Motivates and explains the ktask API for kernel clients. Signed-off-by: Daniel Jordan <daniel.m.jordan@xxxxxxxxxx> --- Documentation/core-api/index.rst | 1 + Documentation/core-api/ktask.rst | 213 +++++++++++++++++++++++++++++++ 2 files changed, 214 insertions(+) create mode 100644 Documentation/core-api/ktask.rst diff --git a/Documentation/core-api/index.rst b/Documentation/core-api/index.rst index 3adee82be311..c143a280a5b1 100644 --- a/Documentation/core-api/index.rst +++ b/Documentation/core-api/index.rst @@ -18,6 +18,7 @@ Core utilities refcount-vs-atomic cpu_hotplug idr + ktask local_ops workqueue genericirq diff --git a/Documentation/core-api/ktask.rst b/Documentation/core-api/ktask.rst new file mode 100644 index 000000000000..c3c00e1f802f --- /dev/null +++ b/Documentation/core-api/ktask.rst @@ -0,0 +1,213 @@ +.. SPDX-License-Identifier: GPL-2.0+ + +============================================ +ktask: parallelize CPU-intensive kernel work +============================================ + +:Date: November, 2018 +:Author: Daniel Jordan <daniel.m.jordan@xxxxxxxxxx> + + +Introduction +============ + +ktask is a generic framework for parallelizing CPU-intensive work in the +kernel. The intended use is for big machines that can use their CPU power to +speed up large tasks that can't otherwise be multithreaded in userland. The +API is generic enough to add concurrency to many different kinds of tasks--for +example, page clearing over an address range or freeing a list of pages--and +aims to save its clients the trouble of splitting up the work, choosing the +number of helper threads to use, maintaining an efficient concurrency level, +starting these threads, and load balancing the work between them. + + +Motivation +========== + +A single CPU can spend an excessive amount of time in the kernel operating on +large amounts of data. Often these situations arise during initialization- and +destruction-related tasks, where the data involved scales with system size. +These long-running jobs can slow startup and shutdown of applications and the +system itself while extra CPUs sit idle. + +To ensure that applications and the kernel continue to perform well as core +counts and memory sizes increase, the kernel harnesses these idle CPUs to +complete such jobs more quickly. + +For example, when booting a large NUMA machine, ktask uses additional CPUs that +would otherwise be idle until the machine is fully up to avoid a needless +bottleneck during system boot and allow the kernel to take advantage of unused +memory bandwidth. Similarly, when starting a large VM using VFIO, ktask takes +advantage of the VM's idle CPUs during VFIO page pinning rather than have the +VM's boot blocked on one thread doing all the work. + +ktask is not a substitute for single-threaded optimization. However, there is +a point where a single CPU hits a wall despite performance tuning, so +parallelize! + + +Concept +======= + +ktask is built on unbound workqueues to take advantage of the thread management +facilities it provides: creation, destruction, flushing, priority setting, and +NUMA affinity. + +A little terminology up front: A 'task' is the total work there is to do and a +'chunk' is a unit of work given to a thread. + +To complete a task using the ktask framework, a client provides a thread +function that is responsible for completing one chunk. The thread function is +defined in a standard way, with start and end arguments that delimit the chunk +as well as an argument that the client uses to pass data specific to the task. + +In addition, the client supplies an object representing the start of the task +and an iterator function that knows how to advance some number of units in the +task to yield another object representing the new task position. The framework +uses the start object and iterator internally to divide the task into chunks. + +Finally, the client passes the total task size and a minimum chunk size to +indicate the minimum amount of work that's appropriate to do in one chunk. The +sizes are given in task-specific units (e.g. pages, inodes, bytes). The +framework uses these sizes, along with the number of online CPUs and an +internal maximum number of threads, to decide how many threads to start and how +many chunks to divide the task into. + +For example, consider the task of clearing a gigantic page. This used to be +done in a single thread with a for loop that calls a page clearing function for +each constituent base page. To parallelize with ktask, the client first moves +the for loop to the thread function, adapting it to operate on the range passed +to the function. In this simple case, the thread function's start and end +arguments are just addresses delimiting the portion of the gigantic page to +clear. Then, where the for loop used to be, the client calls into ktask with +the start address of the gigantic page, the total size of the gigantic page, +and the thread function. Internally, ktask will divide the address range into +an appropriate number of chunks and start an appropriate number of threads to +complete these chunks. + + +Configuration +============= + +To use ktask, configure the kernel with CONFIG_KTASK=y. + +If CONFIG_KTASK=n, calls to the ktask API are simply #define'd to run the +thread function that the client provides so that the task is completed without +concurrency in the current thread. + + +Interface +========= + +.. kernel-doc:: include/linux/ktask.h + + +Resource Limits +=============== + +ktask has resource limits on the number of work items it sends to workqueue. +In ktask, a workqueue item is a thread that runs chunks of the task until the +task is finished. + +These limits support the different ways ktask uses workqueues: + - ktask_run to run threads on the calling thread's node. + - ktask_run_numa to run threads on the node(s) specified. + - ktask_run_numa with nid=NUMA_NO_NODE to run threads on any node in the + system. + +To support these different ways of queueing work while maintaining an efficient +concurrency level, we need both system-wide and per-node limits on the number +of threads. Without per-node limits, a node might become oversubscribed +despite ktask staying within the system-wide limit, and without a system-wide +limit, we can't properly account for work that can run on any node. + +The system-wide limit is based on the total number of CPUs, and the per-node +limit on the CPU count for each node. A per-node work item counts against the +system-wide limit. Workqueue's max_active can't accommodate both types of +limit, no matter how many workqueues are used, so ktask implements its own. + +If a per-node limit is reached, the work item is allowed to run anywhere on the +machine to avoid overwhelming the node. If the global limit is also reached, +ktask won't queue additional work items until we fall below the limit again. + +These limits apply only to workqueue items--that is, helper threads beyond the +one starting the task. That way, one thread per task is always allowed to run. + + +Scheduler Interaction +===================== + +Even within the resource limits, ktask must take care to run a number of +threads appropriate for the system's current CPU load. Under high CPU usage, +starting excessive helper threads may disturb other tasks, unfairly taking CPU +time away from them for the sake of an optimized kernel code path. + +ktask plays nicely in this case by setting helper threads to the lowest +scheduling priority on the system (MAX_NICE). This way, helpers' CPU time is +appropriately throttled on a busy system and other tasks are not disturbed. + +The main thread initiating the task remains at its original priority so that it +still makes progress on a busy system. + +It is possible for a helper thread to start running and then be forced off-CPU +by a higher priority thread. With the helper's CPU time curtailed by MAX_NICE, +the main thread may wait longer for the task to finish than it would have had +it not started any helpers, so to ensure forward progress at a single-threaded +pace, once the main thread is finished with all outstanding work in the task, +the main thread wills its priority to one helper thread at a time. At least +one thread will then always be running at the priority of the calling thread. + + +Cgroup Awareness +================ + +Given the potentially large amount of CPU time ktask threads may consume, they +should be aware of the cgroup of the task that called into ktask and +appropriately throttled. + +TODO: Implement cgroup-awareness in unbound workqueues. + + +Power Management +================ + +Starting additional helper threads may cause the system to consume more energy, +which is undesirable on energy-conscious devices. Therefore ktask needs to be +aware of cpufreq policies and scaling governors. + +If an energy-conscious policy is in use (e.g. powersave, conservative) on any +part of the system, that is a signal that the user has strong power management +preferences, in which case ktask is disabled. + +TODO: Implement this. + + +Backward Compatibility +====================== + +ktask is written so that existing calls to the API will be backwards compatible +should the API gain new features in the future. This is accomplished by +restricting API changes to members of struct ktask_ctl and having clients make +an opaque initialization call (DEFINE_KTASK_CTL). This initialization can then +be modified to include any new arguments so that existing call sites stay the +same. + + +Error Handling +============== + +Calls to ktask fail only if the provided thread function fails. In particular, +ktask avoids allocating memory internally during a task, so it's safe to use in +sensitive contexts. + +Tasks can fail midway through their work. To recover, the finished chunks of +work need to be undone in a task-specific way, so ktask allows clients to pass +an "undo" callback that is responsible for undoing one chunk of work. To avoid +multiple levels of error handling, this "undo" callback should not be allowed +to fail. For simplicity and because it's a slow path, undoing is not +multithreaded. + +Each call to ktask_run and ktask_run_numa returns a single value, +KTASK_RETURN_SUCCESS or a client-specific value. Since threads can fail for +different reasons, however, ktask may need the ability to return +thread-specific error information. This can be added later if needed. -- 2.19.1