#version 450 #extension GL_KHR_vulkan_glsl : enable //#include "ShaderDescriptorDefinitions.glsl" layout(location = 0) in vec3 aVertexPos; layout(location = 1) in vec2 aUV; layout(location = 2) in vec3 aNormal; layout(location = 3) in vec3 aTangent; layout(location = 4) in mat4 worldTransform; //layout(std140, push_constant) uniform TestPushConstant //{ // mat4 pvMat; // vec4 lightPosition; // vec4 eyePosition; // vec4 ambientColor; // vec4 lightColor; // //} testPushConstant; layout(location = 0) out struct { //mat3 BTN; vec4 vertColor; //vec3 localSpacePosition; //vec2 uv; //vec3 localLightPosition; //vec3 localEyePosition; } Out; layout(set = 2, binding = 0) uniform CameraData { vec4 position; mat4 vpMat; } cameraData; void main() { //const float gamma = testPushConstant.eyePosition.w; //mat4 W2L = inverse(worldTransform); //// Since attributes are instanced we want the local positions of light and eye (camera) //Out.localLightPosition = vec3(W2L * vec4(testPushConstant.lightPosition.xyz, 1.0f)); //Out.localEyePosition = vec3(W2L * vec4(testPushConstant.eyePosition.xyz, 1.0f)); //vec3 biTangent = normalize(cross(aNormal, aTangent)); //gl_Position = testPushConstant.pvMat * worldTransform * vec4(aVertexPos, 1.0); //// Since the normal we are sampling is in tangent space, we want to later convert them to local space //// so we need this matrix to multiply with the sampled texel of the normal map. //Out.BTN = mat3(aTangent, biTangent, aNormal); //Out.localSpacePosition = aVertexPos; //Out.uv = aUV; // render NDC first gl_Position = vec4(aVertexPos, 1.0); Out.vertColor = vec4 (aVertexPos, 1.0f); }