I've been doing some research on STM (software transactional memory) implementations, specifically on algorithms that utilize locks and are not dependent on the presence of a garbage collector in order to maintain compatibility with non-managed languages like C/C++. I've read the STM chapter in Herlihy and Shavit's "The Art of Multiprocessor Programming", as well as read a couple of Shavit's papers that describe his "Transactional Locking" and "Transactional Locking II" STM implementations. Their basic approach is to utilize a hash-table that stores the values of a global version-clock and a lock to determine if a memory location has been touched by another thread's write. As I understand the algorithm, when a writing transaction is performed, the version-clock is read and stored in thread-local memory, and a read-set and write-set are also created in thread-local memory. Then the following steps are performed:
- The values of any addresses read are stored in the read-set. This means that the transaction checks that any locations being read are not locked, and they are equal to or less than the locally stored version clock value.
- The values of any addresses written are stored in the write-set, along with the values that are to be written to those locations.
- Once the entire write-transaction is complete (and this can include reading and writing to a number of locations), the transaction attempts to lock each address that is to be written to using the lock in the hash-table that is hashed against the address' value.
- When all the write-set addresses are locked, the global version clock is atomically incremented and the new incremented value is locally stored.
- The write-transaction checks again to make sure that the values in the read-set have not been updated with a new version-number or are not locked by another thread.
- The write-transaction updates the version-stamp for that memory location with the new value it stored from step #4, and commits the values in the write-set to memory
- The locks on the memory locations are released
If any of the above check-steps fail (i.e., steps #1, #3, and #5), then the write-transaction is aborted.
The process for a read-transaction is a lot simpler. According to Shavit's papers, we simply
- Read and locally store the global version-clock value
- Check to make sure the memory locations do not have a clock value greater than the currently stored global version-clock value and also make sure the memory locations are not currently locked
- Perform the read operations
- Repeat step #2 for validation
If either step #2 or #4 fail, then the read-transaction is aborted.
The question that I can't seem to solve in my mind though is what happens when you attempt to read a memory location inside an object that is located in the heap, and another thread calls
delete on a pointer to that object? In Shavit's papers, they go into detail to explain how there can be no writes to a memory location that has been recycled or freed, but it seems that inside of a read-transaction, there is nothing preventing a possible timing scenario that would allow you to read from a memory location inside of an object that is has been freed by another thread. As an example, consider the following code:
Thread A executes the following inside of an atomic read-transaction:
linked_list_node* next_node = node->next;
Thread B executes the following:
next_node is a thread-local variable, it's not a transactional object. The dereferencing operation required to assign it the value of
node->next though actually requires two separate reads. In between those reads,
delete could be called on
node, so that the read from the member
next is actually reading from a segment of memory that has already been freed. Since the reads are optimistic, the freeing of the memory pointed to by
Thread B won't be detected in
Thread A. Won't that cause a possible crash or segmentation fault? If it does, how could that be avoided without locking the memory locations for a read as well (something that both the text-book as well as the papers denotes is unnecessary)?