!!VP1.0 # Compute the surface space light vectors for diffuse bump mapping # c[0]..c[3] contains the concatenation of the modelview and projection matrices. # c[4]..c[7] contains the inverse transpose of the modelview # c[15] contains the eye position in object space # c[16] contains the light direction in object space # c[17] contains H, the normalized sum of the eye and light direction # c[20] contains the light color * object color # c[32] contains the ambient light color * object color # c[33] contains the haze color # c[40] contains (0, 1, 0.5, specPower) # v[6] contains the tangent vector # Transform the vertex by the modelview matrix DP4 o[HPOS].x, c[0], v[OPOS]; DP4 o[HPOS].y, c[1], v[OPOS]; DP4 o[HPOS].z, c[2], v[OPOS]; DP4 o[HPOS].w, c[3], v[OPOS]; MOV R1, v[NRML]; MOV R2, v[6]; # Compute the binormal--cross product of normal and tangent MUL R3, R1.zxyw, R2.yzxw; MAD R3, R1.yzxw, R2.zxyw, -R3; # Assume that the tangent and normal are orthonormal; otherwise # we need to normalize R3 #DP3 R0.w, R3, R3; #RSQ R0.w, R0.w; #MUL R3.xyz, R3, R0.w; # Transform the light direction from object space into surface space DP3 R0.x, R2, c[16]; DP3 R0.y, -R3, c[16]; DP3 R0.z, R1, c[16]; # Compress the light direction to fit in the primary color and output it MOV R5, c[40]; MAD o[COL0], R0, R5.z, R5.z; # Output the texture coordinates. Use different coordinates for # the decal (texture 0) and the bump map (texture 1) MOV o[TEX0], v[TEX0]; MOV o[TEX1], v[TEX1]; END