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hyperrogue/rogueviz/som/tests.cpp
2022-05-28 19:02:20 +02:00

1384 lines
33 KiB
C++

// define all our manifolds, and perform tests on them
// Copyright (C) 2011-2022 Tehora and Zeno Rogue, see 'hyper.cpp' for details
#include "kohonen.h"
#include <unordered_map>
namespace rogueviz {
transmatrix& memo_relative_matrix(cell *c1, cell *c2);
namespace kohonen_test {
using namespace kohonen;
void equal_weights() {
alloc(weights);
for(auto& w: weights) w = 1;
}
void show_all() {
samples_to_show.clear();
for(int i=0; i<samples; i++)
samples_to_show.push_back(i);
}
bool check(bool deb);
vector<pair<int, int> > voronoi_edges;
bool nmap;
vector<cell*> where;
int max_distance = 999;
bool using_subdata;
vector<sample> orig_data;
vector<int> sub_indices;
vector<int> inv_sub_indices;
void ideal() {
for(int i=0; i<isize(net); i++)
for(auto& v: net[i].net) v = 1000;
for(int i=0; i<isize(net); i++)
for(int j=0; j<isize(where); j++)
if(where[j] == net[i].where)
net[i].net = (using_subdata ? orig_data : data)[j].val;
println(hlog, make_pair(isize(net), isize(where)));
}
bool sphere_data = false;
bool edge_data;
vector<bool> is_special;
vector<int> ctrdist;
int ctrdist_max;
voronoi::manifold data_manifold;
using measures::manidata;
manidata test_emb, test_orig;
void create_manidata(manidata& mdata) {
auto ac = gen_neuron_cells();
auto& edges = mdata.edges;
edges.clear();
mdata.size = isize(ac);
mdata.distances.clear();
for(int i=0; i<mdata.size; i++) {
for(int j=0; j<i; j++)
if(isNeighbor(ac[i], ac[j]))
edges.emplace_back(i, j);
}
}
void create_data() {
if(sphere_data) return;
sphere_data = true;
initialize_rv();
cell *c0 = currentmap->gamestart();
where.clear();
is_special.clear();
ctrdist.clear();
ctrdist_max = 0;
edge_data = false;
drawthemap();
data.clear(); samples_to_show.clear();
auto ac = gen_neuron_cells();
for(auto c: ac) {
if(celldistance(c, c0) > max_distance) continue;
where.push_back(c);
sample s;
embeddings::get_coordinates(s.val, c, c0);
data.push_back(move(s));
}
samples = isize(data);
test_orig.size = samples;
colnames.resize(columns);
for(int i=0; i<columns; i++) colnames[i] = "Coordinate " + its(i);
equal_weights();
show_all();
data_manifold = voronoi::build_manifold(ac);
for(int i=0; i<samples; i++) {
bool sign = false;
using embeddings::signposts;
for(cell *c: signposts) if(c == where[i]) sign = true;
if(signposts.empty()) sign = where[i]->type != (S3 == 3 ? 6 : 4);
is_special.push_back(sign);
ctrdist.push_back(celldist(where[i]));
ctrdist_max = max(ctrdist_max, ctrdist.back());
}
create_manidata(test_orig);
}
void create_subdata(int qty) {
if(!using_subdata)
orig_data = data;
using_subdata = true;
int N = isize(orig_data);
sub_indices.resize(N);
for(int i=0; i<N; i++) sub_indices[i] = i;
hrandom_shuffle(sub_indices);
sub_indices.resize(qty);
data.clear();
for(int i=0; i<isize(vdata); i++)
if(vdata[i].m) vdata[i].m->dead = true;
vdata.clear();
sample_vdata_id.clear();
state &= ~KS_SAMPLES;
for(int idx: sub_indices) data.push_back(orig_data[idx]);
samples = isize(data);
inv_sub_indices.clear();
inv_sub_indices.resize(N, -1);
for(int i=0; i<samples; i++) inv_sub_indices[sub_indices[i]] = i;
show_all();
edge_data = false;
}
void create_edgedata() {
if(edge_data) return;
edge_data = true;
create_data();
for(int i=0; i<samples; i++) {
if(is_special[i])
vdata[i].cp.color1 = gradient(0xC0C000FF, 0xC00000FF, 0, ctrdist[i], ctrdist_max);
else
vdata[i].cp.color1 = gradient(0x0000FFFF, 0x101010FF, 0, ctrdist[i], ctrdist_max);
}
auto& edges = test_orig.edges;
for(int i=0; i<samples; i++) {
vector<int> ids;
for(auto e: edges) {
if(e.first == i) ids.push_back(e.second);
if(e.second == i) ids.push_back(e.first);
}
vdata[i].name = lalign(0, "#", i, " ", ids);
}
auto any = add_edgetype("adjacent");
if(!using_subdata) {
for(auto e: edges)
addedge(e.first, e.second, 1, false, any);
}
else {
vector<int> nearest(isize(orig_data), -1);
set<pair<int, int>> subedges;
for(int i=0; i<samples; i++)
nearest[sub_indices[i]] = i;
while(true) {
vector<pair<int, int> > changes;
for(auto e: edges) {
if(nearest[e.first] == -1 && nearest[e.second] >= 0) changes.emplace_back(e.first, nearest[e.second]);
if(nearest[e.second] == -1 && nearest[e.first] >= 0) changes.emplace_back(e.second, nearest[e.first]);
}
if(changes.empty()) break;
// hrandom_shuffle(changes);
for(auto ch: changes) nearest[ch.first] = ch.second;
}
for(auto e: edges)
if(nearest[e.first] != nearest[e.second])
subedges.emplace(nearest[e.first], nearest[e.second]);
// for(auto se: subedges) println(hlog, "subedges = ", se);
for(auto sube: subedges)
addedge(sube.first, sube.second, 1, false, any);
}
println(hlog, "edgedata created, ", using_subdata);
}
void sphere_test() {
create_data();
initialize_dispersion();
initialize_neurons_initial();
analyze();
create_edgedata();
ideal();
analyze();
}
void sphere_test_no_disp() {
create_data();
initialize_neurons_initial();
analyze();
create_edgedata();
ideal();
analyze();
}
void check_energy() {
vector<int> dlist;
vector<cell*> win_cells(samples);
for(int i=0; i<samples; i++)
win_cells[i] = winner(i).where;
vector<int> distlist;
for(int i=0; i<samples; i++)
for(int j=0; j<i; j++)
distlist.push_back(celldistance(where[i], where[j]));
for(int i=0; i<samples; i++) {
shiftmatrix M = ggmatrix(where[i]);
println(hlog, i, ": ", M * C0);
}
// println(hlog, distlist);
for(auto e: test_orig.edges) {
cell *w1 = win_cells[e.first];
cell *w2 = win_cells[e.second];
int d = celldistance(w1, w2);
dlist.push_back(d);
}
println(hlog, dlist);
}
void evaluate() {
create_manidata(test_emb);
test_orig.distances = measures::build_distance_matrix(test_orig.size, test_orig.edges);
test_emb.distances = measures::build_distance_matrix(test_emb.size, test_emb.edges);
vector<int> mapp(test_orig.size, 0);
map<cell*, int> id;
for(int i=0; i<isize(net); i++) id[net[i].where] = i;
for(int i=0; i<samples; i++) mapp[i] = id[winner(i).where];
vector<pair<int, int>> edo_recreated = measures::recreate_topology(mapp, test_orig.edges);
for(int k=0; k<measures::MCOUNT; k++) {
print(hlog, measures::catnames[k], " = ", measures::evaluate_measure(test_emb, test_orig, mapp, voronoi_edges, edo_recreated, k), " ");
}
println(hlog);
}
bool kst_key(int sym, int uni) {
if((cmode & sm::NORMAL) && uni == 'l') {
set_neuron_initial();
t = tmax;
analyze();
return true;
}
else if((cmode & sm::NORMAL) && uni == 'd') {
for(int i=0; i<samples; i++)
println(hlog, i, ": ", data[i].val);
return true;
}
else if((cmode & sm::NORMAL) && uni == 'v') {
voronoi_edges = voronoi::compute_voronoi_edges(data_manifold);
println(hlog, "voronoi edges computed");
evaluate();
return true;
}
else if((cmode & sm::NORMAL) && uni == 'r') {
set_neuron_initial();
t = tmax;
dynamicval ks(qpct, 0);
while(!finished()) kohonen::step();
println(hlog, "check result = ", check(true));
check_energy();
return true;
}
if((cmode & sm::NORMAL) && uni == 't') {
tmax /= 2;
println(hlog, "tmax = ", tmax);
return true;
}
if((cmode & sm::NORMAL) && uni == 'x') {
int t = clock();
println(hlog, "weights = ", weights, " w0 = ", weights[0]);
check(true);
println(hlog, "time = ", int(clock() - t), " power = ", kohonen::ttpower, " dea = ", kohonen::dispersion_end_at, " dm = ", kohonen::distmul);
return true;
}
return false;
}
int ks_empty, ks_nonadj, ks_distant;
int qenergy = 0;
double tot_energy = 0;
bool check(bool deb) {
dynamicval dd(debugflags, 0);
set_neuron_initial();
t = tmax;
dynamicval dp(qpct, 0);
while(!finished()) kohonen::step();
analyze();
int empty = 0, nonadj = 0, distant = 0;
for(int i=0; i<cells; i++)
if(net[i].csample == 0)
empty++;
vector<cell*> win_cells(samples);
for(int i=0; i<samples; i++)
win_cells[i] = winner(i).where;
int energy = 0;
for(auto e: test_orig.edges) {
cell *w1 = win_cells[e.first];
cell *w2 = win_cells[e.second];
int rho = celldistance(w1, w2);
energy += rho * rho;
if(!isNeighbor(w1, w2)) {
nonadj++;
bool dist2 = false;
forCellEx(w3, w1)
if(isNeighbor(w3, w2)) dist2 = true;
if(!dist2) distant++;
}
}
tot_energy += energy;
qenergy++;
if(deb) println(hlog, "empty = ", empty, " nonadj = ", nonadj, " distant = ", distant, " energy = ", energy, " avg ", tot_energy / qenergy);
bool res = empty <= ks_empty && distant <= ks_distant && nonadj <= ks_nonadj;
return res;
}
vector<ld> get_parameters() {
return vector<ld> { ttpower, learning_factor, gaussian ? distmul : dispersion_end_at-1 };
}
void set_parameters(const vector<ld>& v) {
ttpower = v[0];
learning_factor = v[1];
if(gaussian) distmul = v[2];
else dispersion_end_at = v[2] + 1;
}
void som_table() {
sphere_test();
map<array<int, 3>, pair<int, int> > tries;
map<array<int, 3>, string> sucorder;
auto bttpower = ttpower;
auto blearning = learning_factor;
auto bdist = distmul;
auto bdispe = dispersion_end_at - 1;
ld last_distmul = -1;
auto set_parameters = [&] (array<int, 3>& u) {
distmul = bdist * exp(u[0] / 5.);
dispersion_end_at = 1 + bdispe * exp(u[0] / 5.);
ttpower = bttpower * exp(u[2] / 5.);
learning_factor = blearning * exp(u[1] / 5.);
if(last_distmul != distmul) {
last_distmul = distmul, state &=~ KS_DISPERSION;
}
};
array<int, 3> best = {0, 0, 0};
int maxtry = 20;
while(true) {
array<int, 3> best_at;
ld bestval = -1;
vector<ld> vals;
for(int k=0; k<27; k++) {
array<int, 3> cnt;
int k1 = k;
for(int i=0; i<3; i++) cnt[2-i] = best[2-i] + (k1%3-1), k1 /= 3;
set_parameters(cnt);
do {
tries[cnt].second++;
dynamicval dd(debugflags, 0);
bool chk = check(false);
if(chk)
tries[cnt].first++;
sucorder[cnt] += (chk ? 'y' : 'n');
}
while(tries[cnt].second < maxtry);
ld val_here = tries[cnt].first * 1. / tries[cnt].second;
if(val_here > bestval) bestval = val_here, best_at = cnt;
vals.push_back(val_here);
}
sort(vals.begin(), vals.end());
best = best_at;
set_parameters(best);
println(hlog, "score ", bestval, " at ", best_at, " : ", tie(distmul, dispersion_end_at, learning_factor, ttpower), " x", tries[best].second, " s=", vals[vals.size()-2]);
if(tries[best].second > maxtry)
maxtry = tries[best].second;
if(tries[best].second >= 1000) {
println(hlog, "suc ", best, " :\n", sucorder[best]);
for(int vv=10; vv>=0; vv--) {
dynamicval ks(qpct, 0);
t = vv ? tmax * vv / 10 : 1;
step();
println(hlog, "t=", t);
println(hlog, "dispersion_count = ", dispersion_count);
}
return;
}
}
}
vector<string> shapelist;
map<string, reaction_t> shapes;
map<string, reaction_t> embeddings;
int data_scale = 1;
int embed_scale = 1;
int current_scale = 1;
void set_gp(int a, int b) {
a *= current_scale; b *= current_scale;
if(a == 1 && b == 1)
set_variation(eVariation::bitruncated);
else if(a == 1 && b == 0)
set_variation(eVariation::pure);
else {
set_variation(eVariation::goldberg);
gp::param = gp::loc(a, b);
}
}
void set_restrict() {
kohonen::kqty = 5000;
kohonen::kohrestrict = 520 * current_scale * current_scale;
}
void set_torus2(int a, int b, int c, int d, int e) {
using namespace euc;
auto& T0 = eu_input.user_axes;
T0[0][0] = a;
T0[0][1] = b;
T0[1][0] = c;
T0[1][1] = d;
eu_input.twisted = e;
build_torus3();
}
int dim = 10;
string emb;
void add(string name, reaction_t embed, reaction_t set) {
shapelist.push_back(name);
shapes[name] = set;
embeddings[name] = embed;
}
void set_euclid3(int x, int y, int z, int twist) {
using namespace euc;
auto& T0 = eu_input.user_axes;
for(int i=0; i<3; i++)
for(int j=0; j<3; j++) T0[i][j] = 0;
T0[0][0] = x;
T0[1][1] = y;
T0[2][2] = z;
eu_input.twisted = twist;
build_torus3();
}
void klein_signposts() {
embeddings::etype = embeddings::eSignpost;
println(hlog, "marking klein signposts");
embeddings::signposts.clear();
for(cell *c: currentmap->allcells()) setdist(c, 7, nullptr);
for(int x=0; x<4; x++)
for(int y=0; y<13; y++) {
cellwalker cw = cellwalker(currentmap->gamestart(), 0);
for(int i=0; i<x*5*current_scale; i++) {
cw += wstep;
cw += 3;
}
cw+=2;
for(int j=0; j<y*current_scale; j++) {
cw += wstep;
cw += 2;
cw += wstep;
cw -= 2;
}
embeddings::signposts.push_back(cw.at);
}
println(hlog, embeddings::signposts);
}
flagtype flags;
const static flagtype m_symmetric = Flag(0);
int landscape_dim = 60;
void init_shapes() {
auto signpost = [] { emb = "signpost"; embeddings::mark_signposts(false, gen_neuron_cells()); };
auto signpost_subg = [] (int a, int b) { return [a,b] { emb = "signpost" + its(a) + its(b); embeddings::mark_signposts_subg(a, b, gen_neuron_cells()); }; };
// auto signpost_full = [] { emb = "signpost-full"; embeddings::mark_signposts(true, gen_neuron_cells()); };
auto signpost_klein = [] { emb = "signpost-klein"; klein_signposts(); };
auto landscape = [] {
emb = "landscape";
if(landscape_dim)
embeddings::init_landscape(landscape_dim);
else
embeddings::init_landscape_det(gen_neuron_cells());
};
auto natural = [] { emb = "natural"; embeddings::etype = embeddings::eNatural; };
/* disks */
add("disk10", landscape, [] {
set_geometry(gNormal);
set_gp(1,0);
set_restrict();
flags = 0;
});
add("disk11", landscape, [] {
set_geometry(gNormal);
set_gp(1,1);
set_restrict();
flags = 0;
});
add("disk20", landscape, [] {
set_geometry(gNormal);
set_gp(2,0);
set_restrict();
flags = 0;
});
add("disk21", landscape, [] {
set_geometry(gNormal);
set_gp(2,1);
set_restrict();
flags = 0;
});
add("disk40", landscape, [] {
set_geometry(gNormal);
set_gp(4,0);
set_restrict();
flags = 0;
});
add("disk43", landscape, [] {
set_geometry(gNormal);
set_gp(4,3);
set_restrict();
flags = 0;
});
add("disk-euclid", landscape, [] {
set_geometry(gEuclid);
set_gp(1,0);
set_restrict();
set_torus2(0,0,0,0,0);
flags = 0;
});
/* spheres */
add("elliptic", signpost, [] {
set_geometry(gElliptic);
set_gp(6,6);
flags = m_symmetric;
});
add("sphere", natural, [] {
set_geometry(gSphere);
set_gp(6,2);
flags = m_symmetric;
});
add("sphere4", natural, [] {
set_geometry(gSmallSphere);
set_gp(7,6);
flags = m_symmetric;
});
/* tori */
add("torus-hex", natural, [] {
set_geometry(gEuclid);
set_gp(1,0);
dim = 23;
set_torus2(dim, 0, 0, dim, 0);
flags = m_symmetric;
});
add("torus-sq", natural, [] {
set_geometry(gEuclid);
set_gp(1,0);
dim = 13;
set_torus2(dim*1.6,0,-dim,dim*2,0);
});
add("torus-rec", natural, [] {
set_geometry(gEuclid);
set_gp(1,0);
dim = 9;
set_torus2(dim*3+2,0,-dim,dim*2,0);
flags = 0;
});
if(0) add("torus-sq-sq", natural, [] {
set_geometry(gEuclidSquare);
set_gp(1,0);
set_torus2(23,0,0,23,0);
flags = m_symmetric;
});
add("klein-sq", signpost_klein, [] {
set_geometry(gEuclid);
set_gp(1,0);
dim = 13;
set_torus2(dim*1.6,0,-dim,dim*2,8);
flags = 0;
});
/* hyperbolic 8 */
add("Bolza", signpost_subg(1, 1), [] {
set_geometry(gBolza);
set_gp(6,3);
flags = m_symmetric;
});
add("Bolza2", signpost, [] {
set_geometry(gBolza2);
set_gp(5,1);
flags = m_symmetric;
});
/* hyperbolic 7 */
add("minimal", signpost, [] {
set_geometry(gMinimal);
set_gp(5,5);
flags = 0;
});
add("Zebra", signpost, [] {
set_geometry(gZebraQuotient);
set_gp(4,3);
flags = 0;
});
add("KQ", signpost, [] {
set_geometry(gKleinQuartic);
set_gp(3,2);
flags = m_symmetric;
});
add("Macbeath", signpost, [] {
set_geometry(gMacbeath);
set_gp(2,1);
flags = m_symmetric;
});
add("triplet1", signpost, [] {
field_quotient_2d(0, 1, 0);
set_gp(1, 1);
flags = m_symmetric;
});
add("triplet2", signpost, [] {
field_quotient_2d(0, 1, 1);
set_gp(1, 1);
flags = m_symmetric;
});
add("triplet3", signpost, [] {
field_quotient_2d(0, 1, 2);
set_gp(1, 1);
flags = m_symmetric;
});
}
void shot_settings() {
View = Id;
brm_limit = GDIM == 2 ? 1000 : 0;
if(GDIM == 3)
View = cspin(0, 2, 30 * degree) * cspin(1, 2, 30*degree) * View;
shift_view(ctangent(2, -0.5));
vid.creature_scale = GDIM == 2 ? 4.5 : 1;
if(geometry == gCell600) vid.creature_scale = 0.5;
pconf.alpha = 1;
pmodel = mdDisk;
if(GDIM == 3 && hyperbolic) {
sightranges[geometry] = 8;
vid.creature_scale = 2;
}
shot::shotformat = -1;
shot::shotx = 1000;
shot::shoty = 1000;
shot::transparent = GDIM == 2;
pconf.scale = 0.9;
modelcolor = 0xFF;
drawthemap();
if(sphere) pconf.scale = 0.6;
if(euclid) {
ld maxs = 0;
auto& cd = current_display;
for(auto n: net) {
auto w = n.where;
shiftmatrix g = ggmatrix(w);
for(int i=0; i<w->type; i++) {
shiftpoint h = tC0(g * currentmap->adj(w, i));
hyperpoint onscreen;
applymodel(h, onscreen);
maxs = max(maxs, onscreen[0] / cd->xsize);
maxs = max(maxs, onscreen[1] / cd->ysize);
}
}
pconf.alpha = 1;
pconf.scale = pconf.scale / 2 / maxs / cd->radius;
pconf.scale /= 1.2;
if(closed_manifold) pconf.scale = WDIM == 3 ? 0.2 : 0.07;
}
if(GDIM == 3) pmodel = mdPerspective;
if(nil || sol) pmodel = mdGeodesic;
vid.use_smart_range = 2;
vid.smart_range_detail = 7;
vid.cells_generated_limit = 999999;
vid.cells_drawn_limit = 200000;
}
void shot_settings_png() {
vid.use_smart_range = 2;
vid.smart_range_detail = 0.5;
shot::shotx = 500;
shot::shoty = 500;
}
bool more = true;
void create_index() {
system(("mkdir " + som_test_dir).c_str());
fhstream f(som_test_dir + "index-" + its(current_scale) + ".html", "wt");
fhstream csv(som_test_dir + "manifold-data-" + its(current_scale) + ".csv", "wt");
fhstream tex(som_test_dir + "manifold-data-" + its(current_scale) + ".tex", "wt");
println(f, "<html><body>");
// fhstream distf(som_test_dir + "distlists-" + its(current_scale) + ".txt", "wt");
bool add_header = true;
for(auto s: shapelist) {
sphere_data = false;
println(hlog, "building ", s);
kohonen::kqty = kohonen::krad = 0;
kohonen::kohrestrict = 999999999;
stop_game();
shapes[s]();
// if(!euclid) continue;
start_game();
initialize_rv();
embeddings[s]();
println(hlog, "create_data");
create_data();
println(hlog, "sphere_test");
sphere_test_no_disp();
println(hlog, "building disttable");
vector<int> disttable(100, 0);
int pairs = 0;
test_orig.distances = measures::build_distance_matrix(test_orig.size, test_orig.edges);
int N = test_orig.size;
for(int i=0; i<N; i++)
for(int j=0; j<i; j++) {
disttable[test_orig.distances[i][j]]++;
pairs++;
}
println(hlog, "render");
shot_settings();
shot_settings_png();
shot::take(som_test_dir + s + "-" + its(current_scale) + ".png");
println(f, "<img src=\"" + s + "-" + its(current_scale) + ".png\"/><br/>");
println(f, "shape ", s, " : ", samples, " items, ", isize(test_orig.edges), " edges, dim ", columns, " (", emb, "), ", full_geometry_name());
println(f, "<hr/>");
fflush(f.f);
again:
if(add_header) print(csv, "name"); else print(csv, s);
if(add_header) print(tex, "name"); else print(tex, s);
#define Out(title,value) if(add_header) { print(csv, ";", title); print(tex, "&", title); } else { print(csv, ";", value); print(tex, "&", value); }
double avgdist = 0, avgdist2 = 0, sqsum = 0;
int maxdist = 0;
for(int i=0; i<100; i++) {
if(disttable[i] > 0) maxdist = i;
avgdist += i * disttable[i];
avgdist2 += i * i * disttable[i];
sqsum += disttable[i] * (disttable[i]-1.);
}
disttable.resize(maxdist + 1);
if(more) println(hlog, disttable, " pairs = ", pairs);
avgdist /= pairs;
avgdist2 /= pairs;
double kmax = 1 - sqsum / (pairs * (pairs-1.));
Out("samples", samples);
Out("edges", isize(test_orig.edges));
Out("columns", columns);
Out("embtype", emb);
Out("gpx", gp::univ_param().first);
Out("gpy", gp::univ_param().second);
Out("orientable", nonorientable ? 0 : 1);
Out("symmetric", (flags & m_symmetric) ? 1 : 0);
Out("closed", closed_manifold ? 1 : 0);
Out("quotient", quotient ? 1 : 0);
Out("dim", WDIM);
Out("valence", S3);
Out("tile", S7);
println(hlog, "gen neuron cells");
auto ac = gen_neuron_cells();
int sum = 0;
for(cell *c: ac) sum += c->type;
ld curvature = (S3 == 3 ? 6 : S3 >= OINF ? 2 : 4) - sum * 1. / isize(ac);
if(GDIM == 3) curvature = hyperbolic ? -1 : sphere ? 1 : 0;
Out("curvature", curvature);
println(hlog, "compute geometry data");
auto gd = compute_geometry_data();
Out("euler", gd.euler);
Out("area", gd.area);
Out("geometry",
hyperbolic ? "hyperbolic" :
euclid ? "euclidean" :
sphere ? "spherical" :
"other");
if(more) {
Out("maxdist", maxdist);
Out("avgdist", avgdist);
Out("avgdist2", avgdist2);
Out("kmax", kmax);
}
println(csv); println(tex, "\\\\");
fflush(csv.f); fflush(f.f); fflush(tex.f);
if(add_header) { add_header = false; goto again; }
println(hlog, "geom = ", s, " delta = ", isize(embeddings::delta_at));
}
println(f, "</body></html>");
}
unsigned hash(string s) {
unsigned res = 0;
for(char c: s) res = res * 37 + c;
return res;
}
int subdata_value;
bool only_landscape;
string cg() {
string s = "";
if(kohonen::gaussian == 1) s += "-cg";
if(kohonen::gaussian == 2) s += "-gg";
if(kohonen::dispersion_long) s += "-dl";
if(ttpower != 1) s += "-tt" + lalign(0, ttpower);
if(subdata_value) s += "-s" + its(subdata_value);
if(landscape_dim) s += "-l" + its(landscape_dim);
if(data_scale) s += "-d" + its(data_scale);
if(embed_scale) s += "-e" + its(embed_scale);
return s;
}
vector<vector<sample> > saved_data;
void all_pairs(bool one) {
string dir = som_test_dir + "pairs" + cg();
system(("mkdir -p " + dir + "/img").c_str());
int sid = 0;
for(auto s1: shapelist) {
for(auto s2: shapelist) {
sid++;
if(kohonen::gaussian == 2 && s2.substr(0, 4) != "disk" && s2.substr(0, 6) != "sphere") continue;
if(only_landscape && s1.substr(0, 4) != "disk") continue;
string fname_vor = dir + "/" + s1 + "-" + s2 + ".vor";
string fname = dir + "/" + s1 + "-" + s2 + ".txt";
if(file_exists(fname)) continue;
fhstream f(fname, "wt");
fhstream fvor(fname_vor, "wt");
println(hlog, "mapping ", s1, " to " ,s2);
shrand(hash(s1) ^ hash(s2));
sphere_data = false; using_subdata = false;
kohonen::kqty = kohonen::krad = 0;
kohonen::kohrestrict = 999999999;
current_scale = data_scale;
stop_game();
shapes[s1]();
start_game();
initialize_rv();
if(landscape_dim) {
saved_data.clear();
for(int i=0; i<100; i++) {
sphere_data = false;
data.clear();
embeddings[s1]();
create_data();
saved_data.push_back(data);
if(i < 5)
for(int j=0; j<20; j++)
println(hlog, "saved data ", i, ":", j, ": ", saved_data[i][j].val);
}
}
else {
embeddings[s1]();
create_data();
}
stop_game();
kohonen::kqty = kohonen::krad = 0;
kohonen::kohrestrict = 999999999;
current_scale = embed_scale;
shapes[s2]();
initialize_dispersion();
initialize_neurons_initial();
analyze();
create_edgedata();
int orig_samples = samples;
for(int i=0; i<100; i++) {
println(hlog, "iteration ", lalign(3, i), " of ", fname);
if(landscape_dim) { data = orig_data = saved_data[i]; }
if(subdata_value) create_subdata(subdata_value);
set_neuron_initial();
if(0) {
println(hlog, "initial neuron values:"); indenter ind(2);
for(auto& n: net) println(hlog, n.net);
}
t = tmax;
dynamicval ks(qpct, 0);
while(!finished()) kohonen::step();
for(int i=0; i<orig_samples; i++) {
if(i) print(f, " ");
int j = i;
if(using_subdata) {
j = inv_sub_indices[i];
if(j == -1) { print(f, "-1"); continue; }
}
auto& w = winner(j);
print(f, int((&w) - &net[0]));
}
print(f, "\n");
fflush(f.f);
voronoi::debug_str = lalign(0, fname_vor, " iteration ", i);
auto ve = voronoi::compute_voronoi_edges(data_manifold);
println(fvor, isize(ve));
for(auto e: ve) print(fvor, e.first, " ", e.second, " ");
println(fvor);
fflush(fvor.f);
if(i < 10) {
analyze();
if(i == 0) {
shot_settings();
shot_settings_png();
shot::shotx = 200;
shot::shoty = 200;
}
if(using_subdata) {
create_edgedata();
}
shot::take(dir + "/img/" + s1 + "-" + s2 + "-" + its(i) + ".png");
}
if(i == 10) brm_structure.clear();
fflush(stdout);
}
if(1) {
fhstream rndcheck(som_test_dir + "rndcheck" + cg(), "at");
vector<int> rnd;
for(int i=0; i<10; i++) rnd.push_back(hrand(1000));
println(hlog, "finished ", s1, "-", s2, " rnd = ", rnd);
println(rndcheck, "finished ", s1, "-", s2, " rnd = ", rnd);
}
if(one) exit(0);
}
}
system("touch done");
}
bool verify_distlists = false;
void create_edgelists() {
fhstream f("results/edgelists-" + its(current_scale) + ".txt", "wt");
for(auto s: shapelist) {
sphere_data = false;
kohonen::kqty = kohonen::krad = 0;
kohonen::kohrestrict = 999999999;
stop_game();
shapes[s]();
// if(!euclid) continue;
start_game();
initialize_rv();
embeddings[s]();
println(hlog, "create_data");
create_data();
println(hlog, "sphere_test");
sphere_test_no_disp();
auto ac = gen_neuron_cells();
int N = isize(ac);
int M = isize(test_orig.edges);
print(f, s, "\n", N, " ", M);
for(auto e: test_orig.edges) print(f, " ", e.first, " ", e.second);
if(verify_distlists) {
test_orig.distances = measures::build_distance_matrix(test_orig.size, test_orig.edges);
for(int i=0; i<N; i++)
for(int j=0; j<i; j++)
if(celldistance(ac[i], ac[j]) != test_orig.distances[i][j])
println(hlog, "failure on ", tie(i, j));
}
println(f);
fflush(f.f);
}
}
#if CAP_COMMANDLINE
int readArgs() {
using namespace arg;
if(0) ;
/* choose the embedding */
else if(argis("-som-landscape")) {
PHASE(3);
start_game();
initialize_rv();
shift(); embeddings::init_landscape(argi());
println(hlog, "landscape init, ", argi());
}
else if(argis("-som-landscape-det")) {
PHASE(3);
start_game();
initialize_rv();
embeddings::init_landscape_det(gen_neuron_cells());
println(hlog, "landscape init, ", argi());
}
else if(argis("-som-signposts")) {
PHASE(3);
start_game();
initialize_rv();
embeddings::mark_signposts(false, gen_neuron_cells());
}
else if(argis("-som-signposts-full")) {
PHASE(3);
start_game();
initialize_rv();
embeddings::mark_signposts(true, gen_neuron_cells());
}
else if(argis("-som-signposts-klein")) {
PHASE(3);
start_game();
klein_signposts();
}
else if(argis("-som-signposts-subg")) {
PHASE(3);
shift(); int a = argi();
shift(); int b = argi();
start_game();
initialize_rv();
embeddings::mark_signposts_subg(a, b, gen_neuron_cells());
}
else if(argis("-som-signposts-draw")) {
for(cell *c: embeddings::signposts) c->wall = waPlatform;
}
else if(argis("-som-rug")) {
PHASE(3);
start_game();
initialize_rv();
shift(); embeddings::generate_rug(argi(), true);
}
else if(argis("-som-rug-show")) {
PHASE(3);
start_game();
initialize_rv();
shift(); embeddings::generate_rug(argi(), false);
}
else if(argis("-som-proj")) {
PHASE(3); embeddings::etype = embeddings::eProjection;
}
else if(argis("-som-emb")) {
PHASE(3); embeddings::etype = embeddings::eNatural;
}
/* other stuff */
else if(argis("-som-test")) {
PHASE(3);
start_game();
sphere_test();
println(hlog, "data = ", isize(data), " neurons = ", isize(net));
}
else if(argis("-som-cdata")) {
PHASE(3);
start_game();
create_data();
}
else if(argis("-subdata")) {
shift();
create_subdata(argi());
}
else if(argis("-subdata-val")) {
shift();
subdata_value = argi();
}
else if(argis("-landscape-dim")) {
shift(); landscape_dim = argi();
}
else if(argis("-som-optimize")) {
PHASE(3);
start_game();
// som_optimize();
}
else if(argis("-som-table")) {
PHASE(3);
start_game();
som_table();
}
else if(argis("-som-scale-data")) {
PHASE(3);
shift(); current_scale = data_scale = argi();
}
else if(argis("-som-scale-embed")) {
PHASE(3);
shift(); current_scale = embed_scale = argi();
}
else if(argis("-by-name")) {
PHASE(3);
init_shapes();
land_structure = lsSingle;
shift(); string s = args();
if(shapes.count(s)) {
kohonen::kqty = kohonen::krad = 0;
kohonen::kohrestrict = 999999999;
stop_game();
shapes[s]();
start_game();
initialize_rv();
embeddings[s]();
println(hlog, "embedding used: ", emb, " for: ", s);
}
else {
println(hlog, "shape unknown: ", s);
}
}
else if(argis("-only-landscape")) {
only_landscape = true;
}
else if(argis("-som-experiment")) {
PHASE(3);
init_shapes();
land_structure = lsSingle;
all_pairs(false);
}
else if(argis("-som-experiment1")) {
PHASE(3);
init_shapes();
land_structure = lsSingle;
all_pairs(true);
}
else if(argis("-som-experiment-index")) {
PHASE(3);
init_shapes();
land_structure = lsSingle;
create_index();
}
else if(argis("-edgecheck")) {
PHASE(3);
unsigned x = 1;
for(auto e: test_orig.edges) {
x*= 7;
x += e.first;
x += 123 * e.second;
}
println(hlog, "x = ", x, " edges = ", isize(test_orig.edges));
}
else if(argis("-som-experiment-tables")) {
PHASE(3);
init_shapes();
land_structure = lsSingle;
create_edgelists();
}
else if(argis("-ex")) exit(0);
else return 1;
return 0;
}
auto hooks3 = addHook(hooks_args, 100, readArgs);
#endif
auto khook = arg::add3("-kst-keys", [] { rv_hook(hooks_handleKey, 150, kst_key); })
+ addHook(hooks_configfile, 100, [] {
param_i(ks_empty, "ks_empty", 0);
param_i(ks_distant, "ks_distant", 0);
param_i(ks_nonadj, "ks_nonadj", 0);
param_i(max_distance, "ks_max");
})
+ addHook(hooks_markers, 100, [] () {
int N = isize(net);
bool multidraw = quotient;
bool use_brm = closed_manifold && isize(currentmap->allcells()) <= brm_limit;
vid.linewidth *= 3;
for(auto e: voronoi_edges)
if(e.first < N && e.second < N)
for(const shiftmatrix& V1 : hr::span_at(current_display->all_drawn_copies, net[e.first].where)) {
if(use_brm) {
auto V2 = brm_get(net[e.first].where, C0, net[e.second].where, C0);
queueline(V1*C0, V1*V2*C0, 0xC010C0FF, vid.linequality + 3);
}
else if(multidraw || elliptic) {
auto V2 = memo_relative_matrix(net[e.second].where, net[e.first].where);
queueline(V1*C0, V1*V2*C0, 0xC010C0FF, vid.linequality + 3);
}
else
for(const shiftmatrix& V2 : hr::span_at(current_display->all_drawn_copies, net[e.second].where))
queueline(V1*C0, V2*C0, 0xC010C0FF, vid.linequality + 3);
}
vid.linewidth /= 3;
})
+ arg::add3("-kst-animate", [] { rv_hook(anims::hooks_record_anim, 100, [] (int i, int noframes) {
bool steps = false;
ld nf = noframes;
while(t * nf > (nf - i) * tmax)
step(), steps = true;
if(steps) analyze();
}); });
}}