linux/tools/sched_ext
Tejun Heo 8195136669 sched_ext: Add cgroup support
Add sched_ext_ops operations to init/exit cgroups, and track task migrations
and config changes. A BPF scheduler may not implement or implement only
subset of cgroup features. The implemented features can be indicated using
%SCX_OPS_HAS_CGOUP_* flags. If cgroup configuration makes use of features
that are not implemented, a warning is triggered.

While a BPF scheduler is being enabled and disabled, relevant cgroup
operations are locked out using scx_cgroup_rwsem. This avoids situations
like task prep taking place while the task is being moved across cgroups,
making things easier for BPF schedulers.

v7: - cgroup interface file visibility toggling is dropped in favor just
      warning messages. Dynamically changing interface visiblity caused more
      confusion than helping.

v6: - Updated to reflect the removal of SCX_KF_SLEEPABLE.

    - Updated to use CONFIG_GROUP_SCHED_WEIGHT and fixes for
      !CONFIG_FAIR_GROUP_SCHED && CONFIG_EXT_GROUP_SCHED.

v5: - Flipped the locking order between scx_cgroup_rwsem and
      cpus_read_lock() to avoid locking order conflict w/ cpuset. Better
      documentation around locking.

    - sched_move_task() takes an early exit if the source and destination
      are identical. This triggered the warning in scx_cgroup_can_attach()
      as it left p->scx.cgrp_moving_from uncleared. Updated the cgroup
      migration path so that ops.cgroup_prep_move() is skipped for identity
      migrations so that its invocations always match ops.cgroup_move()
      one-to-one.

v4: - Example schedulers moved into their own patches.

    - Fix build failure when !CONFIG_CGROUP_SCHED, reported by Andrea Righi.

v3: - Make scx_example_pair switch all tasks by default.

    - Convert to BPF inline iterators.

    - scx_bpf_task_cgroup() is added to determine the current cgroup from
      CPU controller's POV. This allows BPF schedulers to accurately track
      CPU cgroup membership.

    - scx_example_flatcg added. This demonstrates flattened hierarchy
      implementation of CPU cgroup control and shows significant performance
      improvement when cgroups which are nested multiple levels are under
      competition.

v2: - Build fixes for different CONFIG combinations.

Signed-off-by: Tejun Heo <tj@kernel.org>
Reviewed-by: David Vernet <dvernet@meta.com>
Acked-by: Josh Don <joshdon@google.com>
Acked-by: Hao Luo <haoluo@google.com>
Acked-by: Barret Rhoden <brho@google.com>
Reported-by: kernel test robot <lkp@intel.com>
Cc: Andrea Righi <andrea.righi@canonical.com>
2024-09-04 10:24:59 -10:00
..
include sched_ext: Add cgroup support 2024-09-04 10:24:59 -10:00
.gitignore sched_ext: Add scx_simple and scx_example_qmap example schedulers 2024-06-18 10:09:17 -10:00
Makefile sched_ext: Add a central scheduler which makes all scheduling decisions on one CPU 2024-06-18 10:09:19 -10:00
README.md sched_ext: Documentation: scheduler: Document extensible scheduler class 2024-06-18 10:09:21 -10:00
scx_central.bpf.c scx_central: Fix smatch checker warning 2024-08-27 10:21:34 -10:00
scx_central.c sched_ext: Implement sched_ext_ops.cpu_online/offline() 2024-06-18 10:09:20 -10:00
scx_qmap.bpf.c sched_ext: Don't call put_prev_task_scx() before picking the next task 2024-09-03 21:54:28 -10:00
scx_qmap.c sched_ext/scx_qmap: Pick idle CPU for direct dispatch on !wakeup enqueues 2024-07-12 08:20:33 -10:00
scx_show_state.py tools/sched_ext: Add scx_show_state.py 2024-06-18 10:09:18 -10:00
scx_simple.bpf.c sched_ext: Add vtime-ordered priority queue to dispatch_q's 2024-06-18 10:09:21 -10:00
scx_simple.c sched_ext: Add vtime-ordered priority queue to dispatch_q's 2024-06-18 10:09:21 -10:00

SCHED_EXT EXAMPLE SCHEDULERS

Introduction

This directory contains a number of example sched_ext schedulers. These schedulers are meant to provide examples of different types of schedulers that can be built using sched_ext, and illustrate how various features of sched_ext can be used.

Some of the examples are performant, production-ready schedulers. That is, for the correct workload and with the correct tuning, they may be deployed in a production environment with acceptable or possibly even improved performance. Others are just examples that in practice, would not provide acceptable performance (though they could be improved to get there).

This README will describe these example schedulers, including describing the types of workloads or scenarios they're designed to accommodate, and whether or not they're production ready. For more details on any of these schedulers, please see the header comment in their .bpf.c file.

Compiling the examples

There are a few toolchain dependencies for compiling the example schedulers.

Toolchain dependencies

  1. clang >= 16.0.0

The schedulers are BPF programs, and therefore must be compiled with clang. gcc is actively working on adding a BPF backend compiler as well, but are still missing some features such as BTF type tags which are necessary for using kptrs.

  1. pahole >= 1.25

You may need pahole in order to generate BTF from DWARF.

  1. rust >= 1.70.0

Rust schedulers uses features present in the rust toolchain >= 1.70.0. You should be able to use the stable build from rustup, but if that doesn't work, try using the rustup nightly build.

There are other requirements as well, such as make, but these are the main / non-trivial ones.

Compiling the kernel

In order to run a sched_ext scheduler, you'll have to run a kernel compiled with the patches in this repository, and with a minimum set of necessary Kconfig options:

CONFIG_BPF=y
CONFIG_SCHED_CLASS_EXT=y
CONFIG_BPF_SYSCALL=y
CONFIG_BPF_JIT=y
CONFIG_DEBUG_INFO_BTF=y

It's also recommended that you also include the following Kconfig options:

CONFIG_BPF_JIT_ALWAYS_ON=y
CONFIG_BPF_JIT_DEFAULT_ON=y
CONFIG_PAHOLE_HAS_SPLIT_BTF=y
CONFIG_PAHOLE_HAS_BTF_TAG=y

There is a Kconfig file in this directory whose contents you can append to your local .config file, as long as there are no conflicts with any existing options in the file.

Getting a vmlinux.h file

You may notice that most of the example schedulers include a "vmlinux.h" file. This is a large, auto-generated header file that contains all of the types defined in some vmlinux binary that was compiled with BTF (i.e. with the BTF-related Kconfig options specified above).

The header file is created using bpftool, by passing it a vmlinux binary compiled with BTF as follows:

$ bpftool btf dump file /path/to/vmlinux format c > vmlinux.h

bpftool analyzes all of the BTF encodings in the binary, and produces a header file that can be included by BPF programs to access those types. For example, using vmlinux.h allows a scheduler to access fields defined directly in vmlinux as follows:

#include "vmlinux.h"
// vmlinux.h is also implicitly included by scx_common.bpf.h.
#include "scx_common.bpf.h"

/*
 * vmlinux.h provides definitions for struct task_struct and
 * struct scx_enable_args.
 */
void BPF_STRUCT_OPS(example_enable, struct task_struct *p,
		    struct scx_enable_args *args)
{
	bpf_printk("Task %s enabled in example scheduler", p->comm);
}

// vmlinux.h provides the definition for struct sched_ext_ops.
SEC(".struct_ops.link")
struct sched_ext_ops example_ops {
	.enable	= (void *)example_enable,
	.name	= "example",
}

The scheduler build system will generate this vmlinux.h file as part of the scheduler build pipeline. It looks for a vmlinux file in the following dependency order:

  1. If the O= environment variable is defined, at $O/vmlinux
  2. If the KBUILD_OUTPUT= environment variable is defined, at $KBUILD_OUTPUT/vmlinux
  3. At ../../vmlinux (i.e. at the root of the kernel tree where you're compiling the schedulers)
  4. /sys/kernel/btf/vmlinux
  5. /boot/vmlinux-$(uname -r)

In other words, if you have compiled a kernel in your local repo, its vmlinux file will be used to generate vmlinux.h. Otherwise, it will be the vmlinux of the kernel you're currently running on. This means that if you're running on a kernel with sched_ext support, you may not need to compile a local kernel at all.

Aside on CO-RE

One of the cooler features of BPF is that it supports CO-RE (Compile Once Run Everywhere). This feature allows you to reference fields inside of structs with types defined internal to the kernel, and not have to recompile if you load the BPF program on a different kernel with the field at a different offset. In our example above, we print out a task name with p->comm. CO-RE would perform relocations for that access when the program is loaded to ensure that it's referencing the correct offset for the currently running kernel.

Compiling the schedulers

Once you have your toolchain setup, and a vmlinux that can be used to generate a full vmlinux.h file, you can compile the schedulers using make:

$ make -j($nproc)

Example schedulers

This directory contains the following example schedulers. These schedulers are for testing and demonstrating different aspects of sched_ext. While some may be useful in limited scenarios, they are not intended to be practical.

For more scheduler implementations, tools and documentation, visit https://github.com/sched-ext/scx.

scx_simple

A simple scheduler that provides an example of a minimal sched_ext scheduler. scx_simple can be run in either global weighted vtime mode, or FIFO mode.

Though very simple, in limited scenarios, this scheduler can perform reasonably well on single-socket systems with a unified L3 cache.

scx_qmap

Another simple, yet slightly more complex scheduler that provides an example of a basic weighted FIFO queuing policy. It also provides examples of some common useful BPF features, such as sleepable per-task storage allocation in the ops.prep_enable() callback, and using the BPF_MAP_TYPE_QUEUE map type to enqueue tasks. It also illustrates how core-sched support could be implemented.

scx_central

A "central" scheduler where scheduling decisions are made from a single CPU. This scheduler illustrates how scheduling decisions can be dispatched from a single CPU, allowing other cores to run with infinite slices, without timer ticks, and without having to incur the overhead of making scheduling decisions.

The approach demonstrated by this scheduler may be useful for any workload that benefits from minimizing scheduling overhead and timer ticks. An example of where this could be particularly useful is running VMs, where running with infinite slices and no timer ticks allows the VM to avoid unnecessary expensive vmexits.

Troubleshooting

There are a number of common issues that you may run into when building the schedulers. We'll go over some of the common ones here.

Build Failures

Old version of clang

error: static assertion failed due to requirement 'SCX_DSQ_FLAG_BUILTIN': bpftool generated vmlinux.h is missing high bits for 64bit enums, upgrade clang and pahole
        _Static_assert(SCX_DSQ_FLAG_BUILTIN,
                       ^~~~~~~~~~~~~~~~~~~~
1 error generated.

This means you built the kernel or the schedulers with an older version of clang than what's supported (i.e. older than 16.0.0). To remediate this:

  1. which clang to make sure you're using a sufficiently new version of clang.

  2. make fullclean in the root path of the repository, and rebuild the kernel and schedulers.

  3. Rebuild the kernel, and then your example schedulers.

The schedulers are also cleaned if you invoke make mrproper in the root directory of the tree.

Stale kernel build / incomplete vmlinux.h file

As described above, you'll need a vmlinux.h file that was generated from a vmlinux built with BTF, and with sched_ext support enabled. If you don't, you'll see errors such as the following which indicate that a type being referenced in a scheduler is unknown:

/path/to/sched_ext/tools/sched_ext/user_exit_info.h:25:23: note: forward declaration of 'struct scx_exit_info'

const struct scx_exit_info *ei)

^

In order to resolve this, please follow the steps above in Getting a vmlinux.h file in order to ensure your schedulers are using a vmlinux.h file that includes the requisite types.

Misc

llvm: [OFF]

You may see the following output when building the schedulers:

Auto-detecting system features:
...                         clang-bpf-co-re: [ on  ]
...                                    llvm: [ OFF ]
...                                  libcap: [ on  ]
...                                  libbfd: [ on  ]

Seeing llvm: [ OFF ] here is not an issue. You can safely ignore.