#version 150 core uniform sampler2D uColor; uniform sampler2D uNormal; uniform sampler2D uDepth; uniform sampler2D uAmbientOcclusion; #define USE_SAMPLER2D_SHADOW 1 #ifdef USE_SAMPLER2D_SHADOW uniform sampler2DShadow uShadowMap; #else uniform sampler2D uShadowMap; #endif uniform sampler2D uPosition; uniform vec3 uLightDirection; uniform mat4 uLightSpaceMatrix; uniform mat4 uViewToLightSpaceMatrix; in vec2 ioFragTexCoords; out vec3 outColor; float ShadowCalculationPCF(vec4 frag_pos_light_space, vec3 frag_normal_light_space) { vec3 projected_coordinates = frag_pos_light_space.xyz / frag_pos_light_space.w; projected_coordinates = projected_coordinates * 0.5 + 0.5; float current_depth = projected_coordinates.z; float bias = 0.00; bias = max(0.02 * (1.0 - dot(frag_normal_light_space, uLightDirection)), 0.003); float shadow = 0.0; vec2 texel_size = 1.0 / textureSize(uShadowMap, 0); for (int x = -1; x <= 1; ++x) { for (int y = -1; y <= 1; ++y) { #ifdef USE_SAMPLER2D_SHADOW vec2 coordinate = projected_coordinates.xy + vec2(x, y) * texel_size; float pcf_depth = texture(uShadowMap, vec3(coordinate, current_depth - bias)); #else float pcf_depth = texture(uShadowMap, projected_coordinates.xy).r; #endif shadow += current_depth - bias > pcf_depth ? 1.0 : 0.0; } } shadow /= 9.0; return shadow; } float ShadowCalculation(vec4 frag_pos_light_space, vec3 frag_normal_light_space) { vec3 projected_coordinates = frag_pos_light_space.xyz / frag_pos_light_space.w; projected_coordinates = projected_coordinates * 0.5 + 0.5; float current_depth = projected_coordinates.z; float bias = 0.01; #ifdef USE_SAMPLER2D_SHADOW float closest_depth = texture(uShadowMap, vec3(projected_coordinates.xy, current_depth - bias)); #else float closest_depth = texture(uShadowMap, projected_coordinates.xy).r; bias = max(0.005 * (1.0 - dot(frag_normal_light_space, uLightDirection)), 0.003); #endif return current_depth - bias > closest_depth ? 1.0 : 0.0; } void main() { vec3 color = texture(uColor, ioFragTexCoords).rgb; vec3 normal = texture (uNormal, ioFragTexCoords).xyz; float depth = texture (uDepth, ioFragTexCoords).r; vec3 position = texture (uPosition, ioFragTexCoords).xyz; float ambient_occlusion = texture(uAmbientOcclusion, ioFragTexCoords).r; // ambient lighting float ambient_strength = 0.2; vec3 ambient = ambient_strength * color; vec3 light_dir = uLightDirection; // diffuse lighting float diff = max(dot(normal, light_dir), 0.0); vec3 diffuse = diff * color; // specular lighting vec3 view_dir = normalize(-position); vec3 halfway_dir = normalize(light_dir + view_dir); float spec = pow(max(dot(normal, halfway_dir), 0.0), 32); vec3 specular = spec * vec3(0.5); // shadow (need to transform position and normal to light space) vec4 position_light_space = uViewToLightSpaceMatrix * vec4(position, 1.0); vec3 normal_light_space = (transpose(inverse(uViewToLightSpaceMatrix)) * vec4(normal, 1.0)).xyz; float shadow = ShadowCalculationPCF(position_light_space, normal); outColor = (ambient * ambient_occlusion + (1.0 - shadow) * (diffuse + specular)) * ambient_occlusion; // outColor = (ambient + (diffuse + specular)) * ambient_occlusion; }