Serializing tokens

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In computer science, serializing tokens are a concept in concurrency control arising from the ongoing development of DragonFly BSD. According to Matthew Dillon, they are most akin to SPLs, except a token works across multiple CPUs while SPLs only work within a single CPU's domain.

Serializing tokens allow programmers to write multiprocessor-safe code without themselves or the lower level subsystems needing to be aware of every single entity that may also be holding the same token.

Comparison with mutual exclusion (mutex)

Tokens and mutual exclusion (mutex) mechanisms are locks. Unlike mutexes, tokens do not exclude other threads from accessing the resource while they are blocked or asleep. A thread sharing resources with other threads can be stopped and started for a variety of reasons:

  1. Timeslicing: the user space (US) scheduler tries to ensure that all threads get a fair chance to run, so it runs each thread for a brief period of time (a timeslice) and then switches to another thread.
  2. Concurrent execution: in multiprocessor computers, a thread may be run at exactly the same time as another thread on a different CPU.
  3. Preemption: a thread may preempt a lower-priority thread, such as a hardware interrupt or Light Weight Kernel Threads.
  4. Voluntary blocking: a thread may sleep if it has to wait for something, has no work to do, or calls a function that blocks. Even the call to acquire a lock can block.

The following table summarizes the properties of tokens and mutexes.

Serializing Tokens vs Mutexes
  Serializing tokens Mutexes
Timeslicing Works Works
Concurrent execution Works Works
Preemption Works Works
Voluntary blocking Fails Works
Avoids deadlock Yes No
Avoids priority inversion Yes No

Issues such as deadlock and priority inversion can be very difficult to avoid, and require coordination at many levels of the kernel. Because locking with tokens does not deadlock and acquired tokens need not be atomic when later operations block, it allow much simpler code than mutexes.


Example

The following pseudocode and explanations illustrate how serializing tokens work.

Example PseudoCode using serializing tokens
Thread A Thread B Action
lwkt_gettoken(T1);
iter = list1.head;
...
lwkt_gettoken(T1); // blocks
// waiting for token T1
A acquires token T1 and uses it to get synchronized access to list1, which is shared by both threads.
lwkt_gettoken(T2); // blocks
// waiting for token T1
A's call to lwkt_gettoken(T2) is a blocking function, so A goes to sleep and temporarily loses its tokens. It will be awakened when the scheduler sees that both T1 and T2 are available.
// waiting for T1 and T2
list1.head = list1.head.next;
lwkt_releasetoken(T1);
B acquires T1 and modifies list1. Note that A's "iter" still points to the old head of the list.
// get the new version of the head:
iter = list1.head; 
// make new list:
while (iter != null) {
    list2.tail = iter;
    iter = iter.next;
}
lwkt_releasetoken(T1);
lwkt_releasetoken(T2);
  The scheduler sees that both T1 and T2 are available, so it wakes up thread A. Since A was coded correctly, it refreshes its iterator with the new head of list1, and does some nonblocking operations on it. Note that it would have been better form for A to simply ask for both tokens at the start.

Prior art in the Darwin kernel

Mac OS X's Darwin kernel uses a similar technique (called a funnel) to serialize access to the BSD portion of the kernel.

See also

  • Lock-free and wait-free algorithms

References