My feeling is that your question is not really only about locking but also (or rather) about cooperative editing that isn't a problem that can be solved with a single answer. Cooperative editing is so complex that one could write books about it. Depending on what are the requirements of your coop editing sessions and how is the data structured and how loose/strict constrains/rules/relations you have between different nodes of your data there can be many-many solutions none of which is perfect but having their own pros and cons.
I've recently been working (and sometimes still working) on a cooperative editing tool so I have a clue about how complex the problem is but don't expect a clear answer to your vague question because you won't get one. It's impossible to give you a good answer because as I previously mentioned it is often impossible to provide a good answer even to a clearly specified coop editing problem because every solution has some kind of tradeoff and you have to decide which solution has desirable pros and acceptable cons for you. For example your client may prefer good user interface response time with "fluid" sessions as if he was working alone with a single desktop app at the cost of sometimes rolling back its work because of a conflict that was found out a bit later as the result of hiding network latency, but another client may prefer the other way: always commiting/validating data after every change even if it takes time and pays with worse user experience/slower work for this.
Hierarchical data? Its always a big problem how to protect your data with locks against concurrent access. The big problem here is that you have to define what "consistency" means in case of your data. Lets say someone wants to write a small unit, a "node" in your data and you have to validate the data before actually committing it. You have to lock not only the node that is about to change but all other nodes that are needed in order to check whether the newly written data is consistent with the content of the other nodes according to your rules. For this very simple reason your editing session becomes much more effective with less locks if you have less relations between the nodes, less restrictive consistency rules. Try to make the rules as loose as possible.
Here are some random tips how to make your life easier:
- Less consistency rules, more loosly coupled data is easier to coop-edit. Try to create relations only between nodes that are near to each other but the best is if you can restrict consistency rules to work only within single nodes. Its also you who defines what is a "node", organize the data into the right data structures.
- Give all nodes a unique id, or in case of internet-edited data, a globally unique id. This has so many benefits...
- Sometimes a tree isn't really a tree. :-) At least in memory. If all tree nodes have a unique id then you can treat/handle a tree as a list of nodes that refer to each other with unique ids. Often when it comes to editing/diffing/merging/conflict-handling it is much easier to handle a list of nodes than a hierarchical data structure. Not to mention that if your user deletes a node and there are other nodes that refer to the deleted node you can still keep the invalid references in the other nodes and if the user "undeletes" / undoes his delete operation then the references that you havent deleted become valid again and its very easy to handle undo/redo functionality with ids.
- Cooperative editing has a lot to do with undo/redo buffers. Undo/redo buffers contain basically a series of the following 3 operations:
- Creating a new node with a new ID with default property values.
- Modifying the properties of an existing node. (Note that references to other nodes can practically be treated as properties that have unique id type so you can treat inter-node connection creation/deletion as a property change).
- Deleting a node.
- Note that network communication between your clients and the servers (or between the peers in case of peer-to-peer) often consists of the same operations that you save into your undo/redo buffer.
- As I said you can work with less locks if you have less strict consistency rules. Its better to restrict consistency rules to smaller areas of your node network as usually each consistency rule has an accompanying lock. If your consistency rules spread to the whole tree then you either have too strict rules that will prevent you from efficiently edit it concurrently from many threads or you have organized your data structure poorly, or both.
- In case of having multiple locks over a large data structure (common scenario in all database softwares) you have to define your data structure and consistency rules well to have the least number of conflicts between clients when editing but aside from this there will be scenarios when an operation has to acquire many locks before you can start using different parts of your database in order to perform an operations. If you have several threads that need many locks then it can easily turn into a deadlock. Its enough to have only 2 locks A and B and 2 threads that need both of these locks: T1 and T2. If T1 tries to acquire the lock A and then B while T2 tries to acquire the lock int he reverse order: B and A then it can easily turn in to a deadlock because if T1 successfully acquires A and T2 successfully acquires B at the same time then neither threads will be able to acquire the second lock. There is a very simple solution to this problem: Put the locks into groups and each groups should contain locks that may be acquired together by any threads at the same time. If T1 needs locks A and B while T2 needs B and C then A,B and C go to the same group. When you are done define a locking order in all groups and acquire the locks always in this order. This helps avoiding the deadlocks.
In case of a tree if you have strict consistency rules then you may want to lock whole subtrees, sometimes only just smaller subtrees. Here is a naive solution: You put a lock on every node. If you want to lock a subtree then you have to lock every node in that subtree before you start working with the data. Define the order of the nodes/locks for example as the inorder traversal of the tree. When you want to lock a subtree you just traverse it with inorder traversal and you acquire each lock one-by-one.
As I told you there are many algorithms/methods for cooperative editing, its a hot topic you can use google to find them but I would mention you one algorithm that I love. Its a very simple yet terribly effective algorithm. It does wonders when your data is loosely coupled (when you lock only single nodes or small units of data while editing): https://neil.fraser.name/writing/sync/
EDIT: I just forgot something: In cooperative editing you have to handle conflicts, when the "players" (:-)) modify the same objects "at the same" time. The most basic solutions fall into these two categories and there are several "grey"/intermediate solutions between these black and white solutions:
- When user A starts editing a set of nodes then user A locks all of these objects and others can not modify them while user A holds the lock.
- When both user A and user B modifies the same nodes/properties then the modification of one of these users "wins" because the server or your networking engine will perform these changes sequentially. How to handle the conflict in case of the user whose change couldn't be committed? Good question, you can provide a textual/visual merge tool, you can simply drop the changes automatically (the algorithm I linked does this).
I think that you already have a better grasp of what I'm talking about and that you can create endless number of combinations as solution to an editing problem even from what I've described here. In case of an editing program its also very important to give the users ways to communicate/cooperate with each other. This communication can be chat, but I like visual feedback more. For example in case of a cooperative document editor you could visually show the locations where others are viewing/editing, in case of a 3d world editor you can show other user's selection/locked regions and the location of their camera. Visual feedback is more easily processed by the brain and its more intuitive to use with very short learning curve.