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hyperrogue/fake.cpp

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#include "hyper.h"
// Fake non-Euclidean
namespace hr {
EX namespace fake {
EX ld scale;
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EX bool multiple;
EX bool multiple_special_draw = true;
EX bool recursive_draw = false;
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EX eGeometry underlying;
EX geometry_information *underlying_cgip;
EX hrmap *pmap;
EX geometry_information *pcgip;
EX eGeometry actual_geometry;
EX bool in() { return geometry == gFake; }
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EX bool available() {
if(in()) return true;
if(GDIM == 2 && standard_tiling() && (PURE || BITRUNCATED)) return true;
if(arcm::in() && PURE) return true;
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if(GDIM == 2) return false;
if(among(geometry, gRhombic3, gBitrunc3)) return false;
return euc::in() || reg3::in();
}
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// a dummy map that does nothing
struct hrmap_fake : hrmap {
hrmap *underlying_map;
template<class T> auto in_underlying(const T& t) -> decltype(t()) {
pcgip = cgip;
dynamicval<hrmap*> gpm(pmap, this);
dynamicval<eGeometry> gag(actual_geometry, geometry);
dynamicval<eGeometry> g(geometry, underlying);
dynamicval<geometry_information*> gc(cgip, underlying_cgip);
dynamicval<hrmap*> gu(currentmap, underlying_map);
return t();
}
heptagon *getOrigin() override { return in_underlying([this] { return underlying_map->getOrigin(); }); }
cell* gamestart() override { return in_underlying([this] { return underlying_map->gamestart(); }); }
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hrmap_fake(hrmap *u) {
underlying_map = u;
for(hrmap*& m: allmaps) if(m == underlying_map) m = this;
if(currentmap == u) currentmap = this;
}
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hrmap_fake() {
in_underlying([this] { initcells(); underlying_map = currentmap; });
for(hrmap*& m: allmaps) if(m == underlying_map) m = NULL;
}
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~hrmap_fake() {
in_underlying([this] {
delete underlying_map;
});
}
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heptagon *create_step(heptagon *parent, int d) override {
parent->c.connect(d, parent, d, false);
return parent;
}
transmatrix adj(cell *c, int d) override {
transmatrix S1, S2;
ld dist;
in_underlying([c, d, &S1, &S2, &dist] {
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dynamicval<bool> u(arcm::use_gmatrix, false);
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transmatrix T = currentmap->adj(c, d);
S1 = rspintox(tC0(T));
transmatrix T1 = spintox(tC0(T)) * T;
dist = hdist0(tC0(T1));
S2 = xpush(-dist) * T1;
});
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if(arcm::in()) {
int t = arcm::id_of(c->master);
int t2 = arcm::id_of(c->move(d)->master);
auto& cof = arcm::current_or_fake();
cgi.adjcheck = cof.inradius[t/2] + cof.inradius[t2/2];
}
else if(WDIM == 2) {
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ld dist;
in_underlying([c, d, &dist] {
dist = currentmap->spacedist(c, d);
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});
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auto& u = *underlying_cgip;
if(dist == u.tessf) cgi.adjcheck = cgi.tessf;
else if(dist == u.crossf) cgi.adjcheck = cgi.crossf;
else if(dist == u.hexhexdist) cgi.adjcheck = cgi.hexhexdist;
else cgi.adjcheck = dist * scale;
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}
return S1 * xpush(cgi.adjcheck) * S2;
}
void draw_recursive(cell *c, const transmatrix& V, ld a0, ld a1, cell *parent, int depth) {
band_shift = 0;
if(!do_draw(c, V)) return;
drawcell(c, V);
if(depth >= 15) return;
// queuestr(V, .2, fts(a0)+":"+fts(a1), 0xFFFFFFFF, 1);
ld d = hdist0(tC0(V));
if(false) {
curvepoint(spin(-a0) * xpush0(d));
curvepoint(spin(-a0) * xpush0(d+.2));
curvepoint(spin(-a1) * xpush0(d+.2));
curvepoint(spin(-a1) * xpush0(d));
curvepoint(spin(-a0) * xpush0(d));
queuecurve(0xFF0000FF, 0, PPR::LINE);
}
indenter id(2);
for(int i=0; i<c->type; i++) if(c->move(i) && c->move(i) != parent) {
auto h0 = V * befake(FPIU(get_corner_position(c, i)));
auto h1 = V * befake(FPIU(get_corner_position(c, (i+1) % c->type)));
ld b0 = atan2(h0);
ld b1 = atan2(h1);
while(b1 < b0) b1 += 2 * M_PI;
if(a0 == -1) {
draw_recursive(c->move(i), V * adj(c, i), b0, b1, c, depth+1);
}
else {
if(b1 - b0 > M_PI) continue;
if(b0 < a0 - M_PI) b0 += 2 * M_PI;
if(b0 > a0 + M_PI) b0 -= 2 * M_PI;
if(b0 < a0) b0 = a0;
if(b1 > a1 + M_PI) b1 -= 2 * M_PI;
if(b1 < a1 - M_PI) b1 += 2 * M_PI;
if(b1 > a1) b1 = a1;
if(b0 > b1) continue;
draw_recursive(c->move(i), V * adj(c, i), b0, b1, c, depth+1);
}
}
}
transmatrix relative_matrix(cell *h2, cell *h1, const hyperpoint& hint) override {
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if(arcm::in()) return underlying_map->relative_matrix(h2, h1, hint);
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if(h1 == h2) return Id;
for(int a=0; a<h1->type; a++) if(h1->move(a) == h2)
return adj(h1, a);
return Id;
}
transmatrix relative_matrix(heptagon *h2, heptagon *h1, const hyperpoint& hint) override {
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if(arcm::in()) return underlying_map->relative_matrix(h2, h1, hint);
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return relative_matrix(h2->c7, h1->c7, hint);
}
void draw() override {
sphereflip = Id;
// for(int i=0; i<S6; i++) queuepoly(ggmatrix(cwt.at), shWall3D[i], 0xFF0000FF);
if(pmodel == mdDisk && WDIM == 2 && recursive_draw) {
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draw_recursive(centerover, cview(), -1, -1, nullptr, 0);
return;
}
dq::visited_c.clear();
dq::visited_by_matrix.clear();
auto enqueue = (multiple && multiple_special_draw ? dq::enqueue_by_matrix_c : dq::enqueue_c);
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enqueue(centerover, cview());
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int id = 0;
int limit = 100 * pow(1.2, sightrange_bonus);
if(WDIM == 3 || vid.use_smart_range)
limit = INT_MAX;
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while(!dq::drawqueue_c.empty()) {
auto& p = dq::drawqueue_c.front();
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id++;
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cell *c = get<0>(p);
transmatrix V = get<1>(p);
dynamicval<ld> b(band_shift, get<2>(p));
bandfixer bf(V);
dq::drawqueue_c.pop();
if(!do_draw(c, V)) continue;
drawcell(c, V);
if(in_wallopt() && isWall3(c) && isize(dq::drawqueue_c) > 1000) continue;
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if(id > limit) continue;
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for(int i=0; i<c->type; i++) if(c->move(i)) {
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enqueue(c->move(i), V * adj(c, i));
}
}
}
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ld spin_angle(cell *c, int d) override {
return underlying_map->spin_angle(c,d);
}
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};
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EX hrmap* new_map() { return new hrmap_fake; }
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EX hrmap* get_umap() { if(!dynamic_cast<hrmap_fake*>(currentmap)) return nullptr; else return ((hrmap_fake*)currentmap)->underlying_map; }
#if HDR
template<class T> auto in_underlying_geometry(const T& f) -> decltype(f()) {
if(!fake::in()) return f();
dynamicval<eGeometry> g(geometry, underlying);
dynamicval<eGeometry> gag(actual_geometry, geometry);
dynamicval<geometry_information*> gc(cgip, underlying_cgip);
dynamicval<hrmap*> gpm(pmap, currentmap);
dynamicval<hrmap*> gm(currentmap, get_umap());
return f();
}
#define FPIU(x) hr::fake::in_underlying_geometry([&] { return (x); })
#endif
EX hyperpoint befake(hyperpoint h) {
auto h1 = h / h[WDIM] * scale;
h1[WDIM] = 1;
if(material(h1) > 1e-3)
h1 = normalize(h1);
return h1;
}
EX vector<hyperpoint> befake(const vector<hyperpoint>& v) {
vector<hyperpoint> res;
for(auto& h: v) res.push_back(befake(h));
return res;
}
EX ld compute_around(bool setup) {
auto &ucgi = *underlying_cgip;
auto fcs = befake(ucgi.cellshape);
if(setup) {
cgi.cellshape = fcs;
cgi.vertices_only = befake(ucgi.vertices_only);
}
hyperpoint h = Hypc;
for(int i=0; i<ucgi.face; i++) h += fcs[i];
if(material(h) > 0)
h = normalize(h);
if(setup)
cgi.adjcheck = 2 * hdist0(h);
hyperpoint u = Hypc;
u += fcs[0];
u += fcs[1];
if(material(u) <= 0)
return HUGE_VAL;
u = normalize(u);
hyperpoint h2 = rspintox(h) * xpush0(2 * hdist0(h));
h2 = spintox(u) * h2;
u = spintox(u) * u;
h2 = gpushxto0(u) * h2;
u = gpushxto0(u) * u;
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ld x = hypot(h2[1], h2[2]);
ld y = h2[0];
return 360 / (90 + atan(y/x) / degree);
}
EX void generate() {
FPIU( cgi.require_basics() );
auto &ucgi = *underlying_cgip;
cgi.loop = ucgi.loop;
cgi.face = ucgi.face;
cgi.schmid = ucgi.schmid;
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for(int a=0; a<16; a++)
for(int b=0; b<16; b++) {
cgi.dirs_adjacent[a][b] = ucgi.dirs_adjacent[a][b];
cgi.next_dir[a][b] = ucgi.next_dir[a][b];
}
for(int b=0; b<12; b++)
cgi.spins[b] = ucgi.spins[b];
compute_around(true);
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reg3::compute_ultra();
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}
int get_middle() {
if(S7 == 20) return 5;
if(S7 == 8) return 4;
return 3;
}
EX ld around;
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/** @brief the value of 'around' which makes the tiling Euclidean */
EX ld compute_euclidean() {
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if(arcm::in()) return arcm::current.N * 2 / arcm::current.euclidean_angle_sum;
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if(WDIM == 2) return 4 / (S7-2.) + 2;
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int middle = get_middle();
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return M_PI / asin(cos(M_PI/middle) / sin(M_PI/underlying_cgip->face));
}
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EX int around_orig() {
if(arcm::in())
return arcm::current.N;
if(WDIM == 2)
return S3;
return
underlying_cgip->loop;
}
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EX void compute_scale() {
ld good = compute_euclidean();
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if(around < 0) around = good;
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if(abs(good - around) < 1e-6) good = around;
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int s3 = around_orig();
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multiple = false;
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int mcount = int(around / s3 + .5);
multiple = abs(around - mcount * s3) < 1e-6;
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if(around == good) {
ginf[gFake].g = WDIM == 3 ? giEuclid3 : giEuclid2;
}
if(around > good) {
ginf[gFake].g = WDIM == 3 ? giHyperb3 : giHyperb2;
}
if(around < good) {
ginf[gFake].g = WDIM == 3 ? giSphere3 : giSphere2;
}
ld around_ideal = 1/(1/2. - 1./get_middle());
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if(arcm::in()) {
ginf[gFake].tiling_name = "(" + ginf[gArchimedean].tiling_name + ")^" + fts(around / around_orig());
return;
}
else if(WDIM == 2) {
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ginf[gFake].tiling_name = lalign(0, "{", S7, ",", around, "}");
return;
}
else if(euclid) scale = 1;
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else if(abs(around_ideal - around) < 1e-6) {
hyperpoint h0 = underlying_cgip->cellshape[0];
auto s = kleinize(h0);
ld d = hypot_d(LDIM, s);
scale = 1/d;
hyperpoint h = h0;
auto h1 = h / h[WDIM] * scale;
h1[WDIM] = 1;
set_flag(ginf[gFake].flags, qIDEAL, true);
set_flag(ginf[gFake].flags, qULTRA, false);
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}
else {
set_flag(ginf[gFake].flags, qIDEAL, false);
set_flag(ginf[gFake].flags, qULTRA, around > around_ideal);
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ld minscale = 0, maxscale = 10;
for(int it=0; it<100; it++) {
scale = (minscale + maxscale) / 2;
ld ar = compute_around(false);
if(sphere) {
if(ar < around) maxscale = scale;
else minscale = scale;
}
else {
if(ar > around) maxscale = scale;
else minscale = scale;
}
}
}
auto& u = underlying_cgip;
ginf[gFake].tiling_name = lalign(0, "{", u->face, ",", get_middle(), ",", around, "}");
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}
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void set_gfake(ld _around) {
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cgi.require_basics();
underlying = geometry;
underlying_cgip = cgip;
ginf[gFake] = ginf[underlying];
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geometry = gFake;
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around = _around;
compute_scale();
check_cgi();
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cgi.require_basics();
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ginf[gFake].xcode = no_code;
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if(currentmap) new hrmap_fake(currentmap);
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}
EX void change_around() {
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if(around >= 0 && around <= 2) return;
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ld t = in() ? scale : 1;
hyperpoint h = inverse_exp(tC0(View));
transmatrix T = gpushxto0(tC0(View)) * View;
ld range = sightranges[geometry];
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if(!fake::in()) {
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if(around == around_orig()) return; /* do nothing */
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set_gfake(around);
}
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else {
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compute_scale();
ray::reset_raycaster();
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/* to compute scale */
if(WDIM == 2)
cgi.prepare_basics();
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}
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println(hlog, "scale = ", t, " -> ", scale, " range = ", range);
t = scale / t;
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// println(hlog, "t = ", t, " h distance = ", hypot_d(3, h), " for ", h);
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h *= t;
View = rgpushxto0(direct_exp(h)) * T;
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fixmatrix(View);
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playermoved = false;
sightranges[gFake] = range * t;
}
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EX void configure() {
if(!in()) {
underlying_cgip = cgip;
around = around_orig();
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}
dialog::editNumber(around, 2.01, 10, 1, around, "fake curvature",
"This feature lets you construct the same tiling, but "
"from shapes of different curvature.\n\n"
"The number you give here is (2D) vertex degree or (3D) "
"the number of cells around an edge.\n\n"
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);
if(fake::in())
dialog::reaction = change_around;
else
dialog::reaction_final = change_around;
dialog::extra_options = [] {
ld e = compute_euclidean();
dialog::addSelItem("Euclidean", fts(e), 'E');
dialog::add_action([e] {
around = e;
popScreen();
change_around();
});
dialog::addSelItem("original", fts(around_orig()), 'O');
dialog::add_action([e] {
around = around_orig();
popScreen();
change_around();
});
dialog::addSelItem("double original", fts(2 * around_orig()), 'D');
dialog::add_action([e] {
around = 2 * around_orig();
popScreen();
change_around();
});
dialog::addBoolItem_action("draw all if multiple of original", multiple_special_draw, 'M');
dialog::addBoolItem_action("draw copies (2D only)", recursive_draw, 'C');
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};
}
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int readArgs() {
using namespace arg;
if(0) ;
else if(argis("-gfake")) {
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shift_arg_formula(around, change_around);
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}
else return 1;
return 0;
}
auto fundamentalhook = addHook(hooks_args, 100, readArgs);
EX }
}