// Hyperbolic Rogue -- texture mode // Copyright (C) 2011-2018 Zeno Rogue, see 'hyper.cpp' for details #if CAP_SDL_IMG #include #elif CAP_PNG #include #endif #if CAP_TEXTURE namespace texture { GLuint textureid = 0; cpatterntype cgroup; SDL_Surface *convertSurface(SDL_Surface* s) { SDL_PixelFormat fmt; // fmt.format = SDL_PIXELFORMAT_BGRA8888; fmt.BitsPerPixel = 32; fmt.BytesPerPixel = 4; fmt.Ashift=24; fmt.Rshift=16; fmt.Gshift=8; fmt.Bshift=0; fmt.Amask=0xff<<24; fmt.Rmask=0xff<<16; fmt.Gmask=0xff<<8; fmt.Bmask=0xff; fmt.Aloss = fmt.Rloss = fmt.Gloss = fmt.Bloss = 0; fmt.palette = NULL; #ifndef SDL2 fmt.alpha = 0; fmt.colorkey = 0x1ffffff; #endif return SDL_ConvertSurface(s, &fmt, SDL_SWSURFACE); } int twidth = 2048; unsigned paint_color = 0x000000FF; vector texture_pixels; unsigned& get_texture_pixel(int x, int y) { return texture_pixels[(y&(twidth-1))*twidth+(x&(twidth-1))]; } string texturename = "textures/hyperrogue-texture.png"; string configname = "textures/hyperrogue.txc"; bool saving = false; eTextureState tstate; eTextureState tstate_max; struct undo { unsigned* pix; unsigned last; }; vector> undos; vector > pixels_to_draw; template void scale_colorarray(int origdim, const T& src, const U& dest) { int ox = 0, tx = 0, partials[4]; int omissing = twidth, tmissing = origdim; for(int p=0; p<4; p++) partials[p] = 0; while(tx < twidth) { int fv = min(omissing, tmissing); int c = src(ox); for(int p=0; p<4; p++) partials[p] += part(c, p) * fv; omissing -= fv; tmissing -= fv; if(omissing == 0) { ox++; omissing = twidth; } if(tmissing == 0) { int target; for(int p=0; p<4; p++) { part(target, p) = partials[p] / origdim; partials[p] = 0; } dest(tx++, target); tmissing = origdim; } } } bool loadTextureGL() { if(textureid == 0) glGenTextures(1, &textureid ); glBindTexture( GL_TEXTURE_2D, textureid); glTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_MAG_FILTER,GL_LINEAR); glTexParameteri(GL_TEXTURE_2D,GL_TEXTURE_MIN_FILTER,GL_LINEAR); glTexImage2D( GL_TEXTURE_2D, 0, GL_RGBA, twidth, twidth, 0, GL_BGRA, GL_UNSIGNED_BYTE, &texture_pixels[0] ); return true; } bool whitetexture() { undos.clear(); texture_pixels.resize(0); texture_pixels.resize(twidth * twidth, 0xFFFFFFFF); pixels_to_draw.clear(); return true; } bool readtexture() { undos.clear(); texture_pixels.resize(twidth * twidth); #if CAP_SDL_IMG SDL_Surface *txt = IMG_Load(texturename.c_str()); if(!txt) { addMessage(XLAT("Failed to load %1", texturename)); return false; } auto txt2 = convertSurface(txt); SDL_FreeSurface(txt); int tx = txt2->w, ty = txt2->h; auto pix = [&] (int x, int y) { return qpixel(txt2, x, y); }; #elif CAP_PNG FILE *f = fopen(texturename.c_str(), "rb"); png_structp png = png_create_read_struct(PNG_LIBPNG_VER_STRING, NULL, NULL, NULL); if(!png) return false; if(setjmp(png_jmpbuf(png))) { printf("failed to read\n"); return false; } png_init_io(png, f); // set the expected format png_infop info = png_create_info_struct(png); png_read_info(png, info); int tx = png_get_image_width(png, info); int ty = png_get_image_height(png, info); png_byte color_type = png_get_color_type(png, info); png_byte bit_depth = png_get_bit_depth(png, info); if(bit_depth == 16) png_set_strip_16(png); if(color_type == PNG_COLOR_TYPE_PALETTE) png_set_palette_to_rgb(png); if(color_type == PNG_COLOR_TYPE_GRAY && bit_depth < 8) png_set_expand_gray_1_2_4_to_8(png); if(png_get_valid(png, info, PNG_INFO_tRNS)) png_set_tRNS_to_alpha(png); if(color_type == PNG_COLOR_TYPE_RGB || color_type == PNG_COLOR_TYPE_GRAY || color_type == PNG_COLOR_TYPE_PALETTE) png_set_filler(png, 0xFF, PNG_FILLER_AFTER); if(color_type == PNG_COLOR_TYPE_GRAY || color_type == PNG_COLOR_TYPE_GRAY_ALPHA) png_set_gray_to_rgb(png); png_read_update_info(png, info); // read png vector row_pointers(ty); vector origpixels(ty * tx); for(int y = 0; y < ty; y++) row_pointers[y] = (png_bytep) & origpixels[y * tx]; png_read_image(png, &row_pointers[0]); fclose(f); for(int i=0; i= tx || y >= ty) return 0; return origpixels[y*tx + x]; }; #endif if(tx == twidth && ty == twidth) { int i = 0; for(int y=0; y half_expanded(twidth * ty); for(int y=0; y= ty ? 0 : half_expanded[x + (base_y + y) * twidth]; }, [&] (int y, int v) { get_texture_pixel(x, y) = v; } ); } #if CAP_SDL_IMG SDL_FreeSurface(txt2); #endif return true; } void saveRawTexture() { SDL_Surface *sraw = SDL_CreateRGBSurface(SDL_SWSURFACE,twidth,twidth,32,0,0,0,0); for(int y=0; y& v, const array& tv, int splits = gsplits) { if(splits) { array v2 = make_array( mid(v[1], v[2]), mid(v[2], v[0]), mid(v[0], v[1]) ); array tv2 = make_array( mid(tv[1], tv[2]), mid(tv[2], tv[0]), mid(tv[0], tv[1]) ); mapTextureTriangle(mi, make_array(v[0], v2[2], v2[1]), make_array(tv[0], tv2[2], tv2[1]), splits-1); mapTextureTriangle(mi, make_array(v[1], v2[0], v2[2]), make_array(tv[1], tv2[0], tv2[2]), splits-1); mapTextureTriangle(mi, make_array(v[2], v2[1], v2[0]), make_array(tv[2], tv2[1], tv2[0]), splits-1); mapTextureTriangle(mi, make_array(v2[0], v2[1], v2[2]), make_array(tv2[0], tv2[1], tv2[2]), splits-1); return; } for(int i=0; i<3; i++) { mi.vertices.push_back(glhr::pointtogl(v[i])); hyperpoint inmodel; applymodel(tv[i], inmodel); inmodel = itt * inmodel; inmodel[0] *= vid.radius * 1. / vid.scrsize; inmodel[1] *= vid.radius * 1. / vid.scrsize; mi.tvertices.push_back(make_array((inmodel[0]+1)/2, (inmodel[1]+1)/2, 0)); } } texture_triangle *edited_triangle; textureinfo *edited_tinfo; vector tuned_vertices; map texture_map, texture_map_orig; set models; array findTextureTriangle(cell *c, patterns::patterninfo& si, int i) { // auto si = getpatterninfo0(c); transmatrix M = shmup::ggmatrix(c) * applyPatterndir(c, si); ld z = ctof(c) ? rhexf : hexvdist; hyperpoint h1 = spin(M_PI + M_PI * (2*i -1) / c->type) * xpush(z) * C0; hyperpoint h2 = spin(M_PI + M_PI * (2*i +1) / c->type) * xpush(z) * C0; return make_array(M * C0, M * h1, M * h2); } // using: mouseh, mouseouver int getTriangleID(cell *c, patterns::patterninfo& si, hyperpoint h) { // auto si = getpatterninfo0(c); ld quality = 1e10; int best = 0; for(int i=0; itype; i++) { auto t = findTextureTriangle(c, si, i); ld q = intval(t[1], h) + intval(t[2], h); if(q < quality) quality = q, best = i; } return best; } void mapTexture(cell *c, textureinfo& mi, patterns::patterninfo &si, const transmatrix& T, int shift = 0) { mi.c = c; mi.symmetries = si.symmetries; mi.current_type = c->type; mi.M = T * applyPatterndir(c, si); ld z = ctof(c) ? rhexf : hexvdist; mi.triangles.clear(); for(int i=0; itype; i++) { int i2 = i+shift; hyperpoint h1 = spin(M_PI + M_PI * (2*i2 -1) / c->type) * xpush(z) * C0; hyperpoint h2 = spin(M_PI + M_PI * (2*i2 +1) / c->type) * xpush(z) * C0; mi.triangles.emplace_back(make_array(C0, h1, h2), make_array(mi.M*C0, mi.M*h1, mi.M*h2)); } } void mapTexture2(textureinfo& mi) { mi.vertices.clear(); mi.tvertices.clear(); for(auto& t: mi.triangles) mapTextureTriangle(mi, t.v, t.tv); } int recolor(int col) { if(color_alpha == 0) return col; for(int i=1; i<4; i++) part(col, i) = color_alpha + ((255-color_alpha) * part(col,i) + 127) / 255; return col; } bool apply(cell *c, const transmatrix &V, int col) { if(tstate == tsOff) return false; using namespace patterns; auto si = getpatterninfo0(c); if(tstate == tsAdjusting) { queuepolyat(V, shFullCross[ctof(c)], 0, PPR_LINE); lastptd().u.poly.outline = slave_color; queuepolyat(V, shFullFloor[ctof(c)], 0, PPR_LINE); lastptd().u.poly.outline = slave_color; return false; } try { auto& mi = texture_map.at(si.id); qfi.spin = applyPatterndir(c, si); int n = mi.vertices.size(); qfi.special = false; qfi.shape = &shFullFloor[ctof(c)]; qfi.tinf = &mi; if(chasmg == 2) return false; else if(chasmg && wmspatial) { if(detaillevel == 0) return false; queuetable(V * qfi.spin, mi.vertices, n, mesh_color, recolor(c->land == laCocytus ? 0x080808FF : 0x101010FF), PPR_LAKEBOTTOM); } else { queuetable(V * qfi.spin, mi.vertices, n, mesh_color, recolor(col), PPR_FLOOR); } lastptd().u.poly.tinf = &mi; if(grid_color) { queuepolyat(V, shFullFloor[ctof(c)], 0, PPR_FLOOR); lastptd().u.poly.outline = grid_color; } if(texture::saving) { // create a nicer aura for saved texture for(int i=0; i= 0) break; } ld v[2] = {0,0}; for(int j=0; j<2; j++) for(int k=0; k<3; k++) v[j] += mi.tvertices[i+k][j] * p[k]; int vi[2] = {int(v[0] * twidth), int(v[1] * twidth)}; col = get_texture_pixel(vi[0], vi[1]); hyperpoint h = glhr::gltopoint(mi.vertices[i]); addaura(V*h, col, 0); } } return true; } catch(out_of_range) { // printf("Ignoring tile #%d : not mapped\n", si.id); return false; } } void mark_triangles() { if(tstate == tsAdjusting) for(auto& mi: texture_map) { for(auto& t: mi.second.triangles) { vector t2; for(int i=0; i<3; i++) t2.push_back(t.tv[i]); prettypoly(t2, master_color, master_color, gsplits); } } } typedef tuple texture_parameters; static const auto current_texture_parameters = tie(geometry, nonbitrunc, patterns::whichPattern, patterns::subpattern_flags, pmodel, vid.scale, vid.alpha); texture_parameters orig_texture_parameters; bool texture_tuned = false; string texture_tuner; void clear_texture_map() { texture_map.clear(); edited_triangle = nullptr; edited_tinfo = nullptr; tuned_vertices.clear(); models.clear(); texture_tuned = false; texture_tuner = ""; } void perform_mapping() { if(gsplits < 0) gsplits = 0; if(gsplits > 4) gsplits = 4; using namespace patterns; clear_texture_map(); for(auto& p: gmatrix) { cell *c = p.first; auto si = getpatterninfo0(c); bool replace = false; // int sgn = sphere ? -1 : 1; if(!texture_map.count(si.id)) replace = true; else if(hdist0(p.second*sphereflip * C0) < hdist0(texture_map[si.id].M * sphereflip * C0)) replace = true; if(replace) { auto& mi = texture_map[si.id]; mapTexture(c, mi, si, p.second); mi.texture_id = textureid; } } for(auto& t: texture_map) models.insert(t.second.c); for(auto& p: gmatrix) { cell *c = p.first; bool nearmodel = models.count(c); forCellEx(c2, c) if(models.count(c2)) nearmodel = true; if(nearmodel) { auto si = getpatterninfo0(c); texture_map[si.id].matrices.push_back(p.second * applyPatterndir(c, si)); } } computeCgroup(); texture::cgroup = patterns::cgroup; texture_map_orig = texture_map; orig_texture_parameters = current_texture_parameters; // printf("texture_map has %d elements (S%d)\n", size(texture_map), tstate); } void finish_mapping() { if(tstate == tsActive) for(auto& mi: texture_map) mapTexture2(mi.second); } void saveFullTexture() { addMessage(XLAT("Saving full texture to %1...", texturename)); dynamicval dd(grid_color, 0); dynamicval dm(mesh_color, 0); texture::saving = true; drawscreen(); dynamicval dv(pngres, twidth); saveHighQualityShot(texturename.c_str()); texture::saving = false; drawscreen(); itt = xyscale(Id, vid.scrsize * 1. / vid.radius); readtexture(); perform_mapping(); finish_mapping(); } bool newmove = false; vector rtver(4); void drawRawTexture() { glhr::be_textured(); glhr::color2(0xFFFFFF20); glBindTexture(GL_TEXTURE_2D, textureid); for(int i=0; i<4; i++) { int cx[4] = {2, -2, -2, 2}; int cy[4] = {2, 2, -2, -2}; int x = cx[i]; int y = cy[i]; hyperpoint inmodel = hpxyz(x, y, 1); inmodel = itt * inmodel; rtver[i].texture[0] = (inmodel[0]+1)/2; rtver[i].texture[1] = (inmodel[1]+1)/2; rtver[i].coords[0] = x * vid.scrsize; rtver[i].coords[1] = y * vid.scrsize; } glhr::set_modelview(glhr::translate(0, 0, stereo::scrdist)); glhr::prepare(rtver); glDrawArrays(GL_TRIANGLE_FAN, 0, 4); } struct magicmapper_point { cell *c; hyperpoint cell_relative; hyperpoint texture_coords; }; vector amp; enum eMagicParameter { mpScale, mpProjection, mpMove, mpRotate, mpSlant, mpStretch, mpTexPosX, mpTexPosY, mpMAX }; vector mpnames = { "affect model scale", "affect model projection", "affect model central point", "affect model rotation", "affect texture slanting", "affect texture stretching", "affect texture position X", "affect texture position Y" }; flagtype current_magic = 15; bool have_mp(eMagicParameter i) { return (current_magic >> i) & 1; } struct magic_param { bool do_spin; int texmode; ld spinangle, scale, proj, moveangle, shift, slant, stretch, tx, ty; void shuffle() { do_spin = hrand(2); spinangle = hrandf() - hrandf(); moveangle = hrandf() * 2 * M_PI; shift = hrandf() - hrandf(); scale = hrandf() - hrandf(); proj = hrandf() - hrandf(); texmode = hrand(3); slant = have_mp(mpSlant) ? hrandf() - hrandf() : 0; stretch = have_mp(mpStretch) ? hrandf() - hrandf() : 0; tx = have_mp(mpTexPosX) ? hrandf() - hrandf() : 0; ty = have_mp(mpTexPosY) ? hrandf() - hrandf() : 0; } void affect_itt(const transmatrix& T) { transmatrix Ti = inverse(T); for(auto& p: amp) p.texture_coords = Ti * p.texture_coords; itt = itt * T; } void apply(ld delta) { if(have_mp(mpProjection)) vid.alpha *= exp(delta * proj); if(have_mp(mpScale)) vid.scale *= exp(delta * scale); if(do_spin) { if(have_mp(mpRotate)) View = spin(delta * spinangle) * View; } else { if(have_mp(mpMove)) View = spin(moveangle) * xpush(delta*shift) * spin(-moveangle) * View; } if(texmode == 0 && have_mp(mpStretch)) affect_itt(euaffine(hpxyz(0, delta * stretch, 0))); if(texmode == 1 && have_mp(mpSlant)) affect_itt(euaffine(hpxyz(delta * slant, 0, 0))); if(texmode == 2 && (have_mp(mpTexPosX) || have_mp(mpTexPosY))) affect_itt(eupush(delta * tx, delta * ty)); fixmatrix(View); } }; ld magic_quality() { gmatrix.clear(); calcparam(); ld q = 0; for(auto& p: amp) { hyperpoint inmodel; applymodel(shmup::ggmatrix(p.c) * p.cell_relative, inmodel); inmodel[0] *= vid.radius * 1. / vid.scrsize; inmodel[1] *= vid.radius * 1. / vid.scrsize; q += intvalxy(inmodel, p.texture_coords); } return q; } void applyMagic() { ld cq = magic_quality(); int last_success = 0; for(int s=0; s<50000 && s 1e-9; delta *= (failed ? -.7 : 1.2)) { p.apply(delta); ld nq = magic_quality(); if(nq < cq) { cq = nq; last_success = s; } else { p.apply(-delta); failed = true; } } } } enum eTexturePanstate {tpsModel, tpsMove, tpsScale, tpsAffine, tpsZoom, tpsProjection, tpsCell, tpsTriangle, tpsTune}; eTexturePanstate panstate; void mousemovement() { static hyperpoint lastmouse; hyperpoint mouseeu = hpxyz((mousex - vid.xcenter + .0) / vid.scrsize, (mousey - vid.ycenter + .0) / vid.scrsize, 1); bool nonzero = mouseeu[0] || mouseeu[1]; switch(panstate) { case tpsModel: if(!newmove && mouseh[2] < 50 && lastmouse[2] < 50) { panning(lastmouse, mouseh); perform_mapping(); } lastmouse = mouseh; newmove = false; break; case tpsMove: { if(!newmove) itt = itt * inverse(eupush(mouseeu)) * eupush(lastmouse); lastmouse = mouseeu; newmove = false; break; } case tpsScale: { if(nonzero && !newmove) itt = itt * inverse(euscalezoom(mouseeu)) * euscalezoom(lastmouse); if(nonzero) lastmouse = mouseeu; newmove = false; break; } case tpsAffine: { if(!newmove) itt = itt * inverse(euaffine(mouseeu)) * euaffine(lastmouse); lastmouse = mouseeu; newmove = false; break; } case tpsZoom: { // do not zoom in portrait! if(nonzero && !newmove) { View = inverse(spintox(mouseeu)) * spintox(lastmouse) * View; vid.scale = vid.scale * sqrt(intvalxy(C0, mouseeu)) / sqrt(intvalxy(C0, lastmouse)); } if(nonzero) lastmouse = mouseeu; newmove = false; break; } case tpsProjection: { if(nonzero && !newmove) { vid.alpha = vid.alpha * sqrt(intvalxy(C0, mouseeu)) / sqrt(intvalxy(C0, lastmouse)); } if(nonzero) lastmouse = mouseeu; newmove = false; } case tpsCell: { cell *c = mouseover; if(!c) break; auto si = patterns::getpatterninfo0(c); if(newmove) { edited_tinfo = NULL; if(texture_map.count(si.id)) { edited_tinfo = &texture_map[si.id]; newmove = false; } } if(edited_tinfo && size(edited_tinfo->triangles) == c->type) { for(int i=0; itype; i++) edited_tinfo->triangles[i].tv = findTextureTriangle(c, si, i); texture_tuned = true; } } case tpsTriangle: { cell *c = mouseover; if(!c) break; auto si = patterns::getpatterninfo0(c); int i = getTriangleID(c, si, mouseh); if(newmove) { edited_triangle = NULL; if(texture_map.count(si.id)) { edited_triangle = &texture_map[si.id].triangles[i]; newmove = false; } } if(edited_triangle) { edited_triangle->tv = findTextureTriangle(c, si, i); texture_tuned = true; } } case tpsTune: { ld tdist = 1e20; if(newmove) { tuned_vertices.clear(); for(auto& a: texture_map) for(auto& t: a.second.triangles) for(auto& v: t.tv) if(intval(v, mouseh) < tdist) tdist = intval(v, mouseh); for(auto& a: texture_map) for(auto& t: a.second.triangles) for(auto& v: t.tv) if(intval(v, mouseh) < tdist * (1.000001)) tuned_vertices.push_back(&v); newmove = false; } for(auto v: tuned_vertices) { *v = mouseh; texture_tuned = true; } } default: break; } } patterns::patterninfo si_save; saverlist texturesavers; bool target_nonbitru; void init_textureconfig() { texturesavers = move(savers); for(int i=0; i<3; i++) for(int j=0; j<3; j++) addsaver(itt[i][j], "texturematrix_" + its(i) + its(j), i==j ? 1 : 0); for(int i=0; i<3; i++) for(int j=0; j<3; j++) addsaver(View[i][j], "viewmatrix_" + its(i) + its(j), i==j ? 1 : 0); addsaverenum(targetgeometry, "geometry", gNormal); addsaverenum(pmodel, "used model", mdDisk); addsaver(vid.yshift, "Y shift", 0); addsaver(vid.yposition, "Y position", 0); addsaver(vid.xposition, "X position", 0); addsaver(vid.camera_angle, "camera angle", 0); addsaverenum(target_nonbitru, "bitruncated", false); // ... geometry parameters addsaver(patterns::whichPattern, "pattern", 0); addsaver(patterns::subpattern_flags, "pattern flags", 0); cell *ctr = euclid ? centerover.c : viewctr.h->c7; si_save = patterns::getpatterninfo0(ctr); addsaver(si_save.id, "center type", 1); addsaver(si_save.dir, "center direction", 0); addsaver(si_save.reflect, "center reflection", false); addsaver(viewctr.spin, "center spin", 0); addsaver(twidth, "texture resolution", 2048); addsaver(gsplits, "precision", 1); addsaver(grid_color, "grid color", 0); addsaver(color_alpha, "alpha color", 0); addsaver(mesh_color, "mesh color", 0); addsaver(vid.alpha, "projection", 1); addsaver(vid.scale, "scale", 1); addsaver(texturename, "texture filename", ""); addsaver(texture_tuner, "texture tuning", ""); swap(texturesavers, savers); } bool save_textureconfig() { init_textureconfig(); FILE *f = fopen(configname.c_str(), "wt"); if(!f) return false; if(texture_tuned) { texture_tuner = ""; for(auto& a: texture_map) for(auto& t: a.second.triangles) for(auto& v: t.tv) for(int i=0; i<3; i++) { texture_tuner += ftssmart(v[i]); texture_tuner += ';'; } } targetgeometry = geometry; target_nonbitru = nonbitrunc; for(auto s: texturesavers) if(s->dosave()) fprintf(f, "%s=%s\n", s->name.c_str(), s->save().c_str()); fclose(f); return true; } bool load_textureconfig() { init_textureconfig(); FILE *f = fopen(configname.c_str(), "rt"); if(!f) return false; swap(texturesavers, savers); for(auto s: savers) s->reset(); loadNewConfig(f); swap(texturesavers, savers); fclose(f); if(1) { dynamicval d1(patterns::whichPattern, patterns::whichPattern); dynamicval d2(patterns::subpattern_flags, patterns::subpattern_flags); if(targetgeometry != geometry) { restartGame('g'); return load_textureconfig(); } if(nonbitrunc != target_nonbitru) { restartGame('7'); } } if(true) { celllister cl(currentmap->gamestart(), 20, 10000, NULL); bool found = false; for(cell *c: cl.lst) if(euclid || ctof(c)) { cell *ctr = euclid ? centerover.c : viewctr.h->c7; auto si_here = patterns::getpatterninfo0(c); if(si_here.id == si_save.id && si_here.reflect == si_save.reflect && si_here.dir == si_save.dir) { if(euclid) centerover.c = ctr; else viewctr.h = ctr->master; found = true; break; } } if(!found) addMessage(XLAT("warning: unable to find the center")); } if(!readtexture()) return false; if(!loadTextureGL()) return false; calcparam(); drawthemap(); tstate = tstate_max = tsActive; string s = move(texture_tuner); perform_mapping(); texture_tuner = move(s); if(texture_tuner != "") { texture_tuned = true; vector coords; for(auto& a: texture_map) for(auto& t: a.second.triangles) for(auto& v: t.tv) for(int i=0; i<3; i++) coords.push_back(&v[i]); int semicounter = 0; for(char c: texture_tuner) if(c == ';') semicounter++; if(semicounter != size(coords)) addMessage("Tuning error: wrong number"); else { string cur = ""; int index = 0; for(char c: texture_tuner) if(c == ';') { *(coords[index++]) = atof(cur.c_str()); cur = ""; } else cur += c; printf("index = %d semi = %d sc = %d\n", index, semicounter, size(coords)); } } finish_mapping(); return true; } void showMagicMenu() { cmode = sm::SIDE | sm::MAYDARK | sm::DIALOG_STRICT_X; gamescreen(0); dialog::init(XLAT("texture auto-adjustment")); dialog::addInfo(XLAT("drag from the model to the texture")); for(int i=0; i= 'a' && uni < 'a' + mpMAX) current_magic ^= 1<<(uni - 'a'); else if(uni == 'D') amp.clear(); else if(uni == 'R') applyMagic(); else if(doexiton(sym, uni)) popScreen(); }; } string texturehelp = "This mode lets you to change the floor tesselation easily -- " "select 'paint a new texture' and draw like in a Paint program. " "The obtained pattern can then be easily changed to another geometry, " "or saved.\n\n" "Instead of drawing, it is also possible to use an arbitrary image " "as a texture. " "Works best with spherical/Euclidean/hyperbolic tesselations " "(e.g., a photo of a soccerball, or one of the tesselations by M. C. " "Escher), but it can be also used on arbitrary photos to make them periodic " "(these probably work best with the 'large picture' setting in geometry selection). " "Again, tesselations can have their geometry changed.\n\n"; void showMenu() { cmode = sm::SIDE | sm::MAYDARK | sm::DIALOG_STRICT_X; gamescreen(0); if(tstate == tsAdjusting) { ptds.clear(); texture::mark_triangles(); drawqueue(); } if(tstate == tsOff) { dialog::init(XLAT("texture mode (off)")); dialog::addItem(XLAT("select geometry/pattern"), 'r'); if(tstate_max == tsAdjusting || tstate_max == tsActive) dialog::addItem(XLAT("reactivate the texture"), 't'); dialog::addItem(XLAT("open PNG as texture"), 'o'); dialog::addItem(XLAT("load texture config"), 'l'); dialog::addSelItem(XLAT("texture size"), its(twidth), 'w'); dialog::addItem(XLAT("paint a new texture"), 'n'); dialog::addSelItem(XLAT("precision"), its(gsplits), 'P'); } if(tstate == tsAdjusting) { dialog::init(XLAT("texture mode (overlay)")); dialog::addItem(XLAT("select the texture's pattern"), 'r'); dialog::addItem(XLAT("enable the texture"), 't'); dialog::addItem(XLAT("cancel the texture"), 'T'); dialog::addBoolItem(XLAT("move the model"), panstate == tpsModel, 'm'); dialog::addBoolItem(XLAT("move the texture"), panstate == tpsMove, 'a'); dialog::addBoolItem(XLAT("zoom/scale the texture"), panstate == tpsScale, 'x'); dialog::addBoolItem(XLAT("zoom/scale the model"), panstate == tpsZoom, 'z'); dialog::addBoolItem(XLAT("projection"), panstate == tpsProjection, 'p'); dialog::addBoolItem(XLAT("affine transformations"), panstate == tpsAffine, 'y'); dialog::addBoolItem(XLAT("magic"), false, 'A'); dialog::addBreak(50); dialog::addBoolItem(XLAT("select master cells"), panstate == tpsCell, 'C'); dialog::addBoolItem(XLAT("select master triangles"), panstate == tpsTriangle, 'T'); dialog::addBoolItem(XLAT("fine tune vertices"), panstate == tpsTune, 'F'); dialog::addColorItem(XLAT("grid color (master)"), master_color, 'M'); dialog::addColorItem(XLAT("grid color (copy)"), slave_color, 'C'); dialog::addBreak(50); dialog::addSelItem(XLAT("precision"), its(gsplits), 'P'); dialog::addItem(XLAT("save the raw texture"), 'S'); } if(tstate == tsActive) { dialog::init(XLAT("texture mode (active)")); /* dialog::addSelItem(XLAT("texture scale"), fts(iscale), 's'); dialog::addSelItem(XLAT("texture angle"), fts(irotate), 'a'); dialog::addSelItem(XLAT("texture position X"), fts(ix), 'x'); dialog::addSelItem(XLAT("texture position Y"), fts(iy), 'y'); */ dialog::addItem(XLAT("deactivate the texture"), 't'); dialog::addItem(XLAT("back to overlay mode"), 'T'); dialog::addItem(XLAT("change the geometry"), 'r'); dialog::addColorItem(XLAT("grid color"), grid_color, 'g'); dialog::addColorItem(XLAT("mesh color"), mesh_color, 'm'); dialog::addSelItem(XLAT("color alpha"), its(color_alpha), 'c'); dialog::addSelItem(XLAT("precision"), its(gsplits), 'P'); dialog::addItem(XLAT("edit the texture"), 'e'); dialog::addItem(XLAT("save the full texture image"), 'S'); dialog::addItem(XLAT("save texture config"), 's'); } dialog::addItem(XLAT("help"), SDLK_F1); dialog::addItem(XLAT("back"), '0'); getcstat = '-'; dialog::display(); if(holdmouse) mousemovement(); keyhandler = [] (int sym, int uni) { // handlePanning(sym, uni); dialog::handleNavigation(sym, uni); if(uni == '-' && tstate == tsAdjusting) { if(!holdmouse) { holdmouse = true; newmove = true; } } else if(uni == 'm' && tstate == tsAdjusting) panstate = tpsModel; else if(uni == 'a' && tstate == tsAdjusting) panstate = tpsMove; else if(uni == 'x' && tstate == tsAdjusting) panstate = tpsScale; else if(uni == 'y' && tstate == tsAdjusting) panstate = tpsAffine; else if(uni == 'z' && tstate == tsAdjusting) panstate = tpsZoom; else if(uni == 'p' && tstate == tsAdjusting) panstate = tpsProjection; else if(uni == 'C' && tstate == tsAdjusting) panstate = tpsCell; else if(uni == 'T' && tstate == tsAdjusting) panstate = tpsTriangle; else if(uni == 'F' && tstate == tsAdjusting) panstate = tpsTune; else if(uni == 'A' && tstate == tsAdjusting) pushScreen(showMagicMenu); else if(uni == 's' && tstate == tsActive) dialog::openFileDialog(configname, XLAT("save texture config"), ".txc", [] () { return save_textureconfig(); }); else if(uni == 'l' && tstate == tsOff) dialog::openFileDialog(configname, XLAT("load texture config"), ".txc", [] () { return load_textureconfig(); }); else if(uni == 'r') patterns::pushChangeablePatterns(); else if(uni == 'o' && tstate == tsOff) dialog::openFileDialog(texturename, XLAT("open PNG as texture"), ".png", [] () { if(readtexture() && loadTextureGL()) { if(tstate_max == tsOff) tstate_max = tsAdjusting; tstate = tstate_max; perform_mapping(); finish_mapping(); return true; } else return false; }); else if(uni == 'w' && tstate == tsOff) { twidth *= 2; if(twidth > 9000) twidth = 256; tstate_max = tsOff; } else if(uni == 'e' && tstate == tsActive) { mapeditor::initdraw(cwt.c); pushScreen(mapeditor::showDrawEditor); } else if(uni == 'n' && tstate == tsOff) { addMessage("white"); if(whitetexture() && loadTextureGL()) { tstate = tstate_max = tsActive; perform_mapping(); finish_mapping(); mapeditor::initdraw(cwt.c); pushScreen(mapeditor::showDrawEditor); } } else if(uni == 't' && tstate == tsOff) tstate = tstate_max; else if(uni == 't' && tstate == tsAdjusting) { tstate = tstate_max = tsActive; finish_mapping(); } else if(uni == 't' && tstate == tsActive) tstate = tsOff; else if(uni == 'T' && tstate == tsAdjusting) tstate = tsOff; else if(uni == 'T' && tstate == tsActive) tstate = tsAdjusting; else if(uni == 'g' && tstate == tsActive) dialog::openColorDialog(grid_color, NULL); else if(uni == 'm' && tstate == tsActive) dialog::openColorDialog(mesh_color, NULL); else if(uni == 'M' && tstate == tsAdjusting) dialog::openColorDialog(master_color, NULL); else if(uni == 'C' && tstate == tsAdjusting) dialog::openColorDialog(slave_color, NULL); else if(uni == 'c' && tstate == tsActive) { dialog::editNumber(color_alpha, 0, 255, 15, 0, XLAT("color alpha"), XLAT("The higher the value, the less important the color of underlying terrain is.")); } else if(uni == 'P') { dialog::editNumber(gsplits, 0, 4, 1, 1, XLAT("precision"), XLAT("precision")); if(tstate == tsActive) dialog::reaction = [] () { finish_mapping(); }; } else if(uni == 'S' && tstate == tsAdjusting) dialog::openFileDialog(texturename, XLAT("save the raw texture"), ".png", [] () { saveRawTexture(); return true; }); else if(uni == 'S' && tstate == tsActive) dialog::openFileDialog(texturename, XLAT("save the full texture image"), ".png", [] () { saveFullTexture(); return true; }); else if(uni == SDLK_F1) gotoHelp(texturehelp); else if(doexiton(sym, uni)) popScreen(); }; } typedef pair point; point ptc(hyperpoint h) { hyperpoint inmodel; applymodel(h, inmodel); inmodel = itt * inmodel; inmodel[0] *= vid.radius * 1. / vid.scrsize; inmodel[1] *= vid.radius * 1. / vid.scrsize; int x = (1 + inmodel[0]) * twidth / 2; int y = (1 + inmodel[1]) * twidth / 2; return make_pair(x,y); } array ptc(const array& h) { return make_array(ptc(h[0]), ptc(h[1]), ptc(h[2])); } ld penwidth = .02; int texture_distance(pair p1, pair p2) { return max(abs(p1.first-p2.first), abs(p1.second - p2.second)); } void fillpixel(int x, int y, unsigned col) { if(x<0 || y<0 || x >= twidth || y >= twidth) return; auto& pix = get_texture_pixel(x, y); if(pix != col) { undos.emplace_back(&pix, pix); pix = col; } } void undo() { while(!undos.empty()) { auto p = undos.back(); undos.pop_back(); if(!p.first) { loadTextureGL(); return; } *p.first = p.second; } } void undoLock() { printf("undos size = %d\n", size(undos)); if(size(undos) > 2000000) { // limit undo memory int moveto = 0; for(int i=0; i < size(undos) - 1000000; i++) if(!undos[i].first) moveto = i; if(moveto) { for(int i=0; i+moveto < size(undos); i++) undos[i] = undos[i+moveto]; undos.resize(size(undos) - moveto); printf("undos sized to = %d\n", size(undos)); } } undos.emplace_back(nullptr, 1); } void filltriangle(const array& v, const array& p, int col, int lev) { int d2 = texture_distance(p[0], p[1]), d1 = texture_distance(p[0], p[2]), d0 = texture_distance(p[1], p[2]); int a, b, c; if((d0 <= 1 && d1 <= 1 && d2 <= 1) || lev >= 20) { for(int i=0; i<3; i++) fillpixel(p[i].first, p[i].second, col); return; } else if(d1 >= d0 && d1 >= d2) a = 0, b = 2, c = 1; else if(d2 >= d0 && d2 >= d1) a = 0, b = 1, c = 2; else a = 1, b = 2, c = 0; hyperpoint v3 = mid(v[a], v[b]); point p3 = ptc(v3); filltriangle(make_array(v[c], v[a], v3), make_array(p[c], p[a], p3), col, lev+1); filltriangle(make_array(v[c], v[b], v3), make_array(p[c], p[b], p3), col, lev+1); } void splitseg(const transmatrix& A, const array& angles, const array& h, const array& p, int col, int lev) { ld newangle = (angles[0] + angles[1]) / 2; hyperpoint nh = A * spin(newangle) * xpush(penwidth) * C0; auto np = ptc(nh); filltriangle(make_array(h[0],h[1],nh), make_array(p[0],p[1],np), col, lev); if(lev < 10) { if(texture_distance(p[0],np) > 1) splitseg(A, make_array(angles[0], newangle), make_array(h[0], nh), make_array(p[0], np), col, lev+1); if(texture_distance(np,p[1]) > 1) splitseg(A, make_array(newangle, angles[1]), make_array(nh, h[1]), make_array(np, p[1]), col, lev+1); } } void fillcircle(hyperpoint h, int col) { transmatrix A = rgpushxto0(h); ld step = M_PI * 2/3; array mh = make_array(A * xpush(penwidth) * C0, A * spin(step) * xpush(penwidth) * C0, A * spin(-step) * xpush(penwidth) * C0); auto mp = ptc(mh); filltriangle(mh, mp, col, 0); for(int i=0; i<3; i++) { int j = (i+1) % 3; if(texture_distance(mp[i], mp[j]) > 1) splitseg(A, make_array(step*i, step*(i+1)), make_array(mh[i], mh[j]), make_array(mp[i], mp[j]), col, 1); } } bool texturesym = false; void actDrawPixel(cell *c, hyperpoint h, int col) { try { transmatrix M = gmatrix.at(c); auto si = patterns::getpatterninfo0(c); h = inverse(M * applyPatterndir(c, si)) * h; auto& tinf = texture_map[si.id]; for(auto& M2: tinf.matrices) for(int i = 0; itype; i += si.symmetries) { fillcircle(M2 * spin(2 * M_PI * i / c->type) * h, col); if(texturesym) fillcircle(M2 * spin(2 * M_PI * i / c->type) * Mirror * h, col); } } catch(out_of_range) {} } void drawPixel(cell *c, hyperpoint h, int col) { pixels_to_draw.emplace_back(c, h, col); } cell *where; void drawPixel(hyperpoint h, int col) { try { again: transmatrix g0 = gmatrix[where]; ld cdist0 = hdist(tC0(g0), h); forCellEx(c, where) try { transmatrix g = gmatrix[c]; ld cdist = hdist(tC0(g), h); if(cdist < cdist0) { cdist0 = cdist; where = c; g0 = g; goto again; } } catch(out_of_range) {} drawPixel(where, h, col); } catch(out_of_range) {} } void drawLine(hyperpoint h1, hyperpoint h2, int col, int steps) { if(steps > 0 && hdist(h1, h2) > penwidth / 3) { hyperpoint h3 = mid(h1, h2); drawLine(h1, h3, col, steps-1); drawLine(h3, h2, col, steps-1); } else drawPixel(h2, col); } void remap(eTextureState old_tstate, eTextureState old_tstate_max) { clear_texture_map(); if(old_tstate == tsActive && patterns::compatible(texture::cgroup, patterns::cgroup)) { tstate = old_tstate; tstate_max = old_tstate_max; for(cell *c: dcal) { auto si = patterns::getpatterninfo0(c); if(texture_map.count(si.id)) continue; int oldid = si.id; int pshift = 0; if(texture::cgroup == cpSingle) oldid = 1; if(texture::cgroup == cpFootball && patterns::cgroup == cpThree) { if(si.id == 4) pshift = 1; oldid = !si.id; } try { auto& mi = texture_map_orig.at(oldid); int ncurr = size(mi.tvertices); int ntarget = ncurr * c->type / mi.current_type; vector new_tvertices = mi.tvertices; new_tvertices.resize(ntarget); for(int i=ncurr; i= tsAdjusting) { printf("perform_mapping %d/%d\n", tstate, tstate_max); calcparam(); drawthemap(); perform_mapping(); finish_mapping(); printf("texture_map size = %d\n", size(texture_map)); } } int textureArgs() { using namespace arg; if(0) ; else if(argis("-txpic")) { shift(); texturename = args(); } else if(argis("-txp")) { shift(); gsplits = argf(); } else if(argis("-txc")) { shift(); configname = args(); } else if(argis("-txc")) { shift(); configname = args(); } else if(argis("-txcl")) { PHASE(3); drawscreen(); load_textureconfig(); } else return 1; return 0; } auto texture_hook = addHook(hooks_args, 100, textureArgs) + addHook(clearmemory, 100, [] () { pixels_to_draw.clear(); }); int lastupdate; void update() { if(!pixels_to_draw.empty()) { auto t = SDL_GetTicks(); while(SDL_GetTicks() < t + 75 && !pixels_to_draw.empty()) { auto p = pixels_to_draw.back(); actDrawPixel(get<0>(p), get<1>(p), get<2>(p)); pixels_to_draw.pop_back(); } loadTextureGL(); } } } #endif