fteqw/engine/shaders/glsl/rtlight.glsl

278 lines
7.5 KiB
Text
Raw Normal View History

!!permu BUMP
!!permu SKELETAL
!!permu UPPERLOWER
!!permu FOG
!!cvarf r_glsl_offsetmapping_scale
//this is the main shader responsible for realtime dlights.
//texture units:
//s0=diffuse, s1=normal, s2=specular, s3=shadowmap
//custom modifiers:
//PCF(shadowmap)
//CUBEPROJ(projected cubemap)
//SPOT(projected circle
//CUBESHADOW
#if 0 && defined(GL_ARB_texture_gather) && defined(PCF)
#extension GL_ARB_texture_gather : enable
#endif
#ifdef UPPERLOWER
#define UPPER
#define LOWER
#endif
varying vec2 tcbase;
varying vec3 lightvector;
#if defined(SPECULAR) || defined(OFFSETMAPPING)
varying vec3 eyevector;
#endif
#if defined(PCF) || defined(CUBEPROJ) || defined(SPOT)
varying vec4 vtexprojcoord;
uniform mat4 l_cubematrix;
#ifndef SPOT
uniform mat4 l_projmatrix;
#endif
#endif
#ifdef VERTEX_SHADER
#include "sys/skeletal.h"
uniform vec3 l_lightposition;
attribute vec2 v_texcoord;
#if defined(SPECULAR) || defined(OFFSETMAPPING)
uniform vec3 e_eyepos;
#endif
void main ()
{
vec3 n, s, t, w;
gl_Position = skeletaltransform_wnst(w,n,s,t);
tcbase = v_texcoord; //pass the texture coords straight through
vec3 lightminusvertex = l_lightposition - w.xyz;
lightvector.x = -dot(lightminusvertex, s.xyz);
lightvector.y = dot(lightminusvertex, t.xyz);
lightvector.z = dot(lightminusvertex, n.xyz);
#if defined(SPECULAR)||defined(OFFSETMAPPING)
vec3 eyeminusvertex = e_eyepos - w.xyz;
eyevector.x = -dot(eyeminusvertex, s.xyz);
eyevector.y = dot(eyeminusvertex, t.xyz);
eyevector.z = dot(eyeminusvertex, n.xyz);
#endif
#if defined(PCF) || defined(SPOT) || defined(PROJECTION)
//for texture projections/shadowmapping on dlights
vtexprojcoord = (l_cubematrix*vec4(w.xyz, 1.0));
#endif
}
#endif
#ifdef FRAGMENT_SHADER
#include "sys/fog.h"
uniform sampler2D s_t0; //diffuse
#if defined(BUMP) || defined(SPECULAR) || defined(OFFSETMAPPING)
uniform sampler2D s_t1; //normalmap
#endif
#ifdef SPECULAR
uniform sampler2D s_t2; //specular
#endif
#ifdef CUBEPROJ
uniform samplerCube s_t3; //projected cubemap
#endif
#ifdef PCF
#ifdef CUBESHADOW
uniform samplerCubeShadow s_t4; //shadowmap
#else
#if 0//def GL_ARB_texture_gather
uniform sampler2D s_t4;
#else
uniform sampler2DShadow s_t4;
#endif
#endif
#endif
#ifdef LOWER
uniform sampler2D s_t5; //pants colours
uniform vec3 e_lowercolour;
#endif
#ifdef UPPER
uniform sampler2D s_t6; //shirt colours
uniform vec3 e_uppercolour;
#endif
uniform float l_lightradius;
uniform vec3 l_lightcolour;
uniform vec3 l_lightcolourscale;
#ifdef PCF
//#define shadow2DProj(t,c) (vec2(1.0,1.0))
//#define shadow2DProj(t,c) texture2DProj(t,c).rg
float ShadowmapFilter(void)
{
#ifdef SPOT
const vec3 texscale = vec3(1.0/512.0, 1.0/512.0, 1.0);
#else
const vec3 texscale = vec3(1.0/(512.0*3.0), 1.0/(512.0*2.0), 1.0);
#endif
//dehomogonize input
vec3 shadowcoord = (vtexprojcoord.xyz / vtexprojcoord.w);
#ifdef CUBESHADOW
// vec3 shadowcoord = vshadowcoord.xyz / vshadowcoord.w;
// #define dosamp(x,y) shadowCube(s_t4, shadowcoord + vec2(x,y)*texscale.xy).r
#else
#ifdef SPOT
//bias it. don't bother figuring out which side or anything, its not needed
//l_projmatrix contains the light's projection matrix so no other magic needed
shadowcoord.xyz = (shadowcoord.xyz + vec3(1.0, 1.0, 1.0)) * vec3(0.5, 0.5, 0.5);
#else
//figure out which axis to use
//texture is arranged thusly:
//forward left up
//back right down
vec3 dir = abs(shadowcoord);
//assume z is the major axis (ie: forward from the light)
vec3 t = shadowcoord;
float ma = dir.z;
vec3 axis = vec3(1.0, 1.0, 1.0);
if (dir.x > ma)
{
ma = dir.x;
t = shadowcoord.zyx;
axis.x = 3.0;
}
if (dir.y > ma)
{
ma = dir.y;
t = shadowcoord.xzy;
axis.x = 5.0;
}
if (t.z > 0.0)
{
axis.y = 3.0;
t.z = -t.z;
}
//we also need to pass the result through the light's projection matrix too
vec4 nsc =l_projmatrix*vec4(t, 1.0);
shadowcoord = (nsc.xyz / nsc.w);
//now bias and relocate it
shadowcoord = (shadowcoord + axis.xyz) * vec3(0.5/3.0, 0.5/2.0, 0.5);
#endif
#if 0//def GL_ARB_texture_gather
vec2 ipart, fpart;
#define dosamp(x,y) textureGatherOffset(s_t4, ipart.xy, vec2(x,y)))
vec4 tl = step(shadowcoord.z, dosamp(-1.0, -1.0));
vec4 bl = step(shadowcoord.z, dosamp(-1.0, 1.0));
vec4 tr = step(shadowcoord.z, dosamp(1.0, -1.0));
vec4 br = step(shadowcoord.z, dosamp(1.0, 1.0));
//we now have 4*4 results, woo
//we can just average them for 1/16th precision, but that's still limited graduations
//the middle four pixels are 'full strength', but we interpolate the sides to effectively give 3*3
vec4 col = vec4(tl.ba, tr.ba) + vec4(bl.rg, br.rg) + //middle two rows are full strength
mix(vec4(tl.rg, tr.rg), vec4(bl.ba, br.ba), fpart.y); //top+bottom rows
return dot(mix(col.rgb, col.agb, fpart.x), vec3(1.0/9.0)); //blend r+a, gb are mixed because its pretty much free and gives a nicer dot instruction instead of lots of adds.
#else
#define dosamp(x,y) shadow2D(s_t4, shadowcoord.xyz + (vec3(x,y,0.0)*texscale.xyz)).r
float s = 0.0;
s += dosamp(-1.0, -1.0);
s += dosamp(-1.0, 0.0);
s += dosamp(-1.0, 1.0);
s += dosamp(0.0, -1.0);
s += dosamp(0.0, 0.0);
s += dosamp(0.0, 1.0);
s += dosamp(1.0, -1.0);
s += dosamp(1.0, 0.0);
s += dosamp(1.0, 1.0);
return s/9.0;
#endif
#endif
}
#endif
#ifdef OFFSETMAPPING
#include "sys/offsetmapping.h"
#endif
void main ()
{
//read raw texture samples (offsetmapping munges the tex coords first)
#ifdef OFFSETMAPPING
vec2 tcoffsetmap = offsetmap(s_t1, tcbase, eyevector);
#define tcbase tcoffsetmap
#endif
vec3 bases = vec3(texture2D(s_t0, tcbase));
#ifdef UPPER
vec4 uc = texture2D(s_t6, tcbase);
bases.rgb += uc.rgb*e_uppercolour*uc.a;
#endif
#ifdef LOWER
vec4 lc = texture2D(s_t5, tcbase);
bases.rgb += lc.rgb*e_lowercolour*lc.a;
#endif
#if defined(BUMP) || defined(SPECULAR)
vec3 bumps = normalize(vec3(texture2D(s_t1, tcbase)) - 0.5);
#endif
#ifdef SPECULAR
vec4 specs = texture2D(s_t2, tcbase);
#endif
vec3 nl = normalize(lightvector);
float colorscale = max(1.0 - (dot(lightvector, lightvector)/(l_lightradius*l_lightradius)), 0.0);
vec3 diff;
#ifdef BUMP
diff = bases * (l_lightcolourscale.x + l_lightcolourscale.y * max(dot(bumps, nl), 0.0));
#else
//we still do bumpmapping even without bumps to ensure colours are always sane. light.exe does it too.
diff = bases * (l_lightcolourscale.x + l_lightcolourscale.y * max(dot(vec3(0.0, 0.0, 1.0), nl), 0.0));
#endif
#ifdef SPECULAR
vec3 halfdir = normalize(normalize(eyevector) + nl);
float spec = pow(max(dot(halfdir, bumps), 0.0), 32.0 * specs.a);
diff += l_lightcolourscale.z * spec * specs.rgb;
#endif
#ifdef CUBEPROJ
/*filter the colour by the cubemap projection*/
diff *= textureCube(s_t3, vtexprojcoord.xyz).rgb;
#endif
#if defined(SPOT)
/*filter the colour by the spotlight. discard anything behind the light so we don't get a mirror image*/
if (vtexprojcoord.w < 0.0) discard;
vec2 spot = ((vtexprojcoord.st)/vtexprojcoord.w);colorscale*=1.0-(dot(spot,spot));
#endif
#ifdef PCF
/*filter the light by the shadowmap. logically a boolean, but we allow fractions for softer shadows*/
//diff.rgb = (vtexprojcoord.xyz/vtexprojcoord.w) * 0.5 + 0.5;
colorscale *= ShadowmapFilter();
// gl_FragColor.rgb = vec3(ShadowmapFilter());
#endif
#if defined(PROJECTION)
/*2d projection, not used*/
// diff *= texture2d(s_t3, shadowcoord);
#endif
gl_FragColor.rgb = fog3additive(diff*colorscale*l_lightcolour);
}
#endif