1
0
mirror of https://github.com/zenorogue/hyperrogue.git synced 2024-12-26 01:50:36 +00:00
hyperrogue/rogueviz/sag.cpp
2024-05-09 10:44:37 +02:00

1458 lines
41 KiB
C++

#include "rogueviz.h"
// SAG visualizer (e.g. Reddit roguelikes, GitHub languages)
//-----------------------------------------------------------
// see: https://www.youtube.com/watch?v=mDG3_f8R2Ns (SAG boardgames)
// see: https://www.youtube.com/watch?v=WSyygk_3j9o (SAG roguelikes)
// see: https://www.youtube.com/watch?v=HWQkDkeEUeM (SAG programming languages)
#include "dhrg/dhrg.h"
#include <thread>
#include "leastsquare.cpp"
namespace rogueviz {
namespace sag {
int threads = 1;
int informat; /* format ID */
bool turn(int delta);
int sagpar = 0;
bool angular = false;
bool report_tempi = false;
int best_cost = 1000000000;
enum eSagmode { sagOff, sagHC, sagSA };
eSagmode sagmode; // 0 - off, 1 - hillclimbing, 2 - SA
const char *sagmodes[3] = {"off", "HC", "SA"};
ld temperature = -4;
const char *loadfname;
string auto_save;
bool auto_visualize = true;
int vizsa_start;
int vizsa_len = 5;
/** all the SAG cells */
vector<cell*> sagcells;
/** table of distances between SAG cells */
vector<vector<unsigned short>> sagdist;
/** what node is on sagcells[i] */
vector<int> sagnode;
/** node i is on sagcells[sagid[i]] */
vector<int> sagid;
/** sagcells[ids[c]]] == c */
map<cell*, int> ids;
/** if i in neighbors[j], sagcells[i] is a neighbor of sagcells[j] */
vector<vector<int>> neighbors;
ld pdist(hyperpoint hi, hyperpoint hj);
/** matrix for every sagcell */
vector<transmatrix> cell_matrix;
/** precision of geometric distances */
int gdist_prec;
/** max edge for dijkstra */
int dijkstra_maxedge;
/** the maximum value in sagdist +1 */
int max_sag_dist;
vector<edgeinfo> sagedges;
vector<vector<int>> edges_yes, edges_no;
enum eSagMethod { smClosest, smLogistic, smMatch };
eSagMethod method;
bool loglik_repeat;
/* parameters for smMatch */
ld match_a = 1, match_b = 0;
/* parameters for smLogistic */
dhrg::logistic lgsag(1, 1);
vector<ld> loglik_tab_y, loglik_tab_n;
int ipturn = 100;
long long numiter = 0;
int hightemp = 10;
int lowtemp = -15;
/* for the embedding method: */
bool embedding;
dhrg::logistic lgemb(1, 1);
vector<hyperpoint> placement;
string distance_file;
void compute_dists() {
int N = isize(sagcells);
neighbors.clear();
neighbors.resize(N);
for(int i=0; i<N; i++)
for(cell *c1: adj_minefield_cells(sagcells[i]))
if(ids.count(c1)) neighbors[i].push_back(ids[c1]);
const ld ERRORV = -17.3;
transmatrix unknown = Id; unknown[0][0] = ERRORV;
cell_matrix.clear();
cell_matrix.resize(N, unknown);
vector<int> visited;
auto visit = [&] (int id, const transmatrix& T) {
if(cell_matrix[id][0][0] != ERRORV) return;
cell_matrix[id] = T;
visited.push_back(id);
};
visit(0, Id);
for(int i=0; i<isize(visited); i++) {
cell *c0 = sagcells[visited[i]];
const transmatrix& T0 = cell_matrix[visited[i]];
for(int d=0; d<c0->type; d++)
if(ids.count(c0->move(d)))
visit(ids[c0->move(d)], T0 * currentmap->adj(c0, d));
}
sagdist.clear();
sagdist.resize(N);
for(int i=0; i<N; i++) sagdist[i].resize(N, N);
if(distance_file != "") {
fhstream f(distance_file, "rt");
f.read(sagdist);
}
else if(gdist_prec && dijkstra_maxedge) {
vector<vector<pair<int, ld>>> dijkstra_edges(N);
for(int i=0; i<N; i++) {
celllister cl(sagcells[i], dijkstra_maxedge, 50000, nullptr);
for(auto c1: cl.lst) if(ids.count(c1)) if(c1 != sagcells[i])
dijkstra_edges[i].emplace_back(ids[c1], pdist(tC0(cell_matrix[i]), tC0(cell_matrix[ids[c1]])));
if(i == 0) println(hlog, i, " has ", isize(dijkstra_edges[i]), " edges");
}
parallelize(N, [&] (int a, int b) {
vector<ld> distances(N);
for(int i=a; i<b; i++) {
if(i % 500 == 0) println(hlog, "computing dijkstra for ", i , "/", N);
for(int j=0; j<N; j++) distances[j] = HUGE_VAL;
std::priority_queue<pair<ld, int>> pq;
auto visit = [&] (int i, ld dist) {
if(distances[i] <= dist) return;
distances[i] = dist;
pq.emplace(-dist, i);
};
visit(i, 0);
while(!pq.empty()) {
ld d = -pq.top().first;
int at = pq.top().second;
pq.pop();
for(auto e: dijkstra_edges[at]) visit(e.first, d + e.second);
}
for(int j=0; j<N; j++) sagdist[i][j] = distances[j] * gdist_prec + .5;
}
return 0;
}
);
}
else if(gdist_prec) {
for(int i=0; i<N; i++)
for(int j=0; j<N; j++)
sagdist[i][j] = (pdist(tC0(cell_matrix[i]), tC0(cell_matrix[j])) + .5) * gdist_prec;
}
else {
for(int i=0; i<N; i++) {
auto &sdi = sagdist[i];
vector<int> q;
auto visit = [&] (int j, int dist) { if(sdi[j] < N) return; sdi[j] = dist; q.push_back(j); };
visit(i, 0);
for(int j=0; j<isize(q); j++) for(int k: neighbors[q[j]]) visit(k, sdi[q[j]]+1);
}
}
max_sag_dist = 0;
for(auto& d: sagdist) for(auto& x: d) max_sag_dist = max<int>(max_sag_dist, x);
max_sag_dist++;
}
bool legacy;
/* legacy method */
void init_snake(int n) {
sagcells.clear();
ids.clear();
auto enlist = [&] (cellwalker cw) {
ids[cw.at] = isize(sagcells);
sagcells.push_back(cw.at);
};
cellwalker cw = cwt;
enlist(cw);
cw += wstep;
enlist(cw);
for(int i=2; i<n; i++) {
cw += wstep;
while(ids.count(cw.at)) {
cw = cw + wstep + 1 + wstep;
}
enlist(cw); cw += 1;
}
}
void init_sag_cells() {
sagcells = currentmap->allcells();
int N = isize(sagcells);
ids.clear();
for(int i=0; i<N; i++) ids[sagcells[i]] = i;
}
/* separate hubs -- only for smClosest */
ld hub_penalty;
string hub_filename;
vector<int> hubval;
double costat(int vid, int sid) {
if(vid < 0) return 0;
double cost = 0;
if(method == smLogistic) {
auto &s = sagdist[sid];
for(auto j: edges_yes[vid])
cost += loglik_tab_y[s[sagid[j]]];
for(auto j: edges_no[vid])
cost += loglik_tab_n[s[sagid[j]]];
return -cost;
}
if(method == smMatch) {
vertexdata& vd = vdata[vid];
for(int j=0; j<isize(vd.edges); j++) {
edgeinfo *ei = vd.edges[j].second;
int t2 = vd.edges[j].first;
if(sagid[t2] != -1) {
ld cdist = sagdist[sid][sagid[t2]];
ld expect = match_a / ei->weight2 + match_b;
ld dist = cdist - expect;
cost += dist * dist;
}
}
return cost;
}
vertexdata& vd = vdata[vid];
for(int j=0; j<isize(vd.edges); j++) {
edgeinfo *ei = vd.edges[j].second;
int t2 = vd.edges[j].first;
if(sagid[t2] != -1) cost += sagdist[sid][sagid[t2]] * ei->weight2;
}
if(!hubval.empty()) {
for(auto sid2: neighbors[sid]) {
int vid2 = sagnode[sid2];
if(vid2 >= 0 && (hubval[vid] & hubval[vid]) == 0)
cost += hub_penalty;
}
}
return cost;
}
// std::mt19937 los;
double cost;
vector<double> chgs;
edgetype *sag_edge;
void forgetedges(int id) {
for(int i=0; i<isize(vdata[id].edges); i++)
vdata[id].edges[i].second->orig = NULL;
}
bool chance(double p) {
p *= double(hrngen.max()) + 1;
auto l = hrngen();
auto pv = (decltype(l)) p;
if(l < pv) return true;
if(l == pv) return chance(p-pv);
return false;
}
void saiter() {
int DN = isize(sagid);
int t1 = hrand(DN);
int sid1 = sagid[t1];
int sid2;
int s = hrand(4)+1;
if(s == 4) sid2 = hrand(isize(sagcells));
else {
sid2 = sid1;
for(int ii=0; ii<s; ii++) sid2 = hrand_elt(neighbors[sid2]);
}
int t2 = sagnode[sid2];
sagnode[sid1] = -1; sagid[t1] = -1;
sagnode[sid2] = -1; if(t2 >= 0) sagid[t2] = -1;
double change =
costat(t1,sid2) + costat(t2,sid1) - costat(t1,sid1) - costat(t2,sid2);
sagnode[sid1] = t1; sagid[t1] = sid1;
sagnode[sid2] = t2; if(t2 >= 0) sagid[t2] = sid2;
if(change > 0 && (sagmode == sagHC || !chance(exp(-change * exp(-temperature))))) return;
sagnode[sid1] = t2; sagnode[sid2] = t1;
sagid[t1] = sid2; if(t2 >= 0) sagid[t2] = sid1;
cost += change;
}
void prepare_graph() {
int DN = isize(sagid);
set<pair<int, int>> alledges;
for(auto e: sagedges) {
if(e.i == e.j) continue;
alledges.emplace(e.i, e.j);
alledges.emplace(e.j, e.i);
}
edges_yes.clear(); edges_yes.resize(DN);
edges_no.clear(); edges_no.resize(DN);
for(int i=0; i<DN; i++) for(int j=0; j<DN; j++) if(i != j) {
if(alledges.count({i, j}))
edges_yes[i].push_back(j);
else
edges_no[i].push_back(j);
}
sagnode.clear();
sagnode.resize(isize(sagcells), -1);
for(int i=0; i<DN; i++)
sagnode[sagid[i]] = i;
cost = 0;
for(int i=0; i<DN; i++)
cost += costat(i, sagid[i]);
cost /= 2;
}
void set_inverse() {
if(method == smMatch) vizflags |= RV_INVERSE_WEIGHT;
else vizflags &=~ RV_INVERSE_WEIGHT;
}
void reassign() {
int DN = isize(sagid);
for(int i=0; i<DN; i++) {
vdata[i].m->base = sagcells[sag::sagid[i]];
forgetedges(i);
}
shmup::fixStorage();
set_inverse();
}
void load_sag_solution(const string& fname) {
printf("Loading the sag from: %s\n", fname.c_str());
FILE *sf = fopen(fname.c_str(), "rt");
if(!sf) { printf("Failed to open file.\n"); exit(1); }
int SN = isize(sagcells);
if(sf) while(true) {
string lab;
while(true) {
int c = fgetc(sf);
if(c == EOF) goto afterload;
else if(c == ',' || c == ';') break;
else if(rv_ignore(c)) ;
else lab += c;
}
int sid = -1;
int err = fscanf(sf, "%d", &sid);
if(sid < 0 || sid >= SN || err < 1) sid = -1;
if(!labeler.count(lab)) {
printf("unknown vertex: %s\n", lab.c_str());
}
else {
int id = getid(lab);
sagid[id] = sid;
}
}
afterload:
if(sf) fclose(sf);
prepare_graph();
reassign();
}
void dofullsa(ld satime) {
sagmode = sagSA;
int t1 = SDL_GetTicks();
int tl = -999999;
while(true) {
int t2 = SDL_GetTicks();
double d = (t2-t1) / (1000. * satime);
if(d > 1) break;
temperature = hightemp - (d*(hightemp-lowtemp));
for(int i=0; i<10000; i++) {
numiter++;
sag::saiter();
}
if(t2 - tl > 980) {
tl = t2;
println(hlog, hr::format("it %12lld temp %6.4f [1/e at %13.6f] cost = %f ",
numiter, double(sag::temperature), (double) exp(sag::temperature),
double(sag::cost)));
}
}
temperature = -5;
sagmode = sagOff;
reassign();
}
void dofullsa_iterations(long long saiter) {
sagmode = sagSA;
decltype(SDL_GetTicks()) t1 = -999999;
for(int i=0; i<saiter; i++) {
temperature = hightemp - ((i+.5)/saiter*(hightemp-lowtemp));
numiter++;
sag::saiter();
if(numiter % 10000 == 0) {
auto t2 = SDL_GetTicks();
if(t2 - t1 > 1000) {
t1 = t2;
println(hlog, hr::format("it %12lld temp %6.4f [1/e at %13.6f] cost = %f ",
numiter, double(sag::temperature), (double) exp(sag::temperature),
double(sag::cost)));
}
}
}
temperature = -5;
sagmode = sagOff;
reassign();
}
int sag_ittime = 100;
void iterate() {
if(!sagmode) return;
int t1 = SDL_GetTicks();
#if CAP_SDL && !CAP_SDL2
int last = -1;
#endif
for(int i=0; i<ipturn; i++) {
numiter++;
sag::saiter();
#if CAP_SDL && !CAP_SDL2
int q = i * sag_ittime / ipturn;
if(q > last) { last = 1; SDL_PumpEvents(); }
#endif
}
int t2 = SDL_GetTicks();
int t = t2 - t1;
if(t < (sag_ittime+1) / 2) ipturn *= 2;
else if(t > sag_ittime * 2) ipturn /= 2;
else ipturn = ipturn * sag_ittime / t;
print(hlog, hr::format("it %12lld temp %6.4f [2:%8.6f,10:%8.6f,50:%8.6f] cost = %f\n",
numiter, double(sag::temperature),
(double) exp(-2 * exp(-sag::temperature)),
(double) exp(-10 * exp(-sag::temperature)),
(double) exp(-50 * exp(-sag::temperature)),
(double) sag::cost));
if(auto_visualize) reassign();
}
void save_sag_solution(const string& fname) {
FILE *f = fopen(fname.c_str(), "wt");
for(int i=0; i<isize(sagid); i++)
fprintf(f, "%s;%d\n", vdata[i].name.c_str(), sagid[i]);
fclose(f);
}
void compute_loglik_tab() {
loglik_tab_y.resize(max_sag_dist);
loglik_tab_n.resize(max_sag_dist);
for(int i=0; i<max_sag_dist; i++) {
loglik_tab_y[i] = lgsag.lyes(i);
loglik_tab_n[i] = lgsag.lno(i);
}
}
void compute_auto_rt() {
ld sum0 = 0, sum1 = 0, sum2 = 0;
for(auto& tab: sagdist) for(auto i: tab) {
sum0 ++;
sum1 += i;
sum2 += i*i;
}
lgsag.R = sum1 / sum0;
lgsag.T = sqrt((sum2 - sum1*sum1/sum0) / sum0);
println(hlog, "automatically set R = ", lgsag.R, " and ", lgsag.T, " max_sag_dist = ", max_sag_dist);
if(method == smLogistic) compute_loglik_tab();
}
void optimize_sag_loglik_logistic() {
vector<int> indist(max_sag_dist, 0);
const int mul = 1;
int N = isize(sagid);
for(int i=0; i<N; i++)
for(int j=0; j<i; j++) {
int d = sagdist[sagid[i]][sagid[j]];
indist[d]++;
}
vector<int> pedge(max_sag_dist, 0);
for(int i=0; i<isize(sagedges); i++) {
edgeinfo& ei = sagedges[i];
if(int(sagdist[sagid[ei.i]][sagid[ei.j]] * mul) == 136) printf("E %d,%d\n", ei.i, ei.j);
if(ei.i != ei.j)
if(ei.weight >= sag_edge->visible_from)
pedge[sagdist[sagid[ei.i]][sagid[ei.j]] * mul]++;
}
for(int d=0; d<max_sag_dist; d++)
if(indist[d])
printf("%2d: %7d/%7d %7.3lf\n",
d, pedge[d], indist[d], double(pedge[d] * 100. / indist[d]));
ld loglik = 0;
for(int d=0; d<max_sag_dist; d++) {
int p = pedge[d], pq = indist[d];
int q = pq - p;
if(p && q) {
loglik += p * log(p) + q * log(q) - pq * log(pq);
println(hlog, tie(d, p, q), loglik);
}
}
println(hlog, "loglikelihood best = ", fts(loglik));
auto logisticf = [&] (dhrg::logistic& l) {
ld loglik = 0;
for(int d=0; d<max_sag_dist; d++) {
int p = pedge[d], pq = indist[d];
if(p) loglik += p * l.lyes(d);
if(pq > p) loglik += (pq-p) * l.lno(d);
}
return loglik;
};
dhrg::fast_loglik_cont(lgsag, logisticf, nullptr, 1, 1e-5);
println(hlog, "loglikelihood logistic = ", logisticf(lgsag), " R= ", lgsag.R, " T= ", lgsag.T);
if(method == smLogistic) {
compute_loglik_tab();
prepare_graph();
println(hlog, "cost = ", cost);
}
}
void optimize_sag_loglik_match() {
lsq::leastsquare_solver<2> lsqs;
for(auto& ei: sagedges) {
ld y = sagdist[sagid[ei.i]][sagid[ei.j]];
ld x = 1. / ei.weight;
lsqs.add_data({{x, 1}}, y);
}
array<ld, 2> solution = lsqs.solve();
match_a = solution[0];
match_b = solution[1];
println(hlog, "got a = ", match_a, " b = ", match_b);
if(method == smMatch)
prepare_graph();
}
void optimize_sag_loglik_auto() {
if(method == smLogistic) optimize_sag_loglik_logistic();
if(method == smMatch) optimize_sag_loglik_match();
}
void disttable_add(ld dist, int qty0, int qty1) {
using namespace dhrg;
size_t i = dist * llcont_approx_prec;
constexpr array<ll, 2> zero = {0, 0};
while(disttable_approx.size() <= i) disttable_approx.push_back(zero);
disttable_approx[i][0] += qty0;
disttable_approx[i][1] += qty1;
}
ld approx_01(hyperpoint h) {
ld d = 0;
if(h[0] > 1) {
ld z = log(h[0]);
d += z; h[1] *= h[0]; h[0] = 1; h[2] += z;
}
d += h[0];
if(h[1] > 1) {
ld z = log(h[1]);
d += z; h[1] = 1; h[2] -= z;
}
d += h[1];
d += abs(h[2]);
return d;
}
ld pdist(hyperpoint hi, hyperpoint hj) {
if(sol) return min(geo_dist(hi, hj), geo_dist(hj, hi));
if(mproduct && angular) {
auto di = product_decompose(hi);
auto dj = product_decompose(hj);
ld x = hdist(di.second, dj.second);
ld z = di.first - dj.first;
return log((x*x+z*z) * (x > 0 ? sinh(x) / x : 0));
}
return geo_dist(hi, hj);
};
ld pdist(int i, int j) {
return pdist(placement[i], placement[j]);
};
void prepare_embedding() {
map<int, transmatrix> maps;
vector<int> visited;
auto visit = [&] (int id, const transmatrix& T) {
if(maps.count(id)) return;
maps[id] = T;
visited.push_back(id);
};
visit(0, Id);
for(int i=0; i<isize(visited); i++) {
cell *c0 = sagcells[i];
transmatrix T0 = maps[i];
for(int d=0; d<c0->type; d++)
if(ids.count(c0->move(d)))
visit(ids[c0->move(d)], T0 * currentmap->adj(c0, d));
}
int DN = isize(sagid);
placement.resize(DN);
for(int i=0; i<DN; i++) placement[i] = tC0(maps[sagid[i]]);
}
int embiter;
void compute_loglik() {
dhrg::llcont_approx_prec = 10;
dhrg::disttable_approx.clear();
int DN = isize(sagid);
for(int i=0; i<DN; i++)
for(int j=0; j<i; j++)
disttable_add(pdist(i, j), 1, 0);
for(int i=0; i<isize(sagedges); i++) {
edgeinfo& ei = sagedges[i];
if(ei.i != ei.j)
disttable_add(pdist(ei.i, ei.j), -1, 1);
}
dhrg::logisticfun lc = dhrg::loglik_cont_approx;
dhrg::fast_loglik_cont(lgemb, lc, nullptr, 1, 1e-5);
println(hlog, "loglik = ", hr::format("%.6f", lc(lgemb)), " R = ", lgemb.R, " T = ", lgemb.T, " iterations = ", embiter);
}
void reassign_embedding() {
int DN = isize(sagid);
for(int i=0; i<DN; i++) {
vdata[i].m->base = sagcells[0];
vdata[i].m->at = rgpushxto0(placement[i]);
virtualRebase(vdata[i].m);
forgetedges(i);
}
shmup::fixStorage();
}
void improve_embedding() {
embiter++;
if(placement.empty()) {
prepare_embedding();
compute_loglik();
}
ld eps = .1;
int DN = isize(sagid);
hyperpoint h = C0;
for(int i=0; i<WDIM; i++) h[i] += (hrandf() - 0.5) * eps;
h = normalize(h);
auto nplacement = placement;
parallelize(DN, [&] (int a, int b) {
for(int i=a; i<b; i++) {
hyperpoint np = rgpushxto0(placement[i]) * h;
ld change = 0;
for(auto e: edges_yes[i]) change -= lgemb.lyes(pdist(placement[i], placement[e]));
for(auto e: edges_no[i]) change -= lgemb.lno(pdist(placement[i], placement[e]));
for(auto e: edges_yes[i]) change += lgemb.lyes(pdist(np, placement[e]));
for(auto e: edges_no[i]) change += lgemb.lno(pdist(np, placement[e]));
if(change > 0) nplacement[i] = np;
}
return 0;
});
placement = nplacement;
}
int embturn = 1;
void embedding_iterate() {
int t1 = SDL_GetTicks();
for(int i=0; i<embturn; i++) {
improve_embedding();
}
int t2 = SDL_GetTicks();
int t = t2 - t1;
if(t < 50) embturn *= 2;
else if(t > 200) embturn = (embturn + 1) / 2;
else embturn = (embturn * 100 + (t-1)) / t;
compute_loglik();
if(auto_visualize) reassign_embedding();
}
void save_embedding(const string& fname) {
fhstream f(fname, "wt");
for(int i=0; i<isize(sagid); i++) {
println(f, vdata[i].name);
for(int d=0; d<MDIM; d++)
println(f, hr::format("%.20f", placement[i][d]));
}
}
void load_embedding(const string& fname) {
prepare_embedding();
fhstream f(fname, "rt");
if(informat == 2) {
/* H2 embedding */
while(!feof(f.f)) {
string lab = scan<string>(f);
int id;
if(!labeler.count(lab)) {
printf("unknown vertex: %s\n", lab.c_str());
continue;
}
else id = getid(lab);
ld alpha, r;
if(1) {
dynamicval<eGeometry> g(geometry, gNormal);
hyperpoint h;
for(int d=0; d<MDIM; d++) h[d] = scan<ld>(f);
alpha = atan2(h);
r = hdist0(h);
println(hlog, "read ", lab, " as ", h, " which is ", tie(alpha, r));
}
placement[id] = direct_exp(cspin(0, 2, alpha) * ctangent(0, r));
println(hlog, "dist = ", pdist(placement[id], C0), " expected: ", r);
}
}
else if(informat == 3) {
/* BFKL */
string ignore;
if(!scan(f, ignore, ignore, ignore, ignore, ignore, ignore, ignore, ignore)) {
printf("Error: incorrect format of the first line\n"); exit(1);
}
while(true) {
string lab = scan<string>(f);
if(lab == "" || lab == "#ROGUEVIZ_ENDOFDATA") break;
ld r, alpha;
if(!scan(f, r, alpha)) { printf("Error: incorrect format of r/alpha\n"); exit(1); }
hyperpoint h = spin(alpha * degree) * xpush0(r);
if(!labeler.count(lab)) {
printf("unknown vertex: %s\n", lab.c_str());
}
else {
int id = getid(lab);
placement[id] = h;
}
}
}
else if(informat == 4) {
while(true) {
string lab = scan<string>(f);
if(lab == "") break;
ld r, alpha;
if(!scan(f, r, alpha)) { printf("Error: incorrect format of r/alpha\n"); exit(1); }
hyperpoint h = spin(alpha) * xpush0(r);
if(!labeler.count(lab)) {
printf("unknown vertex: %s\n", lab.c_str());
}
else {
int id = getid(lab);
placement[id] = h;
}
}
}
else {
while(!feof(f.f)) {
string lab = scan<string>(f);
int id;
if(!labeler.count(lab)) {
printf("unknown vertex: %s\n", lab.c_str());
continue;
}
else id = getid(lab);
hyperpoint h;
for(int d=0; d<MDIM; d++) h[d] = scan<ld>(f);
placement[id] = h;
}
}
reassign_embedding();
compute_loglik();
}
void read_hubs(const string& fname) {
hubval.resize(isize(vdata), -1);
fhstream f(fname, "rt");
if(!f.f) { printf("Failed to open hub file: %s\n", fname.c_str()); exit(1); }
println(hlog, "loading hubs: ", fname);
while(!feof(f.f)) {
string l1, l2;
while(true) {
int c = fgetc(f.f);
if(c == EOF) return;
else if(c == ';') break;
else if(rv_ignore(c)) ;
else l1 += c;
}
while(true) {
int c = fgetc(f.f);
if(c == EOF) return;
else if(c == ';') return;
else if(rv_ignore(c)) break;
else l2 += c;
}
if(!id_known(l1)) {
printf("label unknown: %s\n", l1.c_str());
exit(1);
}
hubval[getid(l1)] = atoi(l2.c_str());
}
}
void readsag(const char *fname) {
maxweight = 0;
sag_edge = add_edgetype("SAG edge");
rogueviz::cleanup.push_back([] { sag_edge = nullptr; });
fhstream f(fname, "rt");
if(!f.f) {
printf("Failed to open SAG file: %s\n", fname);
throw "failed to open SAG file";
}
if(informat == 1) {
scanline(f);
set<pair<int, int> > edges;
int all = 0, good = 0;
while(!feof(f.f)) {
string l1 = scan<string>(f);
string l2 = scan<string>(f);
if(l1 == "") continue;
if(l2 == "") continue;
edgeinfo ei(sag_edge);
ei.i = getid(l1);
ei.j = getid(l2);
if(ei.i > ei.j) swap(ei.i, ei.j);
all++;
if(edges.count({ei.i, ei.j})) continue;
good++;
edges.emplace(ei.i, ei.j);
ei.weight = 1;
sagedges.push_back(ei);
}
println(hlog, "N = ", isize(vdata), " edges = ", good, "/", all);
return;
}
while(!feof(f.f)) {
string l1, l2;
while(true) {
int c = fgetc(f.f);
if(c == EOF) return;
else if(c == ';') break;
else if(rv_ignore(c)) ;
else l1 += c;
}
while(true) {
int c = fgetc(f.f);
if(c == EOF) return;
else if(c == ';') break;
else if(rv_ignore(c)) ;
else l2 += c;
}
ld wei;
if(!scan(f, wei)) continue;
edgeinfo ei(sag_edge);
ei.i = getid(l1);
ei.j = getid(l2);
ei.weight = wei;
sagedges.push_back(ei);
}
}
ld edgepower=1, edgemul=1;
void init() {
rogueviz::init(RV_GRAPH | RV_WHICHWEIGHT | RV_AUTO_MAXWEIGHT | RV_HAVE_WEIGHT);
rv_hook(rogueviz::hooks_close, 100, [] { sag::sagedges.clear(); });
rv_hook(shmup::hooks_turn, 100, turn);
rv_hook(rogueviz::hooks_rvmenu, 100, [] {
dialog::addSelItem(XLAT("temperature"), fts(sag::temperature), 't');
dialog::add_action([] {
dialog::editNumber(sag::temperature, sag::lowtemp, sag::hightemp, 1, 0, XLAT("temperature"), "");
});
dialog::addSelItem(XLAT("SAG mode"), sag::sagmodes[sag::sagmode], 'm');
dialog::add_action([] { sag::sagmode = sag::eSagmode( (1+sag::sagmode) % 3 ); });
dialog::addSelItem(XLAT("min temperature"), fts(sag::lowtemp), 'i');
dialog::add_action([] {
dialog::editNumber(sag::lowtemp, -20, 20, 1, 0, XLAT("min temperature"), "");
});
dialog::addSelItem(XLAT("max temperature"), fts(sag::hightemp), 'i');
dialog::add_action([] {
dialog::editNumber(sag::hightemp, -20, 20, 1, 0, XLAT("high temperature"), "");
});
dialog::addSelItem(XLAT("automatic cycle"), fts(sag::vizsa_len), 'c');
dialog::add_action([] {
dialog::editNumber(sag::vizsa_len, 5, 1800, 1, 0, XLAT("automatic cycle"), "");
});
dialog::addBoolItem(XLAT("automatic"), sag::vizsa_start, 'a');
dialog::add_action([] {
sag::vizsa_start = sag::vizsa_start ? 0 : SDL_GetTicks();
sag::sagmode = sagOff;
});
dialog::addSelItem(XLAT("smoothness"), its(sag_ittime), 's');
dialog::add_action([] {
dialog::editNumber(sag_ittime, 0, 1000, 10, 100, XLAT("smoothness"),
XLAT("How much milliseconds to compute before re-rendering the screen when optimizing in the background. Low values look nicer, but may cause less time to be spent on iterations.")
);
});
dialog::addBoolItem_action(XLAT("auto-visualize"), sag::auto_visualize, 'b');
dialog::addBoolItem_action(XLAT("continuous embedding"), sag::embedding, 'e');
if(method == smMatch) {
dialog::addSelItem(XLAT("match parameter A"), fts(match_a), 'A');
dialog::add_action([] {
dialog::editNumber(match_a, 0, 10, 1, 1, XLAT("match parameter A"), "").reaction = prepare_graph;
});
dialog::addSelItem(XLAT("match parameter B"), fts(match_b), 'B');
dialog::add_action([] {
dialog::editNumber(match_b, 0, 10, 1, 1, XLAT("match parameter B"), "").reaction = prepare_graph;
});
}
dialog::addSelItem(XLAT("cost value"), fts(cost), 'X');
dialog::add_action([] {
optimize_sag_loglik_auto();
});
});
weight_label = "min weight";
temperature = 0; sagmode = sagOff;
}
void create_viz() {
int DN = isize(vdata);
for(int i=0; i<DN; i++) vdata[i].data = 0;
for(int i=0; i<isize(sagedges); i++) {
edgeinfo& ei = sagedges[i];
ei.weight2 = pow((double) ei.weight, (double) edgepower) * edgemul;
addedge0(ei.i, ei.j, &ei);
}
for(int i=0; i<DN; i++) {
int ii = i;
vertexdata& vd = vdata[ii];
vd.cp = colorpair(dftcolor);
createViz(ii, sagcells[sagid[i]], Id);
}
storeall();
}
void read(string fn) {
fname = fn;
init();
readsag(fname.c_str());
if(hub_filename != "")
read_hubs(hub_filename);
int DN = isize(vdata);
if(legacy)
init_snake(2 * DN);
else
init_sag_cells();
compute_dists();
int SN = isize(sagcells);
if(SN < DN) {
println(hlog, "SN = ", SN, " DN = ", DN);
throw hr_exception("not enough cells for SAG");
exit(1);
}
sagid.resize(DN);
for(int i=0; i<DN; i++) sagid[i] = i;
prepare_graph();
create_viz();
}
void generate_fake_data(int n, int m) {
init();
init_sag_cells();
compute_dists();
sagid.resize(n);
for(int i=0; i<n; i++) sagid[i] = i;
hrandom_shuffle(sagid);
if(m > n || m < 0) throw hr_exception("generate_fake_data parameters incorrect");
sagid.resize(m);
int SN = isize(sagcells);
int DN = isize(sagid);
vdata.resize(DN);
for(int i=0; i<DN; i++)
vdata[i].name = its(i) + "@" + its(sagid[i]);
sag_edge = add_edgetype("SAG edge");
for(int i=0; i<DN; i++)
for(int j=i+1; j<DN; j++) {
edgeinfo ei(sag_edge);
ei.i = i;
ei.j = j;
ei.weight = 1. / sagdist[sagid[i]][sagid[j]];
sagedges.push_back(ei);
}
if(SN < DN) {
println(hlog, "SN = ", SN, " DN = ", DN);
throw hr_exception("not enough cells for SAG");
exit(1);
}
prepare_graph();
create_viz();
for(int i=0; i<DN; i++) {
color_t col = ccolor::formula.f(sagcells[sagid[i]], ccolor::formula);
col <<= 8;
col |= 0xFF;
vdata[i].cp.color1 = vdata[i].cp.color2 = col;
}
}
ld compute_mAP() {
ld mAP = 0;
int DN = isize(sagid);
for(int i=0; i<DN; i++) {
vector<int> alldist;
for(int j=0; j<DN; j++) if(i != j) alldist.push_back(sagdist[sagid[i]][sagid[j]]);
sort(alldist.begin(), alldist.end());
int q = isize(edges_yes[i]);
int qmin = q-1, qmax = q+1;
int threshold = alldist[q-1];
while(qmin && alldist[qmin-1] == threshold) qmin--;
while(qmax < isize(alldist)-2 && alldist[qmax+1] == threshold) qmax++;
ld on_threshold = (q - qmin) / (qmax + 1. - qmin);
int good = 0, onthr = 0;
for(auto j: edges_yes[i]) {
int d = sagdist[sagid[i]][sagid[j]];
if(d < threshold) good++;
if(d == threshold) onthr++;
}
mAP += (good + onthr * on_threshold) / q / DN;
}
return mAP;
}
int logid;
void geo_stats() {
start_game();
println(hlog, "init_sag_cells started");
init_sag_cells();
println(hlog, "compute_dists started");
compute_dists();
println(hlog, "real");
vector<short> sorted_sagdist;
for(auto& a: sagdist) for(auto b: a) sorted_sagdist.push_back(b);
sort(sorted_sagdist.begin(), sorted_sagdist.end());
vector<int> d(5, 0);
for(auto a: sagdist[0]) if(a < 5) d[a]++;
for(int i=0; i<3; i++) {
bool first = false;
#define out(x, y) if(i == 0) println(hlog, x, " = ", y); else if(first) print(hlog, ";"); first = true; if(i == 1) print(hlog, x); if(i == 2) print(hlog, y);
out("nodes", isize(sagcells));
out("maxsagdist", max_sag_dist);
out("dim", (euclid && WDIM == 2 && euc::eu.user_axes[1][1] == 1) ? 1 : WDIM);
out("geometry", S3 >= OINF ? "tree" : hyperbolic ? "hyperbolic" : sphere ? "sphere" : euclid ? "euclid" : nil ? "nil" : sol ? "solv" : mproduct ? "product" : "other");
out("closed", max_sag_dist == isize(sagcells) ? 0 : closed_manifold ? 1 : 0);
out("angular", angular);
for(int p: {1, 10, 50}) { out(hr::format("sagdist%02d", p), sorted_sagdist[(p * sorted_sagdist.size()) / 100]); }
for(int p: {1, 2, 3, 4}) { out(hr::format("d%d", p), d[p]); }
println(hlog);
#undef out
}
}
void output_stats() {
if(auto_save != "" && cost < best_cost) {
println(hlog, "cost ", cost, " beats ", best_cost);
best_cost = cost;
sag::save_sag_solution(auto_save);
}
println(hlog, "solution: ", sagid);
int DN = isize(sagid);
ld mAP = compute_mAP();
dhrg::iddata routing_result;
dhrg::prepare_pairs(DN, [] (int i) { return edges_yes[i]; });
dhrg::greedy_routing(routing_result, [] (int i, int j) { return sagdist[sagid[i]][sagid[j]]; });
print(hlog, "CSV;", logid++, ";", isize(sagnode), ";", DN, ";", isize(sagedges), ";", lgsag.R, ";", lgsag.T, ";", cost, ";", mAP, ";", routing_result.suc / routing_result.tot, ";", routing_result.routedist / routing_result.bestdist);
if(report_tempi) print(hlog, ";", hightemp,";",lowtemp,";",hr::format("%lld", numiter));
println(hlog);
}
int readArgs() {
#if CAP_COMMANDLINE
using namespace arg;
if(0) ;
else if(argis("-sagmin")) {
auto& ed = sag_edge ? *sag_edge : default_edgetype;
shift_arg_formula(ed.visible_from);
ed.visible_from_hi = ed.visible_from;
}
else if(argis("-sagminhi")) {
auto& ed = sag_edge ? *sag_edge : default_edgetype;
shift_arg_formula(ed.visible_from_hi);
}
else if(argis("-sag_gdist")) {
shift(); sag::gdist_prec = argi();
}
else if(argis("-sag_gdist_dijkstra")) {
shift(); sag::dijkstra_maxedge = argi();
}
else if(argis("-sag_gdist_save")) {
shift();
fhstream f(args(), "wt");
f.write(sagdist);
}
else if(argis("-sag_gdist_load")) {
shift(); distance_file = args();
}
else if(argis("-sagrt")) {
shift(); sag::lgsag.R = argf();
shift(); sag::lgsag.T = argf();
if(method == smLogistic) compute_loglik_tab();
}
else if(argis("-sagmatch-ab")) {
shift(); sag::match_a = argf();
shift(); sag::match_b = argf();
if(method == smMatch) prepare_graph();
}
else if(argis("-sagrt-auto")) {
compute_auto_rt();
}
else if(argis("-sag_use_loglik")) {
shift(); int mtd = argi();
if(mtd == 0) method = smClosest, loglik_repeat = false;
if(mtd == 1) method = smLogistic, loglik_repeat = false;
if(mtd == 2) method = smLogistic, loglik_repeat = true;
if(mtd == 3) method = smMatch, loglik_repeat = false;
if(mtd == 4) method = smMatch, loglik_repeat = true;
if(method == smLogistic)
compute_loglik_tab();
if(method == smMatch) prepare_graph();
}
else if(argis("-sagformat")) {
shift(); informat = argi();
}
// (1) configure edge weights
else if(argis("-sag-edgepower")) {
shift_arg_formula(sag::edgepower);
shift_arg_formula(sag::edgemul);
}
// (1) configure temperature (high, low)
else if(argis("-sagtemp")) {
shift(); sag::hightemp = argi();
shift(); sag::lowtemp = argi();
}
// (2) read the edge data
else if(argis("-sagpar")) {
PHASE(3);
shift();
sag::sagpar = argi();
}
else if(argis("-sag")) {
PHASE(3);
shift(); sag::read(args());
}
else if(argis("-sagfake")) {
PHASE(3);
shift(); int n = argi();
shift(); int m = argi();
sag::generate_fake_data(n, m);
}
else if(argis("-sagaviz")) {
PHASE(3);
shift(); sag::auto_visualize = argi();
}
else if(argis("-saghubs")) {
println(hlog, "HUBS");
PHASE(3);
shift_arg_formula(sag::hub_penalty);
shift(); hub_filename = args();
}
// (3) load the initial positioning
else if(argis("-sagload")) {
PHASE(3); shift(); sag::load_sag_solution(args());
}
// (4) perform simulated annealing: -fullsa <time in seconds>
else if(argis("-sagfull")) {
shift(); sag::dofullsa(argf());
}
else if(argis("-sagfulli")) {
shift(); sag::dofullsa_iterations(argll());
}
else if(argis("-sagviz")) {
sag::vizsa_start = SDL_GetTicks();
shift(); sag::vizsa_len = argi();
}
else if(argis("-sagsmooth")) {
shift(); sag::sag_ittime = argi();
}
else if(argis("-sagstats")) {
output_stats();
}
else if(argis("-sag-angular")) {
shift(); angular = argi();
}
else if(argis("-sagstats-logid")) {
shift(); logid = argi();
}
// (5) save the positioning
else if(argis("-sagsave")) {
PHASE(3); shift(); sag::save_sag_solution(args());
}
else if(argis("-sagsave-auto")) {
PHASE(3); shift(); auto_save = args();
}
// (6) output loglikelihood
else if(argis("-sagloglik-l")) {
sag::optimize_sag_loglik_logistic();
}
else if(argis("-sagloglik-m")) {
sag::optimize_sag_loglik_match();
}
else if(argis("-sagloglik-a")) {
sag::optimize_sag_loglik_auto();
}
else if(argis("-sagmode")) {
shift();
vizsa_start = 0;
sagmode = (eSagmode) argi();
if(sagmode == sagSA) {
shift(); temperature = argf();
}
}
else if(argis("-sagembed")) {
sag::embedding = true;
}
else if(argis("-sag0")) {
sag::report_tempi = true;
numiter = 0;
}
else if(argis("-sagembedoff")) {
sag::embedding = false;
}
else if(argis("-sagsavee")) {
PHASE(3); shift(); sag::save_embedding(args());
}
else if(argis("-sagloade")) {
PHASE(3); shift(); sag::load_embedding(args());
}
else if(argis("-sag-geo-stats")) geo_stats();
else return 1;
#endif
return 0;
}
bool turn(int delta) {
if(vizsa_start) {
if(vizsa_start == -1) vizsa_start = ticks;
auto t = ticks;
double d = (t-vizsa_start) / (1000. * vizsa_len);
if(d > 1 && loglik_repeat) {
optimize_sag_loglik_auto();
output_stats();
vizsa_start = -1;
}
if(d > 1) sagmode = sagOff;
else {
temperature = hightemp - (d*(hightemp-lowtemp));
sagmode = sagSA;
}
}
if(sagmode == sagOff && embedding) {
embedding_iterate();
}
iterate();
return false;
// shmup::pc[0]->rebase();
}
string cname() {
if(euclid) return "coord-6.txt";
if(PURE) return "coord-7.txt";
return "coord-67.txt";
}
int ah = addHook(hooks_args, 100, readArgs)
+ addHook_rvslides(120, [] (string s, vector<tour::slide>& v) {
if(s != "data") return;
using namespace pres;
string sagf = "SAG/";
v.push_back(
slide{sagf+"Roguelikes", 63, LEGAL::UNLIMITED | QUICKGEO,
"A visualization of roguelikes, based on discussion on /r/reddit. "
"See: http://www.roguetemple.com/z/hyper/reddit.php",
roguevizslide('0', [] () {
rogueviz::dftcolor = 0x282828FF;
rogueviz::showlabels = true;
part(rogueviz::default_edgetype.color, 0) = 181;
rogueviz::sag::edgepower = 1;
rogueviz::sag::edgemul = 1;
gmatrix.clear();
drawthemap();
gmatrix0 = gmatrix;
slide_backup(rogueviz::sag::legacy, true);
rogueviz::sag::read(RVPATH "roguelikes/edges.csv");
rogueviz::readcolor(RVPATH "roguelikes/color.csv");
rogueviz::sag::load_sag_solution(RVPATH "roguelikes/" + cname());
})
}
);
v.push_back(slide {sagf+"Programming languages of GitHub", 64, LEGAL::UNLIMITED | QUICKGEO,
"A visualization of programming languages.",
roguevizslide('0', [] () {
rogueviz::dftcolor = 0x282828FF;
rogueviz::showlabels = true;
part(rogueviz::default_edgetype.color, 0) = 128;
rogueviz::sag::edgepower = .4;
rogueviz::sag::edgemul = .02;
gmatrix.clear();
drawthemap();
gmatrix0 = gmatrix;
slide_backup(rogueviz::sag::legacy, true);
rogueviz::sag::read(RVPATH "lang/edges.csv");
rogueviz::readcolor(RVPATH "lang/color.csv");
rogueviz::sag::load_sag_solution(RVPATH "lang/" + cname());
if(euclid) rogueviz::legend.clear();
})
});
v.push_back(slide {sagf+"Boardgames", 62, LEGAL::UNLIMITED | QUICKGEO,
"A visualization of board games, based on discussions on Reddit.",
roguevizslide('0', [] () {
rogueviz::dftcolor = 0x282828FF;
rogueviz::showlabels = true;
part(rogueviz::default_edgetype.color, 0) = 157;
rogueviz::sag::edgepower = 1;
rogueviz::sag::edgemul = 1;
gmatrix.clear();
drawthemap();
gmatrix0 = gmatrix;
slide_backup(rogueviz::sag::legacy, true);
rogueviz::sag::read(RVPATH "boardgames/edges.csv");
rogueviz::readcolor(RVPATH "boardgames/color.csv");
rogueviz::sag::load_sag_solution(RVPATH "boardgames/" + cname());
})
});
});
EX }
}