// -*-C++-*- #version 120 #define BLADE_FRACTION 0.1 #define MAX_LAYERS 30 #define MAX_DISTANCE 1000.0 uniform float visibility; uniform float scattering; uniform float overlay_bias; uniform float season; uniform float max_height; uniform float grass_density; uniform float grass_modulate_height_min; uniform float wind_x; uniform float wind_y; uniform float wash_x; uniform float wash_y; uniform float wash_strength; uniform int grass_modulate_by_overlay; uniform int grass_groups; uniform int wind_effects; uniform sampler2D colorTex; uniform sampler2D densityTex; uniform float osg_SimulationTime; varying in vec2 g_rawpos; // Horizontal position in model space varying in float g_distance_to_eye; // Distance to the camera. Layers were disregarded flat in float g_layer; // The layer where the fragment lives (0-1 range) float rand2D(in vec2 co); float Noise2D(in vec2 co, in float wavelength); vec3 filter_combined (in vec3 color) ; float map(float s, float a1, float a2, float b1, float b2) { return b1+(s-a1)*(b2-b1)/(a2-a1); } float decodeBinary(float n, float layer) { return float(mod(floor(n*pow(0.5, layer)), 2.0)); } float bladeNoise2D(in float x, in float y, in float dDensity, in float layer, in float d_factor, in float h_factor) { float integer_x = x - fract(x); float fractional_x = x - integer_x; float integer_y = y - fract(y); float fractional_y = y - integer_y; if (rand2D(vec2(integer_x+1.0, integer_y +1.0)) > dDensity) {return 0.0;} float hfact = 0.7 + 0.3 * (rand2D(vec2(integer_x, integer_y + 2.0))); hfact *= h_factor; if (layer > hfact) {return 0.0;} float xoffset = (rand2D(vec2(integer_x, integer_y)) -0.5); float yoffset = (rand2D(vec2(integer_x+1.0, integer_y)) - 0.5); float xbend = (rand2D(vec2(integer_x+1.0, integer_y + 1.0)) - 0.5); float ybend = (rand2D(vec2(integer_x, integer_y + 1.0)) - 0.5); float fraction = BLADE_FRACTION * (0.5 + 0.5 * (1.0 - smoothstep(0.5, 1.0, layer))); float bend = 0.5 * layer * layer; vec2 truePos = vec2 (0.5 + xoffset * (1.0 - 2.0 * BLADE_FRACTION) + xbend * bend, 0.5 + yoffset * (1.0 -2.0 * BLADE_FRACTION) + ybend * bend); float distance = length(truePos - vec2(fractional_x, fractional_y)); return 1.0 - step (fraction * d_factor, distance); } float BladeNoise2D(in vec2 coord, in float wavelength, in float dDensity, in float layer, in float d_factor, in float h_factor) { return bladeNoise2D(coord.x/wavelength, coord.y/wavelength, dDensity, layer, d_factor, h_factor); } void main() { if (season > 1.6) {discard;} if (g_distance_to_eye > MAX_DISTANCE) {discard;} vec2 texCoord = gl_TexCoord[0].st; if (wind_effects > 1) { vec2 eyePos = (gl_ModelViewMatrixInverse * vec4 (0.0, 0.0, 0.0, 1.0)).xy; vec2 washDir = vec2 (wash_x, wash_y) - (g_rawpos - eyePos); float washStrength = 20.0 * min(14.0 * wash_strength/(length(washDir) + 1.0), 1.0); washStrength *= (1.0 - 0.8 * sin(20.0 * osg_SimulationTime + length(washDir) + dot(normalize(washDir), vec2(1.0, 0.0)))); vec2 windDir = normalize(vec2 (max(wind_x, 0.1), wind_y) + washStrength * vec2 (-washDir.y, washDir.x)); float windStrength = 0.5 * length(vec2 (wind_x, wind_y)) + washStrength; float windAmplitude = 1.0 + 0.3 * windStrength; float sineTerm = sin(0.7 * windStrength * osg_SimulationTime + 0.05 * (g_rawpos.x + g_rawpos.y)); sineTerm = sineTerm + sin(0.6 * windStrength * osg_SimulationTime + 0.04 * (g_rawpos.x + g_rawpos.y)); sineTerm = sineTerm + sin(0.44 * windStrength * osg_SimulationTime + 0.05 * (g_rawpos.x + g_rawpos.y)); sineTerm = sineTerm/3.0; sineTerm = 5.0 * sineTerm * sineTerm; float windDisplacement = pow(g_layer/32.0, 2.0) * clamp((windStrength + windAmplitude * sineTerm), -35.0, 35.0); texCoord += (windDisplacement * windDir); } float noise_1m = Noise2D(g_rawpos.xy, 1.0); float noise_2m = Noise2D(g_rawpos.xy, 2.0); ; float noise_10m = Noise2D(g_rawpos.xy, 10.0); float h_factor; float overlay_mix = smoothstep(0.45, 0.65, overlay_bias + (0.5 * noise_1m + 0.1 * noise_2m + 0.4 * noise_10m)); if (grass_modulate_by_overlay == 1) {h_factor = grass_modulate_height_min + (1.0 - grass_modulate_height_min) * (1.0 - overlay_mix) ;} else {h_factor = 1.0;} float value = 0.0; float d_fade =smoothstep(100.0, MAX_DISTANCE, g_distance_to_eye); float d_factor = 1.0 + 1.0 * d_fade; d_factor *= clamp(max_height/0.3,0.5, 1.0); float bladeFlag = BladeNoise2D(texCoord, 0.015, grass_density, g_layer, d_factor, h_factor); if (grass_groups >1) {bladeFlag += BladeNoise2D(texCoord, 0.01, grass_density, g_layer, d_factor, h_factor);} if (grass_groups >2) {bladeFlag += BladeNoise2D(texCoord, 0.007, grass_density, g_layer, d_factor, h_factor);} if (bladeFlag > 0.0) {value = 1.0;} else {discard;} vec3 texel = texture2D(colorTex, texCoord).rgb; // autumn coloring texel.r = min(1.0, (1.0 + 2.5 * 0.1 * season) * texel.r); texel.g = texel.g; texel.b = max(0.0, (1.0 - 4.0 * 0.1 * season) * texel.b); float intensity = length(texel.rgb) * (1.0 - 0.5 * smoothstep(1.1,2.0,season)); texel.rgb = intensity * normalize(mix(texel.rgb, vec3(0.23,0.17,0.08), smoothstep(1.1,2.0, season))); float base_alpha = clamp(0.4 * max_height/0.3, 0.4, 1.0); value*= base_alpha * (1.0 - d_fade); value *= 1.0 - smoothstep(visibility* 0.5, visibility, g_distance_to_eye); value= clamp(value, 0.0, 1.0); texel *= length(gl_LightSource[0].diffuse.rgb)/1.73 * scattering; texel = clamp(texel, 0.0, 1.0); vec4 fragColor = vec4 (texel, value); fragColor.rgb = filter_combined(fragColor.rgb); gl_FragColor = fragColor; }