gzdoom-gles/wadsrc/static/shaders/glsl/main.vp

96 lines
3.2 KiB
Text
Raw Normal View History

layout(location = 0) in vec4 aPosition;
layout(location = 1) in vec2 aTexCoord;
layout(location = 2) in vec4 aColor;
#ifndef SIMPLE // we do not need these for simple shaders
layout(location = 3) in vec4 aVertex2;
layout(location = 4) in vec4 aNormal;
out vec4 pixelpos;
out vec3 glowdist;
out vec4 vWorldNormal;
out vec4 vEyeNormal;
#endif
out vec4 vTexCoord;
out vec4 vColor;
void main()
{
vec2 parmTexCoord;
vec4 parmPosition;
#ifndef USE_QUAD_DRAWER
parmTexCoord = aTexCoord;
parmPosition = aPosition;
#else
if (uQuadMode == 0)
{
parmTexCoord = aTexCoord;
parmPosition = aPosition;
}
else
{
parmPosition = uQuadVertices[int(aPosition.x)];
parmTexCoord = uQuadTexCoords[int(aPosition.x)].st;
}
#endif
#ifndef SIMPLE
vec4 worldcoord = ModelMatrix * mix(parmPosition, aVertex2, uInterpolationFactor);
#else
vec4 worldcoord = ModelMatrix * parmPosition;
#endif
vec4 eyeCoordPos = ViewMatrix * worldcoord;
vColor = aColor;
#ifndef SIMPLE
pixelpos.xyz = worldcoord.xyz;
pixelpos.w = -eyeCoordPos.z/eyeCoordPos.w;
float topatpoint = -((uGlowTopPlane.w + uGlowTopPlane.x * worldcoord.x + uGlowTopPlane.y * worldcoord.z) * uGlowTopPlane.z);
float bottomatpoint = -((uGlowBottomPlane.w + uGlowBottomPlane.x * worldcoord.x + uGlowBottomPlane.y * worldcoord.z) * uGlowBottomPlane.z);
glowdist.x = topatpoint - worldcoord.y;
glowdist.y = worldcoord.y - bottomatpoint;
glowdist.z = clamp(glowdist.x / (topatpoint - bottomatpoint), 0.0, 1.0);
if (uSplitBottomPlane.z != 0.0)
{
gl_ClipDistance[3] = -((uSplitTopPlane.w + uSplitTopPlane.x * worldcoord.x + uSplitTopPlane.y * worldcoord.z) * uSplitTopPlane.z) - worldcoord.y;
gl_ClipDistance[4] = worldcoord.y + ((uSplitBottomPlane.w + uSplitBottomPlane.x * worldcoord.x + uSplitBottomPlane.y * worldcoord.z) * uSplitBottomPlane.z);
}
2017-07-27 20:31:57 +00:00
vWorldNormal = NormalModelMatrix * vec4(normalize(aNormal.xyz), 1.0);
vEyeNormal = NormalViewMatrix * vWorldNormal;
#endif
#ifdef SPHEREMAP
vec3 u = normalize(eyeCoordPos.xyz);
vec4 n = normalize(TextureMatrix * vec4(parmTexCoord.x, 0.0, parmTexCoord.y, 0.0)); // use texture matrix and coordinates for our normal. Since this is only used on walls, the normal's y coordinate is always 0.
vec3 r = reflect(u, n.xyz);
float m = 2.0 * sqrt( r.x*r.x + r.y*r.y + (r.z+1.0)*(r.z+1.0) );
vec2 sst = vec2(r.x/m + 0.5, r.y/m + 0.5);
vTexCoord.xy = sst;
#else
vTexCoord = TextureMatrix * vec4(parmTexCoord, 0.0, 1.0);
#endif
gl_Position = ProjectionMatrix * eyeCoordPos;
if (uClipHeightDirection != 0.0) // clip planes used for reflective flats
{
2016-04-27 00:10:42 +00:00
gl_ClipDistance[0] = (worldcoord.y - uClipHeight) * uClipHeightDirection;
}
else if (uClipLine.x > -1000000.0) // and for line portals - this will never be active at the same time as the reflective planes clipping so it can use the same hardware clip plane.
{
gl_ClipDistance[0] = -( (worldcoord.z - uClipLine.y) * uClipLine.z + (uClipLine.x - worldcoord.x) * uClipLine.w ) + 1.0/32768.0; // allow a tiny bit of imprecisions for colinear linedefs.
}
2016-04-27 00:10:42 +00:00
// clip planes used for translucency splitting
gl_ClipDistance[1] = worldcoord.y - uClipSplit.x;
gl_ClipDistance[2] = uClipSplit.y - worldcoord.y;
}