/*
* Our Paint: A light weight GPU powered painting program.
* Copyright (C) 2022-2023 Wu Yiming
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#include "ourpaint.h"
const char OUR_SHADER_VERSION_430[]="#version 430\n#define WORKGROUP_SIZE 32";
const char OUR_SHADER_VERSION_320ES[]="#version 320 es\n#define OUR_GLES\n#define WORKGROUP_SIZE 16";
const char OUR_CANVAS_SHADER[]=R"(
layout(local_size_x = WORKGROUP_SIZE, local_size_y = WORKGROUP_SIZE, local_size_z = 1) in;
#ifdef OUR_GLES
precision highp uimage2D;
precision highp float;
precision highp int;
layout(r32ui, binding = 0) uniform uimage2D img;
layout(r32ui, binding = 1) coherent uniform uimage2D smudge_buckets;
#else
layout(rgba16ui, binding = 0) uniform uimage2D img;
layout(rgba16ui, binding = 1) coherent uniform uimage2D smudge_buckets;
#endif
uniform int uCanvasType;
uniform int uCanvasRandom;
uniform float uCanvasFactor;
uniform ivec2 uImageOffset;
uniform ivec2 uBrushCorner;
uniform vec2 uBrushCenter;
uniform float uBrushSize;
uniform float uBrushHardness;
uniform float uBrushSmudge;
uniform float uBrushSlender;
uniform float uBrushAngle;
uniform vec2 uBrushDirection;
uniform float uBrushForce;
uniform float uBrushGunkyness;
uniform float uBrushRecentness;
uniform vec4 uBrushColor;
uniform vec4 uBackgroundColor;
uniform int uBrushErasing;
uniform int uBrushMix;
#ifdef OUR_GLES
uniform int uBrushRoutineSelectionES;
uniform int uMixRoutineSelectionES;
vec4 cunpack(uint d){
return vec4(float(d&0xFFu)/255.,float((d>>8u)&0xFFu)/255.,float((d>>16u)&0xFFu)/255.,float((d>>24u)&0xFFu)/255.);
}
uvec4 cpack(vec4 c){
uint v= uint(uint(c.r*255.) | (uint(c.g*255.)<<8u) | (uint(c.b*255.)<<16u) | (uint(c.a*255.)<<24u));
return uvec4(v,v,v,v);
}
#define OurImageLoad(img, p) \
(cunpack(imageLoad(img,p).x))
#define OurImageStore(img, p, color) \
imageStore(img,p,cpack(color))
#else
#define OurImageLoad(img, p) \
(vec4(imageLoad(img,p))/65535.)
#define OurImageStore(img, p, color) \
imageStore(img,p,uvec4(vec4(color)*65535.))
#endif
const vec4 p1_22=vec4(1.0/2.2,1.0/2.2,1.0/2.2,1.0/2.2);
const vec4 p22=vec4(2.2,2.2,2.2,2.2);
const float WGM_EPSILON=0.001f;
const float T_MATRIX_SMALL[30] = float[30](0.026595621243689,0.049779426257903,0.022449850859496,-0.218453689278271
,-0.256894883201278,0.445881722194840,0.772365886289756,0.194498761382537
,0.014038157587820,0.007687264480513
,-0.032601672674412,-0.061021043498478,-0.052490001018404
,0.206659098273522,0.572496335158169,0.317837248815438,-0.021216624031211
,-0.019387668756117,-0.001521339050858,-0.000835181622534
,0.339475473216284,0.635401374177222,0.771520797089589,0.113222640692379
,-0.055251113343776,-0.048222578468680,-0.012966666339586
,-0.001523814504223,-0.000094718948810,-0.000051604594741);
const float spectral_r_small[10] = float[10](0.009281362787953,0.009732627042016,0.011254252737167,0.015105578649573
,0.024797924177217,0.083622585502406,0.977865045723212,1.000000000000000
,0.999961046144372,0.999999992756822);
const float spectral_g_small[10] = float[10](0.002854127435775,0.003917589679914,0.012132151699187,0.748259205918013
,1.000000000000000,0.865695937531795,0.037477469241101,0.022816789725717
,0.021747419446456,0.021384940572308);
const float spectral_b_small[10] = float[10](0.537052150373386,0.546646402401469,0.575501819073983,0.258778829633924
,0.041709923751716,0.012662638828324,0.007485593127390,0.006766900622462
,0.006699764779016,0.006676219883241);
void rgb_to_spectral (vec3 rgb, out float spectral_[10]) {
float offset = 1.0 - WGM_EPSILON;
float r = rgb.r * offset + WGM_EPSILON;
float g = rgb.g * offset + WGM_EPSILON;
float b = rgb.b * offset + WGM_EPSILON;
float spec_r[10] = float[10](0.,0.,0.,0.,0.,0.,0.,0.,0.,0.); for (int i=0; i < 10; i++) {spec_r[i] = spectral_r_small[i] * r;}
float spec_g[10] = float[10](0.,0.,0.,0.,0.,0.,0.,0.,0.,0.); for (int i=0; i < 10; i++) {spec_g[i] = spectral_g_small[i] * g;}
float spec_b[10] = float[10](0.,0.,0.,0.,0.,0.,0.,0.,0.,0.); for (int i=0; i < 10; i++) {spec_b[i] = spectral_b_small[i] * b;}
for (int i=0; i<10; i++) {spectral_[i] = spec_r[i] + spec_g[i] + spec_b[i];}
}
vec3 spectral_to_rgb (float spectral[10]) {
float offset = 1.0 - WGM_EPSILON;
// We need this tmp. array to allow auto vectorization. <-- How about on GPU?
float tmp[3] = float[3](0.,0.,0.);
for (int i=0; i<10; i++) {
tmp[0] += T_MATRIX_SMALL[i] * spectral[i];
tmp[1] += T_MATRIX_SMALL[10+i] * spectral[i];
tmp[2] += T_MATRIX_SMALL[20+i] * spectral[i];
}
vec3 rgb_;
for (int i=0; i<3; i++) {rgb_[i] = clamp((tmp[i] - WGM_EPSILON) / offset, 0.0f, 1.0f);}
return rgb_;
}
vec2 hash( vec2 p ){
p = vec2( dot(p,vec2(127.1,311.7)), dot(p,vec2(269.5,183.3)) );
return -1.0 + 2.0*fract(sin(p)*43758.5453123);
}
float rand(vec2 co){
return fract(sin(dot(co, vec2(12.9898, 78.233))) * 43758.5453);
}
float noise(in vec2 p){ // from iq
const float K1 = 0.366025404; // (sqrt(3)-1)/2;
const float K2 = 0.211324865; // (3-sqrt(3))/6;
vec2 i = floor( p + (p.x+p.y)*K1 );
vec2 a = p - i + (i.x+i.y)*K2;
float m = step(a.y,a.x);
vec2 o = vec2(m,1.0-m);
vec2 b = a - o + K2;
vec2 c = a - 1.0 + 2.0*K2;
vec3 h = max( 0.5-vec3(dot(a,a), dot(b,b), dot(c,c) ), 0.0 );
vec3 n = h*h*h*h*vec3( dot(a,hash(i+0.0)), dot(b,hash(i+o)), dot(c,hash(i+1.0)));
return dot( n, vec3(70.0) );
}
#define HEIGHT_STRAND(x,y) abs(fract(x)-.5)<.48? \
(.4+.2*sin(3.14*(y+ceil(x))))* \
((max(abs(sin(3.14*x*2.)+0.2),abs(sin(3.14*x*2.)-0.2))+2.*abs(sin(3.14*x)))/2.+0.5):0.1
#define PATTERN_CANVAS(x,y) \
(max(HEIGHT_STRAND((x),(y)),HEIGHT_STRAND(-(y),(x))))
float HEIGHT_CANVAS(float x,float y){
if(uCanvasType == 1){
return PATTERN_CANVAS(x,y);
}else if(uCanvasType == 2){
vec2 uv=vec2(x,y); float f; uv*=0.1; // from iq
f = 0.2*noise( uv ); uv*=5.;
f += 0.6*noise( uv ); uv*=3.;
f += 0.5*noise( uv );
f = 0.55 + 0.55*f;
return pow(f,0.5);
}
return 1.;
}
float SampleCanvas(vec2 U, vec2 dir,float rfac, float force, float gunky){
if(uCanvasType==0 || abs(gunky)<1.e-2){ return rfac; }
U+=vec2(uImageOffset); U/=20.3; U.x=U.x+rand(U)/10.; U.y=U.y+rand(U)/10.;
mat2 m = mat2(1.6,1.2,-1.2,1.6); vec2 _uv=U; _uv.x+=float(uCanvasRandom%65535)/174.41; _uv.y+=float(uCanvasRandom%65535)/439.87; _uv/=500.;
U.x+=noise(_uv)*2.1; _uv = m*_uv; U.x+=noise(_uv)*0.71;
_uv.y+=365.404;
U.y+=noise(_uv)*1.9; _uv = m*_uv; U.y+=noise(_uv)*0.83;
float d=0.1;
float h=HEIGHT_CANVAS(U.x,U.y);
float hr=HEIGHT_CANVAS(U.x+d,U.y);
float hu=HEIGHT_CANVAS(U.x,U.y+d);
vec3 vx=normalize(vec3(d,0,hr)-vec3(0,0,h)),vy=normalize(vec3(0,d,hu)-vec3(0,0,h)),vz=cross(vx,vy);
float useforce=force*rfac;
float scrape=dot(normalize(vz),vec3(-normalize(dir).xy,0))*mix(0.3,1.,useforce);
float top=h-(1.-pow(useforce,1.5)*2.); float tophard=smoothstep(0.4,0.6,top);
float fac=(gunky>=0.)?mix(mix(1.,top,gunky),tophard,gunky):mix(1.,1.-h,-gunky*0.8);
fac=max(fac,scrape*clamp(gunky,0.,1.));
fac=clamp(fac,0.,1.);
fac*=rfac;
return mix(rfac,fac,uCanvasFactor);
}
#ifndef OUR_GLES
subroutine vec4 MixRoutines(vec4 a, vec4 b, float fac_a);
#endif
#ifndef OUR_GLES
subroutine(MixRoutines)
#endif
vec4 DoMixNormal(vec4 a, vec4 b, float fac_a){
return mix(a,b,1.0f-fac_a);
}
#ifndef OUR_GLES
subroutine(MixRoutines)
#endif
vec4 DoMixSpectral(vec4 a, vec4 b, float fac_a){
vec4 result = vec4(0,0,0,0);
result.a=mix(a.a,b.a,1.0f-fac_a);
float spec_a[10] = float[10](0.,0.,0.,0.,0.,0.,0.,0.,0.,0.); rgb_to_spectral(a.rgb, spec_a);
float spec_b[10] = float[10](0.,0.,0.,0.,0.,0.,0.,0.,0.,0.); rgb_to_spectral(b.rgb, spec_b);
float spectralmix[10] = float[10](0.,0.,0.,0.,0.,0.,0.,0.,0.,0.);
for (int i=0; i < 10; i++) { spectralmix[i] = pow(spec_a[i], fac_a) * pow(spec_b[i], 1.0f-fac_a); }
result.rgb=spectral_to_rgb(spectralmix);
return result;
}
#ifdef OUR_GLES
vec4 uMixRoutineSelection(vec4 a, vec4 b, float fac_a){
if(uMixRoutineSelectionES==0){ return DoMixNormal(a,b,fac_a); }
else{ return DoMixSpectral(a,b,fac_a); }
}
#else
subroutine uniform MixRoutines uMixRoutineSelection;
#endif
vec4 spectral_mix(vec4 a, vec4 b, float fac_a){
return uMixRoutineSelection(a,b,fac_a);
}
vec4 spectral_mix_unpre(vec4 colora, vec4 colorb, float fac){
vec4 ca=(colora.a==0.0f)?colora:vec4(colora.rgb/colora.a,colora.a);
vec4 cb=(colorb.a==0.0f)?colorb:vec4(colorb.rgb/colorb.a,colorb.a);
float af=colora.a*(1.0f-fac);
float aa=af/(af+fac*colorb.a+0.000001);
vec4 result=spectral_mix(ca,cb,aa);
result.a=mix(colora.a,colorb.a,fac);
return vec4(result.rgb*result.a,result.a);
}
float atan2(in float y, in float x){
bool s = (abs(x) > abs(y)); return mix(3.1415926535/2.0 - atan(x,y), atan(y,x), s);
}
vec2 rotate(vec2 v, float angle) {
float s = sin(angle); float c = cos(angle);
return mat2(c,-s,s,c) * v;
}
float brightness(vec4 color) {
return color.r*0.2126+color.b*0.7152+color.g*0.0722;
}
vec4 mix_over(vec4 colora, vec4 colorb){
vec4 a=(colora.a==0.0f)?colora:vec4(colora.rgb/colora.a,colora.a);
vec4 b=(colorb.a==0.0f)?colorb:vec4(colorb.rgb/colorb.a,colorb.a);
vec4 m=vec4(0,0,0,0); float aa=colora.a/(colora.a+(1.0f-colora.a)*colorb.a+0.0001);
m=spectral_mix(a,b,aa);
m.a=colora.a+colorb.a*(1.0f-colora.a);
m=vec4(m.rgb*m.a,m.a);
return m;
}
int dab(float d, vec2 fpx, vec4 color, float size, float hardness, float smudge, vec4 smudge_color, vec4 last_color, out vec4 final){
vec4 cc=color;
float fac=1.0f-pow(d/size,1.0f+1.0f/(1.0f-hardness+1e-4));
float canvas=SampleCanvas(fpx,uBrushDirection,fac,uBrushForce,uBrushGunkyness);
cc.a=color.a*canvas*(1.0f-smudge); cc.rgb=cc.rgb*cc.a;
float erasing=float(uBrushErasing);
cc=cc*(1.0f-erasing);
// this looks better than the one commented out below
vec4 c2=spectral_mix_unpre(last_color,smudge_color,smudge*fac*color.a*canvas);
c2=mix_over(cc,c2);
//vec4 c2=mix_over(cc,last_color);
//c2=spectral_mix_unpre(c2,smudge_color,smudge*fac*color.a*canvas);
c2=spectral_mix_unpre(c2,c2*(1.0f-fac*color.a),erasing*canvas);
final=c2;
return 1;
}
#ifndef saturate
#define saturate(v) clamp(v, 0., 1.)
#endif
const float HCV_EPSILON = 1e-10;
const float HCY_EPSILON = 1e-10;
vec3 hue_to_rgb(float hue){
float R = abs(hue * 6. - 3.) - 1.;
float G = 2. - abs(hue * 6. - 2.);
float B = 2. - abs(hue * 6. - 4.);
return saturate(vec3(R,G,B));
}
vec3 hcy_to_rgb(vec3 hcy){
const vec3 HCYwts = vec3(0.299, 0.587, 0.114);
vec3 RGB = hue_to_rgb(hcy.x);
float Z = dot(RGB, HCYwts);
if (hcy.z < Z) { hcy.y *= hcy.z / Z; }
else if (Z < 1.) { hcy.y *= (1. - hcy.z) / (1. - Z); }
return (RGB - Z) * hcy.y + hcy.z;
}
vec3 rgb_to_hcv(vec3 rgb){
// Based on work by Sam Hocevar and Emil Persson
vec4 P = (rgb.g < rgb.b) ? vec4(rgb.bg, -1.0, 2.0/3.0) : vec4(rgb.gb, 0.0, -1.0/3.0);
vec4 Q = (rgb.r < P.x) ? vec4(P.xyw, rgb.r) : vec4(rgb.r, P.yzx);
float C = Q.x - min(Q.w, Q.y);
float H = abs((Q.w - Q.y) / (6. * C + HCV_EPSILON) + Q.z);
return vec3(H, C, Q.x);
}
vec3 rgb_to_hcy(vec3 rgb){
const vec3 HCYwts = vec3(0.299, 0.587, 0.114);
// Corrected by David Schaeffer
vec3 HCV = rgb_to_hcv(rgb);
float Y = dot(rgb, HCYwts);
float Z = dot(hue_to_rgb(HCV.x), HCYwts);
if (Y < Z) { HCV.y *= Z / (HCY_EPSILON + Y); }
else { HCV.y *= (1. - Z) / (HCY_EPSILON + 1. - Y); }
return vec3(HCV.x, HCV.y, Y);
}
#ifndef OUR_GLES
subroutine void BrushRoutines();
#endif
#ifndef OUR_GLES
subroutine(BrushRoutines)
#endif
void DoDabs(){
ivec2 px = ivec2(gl_GlobalInvocationID.xy)+uBrushCorner;
if(px.x<0||px.y<0||px.x>1024||px.y>1024) return;
vec2 fpx=vec2(px),origfpx=fpx;
fpx=uBrushCenter+rotate(fpx-uBrushCenter,uBrushAngle);
fpx.x=uBrushCenter.x+(fpx.x-uBrushCenter.x)*(1.+uBrushSlender);
float dd=distance(fpx,uBrushCenter); if(dd>uBrushSize) return;
vec4 dabc=OurImageLoad(img, px);
vec4 smudgec=pow(spectral_mix_unpre(pow(OurImageLoad(smudge_buckets,ivec2(1,0)),p1_22),pow(OurImageLoad(smudge_buckets,ivec2(0,0)),p1_22),uBrushRecentness),p22);
vec4 final_color;
dab(dd,origfpx,uBrushColor,uBrushSize,uBrushHardness,uBrushSmudge,smudgec,dabc,final_color);
if(final_color.a>0.){
if(uBrushMix==0){ dabc=final_color; }
else if(uBrushMix==1){ dabc.rgb=final_color.rgb/final_color.a*dabc.a;}
else if(uBrushMix==2){ vec3 xyz=rgb_to_hcy(dabc.rgb); xyz.xy=rgb_to_hcy(final_color.rgb).xy; dabc.rgb=hcy_to_rgb(xyz); }
else if(uBrushMix==3){ dabc.rgb=dabc.rgb+final_color.rgb*0.01;dabc.a=dabc.a*0.99+final_color.a*0.01; }
OurImageStore(img, px, dabc);
}
}
#ifndef OUR_GLES
subroutine(BrushRoutines)
#endif
void DoSample(){
ivec2 p=ivec2(gl_GlobalInvocationID.xy);
int DoSample=1; vec4 color;
if(p.y==0){
vec2 sp=round(vec2(sin(float(p.x)),cos(float(p.x)))*uBrushSize);
ivec2 px=ivec2(sp)+uBrushCorner; if(px.x<0||px.y<0||px.x>=1024||px.y>=1024){ DoSample=0; }
if(DoSample!=0){
ivec2 b=uBrushCorner; if(b.x>=0&&b.y>=0&&b.x<1024&&b.y<1024){ OurImageStore(smudge_buckets,ivec2(128+WORKGROUP_SIZE,0),OurImageLoad(img, b)); }
color=OurImageLoad(img, px);
OurImageStore(smudge_buckets,ivec2(p.x+128,0),color);
}
}else{DoSample=0;}
memoryBarrier();barrier(); if(DoSample==0) return;
if(uBrushErasing==0 || p.x!=0) return;
color=vec4(0.,0.,0.,0.); for(int i=0;i>8u)&0xFFu)/255.,float((d>>16u)&0xFFu)/255.,float((d>>24u)&0xFFu)/255.);
}
uvec4 cpack(vec4 c){
uint v= uint(uint(c.r*255.) | (uint(c.g*255.)<<8u) | (uint(c.b*255.)<<16u) | (uint(c.a*255.)<<24u));
return uvec4(v,v,v,v);
}
#define OurImageLoad(img, p) \
(cunpack(imageLoad(img,p).x))
#define OurImageStore(img, p, color) \
imageStore(img,p,cpack(color))
#else
#define OurImageLoad(img, p) \
(vec4(imageLoad(img,p))/65535.)
#define OurImageStore(img, p, color) \
imageStore(img,p,uvec4(vec4(color)*65535.))
#endif
vec4 mix_over(vec4 colora, vec4 colorb){
colora=colora*uAlphaTop/uAlphaBottom;
vec4 c; c.a=colora.a+colorb.a*(1.0f-colora.a);
c.rgb=(colora.rgb+colorb.rgb*(1.0f-colora.a));
return c;
}
vec4 add_over(vec4 colora, vec4 colorb){
colora=colora*uAlphaTop/uAlphaBottom;
vec4 a=colora+colorb; a.a=clamp(a.a,0.,1.); return a;
}
void main() {
ivec2 px=ivec2(gl_GlobalInvocationID.xy);
vec4 c1=OurImageLoad(top,px); vec4 c2=OurImageLoad(bottom,px);
vec4 c=(uBlendMode==0)?mix_over(c1,c2):add_over(c1,c2);
OurImageStore(bottom,px,c);
OurImageStore(top,px,vec4(1.));
}
)";