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linux-next/Documentation/powerpc/pmu-ebb.txt
Michael Ellerman 330a1eb777 powerpc/perf: Core EBB support for 64-bit book3s
Add support for EBB (Event Based Branches) on 64-bit book3s. See the
included documentation for more details.

EBBs are a feature which allows the hardware to branch directly to a
specified user space address when a PMU event overflows. This can be
used by programs for self-monitoring with no kernel involvement in the
inner loop.

Most of the logic is in the generic book3s code, primarily to avoid a
proliferation of PMU callbacks.

Signed-off-by: Michael Ellerman <michael@ellerman.id.au>
Signed-off-by: Benjamin Herrenschmidt <benh@kernel.crashing.org>
2013-07-01 11:50:10 +10:00

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PMU Event Based Branches
========================
Event Based Branches (EBBs) are a feature which allows the hardware to
branch directly to a specified user space address when certain events occur.
The full specification is available in Power ISA v2.07:
https://www.power.org/documentation/power-isa-version-2-07/
One type of event for which EBBs can be configured is PMU exceptions. This
document describes the API for configuring the Power PMU to generate EBBs,
using the Linux perf_events API.
Terminology
-----------
Throughout this document we will refer to an "EBB event" or "EBB events". This
just refers to a struct perf_event which has set the "EBB" flag in its
attr.config. All events which can be configured on the hardware PMU are
possible "EBB events".
Background
----------
When a PMU EBB occurs it is delivered to the currently running process. As such
EBBs can only sensibly be used by programs for self-monitoring.
It is a feature of the perf_events API that events can be created on other
processes, subject to standard permission checks. This is also true of EBB
events, however unless the target process enables EBBs (via mtspr(BESCR)) no
EBBs will ever be delivered.
This makes it possible for a process to enable EBBs for itself, but not
actually configure any events. At a later time another process can come along
and attach an EBB event to the process, which will then cause EBBs to be
delivered to the first process. It's not clear if this is actually useful.
When the PMU is configured for EBBs, all PMU interrupts are delivered to the
user process. This means once an EBB event is scheduled on the PMU, no non-EBB
events can be configured. This means that EBB events can not be run
concurrently with regular 'perf' commands, or any other perf events.
It is however safe to run 'perf' commands on a process which is using EBBs. The
kernel will in general schedule the EBB event, and perf will be notified that
its events could not run.
The exclusion between EBB events and regular events is implemented using the
existing "pinned" and "exclusive" attributes of perf_events. This means EBB
events will be given priority over other events, unless they are also pinned.
If an EBB event and a regular event are both pinned, then whichever is enabled
first will be scheduled and the other will be put in error state. See the
section below titled "Enabling an EBB event" for more information.
Creating an EBB event
---------------------
To request that an event is counted using EBB, the event code should have bit
63 set.
EBB events must be created with a particular, and restrictive, set of
attributes - this is so that they interoperate correctly with the rest of the
perf_events subsystem.
An EBB event must be created with the "pinned" and "exclusive" attributes set.
Note that if you are creating a group of EBB events, only the leader can have
these attributes set.
An EBB event must NOT set any of the "inherit", "sample_period", "freq" or
"enable_on_exec" attributes.
An EBB event must be attached to a task. This is specified to perf_event_open()
by passing a pid value, typically 0 indicating the current task.
All events in a group must agree on whether they want EBB. That is all events
must request EBB, or none may request EBB.
EBB events must specify the PMC they are to be counted on. This ensures
userspace is able to reliably determine which PMC the event is scheduled on.
Enabling an EBB event
---------------------
Once an EBB event has been successfully opened, it must be enabled with the
perf_events API. This can be achieved either via the ioctl() interface, or the
prctl() interface.
However, due to the design of the perf_events API, enabling an event does not
guarantee that it has been scheduled on the PMU. To ensure that the EBB event
has been scheduled on the PMU, you must perform a read() on the event. If the
read() returns EOF, then the event has not been scheduled and EBBs are not
enabled.
This behaviour occurs because the EBB event is pinned and exclusive. When the
EBB event is enabled it will force all other non-pinned events off the PMU. In
this case the enable will be successful. However if there is already an event
pinned on the PMU then the enable will not be successful.
Reading an EBB event
--------------------
It is possible to read() from an EBB event. However the results are
meaningless. Because interrupts are being delivered to the user process the
kernel is not able to count the event, and so will return a junk value.
Closing an EBB event
--------------------
When an EBB event is finished with, you can close it using close() as for any
regular event. If this is the last EBB event the PMU will be deconfigured and
no further PMU EBBs will be delivered.
EBB Handler
-----------
The EBB handler is just regular userspace code, however it must be written in
the style of an interrupt handler. When the handler is entered all registers
are live (possibly) and so must be saved somehow before the handler can invoke
other code.
It's up to the program how to handle this. For C programs a relatively simple
option is to create an interrupt frame on the stack and save registers there.
Fork
----
EBB events are not inherited across fork. If the child process wishes to use
EBBs it should open a new event for itself. Similarly the EBB state in
BESCR/EBBHR/EBBRR is cleared across fork().