sclass WebNode {
  Web web;
  new L<Lisp> labels;
  
  *() {}
  *(Web *web) { web.fireNewNode(this); }
  
  void addLabel(S label) { addLabel(web.parseLabel(label)); }
  
  void addLabel(Lisp label) {
    if (setAdd(labels, label) && web != null) {
      web.index(label, this);
      ++web.size;
    }
  }
  
  bool hasLabel(Lisp label) { ret labels.contains(label); }
  bool hasLabel(S label) { ret labels.contains(web.parseLabel(label)); }
  
  toString { ret str(labels); }
  
  int count() { ret 1 + l(labels); }
}


sclass Web {
  new L<WebNode> nodes; // Relations are also nodes
  Map<Pair<WebNode>, WebNode> relations = new HashMap;
  new MultiMap<Lisp, WebNode> index; // label -> node
  Map<S, L<WebNode>> pots = new Map;
  transient Lock lock = reentrantLock(true);
  int size;
  bool useCLParse = true;
  static new L onNewNode; // L<voidfunc(WebNode)>
  static new L onNewLabel; // L<voidfunc(WebNode, Lisp)>
  
  bool potNotEmpty(S pot) { ret nempty(getPot(pot)); }
  
  L<WebNode> clearPot(S pot) {
    L<WebNode> l = getPot(pot);
    L<WebNode> l2 = cloneList(l);
    l.clear();
    ret l2;
  }
  
  L<WebNode> getPot(S pot) {
    L<WebNode> l = pots.get(pot);
    if (l == null)
      pots.put(pot, l = cloneList(nodes));
    ret l;
  }
  
  void relation(S a, S arrow, S b) {
    relation(lisp(arrow, a, b));
  }
  
  void relation(Lisp l) {
    if (l(l) == 1) {
      findNode(l.get(0)).addLabel(lisp("wvuyakuvuelmxpwp", l.head));
    } else if (l(l) == 2) {
      S a = lisp2label(l.get(0)), b = lisp2label(l.get(1));
      if (l.is("fgvvrzypbkqomktd")) { // X is Y.
        findNode(a).addLabel(b);
        findNode(b).addLabel(a);
      }
      getRelation(a, b).addLabel(l.head);
    }
  }
  
  void relations(L<Lisp> l) {
    for (Lisp li : l) relation(li);
  }
  
  WebNode getRelation(S a, S b) {
    ret getRelation(findNode(a), findNode(b));
  }
  
  WebNode getRelation(WebNode a, WebNode b) {
    Pair<WebNode> p = pair(a, b);
    WebNode r = relations.get(p);
    if (r == null) relations.put(p, r = newNode());
    ret r;
  }
  
  WebNode newNode() {
    WebNode node = new WebNode(this);
    nodes.add(node); ++size;
    for (L<WebNode> l : values(pots)) l.add(node);
    ret node;
  }
  
  WebNode node(S s) { ret findNode(s); }
  WebNode node(Lisp l) { ret findNode(l); }
  
  WebNode findNode(S s) {
    ret findNode(parseLabel(s));
  }
  
  WebNode findNode(Lisp l) {
    WebNode n = findNodeOpt(l);
    ret n != null ? n : newNode(l);
  }
  
  WebNode findNodeOpt(Lisp l) {
    ret first(index.get(l));
    /*for (WebNode n : nodes)
      if (n.labels.contains(l))
        ret n;
    null;*/
  }
  
  WebNode newNode(S... labels) {
    WebNode n = newNode();
    for (S label : labels) n.addLabel(label);
    ret n;
  }
  
  WebNode newNode(Lisp... labels) {
    WebNode n = newNode();
    for (Lisp label : labels) n.addLabel(label);
    ret n;
  }
  
  toString { ret webToString(this); }
  
  int count() {
    ret size;
    /*int count = 0;
    for (WebNode n : nodes) count += n.count();
    for (WebNode n : values(relations)) count += n.count();
    ret count;*/
  }
  
  void index(Lisp label, WebNode n) {
    index.put(label, n);
    fireNewLabel(n, label);
  }
  
  void clear {
    size = 0;
    clearAll(nodes, relations, index, pots);
  }
  
  Lisp parseLabel(S s) {
    ret useCLParse ? clParse(s) : lisp(s);
  }
  
  void fireNewNode(WebNode node) { for (O f : onNewNode) pcallF(f, node); }
  void fireNewLabel(WebNode node, Lisp label) { for (O f : onNewLabel) pcallF(f, node, label); }
}