WSL2-Linux-Kernel/Documentation/trace/stm.rst

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.. SPDX-License-Identifier: GPL-2.0
===================
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
System Trace Module
===================
System Trace Module (STM) is a device described in MIPI STP specs as
STP trace stream generator. STP (System Trace Protocol) is a trace
protocol multiplexing data from multiple trace sources, each one of
which is assigned a unique pair of master and channel. While some of
these masters and channels are statically allocated to certain
hardware trace sources, others are available to software. Software
trace sources are usually free to pick for themselves any
master/channel combination from this pool.
On the receiving end of this STP stream (the decoder side), trace
sources can only be identified by master/channel combination, so in
order for the decoder to be able to make sense of the trace that
involves multiple trace sources, it needs to be able to map those
master/channel pairs to the trace sources that it understands.
For instance, it is helpful to know that syslog messages come on
master 7 channel 15, while arbitrary user applications can use masters
48 to 63 and channels 0 to 127.
To solve this mapping problem, stm class provides a policy management
mechanism via configfs, that allows defining rules that map string
identifiers to ranges of masters and channels. If these rules (policy)
are consistent with what decoder expects, it will be able to properly
process the trace data.
This policy is a tree structure containing rules (policy_node) that
have a name (string identifier) and a range of masters and channels
associated with it, located in "stp-policy" subsystem directory in
configfs. The topmost directory's name (the policy) is formatted as
the STM device name to which this policy applies and an arbitrary
string identifier separated by a stop. From the example above, a rule
may look like this::
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
$ ls /config/stp-policy/dummy_stm.my-policy/user
channels masters
$ cat /config/stp-policy/dummy_stm.my-policy/user/masters
48 63
$ cat /config/stp-policy/dummy_stm.my-policy/user/channels
0 127
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
which means that the master allocation pool for this rule consists of
masters 48 through 63 and channel allocation pool has channels 0
through 127 in it. Now, any producer (trace source) identifying itself
with "user" identification string will be allocated a master and
channel from within these ranges.
These rules can be nested, for example, one can define a rule "dummy"
under "user" directory from the example above and this new rule will
be used for trace sources with the id string of "user/dummy".
Trace sources have to open the stm class device's node and write their
trace data into its file descriptor.
In order to find an appropriate policy node for a given trace source,
several mechanisms can be used. First, a trace source can explicitly
identify itself by calling an STP_POLICY_ID_SET ioctl on the character
device's file descriptor, providing their id string, before they write
any data there. Secondly, if they chose not to perform the explicit
identification (because you may not want to patch existing software
to do this), they can just start writing the data, at which point the
stm core will try to find a policy node with the name matching the
task's name (e.g., "syslogd") and if one exists, it will be used.
Thirdly, if the task name can't be found among the policy nodes, the
catch-all entry "default" will be used, if it exists. This entry also
needs to be created and configured by the system administrator or
whatever tools are taking care of the policy configuration. Finally,
if all the above steps failed, the write() to an stm file descriptor
will return a error (EINVAL).
Previously, if no policy nodes were found for a trace source, the stm
class would silently fall back to allocating the first available
contiguous range of master/channels from the beginning of the device's
master/channel range. The new requirement for a policy node to exist
will help programmers and sysadmins identify gaps in configuration
and have better control over the un-identified sources.
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
Some STM devices may allow direct mapping of the channel mmio regions
to userspace for zero-copy writing. One mappable page (in terms of
mmu) will usually contain multiple channels' mmios, so the user will
need to allocate that many channels to themselves (via the
aforementioned ioctl() call) to be able to do this. That is, if your
stm device's channel mmio region is 64 bytes and hardware page size is
4096 bytes, after a successful STP_POLICY_ID_SET ioctl() call with
width==64, you should be able to mmap() one page on this file
descriptor and obtain direct access to an mmio region for 64 channels.
Examples of STM devices are Intel(R) Trace Hub [1] and Coresight STM
[2].
stm_source
==========
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
For kernel-based trace sources, there is "stm_source" device
class. Devices of this class can be connected and disconnected to/from
stm devices at runtime via a sysfs attribute called "stm_source_link"
by writing the name of the desired stm device there, for example::
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
$ echo dummy_stm.0 > /sys/class/stm_source/console/stm_source_link
For examples on how to use stm_source interface in the kernel, refer
to stm_console, stm_heartbeat or stm_ftrace drivers.
Each stm_source device will need to assume a master and a range of
channels, depending on how many channels it requires. These are
allocated for the device according to the policy configuration. If
there's a node in the root of the policy directory that matches the
stm_source device's name (for example, "console"), this node will be
used to allocate master and channel numbers. If there's no such policy
node, the stm core will use the catch-all entry "default", if one
exists. If neither policy nodes exist, the write() to stm_source_link
will return an error.
stm_console
===========
One implementation of this interface also used in the example above is
the "stm_console" driver, which basically provides a one-way console
for kernel messages over an stm device.
To configure the master/channel pair that will be assigned to this
console in the STP stream, create a "console" policy entry (see the
beginning of this text on how to do that). When initialized, it will
consume one channel.
stm class: Introduce an abstraction for System Trace Module devices A System Trace Module (STM) is a device exporting data in System Trace Protocol (STP) format as defined by MIPI STP standards. Examples of such devices are Intel(R) Trace Hub and Coresight STM. This abstraction provides a unified interface for software trace sources to send their data over an STM device to a debug host. In order to do that, such a trace source needs to be assigned a pair of master/channel identifiers that all the data from this source will be tagged with. The STP decoder on the debug host side will use these master/channel tags to distinguish different trace streams from one another inside one STP stream. This abstraction provides a configfs-based policy management mechanism for dynamic allocation of these master/channel pairs based on trace source-supplied string identifier. It has the flexibility of being defined at runtime and at the same time (provided that the policy definition is aligned with the decoding end) consistency. For userspace trace sources, this abstraction provides write()-based and mmap()-based (if the underlying stm device allows this) output mechanism. For kernel-side trace sources, we provide "stm_source" device class that can be connected to an stm device at run time. Cc: linux-api@vger.kernel.org Reviewed-by: Mathieu Poirier <mathieu.poirier@linaro.org> Signed-off-by: Alexander Shishkin <alexander.shishkin@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2015-09-22 15:47:10 +03:00
stm_ftrace
==========
This is another "stm_source" device, once the stm_ftrace has been
linked with an stm device, and if "function" tracer is enabled,
function address and parent function address which Ftrace subsystem
would store into ring buffer will be exported via the stm device at
the same time.
Currently only Ftrace "function" tracer is supported.
* [1] https://software.intel.com/sites/default/files/managed/d3/3c/intel-th-developer-manual.pdf
* [2] http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0444b/index.html