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fe9beaaa80
While PREEMPT_RT is undoubtedly totally awesome, it does not, at this
time, make sense to have all{yes,mod}config select it.
Reported-by: Stephen Rothwell <sfr@canb.auug.org.au>
Fixes: 35772d627b
("sched: Enable PREEMPT_DYNAMIC for PREEMPT_RT")
Signed-off-by: Peter Zijlstra (Intel) <peterz@infradead.org>
179 lines
6.4 KiB
Plaintext
179 lines
6.4 KiB
Plaintext
# SPDX-License-Identifier: GPL-2.0-only
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config PREEMPT_NONE_BUILD
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bool
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config PREEMPT_VOLUNTARY_BUILD
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bool
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config PREEMPT_BUILD
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bool
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select PREEMPTION
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select UNINLINE_SPIN_UNLOCK if !ARCH_INLINE_SPIN_UNLOCK
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config ARCH_HAS_PREEMPT_LAZY
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bool
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choice
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prompt "Preemption Model"
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default PREEMPT_NONE
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config PREEMPT_NONE
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bool "No Forced Preemption (Server)"
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depends on !PREEMPT_RT
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select PREEMPT_NONE_BUILD if !PREEMPT_DYNAMIC
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help
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This is the traditional Linux preemption model, geared towards
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throughput. It will still provide good latencies most of the
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time, but there are no guarantees and occasional longer delays
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are possible.
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Select this option if you are building a kernel for a server or
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scientific/computation system, or if you want to maximize the
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raw processing power of the kernel, irrespective of scheduling
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latencies.
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config PREEMPT_VOLUNTARY
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bool "Voluntary Kernel Preemption (Desktop)"
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depends on !ARCH_NO_PREEMPT
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depends on !PREEMPT_RT
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select PREEMPT_VOLUNTARY_BUILD if !PREEMPT_DYNAMIC
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help
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This option reduces the latency of the kernel by adding more
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"explicit preemption points" to the kernel code. These new
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preemption points have been selected to reduce the maximum
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latency of rescheduling, providing faster application reactions,
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at the cost of slightly lower throughput.
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This allows reaction to interactive events by allowing a
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low priority process to voluntarily preempt itself even if it
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is in kernel mode executing a system call. This allows
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applications to run more 'smoothly' even when the system is
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under load.
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Select this if you are building a kernel for a desktop system.
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config PREEMPT
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bool "Preemptible Kernel (Low-Latency Desktop)"
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depends on !ARCH_NO_PREEMPT
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select PREEMPT_BUILD if !PREEMPT_DYNAMIC
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help
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This option reduces the latency of the kernel by making
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all kernel code (that is not executing in a critical section)
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preemptible. This allows reaction to interactive events by
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permitting a low priority process to be preempted involuntarily
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even if it is in kernel mode executing a system call and would
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otherwise not be about to reach a natural preemption point.
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This allows applications to run more 'smoothly' even when the
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system is under load, at the cost of slightly lower throughput
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and a slight runtime overhead to kernel code.
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Select this if you are building a kernel for a desktop or
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embedded system with latency requirements in the milliseconds
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range.
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config PREEMPT_LAZY
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bool "Scheduler controlled preemption model"
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depends on !ARCH_NO_PREEMPT
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depends on ARCH_HAS_PREEMPT_LAZY
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select PREEMPT_BUILD if !PREEMPT_DYNAMIC
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help
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This option provides a scheduler driven preemption model that
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is fundamentally similar to full preemption, but is less
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eager to preempt SCHED_NORMAL tasks in an attempt to
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reduce lock holder preemption and recover some of the performance
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gains seen from using Voluntary preemption.
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endchoice
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config PREEMPT_RT
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bool "Fully Preemptible Kernel (Real-Time)"
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depends on EXPERT && ARCH_SUPPORTS_RT && !COMPILE_TEST
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select PREEMPTION
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help
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This option turns the kernel into a real-time kernel by replacing
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various locking primitives (spinlocks, rwlocks, etc.) with
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preemptible priority-inheritance aware variants, enforcing
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interrupt threading and introducing mechanisms to break up long
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non-preemptible sections. This makes the kernel, except for very
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low level and critical code paths (entry code, scheduler, low
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level interrupt handling) fully preemptible and brings most
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execution contexts under scheduler control.
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Select this if you are building a kernel for systems which
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require real-time guarantees.
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config PREEMPT_COUNT
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bool
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config PREEMPTION
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bool
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select PREEMPT_COUNT
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config PREEMPT_DYNAMIC
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bool "Preemption behaviour defined on boot"
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depends on HAVE_PREEMPT_DYNAMIC
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select JUMP_LABEL if HAVE_PREEMPT_DYNAMIC_KEY
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select PREEMPT_BUILD
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default y if HAVE_PREEMPT_DYNAMIC_CALL
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help
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This option allows to define the preemption model on the kernel
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command line parameter and thus override the default preemption
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model defined during compile time.
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The feature is primarily interesting for Linux distributions which
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provide a pre-built kernel binary to reduce the number of kernel
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flavors they offer while still offering different usecases.
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The runtime overhead is negligible with HAVE_STATIC_CALL_INLINE enabled
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but if runtime patching is not available for the specific architecture
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then the potential overhead should be considered.
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Interesting if you want the same pre-built kernel should be used for
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both Server and Desktop workloads.
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config SCHED_CORE
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bool "Core Scheduling for SMT"
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depends on SCHED_SMT
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help
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This option permits Core Scheduling, a means of coordinated task
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selection across SMT siblings. When enabled -- see
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prctl(PR_SCHED_CORE) -- task selection ensures that all SMT siblings
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will execute a task from the same 'core group', forcing idle when no
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matching task is found.
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Use of this feature includes:
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- mitigation of some (not all) SMT side channels;
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- limiting SMT interference to improve determinism and/or performance.
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SCHED_CORE is default disabled. When it is enabled and unused,
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which is the likely usage by Linux distributions, there should
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be no measurable impact on performance.
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config SCHED_CLASS_EXT
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bool "Extensible Scheduling Class"
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depends on BPF_SYSCALL && BPF_JIT && DEBUG_INFO_BTF
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select STACKTRACE if STACKTRACE_SUPPORT
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help
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This option enables a new scheduler class sched_ext (SCX), which
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allows scheduling policies to be implemented as BPF programs to
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achieve the following:
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- Ease of experimentation and exploration: Enabling rapid
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iteration of new scheduling policies.
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- Customization: Building application-specific schedulers which
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implement policies that are not applicable to general-purpose
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schedulers.
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- Rapid scheduler deployments: Non-disruptive swap outs of
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scheduling policies in production environments.
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sched_ext leverages BPF struct_ops feature to define a structure
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which exports function callbacks and flags to BPF programs that
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wish to implement scheduling policies. The struct_ops structure
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exported by sched_ext is struct sched_ext_ops, and is conceptually
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similar to struct sched_class.
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For more information:
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Documentation/scheduler/sched-ext.rst
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https://github.com/sched-ext/scx
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