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arbiquotient:: support nonorientable

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Zeno Rogue
2025-10-07 21:56:34 +02:00
parent 8a60ef95c7
commit 8eb5e8b642
1 changed files with 135 additions and 44 deletions
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179
arbiquotient.cpp
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@@ -7,11 +7,18 @@ namespace hr {
EX namespace arbiquotient {
int aq_max = 100;
int aq_max = 10;
bool running = false;
bool displaying = false;
bool block_selfedges = true;
bool block_cones = true;
bool block_selfedges = false;
bool block_cones = false;
bool block_mirrors = false;
bool dedup_rotation = true;
bool dedup_mirror = true;
bool dedup_focus = true;
bool allow_nonorientable = false;
map<cell*, cellwalker> aqs;
@@ -93,7 +100,7 @@ bool apply_uni() {
return true;
}
vector<int> quotient_output(int dir) {
vector<int> quotient_output(int dir, bool mirrored) {
vector<int> output;
int next_offset = 0;
map<cell*, pair<int, cellwalker>> offsets;
@@ -110,9 +117,9 @@ vector<int> quotient_output(int dir) {
auto &tmp = offsets[cw.at];
auto ofs = tmp.first;
auto cw1 = tmp.second;
return ofs + gmod(cw.spin - cw1.spin, cw.at->type);
return ofs + cwdiff_fixed(cw, cw1) + (cw.mirrored != cw1.mirrored ? quotientspace::symmask : 0);
};
assign_id(cellwalker(currentmap->gamestart(), dir));
assign_id(cellwalker(currentmap->gamestart(), dir, mirrored));
for(int i=0; i<isize(listorder); i++) {
cell *c = listorder[i];
// auto [ofs, cw] = offsets[c];
@@ -123,48 +130,72 @@ vector<int> quotient_output(int dir) {
return output;
}
/** \brief return the statistical information about the current orbifold
* in case of incorrect identification, may also return ERROR
*/
string statstring() {
int selfedges = 0;
int mirrors = 0;
int tiles = 0;
int goodedges = 0;
map<int, ld> verts;
map<int, ld> mverts;
for(auto p: allaq) {
auto ref = ufind(p->where);
if(ref.at == p->where) {
tiles++;
for(int i=0; i<p->where->type; i++) {
cellwalker cw(p->where, i);
println(hlog, cw, " vs ", ufind(cw+wstep));
if(cw == ufind(cw+wstep)) selfedges++;
else if(cw == ufind(cw+wstep+wmirror)) mirrors++;
else goodedges++;
if(arb::current.have_valence) {
if(arb::current.have_valence) for(bool mirr: {false, true}) {
auto& sh = arb::current.shapes[shvid(cw.at)];
int val = sh.vertex_valence[i];
int val = sh.vertex_valence[mirr ? gmod(i-1, cw.at->type) : i];
int steps = 0;
auto cw1 = cw;
bool has_mirror = false;
auto cwc = cw; if(mirr) cwc += wmirror;
auto cw1 = cwc;
do {
println(hlog, "at ", cw1);
cw1 += wstep; cw1++; steps++;
cw1 += wstep; cw1 = ufind(cw1);
println(hlog, " ", cw1);
if(cw1 == cwc+wmirror) has_mirror = true;
cw1++; steps++;
cw1 = ufind(cw1);
if(steps > 100) { return "ERROR"; }
}
while(cw1 != cw);
println(hlog, "looped back to ", cw);
if(val % steps) throw hr_exception("divisibility error");
verts[val / steps] += 1. / steps;
while(cw1 != cwc);
println(hlog, "looped back to ", cwc, has_mirror ? " (m)" : "");
if(val % steps) return "ERROR";
if(has_mirror) mverts[val / steps] += 1. / steps;
else verts[val / steps] += 0.5 / steps;
}
}
}
}
shstream s;
println(hlog, verts);
print(s, "F:", tiles, " ");
if(goodedges % 2) throw hr_exception("divisibility error III");
print(s, "E:", goodedges/2, " ");
if(!block_selfedges) print(s, "e:", selfedges, " ");
for(auto p: verts) {
auto v = p.second + 1e-6;
auto fl = floor(v);
if(v - fl > 2e-6) throw hr_exception("divisibility error II");
print(s, p.first, ":", int(fl), " ");
println(hlog, tie(goodedges, selfedges, mirrors));
println(hlog, "verts = ", verts, " mverts = ", mverts);
print(s, "F:", tiles);
if(goodedges % 2) return "ERROR";
print(s, " E:", goodedges/2);
if(!block_selfedges) print(s, " e:", selfedges);
if(!block_mirrors) print(s, " M:", mirrors);
for(bool star: {false, true}) {
bool first = true;
for(auto p: (star ? mverts : verts)) {
auto v = p.second + 1e-6;
auto fl = int(floor(v));
if(v - fl > 2e-6) return "ERROR";
if(first) {
print(s, star ? " *" : " ");
first = false;
}
if(fl <= 3) for(int i=0; i<fl; i++) print(s, p.first);
else print(s, p.first, "[", fl, "]");
}
}
return s.s;
}
@@ -241,6 +272,7 @@ void recurse() {
auto ref = ufind(p->where);
hashmix(hash, aq.at(ref.at).id);
hashmix(hash, ref.spin);
hashmix(hash, ref.mirrored);
backup.push_back(p->parent);
if(p->parent.at == p->where) {
active.push_back(p->where);
@@ -252,6 +284,12 @@ void recurse() {
if(aq.count(cw1.at) && cw == ufind(cw1)) return;
}
if(block_mirrors) for(int i=0; i<p->where->type; i++) {
cellwalker cw(p->where, i);
auto cw1 = cw + wstep + wmirror;
if(aq.count(cw1.at) && cw == ufind(cw1)) return;
}
if(block_cones && arb::current.have_valence && p->closed) for(int i=0; i<p->where->type; i++) {
cellwalker cw(p->where, i);
auto& sh = arb::current.shapes[shvid(cw.at)];
@@ -276,14 +314,39 @@ void recurse() {
cellwalker cw0 = currentmap->gamestart();
println(hlog, "active ", isize(active), " numopen = ", numopen, " actives = ", active);
int shid = shvid(cw0.at);
auto& sh = arb::current.shapes[shid];
int cl = sh.cycle_length;
if(numopen == 0) {
println(hlog, "closed found!");
int shid = shvid(cw0.at);
vector<int> bqo = {999};
int cl = arb::current.shapes[shid].cycle_length;
for(int i=0; i<cw0.at->type; i+=cl) {
auto qo = quotient_output(i);
if(qo < bqo) bqo = qo;
vector<int> bqo = {999 | quotientspace::symmask};
for(auto li: active) {
auto oshvid = shvid(li);
bool mirr = arb::current.shapes[oshvid].is_mirrored;
oshvid = arb::current.shapes[oshvid].orig_id;
if(oshvid != shid) continue;
if(!mirr) {
for(int i=0; i<cw0.at->type; i+=cl) {
auto qo = quotient_output(i, false);
if(qo < bqo) bqo = qo;
if(sh.symmetric_value && dedup_mirror) {
auto qo = quotient_output(sh.reflect(i), true);
if(qo < bqo) bqo = qo;
}
if(!dedup_rotation) break;
}
if(!dedup_focus) break;
}
if(mirr && dedup_mirror) {
for(int i=0; i<cw0.at->type; i+=cl) {
auto qo = quotient_output(cw0.at->type-i-1, true);
if(qo < bqo) bqo = qo;
if(!dedup_rotation) break;
}
}
}
buckethash_t vhash = 0;
@@ -291,24 +354,38 @@ void recurse() {
if(seen_outputs.count(vhash)) return;
seen_outputs.insert(vhash);
println(hlog, "[", isize(all_found), "] ", bqo);
all_found.push_back(qdata{statstring() + format("%016lX", (long) vhash), bqo});
auto ss = statstring();
if(ss == "ERROR") return;
all_found.push_back(qdata{ss + format(" %016lX", (long) vhash), bqo});
if(!(cgflags & qCLOSED)) return;
}
indenter ind(2);
int shid = shvid(cw0.at);
int cl = arb::current.shapes[shid].cycle_length;
for(auto li: active) if(li != cw0.at) {
if(shvid(li) != shid) continue;
for(int ro=0; ro<cw0.at->type; ro+=cl) {
unifications.emplace_back(cw0, cellwalker(li, ro));
auto tryout = [&] (cellwalker cw1) {
unifications.emplace_back(cw0, cw1);
bool b = apply_uni();
if(b) recurse();
else unifications.clear();
auto backup_iterator = backup.begin();
for(auto p: allaq) p->parent = *(backup_iterator++);
};
auto oshvid = shvid(li);
bool mirr = arb::current.shapes[oshvid].is_mirrored;
oshvid = arb::current.shapes[oshvid].orig_id;
if(oshvid != shid) continue;
if(allow_nonorientable && mirr) {
for(int ro=0; ro<cw0.at->type; ro+=cl) tryout(cellwalker(li, cw0.at->type-1-ro, true));
}
if(!mirr) for(int ro=0; ro<cw0.at->type; ro+=cl) {
tryout(cellwalker(li, ro));
if(allow_nonorientable && sh.symmetric_value) {
tryout(cellwalker(li, sh.reflect(ro), true));
}
}
auto backup_iterator = backup.begin();
for(auto p: allaq) p->parent = *(backup_iterator++);
}
}
@@ -321,7 +398,7 @@ void auto_create(int num) {
enlist(cw0.at);
int id = 0;
while(id < num) {
while(id < num && id < isize(allaq)) {
auto aqd = allaq[id++];
cell *c = aqd->where;
forCellCM(c1, c) if(!aq.count(c1)) enlist(c1);
@@ -365,9 +442,8 @@ struct hrmap_autoquotient : hrmap {
get_conn(0, 0);
for(int i=0; i<isize(connections); i++) {
auto co = connections[i];
auto co2 = get_conn(quotient_data[i], arb::current.shapes[co.first->zebraval].connections[co.second].sid);
println(hlog, "connectng ", co, " to ", co2);
co.first->c.connect(co.second, co2.first, co2.second, 0);
auto co2 = get_conn(quotient_data[i] &~ quotientspace::symmask, arb::current.shapes[co.first->zebraval].connections[co.second].sid);
co.first->c.connect(co.second, co2.first, co2.second, (quotient_data[i] & quotientspace::symmask));
}
println(hlog, "connections created");
}
@@ -377,7 +453,7 @@ struct hrmap_autoquotient : hrmap {
}
transmatrix adj(heptagon *h, int dir) override {
return arb::get_adj(arb::current_or_slided(), h->zebraval, dir, h->move(dir)->zebraval, h->c.spin(dir), false);
return arb::get_adj(arb::current_or_slided(), h->zebraval, dir, h->move(dir)->zebraval, h->c.spin(dir), h->c.mirror(dir));
}
int shvid(cell *c) override {
@@ -399,6 +475,11 @@ void show_auto_dialog() {
add_edit(aq_max);
add_edit(block_selfedges);
add_edit(block_cones);
add_edit(block_mirrors);
add_edit(allow_nonorientable);
add_edit(dedup_rotation);
add_edit(dedup_focus);
add_edit(dedup_mirror);
dialog::addBoolItem(XLAT("running"), running, 'r');
dialog::add_action([] {
println(hlog, "action");
@@ -465,6 +546,16 @@ auto aqhook =
-> editable("block cone points", 'c');
param_b(block_selfedges, "aq_block_selfedges")
-> editable("block self-edges", 'e');
param_b(block_mirrors, "aq_block_mirrors")
-> editable("block mirrors", 'm');
param_b(allow_nonorientable, "aq_allow_nonorientable")
-> editable("allow nonorientable", 'n');
param_b(dedup_rotation, "aq_dedup_rotation")
-> editable("dedup rotation", 's');
param_b(dedup_focus, "aq_dedup_focus")
-> editable("dedup focus", 'f');
param_b(dedup_mirror, "aq_dedup_mirror")
-> editable("dedup mirror", 'o');
})
+ addHook(hooks_newmap, 0, [] {
if(geometry == gArbitrary && quotient) {