linux-stable/tools/sched_ext/scx_flatcg.bpf.c
Tejun Heo 5209c03c8e sched_ext: Rename scx_bpf_consume() to scx_bpf_dsq_move_to_local()
In sched_ext API, a repeatedly reported pain point is the overuse of the
verb "dispatch" and confusion around "consume":

- ops.dispatch()
- scx_bpf_dispatch[_vtime]()
- scx_bpf_consume()
- scx_bpf_dispatch[_vtime]_from_dsq*()

This overloading of the term is historical. Originally, there were only
built-in DSQs and moving a task into a DSQ always dispatched it for
execution. Using the verb "dispatch" for the kfuncs to move tasks into these
DSQs made sense.

Later, user DSQs were added and scx_bpf_dispatch[_vtime]() updated to be
able to insert tasks into any DSQ. The only allowed DSQ to DSQ transfer was
from a non-local DSQ to a local DSQ and this operation was named "consume".
This was already confusing as a task could be dispatched to a user DSQ from
ops.enqueue() and then the DSQ would have to be consumed in ops.dispatch().
Later addition of scx_bpf_dispatch_from_dsq*() made the confusion even worse
as "dispatch" in this context meant moving a task to an arbitrary DSQ from a
user DSQ.

Clean up the API with the following renames:

1. scx_bpf_dispatch[_vtime]()		-> scx_bpf_dsq_insert[_vtime]()
2. scx_bpf_consume()			-> scx_bpf_dsq_move_to_local()
3. scx_bpf_dispatch[_vtime]_from_dsq*()	-> scx_bpf_dsq_move[_vtime]*()

This patch performs the second rename. Compatibility is maintained by:

- The previous kfunc names are still provided by the kernel so that old
  binaries can run. Kernel generates a warning when the old names are used.

- compat.bpf.h provides wrappers for the new names which automatically fall
  back to the old names when running on older kernels. They also trigger
  build error if old names are used for new builds.

The compat features will be dropped after v6.15.

v2: Comment and documentation updates.

Signed-off-by: Tejun Heo <tj@kernel.org>
Acked-by: Andrea Righi <arighi@nvidia.com>
Acked-by: Changwoo Min <changwoo@igalia.com>
Acked-by: Johannes Bechberger <me@mostlynerdless.de>
Acked-by: Giovanni Gherdovich <ggherdovich@suse.com>
Cc: Dan Schatzberg <dschatzberg@meta.com>
Cc: Ming Yang <yougmark94@gmail.com>
2024-11-11 07:06:16 -10:00

960 lines
24 KiB
C

/* SPDX-License-Identifier: GPL-2.0 */
/*
* A demo sched_ext flattened cgroup hierarchy scheduler. It implements
* hierarchical weight-based cgroup CPU control by flattening the cgroup
* hierarchy into a single layer by compounding the active weight share at each
* level. Consider the following hierarchy with weights in parentheses:
*
* R + A (100) + B (100)
* | \ C (100)
* \ D (200)
*
* Ignoring the root and threaded cgroups, only B, C and D can contain tasks.
* Let's say all three have runnable tasks. The total share that each of these
* three cgroups is entitled to can be calculated by compounding its share at
* each level.
*
* For example, B is competing against C and in that competition its share is
* 100/(100+100) == 1/2. At its parent level, A is competing against D and A's
* share in that competition is 100/(200+100) == 1/3. B's eventual share in the
* system can be calculated by multiplying the two shares, 1/2 * 1/3 == 1/6. C's
* eventual shaer is the same at 1/6. D is only competing at the top level and
* its share is 200/(100+200) == 2/3.
*
* So, instead of hierarchically scheduling level-by-level, we can consider it
* as B, C and D competing each other with respective share of 1/6, 1/6 and 2/3
* and keep updating the eventual shares as the cgroups' runnable states change.
*
* This flattening of hierarchy can bring a substantial performance gain when
* the cgroup hierarchy is nested multiple levels. in a simple benchmark using
* wrk[8] on apache serving a CGI script calculating sha1sum of a small file, it
* outperforms CFS by ~3% with CPU controller disabled and by ~10% with two
* apache instances competing with 2:1 weight ratio nested four level deep.
*
* However, the gain comes at the cost of not being able to properly handle
* thundering herd of cgroups. For example, if many cgroups which are nested
* behind a low priority parent cgroup wake up around the same time, they may be
* able to consume more CPU cycles than they are entitled to. In many use cases,
* this isn't a real concern especially given the performance gain. Also, there
* are ways to mitigate the problem further by e.g. introducing an extra
* scheduling layer on cgroup delegation boundaries.
*
* The scheduler first picks the cgroup to run and then schedule the tasks
* within by using nested weighted vtime scheduling by default. The
* cgroup-internal scheduling can be switched to FIFO with the -f option.
*/
#include <scx/common.bpf.h>
#include "scx_flatcg.h"
/*
* Maximum amount of retries to find a valid cgroup.
*/
enum {
FALLBACK_DSQ = 0,
CGROUP_MAX_RETRIES = 1024,
};
char _license[] SEC("license") = "GPL";
const volatile u32 nr_cpus = 32; /* !0 for veristat, set during init */
const volatile u64 cgrp_slice_ns = SCX_SLICE_DFL;
const volatile bool fifo_sched;
u64 cvtime_now;
UEI_DEFINE(uei);
struct {
__uint(type, BPF_MAP_TYPE_PERCPU_ARRAY);
__type(key, u32);
__type(value, u64);
__uint(max_entries, FCG_NR_STATS);
} stats SEC(".maps");
static void stat_inc(enum fcg_stat_idx idx)
{
u32 idx_v = idx;
u64 *cnt_p = bpf_map_lookup_elem(&stats, &idx_v);
if (cnt_p)
(*cnt_p)++;
}
struct fcg_cpu_ctx {
u64 cur_cgid;
u64 cur_at;
};
struct {
__uint(type, BPF_MAP_TYPE_PERCPU_ARRAY);
__type(key, u32);
__type(value, struct fcg_cpu_ctx);
__uint(max_entries, 1);
} cpu_ctx SEC(".maps");
struct {
__uint(type, BPF_MAP_TYPE_CGRP_STORAGE);
__uint(map_flags, BPF_F_NO_PREALLOC);
__type(key, int);
__type(value, struct fcg_cgrp_ctx);
} cgrp_ctx SEC(".maps");
struct cgv_node {
struct bpf_rb_node rb_node;
__u64 cvtime;
__u64 cgid;
};
private(CGV_TREE) struct bpf_spin_lock cgv_tree_lock;
private(CGV_TREE) struct bpf_rb_root cgv_tree __contains(cgv_node, rb_node);
struct cgv_node_stash {
struct cgv_node __kptr *node;
};
struct {
__uint(type, BPF_MAP_TYPE_HASH);
__uint(max_entries, 16384);
__type(key, __u64);
__type(value, struct cgv_node_stash);
} cgv_node_stash SEC(".maps");
struct fcg_task_ctx {
u64 bypassed_at;
};
struct {
__uint(type, BPF_MAP_TYPE_TASK_STORAGE);
__uint(map_flags, BPF_F_NO_PREALLOC);
__type(key, int);
__type(value, struct fcg_task_ctx);
} task_ctx SEC(".maps");
/* gets inc'd on weight tree changes to expire the cached hweights */
u64 hweight_gen = 1;
static u64 div_round_up(u64 dividend, u64 divisor)
{
return (dividend + divisor - 1) / divisor;
}
static bool vtime_before(u64 a, u64 b)
{
return (s64)(a - b) < 0;
}
static bool cgv_node_less(struct bpf_rb_node *a, const struct bpf_rb_node *b)
{
struct cgv_node *cgc_a, *cgc_b;
cgc_a = container_of(a, struct cgv_node, rb_node);
cgc_b = container_of(b, struct cgv_node, rb_node);
return cgc_a->cvtime < cgc_b->cvtime;
}
static struct fcg_cpu_ctx *find_cpu_ctx(void)
{
struct fcg_cpu_ctx *cpuc;
u32 idx = 0;
cpuc = bpf_map_lookup_elem(&cpu_ctx, &idx);
if (!cpuc) {
scx_bpf_error("cpu_ctx lookup failed");
return NULL;
}
return cpuc;
}
static struct fcg_cgrp_ctx *find_cgrp_ctx(struct cgroup *cgrp)
{
struct fcg_cgrp_ctx *cgc;
cgc = bpf_cgrp_storage_get(&cgrp_ctx, cgrp, 0, 0);
if (!cgc) {
scx_bpf_error("cgrp_ctx lookup failed for cgid %llu", cgrp->kn->id);
return NULL;
}
return cgc;
}
static struct fcg_cgrp_ctx *find_ancestor_cgrp_ctx(struct cgroup *cgrp, int level)
{
struct fcg_cgrp_ctx *cgc;
cgrp = bpf_cgroup_ancestor(cgrp, level);
if (!cgrp) {
scx_bpf_error("ancestor cgroup lookup failed");
return NULL;
}
cgc = find_cgrp_ctx(cgrp);
if (!cgc)
scx_bpf_error("ancestor cgrp_ctx lookup failed");
bpf_cgroup_release(cgrp);
return cgc;
}
static void cgrp_refresh_hweight(struct cgroup *cgrp, struct fcg_cgrp_ctx *cgc)
{
int level;
if (!cgc->nr_active) {
stat_inc(FCG_STAT_HWT_SKIP);
return;
}
if (cgc->hweight_gen == hweight_gen) {
stat_inc(FCG_STAT_HWT_CACHE);
return;
}
stat_inc(FCG_STAT_HWT_UPDATES);
bpf_for(level, 0, cgrp->level + 1) {
struct fcg_cgrp_ctx *cgc;
bool is_active;
cgc = find_ancestor_cgrp_ctx(cgrp, level);
if (!cgc)
break;
if (!level) {
cgc->hweight = FCG_HWEIGHT_ONE;
cgc->hweight_gen = hweight_gen;
} else {
struct fcg_cgrp_ctx *pcgc;
pcgc = find_ancestor_cgrp_ctx(cgrp, level - 1);
if (!pcgc)
break;
/*
* We can be opportunistic here and not grab the
* cgv_tree_lock and deal with the occasional races.
* However, hweight updates are already cached and
* relatively low-frequency. Let's just do the
* straightforward thing.
*/
bpf_spin_lock(&cgv_tree_lock);
is_active = cgc->nr_active;
if (is_active) {
cgc->hweight_gen = pcgc->hweight_gen;
cgc->hweight =
div_round_up(pcgc->hweight * cgc->weight,
pcgc->child_weight_sum);
}
bpf_spin_unlock(&cgv_tree_lock);
if (!is_active) {
stat_inc(FCG_STAT_HWT_RACE);
break;
}
}
}
}
static void cgrp_cap_budget(struct cgv_node *cgv_node, struct fcg_cgrp_ctx *cgc)
{
u64 delta, cvtime, max_budget;
/*
* A node which is on the rbtree can't be pointed to from elsewhere yet
* and thus can't be updated and repositioned. Instead, we collect the
* vtime deltas separately and apply it asynchronously here.
*/
delta = __sync_fetch_and_sub(&cgc->cvtime_delta, cgc->cvtime_delta);
cvtime = cgv_node->cvtime + delta;
/*
* Allow a cgroup to carry the maximum budget proportional to its
* hweight such that a full-hweight cgroup can immediately take up half
* of the CPUs at the most while staying at the front of the rbtree.
*/
max_budget = (cgrp_slice_ns * nr_cpus * cgc->hweight) /
(2 * FCG_HWEIGHT_ONE);
if (vtime_before(cvtime, cvtime_now - max_budget))
cvtime = cvtime_now - max_budget;
cgv_node->cvtime = cvtime;
}
static void cgrp_enqueued(struct cgroup *cgrp, struct fcg_cgrp_ctx *cgc)
{
struct cgv_node_stash *stash;
struct cgv_node *cgv_node;
u64 cgid = cgrp->kn->id;
/* paired with cmpxchg in try_pick_next_cgroup() */
if (__sync_val_compare_and_swap(&cgc->queued, 0, 1)) {
stat_inc(FCG_STAT_ENQ_SKIP);
return;
}
stash = bpf_map_lookup_elem(&cgv_node_stash, &cgid);
if (!stash) {
scx_bpf_error("cgv_node lookup failed for cgid %llu", cgid);
return;
}
/* NULL if the node is already on the rbtree */
cgv_node = bpf_kptr_xchg(&stash->node, NULL);
if (!cgv_node) {
stat_inc(FCG_STAT_ENQ_RACE);
return;
}
bpf_spin_lock(&cgv_tree_lock);
cgrp_cap_budget(cgv_node, cgc);
bpf_rbtree_add(&cgv_tree, &cgv_node->rb_node, cgv_node_less);
bpf_spin_unlock(&cgv_tree_lock);
}
static void set_bypassed_at(struct task_struct *p, struct fcg_task_ctx *taskc)
{
/*
* Tell fcg_stopping() that this bypassed the regular scheduling path
* and should be force charged to the cgroup. 0 is used to indicate that
* the task isn't bypassing, so if the current runtime is 0, go back by
* one nanosecond.
*/
taskc->bypassed_at = p->se.sum_exec_runtime ?: (u64)-1;
}
s32 BPF_STRUCT_OPS(fcg_select_cpu, struct task_struct *p, s32 prev_cpu, u64 wake_flags)
{
struct fcg_task_ctx *taskc;
bool is_idle = false;
s32 cpu;
cpu = scx_bpf_select_cpu_dfl(p, prev_cpu, wake_flags, &is_idle);
taskc = bpf_task_storage_get(&task_ctx, p, 0, 0);
if (!taskc) {
scx_bpf_error("task_ctx lookup failed");
return cpu;
}
/*
* If select_cpu_dfl() is recommending local enqueue, the target CPU is
* idle. Follow it and charge the cgroup later in fcg_stopping() after
* the fact.
*/
if (is_idle) {
set_bypassed_at(p, taskc);
stat_inc(FCG_STAT_LOCAL);
scx_bpf_dsq_insert(p, SCX_DSQ_LOCAL, SCX_SLICE_DFL, 0);
}
return cpu;
}
void BPF_STRUCT_OPS(fcg_enqueue, struct task_struct *p, u64 enq_flags)
{
struct fcg_task_ctx *taskc;
struct cgroup *cgrp;
struct fcg_cgrp_ctx *cgc;
taskc = bpf_task_storage_get(&task_ctx, p, 0, 0);
if (!taskc) {
scx_bpf_error("task_ctx lookup failed");
return;
}
/*
* Use the direct dispatching and force charging to deal with tasks with
* custom affinities so that we don't have to worry about per-cgroup
* dq's containing tasks that can't be executed from some CPUs.
*/
if (p->nr_cpus_allowed != nr_cpus) {
set_bypassed_at(p, taskc);
/*
* The global dq is deprioritized as we don't want to let tasks
* to boost themselves by constraining its cpumask. The
* deprioritization is rather severe, so let's not apply that to
* per-cpu kernel threads. This is ham-fisted. We probably wanna
* implement per-cgroup fallback dq's instead so that we have
* more control over when tasks with custom cpumask get issued.
*/
if (p->nr_cpus_allowed == 1 && (p->flags & PF_KTHREAD)) {
stat_inc(FCG_STAT_LOCAL);
scx_bpf_dsq_insert(p, SCX_DSQ_LOCAL, SCX_SLICE_DFL,
enq_flags);
} else {
stat_inc(FCG_STAT_GLOBAL);
scx_bpf_dsq_insert(p, FALLBACK_DSQ, SCX_SLICE_DFL,
enq_flags);
}
return;
}
cgrp = __COMPAT_scx_bpf_task_cgroup(p);
cgc = find_cgrp_ctx(cgrp);
if (!cgc)
goto out_release;
if (fifo_sched) {
scx_bpf_dsq_insert(p, cgrp->kn->id, SCX_SLICE_DFL, enq_flags);
} else {
u64 tvtime = p->scx.dsq_vtime;
/*
* Limit the amount of budget that an idling task can accumulate
* to one slice.
*/
if (vtime_before(tvtime, cgc->tvtime_now - SCX_SLICE_DFL))
tvtime = cgc->tvtime_now - SCX_SLICE_DFL;
scx_bpf_dsq_insert_vtime(p, cgrp->kn->id, SCX_SLICE_DFL,
tvtime, enq_flags);
}
cgrp_enqueued(cgrp, cgc);
out_release:
bpf_cgroup_release(cgrp);
}
/*
* Walk the cgroup tree to update the active weight sums as tasks wake up and
* sleep. The weight sums are used as the base when calculating the proportion a
* given cgroup or task is entitled to at each level.
*/
static void update_active_weight_sums(struct cgroup *cgrp, bool runnable)
{
struct fcg_cgrp_ctx *cgc;
bool updated = false;
int idx;
cgc = find_cgrp_ctx(cgrp);
if (!cgc)
return;
/*
* In most cases, a hot cgroup would have multiple threads going to
* sleep and waking up while the whole cgroup stays active. In leaf
* cgroups, ->nr_runnable which is updated with __sync operations gates
* ->nr_active updates, so that we don't have to grab the cgv_tree_lock
* repeatedly for a busy cgroup which is staying active.
*/
if (runnable) {
if (__sync_fetch_and_add(&cgc->nr_runnable, 1))
return;
stat_inc(FCG_STAT_ACT);
} else {
if (__sync_sub_and_fetch(&cgc->nr_runnable, 1))
return;
stat_inc(FCG_STAT_DEACT);
}
/*
* If @cgrp is becoming runnable, its hweight should be refreshed after
* it's added to the weight tree so that enqueue has the up-to-date
* value. If @cgrp is becoming quiescent, the hweight should be
* refreshed before it's removed from the weight tree so that the usage
* charging which happens afterwards has access to the latest value.
*/
if (!runnable)
cgrp_refresh_hweight(cgrp, cgc);
/* propagate upwards */
bpf_for(idx, 0, cgrp->level) {
int level = cgrp->level - idx;
struct fcg_cgrp_ctx *cgc, *pcgc = NULL;
bool propagate = false;
cgc = find_ancestor_cgrp_ctx(cgrp, level);
if (!cgc)
break;
if (level) {
pcgc = find_ancestor_cgrp_ctx(cgrp, level - 1);
if (!pcgc)
break;
}
/*
* We need the propagation protected by a lock to synchronize
* against weight changes. There's no reason to drop the lock at
* each level but bpf_spin_lock() doesn't want any function
* calls while locked.
*/
bpf_spin_lock(&cgv_tree_lock);
if (runnable) {
if (!cgc->nr_active++) {
updated = true;
if (pcgc) {
propagate = true;
pcgc->child_weight_sum += cgc->weight;
}
}
} else {
if (!--cgc->nr_active) {
updated = true;
if (pcgc) {
propagate = true;
pcgc->child_weight_sum -= cgc->weight;
}
}
}
bpf_spin_unlock(&cgv_tree_lock);
if (!propagate)
break;
}
if (updated)
__sync_fetch_and_add(&hweight_gen, 1);
if (runnable)
cgrp_refresh_hweight(cgrp, cgc);
}
void BPF_STRUCT_OPS(fcg_runnable, struct task_struct *p, u64 enq_flags)
{
struct cgroup *cgrp;
cgrp = __COMPAT_scx_bpf_task_cgroup(p);
update_active_weight_sums(cgrp, true);
bpf_cgroup_release(cgrp);
}
void BPF_STRUCT_OPS(fcg_running, struct task_struct *p)
{
struct cgroup *cgrp;
struct fcg_cgrp_ctx *cgc;
if (fifo_sched)
return;
cgrp = __COMPAT_scx_bpf_task_cgroup(p);
cgc = find_cgrp_ctx(cgrp);
if (cgc) {
/*
* @cgc->tvtime_now always progresses forward as tasks start
* executing. The test and update can be performed concurrently
* from multiple CPUs and thus racy. Any error should be
* contained and temporary. Let's just live with it.
*/
if (vtime_before(cgc->tvtime_now, p->scx.dsq_vtime))
cgc->tvtime_now = p->scx.dsq_vtime;
}
bpf_cgroup_release(cgrp);
}
void BPF_STRUCT_OPS(fcg_stopping, struct task_struct *p, bool runnable)
{
struct fcg_task_ctx *taskc;
struct cgroup *cgrp;
struct fcg_cgrp_ctx *cgc;
/*
* Scale the execution time by the inverse of the weight and charge.
*
* Note that the default yield implementation yields by setting
* @p->scx.slice to zero and the following would treat the yielding task
* as if it has consumed all its slice. If this penalizes yielding tasks
* too much, determine the execution time by taking explicit timestamps
* instead of depending on @p->scx.slice.
*/
if (!fifo_sched)
p->scx.dsq_vtime +=
(SCX_SLICE_DFL - p->scx.slice) * 100 / p->scx.weight;
taskc = bpf_task_storage_get(&task_ctx, p, 0, 0);
if (!taskc) {
scx_bpf_error("task_ctx lookup failed");
return;
}
if (!taskc->bypassed_at)
return;
cgrp = __COMPAT_scx_bpf_task_cgroup(p);
cgc = find_cgrp_ctx(cgrp);
if (cgc) {
__sync_fetch_and_add(&cgc->cvtime_delta,
p->se.sum_exec_runtime - taskc->bypassed_at);
taskc->bypassed_at = 0;
}
bpf_cgroup_release(cgrp);
}
void BPF_STRUCT_OPS(fcg_quiescent, struct task_struct *p, u64 deq_flags)
{
struct cgroup *cgrp;
cgrp = __COMPAT_scx_bpf_task_cgroup(p);
update_active_weight_sums(cgrp, false);
bpf_cgroup_release(cgrp);
}
void BPF_STRUCT_OPS(fcg_cgroup_set_weight, struct cgroup *cgrp, u32 weight)
{
struct fcg_cgrp_ctx *cgc, *pcgc = NULL;
cgc = find_cgrp_ctx(cgrp);
if (!cgc)
return;
if (cgrp->level) {
pcgc = find_ancestor_cgrp_ctx(cgrp, cgrp->level - 1);
if (!pcgc)
return;
}
bpf_spin_lock(&cgv_tree_lock);
if (pcgc && cgc->nr_active)
pcgc->child_weight_sum += (s64)weight - cgc->weight;
cgc->weight = weight;
bpf_spin_unlock(&cgv_tree_lock);
}
static bool try_pick_next_cgroup(u64 *cgidp)
{
struct bpf_rb_node *rb_node;
struct cgv_node_stash *stash;
struct cgv_node *cgv_node;
struct fcg_cgrp_ctx *cgc;
struct cgroup *cgrp;
u64 cgid;
/* pop the front cgroup and wind cvtime_now accordingly */
bpf_spin_lock(&cgv_tree_lock);
rb_node = bpf_rbtree_first(&cgv_tree);
if (!rb_node) {
bpf_spin_unlock(&cgv_tree_lock);
stat_inc(FCG_STAT_PNC_NO_CGRP);
*cgidp = 0;
return true;
}
rb_node = bpf_rbtree_remove(&cgv_tree, rb_node);
bpf_spin_unlock(&cgv_tree_lock);
if (!rb_node) {
/*
* This should never happen. bpf_rbtree_first() was called
* above while the tree lock was held, so the node should
* always be present.
*/
scx_bpf_error("node could not be removed");
return true;
}
cgv_node = container_of(rb_node, struct cgv_node, rb_node);
cgid = cgv_node->cgid;
if (vtime_before(cvtime_now, cgv_node->cvtime))
cvtime_now = cgv_node->cvtime;
/*
* If lookup fails, the cgroup's gone. Free and move on. See
* fcg_cgroup_exit().
*/
cgrp = bpf_cgroup_from_id(cgid);
if (!cgrp) {
stat_inc(FCG_STAT_PNC_GONE);
goto out_free;
}
cgc = bpf_cgrp_storage_get(&cgrp_ctx, cgrp, 0, 0);
if (!cgc) {
bpf_cgroup_release(cgrp);
stat_inc(FCG_STAT_PNC_GONE);
goto out_free;
}
if (!scx_bpf_dsq_move_to_local(cgid)) {
bpf_cgroup_release(cgrp);
stat_inc(FCG_STAT_PNC_EMPTY);
goto out_stash;
}
/*
* Successfully consumed from the cgroup. This will be our current
* cgroup for the new slice. Refresh its hweight.
*/
cgrp_refresh_hweight(cgrp, cgc);
bpf_cgroup_release(cgrp);
/*
* As the cgroup may have more tasks, add it back to the rbtree. Note
* that here we charge the full slice upfront and then exact later
* according to the actual consumption. This prevents lowpri thundering
* herd from saturating the machine.
*/
bpf_spin_lock(&cgv_tree_lock);
cgv_node->cvtime += cgrp_slice_ns * FCG_HWEIGHT_ONE / (cgc->hweight ?: 1);
cgrp_cap_budget(cgv_node, cgc);
bpf_rbtree_add(&cgv_tree, &cgv_node->rb_node, cgv_node_less);
bpf_spin_unlock(&cgv_tree_lock);
*cgidp = cgid;
stat_inc(FCG_STAT_PNC_NEXT);
return true;
out_stash:
stash = bpf_map_lookup_elem(&cgv_node_stash, &cgid);
if (!stash) {
stat_inc(FCG_STAT_PNC_GONE);
goto out_free;
}
/*
* Paired with cmpxchg in cgrp_enqueued(). If they see the following
* transition, they'll enqueue the cgroup. If they are earlier, we'll
* see their task in the dq below and requeue the cgroup.
*/
__sync_val_compare_and_swap(&cgc->queued, 1, 0);
if (scx_bpf_dsq_nr_queued(cgid)) {
bpf_spin_lock(&cgv_tree_lock);
bpf_rbtree_add(&cgv_tree, &cgv_node->rb_node, cgv_node_less);
bpf_spin_unlock(&cgv_tree_lock);
stat_inc(FCG_STAT_PNC_RACE);
} else {
cgv_node = bpf_kptr_xchg(&stash->node, cgv_node);
if (cgv_node) {
scx_bpf_error("unexpected !NULL cgv_node stash");
goto out_free;
}
}
return false;
out_free:
bpf_obj_drop(cgv_node);
return false;
}
void BPF_STRUCT_OPS(fcg_dispatch, s32 cpu, struct task_struct *prev)
{
struct fcg_cpu_ctx *cpuc;
struct fcg_cgrp_ctx *cgc;
struct cgroup *cgrp;
u64 now = bpf_ktime_get_ns();
bool picked_next = false;
cpuc = find_cpu_ctx();
if (!cpuc)
return;
if (!cpuc->cur_cgid)
goto pick_next_cgroup;
if (vtime_before(now, cpuc->cur_at + cgrp_slice_ns)) {
if (scx_bpf_dsq_move_to_local(cpuc->cur_cgid)) {
stat_inc(FCG_STAT_CNS_KEEP);
return;
}
stat_inc(FCG_STAT_CNS_EMPTY);
} else {
stat_inc(FCG_STAT_CNS_EXPIRE);
}
/*
* The current cgroup is expiring. It was already charged a full slice.
* Calculate the actual usage and accumulate the delta.
*/
cgrp = bpf_cgroup_from_id(cpuc->cur_cgid);
if (!cgrp) {
stat_inc(FCG_STAT_CNS_GONE);
goto pick_next_cgroup;
}
cgc = bpf_cgrp_storage_get(&cgrp_ctx, cgrp, 0, 0);
if (cgc) {
/*
* We want to update the vtime delta and then look for the next
* cgroup to execute but the latter needs to be done in a loop
* and we can't keep the lock held. Oh well...
*/
bpf_spin_lock(&cgv_tree_lock);
__sync_fetch_and_add(&cgc->cvtime_delta,
(cpuc->cur_at + cgrp_slice_ns - now) *
FCG_HWEIGHT_ONE / (cgc->hweight ?: 1));
bpf_spin_unlock(&cgv_tree_lock);
} else {
stat_inc(FCG_STAT_CNS_GONE);
}
bpf_cgroup_release(cgrp);
pick_next_cgroup:
cpuc->cur_at = now;
if (scx_bpf_dsq_move_to_local(FALLBACK_DSQ)) {
cpuc->cur_cgid = 0;
return;
}
bpf_repeat(CGROUP_MAX_RETRIES) {
if (try_pick_next_cgroup(&cpuc->cur_cgid)) {
picked_next = true;
break;
}
}
/*
* This only happens if try_pick_next_cgroup() races against enqueue
* path for more than CGROUP_MAX_RETRIES times, which is extremely
* unlikely and likely indicates an underlying bug. There shouldn't be
* any stall risk as the race is against enqueue.
*/
if (!picked_next)
stat_inc(FCG_STAT_PNC_FAIL);
}
s32 BPF_STRUCT_OPS(fcg_init_task, struct task_struct *p,
struct scx_init_task_args *args)
{
struct fcg_task_ctx *taskc;
struct fcg_cgrp_ctx *cgc;
/*
* @p is new. Let's ensure that its task_ctx is available. We can sleep
* in this function and the following will automatically use GFP_KERNEL.
*/
taskc = bpf_task_storage_get(&task_ctx, p, 0,
BPF_LOCAL_STORAGE_GET_F_CREATE);
if (!taskc)
return -ENOMEM;
taskc->bypassed_at = 0;
if (!(cgc = find_cgrp_ctx(args->cgroup)))
return -ENOENT;
p->scx.dsq_vtime = cgc->tvtime_now;
return 0;
}
int BPF_STRUCT_OPS_SLEEPABLE(fcg_cgroup_init, struct cgroup *cgrp,
struct scx_cgroup_init_args *args)
{
struct fcg_cgrp_ctx *cgc;
struct cgv_node *cgv_node;
struct cgv_node_stash empty_stash = {}, *stash;
u64 cgid = cgrp->kn->id;
int ret;
/*
* Technically incorrect as cgroup ID is full 64bit while dsq ID is
* 63bit. Should not be a problem in practice and easy to spot in the
* unlikely case that it breaks.
*/
ret = scx_bpf_create_dsq(cgid, -1);
if (ret)
return ret;
cgc = bpf_cgrp_storage_get(&cgrp_ctx, cgrp, 0,
BPF_LOCAL_STORAGE_GET_F_CREATE);
if (!cgc) {
ret = -ENOMEM;
goto err_destroy_dsq;
}
cgc->weight = args->weight;
cgc->hweight = FCG_HWEIGHT_ONE;
ret = bpf_map_update_elem(&cgv_node_stash, &cgid, &empty_stash,
BPF_NOEXIST);
if (ret) {
if (ret != -ENOMEM)
scx_bpf_error("unexpected stash creation error (%d)",
ret);
goto err_destroy_dsq;
}
stash = bpf_map_lookup_elem(&cgv_node_stash, &cgid);
if (!stash) {
scx_bpf_error("unexpected cgv_node stash lookup failure");
ret = -ENOENT;
goto err_destroy_dsq;
}
cgv_node = bpf_obj_new(struct cgv_node);
if (!cgv_node) {
ret = -ENOMEM;
goto err_del_cgv_node;
}
cgv_node->cgid = cgid;
cgv_node->cvtime = cvtime_now;
cgv_node = bpf_kptr_xchg(&stash->node, cgv_node);
if (cgv_node) {
scx_bpf_error("unexpected !NULL cgv_node stash");
ret = -EBUSY;
goto err_drop;
}
return 0;
err_drop:
bpf_obj_drop(cgv_node);
err_del_cgv_node:
bpf_map_delete_elem(&cgv_node_stash, &cgid);
err_destroy_dsq:
scx_bpf_destroy_dsq(cgid);
return ret;
}
void BPF_STRUCT_OPS(fcg_cgroup_exit, struct cgroup *cgrp)
{
u64 cgid = cgrp->kn->id;
/*
* For now, there's no way find and remove the cgv_node if it's on the
* cgv_tree. Let's drain them in the dispatch path as they get popped
* off the front of the tree.
*/
bpf_map_delete_elem(&cgv_node_stash, &cgid);
scx_bpf_destroy_dsq(cgid);
}
void BPF_STRUCT_OPS(fcg_cgroup_move, struct task_struct *p,
struct cgroup *from, struct cgroup *to)
{
struct fcg_cgrp_ctx *from_cgc, *to_cgc;
s64 vtime_delta;
/* find_cgrp_ctx() triggers scx_ops_error() on lookup failures */
if (!(from_cgc = find_cgrp_ctx(from)) || !(to_cgc = find_cgrp_ctx(to)))
return;
vtime_delta = p->scx.dsq_vtime - from_cgc->tvtime_now;
p->scx.dsq_vtime = to_cgc->tvtime_now + vtime_delta;
}
s32 BPF_STRUCT_OPS_SLEEPABLE(fcg_init)
{
return scx_bpf_create_dsq(FALLBACK_DSQ, -1);
}
void BPF_STRUCT_OPS(fcg_exit, struct scx_exit_info *ei)
{
UEI_RECORD(uei, ei);
}
SCX_OPS_DEFINE(flatcg_ops,
.select_cpu = (void *)fcg_select_cpu,
.enqueue = (void *)fcg_enqueue,
.dispatch = (void *)fcg_dispatch,
.runnable = (void *)fcg_runnable,
.running = (void *)fcg_running,
.stopping = (void *)fcg_stopping,
.quiescent = (void *)fcg_quiescent,
.init_task = (void *)fcg_init_task,
.cgroup_set_weight = (void *)fcg_cgroup_set_weight,
.cgroup_init = (void *)fcg_cgroup_init,
.cgroup_exit = (void *)fcg_cgroup_exit,
.cgroup_move = (void *)fcg_cgroup_move,
.init = (void *)fcg_init,
.exit = (void *)fcg_exit,
.flags = SCX_OPS_HAS_CGROUP_WEIGHT | SCX_OPS_ENQ_EXITING,
.name = "flatcg");