir), 0.5)),
vec4(vec3(0, 1.7, 0.7) * 3, 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3)
);
break;
case LIFESTEAL_BEAM:
f_reflect = 0.0;
float green_col = 0.8 + 0.8 * sin(tick_loop(2 * PI, 5, lifetime * 5));
float purple_col = 0.6 + 0.5 * sin(loop_inst_time(2 * PI, 4)) - min(max(green_col - 1, 0), 0.3);
float red_col = 1.15 + 0.1 * sin(loop_inst_time(2 * PI, 3)) - min(max(green_col - 1, 0), 0.3) - max(purple_col - 0.5, 0);
attr = Attr(
spiral_motion(inst_dir, 0.3 * (floor(2 * rand0 + 0.5) - 0.5) * min(linear_scale(10), 1), lifetime / inst_lifespan, 10.0, loop_inst_time(2.0 * PI, 1.0)),
vec3((1.7 - 0.7 * abs(floor(2 * rand0 - 0.5) + 0.5)) * (1.5 + 0.5 * sin(tick_loop(2 * PI, 10, -lifetime * 4)))),
vec4(vec3(red_col + purple_col * 0.6, green_col + purple_col * 0.35, purple_col), 1),
spin_in_axis(inst_dir, tick_loop(2 * PI))
);
break;
case ENERGY_NATURE:
f_reflect = 0.0;
spiral_radius = start_end(1 - pow(abs(rand5), 5), 1) * length(inst_dir);
attr = Attr(
spiral_motion(vec3(0, 0, rand3 + 1), spiral_radius, lifetime, abs(rand0), rand1 * 2 * PI) + vec3(0, 0, rand2),
vec3(6 * abs(rand4) * (1 - slow_start(2)) * pow(spiral_radius / length(inst_dir), 0.5)),
vec4(vec3(0, 1.7, 1.3), 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3)
);
break;
case FLAMETHROWER:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3((2.5 * (1 - slow_start(0.2)))),
vec4(6, 3 + rand5 * 0.6 - 0.8 * percent(), 0.4, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case EXPLOSION:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
inst_dir * ((rand0+1.0)/2 + 0.4) * slow_end(0.25) + 0.3 * grav_vel(earth_gravity),
vec3((3 * (1 - slow_start(0.1)))),
vec4(6, 3 + rand5 * 0.3 - 0.8 * percent(), 0.4, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case ICE:
f_reflect = 0.0; // Ice doesn't reflect to look like magic
float ice_color = 1.9 + rand5 * 0.3;
attr = Attr(
inst_dir * ((rand0+1.0)/2 + 0.4) * slow_end(2.0) + 0.3 * grav_vel(earth_gravity),
vec3((5 * (1 - slow_start(.1)))),
vec4(0.8 * ice_color, 0.9 * ice_color, ice_color, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case FIRE_SHOCKWAVE:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
attr = Attr(
vec3(rand0, rand1, lifetime * 10 + rand2),
vec3((5 * (1 - slow_start(0.5)))),
vec4(6, 3 + rand5 * 0.6 - 0.8 * percent(), 0.4, 1),
spin_in_axis(vec3(rand3, rand4, rand5), rand6)
);
break;
case CULTIST_FLAME:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
float purp_color = 0.9 + 0.3 * rand3;
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3((3.5 * (1 - slow_start(0.2)))),
vec4(purp_color, 0.0, purp_color, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case STATIC_SMOKE:
attr = Attr(
vec3(0),
vec3((0.5 * (1 - slow_start(0.8)))),
vec4(1.0),
spin_in_axis(vec3(rand6, rand7, rand8), rand9)
);
break;
case BLOOD:
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand4, rand5, rand6)) * 5.0 + grav_vel(earth_gravity)
),
vec3((2.0 * (1 - slow_start(0.8)))),
vec4(1, 0, 0, 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case ENRAGED:
f_reflect = 0.0;
float red_color = 1.2 + 0.3 * rand3;
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3((3.5 * (1 - slow_start(0.2)))),
vec4(red_color, 0.0, 0.0, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case LASER:
f_reflect = 0.0;
vec3 perp_axis = normalize(cross(inst_dir, vec3(0.0, 0.0, 1.0)));
offset = vec3(0.0);
if (rand0 > 0.0) {
offset = perp_axis * 0.5;
} else {
offset = perp_axis * -0.5;
}
attr = Attr(
inst_dir * percent() + offset,
vec3(1.0, 1.0, 50.0),
vec4(vec3(2.0, 0.0, 0.0), 1),
spin_in_axis(perp_axis, asin(inst_dir.z / length(inst_dir)) + PI / 2.0)
);
break;
case BUBBLES:
f_reflect = 0.0; // Magic water doesn't reflect light, it emits it
float blue_color = 1.5 + 0.2 * rand3 + 1.5 * max(floor(rand4 + 0.3), 0.0);
float size = 8.0 * (1 - slow_start(0.1)) * slow_end(0.15);
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3(size),
vec4(0.5 * blue_color, 0.75 * blue_color, blue_color, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case WATER:
f_reflect = 0.0; // Magic water doesn't reflect light, it emits it
blue_color = 1.25 + 0.2 * rand3 + 1.75 * max(floor(rand4 + 0.15), 0.0);
size = 8.0 * (1 - slow_start(0.1)) * slow_end(0.15);
attr = Attr(
(inst_dir * slow_end(0.2)) + vec3(rand0, rand1, rand2) * 0.5,
vec3(size),
vec4(0.5 * blue_color, 0.9 * blue_color, blue_color, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 5 + 3 * rand9)
);
break;
case ICE_SPIKES:
f_reflect = 0.0; // Ice doesn't reflect to look like magic
ice_color = 1.7 + rand5 * 0.2;
attr = Attr(
vec3(0.0),
vec3(11.0, 11.0, 11.0 * length(inst_dir) * 2.0 * (0.5 - abs(0.5 - slow_end(0.5)))) / 3,
vec4(0.8 * ice_color, 0.9 * ice_color, ice_color, 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case DRIP:
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand4, rand5, rand6)) + grav_vel(earth_gravity)
),
vec3((2.0 * (1 - slow_start(0.2)))),
vec4(1, 1, 0, 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case TORNADO:
f_reflect = 0.0;
attr = Attr(
spiral_motion(vec3(0, 0, 5), abs(rand0) + abs(rand1) * percent() * 3.0, percent(), 15.0 * abs(rand2), rand3),
vec3((2.5 * (1 - slow_start(0.05)))),
vec4(vec3(1.2 + 0.5 * percent()), 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case DEATH:
f_reflect = 0.0;
attr = Attr(
linear_motion(
vec3(0),
vec3(rand2 * 0.02, rand3 * 0.02, 2.0 + rand4 * 0.6)
),
vec3((1.2 * (1 - slow_start(.1)))),
vec4(vec3(1.2 + 0.5 * percent()), 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case ENERGY_BUFFING:
f_reflect = 0.0;
spiral_radius = start_end(1 - pow(abs(rand5), 5), 1) * length(inst_dir);
attr = Attr(
spiral_motion(vec3(0, 0, rand3 + 1), spiral_radius, lifetime, abs(rand0), rand1 * 2 * PI) + vec3(0, 0, rand2),
vec3(6 * abs(rand4) * (1 - slow_start(2)) * pow(spiral_radius / length(inst_dir), 0.5)),
vec4(vec3(1.4), 1),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3)
);
break;
case WEB_STRAND:
f_reflect = 0.0;
perp_axis = normalize(cross(inst_dir, vec3(0.0, 0.0, 1.0)));
attr = Attr(
inst_dir * percent(),
vec3(1.0, 1.0, 50.0),
vec4(vec3(2.0), 1),
spin_in_axis(perp_axis, asin(inst_dir.z / length(inst_dir)) + PI / 2.0)
);
break;
case LIGHTNING:
f_reflect = 0.0;
perp_axis = normalize(cross(inst_dir, vec3(0.0, 0.0, 1.0)));
float z = inst_dir.z * (percent() - 1.0);
vec3 start_off = vec3(abs(fract(vec3(vec2(z) * vec2(0.015, 0.01), 0)) - 0.5) * z * 0.4);
attr = Attr(
inst_dir * percent() + start_off,
vec3(max(3.0, 0.05 * length(start_pos + inst_dir * percent()))),
vec4(10.0, 20.0, 50.0, 1.0),// * (1.0 - length(inst_dir) * 0.1),
identity()//spin_in_axis(perp_axis, asin(inst_dir.z / length(inst_dir)) + PI / 2.0)
);
break;
case STEAM:
f_reflect = 0.0; // Magic steam doesn't reflect light, it emits it
float steam_size = 8.0 * (1 - slow_start(0.1)) * slow_end(0.15);
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3(steam_size),
vec4(vec3(0.7, 2.7, 1.3), 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case BARRELORGAN:
attr = Attr(
linear_motion(
vec3(rand0 * 0.25, rand1 * 0.25, 1.7 + rand5),
vec3(rand2 * 0.1, rand3 * 0.1, 1.0 + rand4 * 0.5)
),
vec3(exp_scale(-0.2)) * rand0,
vec4(vec3(0.7, 2.7, 1.3), 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case POTION_SICKNESS:
attr = Attr(
quadratic_bezier_motion(
vec3(0.0),
vec3(inst_dir.xy, 0.0),
inst_dir
),
vec3((2.0 * (1 - slow_start(0.8)))),
vec4(0.075, 0.625, 0, 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case GIGA_SNOW:
f_reflect = 0.0;
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3((3.5 * (1 - slow_start(0.2)))),
vec4(vec3(2, 2, 2), 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case CYCLOPS_CHARGE:
f_reflect = 0.0;
float burn_size = 8.0 * (1 - slow_start(0.1)) * slow_end(0.15);
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3(burn_size),
vec4(vec3(6.9, 0.0, 0.0), 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case PORTAL_FIZZ:
attr = Attr(
inst_dir * (0.7 + pow(percent(), 5)) + vec3(
sin(lifetime * 1.25 + rand0 * 10) + sin(lifetime * 1.3 + rand3 * 10),
sin(lifetime * 1.2 + rand1 * 10) + sin(lifetime * 1.4 + rand4 * 10),
sin(lifetime * 5 + rand2)
) * 0.03,
vec3(pow(1.0 - abs(percent() - 0.5) * 2.0, 0.2)),
mix(
vec4(mix(vec3(0.4, 0.8, 0.2), vec3(5, 10, 2), pow(percent(), 2)), 1),
vec4(mix(vec3(0.6, 0.2, 0.8), vec3(9, 2, 10), pow(percent(), 2)), 1),
clamp((dot(normalize(focus_pos.xyz - start_pos), inst_dir) - 0.25) * 3.0, 0.0, 1.0)
),
/* vec4(vec3(1.8 - percent() * 2, 0.4 + percent() * 2, 5.0 + rand6), 1), */
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3 + lifetime * 5)
);
break;
case INK:
f_reflect = 0.0; // Magic water doesn't reflect light, it emits it
float black_color = 0.3 + 0.2 * rand3 + 0.3 * max(floor(rand4 + 0.3), 0.0);
float ink_size = 8.0 * (1 - slow_start(0.1)) * slow_end(0.15);
attr = Attr(
(inst_dir * slow_end(1.5)) + vec3(rand0, rand1, rand2) * (percent() + 2) * 0.1,
vec3(ink_size),
vec4(0.5 * black_color, 0.75 * black_color, black_color, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case WHIRLWIND:
f_reflect = 0.0;
attr = Attr(
spiral_motion(vec3(0, 0, 3), abs(rand0) * 3 + percent() * 20.5, percent(), -8.0 + (rand0 * 3), rand1 * 360.),
vec3((-2.5 * (1 - slow_start(0.05)))),
vec4(vec3(1.3, 1.8, 2), 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case FIERY_BURST:
f_reflect = 0.0;
float fiery_radius = start_end(1.0 - pow(abs(rand5), 5.0), 1.0) * length(inst_dir);
float fiery_color1 = (7.0 + 1.0 * percent()) * min(1.0, percent() * 4.0) * 1.5;
float fiery_color2 = (4.0 - 2.0 * percent() + 1.3 * rand5 * slow_end(0.0)) * min(1.0, percent() * 4.0) * 1.3;
float fiery_color3 = 1.0 + 0.3 * percent();
attr = Attr(
spiral_motion(
vec3(
0.0,
0.0,
(rand3 + 1.0)
* max(
((percent() * 8.0) * (1.0 - step(0.2, percent()))),
((2.0 * (1.0 - percent())) * (step(0.2, percent())))
)
),
fiery_radius,
lifetime,
max(0.1, step(0.6, percent())) * 3.0 * abs(rand0),
rand1 * 2.0 * PI) + vec3(0.0, 0.0, rand2),
vec3(6.0 * abs(rand4) * (1.0 - slow_start(2.0)) * pow(fiery_radius / length(inst_dir), 0.5)),
vec4(fiery_color1, fiery_color2, fiery_color3, slow_end(0.4)),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3.0)
);
break;
case FIERY_BURST_VORTEX:
f_reflect = 0.0;
float fiery_vortex_color1 = (min(1, percent() * 2) * (5 + 1 * percent() + 1 * slow_end(0)) * 1.5);
float fiery_vortex_color2 = (min(1, percent() * 2) * (4 - 2.4 * percent() + 1.3 * rand5 * slow_end(0)) * 1.3);
float fiery_vortex_color3 = 0;
attr = Attr(
spiral_motion(
vec3(
0,
0,
(0 + 0.5 * rand4 ) + 4.0
* max(
((percent() * 8) * (1 - step(0.2, percent()))), // first 20% of lifetime particle moves up, then goes down
((2 * (1 - percent())) * (step(0.2, percent())))// to avoid tearing multi should have same proportion as edge(here: 8 before, 2 after)
)
),
abs(rand0) + 0.5 * 10 * percent(),
percent(),
10.0 * abs(rand2),
rand3),
vec3((2.5 * (1 - slow_start(0.05)))),
vec4(fiery_vortex_color1, fiery_vortex_color2, fiery_vortex_color3, start_end(0.5, 1.5) * abs(rand2)),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case FIERY_BURST_SPARKS:
f_reflect = 0.0;
// sparks should flicker, so it stops glowing for 18% of time 4 times per second, same thing used in 4th float of RGBA vector
float fiery_sparks_color1 = 2 + 1 * rand2 + 2 * step(0.18, fract(tick.x*4));
float fiery_sparks_color2 = 4 + 1 * rand2 + 4 * step(0.18, fract(tick.x*4));
float fiery_sparks_color3 = 4 + 6 * step(0.18, fract(tick.x*4));
attr = Attr(
spiral_motion(vec3(0, 0, 5), abs(rand0) + abs(rand1) * percent() * 4.0, percent(), 8.0 * abs(rand2), rand3),
vec3((2.5 * (1 - slow_start(0.05)))),
vec4(fiery_sparks_color1, fiery_sparks_color2, fiery_sparks_color3, 0.5 + 0.5 * step(0.18, fract(tick.x*4))),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case FIERY_BURST_ASH:
f_reflect = 0.0;
/// inst_dir holds info about:
/// .x: radius of random spawn
float fiery_ash_rand_rad = inst_dir.x;
/// .y:
/// in fract: relative time of "setting on fire"
/// in int: radius of curve
float fiery_ash_radius = floor(inst_dir.y);
float fiery_ash_edge = inst_dir.y - fiery_ash_radius;
/// .z: height of the flight
float fiery_ash_height = inst_dir.z;
// {FOR PHOENIX "from the ashes"}sets ash on fire at 0.4 of lifetime, then makes it lose glow, representing losing heat
float fiery_ash_color1 = (2 + 1 * percent() * slow_end(0))
* (max(
1,
8 * step(fiery_ash_edge, percent()) * (1.4 - percent()))
);
float fiery_ash_color2 = (2 - 1 * percent() + 0.3 * abs(rand5) * slow_end(0.5))
* (max(
1,
6.5 * step(fiery_ash_edge, percent()) * (1.4 - percent()))
);
float fiery_ash_color3 = 1.5;
attr = Attr(
spiral_motion(
vec3(
0.0,
0.0,
fiery_ash_height// {FOR PHOENIX "from the ashes"} 8.58
),
abs(rand0 / 2.0 + 1.0)
* max(1.0, ((percent() * fiery_ash_radius * 0.8) * (1.0 - step(0.2, percent())))) // part of lifetime particle moves to periphery
* max(1.0, (fiery_ash_radius * 0.2 * (1.0 - percent()) * (step(0.2, percent())))),// then back to center
percent(),
6.0 * abs(rand2),
rand3 * 5.0
)
+ vec3((rand6 + rand5) * fiery_ash_rand_rad, (rand8 + rand3) * fiery_ash_rand_rad, abs(rand0)),//makes it apear randomly above base animation (Fiery Burst)
vec3((2.5 * (1 - slow_start(0.0)))),
vec4(fiery_ash_color1, fiery_ash_color2, fiery_ash_color3, abs(rand2) * slow_end(0.3)),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case FIERY_TORNADO:
f_reflect = 0.0;
float fiery_tornado_color1 = (2.6 + 0.5 * percent())
* 4.0 * max(0.5, percent() * 1.2);
float fiery_tornado_color2 = (1.7 - 0.6 * pow(1.0 - percent(), 2.0) + 0.3 * abs(rand5))
* 2.0 * max(0.45, percent() * 1.2);
float fiery_tornado_color3 = 1.5 * max(0.6, percent());
attr = Attr(
spiral_motion(vec3(0, 0, 6.0 + rand3 * 1.5), abs(rand0) + abs(rand1) * percent() * 3.0, percent(), 15.0 * abs(rand2), -inst_time),
vec3((2.5 * (1 - slow_start(0.05)))),
vec4(fiery_tornado_color1, fiery_tornado_color2, fiery_tornado_color3, 0.5),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case PHOENIX_CLOUD:
float PC_spin = floor(inst_dir.x);
float refl = floor(inst_dir.y);
float PC_size = floor(inst_dir.z);
//best is 0.4 - reflects some light but only part as
f_reflect = refl * 0.1;
// modifies by + 5% to -15%, if color is less than 0.5 it will get from +10% to +25% to it's value
float PC_rand_color_factor = rand0 * 0.05;
float PC_R = inst_dir.x - PC_spin;
PC_R += PC_R * PC_rand_color_factor * step(0.05, PC_R) * -abs(PC_rand_color_factor * 2.0)
+ PC_R * (1.0 - step(0.05, PC_R)) * max(abs(PC_rand_color_factor), 0.02) * 5.0;
float PC_G = inst_dir.y - refl;
PC_G += PC_G * PC_rand_color_factor * step(0.05, PC_G) * -abs(PC_rand_color_factor * 2.0)
+ PC_G * (1.0 - step(0.05, PC_G)) * max(abs(PC_rand_color_factor), 0.02) * 5.0;
float PC_B = inst_dir.z - PC_size;
PC_B += PC_B * PC_rand_color_factor * step(0.05, PC_B) * -abs(PC_rand_color_factor * 2.0)
+ PC_B * (1.0 - step(0.05, PC_B)) * max(abs(PC_rand_color_factor), 0.02) * 5.0;
attr = Attr(
linear_motion(
vec3(0.0, 0.0, 0.0),
vec3(rand4, rand5, rand6 * 2.5)
),
vec3(8.0 * min(percent() * 3.0, 1.0) * min((1.0 - percent()) * 2.0, 1.0)),
vec4(
PC_R,
PC_G,
PC_B,
PC_size * 1.2) * 10.0,
spin_in_axis(vec3(rand6 + rand5, rand7 + rand9, rand8 + rand2), percent() * PC_spin)
);
break;
case FIERY_DROPLET_TRACE:
float m_r = 4.0;
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
float prcnt = percent(); //idk if compiler would optimize it or not but as we have a lot of those particles... i'll just try
float droplet_color1 = 1 * (5 + 1 * prcnt + 1 * slow_end(0)) * 1.5;
float droplet_color2 = 1 * (4 - 2.4 * prcnt + 1.3 * rand5 * slow_end(0)) * 1.3;
float droplet_color3 = 0;
attr = Attr(
quadratic_bezier_motion(
vec3(0.0),
vec3(m_r * rand0, m_r * rand1, 0.0),
vec3(m_r * rand0, m_r * rand1, 4.0)
),
vec3(1),
vec4(droplet_color1,
droplet_color2,
droplet_color3,
1 * prcnt * (1 - step(0.5, prcnt)) + (1 - prcnt) * (step(0.5, prcnt))),
spin_in_axis(vec3(1,0,0),0)
);
break;
case ENERGY_PHOENIX:
f_reflect = 0.0;
float fiery_r = (2 + 1 * percent() * slow_end(0))
* 6 * (1.4 - percent());
float fiery_g = (2 - 1 * percent() + 0.3 * abs(rand5) * slow_end(0.5))
* 4.5 * (1.4 - percent());
float fiery_b = 1.5;
spiral_radius = length(inst_dir);
attr = Attr(
spiral_motion(vec3(0.0, 0.0, 0.01), spiral_radius + abs(rand1), lifetime / 0.5, abs(rand0), rand1 * 2.0 * PI) + vec3(0.0, 0.0, rand2),
vec3(6.0 * abs(rand4) * (1 - slow_start(2.0))),
vec4(vec3(fiery_r, fiery_g, fiery_b), 1.0),
spin_in_axis(vec3(rand6, rand7, rand8), rand9 * 3.0)
);
break;
case PHOENIX_BEAM:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
float beam_r = 6.0 - (4.0 * percent()) + 15.0 * fract(percent() * 4 + rand0 * rand0) * (1 - percent());
float beam_g = 2.0 + 6.6 * fract(percent() * 4 + rand0 * rand0) * (1 - percent());
float beam_b = 1.4;
vec3 factor_rand = vec3((rand0 * 0.2) * (rand5 * 0.1) + rand6 * 0.9, (rand1 * 0.2) * (rand4 * 0.1) + rand7 * 0.9, (rand2 * 0.2) * (rand3 * 0.1) + rand8 * 0.9);
start_pos += factor_rand + normalize(inst_dir) * 0.6;
attr = Attr(
spiral_motion(inst_dir - factor_rand * 0.4, 0.3 * ((rand2 + 0.5) * 5.5) * (1.0 - min(linear_scale(1.5), 1.0)), lifetime / inst_lifespan, 24.0, -inst_time * 8.0),
vec3((2.5 * (1 - slow_start(0.2)))),
vec4(beam_r, beam_g, beam_b, 1.0),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10.0 + 3.0 * rand9)
);
break;
case PHOENIX_BUILD_UP_AIM:
f_reflect = 0.0; // Fire doesn't reflect light, it emits it
float perc_t = percent(); // in case compiler wont optimize, idk
float aim_r = rand0 * 0.25 + 3.0 + 4.5 * perc_t * (1 - step(0.79, perc_t)) + 8.0 * step(0.81, perc_t) * perc_t;
float aim_g = rand0 * 0.25 + 2.0 - 1.0 * perc_t * (1 - step(0.79, perc_t)) + 2.0 * step(0.81, perc_t) * perc_t;
float aim_b = 1.4 * ((1 - perc_t) + step(0.74, perc_t));
vec3 dir_aim = inst_dir * 1.0;
vec3 rand_pos_aim = (cross(
(1.0 - 2.0 * step(0.0, rand2)) * normalize(inst_dir),
vec3(0.0, 0.0, 1.0)));
vec3 rand_fact = vec3(rand1 * 1, rand0 * 1, rand2 * 1);
start_pos += vec3(0.0, 0.0, 5.0) + rand_fact;
attr = Attr(
spiral_motion(
inst_dir + vec3(0.0, 0.0, -(6.0 - 3.0 * pow(perc_t, 2.5))) - rand_fact,
1.2 * rand9 * max(1.0 - perc_t, 0.0),
perc_t,
6.0,
inst_time * 8.0),
vec3((1.9 * (1 - slow_start(0.2)))),
vec4(aim_r, aim_g, aim_b, 1.0),
spin_in_axis(vec3(rand6, rand7, rand8), perc_t * 10.0 + 3.0 * rand9)
);
break;
case CLAY_SHRAPNEL:
float clay_color = 0.025 + 0.02 * rand1;
attr = Attr(
linear_motion(
vec3(0),
normalize(vec3(rand4, rand5, rand6)) * 15.0 + grav_vel(earth_gravity)
),
vec3(5 * (1 - percent())),
vec4(vec3(clay_color * 3, clay_color * 2, clay_color), 1),
spin_in_axis(vec3(1,0,0),0)
);
break;
case AIRFLOW:
perp_axis = normalize(cross(inst_dir, vec3(1.0, 0.0, 0.0)));
attr = Attr(
// offsets
inst_dir * 0.2 * length(inst_dir) * percent() + inst_dir * percent() * 0.08,
// scale
vec3(
0.3 * length(inst_dir),
0.3 * length(inst_dir),
3.0 * length(inst_dir) * percent() * (1 - percent())
),
// color
vec4(1.1, 1.1, 1.1, 0.3),
// rotation
spin_in_axis(perp_axis, asin(inst_dir.z / length(inst_dir)) + PI / 2.0)
);
break;
case SPORE:
f_reflect = 0.0;
attr = Attr(
linear_motion(
vec3(0),
vec3(0, 0, -1.1)
) + vec3(sin((lifetime + rand9 * 0.1) * 0.5) * 3.0, sin((lifetime+ rand8 * 0.1) * 0.5) * 3.0, sin(lifetime * 0.5) * 1.5),
vec3(0.4 + 0.4 * abs(sin(lifetime))),
vec4(vec3(0.8, 6.0 + rand6 * 1.75, 7.5 + (1.75 + rand5 * 0.5)), 1),
spin_in_axis(vec3(rand1, rand2, rand3), rand4 * 1.5 + lifetime)
);
break;
case SURPRISE_EGG:
f_reflect = 0.0;
// sparks should flicker, so it stops glowing for 18% of time 4 times per second, same thing used in 4th float of RGBA vector
float egg_color1 = 2 + 1 * rand2 + 2 * step(0.18, fract(tick.x*4));
float egg_color2 = 0 + 1 * rand2 + 4 * step(0.18, fract(tick.x*4));
float egg_color3 = 2 + 6 * step(0.18, fract(tick.x*4));
attr = Attr(
spiral_motion(vec3(0, 0, 5), abs(rand0) + abs(rand1) * percent() * 4.0, percent(), 8.0 * abs(rand2), rand3),
vec3((2.5 * (1 - slow_start(0.05)))),
vec4(egg_color1, egg_color2, egg_color3, 0.5 + 0.5 * step(0.18, fract(tick.x*4))),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
case FLAME_TORNADO:
f_reflect = 0.0;
attr = Attr(
spiral_motion(vec3(0, 0, 3), abs(rand0) * 3 + percent() * 70.0, percent(), -8.0 + (rand0 * 3), rand1 * 360.),
vec3((-2.5 * (1 - slow_start(0.05)))),
vec4(6, 3 + rand5 * 0.3 - 0.8 * percent(), 0.4, 1),
spin_in_axis(vec3(rand6, rand7, rand8), percent() * 10 + 3 * rand9)
);
break;
default:
attr = Attr(
linear_motion(
vec3(rand0 * 0.25, rand1 * 0.25, 1.7 + rand5),
vec3(rand2 * 0.1, rand3 * 0.1, 1.0 + rand4 * 0.5)
),
vec3(exp_scale(-0.2)) * rand0,
vec4(1),
spin_in_axis(vec3(1,0,0),0)
);
break;
}
// Temporary: use shrinking particles as a substitute for fading ones
attr.scale *= pow(attr.col.a, 0.25);
f_pos = start_pos + (v_pos * attr.scale * SCALE * mat3(attr.rot) + attr.offs);
#ifdef EXPERIMENTAL_CURVEDWORLD
f_pos.z -= pow(distance(f_pos.xy + focus_off.xy, focus_pos.xy + focus_off.xy) * 0.05, 2);
#endif
// First 3 normals are negative, next 3 are positive
// TODO: Make particle normals match orientation
vec4 normals[6] = vec4[](
vec4(-1,0,0,0),
vec4(1,0,0,0),
vec4(0,-1,0,0),
vec4(0,1,0,0),
vec4(0,0,-1,0),
vec4(0,0,1,0)
);
f_norm =
// inst_pos *
normalize(((normals[(v_norm_ao >> 0) & 0x7u]) * attr.rot).xyz);
//vec3 col = vec3((uvec3(v_col) >> uvec3(0, 8, 16)) & uvec3(0xFFu)) / 255.0;
f_col = vec4(attr.col.rgb, attr.col.a);
gl_Position =
all_mat *
vec4(f_pos, 1);
}