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https://github.com/zenorogue/hyperrogue.git
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237 lines
6.2 KiB
C++
237 lines
6.2 KiB
C++
// show the fundamental domain for quotient spaces
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// Copyright (C) 2018 Zeno and Tehora Rogue, see 'hyper.cpp' for details
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namespace hr {
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namespace fundamental {
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color_t color1, color2;
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map<cell*, int> same;
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map<cell*, transmatrix> gm;
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bool is_connected(cellwalker cw) {
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return same[cw.at] & (1<<cw.spin);
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}
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void be_connected(cellwalker cw) {
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// transmatrix T = gm[cw.at];
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same[cw.at] |= (1<<cw.spin);
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cw += wstep;
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same[cw.at] |= (1<<cw.spin);
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/* printf("%s", display(T * C0));
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printf(" %s\n", display(gm[cw.at] * C0)); */
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// queueline(T * C0, gm[cw.at] * C0, 0xFF0000FF, 3);
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}
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int funmode = 0;
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hyperpoint corner(cellwalker cw) {
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transmatrix T = gm[cw.at];
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if(funmode == 2) {
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while(cw.at->type != S7) {
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cw++;
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T = T * calc_relative_matrix(cw.peek(), cw.at, cw.spin);
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cw += wstep;
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}
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return T * C0;
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}
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return gm[cw.at] * get_corner_position(cw.at, cw.spin+(cw.mirrored?0:1), 3);
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}
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transmatrix rel(cellwalker cw) {
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return calc_relative_matrix(cw.cpeek(), cw.at, cw.spin);
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}
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ld label_dist = .3;
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transmatrix labelpos(hyperpoint h1, hyperpoint h2) {
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hyperpoint h = mid(h1, h2);
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transmatrix T = rgpushxto0(h);
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hyperpoint hx = inverse(T) * h2;
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ld alpha = atan2(-hx[1], hx[0]);
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return T * xspinpush(alpha + M_PI/2, label_dist);
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}
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ld widthfactor = 5;
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ld label_scale = 1;
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void fundamental_marker() {
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if(!funmode || !(quotient || torus || elliptic)) return;
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same.clear();
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gm.clear();
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same[cwt.at] = 0;
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gm[cwt.at] = ggmatrix(cwt.at);
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vector<cell*> cells;
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cells.push_back(cwt.at);
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int tree_edges = 0;
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int face_edges = 0;
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for(int k=0; k<isize(cells); k++) {
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cell *c = cells[k];
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for(int i=0; i<c->type; i++) {
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cellwalker cw(c, i);
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cell *c2 = cw.cpeek();
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if(gm.count(c2)) continue;
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gm[c2] = gm[c] * rel(cw);
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// queueline(gm[c2] * C0, gm[c2] * xspinpush0(ticks, 0.2), 0xFFFFFFFF, 3);
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be_connected(cw);
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tree_edges++;
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cells.push_back(c2);
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}
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}
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while(true) {
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int f = face_edges;
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for(int k=0; k<isize(cells); k++) {
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cell *c = cells[k];
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for(int i=0; i<c->type; i++) {
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cellwalker cw(c, i);
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if(is_connected(cw) && is_connected(cw+1) && !is_connected(cw+wstep-1)) {
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face_edges++;
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be_connected(cw+wstep-1);
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}
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}
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}
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if(f == face_edges) break;
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}
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cellwalker cw;
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int corners = 0;
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for(int k=0; k<isize(cells); k++) {
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cell *c = cells[k];
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for(int i=0; i<c->type; i++) {
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cellwalker cw0(c, i);
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if(!is_connected(cw0) && !is_connected(cw0+1) && !is_connected(cw0+wstep-1))
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corners++, cw = cw0;
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}
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}
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// printf("tree edges = %d, face edges = %d, corners = %d\n", tree_edges, face_edges, corners);
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map<cellwalker, cellwalker> next_corner;
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map<cellwalker, cellwalker> prev_corner;
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for(int ci=0; ci<corners; ci++) {
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cellwalker cw0 = cw;
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while(true) {
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cw++;
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if(is_connected(cw)) {
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cw += wstep;
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cw++;
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}
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if(!is_connected(cw+1) && !is_connected(cw+wstep-1))
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break;
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}
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next_corner[cw0] = cw;
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prev_corner[cw] = cw0;
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}
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vector<transmatrix> nearm;
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for(int ci=0; ci<corners; ci++) {
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for(int u=0; u<1; u++) {
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cellwalker cw1 = cw+u+wstep+(u-1);
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/* printf("%p/%d %p/%d ", cw.at, cw.spin, cw1.at, cw1.spin);
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printf("[%d %d %d] ", is_connected(cw), is_connected(cw+1), is_connected(cw+wstep-1));
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printf("[%d %d %d] ", is_connected(cw1), is_connected(cw1+1), is_connected(cw1+wstep-1));
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printf("%d %d;\n", !!next_corner.count(cw1), !!next_corner.count(cw1+wmirror-1)); */
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transmatrix T_here = gm[cw.at] * rel(cw+u);
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transmatrix T_there = gm[cw1.at];
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nearm.push_back(T_here * inverse(T_there));
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}
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cw = next_corner[cw];
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}
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vid.linewidth *= widthfactor;
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for(int ci=0; ci<corners; ci++) {
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hyperpoint h = corner(cw);
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cw = next_corner[cw];
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hyperpoint h2 = corner(cw);
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for(auto& T: nearm) queueline(T * h, T * h2, color1, 3);
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}
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for(int ci=0; ci<corners; ci++) {
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hyperpoint h = corner(cw);
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cw = next_corner[cw];
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hyperpoint h2 = corner(cw);
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queueline(h, h2, color2, 3);
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}
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if(0) for(int k=0; k<isize(cells); k++) {
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cell *c = cells[k];
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for(int i=0; i<c->type; i++) {
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cellwalker cw0(c, i);
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if(!is_connected(cw0)) continue;
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int v = 0;
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for(auto& n: nearm) {
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queueline(n * gm[cw0.at] * xspinpush0(v, .05), n * gm[cw0.cpeek()] * xspinpush0(v, .05), 0xFF8000FF, 0);
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v++;
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}
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queueline(gm[cw0.at] * C0, gm[cw0.cpeek()] * C0, 0xFF0000FF, 0);
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}
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}
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set<cellwalker> visited;
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int id = 0;
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for(int ci=0; ci<corners; ci++) {
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cellwalker cw1 = (cw+1+wstep);
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bool mirrored = false;
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if(!next_corner.count(cw1)) cw1 = cw1 + wmirror - 1, mirrored = true;
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// visited.insert(next_corner[cw]);
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// cellwalker cw2 = next_corner[cw];
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if(next_corner[cw] < (mirrored ? next_corner[cw1] : cw1)) {
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int mc = (mirrored ? color1 : color2) >> 8;
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if(hdist(corner(cw), corner(next_corner[cw])) > 1e-3) {
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queuestr(labelpos(corner(cw), corner(next_corner[cw])), label_scale/scalefactor, its(id), mc);
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if(mirrored)
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queuestr(labelpos(corner(cw1), corner(next_corner[cw1])), label_scale/scalefactor, its(id), mc);
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else
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queuestr(labelpos(corner(prev_corner[cw1]), corner(cw1)), label_scale/scalefactor, its(id), mc);
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id++;
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}
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}
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cw = next_corner[cw];
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}
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vid.linewidth /= widthfactor;
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}
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int readArgs() {
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using namespace arg;
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if(0) ;
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else if(argis("-fundamental")) {
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shift(); funmode = argi();
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shift(); color1 = arghex();
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shift(); color2 = arghex();
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shift_arg_formula(widthfactor);
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shift_arg_formula(label_scale);
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shift_arg_formula(label_dist);
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}
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else return 1;
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return 0;
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}
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auto fundamentalhook = addHook(hooks_args, 100, readArgs) + addHook(hooks_frame, 100, fundamental_marker);
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}
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} |