As part of an exercise my university has tasked me with, I have written a small Graph implementation, following this header.

class Node {

    std::string name;
    std::vector<Node*> children;

    Node(const std::string& name="");
    virtual ~Node();


When writing code for the destructor ~Node(), I noticed that my implementation fails when the graph contains a cycle. This is my implementation so far, which obviously doesn't work if the graph contains a cycle.

Node::~Node() {
    for (Node* n : children) {
        delete n;
        n = NULL;

I am uncertain as to how I would most elegantly write a destructor that can handle cycles in the graph?

Please note that I was specifically tasked to write a recursive destructor. Thank you for your answers!

  • 1
    1. Don't delete the children in ~Node. 2. Let a higher level function/class manage the destruction of all the Nodes in the graph. – R Sahu May 10 at 14:25
  • 4
    It looks like you have an ownership problem. You have shared ownership (multiple objects can have pointers to the same object, and any of them may be responsible for deleteing it) as well as potentially circular ownership. This is not a trivial problem. You should change your ownership scheme, store your Nodes in some sort of Graph object, and have only the Graph object be responsible for destroying every Node it contains. Remember to use unique_ptr instead of raw pointers (std::unique_ptr<T> vs T*) when a pointer own an object. – François Andrieux May 10 at 14:25
  • 5
    "Please note that I was specifically tasked to write a recursive destructor." A recursive destructor is a very very poor solution for this kind of problem. – François Andrieux May 10 at 14:27
  • 2
    @FrançoisAndrieux "A recursive destructor is a very very poor solution for this kind of problem" not if the problem is to teach ownership and the perils of recursive destructors. The university is a safe place to experiment with code and understand choices. You want to hit these problems now, not on your job where you have real responsibilities and real consequences. – bolov May 10 at 14:41
  • 3
    @bolov It's still a poor solution for the problem, even if it is a good example of a poor solution. And it's good that OP learns of this now, in case they wouldn't learn it in the university where poor solutions don't have real consequences. – eerorika May 10 at 14:46

Option 1: Choose a representation for the graph where nodes are not owned by other nodes, but rather the graph which would be a distinct object. This way the node destructor doesn't need to do anything. This won't satisfy the requirement of recursion:

struct Graph {
    std::vector<std::unique_ptr<Node>> nodes;

Note that if there is no inheritance involved, then you could simply use std::vector<Node>. I assume that there is, due to the usage of virtual desturctor in Node.

Alternatively, you could use another representation for the graph such as adjacency list.

Option 2: Use an algorithm to generate a minimum spanning forest of the graph. Then recursively delete the roots of each spanning tree. You can for example use the Kruskal's algorithm. (Given your representation, it looks like your graph may be connected, in which case there would be only one spaning tree).

  • Option three: collect the nodes in a linked list, in any order, disregarding graph edges entirely. Then free the list recursively. – n. 1.8e9-where's-my-share m. May 10 at 14:58
  • @n.'pronouns'm. Or perhaps collect them in a set, so that we don't need another data structure to detect the need to stop the collection in case of a cycle. Also, with a balanced BST, the recursion would actually make sense. – eerorika May 10 at 15:09
  • As far as I'm concerned, the student could use recursion to print the "done" message at the end of the program and this makes as much sense as anything else. None, that is. In order for a solution to make sense, the problem needs to make sense, and it doesn't. Disclaimer, I am not responsible for opinions of the person whose job is to grade the solution. – n. 1.8e9-where's-my-share m. May 10 at 15:19

One option could be to first create an unordered_set of all the Node*s and then to delete them.

void fill(std::unordered_set<Node*>& to_delete, Node* ptr) {
    // try to insert ptr and return if it was already in the set
    if(not to_delete.emplace(ptr).second) return;

    // swap ptr->children with an empty vector
    std::vector<Node*> tmp;
    std::swap(tmp, ptr->children);

    for(Node* c : tmp)       // loop over the pointers
        fill(to_delete, c);  // fill recursively

virtual ~Node() {
    if(children.empty()) return;          // nothing to do here

    std::unordered_set<Node*> to_delete;  // to collect all the Node*'s
    fill(to_delete, this);                // fill the set recursively
    to_delete.erase(this);                // don't delete "this"

    for(auto c : to_delete)               // delete all - they have no children by now
        delete c;


  • 1
    Sidenote: _ is commonly used as a macro for gettext, which is a very widely used library. Thus using it as a variable name can be problematic in larger programs that use such library. – eerorika May 11 at 9:38
  • @eerorika Oh, I'll replace it. I think I got struck by a bit of python when I wrote this :) Thanks. – Ted Lyngmo May 11 at 9:59
  • You can use [[maybe_unused]] to convey the same intention. – eerorika May 11 at 10:14
  • @eerorika Yeah. I went with a C++14 compatible version instead. I don't remember seeing the C++14 tag on the question when I answered - but now it's there. – Ted Lyngmo May 11 at 10:31

If your graph is a tree (I assume it since your implementation of destructor is valid only for a tree) and you can store parent of the Node then you can write iterative version which do not require any extra data structure to avoid recursion.

Also learn to use smart pointers.

class Node {

    std::string name;
    std::vector<std::unique_ptr<Node>> children;
    Node* parent;

    void safeCleanClildren();
    Node(std::string name="", Node* parent = nullptr)
        : name{std::move(name)}

    ~Node() {

    void addChild(std::string name) {
        children.emplace_back(std::make_unique<Node>(std::move(node), this);

void Node::iterativeCleanClildren()
    auto p = this;
    while (!p->children.empty()) {
        while (!p->children.empty()) {
            p = p->back().get(); // go as deep as possible
        if (p != this) {
           p = p->parent; // go back to parent

How this work?

  1. first it finds leaf (right most) in a tree (node which do not have children)
  2. Then goes back to parent node and remove child which was just found p->children.pop_back(); (this destroys unique_ptr of just found leaf).
  3. Then finds again leaf and so on.
  4. This tree clearing continues until root (this) node is reached

This way root node ends with no children at all and since it is iterative implementation overflown is impossible. It doesn't matter how much unbalance this tree is.

  • Um, how is this code supposed to work? Your inner loop will loop forever in case where the node A has only one child, B, and the node B has only one child, A. And if you prohibit creation of such loops, this code is completely redundant. – Joker_vD May 11 at 1:23
  • 1
    If you use smart pointers you could use shared_ptr, because multiple nodes seem to share ownership of their common peers/children. And once you use shared_ptr there is no need for a manual destructor, I think. – churill May 11 at 6:23
  • I've assumed that he has a tree (unique_ptr implies it) - so no cycles in graph. Naive shared_ptr is not a solution since it will lead to cycle of strong references and end with memory leak. There is nice talk from Herb Sutter about this. He shows his custom container which can handle cycles and garbage collect them. He also mentions stackoverflow issue for list and I just provided answer which handles tree scenario. – Marek R May 11 at 17:11

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