Now, each proxy contains a lock that must be used when necessary to protect
it. Moreover, all proxy's counters are now updated using atomic operations.
First, we use atomic operations to update jobs/totalconn/actconn variables,
listener's nbconn variable and listener's counters. Then we add a lock on
listeners to protect access to their information. And finally, listener queues
(global and per proxy) are also protected by a lock. Here, because access to
these queues are unusal, we use the same lock for all queues instead of a global
one for the global queue and a lock per proxy for others.
2 global locks have been added to protect, respectively, the run queue and the
wait queue. And a process mask has been added on each task. Like for FDs, this
mask is used to know which threads are allowed to process a task.
For many tasks, all threads are granted. And this must be your first intension
when you create a new task, else you have a good reason to make a task sticky on
some threads. This is then the responsibility to the process callback to lock
what have to be locked in the task context.
Nevertheless, all tasks linked to a session must be sticky on the thread
creating the session. It is important that I/O handlers processing session FDs
and these tasks run on the same thread to avoid conflicts.
Many changes have been made to do so. First, the fd_updt array, where all
pending FDs for polling are stored, is now a thread-local array. Then 3 locks
have been added to protect, respectively, the fdtab array, the fd_cache array
and poll information. In addition, a lock for each entry in the fdtab array has
been added to protect all accesses to a specific FD or its information.
For pollers, according to the poller, the way to manage the concurrency is
different. There is a poller loop on each thread. So the set of monitored FDs
may need to be protected. epoll and kqueue are thread-safe per-se, so there few
things to do to protect these pollers. This is not possible with select and
poll, so there is no sharing between the threads. The poller on each thread is
independant from others.
Finally, per-thread init/deinit functions are used for each pollers and for FD
part for manage thread-local ressources.
Now, you must be carefull when a FD is created during the HAProxy startup. All
update on the FD state must be made in the threads context and never before
their creation. This is mandatory because fd_updt array is thread-local and
initialized only for threads. Because there is no pollers for the main one, this
array remains uninitialized in this context. For this reason, listeners are now
enabled in run_thread_poll_loop function, just like the worker pipe.
A sync-point is a protected area where you have the warranty that no concurrency
access is possible. It is implementated as a thread barrier to enter in the
sync-point and another one to exit from it. Inside the sync-point, all threads
that must do some syncrhonous processing will be called one after the other
while all other threads will wait. All threads will then exit from the
sync-point at the same time.
A sync-point will be evaluated only when necessary because it is a costly
operation. To limit the waiting time of each threads, we must have a mechanism
to wakeup all threads. This is done with a pipe shared by all threads. By
writting in this pipe, we will interrupt all threads blocked on a poller. The
pipe is then flushed before exiting from the sync-point.
This file contains all functions and macros used to deal with concurrency in
HAProxy. It contains all high-level function to do atomic operation
(HA_ATOMIC_*). Note, for now, we rely on "__atomic" GCC builtins to do atomic
operation. So HAProxy can be compiled with the thread support iff these builtins
are available.
It also contains wrappers around plocks to use spin or read/write locks. These
wrappers are used to abstract the internal representation of the locking system
and to add information to help debugging, when compiled with suitable
options.
To add extra info on locks, you need to add DEBUG=-DDEBUG_THREAD or
DEBUG=-DDEBUG_FULL compilation option. In addition to timing info on locks, we
keep info on where a lock was acquired the last time (function name, file and
line). There are also the thread id and a flag to know if it is still locked or
not. This will be useful to debug deadlocks.
