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156 lines
6.2 KiB
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======================
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Asymmetric 32-bit SoCs
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======================
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Author: Will Deacon <will@kernel.org>
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This document describes the impact of asymmetric 32-bit SoCs on the
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execution of 32-bit (``AArch32``) applications.
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Date: 2021-05-17
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Introduction
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============
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Some Armv9 SoCs suffer from a big.LITTLE misfeature where only a subset
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of the CPUs are capable of executing 32-bit user applications. On such
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a system, Linux by default treats the asymmetry as a "mismatch" and
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disables support for both the ``PER_LINUX32`` personality and
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``execve(2)`` of 32-bit ELF binaries, with the latter returning
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``-ENOEXEC``. If the mismatch is detected during late onlining of a
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64-bit-only CPU, then the onlining operation fails and the new CPU is
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unavailable for scheduling.
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Surprisingly, these SoCs have been produced with the intention of
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running legacy 32-bit binaries. Unsurprisingly, that doesn't work very
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well with the default behaviour of Linux.
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It seems inevitable that future SoCs will drop 32-bit support
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altogether, so if you're stuck in the unenviable position of needing to
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run 32-bit code on one of these transitionary platforms then you would
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be wise to consider alternatives such as recompilation, emulation or
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retirement. If neither of those options are practical, then read on.
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Enabling kernel support
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=======================
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Since the kernel support is not completely transparent to userspace,
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allowing 32-bit tasks to run on an asymmetric 32-bit system requires an
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explicit "opt-in" and can be enabled by passing the
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``allow_mismatched_32bit_el0`` parameter on the kernel command-line.
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For the remainder of this document we will refer to an *asymmetric
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system* to mean an asymmetric 32-bit SoC running Linux with this kernel
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command-line option enabled.
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Userspace impact
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================
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32-bit tasks running on an asymmetric system behave in mostly the same
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way as on a homogeneous system, with a few key differences relating to
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CPU affinity.
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sysfs
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-----
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The subset of CPUs capable of running 32-bit tasks is described in
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``/sys/devices/system/cpu/aarch32_el0`` and is documented further in
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``Documentation/ABI/testing/sysfs-devices-system-cpu``.
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**Note:** CPUs are advertised by this file as they are detected and so
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late-onlining of 32-bit-capable CPUs can result in the file contents
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being modified by the kernel at runtime. Once advertised, CPUs are never
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removed from the file.
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``execve(2)``
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-------------
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On a homogeneous system, the CPU affinity of a task is preserved across
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``execve(2)``. This is not always possible on an asymmetric system,
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specifically when the new program being executed is 32-bit yet the
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affinity mask contains 64-bit-only CPUs. In this situation, the kernel
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determines the new affinity mask as follows:
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1. If the 32-bit-capable subset of the affinity mask is not empty,
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then the affinity is restricted to that subset and the old affinity
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mask is saved. This saved mask is inherited over ``fork(2)`` and
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preserved across ``execve(2)`` of 32-bit programs.
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**Note:** This step does not apply to ``SCHED_DEADLINE`` tasks.
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See `SCHED_DEADLINE`_.
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2. Otherwise, the cpuset hierarchy of the task is walked until an
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ancestor is found containing at least one 32-bit-capable CPU. The
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affinity of the task is then changed to match the 32-bit-capable
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subset of the cpuset determined by the walk.
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3. On failure (i.e. out of memory), the affinity is changed to the set
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of all 32-bit-capable CPUs of which the kernel is aware.
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A subsequent ``execve(2)`` of a 64-bit program by the 32-bit task will
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invalidate the affinity mask saved in (1) and attempt to restore the CPU
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affinity of the task using the saved mask if it was previously valid.
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This restoration may fail due to intervening changes to the deadline
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policy or cpuset hierarchy, in which case the ``execve(2)`` continues
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with the affinity unchanged.
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Calls to ``sched_setaffinity(2)`` for a 32-bit task will consider only
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the 32-bit-capable CPUs of the requested affinity mask. On success, the
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affinity for the task is updated and any saved mask from a prior
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``execve(2)`` is invalidated.
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``SCHED_DEADLINE``
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------------------
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Explicit admission of a 32-bit deadline task to the default root domain
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(e.g. by calling ``sched_setattr(2)``) is rejected on an asymmetric
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32-bit system unless admission control is disabled by writing -1 to
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``/proc/sys/kernel/sched_rt_runtime_us``.
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``execve(2)`` of a 32-bit program from a 64-bit deadline task will
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return ``-ENOEXEC`` if the root domain for the task contains any
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64-bit-only CPUs and admission control is enabled. Concurrent offlining
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of 32-bit-capable CPUs may still necessitate the procedure described in
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`execve(2)`_, in which case step (1) is skipped and a warning is
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emitted on the console.
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**Note:** It is recommended that a set of 32-bit-capable CPUs are placed
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into a separate root domain if ``SCHED_DEADLINE`` is to be used with
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32-bit tasks on an asymmetric system. Failure to do so is likely to
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result in missed deadlines.
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Cpusets
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-------
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The affinity of a 32-bit task on an asymmetric system may include CPUs
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that are not explicitly allowed by the cpuset to which it is attached.
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This can occur as a result of the following two situations:
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- A 64-bit task attached to a cpuset which allows only 64-bit CPUs
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executes a 32-bit program.
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- All of the 32-bit-capable CPUs allowed by a cpuset containing a
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32-bit task are offlined.
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In both of these cases, the new affinity is calculated according to step
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(2) of the process described in `execve(2)`_ and the cpuset hierarchy is
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unchanged irrespective of the cgroup version.
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CPU hotplug
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-----------
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On an asymmetric system, the first detected 32-bit-capable CPU is
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prevented from being offlined by userspace and any such attempt will
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return ``-EPERM``. Note that suspend is still permitted even if the
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primary CPU (i.e. CPU 0) is 64-bit-only.
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KVM
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---
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Although KVM will not advertise 32-bit EL0 support to any vCPUs on an
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asymmetric system, a broken guest at EL1 could still attempt to execute
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32-bit code at EL0. In this case, an exit from a vCPU thread in 32-bit
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mode will return to host userspace with an ``exit_reason`` of
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``KVM_EXIT_FAIL_ENTRY`` and will remain non-runnable until successfully
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re-initialised by a subsequent ``KVM_ARM_VCPU_INIT`` operation.
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