I think that the key difference between structural and generative recursion is whether the recursive call is being made on data that was constructed from the original input data, or whether it was being made on a subset of the original input data. For example, if you wanted to count the number of elements in a linked list, you could do the following:

```
int NumberOfNodes(ListNode* node) {
if (node == nullptr) return 0;
return 1 + NumberOfNodes(node->next);
}
```

Here, the recursive call to `NumberOfNodes`

is being made on `node->next`

, which is a piece of the original input which already existed. In this case, the recursion works by breaking down the input into smaller pieces, then recursing on the smaller pieces.

Similarly, this code to search a BST for a value would be structural recursion, because the recursive calls are to subparts of the original input:

```
TreeNode* Find(TreeNode* root, DataType value) {
if (root == nullptr) return nullptr;
if (value < root->value) return Find(root->left, value);
else return Find(root->right, value);
```

The term "structural recursion" comes from the fact that these structures (lists, BSTs, etc.) can be defined recursively:

- A list is either nothing, or a cell followed by a list.
- A binary tree is either nothing, or a node with two binary trees as children.

When doing structural recursion, you are "undoing" the operation from which these structures are built out of one another. For example, the `NumberOfNodes`

function "undoes" the construction of taking a node and prepending it to an existing list. The `Find`

operator "undoes" the operation of gluing a node to two other trees. Therefore, it's easy to see why these functions have to terminate - eventually, you "undo" all of the operations that went in to building up the object in the first place, and the recursion stops.

On the other hand, consider Quicksort, which does the following:

- Pick a pivot.
- Create three new lists: one of all elements less than the pivot, one of all elements greater than the pivot, and one of all elements equal to the pivot.
- Recursively sort the first and second of these lists.
- Concatenate the list of smaller, equal, and larger values.

Here, the recursive calls are being made on smaller arrays that weren't part of the original input - the lists had to be created from the data. (Typically, an implementation would reuse space for these lists, but those sublists weren't guaranteed to exist directly within the input).

This distinction is blurry when it comes to natural numbers. Usually, natural numbers are recursively defined as follows:

- 0 is a natural number.
- If n is a natural number, n + 1 is a natural number.
- Nothing else is a natural number.

Under this definition, the number n is a "part" of n + 1. Therefore, this recursive code to compute n! is structural recursion:

```
int Factorial(int n) {
if (n == 0) return 1;
return n * Factorial(n - 1);
}
```

This is structural recursion, because the argument n - 1 was a "part" of the original input n.

Similarly, by this definition, computing the nth Fibonacci number recursively counts as structural recursion:

```
int Fibonacci(int n) {
if (n <= 1) return n;
return Fibonacci(n - 1) + Fibonacci(n - 2);
}
```

This is considered structural recursion because n - 1 is a part of n (formed by "undoing" the +1) and n - 2 is a part of n - 1 (again formed by "undoing" the +1).

On the other hand, this code to compute gcd would be considered generative recursion, rather than structural recursion:

```
int gcd(int a, int b) {
if (b == 0) return a;
return gcd(b, a % b);
}
```

The reasoning is that since `a % b`

is "computed" from `a`

and `b`

, rather than formed by "undoing" some number of +1 operations, the data is generated.

The reason that generative recursion is different from structural recursion is that there's no guarantee that it terminates. For example, think about this function:

```
int BadTimes(int a, int b) {
if (a == 0 && b == 0) return 0;
return BadTimes(a * 2, b - 1);
}
```

This generative recursive function never terminates: `a`

keeps getting bigger even though `b`

keeps getting smaller.

Honestly, I've never heard of this distinction before and I teach courses in discrete math and programming. I wouldn't worry too much about it unless someone is requiring you to know the difference.

Hope this helps!