Directory structures are very well traversed with a recursive approach. If you look at the data type you will see that it is indeed a recursive data structure where one of the constructors, namely
Folder, can take an arbitrary long argument of the data type itself.
Looking at the directory structure as a tree will help. Let's consider
File Ints as leafs of the tree and
Folder [ FileOrFolder ] as nodes which can have an arbitrary number (including 0) of leafs (Files) and/or other nodes (folders).
│ ├── identity.hs
│ ├── madness.hs
│ ├── maybe-another-monoid.hs
│ ├── optional-monoid.hs
│ └── trivial.hs
This is a sample output of the
tree command on linux. As you can see, the main indicator that a file/folder is inside another folder is how they are indented to the right. This indentation corresponds to the root to node/leaf path's length (also called depth or level of the node). As you dive down the recursive stack with your algorithm, you can keep track on how many levels you are down to echo that in your print of the file/folder.
Also, this is pre-order depth first search traversal, since you want to print out the parent folder before the children.