Added the sources of added shaders

2025-08-11 00:01:34 -04:00
parent 0bb4269ae6
commit e3d6de2ffc
16 changed files with 1348 additions and 0 deletions
--- a/tools/src/generative/Accretion.frag
+++ b/tools/src/generative/Accretion.frag
@@ -0,0 +1,38 @@
 /*
    "Accretion" by @XorDev
    I discovered an interesting refraction effect
    by adding the raymarch iterator to the turbulence!
    https://x.com/XorDev/status/1936884244128661986
 */
 void mainImage(out vec4 O, vec2 I)
 {
    //Raymarch depth
    float z,
    //Step distance
    d,
    //Raymarch iterator
    i;
    //Clear fragColor and raymarch 100 steps
    for(O*=i; i++<2e1; )
    {
        //Sample point (from ray direction)
        vec3 p = z*normalize(vec3(I+I,0)-iResolution.xyx)+.1;
        //Polar coordinates and additional transformations
        p = vec3(atan(p.y/.2,p.x)*2., p.z/3., length(p.xy)-5.-z*.2);
        //Apply turbulence and refraction effect
        for(d=0.; d++<7.;)
            p += sin(p.yzx*d+iTime+.3*i)/d;
        //Distance to cylinder and waves with refraction
        z += d = length(vec4(.4*cos(p)-.4, p.z));
        //Coloring and brightness
        O += (1.+cos(p.x+i*.4+z+vec4(6,1,2,0)))/d;
    }
    //Tanh tonemap
    O = tanh(O*O/4e2);
 }
--- a/tools/src/generative/Daedra.frag
+++ b/tools/src/generative/Daedra.frag
@@ -0,0 +1,49 @@
 //const float gridSize = iResolution.x*0.1;
 bool circleTest(vec2 pos, vec2 size, vec2 uv){
    if(distance(pos,uv) < size.x){
        return true;
    } else {
        return false;
    }
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
    // Normalized pixel coordinates (from 0 to 1)
    vec2 uv = fragCoord/iResolution.y;
    float gridSize = iResolution.x*0.05;
    uv = fract(uv*gridSize);
    vec4 cam = texture(iChannel0, floor((fragCoord/iResolution.xy)*gridSize)*(1.0/gridSize));
    vec3 col = vec3(0.0);
    bool circleR = circleTest(vec2(0.7,0.7),vec2(cam.x*0.5), uv);
    bool circleG = circleTest(vec2(0.3,0.5),vec2(cam.y*0.5), uv);
    bool circleB = circleTest(vec2(0.7,0.3),vec2(cam.z*0.5), uv);
    // Output to screen
    if(circleR){
        col.x = 1.0;
    } else {
        col.x = 0.0;
    }
    if(circleG){
        col.y = 1.0;
    } else {
        col.y = 0.0;
    }
    if(circleB){
        col.z = 1.0;
    } else {
        col.z = 0.0;
    }
    fragColor = vec4(col,1.0);
 }
--- a/tools/src/generative/Just
+++ b/tools/src/generative/Just
@@ -0,0 +1,49 @@
 //const float gridSize = iResolution.x*0.1;
 bool circleTest(vec2 pos, vec2 size, vec2 uv){
    if(distance(pos,uv) < size.x){
        return true;
    } else {
        return false;
    }
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
    // Normalized pixel coordinates (from 0 to 1)
    vec2 uv = fragCoord/iResolution.y;
    float gridSize = iResolution.x*0.05;
    uv = fract(uv*gridSize);
    vec4 cam = texture(iChannel0, floor((fragCoord/iResolution.xy)*gridSize)*(1.0/gridSize));
    vec3 col = vec3(0.0);
    bool circleR = circleTest(vec2(0.7,0.7),vec2(cam.x*0.5), uv);
    bool circleG = circleTest(vec2(0.3,0.5),vec2(cam.y*0.5), uv);
    bool circleB = circleTest(vec2(0.7,0.3),vec2(cam.z*0.5), uv);
    // Output to screen
    if(circleR){
        col.x = 1.0;
    } else {
        col.x = 0.0;
    }
    if(circleG){
        col.y = 1.0;
    } else {
        col.y = 0.0;
    }
    if(circleB){
        col.z = 1.0;
    } else {
        col.z = 0.0;
    }
    fragColor = vec4(col,1.0);
 }
--- a/tools/src/generative/Orb
+++ b/tools/src/generative/Orb
@@ -0,0 +1,77 @@
 // sleepy comments, most leftover from previous shader
 // beware... i'll re-read tomorrow :D
 #define T iTime
 // @FabriceNeyret2 golfed this in my "Light Hall" shader
 // the idea is that you pass in the movement frequency (f)
 // the z offset (Z) and the radius (c), you then just do
 // a sphere calc on p: length(p - offset) - radius
 // the offset vec is composed of all the trig stuff below
 // but it's basically just move x and y in squiggly lines
 // and move z relative to iTime and the z offset
 // T*3. because the camera is moving at T*3. speed as well
 #define O(f,Z,c) abs( length(                 /* orb */   \
 p - vec3( sin( sin(p.z*f*.5 ) +T*.7 ) * 3. ,        \
 sin( sin(p.z*f*1.3) +T*.5 ) * 2.,  \
 Z +8. +T*3. +cos(T*.3) *8. )  ) - c )
 void mainImage(out vec4 o, vec2 u) {
    float l, // distance to light orb
    s, // spiral distance
    d, // total distance marched
    i, // raymarch iterator
    n; // noise iterator
    // p is resolution, then raymarch position
    vec3 p = iResolution;
    // scale coords
    u = (u-p.xy/2.)/p.y;
    // clear o, iterate 70 times, accumulate distance (d) and brightness (o)
    // .001+abs(min(s,l)) means take the min of the spiral and the lights,
    // and make it slightly translucent, *.7 to clean up some artifacts
    for(o*=i; i++<60.;d += s = .001+abs(min(s,l))*.5, o += 1./s/l)
        // this for-loop is the noise loop, before entering the loop body,
        // we march. the below is equivalent to p = ro + rd * d, p.z += T;
        // note that the orbs move at T*3. speed as well
        for (p = vec3(u * d, d+T*3.),
            // mirror
            p = abs(p),
             // it's just a mirrored plane with tanh wrapped around it to make it interesting
             // why tanh? i was using cos for repetition and was curious, so i tried
             // tanh, liked it, and kept it :)
             s = tanh(4.-abs(p.x)),
             // store dist to light in l
             l = .01 + .8 *  min( O(.5, 6., .4),
                                  min( O(.4, 3., .2),
                                       O(.3, 4., .3) )),
             // start noise at 1, while < 6, n *= 1.3
             // n += n works, n *= 1.x works, but keep in mind the number of iterations
             // the loop will need
             n = 1.; n < 6.; n *= 1.3 )
            // apply the noise with a scale of .3
            // add .5*T to p to make it move,
            // add p.z to make it less repetitive looking
            s += abs(dot(cos(.5*T+p.z+p*n), vec3(.3))) / n;
            // tanh tonemap, vec4 divides color by d (green and blue) for depth,
            // divide down brightness (o / 1e2),
            // divide by distance for depth
            // add a light in the center length(u),
            o = tanh(2.*abs(vec4(.1,4./d, d/3e1,0)) * o/1e2/max(d,15.) / max(length(u), .001));
            // @Shane color tip, mix o with swizzled components
            o = mix(o.zyxw, o.yxzw, smoothstep(0., 1., length(u)*2.));
 }
--- a/tools/src/generative/Phosphor.frag
+++ b/tools/src/generative/Phosphor.frag
@@ -0,0 +1,47 @@
 /*
    "Phosphor 3" by @XorDev
    https://x.com/XorDev/status/1949897576435581439
    <512 playlist:
    https://www.shadertoy.com/playlist/N3SyzR
 */
 void mainImage(out vec4 O, vec2 I)
 {
    //Animation time
    float t = iTime,
    //Raymarch depth
    z,
    //Step distance
    d,
    //Signed distance
    s,
    //Raymarch iterator
    i;
    //Clear fragColor and raymarch 80 steps
    for(O*=i; i++<8e1;
        //Coloring and brightness
        O+=(cos(s+vec4(0,1,8,0))+1.)/d)
    {
        //Sample point (from ray direction)
        vec3 p = z*normalize(vec3(I+I,0)-iResolution.xyy),
        //Rotation axis
        a = normalize(cos(vec3(5,0,1)+t-d*4.));
        //Move camera back 5 units
        p.z+=5.,
        //Rotated coordinates
        a = a*dot(a,p)-cross(a,p);
        //Turbulence loop
        for(d=1.;d++<9.;)
            a-=sin(a*d+t).zxy/d;
        //Distance to ring
        z+=d=.1*abs(length(p)-3.)+.07*abs(cos(s=a.y));
    }
    //Tanh tonemap
    O = tanh(O/5e3);
 }
--- a/tools/src/generative/Self
+++ b/tools/src/generative/Self
@@ -0,0 +1,370 @@
 // https://www.shadertoy.com/view/XfyXRV
 // CC0: Let's self reflect
 //  Always enjoyed the videos of Platonic solids with inner mirrors
 //  I made some previous attempts but thought I make another attempt it
 // Reducing the alias effects on the inner reflections turned out to be a bit tricky. 
 //  Simplest solution is just to run run fullscreen on a 4K screen ;)
 // Function to generate the solid found here: https://www.shadertoy.com/view/MsKGzw
 // Tinker with these parameters to create different solids
 // -------------------------------------------------------
 const float rotation_speed= 0.25;
 const float poly_U        = 1.;   // [0, inf]
 const float poly_V        = 0.5;  // [0, inf]
 const float poly_W        = 1.0;  // [0, inf]
 const int   poly_type     = 3;    // [2, 5]
 const float poly_zoom     = 2.0;
 const float inner_sphere  = 1.;
 const float refr_index    = 0.9;
 #define MAX_BOUNCES2        6
 // -------------------------------------------------------
 #define TIME        iTime
 #define RESOLUTION  iResolution
 #define PI          3.141592654
 #define TAU         (2.0*PI)
 // License: WTFPL, author: sam hocevar, found: https://stackoverflow.com/a/17897228/418488
 const vec4 hsv2rgb_K = vec4(1.0, 2.0 / 3.0, 1.0 / 3.0, 3.0);
 vec3 hsv2rgb(vec3 c) {
  vec3 p = abs(fract(c.xxx + hsv2rgb_K.xyz) * 6.0 - hsv2rgb_K.www);
  return c.z * mix(hsv2rgb_K.xxx, clamp(p - hsv2rgb_K.xxx, 0.0, 1.0), c.y);
 }
 // License: WTFPL, author: sam hocevar, found: https://stackoverflow.com/a/17897228/418488
 //  Macro version of above to enable compile-time constants
 #define HSV2RGB(c)  (c.z * mix(hsv2rgb_K.xxx, clamp(abs(fract(c.xxx + hsv2rgb_K.xyz) * 6.0 - hsv2rgb_K.www) - hsv2rgb_K.xxx, 0.0, 1.0), c.y))
 #define TOLERANCE2          0.0005
 //#define MAX_RAY_LENGTH2   10.0
 #define MAX_RAY_MARCHES2    50
 #define NORM_OFF2           0.005
 #define BACKSTEP2
 #define TOLERANCE3          0.0005
 #define MAX_RAY_LENGTH3     10.0
 #define MAX_RAY_MARCHES3    90
 #define NORM_OFF3           0.005
 const vec3 rayOrigin    = vec3(0.0, 1., -5.);
 const vec3 sunDir       = normalize(-rayOrigin);
 const vec3 sunCol       = HSV2RGB(vec3(0.06 , 0.90, 1E-2))*1.;
 const vec3 bottomBoxCol = HSV2RGB(vec3(0.66, 0.80, 0.5))*1.;
 const vec3 topBoxCol    = HSV2RGB(vec3(0.60, 0.90, 1.))*1.;
 const vec3 glowCol0     = HSV2RGB(vec3(0.05 , 0.7, 1E-3))*1.;
 const vec3 glowCol1     = HSV2RGB(vec3(0.95, 0.7, 1E-3))*1.;
 const vec3 beerCol      = -HSV2RGB(vec3(0.15+0.5, 0.7, 2.)); 
 const float rrefr_index = 1./refr_index;
 // License: Unknown, author: knighty, found: https://www.shadertoy.com/view/MsKGzw
 const float poly_cospin   = cos(PI/float(poly_type));
 const float poly_scospin  = sqrt(0.75-poly_cospin*poly_cospin);
 const vec3  poly_nc       = vec3(-0.5, -poly_cospin, poly_scospin);
 const vec3  poly_pab      = vec3(0., 0., 1.);
 const vec3  poly_pbc_     = vec3(poly_scospin, 0., 0.5);
 const vec3  poly_pca_     = vec3(0., poly_scospin, poly_cospin);
 const vec3  poly_p        = normalize((poly_U*poly_pab+poly_V*poly_pbc_+poly_W*poly_pca_));
 const vec3  poly_pbc      = normalize(poly_pbc_);
 const vec3  poly_pca      = normalize(poly_pca_);
 mat3 g_rot;
 vec2 g_gd;
 // License: MIT, author: Inigo Quilez, found: https://iquilezles.org/articles/noacos/
 mat3 rot(vec3 d, vec3 z) {
  vec3  v = cross( z, d );
  float c = dot( z, d );
  float k = 1.0/(1.0+c);
  return mat3( v.x*v.x*k + c,     v.y*v.x*k - v.z,    v.z*v.x*k + v.y,
               v.x*v.y*k + v.z,   v.y*v.y*k + c,      v.z*v.y*k - v.x,
               v.x*v.z*k - v.y,   v.y*v.z*k + v.x,    v.z*v.z*k + c    );
 }
 // License: Unknown, author: Matt Taylor (https://github.com/64), found: https://64.github.io/tonemapping/
 vec3 aces_approx(vec3 v) {
  v = max(v, 0.0);
  v *= 0.6;
  float a = 2.51;
  float b = 0.03;
  float c = 2.43;
  float d = 0.59;
  float e = 0.14;
  return clamp((v*(a*v+b))/(v*(c*v+d)+e), 0.0, 1.0);
 }
 float sphere(vec3 p, float r) {
  return length(p) - r;
 }
 // License: MIT, author: Inigo Quilez, found: https://iquilezles.org/articles/distfunctions/
 float box(vec2 p, vec2 b) {
  vec2 d = abs(p)-b;
  return length(max(d,0.0)) + min(max(d.x,d.y),0.0);
 }
 // License: Unknown, author: knighty, found: https://www.shadertoy.com/view/MsKGzw
 void poly_fold(inout vec3 pos) {
  vec3 p = pos;
  for(int i = 0; i < poly_type; ++i){
    p.xy  = abs(p.xy);
    p    -= 2.*min(0., dot(p,poly_nc)) * poly_nc;
  }
  pos = p;
 }
 float poly_plane(vec3 pos) {
  float d0 = dot(pos, poly_pab);
  float d1 = dot(pos, poly_pbc);
  float d2 = dot(pos, poly_pca);
  float d = d0;
  d = max(d, d1);
  d = max(d, d2);
  return d;
 }
 float poly_corner(vec3 pos) {
  float d = length(pos) - .0125;
  return d;
 }
 float dot2(vec3 p) {
  return dot(p, p);
 }
 float poly_edge(vec3 pos) {
  float dla = dot2(pos-min(0., pos.x)*vec3(1., 0., 0.));
  float dlb = dot2(pos-min(0., pos.y)*vec3(0., 1., 0.));
  float dlc = dot2(pos-min(0., dot(pos, poly_nc))*poly_nc);
  return sqrt(min(min(dla, dlb), dlc))-2E-3;
 }
 vec3 shape(vec3 pos) {
  pos *= g_rot;
  pos /= poly_zoom;
  poly_fold(pos);
  pos -= poly_p;
  return vec3(poly_plane(pos), poly_edge(pos), poly_corner(pos))*poly_zoom;
 }
 vec3 render0(vec3 ro, vec3 rd) {
  vec3 col = vec3(0.0);
  float srd  = sign(rd.y);
  float tp   = -(ro.y-6.)/abs(rd.y);
  if (srd < 0.) {
    col += bottomBoxCol*exp(-0.5*(length((ro + tp*rd).xz)));
  }
  if (srd > 0.0) {
    vec3 pos  = ro + tp*rd;
    vec2 pp = pos.xz;
    float db = box(pp, vec2(5.0, 9.0))-3.0;
    col += topBoxCol*rd.y*rd.y*smoothstep(0.25, 0.0, db);
    col += 0.2*topBoxCol*exp(-0.5*max(db, 0.0));
    col += 0.05*sqrt(topBoxCol)*max(-db, 0.0);
  }
  col += sunCol/(1.001-dot(sunDir, rd));
  return col; 
 }
 float df2(vec3 p) {
  vec3 ds = shape(p);
  float d2 = ds.y-5E-3;
  float d0 = min(-ds.x, d2);
  float d1 = sphere(p, inner_sphere);
  g_gd = min(g_gd, vec2(d2, d1));
  float d = (min(d0, d1));
  return d;
 }
 float rayMarch2(vec3 ro, vec3 rd, float tinit) {
  float t = tinit;
 #if defined(BACKSTEP2)
  vec2 dti = vec2(1e10,0.0);
 #endif
  int i;
  for (i = 0; i < MAX_RAY_MARCHES2; ++i) {
    float d = df2(ro + rd*t);
 #if defined(BACKSTEP2)
    if (d<dti.x) { dti=vec2(d,t); }
 #endif  
    // Bouncing in a closed shell, will never miss
    if (d < TOLERANCE2/* || t > MAX_RAY_LENGTH3 */) {
      break;
    }
    t += d;
  }
 #if defined(BACKSTEP2)
  if(i==MAX_RAY_MARCHES2) { t=dti.y; };
 #endif  
  return t;
 }
 vec3 normal2(vec3 pos) {
  vec2  eps = vec2(NORM_OFF2,0.0);
  vec3 nor;
  nor.x = df2(pos+eps.xyy) - df2(pos-eps.xyy);
  nor.y = df2(pos+eps.yxy) - df2(pos-eps.yxy);
  nor.z = df2(pos+eps.yyx) - df2(pos-eps.yyx);
  return normalize(nor);
 }
 vec3 render2(vec3 ro, vec3 rd, float db) {
  vec3 agg = vec3(0.0);
  float ragg = 1.;
  float tagg = 0.;
  for (int bounce = 0; bounce < MAX_BOUNCES2; ++bounce) {
    if (ragg < 0.1) break;
    g_gd      = vec2(1E3);
    float t2  = rayMarch2(ro, rd, min(db+0.05, 0.3));
    vec2 gd2  = g_gd;
    tagg      += t2;
    vec3 p2   = ro+rd*t2;
    vec3 n2   = normal2(p2);
    vec3 r2   = reflect(rd, n2);
    vec3 rr2  = refract(rd, n2, rrefr_index);
    float fre2= 1.+dot(n2,rd);
    vec3 beer = ragg*exp(0.2*beerCol*tagg);
    agg += glowCol1*beer*((1.+tagg*tagg*4E-2)*6./max(gd2.x, 5E-4+tagg*tagg*2E-4/ragg));
    vec3 ocol = 0.2*beer*render0(p2, rr2);
    if (gd2.y <= TOLERANCE2) {
      ragg *= 1.-0.9*fre2;
    } else {
      agg     += ocol;
      ragg    *= 0.8;
    }
    ro        = p2;
    rd        = r2;
    db        = gd2.x; 
  }
  return agg;
 }
 float df3(vec3 p) {
  vec3 ds = shape(p);
  g_gd = min(g_gd, ds.yz);
  const float sw = 0.02;
  float d1 = min(ds.y, ds.z)-sw;
  float d0 = ds.x;
  d0 = min(d0, ds.y);
  d0 = min(d0, ds.z);
  return d0;
 }
 float rayMarch3(vec3 ro, vec3 rd, float tinit, out int iter) {
  float t = tinit;
  int i;
  for (i = 0; i < MAX_RAY_MARCHES3; ++i) {
    float d = df3(ro + rd*t);
    if (d < TOLERANCE3 || t > MAX_RAY_LENGTH3) {
      break;
    }
    t += d;
  }
  iter = i;
  return t;
 }
 vec3 normal3(vec3 pos) {
  vec2  eps = vec2(NORM_OFF3,0.0);
  vec3 nor;
  nor.x = df3(pos+eps.xyy) - df3(pos-eps.xyy);
  nor.y = df3(pos+eps.yxy) - df3(pos-eps.yxy);
  nor.z = df3(pos+eps.yyx) - df3(pos-eps.yyx);
  return normalize(nor);
 }
 vec3 render3(vec3 ro, vec3 rd) {
  int iter;
  vec3 skyCol = render0(ro, rd);
  vec3 col  = skyCol;
  g_gd      = vec2(1E3);
  float t1  = rayMarch3(ro, rd, 0.1, iter);
  vec2 gd1  = g_gd;
  vec3 p1   = ro+t1*rd;
  vec3 n1   = normal3(p1);
  vec3 r1   = reflect(rd, n1);
  vec3 rr1  = refract(rd, n1, refr_index);
  float fre1= 1.+dot(rd, n1);
  fre1 *= fre1;
  float ifo = mix(0.5, 1., smoothstep(1.0, 0.9, float(iter)/float(MAX_RAY_MARCHES3)));
  if (t1 < MAX_RAY_LENGTH3) {
    col = render0(p1, r1)*(0.5+0.5*fre1)*ifo;
    vec3 icol = render2(p1, rr1, gd1.x); 
    if (gd1.x > TOLERANCE3 && gd1.y > TOLERANCE3 && rr1 != vec3(0.)) {
      col += icol*(1.-0.75*fre1)*ifo;
    }
  }
  col += (glowCol0+1.*fre1*(glowCol0))/max(gd1.x, 3E-4);
  return col;
 }
 vec3 effect(vec2 p, vec2 pp) {
  const float fov = 2.0;
  const vec3 up = vec3(0., 1., 0.);
  const vec3 la   = vec3(0.0);
  const vec3 ww = normalize(normalize(la-rayOrigin));
  const vec3 uu = normalize(cross(up, ww));
  const vec3 vv = cross(ww, uu);
  vec3 rd = normalize(-p.x*uu + p.y*vv + fov*ww);
  vec3 col = vec3(0.0);
  col = render3(rayOrigin, rd);
  col -= 2E-2*vec3(2.,3.,1.)*(length(p)+0.25);
  col = aces_approx(col);
  col = sqrt(col);
  return col;
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord ) {
  vec2 q = fragCoord/RESOLUTION.xy;
  vec2 p = -1. + 2. * q;
  vec2 pp = p;
  p.x *= RESOLUTION.x/RESOLUTION.y;
  float a = TIME*rotation_speed;
  vec3 r0 = vec3(1.0, sin(vec2(sqrt(0.5), 1.0)*a));
  vec3 r1 = vec3(cos(vec2(sqrt(0.5), 1.0)*0.913*a), 1.0);
  mat3 rot = rot(normalize(r0), normalize(r1));
  g_rot = rot;
  vec3 col = effect(p, pp);
  fragColor = vec4(col, 1.0);
 }
--- a/tools/src/generative/Windows
+++ b/tools/src/generative/Windows
@@ -0,0 +1,137 @@
 // https://www.shadertoy.com/view/lllSR2
 #define PI     3.1415926535897921284
 #define REP    25
 #define d2r(x) (x * PI / 180.0)
 #define WBCOL  (vec3(0.5, 0.7,  1.7))
 #define WBCOL2 (vec3(0.15, 0.8, 1.7))
 #define ZERO   (min(iFrame,0))
 float hash( vec2 p ) {
 	float h = dot( p, vec2( 127.1, 311.7 ) );
 	return fract( sin( h ) * 458.325421) * 2.0 - 1.0;
 }
 float noise( vec2 p ) {
 	vec2 i = floor( p );
 	vec2 f = fract( p );
 	f = f * f * ( 3.0 - 2.0 * f );
 	return mix(
 		mix( hash( i + vec2( 0.0, 0.0 ) ), hash( i + vec2( 1.0, 0.0 ) ), f.x ),
 		mix( hash( i + vec2( 0.0, 1.0 ) ), hash( i + vec2( 1.0, 1.0 ) ), f.x ),
 		f.y
 	);
 }
 vec2 rot(vec2 p, float a) {
 	return vec2(
 		p.x * cos(a) - p.y * sin(a),
 		p.x * sin(a) + p.y * cos(a));
 }
 float nac(vec3 p, vec2 F, vec3 o) {
 	const float R = 0.0001;
 	p += o;
 	return length(max(abs(p.xy)-vec2(F),0.0)) - R;	
 }
 float by(vec3 p, float F, vec3 o) {
 	const float R = 0.0001;
 	p += o;
 	return length(max(abs(mod(p.xy, 3.0))-F,0.0)) - R;	
 }
 float recta(vec3 p, vec3 F, vec3 o) {
 	const float R = 0.0001;
 	p += o;
 	return length(max(abs(p)-F,0.0)) - R;	
 }
 float map1(vec3 p, float scale) {
 	float G = 0.50;
 	float F = 0.50 * scale;
 	float t =  nac(p, vec2(F,F), vec3( G,  G, 0.0));
 	t = min(t, nac(p, vec2(F,F), vec3( G, -G, 0.0)));
 	t = min(t, nac(p, vec2(F,F), vec3(-G,  G, 0.0)));
 	t = min(t, nac(p, vec2(F,F), vec3(-G, -G, 0.0)));
 	return t;
 }
 float map2(vec3 p) {
 	float t = map1(p, 0.9);
 	//t = max(t, recta(p, vec3(1.0, 1.0, 0.02), vec3(0.0, 0.0, 0.0)));
    t = max(t, recta(p, vec3(1.0, 1.0, 0.02), vec3(0.0, 0.0, 0.0)));
 	return t;
 }
 // http://glslsandbox.com/e#26840.0
 float gennoise(vec2 p) {
 	float d = 0.5;
 	mat2 h = mat2( 1.6, 1.2, -1.2, 1.6 );
 	float color = 0.0;
 	for( int i = 0; i < 2; i++ ) {
 		color += d * noise( p * 5.0 + iTime);
 		p *= h;
 		d /= 2.0;
 	}
 	return color;
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord ) {
    fragColor = vec4(0.0);
    for(int count = 0 ; count < 2; count++) {
        vec2 uv = -1.0 + 2.0 * ( fragCoord.xy / iResolution.xy );
        uv *= 1.4;
        uv.x += hash(uv.xy + iTime + float(count)) / 512.0;
        uv.y += hash(uv.yx + iTime + float(count)) / 512.0;
        vec3 dir = normalize(vec3(uv * vec2(iResolution.x / iResolution.y, 1.0), 1.0 + sin(iTime) * 0.01));
        dir.xz = rot(dir.xz, d2r(70.0));
        dir.xy = rot(dir.xy, d2r(90.0));
        vec3 pos    = vec3(-0.1 + sin(iTime * 0.3) * 0.1, 2.0 + cos(iTime * 0.4) * 0.1, -3.5);
        vec3  col   = vec3(0.0);
        float t     = 0.0;
        float M     = 1.002;
        float bsh   = 0.01;
        float dens  = 0.0;
        for(int i = ZERO ; i < REP * 24; i++) {
            float temp = map1(pos + dir * t, 0.6);
            if(temp < 0.2) {
                col += WBCOL * 0.005 * dens;
            }
            t += bsh * M;
            bsh *= M;
            dens += 0.025;
        }
        //windows
        t = 0.0;
        float y = 0.0;
        //for(int i = 0 ; i < REP * 50; i++)
        for(int i = ZERO ; i < REP; i++)
        {
            float temp = map2(pos + dir * t);
            if(temp < 0.025) {
                //col += WBCOL2 * 0.005;
                col += WBCOL2 * 0.5;
            }
            t += temp;
            y++;
        }
        col += ((2.0 + uv.x) * WBCOL2) + (y / (25.0 * 50.0));
        col += gennoise(dir.xz) * 0.5;
        col *= 1.0 - uv.y * 0.5;
        col *= vec3(0.05);
        col  = pow(col, vec3(0.717));
        fragColor += vec4(col, 1.0 / (t));
    }
    fragColor /= vec4(2.0);
 }
--- a/tools/src/generative/sdEquilateral.frag
+++ b/tools/src/generative/sdEquilateral.frag
@@ -0,0 +1,45 @@
 vec3 palette( float t ) {
    vec3 a = vec3(0.2, 0.2, 0.5); // blue has a greater default
    vec3 b = vec3(0.5, 0.5, 0.5); // all channels contribute
    vec3 c = vec3(0.1, 0.1, 0.4); // dampen blue oscillations
    vec3 d = vec3(0.0,0.33,0.67); // phase shifting by 0.33
    return a + b*cos( 6.28318*(c*t+d) );
 }
 float sdEquilateralTriangle( in vec2 p, in float r )
 {
    const float k = sqrt(3.0);
    p.x = abs(p.x) - r;
    p.y = p.y + r/k;
    if( p.x+k*p.y>0.0 ) p = vec2(p.x-k*p.y,-k*p.x-p.y)/2.0;
    p.x -= clamp( p.x, -2.0*r, 0.0 );
    return -length(p)*sign(p.y);
 }
 float norm( in vec2 p )
 {
    return sdEquilateralTriangle(p*1.5, 0.1);
 }
 void mainImage( out vec4 fragColour, in vec2 fragCoord ) {
    vec2 uv = (fragCoord *2.0 - iResolution.xy) / iResolution.y;
    uv = floor(uv*100.0f)/100.0f;
    vec2 uv0 = uv;
    vec3 finalColour = vec3(0.0);
    for (float i = 0.0; i < 4.0; i++) {
        uv = fract(uv * 1.5) - 0.5;
        float d = norm(uv) * exp(-norm(uv0));
        vec3 col = palette(norm(uv0) + i*.4 + iTime*.4);
        d = sin(d*8. + iTime)/8.;
        d = abs(d);
        d = pow(0.009 / d, 1.6);
        finalColour += col * d;
    }
    fragColour = vec4(finalColour, 1.0);
 }
--- a/tools/src/manipulative/Circle
+++ b/tools/src/manipulative/Circle
@@ -0,0 +1,49 @@
 //const float gridSize = iResolution.x*0.1;
 bool circleTest(vec2 pos, vec2 size, vec2 uv){
    if(distance(pos,uv) < size.x){
        return true;
    } else {
        return false;
    }
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
    // Normalized pixel coordinates (from 0 to 1)
    vec2 uv = fragCoord/iResolution.y;
    float gridSize = iResolution.x*0.05;
    uv = fract(uv*gridSize);
    vec4 cam = texture(iChannel0, floor((fragCoord/iResolution.xy)*gridSize)*(1.0/gridSize));
    vec3 col = vec3(0.0);
    bool circleR = circleTest(vec2(0.7,0.7),vec2(cam.x*0.5), uv);
    bool circleG = circleTest(vec2(0.3,0.5),vec2(cam.y*0.5), uv);
    bool circleB = circleTest(vec2(0.7,0.3),vec2(cam.z*0.5), uv);
    // Output to screen
    if(circleR){
        col.x = 1.0;
    } else {
        col.x = 0.0;
    }
    if(circleG){
        col.y = 1.0;
    } else {
        col.y = 0.0;
    }
    if(circleB){
        col.z = 1.0;
    } else {
        col.z = 0.0;
    }
    fragColor = vec4(col,1.0);
 }
--- a/tools/src/manipulative/Modulo
+++ b/tools/src/manipulative/Modulo
@@ -0,0 +1,47 @@
 // https://www.shadertoy.com/view/lcl3Rs
 // This function returns an integer to use as the modulus value for a given pixel. 
 //  The brighter this pixel, the smaller this integer is, relative to the width of the image (so that a black pixel returns
 //  the image width as an integer)
 int ditherModFactor(float val, vec2 imgSize){
    return int(floor((1.0-pow(val,0.01)) * imgSize.x));
    //The pow here applies an aggressive log curve to the greyscale colour of the image. This is needed due to 
    // multiplying the 0-1 greyscale value by such a large number (screen width in pixels). An exponent of 0.01 happens to work 
    // very well here, but playing around with the exponent can be interesting. 
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
    //Normalized pixel coordinates (from 0 to 1)
    vec2 uv = fragCoord/iResolution.xy;
    //Load a pixel from the image and write it to a variable
    vec4 pix = texture(iChannel0,uv);
    //If the green channel of this pixel is more than a small value, and the red and blue are less than a threshold, make this 
    // pixel black.
    if(pix.y > 0.01 && pix.x < 0.2 && pix.z < 0.2){pix = vec4(0.0,0.0,0.0,1.0);} //uncomment to chroma key (for black background) 
    //Store a float of the average value of all three colour channels of this pixel
    float pixVal = (pix.x+pix.y+pix.z)/3.0;
    //Work out what number/index pixel this is in the image. It is also interesting to use the x or y coordinate of the current
    // pixel (not normalised) in place of i (**try replacing i on line 39 with fragCoord.x or fragCoord.y!**).
    float i = uv.x + (uv.y * iResolution.y);
    //Get the modulo value for this pixel
    int shadeMod = ditherModFactor(pixVal, iResolution.xy);
    //Compare the modulo value for this pixel with it's number/index - if the pixel index is a multiple of the modulo, 
    // output a white pixel - if not, black. This means that brighter pixels in the original image both have more white 
    // neighbours and are more likely to be white themselves, based on where they fall in the image. This is why it's important
    // to scale the modulo to the image width so that no repeating patterns of white appear in parts of the image that should be 
    // black. When this is done, the only black/dark pixels in the original image that will return white in the modulo check are 
    // the pixels that have the "address" (index or x or y coord) equal to the max value in range of values that address can be. 
    if(int(i) % shadeMod == 0){
        fragColor = vec4(1.0);
    } else {
        fragColor = vec4(0.0,0.0,0.0,1.0);
    }
    //if((1.0-uv.x) < uv.y){fragColor = vec4(pixVal,pixVal,pixVal,1.0);} //uncommenting shows undithered b&w image on half of screen
 }
--- a/tools/src/manipulative/VHS
+++ b/tools/src/manipulative/VHS
@@ -0,0 +1,121 @@
 // https://www.shadertoy.com/view/wldBzS
 // change these values to 0.0 to turn off individual effects
 float vertJerkOpt = 0.0;
 float vertMovementOpt = 0.0;
 float bottomStaticOpt = 1.0;
 float scalinesOpt = 1.0;
 float rgbOffsetOpt = 1.0;
 float horzFuzzOpt = 1.0;
 // Noise generation functions borrowed from: 
 // https://github.com/ashima/webgl-noise/blob/master/src/noise2D.glsl
 vec3 mod289(vec3 x) {
  return x - floor(x * (1.0 / 289.0)) * 289.0;
 }
 vec2 mod289(vec2 x) {
  return x - floor(x * (1.0 / 289.0)) * 289.0;
 }
 vec3 permute(vec3 x) {
  return mod289(((x*34.0)+1.0)*x);
 }
 float snoise(vec2 v)
  {
  const vec4 C = vec4(0.211324865405187,  // (3.0-sqrt(3.0))/6.0
                      0.366025403784439,  // 0.5*(sqrt(3.0)-1.0)
                     -0.577350269189626,  // -1.0 + 2.0 * C.x
                      0.024390243902439); // 1.0 / 41.0
 // First corner
  vec2 i  = floor(v + dot(v, C.yy) );
  vec2 x0 = v -   i + dot(i, C.xx);
 // Other corners
  vec2 i1;
  //i1.x = step( x0.y, x0.x ); // x0.x > x0.y ? 1.0 : 0.0
  //i1.y = 1.0 - i1.x;
  i1 = (x0.x > x0.y) ? vec2(1.0, 0.0) : vec2(0.0, 1.0);
  // x0 = x0 - 0.0 + 0.0 * C.xx ;
  // x1 = x0 - i1 + 1.0 * C.xx ;
  // x2 = x0 - 1.0 + 2.0 * C.xx ;
  vec4 x12 = x0.xyxy + C.xxzz;
  x12.xy -= i1;
 // Permutations
  i = mod289(i); // Avoid truncation effects in permutation
  vec3 p = permute( permute( i.y + vec3(0.0, i1.y, 1.0 ))
 		+ i.x + vec3(0.0, i1.x, 1.0 ));
  vec3 m = max(0.5 - vec3(dot(x0,x0), dot(x12.xy,x12.xy), dot(x12.zw,x12.zw)), 0.0);
  m = m*m ;
  m = m*m ;
 // Gradients: 41 points uniformly over a line, mapped onto a diamond.
 // The ring size 17*17 = 289 is close to a multiple of 41 (41*7 = 287)
  vec3 x = 2.0 * fract(p * C.www) - 1.0;
  vec3 h = abs(x) - 0.5;
  vec3 ox = floor(x + 0.5);
  vec3 a0 = x - ox;
 // Normalise gradients implicitly by scaling m
 // Approximation of: m *= inversesqrt( a0*a0 + h*h );
  m *= 1.79284291400159 - 0.85373472095314 * ( a0*a0 + h*h );
 // Compute final noise value at P
  vec3 g;
  g.x  = a0.x  * x0.x  + h.x  * x0.y;
  g.yz = a0.yz * x12.xz + h.yz * x12.yw;
  return 130.0 * dot(m, g);
 }
 float staticV(vec2 uv) {
    float staticHeight = snoise(vec2(9.0,iTime*1.2+3.0))*0.3+5.0;
    float staticAmount = snoise(vec2(1.0,iTime*1.2-6.0))*0.1+0.3;
    float staticStrength = snoise(vec2(-9.75,iTime*0.6-3.0))*2.0+2.0;
 	return (1.0-step(snoise(vec2(5.0*pow(iTime,2.0)+pow(uv.x*7.0,1.2),pow((mod(iTime,100.0)+100.0)*uv.y*0.3+3.0,staticHeight))),staticAmount))*staticStrength;
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
 	vec2 uv =  fragCoord.xy/iResolution.xy;
 	float jerkOffset = (1.0-step(snoise(vec2(iTime*1.3,5.0)),0.8))*0.05;
 	float fuzzOffset = snoise(vec2(iTime*15.0,uv.y*80.0))*0.003;
 	float largeFuzzOffset = snoise(vec2(iTime*1.0,uv.y*25.0))*0.004;
    float vertMovementOn = (1.0-step(snoise(vec2(iTime*0.2,8.0)),0.4))*vertMovementOpt;
    float vertJerk = (1.0-step(snoise(vec2(iTime*1.5,5.0)),0.6))*vertJerkOpt;
    float vertJerk2 = (1.0-step(snoise(vec2(iTime*5.5,5.0)),0.2))*vertJerkOpt;
    float yOffset = abs(sin(iTime)*4.0)*vertMovementOn+vertJerk*vertJerk2*0.3;
    float y = mod(uv.y+yOffset,1.0);
 	float xOffset = (fuzzOffset + largeFuzzOffset) * horzFuzzOpt;
    float staticVal = 0.0;
    for (float y = -1.0; y <= 1.0; y += 1.0) {
        float maxDist = 5.0/200.0;
        float dist = y/200.0;
    	staticVal += staticV(vec2(uv.x,uv.y+dist))*(maxDist-abs(dist))*1.5;
    }
    staticVal *= bottomStaticOpt;
 	float red 	=   texture(	iChannel0, 	vec2(uv.x + xOffset -0.01*rgbOffsetOpt,y)).r+staticVal;
 	float green = 	texture(	iChannel0, 	vec2(uv.x + xOffset,	  y)).g+staticVal;
 	float blue 	=	texture(	iChannel0, 	vec2(uv.x + xOffset +0.01*rgbOffsetOpt,y)).b+staticVal;
 	vec3 color = vec3(red,green,blue);
 	float scanline = sin(uv.y*800.0)*0.04*scalinesOpt;
 	color -= scanline;
 	fragColor = vec4(color,1.0);
 }
--- a/tools/src/manipulative/VHS
+++ b/tools/src/manipulative/VHS
@@ -0,0 +1,66 @@
 //by Vladimir Storm 
 //https://twitter.com/vladstorm_
 #define t iTime
 //random hash
 vec4 hash42(vec2 p){
 	vec4 p4 = fract(vec4(p.xyxy) * vec4(443.8975,397.2973, 491.1871, 470.7827));
    p4 += dot(p4.wzxy, p4+19.19);
    return fract(vec4(p4.x * p4.y, p4.x*p4.z, p4.y*p4.w, p4.x*p4.w));
 }
 float hash( float n ){
    return fract(sin(n)*43758.5453123);
 }
 // 3d noise function (iq's)
 float n( in vec3 x ){
    vec3 p = floor(x);
    vec3 f = fract(x);
    f = f*f*(3.0-2.0*f);
    float n = p.x + p.y*57.0 + 113.0*p.z;
    float res = mix(mix(mix( hash(n+  0.0), hash(n+  1.0),f.x),
                        mix( hash(n+ 57.0), hash(n+ 58.0),f.x),f.y),
                    mix(mix( hash(n+113.0), hash(n+114.0),f.x),
                        mix( hash(n+170.0), hash(n+171.0),f.x),f.y),f.z);
    return res;
 }
 //tape noise
 float nn(vec2 p){
    float y = p.y;
    float s = t*2.;
    float v = (n( vec3(y*.01 +s, 			1., 1.0) ) + .0)
          	 *(n( vec3(y*.011+1000.0+s, 	1., 1.0) ) + .0) 
          	 *(n( vec3(y*.51+421.0+s, 	1., 1.0) ) + .0)   
        ;
    //v*= n( vec3( (fragCoord.xy + vec2(s,0.))*100.,1.0) );
   	v*= hash42(   vec2(p.x +t*0.01, p.y) ).x +.3 ;
    v = pow(v+.3, 1.);
 	if(v<.7) v = 0.;  //threshold
    return v;
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord ){
    vec2 uv = fragCoord.xy / iResolution.xy;
    float linesN = 240.; //fields per seconds
    float one_y = iResolution.y / linesN; //field line
    uv = floor(uv*iResolution.xy/one_y)*one_y;
 	float col =  nn(uv);
 	fragColor = vec4(vec3( col ),1.0);
 }
--- a/tools/src/manipulative/Video
+++ b/tools/src/manipulative/Video
@@ -0,0 +1,106 @@
 //
 // Description : Array and textureless GLSL 2D simplex noise function.
 //      Author : Ian McEwan, Ashima Arts.
 //  Maintainer : stegu
 //     Lastmod : 20110822 (ijm)
 //     License : Copyright (C) 2011 Ashima Arts. All rights reserved.
 //               Distributed under the MIT License. See LICENSE file.
 //               https://github.com/ashima/webgl-noise
 //               https://github.com/stegu/webgl-noise
 // 
 vec3 mod289(vec3 x) {
  return x - floor(x * (1.0 / 289.0)) * 289.0;
 }
 vec2 mod289(vec2 x) {
  return x - floor(x * (1.0 / 289.0)) * 289.0;
 }
 vec3 permute(vec3 x) {
  return mod289(((x*34.0)+1.0)*x);
 }
 float snoise(vec2 v)
  {
  const vec4 C = vec4(0.211324865405187,  // (3.0-sqrt(3.0))/6.0
                      0.366025403784439,  // 0.5*(sqrt(3.0)-1.0)
                     -0.577350269189626,  // -1.0 + 2.0 * C.x
                      0.024390243902439); // 1.0 / 41.0
 // First corner
  vec2 i  = floor(v + dot(v, C.yy) );
  vec2 x0 = v -   i + dot(i, C.xx);
 // Other corners
  vec2 i1;
  //i1.x = step( x0.y, x0.x ); // x0.x > x0.y ? 1.0 : 0.0
  //i1.y = 1.0 - i1.x;
  i1 = (x0.x > x0.y) ? vec2(1.0, 0.0) : vec2(0.0, 1.0);
  // x0 = x0 - 0.0 + 0.0 * C.xx ;
  // x1 = x0 - i1 + 1.0 * C.xx ;
  // x2 = x0 - 1.0 + 2.0 * C.xx ;
  vec4 x12 = x0.xyxy + C.xxzz;
  x12.xy -= i1;
 // Permutations
  i = mod289(i); // Avoid truncation effects in permutation
  vec3 p = permute( permute( i.y + vec3(0.0, i1.y, 1.0 ))
 		+ i.x + vec3(0.0, i1.x, 1.0 ));
  vec3 m = max(0.5 - vec3(dot(x0,x0), dot(x12.xy,x12.xy), dot(x12.zw,x12.zw)), 0.0);
  m = m*m ;
  m = m*m ;
 // Gradients: 41 points uniformly over a line, mapped onto a diamond.
 // The ring size 17*17 = 289 is close to a multiple of 41 (41*7 = 287)
  vec3 x = 2.0 * fract(p * C.www) - 1.0;
  vec3 h = abs(x) - 0.5;
  vec3 ox = floor(x + 0.5);
  vec3 a0 = x - ox;
 // Normalise gradients implicitly by scaling m
 // Approximation of: m *= inversesqrt( a0*a0 + h*h );
  m *= 1.79284291400159 - 0.85373472095314 * ( a0*a0 + h*h );
 // Compute final noise value at P
  vec3 g;
  g.x  = a0.x  * x0.x  + h.x  * x0.y;
  g.yz = a0.yz * x12.xz + h.yz * x12.yw;
  return 130.0 * dot(m, g);
 }
 float rand(vec2 co)
 {
   return fract(sin(dot(co.xy,vec2(12.9898,78.233))) * 43758.5453);
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
 	vec2 uv = fragCoord.xy / iResolution.xy;    
    float time = iTime * 2.0;
    // Create large, incidental noise waves
    float noise = max(0.0, snoise(vec2(time, uv.y * 0.3)) - 0.3) * (1.0 / 0.7);
    // Offset by smaller, constant noise waves
    noise = noise + (snoise(vec2(time*10.0, uv.y * 2.4)) - 0.5) * 0.15;
    // Apply the noise as x displacement for every line
    float xpos = uv.x - noise * noise * 0.25;
 	fragColor = texture(iChannel0, vec2(xpos, uv.y));
    // Mix in some random interference for lines
    fragColor.rgb = mix(fragColor.rgb, vec3(rand(vec2(uv.y * time))), noise * 0.3).rgb;
    // Apply a line pattern every 4 pixels
    if (floor(mod(fragCoord.y * 0.25, 2.0)) == 0.0)
    {
        fragColor.rgb *= 1.0 - (0.15 * noise);
    }
    // Shift green/blue channels (using the red channel)
    fragColor.g = mix(fragColor.r, texture(iChannel0, vec2(xpos + noise * 0.05, uv.y)).g, 0.25);
    fragColor.b = mix(fragColor.r, texture(iChannel0, vec2(xpos - noise * 0.05, uv.y)).b, 0.25);
 }
--- a/tools/src/reactive/AudioTest.frag
+++ b/tools/src/reactive/AudioTest.frag
@@ -0,0 +1,40 @@
 // Created by inigo quilez - iq/2013
 // https://www.youtube.com/c/InigoQuilez
 // https://iquilezles.org/
 // See also:
 //
 // Input - Keyboard    : https://www.shadertoy.com/view/lsXGzf
 // Input - Microphone  : https://www.shadertoy.com/view/llSGDh
 // Input - Mouse       : https://www.shadertoy.com/view/Mss3zH
 // Input - Sound       : https://www.shadertoy.com/view/Xds3Rr
 // Input - SoundCloud  : https://www.shadertoy.com/view/MsdGzn
 // Input - Time        : https://www.shadertoy.com/view/lsXGz8
 // Input - TimeDelta   : https://www.shadertoy.com/view/lsKGWV
 // Inout - 3D Texture  : https://www.shadertoy.com/view/4llcR4
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
    // create pixel coordinates
 	vec2 uv = fragCoord.xy / iResolution.xy;
    // the sound texture is 512x2
    int tx = int(uv.x*512.0);
 	// first row is frequency data (48Khz/4 in 512 texels, meaning 23 Hz per texel)
 	float fft  = texelFetch( iChannel0, ivec2(tx,0), 0 ).x; 
    // second row is the sound wave, one texel is one mono sample
    float wave = texelFetch( iChannel0, ivec2(tx,1), 0 ).x;
 	// convert frequency to colors
 	vec3 col = vec3( fft, 4.0*fft*(1.0-fft), 1.0-fft ) * fft;
    // add wave form on top	
 	col += 1.0 -  smoothstep( 0.0, 0.15, abs(wave - uv.y) );
 	// output final color
 	fragColor = vec4(col,1.0);
 }
--- a/tools/src/reactive/AudioTest2.frag
+++ b/tools/src/reactive/AudioTest2.frag
@@ -0,0 +1,37 @@
 /*
 2D LED Spectrum - Visualiser
 Based on Led Spectrum Analyser by: simesgreen - 27th February, 2013 https://www.shadertoy.com/view/Msl3zr
 2D LED Spectrum by: uNiversal - 27th May, 2015
 Creative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported License.
 */
 void mainImage( out vec4 fragColor, in vec2 fragCoord )
 {
    // create pixel coordinates
    vec2 uv = fragCoord.xy / iResolution.xy;
    // quantize coordinates
    const float bands = 30.0;
    const float segs = 40.0;
    vec2 p;
    p.x = floor(uv.x*bands)/bands;
    p.y = floor(uv.y*segs)/segs;
    // read frequency data from first row of texture
    float fft  = texture( iChannel0, vec2(p.x,0.0) ).x;
    // led color
    vec3 color = mix(vec3(0.0, 2.0, 0.0), vec3(2.0, 0.0, 0.0), sqrt(uv.y));
    // mask for bar graph
    float mask = (p.y < fft) ? 1.0 : 0.1;
    // led shape
    vec2 d = fract((uv - p) *vec2(bands, segs)) - 0.5;
    float led = smoothstep(0.5, 0.35, abs(d.x)) *
                smoothstep(0.5, 0.35, abs(d.y));
    vec3 ledColor = led*color*mask;
    // output final color
    fragColor = vec4(ledColor, 1.0);
 }
--- a/tools/src/reactive/Basic
+++ b/tools/src/reactive/Basic
@@ -0,0 +1,70 @@
 /* Simple audio visualizer by chronos
 // Feel free to use any part of the code and/or improve it further
 // Drop a link in the comments! :)
 // 
 // Recommended tracks:
 // https://soundcloud.com/kubbi/pathfinder
 // https://soundcloud.com/wearecastor/rad
 // https://soundcloud.com/jco-de/coronoid-soundtrack
 //
 */
 #define WIDTH 1.0
 float audio_freq( in sampler2D channel, in float f) { return texture( channel, vec2(f, 0.25) ).x; }
 float audio_ampl( in sampler2D channel, in float t) { return texture( channel, vec2(t, 0.75) ).x; }
 vec3 B2_spline(vec3 x) { // returns 3 B-spline functions of degree 2
    vec3 t = 3.0 * x;
    vec3 b0 = step(0.0, t)     * step(0.0, 1.0-t);
 	vec3 b1 = step(0.0, t-1.0) * step(0.0, 2.0-t);
 	vec3 b2 = step(0.0, t-2.0) * step(0.0, 3.0-t);
 	return 0.5 * (
    	b0 * pow(t, vec3(2.0)) +
    	b1 * (-2.0*pow(t, vec3(2.0)) + 6.0*t - 3.0) + 
    	b2 * pow(3.0-t,vec3(2.0))
    );
 }
 void mainImage( out vec4 fragColor, in vec2 fragCoord ) {
 	vec2 uv = fragCoord.xy / iResolution.xy;
    vec2 centered = 2.0 * uv - 1.0;
    centered.x *= iResolution.x / iResolution.y;
    float dist2 = dot(centered, centered);
    float clamped_dist = smoothstep(0.0, 1.0, dist2);
    float arclength    = abs(atan(centered.y, centered.x) / radians(360.0))+0.01;
    // Color variation functions
    float t = iTime / 100.0;
    float polychrome = (1.0 + sin(t*10.0))/2.0; // 0 -> uniform color, 1 -> full spectrum
    vec3 spline_args = fract(vec3(polychrome*uv.x-t) + vec3(0.0, -1.0/3.0, -2.0/3.0));
    vec3 spline = B2_spline(spline_args);
    float f = abs(centered.y);
    vec3 base_color  = vec3(1.0, 1.0, 1.0) - f*spline;
    vec3 flame_color = pow(base_color, vec3(3.0));
    vec3 disc_color  = 0.20 * base_color;
    vec3 wave_color  = 0.10 * base_color;
    vec3 flash_color = 0.05 * base_color;
    float sample1 = audio_freq(iChannel3, abs((uv.x - .5) / WIDTH) + 0.01);
    float sample2 = audio_ampl(iChannel3, clamped_dist);
    float sample3 = audio_ampl(iChannel3, arclength);
    float disp_dist = smoothstep(-0.2, -0.1, sample3-dist2);
    disp_dist *= (1.0 - disp_dist);
    vec3 color = vec3(0.0);
    // spline debug
    // vec3 s = smoothstep(-0.01, 0.01, spline-uv.y); color += (1.0-s) * s;
    float v = abs(uv.y - 0.5);
    color += flame_color * smoothstep(v, v*8.0, sample1);
    color += disc_color  * smoothstep(0.5, 1.0, sample2) * (1.0 - clamped_dist);
    color += flash_color * smoothstep(0.5, 1.0, sample3) * clamped_dist;
    color += wave_color  * disp_dist;
    color = pow(color, vec3(0.4545));
 	fragColor = vec4(color, 1.0);
 }