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hyperrogue/archimedean.cpp

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// Hyperbolic Rogue -- Archimedean Tilings
// Copyright (C) 2011-2019 Zeno Rogue, see 'hyper.cpp' for details
/** \file archimedean.cpp
* \brief Archimedean tilings
*
* These are tilings available in the 'Archimedean' option in Geometry Experiments; simpler Archimedean tilings are defined in other files.
*/
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#include "hyper.h"
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namespace hr {
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EX namespace arcm {
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EX bool in() { return cgflags & qARCHI; }
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EX ld euclidean_edge_length = .5;
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#if HDR
struct hr_archimedean_error : hr_exception {
hr_archimedean_error(string _s) : hr_exception(_s) {}
};
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struct archimedean_tiling {
int coloring;
string symbol;
vector<int> faces;
vector<int> adj;
vector<bool> invert;
vector<int> nflags;
bool have_ph, have_line, have_symmetry;
int real_faces;
int real_face_type;
int repetition;
int N;
bool regular;
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ld euclidean_angle_sum;
vector<int> flags;
vector<vector<pair<int, int>>> adjacent;
vector<vector<pair<ld, ld>>> triangles;
void make_match(int a, int i, int b, int j);
void prepare();
void compute_sum();
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void compute_geometry();
void parse();
void parse(string s) { symbol = s; parse(); }
ld edgelength;
vector<ld> inradius, circumradius, alphas;
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vector<vector<int>> matches;
vector<int> periods;
vector<int> tilegroup;
vector<int> groupoffset;
int tilegroups;
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int errors;
string errormsg;
pair<int, int>& get_adj(heptagon *h, int cid);
pair<int, int>& get_adj(heptspin hs) { return get_adj(hs.at, hs.spin); }
pair<ld, ld>& get_triangle(heptagon *h, int cid);
pair<ld, ld>& get_triangle(heptspin hs) { return get_triangle(hs.at, hs.spin); }
pair<ld, ld>& get_triangle(const pair<int, int>& p, int delta = 0);
pair<int, int>& get_adj(const pair<int, int>& p, int delta = 0);
int support_threecolor();
int support_threecolor_bitruncated();
int support_football();
bool support_chessboard();
void regroup();
string world_size();
void get_nom_denom(int& anom, int& adenom);
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geometryinfo1& get_geometry(ld mul = 1);
eGeometryClass get_class() { return get_geometry().kind; }
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bool get_step_values(int& steps, int& single_step);
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transmatrix adjcell_matrix(heptagon *h, int d);
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ld scale();
};
#endif
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#if HDR
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static const int sfPH = 1;
static const int sfLINE = 2;
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static const int sfCHESS = 4;
static const int sfTHREE = 8;
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static const int sfSEMILINE = 16;
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#endif
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#if CAP_ARCM
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EX archimedean_tiling current;
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EX archimedean_tiling fake_current;
EX archimedean_tiling& current_or_fake() {
if(fake::in()) return fake_current;
return current;
}
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/** id of vertex in the archimedean tiling
* odd numbers = reflected tiles
* 0, 2, ..., 2(N-1) = as in the symbol
* 2N = bitruncated tile
*/
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EX short& id_of(heptagon *h) {
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return h->zebraval;
}
/** which index in id_of's neighbor list does h->move(0) have */
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EX short& parent_index_of(heptagon *h) {
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return h->emeraldval;
}
/** total number of neighbors */
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EX int neighbors_of(heptagon *h) {
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return isize(current.triangles[id_of(h)]);
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}
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EX int gcd(int x, int y) { return x ? gcd(y%x, x) : y < 0 ? -y : y; }
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void archimedean_tiling::make_match(int a, int i, int b, int j) {
if(isize(adjacent[a]) != isize(adjacent[b])) {
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DEBB(DF_GEOM, ("(error here)"));
errormsg = XLAT("polygons match incorrectly");
errors++;
}
if(matches[a][b] == -1)
matches[a][b] = j - i, matches[b][a] = i - j;
else
periods[a] = periods[b] = gcd(matches[a][b] - (j-i), periods[a]);
}
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/** mostly to protect the user from entering too large numbers */
const int MAX_EDGE_ARCM = FULL_EDGE;
void archimedean_tiling::compute_sum() {
N = isize(faces);
euclidean_angle_sum = 0;
for(int f: faces) euclidean_angle_sum += (f-2.) / f;
real_faces = 0, real_face_type = 0;
for(int i=0; i<N; i++) if(faces[i] > 2) real_faces++, real_face_type += faces[i];
real_face_type /= 2;
}
void archimedean_tiling::prepare() {
compute_sum();
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for(int i: faces) if(i > MAX_EDGE_ARCM) {
errormsg = XLAT("currently no more than %1 edges", its(MAX_EDGE_ARCM));
errors++;
return;
}
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if(isize(faces) > MAX_EDGE_ARCM/2) {
errormsg = XLAT("currently no more than %1 faces in vertex", its(MAX_EDGE_ARCM/2));
errors++;
return;
}
for(int i: faces) if(i < 2) {
errormsg = XLAT("not enough edges");
errors++;
return;
}
vector<int> nondigonal;
for(int i: faces) if(i > 2) nondigonal.push_back(i);
if(isize(faces) < 2 || isize(nondigonal) == 1) {
errormsg = XLAT("not enough faces");
errors++;
return;
}
if(isize(nondigonal) == 2 && faces[0] != faces[1]) {
errormsg = XLAT("invalid dihedron");
errors++;
return;
}
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for(int i=0; i<N; i++) {
bool forward = false;
int f = faces[i];
int i0 = i;
for(int k=0; k<f; k++) {
forward ^= invert[i0];
i0 = adj[i0];
if(forward) { if(faces[i0] != f) { errormsg = XLAT("face mismatch"); errors++; return; } i0++; if(i0 == N) i0 = 0; }
else { if(i0 == 0) i0 = N; i0--; if(faces[i0] != f) { errormsg = XLAT("face mismatch"); errors++; return; } }
}
for(int k=0; k<N; k++) {
f = faces[(i+N-k-1) % N];
if(forward) { if(faces[i0] != f) { errormsg = XLAT("face mismatch II "); errors++; return; } i0++; if(i0 == N) i0 = 0; }
else { if(i0 == 0) i0 = N; i0--; if(faces[i0] != f) { errormsg = XLAT("face mismatch II"); errors++; return; } }
}
}
if(real_faces) {
for(int i=1; i<isize(faces); i++) if(faces[i] == 2 && faces[i-1] == 2) {
errormsg = XLAT("Not implemented.");
errors++;
return;
}
if(faces[0] == 2 && faces[isize(faces)-1] == 2) {
errormsg = XLAT("Not implemented.");
errors++;
return;
}
}
if(real_faces == 2) {
for(int i: faces) if(i != real_face_type) {
errormsg = XLAT("polygons match incorrectly");
errors++;
}
}
errors = 0;
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/* build the 'adjacent' table */
int M = 2 * N + 2;
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adjacent.clear();
adjacent.resize(M);
have_symmetry = false;
for(int i=0; i<N; i++) if(invert[i]) have_symmetry = true;
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matches.resize(M);
for(int i=0; i<M; i++) {
matches[i].resize(M);
for(int j=0; j<M; j++) matches[i][j] = i==j ? 0 : -1;
}
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periods.resize(M);
for(int i=0; i<M; i++) periods[i] = i<2*N ? faces[i/2] : N;
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for(int i=0; i<N; i++) {
for(int oi=0; oi<1; oi++) {
int at = (i+oi)%N;
int inv = oi;
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DEBB0(DF_GEOM, ("vertex "));
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for(int z=0; z<faces[i]; z++) {
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DEBB0(DF_GEOM, (format("[%d %d] " , at, inv)));
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adjacent[2*i+oi].emplace_back(2*N+int(inv), inv ? (2*at+2*N-2) % (2*N) : 2*at);
if(invert[at]) inv ^= 1;
at = adj[at];
if(inv) at = (at+1) % N;
else at = (at+N-1) % N;
}
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if(!inv) make_match(2*i, 0, inv ? (2*at+2*N-1) % 2*N : 2*at, 0);
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DEBB(DF_GEOM, (format("-> [%d %d]\n", at, inv)));
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}
}
for(int i=0; i<N; i++) {
adjacent[2*N].emplace_back(2*i, 0);
int ai = (i+1) % N;
adjacent[2*N].emplace_back(2*N+int(invert[ai]), (2*adj[ai]+2*N-1) % (2*N));
}
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for(int d=0; d<=2*N; d+=2) {
int s = isize(adjacent[d]);
for(int i=0; i<s; i++) {
auto& orig = adjacent[d][s-1-i];
adjacent[d+1].emplace_back(orig.first ^ 1, orig.second);
}
}
for(int d=0; d<M; d++) {
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int s = isize(adjacent[d]);
for(int i=0; i<s; i++) {
auto& orig = adjacent[d][i];
if(orig.first & 1) orig.second = isize(adjacent[orig.first]) - 1 - orig.second;
}
}
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if(debugflags & DF_GEOM) {
for(int i=0; i<M; i++) {
DEBB0(DF_GEOM, ("adjacent ", i, ":"));
for(int j=0; j<isize(adjacent[i]); j++) {
auto p = adjacent[i][j];
DEBB0(DF_GEOM, (" ", p));
}
DEBB(DF_GEOM, ("\n"));
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}
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}
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for(int i=0; i<M; i++) {
for(int j=0; j<isize(adjacent[i]); j++) {
auto p = adjacent[i][j];
auto q = adjacent[p.first][p.second];
make_match(i, j, q.first, q.second);
}
}
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/* verify all the triangles */
for(int i=0; i<M; i++) {
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for(int j=0; j<isize(adjacent[i]); j++) {
int ai = i, aj = j;
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DEBB0(DF_GEOM, ("triangle "));
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for(int s=0; s<3; s++) {
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DEBB0(DF_GEOM, (format("[%d %d] ", ai, aj)));
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tie(ai, aj) = adjacent[ai][aj];
aj++; if(aj >= isize(adjacent[ai])) aj = 0;
}
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DEBB(DF_GEOM, (format("-> [%d %d]\n", ai, aj)));
make_match(i, j, ai, aj);
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}
}
for(int i=0; i<2*N; i++) {
for(int j=0; j<isize(adjacent[i]); j++) {
auto aa = make_pair(i, j);
aa = get_adj(aa, 1);
aa = get_adj(aa, 2);
aa = get_adj(aa, 1);
aa = get_adj(aa, 2);
make_match(i, j, aa.first, aa.second);
}
}
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regroup();
}
void archimedean_tiling::regroup() {
int M = 2 * N + 2;
for(int i=0; i<M; i++) for(int j=0; j<M; j++) if(matches[i][j] != -1)
for(int l=0; l<M; l++) for(int k=0; k<M; k++) if(matches[j][k] != -1) {
make_match(i, 0, k, matches[i][j] + matches[j][k]);
make_match(i, 0, k, matches[i][j] + matches[j][k] + gcd(periods[i], periods[j]));
}
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tilegroup.clear();
tilegroup.resize(M, -1);
groupoffset.resize(M);
tilegroups = 0;
for(int i=0; i<M; i+=(have_symmetry?1:2)) if(tilegroup[i] == -1) {
if(periods[i] < 0) periods[i] = -periods[i];
for(int j=0; j<M; j++) if(matches[i][j] != -1)
tilegroup[j] = tilegroups, groupoffset[j] = matches[i][j] % periods[i];
tilegroups++;
}
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flags.clear();
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flags.resize(M, 0);
for(int i=0; i<M; i++)
for(int j=0; j<M; j++) {
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if(tilegroup[i] == tilegroup[j]) {
flags[i] |= nflags[j/2];
if(j%2 == 1 && (nflags[j/2] & sfSEMILINE))
flags[i] |= sfLINE;
}
}
if(!have_ph) {
for(int i=0; i<M; i++) if(tilegroup[i] == 0) flags[i] |= sfPH;
}
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if(debugflags & DF_GEOM) {
for(int i=0; i<M; i+=(have_symmetry?1:2)) {
DEBB(DF_GEOM, (format("tiling group of %2d: [%2d]%2d+Z%2d\n", i, tilegroup[i], groupoffset[i], periods[i])));
}
}
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}
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geometryinfo1& archimedean_tiling::get_geometry(ld mul) {
if(euclidean_angle_sum * mul < 1.999999) return ginf[gSphere].g;
else if(euclidean_angle_sum * mul > 2.000001) return ginf[gNormal].g;
else return ginf[gEuclid].g;
}
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void archimedean_tiling::compute_geometry() {
ginf[gArchimedean].g = get_geometry();
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set_flag(ginf[gArchimedean].flags, qBOUNDED, get_class() == gcSphere);
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DEBB(DF_GEOM, (format("euclidean_angle_sum = %f\n", float(euclidean_angle_sum))));
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bool infake = fake::in();
dynamicval<eGeometry> dv(geometry, gArchimedean);
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/* compute the geometry */
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inradius.resize(N+1); inradius[N] = 0;
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circumradius.resize(N+1); circumradius[N] = 0;
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alphas.resize(N);
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ld total = M_PI;
dynamicval<geometryinfo1> dgi(ginf[geometry].g, ginf[geometry].g);
if(infake) {
total *= N / fake::around;
ginf[geometry].g = get_geometry(fake::around / N);
}
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ld elmin = 0, elmax = hyperbolic ? 10 : sphere ? M_PI : 2 * euclidean_edge_length;
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/* inradius[N] is used in farcorner and nearcorner. Probably a bug */
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if(real_faces == 2) {
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/* standard methods fail for dihedra, but the answer is easy */
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edgelength = 2 * M_PI / faces[0];
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for(int i=0; i<N; i++)
if(faces[i] == 2)
alphas[i] = 0,
circumradius[i] = M_PI / real_face_type,
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inradius[i] = 0;
else
alphas[i] = M_PI/2,
circumradius[i] = inradius[i] = M_PI/2;
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}
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else if(real_faces == 0) {
// these are called hosohedra
edgelength = M_PI;
for(int i=0; i<N; i++)
alphas[i] = M_PI / N,
circumradius[i] = M_PI/2,
inradius[i] = 0;
}
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else for(int p=0; p<100; p++) {
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edgelength = (elmin + elmax) / 2;
ld alpha_total = 0;
for(int i=0; i<N; i++) {
ld gamma = M_PI / faces[i];
auto& c = circumradius[i];
c = asin_auto(sin_auto(edgelength/2) / sin(gamma));
inradius[i] = hdist0(mid(xpush0(circumradius[i]), xspinpush0(2*gamma, circumradius[i])));
hyperpoint h = xpush(c) * spin(M_PI - 2*gamma) * xpush0(c);
ld a = atan2(h);
cyclefix(a, 0);
if(a < 0) a = -a;
alphas[i] = a;
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alpha_total += alphas[i];
}
if(debugflags & DF_GEOM)
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if(p < 10 || p == 99)
println(hlog, "edgelength = ", edgelength, " angles = ", alphas, " inradius = ", inradius, " circumradius = ", circumradius);
if(isnan(alpha_total)) elmax = edgelength;
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else if(sphere ^ (alpha_total > total)) elmin = edgelength;
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else elmax = edgelength;
if(euclid) break;
}
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DEBB(DF_GEOM, (format("computed edgelength = %f\n", float(edgelength))));
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triangles.clear();
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triangles.resize(2*N+2);
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for(int i=0; i<N; i++) for(int j=0; j<2; j++)
for(int k=0; k<faces[i]; k++)
triangles[2*i+j].emplace_back(2*M_PI/faces[i], circumradius[i]);
for(int k=0; k<N; k++) {
triangles[2*N].emplace_back(alphas[k], circumradius[k]);
triangles[2*N].emplace_back(alphas[(k+1)%N], edgelength);
triangles[2*N+1].emplace_back(alphas[N-1-k], edgelength);
triangles[2*N+1].emplace_back(alphas[N-1-k], circumradius[N-1-k]);
}
for(auto& ts: triangles) {
ld total = 0;
for(auto& t: ts) tie(t.first, total) = make_pair(total, total + t.first);
}
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if(debugflags & DF_GEOM) for(auto& ts: triangles) {
DEBB0(DF_GEOM, ("T"));
for(auto& t: ts) DEBB0(DF_GEOM, (format(" %f@%f", float(t.first), float(t.second))));
DEBB(DF_GEOM, ());
}
regular = true;
for(int i: faces) if(i != faces[0]) regular = false;
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}
ld archimedean_tiling::scale() {
if(real_faces == 0 && N == 2) return M_PI / 2;
if(real_faces == 2) return M_PI / 2;
if(real_faces == 0) return 2 * M_PI / N;
return edgelength;
}
map<heptagon*, vector<pair<heptagon*, transmatrix> > > altmap;
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EX map<heptagon*, pair<heptagon*, transmatrix>> archimedean_gmatrix;
EX hrmap *current_altmap;
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heptagon *build_child(heptspin p, pair<int, int> adj);
bool skip_digons(heptspin hs, int step);
void connect_digons_too(heptspin h1, heptspin h2);
void fixup_matrix(transmatrix& T, const transmatrix& X, ld step);
void connectHeptagons(heptspin hi, heptspin hs);
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/** @brief should we use gmatrix to compute relative_matrix faster? (not while in fake Archimedean) */
EX bool use_gmatrix = true;
/** @brief like adj, but in pure
* not used by arcm itself, but used in fake arcm
*/
EX geometry_information *alt_cgip;
EX geometry_information *find_alt_cgip() {
if(alt_cgip) return alt_cgip;
check_cgi();
cgi.require_basics();
return alt_cgip = cgip;
}
struct hrmap_archimedean : hrmap {
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map<gp::loc, struct cdata> eucdata;
heptagon *origin;
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heptagon *getOrigin() override { return origin; }
hrmap_archimedean() {
dynamicval<hrmap*> curmap(currentmap, this);
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int id = DUAL ? current.N * 2 : 0;;
int N0 = isize(current.adjacent[id]);
origin = init_heptagon(N0);
origin->s = hsOrigin;
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parent_index_of(origin) = DUAL ? 1 : 0;
id_of(origin) = id;
origin->c7 = newCell(N0/DUALMUL, origin);
heptagon *alt = NULL;
if(hyperbolic) {
dynamicval<eGeometry> g(geometry, gNormal);
dynamicval<eVariation> gv(variation, eVariation::pure);
dynamicval<geometry_information*> gi(cgip, find_alt_cgip());
alt = init_heptagon(S7);
alt->s = hsOrigin;
alt->alt = alt;
current_altmap = newAltMap(alt);
}
transmatrix T = xpush(.01241) * spin(1.4117) * xpush(0.1241) * Id;
archimedean_gmatrix[origin] = make_pair(alt, T);
altmap[alt].emplace_back(origin, T);
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if(current.real_faces == 0 && DUAL) {
heptspin hs(origin, 0);
heptagon *hnew = build_child(hs, current.get_adj(hs));
for(int s=1; s<2*current.N; s++)
origin->c.connect(s, hnew, s, false);
}
else if(current.real_faces == 0) {
may_create_step(origin, 0);
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heptagon *o0 = origin->move(0);
may_create_step(origin, 1);
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heptagon *o1 = origin->move(1);
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for(int s=1; s<2*current.N; s+=2)
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o0->c.connect(s, o1, 2*current.N-s, false);
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for(int s=2; s<2*current.N; s+=2) {
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heptspin hs(o0, s);
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heptagon *hnew = build_child(hs, current.get_adj(hs));
// no need to specify archimedean_gmatrix and altmap
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hnew->c.connect(1, heptspin(o1, 2*current.N-s));
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}
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o1->c.connect(1, o0, 2*current.N-1, false);
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}
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else if(origin->degree() == 2) {
may_create_step(origin, 0);
may_create_step(origin, 1);
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origin->move(0)->c.connect(1, origin->move(1), 2*current.N-1, false);
origin->move(1)->c.connect(1, origin->move(0), 2*current.N-1, false);
}
auto_compute_range(origin->c7);
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}
~hrmap_archimedean() {
clearfrom(origin);
altmap.clear();
archimedean_gmatrix.clear();
if(current_altmap) {
dynamicval<eGeometry> g(geometry, gNormal);
dynamicval<eVariation> gv(variation, eVariation::pure);
dynamicval<geometry_information*> gi(cgip, find_alt_cgip());
delete current_altmap;
current_altmap = NULL;
}
}
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void verify() override { }
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heptagon *create_step(heptagon *h, int d) override {
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DEBB(DF_GEOM, (heptspin(h,d), " ~ ?"));
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dynamicval<geometryinfo1> gi(ginf[geometry].g, ginf[gArchimedean].g);
heptspin hi(h, d);
while(skip_digons(hi, 1)) hi++;
auto& t1 = current.get_triangle(hi);
// * spin(-tri[id][pi+i].first) * xpush(t.second) * pispin * spin(tri[id'][p'+d'].first)
auto& p1 = archimedean_gmatrix[h];
heptagon *alt = p1.first;
transmatrix T = p1.second * spin(-t1.first) * xpush(t1.second);
transmatrix U = Id;
if(hyperbolic) {
dynamicval<eGeometry> g(geometry, gNormal);
dynamicval<eVariation> gv(variation, eVariation::pure);
dynamicval<geometry_information*> gi(cgip, find_alt_cgip());
dynamicval<hrmap*> cm(currentmap, current_altmap);
U = T;
current_altmap->virtualRebase(alt, T);
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U = U * iso_inverse(T);
}
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if(euclid) {
/* hash the rough coordinates as heptagon* alt */
size_t s = size_t(T[0][LDIM]+.261) * 124101 + size_t(T[1][LDIM]+.261) * 82143;
alt = (heptagon*) s;
}
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DEBB(DF_GEOM, ("look for: ", alt, " / ", T * C0));
for(auto& p2: altmap[alt]) if(same_point_may_warn(p2.second * C0, T * C0)) {
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DEBB(DF_GEOM, ("cell found: ", p2.first));
for(int d2=0; d2<p2.first->degree(); d2++) {
heptspin hs(p2.first, d2);
auto& t2 = current.get_triangle(p2.first, d2);
transmatrix T1 = T * spin(M_PI + t2.first);
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DEBB(DF_GEOM, ("compare: ", T1 * xpush0(1), ":: ", p2.second * xpush0(1)));
if(same_point_may_warn(T1 * xpush0(1), p2.second * xpush0(1))) {
// T1 = p2.second
// T * spin(pi+t2.first) == p2.second
// p1.second * spinm(-t1.first) * xpush(t1.second) * spin(pi+t2.first) == p2.second
// bring p1 and p2 closer, to prevent floating point errors
if(hyperbolic) {
fixup_matrix(p1.second, U * p2.second * spin(-M_PI - t2.first) * xpush(-t1.second) * spin(t1.first), 0.25);
fixup_matrix(p2.second, T1, 0.25);
}
while(skip_digons(hs, -1)) hs--;
connectHeptagons(hi, hs);
connect_digons_too(hi, hs);
return h->move(d);
}
}
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DEBB(DF_GEOM, ("but rotation not found"));
}
auto& t2 = current.get_triangle(current.get_adj(hi));
transmatrix T1 = T * spin(M_PI + t2.first);
fixmatrix(T1);
heptagon *hnew = build_child(hi, current.get_adj(hi));
altmap[alt].emplace_back(hnew, T1);
archimedean_gmatrix[hnew] = make_pair(alt, T1);
connect_digons_too(hi, heptspin(hnew, 0));
return hnew;
}
void draw_at(cell *at, const shiftmatrix& where) override {
dq::clear_all();
dq::enqueue(at->master, where);
while(!dq::drawqueue.empty()) {
auto& p = dq::drawqueue.front();
heptagon *h = p.first;
shiftmatrix V = p.second;
dq::drawqueue.pop();
int id = id_of(h);
int S = isize(current.triangles[id]);
if(id < 2*current.N ? !DUAL : !PURE) {
if(!do_draw(h->c7, V)) continue;
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drawcell(h->c7, V);
}
for(int i=0; i<S; i++) {
if(DUAL && (i&1)) continue;
h->cmove(i);
if(PURE && id >= 2*current.N && h->move(i) && id_of(h->move(i)) >= 2*current.N) continue;
shiftmatrix V1 = V * current.adjcell_matrix(h, i);
optimize_shift(V1);
dq::enqueue(h->move(i), V1);
}
}
}
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transmatrix adj(cell *c, int dir) override {
return calc_relative_matrix(c->cmove(dir), c, C0);
}
transmatrix relative_matrixh(heptagon *h2, heptagon *h1, const hyperpoint& hint) override {
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if(use_gmatrix && gmatrix0.count(h2->c7) && gmatrix0.count(h1->c7))
return inverse_shift(gmatrix0[h1->c7], gmatrix0[h2->c7]);
transmatrix gm = Id, where = Id;
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auto& cof = current_or_fake();
while(h1 != h2) {
for(int i=0; i<neighbors_of(h1); i++) {
if(h1->move(i) == h2) {
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return gm * cof.adjcell_matrix(h1, i) * where;
}
}
if(h1->distance > h2->distance) {
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gm = gm * cof.adjcell_matrix(h1, 0);
h1 = h1->move(0);
}
else {
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where = iso_inverse(cof.adjcell_matrix(h2, 0)) * where;
h2 = h2->move(0);
}
}
return gm * where;
}
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ld spin_angle(cell *c, int d) override {
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auto &cof = current_or_fake();
if(PURE) {
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auto& t1 = cof.get_triangle(c->master, d-1);
return -(t1.first + M_PI / c->type);
}
else if(DUAL) {
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auto& t1 = cof.get_triangle(c->master, 2*d);
return -t1.first;
}
else { /* BITRUNCATED */
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auto& t1 = cof.get_triangle(c->master, d);
return -t1.first;
}
}
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void find_cell_connection(cell *c, int d) override {
if(PURE) {
if(arcm::id_of(c->master) < arcm::current.N * 2) {
heptspin hs = heptspin(c->master, d) + wstep + 2 + wstep + 1;
c->c.connect(d, hs.at->c7, hs.spin, hs.mirrored);
}
else c->c.connect(d, c, d, false);
}
else if(DUAL) {
if(arcm::id_of(c->master) >= arcm::current.N * 2) {
heptagon *h2 = createStep(c->master, d*2);
int d1 = c->master->c.spin(d*2);
c->c.connect(d, h2->c7, d1/2, false);
}
else {
printf("bad connection\n");
c->c.connect(d,c,d,false);
}
}
else hrmap::find_cell_connection(c, d);
}
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int shvid(cell *c) override {
auto& ac = arcm::current;
int id = arcm::id_of(c->master);
if(ac.regular && id>=2 && id < 2*ac.N) id &= 1;
return id;
}
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int full_shvid(cell *c) override {
return id_of(c->master) + 20 * parent_index_of(c->master);
}
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hyperpoint get_corner(cell *c, int cid, ld cf) override {
auto &ac = arcm::current_or_fake();
if(PURE) {
if(arcm::id_of(c->master) >= ac.N*2) return C0;
auto& t = ac.get_triangle(c->master, cid-1);
return xspinpush0(-t.first, t.second * 3 / cf * (ac.real_faces == 0 ? 0.999 : 1));
}
if(BITRUNCATED) {
auto& t0 = ac.get_triangle(c->master, cid-1);
auto& t1 = ac.get_triangle(c->master, cid);
hyperpoint h0 = xspinpush0(-t0.first, t0.second * 3 / cf * (ac.real_faces == 0 ? 0.999 : 1));
hyperpoint h1 = xspinpush0(-t1.first, t1.second * 3 / cf * (ac.real_faces == 0 ? 0.999 : 1));
return mid3(C0, h0, h1);
}
if(DUAL) {
auto& t0 = ac.get_triangle(c->master, 2*cid-1);
return xspinpush0(-t0.first, t0.second * 3 / cf * (ac.real_faces == 0 ? 0.999 : 1));
}
return C0;
}
};
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EX hrmap *new_map() { return new hrmap_archimedean; }
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heptagon *build_child(heptspin p, pair<int, int> adj) {
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indenter ind;
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auto h = buildHeptagon1(tailored_alloc<heptagon> (isize(current.adjacent[adj.first])), p.at, p.spin, hstate(1), 0);
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DEBB(DF_GEOM, ("NEW ", p, " ~ ", heptspin(h, 0)));
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id_of(h) = adj.first;
parent_index_of(h) = adj.second;
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int nei = neighbors_of(h);
h->c7 = newCell(nei/DUALMUL, h);
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h->distance = p.at->distance + 1;
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if(adj.first < 2*current.N && !DUAL) {
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int s = 0;
heptspin hs(p);
while(id_of(hs.at->move(0)) >= 2 * current.N) {
s += hs.spin / 2 - 1;
hs = hs - hs.spin + wstep - 1;
}
h->fieldval = hs.at->move(0)->fieldval + s + hs.spin/2;
}
else
h->fieldval = -100;
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h->fiftyval = isize(archimedean_gmatrix);
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if(p.at->s == hsOrigin)
h->rval1 = 1 + (p.spin % 2);
else {
if(p.spin % 2 == 0)
h->rval1 = p.at->move(0)->rval1;
else
h->rval1 = 3 - p.at->move(0)->rval1 - p.at->rval1;
}
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h->rval0 = hrand(256);
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heptspin hs(h, 0);
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return h;
}
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bool skip_digons(heptspin hs, int step) {
return
isize(current.adjacent[current.get_adj(hs).first]) == 2 ||
isize(current.adjacent[current.get_adj(hs+step).first]) == 2;
}
void connect_digons_too(heptspin h1, heptspin h2) {
if(skip_digons(h1, -1)) {
h1--, h2++;
heptagon *hnew = build_child(h1, current.get_adj(h1));
// no need to specify archimedean_gmatrix and altmap
hnew->c.connect(1, h2);
h1--, h2++;
DEBB(DF_GEOM, (format("OL2 %p.%d ~ %p.%d\n", hr::voidp(h1.at), h1.spin, hr::voidp(h2.at), h2.spin)));
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h1.at->c.connect(h1.spin, h2);
}
}
void connectHeptagons(heptspin hi, heptspin hs) {
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DEBB(DF_GEOM, ("OLD ", hi, " ~ ", hs));
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if(hi.at->move(hi.spin) == hs.at && hi.at->c.spin(hi.spin) == hs.spin) {
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DEBB(DF_GEOM, (format("WARNING: already connected\n")));
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return;
}
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if(hi.peek()) {
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DEBB(DF_GEOM, (format("ERROR: already connected left\n")));
throw hr_archimedean_error("Archimedean error: already connected left");
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}
if(hs.peek()) {
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DEBB(DF_GEOM, (format("ERROR: already connected right\n")));
throw hr_archimedean_error("Archimedean error: already connected right");
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}
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hi.at->c.connect(hi.spin, hs);
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auto p = current.get_adj(hi);
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if(current.tilegroup[p.first] != current.tilegroup[id_of(hs.at)]) {
printf("should merge %d %d\n", p.first, id_of(hs.at));
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current.make_match(p.first, p.second, id_of(hs.at), hs.spin + parent_index_of(hs.at));
current.regroup();
}
// heptagon *hnew = build_child(h, d, get_adj(h, d).first, get_adj(h, d).second);
}
/** T and X are supposed to be equal -- move T so that it is closer to X */
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void fixup_matrix(transmatrix& T, const transmatrix& X, ld step) {
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for(int i=0; i<MXDIM; i++)
for(int j=0; j<MXDIM; j++)
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T[i][j] = (T[i][j] * (1-step) + X[i][j] * step);
/*
for(int i=0; i<3; i++)
for(int j=0; j<3; j++)
if(T[i][j] - X[i][j] > 1e-3) exit(1);
*/
fixmatrix(T);
}
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pair<ld, ld>& archimedean_tiling::get_triangle(heptagon *h, int cid) {
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return triangles[id_of(h)][gmod(parent_index_of(h) + cid, neighbors_of(h))];
}
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pair<int, int>& archimedean_tiling::get_adj(heptagon *h, int cid) {
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return adjacent[id_of(h)][gmod(parent_index_of(h) + cid, neighbors_of(h))];
}
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pair<int, int>& archimedean_tiling::get_adj(const pair<int, int>& p, int delta) {
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return adjacent[p.first][gmod(p.second + delta, isize(adjacent[p.first]))];
}
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pair<ld, ld>& archimedean_tiling::get_triangle(const pair<int, int>& p, int delta) {
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return triangles[p.first][gmod(p.second + delta, isize(adjacent[p.first]))];
}
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transmatrix archimedean_tiling::adjcell_matrix(heptagon *h, int d) {
auto& t1 = get_triangle(h, d);
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heptagon *h2 = h->move(d);
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int d2 = h->c.spin(d);
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auto& t2 = get_triangle(h2, d2);
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return spin(-t1.first) * xpush(t1.second) * spin(M_PI + t2.first);
}
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EX int fix(heptagon *h, int spin) {
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int type = isize(current.adjacent[id_of(h)]);
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spin %= type;
if(spin < 0) spin += type;
return spin;
}
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void archimedean_tiling::parse() {
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int at = 0;
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auto peek = [&] () { if(at == isize(symbol)) return char(0); else return symbol[at]; };
auto is_number = [&] () { char p = peek(); return p >= '0' && p <= '9'; };
auto read_number = [&] () { int result = 0; while(is_number()) result = 10 * result + peek() - '0', at++; return result; };
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faces.clear(); nflags.clear();
have_line = false;
have_ph = false;
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int nflags0 = 0;
auto nfback = [this, &nflags0] () -> int& { if(nflags.empty()) return nflags0; else return nflags.back(); };
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while(true) {
if(peek() == ')' || (peek() == '(' && isize(faces)) || peek() == 0) break;
else if((peek() == 'L') && faces.size()) {
if(!nflags.empty()) nfback() |= sfLINE;
have_line = true, at++;
}
else if((peek() == 'l') && faces.size()) {
if(!nflags.empty()) nfback() |= sfSEMILINE;
have_line = true, at++;
}
else if((peek() == 'H' || peek() == 'h') && faces.size()) {
if(!nflags.empty()) nfback() |= sfPH;
have_ph = true, at++;
}
else if(is_number()) faces.push_back(read_number()), nflags.push_back(0);
else if(peek() == '^' && !faces.empty()) {
at++;
int rep = read_number();
if(rep == 0) nflags.pop_back(), faces.pop_back();
for(int i=1; i<rep; i++) nflags.push_back(nfback()), faces.push_back(faces.back());
}
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else at++;
}
nflags.push_back(nflags0);
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repetition = 1;
N = isize(faces);
invert.clear(); invert.resize(N, true);
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adj.clear(); adj.resize(N, 0); for(int i=0; i<N; i++) adj[i] = i;
while(peek() != 0) {
if(peek() == '^') at++, repetition = read_number();
else if(peek() == '(') {
at++; int a = read_number(); while(!is_number() && !among(peek(), '(', '[', ')',']', 0)) at++;
if(is_number()) { int b = read_number(); adj[a] = b; adj[b] = a; invert[a] = invert[b] = false; }
else { invert[a] = false; }
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}
else if(peek() == '[') {
at++; int a = read_number(); while(!is_number() && !among(peek(), '(', '[', ')',']', 0)) at++;
if(is_number()) { int b = read_number(); adj[a] = b; adj[b] = a; invert[a] = invert[b] = true; }
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else { invert[a] = true; }
}
else at++;
}
for(int i=0; i<N * (repetition-1); i++)
faces.push_back(faces[i]),
nflags.push_back(nflags[i]),
invert.push_back(invert[i]),
adj.push_back(adj[i] + N);
N *= repetition;
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prepare();
}
#if CAP_COMMANDLINE
int readArgs() {
using namespace arg;
if(0) ;
else if(argis("-symbol")) {
PHASEFROM(2);
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archimedean_tiling at;
shift(); at.parse(args());
if(at.errors) {
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DEBB(DF_ERROR | DF_GEOM, ("error: ", at.errormsg));
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}
else {
set_geometry(gArchimedean);
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current = at;
showstartmenu = false;
}
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}
else if(argis("-dual")) { PHASEFROM(2); set_variation(eVariation::dual); }
else if(argis("-d:arcm"))
launch_dialog(show);
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else return 1;
return 0;
}
#endif
#if CAP_COMMANDLINE
auto hook =
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addHook(hooks_args, 100, readArgs)
+ addHook(hooks_gamedata, 0, [] (gamedata* gd) { gd->store(altmap); gd->store(archimedean_gmatrix); gd->store(current_altmap); });
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#endif
#if MAXMDIM >= 4
auto hooksw = addHook(hooks_swapdim, 100, [] {
dynamicval<eGeometry> g(geometry, gNormal);
dynamicval<eVariation> gv(variation, eVariation::pure);
dynamicval<geometry_information*> gi(cgip, find_alt_cgip());
for(auto& p: altmap) for(auto& pp: p.second) swapmatrix(pp.second);
for(auto& p: archimedean_gmatrix) swapmatrix(p.second.second);
alt_cgip = nullptr;
});
#endif
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int archimedean_tiling::support_threecolor() {
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return (isize(faces) == 3 && invert[0] && invert[1] && invert[2] && faces[0] % 2 == 0 && faces[1] % 2 == 0 && faces[2] % 2 == 0) ? 2 :
tilegroup[N*2] > 1 ? 1 :
0;
return 2;
}
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int archimedean_tiling::support_threecolor_bitruncated() {
for(int i: faces) if(i % 2) return 0;
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return 2;
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}
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int archimedean_tiling::support_football() {
return
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have_ph ? 1 :
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(isize(faces) == 3 && invert[0] && invert[1] && invert[2] && faces[1] % 2 == 0 && faces[2] % 2 == 0) ? 2 :
0;
}
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bool archimedean_tiling::support_chessboard() {
return N % 2 == 0;
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}
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EX bool pseudohept(cell *c) {
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if(DUAL)
return !(c->master->rval0 & 3);
int id = id_of(c->master);
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if(PURE)
return current.flags[id] & arcm::sfPH;
if(BITRUNCATED)
return id < current.N * 2;
return false;
}
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EX bool chessvalue(cell *c) {
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if(DUAL)
return c->master->rval1 - 1;
return c->master->fieldval & 1;
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}
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EX bool linespattern(cell *c) {
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return current.flags[id_of(c->master)] & arcm::sfLINE;
}
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EX int threecolor(cell *c) {
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if(current.have_ph)
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return !arcm::pseudohept(c);
else if(PURE)
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return current.tilegroup[id_of(c->master)];
else {
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int id = id_of(c->master);
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if(current.support_threecolor() == 2) return id < current.N * 2 ? (id&1) : 2;
return current.tilegroup[id];
}
}
int cEucRegular = 0x008000;
int cEucSemiregular = 0x40C040;
int cPlatonic = 0x000080;
int cArchimedean = 0x4040C0;
int cPrism = 0x40A0A0;
int cAntiPrism = 0x80A0A0;
int cHyperRegular = 0x800000;
int cHyperSemi = 0xC04040;
int cWeird = 0xA000A0;
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EX vector<pair<string, int> > samples = {
/* Euclidean */
{"(3,3,3,3,3,3)", cEucRegular},
{"(4,4,4,4)", cEucRegular},
{"(6,6,6)", cEucRegular},
{"(8,8,4)", cEucSemiregular},
{"(4,6,12)", cEucSemiregular},
{"(6,4,3,4)", cEucSemiregular},
{"(3,6,3,6)", cEucSemiregular},
{"(3,12,12)", cEucSemiregular},
{"(4,4,3L,3L,3L) [3,4]", cEucSemiregular},
{"(3,3,3,3,6) (1,2)(0,4)(3)", cEucSemiregular},
{"(3,3,4,3,4) (0,4)(1)(2,3)", cEucSemiregular},
/* Platonic */
{"(3,3,3)", cPlatonic},
{"(3,3,3,3)", cPlatonic},
{"(3,3,3,3,3)", cPlatonic},
{"(4,4,4)", cPlatonic},
{"(5,5,5)", cPlatonic},
/* Archimedean solids */
{"(3,6,6)", cArchimedean},
{"(3,4,3,4)", cArchimedean},
{"(3,8,8)", cArchimedean},
{"(4,6,6)", cArchimedean},
{"(3,4,4,4)", cArchimedean},
{"(4,6,8)", cArchimedean},
{"(3,3,3,3,4) (1,2)(0,4)(3)", cArchimedean},
{"(3,5,3,5)", cArchimedean},
{"(3,10,10)", cArchimedean},
{"(5,6,6)", cArchimedean},
{"(3,4,5,4)", cArchimedean},
{"(4,6,10)", cArchimedean},
{"(3,3,3,3,5) (1,2)(0,4)(3)", cArchimedean},
/* prisms */
{"(3,4,4)", cPrism},
{"(5,4,4)", cPrism},
{"(6,4,4)", cPrism},
{"(7,4,4)", cPrism},
/* sample antiprisms */
{"(3,3,3,4)(1)(2)", cAntiPrism},
{"(3,3,3,5)(1)(2)", cAntiPrism},
{"(3,3,3,6)(1)(2)", cAntiPrism},
{"(3,3,3,7)(1)(2)", cAntiPrism},
/* hyperbolic ones */
{"(3)^7", cHyperRegular},
{"(4)^5", cHyperRegular},
{"(4)^6", cHyperRegular},
{"(5,5,5,5)", cHyperRegular},
{"(7,7,7)", cHyperRegular},
{"(8,8,8)", cHyperRegular},
{"(7,6^2)", cHyperSemi},
{"(4,6,14)", cHyperSemi},
{"(3,4,7,4)", cHyperSemi},
{"(6,6,4L,4L)", cHyperSemi},
{"(8,8,4L,4L)", cHyperSemi},
{"(3,3,3,3,7) (1,2)(0,4)(3)", cHyperSemi},
{"(3H,6,6,6) (1,0)[2](3)", cHyperSemi},
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{"(3,6,6,6) (0 1)(2)(3)", cHyperSemi},
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{"(3,4,4L,4L,4)", cHyperSemi}, // buggy
{"(3l,4l,4,4,4) (0 1)[2 3](4)", cHyperSemi},
{"(3,4,4,4,4) (0 1)(2)(3)(4)", cHyperSemi},
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{"(3,4,4L,4L,4L,4)", cHyperSemi},
{"(6,6,3L,3L,3L) (0 2)(1)(3)(4)", cHyperSemi},
{"(5,3,5,3,3) (0 1)(2 3)(4)", cHyperSemi},
{"(4,3,3,3,3,3) (0 1)(2 3)(4 5)", cHyperSemi},
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{"(3l,5l,5,5,5,5) (0 1)[2 3](4)(5)", cHyperSemi},
{"(3,5,5,5,5,5) (0 1)(2 4)(3 5)", cHyperSemi},
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{"(3l,5l,5,5,5,5) (0 1)(2 4)[3 5]", cHyperSemi},
{"(3l,5l,5,5,5,5) (0 1)[2 4](3)(5)", cHyperSemi},
{"(3,5,5,5,5,5) (0 1)(2)(3)(4)(5)", cHyperSemi},
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{"(3,3,4,3,5)(0,4)(1)(2,3)", cHyperSemi},
{"(3,14,14)", cHyperSemi},
{"(3,3,3,3,3,4)[0](1,2)(3,4)[5]", cHyperSemi},
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/* interesting symmetry variants */
{"(3,3,3,3,3,3) (0,1)(2,3)(4,5)", cEucRegular},
{"(3,3H,3,3,3L,3L,3L) (0 4)(1 2)(3)(5)(6)", cHyperRegular},
{"(3,3H,3,3,3L,3L,3L) (0 4)(1 2)(3)[5 6]", cHyperRegular},
{"(3,3H,3,3L,3,3L,3L) [0 4](1 2)[3 5](6)", cHyperRegular},
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/* with digons */
{"(2,3,3,3,3,3) (2,3)(4,5)", cWeird},
{"(6,6)", cWeird},
{"(2,2)", cWeird},
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{"(2,2,2,2,2,2)", cWeird},
{"(6,6,2)", cWeird},
{"(6,2,6,2)", cWeird},
};
int lastsample = 0;
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vector<archimedean_tiling> tilings;
int spos = 0;
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archimedean_tiling edited;
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bool symbol_editing;
EX void next_variation() {
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set_variation(
PURE ? eVariation::dual :
DUAL ? eVariation::bitruncated :
eVariation::pure);
start_game();
}
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EX void enable(archimedean_tiling& arct) {
stop_game();
if(!in()) set_variation(eVariation::pure);
set_geometry(gArchimedean);
patterns::whichPattern = patterns::PAT_NONE;
current = arct;
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#if CAP_TEXTURE
if(texture::config.tstate == texture::tsActive && texture::cgroup == cpThree) {
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patterns::whichPattern = patterns::PAT_COLORING;
if(geosupport_threecolor() < 2) {
if(arct.support_threecolor() == 2) set_variation(eVariation::pure);
else if(arct.support_threecolor_bitruncated() == 2) set_variation(eVariation::bitruncated);
}
}
if(texture::config.tstate == texture::tsActive && texture::cgroup == cpFootball) {
patterns::whichPattern = patterns::PAT_TYPES, patterns::subpattern_flags = patterns::SPF_FOOTBALL;
if(geosupport_football() < 2) set_variation(eVariation::bitruncated);
}
if(texture::config.tstate == texture::tsActive && texture::cgroup == cpChess) {
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patterns::whichPattern = patterns::PAT_CHESS;
if(!geosupport_chessboard()) {
if(arct.support_chessboard()) set_variation(eVariation::pure);
else if(arct.support_threecolor_bitruncated() == 2) set_variation(eVariation::dual);
}
}
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#endif
start_game();
}
function<void()> setcanvas(char c) {
return [c] () {
stop_game();
enable_canvas();
patterns::whichCanvas = c;
start_game();
};
}
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EX void show() {
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if(lastsample < isize(samples)) {
string s = samples[lastsample].first;
int col = samples[lastsample].second;
lastsample++;
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archimedean_tiling tested;
tested.parse(s);
if(tested.errors) {
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DEBB(DF_GEOM | DF_WARN, ("WARNING: ", tested.errors, " errors on ", s, " '", tested.errormsg, "'"));
}
else {
tested.coloring = col;
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tilings.push_back(move(tested));
/* sort(tilings.begin(), tilings.end(), [] (archimedean_tiling& s1, archimedean_tiling& s2) {
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if(s1.euclidean_angle_sum < s2.euclidean_angle_sum - 1e-6) return true;
if(s2.euclidean_angle_sum < s1.euclidean_angle_sum - 1e-6) return false;
return s1.symbol < s2.symbol;
}); */
}
}
cmode = sm::SIDE | sm::MAYDARK;
gamescreen(0);
dialog::init(XLAT("Archimedean tilings"));
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if(symbol_editing) {
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dialog::addSelItem("edit", dialog::view_edited_string(), '/');
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dialog::add_action([] () {
symbol_editing = false;
if(!edited.errors) enable(edited);
});
dialog::addBreak(100);
if(edited.errors)
dialog::addInfo(edited.errormsg, 0xFF0000);
else
dialog::addInfo(XLAT("OK"), 0x00FF00);
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dialog::addBreak(100);
dialog::addSelItem(XLAT("full angle"), fts(edited.euclidean_angle_sum * 180) + "°", 0);
dialog::addSelItem(XLAT("size of the world"), edited.world_size(), 0);
edited.compute_geometry();
dialog::addSelItem(XLAT("edge length"), fts(edited.edgelength) + (edited.get_class() == gcEuclid ? XLAT(" (arbitrary)") : ""), 0);
current.compute_geometry();
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dialog::addBreak(100);
dialog::addKeyboardItem("1234567890");
dialog::addKeyboardItem("()[]lLhH,");
dialog::addKeyboardItem(" \t\b\x1\x2\n");
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dialog::addBreak(100);
}
else {
string cs = in() ? current.symbol : XLAT("OFF");
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dialog::addSelItem("edit", cs, '/');
dialog::add_action([] () {
symbol_editing = true;
edited = current;
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dialog::start_editing(edited.symbol);
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edited.parse();
});
dialog::addBreak(100);
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int nextpos = spos;
int shown = 0;
while(nextpos < isize(tilings) && shown < 10) {
auto &ps = tilings[nextpos++];
bool valid = true;
string suffix = "";
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#if CAP_TEXTURE
if(texture::config.tstate == texture::tsActive && texture::cgroup == cpThree) {
valid = false;
if(ps.support_threecolor() == 2) valid = true, suffix += bitruncnames[int(eVariation::pure)];
if(ps.support_threecolor_bitruncated() == 2) valid = true, suffix += bitruncnames[int(eVariation::bitruncated)];
}
if(texture::config.tstate == texture::tsActive && texture::cgroup == cpFootball) {
if(ps.support_football() == 2) suffix += bitruncnames[int(eVariation::pure)];
suffix += bitruncnames[int(eVariation::bitruncated)];
}
if(texture::config.tstate == texture::tsActive && texture::cgroup == cpChess && !ps.support_chessboard()) {
valid = false;
if(ps.support_chessboard()) valid = true, suffix += bitruncnames[int(eVariation::pure)];
if(ps.support_threecolor_bitruncated() == 2) valid = true, suffix += bitruncnames[int(eVariation::dual)];
}
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#endif
if(!valid) continue;
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if(current_filter == &gf_hyperbolic && ps.get_geometry().kind != gcHyperbolic) continue;
if(current_filter == &gf_spherical && ps.get_geometry().kind != gcSphere) continue;
if(current_filter == &gf_euclidean && ps.get_geometry().kind != gcEuclid) continue;
dialog::addSelItem(ps.symbol, fts(ps.euclidean_angle_sum * 180) + "°" + suffix, 'a' + shown);
dialog::lastItem().color = ps.coloring;
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dialog::add_action([&] () { enable(ps); });
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shown++;
}
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dialog::addSelItem(XLAT("current filter"), current_filter ? XLAT(current_filter->name) : XLAT("none"), 'x');
dialog::add_action([] {
if(current_filter == &gf_hyperbolic) current_filter = &gf_euclidean;
else if(current_filter == &gf_euclidean) current_filter = &gf_spherical;
else if(current_filter == &gf_spherical) current_filter = nullptr;
else current_filter = &gf_hyperbolic;
});
dialog::addItem(XLAT("next page"), '-');
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if(shown == 0) nextpos = 0;
dialog::add_action([nextpos] () {
if(nextpos >= isize(tilings))
spos = 0;
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else spos = nextpos;
});
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dialog::addItem(XLAT("previous page"), '=');
dialog::add_action([] () {
spos -= 10;
if(spos < 0) spos = 0;
});
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if(in()) {
dialog::addSelItem(XLAT("size of the world"), current.world_size(), 0);
dialog::addSelItem(XLAT("edge length"), current.get_class() == gcEuclid ? (fts(current.edgelength) + XLAT(" (arbitrary)")) : fts(current.edgelength), 0);
dialog::addItem(XLAT("color by symmetries"), 't');
dialog::add_action(setcanvas('A'));
}
else {
dialog::addBreak(100);
dialog::addBreak(100);
dialog::addBreak(100);
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}
if(true) {
dialog::addItem(XLAT("color by sides"), 'u');
dialog::add_action(setcanvas('B'));
}
if(geosupport_threecolor() == 2) {
dialog::addItem(XLAT("three colors"), 'w');
dialog::add_action(setcanvas('T'));
}
else if(geosupport_football() == 2) {
dialog::addItem(XLAT("football"), 'w');
dialog::add_action(setcanvas('F'));
}
else if(geosupport_chessboard()) {
dialog::addItem(XLAT("chessboard"), 'w');
dialog::add_action(setcanvas('c'));
}
else dialog::addBreak(100);
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if(in()) {
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dialog::addSelItem(XLAT("variations"), gp::operation_name(), 'v');
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dialog::add_action(next_variation);
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}
else dialog::addBreak(100);
}
dialog::addHelp();
dialog::addBack();
dialog::display();
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keyhandler = [] (int sym, int uni) {
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if(symbol_editing && sym == SDLK_RETURN) sym = uni = '/';
dialog::handleNavigation(sym, uni);
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if(symbol_editing && dialog::handle_edit_string(sym, uni)) {
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edited.parse(edited.symbol);
return;
}
if(doexiton(sym, uni)) popScreen();
};
}
void archimedean_tiling::get_nom_denom(int& anom, int& adenom) {
int nom = 2 - N, denom = 2;
for(int f: faces) {
int g = gcd(denom, f);
nom = (nom * f + denom) / g;
denom = denom / g * f;
}
anom = 0, adenom = 1;
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if(BITRUNCATED || DUAL) anom = 1, adenom = 1;
if(!DUAL) for(int f: faces) {
int g = gcd(adenom, f);
anom = (anom * f + adenom) / g;
adenom = adenom / g * f;
}
anom *= 2 * denom, adenom *= nom;
int g = gcd(anom, adenom);
if(g != 0) {
anom /= g; adenom /= g;
}
if(adenom < 0) anom = -anom, adenom = -adenom;
}
string archimedean_tiling::world_size() {
if(get_class() == gcEuclid) return "";
int anom, adenom;
get_nom_denom(anom, adenom);
string s;
bool hyp = (anom < 0);
if(hyp) anom = -anom;
if(adenom != 1)
s += its(anom) + "/" + its(adenom);
else
s += its(anom);
if(hyp) s += " exp(∞)";
return s;
}
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EX int degree(heptagon *h) {
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return isize(current.adjacent[id_of(h)]);
}
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EX bool is_vertex(heptagon *h) {
return id_of(h) >= 2 * current.N;
}
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bool archimedean_tiling::get_step_values(int& steps, int& single_step) {
int nom = -2;
int denom = 1;
for(int f: arcm::current.faces) {
if(int(denom*f)/f != denom) { steps = 0; single_step = 0; return false; }
int g = gcd(denom, f);
nom = nom * (f/g) + (f-2) * (denom/g);
denom = denom/g * f;
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}
steps = 2 * abs(denom);
single_step = abs(nom);
if(steps/2 != abs(denom)) return false;
return (2 * denom) % nom == 0;
}
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EX int valence() {
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if(PURE) return arcm::current.N;
if(BITRUNCATED) return 3;
// in DUAL, usually valence would depend on the vertex.
// 3 is the most interesting, as it allows us to kill hedgehog warriors
int total = 0;
for(int i: current.faces) {
if(i == 3) return 3;
total += i;
}
return total / isize(current.faces);
}
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EX map<gp::loc, cdata>& get_cdata() { return ((arcm::hrmap_archimedean*) (currentmap))->eucdata; }
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#endif
EX }
}