mirror of
https://github.com/nzp-team/fteqw.git
synced 2024-11-29 15:12:19 +00:00
6cc5e1762b
git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@5927 fc73d0e0-1445-4013-8a0c-d673dee63da5
418 lines
12 KiB
GLSL
418 lines
12 KiB
GLSL
!!ver 100 150
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!!permu TESS
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!!permu FULLBRIGHT
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!!permu UPPERLOWER
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!!permu FRAMEBLEND
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!!permu SKELETAL
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!!permu FOG
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!!permu BUMP
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!!permu REFLECTCUBEMASK
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!!cvarf r_glsl_offsetmapping_scale
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!!cvarf gl_specular
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!!cvardf gl_affinemodels=0
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!!cvardf r_tessellation_level=5
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!!samps !EIGHTBIT diffuse normalmap specular fullbright upper lower reflectmask reflectcube
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!!samps =EIGHTBIT paletted 1
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!!samps =OCCLUDE occlusion
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//!!permu VC // adds rgba vertex colour multipliers
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//!!permu SPECULAR // auto-added when gl_specular>0
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//!!permu OFFSETMAPPING // auto-added when r_glsl_offsetmapping is set
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//!!permu NONORMALS // states that there's no normals available, which affects lighting.
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//!!permu ORM // specularmap is r:Occlusion, g:Roughness, b:Metalness
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//!!permu SG // specularmap is rgb:F0, a:Roughness (instead of exponent)
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//!!permu PBR // an attempt at pbr logic (enabled from ORM or SG)
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//!!permu NOOCCLUDE // ignores the use of ORM's occlusion... yeah, stupid.
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//!!permu OCCLUDE // use an explicit occlusion texturemap (separate from roughness+metalness).
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//!!permu EIGHTBIT // uses software-style paletted colourmap lookups
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//!!permu ALPHATEST // if defined, this is the required alpha level (more versatile than doing it at the q3shader level)
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#include "sys/defs.h"
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//standard shader used for models.
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//must support skeletal and 2-way vertex blending or Bad Things Will Happen.
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//the vertex shader is responsible for calculating lighting values.
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#if gl_affinemodels==1 && __VERSION__ >= 130 && !defined(GL_ES)
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#define affine noperspective
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#else
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#define affine
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#endif
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#if defined(ORM) || defined(SG)
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#define PBR
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#endif
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#ifdef NONORMALS //lots of things need normals to work properly. make sure nothing breaks simply because they added an extra texture.
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#undef BUMP
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#undef SPECULAR
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#undef OFFSETMAPPING
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#undef REFLECTCUBEMASK
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#endif
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#ifdef VERTEX_SHADER
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#include "sys/skeletal.h"
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affine varying vec2 tc;
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varying vec4 light;
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#if defined(SPECULAR) || defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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varying vec3 eyevector;
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#endif
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#if defined(PBR)||defined(REFLECTCUBEMASK)
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varying mat3 invsurface;
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#endif
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#ifdef TESS
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varying vec3 vertex;
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varying vec3 normal;
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#endif
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void main ()
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{
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light.rgba = vec4(e_light_ambient, 1.0);
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#ifdef NONORMALS
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vec3 n, w;
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gl_Position = skeletaltransform_w(w);
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n = vec3(0.0);
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#else
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vec3 n, s, t, w;
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gl_Position = skeletaltransform_wnst(w,n,s,t);
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n = normalize(n);
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s = normalize(s);
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t = normalize(t);
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#ifndef PBR
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float d = dot(n,e_light_dir);
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if (d < 0.0) //vertex shader. this might get ugly, but I don't really want to make it per vertex.
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d = 0.0; //this avoids the dark side going below the ambient level.
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light.rgb += (d*e_light_mul);
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#else
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light.rgb = vec3(1.0);
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#endif
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#endif
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#if defined(SPECULAR)||defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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vec3 eyeminusvertex = e_eyepos - w.xyz;
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eyevector.x = dot(eyeminusvertex, s.xyz);
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eyevector.y = dot(eyeminusvertex, t.xyz);
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eyevector.z = dot(eyeminusvertex, n.xyz);
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#endif
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#if defined(PBR) || defined(REFLECTCUBEMASK)
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invsurface = mat3(s, t, n);
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#endif
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tc = v_texcoord;
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#ifdef VC
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light *= v_colour;
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#endif
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//FIXME: Software rendering imitation should possibly push out normals by half a pixel or something to approximate software's over-estimation of distant model sizes (small models are drawn using JUST their verticies using the nearest pixel, which results in larger meshes)
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#ifdef TESS
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normal = n;
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vertex = w;
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#endif
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}
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#endif
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#if defined(TESS_CONTROL_SHADER)
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layout(vertices = 3) out;
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in vec3 vertex[];
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out vec3 t_vertex[];
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in vec3 normal[];
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out vec3 t_normal[];
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affine in vec2 tc[];
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affine out vec2 t_tc[];
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in vec4 light[];
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out vec4 t_light[];
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#if defined(SPECULAR) || defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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in vec3 eyevector[];
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out vec3 t_eyevector[];
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#endif
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#ifdef REFLECTCUBEMASK
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in mat3 invsurface[];
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out mat3 t_invsurface[];
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#endif
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void main()
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{
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//the control shader needs to pass stuff through
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#define id gl_InvocationID
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t_vertex[id] = vertex[id];
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t_normal[id] = normal[id];
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t_tc[id] = tc[id];
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t_light[id] = light[id];
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#if defined(SPECULAR) || defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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t_eyevector[id] = eyevector[id];
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#endif
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#ifdef REFLECTCUBEMASK
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t_invsurface[id][0] = invsurface[id][0];
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t_invsurface[id][1] = invsurface[id][1];
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t_invsurface[id][2] = invsurface[id][2];
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#endif
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gl_TessLevelOuter[0] = float(r_tessellation_level);
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gl_TessLevelOuter[1] = float(r_tessellation_level);
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gl_TessLevelOuter[2] = float(r_tessellation_level);
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gl_TessLevelInner[0] = float(r_tessellation_level);
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}
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#endif
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#if defined(TESS_EVALUATION_SHADER)
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layout(triangles) in;
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in vec3 t_vertex[];
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in vec3 t_normal[];
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affine in vec2 t_tc[];
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affine out vec2 tc;
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in vec4 t_light[];
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out vec4 light;
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#if defined(SPECULAR) || defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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in vec3 t_eyevector[];
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out vec3 eyevector;
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#endif
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#ifdef REFLECTCUBEMASK
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in mat3 t_invsurface[];
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out mat3 invsurface;
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#endif
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#define LERP(a) (gl_TessCoord.x*a[0] + gl_TessCoord.y*a[1] + gl_TessCoord.z*a[2])
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void main()
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{
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#define factor 1.0
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tc = LERP(t_tc);
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vec3 w = LERP(t_vertex);
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vec3 t0 = w - dot(w-t_vertex[0],t_normal[0])*t_normal[0];
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vec3 t1 = w - dot(w-t_vertex[1],t_normal[1])*t_normal[1];
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vec3 t2 = w - dot(w-t_vertex[2],t_normal[2])*t_normal[2];
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w = w*(1.0-factor) + factor*(gl_TessCoord.x*t0+gl_TessCoord.y*t1+gl_TessCoord.z*t2);
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//FIXME: we should be recalcing these here, instead of just lerping them
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light = LERP(t_light);
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#if defined(SPECULAR) || defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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eyevector = LERP(t_eyevector);
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#endif
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#ifdef REFLECTCUBEMASK
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invsurface[0] = LERP(t_invsurface[0]);
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invsurface[1] = LERP(t_invsurface[1]);
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invsurface[2] = LERP(t_invsurface[2]);
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#endif
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gl_Position = m_modelviewprojection * vec4(w,1.0);
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}
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#endif
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#ifdef FRAGMENT_SHADER
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#include "sys/fog.h"
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#if defined(SPECULAR)
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uniform float cvar_gl_specular;
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#endif
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#ifdef OFFSETMAPPING
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#include "sys/offsetmapping.h"
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#endif
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#ifdef EIGHTBIT
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#define s_colourmap s_t0
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#endif
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affine varying vec2 tc;
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varying vec4 light;
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#if defined(SPECULAR) || defined(OFFSETMAPPING) || defined(REFLECTCUBEMASK) || defined(PBR)
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varying vec3 eyevector;
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#endif
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#if defined(PBR) || defined(REFLECTCUBEMASK)
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varying mat3 invsurface;
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#endif
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#ifdef PBR
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#include "sys/pbr.h"
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#if 0
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vec3 getIBLContribution(PBRInfo pbrInputs, vec3 n, vec3 reflection)
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{
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float mipCount = 9.0; // resolution of 512x512
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float lod = (pbrInputs.perceptualRoughness * mipCount);
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// retrieve a scale and bias to F0. See [1], Figure 3
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vec3 brdf = texture2D(u_brdfLUT, vec2(pbrInputs.NdotV, 1.0 - pbrInputs.perceptualRoughness)).rgb;
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vec3 diffuseLight = textureCube(u_DiffuseEnvSampler, n).rgb;
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#ifdef USE_TEX_LOD
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vec3 specularLight = textureCubeLodEXT(u_SpecularEnvSampler, reflection, lod).rgb;
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#else
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vec3 specularLight = textureCube(u_SpecularEnvSampler, reflection).rgb;
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#endif
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vec3 diffuse = diffuseLight * pbrInputs.diffuseColor;
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vec3 specular = specularLight * (pbrInputs.specularColor * brdf.x + brdf.y);
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// For presentation, this allows us to disable IBL terms
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diffuse *= u_ScaleIBLAmbient.x;
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specular *= u_ScaleIBLAmbient.y;
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return diffuse + specular;
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}
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#endif
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#endif
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void main ()
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{
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vec4 col, sp;
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#ifdef OFFSETMAPPING
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vec2 tcoffsetmap = offsetmap(s_normalmap, tc, eyevector);
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#define tc tcoffsetmap
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#endif
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#ifdef EIGHTBIT
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vec3 lightlev = light.rgb;
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//FIXME: with this extra flag, half the permutations are redundant.
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lightlev *= 0.5; //counter the fact that the colourmap contains overbright values and logically ranges from 0 to 2 intead of to 1.
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float pal = texture2D(s_paletted, tc).r; //the palette index. hopefully not interpolated.
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// lightlev -= 1.0 / 128.0; //software rendering appears to round down, so make sure we favour the lower values instead of rounding to the nearest
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col.r = texture2D(s_colourmap, vec2(pal, 1.0-lightlev.r)).r; //do 3 lookups. this is to cope with lit files, would be a waste to not support those.
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col.g = texture2D(s_colourmap, vec2(pal, 1.0-lightlev.g)).g; //its not very softwarey, but re-palettizing is ugly.
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col.b = texture2D(s_colourmap, vec2(pal, 1.0-lightlev.b)).b; //without lits, it should be identical.
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col.a = (pal<1.0)?light.a:0.0;
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#else
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col = texture2D(s_diffuse, tc);
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#ifdef UPPER
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vec4 uc = texture2D(s_upper, tc);
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col.rgb += uc.rgb*e_uppercolour*uc.a;
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#endif
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#ifdef LOWER
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vec4 lc = texture2D(s_lower, tc);
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col.rgb += lc.rgb*e_lowercolour*lc.a;
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#endif
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col *= factor_base;
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#ifndef IOR
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#define IOR 1.5 //Index Of Reflection.
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#endif
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#define dielectricSpecular pow(((IOR - 1.0)/(IOR + 1.0)),2.0)
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#ifdef SPECULAR
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vec4 specs = texture2D(s_specular, tc)*factor_spec;
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#ifdef ORM
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#define occlusion specs.r
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#define roughness clamp(specs.g, 0.04, 1.0)
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#define metalness specs.b
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#define gloss 1.0 //sqrt(1.0-roughness)
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#define ambientrgb (specrgb+col.rgb)
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vec3 specrgb = mix(vec3(dielectricSpecular), col.rgb, metalness);
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col.rgb = col.rgb * (1.0 - dielectricSpecular) * (1.0-metalness);
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#elif defined(SG) //pbr-style specular+glossiness, without occlusion
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//occlusion needs to be baked in. :(
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#define roughness (1.0-specs.a)
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#define gloss (specs.a)
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#define specrgb specs.rgb
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#define ambientrgb (specrgb+col.rgb)
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#else //blinn-phong
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#define roughness (1.0-specs.a)
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#define gloss specs.a
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#define specrgb specs.rgb
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#define ambientrgb col.rgb
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#endif
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#else
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#define roughness 0.3
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#define specrgb vec3(1.0) //vec3(dielectricSpecular)
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#define ambientrgb col.rgb
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#endif
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#ifdef BUMP
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#ifdef PBR //to modelspace
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vec3 bumps = normalize(invsurface * (texture2D(s_normalmap, tc).rgb*2.0 - 1.0));
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#else //stay in tangentspace
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vec3 bumps = normalize(vec3(texture2D(s_normalmap, tc)) - 0.5);
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#endif
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#else
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#ifdef PBR //to modelspace
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#define bumps normalize(invsurface[2])
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#else //tangent space
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#define bumps vec3(0.0, 0.0, 1.0)
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#endif
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#endif
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#ifdef PBR
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//move everything to model space
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col.rgb = DoPBR(bumps, normalize(eyevector), -e_light_dir, roughness, col.rgb, specrgb, vec3(0.0,1.0,1.0))*e_light_mul + e_light_ambient*.25*ambientrgb;
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#elif defined(gloss)
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vec3 halfdir = normalize(normalize(eyevector) - e_light_dir);
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float specmag = pow(max(dot(halfdir, bumps), 0.0), FTE_SPECULAR_EXPONENT * gloss);
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col.rgb += FTE_SPECULAR_MULTIPLIER * specmag * specrgb;
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#endif
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#ifdef REFLECTCUBEMASK
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vec3 rtc = reflect(-eyevector, bumps);
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#ifndef PBR
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rtc = rtc.x*invsurface[0] + rtc.y*invsurface[1] + rtc.z*invsurface[2];
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#endif
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rtc = (m_model * vec4(rtc.xyz,0.0)).xyz;
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col.rgb += texture2D(s_reflectmask, tc).rgb * textureCube(s_reflectcube, rtc).rgb;
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#endif
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#ifdef OCCLUDE
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col.rgb *= texture2D(s_occlusion, tc).r;
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#elif defined(occlusion) && !defined(NOOCCLUDE)
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col.rgb *= occlusion;
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#endif
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col *= light * e_colourident;
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#ifdef FULLBRIGHT
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vec4 fb = texture2D(s_fullbright, tc);
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// col.rgb = mix(col.rgb, fb.rgb, fb.a);
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col.rgb += fb.rgb * fb.a * e_glowmod.rgb * factor_emit.rgb;
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#elif defined(PBR)
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col.rgb += e_glowmod.rgb * factor_emit.rgb;
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#endif
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#endif
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#ifdef ALPHATEST
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if (!(col.a ALPHATEST))
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discard;
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#elif defined(MASK)
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#if defined(MASKLT)
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if (col.a < MASK)
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discard;
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#else
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if (col.a >= MASK)
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discard;
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#endif
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col.a = 1.0; //alpha blending AND alpha testing usually looks stupid, plus it screws up our fog.
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#endif
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gl_FragColor = fog4(col);
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}
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#endif
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