CGII/framework/shader/cgv_gl/glsl/sphere.glvs

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2018-05-17 14:01:02 +00:00
uniform int nr_lights;
varying vec3 q_tilde;
varying vec3 inv_T_square_v;
varying vec3 inv_T_square_e_c;
varying vec4 ev_clip;
varying vec3 v;
//varying vec3 h[4];
//varying vec3 l[4];
varying vec4 a;
//varying vec4 d;
varying vec4 s;
void main()
{
// decompress the matrix T
float R = gl_Vertex.w;
float inv_R = 1.0/R;
// determine eye point in parameter space
vec3 e = gl_ModelViewMatrixInverse[3].xyz;
vec3 e_tilde = inv_R*(e - gl_Vertex.xyz);
// compute helper
float inv_e_square = 1.0/dot(e_tilde,e_tilde);
// determine silhoutte center in parameter space
vec3 m_tilde = inv_e_square*e_tilde;
// determine radius of silhouette in parameter space
float r = sqrt(1.0-inv_e_square);
// compute vector x of length r orthogonal to e in parameter space
vec3 x_tilde = r*normalize(cross(gl_ModelViewMatrixInverse[1].xyz,e_tilde));
// compute vector y of length r orthogonal to x and e in parameter space
vec3 y_tilde = r*normalize(cross(e_tilde,x_tilde));
// compute the corner point in homogeneous object coordinates
vec3 V_tilde = m_tilde+gl_MultiTexCoord2.x*x_tilde+gl_MultiTexCoord2.y*y_tilde;
vec3 v_tilde = V_tilde - e_tilde;
vec4 V;
V.xyz = R*V_tilde+gl_Vertex.xyz;
V.w = 1.0;
q_tilde.xy = gl_MultiTexCoord2.xy;
q_tilde.z = sqrt(inv_e_square);
// compute vector from eye to vertex in eye space
v = (gl_ModelViewMatrix*V).xyz;
// compute components to compute normal in eye space
inv_T_square_e_c = gl_NormalMatrix*(e_tilde);
inv_T_square_v = gl_NormalMatrix*(v_tilde);
v = -normalize(v);
gl_Position = gl_ModelViewProjectionMatrix * V;
ev_clip.xy = (gl_ModelViewProjectionMatrix * gl_ModelViewMatrixInverse[3]).zw;
ev_clip.zw = gl_Position.zw - ev_clip.xy;
a = vec4(0.0,0.0,0.0,0.0);
vec4 lpos;
for (int i=0; i<nr_lights; ++i) {
a += gl_LightSource[i].ambient*gl_Color;
}
gl_FrontColor = gl_Color;
//d = gl_Color;
s = gl_FrontMaterial.specular;
}