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891df57b98
Fix up the remaining C schedulers after the recent API and header updates. Also drop stray -p from usage help message from some schedulers.
615 lines
18 KiB
C
615 lines
18 KiB
C
/* SPDX-License-Identifier: GPL-2.0 */
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/*
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* A demo sched_ext core-scheduler which always makes every sibling CPU pair
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* execute from the same CPU cgroup.
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*
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* This scheduler is a minimal implementation and would need some form of
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* priority handling both inside each cgroup and across the cgroups to be
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* practically useful.
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*
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* Each CPU in the system is paired with exactly one other CPU, according to a
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* "stride" value that can be specified when the BPF scheduler program is first
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* loaded. Throughout the runtime of the scheduler, these CPU pairs guarantee
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* that they will only ever schedule tasks that belong to the same CPU cgroup.
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*
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* Scheduler Initialization
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* ------------------------
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*
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* The scheduler BPF program is first initialized from user space, before it is
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* enabled. During this initialization process, each CPU on the system is
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* assigned several values that are constant throughout its runtime:
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*
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* 1. *Pair CPU*: The CPU that it synchronizes with when making scheduling
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* decisions. Paired CPUs always schedule tasks from the same
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* CPU cgroup, and synchronize with each other to guarantee
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* that this constraint is not violated.
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* 2. *Pair ID*: Each CPU pair is assigned a Pair ID, which is used to access
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* a struct pair_ctx object that is shared between the pair.
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* 3. *In-pair-index*: An index, 0 or 1, that is assigned to each core in the
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* pair. Each struct pair_ctx has an active_mask field,
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* which is a bitmap used to indicate whether each core
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* in the pair currently has an actively running task.
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* This index specifies which entry in the bitmap corresponds
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* to each CPU in the pair.
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*
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* During this initialization, the CPUs are paired according to a "stride" that
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* may be specified when invoking the user space program that initializes and
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* loads the scheduler. By default, the stride is 1/2 the total number of CPUs.
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*
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* Tasks and cgroups
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* -----------------
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*
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* Every cgroup in the system is registered with the scheduler using the
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* pair_cgroup_init() callback, and every task in the system is associated with
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* exactly one cgroup. At a high level, the idea with the pair scheduler is to
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* always schedule tasks from the same cgroup within a given CPU pair. When a
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* task is enqueued (i.e. passed to the pair_enqueue() callback function), its
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* cgroup ID is read from its task struct, and then a corresponding queue map
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* is used to FIFO-enqueue the task for that cgroup.
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*
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* If you look through the implementation of the scheduler, you'll notice that
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* there is quite a bit of complexity involved with looking up the per-cgroup
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* FIFO queue that we enqueue tasks in. For example, there is a cgrp_q_idx_hash
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* BPF hash map that is used to map a cgroup ID to a globally unique ID that's
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* allocated in the BPF program. This is done because we use separate maps to
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* store the FIFO queue of tasks, and the length of that map, per cgroup. This
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* complexity is only present because of current deficiencies in BPF that will
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* soon be addressed. The main point to keep in mind is that newly enqueued
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* tasks are added to their cgroup's FIFO queue.
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*
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* Dispatching tasks
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* -----------------
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*
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* This section will describe how enqueued tasks are dispatched and scheduled.
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* Tasks are dispatched in pair_dispatch(), and at a high level the workflow is
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* as follows:
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*
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* 1. Fetch the struct pair_ctx for the current CPU. As mentioned above, this is
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* the structure that's used to synchronize amongst the two pair CPUs in their
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* scheduling decisions. After any of the following events have occurred:
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*
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* - The cgroup's slice run has expired, or
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* - The cgroup becomes empty, or
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* - Either CPU in the pair is preempted by a higher priority scheduling class
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*
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* The cgroup transitions to the draining state and stops executing new tasks
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* from the cgroup.
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*
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* 2. If the pair is still executing a task, mark the pair_ctx as draining, and
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* wait for the pair CPU to be preempted.
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*
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* 3. Otherwise, if the pair CPU is not running a task, we can move onto
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* scheduling new tasks. Pop the next cgroup id from the top_q queue.
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*
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* 4. Pop a task from that cgroup's FIFO task queue, and begin executing it.
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*
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* Note again that this scheduling behavior is simple, but the implementation
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* is complex mostly because this it hits several BPF shortcomings and has to
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* work around in often awkward ways. Most of the shortcomings are expected to
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* be resolved in the near future which should allow greatly simplifying this
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* scheduler.
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*
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* Dealing with preemption
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* -----------------------
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*
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* SCX is the lowest priority sched_class, and could be preempted by them at
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* any time. To address this, the scheduler implements pair_cpu_release() and
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* pair_cpu_acquire() callbacks which are invoked by the core scheduler when
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* the scheduler loses and gains control of the CPU respectively.
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*
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* In pair_cpu_release(), we mark the pair_ctx as having been preempted, and
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* then invoke:
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*
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* scx_bpf_kick_cpu(pair_cpu, SCX_KICK_PREEMPT | SCX_KICK_WAIT);
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*
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* This preempts the pair CPU, and waits until it has re-entered the scheduler
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* before returning. This is necessary to ensure that the higher priority
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* sched_class that preempted our scheduler does not schedule a task
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* concurrently with our pair CPU.
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*
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* When the CPU is re-acquired in pair_cpu_acquire(), we unmark the preemption
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* in the pair_ctx, and send another resched IPI to the pair CPU to re-enable
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* pair scheduling.
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*
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* Copyright (c) 2022 Meta Platforms, Inc. and affiliates.
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* Copyright (c) 2022 Tejun Heo <tj@kernel.org>
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* Copyright (c) 2022 David Vernet <dvernet@meta.com>
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*/
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#include <scx/common.bpf.h>
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#include "scx_pair.h"
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char _license[] SEC("license") = "GPL";
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/* !0 for veristat, set during init */
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const volatile u32 nr_cpu_ids = 1;
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/* a pair of CPUs stay on a cgroup for this duration */
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const volatile u32 pair_batch_dur_ns = SCX_SLICE_DFL;
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/* cpu ID -> pair cpu ID */
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const volatile s32 RESIZABLE_ARRAY(rodata, pair_cpu);
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/* cpu ID -> pair_id */
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const volatile u32 RESIZABLE_ARRAY(rodata, pair_id);
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/* CPU ID -> CPU # in the pair (0 or 1) */
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const volatile u32 RESIZABLE_ARRAY(rodata, in_pair_idx);
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struct pair_ctx {
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struct bpf_spin_lock lock;
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/* the cgroup the pair is currently executing */
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u64 cgid;
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/* the pair started executing the current cgroup at */
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u64 started_at;
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/* whether the current cgroup is draining */
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bool draining;
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/* the CPUs that are currently active on the cgroup */
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u32 active_mask;
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/*
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* the CPUs that are currently preempted and running tasks in a
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* different scheduler.
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*/
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u32 preempted_mask;
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};
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struct {
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__uint(type, BPF_MAP_TYPE_ARRAY);
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__type(key, u32);
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__type(value, struct pair_ctx);
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} pair_ctx SEC(".maps");
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/* queue of cgrp_q's possibly with tasks on them */
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struct {
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__uint(type, BPF_MAP_TYPE_QUEUE);
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/*
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* Because it's difficult to build strong synchronization encompassing
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* multiple non-trivial operations in BPF, this queue is managed in an
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* opportunistic way so that we guarantee that a cgroup w/ active tasks
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* is always on it but possibly multiple times. Once we have more robust
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* synchronization constructs and e.g. linked list, we should be able to
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* do this in a prettier way but for now just size it big enough.
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*/
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__uint(max_entries, 4 * MAX_CGRPS);
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__type(value, u64);
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} top_q SEC(".maps");
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/* per-cgroup q which FIFOs the tasks from the cgroup */
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struct cgrp_q {
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__uint(type, BPF_MAP_TYPE_QUEUE);
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__uint(max_entries, MAX_QUEUED);
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__type(value, u32);
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};
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/*
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* Ideally, we want to allocate cgrp_q and cgrq_q_len in the cgroup local
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* storage; however, a cgroup local storage can only be accessed from the BPF
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* progs attached to the cgroup. For now, work around by allocating array of
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* cgrp_q's and then allocating per-cgroup indices.
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*
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* Another caveat: It's difficult to populate a large array of maps statically
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* or from BPF. Initialize it from userland.
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*/
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struct {
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__uint(type, BPF_MAP_TYPE_ARRAY_OF_MAPS);
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__uint(max_entries, MAX_CGRPS);
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__type(key, s32);
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__array(values, struct cgrp_q);
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} cgrp_q_arr SEC(".maps");
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static u64 cgrp_q_len[MAX_CGRPS];
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/*
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* This and cgrp_q_idx_hash combine into a poor man's IDR. This likely would be
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* useful to have as a map type.
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*/
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static u32 cgrp_q_idx_cursor;
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static u64 cgrp_q_idx_busy[MAX_CGRPS];
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/*
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* All added up, the following is what we do:
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*
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* 1. When a cgroup is enabled, RR cgroup_q_idx_busy array doing cmpxchg looking
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* for a free ID. If not found, fail cgroup creation with -EBUSY.
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*
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* 2. Hash the cgroup ID to the allocated cgrp_q_idx in the following
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* cgrp_q_idx_hash.
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*
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* 3. Whenever a cgrp_q needs to be accessed, first look up the cgrp_q_idx from
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* cgrp_q_idx_hash and then access the corresponding entry in cgrp_q_arr.
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*
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* This is sadly complicated for something pretty simple. Hopefully, we should
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* be able to simplify in the future.
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*/
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struct {
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__uint(type, BPF_MAP_TYPE_HASH);
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__uint(max_entries, MAX_CGRPS);
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__uint(key_size, sizeof(u64)); /* cgrp ID */
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__uint(value_size, sizeof(s32)); /* cgrp_q idx */
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} cgrp_q_idx_hash SEC(".maps");
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/* statistics */
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u64 nr_total, nr_dispatched, nr_missing, nr_kicks, nr_preemptions;
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u64 nr_exps, nr_exp_waits, nr_exp_empty;
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u64 nr_cgrp_next, nr_cgrp_coll, nr_cgrp_empty;
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UEI_DEFINE(uei);
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static bool time_before(u64 a, u64 b)
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{
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return (s64)(a - b) < 0;
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}
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void BPF_STRUCT_OPS(pair_enqueue, struct task_struct *p, u64 enq_flags)
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{
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struct cgroup *cgrp;
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struct cgrp_q *cgq;
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s32 pid = p->pid;
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u64 cgid;
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u32 *q_idx;
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u64 *cgq_len;
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__sync_fetch_and_add(&nr_total, 1);
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cgrp = scx_bpf_task_cgroup(p);
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cgid = cgrp->kn->id;
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bpf_cgroup_release(cgrp);
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/* find the cgroup's q and push @p into it */
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q_idx = bpf_map_lookup_elem(&cgrp_q_idx_hash, &cgid);
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if (!q_idx) {
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scx_bpf_error("failed to lookup q_idx for cgroup[%llu]", cgid);
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return;
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}
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cgq = bpf_map_lookup_elem(&cgrp_q_arr, q_idx);
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if (!cgq) {
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scx_bpf_error("failed to lookup q_arr for cgroup[%llu] q_idx[%u]",
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cgid, *q_idx);
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return;
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}
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if (bpf_map_push_elem(cgq, &pid, 0)) {
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scx_bpf_error("cgroup[%llu] queue overflow", cgid);
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return;
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}
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/* bump q len, if going 0 -> 1, queue cgroup into the top_q */
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cgq_len = MEMBER_VPTR(cgrp_q_len, [*q_idx]);
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if (!cgq_len) {
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scx_bpf_error("MEMBER_VTPR malfunction");
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return;
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}
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if (!__sync_fetch_and_add(cgq_len, 1) &&
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bpf_map_push_elem(&top_q, &cgid, 0)) {
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scx_bpf_error("top_q overflow");
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return;
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}
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}
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static int lookup_pairc_and_mask(s32 cpu, struct pair_ctx **pairc, u32 *mask)
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{
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u32 *vptr;
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vptr = (u32 *)ARRAY_ELEM_PTR(pair_id, cpu, nr_cpu_ids);
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if (!vptr)
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return -EINVAL;
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*pairc = bpf_map_lookup_elem(&pair_ctx, vptr);
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if (!(*pairc))
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return -EINVAL;
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vptr = (u32 *)ARRAY_ELEM_PTR(in_pair_idx, cpu, nr_cpu_ids);
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if (!vptr)
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return -EINVAL;
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*mask = 1U << *vptr;
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return 0;
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}
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static int try_dispatch(s32 cpu)
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{
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struct pair_ctx *pairc;
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struct bpf_map *cgq_map;
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struct task_struct *p;
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u64 now = bpf_ktime_get_ns();
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bool kick_pair = false;
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bool expired, pair_preempted;
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u32 *vptr, in_pair_mask;
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s32 pid, q_idx;
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u64 cgid;
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int ret;
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ret = lookup_pairc_and_mask(cpu, &pairc, &in_pair_mask);
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if (ret) {
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scx_bpf_error("failed to lookup pairc and in_pair_mask for cpu[%d]",
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cpu);
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return -ENOENT;
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}
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bpf_spin_lock(&pairc->lock);
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pairc->active_mask &= ~in_pair_mask;
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expired = time_before(pairc->started_at + pair_batch_dur_ns, now);
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if (expired || pairc->draining) {
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u64 new_cgid = 0;
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__sync_fetch_and_add(&nr_exps, 1);
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/*
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* We're done with the current cgid. An obvious optimization
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* would be not draining if the next cgroup is the current one.
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* For now, be dumb and always expire.
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*/
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pairc->draining = true;
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pair_preempted = pairc->preempted_mask;
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if (pairc->active_mask || pair_preempted) {
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/*
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* The other CPU is still active, or is no longer under
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* our control due to e.g. being preempted by a higher
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* priority sched_class. We want to wait until this
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* cgroup expires, or until control of our pair CPU has
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* been returned to us.
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*
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* If the pair controls its CPU, and the time already
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* expired, kick. When the other CPU arrives at
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* dispatch and clears its active mask, it'll push the
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* pair to the next cgroup and kick this CPU.
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*/
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__sync_fetch_and_add(&nr_exp_waits, 1);
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bpf_spin_unlock(&pairc->lock);
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if (expired && !pair_preempted)
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kick_pair = true;
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goto out_maybe_kick;
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}
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bpf_spin_unlock(&pairc->lock);
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/*
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* Pick the next cgroup. It'd be easier / cleaner to not drop
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* pairc->lock and use stronger synchronization here especially
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* given that we'll be switching cgroups significantly less
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* frequently than tasks. Unfortunately, bpf_spin_lock can't
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* really protect anything non-trivial. Let's do opportunistic
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* operations instead.
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*/
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bpf_repeat(BPF_MAX_LOOPS) {
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u32 *q_idx;
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u64 *cgq_len;
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if (bpf_map_pop_elem(&top_q, &new_cgid)) {
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/* no active cgroup, go idle */
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__sync_fetch_and_add(&nr_exp_empty, 1);
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return 0;
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}
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q_idx = bpf_map_lookup_elem(&cgrp_q_idx_hash, &new_cgid);
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if (!q_idx)
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continue;
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/*
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* This is the only place where empty cgroups are taken
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* off the top_q.
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*/
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cgq_len = MEMBER_VPTR(cgrp_q_len, [*q_idx]);
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if (!cgq_len || !*cgq_len)
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continue;
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/*
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* If it has any tasks, requeue as we may race and not
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* execute it.
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*/
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bpf_map_push_elem(&top_q, &new_cgid, 0);
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break;
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}
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bpf_spin_lock(&pairc->lock);
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/*
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* The other CPU may already have started on a new cgroup while
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* we dropped the lock. Make sure that we're still draining and
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* start on the new cgroup.
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*/
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if (pairc->draining && !pairc->active_mask) {
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__sync_fetch_and_add(&nr_cgrp_next, 1);
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pairc->cgid = new_cgid;
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pairc->started_at = now;
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pairc->draining = false;
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kick_pair = true;
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} else {
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__sync_fetch_and_add(&nr_cgrp_coll, 1);
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}
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}
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cgid = pairc->cgid;
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pairc->active_mask |= in_pair_mask;
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bpf_spin_unlock(&pairc->lock);
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/* again, it'd be better to do all these with the lock held, oh well */
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vptr = bpf_map_lookup_elem(&cgrp_q_idx_hash, &cgid);
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if (!vptr) {
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scx_bpf_error("failed to lookup q_idx for cgroup[%llu]", cgid);
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return -ENOENT;
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}
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q_idx = *vptr;
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/* claim one task from cgrp_q w/ q_idx */
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bpf_repeat(BPF_MAX_LOOPS) {
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u64 *cgq_len, len;
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cgq_len = MEMBER_VPTR(cgrp_q_len, [q_idx]);
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if (!cgq_len || !(len = *(volatile u64 *)cgq_len)) {
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/* the cgroup must be empty, expire and repeat */
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__sync_fetch_and_add(&nr_cgrp_empty, 1);
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bpf_spin_lock(&pairc->lock);
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pairc->draining = true;
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pairc->active_mask &= ~in_pair_mask;
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bpf_spin_unlock(&pairc->lock);
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return -EAGAIN;
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}
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if (__sync_val_compare_and_swap(cgq_len, len, len - 1) != len)
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continue;
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break;
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}
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cgq_map = bpf_map_lookup_elem(&cgrp_q_arr, &q_idx);
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if (!cgq_map) {
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scx_bpf_error("failed to lookup cgq_map for cgroup[%llu] q_idx[%d]",
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cgid, q_idx);
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return -ENOENT;
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}
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if (bpf_map_pop_elem(cgq_map, &pid)) {
|
|
scx_bpf_error("cgq_map is empty for cgroup[%llu] q_idx[%d]",
|
|
cgid, q_idx);
|
|
return -ENOENT;
|
|
}
|
|
|
|
p = bpf_task_from_pid(pid);
|
|
if (p) {
|
|
__sync_fetch_and_add(&nr_dispatched, 1);
|
|
scx_bpf_dispatch(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, 0);
|
|
bpf_task_release(p);
|
|
} else {
|
|
/* we don't handle dequeues, retry on lost tasks */
|
|
__sync_fetch_and_add(&nr_missing, 1);
|
|
return -EAGAIN;
|
|
}
|
|
|
|
out_maybe_kick:
|
|
if (kick_pair) {
|
|
s32 *pair = (s32 *)ARRAY_ELEM_PTR(pair_cpu, cpu, nr_cpu_ids);
|
|
if (pair) {
|
|
__sync_fetch_and_add(&nr_kicks, 1);
|
|
scx_bpf_kick_cpu(*pair, SCX_KICK_PREEMPT);
|
|
}
|
|
}
|
|
return 0;
|
|
}
|
|
|
|
void BPF_STRUCT_OPS(pair_dispatch, s32 cpu, struct task_struct *prev)
|
|
{
|
|
bpf_repeat(BPF_MAX_LOOPS) {
|
|
if (try_dispatch(cpu) != -EAGAIN)
|
|
break;
|
|
}
|
|
}
|
|
|
|
void BPF_STRUCT_OPS(pair_cpu_acquire, s32 cpu, struct scx_cpu_acquire_args *args)
|
|
{
|
|
int ret;
|
|
u32 in_pair_mask;
|
|
struct pair_ctx *pairc;
|
|
bool kick_pair;
|
|
|
|
ret = lookup_pairc_and_mask(cpu, &pairc, &in_pair_mask);
|
|
if (ret)
|
|
return;
|
|
|
|
bpf_spin_lock(&pairc->lock);
|
|
pairc->preempted_mask &= ~in_pair_mask;
|
|
/* Kick the pair CPU, unless it was also preempted. */
|
|
kick_pair = !pairc->preempted_mask;
|
|
bpf_spin_unlock(&pairc->lock);
|
|
|
|
if (kick_pair) {
|
|
s32 *pair = (s32 *)ARRAY_ELEM_PTR(pair_cpu, cpu, nr_cpu_ids);
|
|
|
|
if (pair) {
|
|
__sync_fetch_and_add(&nr_kicks, 1);
|
|
scx_bpf_kick_cpu(*pair, SCX_KICK_PREEMPT);
|
|
}
|
|
}
|
|
}
|
|
|
|
void BPF_STRUCT_OPS(pair_cpu_release, s32 cpu, struct scx_cpu_release_args *args)
|
|
{
|
|
int ret;
|
|
u32 in_pair_mask;
|
|
struct pair_ctx *pairc;
|
|
bool kick_pair;
|
|
|
|
ret = lookup_pairc_and_mask(cpu, &pairc, &in_pair_mask);
|
|
if (ret)
|
|
return;
|
|
|
|
bpf_spin_lock(&pairc->lock);
|
|
pairc->preempted_mask |= in_pair_mask;
|
|
pairc->active_mask &= ~in_pair_mask;
|
|
/* Kick the pair CPU if it's still running. */
|
|
kick_pair = pairc->active_mask;
|
|
pairc->draining = true;
|
|
bpf_spin_unlock(&pairc->lock);
|
|
|
|
if (kick_pair) {
|
|
s32 *pair = (s32 *)ARRAY_ELEM_PTR(pair_cpu, cpu, nr_cpu_ids);
|
|
|
|
if (pair) {
|
|
__sync_fetch_and_add(&nr_kicks, 1);
|
|
scx_bpf_kick_cpu(*pair, SCX_KICK_PREEMPT | SCX_KICK_WAIT);
|
|
}
|
|
}
|
|
__sync_fetch_and_add(&nr_preemptions, 1);
|
|
}
|
|
|
|
s32 BPF_STRUCT_OPS(pair_cgroup_init, struct cgroup *cgrp)
|
|
{
|
|
u64 cgid = cgrp->kn->id;
|
|
s32 i, q_idx;
|
|
|
|
bpf_for(i, 0, MAX_CGRPS) {
|
|
q_idx = __sync_fetch_and_add(&cgrp_q_idx_cursor, 1) % MAX_CGRPS;
|
|
if (!__sync_val_compare_and_swap(&cgrp_q_idx_busy[q_idx], 0, 1))
|
|
break;
|
|
}
|
|
if (i == MAX_CGRPS)
|
|
return -EBUSY;
|
|
|
|
if (bpf_map_update_elem(&cgrp_q_idx_hash, &cgid, &q_idx, BPF_ANY)) {
|
|
u64 *busy = MEMBER_VPTR(cgrp_q_idx_busy, [q_idx]);
|
|
if (busy)
|
|
*busy = 0;
|
|
return -EBUSY;
|
|
}
|
|
|
|
return 0;
|
|
}
|
|
|
|
void BPF_STRUCT_OPS(pair_cgroup_exit, struct cgroup *cgrp)
|
|
{
|
|
u64 cgid = cgrp->kn->id;
|
|
s32 *q_idx;
|
|
|
|
q_idx = bpf_map_lookup_elem(&cgrp_q_idx_hash, &cgid);
|
|
if (q_idx) {
|
|
u64 *busy = MEMBER_VPTR(cgrp_q_idx_busy, [*q_idx]);
|
|
if (busy)
|
|
*busy = 0;
|
|
bpf_map_delete_elem(&cgrp_q_idx_hash, &cgid);
|
|
}
|
|
}
|
|
|
|
void BPF_STRUCT_OPS(pair_exit, struct scx_exit_info *ei)
|
|
{
|
|
UEI_RECORD(uei, ei);
|
|
}
|
|
|
|
SCX_OPS_DEFINE(pair_ops,
|
|
.enqueue = (void *)pair_enqueue,
|
|
.dispatch = (void *)pair_dispatch,
|
|
.cpu_acquire = (void *)pair_cpu_acquire,
|
|
.cpu_release = (void *)pair_cpu_release,
|
|
.cgroup_init = (void *)pair_cgroup_init,
|
|
.cgroup_exit = (void *)pair_cgroup_exit,
|
|
.exit = (void *)pair_exit,
|
|
.name = "pair");
|