| ======================== |
| Deadline Task Scheduling |
| ======================== |
| |
| .. CONTENTS |
| |
| 0. WARNING |
| 1. Overview |
| 2. Scheduling algorithm |
| 2.1 Main algorithm |
| 2.2 Bandwidth reclaiming |
| 3. Scheduling Real-Time Tasks |
| 3.1 Definitions |
| 3.2 Schedulability Analysis for Uniprocessor Systems |
| 3.3 Schedulability Analysis for Multiprocessor Systems |
| 3.4 Relationship with SCHED_DEADLINE Parameters |
| 4. Bandwidth management |
| 4.1 System-wide settings |
| 4.2 Task interface |
| 4.3 Default behavior |
| 4.4 Behavior of sched_yield() |
| 5. Tasks CPU affinity |
| 5.1 SCHED_DEADLINE and cpusets HOWTO |
| 6. Future plans |
| A. Test suite |
| B. Minimal main() |
| |
| |
| 0. WARNING |
| ========== |
| |
| Fiddling with these settings can result in an unpredictable or even unstable |
| system behavior. As for -rt (group) scheduling, it is assumed that root users |
| know what they're doing. |
| |
| |
| 1. Overview |
| =========== |
| |
| The SCHED_DEADLINE policy contained inside the sched_dl scheduling class is |
| basically an implementation of the Earliest Deadline First (EDF) scheduling |
| algorithm, augmented with a mechanism (called Constant Bandwidth Server, CBS) |
| that makes it possible to isolate the behavior of tasks between each other. |
| |
| |
| 2. Scheduling algorithm |
| ======================= |
| |
| 2.1 Main algorithm |
| ------------------ |
| |
| SCHED_DEADLINE [18] uses three parameters, named "runtime", "period", and |
| "deadline", to schedule tasks. A SCHED_DEADLINE task should receive |
| "runtime" microseconds of execution time every "period" microseconds, and |
| these "runtime" microseconds are available within "deadline" microseconds |
| from the beginning of the period. In order to implement this behavior, |
| every time the task wakes up, the scheduler computes a "scheduling deadline" |
| consistent with the guarantee (using the CBS[2,3] algorithm). Tasks are then |
| scheduled using EDF[1] on these scheduling deadlines (the task with the |
| earliest scheduling deadline is selected for execution). Notice that the |
| task actually receives "runtime" time units within "deadline" if a proper |
| "admission control" strategy (see Section "4. Bandwidth management") is used |
| (clearly, if the system is overloaded this guarantee cannot be respected). |
| |
| Summing up, the CBS[2,3] algorithm assigns scheduling deadlines to tasks so |
| that each task runs for at most its runtime every period, avoiding any |
| interference between different tasks (bandwidth isolation), while the EDF[1] |
| algorithm selects the task with the earliest scheduling deadline as the one |
| to be executed next. Thanks to this feature, tasks that do not strictly comply |
| with the "traditional" real-time task model (see Section 3) can effectively |
| use the new policy. |
| |
| In more details, the CBS algorithm assigns scheduling deadlines to |
| tasks in the following way: |
| |
| - Each SCHED_DEADLINE task is characterized by the "runtime", |
| "deadline", and "period" parameters; |
| |
| - The state of the task is described by a "scheduling deadline", and |
| a "remaining runtime". These two parameters are initially set to 0; |
| |
| - When a SCHED_DEADLINE task wakes up (becomes ready for execution), |
| the scheduler checks if:: |
| |
| remaining runtime runtime |
| ---------------------------------- > --------- |
| scheduling deadline - current time period |
| |
| then, if the scheduling deadline is smaller than the current time, or |
| this condition is verified, the scheduling deadline and the |
| remaining runtime are re-initialized as |
| |
| scheduling deadline = current time + deadline |
| remaining runtime = runtime |
| |
| otherwise, the scheduling deadline and the remaining runtime are |
| left unchanged; |
| |
| - When a SCHED_DEADLINE task executes for an amount of time t, its |
| remaining runtime is decreased as:: |
| |
| remaining runtime = remaining runtime - t |
| |
| (technically, the runtime is decreased at every tick, or when the |
| task is descheduled / preempted); |
| |
| - When the remaining runtime becomes less or equal than 0, the task is |
| said to be "throttled" (also known as "depleted" in real-time literature) |
| and cannot be scheduled until its scheduling deadline. The "replenishment |
| time" for this task (see next item) is set to be equal to the current |
| value of the scheduling deadline; |
| |
| - When the current time is equal to the replenishment time of a |
| throttled task, the scheduling deadline and the remaining runtime are |
| updated as:: |
| |
| scheduling deadline = scheduling deadline + period |
| remaining runtime = remaining runtime + runtime |
| |
| The SCHED_FLAG_DL_OVERRUN flag in sched_attr's sched_flags field allows a task |
| to get informed about runtime overruns through the delivery of SIGXCPU |
| signals. |
| |
| |
| 2.2 Bandwidth reclaiming |
| ------------------------ |
| |
| Bandwidth reclaiming for deadline tasks is based on the GRUB (Greedy |
| Reclamation of Unused Bandwidth) algorithm [15, 16, 17] and it is enabled |
| when flag SCHED_FLAG_RECLAIM is set. |
| |
| The following diagram illustrates the state names for tasks handled by GRUB:: |
| |
| ------------ |
| (d) | Active | |
| ------------->| | |
| | | Contending | |
| | ------------ |
| | A | |
| ---------- | | |
| | | | | |
| | Inactive | |(b) | (a) |
| | | | | |
| ---------- | | |
| A | V |
| | ------------ |
| | | Active | |
| --------------| Non | |
| (c) | Contending | |
| ------------ |
| |
| A task can be in one of the following states: |
| |
| - ActiveContending: if it is ready for execution (or executing); |
| |
| - ActiveNonContending: if it just blocked and has not yet surpassed the 0-lag |
| time; |
| |
| - Inactive: if it is blocked and has surpassed the 0-lag time. |
| |
| State transitions: |
| |
| (a) When a task blocks, it does not become immediately inactive since its |
| bandwidth cannot be immediately reclaimed without breaking the |
| real-time guarantees. It therefore enters a transitional state called |
| ActiveNonContending. The scheduler arms the "inactive timer" to fire at |
| the 0-lag time, when the task's bandwidth can be reclaimed without |
| breaking the real-time guarantees. |
| |
| The 0-lag time for a task entering the ActiveNonContending state is |
| computed as:: |
| |
| (runtime * dl_period) |
| deadline - --------------------- |
| dl_runtime |
| |
| where runtime is the remaining runtime, while dl_runtime and dl_period |
| are the reservation parameters. |
| |
| (b) If the task wakes up before the inactive timer fires, the task re-enters |
| the ActiveContending state and the "inactive timer" is canceled. |
| In addition, if the task wakes up on a different runqueue, then |
| the task's utilization must be removed from the previous runqueue's active |
| utilization and must be added to the new runqueue's active utilization. |
| In order to avoid races between a task waking up on a runqueue while the |
| "inactive timer" is running on a different CPU, the "dl_non_contending" |
| flag is used to indicate that a task is not on a runqueue but is active |
| (so, the flag is set when the task blocks and is cleared when the |
| "inactive timer" fires or when the task wakes up). |
| |
| (c) When the "inactive timer" fires, the task enters the Inactive state and |
| its utilization is removed from the runqueue's active utilization. |
| |
| (d) When an inactive task wakes up, it enters the ActiveContending state and |
| its utilization is added to the active utilization of the runqueue where |
| it has been enqueued. |
| |
| For each runqueue, the algorithm GRUB keeps track of two different bandwidths: |
| |
| - Active bandwidth (running_bw): this is the sum of the bandwidths of all |
| tasks in active state (i.e., ActiveContending or ActiveNonContending); |
| |
| - Total bandwidth (this_bw): this is the sum of all tasks "belonging" to the |
| runqueue, including the tasks in Inactive state. |
| |
| - Maximum usable bandwidth (max_bw): This is the maximum bandwidth usable by |
| deadline tasks and is currently set to the RT capacity. |
| |
| |
| The algorithm reclaims the bandwidth of the tasks in Inactive state. |
| It does so by decrementing the runtime of the executing task Ti at a pace equal |
| to |
| |
| dq = -(max{ Ui, (Umax - Uinact - Uextra) } / Umax) dt |
| |
| where: |
| |
| - Ui is the bandwidth of task Ti; |
| - Umax is the maximum reclaimable utilization (subjected to RT throttling |
| limits); |
| - Uinact is the (per runqueue) inactive utilization, computed as |
| (this_bq - running_bw); |
| - Uextra is the (per runqueue) extra reclaimable utilization |
| (subjected to RT throttling limits). |
| |
| |
| Let's now see a trivial example of two deadline tasks with runtime equal |
| to 4 and period equal to 8 (i.e., bandwidth equal to 0.5):: |
| |
| A Task T1 |
| | |
| | | |
| | | |
| |-------- |---- |
| | | V |
| |---|---|---|---|---|---|---|---|--------->t |
| 0 1 2 3 4 5 6 7 8 |
| |
| |
| A Task T2 |
| | |
| | | |
| | | |
| | ------------------------| |
| | | V |
| |---|---|---|---|---|---|---|---|--------->t |
| 0 1 2 3 4 5 6 7 8 |
| |
| |
| A running_bw |
| | |
| 1 ----------------- ------ |
| | | | |
| 0.5- ----------------- |
| | | |
| |---|---|---|---|---|---|---|---|--------->t |
| 0 1 2 3 4 5 6 7 8 |
| |
| |
| - Time t = 0: |
| |
| Both tasks are ready for execution and therefore in ActiveContending state. |
| Suppose Task T1 is the first task to start execution. |
| Since there are no inactive tasks, its runtime is decreased as dq = -1 dt. |
| |
| - Time t = 2: |
| |
| Suppose that task T1 blocks |
| Task T1 therefore enters the ActiveNonContending state. Since its remaining |
| runtime is equal to 2, its 0-lag time is equal to t = 4. |
| Task T2 start execution, with runtime still decreased as dq = -1 dt since |
| there are no inactive tasks. |
| |
| - Time t = 4: |
| |
| This is the 0-lag time for Task T1. Since it didn't woken up in the |
| meantime, it enters the Inactive state. Its bandwidth is removed from |
| running_bw. |
| Task T2 continues its execution. However, its runtime is now decreased as |
| dq = - 0.5 dt because Uinact = 0.5. |
| Task T2 therefore reclaims the bandwidth unused by Task T1. |
| |
| - Time t = 8: |
| |
| Task T1 wakes up. It enters the ActiveContending state again, and the |
| running_bw is incremented. |
| |
| |
| 2.3 Energy-aware scheduling |
| --------------------------- |
| |
| When cpufreq's schedutil governor is selected, SCHED_DEADLINE implements the |
| GRUB-PA [19] algorithm, reducing the CPU operating frequency to the minimum |
| value that still allows to meet the deadlines. This behavior is currently |
| implemented only for ARM architectures. |
| |
| A particular care must be taken in case the time needed for changing frequency |
| is of the same order of magnitude of the reservation period. In such cases, |
| setting a fixed CPU frequency results in a lower amount of deadline misses. |
| |
| |
| 3. Scheduling Real-Time Tasks |
| ============================= |
| |
| |
| |
| .. BIG FAT WARNING ****************************************************** |
| |
| .. warning:: |
| |
| This section contains a (not-thorough) summary on classical deadline |
| scheduling theory, and how it applies to SCHED_DEADLINE. |
| The reader can "safely" skip to Section 4 if only interested in seeing |
| how the scheduling policy can be used. Anyway, we strongly recommend |
| to come back here and continue reading (once the urge for testing is |
| satisfied :P) to be sure of fully understanding all technical details. |
| |
| .. ************************************************************************ |
| |
| There are no limitations on what kind of task can exploit this new |
| scheduling discipline, even if it must be said that it is particularly |
| suited for periodic or sporadic real-time tasks that need guarantees on their |
| timing behavior, e.g., multimedia, streaming, control applications, etc. |
| |
| 3.1 Definitions |
| ------------------------ |
| |
| A typical real-time task is composed of a repetition of computation phases |
| (task instances, or jobs) which are activated on a periodic or sporadic |
| fashion. |
| Each job J_j (where J_j is the j^th job of the task) is characterized by an |
| arrival time r_j (the time when the job starts), an amount of computation |
| time c_j needed to finish the job, and a job absolute deadline d_j, which |
| is the time within which the job should be finished. The maximum execution |
| time max{c_j} is called "Worst Case Execution Time" (WCET) for the task. |
| A real-time task can be periodic with period P if r_{j+1} = r_j + P, or |
| sporadic with minimum inter-arrival time P is r_{j+1} >= r_j + P. Finally, |
| d_j = r_j + D, where D is the task's relative deadline. |
| Summing up, a real-time task can be described as |
| |
| Task = (WCET, D, P) |
| |
| The utilization of a real-time task is defined as the ratio between its |
| WCET and its period (or minimum inter-arrival time), and represents |
| the fraction of CPU time needed to execute the task. |
| |
| If the total utilization U=sum(WCET_i/P_i) is larger than M (with M equal |
| to the number of CPUs), then the scheduler is unable to respect all the |
| deadlines. |
| Note that total utilization is defined as the sum of the utilizations |
| WCET_i/P_i over all the real-time tasks in the system. When considering |
| multiple real-time tasks, the parameters of the i-th task are indicated |
| with the "_i" suffix. |
| Moreover, if the total utilization is larger than M, then we risk starving |
| non- real-time tasks by real-time tasks. |
| If, instead, the total utilization is smaller than M, then non real-time |
| tasks will not be starved and the system might be able to respect all the |
| deadlines. |
| As a matter of fact, in this case it is possible to provide an upper bound |
| for tardiness (defined as the maximum between 0 and the difference |
| between the finishing time of a job and its absolute deadline). |
| More precisely, it can be proven that using a global EDF scheduler the |
| maximum tardiness of each task is smaller or equal than |
| |
| ((M − 1) · WCET_max − WCET_min)/(M − (M − 2) · U_max) + WCET_max |
| |
| where WCET_max = max{WCET_i} is the maximum WCET, WCET_min=min{WCET_i} |
| is the minimum WCET, and U_max = max{WCET_i/P_i} is the maximum |
| utilization[12]. |
| |
| 3.2 Schedulability Analysis for Uniprocessor Systems |
| ---------------------------------------------------- |
| |
| If M=1 (uniprocessor system), or in case of partitioned scheduling (each |
| real-time task is statically assigned to one and only one CPU), it is |
| possible to formally check if all the deadlines are respected. |
| If D_i = P_i for all tasks, then EDF is able to respect all the deadlines |
| of all the tasks executing on a CPU if and only if the total utilization |
| of the tasks running on such a CPU is smaller or equal than 1. |
| If D_i != P_i for some task, then it is possible to define the density of |
| a task as WCET_i/min{D_i,P_i}, and EDF is able to respect all the deadlines |
| of all the tasks running on a CPU if the sum of the densities of the tasks |
| running on such a CPU is smaller or equal than 1: |
| |
| sum(WCET_i / min{D_i, P_i}) <= 1 |
| |
| It is important to notice that this condition is only sufficient, and not |
| necessary: there are task sets that are schedulable, but do not respect the |
| condition. For example, consider the task set {Task_1,Task_2} composed by |
| Task_1=(50ms,50ms,100ms) and Task_2=(10ms,100ms,100ms). |
| EDF is clearly able to schedule the two tasks without missing any deadline |
| (Task_1 is scheduled as soon as it is released, and finishes just in time |
| to respect its deadline; Task_2 is scheduled immediately after Task_1, hence |
| its response time cannot be larger than 50ms + 10ms = 60ms) even if |
| |
| 50 / min{50,100} + 10 / min{100, 100} = 50 / 50 + 10 / 100 = 1.1 |
| |
| Of course it is possible to test the exact schedulability of tasks with |
| D_i != P_i (checking a condition that is both sufficient and necessary), |
| but this cannot be done by comparing the total utilization or density with |
| a constant. Instead, the so called "processor demand" approach can be used, |
| computing the total amount of CPU time h(t) needed by all the tasks to |
| respect all of their deadlines in a time interval of size t, and comparing |
| such a time with the interval size t. If h(t) is smaller than t (that is, |
| the amount of time needed by the tasks in a time interval of size t is |
| smaller than the size of the interval) for all the possible values of t, then |
| EDF is able to schedule the tasks respecting all of their deadlines. Since |
| performing this check for all possible values of t is impossible, it has been |
| proven[4,5,6] that it is sufficient to perform the test for values of t |
| between 0 and a maximum value L. The cited papers contain all of the |
| mathematical details and explain how to compute h(t) and L. |
| In any case, this kind of analysis is too complex as well as too |
| time-consuming to be performed on-line. Hence, as explained in Section |
| 4 Linux uses an admission test based on the tasks' utilizations. |
| |
| 3.3 Schedulability Analysis for Multiprocessor Systems |
| ------------------------------------------------------ |
| |
| On multiprocessor systems with global EDF scheduling (non partitioned |
| systems), a sufficient test for schedulability can not be based on the |
| utilizations or densities: it can be shown that even if D_i = P_i task |
| sets with utilizations slightly larger than 1 can miss deadlines regardless |
| of the number of CPUs. |
| |
| Consider a set {Task_1,...Task_{M+1}} of M+1 tasks on a system with M |
| CPUs, with the first task Task_1=(P,P,P) having period, relative deadline |
| and WCET equal to P. The remaining M tasks Task_i=(e,P-1,P-1) have an |
| arbitrarily small worst case execution time (indicated as "e" here) and a |
| period smaller than the one of the first task. Hence, if all the tasks |
| activate at the same time t, global EDF schedules these M tasks first |
| (because their absolute deadlines are equal to t + P - 1, hence they are |
| smaller than the absolute deadline of Task_1, which is t + P). As a |
| result, Task_1 can be scheduled only at time t + e, and will finish at |
| time t + e + P, after its absolute deadline. The total utilization of the |
| task set is U = M · e / (P - 1) + P / P = M · e / (P - 1) + 1, and for small |
| values of e this can become very close to 1. This is known as "Dhall's |
| effect"[7]. Note: the example in the original paper by Dhall has been |
| slightly simplified here (for example, Dhall more correctly computed |
| lim_{e->0}U). |
| |
| More complex schedulability tests for global EDF have been developed in |
| real-time literature[8,9], but they are not based on a simple comparison |
| between total utilization (or density) and a fixed constant. If all tasks |
| have D_i = P_i, a sufficient schedulability condition can be expressed in |
| a simple way: |
| |
| sum(WCET_i / P_i) <= M - (M - 1) · U_max |
| |
| where U_max = max{WCET_i / P_i}[10]. Notice that for U_max = 1, |
| M - (M - 1) · U_max becomes M - M + 1 = 1 and this schedulability condition |
| just confirms the Dhall's effect. A more complete survey of the literature |
| about schedulability tests for multi-processor real-time scheduling can be |
| found in [11]. |
| |
| As seen, enforcing that the total utilization is smaller than M does not |
| guarantee that global EDF schedules the tasks without missing any deadline |
| (in other words, global EDF is not an optimal scheduling algorithm). However, |
| a total utilization smaller than M is enough to guarantee that non real-time |
| tasks are not starved and that the tardiness of real-time tasks has an upper |
| bound[12] (as previously noted). Different bounds on the maximum tardiness |
| experienced by real-time tasks have been developed in various papers[13,14], |
| but the theoretical result that is important for SCHED_DEADLINE is that if |
| the total utilization is smaller or equal than M then the response times of |
| the tasks are limited. |
| |
| 3.4 Relationship with SCHED_DEADLINE Parameters |
| ----------------------------------------------- |
| |
| Finally, it is important to understand the relationship between the |
| SCHED_DEADLINE scheduling parameters described in Section 2 (runtime, |
| deadline and period) and the real-time task parameters (WCET, D, P) |
| described in this section. Note that the tasks' temporal constraints are |
| represented by its absolute deadlines d_j = r_j + D described above, while |
| SCHED_DEADLINE schedules the tasks according to scheduling deadlines (see |
| Section 2). |
| If an admission test is used to guarantee that the scheduling deadlines |
| are respected, then SCHED_DEADLINE can be used to schedule real-time tasks |
| guaranteeing that all the jobs' deadlines of a task are respected. |
| In order to do this, a task must be scheduled by setting: |
| |
| - runtime >= WCET |
| - deadline = D |
| - period <= P |
| |
| IOW, if runtime >= WCET and if period is <= P, then the scheduling deadlines |
| and the absolute deadlines (d_j) coincide, so a proper admission control |
| allows to respect the jobs' absolute deadlines for this task (this is what is |
| called "hard schedulability property" and is an extension of Lemma 1 of [2]). |
| Notice that if runtime > deadline the admission control will surely reject |
| this task, as it is not possible to respect its temporal constraints. |
| |
| References: |
| |
| 1 - C. L. Liu and J. W. Layland. Scheduling algorithms for multiprogram- |
| ming in a hard-real-time environment. Journal of the Association for |
| Computing Machinery, 20(1), 1973. |
| 2 - L. Abeni , G. Buttazzo. Integrating Multimedia Applications in Hard |
| Real-Time Systems. Proceedings of the 19th IEEE Real-time Systems |
| Symposium, 1998. http://retis.sssup.it/~giorgio/paps/1998/rtss98-cbs.pdf |
| 3 - L. Abeni. Server Mechanisms for Multimedia Applications. ReTiS Lab |
| Technical Report. http://disi.unitn.it/~abeni/tr-98-01.pdf |
| 4 - J. Y. Leung and M.L. Merril. A Note on Preemptive Scheduling of |
| Periodic, Real-Time Tasks. Information Processing Letters, vol. 11, |
| no. 3, pp. 115-118, 1980. |
| 5 - S. K. Baruah, A. K. Mok and L. E. Rosier. Preemptively Scheduling |
| Hard-Real-Time Sporadic Tasks on One Processor. Proceedings of the |
| 11th IEEE Real-time Systems Symposium, 1990. |
| 6 - S. K. Baruah, L. E. Rosier and R. R. Howell. Algorithms and Complexity |
| Concerning the Preemptive Scheduling of Periodic Real-Time tasks on |
| One Processor. Real-Time Systems Journal, vol. 4, no. 2, pp 301-324, |
| 1990. |
| 7 - S. J. Dhall and C. L. Liu. On a real-time scheduling problem. Operations |
| research, vol. 26, no. 1, pp 127-140, 1978. |
| 8 - T. Baker. Multiprocessor EDF and Deadline Monotonic Schedulability |
| Analysis. Proceedings of the 24th IEEE Real-Time Systems Symposium, 2003. |
| 9 - T. Baker. An Analysis of EDF Schedulability on a Multiprocessor. |
| IEEE Transactions on Parallel and Distributed Systems, vol. 16, no. 8, |
| pp 760-768, 2005. |
| 10 - J. Goossens, S. Funk and S. Baruah, Priority-Driven Scheduling of |
| Periodic Task Systems on Multiprocessors. Real-Time Systems Journal, |
| vol. 25, no. 2–3, pp. 187–205, 2003. |
| 11 - R. Davis and A. Burns. A Survey of Hard Real-Time Scheduling for |
| Multiprocessor Systems. ACM Computing Surveys, vol. 43, no. 4, 2011. |
| http://www-users.cs.york.ac.uk/~robdavis/papers/MPSurveyv5.0.pdf |
| 12 - U. C. Devi and J. H. Anderson. Tardiness Bounds under Global EDF |
| Scheduling on a Multiprocessor. Real-Time Systems Journal, vol. 32, |
| no. 2, pp 133-189, 2008. |
| 13 - P. Valente and G. Lipari. An Upper Bound to the Lateness of Soft |
| Real-Time Tasks Scheduled by EDF on Multiprocessors. Proceedings of |
| the 26th IEEE Real-Time Systems Symposium, 2005. |
| 14 - J. Erickson, U. Devi and S. Baruah. Improved tardiness bounds for |
| Global EDF. Proceedings of the 22nd Euromicro Conference on |
| Real-Time Systems, 2010. |
| 15 - G. Lipari, S. Baruah, Greedy reclamation of unused bandwidth in |
| constant-bandwidth servers, 12th IEEE Euromicro Conference on Real-Time |
| Systems, 2000. |
| 16 - L. Abeni, J. Lelli, C. Scordino, L. Palopoli, Greedy CPU reclaiming for |
| SCHED DEADLINE. In Proceedings of the Real-Time Linux Workshop (RTLWS), |
| Dusseldorf, Germany, 2014. |
| 17 - L. Abeni, G. Lipari, A. Parri, Y. Sun, Multicore CPU reclaiming: parallel |
| or sequential?. In Proceedings of the 31st Annual ACM Symposium on Applied |
| Computing, 2016. |
| 18 - J. Lelli, C. Scordino, L. Abeni, D. Faggioli, Deadline scheduling in the |
| Linux kernel, Software: Practice and Experience, 46(6): 821-839, June |
| 2016. |
| 19 - C. Scordino, L. Abeni, J. Lelli, Energy-Aware Real-Time Scheduling in |
| the Linux Kernel, 33rd ACM/SIGAPP Symposium On Applied Computing (SAC |
| 2018), Pau, France, April 2018. |
| |
| |
| 4. Bandwidth management |
| ======================= |
| |
| As previously mentioned, in order for -deadline scheduling to be |
| effective and useful (that is, to be able to provide "runtime" time units |
| within "deadline"), it is important to have some method to keep the allocation |
| of the available fractions of CPU time to the various tasks under control. |
| This is usually called "admission control" and if it is not performed, then |
| no guarantee can be given on the actual scheduling of the -deadline tasks. |
| |
| As already stated in Section 3, a necessary condition to be respected to |
| correctly schedule a set of real-time tasks is that the total utilization |
| is smaller than M. When talking about -deadline tasks, this requires that |
| the sum of the ratio between runtime and period for all tasks is smaller |
| than M. Notice that the ratio runtime/period is equivalent to the utilization |
| of a "traditional" real-time task, and is also often referred to as |
| "bandwidth". |
| The interface used to control the CPU bandwidth that can be allocated |
| to -deadline tasks is similar to the one already used for -rt |
| tasks with real-time group scheduling (a.k.a. RT-throttling - see |
| Documentation/scheduler/sched-rt-group.rst), and is based on readable/ |
| writable control files located in procfs (for system wide settings). |
| Notice that per-group settings (controlled through cgroupfs) are still not |
| defined for -deadline tasks, because more discussion is needed in order to |
| figure out how we want to manage SCHED_DEADLINE bandwidth at the task group |
| level. |
| |
| A main difference between deadline bandwidth management and RT-throttling |
| is that -deadline tasks have bandwidth on their own (while -rt ones don't!), |
| and thus we don't need a higher level throttling mechanism to enforce the |
| desired bandwidth. In other words, this means that interface parameters are |
| only used at admission control time (i.e., when the user calls |
| sched_setattr()). Scheduling is then performed considering actual tasks' |
| parameters, so that CPU bandwidth is allocated to SCHED_DEADLINE tasks |
| respecting their needs in terms of granularity. Therefore, using this simple |
| interface we can put a cap on total utilization of -deadline tasks (i.e., |
| \Sum (runtime_i / period_i) < global_dl_utilization_cap). |
| |
| 4.1 System wide settings |
| ------------------------ |
| |
| The system wide settings are configured under the /proc virtual file system. |
| |
| For now the -rt knobs are used for -deadline admission control and the |
| -deadline runtime is accounted against the -rt runtime. We realize that this |
| isn't entirely desirable; however, it is better to have a small interface for |
| now, and be able to change it easily later. The ideal situation (see 5.) is to |
| run -rt tasks from a -deadline server; in which case the -rt bandwidth is a |
| direct subset of dl_bw. |
| |
| This means that, for a root_domain comprising M CPUs, -deadline tasks |
| can be created while the sum of their bandwidths stays below: |
| |
| M * (sched_rt_runtime_us / sched_rt_period_us) |
| |
| It is also possible to disable this bandwidth management logic, and |
| be thus free of oversubscribing the system up to any arbitrary level. |
| This is done by writing -1 in /proc/sys/kernel/sched_rt_runtime_us. |
| |
| |
| 4.2 Task interface |
| ------------------ |
| |
| Specifying a periodic/sporadic task that executes for a given amount of |
| runtime at each instance, and that is scheduled according to the urgency of |
| its own timing constraints needs, in general, a way of declaring: |
| |
| - a (maximum/typical) instance execution time, |
| - a minimum interval between consecutive instances, |
| - a time constraint by which each instance must be completed. |
| |
| Therefore: |
| |
| * a new struct sched_attr, containing all the necessary fields is |
| provided; |
| * the new scheduling related syscalls that manipulate it, i.e., |
| sched_setattr() and sched_getattr() are implemented. |
| |
| For debugging purposes, the leftover runtime and absolute deadline of a |
| SCHED_DEADLINE task can be retrieved through /proc/<pid>/sched (entries |
| dl.runtime and dl.deadline, both values in ns). A programmatic way to |
| retrieve these values from production code is under discussion. |
| |
| |
| 4.3 Default behavior |
| --------------------- |
| |
| The default value for SCHED_DEADLINE bandwidth is to have rt_runtime equal to |
| 950000. With rt_period equal to 1000000, by default, it means that -deadline |
| tasks can use at most 95%, multiplied by the number of CPUs that compose the |
| root_domain, for each root_domain. |
| This means that non -deadline tasks will receive at least 5% of the CPU time, |
| and that -deadline tasks will receive their runtime with a guaranteed |
| worst-case delay respect to the "deadline" parameter. If "deadline" = "period" |
| and the cpuset mechanism is used to implement partitioned scheduling (see |
| Section 5), then this simple setting of the bandwidth management is able to |
| deterministically guarantee that -deadline tasks will receive their runtime |
| in a period. |
| |
| Finally, notice that in order not to jeopardize the admission control a |
| -deadline task cannot fork. |
| |
| |
| 4.4 Behavior of sched_yield() |
| ----------------------------- |
| |
| When a SCHED_DEADLINE task calls sched_yield(), it gives up its |
| remaining runtime and is immediately throttled, until the next |
| period, when its runtime will be replenished (a special flag |
| dl_yielded is set and used to handle correctly throttling and runtime |
| replenishment after a call to sched_yield()). |
| |
| This behavior of sched_yield() allows the task to wake-up exactly at |
| the beginning of the next period. Also, this may be useful in the |
| future with bandwidth reclaiming mechanisms, where sched_yield() will |
| make the leftoever runtime available for reclamation by other |
| SCHED_DEADLINE tasks. |
| |
| |
| 5. Tasks CPU affinity |
| ===================== |
| |
| -deadline tasks cannot have an affinity mask smaller that the entire |
| root_domain they are created on. However, affinities can be specified |
| through the cpuset facility (Documentation/admin-guide/cgroup-v1/cpusets.rst). |
| |
| 5.1 SCHED_DEADLINE and cpusets HOWTO |
| ------------------------------------ |
| |
| An example of a simple configuration (pin a -deadline task to CPU0) |
| follows (rt-app is used to create a -deadline task):: |
| |
| mkdir /dev/cpuset |
| mount -t cgroup -o cpuset cpuset /dev/cpuset |
| cd /dev/cpuset |
| mkdir cpu0 |
| echo 0 > cpu0/cpuset.cpus |
| echo 0 > cpu0/cpuset.mems |
| echo 1 > cpuset.cpu_exclusive |
| echo 0 > cpuset.sched_load_balance |
| echo 1 > cpu0/cpuset.cpu_exclusive |
| echo 1 > cpu0/cpuset.mem_exclusive |
| echo $$ > cpu0/tasks |
| rt-app -t 100000:10000:d:0 -D5 # it is now actually superfluous to specify |
| # task affinity |
| |
| 6. Future plans |
| =============== |
| |
| Still missing: |
| |
| - programmatic way to retrieve current runtime and absolute deadline |
| - refinements to deadline inheritance, especially regarding the possibility |
| of retaining bandwidth isolation among non-interacting tasks. This is |
| being studied from both theoretical and practical points of view, and |
| hopefully we should be able to produce some demonstrative code soon; |
| - (c)group based bandwidth management, and maybe scheduling; |
| - access control for non-root users (and related security concerns to |
| address), which is the best way to allow unprivileged use of the mechanisms |
| and how to prevent non-root users "cheat" the system? |
| |
| As already discussed, we are planning also to merge this work with the EDF |
| throttling patches [https://lore.kernel.org/r/cover.1266931410.git.fabio@helm.retis] but we still are in |
| the preliminary phases of the merge and we really seek feedback that would |
| help us decide on the direction it should take. |
| |
| Appendix A. Test suite |
| ====================== |
| |
| The SCHED_DEADLINE policy can be easily tested using two applications that |
| are part of a wider Linux Scheduler validation suite. The suite is |
| available as a GitHub repository: https://github.com/scheduler-tools. |
| |
| The first testing application is called rt-app and can be used to |
| start multiple threads with specific parameters. rt-app supports |
| SCHED_{OTHER,FIFO,RR,DEADLINE} scheduling policies and their related |
| parameters (e.g., niceness, priority, runtime/deadline/period). rt-app |
| is a valuable tool, as it can be used to synthetically recreate certain |
| workloads (maybe mimicking real use-cases) and evaluate how the scheduler |
| behaves under such workloads. In this way, results are easily reproducible. |
| rt-app is available at: https://github.com/scheduler-tools/rt-app. |
| |
| Thread parameters can be specified from the command line, with something like |
| this:: |
| |
| # rt-app -t 100000:10000:d -t 150000:20000:f:10 -D5 |
| |
| The above creates 2 threads. The first one, scheduled by SCHED_DEADLINE, |
| executes for 10ms every 100ms. The second one, scheduled at SCHED_FIFO |
| priority 10, executes for 20ms every 150ms. The test will run for a total |
| of 5 seconds. |
| |
| More interestingly, configurations can be described with a json file that |
| can be passed as input to rt-app with something like this:: |
| |
| # rt-app my_config.json |
| |
| The parameters that can be specified with the second method are a superset |
| of the command line options. Please refer to rt-app documentation for more |
| details (`<rt-app-sources>/doc/*.json`). |
| |
| The second testing application is done using chrt which has support |
| for SCHED_DEADLINE. |
| |
| The usage is straightforward:: |
| |
| # chrt -d -T 10000000 -D 100000000 0 ./my_cpuhog_app |
| |
| With this, my_cpuhog_app is put to run inside a SCHED_DEADLINE reservation |
| of 10ms every 100ms (note that parameters are expressed in nanoseconds). |
| You can also use chrt to create a reservation for an already running |
| application, given that you know its pid:: |
| |
| # chrt -d -T 10000000 -D 100000000 -p 0 my_app_pid |
| |
| Appendix B. Minimal main() |
| ========================== |
| |
| We provide in what follows a simple (ugly) self-contained code snippet |
| showing how SCHED_DEADLINE reservations can be created by a real-time |
| application developer:: |
| |
| #define _GNU_SOURCE |
| #include <unistd.h> |
| #include <stdio.h> |
| #include <stdlib.h> |
| #include <string.h> |
| #include <time.h> |
| #include <linux/unistd.h> |
| #include <linux/kernel.h> |
| #include <linux/types.h> |
| #include <sys/syscall.h> |
| #include <pthread.h> |
| |
| #define gettid() syscall(__NR_gettid) |
| |
| #define SCHED_DEADLINE 6 |
| |
| /* XXX use the proper syscall numbers */ |
| #ifdef __x86_64__ |
| #define __NR_sched_setattr 314 |
| #define __NR_sched_getattr 315 |
| #endif |
| |
| #ifdef __i386__ |
| #define __NR_sched_setattr 351 |
| #define __NR_sched_getattr 352 |
| #endif |
| |
| #ifdef __arm__ |
| #define __NR_sched_setattr 380 |
| #define __NR_sched_getattr 381 |
| #endif |
| |
| static volatile int done; |
| |
| struct sched_attr { |
| __u32 size; |
| |
| __u32 sched_policy; |
| __u64 sched_flags; |
| |
| /* SCHED_NORMAL, SCHED_BATCH */ |
| __s32 sched_nice; |
| |
| /* SCHED_FIFO, SCHED_RR */ |
| __u32 sched_priority; |
| |
| /* SCHED_DEADLINE (nsec) */ |
| __u64 sched_runtime; |
| __u64 sched_deadline; |
| __u64 sched_period; |
| }; |
| |
| int sched_setattr(pid_t pid, |
| const struct sched_attr *attr, |
| unsigned int flags) |
| { |
| return syscall(__NR_sched_setattr, pid, attr, flags); |
| } |
| |
| int sched_getattr(pid_t pid, |
| struct sched_attr *attr, |
| unsigned int size, |
| unsigned int flags) |
| { |
| return syscall(__NR_sched_getattr, pid, attr, size, flags); |
| } |
| |
| void *run_deadline(void *data) |
| { |
| struct sched_attr attr; |
| int x = 0; |
| int ret; |
| unsigned int flags = 0; |
| |
| printf("deadline thread started [%ld]\n", gettid()); |
| |
| attr.size = sizeof(attr); |
| attr.sched_flags = 0; |
| attr.sched_nice = 0; |
| attr.sched_priority = 0; |
| |
| /* This creates a 10ms/30ms reservation */ |
| attr.sched_policy = SCHED_DEADLINE; |
| attr.sched_runtime = 10 * 1000 * 1000; |
| attr.sched_period = attr.sched_deadline = 30 * 1000 * 1000; |
| |
| ret = sched_setattr(0, &attr, flags); |
| if (ret < 0) { |
| done = 0; |
| perror("sched_setattr"); |
| exit(-1); |
| } |
| |
| while (!done) { |
| x++; |
| } |
| |
| printf("deadline thread dies [%ld]\n", gettid()); |
| return NULL; |
| } |
| |
| int main (int argc, char **argv) |
| { |
| pthread_t thread; |
| |
| printf("main thread [%ld]\n", gettid()); |
| |
| pthread_create(&thread, NULL, run_deadline, NULL); |
| |
| sleep(10); |
| |
| done = 1; |
| pthread_join(thread, NULL); |
| |
| printf("main dies [%ld]\n", gettid()); |
| return 0; |
| } |