slang-shaders/scalenx/shaders/mmpx.slang

#version 450

// MMPX
// by Morgan McGuire and Mara Gagiu
// https://casual-effects.com/research/McGuire2021PixelArt/
// License: MIT
// adapted for slang by hunterk

layout(push_constant) uniform Push
{
	vec4 SourceSize;
	vec4 OriginalSize;
	vec4 OutputSize;
	uint FrameCount;
} params;

layout(std140, set = 0, binding = 0) uniform UBO
{
	mat4 MVP;
} global;

#pragma stage vertex
layout(location = 0) in vec4 Position;
layout(location = 1) in vec2 TexCoord;
layout(location = 0) out vec2 vTexCoord;

void main()
{
   gl_Position = global.MVP * Position;
   vTexCoord = TexCoord;
}

#pragma stage fragment
layout(location = 0) in vec2 vTexCoord;
layout(location = 0) out vec4 FragColor;
layout(set = 0, binding = 2) uniform sampler2D Source;

float luma(vec3 col){
   return dot(col, vec3(0.2126, 0.7152, 0.0722));
}

// I tried using a hash to speed these up but it didn't really help
bool same(vec3 B, vec3 A0){
   return all(equal(B, A0));
}

bool notsame(vec3 B, vec3 A0){
   return any(notEqual(B, A0));
}

bool all_eq2(vec3 B, vec3 A0, vec3 A1) {
    return (same(B,A0) && same(B,A1));
}

bool all_eq3(vec3 B, vec3 A0, vec3 A1, vec3 A2) {
    return (same(B,A0) && same(B,A1) && same(B,A2));
}

bool all_eq4(vec3 B, vec3 A0, vec3 A1, vec3 A2, vec3 A3) {
    return (same(B,A0) && same(B,A1) && same(B,A2) && same(B,A3));
}

bool any_eq3(vec3 B, vec3 A0, vec3 A1, vec3 A2) {
   return (same(B,A0) || same(B,A1) || same(B,A2));
}

bool none_eq2(vec3 B, vec3 A0, vec3 A1) {
   return (notsame(B,A0) && notsame(B,A1));
}

bool none_eq4(vec3 B, vec3 A0, vec3 A1, vec3 A2, vec3 A3) {
   return (notsame(B,A0) && notsame(B,A1) && notsame(B,A2) && notsame(B,A3));
}

#define src(c,d) texture(Source, vTexCoord + vec2(c,d) * params.SourceSize.zw).rgb

void main()
{
// these do nothing, but just for consistency with the original code...
   float srcX = 0.;
   float srcY = 0.;

// Our current pixel
   vec3 E = src(srcX+0.,srcY+0.);

// Input: A-I central 3x3 grid
   vec3 A = src(srcX-1.,srcY-1.);
   vec3 B = src(srcX+0.,srcY-1.);
   vec3 C = src(srcX+1.,srcY-1.);

   vec3 D = src(srcX-1.,srcY+0.);
   vec3 F = src(srcX+1.,srcY+0.);

   vec3 G = src(srcX-1.,srcY+1.);
   vec3 H = src(srcX+0.,srcY+1.);
   vec3 I = src(srcX+1.,srcY+1.);

// Default to Nearest magnification
   vec3 J = E;
   vec3 K = E;
   vec3 L = E;
   vec3 M = E;
// Go ahead and put this here so we can use an early return on the next
// line to save some cycles
   FragColor = vec4(E, 1.0);
   
// Skip constant 3x3 centers and just use nearest-neighbor
// them.  This gives a good speedup on spritesheets with
// lots of padding and full screen images with large
// constant regions such as skies.
// EDIT: this is a wash for me, but we'll keep it around
 if(same(E,A) && same(E,B) && same(E,C) && same(E,D) && same(E,F) && same(E,G) && same(E,H) && same(E,I)) return;

// Read additional values at the tips of the diamond pattern
   vec3 P  = src(srcX+0.,srcY-2.);
   vec3 Q  = src(srcX-2.,srcY+0.);
   vec3 R  = src(srcX+2.,srcY+0.);
   vec3 S  = src(srcX+0.,srcY+2.);

// Precompute luminances
   float Bl = luma(B);
   float Dl = luma(D);
   float El = luma(E);
   float Fl = luma(F);
   float Hl = luma(H);

// Round some corners and fill in 1:1 slopes, but preserve
// sharp right angles.
//
// In each expression, the left clause is from
// EPX and the others are new. EPX
// recognizes 1:1 single-pixel lines because it
// applies the rounding only to the LINE, and not
// to the background (it looks at the mirrored
// side).  It thus fails on thick 1:1 edges
// because it rounds *both* sides and produces an
// aliased edge shifted by 1 dst pixel.  (This
// also yields the mushroom-shaped arrow heads,
// where that 1-pixel offset runs up against the
// 2-pixel aligned end; this is an inherent
// problem with 2X in-palette scaling.)
//
// The 2nd clause clauses avoid *double* diagonal
// filling on 1:1 slopes to prevent them becoming
// aliased again. It does this by breaking
// symmetry ties using luminance when working with
// thick features (it allows thin and transparent
// features to pass always).
//
// The 3rd clause seeks to preserve square corners
// by considering the center value before
// rounding.
//
// The 4th clause identifies 1-pixel bumps on
// straight lines that are darker than their
// background, such as the tail on a pixel art
// "4", and prevents them from being rounded. This
// corrects for asymmetry in this case that the
// luminance tie breaker introduced.

// .------------ 1st ------------.      .----- 2nd ---------.      .------ 3rd -----.      .--------------- 4th -----------------------.
   if (((same(D,B) && notsame(D,H) && notsame(D,F))) && ((El>=Dl) || same(E,A)) && any_eq3(E,A,C,G) && ((El<Dl) || notsame(A,D) || notsame(E,P) || notsame(E,Q))) J=D;
   if (((same(B,F) && notsame(B,D) && notsame(B,H))) && ((El>=Bl) || same(E,C)) && any_eq3(E,A,C,I) && ((El<Bl) || notsame(C,B) || notsame(E,P) || notsame(E,R))) K=B;
   if (((same(H,D) && notsame(H,F) && notsame(H,B))) && ((El>=Hl) || same(E,G)) && any_eq3(E,A,G,I) && ((El<Hl) || notsame(G,H) || notsame(E,S) || notsame(E,Q))) L=H;
   if (((same(F,H) && notsame(F,B) && notsame(F,D))) && ((El>=Fl) || same(E,I)) && any_eq3(E,C,G,I) && ((El<Fl) || notsame(I,H) || notsame(E,R) || notsame(E,S))) M=F;

// Clean up disconnected line intersections.
//
// The first clause recognizes being on the inside
// of a diagonal corner and ensures that the "foreground"
// has been correctly identified to avoid
// ambiguous cases such as this:
//
//  o#o#
//  oo##
//  o#o#
//
// where trying to fix the center intersection of
// either the "o" or the "#" will leave the other
// one disconnected. This occurs, for example,
// when a pixel-art letter "B" or "R" is next to
// another letter on the right.
//
// The second clause ensures that the pattern is
// not a notch at the edge of a checkerboard
// dithering pattern.
// 
// >
//  .--------------------- 1st ------------------------.      .--------- 2nd -----------. 
   if ((notsame(E,F) && all_eq4(E,C,I,D,Q) && all_eq2(F,B,H)) && notsame(F,src(srcX+3.,srcY))) K=M=F;
   if ((notsame(E,D) && all_eq4(E,A,G,F,R) && all_eq2(D,B,H)) && notsame(D,src(srcX-3.,srcY))) J=L=D;
   if ((notsame(E,H) && all_eq4(E,G,I,B,P) && all_eq2(H,D,F)) && notsame(H,src(srcX,srcY+3.))) L=M=H;
   if ((notsame(E,B) && all_eq4(E,A,C,H,S) && all_eq2(B,D,F)) && notsame(B,src(srcX,srcY-3.))) J=K=B;

// Remove tips of bright triangles on dark
// backgrounds. The luminance tie breaker for 1:1
// pixel lines leaves these as sticking up squared
// off, which makes bright triangles and diamonds
// look bad.
   if ((Bl<El) && all_eq4(E,G,H,I,S) && none_eq4(E,A,D,C,F)) J=K=B;
   if ((Hl<El) && all_eq4(E,A,B,C,P) && none_eq4(E,D,G,I,F)) L=M=H;
   if ((Fl<El) && all_eq4(E,A,D,G,Q) && none_eq4(E,B,C,I,H)) K=M=F;
   if ((Dl<El) && all_eq4(E,C,F,I,R) && none_eq4(E,B,A,G,H)) J=L=D;

//////////////////////////////////////////////////////////////////////////////////
// Do further neighborhood peeking to identify
// 2:1 and 1:2 slopes of constant color.
// The first clause of each rule identifies a 2:1 slope line
// of consistent color.
//
// The second clause verifies that the line is separated from
// every adjacent pixel on one side and not part of a more
// complex pattern. Common subexpressions from the second clause
// are lifted to an outer test on pairs of rules.
// 
// The actions taken by rules are unusual in that they extend
// a color assigned by previous rules rather than drawing from
// the original source image.
//
// The comments show a diagram of the local
// neighborhood in which letters shown with the
// same shape and color must match each other and
// everything else without annotation must be
// different from the solid colored, square
// letters.
   if (notsame(H,B)) { // Common subexpression
                       // Above a 2:1 slope or -2:1 slope   ◢ ◣
                       // First:
      if (notsame(H,A) && notsame(H,E) && notsame(H,C)) {
                       // Second:
                       //     P 
                       //   Ⓐ B C .
                       // Q D 🄴 🅵 🆁
                       //   🅶 🅷 I
                       //     S
         if (all_eq3(H,G,F,R) && none_eq2(H,D,src(srcX+2.,srcY-1.))) L=M;
                       // Third:
                       //     P 
                       // . A B Ⓒ
                       // 🆀 🅳 🄴 F R
                       //   G 🅷 🅸
                       //     S
         if (all_eq3(H,I,D,Q) && none_eq2(H,F,src(srcX-2.,srcY-1.))) M=L;
      }
                        
                       // Below a 2:1 (◤) or -2:1 (◥) slope (reflect the above 2:1 patterns vertically)
      if (notsame(B,I) && notsame(B,G) && notsame(B,E)) {
                       //     P 
                       //   🅰 🅱 C
                       // Q D 🄴 🅵 🆁
                       //   Ⓖ H I .
                       //     S
         if (all_eq3(B,A,F,R) && none_eq2(B,D,src(srcX+2.,srcY+1.))) J=K;
                       //     P 
                       //   A 🅱 🅲
                       // 🆀 🅳 🄴 F R
                       // . G H Ⓘ 
                       //     S
         if (all_eq3(B,C,D,Q) && none_eq2(B,F,src(srcX-2.,srcY+1.))) K=J;
      }
   }

   if (notsame(F,D)) { // Common subexpression
                        
                       // Right of a -1:2 (\) or -1:2 (/) slope (reflect the left 1:2 patterns horizontally)
      if (notsame(D,I) && notsame(D,E) && notsame(D,C)) {
                       //     P
                       //   🅰 B Ⓒ
                       // Q 🅳 🄴 F R
                       //   G 🅷 I
                       //     🆂 .
         if (all_eq3(D,A,H,S) && none_eq2(D,B,src(srcX+1.,srcY+2.))) J=L;
                       //     🅿 .
                       //   A 🅱 C
                       // Q 🅳 🄴 F R
                       //   🅶 H Ⓘ
                       //     S
         if (all_eq3(D,G,B,P) && none_eq2(D,H,src(srcX+1.,srcY-2.))) L=J;
      }
                        
                       // Left of a 1:2 (/) slope or -1:2 (\) slope (transpose the above 2:1 patterns)
                       // Pull common none_eq subexpressions out

      if (notsame(F,E) && notsame(F,A) && notsame(F,G)) {
                       //     P     
                       //   Ⓐ B 🅲   
                       // Q D 🄴 🅵 R 
                       //   G 🅷 I   
                       //   . 🆂   
         if (all_eq3(F,C,H,S) && none_eq2(F,B,src(srcX-1.,srcY+2.))) K=M;
                       //   . 🅿
                       //   A 🅱 C
                       // Q D 🄴 🅵 R
                       //   Ⓖ H 🅸
                       //     S
         if (all_eq3(F,I,B,P) && none_eq2(F,H,src(srcX-1.,srcY-2.))) M=K;
      }
   }

// Determine which of our 4 output pixels we need to use
   vec2 a = fract(vTexCoord * params.SourceSize.xy);
   FragColor.rgb = (a.x < 0.5) ? (a.y < 0.5 ? J : L) : (a.y < 0.5 ? K : M);
}
add MMPX and EPX shaders and presets 2021-02-13 14:37:55 +11:00			`#version 450`

			`// MMPX`
			`// by Morgan McGuire and Mara Gagiu`
			`// https://casual-effects.com/research/McGuire2021PixelArt/`
			`// License: MIT`
			`// adapted for slang by hunterk`

			`layout(push_constant) uniform Push`
			`{`
			`vec4 SourceSize;`
			`vec4 OriginalSize;`
			`vec4 OutputSize;`
			`uint FrameCount;`
			`} params;`

			`layout(std140, set = 0, binding = 0) uniform UBO`
			`{`
			`mat4 MVP;`
			`} global;`

			`#pragma stage vertex`
			`layout(location = 0) in vec4 Position;`
			`layout(location = 1) in vec2 TexCoord;`
			`layout(location = 0) out vec2 vTexCoord;`

			`void main()`
			`{`
			`gl_Position = global.MVP * Position;`
			`vTexCoord = TexCoord;`
			`}`

			`#pragma stage fragment`
			`layout(location = 0) in vec2 vTexCoord;`
			`layout(location = 0) out vec4 FragColor;`
			`layout(set = 0, binding = 2) uniform sampler2D Source;`

			`float luma(vec3 col){`
			`return dot(col, vec3(0.2126, 0.7152, 0.0722));`
			`}`

			`// I tried using a hash to speed these up but it didn't really help`
			`bool same(vec3 B, vec3 A0){`
			`return all(equal(B, A0));`
			`}`

			`bool notsame(vec3 B, vec3 A0){`
			`return any(notEqual(B, A0));`
			`}`

			`bool all_eq2(vec3 B, vec3 A0, vec3 A1) {`
			`return (same(B,A0) && same(B,A1));`
			`}`

			`bool all_eq3(vec3 B, vec3 A0, vec3 A1, vec3 A2) {`
			`return (same(B,A0) && same(B,A1) && same(B,A2));`
			`}`

			`bool all_eq4(vec3 B, vec3 A0, vec3 A1, vec3 A2, vec3 A3) {`
			`return (same(B,A0) && same(B,A1) && same(B,A2) && same(B,A3));`
			`}`

			`bool any_eq3(vec3 B, vec3 A0, vec3 A1, vec3 A2) {`
			`return (same(B,A0) \|\| same(B,A1) \|\| same(B,A2));`
			`}`

			`bool none_eq2(vec3 B, vec3 A0, vec3 A1) {`
			`return (notsame(B,A0) && notsame(B,A1));`
			`}`

			`bool none_eq4(vec3 B, vec3 A0, vec3 A1, vec3 A2, vec3 A3) {`
			`return (notsame(B,A0) && notsame(B,A1) && notsame(B,A2) && notsame(B,A3));`
			`}`

			`#define src(c,d) texture(Source, vTexCoord + vec2(c,d) * params.SourceSize.zw).rgb`

			`void main()`
			`{`
			`// these do nothing, but just for consistency with the original code...`
			`float srcX = 0.;`
			`float srcY = 0.;`

			`// Our current pixel`
			`vec3 E = src(srcX+0.,srcY+0.);`

			`// Input: A-I central 3x3 grid`
			`vec3 A = src(srcX-1.,srcY-1.);`
			`vec3 B = src(srcX+0.,srcY-1.);`
			`vec3 C = src(srcX+1.,srcY-1.);`

			`vec3 D = src(srcX-1.,srcY+0.);`
			`vec3 F = src(srcX+1.,srcY+0.);`

			`vec3 G = src(srcX-1.,srcY+1.);`
			`vec3 H = src(srcX+0.,srcY+1.);`
			`vec3 I = src(srcX+1.,srcY+1.);`

			`// Default to Nearest magnification`
			`vec3 J = E;`
			`vec3 K = E;`
			`vec3 L = E;`
			`vec3 M = E;`
			`// Go ahead and put this here so we can use an early return on the next`
			`// line to save some cycles`
			`FragColor = vec4(E, 1.0);`

			`// Skip constant 3x3 centers and just use nearest-neighbor`
			`// them. This gives a good speedup on spritesheets with`
			`// lots of padding and full screen images with large`
			`// constant regions such as skies.`
			`// EDIT: this is a wash for me, but we'll keep it around`
			`if(same(E,A) && same(E,B) && same(E,C) && same(E,D) && same(E,F) && same(E,G) && same(E,H) && same(E,I)) return;`

			`// Read additional values at the tips of the diamond pattern`
			`vec3 P = src(srcX+0.,srcY-2.);`
			`vec3 Q = src(srcX-2.,srcY+0.);`
			`vec3 R = src(srcX+2.,srcY+0.);`
			`vec3 S = src(srcX+0.,srcY+2.);`

			`// Precompute luminances`
			`float Bl = luma(B);`
			`float Dl = luma(D);`
			`float El = luma(E);`
			`float Fl = luma(F);`
			`float Hl = luma(H);`

			`// Round some corners and fill in 1:1 slopes, but preserve`
			`// sharp right angles.`
			`//`
			`// In each expression, the left clause is from`
			`// EPX and the others are new. EPX`
			`// recognizes 1:1 single-pixel lines because it`
			`// applies the rounding only to the LINE, and not`
			`// to the background (it looks at the mirrored`
			`// side). It thus fails on thick 1:1 edges`
			`// because it rounds both sides and produces an`
			`// aliased edge shifted by 1 dst pixel. (This`
			`// also yields the mushroom-shaped arrow heads,`
			`// where that 1-pixel offset runs up against the`
			`// 2-pixel aligned end; this is an inherent`
			`// problem with 2X in-palette scaling.)`
			`//`
			`// The 2nd clause clauses avoid double diagonal`
			`// filling on 1:1 slopes to prevent them becoming`
			`// aliased again. It does this by breaking`
			`// symmetry ties using luminance when working with`
			`// thick features (it allows thin and transparent`
			`// features to pass always).`
			`//`
			`// The 3rd clause seeks to preserve square corners`
			`// by considering the center value before`
			`// rounding.`
			`//`
			`// The 4th clause identifies 1-pixel bumps on`
			`// straight lines that are darker than their`
			`// background, such as the tail on a pixel art`
			`// "4", and prevents them from being rounded. This`
			`// corrects for asymmetry in this case that the`
			`// luminance tie breaker introduced.`

			`// .------------ 1st ------------. .----- 2nd ---------. .------ 3rd -----. .--------------- 4th -----------------------.`
			`if (((same(D,B) && notsame(D,H) && notsame(D,F))) && ((El>=Dl) \|\| same(E,A)) && any_eq3(E,A,C,G) && ((El<Dl) \|\| notsame(A,D) \|\| notsame(E,P) \|\| notsame(E,Q))) J=D;`
			`if (((same(B,F) && notsame(B,D) && notsame(B,H))) && ((El>=Bl) \|\| same(E,C)) && any_eq3(E,A,C,I) && ((El<Bl) \|\| notsame(C,B) \|\| notsame(E,P) \|\| notsame(E,R))) K=B;`
			`if (((same(H,D) && notsame(H,F) && notsame(H,B))) && ((El>=Hl) \|\| same(E,G)) && any_eq3(E,A,G,I) && ((El<Hl) \|\| notsame(G,H) \|\| notsame(E,S) \|\| notsame(E,Q))) L=H;`
			`if (((same(F,H) && notsame(F,B) && notsame(F,D))) && ((El>=Fl) \|\| same(E,I)) && any_eq3(E,C,G,I) && ((El<Fl) \|\| notsame(I,H) \|\| notsame(E,R) \|\| notsame(E,S))) M=F;`

			`// Clean up disconnected line intersections.`
			`//`
			`// The first clause recognizes being on the inside`
			`// of a diagonal corner and ensures that the "foreground"`
			`// has been correctly identified to avoid`
			`// ambiguous cases such as this:`
			`//`
			`// o#o#`
			`// oo##`
			`// o#o#`
			`//`
			`// where trying to fix the center intersection of`
			`// either the "o" or the "#" will leave the other`
			`// one disconnected. This occurs, for example,`
			`// when a pixel-art letter "B" or "R" is next to`
			`// another letter on the right.`
			`//`
			`// The second clause ensures that the pattern is`
			`// not a notch at the edge of a checkerboard`
			`// dithering pattern.`
			`//`
			`// >`
			`// .--------------------- 1st ------------------------. .--------- 2nd -----------.`
			`if ((notsame(E,F) && all_eq4(E,C,I,D,Q) && all_eq2(F,B,H)) && notsame(F,src(srcX+3.,srcY))) K=M=F;`
			`if ((notsame(E,D) && all_eq4(E,A,G,F,R) && all_eq2(D,B,H)) && notsame(D,src(srcX-3.,srcY))) J=L=D;`
			`if ((notsame(E,H) && all_eq4(E,G,I,B,P) && all_eq2(H,D,F)) && notsame(H,src(srcX,srcY+3.))) L=M=H;`
			`if ((notsame(E,B) && all_eq4(E,A,C,H,S) && all_eq2(B,D,F)) && notsame(B,src(srcX,srcY-3.))) J=K=B;`

			`// Remove tips of bright triangles on dark`
			`// backgrounds. The luminance tie breaker for 1:1`
			`// pixel lines leaves these as sticking up squared`
			`// off, which makes bright triangles and diamonds`
			`// look bad.`
			`if ((Bl<El) && all_eq4(E,G,H,I,S) && none_eq4(E,A,D,C,F)) J=K=B;`
			`if ((Hl<El) && all_eq4(E,A,B,C,P) && none_eq4(E,D,G,I,F)) L=M=H;`
			`if ((Fl<El) && all_eq4(E,A,D,G,Q) && none_eq4(E,B,C,I,H)) K=M=F;`
			`if ((Dl<El) && all_eq4(E,C,F,I,R) && none_eq4(E,B,A,G,H)) J=L=D;`

			`//////////////////////////////////////////////////////////////////////////////////`
			`// Do further neighborhood peeking to identify`
			`// 2:1 and 1:2 slopes of constant color.`
			`// The first clause of each rule identifies a 2:1 slope line`
			`// of consistent color.`
			`//`
			`// The second clause verifies that the line is separated from`
			`// every adjacent pixel on one side and not part of a more`
			`// complex pattern. Common subexpressions from the second clause`
			`// are lifted to an outer test on pairs of rules.`
			`//`
			`// The actions taken by rules are unusual in that they extend`
			`// a color assigned by previous rules rather than drawing from`
			`// the original source image.`
			`//`
			`// The comments show a diagram of the local`
			`// neighborhood in which letters shown with the`
			`// same shape and color must match each other and`
			`// everything else without annotation must be`
			`// different from the solid colored, square`
			`// letters.`
			`if (notsame(H,B)) { // Common subexpression`
			`// Above a 2:1 slope or -2:1 slope ◢ ◣`
			`// First:`
			`if (notsame(H,A) && notsame(H,E) && notsame(H,C)) {`
			`// Second:`
			`// P`
			`// Ⓐ B C .`
			`// Q D 🄴 🅵 🆁`
			`// 🅶 🅷 I`
			`// S`
			`if (all_eq3(H,G,F,R) && none_eq2(H,D,src(srcX+2.,srcY-1.))) L=M;`
			`// Third:`
			`// P`
			`// . A B Ⓒ`
			`// 🆀 🅳 🄴 F R`
			`// G 🅷 🅸`
			`// S`
			`if (all_eq3(H,I,D,Q) && none_eq2(H,F,src(srcX-2.,srcY-1.))) M=L;`
			`}`

			`// Below a 2:1 (◤) or -2:1 (◥) slope (reflect the above 2:1 patterns vertically)`
			`if (notsame(B,I) && notsame(B,G) && notsame(B,E)) {`
			`// P`
			`// 🅰 🅱 C`
			`// Q D 🄴 🅵 🆁`
			`// Ⓖ H I .`
			`// S`
			`if (all_eq3(B,A,F,R) && none_eq2(B,D,src(srcX+2.,srcY+1.))) J=K;`
			`// P`
			`// A 🅱 🅲`
			`// 🆀 🅳 🄴 F R`
			`// . G H Ⓘ`
			`// S`
			`if (all_eq3(B,C,D,Q) && none_eq2(B,F,src(srcX-2.,srcY+1.))) K=J;`
			`}`
			`}`

			`if (notsame(F,D)) { // Common subexpression`

			`// Right of a -1:2 (\) or -1:2 (/) slope (reflect the left 1:2 patterns horizontally)`
			`if (notsame(D,I) && notsame(D,E) && notsame(D,C)) {`
			`// P`
			`// 🅰 B Ⓒ`
			`// Q 🅳 🄴 F R`
			`// G 🅷 I`
			`// 🆂 .`
			`if (all_eq3(D,A,H,S) && none_eq2(D,B,src(srcX+1.,srcY+2.))) J=L;`
			`// 🅿 .`
			`// A 🅱 C`
			`// Q 🅳 🄴 F R`
			`// 🅶 H Ⓘ`
			`// S`
			`if (all_eq3(D,G,B,P) && none_eq2(D,H,src(srcX+1.,srcY-2.))) L=J;`
			`}`

			`// Left of a 1:2 (/) slope or -1:2 (\) slope (transpose the above 2:1 patterns)`
			`// Pull common none_eq subexpressions out`

			`if (notsame(F,E) && notsame(F,A) && notsame(F,G)) {`
			`// P`
			`// Ⓐ B 🅲`
			`// Q D 🄴 🅵 R`
			`// G 🅷 I`
			`// . 🆂`
			`if (all_eq3(F,C,H,S) && none_eq2(F,B,src(srcX-1.,srcY+2.))) K=M;`
			`// . 🅿`
			`// A 🅱 C`
			`// Q D 🄴 🅵 R`
			`// Ⓖ H 🅸`
			`// S`
			`if (all_eq3(F,I,B,P) && none_eq2(F,H,src(srcX-1.,srcY-2.))) M=K;`
			`}`
			`}`

			`// Determine which of our 4 output pixels we need to use`
			`vec2 a = fract(vTexCoord * params.SourceSize.xy);`
			`FragColor.rgb = (a.x < 0.5) ? (a.y < 0.5 ? J : L) : (a.y < 0.5 ? K : M);`
			`}`