project_teddy/addons/zylann.hterrain/shaders/multisplat16_global.gdshader

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2023-04-11 13:31:11 -06:00
shader_type spatial;
// This shader uses a texture array with multiple splatmaps, allowing up to 16 textures.
// Only the 4 textures having highest blending weight are sampled.
// I had to remove source_color` from colormap in Godot 3 because it makes sRGB conversion kick in,
// which snowballs to black when doing GPU painting on that texture...
uniform sampler2D u_terrain_colormap;
uniform sampler2D u_terrain_splatmap;
uniform sampler2D u_terrain_splatmap_1;
uniform sampler2D u_terrain_splatmap_2;
uniform sampler2D u_terrain_splatmap_3;
uniform sampler2DArray u_ground_albedo_bump_array : source_color;
uniform float u_ground_uv_scale = 20.0;
uniform bool u_depth_blending = true;
// TODO Can't put this in a constant: https://github.com/godotengine/godot/issues/44145
//const int TEXTURE_COUNT = 16;
// Blends weights according to the bump of detail textures,
// so for example it allows to have sand fill the gaps between pebbles
vec4 get_depth_blended_weights(vec4 splat, vec4 bumps) {
float dh = 0.2;
vec4 h = bumps + splat;
// TODO Keep improving multilayer blending, there are still some edge cases...
// Mitigation: nullify layers with near-zero splat
h *= smoothstep(0, 0.05, splat);
vec4 d = h + dh;
d.r -= max(h.g, max(h.b, h.a));
d.g -= max(h.r, max(h.b, h.a));
d.b -= max(h.g, max(h.r, h.a));
d.a -= max(h.g, max(h.b, h.r));
return clamp(d, 0, 1);
}
void get_splat_weights(vec2 uv, out vec4 out_high_indices, out vec4 out_high_weights) {
vec4 ew0 = texture(u_terrain_splatmap, uv);
vec4 ew1 = texture(u_terrain_splatmap_1, uv);
vec4 ew2 = texture(u_terrain_splatmap_2, uv);
vec4 ew3 = texture(u_terrain_splatmap_3, uv);
float weights[16] = {
ew0.r, ew0.g, ew0.b, ew0.a,
ew1.r, ew1.g, ew1.b, ew1.a,
ew2.r, ew2.g, ew2.b, ew2.a,
ew3.r, ew3.g, ew3.b, ew3.a
};
// float weights_sum = 0.0;
// for (int i = 0; i < 16; ++i) {
// weights_sum += weights[i];
// }
// for (int i = 0; i < 16; ++i) {
// weights_sum /= weights_sum;
// }
// weights_sum=1.1;
// Now we have to pick the 4 highest weights and use them to blend textures.
// Using arrays because Godot's shader version doesn't support dynamic indexing of vectors
// TODO We should not need to initialize, but apparently we don't always find 4 weights
int high_indices_array[4] = {0, 0, 0, 0};
float high_weights_array[4] = {0.0, 0.0, 0.0, 0.0};
int count = 0;
// We know weights are supposed to be normalized.
// That means the highest value of the pivot above which we can find 4 results
// is 1.0 / 4.0. However that would mean exactly 4 textures have exactly that weight,
// which is very unlikely. If we consider 1.0 / 5.0, we are a bit more likely to find
// 4 results, and finding 5 results remains almost impossible.
float pivot = /*weights_sum*/1.0 / 5.0;
for (int i = 0; i < 16; ++i) {
if (weights[i] > pivot) {
high_weights_array[count] = weights[i];
high_indices_array[count] = i;
weights[i] = 0.0;
++count;
}
}
while (count < 4 && pivot > 0.0) {
float max_weight = 0.0;
int max_index = 0;
for (int i = 0; i < 16; ++i) {
if (/*weights[i] <= pivot && */weights[i] > max_weight) {
max_weight = weights[i];
max_index = i;
weights[i] = 0.0;
}
}
high_indices_array[count] = max_index;
high_weights_array[count] = max_weight;
++count;
pivot = max_weight;
}
out_high_weights = vec4(
high_weights_array[0], high_weights_array[1],
high_weights_array[2], high_weights_array[3]);
out_high_indices = vec4(
float(high_indices_array[0]), float(high_indices_array[1]),
float(high_indices_array[2]), float(high_indices_array[3]));
out_high_weights /=
out_high_weights.r + out_high_weights.g + out_high_weights.b + out_high_weights.a;
}
void vertex() {
vec4 wpos = MODEL_MATRIX * vec4(VERTEX, 1);
vec2 cell_coords = wpos.xz;
// Must add a half-offset so that we sample the center of pixels,
// otherwise bilinear filtering of the textures will give us mixed results (#183)
cell_coords += vec2(0.5);
// Normalized UV
UV = cell_coords / vec2(textureSize(u_terrain_splatmap, 0));
}
void fragment() {
// These were moved from vertex to fragment,
// so we can generate part of the global map with just one quad and we get full quality
vec3 tint = texture(u_terrain_colormap, UV).rgb;
vec4 splat = texture(u_terrain_splatmap, UV);
vec4 high_indices;
vec4 high_weights;
get_splat_weights(UV, high_indices, high_weights);
// Get bump at normal resolution so depth blending is accurate
vec2 ground_uv = UV / u_ground_uv_scale;
float b0 = texture(u_ground_albedo_bump_array, vec3(ground_uv, high_indices.x)).a;
float b1 = texture(u_ground_albedo_bump_array, vec3(ground_uv, high_indices.y)).a;
float b2 = texture(u_ground_albedo_bump_array, vec3(ground_uv, high_indices.z)).a;
float b3 = texture(u_ground_albedo_bump_array, vec3(ground_uv, high_indices.w)).a;
// Take the center of the highest mip as color, because we can't see details from far away.
vec2 ndc_center = vec2(0.5, 0.5);
vec3 a0 = textureLod(u_ground_albedo_bump_array, vec3(ndc_center, high_indices.x), 10.0).rgb;
vec3 a1 = textureLod(u_ground_albedo_bump_array, vec3(ndc_center, high_indices.y), 10.0).rgb;
vec3 a2 = textureLod(u_ground_albedo_bump_array, vec3(ndc_center, high_indices.z), 10.0).rgb;
vec3 a3 = textureLod(u_ground_albedo_bump_array, vec3(ndc_center, high_indices.w), 10.0).rgb;
vec3 col0 = a0 * tint;
vec3 col1 = a1 * tint;
vec3 col2 = a2 * tint;
vec3 col3 = a3 * tint;
vec4 w;
// TODO An #ifdef macro would be nice! Or copy/paste everything in a different shader...
if (u_depth_blending) {
w = get_depth_blended_weights(high_weights, vec4(b0, b1, b2, b3));
} else {
w = high_weights;
}
float w_sum = (w.r + w.g + w.b + w.a);
ALBEDO = (
w.r * col0.rgb +
w.g * col1.rgb +
w.b * col2.rgb +
w.a * col3.rgb) / w_sum;
}