From da76459dc21b5af2449af2d36eb95226cb186ce2 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sun, 28 Apr 2024 11:35:11 +0200 Subject: Adding upstream version 2.6.12. Signed-off-by: Daniel Baumann --- doc/internals/api/scheduler.txt | 226 ++++++++++++++++++++++++++++++++++++++++ 1 file changed, 226 insertions(+) create mode 100644 doc/internals/api/scheduler.txt (limited to 'doc/internals/api/scheduler.txt') diff --git a/doc/internals/api/scheduler.txt b/doc/internals/api/scheduler.txt new file mode 100644 index 0000000..3469543 --- /dev/null +++ b/doc/internals/api/scheduler.txt @@ -0,0 +1,226 @@ +2021-11-17 - Scheduler API + + +1. Background +------------- + +The scheduler relies on two major parts: + - the wait queue or timers queue, which contains an ordered tree of the next + timers to expire + + - the run queue, which contains tasks that were already woken up and are + waiting for a CPU slot to execute. + +There are two types of schedulable objects in HAProxy: + - tasks: they contain one timer and can be in the run queue without leaving + their place in the timers queue. + + - tasklets: they do not have the timers part and are either sleeping or + running. + +Both the timers queue and run queue in fact exist both shared between all +threads and per-thread. A task or tasklet may only be queued in a single of +each at a time. The thread-local queues are not thread-safe while the shared +ones are. This means that it is only permitted to manipulate an object which +is in the local queue or in a shared queue, but then after locking it. As such +tasks and tasklets are usually pinned to threads and do not move, or only in +very specific ways not detailed here. + +In case of doubt, keep in mind that it's not permitted to manipulate another +thread's private task or tasklet, and that any task held by another thread +might vanish while it's being looked at. + +Internally a large part of the task and tasklet struct is shared between +the two types, which reduces code duplication and eases the preservation +of fairness in the run queue by interleaving all of them. As such, some +fields or flags may not always be relevant to tasklets and may be ignored. + + +Tasklets do not use a thread mask but use a thread ID instead, to which they +are bound. If the thread ID is negative, the tasklet is not bound but may only +be run on the calling thread. + + +2. API +------ + +There are few functions exposed by the scheduler. A few more ones are in fact +accessible but if not documented there they'd rather be avoided or used only +when absolutely certain they're suitable, as some have delicate corner cases. +In doubt, checking the sched.pdf diagram may help. + +int total_run_queues() + Return the approximate number of tasks in run queues. This is racy + and a bit inaccurate as it iterates over all queues, but it is + sufficient for stats reporting. + +int task_in_rq(t) + Return non-zero if the designated task is in the run queue (i.e. it was + already woken up). + +int task_in_wq(t) + Return non-zero if the designated task is in the timers queue (i.e. it + has a valid timeout and will eventually expire). + +int thread_has_tasks() + Return non-zero if the current thread has some work to be done in the + run queue. This is used to decide whether or not to sleep in poll(). + +void task_wakeup(t, f) + Will make sure task will wake up, that is, will execute at least + once after the start of the function is called. The task flags will + be ORed on the task's state, among TASK_WOKEN_* flags exclusively. In + multi-threaded environments it is safe to wake up another thread's task + and even if the thread is sleeping it will be woken up. Users have to + keep in mind that a task running on another thread might very well + finish and go back to sleep before the function returns. It is + permitted to wake the current task up, in which case it will be + scheduled to run another time after it returns to the scheduler. + +struct task *task_unlink_wq(t) + Remove the task from the timers queue if it was in it, and return it. + It may only be done for the local thread, or for a shared thread that + might be in the shared queue. It must not be done for another thread's + task. + +void task_queue(t) + Place or update task into the timers queue, where it may already + be, scheduling it for an expiration at date t->expire. If t->expire is + infinite, nothing is done, so it's safe to call this function without + prior checking the expiration date. It is only valid to call this + function for local tasks or for shared tasks who have the calling + thread in their thread mask. + +void task_set_affinity(t, m) + Change task 's thread_mask to new value . This may only be + performed by the task itself while running. This is only used to let a + task voluntarily migrate to another thread. + +void tasklet_wakeup(tl) + Make sure that tasklet will wake up, that is, will execute at + least once. The tasklet will run on its assigned thread, or on any + thread if its TID is negative. + +void tasklet_wakeup_on(tl, thr) + Make sure that tasklet will wake up on thread , that is, will + execute at least once. The designated thread may only differ from the + calling one if the tasklet is already configured to run on another + thread, and it is not permitted to self-assign a tasklet if its tid is + negative, as it may already be scheduled to run somewhere else. Just in + case, only use tasklet_wakeup() which will pick the tasklet's assigned + thread ID. + +struct tasklet *tasklet_new() + Allocate a new tasklet and set it to run by default on the calling + thread. The caller may change its tid to another one before using it. + The new tasklet is returned. + +struct task *task_new_anywhere() + Allocate a new task to run on any thread, and return the task, or NULL + in case of allocation issue. Note that such tasks will be marked as + shared and will go through the locked queues, thus their activity will + be heavier than for other ones. See also task_new_here(). + +struct task *task_new_here() + Allocate a new task to run on the calling thread, and return the task, + or NULL in case of allocation issue. + +struct task *task_new_on(t) + Allocate a new task to run on thread , and return the task, or NULL + in case of allocation issue. + +void task_destroy(t) + Destroy this task. The task will be unlinked from any timers queue, + and either immediately freed, or asynchronously killed if currently + running. This may only be done by one of the threads this task is + allowed to run on. Developers must not forget that the task's memory + area is not always immediately freed, and that certain misuses could + only have effect later down the chain (e.g. use-after-free). + +void tasklet_free() + Free this tasklet, which must not be running, so that may only be + called by the thread responsible for the tasklet, typically the + tasklet's process() function itself. + +void task_schedule(t, d) + Schedule task to run no later than date . If the task is already + running, or scheduled for an earlier instant, nothing is done. If the + task was not in queued or was scheduled to run later, its timer entry + will be updated. This function assumes that it will never be called + with a timer in the past nor with TICK_ETERNITY. Only one of the + threads assigned to the task may call this function. + +The task's ->process() function receives the following arguments: + + - struct task *t: a pointer to the task itself. It is always valid. + + - void *ctx : a copy of the task's ->context pointer at the moment + the ->process() function was called by the scheduler. A + function must use this and not task->context, because + task->context might possibly be changed by another thread. + For instance, the muxes' takeover() function do this. + + - uint state : a copy of the task's ->state field at the moment the + ->process() function was executed. A function must use + this and not task->state as the latter misses the wakeup + reasons and may constantly change during execution along + concurrent wakeups (threads or signals). + +The possible state flags to use during a call to task_wakeup() or seen by the +task being called are the following; they're automatically cleaned from the +state field before the call to ->process() + + - TASK_WOKEN_INIT each creation of a task causes a first wakeup with this + flag set. Applications should not set it themselves. + + - TASK_WOKEN_TIMER this indicates the task's expire date was reached in the + timers queue. Applications should not set it themselves. + + - TASK_WOKEN_IO indicates the wake-up happened due to I/O activity. Now + that all low-level I/O processing happens on tasklets, + this notion of I/O is now application-defined (for + example stream-interfaces use it to notify the stream). + + - TASK_WOKEN_SIGNAL indicates that a signal the task was subscribed to was + received. Applications should not set it themselves. + + - TASK_WOKEN_MSG any application-defined wake-up reason, usually for + inter-task communication (e.g filters vs streams). + + - TASK_WOKEN_RES a resource the task was waiting for was finally made + available, allowing the task to continue its work. This + is essentially used by buffers and queues. Applications + may carefully use it for their own purpose if they're + certain not to rely on existing ones. + + - TASK_WOKEN_OTHER any other application-defined wake-up reason. + + +In addition, a few persistent flags may be observed or manipulated by the +application, both for tasks and tasklets: + + - TASK_SELF_WAKING when set, indicates that this task was found waking + itself up, and its class will change to bulk processing. + If this behavior is under control temporarily expected, + and it is not expected to happen again, it may make + sense to reset this flag from the ->process() function + itself. + + - TASK_HEAVY when set, indicates that this task does so heavy + processing that it will become mandatory to give back + control to I/Os otherwise big latencies might occur. It + may be set by an application that expects something + heavy to happen (tens to hundreds of microseconds), and + reset once finished. An example of user is the TLS stack + which sets it when an imminent crypto operation is + expected. + + - TASK_F_USR1 This is the first application-defined persistent flag. + It is always zero unless the application changes it. An + example of use cases is the I/O handler for backend + connections, to mention whether the connection is safe + to use or might have recently been migrated. + +Finally, when built with -DDEBUG_TASK, an extra sub-structure "debug" is added +to both tasks and tasklets to note the code locations of the last two calls to +task_wakeup() and tasklet_wakeup(). -- cgit v1.2.3