mirror of
https://github.com/Ttanasart-pt/Pixel-Composer.git
synced 2024-12-26 15:06:22 +01:00
327 lines
No EOL
12 KiB
GLSL
327 lines
No EOL
12 KiB
GLSL
//
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// Simple passthrough fragment shader
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//
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varying vec2 v_vTexcoord;
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varying vec4 v_vColour;
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uniform vec2 dimension;
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//enables 2:1 slopes. otherwise only uses 45 degree slopes
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#define SLOPE
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//cleans up small detail slope transitions (if SLOPE is enabled)
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//if only using for rotation, CLEANUP has negligable effect and should be disabled for speed
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#define CLEANUP
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//the color with the highest priority.
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// other colors will be tested based on distance to this
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// color to determine which colors take priority for overlaps.
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/* uniform */ vec3 highestColor = vec3(1., 1., 1.);
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//how close two colors should be to be considered "similar".
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// can group shapes of visually similar colors, but creates
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// some artifacting and should be kept as low as possible.
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/* uniform */ float similarThreshold = 0.0;
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/* uniform */ float lineWidth = 1.0;
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const float scale = 4.0;
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const mat3 yuv_matrix = mat3(vec3(0.299, 0.587, 0.114), vec3(-0.169, -0.331, 0.5), vec3(0.5, -0.419, -0.081));
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const mat3 yuv_matrix_t = mat3(vec3(0.299, -0.169, 0.5), vec3(0.587, -0.331, -0.419), vec3(0.114, 0.5, -0.081));
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vec3 yuv(vec3 col){
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return yuv_matrix_t * col;
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}
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bool similar(vec4 col1, vec4 col2){
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return (col1.a == 0. && col2.a == 0.) || distance(col1, col2) <= similarThreshold;
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}
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//multiple versions because godot doesn't support function overloading
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//note: inner check should ideally check between all permutations
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// but this is good enough, and faster
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bool similar3(vec4 col1, vec4 col2, vec4 col3){
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return similar(col1, col2) && similar(col2, col3);
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}
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bool similar4(vec4 col1, vec4 col2, vec4 col3, vec4 col4){
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return similar(col1, col2) && similar(col2, col3) && similar(col3, col4);
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}
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bool similar5(vec4 col1, vec4 col2, vec4 col3, vec4 col4, vec4 col5){
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return similar(col1, col2) && similar(col2, col3) && similar(col3, col4) && similar(col4, col5);
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}
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bool higher(vec4 thisCol, vec4 otherCol){
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if(similar(thisCol, otherCol)) return false;
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if(thisCol.a == otherCol.a){
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// return yuv(thisCol.rgb).x > yuv(otherCol.rgb).x;
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// return distance(yuv(thisCol.rgb), yuv(highestColor)) < distance(yuv(otherCol.rgb), yuv(highestColor));
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return distance(thisCol.rgb, highestColor) < distance(otherCol.rgb, highestColor);
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} else {
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return thisCol.a > otherCol.a;
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}
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}
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vec4 higherCol(vec4 thisCol, vec4 otherCol){
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return higher(thisCol, otherCol) ? thisCol : otherCol;
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}
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//color distance
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float cd(vec4 col1, vec4 col2){
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return distance(col1.rgba, col2.rgba);
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}
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float distToLine(vec2 testPt, vec2 pt1, vec2 pt2, vec2 dir){
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vec2 lineDir = pt2 - pt1;
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vec2 perpDir = vec2(lineDir.y, -lineDir.x);
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vec2 dirToPt1 = pt1 - testPt;
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return (dot(perpDir, dir) > 0.0 ? 1.0 : -1.0) * (dot(normalize(perpDir), dirToPt1));
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}
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//based on down-forward direction
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vec4 sliceDist(vec2 point, vec2 mainDir, vec2 pointDir, vec4 u, vec4 uf, vec4 uff, vec4 b, vec4 c, vec4 f, vec4 ff, vec4 db, vec4 d, vec4 df, vec4 dff, vec4 ddb, vec4 dd, vec4 ddf){
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#ifdef SLOPE
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float minWidth = 0.44;
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float maxWidth = 1.142;
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#else
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float minWidth = 0.0;
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float maxWidth = 1.4;
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#endif
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float _lineWidth = max(minWidth, min(maxWidth, lineWidth));
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point = mainDir * (point - 0.5) + 0.5; //flip point
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//edge detection
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float distAgainst = 4.0 * cd(f,d) + cd(uf,c) + cd(c,db) + cd(ff,df) + cd(df,dd);
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float distTowards = 4.0 * cd(c,df) + cd(u,f) + cd(f,dff) + cd(b,d) + cd(d,ddf);
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bool shouldSlice =
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(distAgainst < distTowards)
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|| (distAgainst < distTowards + 0.001) && !higher(c, f); //equivalent edges edge case
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if(similar4(f, d, b, u) && similar3(uf, df, db/*, ub*/) && !similar(c, f)){ //checkerboard edge case
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shouldSlice = false;
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}
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if(!shouldSlice) return vec4(-1.0);
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//only applicable for very large lineWidth (>1.3)
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// if(similar3(c, f, df)){ //don't make slice for same color
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// return vec4(-1.0);
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// }
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float dist = 1.0;
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bool flip = false;
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vec2 center = vec2(0.5, 0.5);
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#ifdef SLOPE
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if(similar3(f, d, db) && !similar3(f, d, b) && !similar(uf, db)){ //lower shallow 2:1 slant
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if(similar(c, df) && higher(c, f)){ //single pixel wide diagonal, dont flip
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} else {
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//priority edge cases
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if(higher(c, f)){
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flip = true;
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}
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if(similar(u, f) && !similar(c, df) && !higher(c, u)){
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flip = true;
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}
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}
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if(flip){
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dist = _lineWidth-distToLine(point, center + vec2(1.5, -1.0) * pointDir, center + vec2(-0.5, 0.0) * pointDir, -pointDir); //midpoints of neighbor two-pixel groupings
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} else {
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dist = distToLine(point, center + vec2(1.5, 0.0) * pointDir, center + vec2(-0.5, 1.0) * pointDir, pointDir); //midpoints of neighbor two-pixel groupings
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}
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//cleanup slant transitions
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#ifdef CLEANUP
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if(!flip && similar(c, uf) && !(similar3(c, uf, uff) && !similar3(c, uf, ff) && !similar(d, uff))){ //shallow
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float dist2 = distToLine(point, center + vec2(2.0, -1.0) * pointDir, center + vec2(-0.0, 1.0) * pointDir, pointDir);
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dist = min(dist, dist2);
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}
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#endif
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dist -= (_lineWidth / 2.0);
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return dist <= 0.0 ? ((cd(c,f) <= cd(c,d)) ? f : d) : vec4(-1.0);
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} else if(similar3(uf, f, d) && !similar3(u, f, d) && !similar(uf, db)){ //forward steep 2:1 slant
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if(similar(c, df) && higher(c, d)){ //single pixel wide diagonal, dont flip
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} else {
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//priority edge cases
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if(higher(c, d)){
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flip = true;
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}
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if(similar(b, d) && !similar(c, df) && !higher(c, d)){
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flip = true;
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}
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}
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if(flip){
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dist = _lineWidth-distToLine(point, center + vec2(0.0, -0.5) * pointDir, center + vec2(-1.0, 1.5) * pointDir, -pointDir); //midpoints of neighbor two-pixel groupings
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} else {
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dist = distToLine(point, center + vec2(1.0, -0.5) * pointDir, center + vec2(0.0, 1.5) * pointDir, pointDir); //midpoints of neighbor two-pixel groupings
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}
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//cleanup slant transitions
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#ifdef CLEANUP
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if(!flip && similar(c, db) && !(similar3(c, db, ddb) && !similar3(c, db, dd) && !similar(f, ddb))){ //steep
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float dist2 = distToLine(point, center + vec2(1.0, 0.0) * pointDir, center + vec2(-1.0, 2.0) * pointDir, pointDir);
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dist = min(dist, dist2);
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}
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#endif
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dist -= (_lineWidth/2.0);
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return dist <= 0.0 ? ((cd(c, f) <= cd(c, d)) ? f : d) : vec4(-1.0);
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} else
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#endif
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if(similar(f, d)) { //45 diagonal
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if(similar(c, df) && higher(c, f)) { //single pixel diagonal along neighbors, dont flip
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if(!similar(c, dd) && !similar(c, ff)) { //line against triple color stripe edge case
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flip = true;
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}
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} else {
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//priority edge cases
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if(higher(c, f)) {
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flip = true;
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}
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if(!similar(c, b) && similar4(b, f, d, u)) {
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flip = true;
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}
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}
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//single pixel 2:1 slope, dont flip
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if((( (similar(f, db) && similar3(u, f, df)) || (similar(uf, d) && similar3(b, d, df)) ) && !similar(c, df))){
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flip = true;
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}
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if(flip){
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dist = _lineWidth-distToLine(point, center + vec2(1.0, -1.0) * pointDir, center + vec2(-1.0, 1.0) * pointDir, -pointDir); //midpoints of own diagonal pixels
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} else {
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dist = distToLine(point, center + vec2(1.0, 0.0) * pointDir, center + vec2(0.0, 1.0) * pointDir, pointDir); //midpoints of corner neighbor pixels
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}
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//cleanup slant transitions
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#ifdef SLOPE
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#ifdef CLEANUP
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if(!flip && similar3(c, uf, uff) && !similar3(c, uf, ff) && !similar(d, uff)){ //shallow
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float dist2 = distToLine(point, center + vec2(1.5, 0.0) * pointDir, center + vec2(-0.5, 1.0) * pointDir, pointDir);
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dist = max(dist, dist2);
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}
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if(!flip && similar3(ddb, db, c) && !similar3(dd, db, c) && !similar(ddb, f)){ //steep
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float dist2 = distToLine(point, center + vec2(1.0, -0.5) * pointDir, center + vec2(0.0, 1.5) * pointDir, pointDir);
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dist = max(dist, dist2);
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}
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#endif
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#endif
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dist -= (_lineWidth/2.0);
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return dist <= 0.0 ? ((cd(c,f) <= cd(c,d)) ? f : d) : vec4(-1.0);
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}
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#ifdef SLOPE
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else if(similar3(ff, df, d) && !similar3(ff, df, c) && !similar(uff, d)){ //far corner of shallow slant
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if(similar(f, dff) && higher(f, ff)){ //single pixel wide diagonal, dont flip
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} else {
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//priority edge cases
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if(higher(f, ff)){
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flip = true;
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}
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if(similar(uf, ff) && !similar(f, dff) && !higher(f, uf)){
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flip = true;
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}
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}
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if(flip){
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dist = _lineWidth-distToLine(point, center + vec2(1.5 + 1.0, -1.0) * pointDir, center + vec2(-0.5+1.0, 0.0) * pointDir, -pointDir); //midpoints of neighbor two-pixel groupings
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} else {
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dist = distToLine(point, center + vec2(1.5 + 1.0, 0.0) * pointDir, center + vec2(-0.5 + 1.0, 1.0) * pointDir, pointDir); //midpoints of neighbor two-pixel groupings
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}
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dist -= (_lineWidth/2.0);
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return dist <= 0.0 ? ((cd(f,ff) <= cd(f,df)) ? ff : df) : vec4(-1.0);
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} else if(similar3(f, df, dd) && !similar3(c, df, dd) && !similar(f, ddb)){ //far corner of steep slant
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if(similar(d, ddf) && higher(d, dd)){ //single pixel wide diagonal, dont flip
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} else {
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//priority edge cases
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if(higher(d, dd)){
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flip = true;
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}
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if(similar(db, dd) && !similar(d, ddf) && !higher(d, dd)){
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flip = true;
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}
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// if(!higher(d, dd)){
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// return vec4(1.0);
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// flip = true;
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// }
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}
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if(flip){
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dist = _lineWidth-distToLine(point, center + vec2(0.0, -0.5 + 1.0) * pointDir, center + vec2(-1.0, 1.5 + 1.0) * pointDir, -pointDir); //midpoints of neighbor two-pixel groupings
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} else {
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dist = distToLine(point, center + vec2(1.0, -0.5 + 1.0) * pointDir, center + vec2(0.0, 1.5 + 1.0) * pointDir, pointDir); //midpoints of neighbor two-pixel groupings
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}
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dist -= (_lineWidth/2.0);
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return dist <= 0.0 ? ((cd(d, df) <= cd(d, dd)) ? df : dd) : vec4(-1.0);
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}
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#endif
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return vec4(-1.0);
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}
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float round(float val) { return fract(val) >= 0.5? ceil(val) : floor(val); }
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vec2 round(vec2 vec) { return vec2(round(vec.x), round(vec.y)); }
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void main() {
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vec2 size = dimension + 0.0001; //fix for some sort of rounding error
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vec2 px = v_vTexcoord / dimension * size;
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vec2 local = fract(px);
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px = ceil(px);
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vec2 pointDir = round(local) * 2.0 - 1.0;
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//neighbor pixels
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//Up, Down, Forward, and Back
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//relative to quadrant of current location within pixel
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vec4 uub = texture2D( gm_BaseTexture, (px + vec2(-1.0, -2.0) * pointDir) / size);
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vec4 uu = texture2D( gm_BaseTexture, (px + vec2( 0.0, -2.0) * pointDir) / size);
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vec4 uuf = texture2D( gm_BaseTexture, (px + vec2( 1.0, -2.0) * pointDir) / size);
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vec4 ubb = texture2D( gm_BaseTexture, (px + vec2(-2.0, -2.0) * pointDir) / size);
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vec4 ub = texture2D( gm_BaseTexture, (px + vec2(-1.0, -1.0) * pointDir) / size);
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vec4 u = texture2D( gm_BaseTexture, (px + vec2( 0.0, -1.0) * pointDir) / size);
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vec4 uf = texture2D( gm_BaseTexture, (px + vec2( 1.0, -1.0) * pointDir) / size);
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vec4 uff = texture2D( gm_BaseTexture, (px + vec2( 2.0, -1.0) * pointDir) / size);
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vec4 bb = texture2D( gm_BaseTexture, (px + vec2(-2.0, 0.0) * pointDir) / size);
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vec4 b = texture2D( gm_BaseTexture, (px + vec2(-1.0, 0.0) * pointDir) / size);
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vec4 c = texture2D( gm_BaseTexture, (px + vec2( 0.0, 0.0) * pointDir) / size);
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vec4 f = texture2D( gm_BaseTexture, (px + vec2( 1.0, 0.0) * pointDir) / size);
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vec4 ff = texture2D( gm_BaseTexture, (px + vec2( 2.0, 0.0) * pointDir) / size);
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vec4 dbb = texture2D( gm_BaseTexture, (px + vec2(-2.0, 1.0) * pointDir) / size);
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vec4 db = texture2D( gm_BaseTexture, (px + vec2(-1.0, 1.0) * pointDir) / size);
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vec4 d = texture2D( gm_BaseTexture, (px + vec2( 0.0, 1.0) * pointDir) / size);
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vec4 df = texture2D( gm_BaseTexture, (px + vec2( 1.0, 1.0) * pointDir) / size);
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vec4 dff = texture2D( gm_BaseTexture, (px + vec2( 2.0, 1.0) * pointDir) / size);
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vec4 ddb = texture2D( gm_BaseTexture, (px + vec2(-1.0, 2.0) * pointDir) / size);
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vec4 dd = texture2D( gm_BaseTexture, (px + vec2( 0.0, 2.0) * pointDir) / size);
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vec4 ddf = texture2D( gm_BaseTexture, (px + vec2( 1.0, 2.0) * pointDir) / size);
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vec4 col = c;
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//c_orner, b_ack, and u_p slices
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// (slices from neighbor pixels will only ever reach these 3 quadrants
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vec4 c_col = sliceDist(local, vec2( 1.0, 1.0), pointDir, u, uf, uff, b, c, f, ff, db, d, df, dff, ddb, dd, ddf);
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vec4 b_col = sliceDist(local, vec2(-1.0, 1.0), pointDir, u, ub, ubb, f, c, b, bb, df, d, db, dbb, ddf, dd, ddb);
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vec4 u_col = sliceDist(local, vec2( 1.0,-1.0), pointDir, d, df, dff, b, c, f, ff, ub, u, uf, uff, uub, uu, uuf);
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if(c_col.r >= 0.0){
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col = c_col;
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}
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if(b_col.r >= 0.0){
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col = b_col;
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}
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if(u_col.r >= 0.0){
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col = u_col;
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}
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gl_FragColor = col;
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} |