/*
* Copyright 2017 Google Inc. All Rights Reserved.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
precision mediump float;
uniform sampler2D u_Texture;
uniform vec4 u_LightingParameters;
uniform vec4 u_MaterialParameters;
uniform vec4 u_ColorCorrectionParameters;
varying vec3 v_ViewPosition;
varying vec3 v_ViewNormal;
varying vec2 v_TexCoord;
uniform vec4 u_ObjColor;
void main() {
// We support approximate sRGB gamma.
const float kGamma = 0.4545454;
const float kInverseGamma = 2.2;
const float kMiddleGrayGamma = 0.466;
// Unpack lighting and material parameters for better naming.
vec3 viewLightDirection = u_LightingParameters.xyz;
vec3 colorShift = u_ColorCorrectionParameters.rgb;
float averagePixelIntensity = u_ColorCorrectionParameters.a;
float materialAmbient = u_MaterialParameters.x;
float materialDiffuse = u_MaterialParameters.y;
float materialSpecular = u_MaterialParameters.z;
float materialSpecularPower = u_MaterialParameters.w;
// Normalize varying parameters, because they are linearly interpolated in the vertex shader.
vec3 viewFragmentDirection = normalize(v_ViewPosition);
vec3 viewNormal = normalize(v_ViewNormal);
// Flip the y-texture coordinate to address the texture from top-left.
vec4 objectColor = texture2D(u_Texture, vec2(v_TexCoord.x, 1.0 - v_TexCoord.y));
// Apply color to grayscale image only if the alpha of u_ObjColor is
// greater and equal to 255.0.
if (u_ObjColor.a >= 255.0) {
float intensity = objectColor.r;
objectColor.rgb = u_ObjColor.rgb * intensity / 255.0;
}
// Apply inverse SRGB gamma to the texture before making lighting calculations.
objectColor.rgb = pow(objectColor.rgb, vec3(kInverseGamma));
// Ambient light is unaffected by the light intensity.
float ambient = materialAmbient;
// Approximate a hemisphere light (not a harsh directional light).
float diffuse = materialDiffuse *
0.5 * (dot(viewNormal, viewLightDirection) + 1.0);
// Compute specular light.
vec3 reflectedLightDirection = reflect(viewLightDirection, viewNormal);
float specularStrength = max(0.0, dot(viewFragmentDirection, reflectedLightDirection));
float specular = materialSpecular *
pow(specularStrength, materialSpecularPower);
vec3 color = objectColor.rgb * (ambient + diffuse) + specular;
// Apply SRGB gamma before writing the fragment color.
color.rgb = pow(color, vec3(kGamma));
// Apply average pixel intensity and color shift
color *= colorShift * (averagePixelIntensity / kMiddleGrayGamma);
gl_FragColor.rgb = color;
gl_FragColor.a = objectColor.a;
}
