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hyperrogue/rogueviz/dhrg/mycell.cpp
2022-07-12 14:46:31 +02:00

285 lines
6.8 KiB
C++

// mycell -- information about the given vertex of a triangulation
// cell is the relevant struct from HyperRogue; we do not use cell directly to conserve memory
namespace dhrg {
int mycellcount;
struct segmentlist {
segment *s;
segmentlist *next;
};
struct mycell {
#ifdef BUILD_ON_HR
cell *c;
#else
int type;
#endif
int lev;
mycell *leftparent, *rightparent;
mycell *leftsibling, *rightsibling;
mycell *leftchild;
#ifdef LONG_BRACKETS
segmentlist* bracketing;
#endif
#ifdef BUILD_ON_HR
mycell(cell *_c) : c(_c) {
leftparent = rightparent =
leftsibling = rightsibling =
NULL;
#ifdef LONG_BRACKETS
bracketing = NULL;
#endif
mycellcount++;
for(int i=0; i<SETS; i++)
byleft[i] = byright[i] = NULL;
}
#else
mycell() {
leftsibling = rightsibling = leftchild = NULL;
mycellcount++;
for(int i=0; i<SETS; i++)
byleft[i] = byright[i] = NULL;
#ifdef LONG_BRACKETS
bracketing = NULL;
#endif
}
#endif
segment *byleft[SETS];
segment *byright[SETS];
~mycell() { mycellcount--; }
#ifdef BUILD_ON_HR
void build();
mycell *grightsibling() { return rightsibling; }
mycell *gleftsibling() { return leftsibling; }
mycell *gleftchild() { return leftchild; }
void gchildren() {}
cell *ascell() { return c; }
int gettype() { return celltype(c); }
#else
void build() {}
mycell *grightsibling();
mycell *gleftsibling();
mycell *gleftchild();
void gchildren();
cell *ascell();
int gettype() { return type; }
#endif
};
#ifdef BUILD_ON_HR
map<cell*, mycell*> mymap;
mycell *find_mycell(cell *c) {
mycell*& mc = mymap[c];
if(mc == NULL) mc = new mycell(c);
return mc;
}
void mycell::build() {
const auto m = this;
if(m->leftsibling) return; // already computed
cell *c2[MAX_EDGE+1];
int dist[MAX_EDGE+1];
int t = m->c->type;
int d = celldist(m->c);
m->lev = d;
if(d == 0) {
m->leftsibling = m->rightsibling = m;
m->leftchild = find_mycell(createMov(m->c,0));
forCellCM(c2, croot()) find_mycell(c2)->build();
}
else {
for(int i=0; i<t; i++) c2[i] = createMov(m->c, i);
for(int i=0; i<t; i++) dist[i] = celldist(c2[i]);
dist[t] = dist[0]; c2[t] = c2[0];
for(int i=0; i<t; i++) {
if(dist[i] < d && dist[i+1] == d) {
m->leftparent = find_mycell(c2[i]);
m->leftsibling = find_mycell(c2[i+1]);
m->leftchild = find_mycell(c2[(i+2)%t]);
}
if(dist[i] == d && dist[i+1] < d) {
m->rightparent = find_mycell(c2[i+1]);
m->rightsibling = find_mycell(c2[i]);
}
}
}
}
#endif
mycell *mroot;
void generate_root() {
#if BUILD_ON_HR
mroot = find_mycell(croot());
#else
int origtype = cgi.expansion->rootid;
mroot = new mycell();
mroot->lev = 0;
mroot->type = origtype;
mroot->leftsibling = mroot->rightsibling = mroot;
mroot->leftparent = mroot->rightparent = NULL;
mycell *child;
bool first = true;
for(int c: cgi.expansion->children[origtype]) {
if(first) {
first = false;
mroot->leftchild = child = new mycell();
}
else {
child->rightsibling = new mycell();
child->rightsibling->leftsibling = child;
child = child->rightsibling;
}
child->leftparent = child->rightparent = mroot;
child->type = c;
child->lev = 1;
}
child->rightsibling = mroot->leftchild;
mroot->leftchild->leftsibling = child;
#endif
}
#ifndef BUILD_ON_HR
/* mycell *find_mycell(cell *c) {
printf("find_mycell not implemented\n");
exit(1);
} */
mycell* mycell::gleftsibling() {
if(leftsibling) return leftsibling;
leftparent->gchildren();
if(!leftsibling) {
printf("error: no left sibling found\n");
exit(1);
}
return leftsibling;
}
mycell* mycell::grightsibling() {
if(rightsibling) return rightsibling;
rightparent->gchildren();
if(!rightsibling) {
printf("error: no right sibling found\n");
}
return rightsibling;
}
mycell* mycell::gleftchild() {
if(leftchild) return leftchild;
leftchild = new mycell();
leftchild->leftparent = gleftsibling();
leftchild->rightparent = this;
leftchild->lev = lev+1;
leftchild->type = cgi.expansion->children[type][0];
return leftchild;
}
void mycell::gchildren() {
mycell *child = gleftchild();
if(child->rightsibling) return;
bool first = true;
for(int c: cgi.expansion->children[type]) {
if(first) {
first = false;
continue;
}
child->rightsibling = new mycell();
child->rightsibling->leftsibling = child;
child = child->rightsibling;
child->leftparent = child->rightparent = this;
child->type = c;
child->lev = lev + 1;
}
child->rightsibling = grightsibling()->gleftchild();
child->rightsibling->leftsibling = child;
}
#endif
vector<mycell*> allchildren(mycell *m, int dir=0) {
m->build();
vector<mycell*> res;
if(m->lev == 0) {
mycell *f = mroot->leftchild;
int origtype = cgi.expansion->rootid;
for(int i: cgi.expansion->children[origtype]) {
ignore(i);
res.push_back(f);
f = f->rightsibling;
}
return res;
}
auto m1 = m->gleftchild();
while(true) {
m1->build();
bool isright = m1->rightparent == m;
bool isleft = m1->leftparent == m;
if(!isright && !isleft) return res;
if(dir > 0 && !isright) ;
else if(dir < 0 && !isleft) ;
else res.push_back(m1);
m1 = m1->grightsibling();
}
}
vector<mycell*> allneighbors(mycell *m) {
auto ret = allchildren(m);
if(m->gleftsibling() != m) {
ret.push_back(m->leftsibling);
ret.push_back(m->grightsibling());
}
if(m->leftparent) {
ret.push_back(m->leftparent);
if(m->rightparent != m->leftparent)
ret.push_back(m->rightparent);
}
return ret;
}
mycell *find_mycell_by_path(const string& s) {
mycell *at = mroot;
for(char c: s) {
at = at->gleftchild();
while(c > '0') c--, at = at->grightsibling();
}
return at;
}
int childindex(mycell *c) {
mycell *p = c->rightparent->leftchild;
int i = 0;
while(p != c) p = p->grightsibling(), i++;
return i;
}
string get_path(mycell *c) {
string s;
while(c != mroot) s += '0' + childindex(c), c = c->rightparent;
reverse(s.begin(), s.end());
return s;
}
#ifndef BUILD_ON_HR
cell *mycell::ascell() {
if(lev == 0) return croot();
auto m = this; m->build();
auto c = rightparent->ascell();
int childid = 0;
while(m != m->rightparent->leftchild)
childid++, m = m->gleftsibling();
if(lev == 1) return createMov(croot(), childid);
cell *c2 = ts::child_number(c, childid, celldist);
return c2;
}
#endif
}