hyperrogue/rogueviz/som/voronoi.cpp

// Voronoi used to measure the quality of the embedding (Villman's measure)
// Copyright (C) 2011-2022 Tehora and Zeno Rogue, see 'hyper.cpp' for details

#include "kohonen.h"

namespace rogueviz {

namespace voronoi {

void manifold::generate_data() {
  T = isize(triangles);
  triangles_of_tile.resize(N);

  for(int i=0; i<T; i++) {
    for(auto v: triangles[i])
      triangles_of_tile[v].push_back(i);
    for(int j=0; j<3; j++) {
      int e0 = triangles[i][j%3];
      int e1 = triangles[i][(j+1)%3];
      if(e1<e0) swap(e0, e1);
      auto p = make_pair(e0, e1);
      triangles_of_edge[p].push_back(i);
      }
    }  
  }

manifold build_manifold(const vector<cell*>& cells) {
  map<cell*, int> neuron_id;
  int N = isize(cells);
  for(int i=0; i<N; i++)
    neuron_id[cells[i]] = i;
  
  set<vector<int> > faces_seen;
  
  for(auto c: cells) {
    for(int i=0; i<c->type; i++) {
      cellwalker cw1(c, i);
      cellwalker cw2 = cw1;
      vector<int> tlist;
      do {
        cw2 += wstep;
        cw2++;
        auto p = at_or_null(neuron_id, cw2.at);
        if(!p) goto next;
        tlist.push_back(*p);
        }
      while(cw2 != cw1);
      if(1) {
        int minv = 0;
        for(int i=0; i<isize(tlist); i++)
          if(tlist[i] < tlist[minv])
            minv = i;
        vector<int> tlist_sorted;
        for(int i=minv; i<isize(tlist); i++)
          tlist_sorted.push_back(tlist[i]);
        for(int i=0; i<minv; i++)
          tlist_sorted.push_back(tlist[i]);
        if(tlist_sorted[1] > tlist_sorted.back())
          reverse(tlist_sorted.begin()+1, tlist_sorted.end());
        faces_seen.insert(tlist_sorted);
        }
      next: ;
      }
    }

  manifold m;
  m.N = N;
  for(const auto& v: faces_seen)
    for(int i=2; i<isize(v); i++)
      m.triangles.emplace_back(make_array(v[0], v[i-1], v[i]));

  m.generate_data();
  return m;
  }

vector<pair<int, int> > compute_voronoi_edges(manifold& m) {

  using kohonen::net;
  using kohonen::vnorm;
  using kohonen::vshift;
  using kohonen::data;
  using kohonen::kohvec;
  using kohonen::samples;
  
  vector<int> best_tile;
  /* for every neuron, compute its best tile */
  int N = isize(net);
  for(int i=0; i<N; i++) {
    ld bestval = HUGE_VAL, best_id = -1;
    for(int j=0; j<samples; j++) {
      ld val = vnorm(net[i].net, data[j].val);
      if(val < bestval) bestval = val, best_id = j;
      }
    best_tile.push_back(best_id);
    }
  
  constexpr int SUBD = 8;
  using neuron_triangle_pair = pair<int, int>;
  set< neuron_triangle_pair > visited;
  queue<neuron_triangle_pair> q;
  
  vector<kohvec> projected(N);
  
  auto visit = [&] (neuron_triangle_pair p) {
    if(visited.count(p)) return;
    visited.insert(p);
    q.push(p);
    };
  
  kohvec at;
  kohonen::alloc(at);

  auto project = [&] (kohvec& at, const array<int, 3>& tri, int i, int j) {
    int k = SUBD-i-j;
    for(auto& x: at) x = 0;
    vshift(at, data[tri[0]].val, i * 1. / SUBD);
    vshift(at, data[tri[1]].val, j * 1. / SUBD);      
    vshift(at, data[tri[2]].val, k * 1. / SUBD);
    };
  
  set<kohvec> already_picked;
  
  map<int, string> which_best;
  
  /* project all the net[ni].net on the manifold */
  for(int ni=0; ni<N; ni++) {
    kohvec best;
    int best_tri;
    ld best_dist = HUGE_VAL;
    reaction_t better = [] {};
    set<int> triangles_to_visit;
    queue<int> triangles_queue;
    
    auto visit1 = [&] (int tri) {
      if(triangles_to_visit.count(tri)) return;
      triangles_to_visit.insert(tri);
      triangles_queue.push(tri);
      };
    
    for(int tr: m.triangles_of_tile[best_tile[ni]]) 
      visit1(tr);
    
    auto& bes = which_best[ni];
    
    while(!triangles_queue.empty()) {
      int tri = triangles_queue.front();
      triangles_queue.pop();
      
      for(int i=0; i<=SUBD; i++)
      for(int j=0; j<=SUBD-i; j++) {
        project(at, m.triangles[tri], i, j);
        ld dist = vnorm(at, net[ni].net);
        if(dist < best_dist && !already_picked.count(at)) {
          best_dist = dist, best = at, best_tri = tri;
          bes = lalign(0, tie(tri, i, j));
          better = [&tri, i, j, &m, &visit1] () {
            auto flip_edge = [&] (int t1, int t2) {
              if(t2 < t1) swap(t1, t2);
              for(auto tri1: m.triangles_of_edge[{t1, t2}])
                visit1(tri1);
              };
            auto& tria = m.triangles[tri];
            if(i == 0) flip_edge(tria[1], tria[2]);
            if(j == 0) flip_edge(tria[0], tria[2]);
            if(i+j == SUBD) flip_edge(tria[0], tria[1]);
            };
          }
        }
      
      better();
      }
    projected[ni] = best;
    already_picked.insert(best);
    visit({ni, best_tri});
    }
  
  struct triangle_data {
    double dist[SUBD+1][SUBD+1];
    int which[SUBD+1][SUBD+1];
    triangle_data() {
      for(int i=0; i<=SUBD; i++)
      for(int j=0; j<=SUBD; j++)
        dist[i][j] = HUGE_VAL, which[i][j] = -1;
      }
    };
  
  vector<triangle_data> tdatas(m.T);

  while(!q.empty()) {
    auto ntp = q.front();
    q.pop();
    auto ni = ntp.first;
    auto& tri = m.triangles[ntp.second];
    auto& td = tdatas[ntp.second];
    
    for(int i=0; i<=SUBD; i++)
    for(int j=0; j<=SUBD-i; j++) {
      project(at, tri, i, j);
      ld dist = vnorm(at, projected[ni]);
      auto& odist = td.dist[i][j];
      bool tie = abs(dist - odist) < 1e-6;
      if(tie ? ni < td.which[i][j] : dist < odist) {
        td.dist[i][j] = dist, 
        td.which[i][j] = ni;
        auto flip_edge = [&] (int t1, int t2) {
          if(t2 < t1) swap(t1, t2);
          for(auto tr: m.triangles_of_edge[{t1, t2}]) {
            visit({ni, tr});
            }
          };
        if(i == 0) flip_edge(tri[1], tri[2]);
        if(j == 0) flip_edge(tri[0], tri[2]);
        if(i+j == SUBD) flip_edge(tri[0], tri[1]);
        }
      }      
    }
  
  set<pair<int, int> > voronoi_edges;
  
  auto add_edge = [&] (int i, int j) {
    if(i>j) swap(i, j);
    if(i==j) return;
    voronoi_edges.insert({i, j});
    };

  for(auto& td: tdatas) {
    for(int i=0; i<=SUBD; i++)
    for(int j=0; j<=SUBD-i; j++) {
      if(i>0) add_edge(td.which[i][j], td.which[i-1][j]);
      if(j>0) add_edge(td.which[i][j], td.which[i][j-1]);
      if(j>0) add_edge(td.which[i][j], td.which[i+1][j-1]);
      }
    }

  if(1) {
    vector<int> degs(N, 0);
    for(auto e: voronoi_edges) degs[e.first]++, degs[e.second]++;
    for(int v=0; v<N; v++) if(degs[v] == 0) {
      fhstream vorerr("voronoi-error.txt", "at");
      println(vorerr, "error: degree 0 vertex ", v, " in ", debug_str);
      println(vorerr, "best is: ", which_best[v]);
      int id = 0;
      for(auto& td: tdatas) {
        for(int i=0; i<=SUBD; i++)
        for(int j=0; j<=SUBD-i; j++) 
          if(td.which[i][j] == v) println(vorerr, "Found at ", tie(id, i, j));
        id++;
        }
      }
    }

  vector<pair<int, int> > result;
  for(auto ve: voronoi_edges) result.push_back(ve);
  return result;  
  }

}
}
rv::som:: added our tests 2022-04-21 09:56:01 +00:00			`// Voronoi used to measure the quality of the embedding (Villman's measure)`
			`// Copyright (C) 2011-2022 Tehora and Zeno Rogue, see 'hyper.cpp' for details`

			`#include "kohonen.h"`

			`namespace rogueviz {`

			`namespace voronoi {`

			`void manifold::generate_data() {`
			`T = isize(triangles);`
			`triangles_of_tile.resize(N);`

			`for(int i=0; i<T; i++) {`
			`for(auto v: triangles[i])`
			`triangles_of_tile[v].push_back(i);`
			`for(int j=0; j<3; j++) {`
			`int e0 = triangles[i][j%3];`
			`int e1 = triangles[i][(j+1)%3];`
			`if(e1<e0) swap(e0, e1);`
			`auto p = make_pair(e0, e1);`
			`triangles_of_edge[p].push_back(i);`
			`}`
			`}`
			`}`

			`manifold build_manifold(const vector<cell*>& cells) {`
			`map<cell*, int> neuron_id;`
			`int N = isize(cells);`
			`for(int i=0; i<N; i++)`
			`neuron_id[cells[i]] = i;`

			`set<vector<int> > faces_seen;`

			`for(auto c: cells) {`
			`for(int i=0; i<c->type; i++) {`
			`cellwalker cw1(c, i);`
			`cellwalker cw2 = cw1;`
			`vector<int> tlist;`
			`do {`
			`cw2 += wstep;`
			`cw2++;`
			`auto p = at_or_null(neuron_id, cw2.at);`
			`if(!p) goto next;`
			`tlist.push_back(*p);`
			`}`
			`while(cw2 != cw1);`
			`if(1) {`
			`int minv = 0;`
			`for(int i=0; i<isize(tlist); i++)`
			`if(tlist[i] < tlist[minv])`
			`minv = i;`
			`vector<int> tlist_sorted;`
			`for(int i=minv; i<isize(tlist); i++)`
			`tlist_sorted.push_back(tlist[i]);`
			`for(int i=0; i<minv; i++)`
			`tlist_sorted.push_back(tlist[i]);`
			`if(tlist_sorted[1] > tlist_sorted.back())`
			`reverse(tlist_sorted.begin()+1, tlist_sorted.end());`
			`faces_seen.insert(tlist_sorted);`
			`}`
			`next: ;`
			`}`
			`}`

			`manifold m;`
			`m.N = N;`
			`for(const auto& v: faces_seen)`
			`for(int i=2; i<isize(v); i++)`
			`m.triangles.emplace_back(make_array(v[0], v[i-1], v[i]));`

			`m.generate_data();`
			`return m;`
			`}`

			`vector<pair<int, int> > compute_voronoi_edges(manifold& m) {`

			`using kohonen::net;`
			`using kohonen::vnorm;`
			`using kohonen::vshift;`
			`using kohonen::data;`
			`using kohonen::kohvec;`
			`using kohonen::samples;`

			`vector<int> best_tile;`
			`/* for every neuron, compute its best tile */`
			`int N = isize(net);`
			`for(int i=0; i<N; i++) {`
			`ld bestval = HUGE_VAL, best_id = -1;`
			`for(int j=0; j<samples; j++) {`
			`ld val = vnorm(net[i].net, data[j].val);`
			`if(val < bestval) bestval = val, best_id = j;`
			`}`
			`best_tile.push_back(best_id);`
			`}`

			`constexpr int SUBD = 8;`
			`using neuron_triangle_pair = pair<int, int>;`
			`set< neuron_triangle_pair > visited;`
			`queue<neuron_triangle_pair> q;`

			`vector<kohvec> projected(N);`

			`auto visit = [&] (neuron_triangle_pair p) {`
			`if(visited.count(p)) return;`
			`visited.insert(p);`
			`q.push(p);`
			`};`

			`kohvec at;`
			`kohonen::alloc(at);`

			`auto project = [&] (kohvec& at, const array<int, 3>& tri, int i, int j) {`
			`int k = SUBD-i-j;`
			`for(auto& x: at) x = 0;`
			`vshift(at, data[tri[0]].val, i * 1. / SUBD);`
			`vshift(at, data[tri[1]].val, j * 1. / SUBD);`
			`vshift(at, data[tri[2]].val, k * 1. / SUBD);`
			`};`

			`set<kohvec> already_picked;`

			`map<int, string> which_best;`

			`/* project all the net[ni].net on the manifold */`
			`for(int ni=0; ni<N; ni++) {`
			`kohvec best;`
			`int best_tri;`
			`ld best_dist = HUGE_VAL;`
			`reaction_t better = [] {};`
			`set<int> triangles_to_visit;`
			`queue<int> triangles_queue;`

			`auto visit1 = [&] (int tri) {`
			`if(triangles_to_visit.count(tri)) return;`
			`triangles_to_visit.insert(tri);`
			`triangles_queue.push(tri);`
			`};`

			`for(int tr: m.triangles_of_tile[best_tile[ni]])`
			`visit1(tr);`

			`auto& bes = which_best[ni];`

			`while(!triangles_queue.empty()) {`
			`int tri = triangles_queue.front();`
			`triangles_queue.pop();`

			`for(int i=0; i<=SUBD; i++)`
			`for(int j=0; j<=SUBD-i; j++) {`
			`project(at, m.triangles[tri], i, j);`
			`ld dist = vnorm(at, net[ni].net);`
			`if(dist < best_dist && !already_picked.count(at)) {`
			`best_dist = dist, best = at, best_tri = tri;`
			`bes = lalign(0, tie(tri, i, j));`
			`better = [&tri, i, j, &m, &visit1] () {`
			`auto flip_edge = [&] (int t1, int t2) {`
			`if(t2 < t1) swap(t1, t2);`
			`for(auto tri1: m.triangles_of_edge[{t1, t2}])`
			`visit1(tri1);`
			`};`
			`auto& tria = m.triangles[tri];`
			`if(i == 0) flip_edge(tria[1], tria[2]);`
			`if(j == 0) flip_edge(tria[0], tria[2]);`
			`if(i+j == SUBD) flip_edge(tria[0], tria[1]);`
			`};`
			`}`
			`}`

			`better();`
			`}`
			`projected[ni] = best;`
			`already_picked.insert(best);`
			`visit({ni, best_tri});`
			`}`

			`struct triangle_data {`
			`double dist[SUBD+1][SUBD+1];`
			`int which[SUBD+1][SUBD+1];`
			`triangle_data() {`
			`for(int i=0; i<=SUBD; i++)`
			`for(int j=0; j<=SUBD; j++)`
			`dist[i][j] = HUGE_VAL, which[i][j] = -1;`
			`}`
			`};`

			`vector<triangle_data> tdatas(m.T);`

			`while(!q.empty()) {`
			`auto ntp = q.front();`
			`q.pop();`
			`auto ni = ntp.first;`
			`auto& tri = m.triangles[ntp.second];`
			`auto& td = tdatas[ntp.second];`

			`for(int i=0; i<=SUBD; i++)`
			`for(int j=0; j<=SUBD-i; j++) {`
			`project(at, tri, i, j);`
			`ld dist = vnorm(at, projected[ni]);`
			`auto& odist = td.dist[i][j];`
			`bool tie = abs(dist - odist) < 1e-6;`
			`if(tie ? ni < td.which[i][j] : dist < odist) {`
			`td.dist[i][j] = dist,`
			`td.which[i][j] = ni;`
			`auto flip_edge = [&] (int t1, int t2) {`
			`if(t2 < t1) swap(t1, t2);`
			`for(auto tr: m.triangles_of_edge[{t1, t2}]) {`
			`visit({ni, tr});`
			`}`
			`};`
			`if(i == 0) flip_edge(tri[1], tri[2]);`
			`if(j == 0) flip_edge(tri[0], tri[2]);`
			`if(i+j == SUBD) flip_edge(tri[0], tri[1]);`
			`}`
			`}`
			`}`

			`set<pair<int, int> > voronoi_edges;`

			`auto add_edge = [&] (int i, int j) {`
			`if(i>j) swap(i, j);`
			`if(i==j) return;`
			`voronoi_edges.insert({i, j});`
			`};`

			`for(auto& td: tdatas) {`
			`for(int i=0; i<=SUBD; i++)`
			`for(int j=0; j<=SUBD-i; j++) {`
			`if(i>0) add_edge(td.which[i][j], td.which[i-1][j]);`
			`if(j>0) add_edge(td.which[i][j], td.which[i][j-1]);`
			`if(j>0) add_edge(td.which[i][j], td.which[i+1][j-1]);`
			`}`
			`}`

			`if(1) {`
			`vector<int> degs(N, 0);`
			`for(auto e: voronoi_edges) degs[e.first]++, degs[e.second]++;`
			`for(int v=0; v<N; v++) if(degs[v] == 0) {`
			`fhstream vorerr("voronoi-error.txt", "at");`
			`println(vorerr, "error: degree 0 vertex ", v, " in ", debug_str);`
			`println(vorerr, "best is: ", which_best[v]);`
			`int id = 0;`
			`for(auto& td: tdatas) {`
			`for(int i=0; i<=SUBD; i++)`
			`for(int j=0; j<=SUBD-i; j++)`
			`if(td.which[i][j] == v) println(vorerr, "Found at ", tie(id, i, j));`
			`id++;`
			`}`
			`}`
			`}`

			`vector<pair<int, int> > result;`
			`for(auto ve: voronoi_edges) result.push_back(ve);`
			`return result;`
			`}`

			`}`
			`}`