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Documentation: document adreno preemption
Add documentation about the preemption feature supported by the msm driver. Signed-off-by: Antonino Maniscalco <antomani103@gmail.com> Patchwork: https://patchwork.freedesktop.org/patch/618032/ Signed-off-by: Rob Clark <robdclark@chromium.org>
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Documentation/gpu/msm-preemption.rst
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Documentation/gpu/msm-preemption.rst
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.. SPDX-License-Identifier: GPL-2.0
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:orphan:
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==============
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MSM Preemption
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==============
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Preemption allows Adreno GPUs to switch to a higher priority ring when work is
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pushed to it, reducing latency for high priority submissions.
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When preemption is enabled 4 rings are initialized, corresponding to different
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priority levels. Having multiple rings is purely a software concept as the GPU
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only has registers to keep track of one graphics ring.
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The kernel is able to switch which ring is currently being processed by
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requesting preemption. When certain conditions are met, depending on the
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priority level, the GPU will save its current state in a series of buffers,
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then restores state from a similar set of buffers specified by the kernel. It
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then resumes execution and fires an IRQ to let the kernel know the context
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switch has completed.
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This mechanism can be used by the kernel to switch between rings. Whenever a
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submission occurs the kernel finds the highest priority ring which isn't empty
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and preempts to it if said ring is not the one being currently executed. This is
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also done whenever a submission completes to make sure execution resumes on a
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lower priority ring when a higher priority ring is done.
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Preemption levels
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-----------------
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Preemption can only occur at certain boundaries. The exact conditions can be
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configured by changing the preemption level, this allows to compromise between
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latency (ie. the time that passes between when the kernel requests preemption
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and when the SQE begins saving state) and overhead (the amount of state that
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needs to be saved).
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The GPU offers 3 levels:
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Level 0
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Preemption only occurs at the submission level. This requires the least amount
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of state to be saved as the execution of userspace submitted IBs is never
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interrupted, however it offers very little benefit compared to not enabling
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preemption of any kind.
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Level 1
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Preemption occurs at either bin level, if using GMEM rendering, or draw level
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in the sysmem rendering case.
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Level 2
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Preemption occurs at draw level.
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Level 1 is the mode that is used by the msm driver.
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Additionally the GPU allows to specify a `skip_save_restore` option. This
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disables the saving and restoring of all registers except those relating to the
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operation of the SQE itself, reducing overhead. Saving and restoring is only
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skipped when using GMEM with Level 1 preemption. When enabling this userspace is
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expected to set the state that isn't preserved whenever preemption occurs which
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is done by specifying preamble and postambles. Those are IBs that are executed
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before and after preemption.
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Preemption buffers
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------------------
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A series of buffers are necessary to store the state of rings while they are not
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being executed. There are different kinds of preemption records and most of
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those require one buffer per ring. This is because preemption never occurs
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between submissions on the same ring, which always run in sequence when the ring
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is active. This means that only one context per ring is effectively active.
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SMMU_INFO
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This buffer contains info about the current SMMU configuration such as the
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ttbr0 register. The SQE firmware isn't actually able to save this record.
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As a result SMMU info must be saved manually from the CP to a buffer and the
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SMMU record updated with info from said buffer before triggering
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preemption.
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NON_SECURE
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This is the main preemption record where most state is saved. It is mostly
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opaque to the kernel except for the first few words that must be initialized
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by the kernel.
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SECURE
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This saves state related to the GPU's secure mode.
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NON_PRIV
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The intended purpose of this record is unknown. The SQE firmware actually
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ignores it and therefore msm doesn't handle it.
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COUNTER
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This record is used to save and restore performance counters.
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Handling the permissions of those buffers is critical for security. All but the
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NON_PRIV records need to be inaccessible from userspace, so they must be mapped
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in the kernel address space with the MSM_BO_MAP_PRIV flag.
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For example, making the NON_SECURE record accessible from userspace would allow
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any process to manipulate a saved ring's RPTR which can be used to skip the
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execution of some packets in a ring and execute user commands with higher
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privileges.
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