1337d1b35SAndrea Righi // SPDX-License-Identifier: GPL-2.0
2337d1b35SAndrea Righi /*
3337d1b35SAndrea Righi * BPF extensible scheduler class: Documentation/scheduler/sched-ext.rst
4337d1b35SAndrea Righi *
5337d1b35SAndrea Righi * Built-in idle CPU tracking policy.
6337d1b35SAndrea Righi *
7337d1b35SAndrea Righi * Copyright (c) 2022 Meta Platforms, Inc. and affiliates.
8337d1b35SAndrea Righi * Copyright (c) 2022 Tejun Heo <tj@kernel.org>
9337d1b35SAndrea Righi * Copyright (c) 2022 David Vernet <dvernet@meta.com>
10337d1b35SAndrea Righi * Copyright (c) 2024 Andrea Righi <arighi@nvidia.com>
11337d1b35SAndrea Righi */
12337d1b35SAndrea Righi #include "ext_idle.h"
13337d1b35SAndrea Righi
14337d1b35SAndrea Righi /* Enable/disable built-in idle CPU selection policy */
15d73249f8SAndrea Righi static DEFINE_STATIC_KEY_FALSE(scx_builtin_idle_enabled);
16337d1b35SAndrea Righi
170aaaf89dSAndrea Righi /* Enable/disable per-node idle cpumasks */
180aaaf89dSAndrea Righi static DEFINE_STATIC_KEY_FALSE(scx_builtin_idle_per_node);
190aaaf89dSAndrea Righi
20337d1b35SAndrea Righi #ifdef CONFIG_SMP
21337d1b35SAndrea Righi /* Enable/disable LLC aware optimizations */
22d73249f8SAndrea Righi static DEFINE_STATIC_KEY_FALSE(scx_selcpu_topo_llc);
23337d1b35SAndrea Righi
24337d1b35SAndrea Righi /* Enable/disable NUMA aware optimizations */
25d73249f8SAndrea Righi static DEFINE_STATIC_KEY_FALSE(scx_selcpu_topo_numa);
26337d1b35SAndrea Righi
2748849271SAndrea Righi /*
2848849271SAndrea Righi * cpumasks to track idle CPUs within each NUMA node.
2948849271SAndrea Righi *
3048849271SAndrea Righi * If SCX_OPS_BUILTIN_IDLE_PER_NODE is not enabled, a single global cpumask
3148849271SAndrea Righi * from is used to track all the idle CPUs in the system.
3248849271SAndrea Righi */
3348849271SAndrea Righi struct scx_idle_cpus {
34337d1b35SAndrea Righi cpumask_var_t cpu;
35337d1b35SAndrea Righi cpumask_var_t smt;
3648849271SAndrea Righi };
3748849271SAndrea Righi
3848849271SAndrea Righi /*
3948849271SAndrea Righi * Global host-wide idle cpumasks (used when SCX_OPS_BUILTIN_IDLE_PER_NODE
4048849271SAndrea Righi * is not enabled).
4148849271SAndrea Righi */
4248849271SAndrea Righi static struct scx_idle_cpus scx_idle_global_masks;
4348849271SAndrea Righi
4448849271SAndrea Righi /*
4548849271SAndrea Righi * Per-node idle cpumasks.
4648849271SAndrea Righi */
4748849271SAndrea Righi static struct scx_idle_cpus **scx_idle_node_masks;
4848849271SAndrea Righi
4948849271SAndrea Righi /*
5048849271SAndrea Righi * Return the idle masks associated to a target @node.
5148849271SAndrea Righi *
5248849271SAndrea Righi * NUMA_NO_NODE identifies the global idle cpumask.
5348849271SAndrea Righi */
idle_cpumask(int node)5448849271SAndrea Righi static struct scx_idle_cpus *idle_cpumask(int node)
5548849271SAndrea Righi {
5648849271SAndrea Righi return node == NUMA_NO_NODE ? &scx_idle_global_masks : scx_idle_node_masks[node];
5748849271SAndrea Righi }
5848849271SAndrea Righi
5948849271SAndrea Righi /*
6048849271SAndrea Righi * Returns the NUMA node ID associated with a @cpu, or NUMA_NO_NODE if
6148849271SAndrea Righi * per-node idle cpumasks are disabled.
6248849271SAndrea Righi */
scx_cpu_node_if_enabled(int cpu)6348849271SAndrea Righi static int scx_cpu_node_if_enabled(int cpu)
6448849271SAndrea Righi {
6548849271SAndrea Righi if (!static_branch_maybe(CONFIG_NUMA, &scx_builtin_idle_per_node))
6648849271SAndrea Righi return NUMA_NO_NODE;
6748849271SAndrea Righi
6848849271SAndrea Righi return cpu_to_node(cpu);
6948849271SAndrea Righi }
70337d1b35SAndrea Righi
scx_idle_test_and_clear_cpu(int cpu)71337d1b35SAndrea Righi bool scx_idle_test_and_clear_cpu(int cpu)
72337d1b35SAndrea Righi {
7348849271SAndrea Righi int node = scx_cpu_node_if_enabled(cpu);
7448849271SAndrea Righi struct cpumask *idle_cpus = idle_cpumask(node)->cpu;
7548849271SAndrea Righi
76337d1b35SAndrea Righi #ifdef CONFIG_SCHED_SMT
77337d1b35SAndrea Righi /*
78337d1b35SAndrea Righi * SMT mask should be cleared whether we can claim @cpu or not. The SMT
79337d1b35SAndrea Righi * cluster is not wholly idle either way. This also prevents
80337d1b35SAndrea Righi * scx_pick_idle_cpu() from getting caught in an infinite loop.
81337d1b35SAndrea Righi */
82337d1b35SAndrea Righi if (sched_smt_active()) {
83337d1b35SAndrea Righi const struct cpumask *smt = cpu_smt_mask(cpu);
8448849271SAndrea Righi struct cpumask *idle_smts = idle_cpumask(node)->smt;
85337d1b35SAndrea Righi
86337d1b35SAndrea Righi /*
87337d1b35SAndrea Righi * If offline, @cpu is not its own sibling and
88337d1b35SAndrea Righi * scx_pick_idle_cpu() can get caught in an infinite loop as
8948849271SAndrea Righi * @cpu is never cleared from the idle SMT mask. Ensure that
9048849271SAndrea Righi * @cpu is eventually cleared.
91337d1b35SAndrea Righi *
92337d1b35SAndrea Righi * NOTE: Use cpumask_intersects() and cpumask_test_cpu() to
93337d1b35SAndrea Righi * reduce memory writes, which may help alleviate cache
94337d1b35SAndrea Righi * coherence pressure.
95337d1b35SAndrea Righi */
9648849271SAndrea Righi if (cpumask_intersects(smt, idle_smts))
9748849271SAndrea Righi cpumask_andnot(idle_smts, idle_smts, smt);
9848849271SAndrea Righi else if (cpumask_test_cpu(cpu, idle_smts))
9948849271SAndrea Righi __cpumask_clear_cpu(cpu, idle_smts);
100337d1b35SAndrea Righi }
101337d1b35SAndrea Righi #endif
10248849271SAndrea Righi
10348849271SAndrea Righi return cpumask_test_and_clear_cpu(cpu, idle_cpus);
104337d1b35SAndrea Righi }
105337d1b35SAndrea Righi
10648849271SAndrea Righi /*
10748849271SAndrea Righi * Pick an idle CPU in a specific NUMA node.
10848849271SAndrea Righi */
pick_idle_cpu_in_node(const struct cpumask * cpus_allowed,int node,u64 flags)10948849271SAndrea Righi static s32 pick_idle_cpu_in_node(const struct cpumask *cpus_allowed, int node, u64 flags)
110337d1b35SAndrea Righi {
111337d1b35SAndrea Righi int cpu;
112337d1b35SAndrea Righi
113337d1b35SAndrea Righi retry:
114337d1b35SAndrea Righi if (sched_smt_active()) {
11548849271SAndrea Righi cpu = cpumask_any_and_distribute(idle_cpumask(node)->smt, cpus_allowed);
116337d1b35SAndrea Righi if (cpu < nr_cpu_ids)
117337d1b35SAndrea Righi goto found;
118337d1b35SAndrea Righi
119337d1b35SAndrea Righi if (flags & SCX_PICK_IDLE_CORE)
120337d1b35SAndrea Righi return -EBUSY;
121337d1b35SAndrea Righi }
122337d1b35SAndrea Righi
12348849271SAndrea Righi cpu = cpumask_any_and_distribute(idle_cpumask(node)->cpu, cpus_allowed);
124337d1b35SAndrea Righi if (cpu >= nr_cpu_ids)
125337d1b35SAndrea Righi return -EBUSY;
126337d1b35SAndrea Righi
127337d1b35SAndrea Righi found:
128337d1b35SAndrea Righi if (scx_idle_test_and_clear_cpu(cpu))
129337d1b35SAndrea Righi return cpu;
130337d1b35SAndrea Righi else
131337d1b35SAndrea Righi goto retry;
132337d1b35SAndrea Righi }
133337d1b35SAndrea Righi
134337d1b35SAndrea Righi /*
13548849271SAndrea Righi * Tracks nodes that have not yet been visited when searching for an idle
13648849271SAndrea Righi * CPU across all available nodes.
13748849271SAndrea Righi */
13848849271SAndrea Righi static DEFINE_PER_CPU(nodemask_t, per_cpu_unvisited);
13948849271SAndrea Righi
14048849271SAndrea Righi /*
14148849271SAndrea Righi * Search for an idle CPU across all nodes, excluding @node.
14248849271SAndrea Righi */
pick_idle_cpu_from_online_nodes(const struct cpumask * cpus_allowed,int node,u64 flags)14348849271SAndrea Righi static s32 pick_idle_cpu_from_online_nodes(const struct cpumask *cpus_allowed, int node, u64 flags)
14448849271SAndrea Righi {
14548849271SAndrea Righi nodemask_t *unvisited;
14648849271SAndrea Righi s32 cpu = -EBUSY;
14748849271SAndrea Righi
14848849271SAndrea Righi preempt_disable();
14948849271SAndrea Righi unvisited = this_cpu_ptr(&per_cpu_unvisited);
15048849271SAndrea Righi
15148849271SAndrea Righi /*
15248849271SAndrea Righi * Restrict the search to the online nodes (excluding the current
15348849271SAndrea Righi * node that has been visited already).
15448849271SAndrea Righi */
15548849271SAndrea Righi nodes_copy(*unvisited, node_states[N_ONLINE]);
15648849271SAndrea Righi node_clear(node, *unvisited);
15748849271SAndrea Righi
15848849271SAndrea Righi /*
15948849271SAndrea Righi * Traverse all nodes in order of increasing distance, starting
16048849271SAndrea Righi * from @node.
16148849271SAndrea Righi *
16248849271SAndrea Righi * This loop is O(N^2), with N being the amount of NUMA nodes,
16348849271SAndrea Righi * which might be quite expensive in large NUMA systems. However,
16448849271SAndrea Righi * this complexity comes into play only when a scheduler enables
16548849271SAndrea Righi * SCX_OPS_BUILTIN_IDLE_PER_NODE and it's requesting an idle CPU
16648849271SAndrea Righi * without specifying a target NUMA node, so it shouldn't be a
16748849271SAndrea Righi * bottleneck is most cases.
16848849271SAndrea Righi *
16948849271SAndrea Righi * As a future optimization we may want to cache the list of nodes
17048849271SAndrea Righi * in a per-node array, instead of actually traversing them every
17148849271SAndrea Righi * time.
17248849271SAndrea Righi */
17348849271SAndrea Righi for_each_node_numadist(node, *unvisited) {
17448849271SAndrea Righi cpu = pick_idle_cpu_in_node(cpus_allowed, node, flags);
17548849271SAndrea Righi if (cpu >= 0)
17648849271SAndrea Righi break;
17748849271SAndrea Righi }
17848849271SAndrea Righi preempt_enable();
17948849271SAndrea Righi
18048849271SAndrea Righi return cpu;
18148849271SAndrea Righi }
18248849271SAndrea Righi
18348849271SAndrea Righi /*
18448849271SAndrea Righi * Find an idle CPU in the system, starting from @node.
18548849271SAndrea Righi */
scx_pick_idle_cpu(const struct cpumask * cpus_allowed,int node,u64 flags)18648849271SAndrea Righi s32 scx_pick_idle_cpu(const struct cpumask *cpus_allowed, int node, u64 flags)
18748849271SAndrea Righi {
18848849271SAndrea Righi s32 cpu;
18948849271SAndrea Righi
19048849271SAndrea Righi /*
19148849271SAndrea Righi * Always search in the starting node first (this is an
19248849271SAndrea Righi * optimization that can save some cycles even when the search is
19348849271SAndrea Righi * not limited to a single node).
19448849271SAndrea Righi */
19548849271SAndrea Righi cpu = pick_idle_cpu_in_node(cpus_allowed, node, flags);
19648849271SAndrea Righi if (cpu >= 0)
19748849271SAndrea Righi return cpu;
19848849271SAndrea Righi
19948849271SAndrea Righi /*
20048849271SAndrea Righi * Stop the search if we are using only a single global cpumask
20148849271SAndrea Righi * (NUMA_NO_NODE) or if the search is restricted to the first node
20248849271SAndrea Righi * only.
20348849271SAndrea Righi */
20448849271SAndrea Righi if (node == NUMA_NO_NODE || flags & SCX_PICK_IDLE_IN_NODE)
20548849271SAndrea Righi return -EBUSY;
20648849271SAndrea Righi
20748849271SAndrea Righi /*
20848849271SAndrea Righi * Extend the search to the other online nodes.
20948849271SAndrea Righi */
21048849271SAndrea Righi return pick_idle_cpu_from_online_nodes(cpus_allowed, node, flags);
21148849271SAndrea Righi }
21248849271SAndrea Righi
21348849271SAndrea Righi /*
214337d1b35SAndrea Righi * Return the amount of CPUs in the same LLC domain of @cpu (or zero if the LLC
215337d1b35SAndrea Righi * domain is not defined).
216337d1b35SAndrea Righi */
llc_weight(s32 cpu)217337d1b35SAndrea Righi static unsigned int llc_weight(s32 cpu)
218337d1b35SAndrea Righi {
219337d1b35SAndrea Righi struct sched_domain *sd;
220337d1b35SAndrea Righi
221337d1b35SAndrea Righi sd = rcu_dereference(per_cpu(sd_llc, cpu));
222337d1b35SAndrea Righi if (!sd)
223337d1b35SAndrea Righi return 0;
224337d1b35SAndrea Righi
225337d1b35SAndrea Righi return sd->span_weight;
226337d1b35SAndrea Righi }
227337d1b35SAndrea Righi
228337d1b35SAndrea Righi /*
229337d1b35SAndrea Righi * Return the cpumask representing the LLC domain of @cpu (or NULL if the LLC
230337d1b35SAndrea Righi * domain is not defined).
231337d1b35SAndrea Righi */
llc_span(s32 cpu)232337d1b35SAndrea Righi static struct cpumask *llc_span(s32 cpu)
233337d1b35SAndrea Righi {
234337d1b35SAndrea Righi struct sched_domain *sd;
235337d1b35SAndrea Righi
236337d1b35SAndrea Righi sd = rcu_dereference(per_cpu(sd_llc, cpu));
237337d1b35SAndrea Righi if (!sd)
238337d1b35SAndrea Righi return 0;
239337d1b35SAndrea Righi
240337d1b35SAndrea Righi return sched_domain_span(sd);
241337d1b35SAndrea Righi }
242337d1b35SAndrea Righi
243337d1b35SAndrea Righi /*
244337d1b35SAndrea Righi * Return the amount of CPUs in the same NUMA domain of @cpu (or zero if the
245337d1b35SAndrea Righi * NUMA domain is not defined).
246337d1b35SAndrea Righi */
numa_weight(s32 cpu)247337d1b35SAndrea Righi static unsigned int numa_weight(s32 cpu)
248337d1b35SAndrea Righi {
249337d1b35SAndrea Righi struct sched_domain *sd;
250337d1b35SAndrea Righi struct sched_group *sg;
251337d1b35SAndrea Righi
252337d1b35SAndrea Righi sd = rcu_dereference(per_cpu(sd_numa, cpu));
253337d1b35SAndrea Righi if (!sd)
254337d1b35SAndrea Righi return 0;
255337d1b35SAndrea Righi sg = sd->groups;
256337d1b35SAndrea Righi if (!sg)
257337d1b35SAndrea Righi return 0;
258337d1b35SAndrea Righi
259337d1b35SAndrea Righi return sg->group_weight;
260337d1b35SAndrea Righi }
261337d1b35SAndrea Righi
262337d1b35SAndrea Righi /*
263337d1b35SAndrea Righi * Return the cpumask representing the NUMA domain of @cpu (or NULL if the NUMA
264337d1b35SAndrea Righi * domain is not defined).
265337d1b35SAndrea Righi */
numa_span(s32 cpu)266337d1b35SAndrea Righi static struct cpumask *numa_span(s32 cpu)
267337d1b35SAndrea Righi {
268337d1b35SAndrea Righi struct sched_domain *sd;
269337d1b35SAndrea Righi struct sched_group *sg;
270337d1b35SAndrea Righi
271337d1b35SAndrea Righi sd = rcu_dereference(per_cpu(sd_numa, cpu));
272337d1b35SAndrea Righi if (!sd)
273337d1b35SAndrea Righi return NULL;
274337d1b35SAndrea Righi sg = sd->groups;
275337d1b35SAndrea Righi if (!sg)
276337d1b35SAndrea Righi return NULL;
277337d1b35SAndrea Righi
278337d1b35SAndrea Righi return sched_group_span(sg);
279337d1b35SAndrea Righi }
280337d1b35SAndrea Righi
281337d1b35SAndrea Righi /*
282337d1b35SAndrea Righi * Return true if the LLC domains do not perfectly overlap with the NUMA
283337d1b35SAndrea Righi * domains, false otherwise.
284337d1b35SAndrea Righi */
llc_numa_mismatch(void)285337d1b35SAndrea Righi static bool llc_numa_mismatch(void)
286337d1b35SAndrea Righi {
287337d1b35SAndrea Righi int cpu;
288337d1b35SAndrea Righi
289337d1b35SAndrea Righi /*
290337d1b35SAndrea Righi * We need to scan all online CPUs to verify whether their scheduling
291337d1b35SAndrea Righi * domains overlap.
292337d1b35SAndrea Righi *
293337d1b35SAndrea Righi * While it is rare to encounter architectures with asymmetric NUMA
294337d1b35SAndrea Righi * topologies, CPU hotplugging or virtualized environments can result
295337d1b35SAndrea Righi * in asymmetric configurations.
296337d1b35SAndrea Righi *
297337d1b35SAndrea Righi * For example:
298337d1b35SAndrea Righi *
299337d1b35SAndrea Righi * NUMA 0:
300337d1b35SAndrea Righi * - LLC 0: cpu0..cpu7
301337d1b35SAndrea Righi * - LLC 1: cpu8..cpu15 [offline]
302337d1b35SAndrea Righi *
303337d1b35SAndrea Righi * NUMA 1:
304337d1b35SAndrea Righi * - LLC 0: cpu16..cpu23
305337d1b35SAndrea Righi * - LLC 1: cpu24..cpu31
306337d1b35SAndrea Righi *
307337d1b35SAndrea Righi * In this case, if we only check the first online CPU (cpu0), we might
308337d1b35SAndrea Righi * incorrectly assume that the LLC and NUMA domains are fully
309337d1b35SAndrea Righi * overlapping, which is incorrect (as NUMA 1 has two distinct LLC
310337d1b35SAndrea Righi * domains).
311337d1b35SAndrea Righi */
312337d1b35SAndrea Righi for_each_online_cpu(cpu)
313337d1b35SAndrea Righi if (llc_weight(cpu) != numa_weight(cpu))
314337d1b35SAndrea Righi return true;
315337d1b35SAndrea Righi
316337d1b35SAndrea Righi return false;
317337d1b35SAndrea Righi }
318337d1b35SAndrea Righi
319337d1b35SAndrea Righi /*
320337d1b35SAndrea Righi * Initialize topology-aware scheduling.
321337d1b35SAndrea Righi *
322337d1b35SAndrea Righi * Detect if the system has multiple LLC or multiple NUMA domains and enable
323337d1b35SAndrea Righi * cache-aware / NUMA-aware scheduling optimizations in the default CPU idle
324337d1b35SAndrea Righi * selection policy.
325337d1b35SAndrea Righi *
326337d1b35SAndrea Righi * Assumption: the kernel's internal topology representation assumes that each
327337d1b35SAndrea Righi * CPU belongs to a single LLC domain, and that each LLC domain is entirely
328337d1b35SAndrea Righi * contained within a single NUMA node.
329337d1b35SAndrea Righi */
scx_idle_update_selcpu_topology(struct sched_ext_ops * ops)3300aaaf89dSAndrea Righi void scx_idle_update_selcpu_topology(struct sched_ext_ops *ops)
331337d1b35SAndrea Righi {
332337d1b35SAndrea Righi bool enable_llc = false, enable_numa = false;
333337d1b35SAndrea Righi unsigned int nr_cpus;
334337d1b35SAndrea Righi s32 cpu = cpumask_first(cpu_online_mask);
335337d1b35SAndrea Righi
336337d1b35SAndrea Righi /*
337337d1b35SAndrea Righi * Enable LLC domain optimization only when there are multiple LLC
338337d1b35SAndrea Righi * domains among the online CPUs. If all online CPUs are part of a
339337d1b35SAndrea Righi * single LLC domain, the idle CPU selection logic can choose any
340337d1b35SAndrea Righi * online CPU without bias.
341337d1b35SAndrea Righi *
342337d1b35SAndrea Righi * Note that it is sufficient to check the LLC domain of the first
343337d1b35SAndrea Righi * online CPU to determine whether a single LLC domain includes all
344337d1b35SAndrea Righi * CPUs.
345337d1b35SAndrea Righi */
346337d1b35SAndrea Righi rcu_read_lock();
347337d1b35SAndrea Righi nr_cpus = llc_weight(cpu);
348337d1b35SAndrea Righi if (nr_cpus > 0) {
349337d1b35SAndrea Righi if (nr_cpus < num_online_cpus())
350337d1b35SAndrea Righi enable_llc = true;
351337d1b35SAndrea Righi pr_debug("sched_ext: LLC=%*pb weight=%u\n",
352337d1b35SAndrea Righi cpumask_pr_args(llc_span(cpu)), llc_weight(cpu));
353337d1b35SAndrea Righi }
354337d1b35SAndrea Righi
355337d1b35SAndrea Righi /*
356337d1b35SAndrea Righi * Enable NUMA optimization only when there are multiple NUMA domains
357337d1b35SAndrea Righi * among the online CPUs and the NUMA domains don't perfectly overlaps
358337d1b35SAndrea Righi * with the LLC domains.
359337d1b35SAndrea Righi *
360337d1b35SAndrea Righi * If all CPUs belong to the same NUMA node and the same LLC domain,
361337d1b35SAndrea Righi * enabling both NUMA and LLC optimizations is unnecessary, as checking
362337d1b35SAndrea Righi * for an idle CPU in the same domain twice is redundant.
3630aaaf89dSAndrea Righi *
3640aaaf89dSAndrea Righi * If SCX_OPS_BUILTIN_IDLE_PER_NODE is enabled ignore the NUMA
3650aaaf89dSAndrea Righi * optimization, as we would naturally select idle CPUs within
3660aaaf89dSAndrea Righi * specific NUMA nodes querying the corresponding per-node cpumask.
367337d1b35SAndrea Righi */
3680aaaf89dSAndrea Righi if (!(ops->flags & SCX_OPS_BUILTIN_IDLE_PER_NODE)) {
369337d1b35SAndrea Righi nr_cpus = numa_weight(cpu);
370337d1b35SAndrea Righi if (nr_cpus > 0) {
371337d1b35SAndrea Righi if (nr_cpus < num_online_cpus() && llc_numa_mismatch())
372337d1b35SAndrea Righi enable_numa = true;
373337d1b35SAndrea Righi pr_debug("sched_ext: NUMA=%*pb weight=%u\n",
3740aaaf89dSAndrea Righi cpumask_pr_args(numa_span(cpu)), nr_cpus);
3750aaaf89dSAndrea Righi }
376337d1b35SAndrea Righi }
377337d1b35SAndrea Righi rcu_read_unlock();
378337d1b35SAndrea Righi
379337d1b35SAndrea Righi pr_debug("sched_ext: LLC idle selection %s\n",
380337d1b35SAndrea Righi str_enabled_disabled(enable_llc));
381337d1b35SAndrea Righi pr_debug("sched_ext: NUMA idle selection %s\n",
382337d1b35SAndrea Righi str_enabled_disabled(enable_numa));
383337d1b35SAndrea Righi
384337d1b35SAndrea Righi if (enable_llc)
385337d1b35SAndrea Righi static_branch_enable_cpuslocked(&scx_selcpu_topo_llc);
386337d1b35SAndrea Righi else
387337d1b35SAndrea Righi static_branch_disable_cpuslocked(&scx_selcpu_topo_llc);
388337d1b35SAndrea Righi if (enable_numa)
389337d1b35SAndrea Righi static_branch_enable_cpuslocked(&scx_selcpu_topo_numa);
390337d1b35SAndrea Righi else
391337d1b35SAndrea Righi static_branch_disable_cpuslocked(&scx_selcpu_topo_numa);
392337d1b35SAndrea Righi }
393337d1b35SAndrea Righi
394337d1b35SAndrea Righi /*
395337d1b35SAndrea Righi * Built-in CPU idle selection policy:
396337d1b35SAndrea Righi *
397337d1b35SAndrea Righi * 1. Prioritize full-idle cores:
398337d1b35SAndrea Righi * - always prioritize CPUs from fully idle cores (both logical CPUs are
399337d1b35SAndrea Righi * idle) to avoid interference caused by SMT.
400337d1b35SAndrea Righi *
401337d1b35SAndrea Righi * 2. Reuse the same CPU:
402337d1b35SAndrea Righi * - prefer the last used CPU to take advantage of cached data (L1, L2) and
403337d1b35SAndrea Righi * branch prediction optimizations.
404337d1b35SAndrea Righi *
405337d1b35SAndrea Righi * 3. Pick a CPU within the same LLC (Last-Level Cache):
406337d1b35SAndrea Righi * - if the above conditions aren't met, pick a CPU that shares the same LLC
407337d1b35SAndrea Righi * to maintain cache locality.
408337d1b35SAndrea Righi *
409337d1b35SAndrea Righi * 4. Pick a CPU within the same NUMA node, if enabled:
410337d1b35SAndrea Righi * - choose a CPU from the same NUMA node to reduce memory access latency.
411337d1b35SAndrea Righi *
412337d1b35SAndrea Righi * 5. Pick any idle CPU usable by the task.
413337d1b35SAndrea Righi *
414e4855fc9SAndrea Righi * Step 3 and 4 are performed only if the system has, respectively,
415e4855fc9SAndrea Righi * multiple LLCs / multiple NUMA nodes (see scx_selcpu_topo_llc and
416e4855fc9SAndrea Righi * scx_selcpu_topo_numa) and they don't contain the same subset of CPUs.
417e4855fc9SAndrea Righi *
418e4855fc9SAndrea Righi * If %SCX_OPS_BUILTIN_IDLE_PER_NODE is enabled, the search will always
419e4855fc9SAndrea Righi * begin in @prev_cpu's node and proceed to other nodes in order of
420e4855fc9SAndrea Righi * increasing distance.
421e4855fc9SAndrea Righi *
422e4855fc9SAndrea Righi * Return the picked CPU if idle, or a negative value otherwise.
423337d1b35SAndrea Righi *
424337d1b35SAndrea Righi * NOTE: tasks that can only run on 1 CPU are excluded by this logic, because
425337d1b35SAndrea Righi * we never call ops.select_cpu() for them, see select_task_rq().
426337d1b35SAndrea Righi */
scx_select_cpu_dfl(struct task_struct * p,s32 prev_cpu,u64 wake_flags,u64 flags)427e4855fc9SAndrea Righi s32 scx_select_cpu_dfl(struct task_struct *p, s32 prev_cpu, u64 wake_flags, u64 flags)
428337d1b35SAndrea Righi {
429337d1b35SAndrea Righi const struct cpumask *llc_cpus = NULL;
430337d1b35SAndrea Righi const struct cpumask *numa_cpus = NULL;
43148849271SAndrea Righi int node = scx_cpu_node_if_enabled(prev_cpu);
432337d1b35SAndrea Righi s32 cpu;
433337d1b35SAndrea Righi
434337d1b35SAndrea Righi /*
435337d1b35SAndrea Righi * This is necessary to protect llc_cpus.
436337d1b35SAndrea Righi */
437337d1b35SAndrea Righi rcu_read_lock();
438337d1b35SAndrea Righi
439337d1b35SAndrea Righi /*
440337d1b35SAndrea Righi * Determine the scheduling domain only if the task is allowed to run
441337d1b35SAndrea Righi * on all CPUs.
442337d1b35SAndrea Righi *
443337d1b35SAndrea Righi * This is done primarily for efficiency, as it avoids the overhead of
444337d1b35SAndrea Righi * updating a cpumask every time we need to select an idle CPU (which
445337d1b35SAndrea Righi * can be costly in large SMP systems), but it also aligns logically:
446337d1b35SAndrea Righi * if a task's scheduling domain is restricted by user-space (through
447337d1b35SAndrea Righi * CPU affinity), the task will simply use the flat scheduling domain
448337d1b35SAndrea Righi * defined by user-space.
449337d1b35SAndrea Righi */
450337d1b35SAndrea Righi if (p->nr_cpus_allowed >= num_possible_cpus()) {
451337d1b35SAndrea Righi if (static_branch_maybe(CONFIG_NUMA, &scx_selcpu_topo_numa))
452337d1b35SAndrea Righi numa_cpus = numa_span(prev_cpu);
453337d1b35SAndrea Righi
454337d1b35SAndrea Righi if (static_branch_maybe(CONFIG_SCHED_MC, &scx_selcpu_topo_llc))
455337d1b35SAndrea Righi llc_cpus = llc_span(prev_cpu);
456337d1b35SAndrea Righi }
457337d1b35SAndrea Righi
458337d1b35SAndrea Righi /*
459337d1b35SAndrea Righi * If WAKE_SYNC, try to migrate the wakee to the waker's CPU.
460337d1b35SAndrea Righi */
461337d1b35SAndrea Righi if (wake_flags & SCX_WAKE_SYNC) {
462c414c217SAndrea Righi int waker_node;
463337d1b35SAndrea Righi
464337d1b35SAndrea Righi /*
465337d1b35SAndrea Righi * If the waker's CPU is cache affine and prev_cpu is idle,
466337d1b35SAndrea Righi * then avoid a migration.
467337d1b35SAndrea Righi */
468c414c217SAndrea Righi cpu = smp_processor_id();
469337d1b35SAndrea Righi if (cpus_share_cache(cpu, prev_cpu) &&
470337d1b35SAndrea Righi scx_idle_test_and_clear_cpu(prev_cpu)) {
471337d1b35SAndrea Righi cpu = prev_cpu;
472e4855fc9SAndrea Righi goto out_unlock;
473337d1b35SAndrea Righi }
474337d1b35SAndrea Righi
475337d1b35SAndrea Righi /*
476337d1b35SAndrea Righi * If the waker's local DSQ is empty, and the system is under
477337d1b35SAndrea Righi * utilized, try to wake up @p to the local DSQ of the waker.
478337d1b35SAndrea Righi *
479337d1b35SAndrea Righi * Checking only for an empty local DSQ is insufficient as it
480337d1b35SAndrea Righi * could give the wakee an unfair advantage when the system is
481337d1b35SAndrea Righi * oversaturated.
482337d1b35SAndrea Righi *
483337d1b35SAndrea Righi * Checking only for the presence of idle CPUs is also
484337d1b35SAndrea Righi * insufficient as the local DSQ of the waker could have tasks
485337d1b35SAndrea Righi * piled up on it even if there is an idle core elsewhere on
486337d1b35SAndrea Righi * the system.
487337d1b35SAndrea Righi */
488c414c217SAndrea Righi waker_node = cpu_to_node(cpu);
48948849271SAndrea Righi if (!(current->flags & PF_EXITING) &&
49048849271SAndrea Righi cpu_rq(cpu)->scx.local_dsq.nr == 0 &&
491c414c217SAndrea Righi (!(flags & SCX_PICK_IDLE_IN_NODE) || (waker_node == node)) &&
492c414c217SAndrea Righi !cpumask_empty(idle_cpumask(waker_node)->cpu)) {
493337d1b35SAndrea Righi if (cpumask_test_cpu(cpu, p->cpus_ptr))
494e4855fc9SAndrea Righi goto out_unlock;
495337d1b35SAndrea Righi }
496337d1b35SAndrea Righi }
497337d1b35SAndrea Righi
498337d1b35SAndrea Righi /*
499337d1b35SAndrea Righi * If CPU has SMT, any wholly idle CPU is likely a better pick than
500337d1b35SAndrea Righi * partially idle @prev_cpu.
501337d1b35SAndrea Righi */
502337d1b35SAndrea Righi if (sched_smt_active()) {
503337d1b35SAndrea Righi /*
504337d1b35SAndrea Righi * Keep using @prev_cpu if it's part of a fully idle core.
505337d1b35SAndrea Righi */
50648849271SAndrea Righi if (cpumask_test_cpu(prev_cpu, idle_cpumask(node)->smt) &&
507337d1b35SAndrea Righi scx_idle_test_and_clear_cpu(prev_cpu)) {
508337d1b35SAndrea Righi cpu = prev_cpu;
509e4855fc9SAndrea Righi goto out_unlock;
510337d1b35SAndrea Righi }
511337d1b35SAndrea Righi
512337d1b35SAndrea Righi /*
513337d1b35SAndrea Righi * Search for any fully idle core in the same LLC domain.
514337d1b35SAndrea Righi */
515337d1b35SAndrea Righi if (llc_cpus) {
51648849271SAndrea Righi cpu = pick_idle_cpu_in_node(llc_cpus, node, SCX_PICK_IDLE_CORE);
517337d1b35SAndrea Righi if (cpu >= 0)
518e4855fc9SAndrea Righi goto out_unlock;
519337d1b35SAndrea Righi }
520337d1b35SAndrea Righi
521337d1b35SAndrea Righi /*
522337d1b35SAndrea Righi * Search for any fully idle core in the same NUMA node.
523337d1b35SAndrea Righi */
524337d1b35SAndrea Righi if (numa_cpus) {
52548849271SAndrea Righi cpu = pick_idle_cpu_in_node(numa_cpus, node, SCX_PICK_IDLE_CORE);
526337d1b35SAndrea Righi if (cpu >= 0)
527e4855fc9SAndrea Righi goto out_unlock;
528337d1b35SAndrea Righi }
529337d1b35SAndrea Righi
530337d1b35SAndrea Righi /*
531c414c217SAndrea Righi * Search for any full-idle core usable by the task.
53248849271SAndrea Righi *
533c414c217SAndrea Righi * If the node-aware idle CPU selection policy is enabled
534c414c217SAndrea Righi * (%SCX_OPS_BUILTIN_IDLE_PER_NODE), the search will always
53548849271SAndrea Righi * begin in prev_cpu's node and proceed to other nodes in
53648849271SAndrea Righi * order of increasing distance.
537337d1b35SAndrea Righi */
538c414c217SAndrea Righi cpu = scx_pick_idle_cpu(p->cpus_ptr, node, flags | SCX_PICK_IDLE_CORE);
539337d1b35SAndrea Righi if (cpu >= 0)
540e4855fc9SAndrea Righi goto out_unlock;
541c414c217SAndrea Righi
542c414c217SAndrea Righi /*
543c414c217SAndrea Righi * Give up if we're strictly looking for a full-idle SMT
544c414c217SAndrea Righi * core.
545c414c217SAndrea Righi */
546c414c217SAndrea Righi if (flags & SCX_PICK_IDLE_CORE) {
54737477d9eSAndrea Righi cpu = -EBUSY;
548c414c217SAndrea Righi goto out_unlock;
549c414c217SAndrea Righi }
550337d1b35SAndrea Righi }
551337d1b35SAndrea Righi
552337d1b35SAndrea Righi /*
553337d1b35SAndrea Righi * Use @prev_cpu if it's idle.
554337d1b35SAndrea Righi */
555337d1b35SAndrea Righi if (scx_idle_test_and_clear_cpu(prev_cpu)) {
556337d1b35SAndrea Righi cpu = prev_cpu;
557e4855fc9SAndrea Righi goto out_unlock;
558337d1b35SAndrea Righi }
559337d1b35SAndrea Righi
560337d1b35SAndrea Righi /*
561337d1b35SAndrea Righi * Search for any idle CPU in the same LLC domain.
562337d1b35SAndrea Righi */
563337d1b35SAndrea Righi if (llc_cpus) {
56448849271SAndrea Righi cpu = pick_idle_cpu_in_node(llc_cpus, node, 0);
565337d1b35SAndrea Righi if (cpu >= 0)
566e4855fc9SAndrea Righi goto out_unlock;
567337d1b35SAndrea Righi }
568337d1b35SAndrea Righi
569337d1b35SAndrea Righi /*
570337d1b35SAndrea Righi * Search for any idle CPU in the same NUMA node.
571337d1b35SAndrea Righi */
572337d1b35SAndrea Righi if (numa_cpus) {
57348849271SAndrea Righi cpu = pick_idle_cpu_in_node(numa_cpus, node, 0);
574337d1b35SAndrea Righi if (cpu >= 0)
575e4855fc9SAndrea Righi goto out_unlock;
576337d1b35SAndrea Righi }
577337d1b35SAndrea Righi
578337d1b35SAndrea Righi /*
579337d1b35SAndrea Righi * Search for any idle CPU usable by the task.
580c414c217SAndrea Righi *
581c414c217SAndrea Righi * If the node-aware idle CPU selection policy is enabled
582c414c217SAndrea Righi * (%SCX_OPS_BUILTIN_IDLE_PER_NODE), the search will always begin
583c414c217SAndrea Righi * in prev_cpu's node and proceed to other nodes in order of
584c414c217SAndrea Righi * increasing distance.
585337d1b35SAndrea Righi */
586c414c217SAndrea Righi cpu = scx_pick_idle_cpu(p->cpus_ptr, node, flags);
587337d1b35SAndrea Righi
588c414c217SAndrea Righi out_unlock:
589337d1b35SAndrea Righi rcu_read_unlock();
590337d1b35SAndrea Righi
591337d1b35SAndrea Righi return cpu;
592337d1b35SAndrea Righi }
593337d1b35SAndrea Righi
59448849271SAndrea Righi /*
59548849271SAndrea Righi * Initialize global and per-node idle cpumasks.
59648849271SAndrea Righi */
scx_idle_init_masks(void)597337d1b35SAndrea Righi void scx_idle_init_masks(void)
598337d1b35SAndrea Righi {
59948849271SAndrea Righi int node;
60048849271SAndrea Righi
60148849271SAndrea Righi /* Allocate global idle cpumasks */
60248849271SAndrea Righi BUG_ON(!alloc_cpumask_var(&scx_idle_global_masks.cpu, GFP_KERNEL));
60348849271SAndrea Righi BUG_ON(!alloc_cpumask_var(&scx_idle_global_masks.smt, GFP_KERNEL));
60448849271SAndrea Righi
60548849271SAndrea Righi /* Allocate per-node idle cpumasks */
60648849271SAndrea Righi scx_idle_node_masks = kcalloc(num_possible_nodes(),
60748849271SAndrea Righi sizeof(*scx_idle_node_masks), GFP_KERNEL);
60848849271SAndrea Righi BUG_ON(!scx_idle_node_masks);
60948849271SAndrea Righi
61048849271SAndrea Righi for_each_node(node) {
61148849271SAndrea Righi scx_idle_node_masks[node] = kzalloc_node(sizeof(**scx_idle_node_masks),
61248849271SAndrea Righi GFP_KERNEL, node);
61348849271SAndrea Righi BUG_ON(!scx_idle_node_masks[node]);
61448849271SAndrea Righi
61548849271SAndrea Righi BUG_ON(!alloc_cpumask_var_node(&scx_idle_node_masks[node]->cpu, GFP_KERNEL, node));
61648849271SAndrea Righi BUG_ON(!alloc_cpumask_var_node(&scx_idle_node_masks[node]->smt, GFP_KERNEL, node));
61748849271SAndrea Righi }
618337d1b35SAndrea Righi }
619337d1b35SAndrea Righi
update_builtin_idle(int cpu,bool idle)620337d1b35SAndrea Righi static void update_builtin_idle(int cpu, bool idle)
621337d1b35SAndrea Righi {
62248849271SAndrea Righi int node = scx_cpu_node_if_enabled(cpu);
62348849271SAndrea Righi struct cpumask *idle_cpus = idle_cpumask(node)->cpu;
62448849271SAndrea Righi
62548849271SAndrea Righi assign_cpu(cpu, idle_cpus, idle);
626337d1b35SAndrea Righi
627337d1b35SAndrea Righi #ifdef CONFIG_SCHED_SMT
628337d1b35SAndrea Righi if (sched_smt_active()) {
629337d1b35SAndrea Righi const struct cpumask *smt = cpu_smt_mask(cpu);
63048849271SAndrea Righi struct cpumask *idle_smts = idle_cpumask(node)->smt;
631337d1b35SAndrea Righi
632337d1b35SAndrea Righi if (idle) {
633337d1b35SAndrea Righi /*
63448849271SAndrea Righi * idle_smt handling is racy but that's fine as it's
63548849271SAndrea Righi * only for optimization and self-correcting.
636337d1b35SAndrea Righi */
63748849271SAndrea Righi if (!cpumask_subset(smt, idle_cpus))
638337d1b35SAndrea Righi return;
63948849271SAndrea Righi cpumask_or(idle_smts, idle_smts, smt);
640337d1b35SAndrea Righi } else {
64148849271SAndrea Righi cpumask_andnot(idle_smts, idle_smts, smt);
642337d1b35SAndrea Righi }
643337d1b35SAndrea Righi }
644337d1b35SAndrea Righi #endif
645337d1b35SAndrea Righi }
646337d1b35SAndrea Righi
647337d1b35SAndrea Righi /*
648337d1b35SAndrea Righi * Update the idle state of a CPU to @idle.
649337d1b35SAndrea Righi *
650337d1b35SAndrea Righi * If @do_notify is true, ops.update_idle() is invoked to notify the scx
651337d1b35SAndrea Righi * scheduler of an actual idle state transition (idle to busy or vice
652337d1b35SAndrea Righi * versa). If @do_notify is false, only the idle state in the idle masks is
653337d1b35SAndrea Righi * refreshed without invoking ops.update_idle().
654337d1b35SAndrea Righi *
655337d1b35SAndrea Righi * This distinction is necessary, because an idle CPU can be "reserved" and
656337d1b35SAndrea Righi * awakened via scx_bpf_pick_idle_cpu() + scx_bpf_kick_cpu(), marking it as
657337d1b35SAndrea Righi * busy even if no tasks are dispatched. In this case, the CPU may return
658337d1b35SAndrea Righi * to idle without a true state transition. Refreshing the idle masks
659337d1b35SAndrea Righi * without invoking ops.update_idle() ensures accurate idle state tracking
660337d1b35SAndrea Righi * while avoiding unnecessary updates and maintaining balanced state
661337d1b35SAndrea Righi * transitions.
662337d1b35SAndrea Righi */
__scx_update_idle(struct rq * rq,bool idle,bool do_notify)663337d1b35SAndrea Righi void __scx_update_idle(struct rq *rq, bool idle, bool do_notify)
664337d1b35SAndrea Righi {
665337d1b35SAndrea Righi int cpu = cpu_of(rq);
666337d1b35SAndrea Righi
667337d1b35SAndrea Righi lockdep_assert_rq_held(rq);
668337d1b35SAndrea Righi
669337d1b35SAndrea Righi /*
670337d1b35SAndrea Righi * Trigger ops.update_idle() only when transitioning from a task to
671337d1b35SAndrea Righi * the idle thread and vice versa.
672337d1b35SAndrea Righi *
673337d1b35SAndrea Righi * Idle transitions are indicated by do_notify being set to true,
674337d1b35SAndrea Righi * managed by put_prev_task_idle()/set_next_task_idle().
675337d1b35SAndrea Righi */
676337d1b35SAndrea Righi if (SCX_HAS_OP(update_idle) && do_notify && !scx_rq_bypassing(rq))
677337d1b35SAndrea Righi SCX_CALL_OP(SCX_KF_REST, update_idle, cpu_of(rq), idle);
678337d1b35SAndrea Righi
679337d1b35SAndrea Righi /*
680337d1b35SAndrea Righi * Update the idle masks:
681337d1b35SAndrea Righi * - for real idle transitions (do_notify == true)
682337d1b35SAndrea Righi * - for idle-to-idle transitions (indicated by the previous task
683337d1b35SAndrea Righi * being the idle thread, managed by pick_task_idle())
684337d1b35SAndrea Righi *
685337d1b35SAndrea Righi * Skip updating idle masks if the previous task is not the idle
686337d1b35SAndrea Righi * thread, since set_next_task_idle() has already handled it when
687337d1b35SAndrea Righi * transitioning from a task to the idle thread (calling this
688337d1b35SAndrea Righi * function with do_notify == true).
689337d1b35SAndrea Righi *
690337d1b35SAndrea Righi * In this way we can avoid updating the idle masks twice,
691337d1b35SAndrea Righi * unnecessarily.
692337d1b35SAndrea Righi */
693337d1b35SAndrea Righi if (static_branch_likely(&scx_builtin_idle_enabled))
694337d1b35SAndrea Righi if (do_notify || is_idle_task(rq->curr))
695337d1b35SAndrea Righi update_builtin_idle(cpu, idle);
696337d1b35SAndrea Righi }
69748849271SAndrea Righi
reset_idle_masks(struct sched_ext_ops * ops)69848849271SAndrea Righi static void reset_idle_masks(struct sched_ext_ops *ops)
69948849271SAndrea Righi {
70048849271SAndrea Righi int node;
70148849271SAndrea Righi
70248849271SAndrea Righi /*
70348849271SAndrea Righi * Consider all online cpus idle. Should converge to the actual state
70448849271SAndrea Righi * quickly.
70548849271SAndrea Righi */
70648849271SAndrea Righi if (!(ops->flags & SCX_OPS_BUILTIN_IDLE_PER_NODE)) {
70748849271SAndrea Righi cpumask_copy(idle_cpumask(NUMA_NO_NODE)->cpu, cpu_online_mask);
70848849271SAndrea Righi cpumask_copy(idle_cpumask(NUMA_NO_NODE)->smt, cpu_online_mask);
70948849271SAndrea Righi return;
71048849271SAndrea Righi }
71148849271SAndrea Righi
71248849271SAndrea Righi for_each_node(node) {
71348849271SAndrea Righi const struct cpumask *node_mask = cpumask_of_node(node);
71448849271SAndrea Righi
71548849271SAndrea Righi cpumask_and(idle_cpumask(node)->cpu, cpu_online_mask, node_mask);
71648849271SAndrea Righi cpumask_and(idle_cpumask(node)->smt, cpu_online_mask, node_mask);
71748849271SAndrea Righi }
71848849271SAndrea Righi }
719337d1b35SAndrea Righi #endif /* CONFIG_SMP */
720337d1b35SAndrea Righi
scx_idle_enable(struct sched_ext_ops * ops)721d73249f8SAndrea Righi void scx_idle_enable(struct sched_ext_ops *ops)
722d73249f8SAndrea Righi {
72348849271SAndrea Righi if (!ops->update_idle || (ops->flags & SCX_OPS_KEEP_BUILTIN_IDLE))
724*f0c6eab5SAndrea Righi static_branch_enable_cpuslocked(&scx_builtin_idle_enabled);
72548849271SAndrea Righi else
726*f0c6eab5SAndrea Righi static_branch_disable_cpuslocked(&scx_builtin_idle_enabled);
727d73249f8SAndrea Righi
7280aaaf89dSAndrea Righi if (ops->flags & SCX_OPS_BUILTIN_IDLE_PER_NODE)
729*f0c6eab5SAndrea Righi static_branch_enable_cpuslocked(&scx_builtin_idle_per_node);
7300aaaf89dSAndrea Righi else
731*f0c6eab5SAndrea Righi static_branch_disable_cpuslocked(&scx_builtin_idle_per_node);
7320aaaf89dSAndrea Righi
733d73249f8SAndrea Righi #ifdef CONFIG_SMP
73448849271SAndrea Righi reset_idle_masks(ops);
735d73249f8SAndrea Righi #endif
736d73249f8SAndrea Righi }
737d73249f8SAndrea Righi
scx_idle_disable(void)738d73249f8SAndrea Righi void scx_idle_disable(void)
739d73249f8SAndrea Righi {
740d73249f8SAndrea Righi static_branch_disable(&scx_builtin_idle_enabled);
7410aaaf89dSAndrea Righi static_branch_disable(&scx_builtin_idle_per_node);
742d73249f8SAndrea Righi }
743d73249f8SAndrea Righi
744337d1b35SAndrea Righi /********************************************************************************
745337d1b35SAndrea Righi * Helpers that can be called from the BPF scheduler.
746337d1b35SAndrea Righi */
74701059219SAndrea Righi
validate_node(int node)74801059219SAndrea Righi static int validate_node(int node)
74901059219SAndrea Righi {
75001059219SAndrea Righi if (!static_branch_likely(&scx_builtin_idle_per_node)) {
75101059219SAndrea Righi scx_ops_error("per-node idle tracking is disabled");
75201059219SAndrea Righi return -EOPNOTSUPP;
75301059219SAndrea Righi }
75401059219SAndrea Righi
75501059219SAndrea Righi /* Return no entry for NUMA_NO_NODE (not a critical scx error) */
75601059219SAndrea Righi if (node == NUMA_NO_NODE)
75701059219SAndrea Righi return -ENOENT;
75801059219SAndrea Righi
75901059219SAndrea Righi /* Make sure node is in a valid range */
76001059219SAndrea Righi if (node < 0 || node >= nr_node_ids) {
76101059219SAndrea Righi scx_ops_error("invalid node %d", node);
76201059219SAndrea Righi return -EINVAL;
76301059219SAndrea Righi }
76401059219SAndrea Righi
76501059219SAndrea Righi /* Make sure the node is part of the set of possible nodes */
76601059219SAndrea Righi if (!node_possible(node)) {
76701059219SAndrea Righi scx_ops_error("unavailable node %d", node);
76801059219SAndrea Righi return -EINVAL;
76901059219SAndrea Righi }
77001059219SAndrea Righi
77101059219SAndrea Righi return node;
77201059219SAndrea Righi }
77301059219SAndrea Righi
774337d1b35SAndrea Righi __bpf_kfunc_start_defs();
775337d1b35SAndrea Righi
check_builtin_idle_enabled(void)776337d1b35SAndrea Righi static bool check_builtin_idle_enabled(void)
777337d1b35SAndrea Righi {
778337d1b35SAndrea Righi if (static_branch_likely(&scx_builtin_idle_enabled))
779337d1b35SAndrea Righi return true;
780337d1b35SAndrea Righi
781337d1b35SAndrea Righi scx_ops_error("built-in idle tracking is disabled");
782337d1b35SAndrea Righi return false;
783337d1b35SAndrea Righi }
784337d1b35SAndrea Righi
785337d1b35SAndrea Righi /**
78601059219SAndrea Righi * scx_bpf_cpu_node - Return the NUMA node the given @cpu belongs to, or
78701059219SAndrea Righi * trigger an error if @cpu is invalid
78801059219SAndrea Righi * @cpu: target CPU
78901059219SAndrea Righi */
scx_bpf_cpu_node(s32 cpu)79001059219SAndrea Righi __bpf_kfunc int scx_bpf_cpu_node(s32 cpu)
79101059219SAndrea Righi {
79201059219SAndrea Righi #ifdef CONFIG_NUMA
79301059219SAndrea Righi if (!ops_cpu_valid(cpu, NULL))
79401059219SAndrea Righi return NUMA_NO_NODE;
79501059219SAndrea Righi
79601059219SAndrea Righi return cpu_to_node(cpu);
79701059219SAndrea Righi #else
79801059219SAndrea Righi return 0;
79901059219SAndrea Righi #endif
80001059219SAndrea Righi }
80101059219SAndrea Righi
80201059219SAndrea Righi /**
803337d1b35SAndrea Righi * scx_bpf_select_cpu_dfl - The default implementation of ops.select_cpu()
804337d1b35SAndrea Righi * @p: task_struct to select a CPU for
805337d1b35SAndrea Righi * @prev_cpu: CPU @p was on previously
806337d1b35SAndrea Righi * @wake_flags: %SCX_WAKE_* flags
807337d1b35SAndrea Righi * @is_idle: out parameter indicating whether the returned CPU is idle
808337d1b35SAndrea Righi *
809337d1b35SAndrea Righi * Can only be called from ops.select_cpu() if the built-in CPU selection is
810337d1b35SAndrea Righi * enabled - ops.update_idle() is missing or %SCX_OPS_KEEP_BUILTIN_IDLE is set.
811337d1b35SAndrea Righi * @p, @prev_cpu and @wake_flags match ops.select_cpu().
812337d1b35SAndrea Righi *
813337d1b35SAndrea Righi * Returns the picked CPU with *@is_idle indicating whether the picked CPU is
814337d1b35SAndrea Righi * currently idle and thus a good candidate for direct dispatching.
815337d1b35SAndrea Righi */
scx_bpf_select_cpu_dfl(struct task_struct * p,s32 prev_cpu,u64 wake_flags,bool * is_idle)816337d1b35SAndrea Righi __bpf_kfunc s32 scx_bpf_select_cpu_dfl(struct task_struct *p, s32 prev_cpu,
817337d1b35SAndrea Righi u64 wake_flags, bool *is_idle)
818337d1b35SAndrea Righi {
819e4855fc9SAndrea Righi #ifdef CONFIG_SMP
820e4855fc9SAndrea Righi s32 cpu;
821e4855fc9SAndrea Righi #endif
8228a9b1585STejun Heo if (!ops_cpu_valid(prev_cpu, NULL))
8238a9b1585STejun Heo goto prev_cpu;
8248a9b1585STejun Heo
825337d1b35SAndrea Righi if (!check_builtin_idle_enabled())
826337d1b35SAndrea Righi goto prev_cpu;
827337d1b35SAndrea Righi
828337d1b35SAndrea Righi if (!scx_kf_allowed(SCX_KF_SELECT_CPU))
829337d1b35SAndrea Righi goto prev_cpu;
830337d1b35SAndrea Righi
831337d1b35SAndrea Righi #ifdef CONFIG_SMP
832e4855fc9SAndrea Righi cpu = scx_select_cpu_dfl(p, prev_cpu, wake_flags, 0);
833e4855fc9SAndrea Righi if (cpu >= 0) {
834e4855fc9SAndrea Righi *is_idle = true;
835e4855fc9SAndrea Righi return cpu;
836e4855fc9SAndrea Righi }
837337d1b35SAndrea Righi #endif
838337d1b35SAndrea Righi
839337d1b35SAndrea Righi prev_cpu:
840337d1b35SAndrea Righi *is_idle = false;
841337d1b35SAndrea Righi return prev_cpu;
842337d1b35SAndrea Righi }
843337d1b35SAndrea Righi
844337d1b35SAndrea Righi /**
84501059219SAndrea Righi * scx_bpf_get_idle_cpumask_node - Get a referenced kptr to the
84601059219SAndrea Righi * idle-tracking per-CPU cpumask of a target NUMA node.
84701059219SAndrea Righi * @node: target NUMA node
84801059219SAndrea Righi *
84901059219SAndrea Righi * Returns an empty cpumask if idle tracking is not enabled, if @node is
85001059219SAndrea Righi * not valid, or running on a UP kernel. In this case the actual error will
85101059219SAndrea Righi * be reported to the BPF scheduler via scx_ops_error().
85201059219SAndrea Righi */
scx_bpf_get_idle_cpumask_node(int node)85301059219SAndrea Righi __bpf_kfunc const struct cpumask *scx_bpf_get_idle_cpumask_node(int node)
85401059219SAndrea Righi {
85501059219SAndrea Righi node = validate_node(node);
85601059219SAndrea Righi if (node < 0)
85701059219SAndrea Righi return cpu_none_mask;
85801059219SAndrea Righi
85901059219SAndrea Righi #ifdef CONFIG_SMP
86001059219SAndrea Righi return idle_cpumask(node)->cpu;
86101059219SAndrea Righi #else
86201059219SAndrea Righi return cpu_none_mask;
86301059219SAndrea Righi #endif
86401059219SAndrea Righi }
86501059219SAndrea Righi
86601059219SAndrea Righi /**
867337d1b35SAndrea Righi * scx_bpf_get_idle_cpumask - Get a referenced kptr to the idle-tracking
868337d1b35SAndrea Righi * per-CPU cpumask.
869337d1b35SAndrea Righi *
87048849271SAndrea Righi * Returns an empty mask if idle tracking is not enabled, or running on a
87148849271SAndrea Righi * UP kernel.
872337d1b35SAndrea Righi */
scx_bpf_get_idle_cpumask(void)873337d1b35SAndrea Righi __bpf_kfunc const struct cpumask *scx_bpf_get_idle_cpumask(void)
874337d1b35SAndrea Righi {
87548849271SAndrea Righi if (static_branch_unlikely(&scx_builtin_idle_per_node)) {
87648849271SAndrea Righi scx_ops_error("SCX_OPS_BUILTIN_IDLE_PER_NODE enabled");
87748849271SAndrea Righi return cpu_none_mask;
87848849271SAndrea Righi }
87948849271SAndrea Righi
880337d1b35SAndrea Righi if (!check_builtin_idle_enabled())
881337d1b35SAndrea Righi return cpu_none_mask;
882337d1b35SAndrea Righi
883337d1b35SAndrea Righi #ifdef CONFIG_SMP
88448849271SAndrea Righi return idle_cpumask(NUMA_NO_NODE)->cpu;
885337d1b35SAndrea Righi #else
886337d1b35SAndrea Righi return cpu_none_mask;
887337d1b35SAndrea Righi #endif
888337d1b35SAndrea Righi }
889337d1b35SAndrea Righi
890337d1b35SAndrea Righi /**
89101059219SAndrea Righi * scx_bpf_get_idle_smtmask_node - Get a referenced kptr to the
89201059219SAndrea Righi * idle-tracking, per-physical-core cpumask of a target NUMA node. Can be
89301059219SAndrea Righi * used to determine if an entire physical core is free.
89401059219SAndrea Righi * @node: target NUMA node
89501059219SAndrea Righi *
89601059219SAndrea Righi * Returns an empty cpumask if idle tracking is not enabled, if @node is
89701059219SAndrea Righi * not valid, or running on a UP kernel. In this case the actual error will
89801059219SAndrea Righi * be reported to the BPF scheduler via scx_ops_error().
89901059219SAndrea Righi */
scx_bpf_get_idle_smtmask_node(int node)90001059219SAndrea Righi __bpf_kfunc const struct cpumask *scx_bpf_get_idle_smtmask_node(int node)
90101059219SAndrea Righi {
90201059219SAndrea Righi node = validate_node(node);
90301059219SAndrea Righi if (node < 0)
90401059219SAndrea Righi return cpu_none_mask;
90501059219SAndrea Righi
90601059219SAndrea Righi #ifdef CONFIG_SMP
90701059219SAndrea Righi if (sched_smt_active())
90801059219SAndrea Righi return idle_cpumask(node)->smt;
90901059219SAndrea Righi else
91001059219SAndrea Righi return idle_cpumask(node)->cpu;
91101059219SAndrea Righi #else
91201059219SAndrea Righi return cpu_none_mask;
91301059219SAndrea Righi #endif
91401059219SAndrea Righi }
91501059219SAndrea Righi
91601059219SAndrea Righi /**
917337d1b35SAndrea Righi * scx_bpf_get_idle_smtmask - Get a referenced kptr to the idle-tracking,
918337d1b35SAndrea Righi * per-physical-core cpumask. Can be used to determine if an entire physical
919337d1b35SAndrea Righi * core is free.
920337d1b35SAndrea Righi *
92148849271SAndrea Righi * Returns an empty mask if idle tracking is not enabled, or running on a
92248849271SAndrea Righi * UP kernel.
923337d1b35SAndrea Righi */
scx_bpf_get_idle_smtmask(void)924337d1b35SAndrea Righi __bpf_kfunc const struct cpumask *scx_bpf_get_idle_smtmask(void)
925337d1b35SAndrea Righi {
92648849271SAndrea Righi if (static_branch_unlikely(&scx_builtin_idle_per_node)) {
92748849271SAndrea Righi scx_ops_error("SCX_OPS_BUILTIN_IDLE_PER_NODE enabled");
92848849271SAndrea Righi return cpu_none_mask;
92948849271SAndrea Righi }
93048849271SAndrea Righi
931337d1b35SAndrea Righi if (!check_builtin_idle_enabled())
932337d1b35SAndrea Righi return cpu_none_mask;
933337d1b35SAndrea Righi
934337d1b35SAndrea Righi #ifdef CONFIG_SMP
935337d1b35SAndrea Righi if (sched_smt_active())
93648849271SAndrea Righi return idle_cpumask(NUMA_NO_NODE)->smt;
937337d1b35SAndrea Righi else
93848849271SAndrea Righi return idle_cpumask(NUMA_NO_NODE)->cpu;
939337d1b35SAndrea Righi #else
940337d1b35SAndrea Righi return cpu_none_mask;
941337d1b35SAndrea Righi #endif
942337d1b35SAndrea Righi }
943337d1b35SAndrea Righi
944337d1b35SAndrea Righi /**
945337d1b35SAndrea Righi * scx_bpf_put_idle_cpumask - Release a previously acquired referenced kptr to
946337d1b35SAndrea Righi * either the percpu, or SMT idle-tracking cpumask.
947337d1b35SAndrea Righi * @idle_mask: &cpumask to use
948337d1b35SAndrea Righi */
scx_bpf_put_idle_cpumask(const struct cpumask * idle_mask)949337d1b35SAndrea Righi __bpf_kfunc void scx_bpf_put_idle_cpumask(const struct cpumask *idle_mask)
950337d1b35SAndrea Righi {
951337d1b35SAndrea Righi /*
952337d1b35SAndrea Righi * Empty function body because we aren't actually acquiring or releasing
953337d1b35SAndrea Righi * a reference to a global idle cpumask, which is read-only in the
954337d1b35SAndrea Righi * caller and is never released. The acquire / release semantics here
955337d1b35SAndrea Righi * are just used to make the cpumask a trusted pointer in the caller.
956337d1b35SAndrea Righi */
957337d1b35SAndrea Righi }
958337d1b35SAndrea Righi
959337d1b35SAndrea Righi /**
960337d1b35SAndrea Righi * scx_bpf_test_and_clear_cpu_idle - Test and clear @cpu's idle state
961337d1b35SAndrea Righi * @cpu: cpu to test and clear idle for
962337d1b35SAndrea Righi *
963337d1b35SAndrea Righi * Returns %true if @cpu was idle and its idle state was successfully cleared.
964337d1b35SAndrea Righi * %false otherwise.
965337d1b35SAndrea Righi *
966337d1b35SAndrea Righi * Unavailable if ops.update_idle() is implemented and
967337d1b35SAndrea Righi * %SCX_OPS_KEEP_BUILTIN_IDLE is not set.
968337d1b35SAndrea Righi */
scx_bpf_test_and_clear_cpu_idle(s32 cpu)969337d1b35SAndrea Righi __bpf_kfunc bool scx_bpf_test_and_clear_cpu_idle(s32 cpu)
970337d1b35SAndrea Righi {
971337d1b35SAndrea Righi if (!check_builtin_idle_enabled())
972337d1b35SAndrea Righi return false;
973337d1b35SAndrea Righi
974337d1b35SAndrea Righi if (ops_cpu_valid(cpu, NULL))
975337d1b35SAndrea Righi return scx_idle_test_and_clear_cpu(cpu);
976337d1b35SAndrea Righi else
977337d1b35SAndrea Righi return false;
978337d1b35SAndrea Righi }
979337d1b35SAndrea Righi
980337d1b35SAndrea Righi /**
98101059219SAndrea Righi * scx_bpf_pick_idle_cpu_node - Pick and claim an idle cpu from @node
98201059219SAndrea Righi * @cpus_allowed: Allowed cpumask
98301059219SAndrea Righi * @node: target NUMA node
98401059219SAndrea Righi * @flags: %SCX_PICK_IDLE_* flags
98501059219SAndrea Righi *
98601059219SAndrea Righi * Pick and claim an idle cpu in @cpus_allowed from the NUMA node @node.
98701059219SAndrea Righi *
98801059219SAndrea Righi * Returns the picked idle cpu number on success, or -%EBUSY if no matching
98901059219SAndrea Righi * cpu was found.
99001059219SAndrea Righi *
99101059219SAndrea Righi * The search starts from @node and proceeds to other online NUMA nodes in
99201059219SAndrea Righi * order of increasing distance (unless SCX_PICK_IDLE_IN_NODE is specified,
99301059219SAndrea Righi * in which case the search is limited to the target @node).
99401059219SAndrea Righi *
99501059219SAndrea Righi * Always returns an error if ops.update_idle() is implemented and
99601059219SAndrea Righi * %SCX_OPS_KEEP_BUILTIN_IDLE is not set, or if
99701059219SAndrea Righi * %SCX_OPS_BUILTIN_IDLE_PER_NODE is not set.
99801059219SAndrea Righi */
scx_bpf_pick_idle_cpu_node(const struct cpumask * cpus_allowed,int node,u64 flags)99901059219SAndrea Righi __bpf_kfunc s32 scx_bpf_pick_idle_cpu_node(const struct cpumask *cpus_allowed,
100001059219SAndrea Righi int node, u64 flags)
100101059219SAndrea Righi {
100201059219SAndrea Righi node = validate_node(node);
100301059219SAndrea Righi if (node < 0)
100401059219SAndrea Righi return node;
100501059219SAndrea Righi
100601059219SAndrea Righi return scx_pick_idle_cpu(cpus_allowed, node, flags);
100701059219SAndrea Righi }
100801059219SAndrea Righi
100901059219SAndrea Righi /**
1010337d1b35SAndrea Righi * scx_bpf_pick_idle_cpu - Pick and claim an idle cpu
1011337d1b35SAndrea Righi * @cpus_allowed: Allowed cpumask
1012337d1b35SAndrea Righi * @flags: %SCX_PICK_IDLE_CPU_* flags
1013337d1b35SAndrea Righi *
1014337d1b35SAndrea Righi * Pick and claim an idle cpu in @cpus_allowed. Returns the picked idle cpu
1015337d1b35SAndrea Righi * number on success. -%EBUSY if no matching cpu was found.
1016337d1b35SAndrea Righi *
1017337d1b35SAndrea Righi * Idle CPU tracking may race against CPU scheduling state transitions. For
1018337d1b35SAndrea Righi * example, this function may return -%EBUSY as CPUs are transitioning into the
1019337d1b35SAndrea Righi * idle state. If the caller then assumes that there will be dispatch events on
1020337d1b35SAndrea Righi * the CPUs as they were all busy, the scheduler may end up stalling with CPUs
1021337d1b35SAndrea Righi * idling while there are pending tasks. Use scx_bpf_pick_any_cpu() and
1022337d1b35SAndrea Righi * scx_bpf_kick_cpu() to guarantee that there will be at least one dispatch
1023337d1b35SAndrea Righi * event in the near future.
1024337d1b35SAndrea Righi *
1025337d1b35SAndrea Righi * Unavailable if ops.update_idle() is implemented and
1026337d1b35SAndrea Righi * %SCX_OPS_KEEP_BUILTIN_IDLE is not set.
102701059219SAndrea Righi *
102801059219SAndrea Righi * Always returns an error if %SCX_OPS_BUILTIN_IDLE_PER_NODE is set, use
102901059219SAndrea Righi * scx_bpf_pick_idle_cpu_node() instead.
1030337d1b35SAndrea Righi */
scx_bpf_pick_idle_cpu(const struct cpumask * cpus_allowed,u64 flags)1031337d1b35SAndrea Righi __bpf_kfunc s32 scx_bpf_pick_idle_cpu(const struct cpumask *cpus_allowed,
1032337d1b35SAndrea Righi u64 flags)
1033337d1b35SAndrea Righi {
103401059219SAndrea Righi if (static_branch_maybe(CONFIG_NUMA, &scx_builtin_idle_per_node)) {
103501059219SAndrea Righi scx_ops_error("per-node idle tracking is enabled");
103601059219SAndrea Righi return -EBUSY;
103701059219SAndrea Righi }
103801059219SAndrea Righi
1039337d1b35SAndrea Righi if (!check_builtin_idle_enabled())
1040337d1b35SAndrea Righi return -EBUSY;
1041337d1b35SAndrea Righi
104248849271SAndrea Righi return scx_pick_idle_cpu(cpus_allowed, NUMA_NO_NODE, flags);
1043337d1b35SAndrea Righi }
1044337d1b35SAndrea Righi
1045337d1b35SAndrea Righi /**
104601059219SAndrea Righi * scx_bpf_pick_any_cpu_node - Pick and claim an idle cpu if available
104701059219SAndrea Righi * or pick any CPU from @node
104801059219SAndrea Righi * @cpus_allowed: Allowed cpumask
104901059219SAndrea Righi * @node: target NUMA node
105001059219SAndrea Righi * @flags: %SCX_PICK_IDLE_CPU_* flags
105101059219SAndrea Righi *
105201059219SAndrea Righi * Pick and claim an idle cpu in @cpus_allowed. If none is available, pick any
105301059219SAndrea Righi * CPU in @cpus_allowed. Guaranteed to succeed and returns the picked idle cpu
105401059219SAndrea Righi * number if @cpus_allowed is not empty. -%EBUSY is returned if @cpus_allowed is
105501059219SAndrea Righi * empty.
105601059219SAndrea Righi *
105701059219SAndrea Righi * The search starts from @node and proceeds to other online NUMA nodes in
1058fde7d647SAndrea Righi * order of increasing distance (unless %SCX_PICK_IDLE_IN_NODE is specified,
1059fde7d647SAndrea Righi * in which case the search is limited to the target @node, regardless of
1060fde7d647SAndrea Righi * the CPU idle state).
106101059219SAndrea Righi *
106201059219SAndrea Righi * If ops.update_idle() is implemented and %SCX_OPS_KEEP_BUILTIN_IDLE is not
106301059219SAndrea Righi * set, this function can't tell which CPUs are idle and will always pick any
106401059219SAndrea Righi * CPU.
106501059219SAndrea Righi */
scx_bpf_pick_any_cpu_node(const struct cpumask * cpus_allowed,int node,u64 flags)106601059219SAndrea Righi __bpf_kfunc s32 scx_bpf_pick_any_cpu_node(const struct cpumask *cpus_allowed,
106701059219SAndrea Righi int node, u64 flags)
106801059219SAndrea Righi {
106901059219SAndrea Righi s32 cpu;
107001059219SAndrea Righi
107101059219SAndrea Righi node = validate_node(node);
107201059219SAndrea Righi if (node < 0)
107301059219SAndrea Righi return node;
107401059219SAndrea Righi
107501059219SAndrea Righi cpu = scx_pick_idle_cpu(cpus_allowed, node, flags);
107601059219SAndrea Righi if (cpu >= 0)
107701059219SAndrea Righi return cpu;
107801059219SAndrea Righi
1079fde7d647SAndrea Righi if (flags & SCX_PICK_IDLE_IN_NODE)
1080fde7d647SAndrea Righi cpu = cpumask_any_and_distribute(cpumask_of_node(node), cpus_allowed);
1081fde7d647SAndrea Righi else
108201059219SAndrea Righi cpu = cpumask_any_distribute(cpus_allowed);
108301059219SAndrea Righi if (cpu < nr_cpu_ids)
108401059219SAndrea Righi return cpu;
108501059219SAndrea Righi else
108601059219SAndrea Righi return -EBUSY;
108701059219SAndrea Righi }
108801059219SAndrea Righi
108901059219SAndrea Righi /**
1090337d1b35SAndrea Righi * scx_bpf_pick_any_cpu - Pick and claim an idle cpu if available or pick any CPU
1091337d1b35SAndrea Righi * @cpus_allowed: Allowed cpumask
1092337d1b35SAndrea Righi * @flags: %SCX_PICK_IDLE_CPU_* flags
1093337d1b35SAndrea Righi *
1094337d1b35SAndrea Righi * Pick and claim an idle cpu in @cpus_allowed. If none is available, pick any
1095337d1b35SAndrea Righi * CPU in @cpus_allowed. Guaranteed to succeed and returns the picked idle cpu
1096337d1b35SAndrea Righi * number if @cpus_allowed is not empty. -%EBUSY is returned if @cpus_allowed is
1097337d1b35SAndrea Righi * empty.
1098337d1b35SAndrea Righi *
1099337d1b35SAndrea Righi * If ops.update_idle() is implemented and %SCX_OPS_KEEP_BUILTIN_IDLE is not
1100337d1b35SAndrea Righi * set, this function can't tell which CPUs are idle and will always pick any
1101337d1b35SAndrea Righi * CPU.
110201059219SAndrea Righi *
110301059219SAndrea Righi * Always returns an error if %SCX_OPS_BUILTIN_IDLE_PER_NODE is set, use
110401059219SAndrea Righi * scx_bpf_pick_any_cpu_node() instead.
1105337d1b35SAndrea Righi */
scx_bpf_pick_any_cpu(const struct cpumask * cpus_allowed,u64 flags)1106337d1b35SAndrea Righi __bpf_kfunc s32 scx_bpf_pick_any_cpu(const struct cpumask *cpus_allowed,
1107337d1b35SAndrea Righi u64 flags)
1108337d1b35SAndrea Righi {
1109337d1b35SAndrea Righi s32 cpu;
1110337d1b35SAndrea Righi
111101059219SAndrea Righi if (static_branch_maybe(CONFIG_NUMA, &scx_builtin_idle_per_node)) {
111201059219SAndrea Righi scx_ops_error("per-node idle tracking is enabled");
111301059219SAndrea Righi return -EBUSY;
111401059219SAndrea Righi }
111501059219SAndrea Righi
1116337d1b35SAndrea Righi if (static_branch_likely(&scx_builtin_idle_enabled)) {
111748849271SAndrea Righi cpu = scx_pick_idle_cpu(cpus_allowed, NUMA_NO_NODE, flags);
1118337d1b35SAndrea Righi if (cpu >= 0)
1119337d1b35SAndrea Righi return cpu;
1120337d1b35SAndrea Righi }
1121337d1b35SAndrea Righi
1122337d1b35SAndrea Righi cpu = cpumask_any_distribute(cpus_allowed);
1123337d1b35SAndrea Righi if (cpu < nr_cpu_ids)
1124337d1b35SAndrea Righi return cpu;
1125337d1b35SAndrea Righi else
1126337d1b35SAndrea Righi return -EBUSY;
1127337d1b35SAndrea Righi }
1128337d1b35SAndrea Righi
1129337d1b35SAndrea Righi __bpf_kfunc_end_defs();
1130337d1b35SAndrea Righi
1131337d1b35SAndrea Righi BTF_KFUNCS_START(scx_kfunc_ids_idle)
113201059219SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_cpu_node)
113301059219SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_get_idle_cpumask_node, KF_ACQUIRE)
1134337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_get_idle_cpumask, KF_ACQUIRE)
113501059219SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_get_idle_smtmask_node, KF_ACQUIRE)
1136337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_get_idle_smtmask, KF_ACQUIRE)
1137337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_put_idle_cpumask, KF_RELEASE)
1138337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_test_and_clear_cpu_idle)
113901059219SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_pick_idle_cpu_node, KF_RCU)
1140337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_pick_idle_cpu, KF_RCU)
114101059219SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_pick_any_cpu_node, KF_RCU)
1142337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_pick_any_cpu, KF_RCU)
1143337d1b35SAndrea Righi BTF_KFUNCS_END(scx_kfunc_ids_idle)
1144337d1b35SAndrea Righi
1145337d1b35SAndrea Righi static const struct btf_kfunc_id_set scx_kfunc_set_idle = {
1146337d1b35SAndrea Righi .owner = THIS_MODULE,
1147337d1b35SAndrea Righi .set = &scx_kfunc_ids_idle,
1148337d1b35SAndrea Righi };
1149337d1b35SAndrea Righi
1150337d1b35SAndrea Righi BTF_KFUNCS_START(scx_kfunc_ids_select_cpu)
1151337d1b35SAndrea Righi BTF_ID_FLAGS(func, scx_bpf_select_cpu_dfl, KF_RCU)
1152337d1b35SAndrea Righi BTF_KFUNCS_END(scx_kfunc_ids_select_cpu)
1153337d1b35SAndrea Righi
1154337d1b35SAndrea Righi static const struct btf_kfunc_id_set scx_kfunc_set_select_cpu = {
1155337d1b35SAndrea Righi .owner = THIS_MODULE,
1156337d1b35SAndrea Righi .set = &scx_kfunc_ids_select_cpu,
1157337d1b35SAndrea Righi };
1158337d1b35SAndrea Righi
scx_idle_init(void)1159337d1b35SAndrea Righi int scx_idle_init(void)
1160337d1b35SAndrea Righi {
1161337d1b35SAndrea Righi int ret;
1162337d1b35SAndrea Righi
1163337d1b35SAndrea Righi ret = register_btf_kfunc_id_set(BPF_PROG_TYPE_STRUCT_OPS, &scx_kfunc_set_select_cpu) ||
1164337d1b35SAndrea Righi register_btf_kfunc_id_set(BPF_PROG_TYPE_STRUCT_OPS, &scx_kfunc_set_idle) ||
1165337d1b35SAndrea Righi register_btf_kfunc_id_set(BPF_PROG_TYPE_TRACING, &scx_kfunc_set_idle) ||
1166337d1b35SAndrea Righi register_btf_kfunc_id_set(BPF_PROG_TYPE_SYSCALL, &scx_kfunc_set_idle);
1167337d1b35SAndrea Righi
1168337d1b35SAndrea Righi return ret;
1169337d1b35SAndrea Righi }
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