tools/sched_ext/scx_userland.bpf.c - third_party/linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 /*
  * A minimal userland scheduler.
  *
  * In terms of scheduling, this provides two different types of behaviors:
  * 1. A global FIFO scheduling order for _any_ tasks that have CPU affinity.
  *    All such tasks are direct-dispatched from the kernel, and are never
  *    enqueued in user space.
  * 2. A primitive vruntime scheduler that is implemented in user space, for all
  *    other tasks.
  *
  * Some parts of this example user space scheduler could be implemented more
  * efficiently using more complex and sophisticated data structures. For
  * example, rather than using BPF_MAP_TYPE_QUEUE's,
  * BPF_MAP_TYPE_{USER_}RINGBUF's could be used for exchanging messages between
  * user space and kernel space. Similarly, we use a simple vruntime-sorted list
  * in user space, but an rbtree could be used instead.
  *
  * Copyright (c) 2022 Meta Platforms, Inc. and affiliates.
  * Copyright (c) 2022 Tejun Heo <tj@kernel.org>
  * Copyright (c) 2022 David Vernet <dvernet@meta.com>
  */
 #include <scx/common.bpf.h>
 #include "scx_userland.h"

 /*
  * Maximum amount of tasks enqueued/dispatched between kernel and user-space.
  */
 #define MAX_ENQUEUED_TASKS 4096

 char _license[] SEC("license") = "GPL";

 const volatile s32 usersched_pid;

 /* !0 for veristat, set during init */
 const volatile u32 num_possible_cpus = 64;

 /* Stats that are printed by user space. */
 u64 nr_failed_enqueues, nr_kernel_enqueues, nr_user_enqueues;

 /*
  * Number of tasks that are queued for scheduling.
  *
  * This number is incremented by the BPF component when a task is queued to the
  * user-space scheduler and it must be decremented by the user-space scheduler
  * when a task is consumed.
  */
 volatile u64 nr_queued;

 /*
  * Number of tasks that are waiting for scheduling.
  *
  * This number must be updated by the user-space scheduler to keep track if
  * there is still some scheduling work to do.
  */
 volatile u64 nr_scheduled;

 UEI_DEFINE(uei);

 /*
  * The map containing tasks that are enqueued in user space from the kernel.
  *
  * This map is drained by the user space scheduler.
  */
 struct {
 	__uint(type, BPF_MAP_TYPE_QUEUE);
 	__uint(max_entries, MAX_ENQUEUED_TASKS);
 	__type(value, struct scx_userland_enqueued_task);
 } enqueued SEC(".maps");

 /*
  * The map containing tasks that are dispatched to the kernel from user space.
  *
  * Drained by the kernel in userland_dispatch().
  */
 struct {
 	__uint(type, BPF_MAP_TYPE_QUEUE);
 	__uint(max_entries, MAX_ENQUEUED_TASKS);
 	__type(value, s32);
 } dispatched SEC(".maps");

 /* Per-task scheduling context */
 struct task_ctx {
 	bool force_local; /* Dispatch directly to local DSQ */
 };

 /* Map that contains task-local storage. */
 struct {
 	__uint(type, BPF_MAP_TYPE_TASK_STORAGE);
 	__uint(map_flags, BPF_F_NO_PREALLOC);
 	__type(key, int);
 	__type(value, struct task_ctx);
 } task_ctx_stor SEC(".maps");

 /*
  * Flag used to wake-up the user-space scheduler.
  */
 static volatile u32 usersched_needed;

 /*
  * Set user-space scheduler wake-up flag (equivalent to an atomic release
  * operation).
  */
 static void set_usersched_needed(void)
 {
 	__sync_fetch_and_or(&usersched_needed, 1);
 }

 /*
  * Check and clear user-space scheduler wake-up flag (equivalent to an atomic
  * acquire operation).
  */
 static bool test_and_clear_usersched_needed(void)
 {
 	return __sync_fetch_and_and(&usersched_needed, 0) == 1;
 }

 static bool is_usersched_task(const struct task_struct *p)
 {
 	return p->pid == usersched_pid;
 }

 static bool keep_in_kernel(const struct task_struct *p)
 {
 	return p->nr_cpus_allowed < num_possible_cpus;
 }

 static struct task_struct *usersched_task(void)
 {
 	struct task_struct *p;

 	p = bpf_task_from_pid(usersched_pid);
 	/*
 	 * Should never happen -- the usersched task should always be managed
 	 * by sched_ext.
 	 */
 	if (!p)
 		scx_bpf_error("Failed to find usersched task %d", usersched_pid);

 	return p;
 }

 s32 BPF_STRUCT_OPS(userland_select_cpu, struct task_struct *p,
 		   s32 prev_cpu, u64 wake_flags)
 {
 	if (keep_in_kernel(p)) {
 		s32 cpu;
 		struct task_ctx *tctx;

 		tctx = bpf_task_storage_get(&task_ctx_stor, p, 0, 0);
 		if (!tctx) {
 			scx_bpf_error("Failed to look up task-local storage for %s", p->comm);
 			return -ESRCH;
 		}

 		if (p->nr_cpus_allowed == 1 ||
 		    scx_bpf_test_and_clear_cpu_idle(prev_cpu)) {
 			tctx->force_local = true;
 			return prev_cpu;
 		}

 		cpu = scx_bpf_pick_idle_cpu(p->cpus_ptr, 0);
 		if (cpu >= 0) {
 			tctx->force_local = true;
 			return cpu;
 		}
 	}

 	return prev_cpu;
 }

 static void dispatch_user_scheduler(void)
 {
 	struct task_struct *p;

 	p = usersched_task();
 	if (p) {
 		scx_bpf_dsq_insert(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, 0);
 		bpf_task_release(p);
 	}
 }

 static void enqueue_task_in_user_space(struct task_struct *p, u64 enq_flags)
 {
 	struct scx_userland_enqueued_task task = {};

 	task.pid = p->pid;
 	task.sum_exec_runtime = p->se.sum_exec_runtime;
 	task.weight = p->scx.weight;

 	if (bpf_map_push_elem(&enqueued, &task, 0)) {
 		/*
 		 * If we fail to enqueue the task in user space, put it
 		 * directly on the global DSQ.
 		 */
 		__sync_fetch_and_add(&nr_failed_enqueues, 1);
 		scx_bpf_dsq_insert(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, enq_flags);
 	} else {
 		__sync_fetch_and_add(&nr_user_enqueues, 1);
 		set_usersched_needed();
 	}
 }

 void BPF_STRUCT_OPS(userland_enqueue, struct task_struct *p, u64 enq_flags)
 {
 	if (keep_in_kernel(p)) {
 		u64 dsq_id = SCX_DSQ_GLOBAL;
 		struct task_ctx *tctx;

 		tctx = bpf_task_storage_get(&task_ctx_stor, p, 0, 0);
 		if (!tctx) {
 			scx_bpf_error("Failed to lookup task ctx for %s", p->comm);
 			return;
 		}

 		if (tctx->force_local)
 			dsq_id = SCX_DSQ_LOCAL;
 		tctx->force_local = false;
 		scx_bpf_dsq_insert(p, dsq_id, SCX_SLICE_DFL, enq_flags);
 		__sync_fetch_and_add(&nr_kernel_enqueues, 1);
 		return;
 	} else if (!is_usersched_task(p)) {
 		enqueue_task_in_user_space(p, enq_flags);
 	}
 }

 void BPF_STRUCT_OPS(userland_dispatch, s32 cpu, struct task_struct *prev)
 {
 	if (test_and_clear_usersched_needed())
 		dispatch_user_scheduler();

 	bpf_repeat(MAX_ENQUEUED_TASKS) {
 		s32 pid;
 		struct task_struct *p;

 		if (bpf_map_pop_elem(&dispatched, &pid))
 			break;

 		/*
 		 * The task could have exited by the time we get around to
 		 * dispatching it. Treat this as a normal occurrence, and simply
 		 * move onto the next iteration.
 		 */
 		p = bpf_task_from_pid(pid);
 		if (!p)
 			continue;

 		scx_bpf_dsq_insert(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, 0);
 		bpf_task_release(p);
 	}
 }

 /*
  * A CPU is about to change its idle state. If the CPU is going idle, ensure
  * that the user-space scheduler has a chance to run if there is any remaining
  * work to do.
  */
 void BPF_STRUCT_OPS(userland_update_idle, s32 cpu, bool idle)
 {
 	/*
 	 * Don't do anything if we exit from and idle state, a CPU owner will
 	 * be assigned in .running().
 	 */
 	if (!idle)
 		return;
 	/*
 	 * A CPU is now available, notify the user-space scheduler that tasks
 	 * can be dispatched, if there is at least one task waiting to be
 	 * scheduled, either queued (accounted in nr_queued) or scheduled
 	 * (accounted in nr_scheduled).
 	 *
 	 * NOTE: nr_queued is incremented by the BPF component, more exactly in
 	 * enqueue(), when a task is sent to the user-space scheduler, then
 	 * the scheduler drains the queued tasks (updating nr_queued) and adds
 	 * them to its internal data structures / state; at this point tasks
 	 * become "scheduled" and the user-space scheduler will take care of
 	 * updating nr_scheduled accordingly; lastly tasks will be dispatched
 	 * and the user-space scheduler will update nr_scheduled again.
 	 *
 	 * Checking both counters allows to determine if there is still some
 	 * pending work to do for the scheduler: new tasks have been queued
 	 * since last check, or there are still tasks "queued" or "scheduled"
 	 * since the previous user-space scheduler run. If the counters are
 	 * both zero it is pointless to wake-up the scheduler (even if a CPU
 	 * becomes idle), because there is nothing to do.
 	 *
 	 * Keep in mind that update_idle() doesn't run concurrently with the
 	 * user-space scheduler (that is single-threaded): this function is
 	 * naturally serialized with the user-space scheduler code, therefore
 	 * this check here is also safe from a concurrency perspective.
 	 */
 	if (nr_queued || nr_scheduled) {
 		/*
 		 * Kick the CPU to make it immediately ready to accept
 		 * dispatched tasks.
 		 */
 		set_usersched_needed();
 		scx_bpf_kick_cpu(cpu, 0);
 	}
 }

 s32 BPF_STRUCT_OPS(userland_init_task, struct task_struct *p,
 		   struct scx_init_task_args *args)
 {
 	if (bpf_task_storage_get(&task_ctx_stor, p, 0,
 				 BPF_LOCAL_STORAGE_GET_F_CREATE))
 		return 0;
 	else
 		return -ENOMEM;
 }

 s32 BPF_STRUCT_OPS(userland_init)
 {
 	if (num_possible_cpus == 0) {
 		scx_bpf_error("User scheduler # CPUs uninitialized (%d)",
 			      num_possible_cpus);
 		return -EINVAL;
 	}

 	if (usersched_pid <= 0) {
 		scx_bpf_error("User scheduler pid uninitialized (%d)",
 			      usersched_pid);
 		return -EINVAL;
 	}

 	return 0;
 }

 void BPF_STRUCT_OPS(userland_exit, struct scx_exit_info *ei)
 {
 	UEI_RECORD(uei, ei);
 }

 SCX_OPS_DEFINE(userland_ops,
 	       .select_cpu		= (void *)userland_select_cpu,
 	       .enqueue			= (void *)userland_enqueue,
 	       .dispatch		= (void *)userland_dispatch,
 	       .update_idle		= (void *)userland_update_idle,
 	       .init_task		= (void *)userland_init_task,
 	       .init			= (void *)userland_init,
 	       .exit			= (void *)userland_exit,
 	       .flags			= SCX_OPS_ENQ_LAST |
 					  SCX_OPS_KEEP_BUILTIN_IDLE,
 	       .name			= "userland");
	/* SPDX-License-Identifier: GPL-2.0 */
	/*
	* A minimal userland scheduler.
	*
	* In terms of scheduling, this provides two different types of behaviors:
	* 1. A global FIFO scheduling order for _any_ tasks that have CPU affinity.
	* All such tasks are direct-dispatched from the kernel, and are never
	* enqueued in user space.
	* 2. A primitive vruntime scheduler that is implemented in user space, for all
	* other tasks.
	*
	* Some parts of this example user space scheduler could be implemented more
	* efficiently using more complex and sophisticated data structures. For
	* example, rather than using BPF_MAP_TYPE_QUEUE's,
	* BPF_MAP_TYPE_{USER_}RINGBUF's could be used for exchanging messages between
	* user space and kernel space. Similarly, we use a simple vruntime-sorted list
	* in user space, but an rbtree could be used instead.
	*
	* Copyright (c) 2022 Meta Platforms, Inc. and affiliates.
	* Copyright (c) 2022 Tejun Heo <tj@kernel.org>
	* Copyright (c) 2022 David Vernet <dvernet@meta.com>
	*/
	#include <scx/common.bpf.h>
	#include "scx_userland.h"

	/*
	* Maximum amount of tasks enqueued/dispatched between kernel and user-space.
	*/
	#define MAX_ENQUEUED_TASKS 4096

	char _license[] SEC("license") = "GPL";

	const volatile s32 usersched_pid;

	/* !0 for veristat, set during init */
	const volatile u32 num_possible_cpus = 64;

	/* Stats that are printed by user space. */
	u64 nr_failed_enqueues, nr_kernel_enqueues, nr_user_enqueues;

	/*
	* Number of tasks that are queued for scheduling.
	*
	* This number is incremented by the BPF component when a task is queued to the
	* user-space scheduler and it must be decremented by the user-space scheduler
	* when a task is consumed.
	*/
	volatile u64 nr_queued;

	/*
	* Number of tasks that are waiting for scheduling.
	*
	* This number must be updated by the user-space scheduler to keep track if
	* there is still some scheduling work to do.
	*/
	volatile u64 nr_scheduled;

	UEI_DEFINE(uei);

	/*
	* The map containing tasks that are enqueued in user space from the kernel.
	*
	* This map is drained by the user space scheduler.
	*/
	struct {
	__uint(type, BPF_MAP_TYPE_QUEUE);
	__uint(max_entries, MAX_ENQUEUED_TASKS);
	__type(value, struct scx_userland_enqueued_task);
	} enqueued SEC(".maps");

	/*
	* The map containing tasks that are dispatched to the kernel from user space.
	*
	* Drained by the kernel in userland_dispatch().
	*/
	struct {
	__uint(type, BPF_MAP_TYPE_QUEUE);
	__uint(max_entries, MAX_ENQUEUED_TASKS);
	__type(value, s32);
	} dispatched SEC(".maps");

	/* Per-task scheduling context */
	struct task_ctx {
	bool force_local; /* Dispatch directly to local DSQ */
	};

	/* Map that contains task-local storage. */
	struct {
	__uint(type, BPF_MAP_TYPE_TASK_STORAGE);
	__uint(map_flags, BPF_F_NO_PREALLOC);
	__type(key, int);
	__type(value, struct task_ctx);
	} task_ctx_stor SEC(".maps");

	/*
	* Flag used to wake-up the user-space scheduler.
	*/
	static volatile u32 usersched_needed;

	/*
	* Set user-space scheduler wake-up flag (equivalent to an atomic release
	* operation).
	*/
	static void set_usersched_needed(void)
	{
	__sync_fetch_and_or(&usersched_needed, 1);
	}

	/*
	* Check and clear user-space scheduler wake-up flag (equivalent to an atomic
	* acquire operation).
	*/
	static bool test_and_clear_usersched_needed(void)
	{
	return __sync_fetch_and_and(&usersched_needed, 0) == 1;
	}

	static bool is_usersched_task(const struct task_struct *p)
	{
	return p->pid == usersched_pid;
	}

	static bool keep_in_kernel(const struct task_struct *p)
	{
	return p->nr_cpus_allowed < num_possible_cpus;
	}

	static struct task_struct *usersched_task(void)
	{
	struct task_struct *p;

	p = bpf_task_from_pid(usersched_pid);
	/*
	* Should never happen -- the usersched task should always be managed
	* by sched_ext.
	*/
	if (!p)
	scx_bpf_error("Failed to find usersched task %d", usersched_pid);

	return p;
	}

	s32 BPF_STRUCT_OPS(userland_select_cpu, struct task_struct *p,
	s32 prev_cpu, u64 wake_flags)
	{
	if (keep_in_kernel(p)) {
	s32 cpu;
	struct task_ctx *tctx;

	tctx = bpf_task_storage_get(&task_ctx_stor, p, 0, 0);
	if (!tctx) {
	scx_bpf_error("Failed to look up task-local storage for %s", p->comm);
	return -ESRCH;
	}

	if (p->nr_cpus_allowed == 1 \|\|
	scx_bpf_test_and_clear_cpu_idle(prev_cpu)) {
	tctx->force_local = true;
	return prev_cpu;
	}

	cpu = scx_bpf_pick_idle_cpu(p->cpus_ptr, 0);
	if (cpu >= 0) {
	tctx->force_local = true;
	return cpu;
	}
	}

	return prev_cpu;
	}

	static void dispatch_user_scheduler(void)
	{
	struct task_struct *p;

	p = usersched_task();
	if (p) {
	scx_bpf_dsq_insert(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, 0);
	bpf_task_release(p);
	}
	}

	static void enqueue_task_in_user_space(struct task_struct *p, u64 enq_flags)
	{
	struct scx_userland_enqueued_task task = {};

	task.pid = p->pid;
	task.sum_exec_runtime = p->se.sum_exec_runtime;
	task.weight = p->scx.weight;

	if (bpf_map_push_elem(&enqueued, &task, 0)) {
	/*
	* If we fail to enqueue the task in user space, put it
	* directly on the global DSQ.
	*/
	__sync_fetch_and_add(&nr_failed_enqueues, 1);
	scx_bpf_dsq_insert(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, enq_flags);
	} else {
	__sync_fetch_and_add(&nr_user_enqueues, 1);
	set_usersched_needed();
	}
	}

	void BPF_STRUCT_OPS(userland_enqueue, struct task_struct *p, u64 enq_flags)
	{
	if (keep_in_kernel(p)) {
	u64 dsq_id = SCX_DSQ_GLOBAL;
	struct task_ctx *tctx;

	tctx = bpf_task_storage_get(&task_ctx_stor, p, 0, 0);
	if (!tctx) {
	scx_bpf_error("Failed to lookup task ctx for %s", p->comm);
	return;
	}

	if (tctx->force_local)
	dsq_id = SCX_DSQ_LOCAL;
	tctx->force_local = false;
	scx_bpf_dsq_insert(p, dsq_id, SCX_SLICE_DFL, enq_flags);
	__sync_fetch_and_add(&nr_kernel_enqueues, 1);
	return;
	} else if (!is_usersched_task(p)) {
	enqueue_task_in_user_space(p, enq_flags);
	}
	}

	void BPF_STRUCT_OPS(userland_dispatch, s32 cpu, struct task_struct *prev)
	{
	if (test_and_clear_usersched_needed())
	dispatch_user_scheduler();

	bpf_repeat(MAX_ENQUEUED_TASKS) {
	s32 pid;
	struct task_struct *p;

	if (bpf_map_pop_elem(&dispatched, &pid))
	break;

	/*
	* The task could have exited by the time we get around to
	* dispatching it. Treat this as a normal occurrence, and simply
	* move onto the next iteration.
	*/
	p = bpf_task_from_pid(pid);
	if (!p)
	continue;

	scx_bpf_dsq_insert(p, SCX_DSQ_GLOBAL, SCX_SLICE_DFL, 0);
	bpf_task_release(p);
	}
	}

	/*
	* A CPU is about to change its idle state. If the CPU is going idle, ensure
	* that the user-space scheduler has a chance to run if there is any remaining
	* work to do.
	*/
	void BPF_STRUCT_OPS(userland_update_idle, s32 cpu, bool idle)
	{
	/*
	* Don't do anything if we exit from and idle state, a CPU owner will
	* be assigned in .running().
	*/
	if (!idle)
	return;
	/*
	* A CPU is now available, notify the user-space scheduler that tasks
	* can be dispatched, if there is at least one task waiting to be
	* scheduled, either queued (accounted in nr_queued) or scheduled
	* (accounted in nr_scheduled).
	*
	* NOTE: nr_queued is incremented by the BPF component, more exactly in
	* enqueue(), when a task is sent to the user-space scheduler, then
	* the scheduler drains the queued tasks (updating nr_queued) and adds
	* them to its internal data structures / state; at this point tasks
	* become "scheduled" and the user-space scheduler will take care of
	* updating nr_scheduled accordingly; lastly tasks will be dispatched
	* and the user-space scheduler will update nr_scheduled again.
	*
	* Checking both counters allows to determine if there is still some
	* pending work to do for the scheduler: new tasks have been queued
	* since last check, or there are still tasks "queued" or "scheduled"
	* since the previous user-space scheduler run. If the counters are
	* both zero it is pointless to wake-up the scheduler (even if a CPU
	* becomes idle), because there is nothing to do.
	*
	* Keep in mind that update_idle() doesn't run concurrently with the
	* user-space scheduler (that is single-threaded): this function is
	* naturally serialized with the user-space scheduler code, therefore
	* this check here is also safe from a concurrency perspective.
	*/
	if (nr_queued \|\| nr_scheduled) {
	/*
	* Kick the CPU to make it immediately ready to accept
	* dispatched tasks.
	*/
	set_usersched_needed();
	scx_bpf_kick_cpu(cpu, 0);
	}
	}

	s32 BPF_STRUCT_OPS(userland_init_task, struct task_struct *p,
	struct scx_init_task_args *args)
	{
	if (bpf_task_storage_get(&task_ctx_stor, p, 0,
	BPF_LOCAL_STORAGE_GET_F_CREATE))
	return 0;
	else
	return -ENOMEM;
	}

	s32 BPF_STRUCT_OPS(userland_init)
	{
	if (num_possible_cpus == 0) {
	scx_bpf_error("User scheduler # CPUs uninitialized (%d)",
	num_possible_cpus);
	return -EINVAL;
	}

	if (usersched_pid <= 0) {
	scx_bpf_error("User scheduler pid uninitialized (%d)",
	usersched_pid);
	return -EINVAL;
	}

	return 0;
	}

	void BPF_STRUCT_OPS(userland_exit, struct scx_exit_info *ei)
	{
	UEI_RECORD(uei, ei);
	}

	SCX_OPS_DEFINE(userland_ops,
	.select_cpu = (void *)userland_select_cpu,
	.enqueue = (void *)userland_enqueue,
	.dispatch = (void *)userland_dispatch,
	.update_idle = (void *)userland_update_idle,
	.init_task = (void *)userland_init_task,
	.init = (void *)userland_init,
	.exit = (void *)userland_exit,
	.flags = SCX_OPS_ENQ_LAST \|
	SCX_OPS_KEEP_BUILTIN_IDLE,
	.name = "userland");