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hyperrogue/binary-tiling.cpp

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namespace hr {
namespace binary {
enum bindir {
bd_right = 0,
bd_up_right = 1,
bd_up = 2,
bd_up_left = 3,
bd_left = 4,
bd_down = 5, /* for cells of degree 6 */
bd_down_left = 5, /* for cells of degree 7 */
bd_down_right = 6 /* for cells of degree 7 */
};
int type_of(heptagon *h) {
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return h->c7->type;
}
// 0 - central, -1 - left, +1 - right
int mapside(heptagon *h) {
return h->zebraval;
}
#if DEBUG_BINARY_TILING
map<heptagon*, long long> xcode;
map<long long, heptagon*> rxcode;
long long expected_xcode(heptagon *h, int d) {
auto r =xcode[h];
if(d == 0) return r + 1;
if(d == 1) return 2*r + 1;
if(d == 2) return 2*r;
if(d == 3) return 2*r - 1;
if(d == 4) return r-1;
if(d == 5 && type_of(h) == 6) return r / 2;
if(d == 5 && type_of(h) == 7) return (r-1) / 2;
if(d == 6 && type_of(h) == 7) return (r+1) / 2;
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breakhere();
}
#endif
void breakhere() {
exit(1);
}
heptagon *path(heptagon *h, int d, int d1, std::initializer_list<int> p) {
static int rec = 0;
rec++; if(rec>100) exit(1);
// printf("{generating path from %p (%d/%d) dir %d:", h, type_of(h), mapside(h), d);
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heptagon *h1 = h;
for(int d0: p) {
// printf(" [%d]", d0);
h1 = hr::createStep(h1, d0);
// printf(" %p", h1);
}
#if DEBUG_BINARY_TILING
if(xcode[h1] != expected_xcode(h, d)) {
printf("expected_xcode mismatch\n");
breakhere();
}
#endif
// printf("}\n");
if(h->move(d) && h->move(d) != h1) {
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printf("already connected to something else (1)\n");
breakhere();
}
if(h1->move(d1) && h1->move(d1) != h) {
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printf("already connected to something else (2)\n");
breakhere();
}
h->c.connect(d, h1, d1, false);
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rec--;
return h1;
}
heptagon *build(heptagon *parent, int d, int d1, int t, int side, int delta) {
auto h = buildHeptagon1(tailored_alloc<heptagon> (t), parent, d, hsOrigin, d1);
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h->distance = parent->distance + delta;
h->c7 = newCell(t, h);
h->cdata = NULL;
h->zebraval = side;
#if DEBUG_BINARY_TILING
xcode[h] = expected_xcode(parent, d);
if(rxcode.count(xcode[h])) {
printf("xcode clash\n");
breakhere();
}
rxcode[xcode[h]] = h;
#endif
return h;
}
heptagon *createStep(heptagon *parent, int d) {
auto h = parent;
switch(d) {
case bd_right: {
if(mapside(h) > 0 && type_of(h) == 7)
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return path(h, d, bd_left, {bd_left, bd_down, bd_right, bd_up});
else if(mapside(h) >= 0)
return build(parent, bd_right, bd_left, type_of(parent) ^ 1, 1, 0);
else if(type_of(h) == 6)
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return path(h, d, bd_left, {bd_down, bd_right, bd_up, bd_left});
else
return path(h, d, bd_left, {bd_down_right, bd_up});
}
case bd_left: {
if(mapside(h) < 0 && type_of(h) == 7)
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return path(h, d, bd_right, {bd_right, bd_down, bd_left, bd_up});
else if(mapside(h) <= 0)
return build(parent, bd_left, bd_right, type_of(parent) ^ 1, -1, 0);
else if(type_of(h) == 6)
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return path(h, d, bd_right, {bd_down, bd_left, bd_up, bd_right});
else
return path(h, d, bd_right, {bd_down_left, bd_up});
}
case bd_up_right: {
return path(h, d, bd_down_left, {bd_up, bd_right});
}
case bd_up_left: {
return path(h, d, bd_down_right, {bd_up, bd_left});
}
case bd_up:
return build(parent, bd_up, bd_down, 6, mapside(parent), 1);
default:
/* bd_down */
if(type_of(h) == 6) {
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if(mapside(h) == 0)
return build(parent, bd_down, bd_up, 6, 0, -1);
else if(mapside(h) == 1)
return path(h, d, bd_up, {bd_left, bd_left, bd_down, bd_right});
else if(mapside(h) == -1)
return path(h, d, bd_up, {bd_right, bd_right, bd_down, bd_left});
}
/* bd_down_left */
else if(d == bd_down_left) {
return path(h, d, bd_up_right, {bd_left, bd_down});
}
else if(d == bd_down_right) {
return path(h, d, bd_up_left, {bd_right, bd_down});
}
}
printf("error: case not handled in binary tiling\n");
breakhere();
return NULL;
}
transmatrix parabolic(ld u) {
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u = u * vid.binary_width / log(2);
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return transmatrix {{{-u*u/8+1, u/2, u*u/8}, {-u/2, 1, u/2}, {-u*u/8, u/2, u*u/8+1}}};
}
void draw() {
dq::visited.clear();
dq::enqueue(viewctr.at, cview());
while(!dq::drawqueue.empty()) {
auto& p = dq::drawqueue.front();
heptagon *h = get<0>(p);
transmatrix V = get<1>(p);
dynamicval<ld> b(band_shift, get<2>(p));
bandfixer bf(V);
dq::drawqueue.pop();
cell *c = h->c7;
if(!do_draw(c, V)) continue;
drawcell(c, V, 0, false);
dq::enqueue(h->move(bd_up), V * xpush(-log(2)));
dq::enqueue(h->move(bd_right), V * parabolic(1));
dq::enqueue(h->move(bd_left), V * parabolic(-1));
if(c->type == 6)
dq::enqueue(h->move(bd_down), V * xpush(log(2)));
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// down_left
if(c->type == 7) {
dq::enqueue(h->move(bd_down_left), V * parabolic(-1) * xpush(log(2)));
dq::enqueue(h->move(bd_down_right), V * parabolic(1) * xpush(log(2)));
}
}
}
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transmatrix relative_matrix(heptagon *h2, heptagon *h1) {
if(gmatrix0.count(h2->c7) && gmatrix0.count(h1->c7))
return inverse(gmatrix0[h1->c7]) * gmatrix0[h2->c7];
transmatrix gm = Id, where = Id;
while(h1 != h2) {
if(h1->distance <= h2->distance) {
if(type_of(h2) == 6)
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h2 = hr::createStep(h2, bd_down), where = xpush(-log(2)) * where;
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else if(mapside(h2) == 1)
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h2 = hr::createStep(h2, bd_left), where = parabolic(+1) * where;
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else if(mapside(h2) == -1)
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h2 = hr::createStep(h2, bd_right), where = parabolic(-1) * where;
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}
else {
if(type_of(h1) == 6)
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h1 = hr::createStep(h1, bd_down), gm = gm * xpush(log(2));
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else if(mapside(h1) == 1)
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h1 = hr::createStep(h1, bd_left), gm = gm * parabolic(-1);
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else if(mapside(h1) == -1)
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h1 = hr::createStep(h1, bd_right), gm = gm * parabolic(+1);
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}
}
return gm * where;
}
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auto bt_config = addHook(hooks_args, 0, [] () {
using namespace arg;
if(argis("-btwidth")) {
shift_arg_formula(vid.binary_width, delayed_geo_reset);
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return 0;
}
return 1;
});
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}
}