Hi Leo,
Thanks for your work on this!
On Sat, Aug 26, 2023 at 12:09 AM Leo Yan <[email protected]> wrote:
>
> In the Linux perf tool, the ring buffer serves not only as a medium for
> transferring PMU event data but also as a vital mechanism for hardware
> tracing using technologies like Intel PT and Arm CoreSight, etc.
>
> Consequently, the ring buffer mechanism plays a crucial role by ensuring
> high throughput for data transfer between the kernel and user space
> while avoiding excessive overhead caused by the ring buffer itself.
>
> This commit documents the ring buffer mechanism in detail. It explains
> the implementation of both the regular ring buffer and the AUX ring
> buffer. Additionally, it covers how these ring buffers support various
> tracing modes and explains the synchronization with memory barriers.
>
> Signed-off-by: Leo Yan <[email protected]>
> ---
[SNIP]
> +.. _writing_samples_into_buffer:
> +
> +2.3.2 Writing samples into buffer
> +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
> +
> +Ring buffers are mapped in either read-write mode or read-only mode to
> +the user space.
> +
> +The ring buffer in the read-write mode is mapped with the property
> +``PROT_READ | PROT_WRITE``. With the write permission, the perf tool
> +updates the ``data_tail`` to indicate the data start position. Combining
> +with the head pointer ``data_head``, which works as the end position of
> +the current data, the perf tool can easily know where read out the data
> +from.
> +
> +Alternatively, in the read-only mode, only the kernel keeps to update
> +the ``data_head`` while the user space cannot access the ``data_tail`` due
> +to the mapping property ``PROT_READ``.
> +
> +In addition to the mapping modes, the write direction also matters. The
> +perf tool supports two write directions: forward and backward. As a
s/perf tool/Linux kernel/
> +result, the matrix below shows the combinations between the mapping
> +modes and write directions.
> +
> +.. list-table::
> + :widths: 1 1 1
> + :header-rows: 1
> +
> + * - Mapping mode
> + - Forward
> + - Backward
> + * - read-write
> + - Normal ring buffer
> + - Not supported
> + * - read-only
> + - Not supported
> + - Overwritable ring buffer
In the kernel's point of view, they are supported. It's just perf tool
not using them. So I think we should say "Not used".
> +
> +The normal ring buffer uses the read-write mapping with forward writing.
> +It starts to save data from the beginning of the ring buffer and wrap
> +around when overflow, which is used with the read-write mode in the
> +normal ring buffer. When the consumer doesn't keep up with the
> +producer, it would lose some data, the kernel keeps how many records it
> +lost and generates the ``PERF_RECORD_LOST`` records in the next time
> +when it finds a space in the ring buffer.
> +
> +On the other hand, the overwritable ring buffer uses the backward
> +writing with the read-only mode. It saves the data from the end of the
> +ring buffer and the ``data_head`` keeps the position of current data,
> +the perf always knows where it starts to read and until the end of the
> +ring buffer, thus it don't need the ``data_tail``. In this mode, it
> +will not generate the ``PERF_RECORD_LOST`` records.
> +
> +When a sample is taken and saved into the ring buffer, the kernel
> +prepares sample fields based on the sample type; then it prepares the
> +info for writing ring buffer which is stored in the structure
> +``perf_output_handle``. In the end, the kernel outputs the sample into
> +the ring buffer and updates the head pointer in the user page so the
> +perf tool can see the latest value.
> +
> +The structure ``perf_output_handle`` serves as a temporary context for
> +tracking the information related to the buffer. The advantages of it is
> +that it enables concurrent writing to the buffer by different events.
> +For example, a software event and a hardware PMU event both are enabled
> +for profiling, two instances of ``perf_output_handle`` serve as separate
> +contexts for the software event and the hardware event respectively.
> +This allows each event to reserve its own memory space for populating
> +the record data.
> +
[SNIP]
> +
> +3. The mechanism of AUX ring buffer
> +===================================
> +
> +In this chapter, we will explain the implementation of the AUX ring
> +buffer. In the first part it will discuss the connection between the
> +AUX ring buffer and the regular ring buffer, then the second part will
> +examine how the AUX ring buffer co-works with the regular ring buffer,
> +as well as the additional features introduced by the AUX ring buffer for
> +the sampling mechanism.
> +
> +3.1 The relationship between AUX and regular ring buffers
> +---------------------------------------------------------
> +
> +Generally, the AUX ring buffer is an auxiliary for the regular ring
> +buffer. The regular ring buffer is primarily used to store the event
> +samples and every event format complies with the definition in the
> +union ``perf_event``; the AUX ring buffer is for recording the hardware
> +trace data and the trace data format is hardware IP dependent.
> +
> +The general use and advantage of the AUX ring buffer is that it is
> +written directly by hardware rather than by the kernel. For example,
> +regular profile samples that write to the regular ring buffer cause an
> +interrupt. Tracing execution requires a high number of samples and
> +using interrupts would be overwhelming for the regular ring buffer
> +mechanism. Having an AUX buffer allows for a region of memory more
> +decoupled from the kernel and written to directly by hardware tracing.
> +
> +The AUX ring buffer reuses the same algorithm with the regular ring
> +buffer for the buffer management. The control structure
> +``perf_event_mmap_page`` extends the new fields ``aux_head`` and ``aux_tail``
> +for the head and tail pointers of the AUX ring buffer.
> +
> +During the initialisation phase, besides the mmap()-ed regular ring
> +buffer, the perf tool invokes a second syscall in the
second mmap syscall
> +``auxtrace_mmap__mmap()`` function for the mmap of the AUX buffer;
with non-zero file offset.
> +``rb_alloc_aux()`` in the kernel allocates pages correspondingly, these
> +pages will be deferred to map into VMA when handling the page fault,
> +which is the same lazy mechanism with the regular ring buffer.
> +
> +AUX events and AUX trace data are two different things. Let's see an
> +example::
> +
> + perf record -a -e cycles -e cs_etm/@tmc_etr0/ -- sleep 2
> +
> +The above command enables two events: one is the event *cycles* from PMU
> +and another is the AUX event *cs_etm* from Arm CoreSight, both are saved
> +into the regular ring buffer while the CoreSight's AUX trace data is
> +stored in the AUX ring buffer.
> +
> +As a result, we can see the regular ring buffer and the AUX ring buffer
> +are allocated in pairs. The perf in default mode allocates the regular
> +ring buffer and the AUX ring buffer per CPU-wise, which is the same as
> +the system wide mode, however, the default mode records samples only for
> +the profiled program, whereas the latter mode profiles for all programs
> +in the system. For per-thread mode, the perf tool allocates only one
> +regular ring buffer and one AUX ring buffer for the whole session. For
> +the per-CPU mode, the perf allocates two kinds of ring buffers for CPUs
> +specified by the option ``-C``.
Considering -a option, it can be "ring buffers for selected CPUs".
> +
> +The below figure demonstrates the buffers' layout in the system wide
> +mode; if there are any activities on one CPU, the AUX event samples and
> +the hardware trace data will be recorded into the dedicated buffers for
> +the CPU.
> +
> +::
> +
> + T1 T2 T1
> + +----+ +-----------+ +----+
> + CPU0 |xxxx| |xxxxxxxxxxx| |xxxx|
> + +----+--------------+-----------+----------+----+-------->
> + | | |
> + v v v
> + +-----------------------------------------------------+
> + | Ring buffer 0 |
> + +-----------------------------------------------------+
> + | | |
> + v v v
> + +-----------------------------------------------------+
> + | AUX Ring buffer 0 |
> + +-----------------------------------------------------+
> +
> + T1
> + +-----+
> + CPU1 |xxxxx|
> + -----+-----+--------------------------------------------->
> + |
> + v
> + +-----------------------------------------------------+
> + | Ring buffer 1 |
> + +-----------------------------------------------------+
> + |
> + v
> + +-----------------------------------------------------+
> + | AUX Ring buffer 1 |
> + +-----------------------------------------------------+
> +
> + T1 T3
> + +----+ +-------+
> + CPU2 |xxxx| |xxxxxxx|
> + --------------------------+----+--------+-------+-------->
> + | |
> + v v
> + +-----------------------------------------------------+
> + | Ring buffer 2 |
> + +-----------------------------------------------------+
> + | |
> + v v
> + +-----------------------------------------------------+
> + | AUX Ring buffer 2 |
> + +-----------------------------------------------------+
> +
> + T1
> + +--------------+
> + CPU3 |xxxxxxxxxxxxxx|
> + -----------+--------------+------------------------------>
> + |
> + v
> + +-----------------------------------------------------+
> + | Ring buffer 3 |
> + +-----------------------------------------------------+
> + |
> + v
> + +-----------------------------------------------------+
> + | AUX Ring buffer 3 |
> + +-----------------------------------------------------+
> +
> + T1: Thread 1; T2: Thread 2; T3: Thread 3
> + x: Thread is in running state
> +
> + Figure 8. AUX ring buffer for system wide mode
> +
> +3.2 AUX events
> +--------------
> +
> +Similar to ``perf_output_begin()`` and ``perf_output_end()``'s working for the
> +regular ring buffer, ``perf_aux_output_begin()`` and ``perf_aux_output_end()``
> +serve for the AUX ring buffer for processing the hardware trace data.
> +The structure ``perf_output_handle`` is used as a context to track the AUX
> +buffer’s info.
I feel like this section contains kernel implementation details.
Please focus on the user-visible aspect.
> +
> +``perf_aux_output_begin()`` initializes the structure perf_output_handle.
> +It fetches the AUX head pointer and assigns to ``perf_output_handle::head``,
> +afterwards, the low level driver uses ``perf_output_handle::head`` as the
> +start address for storing hardware trace data.
> +
> +Once the hardware trace data is stored into the AUX ring buffer, the PMU
> +driver will stop hardware tracing by calling the ``pmu::stop()`` callback.
> +Similar to the regular ring buffer, the AUX ring buffer needs to apply
> +the memory synchronization mechanism as discussed in the section
> +:ref:`memory_synchronization`. Since the AUX ring buffer is managed by the
> +PMU driver, the barrier (B), which is a writing barrier to ensure the trace
> +data is externally visible prior to updating the head pointer, is asked
> +to be implemented in the PMU driver.
> +
> +Then ``pmu::stop()`` can safely call the ``perf_aux_output_end()`` function to
> +finish two things:
> +
> +- It fills an event ``PERF_RECORD_AUX`` into the regular ring buffer, this
> + event delivers the information of the start address and data size for a
> + chunk of hardware trace data has been stored into the AUX ring buffer;
> +
> +- Since the hardware trace driver has stored new trace data into the AUX
> + ring buffer, the argument *size* indicates how many bytes have been
> + consumed by the hardware tracing, thus ``perf_aux_output_end()`` updates the
> + header pointer ``perf_buffer::aux_head`` to reflect the latest buffer usage.
> +
> +At the end, the PMU driver will restart hardware tracing. During this
> +temporary suspending period, it will lose hardware trace data, which
> +will introduce a discontinuity during decoding phase.
> +
> +The event ``PERF_RECORD_AUX`` presents an AUX event which is handled in the
> +kernel, but it lacks the information for saving the AUX trace data in
> +the perf file. When the perf tool copies the trace data from AUX ring
> +buffer to the perf data file, it synthesizes a ``PERF_RECORD_AUXTRACE``
I think you should mention that AUXTRACE record is not a kernel ABI.
It's defined by perf tool to describe which portion of data in the AUX
ring buffer is saved.
Thanks,
Namhyung
> +event which includes the offest and size of the AUX trace data in the
> +perf file. Afterwards, the perf tool reads out the AUX trace data from
> +the perf file based on the ``PERF_RECORD_AUXTRACE`` events, and the
> +``PERF_RECORD_AUX`` event is used to decode a chunk of data by correlating
> +with time order.
> +
> +3.3 Snapshot mode
> +-----------------
> +
> +Perf supports snapshot mode for AUX ring buffer, in this mode, users
> +only record AUX trace data at a specific time point which users are
> +interested in. E.g. below gives an example of how to take snapshots
> +with 1 second interval with Arm CoreSight::
> +
> + perf record -e cs_etm/@tmc_etr0/u -S -a program &
> + PERFPID=$!
> + while true; do
> + kill -USR2 $PERFPID
> + sleep 1
> + done
> +
> +The main flow for snapshot mode is:
> +
> +- Before a snapshot is taken, the AUX ring buffer acts in free run mode.
> + During free run mode the perf doesn't record any of the AUX events and
> + trace data;
> +
> +- Once the perf tool receives the *USR2* signal, it triggers the callback
> + function ``auxtrace_record::snapshot_start()`` to deactivate hardware
> + tracing. The kernel driver then populates the AUX ring buffer with the
> + hardware trace data, and the event ``PERF_RECORD_AUX`` is stored in the
> + regular ring buffer;
> +
> +- Then perf tool takes a snapshot, ``record__read_auxtrace_snapshot()``
> + reads out the hardware trace data from the AUX ring buffer and saves it
> + into perf data file;
> +
> +- After the snapshot is finished, ``auxtrace_record::snapshot_finish()``
> + restarts the PMU event for AUX tracing.
> +
> +The perf only accesses the head pointer ``perf_event_mmap_page::aux_head``
> +in snapshot mode and doesn’t touch tail pointer ``aux_tail``, this is
> +because the AUX ring buffer can overflow in free run mode, the tail
> +pointer is useless in this case. Alternatively, the callback
> +``auxtrace_record::find_snapshot()`` is introduced for making the decision
> +of whether the AUX ring buffer has been wrapped around or not, at the
> +end it fixes up the AUX buffer's head which are used to calculate the
> +trace data size.
> +
> +As we know, the buffers' deployment can be per-thread mode, per-CPU
> +mode, or system wide mode, and the snapshot can be applied to any of
> +these modes. Below is an example of taking snapshot with system wide
> +mode.
> +
> +::
> +
> + Snapshot is taken
> + |
> + v
> + +------------------------+
> + | AUX Ring buffer 0 | <- aux_head
> + +------------------------+
> + v
> + +--------------------------------+
> + | AUX Ring buffer 1 | <- aux_head
> + +--------------------------------+
> + v
> + +--------------------------------------------+
> + | AUX Ring buffer 2 | <- aux_head
> + +--------------------------------------------+
> + v
> + +---------------------------------------+
> + | AUX Ring buffer 3 | <- aux_head
> + +---------------------------------------+
> +
> + Figure 9. Snapshot with system wide mode
> --
> 2.34.1
>