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a13a9956da
Change "and and" to "and an". Fix spello of "example". Signed-off-by: Randy Dunlap <rdunlap@infradead.org> Cc: Jonathan Corbet <corbet@lwn.net> Cc: linux-doc@vger.kernel.org Cc: Steven Rostedt <rostedt@goodmis.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Alexander Shishkin <alexander.shishkin@linux.intel.com> Link: https://lore.kernel.org/r/20200703212453.30553-4-rdunlap@infradead.org Signed-off-by: Jonathan Corbet <corbet@lwn.net>
144 lines
6.6 KiB
ReStructuredText
144 lines
6.6 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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===================
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System Trace Module
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===================
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System Trace Module (STM) is a device described in MIPI STP specs as
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STP trace stream generator. STP (System Trace Protocol) is a trace
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protocol multiplexing data from multiple trace sources, each one of
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which is assigned a unique pair of master and channel. While some of
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these masters and channels are statically allocated to certain
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hardware trace sources, others are available to software. Software
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trace sources are usually free to pick for themselves any
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master/channel combination from this pool.
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On the receiving end of this STP stream (the decoder side), trace
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sources can only be identified by master/channel combination, so in
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order for the decoder to be able to make sense of the trace that
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involves multiple trace sources, it needs to be able to map those
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master/channel pairs to the trace sources that it understands.
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For instance, it is helpful to know that syslog messages come on
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master 7 channel 15, while arbitrary user applications can use masters
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48 to 63 and channels 0 to 127.
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To solve this mapping problem, stm class provides a policy management
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mechanism via configfs, that allows defining rules that map string
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identifiers to ranges of masters and channels. If these rules (policy)
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are consistent with what decoder expects, it will be able to properly
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process the trace data.
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This policy is a tree structure containing rules (policy_node) that
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have a name (string identifier) and a range of masters and channels
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associated with it, located in "stp-policy" subsystem directory in
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configfs. The topmost directory's name (the policy) is formatted as
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the STM device name to which this policy applies and an arbitrary
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string identifier separated by a stop. From the example above, a rule
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may look like this::
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$ ls /config/stp-policy/dummy_stm.my-policy/user
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channels masters
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$ cat /config/stp-policy/dummy_stm.my-policy/user/masters
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48 63
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$ cat /config/stp-policy/dummy_stm.my-policy/user/channels
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0 127
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which means that the master allocation pool for this rule consists of
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masters 48 through 63 and channel allocation pool has channels 0
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through 127 in it. Now, any producer (trace source) identifying itself
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with "user" identification string will be allocated a master and
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channel from within these ranges.
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These rules can be nested, for example, one can define a rule "dummy"
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under "user" directory from the example above and this new rule will
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be used for trace sources with the id string of "user/dummy".
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Trace sources have to open the stm class device's node and write their
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trace data into its file descriptor.
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In order to find an appropriate policy node for a given trace source,
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several mechanisms can be used. First, a trace source can explicitly
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identify itself by calling an STP_POLICY_ID_SET ioctl on the character
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device's file descriptor, providing their id string, before they write
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any data there. Secondly, if they chose not to perform the explicit
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identification (because you may not want to patch existing software
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to do this), they can just start writing the data, at which point the
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stm core will try to find a policy node with the name matching the
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task's name (e.g., "syslogd") and if one exists, it will be used.
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Thirdly, if the task name can't be found among the policy nodes, the
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catch-all entry "default" will be used, if it exists. This entry also
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needs to be created and configured by the system administrator or
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whatever tools are taking care of the policy configuration. Finally,
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if all the above steps failed, the write() to an stm file descriptor
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will return a error (EINVAL).
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Previously, if no policy nodes were found for a trace source, the stm
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class would silently fall back to allocating the first available
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contiguous range of master/channels from the beginning of the device's
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master/channel range. The new requirement for a policy node to exist
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will help programmers and sysadmins identify gaps in configuration
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and have better control over the un-identified sources.
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Some STM devices may allow direct mapping of the channel mmio regions
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to userspace for zero-copy writing. One mappable page (in terms of
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mmu) will usually contain multiple channels' mmios, so the user will
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need to allocate that many channels to themselves (via the
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aforementioned ioctl() call) to be able to do this. That is, if your
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stm device's channel mmio region is 64 bytes and hardware page size is
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4096 bytes, after a successful STP_POLICY_ID_SET ioctl() call with
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width==64, you should be able to mmap() one page on this file
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descriptor and obtain direct access to an mmio region for 64 channels.
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Examples of STM devices are Intel(R) Trace Hub [1] and Coresight STM
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[2].
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stm_source
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==========
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For kernel-based trace sources, there is "stm_source" device
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class. Devices of this class can be connected and disconnected to/from
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stm devices at runtime via a sysfs attribute called "stm_source_link"
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by writing the name of the desired stm device there, for example::
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$ echo dummy_stm.0 > /sys/class/stm_source/console/stm_source_link
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For examples on how to use stm_source interface in the kernel, refer
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to stm_console, stm_heartbeat or stm_ftrace drivers.
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Each stm_source device will need to assume a master and a range of
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channels, depending on how many channels it requires. These are
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allocated for the device according to the policy configuration. If
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there's a node in the root of the policy directory that matches the
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stm_source device's name (for example, "console"), this node will be
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used to allocate master and channel numbers. If there's no such policy
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node, the stm core will use the catch-all entry "default", if one
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exists. If neither policy nodes exist, the write() to stm_source_link
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will return an error.
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stm_console
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===========
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One implementation of this interface also used in the example above is
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the "stm_console" driver, which basically provides a one-way console
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for kernel messages over an stm device.
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To configure the master/channel pair that will be assigned to this
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console in the STP stream, create a "console" policy entry (see the
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beginning of this text on how to do that). When initialized, it will
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consume one channel.
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stm_ftrace
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==========
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This is another "stm_source" device, once the stm_ftrace has been
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linked with an stm device, and if "function" tracer is enabled,
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function address and parent function address which Ftrace subsystem
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would store into ring buffer will be exported via the stm device at
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the same time.
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Currently only Ftrace "function" tracer is supported.
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* [1] https://software.intel.com/sites/default/files/managed/d3/3c/intel-th-developer-manual.pdf
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* [2] http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0444b/index.html
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