#version 110 uniform sampler2D environmentIrradianceMapId[6]; uniform sampler2D environmentSpecularMapId[6]; uniform sampler2D textureId; uniform int textureEnabled; uniform sampler2D normalMapId; uniform int normalMapEnabled; uniform sampler2D metalnessRoughnessAoMapId; uniform int metalnessMapEnabled; uniform int roughnessMapEnabled; uniform int aoMapEnabled; uniform vec3 eyePosition; varying vec3 pointPosition; varying vec3 pointNormal; varying vec3 pointColor; varying vec2 pointTexCoord; varying float pointAlpha; varying float pointMetalness; varying float pointRoughness; varying mat3 pointTBN; const float PI = 3.1415926; vec3 fresnelSchlickRoughness(float NoV, vec3 f0, float roughness) { return f0 + (max(vec3(1.0 - roughness), f0) - f0) * pow(clamp(1.0 - NoV, 0.0, 1.0), 5.0); } void cubemap(vec3 r, out float texId, out vec2 st) { vec3 uvw; vec3 absr = abs(r); if (absr.x > absr.y && absr.x > absr.z) { // x major float negx = step(r.x, 0.0); uvw = vec3(r.zy, absr.x) * vec3(mix(-1.0, 1.0, negx), -1, 1); texId = negx; } else if (absr.y > absr.z) { // y major float negy = step(r.y, 0.0); uvw = vec3(r.xz, absr.y) * vec3(1.0, mix(1.0, -1.0, negy), 1.0); texId = 2.0 + negy; } else { // z major float negz = step(r.z, 0.0); uvw = vec3(r.xy, absr.z) * vec3(mix(1.0, -1.0, negz), -1, 1); texId = 4.0 + negz; } st = vec2(uvw.xy / uvw.z + 1.) * .5; } vec4 texturesAsCube(in sampler2D maps[6], in vec3 direction) { float texId; vec2 st; cubemap(direction, texId, st); vec4 color = vec4(0); { vec4 side = texture2D(maps[0], st); float select = step(0.0 - 0.5, texId) * step(texId, 0.0 + 0.5); color = mix(color, side, select); } { vec4 side = texture2D(maps[1], st); float select = step(1.0 - 0.5, texId) * step(texId, 1.0 + 0.5); color = mix(color, side, select); } { vec4 side = texture2D(maps[2], st); float select = step(2.0 - 0.5, texId) * step(texId, 2.0 + 0.5); color = mix(color, side, select); } { vec4 side = texture2D(maps[3], st); float select = step(3.0 - 0.5, texId) * step(texId, 3.0 + 0.5); color = mix(color, side, select); } { vec4 side = texture2D(maps[4], st); float select = step(4.0 - 0.5, texId) * step(texId, 4.0 + 0.5); color = mix(color, side, select); } { vec4 side = texture2D(maps[5], st); float select = step(5.0 - 0.5, texId) * step(texId, 5.0 + 0.5); color = mix(color, side, select); } return color; } void main() { vec3 color = pointColor; float alpha = pointAlpha; if (1 == textureEnabled) { vec4 textColor = texture2D(textureId, pointTexCoord); color = textColor.rgb; alpha = textColor.a; } vec3 normal = pointNormal; if (1 == normalMapEnabled) { normal = texture2D(normalMapId, pointTexCoord).rgb; normal = pointTBN * normalize(normal * 2.0 - 1.0); } float metalness = pointMetalness; if (1 == metalnessMapEnabled) { metalness = texture2D(metalnessRoughnessAoMapId, pointTexCoord).b; } float roughness = pointRoughness; if (1 == roughnessMapEnabled) { roughness = texture2D(metalnessRoughnessAoMapId, pointTexCoord).g; } float ambientOcclusion = 1.0; if (1 == aoMapEnabled) { ambientOcclusion = texture2D(metalnessRoughnessAoMapId, pointTexCoord).r; } vec3 n = normal; vec3 v = normalize(eyePosition - pointPosition); vec3 r = reflect(-v, n); float NoV = abs(dot(n, v)) + 1e-5; vec3 irradiance = texturesAsCube(environmentIrradianceMapId, r).rgb; vec3 diffuse = irradiance * (1.0 - metalness) * color; vec3 f0 = mix(vec3(0.04), color, metalness); vec3 fresnelFactor = fresnelSchlickRoughness(NoV, f0, roughness); vec3 specular = fresnelFactor * texturesAsCube(environmentSpecularMapId, r).rgb; color = (diffuse + specular) * ambientOcclusion; color = color / (color + vec3(1.0)); color = pow(color, vec3(1.0/2.2)); gl_FragColor = vec4(color, alpha); }