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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 18:49:45 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 18:49:45 +0000
commit2c3c1048746a4622d8c89a29670120dc8fab93c4 (patch)
tree848558de17fb3008cdf4d861b01ac7781903ce39 /Documentation/trace
parentInitial commit. (diff)
downloadlinux-2c3c1048746a4622d8c89a29670120dc8fab93c4.tar.xz
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Adding upstream version 6.1.76.upstream/6.1.76upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to '')
-rw-r--r--Documentation/trace/boottime-trace.rst301
-rw-r--r--Documentation/trace/coresight/coresight-config.rst294
-rw-r--r--Documentation/trace/coresight/coresight-cpu-debug.rst193
-rw-r--r--Documentation/trace/coresight/coresight-ect.rst226
-rw-r--r--Documentation/trace/coresight/coresight-etm4x-reference.rst827
-rw-r--r--Documentation/trace/coresight/coresight-perf.rst158
-rw-r--r--Documentation/trace/coresight/coresight-trbe.rst38
-rw-r--r--Documentation/trace/coresight/coresight.rst691
-rw-r--r--Documentation/trace/coresight/index.rst9
-rw-r--r--Documentation/trace/events-kmem.rst119
-rw-r--r--Documentation/trace/events-msr.rst40
-rw-r--r--Documentation/trace/events-nmi.rst45
-rw-r--r--Documentation/trace/events-power.rst104
-rw-r--r--Documentation/trace/events.rst1073
-rw-r--r--Documentation/trace/fprobe.rst174
-rw-r--r--Documentation/trace/ftrace-design.rst411
-rw-r--r--Documentation/trace/ftrace-uses.rst348
-rw-r--r--Documentation/trace/ftrace.rst3570
-rw-r--r--Documentation/trace/function-graph-fold.vim42
-rw-r--r--Documentation/trace/hisi-ptt.rst298
-rw-r--r--Documentation/trace/histogram-design.rst2115
-rw-r--r--Documentation/trace/histogram.rst2909
-rw-r--r--Documentation/trace/hwlat_detector.rst88
-rw-r--r--Documentation/trace/index.rst36
-rw-r--r--Documentation/trace/intel_th.rst150
-rw-r--r--Documentation/trace/kprobes.rst788
-rw-r--r--Documentation/trace/kprobetrace.rst261
-rw-r--r--Documentation/trace/mmiotrace.rst184
-rw-r--r--Documentation/trace/osnoise-tracer.rst152
-rw-r--r--Documentation/trace/postprocess/decode_msr.py37
-rw-r--r--Documentation/trace/postprocess/trace-pagealloc-postprocess.pl418
-rw-r--r--Documentation/trace/postprocess/trace-vmscan-postprocess.pl758
-rw-r--r--Documentation/trace/ring-buffer-design.rst983
-rw-r--r--Documentation/trace/rv/da_monitor_instrumentation.rst171
-rw-r--r--Documentation/trace/rv/da_monitor_synthesis.rst147
-rw-r--r--Documentation/trace/rv/deterministic_automata.rst184
-rw-r--r--Documentation/trace/rv/index.rst14
-rw-r--r--Documentation/trace/rv/monitor_wip.rst55
-rw-r--r--Documentation/trace/rv/monitor_wwnr.rst45
-rw-r--r--Documentation/trace/rv/runtime-verification.rst231
-rw-r--r--Documentation/trace/stm.rst143
-rw-r--r--Documentation/trace/sys-t.rst62
-rw-r--r--Documentation/trace/timerlat-tracer.rst182
-rw-r--r--Documentation/trace/tracepoint-analysis.rst338
-rw-r--r--Documentation/trace/tracepoints.rst175
-rw-r--r--Documentation/trace/uprobetracer.rst186
-rw-r--r--Documentation/trace/user_events.rst238
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diff --git a/Documentation/trace/boottime-trace.rst b/Documentation/trace/boottime-trace.rst
new file mode 100644
index 000000000..d59459720
--- /dev/null
+++ b/Documentation/trace/boottime-trace.rst
@@ -0,0 +1,301 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+=================
+Boot-time tracing
+=================
+
+:Author: Masami Hiramatsu <mhiramat@kernel.org>
+
+Overview
+========
+
+Boot-time tracing allows users to trace boot-time process including
+device initialization with full features of ftrace including per-event
+filter and actions, histograms, kprobe-events and synthetic-events,
+and trace instances.
+Since kernel command line is not enough to control these complex features,
+this uses bootconfig file to describe tracing feature programming.
+
+Options in the Boot Config
+==========================
+
+Here is the list of available options list for boot time tracing in
+boot config file [1]_. All options are under "ftrace." or "kernel."
+prefix. See kernel parameters for the options which starts
+with "kernel." prefix [2]_.
+
+.. [1] See :ref:`Documentation/admin-guide/bootconfig.rst <bootconfig>`
+.. [2] See :ref:`Documentation/admin-guide/kernel-parameters.rst <kernelparameters>`
+
+Ftrace Global Options
+---------------------
+
+Ftrace global options have "kernel." prefix in boot config, which means
+these options are passed as a part of kernel legacy command line.
+
+kernel.tp_printk
+ Output trace-event data on printk buffer too.
+
+kernel.dump_on_oops [= MODE]
+ Dump ftrace on Oops. If MODE = 1 or omitted, dump trace buffer
+ on all CPUs. If MODE = 2, dump a buffer on a CPU which kicks Oops.
+
+kernel.traceoff_on_warning
+ Stop tracing if WARN_ON() occurs.
+
+kernel.fgraph_max_depth = MAX_DEPTH
+ Set MAX_DEPTH to maximum depth of fgraph tracer.
+
+kernel.fgraph_filters = FILTER[, FILTER2...]
+ Add fgraph tracing function filters.
+
+kernel.fgraph_notraces = FILTER[, FILTER2...]
+ Add fgraph non-tracing function filters.
+
+
+Ftrace Per-instance Options
+---------------------------
+
+These options can be used for each instance including global ftrace node.
+
+ftrace.[instance.INSTANCE.]options = OPT1[, OPT2[...]]
+ Enable given ftrace options.
+
+ftrace.[instance.INSTANCE.]tracing_on = 0|1
+ Enable/Disable tracing on this instance when starting boot-time tracing.
+ (you can enable it by the "traceon" event trigger action)
+
+ftrace.[instance.INSTANCE.]trace_clock = CLOCK
+ Set given CLOCK to ftrace's trace_clock.
+
+ftrace.[instance.INSTANCE.]buffer_size = SIZE
+ Configure ftrace buffer size to SIZE. You can use "KB" or "MB"
+ for that SIZE.
+
+ftrace.[instance.INSTANCE.]alloc_snapshot
+ Allocate snapshot buffer.
+
+ftrace.[instance.INSTANCE.]cpumask = CPUMASK
+ Set CPUMASK as trace cpu-mask.
+
+ftrace.[instance.INSTANCE.]events = EVENT[, EVENT2[...]]
+ Enable given events on boot. You can use a wild card in EVENT.
+
+ftrace.[instance.INSTANCE.]tracer = TRACER
+ Set TRACER to current tracer on boot. (e.g. function)
+
+ftrace.[instance.INSTANCE.]ftrace.filters
+ This will take an array of tracing function filter rules.
+
+ftrace.[instance.INSTANCE.]ftrace.notraces
+ This will take an array of NON-tracing function filter rules.
+
+
+Ftrace Per-Event Options
+------------------------
+
+These options are setting per-event options.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.enable
+ Enable GROUP:EVENT tracing.
+
+ftrace.[instance.INSTANCE.]event.GROUP.enable
+ Enable all event tracing within GROUP.
+
+ftrace.[instance.INSTANCE.]event.enable
+ Enable all event tracing.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.filter = FILTER
+ Set FILTER rule to the GROUP:EVENT.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.actions = ACTION[, ACTION2[...]]
+ Set ACTIONs to the GROUP:EVENT.
+
+ftrace.[instance.INSTANCE.]event.kprobes.EVENT.probes = PROBE[, PROBE2[...]]
+ Defines new kprobe event based on PROBEs. It is able to define
+ multiple probes on one event, but those must have same type of
+ arguments. This option is available only for the event which
+ group name is "kprobes".
+
+ftrace.[instance.INSTANCE.]event.synthetic.EVENT.fields = FIELD[, FIELD2[...]]
+ Defines new synthetic event with FIELDs. Each field should be
+ "type varname".
+
+Note that kprobe and synthetic event definitions can be written under
+instance node, but those are also visible from other instances. So please
+take care for event name conflict.
+
+Ftrace Histogram Options
+------------------------
+
+Since it is too long to write a histogram action as a string for per-event
+action option, there are tree-style options under per-event 'hist' subkey
+for the histogram actions. For the detail of the each parameter,
+please read the event histogram document (Documentation/trace/histogram.rst)
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]keys = KEY1[, KEY2[...]]
+ Set histogram key parameters. (Mandatory)
+ The 'N' is a digit string for the multiple histogram. You can omit it
+ if there is one histogram on the event.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]values = VAL1[, VAL2[...]]
+ Set histogram value parameters.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]sort = SORT1[, SORT2[...]]
+ Set histogram sort parameter options.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]size = NR_ENTRIES
+ Set histogram size (number of entries).
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]name = NAME
+ Set histogram name.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]var.VARIABLE = EXPR
+ Define a new VARIABLE by EXPR expression.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]<pause|continue|clear>
+ Set histogram control parameter. You can set one of them.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]onmatch.[M.]event = GROUP.EVENT
+ Set histogram 'onmatch' handler matching event parameter.
+ The 'M' is a digit string for the multiple 'onmatch' handler. You can omit it
+ if there is one 'onmatch' handler on this histogram.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]onmatch.[M.]trace = EVENT[, ARG1[...]]
+ Set histogram 'trace' action for 'onmatch'.
+ EVENT must be a synthetic event name, and ARG1... are parameters
+ for that event. Mandatory if 'onmatch.event' option is set.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]onmax.[M.]var = VAR
+ Set histogram 'onmax' handler variable parameter.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]onchange.[M.]var = VAR
+ Set histogram 'onchange' handler variable parameter.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]<onmax|onchange>.[M.]save = ARG1[, ARG2[...]]
+ Set histogram 'save' action parameters for 'onmax' or 'onchange' handler.
+ This option or below 'snapshot' option is mandatory if 'onmax.var' or
+ 'onchange.var' option is set.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.[N.]<onmax|onchange>.[M.]snapshot
+ Set histogram 'snapshot' action for 'onmax' or 'onchange' handler.
+ This option or above 'save' option is mandatory if 'onmax.var' or
+ 'onchange.var' option is set.
+
+ftrace.[instance.INSTANCE.]event.GROUP.EVENT.hist.filter = FILTER_EXPR
+ Set histogram filter expression. You don't need 'if' in the FILTER_EXPR.
+
+Note that this 'hist' option can conflict with the per-event 'actions'
+option if the 'actions' option has a histogram action.
+
+
+When to Start
+=============
+
+All boot-time tracing options starting with ``ftrace`` will be enabled at the
+end of core_initcall. This means you can trace the events from postcore_initcall.
+Most of the subsystems and architecture dependent drivers will be initialized
+after that (arch_initcall or subsys_initcall). Thus, you can trace those with
+boot-time tracing.
+If you want to trace events before core_initcall, you can use the options
+starting with ``kernel``. Some of them will be enabled eariler than the initcall
+processing (for example,. ``kernel.ftrace=function`` and ``kernel.trace_event``
+will start before the initcall.)
+
+
+Examples
+========
+
+For example, to add filter and actions for each event, define kprobe
+events, and synthetic events with histogram, write a boot config like
+below::
+
+ ftrace.event {
+ task.task_newtask {
+ filter = "pid < 128"
+ enable
+ }
+ kprobes.vfs_read {
+ probes = "vfs_read $arg1 $arg2"
+ filter = "common_pid < 200"
+ enable
+ }
+ synthetic.initcall_latency {
+ fields = "unsigned long func", "u64 lat"
+ hist {
+ keys = func.sym, lat
+ values = lat
+ sort = lat
+ }
+ }
+ initcall.initcall_start.hist {
+ keys = func
+ var.ts0 = common_timestamp.usecs
+ }
+ initcall.initcall_finish.hist {
+ keys = func
+ var.lat = common_timestamp.usecs - $ts0
+ onmatch {
+ event = initcall.initcall_start
+ trace = initcall_latency, func, $lat
+ }
+ }
+ }
+
+Also, boot-time tracing supports "instance" node, which allows us to run
+several tracers for different purpose at once. For example, one tracer
+is for tracing functions starting with "user\_", and others tracing
+"kernel\_" functions, you can write boot config as below::
+
+ ftrace.instance {
+ foo {
+ tracer = "function"
+ ftrace.filters = "user_*"
+ }
+ bar {
+ tracer = "function"
+ ftrace.filters = "kernel_*"
+ }
+ }
+
+The instance node also accepts event nodes so that each instance
+can customize its event tracing.
+
+With the trigger action and kprobes, you can trace function-graph while
+a function is called. For example, this will trace all function calls in
+the pci_proc_init()::
+
+ ftrace {
+ tracing_on = 0
+ tracer = function_graph
+ event.kprobes {
+ start_event {
+ probes = "pci_proc_init"
+ actions = "traceon"
+ }
+ end_event {
+ probes = "pci_proc_init%return"
+ actions = "traceoff"
+ }
+ }
+ }
+
+
+This boot-time tracing also supports ftrace kernel parameters via boot
+config.
+For example, following kernel parameters::
+
+ trace_options=sym-addr trace_event=initcall:* tp_printk trace_buf_size=1M ftrace=function ftrace_filter="vfs*"
+
+This can be written in boot config like below::
+
+ kernel {
+ trace_options = sym-addr
+ trace_event = "initcall:*"
+ tp_printk
+ trace_buf_size = 1M
+ ftrace = function
+ ftrace_filter = "vfs*"
+ }
+
+Note that parameters start with "kernel" prefix instead of "ftrace".
diff --git a/Documentation/trace/coresight/coresight-config.rst b/Documentation/trace/coresight/coresight-config.rst
new file mode 100644
index 000000000..6d5ffa6f7
--- /dev/null
+++ b/Documentation/trace/coresight/coresight-config.rst
@@ -0,0 +1,294 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+======================================
+CoreSight System Configuration Manager
+======================================
+
+ :Author: Mike Leach <mike.leach@linaro.org>
+ :Date: October 2020
+
+Introduction
+============
+
+The CoreSight System Configuration manager is an API that allows the
+programming of the CoreSight system with pre-defined configurations that
+can then be easily enabled from sysfs or perf.
+
+Many CoreSight components can be programmed in complex ways - especially ETMs.
+In addition, components can interact across the CoreSight system, often via
+the cross trigger components such as CTI and CTM. These system settings can
+be defined and enabled as named configurations.
+
+
+Basic Concepts
+==============
+
+This section introduces the basic concepts of a CoreSight system configuration.
+
+
+Features
+--------
+
+A feature is a named set of programming for a CoreSight device. The programming
+is device dependent, and can be defined in terms of absolute register values,
+resource usage and parameter values.
+
+The feature is defined using a descriptor. This descriptor is used to load onto
+a matching device, either when the feature is loaded into the system, or when the
+CoreSight device is registered with the configuration manager.
+
+The load process involves interpreting the descriptor into a set of register
+accesses in the driver - the resource usage and parameter descriptions
+translated into appropriate register accesses. This interpretation makes it easy
+and efficient for the feature to be programmed onto the device when required.
+
+The feature will not be active on the device until the feature is enabled, and
+the device itself is enabled. When the device is enabled then enabled features
+will be programmed into the device hardware.
+
+A feature is enabled as part of a configuration being enabled on the system.
+
+
+Parameter Value
+~~~~~~~~~~~~~~~
+
+A parameter value is a named value that may be set by the user prior to the
+feature being enabled that can adjust the behaviour of the operation programmed
+by the feature.
+
+For example, this could be a count value in a programmed operation that repeats
+at a given rate. When the feature is enabled then the current value of the
+parameter is used in programming the device.
+
+The feature descriptor defines a default value for a parameter, which is used
+if the user does not supply a new value.
+
+Users can update parameter values using the configfs API for the CoreSight
+system - which is described below.
+
+The current value of the parameter is loaded into the device when the feature
+is enabled on that device.
+
+
+Configurations
+--------------
+
+A configuration defines a set of features that are to be used in a trace
+session where the configuration is selected. For any trace session only one
+configuration may be selected.
+
+The features defined may be on any type of device that is registered
+to support system configuration. A configuration may select features to be
+enabled on a class of devices - i.e. any ETMv4, or specific devices, e.g. a
+specific CTI on the system.
+
+As with the feature, a descriptor is used to define the configuration.
+This will define the features that must be enabled as part of the configuration
+as well as any preset values that can be used to override default parameter
+values.
+
+
+Preset Values
+~~~~~~~~~~~~~
+
+Preset values are easily selectable sets of parameter values for the features
+that the configuration uses. The number of values in a single preset set, equals
+the sum of parameter values in the features used by the configuration.
+
+e.g. a configuration consists of 3 features, one has 2 parameters, one has
+a single parameter, and another has no parameters. A single preset set will
+therefore have 3 values.
+
+Presets are optionally defined by the configuration, up to 15 can be defined.
+If no preset is selected, then the parameter values defined in the feature
+are used as normal.
+
+
+Operation
+~~~~~~~~~
+
+The following steps take place in the operation of a configuration.
+
+1) In this example, the configuration is 'autofdo', which has an
+ associated feature 'strobing' that works on ETMv4 CoreSight Devices.
+
+2) The configuration is enabled. For example 'perf' may select the
+ configuration as part of its command line::
+
+ perf record -e cs_etm/autofdo/ myapp
+
+ which will enable the 'autofdo' configuration.
+
+3) perf starts tracing on the system. As each ETMv4 that perf uses for
+ trace is enabled, the configuration manager will check if the ETMv4
+ has a feature that relates to the currently active configuration.
+ In this case 'strobing' is enabled & programmed into the ETMv4.
+
+4) When the ETMv4 is disabled, any registers marked as needing to be
+ saved will be read back.
+
+5) At the end of the perf session, the configuration will be disabled.
+
+
+Viewing Configurations and Features
+===================================
+
+The set of configurations and features that are currently loaded into the
+system can be viewed using the configfs API.
+
+Mount configfs as normal and the 'cs-syscfg' subsystem will appear::
+
+ $ ls /config
+ cs-syscfg stp-policy
+
+This has two sub-directories::
+
+ $ cd cs-syscfg/
+ $ ls
+ configurations features
+
+The system has the configuration 'autofdo' built in. It may be examined as
+follows::
+
+ $ cd configurations/
+ $ ls
+ autofdo
+ $ cd autofdo/
+ $ ls
+ description feature_refs preset1 preset3 preset5 preset7 preset9
+ enable preset preset2 preset4 preset6 preset8
+ $ cat description
+ Setup ETMs with strobing for autofdo
+ $ cat feature_refs
+ strobing
+
+Each preset declared has a 'preset<n>' subdirectory declared. The values for
+the preset can be examined::
+
+ $ cat preset1/values
+ strobing.window = 0x1388 strobing.period = 0x2
+ $ cat preset2/values
+ strobing.window = 0x1388 strobing.period = 0x4
+
+The 'enable' and 'preset' files allow the control of a configuration when
+using CoreSight with sysfs.
+
+The features referenced by the configuration can be examined in the features
+directory::
+
+ $ cd ../../features/strobing/
+ $ ls
+ description matches nr_params params
+ $ cat description
+ Generate periodic trace capture windows.
+ parameter 'window': a number of CPU cycles (W)
+ parameter 'period': trace enabled for W cycles every period x W cycles
+ $ cat matches
+ SRC_ETMV4
+ $ cat nr_params
+ 2
+
+Move to the params directory to examine and adjust parameters::
+
+ cd params
+ $ ls
+ period window
+ $ cd period
+ $ ls
+ value
+ $ cat value
+ 0x2710
+ # echo 15000 > value
+ # cat value
+ 0x3a98
+
+Parameters adjusted in this way are reflected in all device instances that have
+loaded the feature.
+
+
+Using Configurations in perf
+============================
+
+The configurations loaded into the CoreSight configuration management are
+also declared in the perf 'cs_etm' event infrastructure so that they can
+be selected when running trace under perf::
+
+ $ ls /sys/devices/cs_etm
+ cpu0 cpu2 events nr_addr_filters power subsystem uevent
+ cpu1 cpu3 format perf_event_mux_interval_ms sinks type
+
+The key directory here is 'events' - a generic perf directory which allows
+selection on the perf command line. As with the sinks entries, this provides
+a hash of the configuration name.
+
+The entry in the 'events' directory uses perfs built in syntax generator
+to substitute the syntax for the name when evaluating the command::
+
+ $ ls events/
+ autofdo
+ $ cat events/autofdo
+ configid=0xa7c3dddd
+
+The 'autofdo' configuration may be selected on the perf command line::
+
+ $ perf record -e cs_etm/autofdo/u --per-thread <application>
+
+A preset to override the current parameter values can also be selected::
+
+ $ perf record -e cs_etm/autofdo,preset=1/u --per-thread <application>
+
+When configurations are selected in this way, then the trace sink used is
+automatically selected.
+
+Using Configurations in sysfs
+=============================
+
+Coresight can be controlled using sysfs. When this is in use then a configuration
+can be made active for the devices that are used in the sysfs session.
+
+In a configuration there are 'enable' and 'preset' files.
+
+To enable a configuration for use with sysfs::
+
+ $ cd configurations/autofdo
+ $ echo 1 > enable
+
+This will then use any default parameter values in the features - which can be
+adjusted as described above.
+
+To use a preset<n> set of parameter values::
+
+ $ echo 3 > preset
+
+This will select preset3 for the configuration.
+The valid values for preset are 0 - to deselect presets, and any value of
+<n> where a preset<n> sub-directory is present.
+
+Note that the active sysfs configuration is a global parameter, therefore
+only a single configuration can be active for sysfs at any one time.
+Attempting to enable a second configuration will result in an error.
+Additionally, attempting to disable the configuration while in use will
+also result in an error.
+
+The use of the active configuration by sysfs is independent of the configuration
+used in perf.
+
+
+Creating and Loading Custom Configurations
+==========================================
+
+Custom configurations and / or features can be dynamically loaded into the
+system by using a loadable module.
+
+An example of a custom configuration is found in ./samples/coresight.
+
+This creates a new configuration that uses the existing built in
+strobing feature, but provides a different set of presets.
+
+When the module is loaded, then the configuration appears in the configfs
+file system and is selectable in the same way as the built in configuration
+described above.
+
+Configurations can use previously loaded features. The system will ensure
+that it is not possible to unload a feature that is currently in use, by
+enforcing the unload order as the strict reverse of the load order.
diff --git a/Documentation/trace/coresight/coresight-cpu-debug.rst b/Documentation/trace/coresight/coresight-cpu-debug.rst
new file mode 100644
index 000000000..836b35532
--- /dev/null
+++ b/Documentation/trace/coresight/coresight-cpu-debug.rst
@@ -0,0 +1,193 @@
+==========================
+Coresight CPU Debug Module
+==========================
+
+ :Author: Leo Yan <leo.yan@linaro.org>
+ :Date: April 5th, 2017
+
+Introduction
+------------
+
+Coresight CPU debug module is defined in ARMv8-a architecture reference manual
+(ARM DDI 0487A.k) Chapter 'Part H: External debug', the CPU can integrate
+debug module and it is mainly used for two modes: self-hosted debug and
+external debug. Usually the external debug mode is well known as the external
+debugger connects with SoC from JTAG port; on the other hand the program can
+explore debugging method which rely on self-hosted debug mode, this document
+is to focus on this part.
+
+The debug module provides sample-based profiling extension, which can be used
+to sample CPU program counter, secure state and exception level, etc; usually
+every CPU has one dedicated debug module to be connected. Based on self-hosted
+debug mechanism, Linux kernel can access these related registers from mmio
+region when the kernel panic happens. The callback notifier for kernel panic
+will dump related registers for every CPU; finally this is good for assistant
+analysis for panic.
+
+
+Implementation
+--------------
+
+- During driver registration, it uses EDDEVID and EDDEVID1 - two device ID
+ registers to decide if sample-based profiling is implemented or not. On some
+ platforms this hardware feature is fully or partially implemented; and if
+ this feature is not supported then registration will fail.
+
+- At the time this documentation was written, the debug driver mainly relies on
+ information gathered by the kernel panic callback notifier from three
+ sampling registers: EDPCSR, EDVIDSR and EDCIDSR: from EDPCSR we can get
+ program counter; EDVIDSR has information for secure state, exception level,
+ bit width, etc; EDCIDSR is context ID value which contains the sampled value
+ of CONTEXTIDR_EL1.
+
+- The driver supports a CPU running in either AArch64 or AArch32 mode. The
+ registers naming convention is a bit different between them, AArch64 uses
+ 'ED' for register prefix (ARM DDI 0487A.k, chapter H9.1) and AArch32 uses
+ 'DBG' as prefix (ARM DDI 0487A.k, chapter G5.1). The driver is unified to
+ use AArch64 naming convention.
+
+- ARMv8-a (ARM DDI 0487A.k) and ARMv7-a (ARM DDI 0406C.b) have different
+ register bits definition. So the driver consolidates two difference:
+
+ If PCSROffset=0b0000, on ARMv8-a the feature of EDPCSR is not implemented;
+ but ARMv7-a defines "PCSR samples are offset by a value that depends on the
+ instruction set state". For ARMv7-a, the driver checks furthermore if CPU
+ runs with ARM or thumb instruction set and calibrate PCSR value, the
+ detailed description for offset is in ARMv7-a ARM (ARM DDI 0406C.b) chapter
+ C11.11.34 "DBGPCSR, Program Counter Sampling Register".
+
+ If PCSROffset=0b0010, ARMv8-a defines "EDPCSR implemented, and samples have
+ no offset applied and do not sample the instruction set state in AArch32
+ state". So on ARMv8 if EDDEVID1.PCSROffset is 0b0010 and the CPU operates
+ in AArch32 state, EDPCSR is not sampled; when the CPU operates in AArch64
+ state EDPCSR is sampled and no offset are applied.
+
+
+Clock and power domain
+----------------------
+
+Before accessing debug registers, we should ensure the clock and power domain
+have been enabled properly. In ARMv8-a ARM (ARM DDI 0487A.k) chapter 'H9.1
+Debug registers', the debug registers are spread into two domains: the debug
+domain and the CPU domain.
+::
+
+ +---------------+
+ | |
+ | |
+ +----------+--+ |
+ dbg_clock -->| |**| |<-- cpu_clock
+ | Debug |**| CPU |
+ dbg_power_domain -->| |**| |<-- cpu_power_domain
+ +----------+--+ |
+ | |
+ | |
+ +---------------+
+
+For debug domain, the user uses DT binding "clocks" and "power-domains" to
+specify the corresponding clock source and power supply for the debug logic.
+The driver calls the pm_runtime_{put|get} operations as needed to handle the
+debug power domain.
+
+For CPU domain, the different SoC designs have different power management
+schemes and finally this heavily impacts external debug module. So we can
+divide into below cases:
+
+- On systems with a sane power controller which can behave correctly with
+ respect to CPU power domain, the CPU power domain can be controlled by
+ register EDPRCR in driver. The driver firstly writes bit EDPRCR.COREPURQ
+ to power up the CPU, and then writes bit EDPRCR.CORENPDRQ for emulation
+ of CPU power down. As result, this can ensure the CPU power domain is
+ powered on properly during the period when access debug related registers;
+
+- Some designs will power down an entire cluster if all CPUs on the cluster
+ are powered down - including the parts of the debug registers that should
+ remain powered in the debug power domain. The bits in EDPRCR are not
+ respected in these cases, so these designs do not support debug over
+ power down in the way that the CoreSight / Debug designers anticipated.
+ This means that even checking EDPRSR has the potential to cause a bus hang
+ if the target register is unpowered.
+
+ In this case, accessing to the debug registers while they are not powered
+ is a recipe for disaster; so we need preventing CPU low power states at boot
+ time or when user enable module at the run time. Please see chapter
+ "How to use the module" for detailed usage info for this.
+
+
+Device Tree Bindings
+--------------------
+
+See Documentation/devicetree/bindings/arm/arm,coresight-cpu-debug.yaml for
+details.
+
+
+How to use the module
+---------------------
+
+If you want to enable debugging functionality at boot time, you can add
+"coresight_cpu_debug.enable=1" to the kernel command line parameter.
+
+The driver also can work as module, so can enable the debugging when insmod
+module::
+
+ # insmod coresight_cpu_debug.ko debug=1
+
+When boot time or insmod module you have not enabled the debugging, the driver
+uses the debugfs file system to provide a knob to dynamically enable or disable
+debugging:
+
+To enable it, write a '1' into /sys/kernel/debug/coresight_cpu_debug/enable::
+
+ # echo 1 > /sys/kernel/debug/coresight_cpu_debug/enable
+
+To disable it, write a '0' into /sys/kernel/debug/coresight_cpu_debug/enable::
+
+ # echo 0 > /sys/kernel/debug/coresight_cpu_debug/enable
+
+As explained in chapter "Clock and power domain", if you are working on one
+platform which has idle states to power off debug logic and the power
+controller cannot work well for the request from EDPRCR, then you should
+firstly constraint CPU idle states before enable CPU debugging feature; so can
+ensure the accessing to debug logic.
+
+If you want to limit idle states at boot time, you can use "nohlt" or
+"cpuidle.off=1" in the kernel command line.
+
+At the runtime you can disable idle states with below methods:
+
+It is possible to disable CPU idle states by way of the PM QoS
+subsystem, more specifically by using the "/dev/cpu_dma_latency"
+interface (see Documentation/power/pm_qos_interface.rst for more
+details). As specified in the PM QoS documentation the requested
+parameter will stay in effect until the file descriptor is released.
+For example::
+
+ # exec 3<> /dev/cpu_dma_latency; echo 0 >&3
+ ...
+ Do some work...
+ ...
+ # exec 3<>-
+
+The same can also be done from an application program.
+
+Disable specific CPU's specific idle state from cpuidle sysfs (see
+Documentation/admin-guide/pm/cpuidle.rst)::
+
+ # echo 1 > /sys/devices/system/cpu/cpu$cpu/cpuidle/state$state/disable
+
+Output format
+-------------
+
+Here is an example of the debugging output format::
+
+ ARM external debug module:
+ coresight-cpu-debug 850000.debug: CPU[0]:
+ coresight-cpu-debug 850000.debug: EDPRSR: 00000001 (Power:On DLK:Unlock)
+ coresight-cpu-debug 850000.debug: EDPCSR: handle_IPI+0x174/0x1d8
+ coresight-cpu-debug 850000.debug: EDCIDSR: 00000000
+ coresight-cpu-debug 850000.debug: EDVIDSR: 90000000 (State:Non-secure Mode:EL1/0 Width:64bits VMID:0)
+ coresight-cpu-debug 852000.debug: CPU[1]:
+ coresight-cpu-debug 852000.debug: EDPRSR: 00000001 (Power:On DLK:Unlock)
+ coresight-cpu-debug 852000.debug: EDPCSR: debug_notifier_call+0x23c/0x358
+ coresight-cpu-debug 852000.debug: EDCIDSR: 00000000
+ coresight-cpu-debug 852000.debug: EDVIDSR: 90000000 (State:Non-secure Mode:EL1/0 Width:64bits VMID:0)
diff --git a/Documentation/trace/coresight/coresight-ect.rst b/Documentation/trace/coresight/coresight-ect.rst
new file mode 100644
index 000000000..a68732c5c
--- /dev/null
+++ b/Documentation/trace/coresight/coresight-ect.rst
@@ -0,0 +1,226 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+=============================================
+CoreSight Embedded Cross Trigger (CTI & CTM).
+=============================================
+
+ :Author: Mike Leach <mike.leach@linaro.org>
+ :Date: November 2019
+
+Hardware Description
+--------------------
+
+The CoreSight Cross Trigger Interface (CTI) is a hardware device that takes
+individual input and output hardware signals known as triggers to and from
+devices and interconnects them via the Cross Trigger Matrix (CTM) to other
+devices via numbered channels, in order to propagate events between devices.
+
+e.g.::
+
+ 0000000 in_trigs :::::::
+ 0 C 0----------->: : +======>(other CTI channel IO)
+ 0 P 0<-----------: : v
+ 0 U 0 out_trigs : : Channels ***** :::::::
+ 0000000 : CTI :<=========>*CTM*<====>: CTI :---+
+ ####### in_trigs : : (id 0-3) ***** ::::::: v
+ # ETM #----------->: : ^ #######
+ # #<-----------: : +---# ETR #
+ ####### out_trigs ::::::: #######
+
+The CTI driver enables the programming of the CTI to attach triggers to
+channels. When an input trigger becomes active, the attached channel will
+become active. Any output trigger attached to that channel will also
+become active. The active channel is propagated to other CTIs via the CTM,
+activating connected output triggers there, unless filtered by the CTI
+channel gate.
+
+It is also possible to activate a channel using system software directly
+programming registers in the CTI.
+
+The CTIs are registered by the system to be associated with CPUs and/or other
+CoreSight devices on the trace data path. When these devices are enabled the
+attached CTIs will also be enabled. By default/on power up the CTIs have
+no programmed trigger/channel attachments, so will not affect the system
+until explicitly programmed.
+
+The hardware trigger connections between CTIs and devices is implementation
+defined, unless the CPU/ETM combination is a v8 architecture, in which case
+the connections have an architecturally defined standard layout.
+
+The hardware trigger signals can also be connected to non-CoreSight devices
+(e.g. UART), or be propagated off chip as hardware IO lines.
+
+All the CTI devices are associated with a CTM. On many systems there will be a
+single effective CTM (one CTM, or multiple CTMs all interconnected), but it is
+possible that systems can have nets of CTIs+CTM that are not interconnected by
+a CTM to each other. On these systems a CTM index is declared to associate
+CTI devices that are interconnected via a given CTM.
+
+Sysfs files and directories
+---------------------------
+
+The CTI devices appear on the existing CoreSight bus alongside the other
+CoreSight devices::
+
+ >$ ls /sys/bus/coresight/devices
+ cti_cpu0 cti_cpu2 cti_sys0 etm0 etm2 funnel0 replicator0 tmc_etr0
+ cti_cpu1 cti_cpu3 cti_sys1 etm1 etm3 funnel1 tmc_etf0 tpiu0
+
+The ``cti_cpu<N>`` named CTIs are associated with a CPU, and any ETM used by
+that core. The ``cti_sys<N>`` CTIs are general system infrastructure CTIs that
+can be associated with other CoreSight devices, or other system hardware
+capable of generating or using trigger signals.::
+
+ >$ ls /sys/bus/coresight/devices/etm0/cti_cpu0
+ channels ctmid enable nr_trigger_cons mgmt power powered regs
+ connections subsystem triggers0 triggers1 uevent
+
+*Key file items are:-*
+ * ``enable``: enables/disables the CTI. Read to determine current state.
+ If this shows as enabled (1), but ``powered`` shows unpowered (0), then
+ the enable indicates a request to enabled when the device is powered.
+ * ``ctmid`` : associated CTM - only relevant if system has multiple CTI+CTM
+ clusters that are not interconnected.
+ * ``nr_trigger_cons`` : total connections - triggers<N> directories.
+ * ``powered`` : Read to determine if the CTI is currently powered.
+
+*Sub-directories:-*
+ * ``triggers<N>``: contains list of triggers for an individual connection.
+ * ``channels``: Contains the channel API - CTI main programming interface.
+ * ``regs``: Gives access to the raw programmable CTI regs.
+ * ``mgmt``: the standard CoreSight management registers.
+ * ``connections``: Links to connected *CoreSight* devices. The number of
+ links can be 0 to ``nr_trigger_cons``. Actual number given by ``nr_links``
+ in this directory.
+
+
+triggers<N> directories
+~~~~~~~~~~~~~~~~~~~~~~~
+
+Individual trigger connection information. This describes trigger signals for
+CoreSight and non-CoreSight connections.
+
+Each triggers directory has a set of parameters describing the triggers for
+the connection.
+
+ * ``name`` : name of connection
+ * ``in_signals`` : input trigger signal indexes used in this connection.
+ * ``in_types`` : functional types for in signals.
+ * ``out_signals`` : output trigger signals for this connection.
+ * ``out_types`` : functional types for out signals.
+
+e.g::
+
+ >$ ls ./cti_cpu0/triggers0/
+ in_signals in_types name out_signals out_types
+ >$ cat ./cti_cpu0/triggers0/name
+ cpu0
+ >$ cat ./cti_cpu0/triggers0/out_signals
+ 0-2
+ >$ cat ./cti_cpu0/triggers0/out_types
+ pe_edbgreq pe_dbgrestart pe_ctiirq
+ >$ cat ./cti_cpu0/triggers0/in_signals
+ 0-1
+ >$ cat ./cti_cpu0/triggers0/in_types
+ pe_dbgtrigger pe_pmuirq
+
+If a connection has zero signals in either the 'in' or 'out' triggers then
+those parameters will be omitted.
+
+Channels API Directory
+~~~~~~~~~~~~~~~~~~~~~~
+
+This provides an easy way to attach triggers to channels, without needing
+the multiple register operations that are required if manipulating the
+'regs' sub-directory elements directly.
+
+A number of files provide this API::
+
+ >$ ls ./cti_sys0/channels/
+ chan_clear chan_inuse chan_xtrigs_out trigin_attach
+ chan_free chan_pulse chan_xtrigs_reset trigin_detach
+ chan_gate_disable chan_set chan_xtrigs_sel trigout_attach
+ chan_gate_enable chan_xtrigs_in trig_filter_enable trigout_detach
+ trigout_filtered
+
+Most access to these elements take the form::
+
+ echo <chan> [<trigger>] > /<device_path>/<operation>
+
+where the optional <trigger> is only needed for trigXX_attach | detach
+operations.
+
+e.g.::
+
+ >$ echo 0 1 > ./cti_sys0/channels/trigout_attach
+ >$ echo 0 > ./cti_sys0/channels/chan_set
+
+Attaches trigout(1) to channel(0), then activates channel(0) generating a
+set state on cti_sys0.trigout(1)
+
+
+*API operations*
+
+ * ``trigin_attach, trigout_attach``: Attach a channel to a trigger signal.
+ * ``trigin_detach, trigout_detach``: Detach a channel from a trigger signal.
+ * ``chan_set``: Set the channel - the set state will be propagated around
+ the CTM to other connected devices.
+ * ``chan_clear``: Clear the channel.
+ * ``chan_pulse``: Set the channel for a single CoreSight clock cycle.
+ * ``chan_gate_enable``: Write operation sets the CTI gate to propagate
+ (enable) the channel to other devices. This operation takes a channel
+ number. CTI gate is enabled for all channels by default at power up. Read
+ to list the currently enabled channels on the gate.
+ * ``chan_gate_disable``: Write channel number to disable gate for that
+ channel.
+ * ``chan_inuse``: Show the current channels attached to any signal
+ * ``chan_free``: Show channels with no attached signals.
+ * ``chan_xtrigs_sel``: write a channel number to select a channel to view,
+ read to show the selected channel number.
+ * ``chan_xtrigs_in``: Read to show the input triggers attached to
+ the selected view channel.
+ * ``chan_xtrigs_out``:Read to show the output triggers attached to
+ the selected view channel.
+ * ``trig_filter_enable``: Defaults to enabled, disable to allow potentially
+ dangerous output signals to be set.
+ * ``trigout_filtered``: Trigger out signals that are prevented from being
+ set if filtering ``trig_filter_enable`` is enabled. One use is to prevent
+ accidental ``EDBGREQ`` signals stopping a core.
+ * ``chan_xtrigs_reset``: Write 1 to clear all channel / trigger programming.
+ Resets device hardware to default state.
+
+
+The example below attaches input trigger index 1 to channel 2, and output
+trigger index 6 to the same channel. It then examines the state of the
+channel / trigger connections using the appropriate sysfs attributes.
+
+The settings mean that if either input trigger 1, or channel 2 go active then
+trigger out 6 will go active. We then enable the CTI, and use the software
+channel control to activate channel 2. We see the active channel on the
+``choutstatus`` register and the active signal on the ``trigoutstatus``
+register. Finally clearing the channel removes this.
+
+e.g.::
+
+ .../cti_sys0/channels# echo 2 1 > trigin_attach
+ .../cti_sys0/channels# echo 2 6 > trigout_attach
+ .../cti_sys0/channels# cat chan_free
+ 0-1,3
+ .../cti_sys0/channels# cat chan_inuse
+ 2
+ .../cti_sys0/channels# echo 2 > chan_xtrigs_sel
+ .../cti_sys0/channels# cat chan_xtrigs_trigin
+ 1
+ .../cti_sys0/channels# cat chan_xtrigs_trigout
+ 6
+ .../cti_sys0/# echo 1 > enable
+ .../cti_sys0/channels# echo 2 > chan_set
+ .../cti_sys0/channels# cat ../regs/choutstatus
+ 0x4
+ .../cti_sys0/channels# cat ../regs/trigoutstatus
+ 0x40
+ .../cti_sys0/channels# echo 2 > chan_clear
+ .../cti_sys0/channels# cat ../regs/trigoutstatus
+ 0x0
+ .../cti_sys0/channels# cat ../regs/choutstatus
+ 0x0
diff --git a/Documentation/trace/coresight/coresight-etm4x-reference.rst b/Documentation/trace/coresight/coresight-etm4x-reference.rst
new file mode 100644
index 000000000..70e34b8c8
--- /dev/null
+++ b/Documentation/trace/coresight/coresight-etm4x-reference.rst
@@ -0,0 +1,827 @@
+===============================================
+ETMv4 sysfs linux driver programming reference.
+===============================================
+
+ :Author: Mike Leach <mike.leach@linaro.org>
+ :Date: October 11th, 2019
+
+Supplement to existing ETMv4 driver documentation.
+
+Sysfs files and directories
+---------------------------
+
+Root: ``/sys/bus/coresight/devices/etm<N>``
+
+
+The following paragraphs explain the association between sysfs files and the
+ETMv4 registers that they effect. Note the register names are given without
+the ‘TRC’ prefix.
+
+----
+
+:File: ``mode`` (rw)
+:Trace Registers: {CONFIGR + others}
+:Notes:
+ Bit select trace features. See ‘mode’ section below. Bits
+ in this will cause equivalent programming of trace config and
+ other registers to enable the features requested.
+
+:Syntax & eg:
+ ``echo bitfield > mode``
+
+ bitfield up to 32 bits setting trace features.
+
+:Example:
+ ``$> echo 0x012 > mode``
+
+----
+
+:File: ``reset`` (wo)
+:Trace Registers: All
+:Notes:
+ Reset all programming to trace nothing / no logic programmed.
+
+:Syntax:
+ ``echo 1 > reset``
+
+----
+
+:File: ``enable_source`` (wo)
+:Trace Registers: PRGCTLR, All hardware regs.
+:Notes:
+ - > 0 : Programs up the hardware with the current values held in the driver
+ and enables trace.
+
+ - = 0 : disable trace hardware.
+
+:Syntax:
+ ``echo 1 > enable_source``
+
+----
+
+:File: ``cpu`` (ro)
+:Trace Registers: None.
+:Notes:
+ CPU ID that this ETM is attached to.
+
+:Example:
+ ``$> cat cpu``
+
+ ``$> 0``
+
+----
+
+:File: ``ts_source`` (ro)
+:Trace Registers: None.
+:Notes:
+ When FEAT_TRF is implemented, value of TRFCR_ELx.TS used for trace session. Otherwise -1
+ indicates an unknown time source. Check trcidr0.tssize to see if a global timestamp is
+ available.
+
+:Example:
+ ``$> cat ts_source``
+
+ ``$> 1``
+
+----
+
+:File: ``addr_idx`` (rw)
+:Trace Registers: None.
+:Notes:
+ Virtual register to index address comparator and range
+ features. Set index for first of the pair in a range.
+
+:Syntax:
+ ``echo idx > addr_idx``
+
+ Where idx < nr_addr_cmp x 2
+
+----
+
+:File: ``addr_range`` (rw)
+:Trace Registers: ACVR[idx, idx+1], VIIECTLR
+:Notes:
+ Pair of addresses for a range selected by addr_idx. Include
+ / exclude according to the optional parameter, or if omitted
+ uses the current ‘mode’ setting. Select comparator range in
+ control register. Error if index is odd value.
+
+:Depends: ``mode, addr_idx``
+:Syntax:
+ ``echo addr1 addr2 [exclude] > addr_range``
+
+ Where addr1 and addr2 define the range and addr1 < addr2.
+
+ Optional exclude value:-
+
+ - 0 for include
+ - 1 for exclude.
+:Example:
+ ``$> echo 0x0000 0x2000 0 > addr_range``
+
+----
+
+:File: ``addr_single`` (rw)
+:Trace Registers: ACVR[idx]
+:Notes:
+ Set a single address comparator according to addr_idx. This
+ is used if the address comparator is used as part of event
+ generation logic etc.
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``echo addr1 > addr_single``
+
+----
+
+:File: ``addr_start`` (rw)
+:Trace Registers: ACVR[idx], VISSCTLR
+:Notes:
+ Set a trace start address comparator according to addr_idx.
+ Select comparator in control register.
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``echo addr1 > addr_start``
+
+----
+
+:File: ``addr_stop`` (rw)
+:Trace Registers: ACVR[idx], VISSCTLR
+:Notes:
+ Set a trace stop address comparator according to addr_idx.
+ Select comparator in control register.
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``echo addr1 > addr_stop``
+
+----
+
+:File: ``addr_context`` (rw)
+:Trace Registers: ACATR[idx,{6:4}]
+:Notes:
+ Link context ID comparator to address comparator addr_idx
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``echo ctxt_idx > addr_context``
+
+ Where ctxt_idx is the index of the linked context id / vmid
+ comparator.
+
+----
+
+:File: ``addr_ctxtype`` (rw)
+:Trace Registers: ACATR[idx,{3:2}]
+:Notes:
+ Input value string. Set type for linked context ID comparator
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``echo type > addr_ctxtype``
+
+ Type one of {all, vmid, ctxid, none}
+:Example:
+ ``$> echo ctxid > addr_ctxtype``
+
+----
+
+:File: ``addr_exlevel_s_ns`` (rw)
+:Trace Registers: ACATR[idx,{14:8}]
+:Notes:
+ Set the ELx secure and non-secure matching bits for the
+ selected address comparator
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``echo val > addr_exlevel_s_ns``
+
+ val is a 7 bit value for exception levels to exclude. Input
+ value shifted to correct bits in register.
+:Example:
+ ``$> echo 0x4F > addr_exlevel_s_ns``
+
+----
+
+:File: ``addr_instdatatype`` (rw)
+:Trace Registers: ACATR[idx,{1:0}]
+:Notes:
+ Set the comparator address type for matching. Driver only
+ supports setting instruction address type.
+
+:Depends: ``addr_idx``
+
+----
+
+:File: ``addr_cmp_view`` (ro)
+:Trace Registers: ACVR[idx, idx+1], ACATR[idx], VIIECTLR
+:Notes:
+ Read the currently selected address comparator. If part of
+ address range then display both addresses.
+
+:Depends: ``addr_idx``
+:Syntax:
+ ``cat addr_cmp_view``
+:Example:
+ ``$> cat addr_cmp_view``
+
+ ``addr_cmp[0] range 0x0 0xffffffffffffffff include ctrl(0x4b00)``
+
+----
+
+:File: ``nr_addr_cmp`` (ro)
+:Trace Registers: From IDR4
+:Notes:
+ Number of address comparator pairs
+
+----
+
+:File: ``sshot_idx`` (rw)
+:Trace Registers: None
+:Notes:
+ Select single shot register set.
+
+----
+
+:File: ``sshot_ctrl`` (rw)
+:Trace Registers: SSCCR[idx]
+:Notes:
+ Access a single shot comparator control register.
+
+:Depends: ``sshot_idx``
+:Syntax:
+ ``echo val > sshot_ctrl``
+
+ Writes val into the selected control register.
+
+----
+
+:File: ``sshot_status`` (ro)
+:Trace Registers: SSCSR[idx]
+:Notes:
+ Read a single shot comparator status register
+
+:Depends: ``sshot_idx``
+:Syntax:
+ ``cat sshot_status``
+
+ Read status.
+:Example:
+ ``$> cat sshot_status``
+
+ ``0x1``
+
+----
+
+:File: ``sshot_pe_ctrl`` (rw)
+:Trace Registers: SSPCICR[idx]
+:Notes:
+ Access a single shot PE comparator input control register.
+
+:Depends: ``sshot_idx``
+:Syntax:
+ ``echo val > sshot_pe_ctrl``
+
+ Writes val into the selected control register.
+
+----
+
+:File: ``ns_exlevel_vinst`` (rw)
+:Trace Registers: VICTLR{23:20}
+:Notes:
+ Program non-secure exception level filters. Set / clear NS
+ exception filter bits. Setting ‘1’ excludes trace from the
+ exception level.
+
+:Syntax:
+ ``echo bitfield > ns_exlevel_viinst``
+
+ Where bitfield contains bits to set clear for EL0 to EL2
+:Example:
+ ``%> echo 0x4 > ns_exlevel_viinst``
+
+ Excludes EL2 NS trace.
+
+----
+
+:File: ``vinst_pe_cmp_start_stop`` (rw)
+:Trace Registers: VIPCSSCTLR
+:Notes:
+ Access PE start stop comparator input control registers
+
+----
+
+:File: ``bb_ctrl`` (rw)
+:Trace Registers: BBCTLR
+:Notes:
+ Define ranges that Branch Broadcast will operate in.
+ Default (0x0) is all addresses.
+
+:Depends: BB enabled.
+
+----
+
+:File: ``cyc_threshold`` (rw)
+:Trace Registers: CCCTLR
+:Notes:
+ Set the threshold for which cycle counts will be emitted.
+ Error if attempt to set below minimum defined in IDR3, masked
+ to width of valid bits.
+
+:Depends: CC enabled.
+
+----
+
+:File: ``syncfreq`` (rw)
+:Trace Registers: SYNCPR
+:Notes:
+ Set trace synchronisation period. Power of 2 value, 0 (off)
+ or 8-20. Driver defaults to 12 (every 4096 bytes).
+
+----
+
+:File: ``cntr_idx`` (rw)
+:Trace Registers: none
+:Notes:
+ Select the counter to access
+
+:Syntax:
+ ``echo idx > cntr_idx``
+
+ Where idx < nr_cntr
+
+----
+
+:File: ``cntr_ctrl`` (rw)
+:Trace Registers: CNTCTLR[idx]
+:Notes:
+ Set counter control value.
+
+:Depends: ``cntr_idx``
+:Syntax:
+ ``echo val > cntr_ctrl``
+
+ Where val is per ETMv4 spec.
+
+----
+
+:File: ``cntrldvr`` (rw)
+:Trace Registers: CNTRLDVR[idx]
+:Notes:
+ Set counter reload value.
+
+:Depends: ``cntr_idx``
+:Syntax:
+ ``echo val > cntrldvr``
+
+ Where val is per ETMv4 spec.
+
+----
+
+:File: ``nr_cntr`` (ro)
+:Trace Registers: From IDR5
+
+:Notes:
+ Number of counters implemented.
+
+----
+
+:File: ``ctxid_idx`` (rw)
+:Trace Registers: None
+:Notes:
+ Select the context ID comparator to access
+
+:Syntax:
+ ``echo idx > ctxid_idx``
+
+ Where idx < numcidc
+
+----
+
+:File: ``ctxid_pid`` (rw)
+:Trace Registers: CIDCVR[idx]
+:Notes:
+ Set the context ID comparator value
+
+:Depends: ``ctxid_idx``
+
+----
+
+:File: ``ctxid_masks`` (rw)
+:Trace Registers: CIDCCTLR0, CIDCCTLR1, CIDCVR<0-7>
+:Notes:
+ Pair of values to set the byte masks for 1-8 context ID
+ comparators. Automatically clears masked bytes to 0 in CID
+ value registers.
+
+:Syntax:
+ ``echo m3m2m1m0 [m7m6m5m4] > ctxid_masks``
+
+ 32 bit values made up of mask bytes, where mN represents a
+ byte mask value for Context ID comparator N.
+
+ Second value not required on systems that have fewer than 4
+ context ID comparators
+
+----
+
+:File: ``numcidc`` (ro)
+:Trace Registers: From IDR4
+:Notes:
+ Number of Context ID comparators
+
+----
+
+:File: ``vmid_idx`` (rw)
+:Trace Registers: None
+:Notes:
+ Select the VM ID comparator to access.
+
+:Syntax:
+ ``echo idx > vmid_idx``
+
+ Where idx < numvmidc
+
+----
+
+:File: ``vmid_val`` (rw)
+:Trace Registers: VMIDCVR[idx]
+:Notes:
+ Set the VM ID comparator value
+
+:Depends: ``vmid_idx``
+
+----
+
+:File: ``vmid_masks`` (rw)
+:Trace Registers: VMIDCCTLR0, VMIDCCTLR1, VMIDCVR<0-7>
+:Notes:
+ Pair of values to set the byte masks for 1-8 VM ID comparators.
+ Automatically clears masked bytes to 0 in VMID value registers.
+
+:Syntax:
+ ``echo m3m2m1m0 [m7m6m5m4] > vmid_masks``
+
+ Where mN represents a byte mask value for VMID comparator N.
+ Second value not required on systems that have fewer than 4
+ VMID comparators.
+
+----
+
+:File: ``numvmidc`` (ro)
+:Trace Registers: From IDR4
+:Notes:
+ Number of VMID comparators
+
+----
+
+:File: ``res_idx`` (rw)
+:Trace Registers: None.
+:Notes:
+ Select the resource selector control to access. Must be 2 or
+ higher as selectors 0 and 1 are hardwired.
+
+:Syntax:
+ ``echo idx > res_idx``
+
+ Where 2 <= idx < nr_resource x 2
+
+----
+
+:File: ``res_ctrl`` (rw)
+:Trace Registers: RSCTLR[idx]
+:Notes:
+ Set resource selector control value. Value per ETMv4 spec.
+
+:Depends: ``res_idx``
+:Syntax:
+ ``echo val > res_cntr``
+
+ Where val is per ETMv4 spec.
+
+----
+
+:File: ``nr_resource`` (ro)
+:Trace Registers: From IDR4
+:Notes:
+ Number of resource selector pairs
+
+----
+
+:File: ``event`` (rw)
+:Trace Registers: EVENTCTRL0R
+:Notes:
+ Set up to 4 implemented event fields.
+
+:Syntax:
+ ``echo ev3ev2ev1ev0 > event``
+
+ Where evN is an 8 bit event field. Up to 4 event fields make up the
+ 32-bit input value. Number of valid fields is implementation dependent,
+ defined in IDR0.
+
+----
+
+:File: ``event_instren`` (rw)
+:Trace Registers: EVENTCTRL1R
+:Notes:
+ Choose events which insert event packets into trace stream.
+
+:Depends: EVENTCTRL0R
+:Syntax:
+ ``echo bitfield > event_instren``
+
+ Where bitfield is up to 4 bits according to number of event fields.
+
+----
+
+:File: ``event_ts`` (rw)
+:Trace Registers: TSCTLR
+:Notes:
+ Set the event that will generate timestamp requests.
+
+:Depends: ``TS activated``
+:Syntax:
+ ``echo evfield > event_ts``
+
+ Where evfield is an 8 bit event selector.
+
+----
+
+:File: ``seq_idx`` (rw)
+:Trace Registers: None
+:Notes:
+ Sequencer event register select - 0 to 2
+
+----
+
+:File: ``seq_state`` (rw)
+:Trace Registers: SEQSTR
+:Notes:
+ Sequencer current state - 0 to 3.
+
+----
+
+:File: ``seq_event`` (rw)
+:Trace Registers: SEQEVR[idx]
+:Notes:
+ State transition event registers
+
+:Depends: ``seq_idx``
+:Syntax:
+ ``echo evBevF > seq_event``
+
+ Where evBevF is a 16 bit value made up of two event selectors,
+
+ - evB : back
+ - evF : forwards.
+
+----
+
+:File: ``seq_reset_event`` (rw)
+:Trace Registers: SEQRSTEVR
+:Notes:
+ Sequencer reset event
+
+:Syntax:
+ ``echo evfield > seq_reset_event``
+
+ Where evfield is an 8 bit event selector.
+
+----
+
+:File: ``nrseqstate`` (ro)
+:Trace Registers: From IDR5
+:Notes:
+ Number of sequencer states (0 or 4)
+
+----
+
+:File: ``nr_pe_cmp`` (ro)
+:Trace Registers: From IDR4
+:Notes:
+ Number of PE comparator inputs
+
+----
+
+:File: ``nr_ext_inp`` (ro)
+:Trace Registers: From IDR5
+:Notes:
+ Number of external inputs
+
+----
+
+:File: ``nr_ss_cmp`` (ro)
+:Trace Registers: From IDR4
+:Notes:
+ Number of Single Shot control registers
+
+----
+
+*Note:* When programming any address comparator the driver will tag the
+comparator with a type used - i.e. RANGE, SINGLE, START, STOP. Once this tag
+is set, then only the values can be changed using the same sysfs file / type
+used to program it.
+
+Thus::
+
+ % echo 0 > addr_idx ; select address comparator 0
+ % echo 0x1000 0x5000 0 > addr_range ; set address range on comparators 0, 1.
+ % echo 0x2000 > addr_start ; error as comparator 0 is a range comparator
+ % echo 2 > addr_idx ; select address comparator 2
+ % echo 0x2000 > addr_start ; this is OK as comparator 2 is unused.
+ % echo 0x3000 > addr_stop ; error as comparator 2 set as start address.
+ % echo 2 > addr_idx ; select address comparator 3
+ % echo 0x3000 > addr_stop ; this is OK
+
+To remove programming on all the comparators (and all the other hardware) use
+the reset parameter::
+
+ % echo 1 > reset
+
+
+
+The ‘mode’ sysfs parameter.
+---------------------------
+
+This is a bitfield selection parameter that sets the overall trace mode for the
+ETM. The table below describes the bits, using the defines from the driver
+source file, along with a description of the feature these represent. Many
+features are optional and therefore dependent on implementation in the
+hardware.
+
+Bit assignments shown below:-
+
+----
+
+**bit (0):**
+ ETM_MODE_EXCLUDE
+
+**description:**
+ This is the default value for the include / exclude function when
+ setting address ranges. Set 1 for exclude range. When the mode
+ parameter is set this value is applied to the currently indexed
+ address range.
+
+.. _coresight-branch-broadcast:
+
+**bit (4):**
+ ETM_MODE_BB
+
+**description:**
+ Set to enable branch broadcast if supported in hardware [IDR0]. The primary use for this feature
+ is when code is patched dynamically at run time and the full program flow may not be able to be
+ reconstructed using only conditional branches.
+
+ There is currently no support in Perf for supplying modified binaries to the decoder, so this
+ feature is only inteded to be used for debugging purposes or with a 3rd party tool.
+
+ Choosing this option will result in a significant increase in the amount of trace generated -
+ possible danger of overflows, or fewer instructions covered. Note, that this option also
+ overrides any setting of :ref:`ETM_MODE_RETURNSTACK <coresight-return-stack>`, so where a branch
+ broadcast range overlaps a return stack range, return stacks will not be available for that
+ range.
+
+.. _coresight-cycle-accurate:
+
+**bit (5):**
+ ETMv4_MODE_CYCACC
+
+**description:**
+ Set to enable cycle accurate trace if supported [IDR0].
+
+
+**bit (6):**
+ ETMv4_MODE_CTXID
+
+**description:**
+ Set to enable context ID tracing if supported in hardware [IDR2].
+
+
+**bit (7):**
+ ETM_MODE_VMID
+
+**description:**
+ Set to enable virtual machine ID tracing if supported [IDR2].
+
+.. _coresight-timestamp:
+
+**bit (11):**
+ ETMv4_MODE_TIMESTAMP
+
+**description:**
+ Set to enable timestamp generation if supported [IDR0].
+
+.. _coresight-return-stack:
+
+**bit (12):**
+ ETM_MODE_RETURNSTACK
+**description:**
+ Set to enable trace return stack use if supported [IDR0].
+
+
+**bit (13-14):**
+ ETM_MODE_QELEM(val)
+
+**description:**
+ ‘val’ determines level of Q element support enabled if
+ implemented by the ETM [IDR0]
+
+
+**bit (19):**
+ ETM_MODE_ATB_TRIGGER
+
+**description:**
+ Set to enable the ATBTRIGGER bit in the event control register
+ [EVENTCTLR1] if supported [IDR5].
+
+
+**bit (20):**
+ ETM_MODE_LPOVERRIDE
+
+**description:**
+ Set to enable the LPOVERRIDE bit in the event control register
+ [EVENTCTLR1], if supported [IDR5].
+
+
+**bit (21):**
+ ETM_MODE_ISTALL_EN
+
+**description:**
+ Set to enable the ISTALL bit in the stall control register
+ [STALLCTLR]
+
+
+**bit (23):**
+ ETM_MODE_INSTPRIO
+
+**description:**
+ Set to enable the INSTPRIORITY bit in the stall control register
+ [STALLCTLR] , if supported [IDR0].
+
+
+**bit (24):**
+ ETM_MODE_NOOVERFLOW
+
+**description:**
+ Set to enable the NOOVERFLOW bit in the stall control register
+ [STALLCTLR], if supported [IDR3].
+
+
+**bit (25):**
+ ETM_MODE_TRACE_RESET
+
+**description:**
+ Set to enable the TRCRESET bit in the viewinst control register
+ [VICTLR] , if supported [IDR3].
+
+
+**bit (26):**
+ ETM_MODE_TRACE_ERR
+
+**description:**
+ Set to enable the TRCCTRL bit in the viewinst control register
+ [VICTLR].
+
+
+**bit (27):**
+ ETM_MODE_VIEWINST_STARTSTOP
+
+**description:**
+ Set the initial state value of the ViewInst start / stop logic
+ in the viewinst control register [VICTLR]
+
+
+**bit (30):**
+ ETM_MODE_EXCL_KERN
+
+**description:**
+ Set default trace setup to exclude kernel mode trace (see note a)
+
+
+**bit (31):**
+ ETM_MODE_EXCL_USER
+
+**description:**
+ Set default trace setup to exclude user space trace (see note a)
+
+----
+
+*Note a)* On startup the ETM is programmed to trace the complete address space
+using address range comparator 0. ‘mode’ bits 30 / 31 modify this setting to
+set EL exclude bits for NS state in either user space (EL0) or kernel space
+(EL1) in the address range comparator. (the default setting excludes all
+secure EL, and NS EL2)
+
+Once the reset parameter has been used, and/or custom programming has been
+implemented - using these bits will result in the EL bits for address
+comparator 0 being set in the same way.
+
+*Note b)* Bits 2-3, 8-10, 15-16, 18, 22, control features that only work with
+data trace. As A-profile data trace is architecturally prohibited in ETMv4,
+these have been omitted here. Possible uses could be where a kernel has
+support for control of R or M profile infrastructure as part of a heterogeneous
+system.
+
+Bits 17, 28-29 are unused.
diff --git a/Documentation/trace/coresight/coresight-perf.rst b/Documentation/trace/coresight/coresight-perf.rst
new file mode 100644
index 000000000..d087aae7d
--- /dev/null
+++ b/Documentation/trace/coresight/coresight-perf.rst
@@ -0,0 +1,158 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+================
+CoreSight - Perf
+================
+
+ :Author: Carsten Haitzler <carsten.haitzler@arm.com>
+ :Date: June 29th, 2022
+
+Perf is able to locally access CoreSight trace data and store it to the
+output perf data files. This data can then be later decoded to give the
+instructions that were traced for debugging or profiling purposes. You
+can log such data with a perf record command like::
+
+ perf record -e cs_etm//u testbinary
+
+This would run some test binary (testbinary) until it exits and record
+a perf.data trace file. That file would have AUX sections if CoreSight
+is working correctly. You can dump the content of this file as
+readable text with a command like::
+
+ perf report --stdio --dump -i perf.data
+
+You should find some sections of this file have AUX data blocks like::
+
+ 0x1e78 [0x30]: PERF_RECORD_AUXTRACE size: 0x11dd0 offset: 0 ref: 0x1b614fc1061b0ad1 idx: 0 tid: 531230 cpu: -1
+
+ . ... CoreSight ETM Trace data: size 73168 bytes
+ Idx:0; ID:10; I_ASYNC : Alignment Synchronisation.
+ Idx:12; ID:10; I_TRACE_INFO : Trace Info.; INFO=0x0 { CC.0 }
+ Idx:17; ID:10; I_ADDR_L_64IS0 : Address, Long, 64 bit, IS0.; Addr=0x0000000000000000;
+ Idx:26; ID:10; I_TRACE_ON : Trace On.
+ Idx:27; ID:10; I_ADDR_CTXT_L_64IS0 : Address & Context, Long, 64 bit, IS0.; Addr=0x0000FFFFB6069140; Ctxt: AArch64,EL0, NS;
+ Idx:38; ID:10; I_ATOM_F6 : Atom format 6.; EEEEEEEEEEEEEEEEEEEEEEEE
+ Idx:39; ID:10; I_ATOM_F6 : Atom format 6.; EEEEEEEEEEEEEEEEEEEEEEEE
+ Idx:40; ID:10; I_ATOM_F6 : Atom format 6.; EEEEEEEEEEEEEEEEEEEEEEEE
+ Idx:41; ID:10; I_ATOM_F6 : Atom format 6.; EEEEEEEEEEEN
+ ...
+
+If you see these above, then your system is tracing CoreSight data
+correctly.
+
+To compile perf with CoreSight support in the tools/perf directory do::
+
+ make CORESIGHT=1
+
+This requires OpenCSD to build. You may install distribution packages
+for the support such as libopencsd and libopencsd-dev or download it
+and build yourself. Upstream OpenCSD is located at:
+
+ https://github.com/Linaro/OpenCSD
+
+For complete information on building perf with CoreSight support and
+more extensive usage look at:
+
+ https://github.com/Linaro/OpenCSD/blob/master/HOWTO.md
+
+
+Kernel CoreSight Support
+------------------------
+
+You will also want CoreSight support enabled in your kernel config.
+Ensure it is enabled with::
+
+ CONFIG_CORESIGHT=y
+
+There are various other CoreSight options you probably also want
+enabled like::
+
+ CONFIG_CORESIGHT_LINKS_AND_SINKS=y
+ CONFIG_CORESIGHT_LINK_AND_SINK_TMC=y
+ CONFIG_CORESIGHT_CATU=y
+ CONFIG_CORESIGHT_SINK_TPIU=y
+ CONFIG_CORESIGHT_SINK_ETBV10=y
+ CONFIG_CORESIGHT_SOURCE_ETM4X=y
+ CONFIG_CORESIGHT_CTI=y
+ CONFIG_CORESIGHT_CTI_INTEGRATION_REGS=y
+
+Please refer to the kernel configuration help for more information.
+
+Perf test - Verify kernel and userspace perf CoreSight work
+-----------------------------------------------------------
+
+When you run perf test, it will do a lot of self tests. Some of those
+tests will cover CoreSight (only if enabled and on ARM64). You
+generally would run perf test from the tools/perf directory in the
+kernel tree. Some tests will check some internal perf support like:
+
+ Check Arm CoreSight trace data recording and synthesized samples
+ Check Arm SPE trace data recording and synthesized samples
+
+Some others will actually use perf record and some test binaries that
+are in tests/shell/coresight and will collect traces to ensure a
+minimum level of functionality is met. The scripts that launch these
+tests are in the same directory. These will all look like:
+
+ CoreSight / ASM Pure Loop
+ CoreSight / Memcpy 16k 10 Threads
+ CoreSight / Thread Loop 10 Threads - Check TID
+ etc.
+
+These perf record tests will not run if the tool binaries do not exist
+in tests/shell/coresight/\*/ and will be skipped. If you do not have
+CoreSight support in hardware then either do not build perf with
+CoreSight support or remove these binaries in order to not have these
+tests fail and have them skip instead.
+
+These tests will log historical results in the current working
+directory (e.g. tools/perf) and will be named stats-\*.csv like:
+
+ stats-asm_pure_loop-out.csv
+ stats-memcpy_thread-16k_10.csv
+ ...
+
+These statistic files log some aspects of the AUX data sections in
+the perf data output counting some numbers of certain encodings (a
+good way to know that it's working in a very simple way). One problem
+with CoreSight is that given a large enough amount of data needing to
+be logged, some of it can be lost due to the processor not waking up
+in time to read out all the data from buffers etc.. You will notice
+that the amount of data collected can vary a lot per run of perf test.
+If you wish to see how this changes over time, simply run perf test
+multiple times and all these csv files will have more and more data
+appended to it that you can later examine, graph and otherwise use to
+figure out if things have become worse or better.
+
+This means sometimes these tests fail as they don't capture all the
+data needed. This is about tracking quality and amount of data
+produced over time and to see when changes to the Linux kernel improve
+quality of traces.
+
+Be aware that some of these tests take quite a while to run, specifically
+in processing the perf data file and dumping contents to then examine what
+is inside.
+
+You can change where these csv logs are stored by setting the
+PERF_TEST_CORESIGHT_STATDIR environment variable before running perf
+test like::
+
+ export PERF_TEST_CORESIGHT_STATDIR=/var/tmp
+ perf test
+
+They will also store resulting perf output data in the current
+directory for later inspection like::
+
+ perf-asm_pure_loop-out.data
+ perf-memcpy_thread-16k_10.data
+ ...
+
+You can alter where the perf data files are stored by setting the
+PERF_TEST_CORESIGHT_DATADIR environment variable such as::
+
+ PERF_TEST_CORESIGHT_DATADIR=/var/tmp
+ perf test
+
+You may wish to set these above environment variables if you wish to
+keep the output of tests outside of the current working directory for
+longer term storage and examination.
diff --git a/Documentation/trace/coresight/coresight-trbe.rst b/Documentation/trace/coresight/coresight-trbe.rst
new file mode 100644
index 000000000..b9928ef14
--- /dev/null
+++ b/Documentation/trace/coresight/coresight-trbe.rst
@@ -0,0 +1,38 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+==============================
+Trace Buffer Extension (TRBE).
+==============================
+
+ :Author: Anshuman Khandual <anshuman.khandual@arm.com>
+ :Date: November 2020
+
+Hardware Description
+--------------------
+
+Trace Buffer Extension (TRBE) is a percpu hardware which captures in system
+memory, CPU traces generated from a corresponding percpu tracing unit. This
+gets plugged in as a coresight sink device because the corresponding trace
+generators (ETE), are plugged in as source device.
+
+The TRBE is not compliant to CoreSight architecture specifications, but is
+driven via the CoreSight driver framework to support the ETE (which is
+CoreSight compliant) integration.
+
+Sysfs files and directories
+---------------------------
+
+The TRBE devices appear on the existing coresight bus alongside the other
+coresight devices::
+
+ >$ ls /sys/bus/coresight/devices
+ trbe0 trbe1 trbe2 trbe3
+
+The ``trbe<N>`` named TRBEs are associated with a CPU.::
+
+ >$ ls /sys/bus/coresight/devices/trbe0/
+ align flag
+
+*Key file items are:-*
+ * ``align``: TRBE write pointer alignment
+ * ``flag``: TRBE updates memory with access and dirty flags
diff --git a/Documentation/trace/coresight/coresight.rst b/Documentation/trace/coresight/coresight.rst
new file mode 100644
index 000000000..4a71ea6cb
--- /dev/null
+++ b/Documentation/trace/coresight/coresight.rst
@@ -0,0 +1,691 @@
+======================================
+Coresight - HW Assisted Tracing on ARM
+======================================
+
+ :Author: Mathieu Poirier <mathieu.poirier@linaro.org>
+ :Date: September 11th, 2014
+
+Introduction
+------------
+
+Coresight is an umbrella of technologies allowing for the debugging of ARM
+based SoC. It includes solutions for JTAG and HW assisted tracing. This
+document is concerned with the latter.
+
+HW assisted tracing is becoming increasingly useful when dealing with systems
+that have many SoCs and other components like GPU and DMA engines. ARM has
+developed a HW assisted tracing solution by means of different components, each
+being added to a design at synthesis time to cater to specific tracing needs.
+Components are generally categorised as source, link and sinks and are
+(usually) discovered using the AMBA bus.
+
+"Sources" generate a compressed stream representing the processor instruction
+path based on tracing scenarios as configured by users. From there the stream
+flows through the coresight system (via ATB bus) using links that are connecting
+the emanating source to a sink(s). Sinks serve as endpoints to the coresight
+implementation, either storing the compressed stream in a memory buffer or
+creating an interface to the outside world where data can be transferred to a
+host without fear of filling up the onboard coresight memory buffer.
+
+At typical coresight system would look like this::
+
+ *****************************************************************
+ **************************** AMBA AXI ****************************===||
+ ***************************************************************** ||
+ ^ ^ | ||
+ | | * **
+ 0000000 ::::: 0000000 ::::: ::::: @@@@@@@ ||||||||||||
+ 0 CPU 0<-->: C : 0 CPU 0<-->: C : : C : @ STM @ || System ||
+ |->0000000 : T : |->0000000 : T : : T :<--->@@@@@ || Memory ||
+ | #######<-->: I : | #######<-->: I : : I : @@@<-| ||||||||||||
+ | # ETM # ::::: | # PTM # ::::: ::::: @ |
+ | ##### ^ ^ | ##### ^ ! ^ ! . | |||||||||
+ | |->### | ! | |->### | ! | ! . | || DAP ||
+ | | # | ! | | # | ! | ! . | |||||||||
+ | | . | ! | | . | ! | ! . | | |
+ | | . | ! | | . | ! | ! . | | *
+ | | . | ! | | . | ! | ! . | | SWD/
+ | | . | ! | | . | ! | ! . | | JTAG
+ *****************************************************************<-|
+ *************************** AMBA Debug APB ************************
+ *****************************************************************
+ | . ! . ! ! . |
+ | . * . * * . |
+ *****************************************************************
+ ******************** Cross Trigger Matrix (CTM) *******************
+ *****************************************************************
+ | . ^ . . |
+ | * ! * * |
+ *****************************************************************
+ ****************** AMBA Advanced Trace Bus (ATB) ******************
+ *****************************************************************
+ | ! =============== |
+ | * ===== F =====<---------|
+ | ::::::::: ==== U ====
+ |-->:: CTI ::<!! === N ===
+ | ::::::::: ! == N ==
+ | ^ * == E ==
+ | ! &&&&&&&&& IIIIIII == L ==
+ |------>&& ETB &&<......II I =======
+ | ! &&&&&&&&& II I .
+ | ! I I .
+ | ! I REP I<..........
+ | ! I I
+ | !!>&&&&&&&&& II I *Source: ARM ltd.
+ |------>& TPIU &<......II I DAP = Debug Access Port
+ &&&&&&&&& IIIIIII ETM = Embedded Trace Macrocell
+ ; PTM = Program Trace Macrocell
+ ; CTI = Cross Trigger Interface
+ * ETB = Embedded Trace Buffer
+ To trace port TPIU= Trace Port Interface Unit
+ SWD = Serial Wire Debug
+
+While on target configuration of the components is done via the APB bus,
+all trace data are carried out-of-band on the ATB bus. The CTM provides
+a way to aggregate and distribute signals between CoreSight components.
+
+The coresight framework provides a central point to represent, configure and
+manage coresight devices on a platform. This first implementation centers on
+the basic tracing functionality, enabling components such ETM/PTM, funnel,
+replicator, TMC, TPIU and ETB. Future work will enable more
+intricate IP blocks such as STM and CTI.
+
+
+Acronyms and Classification
+---------------------------
+
+Acronyms:
+
+PTM:
+ Program Trace Macrocell
+ETM:
+ Embedded Trace Macrocell
+STM:
+ System trace Macrocell
+ETB:
+ Embedded Trace Buffer
+ITM:
+ Instrumentation Trace Macrocell
+TPIU:
+ Trace Port Interface Unit
+TMC-ETR:
+ Trace Memory Controller, configured as Embedded Trace Router
+TMC-ETF:
+ Trace Memory Controller, configured as Embedded Trace FIFO
+CTI:
+ Cross Trigger Interface
+
+Classification:
+
+Source:
+ ETMv3.x ETMv4, PTMv1.0, PTMv1.1, STM, STM500, ITM
+Link:
+ Funnel, replicator (intelligent or not), TMC-ETR
+Sinks:
+ ETBv1.0, ETB1.1, TPIU, TMC-ETF
+Misc:
+ CTI
+
+
+Device Tree Bindings
+--------------------
+
+See Documentation/devicetree/bindings/arm/arm,coresight-\*.yaml for details.
+
+As of this writing drivers for ITM, STMs and CTIs are not provided but are
+expected to be added as the solution matures.
+
+
+Framework and implementation
+----------------------------
+
+The coresight framework provides a central point to represent, configure and
+manage coresight devices on a platform. Any coresight compliant device can
+register with the framework for as long as they use the right APIs:
+
+.. c:function:: struct coresight_device *coresight_register(struct coresight_desc *desc);
+.. c:function:: void coresight_unregister(struct coresight_device *csdev);
+
+The registering function is taking a ``struct coresight_desc *desc`` and
+register the device with the core framework. The unregister function takes
+a reference to a ``struct coresight_device *csdev`` obtained at registration time.
+
+If everything goes well during the registration process the new devices will
+show up under /sys/bus/coresight/devices, as showns here for a TC2 platform::
+
+ root:~# ls /sys/bus/coresight/devices/
+ replicator 20030000.tpiu 2201c000.ptm 2203c000.etm 2203e000.etm
+ 20010000.etb 20040000.funnel 2201d000.ptm 2203d000.etm
+ root:~#
+
+The functions take a ``struct coresight_device``, which looks like this::
+
+ struct coresight_desc {
+ enum coresight_dev_type type;
+ struct coresight_dev_subtype subtype;
+ const struct coresight_ops *ops;
+ struct coresight_platform_data *pdata;
+ struct device *dev;
+ const struct attribute_group **groups;
+ };
+
+
+The "coresight_dev_type" identifies what the device is, i.e, source link or
+sink while the "coresight_dev_subtype" will characterise that type further.
+
+The ``struct coresight_ops`` is mandatory and will tell the framework how to
+perform base operations related to the components, each component having
+a different set of requirement. For that ``struct coresight_ops_sink``,
+``struct coresight_ops_link`` and ``struct coresight_ops_source`` have been
+provided.
+
+The next field ``struct coresight_platform_data *pdata`` is acquired by calling
+``of_get_coresight_platform_data()``, as part of the driver's _probe routine and
+``struct device *dev`` gets the device reference embedded in the ``amba_device``::
+
+ static int etm_probe(struct amba_device *adev, const struct amba_id *id)
+ {
+ ...
+ ...
+ drvdata->dev = &adev->dev;
+ ...
+ }
+
+Specific class of device (source, link, or sink) have generic operations
+that can be performed on them (see ``struct coresight_ops``). The ``**groups``
+is a list of sysfs entries pertaining to operations
+specific to that component only. "Implementation defined" customisations are
+expected to be accessed and controlled using those entries.
+
+Device Naming scheme
+--------------------
+
+The devices that appear on the "coresight" bus were named the same as their
+parent devices, i.e, the real devices that appears on AMBA bus or the platform bus.
+Thus the names were based on the Linux Open Firmware layer naming convention,
+which follows the base physical address of the device followed by the device
+type. e.g::
+
+ root:~# ls /sys/bus/coresight/devices/
+ 20010000.etf 20040000.funnel 20100000.stm 22040000.etm
+ 22140000.etm 230c0000.funnel 23240000.etm 20030000.tpiu
+ 20070000.etr 20120000.replicator 220c0000.funnel
+ 23040000.etm 23140000.etm 23340000.etm
+
+However, with the introduction of ACPI support, the names of the real
+devices are a bit cryptic and non-obvious. Thus, a new naming scheme was
+introduced to use more generic names based on the type of the device. The
+following rules apply::
+
+ 1) Devices that are bound to CPUs, are named based on the CPU logical
+ number.
+
+ e.g, ETM bound to CPU0 is named "etm0"
+
+ 2) All other devices follow a pattern, "<device_type_prefix>N", where :
+
+ <device_type_prefix> - A prefix specific to the type of the device
+ N - a sequential number assigned based on the order
+ of probing.
+
+ e.g, tmc_etf0, tmc_etr0, funnel0, funnel1
+
+Thus, with the new scheme the devices could appear as ::
+
+ root:~# ls /sys/bus/coresight/devices/
+ etm0 etm1 etm2 etm3 etm4 etm5 funnel0
+ funnel1 funnel2 replicator0 stm0 tmc_etf0 tmc_etr0 tpiu0
+
+Some of the examples below might refer to old naming scheme and some
+to the newer scheme, to give a confirmation that what you see on your
+system is not unexpected. One must use the "names" as they appear on
+the system under specified locations.
+
+Topology Representation
+-----------------------
+
+Each CoreSight component has a ``connections`` directory which will contain
+links to other CoreSight components. This allows the user to explore the trace
+topology and for larger systems, determine the most appropriate sink for a
+given source. The connection information can also be used to establish
+which CTI devices are connected to a given component. This directory contains a
+``nr_links`` attribute detailing the number of links in the directory.
+
+For an ETM source, in this case ``etm0`` on a Juno platform, a typical
+arrangement will be::
+
+ linaro-developer:~# ls - l /sys/bus/coresight/devices/etm0/connections
+ <file details> cti_cpu0 -> ../../../23020000.cti/cti_cpu0
+ <file details> nr_links
+ <file details> out:0 -> ../../../230c0000.funnel/funnel2
+
+Following the out port to ``funnel2``::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/funnel2/connections
+ <file details> in:0 -> ../../../23040000.etm/etm0
+ <file details> in:1 -> ../../../23140000.etm/etm3
+ <file details> in:2 -> ../../../23240000.etm/etm4
+ <file details> in:3 -> ../../../23340000.etm/etm5
+ <file details> nr_links
+ <file details> out:0 -> ../../../20040000.funnel/funnel0
+
+And again to ``funnel0``::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/funnel0/connections
+ <file details> in:0 -> ../../../220c0000.funnel/funnel1
+ <file details> in:1 -> ../../../230c0000.funnel/funnel2
+ <file details> nr_links
+ <file details> out:0 -> ../../../20010000.etf/tmc_etf0
+
+Finding the first sink ``tmc_etf0``. This can be used to collect data
+as a sink, or as a link to propagate further along the chain::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/tmc_etf0/connections
+ <file details> cti_sys0 -> ../../../20020000.cti/cti_sys0
+ <file details> in:0 -> ../../../20040000.funnel/funnel0
+ <file details> nr_links
+ <file details> out:0 -> ../../../20150000.funnel/funnel4
+
+via ``funnel4``::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/funnel4/connections
+ <file details> in:0 -> ../../../20010000.etf/tmc_etf0
+ <file details> in:1 -> ../../../20140000.etf/tmc_etf1
+ <file details> nr_links
+ <file details> out:0 -> ../../../20120000.replicator/replicator0
+
+and a ``replicator0``::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/replicator0/connections
+ <file details> in:0 -> ../../../20150000.funnel/funnel4
+ <file details> nr_links
+ <file details> out:0 -> ../../../20030000.tpiu/tpiu0
+ <file details> out:1 -> ../../../20070000.etr/tmc_etr0
+
+Arriving at the final sink in the chain, ``tmc_etr0``::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/tmc_etr0/connections
+ <file details> cti_sys0 -> ../../../20020000.cti/cti_sys0
+ <file details> in:0 -> ../../../20120000.replicator/replicator0
+ <file details> nr_links
+
+As described below, when using sysfs it is sufficient to enable a sink and
+a source for successful trace. The framework will correctly enable all
+intermediate links as required.
+
+Note: ``cti_sys0`` appears in two of the connections lists above.
+CTIs can connect to multiple devices and are arranged in a star topology
+via the CTM. See (Documentation/trace/coresight/coresight-ect.rst)
+[#fourth]_ for further details.
+Looking at this device we see 4 connections::
+
+ linaro-developer:~# ls -l /sys/bus/coresight/devices/cti_sys0/connections
+ <file details> nr_links
+ <file details> stm0 -> ../../../20100000.stm/stm0
+ <file details> tmc_etf0 -> ../../../20010000.etf/tmc_etf0
+ <file details> tmc_etr0 -> ../../../20070000.etr/tmc_etr0
+ <file details> tpiu0 -> ../../../20030000.tpiu/tpiu0
+
+
+How to use the tracer modules
+-----------------------------
+
+There are two ways to use the Coresight framework:
+
+1. using the perf cmd line tools.
+2. interacting directly with the Coresight devices using the sysFS interface.
+
+Preference is given to the former as using the sysFS interface
+requires a deep understanding of the Coresight HW. The following sections
+provide details on using both methods.
+
+Using the sysFS interface
+~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Before trace collection can start, a coresight sink needs to be identified.
+There is no limit on the amount of sinks (nor sources) that can be enabled at
+any given moment. As a generic operation, all device pertaining to the sink
+class will have an "active" entry in sysfs::
+
+ root:/sys/bus/coresight/devices# ls
+ replicator 20030000.tpiu 2201c000.ptm 2203c000.etm 2203e000.etm
+ 20010000.etb 20040000.funnel 2201d000.ptm 2203d000.etm
+ root:/sys/bus/coresight/devices# ls 20010000.etb
+ enable_sink status trigger_cntr
+ root:/sys/bus/coresight/devices# echo 1 > 20010000.etb/enable_sink
+ root:/sys/bus/coresight/devices# cat 20010000.etb/enable_sink
+ 1
+ root:/sys/bus/coresight/devices#
+
+At boot time the current etm3x driver will configure the first address
+comparator with "_stext" and "_etext", essentially tracing any instruction
+that falls within that range. As such "enabling" a source will immediately
+trigger a trace capture::
+
+ root:/sys/bus/coresight/devices# echo 1 > 2201c000.ptm/enable_source
+ root:/sys/bus/coresight/devices# cat 2201c000.ptm/enable_source
+ 1
+ root:/sys/bus/coresight/devices# cat 20010000.etb/status
+ Depth: 0x2000
+ Status: 0x1
+ RAM read ptr: 0x0
+ RAM wrt ptr: 0x19d3 <----- The write pointer is moving
+ Trigger cnt: 0x0
+ Control: 0x1
+ Flush status: 0x0
+ Flush ctrl: 0x2001
+ root:/sys/bus/coresight/devices#
+
+Trace collection is stopped the same way::
+
+ root:/sys/bus/coresight/devices# echo 0 > 2201c000.ptm/enable_source
+ root:/sys/bus/coresight/devices#
+
+The content of the ETB buffer can be harvested directly from /dev::
+
+ root:/sys/bus/coresight/devices# dd if=/dev/20010000.etb \
+ of=~/cstrace.bin
+ 64+0 records in
+ 64+0 records out
+ 32768 bytes (33 kB) copied, 0.00125258 s, 26.2 MB/s
+ root:/sys/bus/coresight/devices#
+
+The file cstrace.bin can be decompressed using "ptm2human", DS-5 or Trace32.
+
+Following is a DS-5 output of an experimental loop that increments a variable up
+to a certain value. The example is simple and yet provides a glimpse of the
+wealth of possibilities that coresight provides.
+::
+
+ Info Tracing enabled
+ Instruction 106378866 0x8026B53C E52DE004 false PUSH {lr}
+ Instruction 0 0x8026B540 E24DD00C false SUB sp,sp,#0xc
+ Instruction 0 0x8026B544 E3A03000 false MOV r3,#0
+ Instruction 0 0x8026B548 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B54C E59D3004 false LDR r3,[sp,#4]
+ Instruction 0 0x8026B550 E3530004 false CMP r3,#4
+ Instruction 0 0x8026B554 E2833001 false ADD r3,r3,#1
+ Instruction 0 0x8026B558 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B55C DAFFFFFA true BLE {pc}-0x10 ; 0x8026b54c
+ Timestamp Timestamp: 17106715833
+ Instruction 319 0x8026B54C E59D3004 false LDR r3,[sp,#4]
+ Instruction 0 0x8026B550 E3530004 false CMP r3,#4
+ Instruction 0 0x8026B554 E2833001 false ADD r3,r3,#1
+ Instruction 0 0x8026B558 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B55C DAFFFFFA true BLE {pc}-0x10 ; 0x8026b54c
+ Instruction 9 0x8026B54C E59D3004 false LDR r3,[sp,#4]
+ Instruction 0 0x8026B550 E3530004 false CMP r3,#4
+ Instruction 0 0x8026B554 E2833001 false ADD r3,r3,#1
+ Instruction 0 0x8026B558 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B55C DAFFFFFA true BLE {pc}-0x10 ; 0x8026b54c
+ Instruction 7 0x8026B54C E59D3004 false LDR r3,[sp,#4]
+ Instruction 0 0x8026B550 E3530004 false CMP r3,#4
+ Instruction 0 0x8026B554 E2833001 false ADD r3,r3,#1
+ Instruction 0 0x8026B558 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B55C DAFFFFFA true BLE {pc}-0x10 ; 0x8026b54c
+ Instruction 7 0x8026B54C E59D3004 false LDR r3,[sp,#4]
+ Instruction 0 0x8026B550 E3530004 false CMP r3,#4
+ Instruction 0 0x8026B554 E2833001 false ADD r3,r3,#1
+ Instruction 0 0x8026B558 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B55C DAFFFFFA true BLE {pc}-0x10 ; 0x8026b54c
+ Instruction 10 0x8026B54C E59D3004 false LDR r3,[sp,#4]
+ Instruction 0 0x8026B550 E3530004 false CMP r3,#4
+ Instruction 0 0x8026B554 E2833001 false ADD r3,r3,#1
+ Instruction 0 0x8026B558 E58D3004 false STR r3,[sp,#4]
+ Instruction 0 0x8026B55C DAFFFFFA true BLE {pc}-0x10 ; 0x8026b54c
+ Instruction 6 0x8026B560 EE1D3F30 false MRC p15,#0x0,r3,c13,c0,#1
+ Instruction 0 0x8026B564 E1A0100D false MOV r1,sp
+ Instruction 0 0x8026B568 E3C12D7F false BIC r2,r1,#0x1fc0
+ Instruction 0 0x8026B56C E3C2203F false BIC r2,r2,#0x3f
+ Instruction 0 0x8026B570 E59D1004 false LDR r1,[sp,#4]
+ Instruction 0 0x8026B574 E59F0010 false LDR r0,[pc,#16] ; [0x8026B58C] = 0x80550368
+ Instruction 0 0x8026B578 E592200C false LDR r2,[r2,#0xc]
+ Instruction 0 0x8026B57C E59221D0 false LDR r2,[r2,#0x1d0]
+ Instruction 0 0x8026B580 EB07A4CF true BL {pc}+0x1e9344 ; 0x804548c4
+ Info Tracing enabled
+ Instruction 13570831 0x8026B584 E28DD00C false ADD sp,sp,#0xc
+ Instruction 0 0x8026B588 E8BD8000 true LDM sp!,{pc}
+ Timestamp Timestamp: 17107041535
+
+Using perf framework
+~~~~~~~~~~~~~~~~~~~~
+
+Coresight tracers are represented using the Perf framework's Performance
+Monitoring Unit (PMU) abstraction. As such the perf framework takes charge of
+controlling when tracing gets enabled based on when the process of interest is
+scheduled. When configured in a system, Coresight PMUs will be listed when
+queried by the perf command line tool:
+
+ linaro@linaro-nano:~$ ./perf list pmu
+
+ List of pre-defined events (to be used in -e):
+
+ cs_etm// [Kernel PMU event]
+
+ linaro@linaro-nano:~$
+
+Regardless of the number of tracers available in a system (usually equal to the
+amount of processor cores), the "cs_etm" PMU will be listed only once.
+
+A Coresight PMU works the same way as any other PMU, i.e the name of the PMU is
+listed along with configuration options within forward slashes '/'. Since a
+Coresight system will typically have more than one sink, the name of the sink to
+work with needs to be specified as an event option.
+On newer kernels the available sinks are listed in sysFS under
+($SYSFS)/bus/event_source/devices/cs_etm/sinks/::
+
+ root@localhost:/sys/bus/event_source/devices/cs_etm/sinks# ls
+ tmc_etf0 tmc_etr0 tpiu0
+
+On older kernels, this may need to be found from the list of coresight devices,
+available under ($SYSFS)/bus/coresight/devices/::
+
+ root:~# ls /sys/bus/coresight/devices/
+ etm0 etm1 etm2 etm3 etm4 etm5 funnel0
+ funnel1 funnel2 replicator0 stm0 tmc_etf0 tmc_etr0 tpiu0
+ root@linaro-nano:~# perf record -e cs_etm/@tmc_etr0/u --per-thread program
+
+As mentioned above in section "Device Naming scheme", the names of the devices could
+look different from what is used in the example above. One must use the device names
+as it appears under the sysFS.
+
+The syntax within the forward slashes '/' is important. The '@' character
+tells the parser that a sink is about to be specified and that this is the sink
+to use for the trace session.
+
+More information on the above and other example on how to use Coresight with
+the perf tools can be found in the "HOWTO.md" file of the openCSD gitHub
+repository [#third]_.
+
+Advanced perf framework usage
+-----------------------------
+
+AutoFDO analysis using the perf tools
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+perf can be used to record and analyze trace of programs.
+
+Execution can be recorded using 'perf record' with the cs_etm event,
+specifying the name of the sink to record to, e.g::
+
+ perf record -e cs_etm/@tmc_etr0/u --per-thread
+
+The 'perf report' and 'perf script' commands can be used to analyze execution,
+synthesizing instruction and branch events from the instruction trace.
+'perf inject' can be used to replace the trace data with the synthesized events.
+The --itrace option controls the type and frequency of synthesized events
+(see perf documentation).
+
+Note that only 64-bit programs are currently supported - further work is
+required to support instruction decode of 32-bit Arm programs.
+
+Tracing PID
+~~~~~~~~~~~
+
+The kernel can be built to write the PID value into the PE ContextID registers.
+For a kernel running at EL1, the PID is stored in CONTEXTIDR_EL1. A PE may
+implement Arm Virtualization Host Extensions (VHE), which the kernel can
+run at EL2 as a virtualisation host; in this case, the PID value is stored in
+CONTEXTIDR_EL2.
+
+perf provides PMU formats that program the ETM to insert these values into the
+trace data; the PMU formats are defined as below:
+
+ "contextid1": Available on both EL1 kernel and EL2 kernel. When the
+ kernel is running at EL1, "contextid1" enables the PID
+ tracing; when the kernel is running at EL2, this enables
+ tracing the PID of guest applications.
+
+ "contextid2": Only usable when the kernel is running at EL2. When
+ selected, enables PID tracing on EL2 kernel.
+
+ "contextid": Will be an alias for the option that enables PID
+ tracing. I.e,
+ contextid == contextid1, on EL1 kernel.
+ contextid == contextid2, on EL2 kernel.
+
+perf will always enable PID tracing at the relevant EL, this is accomplished by
+automatically enable the "contextid" config - but for EL2 it is possible to make
+specific adjustments using configs "contextid1" and "contextid2", E.g. if a user
+wants to trace PIDs for both host and guest, the two configs "contextid1" and
+"contextid2" can be set at the same time:
+
+ perf record -e cs_etm/contextid1,contextid2/u -- vm
+
+
+Generating coverage files for Feedback Directed Optimization: AutoFDO
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+'perf inject' accepts the --itrace option in which case tracing data is
+removed and replaced with the synthesized events. e.g.
+::
+
+ perf inject --itrace --strip -i perf.data -o perf.data.new
+
+Below is an example of using ARM ETM for autoFDO. It requires autofdo
+(https://github.com/google/autofdo) and gcc version 5. The bubble
+sort example is from the AutoFDO tutorial (https://gcc.gnu.org/wiki/AutoFDO/Tutorial).
+::
+
+ $ gcc-5 -O3 sort.c -o sort
+ $ taskset -c 2 ./sort
+ Bubble sorting array of 30000 elements
+ 5910 ms
+
+ $ perf record -e cs_etm/@tmc_etr0/u --per-thread taskset -c 2 ./sort
+ Bubble sorting array of 30000 elements
+ 12543 ms
+ [ perf record: Woken up 35 times to write data ]
+ [ perf record: Captured and wrote 69.640 MB perf.data ]
+
+ $ perf inject -i perf.data -o inj.data --itrace=il64 --strip
+ $ create_gcov --binary=./sort --profile=inj.data --gcov=sort.gcov -gcov_version=1
+ $ gcc-5 -O3 -fauto-profile=sort.gcov sort.c -o sort_autofdo
+ $ taskset -c 2 ./sort_autofdo
+ Bubble sorting array of 30000 elements
+ 5806 ms
+
+Config option formats
+~~~~~~~~~~~~~~~~~~~~~
+
+The following strings can be provided between // on the perf command line to enable various options.
+They are also listed in the folder /sys/bus/event_source/devices/cs_etm/format/
+
+.. list-table::
+ :header-rows: 1
+
+ * - Option
+ - Description
+ * - branch_broadcast
+ - Session local version of the system wide setting:
+ :ref:`ETM_MODE_BB <coresight-branch-broadcast>`
+ * - contextid
+ - See `Tracing PID`_
+ * - contextid1
+ - See `Tracing PID`_
+ * - contextid2
+ - See `Tracing PID`_
+ * - configid
+ - Selection for a custom configuration. This is an implementation detail and not used directly,
+ see :ref:`trace/coresight/coresight-config:Using Configurations in perf`
+ * - preset
+ - Override for parameters in a custom configuration, see
+ :ref:`trace/coresight/coresight-config:Using Configurations in perf`
+ * - sinkid
+ - Hashed version of the string to select a sink, automatically set when using the @ notation.
+ This is an internal implementation detail and is not used directly, see `Using perf
+ framework`_.
+ * - cycacc
+ - Session local version of the system wide setting: :ref:`ETMv4_MODE_CYCACC
+ <coresight-cycle-accurate>`
+ * - retstack
+ - Session local version of the system wide setting: :ref:`ETM_MODE_RETURNSTACK
+ <coresight-return-stack>`
+ * - timestamp
+ - Session local version of the system wide setting: :ref:`ETMv4_MODE_TIMESTAMP
+ <coresight-timestamp>`
+
+How to use the STM module
+-------------------------
+
+Using the System Trace Macrocell module is the same as the tracers - the only
+difference is that clients are driving the trace capture rather
+than the program flow through the code.
+
+As with any other CoreSight component, specifics about the STM tracer can be
+found in sysfs with more information on each entry being found in [#first]_::
+
+ root@genericarmv8:~# ls /sys/bus/coresight/devices/stm0
+ enable_source hwevent_select port_enable subsystem uevent
+ hwevent_enable mgmt port_select traceid
+ root@genericarmv8:~#
+
+Like any other source a sink needs to be identified and the STM enabled before
+being used::
+
+ root@genericarmv8:~# echo 1 > /sys/bus/coresight/devices/tmc_etf0/enable_sink
+ root@genericarmv8:~# echo 1 > /sys/bus/coresight/devices/stm0/enable_source
+
+From there user space applications can request and use channels using the devfs
+interface provided for that purpose by the generic STM API::
+
+ root@genericarmv8:~# ls -l /dev/stm0
+ crw------- 1 root root 10, 61 Jan 3 18:11 /dev/stm0
+ root@genericarmv8:~#
+
+Details on how to use the generic STM API can be found here:
+- Documentation/trace/stm.rst [#second]_.
+
+The CTI & CTM Modules
+---------------------
+
+The CTI (Cross Trigger Interface) provides a set of trigger signals between
+individual CTIs and components, and can propagate these between all CTIs via
+channels on the CTM (Cross Trigger Matrix).
+
+A separate documentation file is provided to explain the use of these devices.
+(Documentation/trace/coresight/coresight-ect.rst) [#fourth]_.
+
+CoreSight System Configuration
+------------------------------
+
+CoreSight components can be complex devices with many programming options.
+Furthermore, components can be programmed to interact with each other across the
+complete system.
+
+A CoreSight System Configuration manager is provided to allow these complex programming
+configurations to be selected and used easily from perf and sysfs.
+
+See the separate document for further information.
+(Documentation/trace/coresight/coresight-config.rst) [#fifth]_.
+
+
+.. [#first] Documentation/ABI/testing/sysfs-bus-coresight-devices-stm
+
+.. [#second] Documentation/trace/stm.rst
+
+.. [#third] https://github.com/Linaro/perf-opencsd
+
+.. [#fourth] Documentation/trace/coresight/coresight-ect.rst
+
+.. [#fifth] Documentation/trace/coresight/coresight-config.rst
diff --git a/Documentation/trace/coresight/index.rst b/Documentation/trace/coresight/index.rst
new file mode 100644
index 000000000..8d31b155a
--- /dev/null
+++ b/Documentation/trace/coresight/index.rst
@@ -0,0 +1,9 @@
+==============================
+CoreSight - ARM Hardware Trace
+==============================
+
+.. toctree::
+ :maxdepth: 2
+ :glob:
+
+ *
diff --git a/Documentation/trace/events-kmem.rst b/Documentation/trace/events-kmem.rst
new file mode 100644
index 000000000..68fa75247
--- /dev/null
+++ b/Documentation/trace/events-kmem.rst
@@ -0,0 +1,119 @@
+============================
+Subsystem Trace Points: kmem
+============================
+
+The kmem tracing system captures events related to object and page allocation
+within the kernel. Broadly speaking there are five major subheadings.
+
+ - Slab allocation of small objects of unknown type (kmalloc)
+ - Slab allocation of small objects of known type
+ - Page allocation
+ - Per-CPU Allocator Activity
+ - External Fragmentation
+
+This document describes what each of the tracepoints is and why they
+might be useful.
+
+1. Slab allocation of small objects of unknown type
+===================================================
+::
+
+ kmalloc call_site=%lx ptr=%p bytes_req=%zu bytes_alloc=%zu gfp_flags=%s
+ kmalloc_node call_site=%lx ptr=%p bytes_req=%zu bytes_alloc=%zu gfp_flags=%s node=%d
+ kfree call_site=%lx ptr=%p
+
+Heavy activity for these events may indicate that a specific cache is
+justified, particularly if kmalloc slab pages are getting significantly
+internal fragmented as a result of the allocation pattern. By correlating
+kmalloc with kfree, it may be possible to identify memory leaks and where
+the allocation sites were.
+
+
+2. Slab allocation of small objects of known type
+=================================================
+::
+
+ kmem_cache_alloc call_site=%lx ptr=%p bytes_req=%zu bytes_alloc=%zu gfp_flags=%s
+ kmem_cache_alloc_node call_site=%lx ptr=%p bytes_req=%zu bytes_alloc=%zu gfp_flags=%s node=%d
+ kmem_cache_free call_site=%lx ptr=%p
+
+These events are similar in usage to the kmalloc-related events except that
+it is likely easier to pin the event down to a specific cache. At the time
+of writing, no information is available on what slab is being allocated from,
+but the call_site can usually be used to extrapolate that information.
+
+3. Page allocation
+==================
+::
+
+ mm_page_alloc page=%p pfn=%lu order=%d migratetype=%d gfp_flags=%s
+ mm_page_alloc_zone_locked page=%p pfn=%lu order=%u migratetype=%d cpu=%d percpu_refill=%d
+ mm_page_free page=%p pfn=%lu order=%d
+ mm_page_free_batched page=%p pfn=%lu order=%d cold=%d
+
+These four events deal with page allocation and freeing. mm_page_alloc is
+a simple indicator of page allocator activity. Pages may be allocated from
+the per-CPU allocator (high performance) or the buddy allocator.
+
+If pages are allocated directly from the buddy allocator, the
+mm_page_alloc_zone_locked event is triggered. This event is important as high
+amounts of activity imply high activity on the zone->lock. Taking this lock
+impairs performance by disabling interrupts, dirtying cache lines between
+CPUs and serialising many CPUs.
+
+When a page is freed directly by the caller, the only mm_page_free event
+is triggered. Significant amounts of activity here could indicate that the
+callers should be batching their activities.
+
+When pages are freed in batch, the also mm_page_free_batched is triggered.
+Broadly speaking, pages are taken off the LRU lock in bulk and
+freed in batch with a page list. Significant amounts of activity here could
+indicate that the system is under memory pressure and can also indicate
+contention on the lruvec->lru_lock.
+
+4. Per-CPU Allocator Activity
+=============================
+::
+
+ mm_page_alloc_zone_locked page=%p pfn=%lu order=%u migratetype=%d cpu=%d percpu_refill=%d
+ mm_page_pcpu_drain page=%p pfn=%lu order=%d cpu=%d migratetype=%d
+
+In front of the page allocator is a per-cpu page allocator. It exists only
+for order-0 pages, reduces contention on the zone->lock and reduces the
+amount of writing on struct page.
+
+When a per-CPU list is empty or pages of the wrong type are allocated,
+the zone->lock will be taken once and the per-CPU list refilled. The event
+triggered is mm_page_alloc_zone_locked for each page allocated with the
+event indicating whether it is for a percpu_refill or not.
+
+When the per-CPU list is too full, a number of pages are freed, each one
+which triggers a mm_page_pcpu_drain event.
+
+The individual nature of the events is so that pages can be tracked
+between allocation and freeing. A number of drain or refill pages that occur
+consecutively imply the zone->lock being taken once. Large amounts of per-CPU
+refills and drains could imply an imbalance between CPUs where too much work
+is being concentrated in one place. It could also indicate that the per-CPU
+lists should be a larger size. Finally, large amounts of refills on one CPU
+and drains on another could be a factor in causing large amounts of cache
+line bounces due to writes between CPUs and worth investigating if pages
+can be allocated and freed on the same CPU through some algorithm change.
+
+5. External Fragmentation
+=========================
+::
+
+ mm_page_alloc_extfrag page=%p pfn=%lu alloc_order=%d fallback_order=%d pageblock_order=%d alloc_migratetype=%d fallback_migratetype=%d fragmenting=%d change_ownership=%d
+
+External fragmentation affects whether a high-order allocation will be
+successful or not. For some types of hardware, this is important although
+it is avoided where possible. If the system is using huge pages and needs
+to be able to resize the pool over the lifetime of the system, this value
+is important.
+
+Large numbers of this event implies that memory is fragmenting and
+high-order allocations will start failing at some time in the future. One
+means of reducing the occurrence of this event is to increase the size of
+min_free_kbytes in increments of 3*pageblock_size*nr_online_nodes where
+pageblock_size is usually the size of the default hugepage size.
diff --git a/Documentation/trace/events-msr.rst b/Documentation/trace/events-msr.rst
new file mode 100644
index 000000000..810481e53
--- /dev/null
+++ b/Documentation/trace/events-msr.rst
@@ -0,0 +1,40 @@
+================
+MSR Trace Events
+================
+
+The x86 kernel supports tracing most MSR (Model Specific Register) accesses.
+To see the definition of the MSRs on Intel systems please see the SDM
+at https://www.intel.com/sdm (Volume 3)
+
+Available trace points:
+
+/sys/kernel/debug/tracing/events/msr/
+
+Trace MSR reads:
+
+read_msr
+
+ - msr: MSR number
+ - val: Value written
+ - failed: 1 if the access failed, otherwise 0
+
+
+Trace MSR writes:
+
+write_msr
+
+ - msr: MSR number
+ - val: Value written
+ - failed: 1 if the access failed, otherwise 0
+
+
+Trace RDPMC in kernel:
+
+rdpmc
+
+The trace data can be post processed with the postprocess/decode_msr.py script::
+
+ cat /sys/kernel/debug/tracing/trace | decode_msr.py /usr/src/linux/include/asm/msr-index.h
+
+to add symbolic MSR names.
+
diff --git a/Documentation/trace/events-nmi.rst b/Documentation/trace/events-nmi.rst
new file mode 100644
index 000000000..9e0a7289d
--- /dev/null
+++ b/Documentation/trace/events-nmi.rst
@@ -0,0 +1,45 @@
+================
+NMI Trace Events
+================
+
+These events normally show up here:
+
+ /sys/kernel/debug/tracing/events/nmi
+
+
+nmi_handler
+-----------
+
+You might want to use this tracepoint if you suspect that your
+NMI handlers are hogging large amounts of CPU time. The kernel
+will warn if it sees long-running handlers::
+
+ INFO: NMI handler took too long to run: 9.207 msecs
+
+and this tracepoint will allow you to drill down and get some
+more details.
+
+Let's say you suspect that perf_event_nmi_handler() is causing
+you some problems and you only want to trace that handler
+specifically. You need to find its address::
+
+ $ grep perf_event_nmi_handler /proc/kallsyms
+ ffffffff81625600 t perf_event_nmi_handler
+
+Let's also say you are only interested in when that function is
+really hogging a lot of CPU time, like a millisecond at a time.
+Note that the kernel's output is in milliseconds, but the input
+to the filter is in nanoseconds! You can filter on 'delta_ns'::
+
+ cd /sys/kernel/debug/tracing/events/nmi/nmi_handler
+ echo 'handler==0xffffffff81625600 && delta_ns>1000000' > filter
+ echo 1 > enable
+
+Your output would then look like::
+
+ $ cat /sys/kernel/debug/tracing/trace_pipe
+ <idle>-0 [000] d.h3 505.397558: nmi_handler: perf_event_nmi_handler() delta_ns: 3236765 handled: 1
+ <idle>-0 [000] d.h3 505.805893: nmi_handler: perf_event_nmi_handler() delta_ns: 3174234 handled: 1
+ <idle>-0 [000] d.h3 506.158206: nmi_handler: perf_event_nmi_handler() delta_ns: 3084642 handled: 1
+ <idle>-0 [000] d.h3 506.334346: nmi_handler: perf_event_nmi_handler() delta_ns: 3080351 handled: 1
+
diff --git a/Documentation/trace/events-power.rst b/Documentation/trace/events-power.rst
new file mode 100644
index 000000000..f45bf11fa
--- /dev/null
+++ b/Documentation/trace/events-power.rst
@@ -0,0 +1,104 @@
+=============================
+Subsystem Trace Points: power
+=============================
+
+The power tracing system captures events related to power transitions
+within the kernel. Broadly speaking there are three major subheadings:
+
+ - Power state switch which reports events related to suspend (S-states),
+ cpuidle (C-states) and cpufreq (P-states)
+ - System clock related changes
+ - Power domains related changes and transitions
+
+This document describes what each of the tracepoints is and why they
+might be useful.
+
+Cf. include/trace/events/power.h for the events definitions.
+
+1. Power state switch events
+============================
+
+1.1 Trace API
+-----------------
+
+A 'cpu' event class gathers the CPU-related events: cpuidle and
+cpufreq.
+::
+
+ cpu_idle "state=%lu cpu_id=%lu"
+ cpu_frequency "state=%lu cpu_id=%lu"
+ cpu_frequency_limits "min=%lu max=%lu cpu_id=%lu"
+
+A suspend event is used to indicate the system going in and out of the
+suspend mode:
+::
+
+ machine_suspend "state=%lu"
+
+
+Note: the value of '-1' or '4294967295' for state means an exit from the current state,
+i.e. trace_cpu_idle(4, smp_processor_id()) means that the system
+enters the idle state 4, while trace_cpu_idle(PWR_EVENT_EXIT, smp_processor_id())
+means that the system exits the previous idle state.
+
+The event which has 'state=4294967295' in the trace is very important to the user
+space tools which are using it to detect the end of the current state, and so to
+correctly draw the states diagrams and to calculate accurate statistics etc.
+
+2. Clocks events
+================
+The clock events are used for clock enable/disable and for
+clock rate change.
+::
+
+ clock_enable "%s state=%lu cpu_id=%lu"
+ clock_disable "%s state=%lu cpu_id=%lu"
+ clock_set_rate "%s state=%lu cpu_id=%lu"
+
+The first parameter gives the clock name (e.g. "gpio1_iclk").
+The second parameter is '1' for enable, '0' for disable, the target
+clock rate for set_rate.
+
+3. Power domains events
+=======================
+The power domain events are used for power domains transitions
+::
+
+ power_domain_target "%s state=%lu cpu_id=%lu"
+
+The first parameter gives the power domain name (e.g. "mpu_pwrdm").
+The second parameter is the power domain target state.
+
+4. PM QoS events
+================
+The PM QoS events are used for QoS add/update/remove request and for
+target/flags update.
+::
+
+ pm_qos_update_target "action=%s prev_value=%d curr_value=%d"
+ pm_qos_update_flags "action=%s prev_value=0x%x curr_value=0x%x"
+
+The first parameter gives the QoS action name (e.g. "ADD_REQ").
+The second parameter is the previous QoS value.
+The third parameter is the current QoS value to update.
+
+There are also events used for device PM QoS add/update/remove request.
+::
+
+ dev_pm_qos_add_request "device=%s type=%s new_value=%d"
+ dev_pm_qos_update_request "device=%s type=%s new_value=%d"
+ dev_pm_qos_remove_request "device=%s type=%s new_value=%d"
+
+The first parameter gives the device name which tries to add/update/remove
+QoS requests.
+The second parameter gives the request type (e.g. "DEV_PM_QOS_RESUME_LATENCY").
+The third parameter is value to be added/updated/removed.
+
+And, there are events used for CPU latency QoS add/update/remove request.
+::
+
+ pm_qos_add_request "value=%d"
+ pm_qos_update_request "value=%d"
+ pm_qos_remove_request "value=%d"
+
+The parameter is the value to be added/updated/removed.
diff --git a/Documentation/trace/events.rst b/Documentation/trace/events.rst
new file mode 100644
index 000000000..c47f381d0
--- /dev/null
+++ b/Documentation/trace/events.rst
@@ -0,0 +1,1073 @@
+=============
+Event Tracing
+=============
+
+:Author: Theodore Ts'o
+:Updated: Li Zefan and Tom Zanussi
+
+1. Introduction
+===============
+
+Tracepoints (see Documentation/trace/tracepoints.rst) can be used
+without creating custom kernel modules to register probe functions
+using the event tracing infrastructure.
+
+Not all tracepoints can be traced using the event tracing system;
+the kernel developer must provide code snippets which define how the
+tracing information is saved into the tracing buffer, and how the
+tracing information should be printed.
+
+2. Using Event Tracing
+======================
+
+2.1 Via the 'set_event' interface
+---------------------------------
+
+The events which are available for tracing can be found in the file
+/sys/kernel/debug/tracing/available_events.
+
+To enable a particular event, such as 'sched_wakeup', simply echo it
+to /sys/kernel/debug/tracing/set_event. For example::
+
+ # echo sched_wakeup >> /sys/kernel/debug/tracing/set_event
+
+.. Note:: '>>' is necessary, otherwise it will firstly disable all the events.
+
+To disable an event, echo the event name to the set_event file prefixed
+with an exclamation point::
+
+ # echo '!sched_wakeup' >> /sys/kernel/debug/tracing/set_event
+
+To disable all events, echo an empty line to the set_event file::
+
+ # echo > /sys/kernel/debug/tracing/set_event
+
+To enable all events, echo ``*:*`` or ``*:`` to the set_event file::
+
+ # echo *:* > /sys/kernel/debug/tracing/set_event
+
+The events are organized into subsystems, such as ext4, irq, sched,
+etc., and a full event name looks like this: <subsystem>:<event>. The
+subsystem name is optional, but it is displayed in the available_events
+file. All of the events in a subsystem can be specified via the syntax
+``<subsystem>:*``; for example, to enable all irq events, you can use the
+command::
+
+ # echo 'irq:*' > /sys/kernel/debug/tracing/set_event
+
+2.2 Via the 'enable' toggle
+---------------------------
+
+The events available are also listed in /sys/kernel/debug/tracing/events/ hierarchy
+of directories.
+
+To enable event 'sched_wakeup'::
+
+ # echo 1 > /sys/kernel/debug/tracing/events/sched/sched_wakeup/enable
+
+To disable it::
+
+ # echo 0 > /sys/kernel/debug/tracing/events/sched/sched_wakeup/enable
+
+To enable all events in sched subsystem::
+
+ # echo 1 > /sys/kernel/debug/tracing/events/sched/enable
+
+To enable all events::
+
+ # echo 1 > /sys/kernel/debug/tracing/events/enable
+
+When reading one of these enable files, there are four results:
+
+ - 0 - all events this file affects are disabled
+ - 1 - all events this file affects are enabled
+ - X - there is a mixture of events enabled and disabled
+ - ? - this file does not affect any event
+
+2.3 Boot option
+---------------
+
+In order to facilitate early boot debugging, use boot option::
+
+ trace_event=[event-list]
+
+event-list is a comma separated list of events. See section 2.1 for event
+format.
+
+3. Defining an event-enabled tracepoint
+=======================================
+
+See The example provided in samples/trace_events
+
+4. Event formats
+================
+
+Each trace event has a 'format' file associated with it that contains
+a description of each field in a logged event. This information can
+be used to parse the binary trace stream, and is also the place to
+find the field names that can be used in event filters (see section 5).
+
+It also displays the format string that will be used to print the
+event in text mode, along with the event name and ID used for
+profiling.
+
+Every event has a set of ``common`` fields associated with it; these are
+the fields prefixed with ``common_``. The other fields vary between
+events and correspond to the fields defined in the TRACE_EVENT
+definition for that event.
+
+Each field in the format has the form::
+
+ field:field-type field-name; offset:N; size:N;
+
+where offset is the offset of the field in the trace record and size
+is the size of the data item, in bytes.
+
+For example, here's the information displayed for the 'sched_wakeup'
+event::
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_wakeup/format
+
+ name: sched_wakeup
+ ID: 60
+ format:
+ field:unsigned short common_type; offset:0; size:2;
+ field:unsigned char common_flags; offset:2; size:1;
+ field:unsigned char common_preempt_count; offset:3; size:1;
+ field:int common_pid; offset:4; size:4;
+ field:int common_tgid; offset:8; size:4;
+
+ field:char comm[TASK_COMM_LEN]; offset:12; size:16;
+ field:pid_t pid; offset:28; size:4;
+ field:int prio; offset:32; size:4;
+ field:int success; offset:36; size:4;
+ field:int cpu; offset:40; size:4;
+
+ print fmt: "task %s:%d [%d] success=%d [%03d]", REC->comm, REC->pid,
+ REC->prio, REC->success, REC->cpu
+
+This event contains 10 fields, the first 5 common and the remaining 5
+event-specific. All the fields for this event are numeric, except for
+'comm' which is a string, a distinction important for event filtering.
+
+5. Event filtering
+==================
+
+Trace events can be filtered in the kernel by associating boolean
+'filter expressions' with them. As soon as an event is logged into
+the trace buffer, its fields are checked against the filter expression
+associated with that event type. An event with field values that
+'match' the filter will appear in the trace output, and an event whose
+values don't match will be discarded. An event with no filter
+associated with it matches everything, and is the default when no
+filter has been set for an event.
+
+5.1 Expression syntax
+---------------------
+
+A filter expression consists of one or more 'predicates' that can be
+combined using the logical operators '&&' and '||'. A predicate is
+simply a clause that compares the value of a field contained within a
+logged event with a constant value and returns either 0 or 1 depending
+on whether the field value matched (1) or didn't match (0)::
+
+ field-name relational-operator value
+
+Parentheses can be used to provide arbitrary logical groupings and
+double-quotes can be used to prevent the shell from interpreting
+operators as shell metacharacters.
+
+The field-names available for use in filters can be found in the
+'format' files for trace events (see section 4).
+
+The relational-operators depend on the type of the field being tested:
+
+The operators available for numeric fields are:
+
+==, !=, <, <=, >, >=, &
+
+And for string fields they are:
+
+==, !=, ~
+
+The glob (~) accepts a wild card character (\*,?) and character classes
+([). For example::
+
+ prev_comm ~ "*sh"
+ prev_comm ~ "sh*"
+ prev_comm ~ "*sh*"
+ prev_comm ~ "ba*sh"
+
+If the field is a pointer that points into user space (for example
+"filename" from sys_enter_openat), then you have to append ".ustring" to the
+field name::
+
+ filename.ustring ~ "password"
+
+As the kernel will have to know how to retrieve the memory that the pointer
+is at from user space.
+
+5.2 Setting filters
+-------------------
+
+A filter for an individual event is set by writing a filter expression
+to the 'filter' file for the given event.
+
+For example::
+
+ # cd /sys/kernel/debug/tracing/events/sched/sched_wakeup
+ # echo "common_preempt_count > 4" > filter
+
+A slightly more involved example::
+
+ # cd /sys/kernel/debug/tracing/events/signal/signal_generate
+ # echo "((sig >= 10 && sig < 15) || sig == 17) && comm != bash" > filter
+
+If there is an error in the expression, you'll get an 'Invalid
+argument' error when setting it, and the erroneous string along with
+an error message can be seen by looking at the filter e.g.::
+
+ # cd /sys/kernel/debug/tracing/events/signal/signal_generate
+ # echo "((sig >= 10 && sig < 15) || dsig == 17) && comm != bash" > filter
+ -bash: echo: write error: Invalid argument
+ # cat filter
+ ((sig >= 10 && sig < 15) || dsig == 17) && comm != bash
+ ^
+ parse_error: Field not found
+
+Currently the caret ('^') for an error always appears at the beginning of
+the filter string; the error message should still be useful though
+even without more accurate position info.
+
+5.2.1 Filter limitations
+------------------------
+
+If a filter is placed on a string pointer ``(char *)`` that does not point
+to a string on the ring buffer, but instead points to kernel or user space
+memory, then, for safety reasons, at most 1024 bytes of the content is
+copied onto a temporary buffer to do the compare. If the copy of the memory
+faults (the pointer points to memory that should not be accessed), then the
+string compare will be treated as not matching.
+
+5.3 Clearing filters
+--------------------
+
+To clear the filter for an event, write a '0' to the event's filter
+file.
+
+To clear the filters for all events in a subsystem, write a '0' to the
+subsystem's filter file.
+
+5.3 Subsystem filters
+---------------------
+
+For convenience, filters for every event in a subsystem can be set or
+cleared as a group by writing a filter expression into the filter file
+at the root of the subsystem. Note however, that if a filter for any
+event within the subsystem lacks a field specified in the subsystem
+filter, or if the filter can't be applied for any other reason, the
+filter for that event will retain its previous setting. This can
+result in an unintended mixture of filters which could lead to
+confusing (to the user who might think different filters are in
+effect) trace output. Only filters that reference just the common
+fields can be guaranteed to propagate successfully to all events.
+
+Here are a few subsystem filter examples that also illustrate the
+above points:
+
+Clear the filters on all events in the sched subsystem::
+
+ # cd /sys/kernel/debug/tracing/events/sched
+ # echo 0 > filter
+ # cat sched_switch/filter
+ none
+ # cat sched_wakeup/filter
+ none
+
+Set a filter using only common fields for all events in the sched
+subsystem (all events end up with the same filter)::
+
+ # cd /sys/kernel/debug/tracing/events/sched
+ # echo common_pid == 0 > filter
+ # cat sched_switch/filter
+ common_pid == 0
+ # cat sched_wakeup/filter
+ common_pid == 0
+
+Attempt to set a filter using a non-common field for all events in the
+sched subsystem (all events but those that have a prev_pid field retain
+their old filters)::
+
+ # cd /sys/kernel/debug/tracing/events/sched
+ # echo prev_pid == 0 > filter
+ # cat sched_switch/filter
+ prev_pid == 0
+ # cat sched_wakeup/filter
+ common_pid == 0
+
+5.4 PID filtering
+-----------------
+
+The set_event_pid file in the same directory as the top events directory
+exists, will filter all events from tracing any task that does not have the
+PID listed in the set_event_pid file.
+::
+
+ # cd /sys/kernel/debug/tracing
+ # echo $$ > set_event_pid
+ # echo 1 > events/enable
+
+Will only trace events for the current task.
+
+To add more PIDs without losing the PIDs already included, use '>>'.
+::
+
+ # echo 123 244 1 >> set_event_pid
+
+
+6. Event triggers
+=================
+
+Trace events can be made to conditionally invoke trigger 'commands'
+which can take various forms and are described in detail below;
+examples would be enabling or disabling other trace events or invoking
+a stack trace whenever the trace event is hit. Whenever a trace event
+with attached triggers is invoked, the set of trigger commands
+associated with that event is invoked. Any given trigger can
+additionally have an event filter of the same form as described in
+section 5 (Event filtering) associated with it - the command will only
+be invoked if the event being invoked passes the associated filter.
+If no filter is associated with the trigger, it always passes.
+
+Triggers are added to and removed from a particular event by writing
+trigger expressions to the 'trigger' file for the given event.
+
+A given event can have any number of triggers associated with it,
+subject to any restrictions that individual commands may have in that
+regard.
+
+Event triggers are implemented on top of "soft" mode, which means that
+whenever a trace event has one or more triggers associated with it,
+the event is activated even if it isn't actually enabled, but is
+disabled in a "soft" mode. That is, the tracepoint will be called,
+but just will not be traced, unless of course it's actually enabled.
+This scheme allows triggers to be invoked even for events that aren't
+enabled, and also allows the current event filter implementation to be
+used for conditionally invoking triggers.
+
+The syntax for event triggers is roughly based on the syntax for
+set_ftrace_filter 'ftrace filter commands' (see the 'Filter commands'
+section of Documentation/trace/ftrace.rst), but there are major
+differences and the implementation isn't currently tied to it in any
+way, so beware about making generalizations between the two.
+
+.. Note::
+ Writing into trace_marker (See Documentation/trace/ftrace.rst)
+ can also enable triggers that are written into
+ /sys/kernel/tracing/events/ftrace/print/trigger
+
+6.1 Expression syntax
+---------------------
+
+Triggers are added by echoing the command to the 'trigger' file::
+
+ # echo 'command[:count] [if filter]' > trigger
+
+Triggers are removed by echoing the same command but starting with '!'
+to the 'trigger' file::
+
+ # echo '!command[:count] [if filter]' > trigger
+
+The [if filter] part isn't used in matching commands when removing, so
+leaving that off in a '!' command will accomplish the same thing as
+having it in.
+
+The filter syntax is the same as that described in the 'Event
+filtering' section above.
+
+For ease of use, writing to the trigger file using '>' currently just
+adds or removes a single trigger and there's no explicit '>>' support
+('>' actually behaves like '>>') or truncation support to remove all
+triggers (you have to use '!' for each one added.)
+
+6.2 Supported trigger commands
+------------------------------
+
+The following commands are supported:
+
+- enable_event/disable_event
+
+ These commands can enable or disable another trace event whenever
+ the triggering event is hit. When these commands are registered,
+ the other trace event is activated, but disabled in a "soft" mode.
+ That is, the tracepoint will be called, but just will not be traced.
+ The event tracepoint stays in this mode as long as there's a trigger
+ in effect that can trigger it.
+
+ For example, the following trigger causes kmalloc events to be
+ traced when a read system call is entered, and the :1 at the end
+ specifies that this enablement happens only once::
+
+ # echo 'enable_event:kmem:kmalloc:1' > \
+ /sys/kernel/debug/tracing/events/syscalls/sys_enter_read/trigger
+
+ The following trigger causes kmalloc events to stop being traced
+ when a read system call exits. This disablement happens on every
+ read system call exit::
+
+ # echo 'disable_event:kmem:kmalloc' > \
+ /sys/kernel/debug/tracing/events/syscalls/sys_exit_read/trigger
+
+ The format is::
+
+ enable_event:<system>:<event>[:count]
+ disable_event:<system>:<event>[:count]
+
+ To remove the above commands::
+
+ # echo '!enable_event:kmem:kmalloc:1' > \
+ /sys/kernel/debug/tracing/events/syscalls/sys_enter_read/trigger
+
+ # echo '!disable_event:kmem:kmalloc' > \
+ /sys/kernel/debug/tracing/events/syscalls/sys_exit_read/trigger
+
+ Note that there can be any number of enable/disable_event triggers
+ per triggering event, but there can only be one trigger per
+ triggered event. e.g. sys_enter_read can have triggers enabling both
+ kmem:kmalloc and sched:sched_switch, but can't have two kmem:kmalloc
+ versions such as kmem:kmalloc and kmem:kmalloc:1 or 'kmem:kmalloc if
+ bytes_req == 256' and 'kmem:kmalloc if bytes_alloc == 256' (they
+ could be combined into a single filter on kmem:kmalloc though).
+
+- stacktrace
+
+ This command dumps a stacktrace in the trace buffer whenever the
+ triggering event occurs.
+
+ For example, the following trigger dumps a stacktrace every time the
+ kmalloc tracepoint is hit::
+
+ # echo 'stacktrace' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ The following trigger dumps a stacktrace the first 5 times a kmalloc
+ request happens with a size >= 64K::
+
+ # echo 'stacktrace:5 if bytes_req >= 65536' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ The format is::
+
+ stacktrace[:count]
+
+ To remove the above commands::
+
+ # echo '!stacktrace' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ # echo '!stacktrace:5 if bytes_req >= 65536' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ The latter can also be removed more simply by the following (without
+ the filter)::
+
+ # echo '!stacktrace:5' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ Note that there can be only one stacktrace trigger per triggering
+ event.
+
+- snapshot
+
+ This command causes a snapshot to be triggered whenever the
+ triggering event occurs.
+
+ The following command creates a snapshot every time a block request
+ queue is unplugged with a depth > 1. If you were tracing a set of
+ events or functions at the time, the snapshot trace buffer would
+ capture those events when the trigger event occurred::
+
+ # echo 'snapshot if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ To only snapshot once::
+
+ # echo 'snapshot:1 if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ To remove the above commands::
+
+ # echo '!snapshot if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ # echo '!snapshot:1 if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ Note that there can be only one snapshot trigger per triggering
+ event.
+
+- traceon/traceoff
+
+ These commands turn tracing on and off when the specified events are
+ hit. The parameter determines how many times the tracing system is
+ turned on and off. If unspecified, there is no limit.
+
+ The following command turns tracing off the first time a block
+ request queue is unplugged with a depth > 1. If you were tracing a
+ set of events or functions at the time, you could then examine the
+ trace buffer to see the sequence of events that led up to the
+ trigger event::
+
+ # echo 'traceoff:1 if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ To always disable tracing when nr_rq > 1::
+
+ # echo 'traceoff if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ To remove the above commands::
+
+ # echo '!traceoff:1 if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ # echo '!traceoff if nr_rq > 1' > \
+ /sys/kernel/debug/tracing/events/block/block_unplug/trigger
+
+ Note that there can be only one traceon or traceoff trigger per
+ triggering event.
+
+- hist
+
+ This command aggregates event hits into a hash table keyed on one or
+ more trace event format fields (or stacktrace) and a set of running
+ totals derived from one or more trace event format fields and/or
+ event counts (hitcount).
+
+ See Documentation/trace/histogram.rst for details and examples.
+
+7. In-kernel trace event API
+============================
+
+In most cases, the command-line interface to trace events is more than
+sufficient. Sometimes, however, applications might find the need for
+more complex relationships than can be expressed through a simple
+series of linked command-line expressions, or putting together sets of
+commands may be simply too cumbersome. An example might be an
+application that needs to 'listen' to the trace stream in order to
+maintain an in-kernel state machine detecting, for instance, when an
+illegal kernel state occurs in the scheduler.
+
+The trace event subsystem provides an in-kernel API allowing modules
+or other kernel code to generate user-defined 'synthetic' events at
+will, which can be used to either augment the existing trace stream
+and/or signal that a particular important state has occurred.
+
+A similar in-kernel API is also available for creating kprobe and
+kretprobe events.
+
+Both the synthetic event and k/ret/probe event APIs are built on top
+of a lower-level "dynevent_cmd" event command API, which is also
+available for more specialized applications, or as the basis of other
+higher-level trace event APIs.
+
+The API provided for these purposes is describe below and allows the
+following:
+
+ - dynamically creating synthetic event definitions
+ - dynamically creating kprobe and kretprobe event definitions
+ - tracing synthetic events from in-kernel code
+ - the low-level "dynevent_cmd" API
+
+7.1 Dyamically creating synthetic event definitions
+---------------------------------------------------
+
+There are a couple ways to create a new synthetic event from a kernel
+module or other kernel code.
+
+The first creates the event in one step, using synth_event_create().
+In this method, the name of the event to create and an array defining
+the fields is supplied to synth_event_create(). If successful, a
+synthetic event with that name and fields will exist following that
+call. For example, to create a new "schedtest" synthetic event::
+
+ ret = synth_event_create("schedtest", sched_fields,
+ ARRAY_SIZE(sched_fields), THIS_MODULE);
+
+The sched_fields param in this example points to an array of struct
+synth_field_desc, each of which describes an event field by type and
+name::
+
+ static struct synth_field_desc sched_fields[] = {
+ { .type = "pid_t", .name = "next_pid_field" },
+ { .type = "char[16]", .name = "next_comm_field" },
+ { .type = "u64", .name = "ts_ns" },
+ { .type = "u64", .name = "ts_ms" },
+ { .type = "unsigned int", .name = "cpu" },
+ { .type = "char[64]", .name = "my_string_field" },
+ { .type = "int", .name = "my_int_field" },
+ };
+
+See synth_field_size() for available types.
+
+If field_name contains [n], the field is considered to be a static array.
+
+If field_names contains[] (no subscript), the field is considered to
+be a dynamic array, which will only take as much space in the event as
+is required to hold the array.
+
+Because space for an event is reserved before assigning field values
+to the event, using dynamic arrays implies that the piecewise
+in-kernel API described below can't be used with dynamic arrays. The
+other non-piecewise in-kernel APIs can, however, be used with dynamic
+arrays.
+
+If the event is created from within a module, a pointer to the module
+must be passed to synth_event_create(). This will ensure that the
+trace buffer won't contain unreadable events when the module is
+removed.
+
+At this point, the event object is ready to be used for generating new
+events.
+
+In the second method, the event is created in several steps. This
+allows events to be created dynamically and without the need to create
+and populate an array of fields beforehand.
+
+To use this method, an empty or partially empty synthetic event should
+first be created using synth_event_gen_cmd_start() or
+synth_event_gen_cmd_array_start(). For synth_event_gen_cmd_start(),
+the name of the event along with one or more pairs of args each pair
+representing a 'type field_name;' field specification should be
+supplied. For synth_event_gen_cmd_array_start(), the name of the
+event along with an array of struct synth_field_desc should be
+supplied. Before calling synth_event_gen_cmd_start() or
+synth_event_gen_cmd_array_start(), the user should create and
+initialize a dynevent_cmd object using synth_event_cmd_init().
+
+For example, to create a new "schedtest" synthetic event with two
+fields::
+
+ struct dynevent_cmd cmd;
+ char *buf;
+
+ /* Create a buffer to hold the generated command */
+ buf = kzalloc(MAX_DYNEVENT_CMD_LEN, GFP_KERNEL);
+
+ /* Before generating the command, initialize the cmd object */
+ synth_event_cmd_init(&cmd, buf, MAX_DYNEVENT_CMD_LEN);
+
+ ret = synth_event_gen_cmd_start(&cmd, "schedtest", THIS_MODULE,
+ "pid_t", "next_pid_field",
+ "u64", "ts_ns");
+
+Alternatively, using an array of struct synth_field_desc fields
+containing the same information::
+
+ ret = synth_event_gen_cmd_array_start(&cmd, "schedtest", THIS_MODULE,
+ fields, n_fields);
+
+Once the synthetic event object has been created, it can then be
+populated with more fields. Fields are added one by one using
+synth_event_add_field(), supplying the dynevent_cmd object, a field
+type, and a field name. For example, to add a new int field named
+"intfield", the following call should be made::
+
+ ret = synth_event_add_field(&cmd, "int", "intfield");
+
+See synth_field_size() for available types. If field_name contains [n]
+the field is considered to be an array.
+
+A group of fields can also be added all at once using an array of
+synth_field_desc with add_synth_fields(). For example, this would add
+just the first four sched_fields::
+
+ ret = synth_event_add_fields(&cmd, sched_fields, 4);
+
+If you already have a string of the form 'type field_name',
+synth_event_add_field_str() can be used to add it as-is; it will
+also automatically append a ';' to the string.
+
+Once all the fields have been added, the event should be finalized and
+registered by calling the synth_event_gen_cmd_end() function::
+
+ ret = synth_event_gen_cmd_end(&cmd);
+
+At this point, the event object is ready to be used for tracing new
+events.
+
+7.2 Tracing synthetic events from in-kernel code
+------------------------------------------------
+
+To trace a synthetic event, there are several options. The first
+option is to trace the event in one call, using synth_event_trace()
+with a variable number of values, or synth_event_trace_array() with an
+array of values to be set. A second option can be used to avoid the
+need for a pre-formed array of values or list of arguments, via
+synth_event_trace_start() and synth_event_trace_end() along with
+synth_event_add_next_val() or synth_event_add_val() to add the values
+piecewise.
+
+7.2.1 Tracing a synthetic event all at once
+-------------------------------------------
+
+To trace a synthetic event all at once, the synth_event_trace() or
+synth_event_trace_array() functions can be used.
+
+The synth_event_trace() function is passed the trace_event_file
+representing the synthetic event (which can be retrieved using
+trace_get_event_file() using the synthetic event name, "synthetic" as
+the system name, and the trace instance name (NULL if using the global
+trace array)), along with an variable number of u64 args, one for each
+synthetic event field, and the number of values being passed.
+
+So, to trace an event corresponding to the synthetic event definition
+above, code like the following could be used::
+
+ ret = synth_event_trace(create_synth_test, 7, /* number of values */
+ 444, /* next_pid_field */
+ (u64)"clackers", /* next_comm_field */
+ 1000000, /* ts_ns */
+ 1000, /* ts_ms */
+ smp_processor_id(),/* cpu */
+ (u64)"Thneed", /* my_string_field */
+ 999); /* my_int_field */
+
+All vals should be cast to u64, and string vals are just pointers to
+strings, cast to u64. Strings will be copied into space reserved in
+the event for the string, using these pointers.
+
+Alternatively, the synth_event_trace_array() function can be used to
+accomplish the same thing. It is passed the trace_event_file
+representing the synthetic event (which can be retrieved using
+trace_get_event_file() using the synthetic event name, "synthetic" as
+the system name, and the trace instance name (NULL if using the global
+trace array)), along with an array of u64, one for each synthetic
+event field.
+
+To trace an event corresponding to the synthetic event definition
+above, code like the following could be used::
+
+ u64 vals[7];
+
+ vals[0] = 777; /* next_pid_field */
+ vals[1] = (u64)"tiddlywinks"; /* next_comm_field */
+ vals[2] = 1000000; /* ts_ns */
+ vals[3] = 1000; /* ts_ms */
+ vals[4] = smp_processor_id(); /* cpu */
+ vals[5] = (u64)"thneed"; /* my_string_field */
+ vals[6] = 398; /* my_int_field */
+
+The 'vals' array is just an array of u64, the number of which must
+match the number of field in the synthetic event, and which must be in
+the same order as the synthetic event fields.
+
+All vals should be cast to u64, and string vals are just pointers to
+strings, cast to u64. Strings will be copied into space reserved in
+the event for the string, using these pointers.
+
+In order to trace a synthetic event, a pointer to the trace event file
+is needed. The trace_get_event_file() function can be used to get
+it - it will find the file in the given trace instance (in this case
+NULL since the top trace array is being used) while at the same time
+preventing the instance containing it from going away::
+
+ schedtest_event_file = trace_get_event_file(NULL, "synthetic",
+ "schedtest");
+
+Before tracing the event, it should be enabled in some way, otherwise
+the synthetic event won't actually show up in the trace buffer.
+
+To enable a synthetic event from the kernel, trace_array_set_clr_event()
+can be used (which is not specific to synthetic events, so does need
+the "synthetic" system name to be specified explicitly).
+
+To enable the event, pass 'true' to it::
+
+ trace_array_set_clr_event(schedtest_event_file->tr,
+ "synthetic", "schedtest", true);
+
+To disable it pass false::
+
+ trace_array_set_clr_event(schedtest_event_file->tr,
+ "synthetic", "schedtest", false);
+
+Finally, synth_event_trace_array() can be used to actually trace the
+event, which should be visible in the trace buffer afterwards::
+
+ ret = synth_event_trace_array(schedtest_event_file, vals,
+ ARRAY_SIZE(vals));
+
+To remove the synthetic event, the event should be disabled, and the
+trace instance should be 'put' back using trace_put_event_file()::
+
+ trace_array_set_clr_event(schedtest_event_file->tr,
+ "synthetic", "schedtest", false);
+ trace_put_event_file(schedtest_event_file);
+
+If those have been successful, synth_event_delete() can be called to
+remove the event::
+
+ ret = synth_event_delete("schedtest");
+
+7.2.2 Tracing a synthetic event piecewise
+-----------------------------------------
+
+To trace a synthetic using the piecewise method described above, the
+synth_event_trace_start() function is used to 'open' the synthetic
+event trace::
+
+ struct synth_event_trace_state trace_state;
+
+ ret = synth_event_trace_start(schedtest_event_file, &trace_state);
+
+It's passed the trace_event_file representing the synthetic event
+using the same methods as described above, along with a pointer to a
+struct synth_event_trace_state object, which will be zeroed before use and
+used to maintain state between this and following calls.
+
+Once the event has been opened, which means space for it has been
+reserved in the trace buffer, the individual fields can be set. There
+are two ways to do that, either one after another for each field in
+the event, which requires no lookups, or by name, which does. The
+tradeoff is flexibility in doing the assignments vs the cost of a
+lookup per field.
+
+To assign the values one after the other without lookups,
+synth_event_add_next_val() should be used. Each call is passed the
+same synth_event_trace_state object used in the synth_event_trace_start(),
+along with the value to set the next field in the event. After each
+field is set, the 'cursor' points to the next field, which will be set
+by the subsequent call, continuing until all the fields have been set
+in order. The same sequence of calls as in the above examples using
+this method would be (without error-handling code)::
+
+ /* next_pid_field */
+ ret = synth_event_add_next_val(777, &trace_state);
+
+ /* next_comm_field */
+ ret = synth_event_add_next_val((u64)"slinky", &trace_state);
+
+ /* ts_ns */
+ ret = synth_event_add_next_val(1000000, &trace_state);
+
+ /* ts_ms */
+ ret = synth_event_add_next_val(1000, &trace_state);
+
+ /* cpu */
+ ret = synth_event_add_next_val(smp_processor_id(), &trace_state);
+
+ /* my_string_field */
+ ret = synth_event_add_next_val((u64)"thneed_2.01", &trace_state);
+
+ /* my_int_field */
+ ret = synth_event_add_next_val(395, &trace_state);
+
+To assign the values in any order, synth_event_add_val() should be
+used. Each call is passed the same synth_event_trace_state object used in
+the synth_event_trace_start(), along with the field name of the field
+to set and the value to set it to. The same sequence of calls as in
+the above examples using this method would be (without error-handling
+code)::
+
+ ret = synth_event_add_val("next_pid_field", 777, &trace_state);
+ ret = synth_event_add_val("next_comm_field", (u64)"silly putty",
+ &trace_state);
+ ret = synth_event_add_val("ts_ns", 1000000, &trace_state);
+ ret = synth_event_add_val("ts_ms", 1000, &trace_state);
+ ret = synth_event_add_val("cpu", smp_processor_id(), &trace_state);
+ ret = synth_event_add_val("my_string_field", (u64)"thneed_9",
+ &trace_state);
+ ret = synth_event_add_val("my_int_field", 3999, &trace_state);
+
+Note that synth_event_add_next_val() and synth_event_add_val() are
+incompatible if used within the same trace of an event - either one
+can be used but not both at the same time.
+
+Finally, the event won't be actually traced until it's 'closed',
+which is done using synth_event_trace_end(), which takes only the
+struct synth_event_trace_state object used in the previous calls::
+
+ ret = synth_event_trace_end(&trace_state);
+
+Note that synth_event_trace_end() must be called at the end regardless
+of whether any of the add calls failed (say due to a bad field name
+being passed in).
+
+7.3 Dyamically creating kprobe and kretprobe event definitions
+--------------------------------------------------------------
+
+To create a kprobe or kretprobe trace event from kernel code, the
+kprobe_event_gen_cmd_start() or kretprobe_event_gen_cmd_start()
+functions can be used.
+
+To create a kprobe event, an empty or partially empty kprobe event
+should first be created using kprobe_event_gen_cmd_start(). The name
+of the event and the probe location should be specfied along with one
+or args each representing a probe field should be supplied to this
+function. Before calling kprobe_event_gen_cmd_start(), the user
+should create and initialize a dynevent_cmd object using
+kprobe_event_cmd_init().
+
+For example, to create a new "schedtest" kprobe event with two fields::
+
+ struct dynevent_cmd cmd;
+ char *buf;
+
+ /* Create a buffer to hold the generated command */
+ buf = kzalloc(MAX_DYNEVENT_CMD_LEN, GFP_KERNEL);
+
+ /* Before generating the command, initialize the cmd object */
+ kprobe_event_cmd_init(&cmd, buf, MAX_DYNEVENT_CMD_LEN);
+
+ /*
+ * Define the gen_kprobe_test event with the first 2 kprobe
+ * fields.
+ */
+ ret = kprobe_event_gen_cmd_start(&cmd, "gen_kprobe_test", "do_sys_open",
+ "dfd=%ax", "filename=%dx");
+
+Once the kprobe event object has been created, it can then be
+populated with more fields. Fields can be added using
+kprobe_event_add_fields(), supplying the dynevent_cmd object along
+with a variable arg list of probe fields. For example, to add a
+couple additional fields, the following call could be made::
+
+ ret = kprobe_event_add_fields(&cmd, "flags=%cx", "mode=+4($stack)");
+
+Once all the fields have been added, the event should be finalized and
+registered by calling the kprobe_event_gen_cmd_end() or
+kretprobe_event_gen_cmd_end() functions, depending on whether a kprobe
+or kretprobe command was started::
+
+ ret = kprobe_event_gen_cmd_end(&cmd);
+
+or::
+
+ ret = kretprobe_event_gen_cmd_end(&cmd);
+
+At this point, the event object is ready to be used for tracing new
+events.
+
+Similarly, a kretprobe event can be created using
+kretprobe_event_gen_cmd_start() with a probe name and location and
+additional params such as $retval::
+
+ ret = kretprobe_event_gen_cmd_start(&cmd, "gen_kretprobe_test",
+ "do_sys_open", "$retval");
+
+Similar to the synthetic event case, code like the following can be
+used to enable the newly created kprobe event::
+
+ gen_kprobe_test = trace_get_event_file(NULL, "kprobes", "gen_kprobe_test");
+
+ ret = trace_array_set_clr_event(gen_kprobe_test->tr,
+ "kprobes", "gen_kprobe_test", true);
+
+Finally, also similar to synthetic events, the following code can be
+used to give the kprobe event file back and delete the event::
+
+ trace_put_event_file(gen_kprobe_test);
+
+ ret = kprobe_event_delete("gen_kprobe_test");
+
+7.4 The "dynevent_cmd" low-level API
+------------------------------------
+
+Both the in-kernel synthetic event and kprobe interfaces are built on
+top of a lower-level "dynevent_cmd" interface. This interface is
+meant to provide the basis for higher-level interfaces such as the
+synthetic and kprobe interfaces, which can be used as examples.
+
+The basic idea is simple and amounts to providing a general-purpose
+layer that can be used to generate trace event commands. The
+generated command strings can then be passed to the command-parsing
+and event creation code that already exists in the trace event
+subystem for creating the corresponding trace events.
+
+In a nutshell, the way it works is that the higher-level interface
+code creates a struct dynevent_cmd object, then uses a couple
+functions, dynevent_arg_add() and dynevent_arg_pair_add() to build up
+a command string, which finally causes the command to be executed
+using the dynevent_create() function. The details of the interface
+are described below.
+
+The first step in building a new command string is to create and
+initialize an instance of a dynevent_cmd. Here, for instance, we
+create a dynevent_cmd on the stack and initialize it::
+
+ struct dynevent_cmd cmd;
+ char *buf;
+ int ret;
+
+ buf = kzalloc(MAX_DYNEVENT_CMD_LEN, GFP_KERNEL);
+
+ dynevent_cmd_init(cmd, buf, maxlen, DYNEVENT_TYPE_FOO,
+ foo_event_run_command);
+
+The dynevent_cmd initialization needs to be given a user-specified
+buffer and the length of the buffer (MAX_DYNEVENT_CMD_LEN can be used
+for this purpose - at 2k it's generally too big to be comfortably put
+on the stack, so is dynamically allocated), a dynevent type id, which
+is meant to be used to check that further API calls are for the
+correct command type, and a pointer to an event-specific run_command()
+callback that will be called to actually execute the event-specific
+command function.
+
+Once that's done, the command string can by built up by successive
+calls to argument-adding functions.
+
+To add a single argument, define and initialize a struct dynevent_arg
+or struct dynevent_arg_pair object. Here's an example of the simplest
+possible arg addition, which is simply to append the given string as
+a whitespace-separated argument to the command::
+
+ struct dynevent_arg arg;
+
+ dynevent_arg_init(&arg, NULL, 0);
+
+ arg.str = name;
+
+ ret = dynevent_arg_add(cmd, &arg);
+
+The arg object is first initialized using dynevent_arg_init() and in
+this case the parameters are NULL or 0, which means there's no
+optional sanity-checking function or separator appended to the end of
+the arg.
+
+Here's another more complicated example using an 'arg pair', which is
+used to create an argument that consists of a couple components added
+together as a unit, for example, a 'type field_name;' arg or a simple
+expression arg e.g. 'flags=%cx'::
+
+ struct dynevent_arg_pair arg_pair;
+
+ dynevent_arg_pair_init(&arg_pair, dynevent_foo_check_arg_fn, 0, ';');
+
+ arg_pair.lhs = type;
+ arg_pair.rhs = name;
+
+ ret = dynevent_arg_pair_add(cmd, &arg_pair);
+
+Again, the arg_pair is first initialized, in this case with a callback
+function used to check the sanity of the args (for example, that
+neither part of the pair is NULL), along with a character to be used
+to add an operator between the pair (here none) and a separator to be
+appended onto the end of the arg pair (here ';').
+
+There's also a dynevent_str_add() function that can be used to simply
+add a string as-is, with no spaces, delimeters, or arg check.
+
+Any number of dynevent_*_add() calls can be made to build up the string
+(until its length surpasses cmd->maxlen). When all the arguments have
+been added and the command string is complete, the only thing left to
+do is run the command, which happens by simply calling
+dynevent_create()::
+
+ ret = dynevent_create(&cmd);
+
+At that point, if the return value is 0, the dynamic event has been
+created and is ready to use.
+
+See the dynevent_cmd function definitions themselves for the details
+of the API.
diff --git a/Documentation/trace/fprobe.rst b/Documentation/trace/fprobe.rst
new file mode 100644
index 000000000..b64bec1ce
--- /dev/null
+++ b/Documentation/trace/fprobe.rst
@@ -0,0 +1,174 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+==================================
+Fprobe - Function entry/exit probe
+==================================
+
+.. Author: Masami Hiramatsu <mhiramat@kernel.org>
+
+Introduction
+============
+
+Fprobe is a function entry/exit probe mechanism based on ftrace.
+Instead of using ftrace full feature, if you only want to attach callbacks
+on function entry and exit, similar to the kprobes and kretprobes, you can
+use fprobe. Compared with kprobes and kretprobes, fprobe gives faster
+instrumentation for multiple functions with single handler. This document
+describes how to use fprobe.
+
+The usage of fprobe
+===================
+
+The fprobe is a wrapper of ftrace (+ kretprobe-like return callback) to
+attach callbacks to multiple function entry and exit. User needs to set up
+the `struct fprobe` and pass it to `register_fprobe()`.
+
+Typically, `fprobe` data structure is initialized with the `entry_handler`
+and/or `exit_handler` as below.
+
+.. code-block:: c
+
+ struct fprobe fp = {
+ .entry_handler = my_entry_callback,
+ .exit_handler = my_exit_callback,
+ };
+
+To enable the fprobe, call one of register_fprobe(), register_fprobe_ips(), and
+register_fprobe_syms(). These functions register the fprobe with different types
+of parameters.
+
+The register_fprobe() enables a fprobe by function-name filters.
+E.g. this enables @fp on "func*()" function except "func2()".::
+
+ register_fprobe(&fp, "func*", "func2");
+
+The register_fprobe_ips() enables a fprobe by ftrace-location addresses.
+E.g.
+
+.. code-block:: c
+
+ unsigned long ips[] = { 0x.... };
+
+ register_fprobe_ips(&fp, ips, ARRAY_SIZE(ips));
+
+And the register_fprobe_syms() enables a fprobe by symbol names.
+E.g.
+
+.. code-block:: c
+
+ char syms[] = {"func1", "func2", "func3"};
+
+ register_fprobe_syms(&fp, syms, ARRAY_SIZE(syms));
+
+To disable (remove from functions) this fprobe, call::
+
+ unregister_fprobe(&fp);
+
+You can temporally (soft) disable the fprobe by::
+
+ disable_fprobe(&fp);
+
+and resume by::
+
+ enable_fprobe(&fp);
+
+The above is defined by including the header::
+
+ #include <linux/fprobe.h>
+
+Same as ftrace, the registered callbacks will start being called some time
+after the register_fprobe() is called and before it returns. See
+:file:`Documentation/trace/ftrace.rst`.
+
+Also, the unregister_fprobe() will guarantee that the both enter and exit
+handlers are no longer being called by functions after unregister_fprobe()
+returns as same as unregister_ftrace_function().
+
+The fprobe entry/exit handler
+=============================
+
+The prototype of the entry/exit callback function is as follows:
+
+.. code-block:: c
+
+ void callback_func(struct fprobe *fp, unsigned long entry_ip, struct pt_regs *regs);
+
+Note that both entry and exit callbacks have same ptototype. The @entry_ip is
+saved at function entry and passed to exit handler.
+
+@fp
+ This is the address of `fprobe` data structure related to this handler.
+ You can embed the `fprobe` to your data structure and get it by
+ container_of() macro from @fp. The @fp must not be NULL.
+
+@entry_ip
+ This is the ftrace address of the traced function (both entry and exit).
+ Note that this may not be the actual entry address of the function but
+ the address where the ftrace is instrumented.
+
+@regs
+ This is the `pt_regs` data structure at the entry and exit. Note that
+ the instruction pointer of @regs may be different from the @entry_ip
+ in the entry_handler. If you need traced instruction pointer, you need
+ to use @entry_ip. On the other hand, in the exit_handler, the instruction
+ pointer of @regs is set to the currect return address.
+
+Share the callbacks with kprobes
+================================
+
+Since the recursion safeness of the fprobe (and ftrace) is a bit different
+from the kprobes, this may cause an issue if user wants to run the same
+code from the fprobe and the kprobes.
+
+Kprobes has per-cpu 'current_kprobe' variable which protects the kprobe
+handler from recursion in all cases. On the other hand, fprobe uses
+only ftrace_test_recursion_trylock(). This allows interrupt context to
+call another (or same) fprobe while the fprobe user handler is running.
+
+This is not a matter if the common callback code has its own recursion
+detection, or it can handle the recursion in the different contexts
+(normal/interrupt/NMI.)
+But if it relies on the 'current_kprobe' recursion lock, it has to check
+kprobe_running() and use kprobe_busy_*() APIs.
+
+Fprobe has FPROBE_FL_KPROBE_SHARED flag to do this. If your common callback
+code will be shared with kprobes, please set FPROBE_FL_KPROBE_SHARED
+*before* registering the fprobe, like:
+
+.. code-block:: c
+
+ fprobe.flags = FPROBE_FL_KPROBE_SHARED;
+
+ register_fprobe(&fprobe, "func*", NULL);
+
+This will protect your common callback from the nested call.
+
+The missed counter
+==================
+
+The `fprobe` data structure has `fprobe::nmissed` counter field as same as
+kprobes.
+This counter counts up when;
+
+ - fprobe fails to take ftrace_recursion lock. This usually means that a function
+ which is traced by other ftrace users is called from the entry_handler.
+
+ - fprobe fails to setup the function exit because of the shortage of rethook
+ (the shadow stack for hooking the function return.)
+
+The `fprobe::nmissed` field counts up in both cases. Therefore, the former
+skips both of entry and exit callback and the latter skips the exit
+callback, but in both case the counter will increase by 1.
+
+Note that if you set the FTRACE_OPS_FL_RECURSION and/or FTRACE_OPS_FL_RCU to
+`fprobe::ops::flags` (ftrace_ops::flags) when registering the fprobe, this
+counter may not work correctly, because ftrace skips the fprobe function which
+increase the counter.
+
+
+Functions and structures
+========================
+
+.. kernel-doc:: include/linux/fprobe.h
+.. kernel-doc:: kernel/trace/fprobe.c
+
diff --git a/Documentation/trace/ftrace-design.rst b/Documentation/trace/ftrace-design.rst
new file mode 100644
index 000000000..689339915
--- /dev/null
+++ b/Documentation/trace/ftrace-design.rst
@@ -0,0 +1,411 @@
+======================
+Function Tracer Design
+======================
+
+:Author: Mike Frysinger
+
+.. caution::
+ This document is out of date. Some of the description below doesn't
+ match current implementation now.
+
+Introduction
+------------
+
+Here we will cover the architecture pieces that the common function tracing
+code relies on for proper functioning. Things are broken down into increasing
+complexity so that you can start simple and at least get basic functionality.
+
+Note that this focuses on architecture implementation details only. If you
+want more explanation of a feature in terms of common code, review the common
+ftrace.txt file.
+
+Ideally, everyone who wishes to retain performance while supporting tracing in
+their kernel should make it all the way to dynamic ftrace support.
+
+
+Prerequisites
+-------------
+
+Ftrace relies on these features being implemented:
+ - STACKTRACE_SUPPORT - implement save_stack_trace()
+ - TRACE_IRQFLAGS_SUPPORT - implement include/asm/irqflags.h
+
+
+HAVE_FUNCTION_TRACER
+--------------------
+
+You will need to implement the mcount and the ftrace_stub functions.
+
+The exact mcount symbol name will depend on your toolchain. Some call it
+"mcount", "_mcount", or even "__mcount". You can probably figure it out by
+running something like::
+
+ $ echo 'main(){}' | gcc -x c -S -o - - -pg | grep mcount
+ call mcount
+
+We'll make the assumption below that the symbol is "mcount" just to keep things
+nice and simple in the examples.
+
+Keep in mind that the ABI that is in effect inside of the mcount function is
+*highly* architecture/toolchain specific. We cannot help you in this regard,
+sorry. Dig up some old documentation and/or find someone more familiar than
+you to bang ideas off of. Typically, register usage (argument/scratch/etc...)
+is a major issue at this point, especially in relation to the location of the
+mcount call (before/after function prologue). You might also want to look at
+how glibc has implemented the mcount function for your architecture. It might
+be (semi-)relevant.
+
+The mcount function should check the function pointer ftrace_trace_function
+to see if it is set to ftrace_stub. If it is, there is nothing for you to do,
+so return immediately. If it isn't, then call that function in the same way
+the mcount function normally calls __mcount_internal -- the first argument is
+the "frompc" while the second argument is the "selfpc" (adjusted to remove the
+size of the mcount call that is embedded in the function).
+
+For example, if the function foo() calls bar(), when the bar() function calls
+mcount(), the arguments mcount() will pass to the tracer are:
+
+ - "frompc" - the address bar() will use to return to foo()
+ - "selfpc" - the address bar() (with mcount() size adjustment)
+
+Also keep in mind that this mcount function will be called *a lot*, so
+optimizing for the default case of no tracer will help the smooth running of
+your system when tracing is disabled. So the start of the mcount function is
+typically the bare minimum with checking things before returning. That also
+means the code flow should usually be kept linear (i.e. no branching in the nop
+case). This is of course an optimization and not a hard requirement.
+
+Here is some pseudo code that should help (these functions should actually be
+implemented in assembly)::
+
+ void ftrace_stub(void)
+ {
+ return;
+ }
+
+ void mcount(void)
+ {
+ /* save any bare state needed in order to do initial checking */
+
+ extern void (*ftrace_trace_function)(unsigned long, unsigned long);
+ if (ftrace_trace_function != ftrace_stub)
+ goto do_trace;
+
+ /* restore any bare state */
+
+ return;
+
+ do_trace:
+
+ /* save all state needed by the ABI (see paragraph above) */
+
+ unsigned long frompc = ...;
+ unsigned long selfpc = <return address> - MCOUNT_INSN_SIZE;
+ ftrace_trace_function(frompc, selfpc);
+
+ /* restore all state needed by the ABI */
+ }
+
+Don't forget to export mcount for modules !
+::
+
+ extern void mcount(void);
+ EXPORT_SYMBOL(mcount);
+
+
+HAVE_FUNCTION_GRAPH_TRACER
+--------------------------
+
+Deep breath ... time to do some real work. Here you will need to update the
+mcount function to check ftrace graph function pointers, as well as implement
+some functions to save (hijack) and restore the return address.
+
+The mcount function should check the function pointers ftrace_graph_return
+(compare to ftrace_stub) and ftrace_graph_entry (compare to
+ftrace_graph_entry_stub). If either of those is not set to the relevant stub
+function, call the arch-specific function ftrace_graph_caller which in turn
+calls the arch-specific function prepare_ftrace_return. Neither of these
+function names is strictly required, but you should use them anyway to stay
+consistent across the architecture ports -- easier to compare & contrast
+things.
+
+The arguments to prepare_ftrace_return are slightly different than what are
+passed to ftrace_trace_function. The second argument "selfpc" is the same,
+but the first argument should be a pointer to the "frompc". Typically this is
+located on the stack. This allows the function to hijack the return address
+temporarily to have it point to the arch-specific function return_to_handler.
+That function will simply call the common ftrace_return_to_handler function and
+that will return the original return address with which you can return to the
+original call site.
+
+Here is the updated mcount pseudo code::
+
+ void mcount(void)
+ {
+ ...
+ if (ftrace_trace_function != ftrace_stub)
+ goto do_trace;
+
+ +#ifdef CONFIG_FUNCTION_GRAPH_TRACER
+ + extern void (*ftrace_graph_return)(...);
+ + extern void (*ftrace_graph_entry)(...);
+ + if (ftrace_graph_return != ftrace_stub ||
+ + ftrace_graph_entry != ftrace_graph_entry_stub)
+ + ftrace_graph_caller();
+ +#endif
+
+ /* restore any bare state */
+ ...
+
+Here is the pseudo code for the new ftrace_graph_caller assembly function::
+
+ #ifdef CONFIG_FUNCTION_GRAPH_TRACER
+ void ftrace_graph_caller(void)
+ {
+ /* save all state needed by the ABI */
+
+ unsigned long *frompc = &...;
+ unsigned long selfpc = <return address> - MCOUNT_INSN_SIZE;
+ /* passing frame pointer up is optional -- see below */
+ prepare_ftrace_return(frompc, selfpc, frame_pointer);
+
+ /* restore all state needed by the ABI */
+ }
+ #endif
+
+For information on how to implement prepare_ftrace_return(), simply look at the
+x86 version (the frame pointer passing is optional; see the next section for
+more information). The only architecture-specific piece in it is the setup of
+the fault recovery table (the asm(...) code). The rest should be the same
+across architectures.
+
+Here is the pseudo code for the new return_to_handler assembly function. Note
+that the ABI that applies here is different from what applies to the mcount
+code. Since you are returning from a function (after the epilogue), you might
+be able to skimp on things saved/restored (usually just registers used to pass
+return values).
+::
+
+ #ifdef CONFIG_FUNCTION_GRAPH_TRACER
+ void return_to_handler(void)
+ {
+ /* save all state needed by the ABI (see paragraph above) */
+
+ void (*original_return_point)(void) = ftrace_return_to_handler();
+
+ /* restore all state needed by the ABI */
+
+ /* this is usually either a return or a jump */
+ original_return_point();
+ }
+ #endif
+
+
+HAVE_FUNCTION_GRAPH_FP_TEST
+---------------------------
+
+An arch may pass in a unique value (frame pointer) to both the entering and
+exiting of a function. On exit, the value is compared and if it does not
+match, then it will panic the kernel. This is largely a sanity check for bad
+code generation with gcc. If gcc for your port sanely updates the frame
+pointer under different optimization levels, then ignore this option.
+
+However, adding support for it isn't terribly difficult. In your assembly code
+that calls prepare_ftrace_return(), pass the frame pointer as the 3rd argument.
+Then in the C version of that function, do what the x86 port does and pass it
+along to ftrace_push_return_trace() instead of a stub value of 0.
+
+Similarly, when you call ftrace_return_to_handler(), pass it the frame pointer.
+
+HAVE_FUNCTION_GRAPH_RET_ADDR_PTR
+--------------------------------
+
+An arch may pass in a pointer to the return address on the stack. This
+prevents potential stack unwinding issues where the unwinder gets out of
+sync with ret_stack and the wrong addresses are reported by
+ftrace_graph_ret_addr().
+
+Adding support for it is easy: just define the macro in asm/ftrace.h and
+pass the return address pointer as the 'retp' argument to
+ftrace_push_return_trace().
+
+HAVE_SYSCALL_TRACEPOINTS
+------------------------
+
+You need very few things to get the syscalls tracing in an arch.
+
+ - Support HAVE_ARCH_TRACEHOOK (see arch/Kconfig).
+ - Have a NR_syscalls variable in <asm/unistd.h> that provides the number
+ of syscalls supported by the arch.
+ - Support the TIF_SYSCALL_TRACEPOINT thread flags.
+ - Put the trace_sys_enter() and trace_sys_exit() tracepoints calls from ptrace
+ in the ptrace syscalls tracing path.
+ - If the system call table on this arch is more complicated than a simple array
+ of addresses of the system calls, implement an arch_syscall_addr to return
+ the address of a given system call.
+ - If the symbol names of the system calls do not match the function names on
+ this arch, define ARCH_HAS_SYSCALL_MATCH_SYM_NAME in asm/ftrace.h and
+ implement arch_syscall_match_sym_name with the appropriate logic to return
+ true if the function name corresponds with the symbol name.
+ - Tag this arch as HAVE_SYSCALL_TRACEPOINTS.
+
+
+HAVE_FTRACE_MCOUNT_RECORD
+-------------------------
+
+See scripts/recordmcount.pl for more info. Just fill in the arch-specific
+details for how to locate the addresses of mcount call sites via objdump.
+This option doesn't make much sense without also implementing dynamic ftrace.
+
+
+HAVE_DYNAMIC_FTRACE
+-------------------
+
+You will first need HAVE_FTRACE_MCOUNT_RECORD and HAVE_FUNCTION_TRACER, so
+scroll your reader back up if you got over eager.
+
+Once those are out of the way, you will need to implement:
+ - asm/ftrace.h:
+ - MCOUNT_ADDR
+ - ftrace_call_adjust()
+ - struct dyn_arch_ftrace{}
+ - asm code:
+ - mcount() (new stub)
+ - ftrace_caller()
+ - ftrace_call()
+ - ftrace_stub()
+ - C code:
+ - ftrace_dyn_arch_init()
+ - ftrace_make_nop()
+ - ftrace_make_call()
+ - ftrace_update_ftrace_func()
+
+First you will need to fill out some arch details in your asm/ftrace.h.
+
+Define MCOUNT_ADDR as the address of your mcount symbol similar to::
+
+ #define MCOUNT_ADDR ((unsigned long)mcount)
+
+Since no one else will have a decl for that function, you will need to::
+
+ extern void mcount(void);
+
+You will also need the helper function ftrace_call_adjust(). Most people
+will be able to stub it out like so::
+
+ static inline unsigned long ftrace_call_adjust(unsigned long addr)
+ {
+ return addr;
+ }
+
+<details to be filled>
+
+Lastly you will need the custom dyn_arch_ftrace structure. If you need
+some extra state when runtime patching arbitrary call sites, this is the
+place. For now though, create an empty struct::
+
+ struct dyn_arch_ftrace {
+ /* No extra data needed */
+ };
+
+With the header out of the way, we can fill out the assembly code. While we
+did already create a mcount() function earlier, dynamic ftrace only wants a
+stub function. This is because the mcount() will only be used during boot
+and then all references to it will be patched out never to return. Instead,
+the guts of the old mcount() will be used to create a new ftrace_caller()
+function. Because the two are hard to merge, it will most likely be a lot
+easier to have two separate definitions split up by #ifdefs. Same goes for
+the ftrace_stub() as that will now be inlined in ftrace_caller().
+
+Before we get confused anymore, let's check out some pseudo code so you can
+implement your own stuff in assembly::
+
+ void mcount(void)
+ {
+ return;
+ }
+
+ void ftrace_caller(void)
+ {
+ /* save all state needed by the ABI (see paragraph above) */
+
+ unsigned long frompc = ...;
+ unsigned long selfpc = <return address> - MCOUNT_INSN_SIZE;
+
+ ftrace_call:
+ ftrace_stub(frompc, selfpc);
+
+ /* restore all state needed by the ABI */
+
+ ftrace_stub:
+ return;
+ }
+
+This might look a little odd at first, but keep in mind that we will be runtime
+patching multiple things. First, only functions that we actually want to trace
+will be patched to call ftrace_caller(). Second, since we only have one tracer
+active at a time, we will patch the ftrace_caller() function itself to call the
+specific tracer in question. That is the point of the ftrace_call label.
+
+With that in mind, let's move on to the C code that will actually be doing the
+runtime patching. You'll need a little knowledge of your arch's opcodes in
+order to make it through the next section.
+
+Every arch has an init callback function. If you need to do something early on
+to initialize some state, this is the time to do that. Otherwise, this simple
+function below should be sufficient for most people::
+
+ int __init ftrace_dyn_arch_init(void)
+ {
+ return 0;
+ }
+
+There are two functions that are used to do runtime patching of arbitrary
+functions. The first is used to turn the mcount call site into a nop (which
+is what helps us retain runtime performance when not tracing). The second is
+used to turn the mcount call site into a call to an arbitrary location (but
+typically that is ftracer_caller()). See the general function definition in
+linux/ftrace.h for the functions::
+
+ ftrace_make_nop()
+ ftrace_make_call()
+
+The rec->ip value is the address of the mcount call site that was collected
+by the scripts/recordmcount.pl during build time.
+
+The last function is used to do runtime patching of the active tracer. This
+will be modifying the assembly code at the location of the ftrace_call symbol
+inside of the ftrace_caller() function. So you should have sufficient padding
+at that location to support the new function calls you'll be inserting. Some
+people will be using a "call" type instruction while others will be using a
+"branch" type instruction. Specifically, the function is::
+
+ ftrace_update_ftrace_func()
+
+
+HAVE_DYNAMIC_FTRACE + HAVE_FUNCTION_GRAPH_TRACER
+------------------------------------------------
+
+The function grapher needs a few tweaks in order to work with dynamic ftrace.
+Basically, you will need to:
+
+ - update:
+ - ftrace_caller()
+ - ftrace_graph_call()
+ - ftrace_graph_caller()
+ - implement:
+ - ftrace_enable_ftrace_graph_caller()
+ - ftrace_disable_ftrace_graph_caller()
+
+<details to be filled>
+
+Quick notes:
+
+ - add a nop stub after the ftrace_call location named ftrace_graph_call;
+ stub needs to be large enough to support a call to ftrace_graph_caller()
+ - update ftrace_graph_caller() to work with being called by the new
+ ftrace_caller() since some semantics may have changed
+ - ftrace_enable_ftrace_graph_caller() will runtime patch the
+ ftrace_graph_call location with a call to ftrace_graph_caller()
+ - ftrace_disable_ftrace_graph_caller() will runtime patch the
+ ftrace_graph_call location with nops
diff --git a/Documentation/trace/ftrace-uses.rst b/Documentation/trace/ftrace-uses.rst
new file mode 100644
index 000000000..f7d98ae5b
--- /dev/null
+++ b/Documentation/trace/ftrace-uses.rst
@@ -0,0 +1,348 @@
+=================================
+Using ftrace to hook to functions
+=================================
+
+.. Copyright 2017 VMware Inc.
+.. Author: Steven Rostedt <srostedt@goodmis.org>
+.. License: The GNU Free Documentation License, Version 1.2
+.. (dual licensed under the GPL v2)
+
+Written for: 4.14
+
+Introduction
+============
+
+The ftrace infrastructure was originally created to attach callbacks to the
+beginning of functions in order to record and trace the flow of the kernel.
+But callbacks to the start of a function can have other use cases. Either
+for live kernel patching, or for security monitoring. This document describes
+how to use ftrace to implement your own function callbacks.
+
+
+The ftrace context
+==================
+.. warning::
+
+ The ability to add a callback to almost any function within the
+ kernel comes with risks. A callback can be called from any context
+ (normal, softirq, irq, and NMI). Callbacks can also be called just before
+ going to idle, during CPU bring up and takedown, or going to user space.
+ This requires extra care to what can be done inside a callback. A callback
+ can be called outside the protective scope of RCU.
+
+There are helper functions to help against recursion, and making sure
+RCU is watching. These are explained below.
+
+
+The ftrace_ops structure
+========================
+
+To register a function callback, a ftrace_ops is required. This structure
+is used to tell ftrace what function should be called as the callback
+as well as what protections the callback will perform and not require
+ftrace to handle.
+
+There is only one field that is needed to be set when registering
+an ftrace_ops with ftrace:
+
+.. code-block:: c
+
+ struct ftrace_ops ops = {
+ .func = my_callback_func,
+ .flags = MY_FTRACE_FLAGS
+ .private = any_private_data_structure,
+ };
+
+Both .flags and .private are optional. Only .func is required.
+
+To enable tracing call::
+
+ register_ftrace_function(&ops);
+
+To disable tracing call::
+
+ unregister_ftrace_function(&ops);
+
+The above is defined by including the header::
+
+ #include <linux/ftrace.h>
+
+The registered callback will start being called some time after the
+register_ftrace_function() is called and before it returns. The exact time
+that callbacks start being called is dependent upon architecture and scheduling
+of services. The callback itself will have to handle any synchronization if it
+must begin at an exact moment.
+
+The unregister_ftrace_function() will guarantee that the callback is
+no longer being called by functions after the unregister_ftrace_function()
+returns. Note that to perform this guarantee, the unregister_ftrace_function()
+may take some time to finish.
+
+
+The callback function
+=====================
+
+The prototype of the callback function is as follows (as of v4.14):
+
+.. code-block:: c
+
+ void callback_func(unsigned long ip, unsigned long parent_ip,
+ struct ftrace_ops *op, struct pt_regs *regs);
+
+@ip
+ This is the instruction pointer of the function that is being traced.
+ (where the fentry or mcount is within the function)
+
+@parent_ip
+ This is the instruction pointer of the function that called the
+ the function being traced (where the call of the function occurred).
+
+@op
+ This is a pointer to ftrace_ops that was used to register the callback.
+ This can be used to pass data to the callback via the private pointer.
+
+@regs
+ If the FTRACE_OPS_FL_SAVE_REGS or FTRACE_OPS_FL_SAVE_REGS_IF_SUPPORTED
+ flags are set in the ftrace_ops structure, then this will be pointing
+ to the pt_regs structure like it would be if an breakpoint was placed
+ at the start of the function where ftrace was tracing. Otherwise it
+ either contains garbage, or NULL.
+
+Protect your callback
+=====================
+
+As functions can be called from anywhere, and it is possible that a function
+called by a callback may also be traced, and call that same callback,
+recursion protection must be used. There are two helper functions that
+can help in this regard. If you start your code with:
+
+.. code-block:: c
+
+ int bit;
+
+ bit = ftrace_test_recursion_trylock(ip, parent_ip);
+ if (bit < 0)
+ return;
+
+and end it with:
+
+.. code-block:: c
+
+ ftrace_test_recursion_unlock(bit);
+
+The code in between will be safe to use, even if it ends up calling a
+function that the callback is tracing. Note, on success,
+ftrace_test_recursion_trylock() will disable preemption, and the
+ftrace_test_recursion_unlock() will enable it again (if it was previously
+enabled). The instruction pointer (ip) and its parent (parent_ip) is passed to
+ftrace_test_recursion_trylock() to record where the recursion happened
+(if CONFIG_FTRACE_RECORD_RECURSION is set).
+
+Alternatively, if the FTRACE_OPS_FL_RECURSION flag is set on the ftrace_ops
+(as explained below), then a helper trampoline will be used to test
+for recursion for the callback and no recursion test needs to be done.
+But this is at the expense of a slightly more overhead from an extra
+function call.
+
+If your callback accesses any data or critical section that requires RCU
+protection, it is best to make sure that RCU is "watching", otherwise
+that data or critical section will not be protected as expected. In this
+case add:
+
+.. code-block:: c
+
+ if (!rcu_is_watching())
+ return;
+
+Alternatively, if the FTRACE_OPS_FL_RCU flag is set on the ftrace_ops
+(as explained below), then a helper trampoline will be used to test
+for rcu_is_watching for the callback and no other test needs to be done.
+But this is at the expense of a slightly more overhead from an extra
+function call.
+
+
+The ftrace FLAGS
+================
+
+The ftrace_ops flags are all defined and documented in include/linux/ftrace.h.
+Some of the flags are used for internal infrastructure of ftrace, but the
+ones that users should be aware of are the following:
+
+FTRACE_OPS_FL_SAVE_REGS
+ If the callback requires reading or modifying the pt_regs
+ passed to the callback, then it must set this flag. Registering
+ a ftrace_ops with this flag set on an architecture that does not
+ support passing of pt_regs to the callback will fail.
+
+FTRACE_OPS_FL_SAVE_REGS_IF_SUPPORTED
+ Similar to SAVE_REGS but the registering of a
+ ftrace_ops on an architecture that does not support passing of regs
+ will not fail with this flag set. But the callback must check if
+ regs is NULL or not to determine if the architecture supports it.
+
+FTRACE_OPS_FL_RECURSION
+ By default, it is expected that the callback can handle recursion.
+ But if the callback is not that worried about overehead, then
+ setting this bit will add the recursion protection around the
+ callback by calling a helper function that will do the recursion
+ protection and only call the callback if it did not recurse.
+
+ Note, if this flag is not set, and recursion does occur, it could
+ cause the system to crash, and possibly reboot via a triple fault.
+
+ Not, if this flag is set, then the callback will always be called
+ with preemption disabled. If it is not set, then it is possible
+ (but not guaranteed) that the callback will be called in
+ preemptable context.
+
+FTRACE_OPS_FL_IPMODIFY
+ Requires FTRACE_OPS_FL_SAVE_REGS set. If the callback is to "hijack"
+ the traced function (have another function called instead of the
+ traced function), it requires setting this flag. This is what live
+ kernel patches uses. Without this flag the pt_regs->ip can not be
+ modified.
+
+ Note, only one ftrace_ops with FTRACE_OPS_FL_IPMODIFY set may be
+ registered to any given function at a time.
+
+FTRACE_OPS_FL_RCU
+ If this is set, then the callback will only be called by functions
+ where RCU is "watching". This is required if the callback function
+ performs any rcu_read_lock() operation.
+
+ RCU stops watching when the system goes idle, the time when a CPU
+ is taken down and comes back online, and when entering from kernel
+ to user space and back to kernel space. During these transitions,
+ a callback may be executed and RCU synchronization will not protect
+ it.
+
+FTRACE_OPS_FL_PERMANENT
+ If this is set on any ftrace ops, then the tracing cannot disabled by
+ writing 0 to the proc sysctl ftrace_enabled. Equally, a callback with
+ the flag set cannot be registered if ftrace_enabled is 0.
+
+ Livepatch uses it not to lose the function redirection, so the system
+ stays protected.
+
+
+Filtering which functions to trace
+==================================
+
+If a callback is only to be called from specific functions, a filter must be
+set up. The filters are added by name, or ip if it is known.
+
+.. code-block:: c
+
+ int ftrace_set_filter(struct ftrace_ops *ops, unsigned char *buf,
+ int len, int reset);
+
+@ops
+ The ops to set the filter with
+
+@buf
+ The string that holds the function filter text.
+@len
+ The length of the string.
+
+@reset
+ Non-zero to reset all filters before applying this filter.
+
+Filters denote which functions should be enabled when tracing is enabled.
+If @buf is NULL and reset is set, all functions will be enabled for tracing.
+
+The @buf can also be a glob expression to enable all functions that
+match a specific pattern.
+
+See Filter Commands in :file:`Documentation/trace/ftrace.rst`.
+
+To just trace the schedule function:
+
+.. code-block:: c
+
+ ret = ftrace_set_filter(&ops, "schedule", strlen("schedule"), 0);
+
+To add more functions, call the ftrace_set_filter() more than once with the
+@reset parameter set to zero. To remove the current filter set and replace it
+with new functions defined by @buf, have @reset be non-zero.
+
+To remove all the filtered functions and trace all functions:
+
+.. code-block:: c
+
+ ret = ftrace_set_filter(&ops, NULL, 0, 1);
+
+
+Sometimes more than one function has the same name. To trace just a specific
+function in this case, ftrace_set_filter_ip() can be used.
+
+.. code-block:: c
+
+ ret = ftrace_set_filter_ip(&ops, ip, 0, 0);
+
+Although the ip must be the address where the call to fentry or mcount is
+located in the function. This function is used by perf and kprobes that
+gets the ip address from the user (usually using debug info from the kernel).
+
+If a glob is used to set the filter, functions can be added to a "notrace"
+list that will prevent those functions from calling the callback.
+The "notrace" list takes precedence over the "filter" list. If the
+two lists are non-empty and contain the same functions, the callback will not
+be called by any function.
+
+An empty "notrace" list means to allow all functions defined by the filter
+to be traced.
+
+.. code-block:: c
+
+ int ftrace_set_notrace(struct ftrace_ops *ops, unsigned char *buf,
+ int len, int reset);
+
+This takes the same parameters as ftrace_set_filter() but will add the
+functions it finds to not be traced. This is a separate list from the
+filter list, and this function does not modify the filter list.
+
+A non-zero @reset will clear the "notrace" list before adding functions
+that match @buf to it.
+
+Clearing the "notrace" list is the same as clearing the filter list
+
+.. code-block:: c
+
+ ret = ftrace_set_notrace(&ops, NULL, 0, 1);
+
+The filter and notrace lists may be changed at any time. If only a set of
+functions should call the callback, it is best to set the filters before
+registering the callback. But the changes may also happen after the callback
+has been registered.
+
+If a filter is in place, and the @reset is non-zero, and @buf contains a
+matching glob to functions, the switch will happen during the time of
+the ftrace_set_filter() call. At no time will all functions call the callback.
+
+.. code-block:: c
+
+ ftrace_set_filter(&ops, "schedule", strlen("schedule"), 1);
+
+ register_ftrace_function(&ops);
+
+ msleep(10);
+
+ ftrace_set_filter(&ops, "try_to_wake_up", strlen("try_to_wake_up"), 1);
+
+is not the same as:
+
+.. code-block:: c
+
+ ftrace_set_filter(&ops, "schedule", strlen("schedule"), 1);
+
+ register_ftrace_function(&ops);
+
+ msleep(10);
+
+ ftrace_set_filter(&ops, NULL, 0, 1);
+
+ ftrace_set_filter(&ops, "try_to_wake_up", strlen("try_to_wake_up"), 0);
+
+As the latter will have a short time where all functions will call
+the callback, between the time of the reset, and the time of the
+new setting of the filter.
diff --git a/Documentation/trace/ftrace.rst b/Documentation/trace/ftrace.rst
new file mode 100644
index 000000000..21f01d32c
--- /dev/null
+++ b/Documentation/trace/ftrace.rst
@@ -0,0 +1,3570 @@
+========================
+ftrace - Function Tracer
+========================
+
+Copyright 2008 Red Hat Inc.
+
+:Author: Steven Rostedt <srostedt@redhat.com>
+:License: The GNU Free Documentation License, Version 1.2
+ (dual licensed under the GPL v2)
+:Original Reviewers: Elias Oltmanns, Randy Dunlap, Andrew Morton,
+ John Kacur, and David Teigland.
+
+- Written for: 2.6.28-rc2
+- Updated for: 3.10
+- Updated for: 4.13 - Copyright 2017 VMware Inc. Steven Rostedt
+- Converted to rst format - Changbin Du <changbin.du@intel.com>
+
+Introduction
+------------
+
+Ftrace is an internal tracer designed to help out developers and
+designers of systems to find what is going on inside the kernel.
+It can be used for debugging or analyzing latencies and
+performance issues that take place outside of user-space.
+
+Although ftrace is typically considered the function tracer, it
+is really a framework of several assorted tracing utilities.
+There's latency tracing to examine what occurs between interrupts
+disabled and enabled, as well as for preemption and from a time
+a task is woken to the task is actually scheduled in.
+
+One of the most common uses of ftrace is the event tracing.
+Throughout the kernel is hundreds of static event points that
+can be enabled via the tracefs file system to see what is
+going on in certain parts of the kernel.
+
+See events.rst for more information.
+
+
+Implementation Details
+----------------------
+
+See Documentation/trace/ftrace-design.rst for details for arch porters and such.
+
+
+The File System
+---------------
+
+Ftrace uses the tracefs file system to hold the control files as
+well as the files to display output.
+
+When tracefs is configured into the kernel (which selecting any ftrace
+option will do) the directory /sys/kernel/tracing will be created. To mount
+this directory, you can add to your /etc/fstab file::
+
+ tracefs /sys/kernel/tracing tracefs defaults 0 0
+
+Or you can mount it at run time with::
+
+ mount -t tracefs nodev /sys/kernel/tracing
+
+For quicker access to that directory you may want to make a soft link to
+it::
+
+ ln -s /sys/kernel/tracing /tracing
+
+.. attention::
+
+ Before 4.1, all ftrace tracing control files were within the debugfs
+ file system, which is typically located at /sys/kernel/debug/tracing.
+ For backward compatibility, when mounting the debugfs file system,
+ the tracefs file system will be automatically mounted at:
+
+ /sys/kernel/debug/tracing
+
+ All files located in the tracefs file system will be located in that
+ debugfs file system directory as well.
+
+.. attention::
+
+ Any selected ftrace option will also create the tracefs file system.
+ The rest of the document will assume that you are in the ftrace directory
+ (cd /sys/kernel/tracing) and will only concentrate on the files within that
+ directory and not distract from the content with the extended
+ "/sys/kernel/tracing" path name.
+
+That's it! (assuming that you have ftrace configured into your kernel)
+
+After mounting tracefs you will have access to the control and output files
+of ftrace. Here is a list of some of the key files:
+
+
+ Note: all time values are in microseconds.
+
+ current_tracer:
+
+ This is used to set or display the current tracer
+ that is configured. Changing the current tracer clears
+ the ring buffer content as well as the "snapshot" buffer.
+
+ available_tracers:
+
+ This holds the different types of tracers that
+ have been compiled into the kernel. The
+ tracers listed here can be configured by
+ echoing their name into current_tracer.
+
+ tracing_on:
+
+ This sets or displays whether writing to the trace
+ ring buffer is enabled. Echo 0 into this file to disable
+ the tracer or 1 to enable it. Note, this only disables
+ writing to the ring buffer, the tracing overhead may
+ still be occurring.
+
+ The kernel function tracing_off() can be used within the
+ kernel to disable writing to the ring buffer, which will
+ set this file to "0". User space can re-enable tracing by
+ echoing "1" into the file.
+
+ Note, the function and event trigger "traceoff" will also
+ set this file to zero and stop tracing. Which can also
+ be re-enabled by user space using this file.
+
+ trace:
+
+ This file holds the output of the trace in a human
+ readable format (described below). Opening this file for
+ writing with the O_TRUNC flag clears the ring buffer content.
+ Note, this file is not a consumer. If tracing is off
+ (no tracer running, or tracing_on is zero), it will produce
+ the same output each time it is read. When tracing is on,
+ it may produce inconsistent results as it tries to read
+ the entire buffer without consuming it.
+
+ trace_pipe:
+
+ The output is the same as the "trace" file but this
+ file is meant to be streamed with live tracing.
+ Reads from this file will block until new data is
+ retrieved. Unlike the "trace" file, this file is a
+ consumer. This means reading from this file causes
+ sequential reads to display more current data. Once
+ data is read from this file, it is consumed, and
+ will not be read again with a sequential read. The
+ "trace" file is static, and if the tracer is not
+ adding more data, it will display the same
+ information every time it is read.
+
+ trace_options:
+
+ This file lets the user control the amount of data
+ that is displayed in one of the above output
+ files. Options also exist to modify how a tracer
+ or events work (stack traces, timestamps, etc).
+
+ options:
+
+ This is a directory that has a file for every available
+ trace option (also in trace_options). Options may also be set
+ or cleared by writing a "1" or "0" respectively into the
+ corresponding file with the option name.
+
+ tracing_max_latency:
+
+ Some of the tracers record the max latency.
+ For example, the maximum time that interrupts are disabled.
+ The maximum time is saved in this file. The max trace will also be
+ stored, and displayed by "trace". A new max trace will only be
+ recorded if the latency is greater than the value in this file
+ (in microseconds).
+
+ By echoing in a time into this file, no latency will be recorded
+ unless it is greater than the time in this file.
+
+ tracing_thresh:
+
+ Some latency tracers will record a trace whenever the
+ latency is greater than the number in this file.
+ Only active when the file contains a number greater than 0.
+ (in microseconds)
+
+ buffer_size_kb:
+
+ This sets or displays the number of kilobytes each CPU
+ buffer holds. By default, the trace buffers are the same size
+ for each CPU. The displayed number is the size of the
+ CPU buffer and not total size of all buffers. The
+ trace buffers are allocated in pages (blocks of memory
+ that the kernel uses for allocation, usually 4 KB in size).
+ A few extra pages may be allocated to accommodate buffer management
+ meta-data. If the last page allocated has room for more bytes
+ than requested, the rest of the page will be used,
+ making the actual allocation bigger than requested or shown.
+ ( Note, the size may not be a multiple of the page size
+ due to buffer management meta-data. )
+
+ Buffer sizes for individual CPUs may vary
+ (see "per_cpu/cpu0/buffer_size_kb" below), and if they do
+ this file will show "X".
+
+ buffer_total_size_kb:
+
+ This displays the total combined size of all the trace buffers.
+
+ free_buffer:
+
+ If a process is performing tracing, and the ring buffer should be
+ shrunk "freed" when the process is finished, even if it were to be
+ killed by a signal, this file can be used for that purpose. On close
+ of this file, the ring buffer will be resized to its minimum size.
+ Having a process that is tracing also open this file, when the process
+ exits its file descriptor for this file will be closed, and in doing so,
+ the ring buffer will be "freed".
+
+ It may also stop tracing if disable_on_free option is set.
+
+ tracing_cpumask:
+
+ This is a mask that lets the user only trace on specified CPUs.
+ The format is a hex string representing the CPUs.
+
+ set_ftrace_filter:
+
+ When dynamic ftrace is configured in (see the
+ section below "dynamic ftrace"), the code is dynamically
+ modified (code text rewrite) to disable calling of the
+ function profiler (mcount). This lets tracing be configured
+ in with practically no overhead in performance. This also
+ has a side effect of enabling or disabling specific functions
+ to be traced. Echoing names of functions into this file
+ will limit the trace to only those functions.
+ This influences the tracers "function" and "function_graph"
+ and thus also function profiling (see "function_profile_enabled").
+
+ The functions listed in "available_filter_functions" are what
+ can be written into this file.
+
+ This interface also allows for commands to be used. See the
+ "Filter commands" section for more details.
+
+ As a speed up, since processing strings can be quite expensive
+ and requires a check of all functions registered to tracing, instead
+ an index can be written into this file. A number (starting with "1")
+ written will instead select the same corresponding at the line position
+ of the "available_filter_functions" file.
+
+ set_ftrace_notrace:
+
+ This has an effect opposite to that of
+ set_ftrace_filter. Any function that is added here will not
+ be traced. If a function exists in both set_ftrace_filter
+ and set_ftrace_notrace, the function will _not_ be traced.
+
+ set_ftrace_pid:
+
+ Have the function tracer only trace the threads whose PID are
+ listed in this file.
+
+ If the "function-fork" option is set, then when a task whose
+ PID is listed in this file forks, the child's PID will
+ automatically be added to this file, and the child will be
+ traced by the function tracer as well. This option will also
+ cause PIDs of tasks that exit to be removed from the file.
+
+ set_ftrace_notrace_pid:
+
+ Have the function tracer ignore threads whose PID are listed in
+ this file.
+
+ If the "function-fork" option is set, then when a task whose
+ PID is listed in this file forks, the child's PID will
+ automatically be added to this file, and the child will not be
+ traced by the function tracer as well. This option will also
+ cause PIDs of tasks that exit to be removed from the file.
+
+ If a PID is in both this file and "set_ftrace_pid", then this
+ file takes precedence, and the thread will not be traced.
+
+ set_event_pid:
+
+ Have the events only trace a task with a PID listed in this file.
+ Note, sched_switch and sched_wake_up will also trace events
+ listed in this file.
+
+ To have the PIDs of children of tasks with their PID in this file
+ added on fork, enable the "event-fork" option. That option will also
+ cause the PIDs of tasks to be removed from this file when the task
+ exits.
+
+ set_event_notrace_pid:
+
+ Have the events not trace a task with a PID listed in this file.
+ Note, sched_switch and sched_wakeup will trace threads not listed
+ in this file, even if a thread's PID is in the file if the
+ sched_switch or sched_wakeup events also trace a thread that should
+ be traced.
+
+ To have the PIDs of children of tasks with their PID in this file
+ added on fork, enable the "event-fork" option. That option will also
+ cause the PIDs of tasks to be removed from this file when the task
+ exits.
+
+ set_graph_function:
+
+ Functions listed in this file will cause the function graph
+ tracer to only trace these functions and the functions that
+ they call. (See the section "dynamic ftrace" for more details).
+ Note, set_ftrace_filter and set_ftrace_notrace still affects
+ what functions are being traced.
+
+ set_graph_notrace:
+
+ Similar to set_graph_function, but will disable function graph
+ tracing when the function is hit until it exits the function.
+ This makes it possible to ignore tracing functions that are called
+ by a specific function.
+
+ available_filter_functions:
+
+ This lists the functions that ftrace has processed and can trace.
+ These are the function names that you can pass to
+ "set_ftrace_filter", "set_ftrace_notrace",
+ "set_graph_function", or "set_graph_notrace".
+ (See the section "dynamic ftrace" below for more details.)
+
+ dyn_ftrace_total_info:
+
+ This file is for debugging purposes. The number of functions that
+ have been converted to nops and are available to be traced.
+
+ enabled_functions:
+
+ This file is more for debugging ftrace, but can also be useful
+ in seeing if any function has a callback attached to it.
+ Not only does the trace infrastructure use ftrace function
+ trace utility, but other subsystems might too. This file
+ displays all functions that have a callback attached to them
+ as well as the number of callbacks that have been attached.
+ Note, a callback may also call multiple functions which will
+ not be listed in this count.
+
+ If the callback registered to be traced by a function with
+ the "save regs" attribute (thus even more overhead), a 'R'
+ will be displayed on the same line as the function that
+ is returning registers.
+
+ If the callback registered to be traced by a function with
+ the "ip modify" attribute (thus the regs->ip can be changed),
+ an 'I' will be displayed on the same line as the function that
+ can be overridden.
+
+ If the architecture supports it, it will also show what callback
+ is being directly called by the function. If the count is greater
+ than 1 it most likely will be ftrace_ops_list_func().
+
+ If the callback of a function jumps to a trampoline that is
+ specific to the callback and which is not the standard trampoline,
+ its address will be printed as well as the function that the
+ trampoline calls.
+
+ function_profile_enabled:
+
+ When set it will enable all functions with either the function
+ tracer, or if configured, the function graph tracer. It will
+ keep a histogram of the number of functions that were called
+ and if the function graph tracer was configured, it will also keep
+ track of the time spent in those functions. The histogram
+ content can be displayed in the files:
+
+ trace_stat/function<cpu> ( function0, function1, etc).
+
+ trace_stat:
+
+ A directory that holds different tracing stats.
+
+ kprobe_events:
+
+ Enable dynamic trace points. See kprobetrace.rst.
+
+ kprobe_profile:
+
+ Dynamic trace points stats. See kprobetrace.rst.
+
+ max_graph_depth:
+
+ Used with the function graph tracer. This is the max depth
+ it will trace into a function. Setting this to a value of
+ one will show only the first kernel function that is called
+ from user space.
+
+ printk_formats:
+
+ This is for tools that read the raw format files. If an event in
+ the ring buffer references a string, only a pointer to the string
+ is recorded into the buffer and not the string itself. This prevents
+ tools from knowing what that string was. This file displays the string
+ and address for the string allowing tools to map the pointers to what
+ the strings were.
+
+ saved_cmdlines:
+
+ Only the pid of the task is recorded in a trace event unless
+ the event specifically saves the task comm as well. Ftrace
+ makes a cache of pid mappings to comms to try to display
+ comms for events. If a pid for a comm is not listed, then
+ "<...>" is displayed in the output.
+
+ If the option "record-cmd" is set to "0", then comms of tasks
+ will not be saved during recording. By default, it is enabled.
+
+ saved_cmdlines_size:
+
+ By default, 128 comms are saved (see "saved_cmdlines" above). To
+ increase or decrease the amount of comms that are cached, echo
+ the number of comms to cache into this file.
+
+ saved_tgids:
+
+ If the option "record-tgid" is set, on each scheduling context switch
+ the Task Group ID of a task is saved in a table mapping the PID of
+ the thread to its TGID. By default, the "record-tgid" option is
+ disabled.
+
+ snapshot:
+
+ This displays the "snapshot" buffer and also lets the user
+ take a snapshot of the current running trace.
+ See the "Snapshot" section below for more details.
+
+ stack_max_size:
+
+ When the stack tracer is activated, this will display the
+ maximum stack size it has encountered.
+ See the "Stack Trace" section below.
+
+ stack_trace:
+
+ This displays the stack back trace of the largest stack
+ that was encountered when the stack tracer is activated.
+ See the "Stack Trace" section below.
+
+ stack_trace_filter:
+
+ This is similar to "set_ftrace_filter" but it limits what
+ functions the stack tracer will check.
+
+ trace_clock:
+
+ Whenever an event is recorded into the ring buffer, a
+ "timestamp" is added. This stamp comes from a specified
+ clock. By default, ftrace uses the "local" clock. This
+ clock is very fast and strictly per cpu, but on some
+ systems it may not be monotonic with respect to other
+ CPUs. In other words, the local clocks may not be in sync
+ with local clocks on other CPUs.
+
+ Usual clocks for tracing::
+
+ # cat trace_clock
+ [local] global counter x86-tsc
+
+ The clock with the square brackets around it is the one in effect.
+
+ local:
+ Default clock, but may not be in sync across CPUs
+
+ global:
+ This clock is in sync with all CPUs but may
+ be a bit slower than the local clock.
+
+ counter:
+ This is not a clock at all, but literally an atomic
+ counter. It counts up one by one, but is in sync
+ with all CPUs. This is useful when you need to
+ know exactly the order events occurred with respect to
+ each other on different CPUs.
+
+ uptime:
+ This uses the jiffies counter and the time stamp
+ is relative to the time since boot up.
+
+ perf:
+ This makes ftrace use the same clock that perf uses.
+ Eventually perf will be able to read ftrace buffers
+ and this will help out in interleaving the data.
+
+ x86-tsc:
+ Architectures may define their own clocks. For
+ example, x86 uses its own TSC cycle clock here.
+
+ ppc-tb:
+ This uses the powerpc timebase register value.
+ This is in sync across CPUs and can also be used
+ to correlate events across hypervisor/guest if
+ tb_offset is known.
+
+ mono:
+ This uses the fast monotonic clock (CLOCK_MONOTONIC)
+ which is monotonic and is subject to NTP rate adjustments.
+
+ mono_raw:
+ This is the raw monotonic clock (CLOCK_MONOTONIC_RAW)
+ which is monotonic but is not subject to any rate adjustments
+ and ticks at the same rate as the hardware clocksource.
+
+ boot:
+ This is the boot clock (CLOCK_BOOTTIME) and is based on the
+ fast monotonic clock, but also accounts for time spent in
+ suspend. Since the clock access is designed for use in
+ tracing in the suspend path, some side effects are possible
+ if clock is accessed after the suspend time is accounted before
+ the fast mono clock is updated. In this case, the clock update
+ appears to happen slightly sooner than it normally would have.
+ Also on 32-bit systems, it's possible that the 64-bit boot offset
+ sees a partial update. These effects are rare and post
+ processing should be able to handle them. See comments in the
+ ktime_get_boot_fast_ns() function for more information.
+
+ tai:
+ This is the tai clock (CLOCK_TAI) and is derived from the wall-
+ clock time. However, this clock does not experience
+ discontinuities and backwards jumps caused by NTP inserting leap
+ seconds. Since the clock access is designed for use in tracing,
+ side effects are possible. The clock access may yield wrong
+ readouts in case the internal TAI offset is updated e.g., caused
+ by setting the system time or using adjtimex() with an offset.
+ These effects are rare and post processing should be able to
+ handle them. See comments in the ktime_get_tai_fast_ns()
+ function for more information.
+
+ To set a clock, simply echo the clock name into this file::
+
+ # echo global > trace_clock
+
+ Setting a clock clears the ring buffer content as well as the
+ "snapshot" buffer.
+
+ trace_marker:
+
+ This is a very useful file for synchronizing user space
+ with events happening in the kernel. Writing strings into
+ this file will be written into the ftrace buffer.
+
+ It is useful in applications to open this file at the start
+ of the application and just reference the file descriptor
+ for the file::
+
+ void trace_write(const char *fmt, ...)
+ {
+ va_list ap;
+ char buf[256];
+ int n;
+
+ if (trace_fd < 0)
+ return;
+
+ va_start(ap, fmt);
+ n = vsnprintf(buf, 256, fmt, ap);
+ va_end(ap);
+
+ write(trace_fd, buf, n);
+ }
+
+ start::
+
+ trace_fd = open("trace_marker", O_WRONLY);
+
+ Note: Writing into the trace_marker file can also initiate triggers
+ that are written into /sys/kernel/tracing/events/ftrace/print/trigger
+ See "Event triggers" in Documentation/trace/events.rst and an
+ example in Documentation/trace/histogram.rst (Section 3.)
+
+ trace_marker_raw:
+
+ This is similar to trace_marker above, but is meant for binary data
+ to be written to it, where a tool can be used to parse the data
+ from trace_pipe_raw.
+
+ uprobe_events:
+
+ Add dynamic tracepoints in programs.
+ See uprobetracer.rst
+
+ uprobe_profile:
+
+ Uprobe statistics. See uprobetrace.txt
+
+ instances:
+
+ This is a way to make multiple trace buffers where different
+ events can be recorded in different buffers.
+ See "Instances" section below.
+
+ events:
+
+ This is the trace event directory. It holds event tracepoints
+ (also known as static tracepoints) that have been compiled
+ into the kernel. It shows what event tracepoints exist
+ and how they are grouped by system. There are "enable"
+ files at various levels that can enable the tracepoints
+ when a "1" is written to them.
+
+ See events.rst for more information.
+
+ set_event:
+
+ By echoing in the event into this file, will enable that event.
+
+ See events.rst for more information.
+
+ available_events:
+
+ A list of events that can be enabled in tracing.
+
+ See events.rst for more information.
+
+ timestamp_mode:
+
+ Certain tracers may change the timestamp mode used when
+ logging trace events into the event buffer. Events with
+ different modes can coexist within a buffer but the mode in
+ effect when an event is logged determines which timestamp mode
+ is used for that event. The default timestamp mode is
+ 'delta'.
+
+ Usual timestamp modes for tracing:
+
+ # cat timestamp_mode
+ [delta] absolute
+
+ The timestamp mode with the square brackets around it is the
+ one in effect.
+
+ delta: Default timestamp mode - timestamp is a delta against
+ a per-buffer timestamp.
+
+ absolute: The timestamp is a full timestamp, not a delta
+ against some other value. As such it takes up more
+ space and is less efficient.
+
+ hwlat_detector:
+
+ Directory for the Hardware Latency Detector.
+ See "Hardware Latency Detector" section below.
+
+ per_cpu:
+
+ This is a directory that contains the trace per_cpu information.
+
+ per_cpu/cpu0/buffer_size_kb:
+
+ The ftrace buffer is defined per_cpu. That is, there's a separate
+ buffer for each CPU to allow writes to be done atomically,
+ and free from cache bouncing. These buffers may have different
+ size buffers. This file is similar to the buffer_size_kb
+ file, but it only displays or sets the buffer size for the
+ specific CPU. (here cpu0).
+
+ per_cpu/cpu0/trace:
+
+ This is similar to the "trace" file, but it will only display
+ the data specific for the CPU. If written to, it only clears
+ the specific CPU buffer.
+
+ per_cpu/cpu0/trace_pipe
+
+ This is similar to the "trace_pipe" file, and is a consuming
+ read, but it will only display (and consume) the data specific
+ for the CPU.
+
+ per_cpu/cpu0/trace_pipe_raw
+
+ For tools that can parse the ftrace ring buffer binary format,
+ the trace_pipe_raw file can be used to extract the data
+ from the ring buffer directly. With the use of the splice()
+ system call, the buffer data can be quickly transferred to
+ a file or to the network where a server is collecting the
+ data.
+
+ Like trace_pipe, this is a consuming reader, where multiple
+ reads will always produce different data.
+
+ per_cpu/cpu0/snapshot:
+
+ This is similar to the main "snapshot" file, but will only
+ snapshot the current CPU (if supported). It only displays
+ the content of the snapshot for a given CPU, and if
+ written to, only clears this CPU buffer.
+
+ per_cpu/cpu0/snapshot_raw:
+
+ Similar to the trace_pipe_raw, but will read the binary format
+ from the snapshot buffer for the given CPU.
+
+ per_cpu/cpu0/stats:
+
+ This displays certain stats about the ring buffer:
+
+ entries:
+ The number of events that are still in the buffer.
+
+ overrun:
+ The number of lost events due to overwriting when
+ the buffer was full.
+
+ commit overrun:
+ Should always be zero.
+ This gets set if so many events happened within a nested
+ event (ring buffer is re-entrant), that it fills the
+ buffer and starts dropping events.
+
+ bytes:
+ Bytes actually read (not overwritten).
+
+ oldest event ts:
+ The oldest timestamp in the buffer
+
+ now ts:
+ The current timestamp
+
+ dropped events:
+ Events lost due to overwrite option being off.
+
+ read events:
+ The number of events read.
+
+The Tracers
+-----------
+
+Here is the list of current tracers that may be configured.
+
+ "function"
+
+ Function call tracer to trace all kernel functions.
+
+ "function_graph"
+
+ Similar to the function tracer except that the
+ function tracer probes the functions on their entry
+ whereas the function graph tracer traces on both entry
+ and exit of the functions. It then provides the ability
+ to draw a graph of function calls similar to C code
+ source.
+
+ "blk"
+
+ The block tracer. The tracer used by the blktrace user
+ application.
+
+ "hwlat"
+
+ The Hardware Latency tracer is used to detect if the hardware
+ produces any latency. See "Hardware Latency Detector" section
+ below.
+
+ "irqsoff"
+
+ Traces the areas that disable interrupts and saves
+ the trace with the longest max latency.
+ See tracing_max_latency. When a new max is recorded,
+ it replaces the old trace. It is best to view this
+ trace with the latency-format option enabled, which
+ happens automatically when the tracer is selected.
+
+ "preemptoff"
+
+ Similar to irqsoff but traces and records the amount of
+ time for which preemption is disabled.
+
+ "preemptirqsoff"
+
+ Similar to irqsoff and preemptoff, but traces and
+ records the largest time for which irqs and/or preemption
+ is disabled.
+
+ "wakeup"
+
+ Traces and records the max latency that it takes for
+ the highest priority task to get scheduled after
+ it has been woken up.
+ Traces all tasks as an average developer would expect.
+
+ "wakeup_rt"
+
+ Traces and records the max latency that it takes for just
+ RT tasks (as the current "wakeup" does). This is useful
+ for those interested in wake up timings of RT tasks.
+
+ "wakeup_dl"
+
+ Traces and records the max latency that it takes for
+ a SCHED_DEADLINE task to be woken (as the "wakeup" and
+ "wakeup_rt" does).
+
+ "mmiotrace"
+
+ A special tracer that is used to trace binary module.
+ It will trace all the calls that a module makes to the
+ hardware. Everything it writes and reads from the I/O
+ as well.
+
+ "branch"
+
+ This tracer can be configured when tracing likely/unlikely
+ calls within the kernel. It will trace when a likely and
+ unlikely branch is hit and if it was correct in its prediction
+ of being correct.
+
+ "nop"
+
+ This is the "trace nothing" tracer. To remove all
+ tracers from tracing simply echo "nop" into
+ current_tracer.
+
+Error conditions
+----------------
+
+ For most ftrace commands, failure modes are obvious and communicated
+ using standard return codes.
+
+ For other more involved commands, extended error information may be
+ available via the tracing/error_log file. For the commands that
+ support it, reading the tracing/error_log file after an error will
+ display more detailed information about what went wrong, if
+ information is available. The tracing/error_log file is a circular
+ error log displaying a small number (currently, 8) of ftrace errors
+ for the last (8) failed commands.
+
+ The extended error information and usage takes the form shown in
+ this example::
+
+ # echo xxx > /sys/kernel/debug/tracing/events/sched/sched_wakeup/trigger
+ echo: write error: Invalid argument
+
+ # cat /sys/kernel/debug/tracing/error_log
+ [ 5348.887237] location: error: Couldn't yyy: zzz
+ Command: xxx
+ ^
+ [ 7517.023364] location: error: Bad rrr: sss
+ Command: ppp qqq
+ ^
+
+ To clear the error log, echo the empty string into it::
+
+ # echo > /sys/kernel/debug/tracing/error_log
+
+Examples of using the tracer
+----------------------------
+
+Here are typical examples of using the tracers when controlling
+them only with the tracefs interface (without using any
+user-land utilities).
+
+Output format:
+--------------
+
+Here is an example of the output format of the file "trace"::
+
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 140080/250280 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ bash-1977 [000] .... 17284.993652: sys_close <-system_call_fastpath
+ bash-1977 [000] .... 17284.993653: __close_fd <-sys_close
+ bash-1977 [000] .... 17284.993653: _raw_spin_lock <-__close_fd
+ sshd-1974 [003] .... 17284.993653: __srcu_read_unlock <-fsnotify
+ bash-1977 [000] .... 17284.993654: add_preempt_count <-_raw_spin_lock
+ bash-1977 [000] ...1 17284.993655: _raw_spin_unlock <-__close_fd
+ bash-1977 [000] ...1 17284.993656: sub_preempt_count <-_raw_spin_unlock
+ bash-1977 [000] .... 17284.993657: filp_close <-__close_fd
+ bash-1977 [000] .... 17284.993657: dnotify_flush <-filp_close
+ sshd-1974 [003] .... 17284.993658: sys_select <-system_call_fastpath
+ ....
+
+A header is printed with the tracer name that is represented by
+the trace. In this case the tracer is "function". Then it shows the
+number of events in the buffer as well as the total number of entries
+that were written. The difference is the number of entries that were
+lost due to the buffer filling up (250280 - 140080 = 110200 events
+lost).
+
+The header explains the content of the events. Task name "bash", the task
+PID "1977", the CPU that it was running on "000", the latency format
+(explained below), the timestamp in <secs>.<usecs> format, the
+function name that was traced "sys_close" and the parent function that
+called this function "system_call_fastpath". The timestamp is the time
+at which the function was entered.
+
+Latency trace format
+--------------------
+
+When the latency-format option is enabled or when one of the latency
+tracers is set, the trace file gives somewhat more information to see
+why a latency happened. Here is a typical trace::
+
+ # tracer: irqsoff
+ #
+ # irqsoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 259 us, #4/4, CPU#2 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: ps-6143 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: __lock_task_sighand
+ # => ended at: _raw_spin_unlock_irqrestore
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ ps-6143 2d... 0us!: trace_hardirqs_off <-__lock_task_sighand
+ ps-6143 2d..1 259us+: trace_hardirqs_on <-_raw_spin_unlock_irqrestore
+ ps-6143 2d..1 263us+: time_hardirqs_on <-_raw_spin_unlock_irqrestore
+ ps-6143 2d..1 306us : <stack trace>
+ => trace_hardirqs_on_caller
+ => trace_hardirqs_on
+ => _raw_spin_unlock_irqrestore
+ => do_task_stat
+ => proc_tgid_stat
+ => proc_single_show
+ => seq_read
+ => vfs_read
+ => sys_read
+ => system_call_fastpath
+
+
+This shows that the current tracer is "irqsoff" tracing the time
+for which interrupts were disabled. It gives the trace version (which
+never changes) and the version of the kernel upon which this was executed on
+(3.8). Then it displays the max latency in microseconds (259 us). The number
+of trace entries displayed and the total number (both are four: #4/4).
+VP, KP, SP, and HP are always zero and are reserved for later use.
+#P is the number of online CPUs (#P:4).
+
+The task is the process that was running when the latency
+occurred. (ps pid: 6143).
+
+The start and stop (the functions in which the interrupts were
+disabled and enabled respectively) that caused the latencies:
+
+ - __lock_task_sighand is where the interrupts were disabled.
+ - _raw_spin_unlock_irqrestore is where they were enabled again.
+
+The next lines after the header are the trace itself. The header
+explains which is which.
+
+ cmd: The name of the process in the trace.
+
+ pid: The PID of that process.
+
+ CPU#: The CPU which the process was running on.
+
+ irqs-off: 'd' interrupts are disabled. '.' otherwise.
+ .. caution:: If the architecture does not support a way to
+ read the irq flags variable, an 'X' will always
+ be printed here.
+
+ need-resched:
+ - 'N' both TIF_NEED_RESCHED and PREEMPT_NEED_RESCHED is set,
+ - 'n' only TIF_NEED_RESCHED is set,
+ - 'p' only PREEMPT_NEED_RESCHED is set,
+ - '.' otherwise.
+
+ hardirq/softirq:
+ - 'Z' - NMI occurred inside a hardirq
+ - 'z' - NMI is running
+ - 'H' - hard irq occurred inside a softirq.
+ - 'h' - hard irq is running
+ - 's' - soft irq is running
+ - '.' - normal context.
+
+ preempt-depth: The level of preempt_disabled
+
+The above is mostly meaningful for kernel developers.
+
+ time:
+ When the latency-format option is enabled, the trace file
+ output includes a timestamp relative to the start of the
+ trace. This differs from the output when latency-format
+ is disabled, which includes an absolute timestamp.
+
+ delay:
+ This is just to help catch your eye a bit better. And
+ needs to be fixed to be only relative to the same CPU.
+ The marks are determined by the difference between this
+ current trace and the next trace.
+
+ - '$' - greater than 1 second
+ - '@' - greater than 100 millisecond
+ - '*' - greater than 10 millisecond
+ - '#' - greater than 1000 microsecond
+ - '!' - greater than 100 microsecond
+ - '+' - greater than 10 microsecond
+ - ' ' - less than or equal to 10 microsecond.
+
+ The rest is the same as the 'trace' file.
+
+ Note, the latency tracers will usually end with a back trace
+ to easily find where the latency occurred.
+
+trace_options
+-------------
+
+The trace_options file (or the options directory) is used to control
+what gets printed in the trace output, or manipulate the tracers.
+To see what is available, simply cat the file::
+
+ cat trace_options
+ print-parent
+ nosym-offset
+ nosym-addr
+ noverbose
+ noraw
+ nohex
+ nobin
+ noblock
+ trace_printk
+ annotate
+ nouserstacktrace
+ nosym-userobj
+ noprintk-msg-only
+ context-info
+ nolatency-format
+ record-cmd
+ norecord-tgid
+ overwrite
+ nodisable_on_free
+ irq-info
+ markers
+ noevent-fork
+ function-trace
+ nofunction-fork
+ nodisplay-graph
+ nostacktrace
+ nobranch
+
+To disable one of the options, echo in the option prepended with
+"no"::
+
+ echo noprint-parent > trace_options
+
+To enable an option, leave off the "no"::
+
+ echo sym-offset > trace_options
+
+Here are the available options:
+
+ print-parent
+ On function traces, display the calling (parent)
+ function as well as the function being traced.
+ ::
+
+ print-parent:
+ bash-4000 [01] 1477.606694: simple_strtoul <-kstrtoul
+
+ noprint-parent:
+ bash-4000 [01] 1477.606694: simple_strtoul
+
+
+ sym-offset
+ Display not only the function name, but also the
+ offset in the function. For example, instead of
+ seeing just "ktime_get", you will see
+ "ktime_get+0xb/0x20".
+ ::
+
+ sym-offset:
+ bash-4000 [01] 1477.606694: simple_strtoul+0x6/0xa0
+
+ sym-addr
+ This will also display the function address as well
+ as the function name.
+ ::
+
+ sym-addr:
+ bash-4000 [01] 1477.606694: simple_strtoul <c0339346>
+
+ verbose
+ This deals with the trace file when the
+ latency-format option is enabled.
+ ::
+
+ bash 4000 1 0 00000000 00010a95 [58127d26] 1720.415ms \
+ (+0.000ms): simple_strtoul (kstrtoul)
+
+ raw
+ This will display raw numbers. This option is best for
+ use with user applications that can translate the raw
+ numbers better than having it done in the kernel.
+
+ hex
+ Similar to raw, but the numbers will be in a hexadecimal format.
+
+ bin
+ This will print out the formats in raw binary.
+
+ block
+ When set, reading trace_pipe will not block when polled.
+
+ trace_printk
+ Can disable trace_printk() from writing into the buffer.
+
+ annotate
+ It is sometimes confusing when the CPU buffers are full
+ and one CPU buffer had a lot of events recently, thus
+ a shorter time frame, were another CPU may have only had
+ a few events, which lets it have older events. When
+ the trace is reported, it shows the oldest events first,
+ and it may look like only one CPU ran (the one with the
+ oldest events). When the annotate option is set, it will
+ display when a new CPU buffer started::
+
+ <idle>-0 [001] dNs4 21169.031481: wake_up_idle_cpu <-add_timer_on
+ <idle>-0 [001] dNs4 21169.031482: _raw_spin_unlock_irqrestore <-add_timer_on
+ <idle>-0 [001] .Ns4 21169.031484: sub_preempt_count <-_raw_spin_unlock_irqrestore
+ ##### CPU 2 buffer started ####
+ <idle>-0 [002] .N.1 21169.031484: rcu_idle_exit <-cpu_idle
+ <idle>-0 [001] .Ns3 21169.031484: _raw_spin_unlock <-clocksource_watchdog
+ <idle>-0 [001] .Ns3 21169.031485: sub_preempt_count <-_raw_spin_unlock
+
+ userstacktrace
+ This option changes the trace. It records a
+ stacktrace of the current user space thread after
+ each trace event.
+
+ sym-userobj
+ when user stacktrace are enabled, look up which
+ object the address belongs to, and print a
+ relative address. This is especially useful when
+ ASLR is on, otherwise you don't get a chance to
+ resolve the address to object/file/line after
+ the app is no longer running
+
+ The lookup is performed when you read
+ trace,trace_pipe. Example::
+
+ a.out-1623 [000] 40874.465068: /root/a.out[+0x480] <-/root/a.out[+0
+ x494] <- /root/a.out[+0x4a8] <- /lib/libc-2.7.so[+0x1e1a6]
+
+
+ printk-msg-only
+ When set, trace_printk()s will only show the format
+ and not their parameters (if trace_bprintk() or
+ trace_bputs() was used to save the trace_printk()).
+
+ context-info
+ Show only the event data. Hides the comm, PID,
+ timestamp, CPU, and other useful data.
+
+ latency-format
+ This option changes the trace output. When it is enabled,
+ the trace displays additional information about the
+ latency, as described in "Latency trace format".
+
+ pause-on-trace
+ When set, opening the trace file for read, will pause
+ writing to the ring buffer (as if tracing_on was set to zero).
+ This simulates the original behavior of the trace file.
+ When the file is closed, tracing will be enabled again.
+
+ hash-ptr
+ When set, "%p" in the event printk format displays the
+ hashed pointer value instead of real address.
+ This will be useful if you want to find out which hashed
+ value is corresponding to the real value in trace log.
+
+ record-cmd
+ When any event or tracer is enabled, a hook is enabled
+ in the sched_switch trace point to fill comm cache
+ with mapped pids and comms. But this may cause some
+ overhead, and if you only care about pids, and not the
+ name of the task, disabling this option can lower the
+ impact of tracing. See "saved_cmdlines".
+
+ record-tgid
+ When any event or tracer is enabled, a hook is enabled
+ in the sched_switch trace point to fill the cache of
+ mapped Thread Group IDs (TGID) mapping to pids. See
+ "saved_tgids".
+
+ overwrite
+ This controls what happens when the trace buffer is
+ full. If "1" (default), the oldest events are
+ discarded and overwritten. If "0", then the newest
+ events are discarded.
+ (see per_cpu/cpu0/stats for overrun and dropped)
+
+ disable_on_free
+ When the free_buffer is closed, tracing will
+ stop (tracing_on set to 0).
+
+ irq-info
+ Shows the interrupt, preempt count, need resched data.
+ When disabled, the trace looks like::
+
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 144405/9452052 #P:4
+ #
+ # TASK-PID CPU# TIMESTAMP FUNCTION
+ # | | | | |
+ <idle>-0 [002] 23636.756054: ttwu_do_activate.constprop.89 <-try_to_wake_up
+ <idle>-0 [002] 23636.756054: activate_task <-ttwu_do_activate.constprop.89
+ <idle>-0 [002] 23636.756055: enqueue_task <-activate_task
+
+
+ markers
+ When set, the trace_marker is writable (only by root).
+ When disabled, the trace_marker will error with EINVAL
+ on write.
+
+ event-fork
+ When set, tasks with PIDs listed in set_event_pid will have
+ the PIDs of their children added to set_event_pid when those
+ tasks fork. Also, when tasks with PIDs in set_event_pid exit,
+ their PIDs will be removed from the file.
+
+ This affects PIDs listed in set_event_notrace_pid as well.
+
+ function-trace
+ The latency tracers will enable function tracing
+ if this option is enabled (default it is). When
+ it is disabled, the latency tracers do not trace
+ functions. This keeps the overhead of the tracer down
+ when performing latency tests.
+
+ function-fork
+ When set, tasks with PIDs listed in set_ftrace_pid will
+ have the PIDs of their children added to set_ftrace_pid
+ when those tasks fork. Also, when tasks with PIDs in
+ set_ftrace_pid exit, their PIDs will be removed from the
+ file.
+
+ This affects PIDs in set_ftrace_notrace_pid as well.
+
+ display-graph
+ When set, the latency tracers (irqsoff, wakeup, etc) will
+ use function graph tracing instead of function tracing.
+
+ stacktrace
+ When set, a stack trace is recorded after any trace event
+ is recorded.
+
+ branch
+ Enable branch tracing with the tracer. This enables branch
+ tracer along with the currently set tracer. Enabling this
+ with the "nop" tracer is the same as just enabling the
+ "branch" tracer.
+
+.. tip:: Some tracers have their own options. They only appear in this
+ file when the tracer is active. They always appear in the
+ options directory.
+
+
+Here are the per tracer options:
+
+Options for function tracer:
+
+ func_stack_trace
+ When set, a stack trace is recorded after every
+ function that is recorded. NOTE! Limit the functions
+ that are recorded before enabling this, with
+ "set_ftrace_filter" otherwise the system performance
+ will be critically degraded. Remember to disable
+ this option before clearing the function filter.
+
+Options for function_graph tracer:
+
+ Since the function_graph tracer has a slightly different output
+ it has its own options to control what is displayed.
+
+ funcgraph-overrun
+ When set, the "overrun" of the graph stack is
+ displayed after each function traced. The
+ overrun, is when the stack depth of the calls
+ is greater than what is reserved for each task.
+ Each task has a fixed array of functions to
+ trace in the call graph. If the depth of the
+ calls exceeds that, the function is not traced.
+ The overrun is the number of functions missed
+ due to exceeding this array.
+
+ funcgraph-cpu
+ When set, the CPU number of the CPU where the trace
+ occurred is displayed.
+
+ funcgraph-overhead
+ When set, if the function takes longer than
+ A certain amount, then a delay marker is
+ displayed. See "delay" above, under the
+ header description.
+
+ funcgraph-proc
+ Unlike other tracers, the process' command line
+ is not displayed by default, but instead only
+ when a task is traced in and out during a context
+ switch. Enabling this options has the command
+ of each process displayed at every line.
+
+ funcgraph-duration
+ At the end of each function (the return)
+ the duration of the amount of time in the
+ function is displayed in microseconds.
+
+ funcgraph-abstime
+ When set, the timestamp is displayed at each line.
+
+ funcgraph-irqs
+ When disabled, functions that happen inside an
+ interrupt will not be traced.
+
+ funcgraph-tail
+ When set, the return event will include the function
+ that it represents. By default this is off, and
+ only a closing curly bracket "}" is displayed for
+ the return of a function.
+
+ sleep-time
+ When running function graph tracer, to include
+ the time a task schedules out in its function.
+ When enabled, it will account time the task has been
+ scheduled out as part of the function call.
+
+ graph-time
+ When running function profiler with function graph tracer,
+ to include the time to call nested functions. When this is
+ not set, the time reported for the function will only
+ include the time the function itself executed for, not the
+ time for functions that it called.
+
+Options for blk tracer:
+
+ blk_classic
+ Shows a more minimalistic output.
+
+
+irqsoff
+-------
+
+When interrupts are disabled, the CPU can not react to any other
+external event (besides NMIs and SMIs). This prevents the timer
+interrupt from triggering or the mouse interrupt from letting
+the kernel know of a new mouse event. The result is a latency
+with the reaction time.
+
+The irqsoff tracer tracks the time for which interrupts are
+disabled. When a new maximum latency is hit, the tracer saves
+the trace leading up to that latency point so that every time a
+new maximum is reached, the old saved trace is discarded and the
+new trace is saved.
+
+To reset the maximum, echo 0 into tracing_max_latency. Here is
+an example::
+
+ # echo 0 > options/function-trace
+ # echo irqsoff > current_tracer
+ # echo 1 > tracing_on
+ # echo 0 > tracing_max_latency
+ # ls -ltr
+ [...]
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: irqsoff
+ #
+ # irqsoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 16 us, #4/4, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: swapper/0-0 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: run_timer_softirq
+ # => ended at: run_timer_softirq
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ <idle>-0 0d.s2 0us+: _raw_spin_lock_irq <-run_timer_softirq
+ <idle>-0 0dNs3 17us : _raw_spin_unlock_irq <-run_timer_softirq
+ <idle>-0 0dNs3 17us+: trace_hardirqs_on <-run_timer_softirq
+ <idle>-0 0dNs3 25us : <stack trace>
+ => _raw_spin_unlock_irq
+ => run_timer_softirq
+ => __do_softirq
+ => call_softirq
+ => do_softirq
+ => irq_exit
+ => smp_apic_timer_interrupt
+ => apic_timer_interrupt
+ => rcu_idle_exit
+ => cpu_idle
+ => rest_init
+ => start_kernel
+ => x86_64_start_reservations
+ => x86_64_start_kernel
+
+Here we see that we had a latency of 16 microseconds (which is
+very good). The _raw_spin_lock_irq in run_timer_softirq disabled
+interrupts. The difference between the 16 and the displayed
+timestamp 25us occurred because the clock was incremented
+between the time of recording the max latency and the time of
+recording the function that had that latency.
+
+Note the above example had function-trace not set. If we set
+function-trace, we get a much larger output::
+
+ with echo 1 > options/function-trace
+
+ # tracer: irqsoff
+ #
+ # irqsoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 71 us, #168/168, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: bash-2042 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: ata_scsi_queuecmd
+ # => ended at: ata_scsi_queuecmd
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ bash-2042 3d... 0us : _raw_spin_lock_irqsave <-ata_scsi_queuecmd
+ bash-2042 3d... 0us : add_preempt_count <-_raw_spin_lock_irqsave
+ bash-2042 3d..1 1us : ata_scsi_find_dev <-ata_scsi_queuecmd
+ bash-2042 3d..1 1us : __ata_scsi_find_dev <-ata_scsi_find_dev
+ bash-2042 3d..1 2us : ata_find_dev.part.14 <-__ata_scsi_find_dev
+ bash-2042 3d..1 2us : ata_qc_new_init <-__ata_scsi_queuecmd
+ bash-2042 3d..1 3us : ata_sg_init <-__ata_scsi_queuecmd
+ bash-2042 3d..1 4us : ata_scsi_rw_xlat <-__ata_scsi_queuecmd
+ bash-2042 3d..1 4us : ata_build_rw_tf <-ata_scsi_rw_xlat
+ [...]
+ bash-2042 3d..1 67us : delay_tsc <-__delay
+ bash-2042 3d..1 67us : add_preempt_count <-delay_tsc
+ bash-2042 3d..2 67us : sub_preempt_count <-delay_tsc
+ bash-2042 3d..1 67us : add_preempt_count <-delay_tsc
+ bash-2042 3d..2 68us : sub_preempt_count <-delay_tsc
+ bash-2042 3d..1 68us+: ata_bmdma_start <-ata_bmdma_qc_issue
+ bash-2042 3d..1 71us : _raw_spin_unlock_irqrestore <-ata_scsi_queuecmd
+ bash-2042 3d..1 71us : _raw_spin_unlock_irqrestore <-ata_scsi_queuecmd
+ bash-2042 3d..1 72us+: trace_hardirqs_on <-ata_scsi_queuecmd
+ bash-2042 3d..1 120us : <stack trace>
+ => _raw_spin_unlock_irqrestore
+ => ata_scsi_queuecmd
+ => scsi_dispatch_cmd
+ => scsi_request_fn
+ => __blk_run_queue_uncond
+ => __blk_run_queue
+ => blk_queue_bio
+ => submit_bio_noacct
+ => submit_bio
+ => submit_bh
+ => __ext3_get_inode_loc
+ => ext3_iget
+ => ext3_lookup
+ => lookup_real
+ => __lookup_hash
+ => walk_component
+ => lookup_last
+ => path_lookupat
+ => filename_lookup
+ => user_path_at_empty
+ => user_path_at
+ => vfs_fstatat
+ => vfs_stat
+ => sys_newstat
+ => system_call_fastpath
+
+
+Here we traced a 71 microsecond latency. But we also see all the
+functions that were called during that time. Note that by
+enabling function tracing, we incur an added overhead. This
+overhead may extend the latency times. But nevertheless, this
+trace has provided some very helpful debugging information.
+
+If we prefer function graph output instead of function, we can set
+display-graph option::
+
+ with echo 1 > options/display-graph
+
+ # tracer: irqsoff
+ #
+ # irqsoff latency trace v1.1.5 on 4.20.0-rc6+
+ # --------------------------------------------------------------------
+ # latency: 3751 us, #274/274, CPU#0 | (M:desktop VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: bash-1507 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: free_debug_processing
+ # => ended at: return_to_handler
+ #
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| /
+ # REL TIME CPU TASK/PID |||| DURATION FUNCTION CALLS
+ # | | | | |||| | | | | | |
+ 0 us | 0) bash-1507 | d... | 0.000 us | _raw_spin_lock_irqsave();
+ 0 us | 0) bash-1507 | d..1 | 0.378 us | do_raw_spin_trylock();
+ 1 us | 0) bash-1507 | d..2 | | set_track() {
+ 2 us | 0) bash-1507 | d..2 | | save_stack_trace() {
+ 2 us | 0) bash-1507 | d..2 | | __save_stack_trace() {
+ 3 us | 0) bash-1507 | d..2 | | __unwind_start() {
+ 3 us | 0) bash-1507 | d..2 | | get_stack_info() {
+ 3 us | 0) bash-1507 | d..2 | 0.351 us | in_task_stack();
+ 4 us | 0) bash-1507 | d..2 | 1.107 us | }
+ [...]
+ 3750 us | 0) bash-1507 | d..1 | 0.516 us | do_raw_spin_unlock();
+ 3750 us | 0) bash-1507 | d..1 | 0.000 us | _raw_spin_unlock_irqrestore();
+ 3764 us | 0) bash-1507 | d..1 | 0.000 us | tracer_hardirqs_on();
+ bash-1507 0d..1 3792us : <stack trace>
+ => free_debug_processing
+ => __slab_free
+ => kmem_cache_free
+ => vm_area_free
+ => remove_vma
+ => exit_mmap
+ => mmput
+ => begin_new_exec
+ => load_elf_binary
+ => search_binary_handler
+ => __do_execve_file.isra.32
+ => __x64_sys_execve
+ => do_syscall_64
+ => entry_SYSCALL_64_after_hwframe
+
+preemptoff
+----------
+
+When preemption is disabled, we may be able to receive
+interrupts but the task cannot be preempted and a higher
+priority task must wait for preemption to be enabled again
+before it can preempt a lower priority task.
+
+The preemptoff tracer traces the places that disable preemption.
+Like the irqsoff tracer, it records the maximum latency for
+which preemption was disabled. The control of preemptoff tracer
+is much like the irqsoff tracer.
+::
+
+ # echo 0 > options/function-trace
+ # echo preemptoff > current_tracer
+ # echo 1 > tracing_on
+ # echo 0 > tracing_max_latency
+ # ls -ltr
+ [...]
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: preemptoff
+ #
+ # preemptoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 46 us, #4/4, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: sshd-1991 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: do_IRQ
+ # => ended at: do_IRQ
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ sshd-1991 1d.h. 0us+: irq_enter <-do_IRQ
+ sshd-1991 1d..1 46us : irq_exit <-do_IRQ
+ sshd-1991 1d..1 47us+: trace_preempt_on <-do_IRQ
+ sshd-1991 1d..1 52us : <stack trace>
+ => sub_preempt_count
+ => irq_exit
+ => do_IRQ
+ => ret_from_intr
+
+
+This has some more changes. Preemption was disabled when an
+interrupt came in (notice the 'h'), and was enabled on exit.
+But we also see that interrupts have been disabled when entering
+the preempt off section and leaving it (the 'd'). We do not know if
+interrupts were enabled in the mean time or shortly after this
+was over.
+::
+
+ # tracer: preemptoff
+ #
+ # preemptoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 83 us, #241/241, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: bash-1994 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: wake_up_new_task
+ # => ended at: task_rq_unlock
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ bash-1994 1d..1 0us : _raw_spin_lock_irqsave <-wake_up_new_task
+ bash-1994 1d..1 0us : select_task_rq_fair <-select_task_rq
+ bash-1994 1d..1 1us : __rcu_read_lock <-select_task_rq_fair
+ bash-1994 1d..1 1us : source_load <-select_task_rq_fair
+ bash-1994 1d..1 1us : source_load <-select_task_rq_fair
+ [...]
+ bash-1994 1d..1 12us : irq_enter <-smp_apic_timer_interrupt
+ bash-1994 1d..1 12us : rcu_irq_enter <-irq_enter
+ bash-1994 1d..1 13us : add_preempt_count <-irq_enter
+ bash-1994 1d.h1 13us : exit_idle <-smp_apic_timer_interrupt
+ bash-1994 1d.h1 13us : hrtimer_interrupt <-smp_apic_timer_interrupt
+ bash-1994 1d.h1 13us : _raw_spin_lock <-hrtimer_interrupt
+ bash-1994 1d.h1 14us : add_preempt_count <-_raw_spin_lock
+ bash-1994 1d.h2 14us : ktime_get_update_offsets <-hrtimer_interrupt
+ [...]
+ bash-1994 1d.h1 35us : lapic_next_event <-clockevents_program_event
+ bash-1994 1d.h1 35us : irq_exit <-smp_apic_timer_interrupt
+ bash-1994 1d.h1 36us : sub_preempt_count <-irq_exit
+ bash-1994 1d..2 36us : do_softirq <-irq_exit
+ bash-1994 1d..2 36us : __do_softirq <-call_softirq
+ bash-1994 1d..2 36us : __local_bh_disable <-__do_softirq
+ bash-1994 1d.s2 37us : add_preempt_count <-_raw_spin_lock_irq
+ bash-1994 1d.s3 38us : _raw_spin_unlock <-run_timer_softirq
+ bash-1994 1d.s3 39us : sub_preempt_count <-_raw_spin_unlock
+ bash-1994 1d.s2 39us : call_timer_fn <-run_timer_softirq
+ [...]
+ bash-1994 1dNs2 81us : cpu_needs_another_gp <-rcu_process_callbacks
+ bash-1994 1dNs2 82us : __local_bh_enable <-__do_softirq
+ bash-1994 1dNs2 82us : sub_preempt_count <-__local_bh_enable
+ bash-1994 1dN.2 82us : idle_cpu <-irq_exit
+ bash-1994 1dN.2 83us : rcu_irq_exit <-irq_exit
+ bash-1994 1dN.2 83us : sub_preempt_count <-irq_exit
+ bash-1994 1.N.1 84us : _raw_spin_unlock_irqrestore <-task_rq_unlock
+ bash-1994 1.N.1 84us+: trace_preempt_on <-task_rq_unlock
+ bash-1994 1.N.1 104us : <stack trace>
+ => sub_preempt_count
+ => _raw_spin_unlock_irqrestore
+ => task_rq_unlock
+ => wake_up_new_task
+ => do_fork
+ => sys_clone
+ => stub_clone
+
+
+The above is an example of the preemptoff trace with
+function-trace set. Here we see that interrupts were not disabled
+the entire time. The irq_enter code lets us know that we entered
+an interrupt 'h'. Before that, the functions being traced still
+show that it is not in an interrupt, but we can see from the
+functions themselves that this is not the case.
+
+preemptirqsoff
+--------------
+
+Knowing the locations that have interrupts disabled or
+preemption disabled for the longest times is helpful. But
+sometimes we would like to know when either preemption and/or
+interrupts are disabled.
+
+Consider the following code::
+
+ local_irq_disable();
+ call_function_with_irqs_off();
+ preempt_disable();
+ call_function_with_irqs_and_preemption_off();
+ local_irq_enable();
+ call_function_with_preemption_off();
+ preempt_enable();
+
+The irqsoff tracer will record the total length of
+call_function_with_irqs_off() and
+call_function_with_irqs_and_preemption_off().
+
+The preemptoff tracer will record the total length of
+call_function_with_irqs_and_preemption_off() and
+call_function_with_preemption_off().
+
+But neither will trace the time that interrupts and/or
+preemption is disabled. This total time is the time that we can
+not schedule. To record this time, use the preemptirqsoff
+tracer.
+
+Again, using this trace is much like the irqsoff and preemptoff
+tracers.
+::
+
+ # echo 0 > options/function-trace
+ # echo preemptirqsoff > current_tracer
+ # echo 1 > tracing_on
+ # echo 0 > tracing_max_latency
+ # ls -ltr
+ [...]
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: preemptirqsoff
+ #
+ # preemptirqsoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 100 us, #4/4, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: ls-2230 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: ata_scsi_queuecmd
+ # => ended at: ata_scsi_queuecmd
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ ls-2230 3d... 0us+: _raw_spin_lock_irqsave <-ata_scsi_queuecmd
+ ls-2230 3...1 100us : _raw_spin_unlock_irqrestore <-ata_scsi_queuecmd
+ ls-2230 3...1 101us+: trace_preempt_on <-ata_scsi_queuecmd
+ ls-2230 3...1 111us : <stack trace>
+ => sub_preempt_count
+ => _raw_spin_unlock_irqrestore
+ => ata_scsi_queuecmd
+ => scsi_dispatch_cmd
+ => scsi_request_fn
+ => __blk_run_queue_uncond
+ => __blk_run_queue
+ => blk_queue_bio
+ => submit_bio_noacct
+ => submit_bio
+ => submit_bh
+ => ext3_bread
+ => ext3_dir_bread
+ => htree_dirblock_to_tree
+ => ext3_htree_fill_tree
+ => ext3_readdir
+ => vfs_readdir
+ => sys_getdents
+ => system_call_fastpath
+
+
+The trace_hardirqs_off_thunk is called from assembly on x86 when
+interrupts are disabled in the assembly code. Without the
+function tracing, we do not know if interrupts were enabled
+within the preemption points. We do see that it started with
+preemption enabled.
+
+Here is a trace with function-trace set::
+
+ # tracer: preemptirqsoff
+ #
+ # preemptirqsoff latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 161 us, #339/339, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: ls-2269 (uid:0 nice:0 policy:0 rt_prio:0)
+ # -----------------
+ # => started at: schedule
+ # => ended at: mutex_unlock
+ #
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ kworker/-59 3...1 0us : __schedule <-schedule
+ kworker/-59 3d..1 0us : rcu_preempt_qs <-rcu_note_context_switch
+ kworker/-59 3d..1 1us : add_preempt_count <-_raw_spin_lock_irq
+ kworker/-59 3d..2 1us : deactivate_task <-__schedule
+ kworker/-59 3d..2 1us : dequeue_task <-deactivate_task
+ kworker/-59 3d..2 2us : update_rq_clock <-dequeue_task
+ kworker/-59 3d..2 2us : dequeue_task_fair <-dequeue_task
+ kworker/-59 3d..2 2us : update_curr <-dequeue_task_fair
+ kworker/-59 3d..2 2us : update_min_vruntime <-update_curr
+ kworker/-59 3d..2 3us : cpuacct_charge <-update_curr
+ kworker/-59 3d..2 3us : __rcu_read_lock <-cpuacct_charge
+ kworker/-59 3d..2 3us : __rcu_read_unlock <-cpuacct_charge
+ kworker/-59 3d..2 3us : update_cfs_rq_blocked_load <-dequeue_task_fair
+ kworker/-59 3d..2 4us : clear_buddies <-dequeue_task_fair
+ kworker/-59 3d..2 4us : account_entity_dequeue <-dequeue_task_fair
+ kworker/-59 3d..2 4us : update_min_vruntime <-dequeue_task_fair
+ kworker/-59 3d..2 4us : update_cfs_shares <-dequeue_task_fair
+ kworker/-59 3d..2 5us : hrtick_update <-dequeue_task_fair
+ kworker/-59 3d..2 5us : wq_worker_sleeping <-__schedule
+ kworker/-59 3d..2 5us : kthread_data <-wq_worker_sleeping
+ kworker/-59 3d..2 5us : put_prev_task_fair <-__schedule
+ kworker/-59 3d..2 6us : pick_next_task_fair <-pick_next_task
+ kworker/-59 3d..2 6us : clear_buddies <-pick_next_task_fair
+ kworker/-59 3d..2 6us : set_next_entity <-pick_next_task_fair
+ kworker/-59 3d..2 6us : update_stats_wait_end <-set_next_entity
+ ls-2269 3d..2 7us : finish_task_switch <-__schedule
+ ls-2269 3d..2 7us : _raw_spin_unlock_irq <-finish_task_switch
+ ls-2269 3d..2 8us : do_IRQ <-ret_from_intr
+ ls-2269 3d..2 8us : irq_enter <-do_IRQ
+ ls-2269 3d..2 8us : rcu_irq_enter <-irq_enter
+ ls-2269 3d..2 9us : add_preempt_count <-irq_enter
+ ls-2269 3d.h2 9us : exit_idle <-do_IRQ
+ [...]
+ ls-2269 3d.h3 20us : sub_preempt_count <-_raw_spin_unlock
+ ls-2269 3d.h2 20us : irq_exit <-do_IRQ
+ ls-2269 3d.h2 21us : sub_preempt_count <-irq_exit
+ ls-2269 3d..3 21us : do_softirq <-irq_exit
+ ls-2269 3d..3 21us : __do_softirq <-call_softirq
+ ls-2269 3d..3 21us+: __local_bh_disable <-__do_softirq
+ ls-2269 3d.s4 29us : sub_preempt_count <-_local_bh_enable_ip
+ ls-2269 3d.s5 29us : sub_preempt_count <-_local_bh_enable_ip
+ ls-2269 3d.s5 31us : do_IRQ <-ret_from_intr
+ ls-2269 3d.s5 31us : irq_enter <-do_IRQ
+ ls-2269 3d.s5 31us : rcu_irq_enter <-irq_enter
+ [...]
+ ls-2269 3d.s5 31us : rcu_irq_enter <-irq_enter
+ ls-2269 3d.s5 32us : add_preempt_count <-irq_enter
+ ls-2269 3d.H5 32us : exit_idle <-do_IRQ
+ ls-2269 3d.H5 32us : handle_irq <-do_IRQ
+ ls-2269 3d.H5 32us : irq_to_desc <-handle_irq
+ ls-2269 3d.H5 33us : handle_fasteoi_irq <-handle_irq
+ [...]
+ ls-2269 3d.s5 158us : _raw_spin_unlock_irqrestore <-rtl8139_poll
+ ls-2269 3d.s3 158us : net_rps_action_and_irq_enable.isra.65 <-net_rx_action
+ ls-2269 3d.s3 159us : __local_bh_enable <-__do_softirq
+ ls-2269 3d.s3 159us : sub_preempt_count <-__local_bh_enable
+ ls-2269 3d..3 159us : idle_cpu <-irq_exit
+ ls-2269 3d..3 159us : rcu_irq_exit <-irq_exit
+ ls-2269 3d..3 160us : sub_preempt_count <-irq_exit
+ ls-2269 3d... 161us : __mutex_unlock_slowpath <-mutex_unlock
+ ls-2269 3d... 162us+: trace_hardirqs_on <-mutex_unlock
+ ls-2269 3d... 186us : <stack trace>
+ => __mutex_unlock_slowpath
+ => mutex_unlock
+ => process_output
+ => n_tty_write
+ => tty_write
+ => vfs_write
+ => sys_write
+ => system_call_fastpath
+
+This is an interesting trace. It started with kworker running and
+scheduling out and ls taking over. But as soon as ls released the
+rq lock and enabled interrupts (but not preemption) an interrupt
+triggered. When the interrupt finished, it started running softirqs.
+But while the softirq was running, another interrupt triggered.
+When an interrupt is running inside a softirq, the annotation is 'H'.
+
+
+wakeup
+------
+
+One common case that people are interested in tracing is the
+time it takes for a task that is woken to actually wake up.
+Now for non Real-Time tasks, this can be arbitrary. But tracing
+it none the less can be interesting.
+
+Without function tracing::
+
+ # echo 0 > options/function-trace
+ # echo wakeup > current_tracer
+ # echo 1 > tracing_on
+ # echo 0 > tracing_max_latency
+ # chrt -f 5 sleep 1
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: wakeup
+ #
+ # wakeup latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 15 us, #4/4, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: kworker/3:1H-312 (uid:0 nice:-20 policy:0 rt_prio:0)
+ # -----------------
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ <idle>-0 3dNs7 0us : 0:120:R + [003] 312:100:R kworker/3:1H
+ <idle>-0 3dNs7 1us+: ttwu_do_activate.constprop.87 <-try_to_wake_up
+ <idle>-0 3d..3 15us : __schedule <-schedule
+ <idle>-0 3d..3 15us : 0:120:R ==> [003] 312:100:R kworker/3:1H
+
+The tracer only traces the highest priority task in the system
+to avoid tracing the normal circumstances. Here we see that
+the kworker with a nice priority of -20 (not very nice), took
+just 15 microseconds from the time it woke up, to the time it
+ran.
+
+Non Real-Time tasks are not that interesting. A more interesting
+trace is to concentrate only on Real-Time tasks.
+
+wakeup_rt
+---------
+
+In a Real-Time environment it is very important to know the
+wakeup time it takes for the highest priority task that is woken
+up to the time that it executes. This is also known as "schedule
+latency". I stress the point that this is about RT tasks. It is
+also important to know the scheduling latency of non-RT tasks,
+but the average schedule latency is better for non-RT tasks.
+Tools like LatencyTop are more appropriate for such
+measurements.
+
+Real-Time environments are interested in the worst case latency.
+That is the longest latency it takes for something to happen,
+and not the average. We can have a very fast scheduler that may
+only have a large latency once in a while, but that would not
+work well with Real-Time tasks. The wakeup_rt tracer was designed
+to record the worst case wakeups of RT tasks. Non-RT tasks are
+not recorded because the tracer only records one worst case and
+tracing non-RT tasks that are unpredictable will overwrite the
+worst case latency of RT tasks (just run the normal wakeup
+tracer for a while to see that effect).
+
+Since this tracer only deals with RT tasks, we will run this
+slightly differently than we did with the previous tracers.
+Instead of performing an 'ls', we will run 'sleep 1' under
+'chrt' which changes the priority of the task.
+::
+
+ # echo 0 > options/function-trace
+ # echo wakeup_rt > current_tracer
+ # echo 1 > tracing_on
+ # echo 0 > tracing_max_latency
+ # chrt -f 5 sleep 1
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: wakeup
+ #
+ # tracer: wakeup_rt
+ #
+ # wakeup_rt latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 5 us, #4/4, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: sleep-2389 (uid:0 nice:0 policy:1 rt_prio:5)
+ # -----------------
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ <idle>-0 3d.h4 0us : 0:120:R + [003] 2389: 94:R sleep
+ <idle>-0 3d.h4 1us+: ttwu_do_activate.constprop.87 <-try_to_wake_up
+ <idle>-0 3d..3 5us : __schedule <-schedule
+ <idle>-0 3d..3 5us : 0:120:R ==> [003] 2389: 94:R sleep
+
+
+Running this on an idle system, we see that it only took 5 microseconds
+to perform the task switch. Note, since the trace point in the schedule
+is before the actual "switch", we stop the tracing when the recorded task
+is about to schedule in. This may change if we add a new marker at the
+end of the scheduler.
+
+Notice that the recorded task is 'sleep' with the PID of 2389
+and it has an rt_prio of 5. This priority is user-space priority
+and not the internal kernel priority. The policy is 1 for
+SCHED_FIFO and 2 for SCHED_RR.
+
+Note, that the trace data shows the internal priority (99 - rtprio).
+::
+
+ <idle>-0 3d..3 5us : 0:120:R ==> [003] 2389: 94:R sleep
+
+The 0:120:R means idle was running with a nice priority of 0 (120 - 120)
+and in the running state 'R'. The sleep task was scheduled in with
+2389: 94:R. That is the priority is the kernel rtprio (99 - 5 = 94)
+and it too is in the running state.
+
+Doing the same with chrt -r 5 and function-trace set.
+::
+
+ echo 1 > options/function-trace
+
+ # tracer: wakeup_rt
+ #
+ # wakeup_rt latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 29 us, #85/85, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: sleep-2448 (uid:0 nice:0 policy:1 rt_prio:5)
+ # -----------------
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ <idle>-0 3d.h4 1us+: 0:120:R + [003] 2448: 94:R sleep
+ <idle>-0 3d.h4 2us : ttwu_do_activate.constprop.87 <-try_to_wake_up
+ <idle>-0 3d.h3 3us : check_preempt_curr <-ttwu_do_wakeup
+ <idle>-0 3d.h3 3us : resched_curr <-check_preempt_curr
+ <idle>-0 3dNh3 4us : task_woken_rt <-ttwu_do_wakeup
+ <idle>-0 3dNh3 4us : _raw_spin_unlock <-try_to_wake_up
+ <idle>-0 3dNh3 4us : sub_preempt_count <-_raw_spin_unlock
+ <idle>-0 3dNh2 5us : ttwu_stat <-try_to_wake_up
+ <idle>-0 3dNh2 5us : _raw_spin_unlock_irqrestore <-try_to_wake_up
+ <idle>-0 3dNh2 6us : sub_preempt_count <-_raw_spin_unlock_irqrestore
+ <idle>-0 3dNh1 6us : _raw_spin_lock <-__run_hrtimer
+ <idle>-0 3dNh1 6us : add_preempt_count <-_raw_spin_lock
+ <idle>-0 3dNh2 7us : _raw_spin_unlock <-hrtimer_interrupt
+ <idle>-0 3dNh2 7us : sub_preempt_count <-_raw_spin_unlock
+ <idle>-0 3dNh1 7us : tick_program_event <-hrtimer_interrupt
+ <idle>-0 3dNh1 7us : clockevents_program_event <-tick_program_event
+ <idle>-0 3dNh1 8us : ktime_get <-clockevents_program_event
+ <idle>-0 3dNh1 8us : lapic_next_event <-clockevents_program_event
+ <idle>-0 3dNh1 8us : irq_exit <-smp_apic_timer_interrupt
+ <idle>-0 3dNh1 9us : sub_preempt_count <-irq_exit
+ <idle>-0 3dN.2 9us : idle_cpu <-irq_exit
+ <idle>-0 3dN.2 9us : rcu_irq_exit <-irq_exit
+ <idle>-0 3dN.2 10us : rcu_eqs_enter_common.isra.45 <-rcu_irq_exit
+ <idle>-0 3dN.2 10us : sub_preempt_count <-irq_exit
+ <idle>-0 3.N.1 11us : rcu_idle_exit <-cpu_idle
+ <idle>-0 3dN.1 11us : rcu_eqs_exit_common.isra.43 <-rcu_idle_exit
+ <idle>-0 3.N.1 11us : tick_nohz_idle_exit <-cpu_idle
+ <idle>-0 3dN.1 12us : menu_hrtimer_cancel <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 12us : ktime_get <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 12us : tick_do_update_jiffies64 <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 13us : cpu_load_update_nohz <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 13us : _raw_spin_lock <-cpu_load_update_nohz
+ <idle>-0 3dN.1 13us : add_preempt_count <-_raw_spin_lock
+ <idle>-0 3dN.2 13us : __cpu_load_update <-cpu_load_update_nohz
+ <idle>-0 3dN.2 14us : sched_avg_update <-__cpu_load_update
+ <idle>-0 3dN.2 14us : _raw_spin_unlock <-cpu_load_update_nohz
+ <idle>-0 3dN.2 14us : sub_preempt_count <-_raw_spin_unlock
+ <idle>-0 3dN.1 15us : calc_load_nohz_stop <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 15us : touch_softlockup_watchdog <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 15us : hrtimer_cancel <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 15us : hrtimer_try_to_cancel <-hrtimer_cancel
+ <idle>-0 3dN.1 16us : lock_hrtimer_base.isra.18 <-hrtimer_try_to_cancel
+ <idle>-0 3dN.1 16us : _raw_spin_lock_irqsave <-lock_hrtimer_base.isra.18
+ <idle>-0 3dN.1 16us : add_preempt_count <-_raw_spin_lock_irqsave
+ <idle>-0 3dN.2 17us : __remove_hrtimer <-remove_hrtimer.part.16
+ <idle>-0 3dN.2 17us : hrtimer_force_reprogram <-__remove_hrtimer
+ <idle>-0 3dN.2 17us : tick_program_event <-hrtimer_force_reprogram
+ <idle>-0 3dN.2 18us : clockevents_program_event <-tick_program_event
+ <idle>-0 3dN.2 18us : ktime_get <-clockevents_program_event
+ <idle>-0 3dN.2 18us : lapic_next_event <-clockevents_program_event
+ <idle>-0 3dN.2 19us : _raw_spin_unlock_irqrestore <-hrtimer_try_to_cancel
+ <idle>-0 3dN.2 19us : sub_preempt_count <-_raw_spin_unlock_irqrestore
+ <idle>-0 3dN.1 19us : hrtimer_forward <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 20us : ktime_add_safe <-hrtimer_forward
+ <idle>-0 3dN.1 20us : ktime_add_safe <-hrtimer_forward
+ <idle>-0 3dN.1 20us : hrtimer_start_range_ns <-hrtimer_start_expires.constprop.11
+ <idle>-0 3dN.1 20us : __hrtimer_start_range_ns <-hrtimer_start_range_ns
+ <idle>-0 3dN.1 21us : lock_hrtimer_base.isra.18 <-__hrtimer_start_range_ns
+ <idle>-0 3dN.1 21us : _raw_spin_lock_irqsave <-lock_hrtimer_base.isra.18
+ <idle>-0 3dN.1 21us : add_preempt_count <-_raw_spin_lock_irqsave
+ <idle>-0 3dN.2 22us : ktime_add_safe <-__hrtimer_start_range_ns
+ <idle>-0 3dN.2 22us : enqueue_hrtimer <-__hrtimer_start_range_ns
+ <idle>-0 3dN.2 22us : tick_program_event <-__hrtimer_start_range_ns
+ <idle>-0 3dN.2 23us : clockevents_program_event <-tick_program_event
+ <idle>-0 3dN.2 23us : ktime_get <-clockevents_program_event
+ <idle>-0 3dN.2 23us : lapic_next_event <-clockevents_program_event
+ <idle>-0 3dN.2 24us : _raw_spin_unlock_irqrestore <-__hrtimer_start_range_ns
+ <idle>-0 3dN.2 24us : sub_preempt_count <-_raw_spin_unlock_irqrestore
+ <idle>-0 3dN.1 24us : account_idle_ticks <-tick_nohz_idle_exit
+ <idle>-0 3dN.1 24us : account_idle_time <-account_idle_ticks
+ <idle>-0 3.N.1 25us : sub_preempt_count <-cpu_idle
+ <idle>-0 3.N.. 25us : schedule <-cpu_idle
+ <idle>-0 3.N.. 25us : __schedule <-preempt_schedule
+ <idle>-0 3.N.. 26us : add_preempt_count <-__schedule
+ <idle>-0 3.N.1 26us : rcu_note_context_switch <-__schedule
+ <idle>-0 3.N.1 26us : rcu_sched_qs <-rcu_note_context_switch
+ <idle>-0 3dN.1 27us : rcu_preempt_qs <-rcu_note_context_switch
+ <idle>-0 3.N.1 27us : _raw_spin_lock_irq <-__schedule
+ <idle>-0 3dN.1 27us : add_preempt_count <-_raw_spin_lock_irq
+ <idle>-0 3dN.2 28us : put_prev_task_idle <-__schedule
+ <idle>-0 3dN.2 28us : pick_next_task_stop <-pick_next_task
+ <idle>-0 3dN.2 28us : pick_next_task_rt <-pick_next_task
+ <idle>-0 3dN.2 29us : dequeue_pushable_task <-pick_next_task_rt
+ <idle>-0 3d..3 29us : __schedule <-preempt_schedule
+ <idle>-0 3d..3 30us : 0:120:R ==> [003] 2448: 94:R sleep
+
+This isn't that big of a trace, even with function tracing enabled,
+so I included the entire trace.
+
+The interrupt went off while when the system was idle. Somewhere
+before task_woken_rt() was called, the NEED_RESCHED flag was set,
+this is indicated by the first occurrence of the 'N' flag.
+
+Latency tracing and events
+--------------------------
+As function tracing can induce a much larger latency, but without
+seeing what happens within the latency it is hard to know what
+caused it. There is a middle ground, and that is with enabling
+events.
+::
+
+ # echo 0 > options/function-trace
+ # echo wakeup_rt > current_tracer
+ # echo 1 > events/enable
+ # echo 1 > tracing_on
+ # echo 0 > tracing_max_latency
+ # chrt -f 5 sleep 1
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: wakeup_rt
+ #
+ # wakeup_rt latency trace v1.1.5 on 3.8.0-test+
+ # --------------------------------------------------------------------
+ # latency: 6 us, #12/12, CPU#2 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4)
+ # -----------------
+ # | task: sleep-5882 (uid:0 nice:0 policy:1 rt_prio:5)
+ # -----------------
+ #
+ # _------=> CPU#
+ # / _-----=> irqs-off
+ # | / _----=> need-resched
+ # || / _---=> hardirq/softirq
+ # ||| / _--=> preempt-depth
+ # |||| / delay
+ # cmd pid ||||| time | caller
+ # \ / ||||| \ | /
+ <idle>-0 2d.h4 0us : 0:120:R + [002] 5882: 94:R sleep
+ <idle>-0 2d.h4 0us : ttwu_do_activate.constprop.87 <-try_to_wake_up
+ <idle>-0 2d.h4 1us : sched_wakeup: comm=sleep pid=5882 prio=94 success=1 target_cpu=002
+ <idle>-0 2dNh2 1us : hrtimer_expire_exit: hrtimer=ffff88007796feb8
+ <idle>-0 2.N.2 2us : power_end: cpu_id=2
+ <idle>-0 2.N.2 3us : cpu_idle: state=4294967295 cpu_id=2
+ <idle>-0 2dN.3 4us : hrtimer_cancel: hrtimer=ffff88007d50d5e0
+ <idle>-0 2dN.3 4us : hrtimer_start: hrtimer=ffff88007d50d5e0 function=tick_sched_timer expires=34311211000000 softexpires=34311211000000
+ <idle>-0 2.N.2 5us : rcu_utilization: Start context switch
+ <idle>-0 2.N.2 5us : rcu_utilization: End context switch
+ <idle>-0 2d..3 6us : __schedule <-schedule
+ <idle>-0 2d..3 6us : 0:120:R ==> [002] 5882: 94:R sleep
+
+
+Hardware Latency Detector
+-------------------------
+
+The hardware latency detector is executed by enabling the "hwlat" tracer.
+
+NOTE, this tracer will affect the performance of the system as it will
+periodically make a CPU constantly busy with interrupts disabled.
+::
+
+ # echo hwlat > current_tracer
+ # sleep 100
+ # cat trace
+ # tracer: hwlat
+ #
+ # entries-in-buffer/entries-written: 13/13 #P:8
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ <...>-1729 [001] d... 678.473449: #1 inner/outer(us): 11/12 ts:1581527483.343962693 count:6
+ <...>-1729 [004] d... 689.556542: #2 inner/outer(us): 16/9 ts:1581527494.889008092 count:1
+ <...>-1729 [005] d... 714.756290: #3 inner/outer(us): 16/16 ts:1581527519.678961629 count:5
+ <...>-1729 [001] d... 718.788247: #4 inner/outer(us): 9/17 ts:1581527523.889012713 count:1
+ <...>-1729 [002] d... 719.796341: #5 inner/outer(us): 13/9 ts:1581527524.912872606 count:1
+ <...>-1729 [006] d... 844.787091: #6 inner/outer(us): 9/12 ts:1581527649.889048502 count:2
+ <...>-1729 [003] d... 849.827033: #7 inner/outer(us): 18/9 ts:1581527654.889013793 count:1
+ <...>-1729 [007] d... 853.859002: #8 inner/outer(us): 9/12 ts:1581527658.889065736 count:1
+ <...>-1729 [001] d... 855.874978: #9 inner/outer(us): 9/11 ts:1581527660.861991877 count:1
+ <...>-1729 [001] d... 863.938932: #10 inner/outer(us): 9/11 ts:1581527668.970010500 count:1 nmi-total:7 nmi-count:1
+ <...>-1729 [007] d... 878.050780: #11 inner/outer(us): 9/12 ts:1581527683.385002600 count:1 nmi-total:5 nmi-count:1
+ <...>-1729 [007] d... 886.114702: #12 inner/outer(us): 9/12 ts:1581527691.385001600 count:1
+
+
+The above output is somewhat the same in the header. All events will have
+interrupts disabled 'd'. Under the FUNCTION title there is:
+
+ #1
+ This is the count of events recorded that were greater than the
+ tracing_threshold (See below).
+
+ inner/outer(us): 11/11
+
+ This shows two numbers as "inner latency" and "outer latency". The test
+ runs in a loop checking a timestamp twice. The latency detected within
+ the two timestamps is the "inner latency" and the latency detected
+ after the previous timestamp and the next timestamp in the loop is
+ the "outer latency".
+
+ ts:1581527483.343962693
+
+ The absolute timestamp that the first latency was recorded in the window.
+
+ count:6
+
+ The number of times a latency was detected during the window.
+
+ nmi-total:7 nmi-count:1
+
+ On architectures that support it, if an NMI comes in during the
+ test, the time spent in NMI is reported in "nmi-total" (in
+ microseconds).
+
+ All architectures that have NMIs will show the "nmi-count" if an
+ NMI comes in during the test.
+
+hwlat files:
+
+ tracing_threshold
+ This gets automatically set to "10" to represent 10
+ microseconds. This is the threshold of latency that
+ needs to be detected before the trace will be recorded.
+
+ Note, when hwlat tracer is finished (another tracer is
+ written into "current_tracer"), the original value for
+ tracing_threshold is placed back into this file.
+
+ hwlat_detector/width
+ The length of time the test runs with interrupts disabled.
+
+ hwlat_detector/window
+ The length of time of the window which the test
+ runs. That is, the test will run for "width"
+ microseconds per "window" microseconds
+
+ tracing_cpumask
+ When the test is started. A kernel thread is created that
+ runs the test. This thread will alternate between CPUs
+ listed in the tracing_cpumask between each period
+ (one "window"). To limit the test to specific CPUs
+ set the mask in this file to only the CPUs that the test
+ should run on.
+
+function
+--------
+
+This tracer is the function tracer. Enabling the function tracer
+can be done from the debug file system. Make sure the
+ftrace_enabled is set; otherwise this tracer is a nop.
+See the "ftrace_enabled" section below.
+::
+
+ # sysctl kernel.ftrace_enabled=1
+ # echo function > current_tracer
+ # echo 1 > tracing_on
+ # usleep 1
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 24799/24799 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ bash-1994 [002] .... 3082.063030: mutex_unlock <-rb_simple_write
+ bash-1994 [002] .... 3082.063031: __mutex_unlock_slowpath <-mutex_unlock
+ bash-1994 [002] .... 3082.063031: __fsnotify_parent <-fsnotify_modify
+ bash-1994 [002] .... 3082.063032: fsnotify <-fsnotify_modify
+ bash-1994 [002] .... 3082.063032: __srcu_read_lock <-fsnotify
+ bash-1994 [002] .... 3082.063032: add_preempt_count <-__srcu_read_lock
+ bash-1994 [002] ...1 3082.063032: sub_preempt_count <-__srcu_read_lock
+ bash-1994 [002] .... 3082.063033: __srcu_read_unlock <-fsnotify
+ [...]
+
+
+Note: function tracer uses ring buffers to store the above
+entries. The newest data may overwrite the oldest data.
+Sometimes using echo to stop the trace is not sufficient because
+the tracing could have overwritten the data that you wanted to
+record. For this reason, it is sometimes better to disable
+tracing directly from a program. This allows you to stop the
+tracing at the point that you hit the part that you are
+interested in. To disable the tracing directly from a C program,
+something like following code snippet can be used::
+
+ int trace_fd;
+ [...]
+ int main(int argc, char *argv[]) {
+ [...]
+ trace_fd = open(tracing_file("tracing_on"), O_WRONLY);
+ [...]
+ if (condition_hit()) {
+ write(trace_fd, "0", 1);
+ }
+ [...]
+ }
+
+
+Single thread tracing
+---------------------
+
+By writing into set_ftrace_pid you can trace a
+single thread. For example::
+
+ # cat set_ftrace_pid
+ no pid
+ # echo 3111 > set_ftrace_pid
+ # cat set_ftrace_pid
+ 3111
+ # echo function > current_tracer
+ # cat trace | head
+ # tracer: function
+ #
+ # TASK-PID CPU# TIMESTAMP FUNCTION
+ # | | | | |
+ yum-updatesd-3111 [003] 1637.254676: finish_task_switch <-thread_return
+ yum-updatesd-3111 [003] 1637.254681: hrtimer_cancel <-schedule_hrtimeout_range
+ yum-updatesd-3111 [003] 1637.254682: hrtimer_try_to_cancel <-hrtimer_cancel
+ yum-updatesd-3111 [003] 1637.254683: lock_hrtimer_base <-hrtimer_try_to_cancel
+ yum-updatesd-3111 [003] 1637.254685: fget_light <-do_sys_poll
+ yum-updatesd-3111 [003] 1637.254686: pipe_poll <-do_sys_poll
+ # echo > set_ftrace_pid
+ # cat trace |head
+ # tracer: function
+ #
+ # TASK-PID CPU# TIMESTAMP FUNCTION
+ # | | | | |
+ ##### CPU 3 buffer started ####
+ yum-updatesd-3111 [003] 1701.957688: free_poll_entry <-poll_freewait
+ yum-updatesd-3111 [003] 1701.957689: remove_wait_queue <-free_poll_entry
+ yum-updatesd-3111 [003] 1701.957691: fput <-free_poll_entry
+ yum-updatesd-3111 [003] 1701.957692: audit_syscall_exit <-sysret_audit
+ yum-updatesd-3111 [003] 1701.957693: path_put <-audit_syscall_exit
+
+If you want to trace a function when executing, you could use
+something like this simple program.
+::
+
+ #include <stdio.h>
+ #include <stdlib.h>
+ #include <sys/types.h>
+ #include <sys/stat.h>
+ #include <fcntl.h>
+ #include <unistd.h>
+ #include <string.h>
+
+ #define _STR(x) #x
+ #define STR(x) _STR(x)
+ #define MAX_PATH 256
+
+ const char *find_tracefs(void)
+ {
+ static char tracefs[MAX_PATH+1];
+ static int tracefs_found;
+ char type[100];
+ FILE *fp;
+
+ if (tracefs_found)
+ return tracefs;
+
+ if ((fp = fopen("/proc/mounts","r")) == NULL) {
+ perror("/proc/mounts");
+ return NULL;
+ }
+
+ while (fscanf(fp, "%*s %"
+ STR(MAX_PATH)
+ "s %99s %*s %*d %*d\n",
+ tracefs, type) == 2) {
+ if (strcmp(type, "tracefs") == 0)
+ break;
+ }
+ fclose(fp);
+
+ if (strcmp(type, "tracefs") != 0) {
+ fprintf(stderr, "tracefs not mounted");
+ return NULL;
+ }
+
+ strcat(tracefs, "/tracing/");
+ tracefs_found = 1;
+
+ return tracefs;
+ }
+
+ const char *tracing_file(const char *file_name)
+ {
+ static char trace_file[MAX_PATH+1];
+ snprintf(trace_file, MAX_PATH, "%s/%s", find_tracefs(), file_name);
+ return trace_file;
+ }
+
+ int main (int argc, char **argv)
+ {
+ if (argc < 1)
+ exit(-1);
+
+ if (fork() > 0) {
+ int fd, ffd;
+ char line[64];
+ int s;
+
+ ffd = open(tracing_file("current_tracer"), O_WRONLY);
+ if (ffd < 0)
+ exit(-1);
+ write(ffd, "nop", 3);
+
+ fd = open(tracing_file("set_ftrace_pid"), O_WRONLY);
+ s = sprintf(line, "%d\n", getpid());
+ write(fd, line, s);
+
+ write(ffd, "function", 8);
+
+ close(fd);
+ close(ffd);
+
+ execvp(argv[1], argv+1);
+ }
+
+ return 0;
+ }
+
+Or this simple script!
+::
+
+ #!/bin/bash
+
+ tracefs=`sed -ne 's/^tracefs \(.*\) tracefs.*/\1/p' /proc/mounts`
+ echo 0 > $tracefs/tracing_on
+ echo $$ > $tracefs/set_ftrace_pid
+ echo function > $tracefs/current_tracer
+ echo 1 > $tracefs/tracing_on
+ exec "$@"
+
+
+function graph tracer
+---------------------------
+
+This tracer is similar to the function tracer except that it
+probes a function on its entry and its exit. This is done by
+using a dynamically allocated stack of return addresses in each
+task_struct. On function entry the tracer overwrites the return
+address of each function traced to set a custom probe. Thus the
+original return address is stored on the stack of return address
+in the task_struct.
+
+Probing on both ends of a function leads to special features
+such as:
+
+- measure of a function's time execution
+- having a reliable call stack to draw function calls graph
+
+This tracer is useful in several situations:
+
+- you want to find the reason of a strange kernel behavior and
+ need to see what happens in detail on any areas (or specific
+ ones).
+
+- you are experiencing weird latencies but it's difficult to
+ find its origin.
+
+- you want to find quickly which path is taken by a specific
+ function
+
+- you just want to peek inside a working kernel and want to see
+ what happens there.
+
+::
+
+ # tracer: function_graph
+ #
+ # CPU DURATION FUNCTION CALLS
+ # | | | | | | |
+
+ 0) | sys_open() {
+ 0) | do_sys_open() {
+ 0) | getname() {
+ 0) | kmem_cache_alloc() {
+ 0) 1.382 us | __might_sleep();
+ 0) 2.478 us | }
+ 0) | strncpy_from_user() {
+ 0) | might_fault() {
+ 0) 1.389 us | __might_sleep();
+ 0) 2.553 us | }
+ 0) 3.807 us | }
+ 0) 7.876 us | }
+ 0) | alloc_fd() {
+ 0) 0.668 us | _spin_lock();
+ 0) 0.570 us | expand_files();
+ 0) 0.586 us | _spin_unlock();
+
+
+There are several columns that can be dynamically
+enabled/disabled. You can use every combination of options you
+want, depending on your needs.
+
+- The cpu number on which the function executed is default
+ enabled. It is sometimes better to only trace one cpu (see
+ tracing_cpu_mask file) or you might sometimes see unordered
+ function calls while cpu tracing switch.
+
+ - hide: echo nofuncgraph-cpu > trace_options
+ - show: echo funcgraph-cpu > trace_options
+
+- The duration (function's time of execution) is displayed on
+ the closing bracket line of a function or on the same line
+ than the current function in case of a leaf one. It is default
+ enabled.
+
+ - hide: echo nofuncgraph-duration > trace_options
+ - show: echo funcgraph-duration > trace_options
+
+- The overhead field precedes the duration field in case of
+ reached duration thresholds.
+
+ - hide: echo nofuncgraph-overhead > trace_options
+ - show: echo funcgraph-overhead > trace_options
+ - depends on: funcgraph-duration
+
+ ie::
+
+ 3) # 1837.709 us | } /* __switch_to */
+ 3) | finish_task_switch() {
+ 3) 0.313 us | _raw_spin_unlock_irq();
+ 3) 3.177 us | }
+ 3) # 1889.063 us | } /* __schedule */
+ 3) ! 140.417 us | } /* __schedule */
+ 3) # 2034.948 us | } /* schedule */
+ 3) * 33998.59 us | } /* schedule_preempt_disabled */
+
+ [...]
+
+ 1) 0.260 us | msecs_to_jiffies();
+ 1) 0.313 us | __rcu_read_unlock();
+ 1) + 61.770 us | }
+ 1) + 64.479 us | }
+ 1) 0.313 us | rcu_bh_qs();
+ 1) 0.313 us | __local_bh_enable();
+ 1) ! 217.240 us | }
+ 1) 0.365 us | idle_cpu();
+ 1) | rcu_irq_exit() {
+ 1) 0.417 us | rcu_eqs_enter_common.isra.47();
+ 1) 3.125 us | }
+ 1) ! 227.812 us | }
+ 1) ! 457.395 us | }
+ 1) @ 119760.2 us | }
+
+ [...]
+
+ 2) | handle_IPI() {
+ 1) 6.979 us | }
+ 2) 0.417 us | scheduler_ipi();
+ 1) 9.791 us | }
+ 1) + 12.917 us | }
+ 2) 3.490 us | }
+ 1) + 15.729 us | }
+ 1) + 18.542 us | }
+ 2) $ 3594274 us | }
+
+Flags::
+
+ + means that the function exceeded 10 usecs.
+ ! means that the function exceeded 100 usecs.
+ # means that the function exceeded 1000 usecs.
+ * means that the function exceeded 10 msecs.
+ @ means that the function exceeded 100 msecs.
+ $ means that the function exceeded 1 sec.
+
+
+- The task/pid field displays the thread cmdline and pid which
+ executed the function. It is default disabled.
+
+ - hide: echo nofuncgraph-proc > trace_options
+ - show: echo funcgraph-proc > trace_options
+
+ ie::
+
+ # tracer: function_graph
+ #
+ # CPU TASK/PID DURATION FUNCTION CALLS
+ # | | | | | | | | |
+ 0) sh-4802 | | d_free() {
+ 0) sh-4802 | | call_rcu() {
+ 0) sh-4802 | | __call_rcu() {
+ 0) sh-4802 | 0.616 us | rcu_process_gp_end();
+ 0) sh-4802 | 0.586 us | check_for_new_grace_period();
+ 0) sh-4802 | 2.899 us | }
+ 0) sh-4802 | 4.040 us | }
+ 0) sh-4802 | 5.151 us | }
+ 0) sh-4802 | + 49.370 us | }
+
+
+- The absolute time field is an absolute timestamp given by the
+ system clock since it started. A snapshot of this time is
+ given on each entry/exit of functions
+
+ - hide: echo nofuncgraph-abstime > trace_options
+ - show: echo funcgraph-abstime > trace_options
+
+ ie::
+
+ #
+ # TIME CPU DURATION FUNCTION CALLS
+ # | | | | | | | |
+ 360.774522 | 1) 0.541 us | }
+ 360.774522 | 1) 4.663 us | }
+ 360.774523 | 1) 0.541 us | __wake_up_bit();
+ 360.774524 | 1) 6.796 us | }
+ 360.774524 | 1) 7.952 us | }
+ 360.774525 | 1) 9.063 us | }
+ 360.774525 | 1) 0.615 us | journal_mark_dirty();
+ 360.774527 | 1) 0.578 us | __brelse();
+ 360.774528 | 1) | reiserfs_prepare_for_journal() {
+ 360.774528 | 1) | unlock_buffer() {
+ 360.774529 | 1) | wake_up_bit() {
+ 360.774529 | 1) | bit_waitqueue() {
+ 360.774530 | 1) 0.594 us | __phys_addr();
+
+
+The function name is always displayed after the closing bracket
+for a function if the start of that function is not in the
+trace buffer.
+
+Display of the function name after the closing bracket may be
+enabled for functions whose start is in the trace buffer,
+allowing easier searching with grep for function durations.
+It is default disabled.
+
+ - hide: echo nofuncgraph-tail > trace_options
+ - show: echo funcgraph-tail > trace_options
+
+ Example with nofuncgraph-tail (default)::
+
+ 0) | putname() {
+ 0) | kmem_cache_free() {
+ 0) 0.518 us | __phys_addr();
+ 0) 1.757 us | }
+ 0) 2.861 us | }
+
+ Example with funcgraph-tail::
+
+ 0) | putname() {
+ 0) | kmem_cache_free() {
+ 0) 0.518 us | __phys_addr();
+ 0) 1.757 us | } /* kmem_cache_free() */
+ 0) 2.861 us | } /* putname() */
+
+You can put some comments on specific functions by using
+trace_printk() For example, if you want to put a comment inside
+the __might_sleep() function, you just have to include
+<linux/ftrace.h> and call trace_printk() inside __might_sleep()::
+
+ trace_printk("I'm a comment!\n")
+
+will produce::
+
+ 1) | __might_sleep() {
+ 1) | /* I'm a comment! */
+ 1) 1.449 us | }
+
+
+You might find other useful features for this tracer in the
+following "dynamic ftrace" section such as tracing only specific
+functions or tasks.
+
+dynamic ftrace
+--------------
+
+If CONFIG_DYNAMIC_FTRACE is set, the system will run with
+virtually no overhead when function tracing is disabled. The way
+this works is the mcount function call (placed at the start of
+every kernel function, produced by the -pg switch in gcc),
+starts of pointing to a simple return. (Enabling FTRACE will
+include the -pg switch in the compiling of the kernel.)
+
+At compile time every C file object is run through the
+recordmcount program (located in the scripts directory). This
+program will parse the ELF headers in the C object to find all
+the locations in the .text section that call mcount. Starting
+with gcc version 4.6, the -mfentry has been added for x86, which
+calls "__fentry__" instead of "mcount". Which is called before
+the creation of the stack frame.
+
+Note, not all sections are traced. They may be prevented by either
+a notrace, or blocked another way and all inline functions are not
+traced. Check the "available_filter_functions" file to see what functions
+can be traced.
+
+A section called "__mcount_loc" is created that holds
+references to all the mcount/fentry call sites in the .text section.
+The recordmcount program re-links this section back into the
+original object. The final linking stage of the kernel will add all these
+references into a single table.
+
+On boot up, before SMP is initialized, the dynamic ftrace code
+scans this table and updates all the locations into nops. It
+also records the locations, which are added to the
+available_filter_functions list. Modules are processed as they
+are loaded and before they are executed. When a module is
+unloaded, it also removes its functions from the ftrace function
+list. This is automatic in the module unload code, and the
+module author does not need to worry about it.
+
+When tracing is enabled, the process of modifying the function
+tracepoints is dependent on architecture. The old method is to use
+kstop_machine to prevent races with the CPUs executing code being
+modified (which can cause the CPU to do undesirable things, especially
+if the modified code crosses cache (or page) boundaries), and the nops are
+patched back to calls. But this time, they do not call mcount
+(which is just a function stub). They now call into the ftrace
+infrastructure.
+
+The new method of modifying the function tracepoints is to place
+a breakpoint at the location to be modified, sync all CPUs, modify
+the rest of the instruction not covered by the breakpoint. Sync
+all CPUs again, and then remove the breakpoint with the finished
+version to the ftrace call site.
+
+Some archs do not even need to monkey around with the synchronization,
+and can just slap the new code on top of the old without any
+problems with other CPUs executing it at the same time.
+
+One special side-effect to the recording of the functions being
+traced is that we can now selectively choose which functions we
+wish to trace and which ones we want the mcount calls to remain
+as nops.
+
+Two files are used, one for enabling and one for disabling the
+tracing of specified functions. They are:
+
+ set_ftrace_filter
+
+and
+
+ set_ftrace_notrace
+
+A list of available functions that you can add to these files is
+listed in:
+
+ available_filter_functions
+
+::
+
+ # cat available_filter_functions
+ put_prev_task_idle
+ kmem_cache_create
+ pick_next_task_rt
+ cpus_read_lock
+ pick_next_task_fair
+ mutex_lock
+ [...]
+
+If I am only interested in sys_nanosleep and hrtimer_interrupt::
+
+ # echo sys_nanosleep hrtimer_interrupt > set_ftrace_filter
+ # echo function > current_tracer
+ # echo 1 > tracing_on
+ # usleep 1
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 5/5 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ usleep-2665 [001] .... 4186.475355: sys_nanosleep <-system_call_fastpath
+ <idle>-0 [001] d.h1 4186.475409: hrtimer_interrupt <-smp_apic_timer_interrupt
+ usleep-2665 [001] d.h1 4186.475426: hrtimer_interrupt <-smp_apic_timer_interrupt
+ <idle>-0 [003] d.h1 4186.475426: hrtimer_interrupt <-smp_apic_timer_interrupt
+ <idle>-0 [002] d.h1 4186.475427: hrtimer_interrupt <-smp_apic_timer_interrupt
+
+To see which functions are being traced, you can cat the file:
+::
+
+ # cat set_ftrace_filter
+ hrtimer_interrupt
+ sys_nanosleep
+
+
+Perhaps this is not enough. The filters also allow glob(7) matching.
+
+ ``<match>*``
+ will match functions that begin with <match>
+ ``*<match>``
+ will match functions that end with <match>
+ ``*<match>*``
+ will match functions that have <match> in it
+ ``<match1>*<match2>``
+ will match functions that begin with <match1> and end with <match2>
+
+.. note::
+ It is better to use quotes to enclose the wild cards,
+ otherwise the shell may expand the parameters into names
+ of files in the local directory.
+
+::
+
+ # echo 'hrtimer_*' > set_ftrace_filter
+
+Produces::
+
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 897/897 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ <idle>-0 [003] dN.1 4228.547803: hrtimer_cancel <-tick_nohz_idle_exit
+ <idle>-0 [003] dN.1 4228.547804: hrtimer_try_to_cancel <-hrtimer_cancel
+ <idle>-0 [003] dN.2 4228.547805: hrtimer_force_reprogram <-__remove_hrtimer
+ <idle>-0 [003] dN.1 4228.547805: hrtimer_forward <-tick_nohz_idle_exit
+ <idle>-0 [003] dN.1 4228.547805: hrtimer_start_range_ns <-hrtimer_start_expires.constprop.11
+ <idle>-0 [003] d..1 4228.547858: hrtimer_get_next_event <-get_next_timer_interrupt
+ <idle>-0 [003] d..1 4228.547859: hrtimer_start <-__tick_nohz_idle_enter
+ <idle>-0 [003] d..2 4228.547860: hrtimer_force_reprogram <-__rem
+
+Notice that we lost the sys_nanosleep.
+::
+
+ # cat set_ftrace_filter
+ hrtimer_run_queues
+ hrtimer_run_pending
+ hrtimer_init
+ hrtimer_cancel
+ hrtimer_try_to_cancel
+ hrtimer_forward
+ hrtimer_start
+ hrtimer_reprogram
+ hrtimer_force_reprogram
+ hrtimer_get_next_event
+ hrtimer_interrupt
+ hrtimer_nanosleep
+ hrtimer_wakeup
+ hrtimer_get_remaining
+ hrtimer_get_res
+ hrtimer_init_sleeper
+
+
+This is because the '>' and '>>' act just like they do in bash.
+To rewrite the filters, use '>'
+To append to the filters, use '>>'
+
+To clear out a filter so that all functions will be recorded
+again::
+
+ # echo > set_ftrace_filter
+ # cat set_ftrace_filter
+ #
+
+Again, now we want to append.
+
+::
+
+ # echo sys_nanosleep > set_ftrace_filter
+ # cat set_ftrace_filter
+ sys_nanosleep
+ # echo 'hrtimer_*' >> set_ftrace_filter
+ # cat set_ftrace_filter
+ hrtimer_run_queues
+ hrtimer_run_pending
+ hrtimer_init
+ hrtimer_cancel
+ hrtimer_try_to_cancel
+ hrtimer_forward
+ hrtimer_start
+ hrtimer_reprogram
+ hrtimer_force_reprogram
+ hrtimer_get_next_event
+ hrtimer_interrupt
+ sys_nanosleep
+ hrtimer_nanosleep
+ hrtimer_wakeup
+ hrtimer_get_remaining
+ hrtimer_get_res
+ hrtimer_init_sleeper
+
+
+The set_ftrace_notrace prevents those functions from being
+traced.
+::
+
+ # echo '*preempt*' '*lock*' > set_ftrace_notrace
+
+Produces::
+
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 39608/39608 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ bash-1994 [000] .... 4342.324896: file_ra_state_init <-do_dentry_open
+ bash-1994 [000] .... 4342.324897: open_check_o_direct <-do_last
+ bash-1994 [000] .... 4342.324897: ima_file_check <-do_last
+ bash-1994 [000] .... 4342.324898: process_measurement <-ima_file_check
+ bash-1994 [000] .... 4342.324898: ima_get_action <-process_measurement
+ bash-1994 [000] .... 4342.324898: ima_match_policy <-ima_get_action
+ bash-1994 [000] .... 4342.324899: do_truncate <-do_last
+ bash-1994 [000] .... 4342.324899: setattr_should_drop_suidgid <-do_truncate
+ bash-1994 [000] .... 4342.324899: notify_change <-do_truncate
+ bash-1994 [000] .... 4342.324900: current_fs_time <-notify_change
+ bash-1994 [000] .... 4342.324900: current_kernel_time <-current_fs_time
+ bash-1994 [000] .... 4342.324900: timespec_trunc <-current_fs_time
+
+We can see that there's no more lock or preempt tracing.
+
+Selecting function filters via index
+------------------------------------
+
+Because processing of strings is expensive (the address of the function
+needs to be looked up before comparing to the string being passed in),
+an index can be used as well to enable functions. This is useful in the
+case of setting thousands of specific functions at a time. By passing
+in a list of numbers, no string processing will occur. Instead, the function
+at the specific location in the internal array (which corresponds to the
+functions in the "available_filter_functions" file), is selected.
+
+::
+
+ # echo 1 > set_ftrace_filter
+
+Will select the first function listed in "available_filter_functions"
+
+::
+
+ # head -1 available_filter_functions
+ trace_initcall_finish_cb
+
+ # cat set_ftrace_filter
+ trace_initcall_finish_cb
+
+ # head -50 available_filter_functions | tail -1
+ x86_pmu_commit_txn
+
+ # echo 1 50 > set_ftrace_filter
+ # cat set_ftrace_filter
+ trace_initcall_finish_cb
+ x86_pmu_commit_txn
+
+Dynamic ftrace with the function graph tracer
+---------------------------------------------
+
+Although what has been explained above concerns both the
+function tracer and the function-graph-tracer, there are some
+special features only available in the function-graph tracer.
+
+If you want to trace only one function and all of its children,
+you just have to echo its name into set_graph_function::
+
+ echo __do_fault > set_graph_function
+
+will produce the following "expanded" trace of the __do_fault()
+function::
+
+ 0) | __do_fault() {
+ 0) | filemap_fault() {
+ 0) | find_lock_page() {
+ 0) 0.804 us | find_get_page();
+ 0) | __might_sleep() {
+ 0) 1.329 us | }
+ 0) 3.904 us | }
+ 0) 4.979 us | }
+ 0) 0.653 us | _spin_lock();
+ 0) 0.578 us | page_add_file_rmap();
+ 0) 0.525 us | native_set_pte_at();
+ 0) 0.585 us | _spin_unlock();
+ 0) | unlock_page() {
+ 0) 0.541 us | page_waitqueue();
+ 0) 0.639 us | __wake_up_bit();
+ 0) 2.786 us | }
+ 0) + 14.237 us | }
+ 0) | __do_fault() {
+ 0) | filemap_fault() {
+ 0) | find_lock_page() {
+ 0) 0.698 us | find_get_page();
+ 0) | __might_sleep() {
+ 0) 1.412 us | }
+ 0) 3.950 us | }
+ 0) 5.098 us | }
+ 0) 0.631 us | _spin_lock();
+ 0) 0.571 us | page_add_file_rmap();
+ 0) 0.526 us | native_set_pte_at();
+ 0) 0.586 us | _spin_unlock();
+ 0) | unlock_page() {
+ 0) 0.533 us | page_waitqueue();
+ 0) 0.638 us | __wake_up_bit();
+ 0) 2.793 us | }
+ 0) + 14.012 us | }
+
+You can also expand several functions at once::
+
+ echo sys_open > set_graph_function
+ echo sys_close >> set_graph_function
+
+Now if you want to go back to trace all functions you can clear
+this special filter via::
+
+ echo > set_graph_function
+
+
+ftrace_enabled
+--------------
+
+Note, the proc sysctl ftrace_enable is a big on/off switch for the
+function tracer. By default it is enabled (when function tracing is
+enabled in the kernel). If it is disabled, all function tracing is
+disabled. This includes not only the function tracers for ftrace, but
+also for any other uses (perf, kprobes, stack tracing, profiling, etc). It
+cannot be disabled if there is a callback with FTRACE_OPS_FL_PERMANENT set
+registered.
+
+Please disable this with care.
+
+This can be disable (and enabled) with::
+
+ sysctl kernel.ftrace_enabled=0
+ sysctl kernel.ftrace_enabled=1
+
+ or
+
+ echo 0 > /proc/sys/kernel/ftrace_enabled
+ echo 1 > /proc/sys/kernel/ftrace_enabled
+
+
+Filter commands
+---------------
+
+A few commands are supported by the set_ftrace_filter interface.
+Trace commands have the following format::
+
+ <function>:<command>:<parameter>
+
+The following commands are supported:
+
+- mod:
+ This command enables function filtering per module. The
+ parameter defines the module. For example, if only the write*
+ functions in the ext3 module are desired, run:
+
+ echo 'write*:mod:ext3' > set_ftrace_filter
+
+ This command interacts with the filter in the same way as
+ filtering based on function names. Thus, adding more functions
+ in a different module is accomplished by appending (>>) to the
+ filter file. Remove specific module functions by prepending
+ '!'::
+
+ echo '!writeback*:mod:ext3' >> set_ftrace_filter
+
+ Mod command supports module globbing. Disable tracing for all
+ functions except a specific module::
+
+ echo '!*:mod:!ext3' >> set_ftrace_filter
+
+ Disable tracing for all modules, but still trace kernel::
+
+ echo '!*:mod:*' >> set_ftrace_filter
+
+ Enable filter only for kernel::
+
+ echo '*write*:mod:!*' >> set_ftrace_filter
+
+ Enable filter for module globbing::
+
+ echo '*write*:mod:*snd*' >> set_ftrace_filter
+
+- traceon/traceoff:
+ These commands turn tracing on and off when the specified
+ functions are hit. The parameter determines how many times the
+ tracing system is turned on and off. If unspecified, there is
+ no limit. For example, to disable tracing when a schedule bug
+ is hit the first 5 times, run::
+
+ echo '__schedule_bug:traceoff:5' > set_ftrace_filter
+
+ To always disable tracing when __schedule_bug is hit::
+
+ echo '__schedule_bug:traceoff' > set_ftrace_filter
+
+ These commands are cumulative whether or not they are appended
+ to set_ftrace_filter. To remove a command, prepend it by '!'
+ and drop the parameter::
+
+ echo '!__schedule_bug:traceoff:0' > set_ftrace_filter
+
+ The above removes the traceoff command for __schedule_bug
+ that have a counter. To remove commands without counters::
+
+ echo '!__schedule_bug:traceoff' > set_ftrace_filter
+
+- snapshot:
+ Will cause a snapshot to be triggered when the function is hit.
+ ::
+
+ echo 'native_flush_tlb_others:snapshot' > set_ftrace_filter
+
+ To only snapshot once:
+ ::
+
+ echo 'native_flush_tlb_others:snapshot:1' > set_ftrace_filter
+
+ To remove the above commands::
+
+ echo '!native_flush_tlb_others:snapshot' > set_ftrace_filter
+ echo '!native_flush_tlb_others:snapshot:0' > set_ftrace_filter
+
+- enable_event/disable_event:
+ These commands can enable or disable a trace event. Note, because
+ function tracing callbacks are very sensitive, when these commands
+ are registered, the trace point is activated, but disabled in
+ a "soft" mode. That is, the tracepoint will be called, but
+ just will not be traced. The event tracepoint stays in this mode
+ as long as there's a command that triggers it.
+ ::
+
+ echo 'try_to_wake_up:enable_event:sched:sched_switch:2' > \
+ set_ftrace_filter
+
+ The format is::
+
+ <function>:enable_event:<system>:<event>[:count]
+ <function>:disable_event:<system>:<event>[:count]
+
+ To remove the events commands::
+
+ echo '!try_to_wake_up:enable_event:sched:sched_switch:0' > \
+ set_ftrace_filter
+ echo '!schedule:disable_event:sched:sched_switch' > \
+ set_ftrace_filter
+
+- dump:
+ When the function is hit, it will dump the contents of the ftrace
+ ring buffer to the console. This is useful if you need to debug
+ something, and want to dump the trace when a certain function
+ is hit. Perhaps it's a function that is called before a triple
+ fault happens and does not allow you to get a regular dump.
+
+- cpudump:
+ When the function is hit, it will dump the contents of the ftrace
+ ring buffer for the current CPU to the console. Unlike the "dump"
+ command, it only prints out the contents of the ring buffer for the
+ CPU that executed the function that triggered the dump.
+
+- stacktrace:
+ When the function is hit, a stack trace is recorded.
+
+trace_pipe
+----------
+
+The trace_pipe outputs the same content as the trace file, but
+the effect on the tracing is different. Every read from
+trace_pipe is consumed. This means that subsequent reads will be
+different. The trace is live.
+::
+
+ # echo function > current_tracer
+ # cat trace_pipe > /tmp/trace.out &
+ [1] 4153
+ # echo 1 > tracing_on
+ # usleep 1
+ # echo 0 > tracing_on
+ # cat trace
+ # tracer: function
+ #
+ # entries-in-buffer/entries-written: 0/0 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+
+ #
+ # cat /tmp/trace.out
+ bash-1994 [000] .... 5281.568961: mutex_unlock <-rb_simple_write
+ bash-1994 [000] .... 5281.568963: __mutex_unlock_slowpath <-mutex_unlock
+ bash-1994 [000] .... 5281.568963: __fsnotify_parent <-fsnotify_modify
+ bash-1994 [000] .... 5281.568964: fsnotify <-fsnotify_modify
+ bash-1994 [000] .... 5281.568964: __srcu_read_lock <-fsnotify
+ bash-1994 [000] .... 5281.568964: add_preempt_count <-__srcu_read_lock
+ bash-1994 [000] ...1 5281.568965: sub_preempt_count <-__srcu_read_lock
+ bash-1994 [000] .... 5281.568965: __srcu_read_unlock <-fsnotify
+ bash-1994 [000] .... 5281.568967: sys_dup2 <-system_call_fastpath
+
+
+Note, reading the trace_pipe file will block until more input is
+added. This is contrary to the trace file. If any process opened
+the trace file for reading, it will actually disable tracing and
+prevent new entries from being added. The trace_pipe file does
+not have this limitation.
+
+trace entries
+-------------
+
+Having too much or not enough data can be troublesome in
+diagnosing an issue in the kernel. The file buffer_size_kb is
+used to modify the size of the internal trace buffers. The
+number listed is the number of entries that can be recorded per
+CPU. To know the full size, multiply the number of possible CPUs
+with the number of entries.
+::
+
+ # cat buffer_size_kb
+ 1408 (units kilobytes)
+
+Or simply read buffer_total_size_kb
+::
+
+ # cat buffer_total_size_kb
+ 5632
+
+To modify the buffer, simple echo in a number (in 1024 byte segments).
+::
+
+ # echo 10000 > buffer_size_kb
+ # cat buffer_size_kb
+ 10000 (units kilobytes)
+
+It will try to allocate as much as possible. If you allocate too
+much, it can cause Out-Of-Memory to trigger.
+::
+
+ # echo 1000000000000 > buffer_size_kb
+ -bash: echo: write error: Cannot allocate memory
+ # cat buffer_size_kb
+ 85
+
+The per_cpu buffers can be changed individually as well:
+::
+
+ # echo 10000 > per_cpu/cpu0/buffer_size_kb
+ # echo 100 > per_cpu/cpu1/buffer_size_kb
+
+When the per_cpu buffers are not the same, the buffer_size_kb
+at the top level will just show an X
+::
+
+ # cat buffer_size_kb
+ X
+
+This is where the buffer_total_size_kb is useful:
+::
+
+ # cat buffer_total_size_kb
+ 12916
+
+Writing to the top level buffer_size_kb will reset all the buffers
+to be the same again.
+
+Snapshot
+--------
+CONFIG_TRACER_SNAPSHOT makes a generic snapshot feature
+available to all non latency tracers. (Latency tracers which
+record max latency, such as "irqsoff" or "wakeup", can't use
+this feature, since those are already using the snapshot
+mechanism internally.)
+
+Snapshot preserves a current trace buffer at a particular point
+in time without stopping tracing. Ftrace swaps the current
+buffer with a spare buffer, and tracing continues in the new
+current (=previous spare) buffer.
+
+The following tracefs files in "tracing" are related to this
+feature:
+
+ snapshot:
+
+ This is used to take a snapshot and to read the output
+ of the snapshot. Echo 1 into this file to allocate a
+ spare buffer and to take a snapshot (swap), then read
+ the snapshot from this file in the same format as
+ "trace" (described above in the section "The File
+ System"). Both reads snapshot and tracing are executable
+ in parallel. When the spare buffer is allocated, echoing
+ 0 frees it, and echoing else (positive) values clear the
+ snapshot contents.
+ More details are shown in the table below.
+
+ +--------------+------------+------------+------------+
+ |status\\input | 0 | 1 | else |
+ +==============+============+============+============+
+ |not allocated |(do nothing)| alloc+swap |(do nothing)|
+ +--------------+------------+------------+------------+
+ |allocated | free | swap | clear |
+ +--------------+------------+------------+------------+
+
+Here is an example of using the snapshot feature.
+::
+
+ # echo 1 > events/sched/enable
+ # echo 1 > snapshot
+ # cat snapshot
+ # tracer: nop
+ #
+ # entries-in-buffer/entries-written: 71/71 #P:8
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ <idle>-0 [005] d... 2440.603828: sched_switch: prev_comm=swapper/5 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=snapshot-test-2 next_pid=2242 next_prio=120
+ sleep-2242 [005] d... 2440.603846: sched_switch: prev_comm=snapshot-test-2 prev_pid=2242 prev_prio=120 prev_state=R ==> next_comm=kworker/5:1 next_pid=60 next_prio=120
+ [...]
+ <idle>-0 [002] d... 2440.707230: sched_switch: prev_comm=swapper/2 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=snapshot-test-2 next_pid=2229 next_prio=120
+
+ # cat trace
+ # tracer: nop
+ #
+ # entries-in-buffer/entries-written: 77/77 #P:8
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ <idle>-0 [007] d... 2440.707395: sched_switch: prev_comm=swapper/7 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=snapshot-test-2 next_pid=2243 next_prio=120
+ snapshot-test-2-2229 [002] d... 2440.707438: sched_switch: prev_comm=snapshot-test-2 prev_pid=2229 prev_prio=120 prev_state=S ==> next_comm=swapper/2 next_pid=0 next_prio=120
+ [...]
+
+
+If you try to use this snapshot feature when current tracer is
+one of the latency tracers, you will get the following results.
+::
+
+ # echo wakeup > current_tracer
+ # echo 1 > snapshot
+ bash: echo: write error: Device or resource busy
+ # cat snapshot
+ cat: snapshot: Device or resource busy
+
+
+Instances
+---------
+In the tracefs tracing directory, there is a directory called "instances".
+This directory can have new directories created inside of it using
+mkdir, and removing directories with rmdir. The directory created
+with mkdir in this directory will already contain files and other
+directories after it is created.
+::
+
+ # mkdir instances/foo
+ # ls instances/foo
+ buffer_size_kb buffer_total_size_kb events free_buffer per_cpu
+ set_event snapshot trace trace_clock trace_marker trace_options
+ trace_pipe tracing_on
+
+As you can see, the new directory looks similar to the tracing directory
+itself. In fact, it is very similar, except that the buffer and
+events are agnostic from the main directory, or from any other
+instances that are created.
+
+The files in the new directory work just like the files with the
+same name in the tracing directory except the buffer that is used
+is a separate and new buffer. The files affect that buffer but do not
+affect the main buffer with the exception of trace_options. Currently,
+the trace_options affect all instances and the top level buffer
+the same, but this may change in future releases. That is, options
+may become specific to the instance they reside in.
+
+Notice that none of the function tracer files are there, nor is
+current_tracer and available_tracers. This is because the buffers
+can currently only have events enabled for them.
+::
+
+ # mkdir instances/foo
+ # mkdir instances/bar
+ # mkdir instances/zoot
+ # echo 100000 > buffer_size_kb
+ # echo 1000 > instances/foo/buffer_size_kb
+ # echo 5000 > instances/bar/per_cpu/cpu1/buffer_size_kb
+ # echo function > current_trace
+ # echo 1 > instances/foo/events/sched/sched_wakeup/enable
+ # echo 1 > instances/foo/events/sched/sched_wakeup_new/enable
+ # echo 1 > instances/foo/events/sched/sched_switch/enable
+ # echo 1 > instances/bar/events/irq/enable
+ # echo 1 > instances/zoot/events/syscalls/enable
+ # cat trace_pipe
+ CPU:2 [LOST 11745 EVENTS]
+ bash-2044 [002] .... 10594.481032: _raw_spin_lock_irqsave <-get_page_from_freelist
+ bash-2044 [002] d... 10594.481032: add_preempt_count <-_raw_spin_lock_irqsave
+ bash-2044 [002] d..1 10594.481032: __rmqueue <-get_page_from_freelist
+ bash-2044 [002] d..1 10594.481033: _raw_spin_unlock <-get_page_from_freelist
+ bash-2044 [002] d..1 10594.481033: sub_preempt_count <-_raw_spin_unlock
+ bash-2044 [002] d... 10594.481033: get_pageblock_flags_group <-get_pageblock_migratetype
+ bash-2044 [002] d... 10594.481034: __mod_zone_page_state <-get_page_from_freelist
+ bash-2044 [002] d... 10594.481034: zone_statistics <-get_page_from_freelist
+ bash-2044 [002] d... 10594.481034: __inc_zone_state <-zone_statistics
+ bash-2044 [002] d... 10594.481034: __inc_zone_state <-zone_statistics
+ bash-2044 [002] .... 10594.481035: arch_dup_task_struct <-copy_process
+ [...]
+
+ # cat instances/foo/trace_pipe
+ bash-1998 [000] d..4 136.676759: sched_wakeup: comm=kworker/0:1 pid=59 prio=120 success=1 target_cpu=000
+ bash-1998 [000] dN.4 136.676760: sched_wakeup: comm=bash pid=1998 prio=120 success=1 target_cpu=000
+ <idle>-0 [003] d.h3 136.676906: sched_wakeup: comm=rcu_preempt pid=9 prio=120 success=1 target_cpu=003
+ <idle>-0 [003] d..3 136.676909: sched_switch: prev_comm=swapper/3 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=rcu_preempt next_pid=9 next_prio=120
+ rcu_preempt-9 [003] d..3 136.676916: sched_switch: prev_comm=rcu_preempt prev_pid=9 prev_prio=120 prev_state=S ==> next_comm=swapper/3 next_pid=0 next_prio=120
+ bash-1998 [000] d..4 136.677014: sched_wakeup: comm=kworker/0:1 pid=59 prio=120 success=1 target_cpu=000
+ bash-1998 [000] dN.4 136.677016: sched_wakeup: comm=bash pid=1998 prio=120 success=1 target_cpu=000
+ bash-1998 [000] d..3 136.677018: sched_switch: prev_comm=bash prev_pid=1998 prev_prio=120 prev_state=R+ ==> next_comm=kworker/0:1 next_pid=59 next_prio=120
+ kworker/0:1-59 [000] d..4 136.677022: sched_wakeup: comm=sshd pid=1995 prio=120 success=1 target_cpu=001
+ kworker/0:1-59 [000] d..3 136.677025: sched_switch: prev_comm=kworker/0:1 prev_pid=59 prev_prio=120 prev_state=S ==> next_comm=bash next_pid=1998 next_prio=120
+ [...]
+
+ # cat instances/bar/trace_pipe
+ migration/1-14 [001] d.h3 138.732674: softirq_raise: vec=3 [action=NET_RX]
+ <idle>-0 [001] dNh3 138.732725: softirq_raise: vec=3 [action=NET_RX]
+ bash-1998 [000] d.h1 138.733101: softirq_raise: vec=1 [action=TIMER]
+ bash-1998 [000] d.h1 138.733102: softirq_raise: vec=9 [action=RCU]
+ bash-1998 [000] ..s2 138.733105: softirq_entry: vec=1 [action=TIMER]
+ bash-1998 [000] ..s2 138.733106: softirq_exit: vec=1 [action=TIMER]
+ bash-1998 [000] ..s2 138.733106: softirq_entry: vec=9 [action=RCU]
+ bash-1998 [000] ..s2 138.733109: softirq_exit: vec=9 [action=RCU]
+ sshd-1995 [001] d.h1 138.733278: irq_handler_entry: irq=21 name=uhci_hcd:usb4
+ sshd-1995 [001] d.h1 138.733280: irq_handler_exit: irq=21 ret=unhandled
+ sshd-1995 [001] d.h1 138.733281: irq_handler_entry: irq=21 name=eth0
+ sshd-1995 [001] d.h1 138.733283: irq_handler_exit: irq=21 ret=handled
+ [...]
+
+ # cat instances/zoot/trace
+ # tracer: nop
+ #
+ # entries-in-buffer/entries-written: 18996/18996 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ bash-1998 [000] d... 140.733501: sys_write -> 0x2
+ bash-1998 [000] d... 140.733504: sys_dup2(oldfd: a, newfd: 1)
+ bash-1998 [000] d... 140.733506: sys_dup2 -> 0x1
+ bash-1998 [000] d... 140.733508: sys_fcntl(fd: a, cmd: 1, arg: 0)
+ bash-1998 [000] d... 140.733509: sys_fcntl -> 0x1
+ bash-1998 [000] d... 140.733510: sys_close(fd: a)
+ bash-1998 [000] d... 140.733510: sys_close -> 0x0
+ bash-1998 [000] d... 140.733514: sys_rt_sigprocmask(how: 0, nset: 0, oset: 6e2768, sigsetsize: 8)
+ bash-1998 [000] d... 140.733515: sys_rt_sigprocmask -> 0x0
+ bash-1998 [000] d... 140.733516: sys_rt_sigaction(sig: 2, act: 7fff718846f0, oact: 7fff71884650, sigsetsize: 8)
+ bash-1998 [000] d... 140.733516: sys_rt_sigaction -> 0x0
+
+You can see that the trace of the top most trace buffer shows only
+the function tracing. The foo instance displays wakeups and task
+switches.
+
+To remove the instances, simply delete their directories:
+::
+
+ # rmdir instances/foo
+ # rmdir instances/bar
+ # rmdir instances/zoot
+
+Note, if a process has a trace file open in one of the instance
+directories, the rmdir will fail with EBUSY.
+
+
+Stack trace
+-----------
+Since the kernel has a fixed sized stack, it is important not to
+waste it in functions. A kernel developer must be conscience of
+what they allocate on the stack. If they add too much, the system
+can be in danger of a stack overflow, and corruption will occur,
+usually leading to a system panic.
+
+There are some tools that check this, usually with interrupts
+periodically checking usage. But if you can perform a check
+at every function call that will become very useful. As ftrace provides
+a function tracer, it makes it convenient to check the stack size
+at every function call. This is enabled via the stack tracer.
+
+CONFIG_STACK_TRACER enables the ftrace stack tracing functionality.
+To enable it, write a '1' into /proc/sys/kernel/stack_tracer_enabled.
+::
+
+ # echo 1 > /proc/sys/kernel/stack_tracer_enabled
+
+You can also enable it from the kernel command line to trace
+the stack size of the kernel during boot up, by adding "stacktrace"
+to the kernel command line parameter.
+
+After running it for a few minutes, the output looks like:
+::
+
+ # cat stack_max_size
+ 2928
+
+ # cat stack_trace
+ Depth Size Location (18 entries)
+ ----- ---- --------
+ 0) 2928 224 update_sd_lb_stats+0xbc/0x4ac
+ 1) 2704 160 find_busiest_group+0x31/0x1f1
+ 2) 2544 256 load_balance+0xd9/0x662
+ 3) 2288 80 idle_balance+0xbb/0x130
+ 4) 2208 128 __schedule+0x26e/0x5b9
+ 5) 2080 16 schedule+0x64/0x66
+ 6) 2064 128 schedule_timeout+0x34/0xe0
+ 7) 1936 112 wait_for_common+0x97/0xf1
+ 8) 1824 16 wait_for_completion+0x1d/0x1f
+ 9) 1808 128 flush_work+0xfe/0x119
+ 10) 1680 16 tty_flush_to_ldisc+0x1e/0x20
+ 11) 1664 48 input_available_p+0x1d/0x5c
+ 12) 1616 48 n_tty_poll+0x6d/0x134
+ 13) 1568 64 tty_poll+0x64/0x7f
+ 14) 1504 880 do_select+0x31e/0x511
+ 15) 624 400 core_sys_select+0x177/0x216
+ 16) 224 96 sys_select+0x91/0xb9
+ 17) 128 128 system_call_fastpath+0x16/0x1b
+
+Note, if -mfentry is being used by gcc, functions get traced before
+they set up the stack frame. This means that leaf level functions
+are not tested by the stack tracer when -mfentry is used.
+
+Currently, -mfentry is used by gcc 4.6.0 and above on x86 only.
+
+More
+----
+More details can be found in the source code, in the `kernel/trace/*.c` files.
diff --git a/Documentation/trace/function-graph-fold.vim b/Documentation/trace/function-graph-fold.vim
new file mode 100644
index 000000000..0544b504c
--- /dev/null
+++ b/Documentation/trace/function-graph-fold.vim
@@ -0,0 +1,42 @@
+" Enable folding for ftrace function_graph traces.
+"
+" To use, :source this file while viewing a function_graph trace, or use vim's
+" -S option to load from the command-line together with a trace. You can then
+" use the usual vim fold commands, such as "za", to open and close nested
+" functions. While closed, a fold will show the total time taken for a call,
+" as would normally appear on the line with the closing brace. Folded
+" functions will not include finish_task_switch(), so folding should remain
+" relatively sane even through a context switch.
+"
+" Note that this will almost certainly only work well with a
+" single-CPU trace (e.g. trace-cmd report --cpu 1).
+
+function! FunctionGraphFoldExpr(lnum)
+ let line = getline(a:lnum)
+ if line[-1:] == '{'
+ if line =~ 'finish_task_switch() {$'
+ return '>1'
+ endif
+ return 'a1'
+ elseif line[-1:] == '}'
+ return 's1'
+ else
+ return '='
+ endif
+endfunction
+
+function! FunctionGraphFoldText()
+ let s = split(getline(v:foldstart), '|', 1)
+ if getline(v:foldend+1) =~ 'finish_task_switch() {$'
+ let s[2] = ' task switch '
+ else
+ let e = split(getline(v:foldend), '|', 1)
+ let s[2] = e[2]
+ endif
+ return join(s, '|')
+endfunction
+
+setlocal foldexpr=FunctionGraphFoldExpr(v:lnum)
+setlocal foldtext=FunctionGraphFoldText()
+setlocal foldcolumn=12
+setlocal foldmethod=expr
diff --git a/Documentation/trace/hisi-ptt.rst b/Documentation/trace/hisi-ptt.rst
new file mode 100644
index 000000000..4f87d8e21
--- /dev/null
+++ b/Documentation/trace/hisi-ptt.rst
@@ -0,0 +1,298 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+======================================
+HiSilicon PCIe Tune and Trace device
+======================================
+
+Introduction
+============
+
+HiSilicon PCIe tune and trace device (PTT) is a PCIe Root Complex
+integrated Endpoint (RCiEP) device, providing the capability
+to dynamically monitor and tune the PCIe link's events (tune),
+and trace the TLP headers (trace). The two functions are independent,
+but is recommended to use them together to analyze and enhance the
+PCIe link's performance.
+
+On Kunpeng 930 SoC, the PCIe Root Complex is composed of several
+PCIe cores. Each PCIe core includes several Root Ports and a PTT
+RCiEP, like below. The PTT device is capable of tuning and
+tracing the links of the PCIe core.
+::
+
+ +--------------Core 0-------+
+ | | [ PTT ] |
+ | | [Root Port]---[Endpoint]
+ | | [Root Port]---[Endpoint]
+ | | [Root Port]---[Endpoint]
+ Root Complex |------Core 1-------+
+ | | [ PTT ] |
+ | | [Root Port]---[ Switch ]---[Endpoint]
+ | | [Root Port]---[Endpoint] `-[Endpoint]
+ | | [Root Port]---[Endpoint]
+ +---------------------------+
+
+The PTT device driver registers one PMU device for each PTT device.
+The name of each PTT device is composed of 'hisi_ptt' prefix with
+the id of the SICL and the Core where it locates. The Kunpeng 930
+SoC encapsulates multiple CPU dies (SCCL, Super CPU Cluster) and
+IO dies (SICL, Super I/O Cluster), where there's one PCIe Root
+Complex for each SICL.
+::
+
+ /sys/devices/hisi_ptt<sicl_id>_<core_id>
+
+Tune
+====
+
+PTT tune is designed for monitoring and adjusting PCIe link parameters (events).
+Currently we support events in 2 classes. The scope of the events
+covers the PCIe core to which the PTT device belongs.
+
+Each event is presented as a file under $(PTT PMU dir)/tune, and
+a simple open/read/write/close cycle will be used to tune the event.
+::
+
+ $ cd /sys/devices/hisi_ptt<sicl_id>_<core_id>/tune
+ $ ls
+ qos_tx_cpl qos_tx_np qos_tx_p
+ tx_path_rx_req_alloc_buf_level
+ tx_path_tx_req_alloc_buf_level
+ $ cat qos_tx_dp
+ 1
+ $ echo 2 > qos_tx_dp
+ $ cat qos_tx_dp
+ 2
+
+Current value (numerical value) of the event can be simply read
+from the file, and the desired value written to the file to tune.
+
+1. Tx Path QoS Control
+------------------------
+
+The following files are provided to tune the QoS of the tx path of
+the PCIe core.
+
+- qos_tx_cpl: weight of Tx completion TLPs
+- qos_tx_np: weight of Tx non-posted TLPs
+- qos_tx_p: weight of Tx posted TLPs
+
+The weight influences the proportion of certain packets on the PCIe link.
+For example, for the storage scenario, increase the proportion
+of the completion packets on the link to enhance the performance as
+more completions are consumed.
+
+The available tune data of these events is [0, 1, 2].
+Writing a negative value will return an error, and out of range
+values will be converted to 2. Note that the event value just
+indicates a probable level, but is not precise.
+
+2. Tx Path Buffer Control
+-------------------------
+
+Following files are provided to tune the buffer of tx path of the PCIe core.
+
+- rx_alloc_buf_level: watermark of Rx requested
+- tx_alloc_buf_level: watermark of Tx requested
+
+These events influence the watermark of the buffer allocated for each
+type. Rx means the inbound while Tx means outbound. The packets will
+be stored in the buffer first and then transmitted either when the
+watermark reached or when timed out. For a busy direction, you should
+increase the related buffer watermark to avoid frequently posting and
+thus enhance the performance. In most cases just keep the default value.
+
+The available tune data of above events is [0, 1, 2].
+Writing a negative value will return an error, and out of range
+values will be converted to 2. Note that the event value just
+indicates a probable level, but is not precise.
+
+Trace
+=====
+
+PTT trace is designed for dumping the TLP headers to the memory, which
+can be used to analyze the transactions and usage condition of the PCIe
+Link. You can choose to filter the traced headers by either Requester ID,
+or those downstream of a set of Root Ports on the same core of the PTT
+device. It's also supported to trace the headers of certain type and of
+certain direction.
+
+You can use the perf command `perf record` to set the parameters, start
+trace and get the data. It's also supported to decode the trace
+data with `perf report`. The control parameters for trace is inputted
+as event code for each events, which will be further illustrated later.
+An example usage is like
+::
+
+ $ perf record -e hisi_ptt0_2/filter=0x80001,type=1,direction=1,
+ format=1/ -- sleep 5
+
+This will trace the TLP headers downstream root port 0000:00:10.1 (event
+code for event 'filter' is 0x80001) with type of posted TLP requests,
+direction of inbound and traced data format of 8DW.
+
+1. Filter
+---------
+
+The TLP headers to trace can be filtered by the Root Ports or the Requester ID
+of the Endpoint, which are located on the same core of the PTT device. You can
+set the filter by specifying the `filter` parameter which is required to start
+the trace. The parameter value is 20 bit. Bit 19 indicates the filter type.
+1 for Root Port filter and 0 for Requester filter. Bit[15:0] indicates the
+filter value. The value for a Root Port is a mask of the core port id which is
+calculated from its PCI Slot ID as (slotid & 7) * 2. The value for a Requester
+is the Requester ID (Device ID of the PCIe function). Bit[18:16] is currently
+reserved for extension.
+
+For example, if the desired filter is Endpoint function 0000:01:00.1 the filter
+value will be 0x00101. If the desired filter is Root Port 0000:00:10.0 then
+then filter value is calculated as 0x80001.
+
+Note that multiple Root Ports can be specified at one time, but only one
+Endpoint function can be specified in one trace. Specifying both Root Port
+and function at the same time is not supported. Driver maintains a list of
+available filters and will check the invalid inputs.
+
+Currently the available filters are detected in driver's probe. If the supported
+devices are removed/added after probe, you may need to reload the driver to update
+the filters.
+
+2. Type
+-------
+
+You can trace the TLP headers of certain types by specifying the `type`
+parameter, which is required to start the trace. The parameter value is
+8 bit. Current supported types and related values are shown below:
+
+- 8'b00000001: posted requests (P)
+- 8'b00000010: non-posted requests (NP)
+- 8'b00000100: completions (CPL)
+
+You can specify multiple types when tracing inbound TLP headers, but can only
+specify one when tracing outbound TLP headers.
+
+3. Direction
+------------
+
+You can trace the TLP headers from certain direction, which is relative
+to the Root Port or the PCIe core, by specifying the `direction` parameter.
+This is optional and the default parameter is inbound. The parameter value
+is 4 bit. When the desired format is 4DW, directions and related values
+supported are shown below:
+
+- 4'b0000: inbound TLPs (P, NP, CPL)
+- 4'b0001: outbound TLPs (P, NP, CPL)
+- 4'b0010: outbound TLPs (P, NP, CPL) and inbound TLPs (P, NP, CPL B)
+- 4'b0011: outbound TLPs (P, NP, CPL) and inbound TLPs (CPL A)
+
+When the desired format is 8DW, directions and related values supported are
+shown below:
+
+- 4'b0000: reserved
+- 4'b0001: outbound TLPs (P, NP, CPL)
+- 4'b0010: inbound TLPs (P, NP, CPL B)
+- 4'b0011: inbound TLPs (CPL A)
+
+Inbound completions are classified into two types:
+
+- completion A (CPL A): completion of CHI/DMA/Native non-posted requests, except for CPL B
+- completion B (CPL B): completion of DMA remote2local and P2P non-posted requests
+
+4. Format
+--------------
+
+You can change the format of the traced TLP headers by specifying the
+`format` parameter. The default format is 4DW. The parameter value is 4 bit.
+Current supported formats and related values are shown below:
+
+- 4'b0000: 4DW length per TLP header
+- 4'b0001: 8DW length per TLP header
+
+The traced TLP header format is different from the PCIe standard.
+
+When using the 8DW data format, the entire TLP header is logged
+(Header DW0-3 shown below). For example, the TLP header for Memory
+Reads with 64-bit addresses is shown in PCIe r5.0, Figure 2-17;
+the header for Configuration Requests is shown in Figure 2.20, etc.
+
+In addition, 8DW trace buffer entries contain a timestamp and
+possibly a prefix for a PASID TLP prefix (see Figure 6-20, PCIe r5.0).
+Otherwise this field will be all 0.
+
+The bit[31:11] of DW0 is always 0x1fffff, which can be
+used to distinguish the data format. 8DW format is like
+::
+
+ bits [ 31:11 ][ 10:0 ]
+ |---------------------------------------|-------------------|
+ DW0 [ 0x1fffff ][ Reserved (0x7ff) ]
+ DW1 [ Prefix ]
+ DW2 [ Header DW0 ]
+ DW3 [ Header DW1 ]
+ DW4 [ Header DW2 ]
+ DW5 [ Header DW3 ]
+ DW6 [ Reserved (0x0) ]
+ DW7 [ Time ]
+
+When using the 4DW data format, DW0 of the trace buffer entry
+contains selected fields of DW0 of the TLP, together with a
+timestamp. DW1-DW3 of the trace buffer entry contain DW1-DW3
+directly from the TLP header.
+
+4DW format is like
+::
+
+ bits [31:30] [ 29:25 ][24][23][22][21][ 20:11 ][ 10:0 ]
+ |-----|---------|---|---|---|---|-------------|-------------|
+ DW0 [ Fmt ][ Type ][T9][T8][TH][SO][ Length ][ Time ]
+ DW1 [ Header DW1 ]
+ DW2 [ Header DW2 ]
+ DW3 [ Header DW3 ]
+
+5. Memory Management
+--------------------
+
+The traced TLP headers will be written to the memory allocated
+by the driver. The hardware accepts 4 DMA address with same size,
+and writes the buffer sequentially like below. If DMA addr 3 is
+finished and the trace is still on, it will return to addr 0.
+::
+
+ +->[DMA addr 0]->[DMA addr 1]->[DMA addr 2]->[DMA addr 3]-+
+ +---------------------------------------------------------+
+
+Driver will allocate each DMA buffer of 4MiB. The finished buffer
+will be copied to the perf AUX buffer allocated by the perf core.
+Once the AUX buffer is full while the trace is still on, driver
+will commit the AUX buffer first and then apply for a new one with
+the same size. The size of AUX buffer is default to 16MiB. User can
+adjust the size by specifying the `-m` parameter of the perf command.
+
+6. Decoding
+-----------
+
+You can decode the traced data with `perf report -D` command (currently
+only support to dump the raw trace data). The traced data will be decoded
+according to the format described previously (take 8DW as an example):
+::
+
+ [...perf headers and other information]
+ . ... HISI PTT data: size 4194304 bytes
+ . 00000000: 00 00 00 00 Prefix
+ . 00000004: 01 00 00 60 Header DW0
+ . 00000008: 0f 1e 00 01 Header DW1
+ . 0000000c: 04 00 00 00 Header DW2
+ . 00000010: 40 00 81 02 Header DW3
+ . 00000014: 33 c0 04 00 Time
+ . 00000020: 00 00 00 00 Prefix
+ . 00000024: 01 00 00 60 Header DW0
+ . 00000028: 0f 1e 00 01 Header DW1
+ . 0000002c: 04 00 00 00 Header DW2
+ . 00000030: 40 00 81 02 Header DW3
+ . 00000034: 02 00 00 00 Time
+ . 00000040: 00 00 00 00 Prefix
+ . 00000044: 01 00 00 60 Header DW0
+ . 00000048: 0f 1e 00 01 Header DW1
+ . 0000004c: 04 00 00 00 Header DW2
+ . 00000050: 40 00 81 02 Header DW3
+ [...]
diff --git a/Documentation/trace/histogram-design.rst b/Documentation/trace/histogram-design.rst
new file mode 100644
index 000000000..088c8cce7
--- /dev/null
+++ b/Documentation/trace/histogram-design.rst
@@ -0,0 +1,2115 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+======================
+Histogram Design Notes
+======================
+
+:Author: Tom Zanussi <zanussi@kernel.org>
+
+This document attempts to provide a description of how the ftrace
+histograms work and how the individual pieces map to the data
+structures used to implement them in trace_events_hist.c and
+tracing_map.c.
+
+Note: All the ftrace histogram command examples assume the working
+ directory is the ftrace /tracing directory. For example::
+
+ # cd /sys/kernel/debug/tracing
+
+Also, the histogram output displayed for those commands will be
+generally be truncated - only enough to make the point is displayed.
+
+'hist_debug' trace event files
+==============================
+
+If the kernel is compiled with CONFIG_HIST_TRIGGERS_DEBUG set, an
+event file named 'hist_debug' will appear in each event's
+subdirectory. This file can be read at any time and will display some
+of the hist trigger internals described in this document. Specific
+examples and output will be described in test cases below.
+
+Basic histograms
+================
+
+First, basic histograms. Below is pretty much the simplest thing you
+can do with histograms - create one with a single key on a single
+event and cat the output::
+
+ # echo 'hist:keys=pid' >> events/sched/sched_waking/trigger
+
+ # cat events/sched/sched_waking/hist
+
+ { pid: 18249 } hitcount: 1
+ { pid: 13399 } hitcount: 1
+ { pid: 17973 } hitcount: 1
+ { pid: 12572 } hitcount: 1
+ ...
+ { pid: 10 } hitcount: 921
+ { pid: 18255 } hitcount: 1444
+ { pid: 25526 } hitcount: 2055
+ { pid: 5257 } hitcount: 2055
+ { pid: 27367 } hitcount: 2055
+ { pid: 1728 } hitcount: 2161
+
+ Totals:
+ Hits: 21305
+ Entries: 183
+ Dropped: 0
+
+What this does is create a histogram on the sched_waking event using
+pid as a key and with a single value, hitcount, which even if not
+explicitly specified, exists for every histogram regardless.
+
+The hitcount value is a per-bucket value that's automatically
+incremented on every hit for the given key, which in this case is the
+pid.
+
+So in this histogram, there's a separate bucket for each pid, and each
+bucket contains a value for that bucket, counting the number of times
+sched_waking was called for that pid.
+
+Each histogram is represented by a hist_data struct.
+
+To keep track of each key and value field in the histogram, hist_data
+keeps an array of these fields named fields[]. The fields[] array is
+an array containing struct hist_field representations of each
+histogram val and key in the histogram (variables are also included
+here, but are discussed later). So for the above histogram we have one
+key and one value; in this case the one value is the hitcount value,
+which all histograms have, regardless of whether they define that
+value or not, which the above histogram does not.
+
+Each struct hist_field contains a pointer to the ftrace_event_field
+from the event's trace_event_file along with various bits related to
+that such as the size, offset, type, and a hist_field_fn_t function,
+which is used to grab the field's data from the ftrace event buffer
+(in most cases - some hist_fields such as hitcount don't directly map
+to an event field in the trace buffer - in these cases the function
+implementation gets its value from somewhere else). The flags field
+indicates which type of field it is - key, value, variable, variable
+reference, etc., with value being the default.
+
+The other important hist_data data structure in addition to the
+fields[] array is the tracing_map instance created for the histogram,
+which is held in the .map member. The tracing_map implements the
+lock-free hash table used to implement histograms (see
+kernel/trace/tracing_map.h for much more discussion about the
+low-level data structures implementing the tracing_map). For the
+purposes of this discussion, the tracing_map contains a number of
+buckets, each bucket corresponding to a particular tracing_map_elt
+object hashed by a given histogram key.
+
+Below is a diagram the first part of which describes the hist_data and
+associated key and value fields for the histogram described above. As
+you can see, there are two fields in the fields array, one val field
+for the hitcount and one key field for the pid key.
+
+Below that is a diagram of a run-time snapshot of what the tracing_map
+might look like for a given run. It attempts to show the
+relationships between the hist_data fields and the tracing_map
+elements for a couple hypothetical keys and values.::
+
+ +------------------+
+ | hist_data |
+ +------------------+ +----------------+
+ | .fields[] |---->| val = hitcount |----------------------------+
+ +----------------+ +----------------+ |
+ | .map | | .size | |
+ +----------------+ +--------------+ |
+ | .offset | |
+ +--------------+ |
+ | .fn() | |
+ +--------------+ |
+ . |
+ . |
+ . |
+ +----------------+ <--- n_vals |
+ | key = pid |----------------------------|--+
+ +----------------+ | |
+ | .size | | |
+ +--------------+ | |
+ | .offset | | |
+ +--------------+ | |
+ | .fn() | | |
+ +----------------+ <--- n_fields | |
+ | unused | | |
+ +----------------+ | |
+ | | | |
+ +--------------+ | |
+ | | | |
+ +--------------+ | |
+ | | | |
+ +--------------+ | |
+ n_keys = n_fields - n_vals | |
+
+The hist_data n_vals and n_fields delineate the extent of the fields[] | |
+array and separate keys from values for the rest of the code. | |
+
+Below is a run-time representation of the tracing_map part of the | |
+histogram, with pointers from various parts of the fields[] array | |
+to corresponding parts of the tracing_map. | |
+
+The tracing_map consists of an array of tracing_map_entrys and a set | |
+of preallocated tracing_map_elts (abbreviated below as map_entry and | |
+map_elt). The total number of map_entrys in the hist_data.map array = | |
+map->max_elts (actually map->map_size but only max_elts of those are | |
+used. This is a property required by the map_insert() algorithm). | |
+
+If a map_entry is unused, meaning no key has yet hashed into it, its | |
+.key value is 0 and its .val pointer is NULL. Once a map_entry has | |
+been claimed, the .key value contains the key's hash value and the | |
+.val member points to a map_elt containing the full key and an entry | |
+for each key or value in the map_elt.fields[] array. There is an | |
+entry in the map_elt.fields[] array corresponding to each hist_field | |
+in the histogram, and this is where the continually aggregated sums | |
+corresponding to each histogram value are kept. | |
+
+The diagram attempts to show the relationship between the | |
+hist_data.fields[] and the map_elt.fields[] with the links drawn | |
+between diagrams::
+
+ +-----------+ | |
+ | hist_data | | |
+ +-----------+ | |
+ | .fields | | |
+ +---------+ +-----------+ | |
+ | .map |---->| map_entry | | |
+ +---------+ +-----------+ | |
+ | .key |---> 0 | |
+ +---------+ | |
+ | .val |---> NULL | |
+ +-----------+ | |
+ | map_entry | | |
+ +-----------+ | |
+ | .key |---> pid = 999 | |
+ +---------+ +-----------+ | |
+ | .val |--->| map_elt | | |
+ +---------+ +-----------+ | |
+ . | .key |---> full key * | |
+ . +---------+ +---------------+ | |
+ . | .fields |--->| .sum (val) |<-+ |
+ +-----------+ +---------+ | 2345 | | |
+ | map_entry | +---------------+ | |
+ +-----------+ | .offset (key) |<----+
+ | .key |---> 0 | 0 | | |
+ +---------+ +---------------+ | |
+ | .val |---> NULL . | |
+ +-----------+ . | |
+ | map_entry | . | |
+ +-----------+ +---------------+ | |
+ | .key | | .sum (val) or | | |
+ +---------+ +---------+ | .offset (key) | | |
+ | .val |--->| map_elt | +---------------+ | |
+ +-----------+ +---------+ | .sum (val) or | | |
+ | map_entry | | .offset (key) | | |
+ +-----------+ +---------------+ | |
+ | .key |---> pid = 4444 | |
+ +---------+ +-----------+ | |
+ | .val | | map_elt | | |
+ +---------+ +-----------+ | |
+ | .key |---> full key * | |
+ +---------+ +---------------+ | |
+ | .fields |--->| .sum (val) |<-+ |
+ +---------+ | 65523 | |
+ +---------------+ |
+ | .offset (key) |<----+
+ | 0 |
+ +---------------+
+ .
+ .
+ .
+ +---------------+
+ | .sum (val) or |
+ | .offset (key) |
+ +---------------+
+ | .sum (val) or |
+ | .offset (key) |
+ +---------------+
+
+Abbreviations used in the diagrams::
+
+ hist_data = struct hist_trigger_data
+ hist_data.fields = struct hist_field
+ fn = hist_field_fn_t
+ map_entry = struct tracing_map_entry
+ map_elt = struct tracing_map_elt
+ map_elt.fields = struct tracing_map_field
+
+Whenever a new event occurs and it has a hist trigger associated with
+it, event_hist_trigger() is called. event_hist_trigger() first deals
+with the key: for each subkey in the key (in the above example, there
+is just one subkey corresponding to pid), the hist_field that
+represents that subkey is retrieved from hist_data.fields[] and the
+hist_field_fn_t fn() associated with that field, along with the
+field's size and offset, is used to grab that subkey's data from the
+current trace record.
+
+Once the complete key has been retrieved, it's used to look that key
+up in the tracing_map. If there's no tracing_map_elt associated with
+that key, an empty one is claimed and inserted in the map for the new
+key. In either case, the tracing_map_elt associated with that key is
+returned.
+
+Once a tracing_map_elt available, hist_trigger_elt_update() is called.
+As the name implies, this updates the element, which basically means
+updating the element's fields. There's a tracing_map_field associated
+with each key and value in the histogram, and each of these correspond
+to the key and value hist_fields created when the histogram was
+created. hist_trigger_elt_update() goes through each value hist_field
+and, as for the keys, uses the hist_field's fn() and size and offset
+to grab the field's value from the current trace record. Once it has
+that value, it simply adds that value to that field's
+continually-updated tracing_map_field.sum member. Some hist_field
+fn()s, such as for the hitcount, don't actually grab anything from the
+trace record (the hitcount fn() just increments the counter sum by 1),
+but the idea is the same.
+
+Once all the values have been updated, hist_trigger_elt_update() is
+done and returns. Note that there are also tracing_map_fields for
+each subkey in the key, but hist_trigger_elt_update() doesn't look at
+them or update anything - those exist only for sorting, which can
+happen later.
+
+Basic histogram test
+--------------------
+
+This is a good example to try. It produces 3 value fields and 2 key
+fields in the output::
+
+ # echo 'hist:keys=common_pid,call_site.sym:values=bytes_req,bytes_alloc,hitcount' >> events/kmem/kmalloc/trigger
+
+To see the debug data, cat the kmem/kmalloc's 'hist_debug' file. It
+will show the trigger info of the histogram it corresponds to, along
+with the address of the hist_data associated with the histogram, which
+will become useful in later examples. It then displays the number of
+total hist_fields associated with the histogram along with a count of
+how many of those correspond to keys and how many correspond to values.
+
+It then goes on to display details for each field, including the
+field's flags and the position of each field in the hist_data's
+fields[] array, which is useful information for verifying that things
+internally appear correct or not, and which again will become even
+more useful in further examples::
+
+ # cat events/kmem/kmalloc/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=common_pid,call_site.sym:vals=hitcount,bytes_req,bytes_alloc:sort=hitcount:size=2048 [active]
+ #
+
+ hist_data: 000000005e48c9a5
+
+ n_vals: 3
+ n_keys: 2
+ n_fields: 5
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ VAL: normal u64 value
+ ftrace_event_field name: bytes_req
+ type: size_t
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[2]:
+ flags:
+ VAL: normal u64 value
+ ftrace_event_field name: bytes_alloc
+ type: size_t
+ size: 8
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[3]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: common_pid
+ type: int
+ size: 8
+ is_signed: 1
+
+ hist_data->fields[4]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: call_site
+ type: unsigned long
+ size: 8
+ is_signed: 0
+
+The commands below can be used to clean things up for the next test::
+
+ # echo '!hist:keys=common_pid,call_site.sym:values=bytes_req,bytes_alloc,hitcount' >> events/kmem/kmalloc/trigger
+
+Variables
+=========
+
+Variables allow data from one hist trigger to be saved by one hist
+trigger and retrieved by another hist trigger. For example, a trigger
+on the sched_waking event can capture a timestamp for a particular
+pid, and later a sched_switch event that switches to that pid event
+can grab the timestamp and use it to calculate a time delta between
+the two events::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' >>
+ events/sched/sched_waking/trigger
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0' >>
+ events/sched/sched_switch/trigger
+
+In terms of the histogram data structures, variables are implemented
+as another type of hist_field and for a given hist trigger are added
+to the hist_data.fields[] array just after all the val fields. To
+distinguish them from the existing key and val fields, they're given a
+new flag type, HIST_FIELD_FL_VAR (abbreviated FL_VAR) and they also
+make use of a new .var.idx field member in struct hist_field, which
+maps them to an index in a new map_elt.vars[] array added to the
+map_elt specifically designed to store and retrieve variable values.
+The diagram below shows those new elements and adds a new variable
+entry, ts0, corresponding to the ts0 variable in the sched_waking
+trigger above.
+
+sched_waking histogram
+----------------------::
+
+ +------------------+
+ | hist_data |<-------------------------------------------------------+
+ +------------------+ +-------------------+ |
+ | .fields[] |-->| val = hitcount | |
+ +----------------+ +-------------------+ |
+ | .map | | .size | |
+ +----------------+ +-----------------+ |
+ | .offset | |
+ +-----------------+ |
+ | .fn() | |
+ +-----------------+ |
+ | .flags | |
+ +-----------------+ |
+ | .var.idx | |
+ +-------------------+ |
+ | var = ts0 | |
+ +-------------------+ |
+ | .size | |
+ +-----------------+ |
+ | .offset | |
+ +-----------------+ |
+ | .fn() | |
+ +-----------------+ |
+ | .flags & FL_VAR | |
+ +-----------------+ |
+ | .var.idx |----------------------------+-+ |
+ +-----------------+ | | |
+ . | | |
+ . | | |
+ . | | |
+ +-------------------+ <--- n_vals | | |
+ | key = pid | | | |
+ +-------------------+ | | |
+ | .size | | | |
+ +-----------------+ | | |
+ | .offset | | | |
+ +-----------------+ | | |
+ | .fn() | | | |
+ +-----------------+ | | |
+ | .flags & FL_KEY | | | |
+ +-----------------+ | | |
+ | .var.idx | | | |
+ +-------------------+ <--- n_fields | | |
+ | unused | | | |
+ +-------------------+ | | |
+ | | | | |
+ +-----------------+ | | |
+ | | | | |
+ +-----------------+ | | |
+ | | | | |
+ +-----------------+ | | |
+ | | | | |
+ +-----------------+ | | |
+ | | | | |
+ +-----------------+ | | |
+ n_keys = n_fields - n_vals | | |
+ | | |
+
+This is very similar to the basic case. In the above diagram, we can | | |
+see a new .flags member has been added to the struct hist_field | | |
+struct, and a new entry added to hist_data.fields representing the ts0 | | |
+variable. For a normal val hist_field, .flags is just 0 (modulo | | |
+modifier flags), but if the value is defined as a variable, the .flags | | |
+contains a set FL_VAR bit. | | |
+
+As you can see, the ts0 entry's .var.idx member contains the index | | |
+into the tracing_map_elts' .vars[] array containing variable values. | | |
+This idx is used whenever the value of the variable is set or read. | | |
+The map_elt.vars idx assigned to the given variable is assigned and | | |
+saved in .var.idx by create_tracing_map_fields() after it calls | | |
+tracing_map_add_var(). | | |
+
+Below is a representation of the histogram at run-time, which | | |
+populates the map, along with correspondence to the above hist_data and | | |
+hist_field data structures. | | |
+
+The diagram attempts to show the relationship between the | | |
+hist_data.fields[] and the map_elt.fields[] and map_elt.vars[] with | | |
+the links drawn between diagrams. For each of the map_elts, you can | | |
+see that the .fields[] members point to the .sum or .offset of a key | | |
+or val and the .vars[] members point to the value of a variable. The | | |
+arrows between the two diagrams show the linkages between those | | |
+tracing_map members and the field definitions in the corresponding | | |
+hist_data fields[] members.::
+
+ +-----------+ | | |
+ | hist_data | | | |
+ +-----------+ | | |
+ | .fields | | | |
+ +---------+ +-----------+ | | |
+ | .map |---->| map_entry | | | |
+ +---------+ +-----------+ | | |
+ | .key |---> 0 | | |
+ +---------+ | | |
+ | .val |---> NULL | | |
+ +-----------+ | | |
+ | map_entry | | | |
+ +-----------+ | | |
+ | .key |---> pid = 999 | | |
+ +---------+ +-----------+ | | |
+ | .val |--->| map_elt | | | |
+ +---------+ +-----------+ | | |
+ . | .key |---> full key * | | |
+ . +---------+ +---------------+ | | |
+ . | .fields |--->| .sum (val) | | | |
+ . +---------+ | 2345 | | | |
+ . +--| .vars | +---------------+ | | |
+ . | +---------+ | .offset (key) | | | |
+ . | | 0 | | | |
+ . | +---------------+ | | |
+ . | . | | |
+ . | . | | |
+ . | . | | |
+ . | +---------------+ | | |
+ . | | .sum (val) or | | | |
+ . | | .offset (key) | | | |
+ . | +---------------+ | | |
+ . | | .sum (val) or | | | |
+ . | | .offset (key) | | | |
+ . | +---------------+ | | |
+ . | | | |
+ . +---------------->+---------------+ | | |
+ . | ts0 |<--+ | |
+ . | 113345679876 | | | |
+ . +---------------+ | | |
+ . | unused | | | |
+ . | | | | |
+ . +---------------+ | | |
+ . . | | |
+ . . | | |
+ . . | | |
+ . +---------------+ | | |
+ . | unused | | | |
+ . | | | | |
+ . +---------------+ | | |
+ . | unused | | | |
+ . | | | | |
+ . +---------------+ | | |
+ . | | |
+ +-----------+ | | |
+ | map_entry | | | |
+ +-----------+ | | |
+ | .key |---> pid = 4444 | | |
+ +---------+ +-----------+ | | |
+ | .val |--->| map_elt | | | |
+ +---------+ +-----------+ | | |
+ . | .key |---> full key * | | |
+ . +---------+ +---------------+ | | |
+ . | .fields |--->| .sum (val) | | | |
+ +---------+ | 2345 | | | |
+ +--| .vars | +---------------+ | | |
+ | +---------+ | .offset (key) | | | |
+ | | 0 | | | |
+ | +---------------+ | | |
+ | . | | |
+ | . | | |
+ | . | | |
+ | +---------------+ | | |
+ | | .sum (val) or | | | |
+ | | .offset (key) | | | |
+ | +---------------+ | | |
+ | | .sum (val) or | | | |
+ | | .offset (key) | | | |
+ | +---------------+ | | |
+ | | | |
+ | +---------------+ | | |
+ +---------------->| ts0 |<--+ | |
+ | 213499240729 | | |
+ +---------------+ | |
+ | unused | | |
+ | | | |
+ +---------------+ | |
+ . | |
+ . | |
+ . | |
+ +---------------+ | |
+ | unused | | |
+ | | | |
+ +---------------+ | |
+ | unused | | |
+ | | | |
+ +---------------+ | |
+
+For each used map entry, there's a map_elt pointing to an array of | |
+.vars containing the current value of the variables associated with | |
+that histogram entry. So in the above, the timestamp associated with | |
+pid 999 is 113345679876, and the timestamp variable in the same | |
+.var.idx for pid 4444 is 213499240729. | |
+
+sched_switch histogram | |
+---------------------- | |
+
+The sched_switch histogram paired with the above sched_waking | |
+histogram is shown below. The most important aspect of the | |
+sched_switch histogram is that it references a variable on the | |
+sched_waking histogram above. | |
+
+The histogram diagram is very similar to the others so far displayed, | |
+but it adds variable references. You can see the normal hitcount and | |
+key fields along with a new wakeup_lat variable implemented in the | |
+same way as the sched_waking ts0 variable, but in addition there's an | |
+entry with the new FL_VAR_REF (short for HIST_FIELD_FL_VAR_REF) flag. | |
+
+Associated with the new var ref field are a couple of new hist_field | |
+members, var.hist_data and var_ref_idx. For a variable reference, the | |
+var.hist_data goes with the var.idx, which together uniquely identify | |
+a particular variable on a particular histogram. The var_ref_idx is | |
+just the index into the var_ref_vals[] array that caches the values of | |
+each variable whenever a hist trigger is updated. Those resulting | |
+values are then finally accessed by other code such as trace action | |
+code that uses the var_ref_idx values to assign param values. | |
+
+The diagram below describes the situation for the sched_switch | |
+histogram referred to before::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0' >> | |
+ events/sched/sched_switch/trigger | |
+ | |
+ +------------------+ | |
+ | hist_data | | |
+ +------------------+ +-----------------------+ | |
+ | .fields[] |-->| val = hitcount | | |
+ +----------------+ +-----------------------+ | |
+ | .map | | .size | | |
+ +----------------+ +---------------------+ | |
+ +--| .var_refs[] | | .offset | | |
+ | +----------------+ +---------------------+ | |
+ | | .fn() | | |
+ | var_ref_vals[] +---------------------+ | |
+ | +-------------+ | .flags | | |
+ | | $ts0 |<---+ +---------------------+ | |
+ | +-------------+ | | .var.idx | | |
+ | | | | +---------------------+ | |
+ | +-------------+ | | .var.hist_data | | |
+ | | | | +---------------------+ | |
+ | +-------------+ | | .var_ref_idx | | |
+ | | | | +-----------------------+ | |
+ | +-------------+ | | var = wakeup_lat | | |
+ | . | +-----------------------+ | |
+ | . | | .size | | |
+ | . | +---------------------+ | |
+ | +-------------+ | | .offset | | |
+ | | | | +---------------------+ | |
+ | +-------------+ | | .fn() | | |
+ | | | | +---------------------+ | |
+ | +-------------+ | | .flags & FL_VAR | | |
+ | | +---------------------+ | |
+ | | | .var.idx | | |
+ | | +---------------------+ | |
+ | | | .var.hist_data | | |
+ | | +---------------------+ | |
+ | | | .var_ref_idx | | |
+ | | +---------------------+ | |
+ | | . | |
+ | | . | |
+ | | . | |
+ | | +-----------------------+ <--- n_vals | |
+ | | | key = pid | | |
+ | | +-----------------------+ | |
+ | | | .size | | |
+ | | +---------------------+ | |
+ | | | .offset | | |
+ | | +---------------------+ | |
+ | | | .fn() | | |
+ | | +---------------------+ | |
+ | | | .flags | | |
+ | | +---------------------+ | |
+ | | | .var.idx | | |
+ | | +-----------------------+ <--- n_fields | |
+ | | | unused | | |
+ | | +-----------------------+ | |
+ | | | | | |
+ | | +---------------------+ | |
+ | | | | | |
+ | | +---------------------+ | |
+ | | | | | |
+ | | +---------------------+ | |
+ | | | | | |
+ | | +---------------------+ | |
+ | | | | | |
+ | | +---------------------+ | |
+ | | n_keys = n_fields - n_vals | |
+ | | | |
+ | | | |
+ | | +-----------------------+ | |
+ +---------------------->| var_ref = $ts0 | | |
+ | +-----------------------+ | |
+ | | .size | | |
+ | +---------------------+ | |
+ | | .offset | | |
+ | +---------------------+ | |
+ | | .fn() | | |
+ | +---------------------+ | |
+ | | .flags & FL_VAR_REF | | |
+ | +---------------------+ | |
+ | | .var.idx |--------------------------+ |
+ | +---------------------+ |
+ | | .var.hist_data |----------------------------+
+ | +---------------------+
+ +---| .var_ref_idx |
+ +---------------------+
+
+Abbreviations used in the diagrams::
+
+ hist_data = struct hist_trigger_data
+ hist_data.fields = struct hist_field
+ fn = hist_field_fn_t
+ FL_KEY = HIST_FIELD_FL_KEY
+ FL_VAR = HIST_FIELD_FL_VAR
+ FL_VAR_REF = HIST_FIELD_FL_VAR_REF
+
+When a hist trigger makes use of a variable, a new hist_field is
+created with flag HIST_FIELD_FL_VAR_REF. For a VAR_REF field, the
+var.idx and var.hist_data take the same values as the referenced
+variable, as well as the referenced variable's size, type, and
+is_signed values. The VAR_REF field's .name is set to the name of the
+variable it references. If a variable reference was created using the
+explicit system.event.$var_ref notation, the hist_field's system and
+event_name variables are also set.
+
+So, in order to handle an event for the sched_switch histogram,
+because we have a reference to a variable on another histogram, we
+need to resolve all variable references first. This is done via the
+resolve_var_refs() calls made from event_hist_trigger(). What this
+does is grabs the var_refs[] array from the hist_data representing the
+sched_switch histogram. For each one of those, the referenced
+variable's var.hist_data along with the current key is used to look up
+the corresponding tracing_map_elt in that histogram. Once found, the
+referenced variable's var.idx is used to look up the variable's value
+using tracing_map_read_var(elt, var.idx), which yields the value of
+the variable for that element, ts0 in the case above. Note that both
+the hist_fields representing both the variable and the variable
+reference have the same var.idx, so this is straightforward.
+
+Variable and variable reference test
+------------------------------------
+
+This example creates a variable on the sched_waking event, ts0, and
+uses it in the sched_switch trigger. The sched_switch trigger also
+creates its own variable, wakeup_lat, but nothing yet uses it::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0' >> events/sched/sched_switch/trigger
+
+Looking at the sched_waking 'hist_debug' output, in addition to the
+normal key and value hist_fields, in the val fields section we see a
+field with the HIST_FIELD_FL_VAR flag, which indicates that that field
+represents a variable. Note that in addition to the variable name,
+contained in the var.name field, it includes the var.idx, which is the
+index into the tracing_map_elt.vars[] array of the actual variable
+location. Note also that the output shows that variables live in the
+same part of the hist_data->fields[] array as normal values::
+
+ # cat events/sched/sched_waking/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid:vals=hitcount:ts0=common_timestamp.usecs:sort=hitcount:size=2048:clock=global [active]
+ #
+
+ hist_data: 000000009536f554
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+Moving on to the sched_switch trigger hist_debug output, in addition
+to the unused wakeup_lat variable, we see a new section displaying
+variable references. Variable references are displayed in a separate
+section because in addition to being logically separate from
+variables and values, they actually live in a separate hist_data
+array, var_refs[].
+
+In this example, the sched_switch trigger has a reference to a
+variable on the sched_waking trigger, $ts0. Looking at the details,
+we can see that the var.hist_data value of the referenced variable
+matches the previously displayed sched_waking trigger, and the var.idx
+value matches the previously displayed var.idx value for that
+variable. Also displayed is the var_ref_idx value for that variable
+reference, which is where the value for that variable is cached for
+use when the trigger is invoked::
+
+ # cat events/sched/sched_switch/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=next_pid:vals=hitcount:wakeup_lat=common_timestamp.usecs-$ts0:sort=hitcount:size=2048:clock=global [active]
+ #
+
+ hist_data: 00000000f4ee8006
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 0
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+ variable reference fields:
+
+ hist_data->var_refs[0]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 000000009536f554
+ var_ref_idx (into hist_data->var_refs[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+The commands below can be used to clean things up for the next test::
+
+ # echo '!hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0' >> events/sched/sched_switch/trigger
+
+ # echo '!hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+Actions and Handlers
+====================
+
+Adding onto the previous example, we will now do something with that
+wakeup_lat variable, namely send it and another field as a synthetic
+event.
+
+The onmatch() action below basically says that whenever we have a
+sched_switch event, if we have a matching sched_waking event, in this
+case if we have a pid in the sched_waking histogram that matches the
+next_pid field on this sched_switch event, we retrieve the
+variables specified in the wakeup_latency() trace action, and use
+them to generate a new wakeup_latency event into the trace stream.
+
+Note that the way the trace handlers such as wakeup_latency() (which
+could equivalently be written trace(wakeup_latency,$wakeup_lat,next_pid)
+are implemented, the parameters specified to the trace handler must be
+variables. In this case, $wakeup_lat is obviously a variable, but
+next_pid isn't, since it's just naming a field in the sched_switch
+trace event. Since this is something that almost every trace() and
+save() action does, a special shortcut is implemented to allow field
+names to be used directly in those cases. How it works is that under
+the covers, a temporary variable is created for the named field, and
+this variable is what is actually passed to the trace handler. In the
+code and documentation, this type of variable is called a 'field
+variable'.
+
+Fields on other trace event's histograms can be used as well. In that
+case we have to generate a new histogram and an unfortunately named
+'synthetic_field' (the use of synthetic here has nothing to do with
+synthetic events) and use that special histogram field as a variable.
+
+The diagram below illustrates the new elements described above in the
+context of the sched_switch histogram using the onmatch() handler and
+the trace() action.
+
+First, we define the wakeup_latency synthetic event::
+
+ # echo 'wakeup_latency u64 lat; pid_t pid' >> synthetic_events
+
+Next, the sched_waking hist trigger as before::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' >>
+ events/sched/sched_waking/trigger
+
+Finally, we create a hist trigger on the sched_switch event that
+generates a wakeup_latency() trace event. In this case we pass
+next_pid into the wakeup_latency synthetic event invocation, which
+means it will be automatically converted into a field variable::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0: \
+ onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid)' >>
+ /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+The diagram for the sched_switch event is similar to previous examples
+but shows the additional field_vars[] array for hist_data and shows
+the linkages between the field_vars and the variables and references
+created to implement the field variables. The details are discussed
+below::
+
+ +------------------+
+ | hist_data |
+ +------------------+ +-----------------------+
+ | .fields[] |-->| val = hitcount |
+ +----------------+ +-----------------------+
+ | .map | | .size |
+ +----------------+ +---------------------+
+ +---| .field_vars[] | | .offset |
+ | +----------------+ +---------------------+
+ |+--| .var_refs[] | | .offset |
+ || +----------------+ +---------------------+
+ || | .fn() |
+ || var_ref_vals[] +---------------------+
+ || +-------------+ | .flags |
+ || | $ts0 |<---+ +---------------------+
+ || +-------------+ | | .var.idx |
+ || | $next_pid |<-+ | +---------------------+
+ || +-------------+ | | | .var.hist_data |
+ ||+>| $wakeup_lat | | | +---------------------+
+ ||| +-------------+ | | | .var_ref_idx |
+ ||| | | | | +-----------------------+
+ ||| +-------------+ | | | var = wakeup_lat |
+ ||| . | | +-----------------------+
+ ||| . | | | .size |
+ ||| . | | +---------------------+
+ ||| +-------------+ | | | .offset |
+ ||| | | | | +---------------------+
+ ||| +-------------+ | | | .fn() |
+ ||| | | | | +---------------------+
+ ||| +-------------+ | | | .flags & FL_VAR |
+ ||| | | +---------------------+
+ ||| | | | .var.idx |
+ ||| | | +---------------------+
+ ||| | | | .var.hist_data |
+ ||| | | +---------------------+
+ ||| | | | .var_ref_idx |
+ ||| | | +---------------------+
+ ||| | | .
+ ||| | | .
+ ||| | | .
+ ||| | | .
+ ||| +--------------+ | | .
+ +-->| field_var | | | .
+ || +--------------+ | | .
+ || | var | | | .
+ || +------------+ | | .
+ || | val | | | .
+ || +--------------+ | | .
+ || | field_var | | | .
+ || +--------------+ | | .
+ || | var | | | .
+ || +------------+ | | .
+ || | val | | | .
+ || +------------+ | | .
+ || . | | .
+ || . | | .
+ || . | | +-----------------------+ <--- n_vals
+ || +--------------+ | | | key = pid |
+ || | field_var | | | +-----------------------+
+ || +--------------+ | | | .size |
+ || | var |--+| +---------------------+
+ || +------------+ ||| | .offset |
+ || | val |-+|| +---------------------+
+ || +------------+ ||| | .fn() |
+ || ||| +---------------------+
+ || ||| | .flags |
+ || ||| +---------------------+
+ || ||| | .var.idx |
+ || ||| +---------------------+ <--- n_fields
+ || |||
+ || ||| n_keys = n_fields - n_vals
+ || ||| +-----------------------+
+ || |+->| var = next_pid |
+ || | | +-----------------------+
+ || | | | .size |
+ || | | +---------------------+
+ || | | | .offset |
+ || | | +---------------------+
+ || | | | .flags & FL_VAR |
+ || | | +---------------------+
+ || | | | .var.idx |
+ || | | +---------------------+
+ || | | | .var.hist_data |
+ || | | +-----------------------+
+ || +-->| val for next_pid |
+ || | | +-----------------------+
+ || | | | .size |
+ || | | +---------------------+
+ || | | | .offset |
+ || | | +---------------------+
+ || | | | .fn() |
+ || | | +---------------------+
+ || | | | .flags |
+ || | | +---------------------+
+ || | | | |
+ || | | +---------------------+
+ || | |
+ || | |
+ || | | +-----------------------+
+ +|------------------|-|>| var_ref = $ts0 |
+ | | | +-----------------------+
+ | | | | .size |
+ | | | +---------------------+
+ | | | | .offset |
+ | | | +---------------------+
+ | | | | .fn() |
+ | | | +---------------------+
+ | | | | .flags & FL_VAR_REF |
+ | | | +---------------------+
+ | | +---| .var_ref_idx |
+ | | +-----------------------+
+ | | | var_ref = $next_pid |
+ | | +-----------------------+
+ | | | .size |
+ | | +---------------------+
+ | | | .offset |
+ | | +---------------------+
+ | | | .fn() |
+ | | +---------------------+
+ | | | .flags & FL_VAR_REF |
+ | | +---------------------+
+ | +-----| .var_ref_idx |
+ | +-----------------------+
+ | | var_ref = $wakeup_lat |
+ | +-----------------------+
+ | | .size |
+ | +---------------------+
+ | | .offset |
+ | +---------------------+
+ | | .fn() |
+ | +---------------------+
+ | | .flags & FL_VAR_REF |
+ | +---------------------+
+ +------------------------| .var_ref_idx |
+ +---------------------+
+
+As you can see, for a field variable, two hist_fields are created: one
+representing the variable, in this case next_pid, and one to actually
+get the value of the field from the trace stream, like a normal val
+field does. These are created separately from normal variable
+creation and are saved in the hist_data->field_vars[] array. See
+below for how these are used. In addition, a reference hist_field is
+also created, which is needed to reference the field variables such as
+$next_pid variable in the trace() action.
+
+Note that $wakeup_lat is also a variable reference, referencing the
+value of the expression common_timestamp-$ts0, and so also needs to
+have a hist field entry representing that reference created.
+
+When hist_trigger_elt_update() is called to get the normal key and
+value fields, it also calls update_field_vars(), which goes through
+each field_var created for the histogram, and available from
+hist_data->field_vars and calls val->fn() to get the data from the
+current trace record, and then uses the var's var.idx to set the
+variable at the var.idx offset in the appropriate tracing_map_elt's
+variable at elt->vars[var.idx].
+
+Once all the variables have been updated, resolve_var_refs() can be
+called from event_hist_trigger(), and not only can our $ts0 and
+$next_pid references be resolved but the $wakeup_lat reference as
+well. At this point, the trace() action can simply access the values
+assembled in the var_ref_vals[] array and generate the trace event.
+
+The same process occurs for the field variables associated with the
+save() action.
+
+Abbreviations used in the diagram::
+
+ hist_data = struct hist_trigger_data
+ hist_data.fields = struct hist_field
+ field_var = struct field_var
+ fn = hist_field_fn_t
+ FL_KEY = HIST_FIELD_FL_KEY
+ FL_VAR = HIST_FIELD_FL_VAR
+ FL_VAR_REF = HIST_FIELD_FL_VAR_REF
+
+trace() action field variable test
+----------------------------------
+
+This example adds to the previous test example by finally making use
+of the wakeup_lat variable, but in addition also creates a couple of
+field variables that then are all passed to the wakeup_latency() trace
+action via the onmatch() handler.
+
+First, we create the wakeup_latency synthetic event::
+
+ # echo 'wakeup_latency u64 lat; pid_t pid; char comm[16]' >> synthetic_events
+
+Next, the sched_waking trigger from previous examples::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+Finally, as in the previous test example, we calculate and assign the
+wakeup latency using the $ts0 reference from the sched_waking trigger
+to the wakeup_lat variable, and finally use it along with a couple
+sched_switch event fields, next_pid and next_comm, to generate a
+wakeup_latency trace event. The next_pid and next_comm event fields
+are automatically converted into field variables for this purpose::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid,next_comm)' >> /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+The sched_waking hist_debug output shows the same data as in the
+previous test example::
+
+ # cat events/sched/sched_waking/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid:vals=hitcount:ts0=common_timestamp.usecs:sort=hitcount:size=2048:clock=global [active]
+ #
+
+ hist_data: 00000000d60ff61f
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+The sched_switch hist_debug output shows the same key and value fields
+as in the previous test example - note that wakeup_lat is still in the
+val fields section, but that the new field variables are not there -
+although the field variables are variables, they're held separately in
+the hist_data's field_vars[] array. Although the field variables and
+the normal variables are located in separate places, you can see that
+the actual variable locations for those variables in the
+tracing_map_elt.vars[] do have increasing indices as expected:
+wakeup_lat takes the var.idx = 0 slot, while the field variables for
+next_pid and next_comm have values var.idx = 1, and var.idx = 2. Note
+also that those are the same values displayed for the variable
+references corresponding to those variables in the variable reference
+fields section. Since there are two triggers and thus two hist_data
+addresses, those addresses also need to be accounted for when doing
+the matching - you can see that the first variable refers to the 0
+var.idx on the previous hist trigger (see the hist_data address
+associated with that trigger), while the second variable refers to the
+0 var.idx on the sched_switch hist trigger, as do all the remaining
+variable references.
+
+Finally, the action tracking variables section just shows the system
+and event name for the onmatch() handler::
+
+ # cat events/sched/sched_switch/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=next_pid:vals=hitcount:wakeup_lat=common_timestamp.usecs-$ts0:sort=hitcount:size=2048:clock=global:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid,next_comm) [active]
+ #
+
+ hist_data: 0000000008f551b7
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 0
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+ variable reference fields:
+
+ hist_data->var_refs[0]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 00000000d60ff61f
+ var_ref_idx (into hist_data->var_refs[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->var_refs[1]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 0000000008f551b7
+ var_ref_idx (into hist_data->var_refs[]): 1
+ type: u64
+ size: 0
+ is_signed: 0
+
+ hist_data->var_refs[2]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: next_pid
+ var.idx (into tracing_map_elt.vars[]): 1
+ var.hist_data: 0000000008f551b7
+ var_ref_idx (into hist_data->var_refs[]): 2
+ type: pid_t
+ size: 4
+ is_signed: 0
+
+ hist_data->var_refs[3]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: next_comm
+ var.idx (into tracing_map_elt.vars[]): 2
+ var.hist_data: 0000000008f551b7
+ var_ref_idx (into hist_data->var_refs[]): 3
+ type: char[16]
+ size: 256
+ is_signed: 0
+
+ field variables:
+
+ hist_data->field_vars[0]:
+
+ field_vars[0].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: next_pid
+ var.idx (into tracing_map_elt.vars[]): 1
+
+ field_vars[0].val:
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ hist_data->field_vars[1]:
+
+ field_vars[1].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: next_comm
+ var.idx (into tracing_map_elt.vars[]): 2
+
+ field_vars[1].val:
+ ftrace_event_field name: next_comm
+ type: char[16]
+ size: 256
+ is_signed: 0
+
+ action tracking variables (for onmax()/onchange()/onmatch()):
+
+ hist_data->actions[0].match_data.event_system: sched
+ hist_data->actions[0].match_data.event: sched_waking
+
+The commands below can be used to clean things up for the next test::
+
+ # echo '!hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid,next_comm)' >> /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+ # echo '!hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+ # echo '!wakeup_latency u64 lat; pid_t pid; char comm[16]' >> synthetic_events
+
+action_data and the trace() action
+----------------------------------
+
+As mentioned above, when the trace() action generates a synthetic
+event, all the parameters to the synthetic event either already are
+variables or are converted into variables (via field variables), and
+finally all those variable values are collected via references to them
+into a var_ref_vals[] array.
+
+The values in the var_ref_vals[] array, however, don't necessarily
+follow the same ordering as the synthetic event params. To address
+that, struct action_data contains another array, var_ref_idx[] that
+maps the trace action params to the var_ref_vals[] values. Below is a
+diagram illustrating that for the wakeup_latency() synthetic event::
+
+ +------------------+ wakeup_latency()
+ | action_data | event params var_ref_vals[]
+ +------------------+ +-----------------+ +-----------------+
+ | .var_ref_idx[] |--->| $wakeup_lat idx |---+ | |
+ +----------------+ +-----------------+ | +-----------------+
+ | .synth_event | | $next_pid idx |---|-+ | $wakeup_lat val |
+ +----------------+ +-----------------+ | | +-----------------+
+ . | +->| $next_pid val |
+ . | +-----------------+
+ . | .
+ +-----------------+ | .
+ | | | .
+ +-----------------+ | +-----------------+
+ +--->| $wakeup_lat val |
+ +-----------------+
+
+Basically, how this ends up getting used in the synthetic event probe
+function, trace_event_raw_event_synth(), is as follows::
+
+ for each field i in .synth_event
+ val_idx = .var_ref_idx[i]
+ val = var_ref_vals[val_idx]
+
+action_data and the onXXX() handlers
+------------------------------------
+
+The hist trigger onXXX() actions other than onmatch(), such as onmax()
+and onchange(), also make use of and internally create hidden
+variables. This information is contained in the
+action_data.track_data struct, and is also visible in the hist_debug
+output as will be described in the example below.
+
+Typically, the onmax() or onchange() handlers are used in conjunction
+with the save() and snapshot() actions. For example::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0: \
+ onmax($wakeup_lat).save(next_comm,prev_pid,prev_prio,prev_comm)' >>
+ /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+or::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0: \
+ onmax($wakeup_lat).snapshot()' >>
+ /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+save() action field variable test
+---------------------------------
+
+For this example, instead of generating a synthetic event, the save()
+action is used to save field values whenever an onmax() handler
+detects that a new max latency has been hit. As in the previous
+example, the values being saved are also field values, but in this
+case, are kept in a separate hist_data array named save_vars[].
+
+As in previous test examples, we set up the sched_waking trigger::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+In this case, however, we set up the sched_switch trigger to save some
+sched_switch field values whenever we hit a new maximum latency. For
+both the onmax() handler and save() action, variables will be created,
+which we can use the hist_debug files to examine::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmax($wakeup_lat).save(next_comm,prev_pid,prev_prio,prev_comm)' >> events/sched/sched_switch/trigger
+
+The sched_waking hist_debug output shows the same data as in the
+previous test examples::
+
+ # cat events/sched/sched_waking/hist_debug
+
+ #
+ # trigger info: hist:keys=pid:vals=hitcount:ts0=common_timestamp.usecs:sort=hitcount:size=2048:clock=global [active]
+ #
+
+ hist_data: 00000000e6290f48
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+The output of the sched_switch trigger shows the same val and key
+values as before, but also shows a couple new sections.
+
+First, the action tracking variables section now shows the
+actions[].track_data information describing the special tracking
+variables and references used to track, in this case, the running
+maximum value. The actions[].track_data.var_ref member contains the
+reference to the variable being tracked, in this case the $wakeup_lat
+variable. In order to perform the onmax() handler function, there
+also needs to be a variable that tracks the current maximum by getting
+updated whenever a new maximum is hit. In this case, we can see that
+an auto-generated variable named ' __max' has been created and is
+visible in the actions[].track_data.track_var variable.
+
+Finally, in the new 'save action variables' section, we can see that
+the 4 params to the save() function have resulted in 4 field variables
+being created for the purposes of saving the values of the named
+fields when the max is hit. These variables are kept in a separate
+save_vars[] array off of hist_data, so are displayed in a separate
+section::
+
+ # cat events/sched/sched_switch/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=next_pid:vals=hitcount:wakeup_lat=common_timestamp.usecs-$ts0:sort=hitcount:size=2048:clock=global:onmax($wakeup_lat).save(next_comm,prev_pid,prev_prio,prev_comm) [active]
+ #
+
+ hist_data: 0000000057bcd28d
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 0
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+ variable reference fields:
+
+ hist_data->var_refs[0]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 00000000e6290f48
+ var_ref_idx (into hist_data->var_refs[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->var_refs[1]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 0000000057bcd28d
+ var_ref_idx (into hist_data->var_refs[]): 1
+ type: u64
+ size: 0
+ is_signed: 0
+
+ action tracking variables (for onmax()/onchange()/onmatch()):
+
+ hist_data->actions[0].track_data.var_ref:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 0000000057bcd28d
+ var_ref_idx (into hist_data->var_refs[]): 1
+ type: u64
+ size: 0
+ is_signed: 0
+
+ hist_data->actions[0].track_data.track_var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: __max
+ var.idx (into tracing_map_elt.vars[]): 1
+ type: u64
+ size: 8
+ is_signed: 0
+
+ save action variables (save() params):
+
+ hist_data->save_vars[0]:
+
+ save_vars[0].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: next_comm
+ var.idx (into tracing_map_elt.vars[]): 2
+
+ save_vars[0].val:
+ ftrace_event_field name: next_comm
+ type: char[16]
+ size: 256
+ is_signed: 0
+
+ hist_data->save_vars[1]:
+
+ save_vars[1].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: prev_pid
+ var.idx (into tracing_map_elt.vars[]): 3
+
+ save_vars[1].val:
+ ftrace_event_field name: prev_pid
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ hist_data->save_vars[2]:
+
+ save_vars[2].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: prev_prio
+ var.idx (into tracing_map_elt.vars[]): 4
+
+ save_vars[2].val:
+ ftrace_event_field name: prev_prio
+ type: int
+ size: 4
+ is_signed: 1
+
+ hist_data->save_vars[3]:
+
+ save_vars[3].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: prev_comm
+ var.idx (into tracing_map_elt.vars[]): 5
+
+ save_vars[3].val:
+ ftrace_event_field name: prev_comm
+ type: char[16]
+ size: 256
+ is_signed: 0
+
+The commands below can be used to clean things up for the next test::
+
+ # echo '!hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmax($wakeup_lat).save(next_comm,prev_pid,prev_prio,prev_comm)' >> events/sched/sched_switch/trigger
+
+ # echo '!hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+A couple special cases
+======================
+
+While the above covers the basics of the histogram internals, there
+are a couple of special cases that should be discussed, since they
+tend to create even more confusion. Those are field variables on other
+histograms, and aliases, both described below through example tests
+using the hist_debug files.
+
+Test of field variables on other histograms
+-------------------------------------------
+
+This example is similar to the previous examples, but in this case,
+the sched_switch trigger references a hist trigger field on another
+event, namely the sched_waking event. In order to accomplish this, a
+field variable is created for the other event, but since an existing
+histogram can't be used, as existing histograms are immutable, a new
+histogram with a matching variable is created and used, and we'll see
+that reflected in the hist_debug output shown below.
+
+First, we create the wakeup_latency synthetic event. Note the
+addition of the prio field::
+
+ # echo 'wakeup_latency u64 lat; pid_t pid; int prio' >> synthetic_events
+
+As in previous test examples, we set up the sched_waking trigger::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+Here we set up a hist trigger on sched_switch to send a wakeup_latency
+event using an onmatch handler naming the sched_waking event. Note
+that the third param being passed to the wakeup_latency() is prio,
+which is a field name that needs to have a field variable created for
+it. There isn't however any prio field on the sched_switch event so
+it would seem that it wouldn't be possible to create a field variable
+for it. The matching sched_waking event does have a prio field, so it
+should be possible to make use of it for this purpose. The problem
+with that is that it's not currently possible to define a new variable
+on an existing histogram, so it's not possible to add a new prio field
+variable to the existing sched_waking histogram. It is however
+possible to create an additional new 'matching' sched_waking histogram
+for the same event, meaning that it uses the same key and filters, and
+define the new prio field variable on that.
+
+Here's the sched_switch trigger::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid,prio)' >> events/sched/sched_switch/trigger
+
+And here's the output of the hist_debug information for the
+sched_waking hist trigger. Note that there are two histograms
+displayed in the output: the first is the normal sched_waking
+histogram we've seen in the previous examples, and the second is the
+special histogram we created to provide the prio field variable.
+
+Looking at the second histogram below, we see a variable with the name
+synthetic_prio. This is the field variable created for the prio field
+on that sched_waking histogram::
+
+ # cat events/sched/sched_waking/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid:vals=hitcount:ts0=common_timestamp.usecs:sort=hitcount:size=2048:clock=global [active]
+ #
+
+ hist_data: 00000000349570e4
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid:vals=hitcount:synthetic_prio=prio:sort=hitcount:size=2048 [active]
+ #
+
+ hist_data: 000000006920cf38
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ ftrace_event_field name: prio
+ var.name: synthetic_prio
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: int
+ size: 4
+ is_signed: 1
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+Looking at the sched_switch histogram below, we can see a reference to
+the synthetic_prio variable on sched_waking, and looking at the
+associated hist_data address we see that it is indeed associated with
+the new histogram. Note also that the other references are to a
+normal variable, wakeup_lat, and to a normal field variable, next_pid,
+the details of which are in the field variables section::
+
+ # cat events/sched/sched_switch/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=next_pid:vals=hitcount:wakeup_lat=common_timestamp.usecs-$ts0:sort=hitcount:size=2048:clock=global:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid,prio) [active]
+ #
+
+ hist_data: 00000000a73b67df
+
+ n_vals: 2
+ n_keys: 1
+ n_fields: 3
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: u64
+ size: 0
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+ variable reference fields:
+
+ hist_data->var_refs[0]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: ts0
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 00000000349570e4
+ var_ref_idx (into hist_data->var_refs[]): 0
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->var_refs[1]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 00000000a73b67df
+ var_ref_idx (into hist_data->var_refs[]): 1
+ type: u64
+ size: 0
+ is_signed: 0
+
+ hist_data->var_refs[2]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: next_pid
+ var.idx (into tracing_map_elt.vars[]): 1
+ var.hist_data: 00000000a73b67df
+ var_ref_idx (into hist_data->var_refs[]): 2
+ type: pid_t
+ size: 4
+ is_signed: 0
+
+ hist_data->var_refs[3]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: synthetic_prio
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 000000006920cf38
+ var_ref_idx (into hist_data->var_refs[]): 3
+ type: int
+ size: 4
+ is_signed: 1
+
+ field variables:
+
+ hist_data->field_vars[0]:
+
+ field_vars[0].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: next_pid
+ var.idx (into tracing_map_elt.vars[]): 1
+
+ field_vars[0].val:
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ action tracking variables (for onmax()/onchange()/onmatch()):
+
+ hist_data->actions[0].match_data.event_system: sched
+ hist_data->actions[0].match_data.event: sched_waking
+
+The commands below can be used to clean things up for the next test::
+
+ # echo '!hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,next_pid,prio)' >> events/sched/sched_switch/trigger
+
+ # echo '!hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+ # echo '!wakeup_latency u64 lat; pid_t pid; int prio' >> synthetic_events
+
+Alias test
+----------
+
+This example is very similar to previous examples, but demonstrates
+the alias flag.
+
+First, we create the wakeup_latency synthetic event::
+
+ # echo 'wakeup_latency u64 lat; pid_t pid; char comm[16]' >> synthetic_events
+
+Next, we create a sched_waking trigger similar to previous examples,
+but in this case we save the pid in the waking_pid variable::
+
+ # echo 'hist:keys=pid:waking_pid=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+For the sched_switch trigger, instead of using $waking_pid directly in
+the wakeup_latency synthetic event invocation, we create an alias of
+$waking_pid named $woken_pid, and use that in the synthetic event
+invocation instead::
+
+ # echo 'hist:keys=next_pid:woken_pid=$waking_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,$woken_pid,next_comm)' >> events/sched/sched_switch/trigger
+
+Looking at the sched_waking hist_debug output, in addition to the
+normal fields, we can see the waking_pid variable::
+
+ # cat events/sched/sched_waking/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid:vals=hitcount:waking_pid=pid,ts0=common_timestamp.usecs:sort=hitcount:size=2048:clock=global [active]
+ #
+
+ hist_data: 00000000a250528c
+
+ n_vals: 3
+ n_keys: 1
+ n_fields: 4
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ ftrace_event_field name: pid
+ var.name: waking_pid
+ var.idx (into tracing_map_elt.vars[]): 0
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: ts0
+ var.idx (into tracing_map_elt.vars[]): 1
+ type: u64
+ size: 8
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[3]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+The sched_switch hist_debug output shows that a variable named
+woken_pid has been created but that it also has the
+HIST_FIELD_FL_ALIAS flag set. It also has the HIST_FIELD_FL_VAR flag
+set, which is why it appears in the val field section.
+
+Despite that implementation detail, an alias variable is actually more
+like a variable reference; in fact it can be thought of as a reference
+to a reference. The implementation copies the var_ref->fn() from the
+variable reference being referenced, in this case, the waking_pid
+fn(), which is hist_field_var_ref() and makes that the fn() of the
+alias. The hist_field_var_ref() fn() requires the var_ref_idx of the
+variable reference it's using, so waking_pid's var_ref_idx is also
+copied to the alias. The end result is that when the value of alias
+is retrieved, in the end it just does the same thing the original
+reference would have done and retrieves the same value from the
+var_ref_vals[] array. You can verify this in the output by noting
+that the var_ref_idx of the alias, in this case woken_pid, is the same
+as the var_ref_idx of the reference, waking_pid, in the variable
+reference fields section.
+
+Additionally, once it gets that value, since it is also a variable, it
+then saves that value into its var.idx. So the var.idx of the
+woken_pid alias is 0, which it fills with the value from var_ref_idx 0
+when its fn() is called to update itself. You'll also notice that
+there's a woken_pid var_ref in the variable refs section. That is the
+reference to the woken_pid alias variable, and you can see that it
+retrieves the value from the same var.idx as the woken_pid alias, 0,
+and then in turn saves that value in its own var_ref_idx slot, 3, and
+the value at this position is finally what gets assigned to the
+$woken_pid slot in the trace event invocation::
+
+ # cat events/sched/sched_switch/hist_debug
+
+ # event histogram
+ #
+ # trigger info: hist:keys=next_pid:vals=hitcount:woken_pid=$waking_pid,wakeup_lat=common_timestamp.usecs-$ts0:sort=hitcount:size=2048:clock=global:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,$woken_pid,next_comm) [active]
+ #
+
+ hist_data: 0000000055d65ed0
+
+ n_vals: 3
+ n_keys: 1
+ n_fields: 4
+
+ val fields:
+
+ hist_data->fields[0]:
+ flags:
+ VAL: HIST_FIELD_FL_HITCOUNT
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->fields[1]:
+ flags:
+ HIST_FIELD_FL_VAR
+ HIST_FIELD_FL_ALIAS
+ var.name: woken_pid
+ var.idx (into tracing_map_elt.vars[]): 0
+ var_ref_idx (into hist_data->var_refs[]): 0
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ hist_data->fields[2]:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 1
+ type: u64
+ size: 0
+ is_signed: 0
+
+ key fields:
+
+ hist_data->fields[3]:
+ flags:
+ HIST_FIELD_FL_KEY
+ ftrace_event_field name: next_pid
+ type: pid_t
+ size: 8
+ is_signed: 1
+
+ variable reference fields:
+
+ hist_data->var_refs[0]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: waking_pid
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 00000000a250528c
+ var_ref_idx (into hist_data->var_refs[]): 0
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ hist_data->var_refs[1]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: ts0
+ var.idx (into tracing_map_elt.vars[]): 1
+ var.hist_data: 00000000a250528c
+ var_ref_idx (into hist_data->var_refs[]): 1
+ type: u64
+ size: 8
+ is_signed: 0
+
+ hist_data->var_refs[2]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: wakeup_lat
+ var.idx (into tracing_map_elt.vars[]): 1
+ var.hist_data: 0000000055d65ed0
+ var_ref_idx (into hist_data->var_refs[]): 2
+ type: u64
+ size: 0
+ is_signed: 0
+
+ hist_data->var_refs[3]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: woken_pid
+ var.idx (into tracing_map_elt.vars[]): 0
+ var.hist_data: 0000000055d65ed0
+ var_ref_idx (into hist_data->var_refs[]): 3
+ type: pid_t
+ size: 4
+ is_signed: 1
+
+ hist_data->var_refs[4]:
+ flags:
+ HIST_FIELD_FL_VAR_REF
+ name: next_comm
+ var.idx (into tracing_map_elt.vars[]): 2
+ var.hist_data: 0000000055d65ed0
+ var_ref_idx (into hist_data->var_refs[]): 4
+ type: char[16]
+ size: 256
+ is_signed: 0
+
+ field variables:
+
+ hist_data->field_vars[0]:
+
+ field_vars[0].var:
+ flags:
+ HIST_FIELD_FL_VAR
+ var.name: next_comm
+ var.idx (into tracing_map_elt.vars[]): 2
+
+ field_vars[0].val:
+ ftrace_event_field name: next_comm
+ type: char[16]
+ size: 256
+ is_signed: 0
+
+ action tracking variables (for onmax()/onchange()/onmatch()):
+
+ hist_data->actions[0].match_data.event_system: sched
+ hist_data->actions[0].match_data.event: sched_waking
+
+The commands below can be used to clean things up for the next test::
+
+ # echo '!hist:keys=next_pid:woken_pid=$waking_pid:wakeup_lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,$woken_pid,next_comm)' >> events/sched/sched_switch/trigger
+
+ # echo '!hist:keys=pid:ts0=common_timestamp.usecs' >> events/sched/sched_waking/trigger
+
+ # echo '!wakeup_latency u64 lat; pid_t pid; char comm[16]' >> synthetic_events
diff --git a/Documentation/trace/histogram.rst b/Documentation/trace/histogram.rst
new file mode 100644
index 000000000..87bd77283
--- /dev/null
+++ b/Documentation/trace/histogram.rst
@@ -0,0 +1,2909 @@
+================
+Event Histograms
+================
+
+Documentation written by Tom Zanussi
+
+1. Introduction
+===============
+
+ Histogram triggers are special event triggers that can be used to
+ aggregate trace event data into histograms. For information on
+ trace events and event triggers, see Documentation/trace/events.rst.
+
+
+2. Histogram Trigger Command
+============================
+
+ A histogram trigger command is an event trigger command that
+ aggregates event hits into a hash table keyed on one or more trace
+ event format fields (or stacktrace) and a set of running totals
+ derived from one or more trace event format fields and/or event
+ counts (hitcount).
+
+ The format of a hist trigger is as follows::
+
+ hist:keys=<field1[,field2,...]>[:values=<field1[,field2,...]>]
+ [:sort=<field1[,field2,...]>][:size=#entries][:pause][:continue]
+ [:clear][:name=histname1][:<handler>.<action>] [if <filter>]
+
+ When a matching event is hit, an entry is added to a hash table
+ using the key(s) and value(s) named. Keys and values correspond to
+ fields in the event's format description. Values must correspond to
+ numeric fields - on an event hit, the value(s) will be added to a
+ sum kept for that field. The special string 'hitcount' can be used
+ in place of an explicit value field - this is simply a count of
+ event hits. If 'values' isn't specified, an implicit 'hitcount'
+ value will be automatically created and used as the only value.
+ Keys can be any field, or the special string 'stacktrace', which
+ will use the event's kernel stacktrace as the key. The keywords
+ 'keys' or 'key' can be used to specify keys, and the keywords
+ 'values', 'vals', or 'val' can be used to specify values. Compound
+ keys consisting of up to three fields can be specified by the 'keys'
+ keyword. Hashing a compound key produces a unique entry in the
+ table for each unique combination of component keys, and can be
+ useful for providing more fine-grained summaries of event data.
+ Additionally, sort keys consisting of up to two fields can be
+ specified by the 'sort' keyword. If more than one field is
+ specified, the result will be a 'sort within a sort': the first key
+ is taken to be the primary sort key and the second the secondary
+ key. If a hist trigger is given a name using the 'name' parameter,
+ its histogram data will be shared with other triggers of the same
+ name, and trigger hits will update this common data. Only triggers
+ with 'compatible' fields can be combined in this way; triggers are
+ 'compatible' if the fields named in the trigger share the same
+ number and type of fields and those fields also have the same names.
+ Note that any two events always share the compatible 'hitcount' and
+ 'stacktrace' fields and can therefore be combined using those
+ fields, however pointless that may be.
+
+ 'hist' triggers add a 'hist' file to each event's subdirectory.
+ Reading the 'hist' file for the event will dump the hash table in
+ its entirety to stdout. If there are multiple hist triggers
+ attached to an event, there will be a table for each trigger in the
+ output. The table displayed for a named trigger will be the same as
+ any other instance having the same name. Each printed hash table
+ entry is a simple list of the keys and values comprising the entry;
+ keys are printed first and are delineated by curly braces, and are
+ followed by the set of value fields for the entry. By default,
+ numeric fields are displayed as base-10 integers. This can be
+ modified by appending any of the following modifiers to the field
+ name:
+
+ ============= =================================================
+ .hex display a number as a hex value
+ .sym display an address as a symbol
+ .sym-offset display an address as a symbol and offset
+ .syscall display a syscall id as a system call name
+ .execname display a common_pid as a program name
+ .log2 display log2 value rather than raw number
+ .buckets=size display grouping of values rather than raw number
+ .usecs display a common_timestamp in microseconds
+ ============= =================================================
+
+ Note that in general the semantics of a given field aren't
+ interpreted when applying a modifier to it, but there are some
+ restrictions to be aware of in this regard:
+
+ - only the 'hex' modifier can be used for values (because values
+ are essentially sums, and the other modifiers don't make sense
+ in that context).
+ - the 'execname' modifier can only be used on a 'common_pid'. The
+ reason for this is that the execname is simply the 'comm' value
+ saved for the 'current' process when an event was triggered,
+ which is the same as the common_pid value saved by the event
+ tracing code. Trying to apply that comm value to other pid
+ values wouldn't be correct, and typically events that care save
+ pid-specific comm fields in the event itself.
+
+ A typical usage scenario would be the following to enable a hist
+ trigger, read its current contents, and then turn it off::
+
+ # echo 'hist:keys=skbaddr.hex:vals=len' > \
+ /sys/kernel/debug/tracing/events/net/netif_rx/trigger
+
+ # cat /sys/kernel/debug/tracing/events/net/netif_rx/hist
+
+ # echo '!hist:keys=skbaddr.hex:vals=len' > \
+ /sys/kernel/debug/tracing/events/net/netif_rx/trigger
+
+ The trigger file itself can be read to show the details of the
+ currently attached hist trigger. This information is also displayed
+ at the top of the 'hist' file when read.
+
+ By default, the size of the hash table is 2048 entries. The 'size'
+ parameter can be used to specify more or fewer than that. The units
+ are in terms of hashtable entries - if a run uses more entries than
+ specified, the results will show the number of 'drops', the number
+ of hits that were ignored. The size should be a power of 2 between
+ 128 and 131072 (any non- power-of-2 number specified will be rounded
+ up).
+
+ The 'sort' parameter can be used to specify a value field to sort
+ on. The default if unspecified is 'hitcount' and the default sort
+ order is 'ascending'. To sort in the opposite direction, append
+ .descending' to the sort key.
+
+ The 'pause' parameter can be used to pause an existing hist trigger
+ or to start a hist trigger but not log any events until told to do
+ so. 'continue' or 'cont' can be used to start or restart a paused
+ hist trigger.
+
+ The 'clear' parameter will clear the contents of a running hist
+ trigger and leave its current paused/active state.
+
+ Note that the 'pause', 'cont', and 'clear' parameters should be
+ applied using 'append' shell operator ('>>') if applied to an
+ existing trigger, rather than via the '>' operator, which will cause
+ the trigger to be removed through truncation.
+
+- enable_hist/disable_hist
+
+ The enable_hist and disable_hist triggers can be used to have one
+ event conditionally start and stop another event's already-attached
+ hist trigger. Any number of enable_hist and disable_hist triggers
+ can be attached to a given event, allowing that event to kick off
+ and stop aggregations on a host of other events.
+
+ The format is very similar to the enable/disable_event triggers::
+
+ enable_hist:<system>:<event>[:count]
+ disable_hist:<system>:<event>[:count]
+
+ Instead of enabling or disabling the tracing of the target event
+ into the trace buffer as the enable/disable_event triggers do, the
+ enable/disable_hist triggers enable or disable the aggregation of
+ the target event into a hash table.
+
+ A typical usage scenario for the enable_hist/disable_hist triggers
+ would be to first set up a paused hist trigger on some event,
+ followed by an enable_hist/disable_hist pair that turns the hist
+ aggregation on and off when conditions of interest are hit::
+
+ # echo 'hist:keys=skbaddr.hex:vals=len:pause' > \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+
+ # echo 'enable_hist:net:netif_receive_skb if filename==/usr/bin/wget' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_exec/trigger
+
+ # echo 'disable_hist:net:netif_receive_skb if comm==wget' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_exit/trigger
+
+ The above sets up an initially paused hist trigger which is unpaused
+ and starts aggregating events when a given program is executed, and
+ which stops aggregating when the process exits and the hist trigger
+ is paused again.
+
+ The examples below provide a more concrete illustration of the
+ concepts and typical usage patterns discussed above.
+
+'special' event fields
+------------------------
+
+ There are a number of 'special event fields' available for use as
+ keys or values in a hist trigger. These look like and behave as if
+ they were actual event fields, but aren't really part of the event's
+ field definition or format file. They are however available for any
+ event, and can be used anywhere an actual event field could be.
+ They are:
+
+ ====================== ==== =======================================
+ common_timestamp u64 timestamp (from ring buffer) associated
+ with the event, in nanoseconds. May be
+ modified by .usecs to have timestamps
+ interpreted as microseconds.
+ common_cpu int the cpu on which the event occurred.
+ ====================== ==== =======================================
+
+Extended error information
+--------------------------
+
+ For some error conditions encountered when invoking a hist trigger
+ command, extended error information is available via the
+ tracing/error_log file. See Error Conditions in
+ :file:`Documentation/trace/ftrace.rst` for details.
+
+6.2 'hist' trigger examples
+---------------------------
+
+ The first set of examples creates aggregations using the kmalloc
+ event. The fields that can be used for the hist trigger are listed
+ in the kmalloc event's format file::
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/format
+ name: kmalloc
+ ID: 374
+ format:
+ field:unsigned short common_type; offset:0; size:2; signed:0;
+ field:unsigned char common_flags; offset:2; size:1; signed:0;
+ field:unsigned char common_preempt_count; offset:3; size:1; signed:0;
+ field:int common_pid; offset:4; size:4; signed:1;
+
+ field:unsigned long call_site; offset:8; size:8; signed:0;
+ field:const void * ptr; offset:16; size:8; signed:0;
+ field:size_t bytes_req; offset:24; size:8; signed:0;
+ field:size_t bytes_alloc; offset:32; size:8; signed:0;
+ field:gfp_t gfp_flags; offset:40; size:4; signed:0;
+
+ We'll start by creating a hist trigger that generates a simple table
+ that lists the total number of bytes requested for each function in
+ the kernel that made one or more calls to kmalloc::
+
+ # echo 'hist:key=call_site:val=bytes_req.buckets=32' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ This tells the tracing system to create a 'hist' trigger using the
+ call_site field of the kmalloc event as the key for the table, which
+ just means that each unique call_site address will have an entry
+ created for it in the table. The 'val=bytes_req' parameter tells
+ the hist trigger that for each unique entry (call_site) in the
+ table, it should keep a running total of the number of bytes
+ requested by that call_site.
+
+ We'll let it run for awhile and then dump the contents of the 'hist'
+ file in the kmalloc event's subdirectory (for readability, a number
+ of entries have been omitted)::
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=call_site:vals=bytes_req:sort=hitcount:size=2048 [active]
+
+ { call_site: 18446744072106379007 } hitcount: 1 bytes_req: 176
+ { call_site: 18446744071579557049 } hitcount: 1 bytes_req: 1024
+ { call_site: 18446744071580608289 } hitcount: 1 bytes_req: 16384
+ { call_site: 18446744071581827654 } hitcount: 1 bytes_req: 24
+ { call_site: 18446744071580700980 } hitcount: 1 bytes_req: 8
+ { call_site: 18446744071579359876 } hitcount: 1 bytes_req: 152
+ { call_site: 18446744071580795365 } hitcount: 3 bytes_req: 144
+ { call_site: 18446744071581303129 } hitcount: 3 bytes_req: 144
+ { call_site: 18446744071580713234 } hitcount: 4 bytes_req: 2560
+ { call_site: 18446744071580933750 } hitcount: 4 bytes_req: 736
+ .
+ .
+ .
+ { call_site: 18446744072106047046 } hitcount: 69 bytes_req: 5576
+ { call_site: 18446744071582116407 } hitcount: 73 bytes_req: 2336
+ { call_site: 18446744072106054684 } hitcount: 136 bytes_req: 140504
+ { call_site: 18446744072106224230 } hitcount: 136 bytes_req: 19584
+ { call_site: 18446744072106078074 } hitcount: 153 bytes_req: 2448
+ { call_site: 18446744072106062406 } hitcount: 153 bytes_req: 36720
+ { call_site: 18446744071582507929 } hitcount: 153 bytes_req: 37088
+ { call_site: 18446744072102520590 } hitcount: 273 bytes_req: 10920
+ { call_site: 18446744071582143559 } hitcount: 358 bytes_req: 716
+ { call_site: 18446744072106465852 } hitcount: 417 bytes_req: 56712
+ { call_site: 18446744072102523378 } hitcount: 485 bytes_req: 27160
+ { call_site: 18446744072099568646 } hitcount: 1676 bytes_req: 33520
+
+ Totals:
+ Hits: 4610
+ Entries: 45
+ Dropped: 0
+
+ The output displays a line for each entry, beginning with the key
+ specified in the trigger, followed by the value(s) also specified in
+ the trigger. At the beginning of the output is a line that displays
+ the trigger info, which can also be displayed by reading the
+ 'trigger' file::
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+ hist:keys=call_site:vals=bytes_req:sort=hitcount:size=2048 [active]
+
+ At the end of the output are a few lines that display the overall
+ totals for the run. The 'Hits' field shows the total number of
+ times the event trigger was hit, the 'Entries' field shows the total
+ number of used entries in the hash table, and the 'Dropped' field
+ shows the number of hits that were dropped because the number of
+ used entries for the run exceeded the maximum number of entries
+ allowed for the table (normally 0, but if not a hint that you may
+ want to increase the size of the table using the 'size' parameter).
+
+ Notice in the above output that there's an extra field, 'hitcount',
+ which wasn't specified in the trigger. Also notice that in the
+ trigger info output, there's a parameter, 'sort=hitcount', which
+ wasn't specified in the trigger either. The reason for that is that
+ every trigger implicitly keeps a count of the total number of hits
+ attributed to a given entry, called the 'hitcount'. That hitcount
+ information is explicitly displayed in the output, and in the
+ absence of a user-specified sort parameter, is used as the default
+ sort field.
+
+ The value 'hitcount' can be used in place of an explicit value in
+ the 'values' parameter if you don't really need to have any
+ particular field summed and are mainly interested in hit
+ frequencies.
+
+ To turn the hist trigger off, simply call up the trigger in the
+ command history and re-execute it with a '!' prepended::
+
+ # echo '!hist:key=call_site:val=bytes_req' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ Finally, notice that the call_site as displayed in the output above
+ isn't really very useful. It's an address, but normally addresses
+ are displayed in hex. To have a numeric field displayed as a hex
+ value, simply append '.hex' to the field name in the trigger::
+
+ # echo 'hist:key=call_site.hex:val=bytes_req' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=call_site.hex:vals=bytes_req:sort=hitcount:size=2048 [active]
+
+ { call_site: ffffffffa026b291 } hitcount: 1 bytes_req: 433
+ { call_site: ffffffffa07186ff } hitcount: 1 bytes_req: 176
+ { call_site: ffffffff811ae721 } hitcount: 1 bytes_req: 16384
+ { call_site: ffffffff811c5134 } hitcount: 1 bytes_req: 8
+ { call_site: ffffffffa04a9ebb } hitcount: 1 bytes_req: 511
+ { call_site: ffffffff8122e0a6 } hitcount: 1 bytes_req: 12
+ { call_site: ffffffff8107da84 } hitcount: 1 bytes_req: 152
+ { call_site: ffffffff812d8246 } hitcount: 1 bytes_req: 24
+ { call_site: ffffffff811dc1e5 } hitcount: 3 bytes_req: 144
+ { call_site: ffffffffa02515e8 } hitcount: 3 bytes_req: 648
+ { call_site: ffffffff81258159 } hitcount: 3 bytes_req: 144
+ { call_site: ffffffff811c80f4 } hitcount: 4 bytes_req: 544
+ .
+ .
+ .
+ { call_site: ffffffffa06c7646 } hitcount: 106 bytes_req: 8024
+ { call_site: ffffffffa06cb246 } hitcount: 132 bytes_req: 31680
+ { call_site: ffffffffa06cef7a } hitcount: 132 bytes_req: 2112
+ { call_site: ffffffff8137e399 } hitcount: 132 bytes_req: 23232
+ { call_site: ffffffffa06c941c } hitcount: 185 bytes_req: 171360
+ { call_site: ffffffffa06f2a66 } hitcount: 185 bytes_req: 26640
+ { call_site: ffffffffa036a70e } hitcount: 265 bytes_req: 10600
+ { call_site: ffffffff81325447 } hitcount: 292 bytes_req: 584
+ { call_site: ffffffffa072da3c } hitcount: 446 bytes_req: 60656
+ { call_site: ffffffffa036b1f2 } hitcount: 526 bytes_req: 29456
+ { call_site: ffffffffa0099c06 } hitcount: 1780 bytes_req: 35600
+
+ Totals:
+ Hits: 4775
+ Entries: 46
+ Dropped: 0
+
+ Even that's only marginally more useful - while hex values do look
+ more like addresses, what users are typically more interested in
+ when looking at text addresses are the corresponding symbols
+ instead. To have an address displayed as symbolic value instead,
+ simply append '.sym' or '.sym-offset' to the field name in the
+ trigger::
+
+ # echo 'hist:key=call_site.sym:val=bytes_req' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=call_site.sym:vals=bytes_req:sort=hitcount:size=2048 [active]
+
+ { call_site: [ffffffff810adcb9] syslog_print_all } hitcount: 1 bytes_req: 1024
+ { call_site: [ffffffff8154bc62] usb_control_msg } hitcount: 1 bytes_req: 8
+ { call_site: [ffffffffa00bf6fe] hidraw_send_report [hid] } hitcount: 1 bytes_req: 7
+ { call_site: [ffffffff8154acbe] usb_alloc_urb } hitcount: 1 bytes_req: 192
+ { call_site: [ffffffffa00bf1ca] hidraw_report_event [hid] } hitcount: 1 bytes_req: 7
+ { call_site: [ffffffff811e3a25] __seq_open_private } hitcount: 1 bytes_req: 40
+ { call_site: [ffffffff8109524a] alloc_fair_sched_group } hitcount: 2 bytes_req: 128
+ { call_site: [ffffffff811febd5] fsnotify_alloc_group } hitcount: 2 bytes_req: 528
+ { call_site: [ffffffff81440f58] __tty_buffer_request_room } hitcount: 2 bytes_req: 2624
+ { call_site: [ffffffff81200ba6] inotify_new_group } hitcount: 2 bytes_req: 96
+ { call_site: [ffffffffa05e19af] ieee80211_start_tx_ba_session [mac80211] } hitcount: 2 bytes_req: 464
+ { call_site: [ffffffff81672406] tcp_get_metrics } hitcount: 2 bytes_req: 304
+ { call_site: [ffffffff81097ec2] alloc_rt_sched_group } hitcount: 2 bytes_req: 128
+ { call_site: [ffffffff81089b05] sched_create_group } hitcount: 2 bytes_req: 1424
+ .
+ .
+ .
+ { call_site: [ffffffffa04a580c] intel_crtc_page_flip [i915] } hitcount: 1185 bytes_req: 123240
+ { call_site: [ffffffffa0287592] drm_mode_page_flip_ioctl [drm] } hitcount: 1185 bytes_req: 104280
+ { call_site: [ffffffffa04c4a3c] intel_plane_duplicate_state [i915] } hitcount: 1402 bytes_req: 190672
+ { call_site: [ffffffff812891ca] ext4_find_extent } hitcount: 1518 bytes_req: 146208
+ { call_site: [ffffffffa029070e] drm_vma_node_allow [drm] } hitcount: 1746 bytes_req: 69840
+ { call_site: [ffffffffa045e7c4] i915_gem_do_execbuffer.isra.23 [i915] } hitcount: 2021 bytes_req: 792312
+ { call_site: [ffffffffa02911f2] drm_modeset_lock_crtc [drm] } hitcount: 2592 bytes_req: 145152
+ { call_site: [ffffffffa0489a66] intel_ring_begin [i915] } hitcount: 2629 bytes_req: 378576
+ { call_site: [ffffffffa046041c] i915_gem_execbuffer2 [i915] } hitcount: 2629 bytes_req: 3783248
+ { call_site: [ffffffff81325607] apparmor_file_alloc_security } hitcount: 5192 bytes_req: 10384
+ { call_site: [ffffffffa00b7c06] hid_report_raw_event [hid] } hitcount: 5529 bytes_req: 110584
+ { call_site: [ffffffff8131ebf7] aa_alloc_task_context } hitcount: 21943 bytes_req: 702176
+ { call_site: [ffffffff8125847d] ext4_htree_store_dirent } hitcount: 55759 bytes_req: 5074265
+
+ Totals:
+ Hits: 109928
+ Entries: 71
+ Dropped: 0
+
+ Because the default sort key above is 'hitcount', the above shows a
+ the list of call_sites by increasing hitcount, so that at the bottom
+ we see the functions that made the most kmalloc calls during the
+ run. If instead we wanted to see the top kmalloc callers in
+ terms of the number of bytes requested rather than the number of
+ calls, and we wanted the top caller to appear at the top, we can use
+ the 'sort' parameter, along with the 'descending' modifier::
+
+ # echo 'hist:key=call_site.sym:val=bytes_req:sort=bytes_req.descending' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=call_site.sym:vals=bytes_req:sort=bytes_req.descending:size=2048 [active]
+
+ { call_site: [ffffffffa046041c] i915_gem_execbuffer2 [i915] } hitcount: 2186 bytes_req: 3397464
+ { call_site: [ffffffffa045e7c4] i915_gem_do_execbuffer.isra.23 [i915] } hitcount: 1790 bytes_req: 712176
+ { call_site: [ffffffff8125847d] ext4_htree_store_dirent } hitcount: 8132 bytes_req: 513135
+ { call_site: [ffffffff811e2a1b] seq_buf_alloc } hitcount: 106 bytes_req: 440128
+ { call_site: [ffffffffa0489a66] intel_ring_begin [i915] } hitcount: 2186 bytes_req: 314784
+ { call_site: [ffffffff812891ca] ext4_find_extent } hitcount: 2174 bytes_req: 208992
+ { call_site: [ffffffff811ae8e1] __kmalloc } hitcount: 8 bytes_req: 131072
+ { call_site: [ffffffffa04c4a3c] intel_plane_duplicate_state [i915] } hitcount: 859 bytes_req: 116824
+ { call_site: [ffffffffa02911f2] drm_modeset_lock_crtc [drm] } hitcount: 1834 bytes_req: 102704
+ { call_site: [ffffffffa04a580c] intel_crtc_page_flip [i915] } hitcount: 972 bytes_req: 101088
+ { call_site: [ffffffffa0287592] drm_mode_page_flip_ioctl [drm] } hitcount: 972 bytes_req: 85536
+ { call_site: [ffffffffa00b7c06] hid_report_raw_event [hid] } hitcount: 3333 bytes_req: 66664
+ { call_site: [ffffffff8137e559] sg_kmalloc } hitcount: 209 bytes_req: 61632
+ .
+ .
+ .
+ { call_site: [ffffffff81095225] alloc_fair_sched_group } hitcount: 2 bytes_req: 128
+ { call_site: [ffffffff81097ec2] alloc_rt_sched_group } hitcount: 2 bytes_req: 128
+ { call_site: [ffffffff812d8406] copy_semundo } hitcount: 2 bytes_req: 48
+ { call_site: [ffffffff81200ba6] inotify_new_group } hitcount: 1 bytes_req: 48
+ { call_site: [ffffffffa027121a] drm_getmagic [drm] } hitcount: 1 bytes_req: 48
+ { call_site: [ffffffff811e3a25] __seq_open_private } hitcount: 1 bytes_req: 40
+ { call_site: [ffffffff811c52f4] bprm_change_interp } hitcount: 2 bytes_req: 16
+ { call_site: [ffffffff8154bc62] usb_control_msg } hitcount: 1 bytes_req: 8
+ { call_site: [ffffffffa00bf1ca] hidraw_report_event [hid] } hitcount: 1 bytes_req: 7
+ { call_site: [ffffffffa00bf6fe] hidraw_send_report [hid] } hitcount: 1 bytes_req: 7
+
+ Totals:
+ Hits: 32133
+ Entries: 81
+ Dropped: 0
+
+ To display the offset and size information in addition to the symbol
+ name, just use 'sym-offset' instead::
+
+ # echo 'hist:key=call_site.sym-offset:val=bytes_req:sort=bytes_req.descending' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=call_site.sym-offset:vals=bytes_req:sort=bytes_req.descending:size=2048 [active]
+
+ { call_site: [ffffffffa046041c] i915_gem_execbuffer2+0x6c/0x2c0 [i915] } hitcount: 4569 bytes_req: 3163720
+ { call_site: [ffffffffa0489a66] intel_ring_begin+0xc6/0x1f0 [i915] } hitcount: 4569 bytes_req: 657936
+ { call_site: [ffffffffa045e7c4] i915_gem_do_execbuffer.isra.23+0x694/0x1020 [i915] } hitcount: 1519 bytes_req: 472936
+ { call_site: [ffffffffa045e646] i915_gem_do_execbuffer.isra.23+0x516/0x1020 [i915] } hitcount: 3050 bytes_req: 211832
+ { call_site: [ffffffff811e2a1b] seq_buf_alloc+0x1b/0x50 } hitcount: 34 bytes_req: 148384
+ { call_site: [ffffffffa04a580c] intel_crtc_page_flip+0xbc/0x870 [i915] } hitcount: 1385 bytes_req: 144040
+ { call_site: [ffffffff811ae8e1] __kmalloc+0x191/0x1b0 } hitcount: 8 bytes_req: 131072
+ { call_site: [ffffffffa0287592] drm_mode_page_flip_ioctl+0x282/0x360 [drm] } hitcount: 1385 bytes_req: 121880
+ { call_site: [ffffffffa02911f2] drm_modeset_lock_crtc+0x32/0x100 [drm] } hitcount: 1848 bytes_req: 103488
+ { call_site: [ffffffffa04c4a3c] intel_plane_duplicate_state+0x2c/0xa0 [i915] } hitcount: 461 bytes_req: 62696
+ { call_site: [ffffffffa029070e] drm_vma_node_allow+0x2e/0xd0 [drm] } hitcount: 1541 bytes_req: 61640
+ { call_site: [ffffffff815f8d7b] sk_prot_alloc+0xcb/0x1b0 } hitcount: 57 bytes_req: 57456
+ .
+ .
+ .
+ { call_site: [ffffffff8109524a] alloc_fair_sched_group+0x5a/0x1a0 } hitcount: 2 bytes_req: 128
+ { call_site: [ffffffffa027b921] drm_vm_open_locked+0x31/0xa0 [drm] } hitcount: 3 bytes_req: 96
+ { call_site: [ffffffff8122e266] proc_self_follow_link+0x76/0xb0 } hitcount: 8 bytes_req: 96
+ { call_site: [ffffffff81213e80] load_elf_binary+0x240/0x1650 } hitcount: 3 bytes_req: 84
+ { call_site: [ffffffff8154bc62] usb_control_msg+0x42/0x110 } hitcount: 1 bytes_req: 8
+ { call_site: [ffffffffa00bf6fe] hidraw_send_report+0x7e/0x1a0 [hid] } hitcount: 1 bytes_req: 7
+ { call_site: [ffffffffa00bf1ca] hidraw_report_event+0x8a/0x120 [hid] } hitcount: 1 bytes_req: 7
+
+ Totals:
+ Hits: 26098
+ Entries: 64
+ Dropped: 0
+
+ We can also add multiple fields to the 'values' parameter. For
+ example, we might want to see the total number of bytes allocated
+ alongside bytes requested, and display the result sorted by bytes
+ allocated in a descending order::
+
+ # echo 'hist:keys=call_site.sym:values=bytes_req,bytes_alloc:sort=bytes_alloc.descending' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=call_site.sym:vals=bytes_req,bytes_alloc:sort=bytes_alloc.descending:size=2048 [active]
+
+ { call_site: [ffffffffa046041c] i915_gem_execbuffer2 [i915] } hitcount: 7403 bytes_req: 4084360 bytes_alloc: 5958016
+ { call_site: [ffffffff811e2a1b] seq_buf_alloc } hitcount: 541 bytes_req: 2213968 bytes_alloc: 2228224
+ { call_site: [ffffffffa0489a66] intel_ring_begin [i915] } hitcount: 7404 bytes_req: 1066176 bytes_alloc: 1421568
+ { call_site: [ffffffffa045e7c4] i915_gem_do_execbuffer.isra.23 [i915] } hitcount: 1565 bytes_req: 557368 bytes_alloc: 1037760
+ { call_site: [ffffffff8125847d] ext4_htree_store_dirent } hitcount: 9557 bytes_req: 595778 bytes_alloc: 695744
+ { call_site: [ffffffffa045e646] i915_gem_do_execbuffer.isra.23 [i915] } hitcount: 5839 bytes_req: 430680 bytes_alloc: 470400
+ { call_site: [ffffffffa04c4a3c] intel_plane_duplicate_state [i915] } hitcount: 2388 bytes_req: 324768 bytes_alloc: 458496
+ { call_site: [ffffffffa02911f2] drm_modeset_lock_crtc [drm] } hitcount: 3911 bytes_req: 219016 bytes_alloc: 250304
+ { call_site: [ffffffff815f8d7b] sk_prot_alloc } hitcount: 235 bytes_req: 236880 bytes_alloc: 240640
+ { call_site: [ffffffff8137e559] sg_kmalloc } hitcount: 557 bytes_req: 169024 bytes_alloc: 221760
+ { call_site: [ffffffffa00b7c06] hid_report_raw_event [hid] } hitcount: 9378 bytes_req: 187548 bytes_alloc: 206312
+ { call_site: [ffffffffa04a580c] intel_crtc_page_flip [i915] } hitcount: 1519 bytes_req: 157976 bytes_alloc: 194432
+ .
+ .
+ .
+ { call_site: [ffffffff8109bd3b] sched_autogroup_create_attach } hitcount: 2 bytes_req: 144 bytes_alloc: 192
+ { call_site: [ffffffff81097ee8] alloc_rt_sched_group } hitcount: 2 bytes_req: 128 bytes_alloc: 128
+ { call_site: [ffffffff8109524a] alloc_fair_sched_group } hitcount: 2 bytes_req: 128 bytes_alloc: 128
+ { call_site: [ffffffff81095225] alloc_fair_sched_group } hitcount: 2 bytes_req: 128 bytes_alloc: 128
+ { call_site: [ffffffff81097ec2] alloc_rt_sched_group } hitcount: 2 bytes_req: 128 bytes_alloc: 128
+ { call_site: [ffffffff81213e80] load_elf_binary } hitcount: 3 bytes_req: 84 bytes_alloc: 96
+ { call_site: [ffffffff81079a2e] kthread_create_on_node } hitcount: 1 bytes_req: 56 bytes_alloc: 64
+ { call_site: [ffffffffa00bf6fe] hidraw_send_report [hid] } hitcount: 1 bytes_req: 7 bytes_alloc: 8
+ { call_site: [ffffffff8154bc62] usb_control_msg } hitcount: 1 bytes_req: 8 bytes_alloc: 8
+ { call_site: [ffffffffa00bf1ca] hidraw_report_event [hid] } hitcount: 1 bytes_req: 7 bytes_alloc: 8
+
+ Totals:
+ Hits: 66598
+ Entries: 65
+ Dropped: 0
+
+ Finally, to finish off our kmalloc example, instead of simply having
+ the hist trigger display symbolic call_sites, we can have the hist
+ trigger additionally display the complete set of kernel stack traces
+ that led to each call_site. To do that, we simply use the special
+ value 'stacktrace' for the key parameter::
+
+ # echo 'hist:keys=stacktrace:values=bytes_req,bytes_alloc:sort=bytes_alloc' > \
+ /sys/kernel/debug/tracing/events/kmem/kmalloc/trigger
+
+ The above trigger will use the kernel stack trace in effect when an
+ event is triggered as the key for the hash table. This allows the
+ enumeration of every kernel callpath that led up to a particular
+ event, along with a running total of any of the event fields for
+ that event. Here we tally bytes requested and bytes allocated for
+ every callpath in the system that led up to a kmalloc (in this case
+ every callpath to a kmalloc for a kernel compile)::
+
+ # cat /sys/kernel/debug/tracing/events/kmem/kmalloc/hist
+ # trigger info: hist:keys=stacktrace:vals=bytes_req,bytes_alloc:sort=bytes_alloc:size=2048 [active]
+
+ { stacktrace:
+ __kmalloc_track_caller+0x10b/0x1a0
+ kmemdup+0x20/0x50
+ hidraw_report_event+0x8a/0x120 [hid]
+ hid_report_raw_event+0x3ea/0x440 [hid]
+ hid_input_report+0x112/0x190 [hid]
+ hid_irq_in+0xc2/0x260 [usbhid]
+ __usb_hcd_giveback_urb+0x72/0x120
+ usb_giveback_urb_bh+0x9e/0xe0
+ tasklet_hi_action+0xf8/0x100
+ __do_softirq+0x114/0x2c0
+ irq_exit+0xa5/0xb0
+ do_IRQ+0x5a/0xf0
+ ret_from_intr+0x0/0x30
+ cpuidle_enter+0x17/0x20
+ cpu_startup_entry+0x315/0x3e0
+ rest_init+0x7c/0x80
+ } hitcount: 3 bytes_req: 21 bytes_alloc: 24
+ { stacktrace:
+ __kmalloc_track_caller+0x10b/0x1a0
+ kmemdup+0x20/0x50
+ hidraw_report_event+0x8a/0x120 [hid]
+ hid_report_raw_event+0x3ea/0x440 [hid]
+ hid_input_report+0x112/0x190 [hid]
+ hid_irq_in+0xc2/0x260 [usbhid]
+ __usb_hcd_giveback_urb+0x72/0x120
+ usb_giveback_urb_bh+0x9e/0xe0
+ tasklet_hi_action+0xf8/0x100
+ __do_softirq+0x114/0x2c0
+ irq_exit+0xa5/0xb0
+ do_IRQ+0x5a/0xf0
+ ret_from_intr+0x0/0x30
+ } hitcount: 3 bytes_req: 21 bytes_alloc: 24
+ { stacktrace:
+ kmem_cache_alloc_trace+0xeb/0x150
+ aa_alloc_task_context+0x27/0x40
+ apparmor_cred_prepare+0x1f/0x50
+ security_prepare_creds+0x16/0x20
+ prepare_creds+0xdf/0x1a0
+ SyS_capset+0xb5/0x200
+ system_call_fastpath+0x12/0x6a
+ } hitcount: 1 bytes_req: 32 bytes_alloc: 32
+ .
+ .
+ .
+ { stacktrace:
+ __kmalloc+0x11b/0x1b0
+ i915_gem_execbuffer2+0x6c/0x2c0 [i915]
+ drm_ioctl+0x349/0x670 [drm]
+ do_vfs_ioctl+0x2f0/0x4f0
+ SyS_ioctl+0x81/0xa0
+ system_call_fastpath+0x12/0x6a
+ } hitcount: 17726 bytes_req: 13944120 bytes_alloc: 19593808
+ { stacktrace:
+ __kmalloc+0x11b/0x1b0
+ load_elf_phdrs+0x76/0xa0
+ load_elf_binary+0x102/0x1650
+ search_binary_handler+0x97/0x1d0
+ do_execveat_common.isra.34+0x551/0x6e0
+ SyS_execve+0x3a/0x50
+ return_from_execve+0x0/0x23
+ } hitcount: 33348 bytes_req: 17152128 bytes_alloc: 20226048
+ { stacktrace:
+ kmem_cache_alloc_trace+0xeb/0x150
+ apparmor_file_alloc_security+0x27/0x40
+ security_file_alloc+0x16/0x20
+ get_empty_filp+0x93/0x1c0
+ path_openat+0x31/0x5f0
+ do_filp_open+0x3a/0x90
+ do_sys_open+0x128/0x220
+ SyS_open+0x1e/0x20
+ system_call_fastpath+0x12/0x6a
+ } hitcount: 4766422 bytes_req: 9532844 bytes_alloc: 38131376
+ { stacktrace:
+ __kmalloc+0x11b/0x1b0
+ seq_buf_alloc+0x1b/0x50
+ seq_read+0x2cc/0x370
+ proc_reg_read+0x3d/0x80
+ __vfs_read+0x28/0xe0
+ vfs_read+0x86/0x140
+ SyS_read+0x46/0xb0
+ system_call_fastpath+0x12/0x6a
+ } hitcount: 19133 bytes_req: 78368768 bytes_alloc: 78368768
+
+ Totals:
+ Hits: 6085872
+ Entries: 253
+ Dropped: 0
+
+ If you key a hist trigger on common_pid, in order for example to
+ gather and display sorted totals for each process, you can use the
+ special .execname modifier to display the executable names for the
+ processes in the table rather than raw pids. The example below
+ keeps a per-process sum of total bytes read::
+
+ # echo 'hist:key=common_pid.execname:val=count:sort=count.descending' > \
+ /sys/kernel/debug/tracing/events/syscalls/sys_enter_read/trigger
+
+ # cat /sys/kernel/debug/tracing/events/syscalls/sys_enter_read/hist
+ # trigger info: hist:keys=common_pid.execname:vals=count:sort=count.descending:size=2048 [active]
+
+ { common_pid: gnome-terminal [ 3196] } hitcount: 280 count: 1093512
+ { common_pid: Xorg [ 1309] } hitcount: 525 count: 256640
+ { common_pid: compiz [ 2889] } hitcount: 59 count: 254400
+ { common_pid: bash [ 8710] } hitcount: 3 count: 66369
+ { common_pid: dbus-daemon-lau [ 8703] } hitcount: 49 count: 47739
+ { common_pid: irqbalance [ 1252] } hitcount: 27 count: 27648
+ { common_pid: 01ifupdown [ 8705] } hitcount: 3 count: 17216
+ { common_pid: dbus-daemon [ 772] } hitcount: 10 count: 12396
+ { common_pid: Socket Thread [ 8342] } hitcount: 11 count: 11264
+ { common_pid: nm-dhcp-client. [ 8701] } hitcount: 6 count: 7424
+ { common_pid: gmain [ 1315] } hitcount: 18 count: 6336
+ .
+ .
+ .
+ { common_pid: postgres [ 1892] } hitcount: 2 count: 32
+ { common_pid: postgres [ 1891] } hitcount: 2 count: 32
+ { common_pid: gmain [ 8704] } hitcount: 2 count: 32
+ { common_pid: upstart-dbus-br [ 2740] } hitcount: 21 count: 21
+ { common_pid: nm-dispatcher.a [ 8696] } hitcount: 1 count: 16
+ { common_pid: indicator-datet [ 2904] } hitcount: 1 count: 16
+ { common_pid: gdbus [ 2998] } hitcount: 1 count: 16
+ { common_pid: rtkit-daemon [ 2052] } hitcount: 1 count: 8
+ { common_pid: init [ 1] } hitcount: 2 count: 2
+
+ Totals:
+ Hits: 2116
+ Entries: 51
+ Dropped: 0
+
+ Similarly, if you key a hist trigger on syscall id, for example to
+ gather and display a list of systemwide syscall hits, you can use
+ the special .syscall modifier to display the syscall names rather
+ than raw ids. The example below keeps a running total of syscall
+ counts for the system during the run::
+
+ # echo 'hist:key=id.syscall:val=hitcount' > \
+ /sys/kernel/debug/tracing/events/raw_syscalls/sys_enter/trigger
+
+ # cat /sys/kernel/debug/tracing/events/raw_syscalls/sys_enter/hist
+ # trigger info: hist:keys=id.syscall:vals=hitcount:sort=hitcount:size=2048 [active]
+
+ { id: sys_fsync [ 74] } hitcount: 1
+ { id: sys_newuname [ 63] } hitcount: 1
+ { id: sys_prctl [157] } hitcount: 1
+ { id: sys_statfs [137] } hitcount: 1
+ { id: sys_symlink [ 88] } hitcount: 1
+ { id: sys_sendmmsg [307] } hitcount: 1
+ { id: sys_semctl [ 66] } hitcount: 1
+ { id: sys_readlink [ 89] } hitcount: 3
+ { id: sys_bind [ 49] } hitcount: 3
+ { id: sys_getsockname [ 51] } hitcount: 3
+ { id: sys_unlink [ 87] } hitcount: 3
+ { id: sys_rename [ 82] } hitcount: 4
+ { id: unknown_syscall [ 58] } hitcount: 4
+ { id: sys_connect [ 42] } hitcount: 4
+ { id: sys_getpid [ 39] } hitcount: 4
+ .
+ .
+ .
+ { id: sys_rt_sigprocmask [ 14] } hitcount: 952
+ { id: sys_futex [202] } hitcount: 1534
+ { id: sys_write [ 1] } hitcount: 2689
+ { id: sys_setitimer [ 38] } hitcount: 2797
+ { id: sys_read [ 0] } hitcount: 3202
+ { id: sys_select [ 23] } hitcount: 3773
+ { id: sys_writev [ 20] } hitcount: 4531
+ { id: sys_poll [ 7] } hitcount: 8314
+ { id: sys_recvmsg [ 47] } hitcount: 13738
+ { id: sys_ioctl [ 16] } hitcount: 21843
+
+ Totals:
+ Hits: 67612
+ Entries: 72
+ Dropped: 0
+
+ The syscall counts above provide a rough overall picture of system
+ call activity on the system; we can see for example that the most
+ popular system call on this system was the 'sys_ioctl' system call.
+
+ We can use 'compound' keys to refine that number and provide some
+ further insight as to which processes exactly contribute to the
+ overall ioctl count.
+
+ The command below keeps a hitcount for every unique combination of
+ system call id and pid - the end result is essentially a table
+ that keeps a per-pid sum of system call hits. The results are
+ sorted using the system call id as the primary key, and the
+ hitcount sum as the secondary key::
+
+ # echo 'hist:key=id.syscall,common_pid.execname:val=hitcount:sort=id,hitcount' > \
+ /sys/kernel/debug/tracing/events/raw_syscalls/sys_enter/trigger
+
+ # cat /sys/kernel/debug/tracing/events/raw_syscalls/sys_enter/hist
+ # trigger info: hist:keys=id.syscall,common_pid.execname:vals=hitcount:sort=id.syscall,hitcount:size=2048 [active]
+
+ { id: sys_read [ 0], common_pid: rtkit-daemon [ 1877] } hitcount: 1
+ { id: sys_read [ 0], common_pid: gdbus [ 2976] } hitcount: 1
+ { id: sys_read [ 0], common_pid: console-kit-dae [ 3400] } hitcount: 1
+ { id: sys_read [ 0], common_pid: postgres [ 1865] } hitcount: 1
+ { id: sys_read [ 0], common_pid: deja-dup-monito [ 3543] } hitcount: 2
+ { id: sys_read [ 0], common_pid: NetworkManager [ 890] } hitcount: 2
+ { id: sys_read [ 0], common_pid: evolution-calen [ 3048] } hitcount: 2
+ { id: sys_read [ 0], common_pid: postgres [ 1864] } hitcount: 2
+ { id: sys_read [ 0], common_pid: nm-applet [ 3022] } hitcount: 2
+ { id: sys_read [ 0], common_pid: whoopsie [ 1212] } hitcount: 2
+ .
+ .
+ .
+ { id: sys_ioctl [ 16], common_pid: bash [ 8479] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: bash [ 3472] } hitcount: 12
+ { id: sys_ioctl [ 16], common_pid: gnome-terminal [ 3199] } hitcount: 16
+ { id: sys_ioctl [ 16], common_pid: Xorg [ 1267] } hitcount: 1808
+ { id: sys_ioctl [ 16], common_pid: compiz [ 2994] } hitcount: 5580
+ .
+ .
+ .
+ { id: sys_waitid [247], common_pid: upstart-dbus-br [ 2690] } hitcount: 3
+ { id: sys_waitid [247], common_pid: upstart-dbus-br [ 2688] } hitcount: 16
+ { id: sys_inotify_add_watch [254], common_pid: gmain [ 975] } hitcount: 2
+ { id: sys_inotify_add_watch [254], common_pid: gmain [ 3204] } hitcount: 4
+ { id: sys_inotify_add_watch [254], common_pid: gmain [ 2888] } hitcount: 4
+ { id: sys_inotify_add_watch [254], common_pid: gmain [ 3003] } hitcount: 4
+ { id: sys_inotify_add_watch [254], common_pid: gmain [ 2873] } hitcount: 4
+ { id: sys_inotify_add_watch [254], common_pid: gmain [ 3196] } hitcount: 6
+ { id: sys_openat [257], common_pid: java [ 2623] } hitcount: 2
+ { id: sys_eventfd2 [290], common_pid: ibus-ui-gtk3 [ 2760] } hitcount: 4
+ { id: sys_eventfd2 [290], common_pid: compiz [ 2994] } hitcount: 6
+
+ Totals:
+ Hits: 31536
+ Entries: 323
+ Dropped: 0
+
+ The above list does give us a breakdown of the ioctl syscall by
+ pid, but it also gives us quite a bit more than that, which we
+ don't really care about at the moment. Since we know the syscall
+ id for sys_ioctl (16, displayed next to the sys_ioctl name), we
+ can use that to filter out all the other syscalls::
+
+ # echo 'hist:key=id.syscall,common_pid.execname:val=hitcount:sort=id,hitcount if id == 16' > \
+ /sys/kernel/debug/tracing/events/raw_syscalls/sys_enter/trigger
+
+ # cat /sys/kernel/debug/tracing/events/raw_syscalls/sys_enter/hist
+ # trigger info: hist:keys=id.syscall,common_pid.execname:vals=hitcount:sort=id.syscall,hitcount:size=2048 if id == 16 [active]
+
+ { id: sys_ioctl [ 16], common_pid: gmain [ 2769] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: evolution-addre [ 8571] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: gmain [ 3003] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: gmain [ 2781] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: gmain [ 2829] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: bash [ 8726] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: bash [ 8508] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: gmain [ 2970] } hitcount: 1
+ { id: sys_ioctl [ 16], common_pid: gmain [ 2768] } hitcount: 1
+ .
+ .
+ .
+ { id: sys_ioctl [ 16], common_pid: pool [ 8559] } hitcount: 45
+ { id: sys_ioctl [ 16], common_pid: pool [ 8555] } hitcount: 48
+ { id: sys_ioctl [ 16], common_pid: pool [ 8551] } hitcount: 48
+ { id: sys_ioctl [ 16], common_pid: avahi-daemon [ 896] } hitcount: 66
+ { id: sys_ioctl [ 16], common_pid: Xorg [ 1267] } hitcount: 26674
+ { id: sys_ioctl [ 16], common_pid: compiz [ 2994] } hitcount: 73443
+
+ Totals:
+ Hits: 101162
+ Entries: 103
+ Dropped: 0
+
+ The above output shows that 'compiz' and 'Xorg' are far and away
+ the heaviest ioctl callers (which might lead to questions about
+ whether they really need to be making all those calls and to
+ possible avenues for further investigation.)
+
+ The compound key examples used a key and a sum value (hitcount) to
+ sort the output, but we can just as easily use two keys instead.
+ Here's an example where we use a compound key composed of the the
+ common_pid and size event fields. Sorting with pid as the primary
+ key and 'size' as the secondary key allows us to display an
+ ordered summary of the recvfrom sizes, with counts, received by
+ each process::
+
+ # echo 'hist:key=common_pid.execname,size:val=hitcount:sort=common_pid,size' > \
+ /sys/kernel/debug/tracing/events/syscalls/sys_enter_recvfrom/trigger
+
+ # cat /sys/kernel/debug/tracing/events/syscalls/sys_enter_recvfrom/hist
+ # trigger info: hist:keys=common_pid.execname,size:vals=hitcount:sort=common_pid.execname,size:size=2048 [active]
+
+ { common_pid: smbd [ 784], size: 4 } hitcount: 1
+ { common_pid: dnsmasq [ 1412], size: 4096 } hitcount: 672
+ { common_pid: postgres [ 1796], size: 1000 } hitcount: 6
+ { common_pid: postgres [ 1867], size: 1000 } hitcount: 10
+ { common_pid: bamfdaemon [ 2787], size: 28 } hitcount: 2
+ { common_pid: bamfdaemon [ 2787], size: 14360 } hitcount: 1
+ { common_pid: compiz [ 2994], size: 8 } hitcount: 1
+ { common_pid: compiz [ 2994], size: 20 } hitcount: 11
+ { common_pid: gnome-terminal [ 3199], size: 4 } hitcount: 2
+ { common_pid: firefox [ 8817], size: 4 } hitcount: 1
+ { common_pid: firefox [ 8817], size: 8 } hitcount: 5
+ { common_pid: firefox [ 8817], size: 588 } hitcount: 2
+ { common_pid: firefox [ 8817], size: 628 } hitcount: 1
+ { common_pid: firefox [ 8817], size: 6944 } hitcount: 1
+ { common_pid: firefox [ 8817], size: 408880 } hitcount: 2
+ { common_pid: firefox [ 8822], size: 8 } hitcount: 2
+ { common_pid: firefox [ 8822], size: 160 } hitcount: 2
+ { common_pid: firefox [ 8822], size: 320 } hitcount: 2
+ { common_pid: firefox [ 8822], size: 352 } hitcount: 1
+ .
+ .
+ .
+ { common_pid: pool [ 8923], size: 1960 } hitcount: 10
+ { common_pid: pool [ 8923], size: 2048 } hitcount: 10
+ { common_pid: pool [ 8924], size: 1960 } hitcount: 10
+ { common_pid: pool [ 8924], size: 2048 } hitcount: 10
+ { common_pid: pool [ 8928], size: 1964 } hitcount: 4
+ { common_pid: pool [ 8928], size: 1965 } hitcount: 2
+ { common_pid: pool [ 8928], size: 2048 } hitcount: 6
+ { common_pid: pool [ 8929], size: 1982 } hitcount: 1
+ { common_pid: pool [ 8929], size: 2048 } hitcount: 1
+
+ Totals:
+ Hits: 2016
+ Entries: 224
+ Dropped: 0
+
+ The above example also illustrates the fact that although a compound
+ key is treated as a single entity for hashing purposes, the sub-keys
+ it's composed of can be accessed independently.
+
+ The next example uses a string field as the hash key and
+ demonstrates how you can manually pause and continue a hist trigger.
+ In this example, we'll aggregate fork counts and don't expect a
+ large number of entries in the hash table, so we'll drop it to a
+ much smaller number, say 256::
+
+ # echo 'hist:key=child_comm:val=hitcount:size=256' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_fork/trigger
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_process_fork/hist
+ # trigger info: hist:keys=child_comm:vals=hitcount:sort=hitcount:size=256 [active]
+
+ { child_comm: dconf worker } hitcount: 1
+ { child_comm: ibus-daemon } hitcount: 1
+ { child_comm: whoopsie } hitcount: 1
+ { child_comm: smbd } hitcount: 1
+ { child_comm: gdbus } hitcount: 1
+ { child_comm: kthreadd } hitcount: 1
+ { child_comm: dconf worker } hitcount: 1
+ { child_comm: evolution-alarm } hitcount: 2
+ { child_comm: Socket Thread } hitcount: 2
+ { child_comm: postgres } hitcount: 2
+ { child_comm: bash } hitcount: 3
+ { child_comm: compiz } hitcount: 3
+ { child_comm: evolution-sourc } hitcount: 4
+ { child_comm: dhclient } hitcount: 4
+ { child_comm: pool } hitcount: 5
+ { child_comm: nm-dispatcher.a } hitcount: 8
+ { child_comm: firefox } hitcount: 8
+ { child_comm: dbus-daemon } hitcount: 8
+ { child_comm: glib-pacrunner } hitcount: 10
+ { child_comm: evolution } hitcount: 23
+
+ Totals:
+ Hits: 89
+ Entries: 20
+ Dropped: 0
+
+ If we want to pause the hist trigger, we can simply append :pause to
+ the command that started the trigger. Notice that the trigger info
+ displays as [paused]::
+
+ # echo 'hist:key=child_comm:val=hitcount:size=256:pause' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_process_fork/trigger
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_process_fork/hist
+ # trigger info: hist:keys=child_comm:vals=hitcount:sort=hitcount:size=256 [paused]
+
+ { child_comm: dconf worker } hitcount: 1
+ { child_comm: kthreadd } hitcount: 1
+ { child_comm: dconf worker } hitcount: 1
+ { child_comm: gdbus } hitcount: 1
+ { child_comm: ibus-daemon } hitcount: 1
+ { child_comm: Socket Thread } hitcount: 2
+ { child_comm: evolution-alarm } hitcount: 2
+ { child_comm: smbd } hitcount: 2
+ { child_comm: bash } hitcount: 3
+ { child_comm: whoopsie } hitcount: 3
+ { child_comm: compiz } hitcount: 3
+ { child_comm: evolution-sourc } hitcount: 4
+ { child_comm: pool } hitcount: 5
+ { child_comm: postgres } hitcount: 6
+ { child_comm: firefox } hitcount: 8
+ { child_comm: dhclient } hitcount: 10
+ { child_comm: emacs } hitcount: 12
+ { child_comm: dbus-daemon } hitcount: 20
+ { child_comm: nm-dispatcher.a } hitcount: 20
+ { child_comm: evolution } hitcount: 35
+ { child_comm: glib-pacrunner } hitcount: 59
+
+ Totals:
+ Hits: 199
+ Entries: 21
+ Dropped: 0
+
+ To manually continue having the trigger aggregate events, append
+ :cont instead. Notice that the trigger info displays as [active]
+ again, and the data has changed::
+
+ # echo 'hist:key=child_comm:val=hitcount:size=256:cont' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_process_fork/trigger
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_process_fork/hist
+ # trigger info: hist:keys=child_comm:vals=hitcount:sort=hitcount:size=256 [active]
+
+ { child_comm: dconf worker } hitcount: 1
+ { child_comm: dconf worker } hitcount: 1
+ { child_comm: kthreadd } hitcount: 1
+ { child_comm: gdbus } hitcount: 1
+ { child_comm: ibus-daemon } hitcount: 1
+ { child_comm: Socket Thread } hitcount: 2
+ { child_comm: evolution-alarm } hitcount: 2
+ { child_comm: smbd } hitcount: 2
+ { child_comm: whoopsie } hitcount: 3
+ { child_comm: compiz } hitcount: 3
+ { child_comm: evolution-sourc } hitcount: 4
+ { child_comm: bash } hitcount: 5
+ { child_comm: pool } hitcount: 5
+ { child_comm: postgres } hitcount: 6
+ { child_comm: firefox } hitcount: 8
+ { child_comm: dhclient } hitcount: 11
+ { child_comm: emacs } hitcount: 12
+ { child_comm: dbus-daemon } hitcount: 22
+ { child_comm: nm-dispatcher.a } hitcount: 22
+ { child_comm: evolution } hitcount: 35
+ { child_comm: glib-pacrunner } hitcount: 59
+
+ Totals:
+ Hits: 206
+ Entries: 21
+ Dropped: 0
+
+ The previous example showed how to start and stop a hist trigger by
+ appending 'pause' and 'continue' to the hist trigger command. A
+ hist trigger can also be started in a paused state by initially
+ starting the trigger with ':pause' appended. This allows you to
+ start the trigger only when you're ready to start collecting data
+ and not before. For example, you could start the trigger in a
+ paused state, then unpause it and do something you want to measure,
+ then pause the trigger again when done.
+
+ Of course, doing this manually can be difficult and error-prone, but
+ it is possible to automatically start and stop a hist trigger based
+ on some condition, via the enable_hist and disable_hist triggers.
+
+ For example, suppose we wanted to take a look at the relative
+ weights in terms of skb length for each callpath that leads to a
+ netif_receive_skb event when downloading a decent-sized file using
+ wget.
+
+ First we set up an initially paused stacktrace trigger on the
+ netif_receive_skb event::
+
+ # echo 'hist:key=stacktrace:vals=len:pause' > \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+
+ Next, we set up an 'enable_hist' trigger on the sched_process_exec
+ event, with an 'if filename==/usr/bin/wget' filter. The effect of
+ this new trigger is that it will 'unpause' the hist trigger we just
+ set up on netif_receive_skb if and only if it sees a
+ sched_process_exec event with a filename of '/usr/bin/wget'. When
+ that happens, all netif_receive_skb events are aggregated into a
+ hash table keyed on stacktrace::
+
+ # echo 'enable_hist:net:netif_receive_skb if filename==/usr/bin/wget' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_exec/trigger
+
+ The aggregation continues until the netif_receive_skb is paused
+ again, which is what the following disable_hist event does by
+ creating a similar setup on the sched_process_exit event, using the
+ filter 'comm==wget'::
+
+ # echo 'disable_hist:net:netif_receive_skb if comm==wget' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_exit/trigger
+
+ Whenever a process exits and the comm field of the disable_hist
+ trigger filter matches 'comm==wget', the netif_receive_skb hist
+ trigger is disabled.
+
+ The overall effect is that netif_receive_skb events are aggregated
+ into the hash table for only the duration of the wget. Executing a
+ wget command and then listing the 'hist' file will display the
+ output generated by the wget command::
+
+ $ wget https://www.kernel.org/pub/linux/kernel/v3.x/patch-3.19.xz
+
+ # cat /sys/kernel/debug/tracing/events/net/netif_receive_skb/hist
+ # trigger info: hist:keys=stacktrace:vals=len:sort=hitcount:size=2048 [paused]
+
+ { stacktrace:
+ __netif_receive_skb_core+0x46d/0x990
+ __netif_receive_skb+0x18/0x60
+ netif_receive_skb_internal+0x23/0x90
+ napi_gro_receive+0xc8/0x100
+ ieee80211_deliver_skb+0xd6/0x270 [mac80211]
+ ieee80211_rx_handlers+0xccf/0x22f0 [mac80211]
+ ieee80211_prepare_and_rx_handle+0x4e7/0xc40 [mac80211]
+ ieee80211_rx+0x31d/0x900 [mac80211]
+ iwlagn_rx_reply_rx+0x3db/0x6f0 [iwldvm]
+ iwl_rx_dispatch+0x8e/0xf0 [iwldvm]
+ iwl_pcie_irq_handler+0xe3c/0x12f0 [iwlwifi]
+ irq_thread_fn+0x20/0x50
+ irq_thread+0x11f/0x150
+ kthread+0xd2/0xf0
+ ret_from_fork+0x42/0x70
+ } hitcount: 85 len: 28884
+ { stacktrace:
+ __netif_receive_skb_core+0x46d/0x990
+ __netif_receive_skb+0x18/0x60
+ netif_receive_skb_internal+0x23/0x90
+ napi_gro_complete+0xa4/0xe0
+ dev_gro_receive+0x23a/0x360
+ napi_gro_receive+0x30/0x100
+ ieee80211_deliver_skb+0xd6/0x270 [mac80211]
+ ieee80211_rx_handlers+0xccf/0x22f0 [mac80211]
+ ieee80211_prepare_and_rx_handle+0x4e7/0xc40 [mac80211]
+ ieee80211_rx+0x31d/0x900 [mac80211]
+ iwlagn_rx_reply_rx+0x3db/0x6f0 [iwldvm]
+ iwl_rx_dispatch+0x8e/0xf0 [iwldvm]
+ iwl_pcie_irq_handler+0xe3c/0x12f0 [iwlwifi]
+ irq_thread_fn+0x20/0x50
+ irq_thread+0x11f/0x150
+ kthread+0xd2/0xf0
+ } hitcount: 98 len: 664329
+ { stacktrace:
+ __netif_receive_skb_core+0x46d/0x990
+ __netif_receive_skb+0x18/0x60
+ process_backlog+0xa8/0x150
+ net_rx_action+0x15d/0x340
+ __do_softirq+0x114/0x2c0
+ do_softirq_own_stack+0x1c/0x30
+ do_softirq+0x65/0x70
+ __local_bh_enable_ip+0xb5/0xc0
+ ip_finish_output+0x1f4/0x840
+ ip_output+0x6b/0xc0
+ ip_local_out_sk+0x31/0x40
+ ip_send_skb+0x1a/0x50
+ udp_send_skb+0x173/0x2a0
+ udp_sendmsg+0x2bf/0x9f0
+ inet_sendmsg+0x64/0xa0
+ sock_sendmsg+0x3d/0x50
+ } hitcount: 115 len: 13030
+ { stacktrace:
+ __netif_receive_skb_core+0x46d/0x990
+ __netif_receive_skb+0x18/0x60
+ netif_receive_skb_internal+0x23/0x90
+ napi_gro_complete+0xa4/0xe0
+ napi_gro_flush+0x6d/0x90
+ iwl_pcie_irq_handler+0x92a/0x12f0 [iwlwifi]
+ irq_thread_fn+0x20/0x50
+ irq_thread+0x11f/0x150
+ kthread+0xd2/0xf0
+ ret_from_fork+0x42/0x70
+ } hitcount: 934 len: 5512212
+
+ Totals:
+ Hits: 1232
+ Entries: 4
+ Dropped: 0
+
+ The above shows all the netif_receive_skb callpaths and their total
+ lengths for the duration of the wget command.
+
+ The 'clear' hist trigger param can be used to clear the hash table.
+ Suppose we wanted to try another run of the previous example but
+ this time also wanted to see the complete list of events that went
+ into the histogram. In order to avoid having to set everything up
+ again, we can just clear the histogram first::
+
+ # echo 'hist:key=stacktrace:vals=len:clear' >> \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+
+ Just to verify that it is in fact cleared, here's what we now see in
+ the hist file::
+
+ # cat /sys/kernel/debug/tracing/events/net/netif_receive_skb/hist
+ # trigger info: hist:keys=stacktrace:vals=len:sort=hitcount:size=2048 [paused]
+
+ Totals:
+ Hits: 0
+ Entries: 0
+ Dropped: 0
+
+ Since we want to see the detailed list of every netif_receive_skb
+ event occurring during the new run, which are in fact the same
+ events being aggregated into the hash table, we add some additional
+ 'enable_event' events to the triggering sched_process_exec and
+ sched_process_exit events as such::
+
+ # echo 'enable_event:net:netif_receive_skb if filename==/usr/bin/wget' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_exec/trigger
+
+ # echo 'disable_event:net:netif_receive_skb if comm==wget' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_exit/trigger
+
+ If you read the trigger files for the sched_process_exec and
+ sched_process_exit triggers, you should see two triggers for each:
+ one enabling/disabling the hist aggregation and the other
+ enabling/disabling the logging of events::
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_process_exec/trigger
+ enable_event:net:netif_receive_skb:unlimited if filename==/usr/bin/wget
+ enable_hist:net:netif_receive_skb:unlimited if filename==/usr/bin/wget
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_process_exit/trigger
+ enable_event:net:netif_receive_skb:unlimited if comm==wget
+ disable_hist:net:netif_receive_skb:unlimited if comm==wget
+
+ In other words, whenever either of the sched_process_exec or
+ sched_process_exit events is hit and matches 'wget', it enables or
+ disables both the histogram and the event log, and what you end up
+ with is a hash table and set of events just covering the specified
+ duration. Run the wget command again::
+
+ $ wget https://www.kernel.org/pub/linux/kernel/v3.x/patch-3.19.xz
+
+ Displaying the 'hist' file should show something similar to what you
+ saw in the last run, but this time you should also see the
+ individual events in the trace file::
+
+ # cat /sys/kernel/debug/tracing/trace
+
+ # tracer: nop
+ #
+ # entries-in-buffer/entries-written: 183/1426 #P:4
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # ||| / delay
+ # TASK-PID CPU# |||| TIMESTAMP FUNCTION
+ # | | | |||| | |
+ wget-15108 [000] ..s1 31769.606929: netif_receive_skb: dev=lo skbaddr=ffff88009c353100 len=60
+ wget-15108 [000] ..s1 31769.606999: netif_receive_skb: dev=lo skbaddr=ffff88009c353200 len=60
+ dnsmasq-1382 [000] ..s1 31769.677652: netif_receive_skb: dev=lo skbaddr=ffff88009c352b00 len=130
+ dnsmasq-1382 [000] ..s1 31769.685917: netif_receive_skb: dev=lo skbaddr=ffff88009c352200 len=138
+ ##### CPU 2 buffer started ####
+ irq/29-iwlwifi-559 [002] ..s. 31772.031529: netif_receive_skb: dev=wlan0 skbaddr=ffff88009d433d00 len=2948
+ irq/29-iwlwifi-559 [002] ..s. 31772.031572: netif_receive_skb: dev=wlan0 skbaddr=ffff88009d432200 len=1500
+ irq/29-iwlwifi-559 [002] ..s. 31772.032196: netif_receive_skb: dev=wlan0 skbaddr=ffff88009d433100 len=2948
+ irq/29-iwlwifi-559 [002] ..s. 31772.032761: netif_receive_skb: dev=wlan0 skbaddr=ffff88009d433000 len=2948
+ irq/29-iwlwifi-559 [002] ..s. 31772.033220: netif_receive_skb: dev=wlan0 skbaddr=ffff88009d432e00 len=1500
+ .
+ .
+ .
+
+ The following example demonstrates how multiple hist triggers can be
+ attached to a given event. This capability can be useful for
+ creating a set of different summaries derived from the same set of
+ events, or for comparing the effects of different filters, among
+ other things::
+
+ # echo 'hist:keys=skbaddr.hex:vals=len if len < 0' >> \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+ # echo 'hist:keys=skbaddr.hex:vals=len if len > 4096' >> \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+ # echo 'hist:keys=skbaddr.hex:vals=len if len == 256' >> \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+ # echo 'hist:keys=skbaddr.hex:vals=len' >> \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+ # echo 'hist:keys=len:vals=common_preempt_count' >> \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+
+ The above set of commands create four triggers differing only in
+ their filters, along with a completely different though fairly
+ nonsensical trigger. Note that in order to append multiple hist
+ triggers to the same file, you should use the '>>' operator to
+ append them ('>' will also add the new hist trigger, but will remove
+ any existing hist triggers beforehand).
+
+ Displaying the contents of the 'hist' file for the event shows the
+ contents of all five histograms::
+
+ # cat /sys/kernel/debug/tracing/events/net/netif_receive_skb/hist
+
+ # event histogram
+ #
+ # trigger info: hist:keys=len:vals=hitcount,common_preempt_count:sort=hitcount:size=2048 [active]
+ #
+
+ { len: 176 } hitcount: 1 common_preempt_count: 0
+ { len: 223 } hitcount: 1 common_preempt_count: 0
+ { len: 4854 } hitcount: 1 common_preempt_count: 0
+ { len: 395 } hitcount: 1 common_preempt_count: 0
+ { len: 177 } hitcount: 1 common_preempt_count: 0
+ { len: 446 } hitcount: 1 common_preempt_count: 0
+ { len: 1601 } hitcount: 1 common_preempt_count: 0
+ .
+ .
+ .
+ { len: 1280 } hitcount: 66 common_preempt_count: 0
+ { len: 116 } hitcount: 81 common_preempt_count: 40
+ { len: 708 } hitcount: 112 common_preempt_count: 0
+ { len: 46 } hitcount: 221 common_preempt_count: 0
+ { len: 1264 } hitcount: 458 common_preempt_count: 0
+
+ Totals:
+ Hits: 1428
+ Entries: 147
+ Dropped: 0
+
+
+ # event histogram
+ #
+ # trigger info: hist:keys=skbaddr.hex:vals=hitcount,len:sort=hitcount:size=2048 [active]
+ #
+
+ { skbaddr: ffff8800baee5e00 } hitcount: 1 len: 130
+ { skbaddr: ffff88005f3d5600 } hitcount: 1 len: 1280
+ { skbaddr: ffff88005f3d4900 } hitcount: 1 len: 1280
+ { skbaddr: ffff88009fed6300 } hitcount: 1 len: 115
+ { skbaddr: ffff88009fe0ad00 } hitcount: 1 len: 115
+ { skbaddr: ffff88008cdb1900 } hitcount: 1 len: 46
+ { skbaddr: ffff880064b5ef00 } hitcount: 1 len: 118
+ { skbaddr: ffff880044e3c700 } hitcount: 1 len: 60
+ { skbaddr: ffff880100065900 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d46bd500 } hitcount: 1 len: 116
+ { skbaddr: ffff88005f3d5f00 } hitcount: 1 len: 1280
+ { skbaddr: ffff880100064700 } hitcount: 1 len: 365
+ { skbaddr: ffff8800badb6f00 } hitcount: 1 len: 60
+ .
+ .
+ .
+ { skbaddr: ffff88009fe0be00 } hitcount: 27 len: 24677
+ { skbaddr: ffff88009fe0a400 } hitcount: 27 len: 23052
+ { skbaddr: ffff88009fe0b700 } hitcount: 31 len: 25589
+ { skbaddr: ffff88009fe0b600 } hitcount: 32 len: 27326
+ { skbaddr: ffff88006a462800 } hitcount: 68 len: 71678
+ { skbaddr: ffff88006a463700 } hitcount: 70 len: 72678
+ { skbaddr: ffff88006a462b00 } hitcount: 71 len: 77589
+ { skbaddr: ffff88006a463600 } hitcount: 73 len: 71307
+ { skbaddr: ffff88006a462200 } hitcount: 81 len: 81032
+
+ Totals:
+ Hits: 1451
+ Entries: 318
+ Dropped: 0
+
+
+ # event histogram
+ #
+ # trigger info: hist:keys=skbaddr.hex:vals=hitcount,len:sort=hitcount:size=2048 if len == 256 [active]
+ #
+
+
+ Totals:
+ Hits: 0
+ Entries: 0
+ Dropped: 0
+
+
+ # event histogram
+ #
+ # trigger info: hist:keys=skbaddr.hex:vals=hitcount,len:sort=hitcount:size=2048 if len > 4096 [active]
+ #
+
+ { skbaddr: ffff88009fd2c300 } hitcount: 1 len: 7212
+ { skbaddr: ffff8800d2bcce00 } hitcount: 1 len: 7212
+ { skbaddr: ffff8800d2bcd700 } hitcount: 1 len: 7212
+ { skbaddr: ffff8800d2bcda00 } hitcount: 1 len: 21492
+ { skbaddr: ffff8800ae2e2d00 } hitcount: 1 len: 7212
+ { skbaddr: ffff8800d2bcdb00 } hitcount: 1 len: 7212
+ { skbaddr: ffff88006a4df500 } hitcount: 1 len: 4854
+ { skbaddr: ffff88008ce47b00 } hitcount: 1 len: 18636
+ { skbaddr: ffff8800ae2e2200 } hitcount: 1 len: 12924
+ { skbaddr: ffff88005f3e1000 } hitcount: 1 len: 4356
+ { skbaddr: ffff8800d2bcdc00 } hitcount: 2 len: 24420
+ { skbaddr: ffff8800d2bcc200 } hitcount: 2 len: 12996
+
+ Totals:
+ Hits: 14
+ Entries: 12
+ Dropped: 0
+
+
+ # event histogram
+ #
+ # trigger info: hist:keys=skbaddr.hex:vals=hitcount,len:sort=hitcount:size=2048 if len < 0 [active]
+ #
+
+
+ Totals:
+ Hits: 0
+ Entries: 0
+ Dropped: 0
+
+ Named triggers can be used to have triggers share a common set of
+ histogram data. This capability is mostly useful for combining the
+ output of events generated by tracepoints contained inside inline
+ functions, but names can be used in a hist trigger on any event.
+ For example, these two triggers when hit will update the same 'len'
+ field in the shared 'foo' histogram data::
+
+ # echo 'hist:name=foo:keys=skbaddr.hex:vals=len' > \
+ /sys/kernel/debug/tracing/events/net/netif_receive_skb/trigger
+ # echo 'hist:name=foo:keys=skbaddr.hex:vals=len' > \
+ /sys/kernel/debug/tracing/events/net/netif_rx/trigger
+
+ You can see that they're updating common histogram data by reading
+ each event's hist files at the same time::
+
+ # cat /sys/kernel/debug/tracing/events/net/netif_receive_skb/hist;
+ cat /sys/kernel/debug/tracing/events/net/netif_rx/hist
+
+ # event histogram
+ #
+ # trigger info: hist:name=foo:keys=skbaddr.hex:vals=hitcount,len:sort=hitcount:size=2048 [active]
+ #
+
+ { skbaddr: ffff88000ad53500 } hitcount: 1 len: 46
+ { skbaddr: ffff8800af5a1500 } hitcount: 1 len: 76
+ { skbaddr: ffff8800d62a1900 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bccb00 } hitcount: 1 len: 468
+ { skbaddr: ffff8800d3c69900 } hitcount: 1 len: 46
+ { skbaddr: ffff88009ff09100 } hitcount: 1 len: 52
+ { skbaddr: ffff88010f13ab00 } hitcount: 1 len: 168
+ { skbaddr: ffff88006a54f400 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bcc500 } hitcount: 1 len: 260
+ { skbaddr: ffff880064505000 } hitcount: 1 len: 46
+ { skbaddr: ffff8800baf24e00 } hitcount: 1 len: 32
+ { skbaddr: ffff88009fe0ad00 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d3edff00 } hitcount: 1 len: 44
+ { skbaddr: ffff88009fe0b400 } hitcount: 1 len: 168
+ { skbaddr: ffff8800a1c55a00 } hitcount: 1 len: 40
+ { skbaddr: ffff8800d2bcd100 } hitcount: 1 len: 40
+ { skbaddr: ffff880064505f00 } hitcount: 1 len: 174
+ { skbaddr: ffff8800a8bff200 } hitcount: 1 len: 160
+ { skbaddr: ffff880044e3cc00 } hitcount: 1 len: 76
+ { skbaddr: ffff8800a8bfe700 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bcdc00 } hitcount: 1 len: 32
+ { skbaddr: ffff8800a1f64800 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bcde00 } hitcount: 1 len: 988
+ { skbaddr: ffff88006a5dea00 } hitcount: 1 len: 46
+ { skbaddr: ffff88002e37a200 } hitcount: 1 len: 44
+ { skbaddr: ffff8800a1f32c00 } hitcount: 2 len: 676
+ { skbaddr: ffff88000ad52600 } hitcount: 2 len: 107
+ { skbaddr: ffff8800a1f91e00 } hitcount: 2 len: 92
+ { skbaddr: ffff8800af5a0200 } hitcount: 2 len: 142
+ { skbaddr: ffff8800d2bcc600 } hitcount: 2 len: 220
+ { skbaddr: ffff8800ba36f500 } hitcount: 2 len: 92
+ { skbaddr: ffff8800d021f800 } hitcount: 2 len: 92
+ { skbaddr: ffff8800a1f33600 } hitcount: 2 len: 675
+ { skbaddr: ffff8800a8bfff00 } hitcount: 3 len: 138
+ { skbaddr: ffff8800d62a1300 } hitcount: 3 len: 138
+ { skbaddr: ffff88002e37a100 } hitcount: 4 len: 184
+ { skbaddr: ffff880064504400 } hitcount: 4 len: 184
+ { skbaddr: ffff8800a8bfec00 } hitcount: 4 len: 184
+ { skbaddr: ffff88000ad53700 } hitcount: 5 len: 230
+ { skbaddr: ffff8800d2bcdb00 } hitcount: 5 len: 196
+ { skbaddr: ffff8800a1f90000 } hitcount: 6 len: 276
+ { skbaddr: ffff88006a54f900 } hitcount: 6 len: 276
+
+ Totals:
+ Hits: 81
+ Entries: 42
+ Dropped: 0
+ # event histogram
+ #
+ # trigger info: hist:name=foo:keys=skbaddr.hex:vals=hitcount,len:sort=hitcount:size=2048 [active]
+ #
+
+ { skbaddr: ffff88000ad53500 } hitcount: 1 len: 46
+ { skbaddr: ffff8800af5a1500 } hitcount: 1 len: 76
+ { skbaddr: ffff8800d62a1900 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bccb00 } hitcount: 1 len: 468
+ { skbaddr: ffff8800d3c69900 } hitcount: 1 len: 46
+ { skbaddr: ffff88009ff09100 } hitcount: 1 len: 52
+ { skbaddr: ffff88010f13ab00 } hitcount: 1 len: 168
+ { skbaddr: ffff88006a54f400 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bcc500 } hitcount: 1 len: 260
+ { skbaddr: ffff880064505000 } hitcount: 1 len: 46
+ { skbaddr: ffff8800baf24e00 } hitcount: 1 len: 32
+ { skbaddr: ffff88009fe0ad00 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d3edff00 } hitcount: 1 len: 44
+ { skbaddr: ffff88009fe0b400 } hitcount: 1 len: 168
+ { skbaddr: ffff8800a1c55a00 } hitcount: 1 len: 40
+ { skbaddr: ffff8800d2bcd100 } hitcount: 1 len: 40
+ { skbaddr: ffff880064505f00 } hitcount: 1 len: 174
+ { skbaddr: ffff8800a8bff200 } hitcount: 1 len: 160
+ { skbaddr: ffff880044e3cc00 } hitcount: 1 len: 76
+ { skbaddr: ffff8800a8bfe700 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bcdc00 } hitcount: 1 len: 32
+ { skbaddr: ffff8800a1f64800 } hitcount: 1 len: 46
+ { skbaddr: ffff8800d2bcde00 } hitcount: 1 len: 988
+ { skbaddr: ffff88006a5dea00 } hitcount: 1 len: 46
+ { skbaddr: ffff88002e37a200 } hitcount: 1 len: 44
+ { skbaddr: ffff8800a1f32c00 } hitcount: 2 len: 676
+ { skbaddr: ffff88000ad52600 } hitcount: 2 len: 107
+ { skbaddr: ffff8800a1f91e00 } hitcount: 2 len: 92
+ { skbaddr: ffff8800af5a0200 } hitcount: 2 len: 142
+ { skbaddr: ffff8800d2bcc600 } hitcount: 2 len: 220
+ { skbaddr: ffff8800ba36f500 } hitcount: 2 len: 92
+ { skbaddr: ffff8800d021f800 } hitcount: 2 len: 92
+ { skbaddr: ffff8800a1f33600 } hitcount: 2 len: 675
+ { skbaddr: ffff8800a8bfff00 } hitcount: 3 len: 138
+ { skbaddr: ffff8800d62a1300 } hitcount: 3 len: 138
+ { skbaddr: ffff88002e37a100 } hitcount: 4 len: 184
+ { skbaddr: ffff880064504400 } hitcount: 4 len: 184
+ { skbaddr: ffff8800a8bfec00 } hitcount: 4 len: 184
+ { skbaddr: ffff88000ad53700 } hitcount: 5 len: 230
+ { skbaddr: ffff8800d2bcdb00 } hitcount: 5 len: 196
+ { skbaddr: ffff8800a1f90000 } hitcount: 6 len: 276
+ { skbaddr: ffff88006a54f900 } hitcount: 6 len: 276
+
+ Totals:
+ Hits: 81
+ Entries: 42
+ Dropped: 0
+
+ And here's an example that shows how to combine histogram data from
+ any two events even if they don't share any 'compatible' fields
+ other than 'hitcount' and 'stacktrace'. These commands create a
+ couple of triggers named 'bar' using those fields::
+
+ # echo 'hist:name=bar:key=stacktrace:val=hitcount' > \
+ /sys/kernel/debug/tracing/events/sched/sched_process_fork/trigger
+ # echo 'hist:name=bar:key=stacktrace:val=hitcount' > \
+ /sys/kernel/debug/tracing/events/net/netif_rx/trigger
+
+ And displaying the output of either shows some interesting if
+ somewhat confusing output::
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_process_fork/hist
+ # cat /sys/kernel/debug/tracing/events/net/netif_rx/hist
+
+ # event histogram
+ #
+ # trigger info: hist:name=bar:keys=stacktrace:vals=hitcount:sort=hitcount:size=2048 [active]
+ #
+
+ { stacktrace:
+ kernel_clone+0x18e/0x330
+ kernel_thread+0x29/0x30
+ kthreadd+0x154/0x1b0
+ ret_from_fork+0x3f/0x70
+ } hitcount: 1
+ { stacktrace:
+ netif_rx_internal+0xb2/0xd0
+ netif_rx_ni+0x20/0x70
+ dev_loopback_xmit+0xaa/0xd0
+ ip_mc_output+0x126/0x240
+ ip_local_out_sk+0x31/0x40
+ igmp_send_report+0x1e9/0x230
+ igmp_timer_expire+0xe9/0x120
+ call_timer_fn+0x39/0xf0
+ run_timer_softirq+0x1e1/0x290
+ __do_softirq+0xfd/0x290
+ irq_exit+0x98/0xb0
+ smp_apic_timer_interrupt+0x4a/0x60
+ apic_timer_interrupt+0x6d/0x80
+ cpuidle_enter+0x17/0x20
+ call_cpuidle+0x3b/0x60
+ cpu_startup_entry+0x22d/0x310
+ } hitcount: 1
+ { stacktrace:
+ netif_rx_internal+0xb2/0xd0
+ netif_rx_ni+0x20/0x70
+ dev_loopback_xmit+0xaa/0xd0
+ ip_mc_output+0x17f/0x240
+ ip_local_out_sk+0x31/0x40
+ ip_send_skb+0x1a/0x50
+ udp_send_skb+0x13e/0x270
+ udp_sendmsg+0x2bf/0x980
+ inet_sendmsg+0x67/0xa0
+ sock_sendmsg+0x38/0x50
+ SYSC_sendto+0xef/0x170
+ SyS_sendto+0xe/0x10
+ entry_SYSCALL_64_fastpath+0x12/0x6a
+ } hitcount: 2
+ { stacktrace:
+ netif_rx_internal+0xb2/0xd0
+ netif_rx+0x1c/0x60
+ loopback_xmit+0x6c/0xb0
+ dev_hard_start_xmit+0x219/0x3a0
+ __dev_queue_xmit+0x415/0x4f0
+ dev_queue_xmit_sk+0x13/0x20
+ ip_finish_output2+0x237/0x340
+ ip_finish_output+0x113/0x1d0
+ ip_output+0x66/0xc0
+ ip_local_out_sk+0x31/0x40
+ ip_send_skb+0x1a/0x50
+ udp_send_skb+0x16d/0x270
+ udp_sendmsg+0x2bf/0x980
+ inet_sendmsg+0x67/0xa0
+ sock_sendmsg+0x38/0x50
+ ___sys_sendmsg+0x14e/0x270
+ } hitcount: 76
+ { stacktrace:
+ netif_rx_internal+0xb2/0xd0
+ netif_rx+0x1c/0x60
+ loopback_xmit+0x6c/0xb0
+ dev_hard_start_xmit+0x219/0x3a0
+ __dev_queue_xmit+0x415/0x4f0
+ dev_queue_xmit_sk+0x13/0x20
+ ip_finish_output2+0x237/0x340
+ ip_finish_output+0x113/0x1d0
+ ip_output+0x66/0xc0
+ ip_local_out_sk+0x31/0x40
+ ip_send_skb+0x1a/0x50
+ udp_send_skb+0x16d/0x270
+ udp_sendmsg+0x2bf/0x980
+ inet_sendmsg+0x67/0xa0
+ sock_sendmsg+0x38/0x50
+ ___sys_sendmsg+0x269/0x270
+ } hitcount: 77
+ { stacktrace:
+ netif_rx_internal+0xb2/0xd0
+ netif_rx+0x1c/0x60
+ loopback_xmit+0x6c/0xb0
+ dev_hard_start_xmit+0x219/0x3a0
+ __dev_queue_xmit+0x415/0x4f0
+ dev_queue_xmit_sk+0x13/0x20
+ ip_finish_output2+0x237/0x340
+ ip_finish_output+0x113/0x1d0
+ ip_output+0x66/0xc0
+ ip_local_out_sk+0x31/0x40
+ ip_send_skb+0x1a/0x50
+ udp_send_skb+0x16d/0x270
+ udp_sendmsg+0x2bf/0x980
+ inet_sendmsg+0x67/0xa0
+ sock_sendmsg+0x38/0x50
+ SYSC_sendto+0xef/0x170
+ } hitcount: 88
+ { stacktrace:
+ kernel_clone+0x18e/0x330
+ SyS_clone+0x19/0x20
+ entry_SYSCALL_64_fastpath+0x12/0x6a
+ } hitcount: 244
+
+ Totals:
+ Hits: 489
+ Entries: 7
+ Dropped: 0
+
+2.2 Inter-event hist triggers
+-----------------------------
+
+Inter-event hist triggers are hist triggers that combine values from
+one or more other events and create a histogram using that data. Data
+from an inter-event histogram can in turn become the source for
+further combined histograms, thus providing a chain of related
+histograms, which is important for some applications.
+
+The most important example of an inter-event quantity that can be used
+in this manner is latency, which is simply a difference in timestamps
+between two events. Although latency is the most important
+inter-event quantity, note that because the support is completely
+general across the trace event subsystem, any event field can be used
+in an inter-event quantity.
+
+An example of a histogram that combines data from other histograms
+into a useful chain would be a 'wakeupswitch latency' histogram that
+combines a 'wakeup latency' histogram and a 'switch latency'
+histogram.
+
+Normally, a hist trigger specification consists of a (possibly
+compound) key along with one or more numeric values, which are
+continually updated sums associated with that key. A histogram
+specification in this case consists of individual key and value
+specifications that refer to trace event fields associated with a
+single event type.
+
+The inter-event hist trigger extension allows fields from multiple
+events to be referenced and combined into a multi-event histogram
+specification. In support of this overall goal, a few enabling
+features have been added to the hist trigger support:
+
+ - In order to compute an inter-event quantity, a value from one
+ event needs to saved and then referenced from another event. This
+ requires the introduction of support for histogram 'variables'.
+
+ - The computation of inter-event quantities and their combination
+ require some minimal amount of support for applying simple
+ expressions to variables (+ and -).
+
+ - A histogram consisting of inter-event quantities isn't logically a
+ histogram on either event (so having the 'hist' file for either
+ event host the histogram output doesn't really make sense). To
+ address the idea that the histogram is associated with a
+ combination of events, support is added allowing the creation of
+ 'synthetic' events that are events derived from other events.
+ These synthetic events are full-fledged events just like any other
+ and can be used as such, as for instance to create the
+ 'combination' histograms mentioned previously.
+
+ - A set of 'actions' can be associated with histogram entries -
+ these can be used to generate the previously mentioned synthetic
+ events, but can also be used for other purposes, such as for
+ example saving context when a 'max' latency has been hit.
+
+ - Trace events don't have a 'timestamp' associated with them, but
+ there is an implicit timestamp saved along with an event in the
+ underlying ftrace ring buffer. This timestamp is now exposed as a
+ a synthetic field named 'common_timestamp' which can be used in
+ histograms as if it were any other event field; it isn't an actual
+ field in the trace format but rather is a synthesized value that
+ nonetheless can be used as if it were an actual field. By default
+ it is in units of nanoseconds; appending '.usecs' to a
+ common_timestamp field changes the units to microseconds.
+
+A note on inter-event timestamps: If common_timestamp is used in a
+histogram, the trace buffer is automatically switched over to using
+absolute timestamps and the "global" trace clock, in order to avoid
+bogus timestamp differences with other clocks that aren't coherent
+across CPUs. This can be overridden by specifying one of the other
+trace clocks instead, using the "clock=XXX" hist trigger attribute,
+where XXX is any of the clocks listed in the tracing/trace_clock
+pseudo-file.
+
+These features are described in more detail in the following sections.
+
+2.2.1 Histogram Variables
+-------------------------
+
+Variables are simply named locations used for saving and retrieving
+values between matching events. A 'matching' event is defined as an
+event that has a matching key - if a variable is saved for a histogram
+entry corresponding to that key, any subsequent event with a matching
+key can access that variable.
+
+A variable's value is normally available to any subsequent event until
+it is set to something else by a subsequent event. The one exception
+to that rule is that any variable used in an expression is essentially
+'read-once' - once it's used by an expression in a subsequent event,
+it's reset to its 'unset' state, which means it can't be used again
+unless it's set again. This ensures not only that an event doesn't
+use an uninitialized variable in a calculation, but that that variable
+is used only once and not for any unrelated subsequent match.
+
+The basic syntax for saving a variable is to simply prefix a unique
+variable name not corresponding to any keyword along with an '=' sign
+to any event field.
+
+Either keys or values can be saved and retrieved in this way. This
+creates a variable named 'ts0' for a histogram entry with the key
+'next_pid'::
+
+ # echo 'hist:keys=next_pid:vals=$ts0:ts0=common_timestamp ... >> \
+ event/trigger
+
+The ts0 variable can be accessed by any subsequent event having the
+same pid as 'next_pid'.
+
+Variable references are formed by prepending the variable name with
+the '$' sign. Thus for example, the ts0 variable above would be
+referenced as '$ts0' in expressions.
+
+Because 'vals=' is used, the common_timestamp variable value above
+will also be summed as a normal histogram value would (though for a
+timestamp it makes little sense).
+
+The below shows that a key value can also be saved in the same way::
+
+ # echo 'hist:timer_pid=common_pid:key=timer_pid ...' >> event/trigger
+
+If a variable isn't a key variable or prefixed with 'vals=', the
+associated event field will be saved in a variable but won't be summed
+as a value::
+
+ # echo 'hist:keys=next_pid:ts1=common_timestamp ...' >> event/trigger
+
+Multiple variables can be assigned at the same time. The below would
+result in both ts0 and b being created as variables, with both
+common_timestamp and field1 additionally being summed as values::
+
+ # echo 'hist:keys=pid:vals=$ts0,$b:ts0=common_timestamp,b=field1 ...' >> \
+ event/trigger
+
+Note that variable assignments can appear either preceding or
+following their use. The command below behaves identically to the
+command above::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp,b=field1:vals=$ts0,$b ...' >> \
+ event/trigger
+
+Any number of variables not bound to a 'vals=' prefix can also be
+assigned by simply separating them with colons. Below is the same
+thing but without the values being summed in the histogram::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp:b=field1 ...' >> event/trigger
+
+Variables set as above can be referenced and used in expressions on
+another event.
+
+For example, here's how a latency can be calculated::
+
+ # echo 'hist:keys=pid,prio:ts0=common_timestamp ...' >> event1/trigger
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp-$ts0 ...' >> event2/trigger
+
+In the first line above, the event's timestamp is saved into the
+variable ts0. In the next line, ts0 is subtracted from the second
+event's timestamp to produce the latency, which is then assigned into
+yet another variable, 'wakeup_lat'. The hist trigger below in turn
+makes use of the wakeup_lat variable to compute a combined latency
+using the same key and variable from yet another event::
+
+ # echo 'hist:key=pid:wakeupswitch_lat=$wakeup_lat+$switchtime_lat ...' >> event3/trigger
+
+Expressions support the use of addition, subtraction, multiplication and
+division operators (+-\*/).
+
+Note if division by zero cannot be detected at parse time (i.e. the
+divisor is not a constant), the result will be -1.
+
+Numeric constants can also be used directly in an expression::
+
+ # echo 'hist:keys=next_pid:timestamp_secs=common_timestamp/1000000 ...' >> event/trigger
+
+or assigned to a variable and referenced in a subsequent expression::
+
+ # echo 'hist:keys=next_pid:us_per_sec=1000000 ...' >> event/trigger
+ # echo 'hist:keys=next_pid:timestamp_secs=common_timestamp/$us_per_sec ...' >> event/trigger
+
+2.2.2 Synthetic Events
+----------------------
+
+Synthetic events are user-defined events generated from hist trigger
+variables or fields associated with one or more other events. Their
+purpose is to provide a mechanism for displaying data spanning
+multiple events consistent with the existing and already familiar
+usage for normal events.
+
+To define a synthetic event, the user writes a simple specification
+consisting of the name of the new event along with one or more
+variables and their types, which can be any valid field type,
+separated by semicolons, to the tracing/synthetic_events file.
+
+See synth_field_size() for available types.
+
+If field_name contains [n], the field is considered to be a static array.
+
+If field_names contains[] (no subscript), the field is considered to
+be a dynamic array, which will only take as much space in the event as
+is required to hold the array.
+
+A string field can be specified using either the static notation:
+
+ char name[32];
+
+Or the dynamic:
+
+ char name[];
+
+The size limit for either is 256.
+
+For instance, the following creates a new event named 'wakeup_latency'
+with 3 fields: lat, pid, and prio. Each of those fields is simply a
+variable reference to a variable on another event::
+
+ # echo 'wakeup_latency \
+ u64 lat; \
+ pid_t pid; \
+ int prio' >> \
+ /sys/kernel/debug/tracing/synthetic_events
+
+Reading the tracing/synthetic_events file lists all the currently
+defined synthetic events, in this case the event defined above::
+
+ # cat /sys/kernel/debug/tracing/synthetic_events
+ wakeup_latency u64 lat; pid_t pid; int prio
+
+An existing synthetic event definition can be removed by prepending
+the command that defined it with a '!'::
+
+ # echo '!wakeup_latency u64 lat pid_t pid int prio' >> \
+ /sys/kernel/debug/tracing/synthetic_events
+
+At this point, there isn't yet an actual 'wakeup_latency' event
+instantiated in the event subsystem - for this to happen, a 'hist
+trigger action' needs to be instantiated and bound to actual fields
+and variables defined on other events (see Section 2.2.3 below on
+how that is done using hist trigger 'onmatch' action). Once that is
+done, the 'wakeup_latency' synthetic event instance is created.
+
+The new event is created under the tracing/events/synthetic/ directory
+and looks and behaves just like any other event::
+
+ # ls /sys/kernel/debug/tracing/events/synthetic/wakeup_latency
+ enable filter format hist id trigger
+
+A histogram can now be defined for the new synthetic event::
+
+ # echo 'hist:keys=pid,prio,lat.log2:sort=lat' >> \
+ /sys/kernel/debug/tracing/events/synthetic/wakeup_latency/trigger
+
+The above shows the latency "lat" in a power of 2 grouping.
+
+Like any other event, once a histogram is enabled for the event, the
+output can be displayed by reading the event's 'hist' file.
+
+ # cat /sys/kernel/debug/tracing/events/synthetic/wakeup_latency/hist
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid,prio,lat.log2:vals=hitcount:sort=lat.log2:size=2048 [active]
+ #
+
+ { pid: 2035, prio: 9, lat: ~ 2^2 } hitcount: 43
+ { pid: 2034, prio: 9, lat: ~ 2^2 } hitcount: 60
+ { pid: 2029, prio: 9, lat: ~ 2^2 } hitcount: 965
+ { pid: 2034, prio: 120, lat: ~ 2^2 } hitcount: 9
+ { pid: 2033, prio: 120, lat: ~ 2^2 } hitcount: 5
+ { pid: 2030, prio: 9, lat: ~ 2^2 } hitcount: 335
+ { pid: 2030, prio: 120, lat: ~ 2^2 } hitcount: 10
+ { pid: 2032, prio: 120, lat: ~ 2^2 } hitcount: 1
+ { pid: 2035, prio: 120, lat: ~ 2^2 } hitcount: 2
+ { pid: 2031, prio: 9, lat: ~ 2^2 } hitcount: 176
+ { pid: 2028, prio: 120, lat: ~ 2^2 } hitcount: 15
+ { pid: 2033, prio: 9, lat: ~ 2^2 } hitcount: 91
+ { pid: 2032, prio: 9, lat: ~ 2^2 } hitcount: 125
+ { pid: 2029, prio: 120, lat: ~ 2^2 } hitcount: 4
+ { pid: 2031, prio: 120, lat: ~ 2^2 } hitcount: 3
+ { pid: 2029, prio: 120, lat: ~ 2^3 } hitcount: 2
+ { pid: 2035, prio: 9, lat: ~ 2^3 } hitcount: 41
+ { pid: 2030, prio: 120, lat: ~ 2^3 } hitcount: 1
+ { pid: 2032, prio: 9, lat: ~ 2^3 } hitcount: 32
+ { pid: 2031, prio: 9, lat: ~ 2^3 } hitcount: 44
+ { pid: 2034, prio: 9, lat: ~ 2^3 } hitcount: 40
+ { pid: 2030, prio: 9, lat: ~ 2^3 } hitcount: 29
+ { pid: 2033, prio: 9, lat: ~ 2^3 } hitcount: 31
+ { pid: 2029, prio: 9, lat: ~ 2^3 } hitcount: 31
+ { pid: 2028, prio: 120, lat: ~ 2^3 } hitcount: 18
+ { pid: 2031, prio: 120, lat: ~ 2^3 } hitcount: 2
+ { pid: 2028, prio: 120, lat: ~ 2^4 } hitcount: 1
+ { pid: 2029, prio: 9, lat: ~ 2^4 } hitcount: 4
+ { pid: 2031, prio: 120, lat: ~ 2^7 } hitcount: 1
+ { pid: 2032, prio: 120, lat: ~ 2^7 } hitcount: 1
+
+ Totals:
+ Hits: 2122
+ Entries: 30
+ Dropped: 0
+
+
+The latency values can also be grouped linearly by a given size with
+the ".buckets" modifier and specify a size (in this case groups of 10).
+
+ # echo 'hist:keys=pid,prio,lat.buckets=10:sort=lat' >> \
+ /sys/kernel/debug/tracing/events/synthetic/wakeup_latency/trigger
+
+ # event histogram
+ #
+ # trigger info: hist:keys=pid,prio,lat.buckets=10:vals=hitcount:sort=lat.buckets=10:size=2048 [active]
+ #
+
+ { pid: 2067, prio: 9, lat: ~ 0-9 } hitcount: 220
+ { pid: 2068, prio: 9, lat: ~ 0-9 } hitcount: 157
+ { pid: 2070, prio: 9, lat: ~ 0-9 } hitcount: 100
+ { pid: 2067, prio: 120, lat: ~ 0-9 } hitcount: 6
+ { pid: 2065, prio: 120, lat: ~ 0-9 } hitcount: 2
+ { pid: 2066, prio: 120, lat: ~ 0-9 } hitcount: 2
+ { pid: 2069, prio: 9, lat: ~ 0-9 } hitcount: 122
+ { pid: 2069, prio: 120, lat: ~ 0-9 } hitcount: 8
+ { pid: 2070, prio: 120, lat: ~ 0-9 } hitcount: 1
+ { pid: 2068, prio: 120, lat: ~ 0-9 } hitcount: 7
+ { pid: 2066, prio: 9, lat: ~ 0-9 } hitcount: 365
+ { pid: 2064, prio: 120, lat: ~ 0-9 } hitcount: 35
+ { pid: 2065, prio: 9, lat: ~ 0-9 } hitcount: 998
+ { pid: 2071, prio: 9, lat: ~ 0-9 } hitcount: 85
+ { pid: 2065, prio: 9, lat: ~ 10-19 } hitcount: 2
+ { pid: 2064, prio: 120, lat: ~ 10-19 } hitcount: 2
+
+ Totals:
+ Hits: 2112
+ Entries: 16
+ Dropped: 0
+
+2.2.3 Hist trigger 'handlers' and 'actions'
+-------------------------------------------
+
+A hist trigger 'action' is a function that's executed (in most cases
+conditionally) whenever a histogram entry is added or updated.
+
+When a histogram entry is added or updated, a hist trigger 'handler'
+is what decides whether the corresponding action is actually invoked
+or not.
+
+Hist trigger handlers and actions are paired together in the general
+form:
+
+ <handler>.<action>
+
+To specify a handler.action pair for a given event, simply specify
+that handler.action pair between colons in the hist trigger
+specification.
+
+In theory, any handler can be combined with any action, but in
+practice, not every handler.action combination is currently supported;
+if a given handler.action combination isn't supported, the hist
+trigger will fail with -EINVAL;
+
+The default 'handler.action' if none is explicitly specified is as it
+always has been, to simply update the set of values associated with an
+entry. Some applications, however, may want to perform additional
+actions at that point, such as generate another event, or compare and
+save a maximum.
+
+The supported handlers and actions are listed below, and each is
+described in more detail in the following paragraphs, in the context
+of descriptions of some common and useful handler.action combinations.
+
+The available handlers are:
+
+ - onmatch(matching.event) - invoke action on any addition or update
+ - onmax(var) - invoke action if var exceeds current max
+ - onchange(var) - invoke action if var changes
+
+The available actions are:
+
+ - trace(<synthetic_event_name>,param list) - generate synthetic event
+ - save(field,...) - save current event fields
+ - snapshot() - snapshot the trace buffer
+
+The following commonly-used handler.action pairs are available:
+
+ - onmatch(matching.event).trace(<synthetic_event_name>,param list)
+
+ The 'onmatch(matching.event).trace(<synthetic_event_name>,param
+ list)' hist trigger action is invoked whenever an event matches
+ and the histogram entry would be added or updated. It causes the
+ named synthetic event to be generated with the values given in the
+ 'param list'. The result is the generation of a synthetic event
+ that consists of the values contained in those variables at the
+ time the invoking event was hit. For example, if the synthetic
+ event name is 'wakeup_latency', a wakeup_latency event is
+ generated using onmatch(event).trace(wakeup_latency,arg1,arg2).
+
+ There is also an equivalent alternative form available for
+ generating synthetic events. In this form, the synthetic event
+ name is used as if it were a function name. For example, using
+ the 'wakeup_latency' synthetic event name again, the
+ wakeup_latency event would be generated by invoking it as if it
+ were a function call, with the event field values passed in as
+ arguments: onmatch(event).wakeup_latency(arg1,arg2). The syntax
+ for this form is:
+
+ onmatch(matching.event).<synthetic_event_name>(param list)
+
+ In either case, the 'param list' consists of one or more
+ parameters which may be either variables or fields defined on
+ either the 'matching.event' or the target event. The variables or
+ fields specified in the param list may be either fully-qualified
+ or unqualified. If a variable is specified as unqualified, it
+ must be unique between the two events. A field name used as a
+ param can be unqualified if it refers to the target event, but
+ must be fully qualified if it refers to the matching event. A
+ fully-qualified name is of the form 'system.event_name.$var_name'
+ or 'system.event_name.field'.
+
+ The 'matching.event' specification is simply the fully qualified
+ event name of the event that matches the target event for the
+ onmatch() functionality, in the form 'system.event_name'. Histogram
+ keys of both events are compared to find if events match. In case
+ multiple histogram keys are used, they all must match in the specified
+ order.
+
+ Finally, the number and type of variables/fields in the 'param
+ list' must match the number and types of the fields in the
+ synthetic event being generated.
+
+ As an example the below defines a simple synthetic event and uses
+ a variable defined on the sched_wakeup_new event as a parameter
+ when invoking the synthetic event. Here we define the synthetic
+ event::
+
+ # echo 'wakeup_new_test pid_t pid' >> \
+ /sys/kernel/debug/tracing/synthetic_events
+
+ # cat /sys/kernel/debug/tracing/synthetic_events
+ wakeup_new_test pid_t pid
+
+ The following hist trigger both defines the missing testpid
+ variable and specifies an onmatch() action that generates a
+ wakeup_new_test synthetic event whenever a sched_wakeup_new event
+ occurs, which because of the 'if comm == "cyclictest"' filter only
+ happens when the executable is cyclictest::
+
+ # echo 'hist:keys=$testpid:testpid=pid:onmatch(sched.sched_wakeup_new).\
+ wakeup_new_test($testpid) if comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_wakeup_new/trigger
+
+ Or, equivalently, using the 'trace' keyword syntax:
+
+ # echo 'hist:keys=$testpid:testpid=pid:onmatch(sched.sched_wakeup_new).\
+ trace(wakeup_new_test,$testpid) if comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_wakeup_new/trigger
+
+ Creating and displaying a histogram based on those events is now
+ just a matter of using the fields and new synthetic event in the
+ tracing/events/synthetic directory, as usual::
+
+ # echo 'hist:keys=pid:sort=pid' >> \
+ /sys/kernel/debug/tracing/events/synthetic/wakeup_new_test/trigger
+
+ Running 'cyclictest' should cause wakeup_new events to generate
+ wakeup_new_test synthetic events which should result in histogram
+ output in the wakeup_new_test event's hist file::
+
+ # cat /sys/kernel/debug/tracing/events/synthetic/wakeup_new_test/hist
+
+ A more typical usage would be to use two events to calculate a
+ latency. The following example uses a set of hist triggers to
+ produce a 'wakeup_latency' histogram.
+
+ First, we define a 'wakeup_latency' synthetic event::
+
+ # echo 'wakeup_latency u64 lat; pid_t pid; int prio' >> \
+ /sys/kernel/debug/tracing/synthetic_events
+
+ Next, we specify that whenever we see a sched_waking event for a
+ cyclictest thread, save the timestamp in a 'ts0' variable::
+
+ # echo 'hist:keys=$saved_pid:saved_pid=pid:ts0=common_timestamp.usecs \
+ if comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_waking/trigger
+
+ Then, when the corresponding thread is actually scheduled onto the
+ CPU by a sched_switch event (saved_pid matches next_pid), calculate
+ the latency and use that along with another variable and an event field
+ to generate a wakeup_latency synthetic event::
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0:\
+ onmatch(sched.sched_waking).wakeup_latency($wakeup_lat,\
+ $saved_pid,next_prio) if next_comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+ We also need to create a histogram on the wakeup_latency synthetic
+ event in order to aggregate the generated synthetic event data::
+
+ # echo 'hist:keys=pid,prio,lat:sort=pid,lat' >> \
+ /sys/kernel/debug/tracing/events/synthetic/wakeup_latency/trigger
+
+ Finally, once we've run cyclictest to actually generate some
+ events, we can see the output by looking at the wakeup_latency
+ synthetic event's hist file::
+
+ # cat /sys/kernel/debug/tracing/events/synthetic/wakeup_latency/hist
+
+ - onmax(var).save(field,.. .)
+
+ The 'onmax(var).save(field,...)' hist trigger action is invoked
+ whenever the value of 'var' associated with a histogram entry
+ exceeds the current maximum contained in that variable.
+
+ The end result is that the trace event fields specified as the
+ onmax.save() params will be saved if 'var' exceeds the current
+ maximum for that hist trigger entry. This allows context from the
+ event that exhibited the new maximum to be saved for later
+ reference. When the histogram is displayed, additional fields
+ displaying the saved values will be printed.
+
+ As an example the below defines a couple of hist triggers, one for
+ sched_waking and another for sched_switch, keyed on pid. Whenever
+ a sched_waking occurs, the timestamp is saved in the entry
+ corresponding to the current pid, and when the scheduler switches
+ back to that pid, the timestamp difference is calculated. If the
+ resulting latency, stored in wakeup_lat, exceeds the current
+ maximum latency, the values specified in the save() fields are
+ recorded::
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs \
+ if comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_waking/trigger
+
+ # echo 'hist:keys=next_pid:\
+ wakeup_lat=common_timestamp.usecs-$ts0:\
+ onmax($wakeup_lat).save(next_comm,prev_pid,prev_prio,prev_comm) \
+ if next_comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+ When the histogram is displayed, the max value and the saved
+ values corresponding to the max are displayed following the rest
+ of the fields::
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_switch/hist
+ { next_pid: 2255 } hitcount: 239
+ common_timestamp-ts0: 0
+ max: 27
+ next_comm: cyclictest
+ prev_pid: 0 prev_prio: 120 prev_comm: swapper/1
+
+ { next_pid: 2256 } hitcount: 2355
+ common_timestamp-ts0: 0
+ max: 49 next_comm: cyclictest
+ prev_pid: 0 prev_prio: 120 prev_comm: swapper/0
+
+ Totals:
+ Hits: 12970
+ Entries: 2
+ Dropped: 0
+
+ - onmax(var).snapshot()
+
+ The 'onmax(var).snapshot()' hist trigger action is invoked
+ whenever the value of 'var' associated with a histogram entry
+ exceeds the current maximum contained in that variable.
+
+ The end result is that a global snapshot of the trace buffer will
+ be saved in the tracing/snapshot file if 'var' exceeds the current
+ maximum for any hist trigger entry.
+
+ Note that in this case the maximum is a global maximum for the
+ current trace instance, which is the maximum across all buckets of
+ the histogram. The key of the specific trace event that caused
+ the global maximum and the global maximum itself are displayed,
+ along with a message stating that a snapshot has been taken and
+ where to find it. The user can use the key information displayed
+ to locate the corresponding bucket in the histogram for even more
+ detail.
+
+ As an example the below defines a couple of hist triggers, one for
+ sched_waking and another for sched_switch, keyed on pid. Whenever
+ a sched_waking event occurs, the timestamp is saved in the entry
+ corresponding to the current pid, and when the scheduler switches
+ back to that pid, the timestamp difference is calculated. If the
+ resulting latency, stored in wakeup_lat, exceeds the current
+ maximum latency, a snapshot is taken. As part of the setup, all
+ the scheduler events are also enabled, which are the events that
+ will show up in the snapshot when it is taken at some point:
+
+ # echo 1 > /sys/kernel/debug/tracing/events/sched/enable
+
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs \
+ if comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_waking/trigger
+
+ # echo 'hist:keys=next_pid:wakeup_lat=common_timestamp.usecs-$ts0: \
+ onmax($wakeup_lat).save(next_prio,next_comm,prev_pid,prev_prio, \
+ prev_comm):onmax($wakeup_lat).snapshot() \
+ if next_comm=="cyclictest"' >> \
+ /sys/kernel/debug/tracing/events/sched/sched_switch/trigger
+
+ When the histogram is displayed, for each bucket the max value
+ and the saved values corresponding to the max are displayed
+ following the rest of the fields.
+
+ If a snapshot was taken, there is also a message indicating that,
+ along with the value and event that triggered the global maximum:
+
+ # cat /sys/kernel/debug/tracing/events/sched/sched_switch/hist
+ { next_pid: 2101 } hitcount: 200
+ max: 52 next_prio: 120 next_comm: cyclictest \
+ prev_pid: 0 prev_prio: 120 prev_comm: swapper/6
+
+ { next_pid: 2103 } hitcount: 1326
+ max: 572 next_prio: 19 next_comm: cyclictest \
+ prev_pid: 0 prev_prio: 120 prev_comm: swapper/1
+
+ { next_pid: 2102 } hitcount: 1982 \
+ max: 74 next_prio: 19 next_comm: cyclictest \
+ prev_pid: 0 prev_prio: 120 prev_comm: swapper/5
+
+ Snapshot taken (see tracing/snapshot). Details:
+ triggering value { onmax($wakeup_lat) }: 572 \
+ triggered by event with key: { next_pid: 2103 }
+
+ Totals:
+ Hits: 3508
+ Entries: 3
+ Dropped: 0
+
+ In the above case, the event that triggered the global maximum has
+ the key with next_pid == 2103. If you look at the bucket that has
+ 2103 as the key, you'll find the additional values save()'d along
+ with the local maximum for that bucket, which should be the same
+ as the global maximum (since that was the same value that
+ triggered the global snapshot).
+
+ And finally, looking at the snapshot data should show at or near
+ the end the event that triggered the snapshot (in this case you
+ can verify the timestamps between the sched_waking and
+ sched_switch events, which should match the time displayed in the
+ global maximum)::
+
+ # cat /sys/kernel/debug/tracing/snapshot
+
+ <...>-2103 [005] d..3 309.873125: sched_switch: prev_comm=cyclictest prev_pid=2103 prev_prio=19 prev_state=D ==> next_comm=swapper/5 next_pid=0 next_prio=120
+ <idle>-0 [005] d.h3 309.873611: sched_waking: comm=cyclictest pid=2102 prio=19 target_cpu=005
+ <idle>-0 [005] dNh4 309.873613: sched_wakeup: comm=cyclictest pid=2102 prio=19 target_cpu=005
+ <idle>-0 [005] d..3 309.873616: sched_switch: prev_comm=swapper/5 prev_pid=0 prev_prio=120 prev_state=S ==> next_comm=cyclictest next_pid=2102 next_prio=19
+ <...>-2102 [005] d..3 309.873625: sched_switch: prev_comm=cyclictest prev_pid=2102 prev_prio=19 prev_state=D ==> next_comm=swapper/5 next_pid=0 next_prio=120
+ <idle>-0 [005] d.h3 309.874624: sched_waking: comm=cyclictest pid=2102 prio=19 target_cpu=005
+ <idle>-0 [005] dNh4 309.874626: sched_wakeup: comm=cyclictest pid=2102 prio=19 target_cpu=005
+ <idle>-0 [005] dNh3 309.874628: sched_waking: comm=cyclictest pid=2103 prio=19 target_cpu=005
+ <idle>-0 [005] dNh4 309.874630: sched_wakeup: comm=cyclictest pid=2103 prio=19 target_cpu=005
+ <idle>-0 [005] d..3 309.874633: sched_switch: prev_comm=swapper/5 prev_pid=0 prev_prio=120 prev_state=S ==> next_comm=cyclictest next_pid=2102 next_prio=19
+ <idle>-0 [004] d.h3 309.874757: sched_waking: comm=gnome-terminal- pid=1699 prio=120 target_cpu=004
+ <idle>-0 [004] dNh4 309.874762: sched_wakeup: comm=gnome-terminal- pid=1699 prio=120 target_cpu=004
+ <idle>-0 [004] d..3 309.874766: sched_switch: prev_comm=swapper/4 prev_pid=0 prev_prio=120 prev_state=S ==> next_comm=gnome-terminal- next_pid=1699 next_prio=120
+ gnome-terminal--1699 [004] d.h2 309.874941: sched_stat_runtime: comm=gnome-terminal- pid=1699 runtime=180706 [ns] vruntime=1126870572 [ns]
+ <idle>-0 [003] d.s4 309.874956: sched_waking: comm=rcu_sched pid=9 prio=120 target_cpu=007
+ <idle>-0 [003] d.s5 309.874960: sched_wake_idle_without_ipi: cpu=7
+ <idle>-0 [003] d.s5 309.874961: sched_wakeup: comm=rcu_sched pid=9 prio=120 target_cpu=007
+ <idle>-0 [007] d..3 309.874963: sched_switch: prev_comm=swapper/7 prev_pid=0 prev_prio=120 prev_state=S ==> next_comm=rcu_sched next_pid=9 next_prio=120
+ rcu_sched-9 [007] d..3 309.874973: sched_stat_runtime: comm=rcu_sched pid=9 runtime=13646 [ns] vruntime=22531430286 [ns]
+ rcu_sched-9 [007] d..3 309.874978: sched_switch: prev_comm=rcu_sched prev_pid=9 prev_prio=120 prev_state=R+ ==> next_comm=swapper/7 next_pid=0 next_prio=120
+ <...>-2102 [005] d..4 309.874994: sched_migrate_task: comm=cyclictest pid=2103 prio=19 orig_cpu=5 dest_cpu=1
+ <...>-2102 [005] d..4 309.875185: sched_wake_idle_without_ipi: cpu=1
+ <idle>-0 [001] d..3 309.875200: sched_switch: prev_comm=swapper/1 prev_pid=0 prev_prio=120 prev_state=S ==> next_comm=cyclictest next_pid=2103 next_prio=19
+
+ - onchange(var).save(field,.. .)
+
+ The 'onchange(var).save(field,...)' hist trigger action is invoked
+ whenever the value of 'var' associated with a histogram entry
+ changes.
+
+ The end result is that the trace event fields specified as the
+ onchange.save() params will be saved if 'var' changes for that
+ hist trigger entry. This allows context from the event that
+ changed the value to be saved for later reference. When the
+ histogram is displayed, additional fields displaying the saved
+ values will be printed.
+
+ - onchange(var).snapshot()
+
+ The 'onchange(var).snapshot()' hist trigger action is invoked
+ whenever the value of 'var' associated with a histogram entry
+ changes.
+
+ The end result is that a global snapshot of the trace buffer will
+ be saved in the tracing/snapshot file if 'var' changes for any
+ hist trigger entry.
+
+ Note that in this case the changed value is a global variable
+ associated with current trace instance. The key of the specific
+ trace event that caused the value to change and the global value
+ itself are displayed, along with a message stating that a snapshot
+ has been taken and where to find it. The user can use the key
+ information displayed to locate the corresponding bucket in the
+ histogram for even more detail.
+
+ As an example the below defines a hist trigger on the tcp_probe
+ event, keyed on dport. Whenever a tcp_probe event occurs, the
+ cwnd field is checked against the current value stored in the
+ $cwnd variable. If the value has changed, a snapshot is taken.
+ As part of the setup, all the scheduler and tcp events are also
+ enabled, which are the events that will show up in the snapshot
+ when it is taken at some point:
+
+ # echo 1 > /sys/kernel/debug/tracing/events/sched/enable
+ # echo 1 > /sys/kernel/debug/tracing/events/tcp/enable
+
+ # echo 'hist:keys=dport:cwnd=snd_cwnd: \
+ onchange($cwnd).save(snd_wnd,srtt,rcv_wnd): \
+ onchange($cwnd).snapshot()' >> \
+ /sys/kernel/debug/tracing/events/tcp/tcp_probe/trigger
+
+ When the histogram is displayed, for each bucket the tracked value
+ and the saved values corresponding to that value are displayed
+ following the rest of the fields.
+
+ If a snapshot was taken, there is also a message indicating that,
+ along with the value and event that triggered the snapshot::
+
+ # cat /sys/kernel/debug/tracing/events/tcp/tcp_probe/hist
+
+ { dport: 1521 } hitcount: 8
+ changed: 10 snd_wnd: 35456 srtt: 154262 rcv_wnd: 42112
+
+ { dport: 80 } hitcount: 23
+ changed: 10 snd_wnd: 28960 srtt: 19604 rcv_wnd: 29312
+
+ { dport: 9001 } hitcount: 172
+ changed: 10 snd_wnd: 48384 srtt: 260444 rcv_wnd: 55168
+
+ { dport: 443 } hitcount: 211
+ changed: 10 snd_wnd: 26960 srtt: 17379 rcv_wnd: 28800
+
+ Snapshot taken (see tracing/snapshot). Details::
+
+ triggering value { onchange($cwnd) }: 10
+ triggered by event with key: { dport: 80 }
+
+ Totals:
+ Hits: 414
+ Entries: 4
+ Dropped: 0
+
+ In the above case, the event that triggered the snapshot has the
+ key with dport == 80. If you look at the bucket that has 80 as
+ the key, you'll find the additional values save()'d along with the
+ changed value for that bucket, which should be the same as the
+ global changed value (since that was the same value that triggered
+ the global snapshot).
+
+ And finally, looking at the snapshot data should show at or near
+ the end the event that triggered the snapshot::
+
+ # cat /sys/kernel/debug/tracing/snapshot
+
+ gnome-shell-1261 [006] dN.3 49.823113: sched_stat_runtime: comm=gnome-shell pid=1261 runtime=49347 [ns] vruntime=1835730389 [ns]
+ kworker/u16:4-773 [003] d..3 49.823114: sched_switch: prev_comm=kworker/u16:4 prev_pid=773 prev_prio=120 prev_state=R+ ==> next_comm=kworker/3:2 next_pid=135 next_prio=120
+ gnome-shell-1261 [006] d..3 49.823114: sched_switch: prev_comm=gnome-shell prev_pid=1261 prev_prio=120 prev_state=R+ ==> next_comm=kworker/6:2 next_pid=387 next_prio=120
+ kworker/3:2-135 [003] d..3 49.823118: sched_stat_runtime: comm=kworker/3:2 pid=135 runtime=5339 [ns] vruntime=17815800388 [ns]
+ kworker/6:2-387 [006] d..3 49.823120: sched_stat_runtime: comm=kworker/6:2 pid=387 runtime=9594 [ns] vruntime=14589605367 [ns]
+ kworker/6:2-387 [006] d..3 49.823122: sched_switch: prev_comm=kworker/6:2 prev_pid=387 prev_prio=120 prev_state=R+ ==> next_comm=gnome-shell next_pid=1261 next_prio=120
+ kworker/3:2-135 [003] d..3 49.823123: sched_switch: prev_comm=kworker/3:2 prev_pid=135 prev_prio=120 prev_state=T ==> next_comm=swapper/3 next_pid=0 next_prio=120
+ <idle>-0 [004] ..s7 49.823798: tcp_probe: src=10.0.0.10:54326 dest=23.215.104.193:80 mark=0x0 length=32 snd_nxt=0xe3ae2ff5 snd_una=0xe3ae2ecd snd_cwnd=10 ssthresh=2147483647 snd_wnd=28960 srtt=19604 rcv_wnd=29312
+
+3. User space creating a trigger
+--------------------------------
+
+Writing into /sys/kernel/tracing/trace_marker writes into the ftrace
+ring buffer. This can also act like an event, by writing into the trigger
+file located in /sys/kernel/tracing/events/ftrace/print/
+
+Modifying cyclictest to write into the trace_marker file before it sleeps
+and after it wakes up, something like this::
+
+ static void traceputs(char *str)
+ {
+ /* tracemark_fd is the trace_marker file descriptor */
+ if (tracemark_fd < 0)
+ return;
+ /* write the tracemark message */
+ write(tracemark_fd, str, strlen(str));
+ }
+
+And later add something like::
+
+ traceputs("start");
+ clock_nanosleep(...);
+ traceputs("end");
+
+We can make a histogram from this::
+
+ # cd /sys/kernel/tracing
+ # echo 'latency u64 lat' > synthetic_events
+ # echo 'hist:keys=common_pid:ts0=common_timestamp.usecs if buf == "start"' > events/ftrace/print/trigger
+ # echo 'hist:keys=common_pid:lat=common_timestamp.usecs-$ts0:onmatch(ftrace.print).latency($lat) if buf == "end"' >> events/ftrace/print/trigger
+ # echo 'hist:keys=lat,common_pid:sort=lat' > events/synthetic/latency/trigger
+
+The above created a synthetic event called "latency" and two histograms
+against the trace_marker, one gets triggered when "start" is written into the
+trace_marker file and the other when "end" is written. If the pids match, then
+it will call the "latency" synthetic event with the calculated latency as its
+parameter. Finally, a histogram is added to the latency synthetic event to
+record the calculated latency along with the pid.
+
+Now running cyclictest with::
+
+ # ./cyclictest -p80 -d0 -i250 -n -a -t --tracemark -b 1000
+
+ -p80 : run threads at priority 80
+ -d0 : have all threads run at the same interval
+ -i250 : start the interval at 250 microseconds (all threads will do this)
+ -n : sleep with nanosleep
+ -a : affine all threads to a separate CPU
+ -t : one thread per available CPU
+ --tracemark : enable trace mark writing
+ -b 1000 : stop if any latency is greater than 1000 microseconds
+
+Note, the -b 1000 is used just to make --tracemark available.
+
+Then we can see the histogram created by this with::
+
+ # cat events/synthetic/latency/hist
+ # event histogram
+ #
+ # trigger info: hist:keys=lat,common_pid:vals=hitcount:sort=lat:size=2048 [active]
+ #
+
+ { lat: 107, common_pid: 2039 } hitcount: 1
+ { lat: 122, common_pid: 2041 } hitcount: 1
+ { lat: 166, common_pid: 2039 } hitcount: 1
+ { lat: 174, common_pid: 2039 } hitcount: 1
+ { lat: 194, common_pid: 2041 } hitcount: 1
+ { lat: 196, common_pid: 2036 } hitcount: 1
+ { lat: 197, common_pid: 2038 } hitcount: 1
+ { lat: 198, common_pid: 2039 } hitcount: 1
+ { lat: 199, common_pid: 2039 } hitcount: 1
+ { lat: 200, common_pid: 2041 } hitcount: 1
+ { lat: 201, common_pid: 2039 } hitcount: 2
+ { lat: 202, common_pid: 2038 } hitcount: 1
+ { lat: 202, common_pid: 2043 } hitcount: 1
+ { lat: 203, common_pid: 2039 } hitcount: 1
+ { lat: 203, common_pid: 2036 } hitcount: 1
+ { lat: 203, common_pid: 2041 } hitcount: 1
+ { lat: 206, common_pid: 2038 } hitcount: 2
+ { lat: 207, common_pid: 2039 } hitcount: 1
+ { lat: 207, common_pid: 2036 } hitcount: 1
+ { lat: 208, common_pid: 2040 } hitcount: 1
+ { lat: 209, common_pid: 2043 } hitcount: 1
+ { lat: 210, common_pid: 2039 } hitcount: 1
+ { lat: 211, common_pid: 2039 } hitcount: 4
+ { lat: 212, common_pid: 2043 } hitcount: 1
+ { lat: 212, common_pid: 2039 } hitcount: 2
+ { lat: 213, common_pid: 2039 } hitcount: 1
+ { lat: 214, common_pid: 2038 } hitcount: 1
+ { lat: 214, common_pid: 2039 } hitcount: 2
+ { lat: 214, common_pid: 2042 } hitcount: 1
+ { lat: 215, common_pid: 2039 } hitcount: 1
+ { lat: 217, common_pid: 2036 } hitcount: 1
+ { lat: 217, common_pid: 2040 } hitcount: 1
+ { lat: 217, common_pid: 2039 } hitcount: 1
+ { lat: 218, common_pid: 2039 } hitcount: 6
+ { lat: 219, common_pid: 2039 } hitcount: 9
+ { lat: 220, common_pid: 2039 } hitcount: 11
+ { lat: 221, common_pid: 2039 } hitcount: 5
+ { lat: 221, common_pid: 2042 } hitcount: 1
+ { lat: 222, common_pid: 2039 } hitcount: 7
+ { lat: 223, common_pid: 2036 } hitcount: 1
+ { lat: 223, common_pid: 2039 } hitcount: 3
+ { lat: 224, common_pid: 2039 } hitcount: 4
+ { lat: 224, common_pid: 2037 } hitcount: 1
+ { lat: 224, common_pid: 2036 } hitcount: 2
+ { lat: 225, common_pid: 2039 } hitcount: 5
+ { lat: 225, common_pid: 2042 } hitcount: 1
+ { lat: 226, common_pid: 2039 } hitcount: 7
+ { lat: 226, common_pid: 2036 } hitcount: 4
+ { lat: 227, common_pid: 2039 } hitcount: 6
+ { lat: 227, common_pid: 2036 } hitcount: 12
+ { lat: 227, common_pid: 2043 } hitcount: 1
+ { lat: 228, common_pid: 2039 } hitcount: 7
+ { lat: 228, common_pid: 2036 } hitcount: 14
+ { lat: 229, common_pid: 2039 } hitcount: 9
+ { lat: 229, common_pid: 2036 } hitcount: 8
+ { lat: 229, common_pid: 2038 } hitcount: 1
+ { lat: 230, common_pid: 2039 } hitcount: 11
+ { lat: 230, common_pid: 2036 } hitcount: 6
+ { lat: 230, common_pid: 2043 } hitcount: 1
+ { lat: 230, common_pid: 2042 } hitcount: 2
+ { lat: 231, common_pid: 2041 } hitcount: 1
+ { lat: 231, common_pid: 2036 } hitcount: 6
+ { lat: 231, common_pid: 2043 } hitcount: 1
+ { lat: 231, common_pid: 2039 } hitcount: 8
+ { lat: 232, common_pid: 2037 } hitcount: 1
+ { lat: 232, common_pid: 2039 } hitcount: 6
+ { lat: 232, common_pid: 2040 } hitcount: 2
+ { lat: 232, common_pid: 2036 } hitcount: 5
+ { lat: 232, common_pid: 2043 } hitcount: 1
+ { lat: 233, common_pid: 2036 } hitcount: 5
+ { lat: 233, common_pid: 2039 } hitcount: 11
+ { lat: 234, common_pid: 2039 } hitcount: 4
+ { lat: 234, common_pid: 2038 } hitcount: 2
+ { lat: 234, common_pid: 2043 } hitcount: 2
+ { lat: 234, common_pid: 2036 } hitcount: 11
+ { lat: 234, common_pid: 2040 } hitcount: 1
+ { lat: 235, common_pid: 2037 } hitcount: 2
+ { lat: 235, common_pid: 2036 } hitcount: 8
+ { lat: 235, common_pid: 2043 } hitcount: 2
+ { lat: 235, common_pid: 2039 } hitcount: 5
+ { lat: 235, common_pid: 2042 } hitcount: 2
+ { lat: 235, common_pid: 2040 } hitcount: 4
+ { lat: 235, common_pid: 2041 } hitcount: 1
+ { lat: 236, common_pid: 2036 } hitcount: 7
+ { lat: 236, common_pid: 2037 } hitcount: 1
+ { lat: 236, common_pid: 2041 } hitcount: 5
+ { lat: 236, common_pid: 2039 } hitcount: 3
+ { lat: 236, common_pid: 2043 } hitcount: 9
+ { lat: 236, common_pid: 2040 } hitcount: 7
+ { lat: 237, common_pid: 2037 } hitcount: 1
+ { lat: 237, common_pid: 2040 } hitcount: 1
+ { lat: 237, common_pid: 2036 } hitcount: 9
+ { lat: 237, common_pid: 2039 } hitcount: 3
+ { lat: 237, common_pid: 2043 } hitcount: 8
+ { lat: 237, common_pid: 2042 } hitcount: 2
+ { lat: 237, common_pid: 2041 } hitcount: 2
+ { lat: 238, common_pid: 2043 } hitcount: 10
+ { lat: 238, common_pid: 2040 } hitcount: 1
+ { lat: 238, common_pid: 2037 } hitcount: 9
+ { lat: 238, common_pid: 2038 } hitcount: 1
+ { lat: 238, common_pid: 2039 } hitcount: 1
+ { lat: 238, common_pid: 2042 } hitcount: 3
+ { lat: 238, common_pid: 2036 } hitcount: 7
+ { lat: 239, common_pid: 2041 } hitcount: 1
+ { lat: 239, common_pid: 2043 } hitcount: 11
+ { lat: 239, common_pid: 2037 } hitcount: 11
+ { lat: 239, common_pid: 2038 } hitcount: 6
+ { lat: 239, common_pid: 2036 } hitcount: 7
+ { lat: 239, common_pid: 2040 } hitcount: 1
+ { lat: 239, common_pid: 2042 } hitcount: 9
+ { lat: 240, common_pid: 2037 } hitcount: 29
+ { lat: 240, common_pid: 2043 } hitcount: 15
+ { lat: 240, common_pid: 2040 } hitcount: 44
+ { lat: 240, common_pid: 2039 } hitcount: 1
+ { lat: 240, common_pid: 2041 } hitcount: 2
+ { lat: 240, common_pid: 2038 } hitcount: 1
+ { lat: 240, common_pid: 2036 } hitcount: 10
+ { lat: 240, common_pid: 2042 } hitcount: 13
+ { lat: 241, common_pid: 2036 } hitcount: 21
+ { lat: 241, common_pid: 2041 } hitcount: 36
+ { lat: 241, common_pid: 2037 } hitcount: 34
+ { lat: 241, common_pid: 2042 } hitcount: 14
+ { lat: 241, common_pid: 2040 } hitcount: 94
+ { lat: 241, common_pid: 2039 } hitcount: 12
+ { lat: 241, common_pid: 2038 } hitcount: 2
+ { lat: 241, common_pid: 2043 } hitcount: 28
+ { lat: 242, common_pid: 2040 } hitcount: 109
+ { lat: 242, common_pid: 2041 } hitcount: 506
+ { lat: 242, common_pid: 2039 } hitcount: 155
+ { lat: 242, common_pid: 2042 } hitcount: 21
+ { lat: 242, common_pid: 2037 } hitcount: 52
+ { lat: 242, common_pid: 2043 } hitcount: 21
+ { lat: 242, common_pid: 2036 } hitcount: 16
+ { lat: 242, common_pid: 2038 } hitcount: 156
+ { lat: 243, common_pid: 2037 } hitcount: 46
+ { lat: 243, common_pid: 2039 } hitcount: 40
+ { lat: 243, common_pid: 2042 } hitcount: 119
+ { lat: 243, common_pid: 2041 } hitcount: 611
+ { lat: 243, common_pid: 2036 } hitcount: 69
+ { lat: 243, common_pid: 2038 } hitcount: 784
+ { lat: 243, common_pid: 2040 } hitcount: 323
+ { lat: 243, common_pid: 2043 } hitcount: 14
+ { lat: 244, common_pid: 2043 } hitcount: 35
+ { lat: 244, common_pid: 2042 } hitcount: 305
+ { lat: 244, common_pid: 2039 } hitcount: 8
+ { lat: 244, common_pid: 2040 } hitcount: 4515
+ { lat: 244, common_pid: 2038 } hitcount: 371
+ { lat: 244, common_pid: 2037 } hitcount: 31
+ { lat: 244, common_pid: 2036 } hitcount: 114
+ { lat: 244, common_pid: 2041 } hitcount: 3396
+ { lat: 245, common_pid: 2036 } hitcount: 700
+ { lat: 245, common_pid: 2041 } hitcount: 2772
+ { lat: 245, common_pid: 2037 } hitcount: 268
+ { lat: 245, common_pid: 2039 } hitcount: 472
+ { lat: 245, common_pid: 2038 } hitcount: 2758
+ { lat: 245, common_pid: 2042 } hitcount: 3833
+ { lat: 245, common_pid: 2040 } hitcount: 3105
+ { lat: 245, common_pid: 2043 } hitcount: 645
+ { lat: 246, common_pid: 2038 } hitcount: 3451
+ { lat: 246, common_pid: 2041 } hitcount: 142
+ { lat: 246, common_pid: 2037 } hitcount: 5101
+ { lat: 246, common_pid: 2040 } hitcount: 68
+ { lat: 246, common_pid: 2043 } hitcount: 5099
+ { lat: 246, common_pid: 2039 } hitcount: 5608
+ { lat: 246, common_pid: 2042 } hitcount: 3723
+ { lat: 246, common_pid: 2036 } hitcount: 4738
+ { lat: 247, common_pid: 2042 } hitcount: 312
+ { lat: 247, common_pid: 2043 } hitcount: 2385
+ { lat: 247, common_pid: 2041 } hitcount: 452
+ { lat: 247, common_pid: 2038 } hitcount: 792
+ { lat: 247, common_pid: 2040 } hitcount: 78
+ { lat: 247, common_pid: 2036 } hitcount: 2375
+ { lat: 247, common_pid: 2039 } hitcount: 1834
+ { lat: 247, common_pid: 2037 } hitcount: 2655
+ { lat: 248, common_pid: 2037 } hitcount: 36
+ { lat: 248, common_pid: 2042 } hitcount: 11
+ { lat: 248, common_pid: 2038 } hitcount: 122
+ { lat: 248, common_pid: 2036 } hitcount: 135
+ { lat: 248, common_pid: 2039 } hitcount: 26
+ { lat: 248, common_pid: 2041 } hitcount: 503
+ { lat: 248, common_pid: 2043 } hitcount: 66
+ { lat: 248, common_pid: 2040 } hitcount: 46
+ { lat: 249, common_pid: 2037 } hitcount: 29
+ { lat: 249, common_pid: 2038 } hitcount: 1
+ { lat: 249, common_pid: 2043 } hitcount: 29
+ { lat: 249, common_pid: 2039 } hitcount: 8
+ { lat: 249, common_pid: 2042 } hitcount: 56
+ { lat: 249, common_pid: 2040 } hitcount: 27
+ { lat: 249, common_pid: 2041 } hitcount: 11
+ { lat: 249, common_pid: 2036 } hitcount: 27
+ { lat: 250, common_pid: 2038 } hitcount: 1
+ { lat: 250, common_pid: 2036 } hitcount: 30
+ { lat: 250, common_pid: 2040 } hitcount: 19
+ { lat: 250, common_pid: 2043 } hitcount: 22
+ { lat: 250, common_pid: 2042 } hitcount: 20
+ { lat: 250, common_pid: 2041 } hitcount: 1
+ { lat: 250, common_pid: 2039 } hitcount: 6
+ { lat: 250, common_pid: 2037 } hitcount: 48
+ { lat: 251, common_pid: 2037 } hitcount: 43
+ { lat: 251, common_pid: 2039 } hitcount: 1
+ { lat: 251, common_pid: 2036 } hitcount: 12
+ { lat: 251, common_pid: 2042 } hitcount: 2
+ { lat: 251, common_pid: 2041 } hitcount: 1
+ { lat: 251, common_pid: 2043 } hitcount: 15
+ { lat: 251, common_pid: 2040 } hitcount: 3
+ { lat: 252, common_pid: 2040 } hitcount: 1
+ { lat: 252, common_pid: 2036 } hitcount: 12
+ { lat: 252, common_pid: 2037 } hitcount: 21
+ { lat: 252, common_pid: 2043 } hitcount: 14
+ { lat: 253, common_pid: 2037 } hitcount: 21
+ { lat: 253, common_pid: 2039 } hitcount: 2
+ { lat: 253, common_pid: 2036 } hitcount: 9
+ { lat: 253, common_pid: 2043 } hitcount: 6
+ { lat: 253, common_pid: 2040 } hitcount: 1
+ { lat: 254, common_pid: 2036 } hitcount: 8
+ { lat: 254, common_pid: 2043 } hitcount: 3
+ { lat: 254, common_pid: 2041 } hitcount: 1
+ { lat: 254, common_pid: 2042 } hitcount: 1
+ { lat: 254, common_pid: 2039 } hitcount: 1
+ { lat: 254, common_pid: 2037 } hitcount: 12
+ { lat: 255, common_pid: 2043 } hitcount: 1
+ { lat: 255, common_pid: 2037 } hitcount: 2
+ { lat: 255, common_pid: 2036 } hitcount: 2
+ { lat: 255, common_pid: 2039 } hitcount: 8
+ { lat: 256, common_pid: 2043 } hitcount: 1
+ { lat: 256, common_pid: 2036 } hitcount: 4
+ { lat: 256, common_pid: 2039 } hitcount: 6
+ { lat: 257, common_pid: 2039 } hitcount: 5
+ { lat: 257, common_pid: 2036 } hitcount: 4
+ { lat: 258, common_pid: 2039 } hitcount: 5
+ { lat: 258, common_pid: 2036 } hitcount: 2
+ { lat: 259, common_pid: 2036 } hitcount: 7
+ { lat: 259, common_pid: 2039 } hitcount: 7
+ { lat: 260, common_pid: 2036 } hitcount: 8
+ { lat: 260, common_pid: 2039 } hitcount: 6
+ { lat: 261, common_pid: 2036 } hitcount: 5
+ { lat: 261, common_pid: 2039 } hitcount: 7
+ { lat: 262, common_pid: 2039 } hitcount: 5
+ { lat: 262, common_pid: 2036 } hitcount: 5
+ { lat: 263, common_pid: 2039 } hitcount: 7
+ { lat: 263, common_pid: 2036 } hitcount: 7
+ { lat: 264, common_pid: 2039 } hitcount: 9
+ { lat: 264, common_pid: 2036 } hitcount: 9
+ { lat: 265, common_pid: 2036 } hitcount: 5
+ { lat: 265, common_pid: 2039 } hitcount: 1
+ { lat: 266, common_pid: 2036 } hitcount: 1
+ { lat: 266, common_pid: 2039 } hitcount: 3
+ { lat: 267, common_pid: 2036 } hitcount: 1
+ { lat: 267, common_pid: 2039 } hitcount: 3
+ { lat: 268, common_pid: 2036 } hitcount: 1
+ { lat: 268, common_pid: 2039 } hitcount: 6
+ { lat: 269, common_pid: 2036 } hitcount: 1
+ { lat: 269, common_pid: 2043 } hitcount: 1
+ { lat: 269, common_pid: 2039 } hitcount: 2
+ { lat: 270, common_pid: 2040 } hitcount: 1
+ { lat: 270, common_pid: 2039 } hitcount: 6
+ { lat: 271, common_pid: 2041 } hitcount: 1
+ { lat: 271, common_pid: 2039 } hitcount: 5
+ { lat: 272, common_pid: 2039 } hitcount: 10
+ { lat: 273, common_pid: 2039 } hitcount: 8
+ { lat: 274, common_pid: 2039 } hitcount: 2
+ { lat: 275, common_pid: 2039 } hitcount: 1
+ { lat: 276, common_pid: 2039 } hitcount: 2
+ { lat: 276, common_pid: 2037 } hitcount: 1
+ { lat: 276, common_pid: 2038 } hitcount: 1
+ { lat: 277, common_pid: 2039 } hitcount: 1
+ { lat: 277, common_pid: 2042 } hitcount: 1
+ { lat: 278, common_pid: 2039 } hitcount: 1
+ { lat: 279, common_pid: 2039 } hitcount: 4
+ { lat: 279, common_pid: 2043 } hitcount: 1
+ { lat: 280, common_pid: 2039 } hitcount: 3
+ { lat: 283, common_pid: 2036 } hitcount: 2
+ { lat: 284, common_pid: 2039 } hitcount: 1
+ { lat: 284, common_pid: 2043 } hitcount: 1
+ { lat: 288, common_pid: 2039 } hitcount: 1
+ { lat: 289, common_pid: 2039 } hitcount: 1
+ { lat: 300, common_pid: 2039 } hitcount: 1
+ { lat: 384, common_pid: 2039 } hitcount: 1
+
+ Totals:
+ Hits: 67625
+ Entries: 278
+ Dropped: 0
+
+Note, the writes are around the sleep, so ideally they will all be of 250
+microseconds. If you are wondering how there are several that are under
+250 microseconds, that is because the way cyclictest works, is if one
+iteration comes in late, the next one will set the timer to wake up less that
+250. That is, if an iteration came in 50 microseconds late, the next wake up
+will be at 200 microseconds.
+
+But this could easily be done in userspace. To make this even more
+interesting, we can mix the histogram between events that happened in the
+kernel with trace_marker::
+
+ # cd /sys/kernel/tracing
+ # echo 'latency u64 lat' > synthetic_events
+ # echo 'hist:keys=pid:ts0=common_timestamp.usecs' > events/sched/sched_waking/trigger
+ # echo 'hist:keys=common_pid:lat=common_timestamp.usecs-$ts0:onmatch(sched.sched_waking).latency($lat) if buf == "end"' > events/ftrace/print/trigger
+ # echo 'hist:keys=lat,common_pid:sort=lat' > events/synthetic/latency/trigger
+
+The difference this time is that instead of using the trace_marker to start
+the latency, the sched_waking event is used, matching the common_pid for the
+trace_marker write with the pid that is being woken by sched_waking.
+
+After running cyclictest again with the same parameters, we now have::
+
+ # cat events/synthetic/latency/hist
+ # event histogram
+ #
+ # trigger info: hist:keys=lat,common_pid:vals=hitcount:sort=lat:size=2048 [active]
+ #
+
+ { lat: 7, common_pid: 2302 } hitcount: 640
+ { lat: 7, common_pid: 2299 } hitcount: 42
+ { lat: 7, common_pid: 2303 } hitcount: 18
+ { lat: 7, common_pid: 2305 } hitcount: 166
+ { lat: 7, common_pid: 2306 } hitcount: 1
+ { lat: 7, common_pid: 2301 } hitcount: 91
+ { lat: 7, common_pid: 2300 } hitcount: 17
+ { lat: 8, common_pid: 2303 } hitcount: 8296
+ { lat: 8, common_pid: 2304 } hitcount: 6864
+ { lat: 8, common_pid: 2305 } hitcount: 9464
+ { lat: 8, common_pid: 2301 } hitcount: 9213
+ { lat: 8, common_pid: 2306 } hitcount: 6246
+ { lat: 8, common_pid: 2302 } hitcount: 8797
+ { lat: 8, common_pid: 2299 } hitcount: 8771
+ { lat: 8, common_pid: 2300 } hitcount: 8119
+ { lat: 9, common_pid: 2305 } hitcount: 1519
+ { lat: 9, common_pid: 2299 } hitcount: 2346
+ { lat: 9, common_pid: 2303 } hitcount: 2841
+ { lat: 9, common_pid: 2301 } hitcount: 1846
+ { lat: 9, common_pid: 2304 } hitcount: 3861
+ { lat: 9, common_pid: 2302 } hitcount: 1210
+ { lat: 9, common_pid: 2300 } hitcount: 2762
+ { lat: 9, common_pid: 2306 } hitcount: 4247
+ { lat: 10, common_pid: 2299 } hitcount: 16
+ { lat: 10, common_pid: 2306 } hitcount: 333
+ { lat: 10, common_pid: 2303 } hitcount: 16
+ { lat: 10, common_pid: 2304 } hitcount: 168
+ { lat: 10, common_pid: 2302 } hitcount: 240
+ { lat: 10, common_pid: 2301 } hitcount: 28
+ { lat: 10, common_pid: 2300 } hitcount: 95
+ { lat: 10, common_pid: 2305 } hitcount: 18
+ { lat: 11, common_pid: 2303 } hitcount: 5
+ { lat: 11, common_pid: 2305 } hitcount: 8
+ { lat: 11, common_pid: 2306 } hitcount: 221
+ { lat: 11, common_pid: 2302 } hitcount: 76
+ { lat: 11, common_pid: 2304 } hitcount: 26
+ { lat: 11, common_pid: 2300 } hitcount: 125
+ { lat: 11, common_pid: 2299 } hitcount: 2
+ { lat: 12, common_pid: 2305 } hitcount: 3
+ { lat: 12, common_pid: 2300 } hitcount: 6
+ { lat: 12, common_pid: 2306 } hitcount: 90
+ { lat: 12, common_pid: 2302 } hitcount: 4
+ { lat: 12, common_pid: 2303 } hitcount: 1
+ { lat: 12, common_pid: 2304 } hitcount: 122
+ { lat: 13, common_pid: 2300 } hitcount: 12
+ { lat: 13, common_pid: 2301 } hitcount: 1
+ { lat: 13, common_pid: 2306 } hitcount: 32
+ { lat: 13, common_pid: 2302 } hitcount: 5
+ { lat: 13, common_pid: 2305 } hitcount: 1
+ { lat: 13, common_pid: 2303 } hitcount: 1
+ { lat: 13, common_pid: 2304 } hitcount: 61
+ { lat: 14, common_pid: 2303 } hitcount: 4
+ { lat: 14, common_pid: 2306 } hitcount: 5
+ { lat: 14, common_pid: 2305 } hitcount: 4
+ { lat: 14, common_pid: 2304 } hitcount: 62
+ { lat: 14, common_pid: 2302 } hitcount: 19
+ { lat: 14, common_pid: 2300 } hitcount: 33
+ { lat: 14, common_pid: 2299 } hitcount: 1
+ { lat: 14, common_pid: 2301 } hitcount: 4
+ { lat: 15, common_pid: 2305 } hitcount: 1
+ { lat: 15, common_pid: 2302 } hitcount: 25
+ { lat: 15, common_pid: 2300 } hitcount: 11
+ { lat: 15, common_pid: 2299 } hitcount: 5
+ { lat: 15, common_pid: 2301 } hitcount: 1
+ { lat: 15, common_pid: 2304 } hitcount: 8
+ { lat: 15, common_pid: 2303 } hitcount: 1
+ { lat: 15, common_pid: 2306 } hitcount: 6
+ { lat: 16, common_pid: 2302 } hitcount: 31
+ { lat: 16, common_pid: 2306 } hitcount: 3
+ { lat: 16, common_pid: 2300 } hitcount: 5
+ { lat: 17, common_pid: 2302 } hitcount: 6
+ { lat: 17, common_pid: 2303 } hitcount: 1
+ { lat: 18, common_pid: 2304 } hitcount: 1
+ { lat: 18, common_pid: 2302 } hitcount: 8
+ { lat: 18, common_pid: 2299 } hitcount: 1
+ { lat: 18, common_pid: 2301 } hitcount: 1
+ { lat: 19, common_pid: 2303 } hitcount: 4
+ { lat: 19, common_pid: 2304 } hitcount: 5
+ { lat: 19, common_pid: 2302 } hitcount: 4
+ { lat: 19, common_pid: 2299 } hitcount: 3
+ { lat: 19, common_pid: 2306 } hitcount: 1
+ { lat: 19, common_pid: 2300 } hitcount: 4
+ { lat: 19, common_pid: 2305 } hitcount: 5
+ { lat: 20, common_pid: 2299 } hitcount: 2
+ { lat: 20, common_pid: 2302 } hitcount: 3
+ { lat: 20, common_pid: 2305 } hitcount: 1
+ { lat: 20, common_pid: 2300 } hitcount: 2
+ { lat: 20, common_pid: 2301 } hitcount: 2
+ { lat: 20, common_pid: 2303 } hitcount: 3
+ { lat: 21, common_pid: 2305 } hitcount: 1
+ { lat: 21, common_pid: 2299 } hitcount: 5
+ { lat: 21, common_pid: 2303 } hitcount: 4
+ { lat: 21, common_pid: 2302 } hitcount: 7
+ { lat: 21, common_pid: 2300 } hitcount: 1
+ { lat: 21, common_pid: 2301 } hitcount: 5
+ { lat: 21, common_pid: 2304 } hitcount: 2
+ { lat: 22, common_pid: 2302 } hitcount: 5
+ { lat: 22, common_pid: 2303 } hitcount: 1
+ { lat: 22, common_pid: 2306 } hitcount: 3
+ { lat: 22, common_pid: 2301 } hitcount: 2
+ { lat: 22, common_pid: 2300 } hitcount: 1
+ { lat: 22, common_pid: 2299 } hitcount: 1
+ { lat: 22, common_pid: 2305 } hitcount: 1
+ { lat: 22, common_pid: 2304 } hitcount: 1
+ { lat: 23, common_pid: 2299 } hitcount: 1
+ { lat: 23, common_pid: 2306 } hitcount: 2
+ { lat: 23, common_pid: 2302 } hitcount: 6
+ { lat: 24, common_pid: 2302 } hitcount: 3
+ { lat: 24, common_pid: 2300 } hitcount: 1
+ { lat: 24, common_pid: 2306 } hitcount: 2
+ { lat: 24, common_pid: 2305 } hitcount: 1
+ { lat: 24, common_pid: 2299 } hitcount: 1
+ { lat: 25, common_pid: 2300 } hitcount: 1
+ { lat: 25, common_pid: 2302 } hitcount: 4
+ { lat: 26, common_pid: 2302 } hitcount: 2
+ { lat: 27, common_pid: 2305 } hitcount: 1
+ { lat: 27, common_pid: 2300 } hitcount: 1
+ { lat: 27, common_pid: 2302 } hitcount: 3
+ { lat: 28, common_pid: 2306 } hitcount: 1
+ { lat: 28, common_pid: 2302 } hitcount: 4
+ { lat: 29, common_pid: 2302 } hitcount: 1
+ { lat: 29, common_pid: 2300 } hitcount: 2
+ { lat: 29, common_pid: 2306 } hitcount: 1
+ { lat: 29, common_pid: 2304 } hitcount: 1
+ { lat: 30, common_pid: 2302 } hitcount: 4
+ { lat: 31, common_pid: 2302 } hitcount: 6
+ { lat: 32, common_pid: 2302 } hitcount: 1
+ { lat: 33, common_pid: 2299 } hitcount: 1
+ { lat: 33, common_pid: 2302 } hitcount: 3
+ { lat: 34, common_pid: 2302 } hitcount: 2
+ { lat: 35, common_pid: 2302 } hitcount: 1
+ { lat: 35, common_pid: 2304 } hitcount: 1
+ { lat: 36, common_pid: 2302 } hitcount: 4
+ { lat: 37, common_pid: 2302 } hitcount: 6
+ { lat: 38, common_pid: 2302 } hitcount: 2
+ { lat: 39, common_pid: 2302 } hitcount: 2
+ { lat: 39, common_pid: 2304 } hitcount: 1
+ { lat: 40, common_pid: 2304 } hitcount: 2
+ { lat: 40, common_pid: 2302 } hitcount: 5
+ { lat: 41, common_pid: 2304 } hitcount: 1
+ { lat: 41, common_pid: 2302 } hitcount: 8
+ { lat: 42, common_pid: 2302 } hitcount: 6
+ { lat: 42, common_pid: 2304 } hitcount: 1
+ { lat: 43, common_pid: 2302 } hitcount: 3
+ { lat: 43, common_pid: 2304 } hitcount: 4
+ { lat: 44, common_pid: 2302 } hitcount: 6
+ { lat: 45, common_pid: 2302 } hitcount: 5
+ { lat: 46, common_pid: 2302 } hitcount: 5
+ { lat: 47, common_pid: 2302 } hitcount: 7
+ { lat: 48, common_pid: 2301 } hitcount: 1
+ { lat: 48, common_pid: 2302 } hitcount: 9
+ { lat: 49, common_pid: 2302 } hitcount: 3
+ { lat: 50, common_pid: 2302 } hitcount: 1
+ { lat: 50, common_pid: 2301 } hitcount: 1
+ { lat: 51, common_pid: 2302 } hitcount: 2
+ { lat: 51, common_pid: 2301 } hitcount: 1
+ { lat: 61, common_pid: 2302 } hitcount: 1
+ { lat: 110, common_pid: 2302 } hitcount: 1
+
+ Totals:
+ Hits: 89565
+ Entries: 158
+ Dropped: 0
+
+This doesn't tell us any information about how late cyclictest may have
+woken up, but it does show us a nice histogram of how long it took from
+the time that cyclictest was woken to the time it made it into user space.
diff --git a/Documentation/trace/hwlat_detector.rst b/Documentation/trace/hwlat_detector.rst
new file mode 100644
index 000000000..de94b499b
--- /dev/null
+++ b/Documentation/trace/hwlat_detector.rst
@@ -0,0 +1,88 @@
+=========================
+Hardware Latency Detector
+=========================
+
+Introduction
+-------------
+
+The tracer hwlat_detector is a special purpose tracer that is used to
+detect large system latencies induced by the behavior of certain underlying
+hardware or firmware, independent of Linux itself. The code was developed
+originally to detect SMIs (System Management Interrupts) on x86 systems,
+however there is nothing x86 specific about this patchset. It was
+originally written for use by the "RT" patch since the Real Time
+kernel is highly latency sensitive.
+
+SMIs are not serviced by the Linux kernel, which means that it does not
+even know that they are occuring. SMIs are instead set up by BIOS code
+and are serviced by BIOS code, usually for "critical" events such as
+management of thermal sensors and fans. Sometimes though, SMIs are used for
+other tasks and those tasks can spend an inordinate amount of time in the
+handler (sometimes measured in milliseconds). Obviously this is a problem if
+you are trying to keep event service latencies down in the microsecond range.
+
+The hardware latency detector works by hogging one of the cpus for configurable
+amounts of time (with interrupts disabled), polling the CPU Time Stamp Counter
+for some period, then looking for gaps in the TSC data. Any gap indicates a
+time when the polling was interrupted and since the interrupts are disabled,
+the only thing that could do that would be an SMI or other hardware hiccup
+(or an NMI, but those can be tracked).
+
+Note that the hwlat detector should *NEVER* be used in a production environment.
+It is intended to be run manually to determine if the hardware platform has a
+problem with long system firmware service routines.
+
+Usage
+------
+
+Write the ASCII text "hwlat" into the current_tracer file of the tracing system
+(mounted at /sys/kernel/tracing or /sys/kernel/tracing). It is possible to
+redefine the threshold in microseconds (us) above which latency spikes will
+be taken into account.
+
+Example::
+
+ # echo hwlat > /sys/kernel/tracing/current_tracer
+ # echo 100 > /sys/kernel/tracing/tracing_thresh
+
+The /sys/kernel/tracing/hwlat_detector interface contains the following files:
+
+ - width - time period to sample with CPUs held (usecs)
+ must be less than the total window size (enforced)
+ - window - total period of sampling, width being inside (usecs)
+
+By default the width is set to 500,000 and window to 1,000,000, meaning that
+for every 1,000,000 usecs (1s) the hwlat detector will spin for 500,000 usecs
+(0.5s). If tracing_thresh contains zero when hwlat tracer is enabled, it will
+change to a default of 10 usecs. If any latencies that exceed the threshold is
+observed then the data will be written to the tracing ring buffer.
+
+The minimum sleep time between periods is 1 millisecond. Even if width
+is less than 1 millisecond apart from window, to allow the system to not
+be totally starved.
+
+If tracing_thresh was zero when hwlat detector was started, it will be set
+back to zero if another tracer is loaded. Note, the last value in
+tracing_thresh that hwlat detector had will be saved and this value will
+be restored in tracing_thresh if it is still zero when hwlat detector is
+started again.
+
+The following tracing directory files are used by the hwlat_detector:
+
+in /sys/kernel/tracing:
+
+ - tracing_threshold - minimum latency value to be considered (usecs)
+ - tracing_max_latency - maximum hardware latency actually observed (usecs)
+ - tracing_cpumask - the CPUs to move the hwlat thread across
+ - hwlat_detector/width - specified amount of time to spin within window (usecs)
+ - hwlat_detector/window - amount of time between (width) runs (usecs)
+ - hwlat_detector/mode - the thread mode
+
+By default, one hwlat detector's kernel thread will migrate across each CPU
+specified in cpumask at the beginning of a new window, in a round-robin
+fashion. This behavior can be changed by changing the thread mode,
+the available options are:
+
+ - none: do not force migration
+ - round-robin: migrate across each CPU specified in cpumask [default]
+ - per-cpu: create one thread for each cpu in tracing_cpumask
diff --git a/Documentation/trace/index.rst b/Documentation/trace/index.rst
new file mode 100644
index 000000000..ea25a9220
--- /dev/null
+++ b/Documentation/trace/index.rst
@@ -0,0 +1,36 @@
+==========================
+Linux Tracing Technologies
+==========================
+
+.. toctree::
+ :maxdepth: 2
+
+ ftrace-design
+ tracepoint-analysis
+ ftrace
+ ftrace-uses
+ fprobe
+ kprobes
+ kprobetrace
+ uprobetracer
+ tracepoints
+ events
+ events-kmem
+ events-power
+ events-nmi
+ events-msr
+ mmiotrace
+ histogram
+ histogram-design
+ boottime-trace
+ hwlat_detector
+ osnoise-tracer
+ timerlat-tracer
+ intel_th
+ ring-buffer-design
+ stm
+ sys-t
+ coresight/index
+ user_events
+ rv/index
+ hisi-ptt
diff --git a/Documentation/trace/intel_th.rst b/Documentation/trace/intel_th.rst
new file mode 100644
index 000000000..b31818d5f
--- /dev/null
+++ b/Documentation/trace/intel_th.rst
@@ -0,0 +1,150 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+=======================
+Intel(R) Trace Hub (TH)
+=======================
+
+Overview
+--------
+
+Intel(R) Trace Hub (TH) is a set of hardware blocks that produce,
+switch and output trace data from multiple hardware and software
+sources over several types of trace output ports encoded in System
+Trace Protocol (MIPI STPv2) and is intended to perform full system
+debugging. For more information on the hardware, see Intel(R) Trace
+Hub developer's manual [1].
+
+It consists of trace sources, trace destinations (outputs) and a
+switch (Global Trace Hub, GTH). These devices are placed on a bus of
+their own ("intel_th"), where they can be discovered and configured
+via sysfs attributes.
+
+Currently, the following Intel TH subdevices (blocks) are supported:
+ - Software Trace Hub (STH), trace source, which is a System Trace
+ Module (STM) device,
+ - Memory Storage Unit (MSU), trace output, which allows storing
+ trace hub output in system memory,
+ - Parallel Trace Interface output (PTI), trace output to an external
+ debug host via a PTI port,
+ - Global Trace Hub (GTH), which is a switch and a central component
+ of Intel(R) Trace Hub architecture.
+
+Common attributes for output devices are described in
+Documentation/ABI/testing/sysfs-bus-intel_th-output-devices, the most
+notable of them is "active", which enables or disables trace output
+into that particular output device.
+
+GTH allows directing different STP masters into different output ports
+via its "masters" attribute group. More detailed GTH interface
+description is at Documentation/ABI/testing/sysfs-bus-intel_th-devices-gth.
+
+STH registers an stm class device, through which it provides interface
+to userspace and kernelspace software trace sources. See
+Documentation/trace/stm.rst for more information on that.
+
+MSU can be configured to collect trace data into a system memory
+buffer, which can later on be read from its device nodes via read() or
+mmap() interface and directed to a "software sink" driver that will
+consume the data and/or relay it further.
+
+On the whole, Intel(R) Trace Hub does not require any special
+userspace software to function; everything can be configured, started
+and collected via sysfs attributes, and device nodes.
+
+[1] https://software.intel.com/sites/default/files/managed/d3/3c/intel-th-developer-manual.pdf
+
+Bus and Subdevices
+------------------
+
+For each Intel TH device in the system a bus of its own is
+created and assigned an id number that reflects the order in which TH
+devices were enumerated. All TH subdevices (devices on intel_th bus)
+begin with this id: 0-gth, 0-msc0, 0-msc1, 0-pti, 0-sth, which is
+followed by device's name and an optional index.
+
+Output devices also get a device node in /dev/intel_thN, where N is
+the Intel TH device id. For example, MSU's memory buffers, when
+allocated, are accessible via /dev/intel_th0/msc{0,1}.
+
+Quick example
+-------------
+
+# figure out which GTH port is the first memory controller::
+
+ $ cat /sys/bus/intel_th/devices/0-msc0/port
+ 0
+
+# looks like it's port 0, configure master 33 to send data to port 0::
+
+ $ echo 0 > /sys/bus/intel_th/devices/0-gth/masters/33
+
+# allocate a 2-windowed multiblock buffer on the first memory
+# controller, each with 64 pages::
+
+ $ echo multi > /sys/bus/intel_th/devices/0-msc0/mode
+ $ echo 64,64 > /sys/bus/intel_th/devices/0-msc0/nr_pages
+
+# enable wrapping for this controller, too::
+
+ $ echo 1 > /sys/bus/intel_th/devices/0-msc0/wrap
+
+# and enable tracing into this port::
+
+ $ echo 1 > /sys/bus/intel_th/devices/0-msc0/active
+
+# .. send data to master 33, see stm.txt for more details ..
+# .. wait for traces to pile up ..
+# .. and stop the trace::
+
+ $ echo 0 > /sys/bus/intel_th/devices/0-msc0/active
+
+# and now you can collect the trace from the device node::
+
+ $ cat /dev/intel_th0/msc0 > my_stp_trace
+
+Host Debugger Mode
+------------------
+
+It is possible to configure the Trace Hub and control its trace
+capture from a remote debug host, which should be connected via one of
+the hardware debugging interfaces, which will then be used to both
+control Intel Trace Hub and transfer its trace data to the debug host.
+
+The driver needs to be told that such an arrangement is taking place
+so that it does not touch any capture/port configuration and avoids
+conflicting with the debug host's configuration accesses. The only
+activity that the driver will perform in this mode is collecting
+software traces to the Software Trace Hub (an stm class device). The
+user is still responsible for setting up adequate master/channel
+mappings that the decoder on the receiving end would recognize.
+
+In order to enable the host mode, set the 'host_mode' parameter of the
+'intel_th' kernel module to 'y'. None of the virtual output devices
+will show up on the intel_th bus. Also, trace configuration and
+capture controlling attribute groups of the 'gth' device will not be
+exposed. The 'sth' device will operate as usual.
+
+Software Sinks
+--------------
+
+The Memory Storage Unit (MSU) driver provides an in-kernel API for
+drivers to register themselves as software sinks for the trace data.
+Such drivers can further export the data via other devices, such as
+USB device controllers or network cards.
+
+The API has two main parts::
+ - notifying the software sink that a particular window is full, and
+ "locking" that window, that is, making it unavailable for the trace
+ collection; when this happens, the MSU driver will automatically
+ switch to the next window in the buffer if it is unlocked, or stop
+ the trace capture if it's not;
+ - tracking the "locked" state of windows and providing a way for the
+ software sink driver to notify the MSU driver when a window is
+ unlocked and can be used again to collect trace data.
+
+An example sink driver, msu-sink illustrates the implementation of a
+software sink. Functionally, it simply unlocks windows as soon as they
+are full, keeping the MSU running in a circular buffer mode. Unlike the
+"multi" mode, it will fill out all the windows in the buffer as opposed
+to just the first one. It can be enabled by writing "sink" to the "mode"
+file (assuming msu-sink.ko is loaded).
diff --git a/Documentation/trace/kprobes.rst b/Documentation/trace/kprobes.rst
new file mode 100644
index 000000000..fc7ce76ea
--- /dev/null
+++ b/Documentation/trace/kprobes.rst
@@ -0,0 +1,788 @@
+=======================
+Kernel Probes (Kprobes)
+=======================
+
+:Author: Jim Keniston <jkenisto@us.ibm.com>
+:Author: Prasanna S Panchamukhi <prasanna.panchamukhi@gmail.com>
+:Author: Masami Hiramatsu <mhiramat@redhat.com>
+
+.. CONTENTS
+
+ 1. Concepts: Kprobes, and Return Probes
+ 2. Architectures Supported
+ 3. Configuring Kprobes
+ 4. API Reference
+ 5. Kprobes Features and Limitations
+ 6. Probe Overhead
+ 7. TODO
+ 8. Kprobes Example
+ 9. Kretprobes Example
+ 10. Deprecated Features
+ Appendix A: The kprobes debugfs interface
+ Appendix B: The kprobes sysctl interface
+ Appendix C: References
+
+Concepts: Kprobes and Return Probes
+=========================================
+
+Kprobes enables you to dynamically break into any kernel routine and
+collect debugging and performance information non-disruptively. You
+can trap at almost any kernel code address [1]_, specifying a handler
+routine to be invoked when the breakpoint is hit.
+
+.. [1] some parts of the kernel code can not be trapped, see
+ :ref:`kprobes_blacklist`)
+
+There are currently two types of probes: kprobes, and kretprobes
+(also called return probes). A kprobe can be inserted on virtually
+any instruction in the kernel. A return probe fires when a specified
+function returns.
+
+In the typical case, Kprobes-based instrumentation is packaged as
+a kernel module. The module's init function installs ("registers")
+one or more probes, and the exit function unregisters them. A
+registration function such as register_kprobe() specifies where
+the probe is to be inserted and what handler is to be called when
+the probe is hit.
+
+There are also ``register_/unregister_*probes()`` functions for batch
+registration/unregistration of a group of ``*probes``. These functions
+can speed up unregistration process when you have to unregister
+a lot of probes at once.
+
+The next four subsections explain how the different types of
+probes work and how jump optimization works. They explain certain
+things that you'll need to know in order to make the best use of
+Kprobes -- e.g., the difference between a pre_handler and
+a post_handler, and how to use the maxactive and nmissed fields of
+a kretprobe. But if you're in a hurry to start using Kprobes, you
+can skip ahead to :ref:`kprobes_archs_supported`.
+
+How Does a Kprobe Work?
+-----------------------
+
+When a kprobe is registered, Kprobes makes a copy of the probed
+instruction and replaces the first byte(s) of the probed instruction
+with a breakpoint instruction (e.g., int3 on i386 and x86_64).
+
+When a CPU hits the breakpoint instruction, a trap occurs, the CPU's
+registers are saved, and control passes to Kprobes via the
+notifier_call_chain mechanism. Kprobes executes the "pre_handler"
+associated with the kprobe, passing the handler the addresses of the
+kprobe struct and the saved registers.
+
+Next, Kprobes single-steps its copy of the probed instruction.
+(It would be simpler to single-step the actual instruction in place,
+but then Kprobes would have to temporarily remove the breakpoint
+instruction. This would open a small time window when another CPU
+could sail right past the probepoint.)
+
+After the instruction is single-stepped, Kprobes executes the
+"post_handler," if any, that is associated with the kprobe.
+Execution then continues with the instruction following the probepoint.
+
+Changing Execution Path
+-----------------------
+
+Since kprobes can probe into a running kernel code, it can change the
+register set, including instruction pointer. This operation requires
+maximum care, such as keeping the stack frame, recovering the execution
+path etc. Since it operates on a running kernel and needs deep knowledge
+of computer architecture and concurrent computing, you can easily shoot
+your foot.
+
+If you change the instruction pointer (and set up other related
+registers) in pre_handler, you must return !0 so that kprobes stops
+single stepping and just returns to the given address.
+This also means post_handler should not be called anymore.
+
+Note that this operation may be harder on some architectures which use
+TOC (Table of Contents) for function call, since you have to setup a new
+TOC for your function in your module, and recover the old one after
+returning from it.
+
+Return Probes
+-------------
+
+How Does a Return Probe Work?
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+
+When you call register_kretprobe(), Kprobes establishes a kprobe at
+the entry to the function. When the probed function is called and this
+probe is hit, Kprobes saves a copy of the return address, and replaces
+the return address with the address of a "trampoline." The trampoline
+is an arbitrary piece of code -- typically just a nop instruction.
+At boot time, Kprobes registers a kprobe at the trampoline.
+
+When the probed function executes its return instruction, control
+passes to the trampoline and that probe is hit. Kprobes' trampoline
+handler calls the user-specified return handler associated with the
+kretprobe, then sets the saved instruction pointer to the saved return
+address, and that's where execution resumes upon return from the trap.
+
+While the probed function is executing, its return address is
+stored in an object of type kretprobe_instance. Before calling
+register_kretprobe(), the user sets the maxactive field of the
+kretprobe struct to specify how many instances of the specified
+function can be probed simultaneously. register_kretprobe()
+pre-allocates the indicated number of kretprobe_instance objects.
+
+For example, if the function is non-recursive and is called with a
+spinlock held, maxactive = 1 should be enough. If the function is
+non-recursive and can never relinquish the CPU (e.g., via a semaphore
+or preemption), NR_CPUS should be enough. If maxactive <= 0, it is
+set to a default value: max(10, 2*NR_CPUS).
+
+It's not a disaster if you set maxactive too low; you'll just miss
+some probes. In the kretprobe struct, the nmissed field is set to
+zero when the return probe is registered, and is incremented every
+time the probed function is entered but there is no kretprobe_instance
+object available for establishing the return probe.
+
+Kretprobe entry-handler
+^^^^^^^^^^^^^^^^^^^^^^^
+
+Kretprobes also provides an optional user-specified handler which runs
+on function entry. This handler is specified by setting the entry_handler
+field of the kretprobe struct. Whenever the kprobe placed by kretprobe at the
+function entry is hit, the user-defined entry_handler, if any, is invoked.
+If the entry_handler returns 0 (success) then a corresponding return handler
+is guaranteed to be called upon function return. If the entry_handler
+returns a non-zero error then Kprobes leaves the return address as is, and
+the kretprobe has no further effect for that particular function instance.
+
+Multiple entry and return handler invocations are matched using the unique
+kretprobe_instance object associated with them. Additionally, a user
+may also specify per return-instance private data to be part of each
+kretprobe_instance object. This is especially useful when sharing private
+data between corresponding user entry and return handlers. The size of each
+private data object can be specified at kretprobe registration time by
+setting the data_size field of the kretprobe struct. This data can be
+accessed through the data field of each kretprobe_instance object.
+
+In case probed function is entered but there is no kretprobe_instance
+object available, then in addition to incrementing the nmissed count,
+the user entry_handler invocation is also skipped.
+
+.. _kprobes_jump_optimization:
+
+How Does Jump Optimization Work?
+--------------------------------
+
+If your kernel is built with CONFIG_OPTPROBES=y (currently this flag
+is automatically set 'y' on x86/x86-64, non-preemptive kernel) and
+the "debug.kprobes_optimization" kernel parameter is set to 1 (see
+sysctl(8)), Kprobes tries to reduce probe-hit overhead by using a jump
+instruction instead of a breakpoint instruction at each probepoint.
+
+Init a Kprobe
+^^^^^^^^^^^^^
+
+When a probe is registered, before attempting this optimization,
+Kprobes inserts an ordinary, breakpoint-based kprobe at the specified
+address. So, even if it's not possible to optimize this particular
+probepoint, there'll be a probe there.
+
+Safety Check
+^^^^^^^^^^^^
+
+Before optimizing a probe, Kprobes performs the following safety checks:
+
+- Kprobes verifies that the region that will be replaced by the jump
+ instruction (the "optimized region") lies entirely within one function.
+ (A jump instruction is multiple bytes, and so may overlay multiple
+ instructions.)
+
+- Kprobes analyzes the entire function and verifies that there is no
+ jump into the optimized region. Specifically:
+
+ - the function contains no indirect jump;
+ - the function contains no instruction that causes an exception (since
+ the fixup code triggered by the exception could jump back into the
+ optimized region -- Kprobes checks the exception tables to verify this);
+ - there is no near jump to the optimized region (other than to the first
+ byte).
+
+- For each instruction in the optimized region, Kprobes verifies that
+ the instruction can be executed out of line.
+
+Preparing Detour Buffer
+^^^^^^^^^^^^^^^^^^^^^^^
+
+Next, Kprobes prepares a "detour" buffer, which contains the following
+instruction sequence:
+
+- code to push the CPU's registers (emulating a breakpoint trap)
+- a call to the trampoline code which calls user's probe handlers.
+- code to restore registers
+- the instructions from the optimized region
+- a jump back to the original execution path.
+
+Pre-optimization
+^^^^^^^^^^^^^^^^
+
+After preparing the detour buffer, Kprobes verifies that none of the
+following situations exist:
+
+- The probe has a post_handler.
+- Other instructions in the optimized region are probed.
+- The probe is disabled.
+
+In any of the above cases, Kprobes won't start optimizing the probe.
+Since these are temporary situations, Kprobes tries to start
+optimizing it again if the situation is changed.
+
+If the kprobe can be optimized, Kprobes enqueues the kprobe to an
+optimizing list, and kicks the kprobe-optimizer workqueue to optimize
+it. If the to-be-optimized probepoint is hit before being optimized,
+Kprobes returns control to the original instruction path by setting
+the CPU's instruction pointer to the copied code in the detour buffer
+-- thus at least avoiding the single-step.
+
+Optimization
+^^^^^^^^^^^^
+
+The Kprobe-optimizer doesn't insert the jump instruction immediately;
+rather, it calls synchronize_rcu() for safety first, because it's
+possible for a CPU to be interrupted in the middle of executing the
+optimized region [3]_. As you know, synchronize_rcu() can ensure
+that all interruptions that were active when synchronize_rcu()
+was called are done, but only if CONFIG_PREEMPT=n. So, this version
+of kprobe optimization supports only kernels with CONFIG_PREEMPT=n [4]_.
+
+After that, the Kprobe-optimizer calls stop_machine() to replace
+the optimized region with a jump instruction to the detour buffer,
+using text_poke_smp().
+
+Unoptimization
+^^^^^^^^^^^^^^
+
+When an optimized kprobe is unregistered, disabled, or blocked by
+another kprobe, it will be unoptimized. If this happens before
+the optimization is complete, the kprobe is just dequeued from the
+optimized list. If the optimization has been done, the jump is
+replaced with the original code (except for an int3 breakpoint in
+the first byte) by using text_poke_smp().
+
+.. [3] Please imagine that the 2nd instruction is interrupted and then
+ the optimizer replaces the 2nd instruction with the jump *address*
+ while the interrupt handler is running. When the interrupt
+ returns to original address, there is no valid instruction,
+ and it causes an unexpected result.
+
+.. [4] This optimization-safety checking may be replaced with the
+ stop-machine method that ksplice uses for supporting a CONFIG_PREEMPT=y
+ kernel.
+
+NOTE for geeks:
+The jump optimization changes the kprobe's pre_handler behavior.
+Without optimization, the pre_handler can change the kernel's execution
+path by changing regs->ip and returning 1. However, when the probe
+is optimized, that modification is ignored. Thus, if you want to
+tweak the kernel's execution path, you need to suppress optimization,
+using one of the following techniques:
+
+- Specify an empty function for the kprobe's post_handler.
+
+or
+
+- Execute 'sysctl -w debug.kprobes_optimization=n'
+
+.. _kprobes_blacklist:
+
+Blacklist
+---------
+
+Kprobes can probe most of the kernel except itself. This means
+that there are some functions where kprobes cannot probe. Probing
+(trapping) such functions can cause a recursive trap (e.g. double
+fault) or the nested probe handler may never be called.
+Kprobes manages such functions as a blacklist.
+If you want to add a function into the blacklist, you just need
+to (1) include linux/kprobes.h and (2) use NOKPROBE_SYMBOL() macro
+to specify a blacklisted function.
+Kprobes checks the given probe address against the blacklist and
+rejects registering it, if the given address is in the blacklist.
+
+.. _kprobes_archs_supported:
+
+Architectures Supported
+=======================
+
+Kprobes and return probes are implemented on the following
+architectures:
+
+- i386 (Supports jump optimization)
+- x86_64 (AMD-64, EM64T) (Supports jump optimization)
+- ppc64
+- ia64 (Does not support probes on instruction slot1.)
+- sparc64 (Return probes not yet implemented.)
+- arm
+- ppc
+- mips
+- s390
+- parisc
+
+Configuring Kprobes
+===================
+
+When configuring the kernel using make menuconfig/xconfig/oldconfig,
+ensure that CONFIG_KPROBES is set to "y", look for "Kprobes" under
+"General architecture-dependent options".
+
+So that you can load and unload Kprobes-based instrumentation modules,
+make sure "Loadable module support" (CONFIG_MODULES) and "Module
+unloading" (CONFIG_MODULE_UNLOAD) are set to "y".
+
+Also make sure that CONFIG_KALLSYMS and perhaps even CONFIG_KALLSYMS_ALL
+are set to "y", since kallsyms_lookup_name() is used by the in-kernel
+kprobe address resolution code.
+
+If you need to insert a probe in the middle of a function, you may find
+it useful to "Compile the kernel with debug info" (CONFIG_DEBUG_INFO),
+so you can use "objdump -d -l vmlinux" to see the source-to-object
+code mapping.
+
+API Reference
+=============
+
+The Kprobes API includes a "register" function and an "unregister"
+function for each type of probe. The API also includes "register_*probes"
+and "unregister_*probes" functions for (un)registering arrays of probes.
+Here are terse, mini-man-page specifications for these functions and
+the associated probe handlers that you'll write. See the files in the
+samples/kprobes/ sub-directory for examples.
+
+register_kprobe
+---------------
+
+::
+
+ #include <linux/kprobes.h>
+ int register_kprobe(struct kprobe *kp);
+
+Sets a breakpoint at the address kp->addr. When the breakpoint is hit, Kprobes
+calls kp->pre_handler. After the probed instruction is single-stepped, Kprobe
+calls kp->post_handler. Any or all handlers can be NULL. If kp->flags is set
+KPROBE_FLAG_DISABLED, that kp will be registered but disabled, so, its handlers
+aren't hit until calling enable_kprobe(kp).
+
+.. note::
+
+ 1. With the introduction of the "symbol_name" field to struct kprobe,
+ the probepoint address resolution will now be taken care of by the kernel.
+ The following will now work::
+
+ kp.symbol_name = "symbol_name";
+
+ (64-bit powerpc intricacies such as function descriptors are handled
+ transparently)
+
+ 2. Use the "offset" field of struct kprobe if the offset into the symbol
+ to install a probepoint is known. This field is used to calculate the
+ probepoint.
+
+ 3. Specify either the kprobe "symbol_name" OR the "addr". If both are
+ specified, kprobe registration will fail with -EINVAL.
+
+ 4. With CISC architectures (such as i386 and x86_64), the kprobes code
+ does not validate if the kprobe.addr is at an instruction boundary.
+ Use "offset" with caution.
+
+register_kprobe() returns 0 on success, or a negative errno otherwise.
+
+User's pre-handler (kp->pre_handler)::
+
+ #include <linux/kprobes.h>
+ #include <linux/ptrace.h>
+ int pre_handler(struct kprobe *p, struct pt_regs *regs);
+
+Called with p pointing to the kprobe associated with the breakpoint,
+and regs pointing to the struct containing the registers saved when
+the breakpoint was hit. Return 0 here unless you're a Kprobes geek.
+
+User's post-handler (kp->post_handler)::
+
+ #include <linux/kprobes.h>
+ #include <linux/ptrace.h>
+ void post_handler(struct kprobe *p, struct pt_regs *regs,
+ unsigned long flags);
+
+p and regs are as described for the pre_handler. flags always seems
+to be zero.
+
+register_kretprobe
+------------------
+
+::
+
+ #include <linux/kprobes.h>
+ int register_kretprobe(struct kretprobe *rp);
+
+Establishes a return probe for the function whose address is
+rp->kp.addr. When that function returns, Kprobes calls rp->handler.
+You must set rp->maxactive appropriately before you call
+register_kretprobe(); see "How Does a Return Probe Work?" for details.
+
+register_kretprobe() returns 0 on success, or a negative errno
+otherwise.
+
+User's return-probe handler (rp->handler)::
+
+ #include <linux/kprobes.h>
+ #include <linux/ptrace.h>
+ int kretprobe_handler(struct kretprobe_instance *ri,
+ struct pt_regs *regs);
+
+regs is as described for kprobe.pre_handler. ri points to the
+kretprobe_instance object, of which the following fields may be
+of interest:
+
+- ret_addr: the return address
+- rp: points to the corresponding kretprobe object
+- task: points to the corresponding task struct
+- data: points to per return-instance private data; see "Kretprobe
+ entry-handler" for details.
+
+The regs_return_value(regs) macro provides a simple abstraction to
+extract the return value from the appropriate register as defined by
+the architecture's ABI.
+
+The handler's return value is currently ignored.
+
+unregister_*probe
+------------------
+
+::
+
+ #include <linux/kprobes.h>
+ void unregister_kprobe(struct kprobe *kp);
+ void unregister_kretprobe(struct kretprobe *rp);
+
+Removes the specified probe. The unregister function can be called
+at any time after the probe has been registered.
+
+.. note::
+
+ If the functions find an incorrect probe (ex. an unregistered probe),
+ they clear the addr field of the probe.
+
+register_*probes
+----------------
+
+::
+
+ #include <linux/kprobes.h>
+ int register_kprobes(struct kprobe **kps, int num);
+ int register_kretprobes(struct kretprobe **rps, int num);
+
+Registers each of the num probes in the specified array. If any
+error occurs during registration, all probes in the array, up to
+the bad probe, are safely unregistered before the register_*probes
+function returns.
+
+- kps/rps: an array of pointers to ``*probe`` data structures
+- num: the number of the array entries.
+
+.. note::
+
+ You have to allocate(or define) an array of pointers and set all
+ of the array entries before using these functions.
+
+unregister_*probes
+------------------
+
+::
+
+ #include <linux/kprobes.h>
+ void unregister_kprobes(struct kprobe **kps, int num);
+ void unregister_kretprobes(struct kretprobe **rps, int num);
+
+Removes each of the num probes in the specified array at once.
+
+.. note::
+
+ If the functions find some incorrect probes (ex. unregistered
+ probes) in the specified array, they clear the addr field of those
+ incorrect probes. However, other probes in the array are
+ unregistered correctly.
+
+disable_*probe
+--------------
+
+::
+
+ #include <linux/kprobes.h>
+ int disable_kprobe(struct kprobe *kp);
+ int disable_kretprobe(struct kretprobe *rp);
+
+Temporarily disables the specified ``*probe``. You can enable it again by using
+enable_*probe(). You must specify the probe which has been registered.
+
+enable_*probe
+-------------
+
+::
+
+ #include <linux/kprobes.h>
+ int enable_kprobe(struct kprobe *kp);
+ int enable_kretprobe(struct kretprobe *rp);
+
+Enables ``*probe`` which has been disabled by disable_*probe(). You must specify
+the probe which has been registered.
+
+Kprobes Features and Limitations
+================================
+
+Kprobes allows multiple probes at the same address. Also,
+a probepoint for which there is a post_handler cannot be optimized.
+So if you install a kprobe with a post_handler, at an optimized
+probepoint, the probepoint will be unoptimized automatically.
+
+In general, you can install a probe anywhere in the kernel.
+In particular, you can probe interrupt handlers. Known exceptions
+are discussed in this section.
+
+The register_*probe functions will return -EINVAL if you attempt
+to install a probe in the code that implements Kprobes (mostly
+kernel/kprobes.c and ``arch/*/kernel/kprobes.c``, but also functions such
+as do_page_fault and notifier_call_chain).
+
+If you install a probe in an inline-able function, Kprobes makes
+no attempt to chase down all inline instances of the function and
+install probes there. gcc may inline a function without being asked,
+so keep this in mind if you're not seeing the probe hits you expect.
+
+A probe handler can modify the environment of the probed function
+-- e.g., by modifying kernel data structures, or by modifying the
+contents of the pt_regs struct (which are restored to the registers
+upon return from the breakpoint). So Kprobes can be used, for example,
+to install a bug fix or to inject faults for testing. Kprobes, of
+course, has no way to distinguish the deliberately injected faults
+from the accidental ones. Don't drink and probe.
+
+Kprobes makes no attempt to prevent probe handlers from stepping on
+each other -- e.g., probing printk() and then calling printk() from a
+probe handler. If a probe handler hits a probe, that second probe's
+handlers won't be run in that instance, and the kprobe.nmissed member
+of the second probe will be incremented.
+
+As of Linux v2.6.15-rc1, multiple handlers (or multiple instances of
+the same handler) may run concurrently on different CPUs.
+
+Kprobes does not use mutexes or allocate memory except during
+registration and unregistration.
+
+Probe handlers are run with preemption disabled or interrupt disabled,
+which depends on the architecture and optimization state. (e.g.,
+kretprobe handlers and optimized kprobe handlers run without interrupt
+disabled on x86/x86-64). In any case, your handler should not yield
+the CPU (e.g., by attempting to acquire a semaphore, or waiting I/O).
+
+Since a return probe is implemented by replacing the return
+address with the trampoline's address, stack backtraces and calls
+to __builtin_return_address() will typically yield the trampoline's
+address instead of the real return address for kretprobed functions.
+(As far as we can tell, __builtin_return_address() is used only
+for instrumentation and error reporting.)
+
+If the number of times a function is called does not match the number
+of times it returns, registering a return probe on that function may
+produce undesirable results. In such a case, a line:
+kretprobe BUG!: Processing kretprobe d000000000041aa8 @ c00000000004f48c
+gets printed. With this information, one will be able to correlate the
+exact instance of the kretprobe that caused the problem. We have the
+do_exit() case covered. do_execve() and do_fork() are not an issue.
+We're unaware of other specific cases where this could be a problem.
+
+If, upon entry to or exit from a function, the CPU is running on
+a stack other than that of the current task, registering a return
+probe on that function may produce undesirable results. For this
+reason, Kprobes doesn't support return probes (or kprobes)
+on the x86_64 version of __switch_to(); the registration functions
+return -EINVAL.
+
+On x86/x86-64, since the Jump Optimization of Kprobes modifies
+instructions widely, there are some limitations to optimization. To
+explain it, we introduce some terminology. Imagine a 3-instruction
+sequence consisting of a two 2-byte instructions and one 3-byte
+instruction.
+
+::
+
+ IA
+ |
+ [-2][-1][0][1][2][3][4][5][6][7]
+ [ins1][ins2][ ins3 ]
+ [<- DCR ->]
+ [<- JTPR ->]
+
+ ins1: 1st Instruction
+ ins2: 2nd Instruction
+ ins3: 3rd Instruction
+ IA: Insertion Address
+ JTPR: Jump Target Prohibition Region
+ DCR: Detoured Code Region
+
+The instructions in DCR are copied to the out-of-line buffer
+of the kprobe, because the bytes in DCR are replaced by
+a 5-byte jump instruction. So there are several limitations.
+
+a) The instructions in DCR must be relocatable.
+b) The instructions in DCR must not include a call instruction.
+c) JTPR must not be targeted by any jump or call instruction.
+d) DCR must not straddle the border between functions.
+
+Anyway, these limitations are checked by the in-kernel instruction
+decoder, so you don't need to worry about that.
+
+Probe Overhead
+==============
+
+On a typical CPU in use in 2005, a kprobe hit takes 0.5 to 1.0
+microseconds to process. Specifically, a benchmark that hits the same
+probepoint repeatedly, firing a simple handler each time, reports 1-2
+million hits per second, depending on the architecture. A return-probe
+hit typically takes 50-75% longer than a kprobe hit.
+When you have a return probe set on a function, adding a kprobe at
+the entry to that function adds essentially no overhead.
+
+Here are sample overhead figures (in usec) for different architectures::
+
+ k = kprobe; r = return probe; kr = kprobe + return probe
+ on same function
+
+ i386: Intel Pentium M, 1495 MHz, 2957.31 bogomips
+ k = 0.57 usec; r = 0.92; kr = 0.99
+
+ x86_64: AMD Opteron 246, 1994 MHz, 3971.48 bogomips
+ k = 0.49 usec; r = 0.80; kr = 0.82
+
+ ppc64: POWER5 (gr), 1656 MHz (SMT disabled, 1 virtual CPU per physical CPU)
+ k = 0.77 usec; r = 1.26; kr = 1.45
+
+Optimized Probe Overhead
+------------------------
+
+Typically, an optimized kprobe hit takes 0.07 to 0.1 microseconds to
+process. Here are sample overhead figures (in usec) for x86 architectures::
+
+ k = unoptimized kprobe, b = boosted (single-step skipped), o = optimized kprobe,
+ r = unoptimized kretprobe, rb = boosted kretprobe, ro = optimized kretprobe.
+
+ i386: Intel(R) Xeon(R) E5410, 2.33GHz, 4656.90 bogomips
+ k = 0.80 usec; b = 0.33; o = 0.05; r = 1.10; rb = 0.61; ro = 0.33
+
+ x86-64: Intel(R) Xeon(R) E5410, 2.33GHz, 4656.90 bogomips
+ k = 0.99 usec; b = 0.43; o = 0.06; r = 1.24; rb = 0.68; ro = 0.30
+
+TODO
+====
+
+a. SystemTap (http://sourceware.org/systemtap): Provides a simplified
+ programming interface for probe-based instrumentation. Try it out.
+b. Kernel return probes for sparc64.
+c. Support for other architectures.
+d. User-space probes.
+e. Watchpoint probes (which fire on data references).
+
+Kprobes Example
+===============
+
+See samples/kprobes/kprobe_example.c
+
+Kretprobes Example
+==================
+
+See samples/kprobes/kretprobe_example.c
+
+Deprecated Features
+===================
+
+Jprobes is now a deprecated feature. People who are depending on it should
+migrate to other tracing features or use older kernels. Please consider to
+migrate your tool to one of the following options:
+
+- Use trace-event to trace target function with arguments.
+
+ trace-event is a low-overhead (and almost no visible overhead if it
+ is off) statically defined event interface. You can define new events
+ and trace it via ftrace or any other tracing tools.
+
+ See the following urls:
+
+ - https://lwn.net/Articles/379903/
+ - https://lwn.net/Articles/381064/
+ - https://lwn.net/Articles/383362/
+
+- Use ftrace dynamic events (kprobe event) with perf-probe.
+
+ If you build your kernel with debug info (CONFIG_DEBUG_INFO=y), you can
+ find which register/stack is assigned to which local variable or arguments
+ by using perf-probe and set up new event to trace it.
+
+ See following documents:
+
+ - Documentation/trace/kprobetrace.rst
+ - Documentation/trace/events.rst
+ - tools/perf/Documentation/perf-probe.txt
+
+
+The kprobes debugfs interface
+=============================
+
+
+With recent kernels (> 2.6.20) the list of registered kprobes is visible
+under the /sys/kernel/debug/kprobes/ directory (assuming debugfs is mounted at //sys/kernel/debug).
+
+/sys/kernel/debug/kprobes/list: Lists all registered probes on the system::
+
+ c015d71a k vfs_read+0x0
+ c03dedc5 r tcp_v4_rcv+0x0
+
+The first column provides the kernel address where the probe is inserted.
+The second column identifies the type of probe (k - kprobe and r - kretprobe)
+while the third column specifies the symbol+offset of the probe.
+If the probed function belongs to a module, the module name is also
+specified. Following columns show probe status. If the probe is on
+a virtual address that is no longer valid (module init sections, module
+virtual addresses that correspond to modules that've been unloaded),
+such probes are marked with [GONE]. If the probe is temporarily disabled,
+such probes are marked with [DISABLED]. If the probe is optimized, it is
+marked with [OPTIMIZED]. If the probe is ftrace-based, it is marked with
+[FTRACE].
+
+/sys/kernel/debug/kprobes/enabled: Turn kprobes ON/OFF forcibly.
+
+Provides a knob to globally and forcibly turn registered kprobes ON or OFF.
+By default, all kprobes are enabled. By echoing "0" to this file, all
+registered probes will be disarmed, till such time a "1" is echoed to this
+file. Note that this knob just disarms and arms all kprobes and doesn't
+change each probe's disabling state. This means that disabled kprobes (marked
+[DISABLED]) will be not enabled if you turn ON all kprobes by this knob.
+
+
+The kprobes sysctl interface
+============================
+
+/proc/sys/debug/kprobes-optimization: Turn kprobes optimization ON/OFF.
+
+When CONFIG_OPTPROBES=y, this sysctl interface appears and it provides
+a knob to globally and forcibly turn jump optimization (see section
+:ref:`kprobes_jump_optimization`) ON or OFF. By default, jump optimization
+is allowed (ON). If you echo "0" to this file or set
+"debug.kprobes_optimization" to 0 via sysctl, all optimized probes will be
+unoptimized, and any new probes registered after that will not be optimized.
+
+Note that this knob *changes* the optimized state. This means that optimized
+probes (marked [OPTIMIZED]) will be unoptimized ([OPTIMIZED] tag will be
+removed). If the knob is turned on, they will be optimized again.
+
+References
+==========
+
+For additional information on Kprobes, refer to the following URLs:
+
+- https://lwn.net/Articles/132196/
+- https://www.kernel.org/doc/ols/2006/ols2006v2-pages-109-124.pdf
+
diff --git a/Documentation/trace/kprobetrace.rst b/Documentation/trace/kprobetrace.rst
new file mode 100644
index 000000000..08a2a6a37
--- /dev/null
+++ b/Documentation/trace/kprobetrace.rst
@@ -0,0 +1,261 @@
+==========================
+Kprobe-based Event Tracing
+==========================
+
+:Author: Masami Hiramatsu
+
+Overview
+--------
+These events are similar to tracepoint based events. Instead of Tracepoint,
+this is based on kprobes (kprobe and kretprobe). So it can probe wherever
+kprobes can probe (this means, all functions except those with
+__kprobes/nokprobe_inline annotation and those marked NOKPROBE_SYMBOL).
+Unlike the Tracepoint based event, this can be added and removed
+dynamically, on the fly.
+
+To enable this feature, build your kernel with CONFIG_KPROBE_EVENTS=y.
+
+Similar to the events tracer, this doesn't need to be activated via
+current_tracer. Instead of that, add probe points via
+/sys/kernel/debug/tracing/kprobe_events, and enable it via
+/sys/kernel/debug/tracing/events/kprobes/<EVENT>/enable.
+
+You can also use /sys/kernel/debug/tracing/dynamic_events instead of
+kprobe_events. That interface will provide unified access to other
+dynamic events too.
+
+Synopsis of kprobe_events
+-------------------------
+::
+
+ p[:[GRP/][EVENT]] [MOD:]SYM[+offs]|MEMADDR [FETCHARGS] : Set a probe
+ r[MAXACTIVE][:[GRP/][EVENT]] [MOD:]SYM[+0] [FETCHARGS] : Set a return probe
+ p[:[GRP/][EVENT]] [MOD:]SYM[+0]%return [FETCHARGS] : Set a return probe
+ -:[GRP/][EVENT] : Clear a probe
+
+ GRP : Group name. If omitted, use "kprobes" for it.
+ EVENT : Event name. If omitted, the event name is generated
+ based on SYM+offs or MEMADDR.
+ MOD : Module name which has given SYM.
+ SYM[+offs] : Symbol+offset where the probe is inserted.
+ SYM%return : Return address of the symbol
+ MEMADDR : Address where the probe is inserted.
+ MAXACTIVE : Maximum number of instances of the specified function that
+ can be probed simultaneously, or 0 for the default value
+ as defined in Documentation/trace/kprobes.rst section 1.3.1.
+
+ FETCHARGS : Arguments. Each probe can have up to 128 args.
+ %REG : Fetch register REG
+ @ADDR : Fetch memory at ADDR (ADDR should be in kernel)
+ @SYM[+|-offs] : Fetch memory at SYM +|- offs (SYM should be a data symbol)
+ $stackN : Fetch Nth entry of stack (N >= 0)
+ $stack : Fetch stack address.
+ $argN : Fetch the Nth function argument. (N >= 1) (\*1)
+ $retval : Fetch return value.(\*2)
+ $comm : Fetch current task comm.
+ +|-[u]OFFS(FETCHARG) : Fetch memory at FETCHARG +|- OFFS address.(\*3)(\*4)
+ \IMM : Store an immediate value to the argument.
+ NAME=FETCHARG : Set NAME as the argument name of FETCHARG.
+ FETCHARG:TYPE : Set TYPE as the type of FETCHARG. Currently, basic types
+ (u8/u16/u32/u64/s8/s16/s32/s64), hexadecimal types
+ (x8/x16/x32/x64), "string", "ustring", "symbol", "symstr"
+ and bitfield are supported.
+
+ (\*1) only for the probe on function entry (offs == 0).
+ (\*2) only for return probe.
+ (\*3) this is useful for fetching a field of data structures.
+ (\*4) "u" means user-space dereference. See :ref:`user_mem_access`.
+
+Types
+-----
+Several types are supported for fetch-args. Kprobe tracer will access memory
+by given type. Prefix 's' and 'u' means those types are signed and unsigned
+respectively. 'x' prefix implies it is unsigned. Traced arguments are shown
+in decimal ('s' and 'u') or hexadecimal ('x'). Without type casting, 'x32'
+or 'x64' is used depends on the architecture (e.g. x86-32 uses x32, and
+x86-64 uses x64).
+These value types can be an array. To record array data, you can add '[N]'
+(where N is a fixed number, less than 64) to the base type.
+E.g. 'x16[4]' means an array of x16 (2bytes hex) with 4 elements.
+Note that the array can be applied to memory type fetchargs, you can not
+apply it to registers/stack-entries etc. (for example, '$stack1:x8[8]' is
+wrong, but '+8($stack):x8[8]' is OK.)
+String type is a special type, which fetches a "null-terminated" string from
+kernel space. This means it will fail and store NULL if the string container
+has been paged out. "ustring" type is an alternative of string for user-space.
+See :ref:`user_mem_access` for more info..
+The string array type is a bit different from other types. For other base
+types, <base-type>[1] is equal to <base-type> (e.g. +0(%di):x32[1] is same
+as +0(%di):x32.) But string[1] is not equal to string. The string type itself
+represents "char array", but string array type represents "char * array".
+So, for example, +0(%di):string[1] is equal to +0(+0(%di)):string.
+Bitfield is another special type, which takes 3 parameters, bit-width, bit-
+offset, and container-size (usually 32). The syntax is::
+
+ b<bit-width>@<bit-offset>/<container-size>
+
+Symbol type('symbol') is an alias of u32 or u64 type (depends on BITS_PER_LONG)
+which shows given pointer in "symbol+offset" style.
+On the other hand, symbol-string type ('symstr') converts the given address to
+"symbol+offset/symbolsize" style and stores it as a null-terminated string.
+With 'symstr' type, you can filter the event with wildcard pattern of the
+symbols, and you don't need to solve symbol name by yourself.
+For $comm, the default type is "string"; any other type is invalid.
+
+.. _user_mem_access:
+
+User Memory Access
+------------------
+Kprobe events supports user-space memory access. For that purpose, you can use
+either user-space dereference syntax or 'ustring' type.
+
+The user-space dereference syntax allows you to access a field of a data
+structure in user-space. This is done by adding the "u" prefix to the
+dereference syntax. For example, +u4(%si) means it will read memory from the
+address in the register %si offset by 4, and the memory is expected to be in
+user-space. You can use this for strings too, e.g. +u0(%si):string will read
+a string from the address in the register %si that is expected to be in user-
+space. 'ustring' is a shortcut way of performing the same task. That is,
++0(%si):ustring is equivalent to +u0(%si):string.
+
+Note that kprobe-event provides the user-memory access syntax but it doesn't
+use it transparently. This means if you use normal dereference or string type
+for user memory, it might fail, and may always fail on some archs. The user
+has to carefully check if the target data is in kernel or user space.
+
+Per-Probe Event Filtering
+-------------------------
+Per-probe event filtering feature allows you to set different filter on each
+probe and gives you what arguments will be shown in trace buffer. If an event
+name is specified right after 'p:' or 'r:' in kprobe_events, it adds an event
+under tracing/events/kprobes/<EVENT>, at the directory you can see 'id',
+'enable', 'format', 'filter' and 'trigger'.
+
+enable:
+ You can enable/disable the probe by writing 1 or 0 on it.
+
+format:
+ This shows the format of this probe event.
+
+filter:
+ You can write filtering rules of this event.
+
+id:
+ This shows the id of this probe event.
+
+trigger:
+ This allows to install trigger commands which are executed when the event is
+ hit (for details, see Documentation/trace/events.rst, section 6).
+
+Event Profiling
+---------------
+You can check the total number of probe hits and probe miss-hits via
+/sys/kernel/debug/tracing/kprobe_profile.
+The first column is event name, the second is the number of probe hits,
+the third is the number of probe miss-hits.
+
+Kernel Boot Parameter
+---------------------
+You can add and enable new kprobe events when booting up the kernel by
+"kprobe_event=" parameter. The parameter accepts a semicolon-delimited
+kprobe events, which format is similar to the kprobe_events.
+The difference is that the probe definition parameters are comma-delimited
+instead of space. For example, adding myprobe event on do_sys_open like below
+
+ p:myprobe do_sys_open dfd=%ax filename=%dx flags=%cx mode=+4($stack)
+
+should be below for kernel boot parameter (just replace spaces with comma)
+
+ p:myprobe,do_sys_open,dfd=%ax,filename=%dx,flags=%cx,mode=+4($stack)
+
+
+Usage examples
+--------------
+To add a probe as a new event, write a new definition to kprobe_events
+as below::
+
+ echo 'p:myprobe do_sys_open dfd=%ax filename=%dx flags=%cx mode=+4($stack)' > /sys/kernel/debug/tracing/kprobe_events
+
+This sets a kprobe on the top of do_sys_open() function with recording
+1st to 4th arguments as "myprobe" event. Note, which register/stack entry is
+assigned to each function argument depends on arch-specific ABI. If you unsure
+the ABI, please try to use probe subcommand of perf-tools (you can find it
+under tools/perf/).
+As this example shows, users can choose more familiar names for each arguments.
+::
+
+ echo 'r:myretprobe do_sys_open $retval' >> /sys/kernel/debug/tracing/kprobe_events
+
+This sets a kretprobe on the return point of do_sys_open() function with
+recording return value as "myretprobe" event.
+You can see the format of these events via
+/sys/kernel/debug/tracing/events/kprobes/<EVENT>/format.
+::
+
+ cat /sys/kernel/debug/tracing/events/kprobes/myprobe/format
+ name: myprobe
+ ID: 780
+ format:
+ field:unsigned short common_type; offset:0; size:2; signed:0;
+ field:unsigned char common_flags; offset:2; size:1; signed:0;
+ field:unsigned char common_preempt_count; offset:3; size:1;signed:0;
+ field:int common_pid; offset:4; size:4; signed:1;
+
+ field:unsigned long __probe_ip; offset:12; size:4; signed:0;
+ field:int __probe_nargs; offset:16; size:4; signed:1;
+ field:unsigned long dfd; offset:20; size:4; signed:0;
+ field:unsigned long filename; offset:24; size:4; signed:0;
+ field:unsigned long flags; offset:28; size:4; signed:0;
+ field:unsigned long mode; offset:32; size:4; signed:0;
+
+
+ print fmt: "(%lx) dfd=%lx filename=%lx flags=%lx mode=%lx", REC->__probe_ip,
+ REC->dfd, REC->filename, REC->flags, REC->mode
+
+You can see that the event has 4 arguments as in the expressions you specified.
+::
+
+ echo > /sys/kernel/debug/tracing/kprobe_events
+
+This clears all probe points.
+
+Or,
+::
+
+ echo -:myprobe >> kprobe_events
+
+This clears probe points selectively.
+
+Right after definition, each event is disabled by default. For tracing these
+events, you need to enable it.
+::
+
+ echo 1 > /sys/kernel/debug/tracing/events/kprobes/myprobe/enable
+ echo 1 > /sys/kernel/debug/tracing/events/kprobes/myretprobe/enable
+
+Use the following command to start tracing in an interval.
+::
+
+ # echo 1 > tracing_on
+ Open something...
+ # echo 0 > tracing_on
+
+And you can see the traced information via /sys/kernel/debug/tracing/trace.
+::
+
+ cat /sys/kernel/debug/tracing/trace
+ # tracer: nop
+ #
+ # TASK-PID CPU# TIMESTAMP FUNCTION
+ # | | | | |
+ <...>-1447 [001] 1038282.286875: myprobe: (do_sys_open+0x0/0xd6) dfd=3 filename=7fffd1ec4440 flags=8000 mode=0
+ <...>-1447 [001] 1038282.286878: myretprobe: (sys_openat+0xc/0xe <- do_sys_open) $retval=fffffffffffffffe
+ <...>-1447 [001] 1038282.286885: myprobe: (do_sys_open+0x0/0xd6) dfd=ffffff9c filename=40413c flags=8000 mode=1b6
+ <...>-1447 [001] 1038282.286915: myretprobe: (sys_open+0x1b/0x1d <- do_sys_open) $retval=3
+ <...>-1447 [001] 1038282.286969: myprobe: (do_sys_open+0x0/0xd6) dfd=ffffff9c filename=4041c6 flags=98800 mode=10
+ <...>-1447 [001] 1038282.286976: myretprobe: (sys_open+0x1b/0x1d <- do_sys_open) $retval=3
+
+
+Each line shows when the kernel hits an event, and <- SYMBOL means kernel
+returns from SYMBOL(e.g. "sys_open+0x1b/0x1d <- do_sys_open" means kernel
+returns from do_sys_open to sys_open+0x1b).
diff --git a/Documentation/trace/mmiotrace.rst b/Documentation/trace/mmiotrace.rst
new file mode 100644
index 000000000..fed13eaea
--- /dev/null
+++ b/Documentation/trace/mmiotrace.rst
@@ -0,0 +1,184 @@
+===================================
+In-kernel memory-mapped I/O tracing
+===================================
+
+
+Home page and links to optional user space tools:
+
+ https://nouveau.freedesktop.org/wiki/MmioTrace
+
+MMIO tracing was originally developed by Intel around 2003 for their Fault
+Injection Test Harness. In Dec 2006 - Jan 2007, using the code from Intel,
+Jeff Muizelaar created a tool for tracing MMIO accesses with the Nouveau
+project in mind. Since then many people have contributed.
+
+Mmiotrace was built for reverse engineering any memory-mapped IO device with
+the Nouveau project as the first real user. Only x86 and x86_64 architectures
+are supported.
+
+Out-of-tree mmiotrace was originally modified for mainline inclusion and
+ftrace framework by Pekka Paalanen <pq@iki.fi>.
+
+
+Preparation
+-----------
+
+Mmiotrace feature is compiled in by the CONFIG_MMIOTRACE option. Tracing is
+disabled by default, so it is safe to have this set to yes. SMP systems are
+supported, but tracing is unreliable and may miss events if more than one CPU
+is on-line, therefore mmiotrace takes all but one CPU off-line during run-time
+activation. You can re-enable CPUs by hand, but you have been warned, there
+is no way to automatically detect if you are losing events due to CPUs racing.
+
+
+Usage Quick Reference
+---------------------
+::
+
+ $ mount -t debugfs debugfs /sys/kernel/debug
+ $ echo mmiotrace > /sys/kernel/debug/tracing/current_tracer
+ $ cat /sys/kernel/debug/tracing/trace_pipe > mydump.txt &
+ Start X or whatever.
+ $ echo "X is up" > /sys/kernel/debug/tracing/trace_marker
+ $ echo nop > /sys/kernel/debug/tracing/current_tracer
+ Check for lost events.
+
+
+Usage
+-----
+
+Make sure debugfs is mounted to /sys/kernel/debug.
+If not (requires root privileges)::
+
+ $ mount -t debugfs debugfs /sys/kernel/debug
+
+Check that the driver you are about to trace is not loaded.
+
+Activate mmiotrace (requires root privileges)::
+
+ $ echo mmiotrace > /sys/kernel/debug/tracing/current_tracer
+
+Start storing the trace::
+
+ $ cat /sys/kernel/debug/tracing/trace_pipe > mydump.txt &
+
+The 'cat' process should stay running (sleeping) in the background.
+
+Load the driver you want to trace and use it. Mmiotrace will only catch MMIO
+accesses to areas that are ioremapped while mmiotrace is active.
+
+During tracing you can place comments (markers) into the trace by
+$ echo "X is up" > /sys/kernel/debug/tracing/trace_marker
+This makes it easier to see which part of the (huge) trace corresponds to
+which action. It is recommended to place descriptive markers about what you
+do.
+
+Shut down mmiotrace (requires root privileges)::
+
+ $ echo nop > /sys/kernel/debug/tracing/current_tracer
+
+The 'cat' process exits. If it does not, kill it by issuing 'fg' command and
+pressing ctrl+c.
+
+Check that mmiotrace did not lose events due to a buffer filling up. Either::
+
+ $ grep -i lost mydump.txt
+
+which tells you exactly how many events were lost, or use::
+
+ $ dmesg
+
+to view your kernel log and look for "mmiotrace has lost events" warning. If
+events were lost, the trace is incomplete. You should enlarge the buffers and
+try again. Buffers are enlarged by first seeing how large the current buffers
+are::
+
+ $ cat /sys/kernel/debug/tracing/buffer_size_kb
+
+gives you a number. Approximately double this number and write it back, for
+instance::
+
+ $ echo 128000 > /sys/kernel/debug/tracing/buffer_size_kb
+
+Then start again from the top.
+
+If you are doing a trace for a driver project, e.g. Nouveau, you should also
+do the following before sending your results::
+
+ $ lspci -vvv > lspci.txt
+ $ dmesg > dmesg.txt
+ $ tar zcf pciid-nick-mmiotrace.tar.gz mydump.txt lspci.txt dmesg.txt
+
+and then send the .tar.gz file. The trace compresses considerably. Replace
+"pciid" and "nick" with the PCI ID or model name of your piece of hardware
+under investigation and your nickname.
+
+
+How Mmiotrace Works
+-------------------
+
+Access to hardware IO-memory is gained by mapping addresses from PCI bus by
+calling one of the ioremap_*() functions. Mmiotrace is hooked into the
+__ioremap() function and gets called whenever a mapping is created. Mapping is
+an event that is recorded into the trace log. Note that ISA range mappings
+are not caught, since the mapping always exists and is returned directly.
+
+MMIO accesses are recorded via page faults. Just before __ioremap() returns,
+the mapped pages are marked as not present. Any access to the pages causes a
+fault. The page fault handler calls mmiotrace to handle the fault. Mmiotrace
+marks the page present, sets TF flag to achieve single stepping and exits the
+fault handler. The instruction that faulted is executed and debug trap is
+entered. Here mmiotrace again marks the page as not present. The instruction
+is decoded to get the type of operation (read/write), data width and the value
+read or written. These are stored to the trace log.
+
+Setting the page present in the page fault handler has a race condition on SMP
+machines. During the single stepping other CPUs may run freely on that page
+and events can be missed without a notice. Re-enabling other CPUs during
+tracing is discouraged.
+
+
+Trace Log Format
+----------------
+
+The raw log is text and easily filtered with e.g. grep and awk. One record is
+one line in the log. A record starts with a keyword, followed by keyword-
+dependent arguments. Arguments are separated by a space, or continue until the
+end of line. The format for version 20070824 is as follows:
+
+Explanation Keyword Space-separated arguments
+---------------------------------------------------------------------------
+
+read event R width, timestamp, map id, physical, value, PC, PID
+write event W width, timestamp, map id, physical, value, PC, PID
+ioremap event MAP timestamp, map id, physical, virtual, length, PC, PID
+iounmap event UNMAP timestamp, map id, PC, PID
+marker MARK timestamp, text
+version VERSION the string "20070824"
+info for reader LSPCI one line from lspci -v
+PCI address map PCIDEV space-separated /proc/bus/pci/devices data
+unk. opcode UNKNOWN timestamp, map id, physical, data, PC, PID
+
+Timestamp is in seconds with decimals. Physical is a PCI bus address, virtual
+is a kernel virtual address. Width is the data width in bytes and value is the
+data value. Map id is an arbitrary id number identifying the mapping that was
+used in an operation. PC is the program counter and PID is process id. PC is
+zero if it is not recorded. PID is always zero as tracing MMIO accesses
+originating in user space memory is not yet supported.
+
+For instance, the following awk filter will pass all 32-bit writes that target
+physical addresses in the range [0xfb73ce40, 0xfb800000]
+::
+
+ $ awk '/W 4 / { adr=strtonum($5); if (adr >= 0xfb73ce40 &&
+ adr < 0xfb800000) print; }'
+
+
+Tools for Developers
+--------------------
+
+The user space tools include utilities for:
+ - replacing numeric addresses and values with hardware register names
+ - replaying MMIO logs, i.e., re-executing the recorded writes
+
+
diff --git a/Documentation/trace/osnoise-tracer.rst b/Documentation/trace/osnoise-tracer.rst
new file mode 100644
index 000000000..963def9f9
--- /dev/null
+++ b/Documentation/trace/osnoise-tracer.rst
@@ -0,0 +1,152 @@
+==============
+OSNOISE Tracer
+==============
+
+In the context of high-performance computing (HPC), the Operating System
+Noise (*osnoise*) refers to the interference experienced by an application
+due to activities inside the operating system. In the context of Linux,
+NMIs, IRQs, SoftIRQs, and any other system thread can cause noise to the
+system. Moreover, hardware-related jobs can also cause noise, for example,
+via SMIs.
+
+hwlat_detector is one of the tools used to identify the most complex
+source of noise: *hardware noise*.
+
+In a nutshell, the hwlat_detector creates a thread that runs
+periodically for a given period. At the beginning of a period, the thread
+disables interrupt and starts sampling. While running, the hwlatd
+thread reads the time in a loop. As interrupts are disabled, threads,
+IRQs, and SoftIRQs cannot interfere with the hwlatd thread. Hence, the
+cause of any gap between two different reads of the time roots either on
+NMI or in the hardware itself. At the end of the period, hwlatd enables
+interrupts and reports the max observed gap between the reads. It also
+prints a NMI occurrence counter. If the output does not report NMI
+executions, the user can conclude that the hardware is the culprit for
+the latency. The hwlat detects the NMI execution by observing
+the entry and exit of a NMI.
+
+The osnoise tracer leverages the hwlat_detector by running a
+similar loop with preemption, SoftIRQs and IRQs enabled, thus allowing
+all the sources of *osnoise* during its execution. Using the same approach
+of hwlat, osnoise takes note of the entry and exit point of any
+source of interferences, increasing a per-cpu interference counter. The
+osnoise tracer also saves an interference counter for each source of
+interference. The interference counter for NMI, IRQs, SoftIRQs, and
+threads is increased anytime the tool observes these interferences' entry
+events. When a noise happens without any interference from the operating
+system level, the hardware noise counter increases, pointing to a
+hardware-related noise. In this way, osnoise can account for any
+source of interference. At the end of the period, the osnoise tracer
+prints the sum of all noise, the max single noise, the percentage of CPU
+available for the thread, and the counters for the noise sources.
+
+Usage
+-----
+
+Write the ASCII text "osnoise" into the current_tracer file of the
+tracing system (generally mounted at /sys/kernel/tracing).
+
+For example::
+
+ [root@f32 ~]# cd /sys/kernel/tracing/
+ [root@f32 tracing]# echo osnoise > current_tracer
+
+It is possible to follow the trace by reading the trace file::
+
+ [root@f32 tracing]# cat trace
+ # tracer: osnoise
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth MAX
+ # || / SINGLE Interference counters:
+ # |||| RUNTIME NOISE % OF CPU NOISE +-----------------------------+
+ # TASK-PID CPU# |||| TIMESTAMP IN US IN US AVAILABLE IN US HW NMI IRQ SIRQ THREAD
+ # | | | |||| | | | | | | | | | |
+ <...>-859 [000] .... 81.637220: 1000000 190 99.98100 9 18 0 1007 18 1
+ <...>-860 [001] .... 81.638154: 1000000 656 99.93440 74 23 0 1006 16 3
+ <...>-861 [002] .... 81.638193: 1000000 5675 99.43250 202 6 0 1013 25 21
+ <...>-862 [003] .... 81.638242: 1000000 125 99.98750 45 1 0 1011 23 0
+ <...>-863 [004] .... 81.638260: 1000000 1721 99.82790 168 7 0 1002 49 41
+ <...>-864 [005] .... 81.638286: 1000000 263 99.97370 57 6 0 1006 26 2
+ <...>-865 [006] .... 81.638302: 1000000 109 99.98910 21 3 0 1006 18 1
+ <...>-866 [007] .... 81.638326: 1000000 7816 99.21840 107 8 0 1016 39 19
+
+In addition to the regular trace fields (from TASK-PID to TIMESTAMP), the
+tracer prints a message at the end of each period for each CPU that is
+running an osnoise/ thread. The osnoise specific fields report:
+
+ - The RUNTIME IN US reports the amount of time in microseconds that
+ the osnoise thread kept looping reading the time.
+ - The NOISE IN US reports the sum of noise in microseconds observed
+ by the osnoise tracer during the associated runtime.
+ - The % OF CPU AVAILABLE reports the percentage of CPU available for
+ the osnoise thread during the runtime window.
+ - The MAX SINGLE NOISE IN US reports the maximum single noise observed
+ during the runtime window.
+ - The Interference counters display how many each of the respective
+ interference happened during the runtime window.
+
+Note that the example above shows a high number of HW noise samples.
+The reason being is that this sample was taken on a virtual machine,
+and the host interference is detected as a hardware interference.
+
+Tracer options
+---------------------
+
+The tracer has a set of options inside the osnoise directory, they are:
+
+ - osnoise/cpus: CPUs at which a osnoise thread will execute.
+ - osnoise/period_us: the period of the osnoise thread.
+ - osnoise/runtime_us: how long an osnoise thread will look for noise.
+ - osnoise/stop_tracing_us: stop the system tracing if a single noise
+ higher than the configured value happens. Writing 0 disables this
+ option.
+ - osnoise/stop_tracing_total_us: stop the system tracing if total noise
+ higher than the configured value happens. Writing 0 disables this
+ option.
+ - tracing_threshold: the minimum delta between two time() reads to be
+ considered as noise, in us. When set to 0, the default value will
+ be used, which is currently 5 us.
+
+Additional Tracing
+------------------
+
+In addition to the tracer, a set of tracepoints were added to
+facilitate the identification of the osnoise source.
+
+ - osnoise:sample_threshold: printed anytime a noise is higher than
+ the configurable tolerance_ns.
+ - osnoise:nmi_noise: noise from NMI, including the duration.
+ - osnoise:irq_noise: noise from an IRQ, including the duration.
+ - osnoise:softirq_noise: noise from a SoftIRQ, including the
+ duration.
+ - osnoise:thread_noise: noise from a thread, including the duration.
+
+Note that all the values are *net values*. For example, if while osnoise
+is running, another thread preempts the osnoise thread, it will start a
+thread_noise duration at the start. Then, an IRQ takes place, preempting
+the thread_noise, starting a irq_noise. When the IRQ ends its execution,
+it will compute its duration, and this duration will be subtracted from
+the thread_noise, in such a way as to avoid the double accounting of the
+IRQ execution. This logic is valid for all sources of noise.
+
+Here is one example of the usage of these tracepoints::
+
+ osnoise/8-961 [008] d.h. 5789.857532: irq_noise: local_timer:236 start 5789.857529929 duration 1845 ns
+ osnoise/8-961 [008] dNh. 5789.858408: irq_noise: local_timer:236 start 5789.858404871 duration 2848 ns
+ migration/8-54 [008] d... 5789.858413: thread_noise: migration/8:54 start 5789.858409300 duration 3068 ns
+ osnoise/8-961 [008] .... 5789.858413: sample_threshold: start 5789.858404555 duration 8812 ns interferences 2
+
+In this example, a noise sample of 8 microseconds was reported in the last
+line, pointing to two interferences. Looking backward in the trace, the
+two previous entries were about the migration thread running after a
+timer IRQ execution. The first event is not part of the noise because
+it took place one millisecond before.
+
+It is worth noticing that the sum of the duration reported in the
+tracepoints is smaller than eight us reported in the sample_threshold.
+The reason roots in the overhead of the entry and exit code that happens
+before and after any interference execution. This justifies the dual
+approach: measuring thread and tracing.
diff --git a/Documentation/trace/postprocess/decode_msr.py b/Documentation/trace/postprocess/decode_msr.py
new file mode 100644
index 000000000..aa9cc7abd
--- /dev/null
+++ b/Documentation/trace/postprocess/decode_msr.py
@@ -0,0 +1,37 @@
+#!/usr/bin/env python
+# add symbolic names to read_msr / write_msr in trace
+# decode_msr msr-index.h < trace
+import sys
+import re
+
+msrs = dict()
+
+with open(sys.argv[1] if len(sys.argv) > 1 else "msr-index.h", "r") as f:
+ for j in f:
+ m = re.match(r'#define (MSR_\w+)\s+(0x[0-9a-fA-F]+)', j)
+ if m:
+ msrs[int(m.group(2), 16)] = m.group(1)
+
+extra_ranges = (
+ ( "MSR_LASTBRANCH_%d_FROM_IP", 0x680, 0x69F ),
+ ( "MSR_LASTBRANCH_%d_TO_IP", 0x6C0, 0x6DF ),
+ ( "LBR_INFO_%d", 0xdc0, 0xddf ),
+)
+
+for j in sys.stdin:
+ m = re.search(r'(read|write)_msr:\s+([0-9a-f]+)', j)
+ if m:
+ r = None
+ num = int(m.group(2), 16)
+ if num in msrs:
+ r = msrs[num]
+ else:
+ for er in extra_ranges:
+ if er[1] <= num <= er[2]:
+ r = er[0] % (num - er[1],)
+ break
+ if r:
+ j = j.replace(" " + m.group(2), " " + r + "(" + m.group(2) + ")")
+ print j,
+
+
diff --git a/Documentation/trace/postprocess/trace-pagealloc-postprocess.pl b/Documentation/trace/postprocess/trace-pagealloc-postprocess.pl
new file mode 100644
index 000000000..b9b7d80c2
--- /dev/null
+++ b/Documentation/trace/postprocess/trace-pagealloc-postprocess.pl
@@ -0,0 +1,418 @@
+#!/usr/bin/env perl
+# This is a POC (proof of concept or piece of crap, take your pick) for reading the
+# text representation of trace output related to page allocation. It makes an attempt
+# to extract some high-level information on what is going on. The accuracy of the parser
+# may vary considerably
+#
+# Example usage: trace-pagealloc-postprocess.pl < /sys/kernel/debug/tracing/trace_pipe
+# other options
+# --prepend-parent Report on the parent proc and PID
+# --read-procstat If the trace lacks process info, get it from /proc
+# --ignore-pid Aggregate processes of the same name together
+#
+# Copyright (c) IBM Corporation 2009
+# Author: Mel Gorman <mel@csn.ul.ie>
+use strict;
+use Getopt::Long;
+
+# Tracepoint events
+use constant MM_PAGE_ALLOC => 1;
+use constant MM_PAGE_FREE => 2;
+use constant MM_PAGE_FREE_BATCHED => 3;
+use constant MM_PAGE_PCPU_DRAIN => 4;
+use constant MM_PAGE_ALLOC_ZONE_LOCKED => 5;
+use constant MM_PAGE_ALLOC_EXTFRAG => 6;
+use constant EVENT_UNKNOWN => 7;
+
+# Constants used to track state
+use constant STATE_PCPU_PAGES_DRAINED => 8;
+use constant STATE_PCPU_PAGES_REFILLED => 9;
+
+# High-level events extrapolated from tracepoints
+use constant HIGH_PCPU_DRAINS => 10;
+use constant HIGH_PCPU_REFILLS => 11;
+use constant HIGH_EXT_FRAGMENT => 12;
+use constant HIGH_EXT_FRAGMENT_SEVERE => 13;
+use constant HIGH_EXT_FRAGMENT_MODERATE => 14;
+use constant HIGH_EXT_FRAGMENT_CHANGED => 15;
+
+my %perprocesspid;
+my %perprocess;
+my $opt_ignorepid;
+my $opt_read_procstat;
+my $opt_prepend_parent;
+
+# Catch sigint and exit on request
+my $sigint_report = 0;
+my $sigint_exit = 0;
+my $sigint_pending = 0;
+my $sigint_received = 0;
+sub sigint_handler {
+ my $current_time = time;
+ if ($current_time - 2 > $sigint_received) {
+ print "SIGINT received, report pending. Hit ctrl-c again to exit\n";
+ $sigint_report = 1;
+ } else {
+ if (!$sigint_exit) {
+ print "Second SIGINT received quickly, exiting\n";
+ }
+ $sigint_exit++;
+ }
+
+ if ($sigint_exit > 3) {
+ print "Many SIGINTs received, exiting now without report\n";
+ exit;
+ }
+
+ $sigint_received = $current_time;
+ $sigint_pending = 1;
+}
+$SIG{INT} = "sigint_handler";
+
+# Parse command line options
+GetOptions(
+ 'ignore-pid' => \$opt_ignorepid,
+ 'read-procstat' => \$opt_read_procstat,
+ 'prepend-parent' => \$opt_prepend_parent,
+);
+
+# Defaults for dynamically discovered regex's
+my $regex_fragdetails_default = 'page=([0-9a-f]*) pfn=([0-9]*) alloc_order=([-0-9]*) fallback_order=([-0-9]*) pageblock_order=([-0-9]*) alloc_migratetype=([-0-9]*) fallback_migratetype=([-0-9]*) fragmenting=([-0-9]) change_ownership=([-0-9])';
+
+# Dyanically discovered regex
+my $regex_fragdetails;
+
+# Static regex used. Specified like this for readability and for use with /o
+# (process_pid) (cpus ) ( time ) (tpoint ) (details)
+my $regex_traceevent = '\s*([a-zA-Z0-9-]*)\s*(\[[0-9]*\])\s*([0-9.]*):\s*([a-zA-Z_]*):\s*(.*)';
+my $regex_statname = '[-0-9]*\s\((.*)\).*';
+my $regex_statppid = '[-0-9]*\s\(.*\)\s[A-Za-z]\s([0-9]*).*';
+
+sub generate_traceevent_regex {
+ my $event = shift;
+ my $default = shift;
+ my $regex;
+
+ # Read the event format or use the default
+ if (!open (FORMAT, "/sys/kernel/debug/tracing/events/$event/format")) {
+ $regex = $default;
+ } else {
+ my $line;
+ while (!eof(FORMAT)) {
+ $line = <FORMAT>;
+ if ($line =~ /^print fmt:\s"(.*)",.*/) {
+ $regex = $1;
+ $regex =~ s/%p/\([0-9a-f]*\)/g;
+ $regex =~ s/%d/\([-0-9]*\)/g;
+ $regex =~ s/%lu/\([0-9]*\)/g;
+ }
+ }
+ }
+
+ # Verify fields are in the right order
+ my $tuple;
+ foreach $tuple (split /\s/, $regex) {
+ my ($key, $value) = split(/=/, $tuple);
+ my $expected = shift;
+ if ($key ne $expected) {
+ print("WARNING: Format not as expected '$key' != '$expected'");
+ $regex =~ s/$key=\((.*)\)/$key=$1/;
+ }
+ }
+
+ if (defined shift) {
+ die("Fewer fields than expected in format");
+ }
+
+ return $regex;
+}
+$regex_fragdetails = generate_traceevent_regex("kmem/mm_page_alloc_extfrag",
+ $regex_fragdetails_default,
+ "page", "pfn",
+ "alloc_order", "fallback_order", "pageblock_order",
+ "alloc_migratetype", "fallback_migratetype",
+ "fragmenting", "change_ownership");
+
+sub read_statline($) {
+ my $pid = $_[0];
+ my $statline;
+
+ if (open(STAT, "/proc/$pid/stat")) {
+ $statline = <STAT>;
+ close(STAT);
+ }
+
+ if ($statline eq '') {
+ $statline = "-1 (UNKNOWN_PROCESS_NAME) R 0";
+ }
+
+ return $statline;
+}
+
+sub guess_process_pid($$) {
+ my $pid = $_[0];
+ my $statline = $_[1];
+
+ if ($pid == 0) {
+ return "swapper-0";
+ }
+
+ if ($statline !~ /$regex_statname/o) {
+ die("Failed to math stat line for process name :: $statline");
+ }
+ return "$1-$pid";
+}
+
+sub parent_info($$) {
+ my $pid = $_[0];
+ my $statline = $_[1];
+ my $ppid;
+
+ if ($pid == 0) {
+ return "NOPARENT-0";
+ }
+
+ if ($statline !~ /$regex_statppid/o) {
+ die("Failed to match stat line process ppid:: $statline");
+ }
+
+ # Read the ppid stat line
+ $ppid = $1;
+ return guess_process_pid($ppid, read_statline($ppid));
+}
+
+sub process_events {
+ my $traceevent;
+ my $process_pid;
+ my $cpus;
+ my $timestamp;
+ my $tracepoint;
+ my $details;
+ my $statline;
+
+ # Read each line of the event log
+EVENT_PROCESS:
+ while ($traceevent = <STDIN>) {
+ if ($traceevent =~ /$regex_traceevent/o) {
+ $process_pid = $1;
+ $tracepoint = $4;
+
+ if ($opt_read_procstat || $opt_prepend_parent) {
+ $process_pid =~ /(.*)-([0-9]*)$/;
+ my $process = $1;
+ my $pid = $2;
+
+ $statline = read_statline($pid);
+
+ if ($opt_read_procstat && $process eq '') {
+ $process_pid = guess_process_pid($pid, $statline);
+ }
+
+ if ($opt_prepend_parent) {
+ $process_pid = parent_info($pid, $statline) . " :: $process_pid";
+ }
+ }
+
+ # Unnecessary in this script. Uncomment if required
+ # $cpus = $2;
+ # $timestamp = $3;
+ } else {
+ next;
+ }
+
+ # Perl Switch() sucks majorly
+ if ($tracepoint eq "mm_page_alloc") {
+ $perprocesspid{$process_pid}->{MM_PAGE_ALLOC}++;
+ } elsif ($tracepoint eq "mm_page_free") {
+ $perprocesspid{$process_pid}->{MM_PAGE_FREE}++
+ } elsif ($tracepoint eq "mm_page_free_batched") {
+ $perprocesspid{$process_pid}->{MM_PAGE_FREE_BATCHED}++;
+ } elsif ($tracepoint eq "mm_page_pcpu_drain") {
+ $perprocesspid{$process_pid}->{MM_PAGE_PCPU_DRAIN}++;
+ $perprocesspid{$process_pid}->{STATE_PCPU_PAGES_DRAINED}++;
+ } elsif ($tracepoint eq "mm_page_alloc_zone_locked") {
+ $perprocesspid{$process_pid}->{MM_PAGE_ALLOC_ZONE_LOCKED}++;
+ $perprocesspid{$process_pid}->{STATE_PCPU_PAGES_REFILLED}++;
+ } elsif ($tracepoint eq "mm_page_alloc_extfrag") {
+
+ # Extract the details of the event now
+ $details = $5;
+
+ my ($page, $pfn);
+ my ($alloc_order, $fallback_order, $pageblock_order);
+ my ($alloc_migratetype, $fallback_migratetype);
+ my ($fragmenting, $change_ownership);
+
+ if ($details !~ /$regex_fragdetails/o) {
+ print "WARNING: Failed to parse mm_page_alloc_extfrag as expected\n";
+ next;
+ }
+
+ $perprocesspid{$process_pid}->{MM_PAGE_ALLOC_EXTFRAG}++;
+ $page = $1;
+ $pfn = $2;
+ $alloc_order = $3;
+ $fallback_order = $4;
+ $pageblock_order = $5;
+ $alloc_migratetype = $6;
+ $fallback_migratetype = $7;
+ $fragmenting = $8;
+ $change_ownership = $9;
+
+ if ($fragmenting) {
+ $perprocesspid{$process_pid}->{HIGH_EXT_FRAG}++;
+ if ($fallback_order <= 3) {
+ $perprocesspid{$process_pid}->{HIGH_EXT_FRAGMENT_SEVERE}++;
+ } else {
+ $perprocesspid{$process_pid}->{HIGH_EXT_FRAGMENT_MODERATE}++;
+ }
+ }
+ if ($change_ownership) {
+ $perprocesspid{$process_pid}->{HIGH_EXT_FRAGMENT_CHANGED}++;
+ }
+ } else {
+ $perprocesspid{$process_pid}->{EVENT_UNKNOWN}++;
+ }
+
+ # Catch a full pcpu drain event
+ if ($perprocesspid{$process_pid}->{STATE_PCPU_PAGES_DRAINED} &&
+ $tracepoint ne "mm_page_pcpu_drain") {
+
+ $perprocesspid{$process_pid}->{HIGH_PCPU_DRAINS}++;
+ $perprocesspid{$process_pid}->{STATE_PCPU_PAGES_DRAINED} = 0;
+ }
+
+ # Catch a full pcpu refill event
+ if ($perprocesspid{$process_pid}->{STATE_PCPU_PAGES_REFILLED} &&
+ $tracepoint ne "mm_page_alloc_zone_locked") {
+ $perprocesspid{$process_pid}->{HIGH_PCPU_REFILLS}++;
+ $perprocesspid{$process_pid}->{STATE_PCPU_PAGES_REFILLED} = 0;
+ }
+
+ if ($sigint_pending) {
+ last EVENT_PROCESS;
+ }
+ }
+}
+
+sub dump_stats {
+ my $hashref = shift;
+ my %stats = %$hashref;
+
+ # Dump per-process stats
+ my $process_pid;
+ my $max_strlen = 0;
+
+ # Get the maximum process name
+ foreach $process_pid (keys %perprocesspid) {
+ my $len = length($process_pid);
+ if ($len > $max_strlen) {
+ $max_strlen = $len;
+ }
+ }
+ $max_strlen += 2;
+
+ printf("\n");
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s %8s %8s %8s %8s %8s %8s %8s\n",
+ "Process", "Pages", "Pages", "Pages", "Pages", "PCPU", "PCPU", "PCPU", "Fragment", "Fragment", "MigType", "Fragment", "Fragment", "Unknown");
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s %8s %8s %8s %8s %8s %8s %8s\n",
+ "details", "allocd", "allocd", "freed", "freed", "pages", "drains", "refills", "Fallback", "Causing", "Changed", "Severe", "Moderate", "");
+
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s %8s %8s %8s %8s %8s %8s %8s\n",
+ "", "", "under lock", "direct", "pagevec", "drain", "", "", "", "", "", "", "", "");
+
+ foreach $process_pid (keys %stats) {
+ # Dump final aggregates
+ if ($stats{$process_pid}->{STATE_PCPU_PAGES_DRAINED}) {
+ $stats{$process_pid}->{HIGH_PCPU_DRAINS}++;
+ $stats{$process_pid}->{STATE_PCPU_PAGES_DRAINED} = 0;
+ }
+ if ($stats{$process_pid}->{STATE_PCPU_PAGES_REFILLED}) {
+ $stats{$process_pid}->{HIGH_PCPU_REFILLS}++;
+ $stats{$process_pid}->{STATE_PCPU_PAGES_REFILLED} = 0;
+ }
+
+ printf("%-" . $max_strlen . "s %8d %10d %8d %8d %8d %8d %8d %8d %8d %8d %8d %8d %8d\n",
+ $process_pid,
+ $stats{$process_pid}->{MM_PAGE_ALLOC},
+ $stats{$process_pid}->{MM_PAGE_ALLOC_ZONE_LOCKED},
+ $stats{$process_pid}->{MM_PAGE_FREE},
+ $stats{$process_pid}->{MM_PAGE_FREE_BATCHED},
+ $stats{$process_pid}->{MM_PAGE_PCPU_DRAIN},
+ $stats{$process_pid}->{HIGH_PCPU_DRAINS},
+ $stats{$process_pid}->{HIGH_PCPU_REFILLS},
+ $stats{$process_pid}->{MM_PAGE_ALLOC_EXTFRAG},
+ $stats{$process_pid}->{HIGH_EXT_FRAG},
+ $stats{$process_pid}->{HIGH_EXT_FRAGMENT_CHANGED},
+ $stats{$process_pid}->{HIGH_EXT_FRAGMENT_SEVERE},
+ $stats{$process_pid}->{HIGH_EXT_FRAGMENT_MODERATE},
+ $stats{$process_pid}->{EVENT_UNKNOWN});
+ }
+}
+
+sub aggregate_perprocesspid() {
+ my $process_pid;
+ my $process;
+ undef %perprocess;
+
+ foreach $process_pid (keys %perprocesspid) {
+ $process = $process_pid;
+ $process =~ s/-([0-9])*$//;
+ if ($process eq '') {
+ $process = "NO_PROCESS_NAME";
+ }
+
+ $perprocess{$process}->{MM_PAGE_ALLOC} += $perprocesspid{$process_pid}->{MM_PAGE_ALLOC};
+ $perprocess{$process}->{MM_PAGE_ALLOC_ZONE_LOCKED} += $perprocesspid{$process_pid}->{MM_PAGE_ALLOC_ZONE_LOCKED};
+ $perprocess{$process}->{MM_PAGE_FREE} += $perprocesspid{$process_pid}->{MM_PAGE_FREE};
+ $perprocess{$process}->{MM_PAGE_FREE_BATCHED} += $perprocesspid{$process_pid}->{MM_PAGE_FREE_BATCHED};
+ $perprocess{$process}->{MM_PAGE_PCPU_DRAIN} += $perprocesspid{$process_pid}->{MM_PAGE_PCPU_DRAIN};
+ $perprocess{$process}->{HIGH_PCPU_DRAINS} += $perprocesspid{$process_pid}->{HIGH_PCPU_DRAINS};
+ $perprocess{$process}->{HIGH_PCPU_REFILLS} += $perprocesspid{$process_pid}->{HIGH_PCPU_REFILLS};
+ $perprocess{$process}->{MM_PAGE_ALLOC_EXTFRAG} += $perprocesspid{$process_pid}->{MM_PAGE_ALLOC_EXTFRAG};
+ $perprocess{$process}->{HIGH_EXT_FRAG} += $perprocesspid{$process_pid}->{HIGH_EXT_FRAG};
+ $perprocess{$process}->{HIGH_EXT_FRAGMENT_CHANGED} += $perprocesspid{$process_pid}->{HIGH_EXT_FRAGMENT_CHANGED};
+ $perprocess{$process}->{HIGH_EXT_FRAGMENT_SEVERE} += $perprocesspid{$process_pid}->{HIGH_EXT_FRAGMENT_SEVERE};
+ $perprocess{$process}->{HIGH_EXT_FRAGMENT_MODERATE} += $perprocesspid{$process_pid}->{HIGH_EXT_FRAGMENT_MODERATE};
+ $perprocess{$process}->{EVENT_UNKNOWN} += $perprocesspid{$process_pid}->{EVENT_UNKNOWN};
+ }
+}
+
+sub report() {
+ if (!$opt_ignorepid) {
+ dump_stats(\%perprocesspid);
+ } else {
+ aggregate_perprocesspid();
+ dump_stats(\%perprocess);
+ }
+}
+
+# Process events or signals until neither is available
+sub signal_loop() {
+ my $sigint_processed;
+ do {
+ $sigint_processed = 0;
+ process_events();
+
+ # Handle pending signals if any
+ if ($sigint_pending) {
+ my $current_time = time;
+
+ if ($sigint_exit) {
+ print "Received exit signal\n";
+ $sigint_pending = 0;
+ }
+ if ($sigint_report) {
+ if ($current_time >= $sigint_received + 2) {
+ report();
+ $sigint_report = 0;
+ $sigint_pending = 0;
+ $sigint_processed = 1;
+ }
+ }
+ }
+ } while ($sigint_pending || $sigint_processed);
+}
+
+signal_loop();
+report();
diff --git a/Documentation/trace/postprocess/trace-vmscan-postprocess.pl b/Documentation/trace/postprocess/trace-vmscan-postprocess.pl
new file mode 100644
index 000000000..2f4e39875
--- /dev/null
+++ b/Documentation/trace/postprocess/trace-vmscan-postprocess.pl
@@ -0,0 +1,758 @@
+#!/usr/bin/env perl
+# This is a POC for reading the text representation of trace output related to
+# page reclaim. It makes an attempt to extract some high-level information on
+# what is going on. The accuracy of the parser may vary
+#
+# Example usage: trace-vmscan-postprocess.pl < /sys/kernel/debug/tracing/trace_pipe
+# other options
+# --read-procstat If the trace lacks process info, get it from /proc
+# --ignore-pid Aggregate processes of the same name together
+#
+# Copyright (c) IBM Corporation 2009
+# Author: Mel Gorman <mel@csn.ul.ie>
+use strict;
+use Getopt::Long;
+
+# Tracepoint events
+use constant MM_VMSCAN_DIRECT_RECLAIM_BEGIN => 1;
+use constant MM_VMSCAN_DIRECT_RECLAIM_END => 2;
+use constant MM_VMSCAN_KSWAPD_WAKE => 3;
+use constant MM_VMSCAN_KSWAPD_SLEEP => 4;
+use constant MM_VMSCAN_LRU_SHRINK_ACTIVE => 5;
+use constant MM_VMSCAN_LRU_SHRINK_INACTIVE => 6;
+use constant MM_VMSCAN_LRU_ISOLATE => 7;
+use constant MM_VMSCAN_WRITEPAGE_FILE_SYNC => 8;
+use constant MM_VMSCAN_WRITEPAGE_ANON_SYNC => 9;
+use constant MM_VMSCAN_WRITEPAGE_FILE_ASYNC => 10;
+use constant MM_VMSCAN_WRITEPAGE_ANON_ASYNC => 11;
+use constant MM_VMSCAN_WRITEPAGE_ASYNC => 12;
+use constant EVENT_UNKNOWN => 13;
+
+# Per-order events
+use constant MM_VMSCAN_DIRECT_RECLAIM_BEGIN_PERORDER => 11;
+use constant MM_VMSCAN_WAKEUP_KSWAPD_PERORDER => 12;
+use constant MM_VMSCAN_KSWAPD_WAKE_PERORDER => 13;
+use constant HIGH_KSWAPD_REWAKEUP_PERORDER => 14;
+
+# Constants used to track state
+use constant STATE_DIRECT_BEGIN => 15;
+use constant STATE_DIRECT_ORDER => 16;
+use constant STATE_KSWAPD_BEGIN => 17;
+use constant STATE_KSWAPD_ORDER => 18;
+
+# High-level events extrapolated from tracepoints
+use constant HIGH_DIRECT_RECLAIM_LATENCY => 19;
+use constant HIGH_KSWAPD_LATENCY => 20;
+use constant HIGH_KSWAPD_REWAKEUP => 21;
+use constant HIGH_NR_SCANNED => 22;
+use constant HIGH_NR_TAKEN => 23;
+use constant HIGH_NR_RECLAIMED => 24;
+use constant HIGH_NR_FILE_SCANNED => 25;
+use constant HIGH_NR_ANON_SCANNED => 26;
+use constant HIGH_NR_FILE_RECLAIMED => 27;
+use constant HIGH_NR_ANON_RECLAIMED => 28;
+
+my %perprocesspid;
+my %perprocess;
+my %last_procmap;
+my $opt_ignorepid;
+my $opt_read_procstat;
+
+my $total_wakeup_kswapd;
+my ($total_direct_reclaim, $total_direct_nr_scanned);
+my ($total_direct_nr_file_scanned, $total_direct_nr_anon_scanned);
+my ($total_direct_latency, $total_kswapd_latency);
+my ($total_direct_nr_reclaimed);
+my ($total_direct_nr_file_reclaimed, $total_direct_nr_anon_reclaimed);
+my ($total_direct_writepage_file_sync, $total_direct_writepage_file_async);
+my ($total_direct_writepage_anon_sync, $total_direct_writepage_anon_async);
+my ($total_kswapd_nr_scanned, $total_kswapd_wake);
+my ($total_kswapd_nr_file_scanned, $total_kswapd_nr_anon_scanned);
+my ($total_kswapd_writepage_file_sync, $total_kswapd_writepage_file_async);
+my ($total_kswapd_writepage_anon_sync, $total_kswapd_writepage_anon_async);
+my ($total_kswapd_nr_reclaimed);
+my ($total_kswapd_nr_file_reclaimed, $total_kswapd_nr_anon_reclaimed);
+
+# Catch sigint and exit on request
+my $sigint_report = 0;
+my $sigint_exit = 0;
+my $sigint_pending = 0;
+my $sigint_received = 0;
+sub sigint_handler {
+ my $current_time = time;
+ if ($current_time - 2 > $sigint_received) {
+ print "SIGINT received, report pending. Hit ctrl-c again to exit\n";
+ $sigint_report = 1;
+ } else {
+ if (!$sigint_exit) {
+ print "Second SIGINT received quickly, exiting\n";
+ }
+ $sigint_exit++;
+ }
+
+ if ($sigint_exit > 3) {
+ print "Many SIGINTs received, exiting now without report\n";
+ exit;
+ }
+
+ $sigint_received = $current_time;
+ $sigint_pending = 1;
+}
+$SIG{INT} = "sigint_handler";
+
+# Parse command line options
+GetOptions(
+ 'ignore-pid' => \$opt_ignorepid,
+ 'read-procstat' => \$opt_read_procstat,
+);
+
+# Defaults for dynamically discovered regex's
+my $regex_direct_begin_default = 'order=([0-9]*) may_writepage=([0-9]*) gfp_flags=([A-Z_|]*)';
+my $regex_direct_end_default = 'nr_reclaimed=([0-9]*)';
+my $regex_kswapd_wake_default = 'nid=([0-9]*) order=([0-9]*)';
+my $regex_kswapd_sleep_default = 'nid=([0-9]*)';
+my $regex_wakeup_kswapd_default = 'nid=([0-9]*) zid=([0-9]*) order=([0-9]*) gfp_flags=([A-Z_|]*)';
+my $regex_lru_isolate_default = 'isolate_mode=([0-9]*) classzone_idx=([0-9]*) order=([0-9]*) nr_requested=([0-9]*) nr_scanned=([0-9]*) nr_skipped=([0-9]*) nr_taken=([0-9]*) lru=([a-z_]*)';
+my $regex_lru_shrink_inactive_default = 'nid=([0-9]*) nr_scanned=([0-9]*) nr_reclaimed=([0-9]*) nr_dirty=([0-9]*) nr_writeback=([0-9]*) nr_congested=([0-9]*) nr_immediate=([0-9]*) nr_activate_anon=([0-9]*) nr_activate_file=([0-9]*) nr_ref_keep=([0-9]*) nr_unmap_fail=([0-9]*) priority=([0-9]*) flags=([A-Z_|]*)';
+my $regex_lru_shrink_active_default = 'lru=([A-Z_]*) nr_scanned=([0-9]*) nr_rotated=([0-9]*) priority=([0-9]*)';
+my $regex_writepage_default = 'page=([0-9a-f]*) pfn=([0-9]*) flags=([A-Z_|]*)';
+
+# Dyanically discovered regex
+my $regex_direct_begin;
+my $regex_direct_end;
+my $regex_kswapd_wake;
+my $regex_kswapd_sleep;
+my $regex_wakeup_kswapd;
+my $regex_lru_isolate;
+my $regex_lru_shrink_inactive;
+my $regex_lru_shrink_active;
+my $regex_writepage;
+
+# Static regex used. Specified like this for readability and for use with /o
+# (process_pid) (cpus ) ( time ) (tpoint ) (details)
+my $regex_traceevent = '\s*([a-zA-Z0-9-]*)\s*(\[[0-9]*\])(\s*[dX.][Nnp.][Hhs.][0-9a-fA-F.]*|)\s*([0-9.]*):\s*([a-zA-Z_]*):\s*(.*)';
+my $regex_statname = '[-0-9]*\s\((.*)\).*';
+my $regex_statppid = '[-0-9]*\s\(.*\)\s[A-Za-z]\s([0-9]*).*';
+
+sub generate_traceevent_regex {
+ my $event = shift;
+ my $default = shift;
+ my $regex;
+
+ # Read the event format or use the default
+ if (!open (FORMAT, "/sys/kernel/debug/tracing/events/$event/format")) {
+ print("WARNING: Event $event format string not found\n");
+ return $default;
+ } else {
+ my $line;
+ while (!eof(FORMAT)) {
+ $line = <FORMAT>;
+ $line =~ s/, REC->.*//;
+ if ($line =~ /^print fmt:\s"(.*)".*/) {
+ $regex = $1;
+ $regex =~ s/%s/\([0-9a-zA-Z|_]*\)/g;
+ $regex =~ s/%p/\([0-9a-f]*\)/g;
+ $regex =~ s/%d/\([-0-9]*\)/g;
+ $regex =~ s/%ld/\([-0-9]*\)/g;
+ $regex =~ s/%lu/\([0-9]*\)/g;
+ }
+ }
+ }
+
+ # Can't handle the print_flags stuff but in the context of this
+ # script, it really doesn't matter
+ $regex =~ s/\(REC.*\) \? __print_flags.*//;
+
+ # Verify fields are in the right order
+ my $tuple;
+ foreach $tuple (split /\s/, $regex) {
+ my ($key, $value) = split(/=/, $tuple);
+ my $expected = shift;
+ if ($key ne $expected) {
+ print("WARNING: Format not as expected for event $event '$key' != '$expected'\n");
+ $regex =~ s/$key=\((.*)\)/$key=$1/;
+ }
+ }
+
+ if (defined shift) {
+ die("Fewer fields than expected in format");
+ }
+
+ return $regex;
+}
+
+$regex_direct_begin = generate_traceevent_regex(
+ "vmscan/mm_vmscan_direct_reclaim_begin",
+ $regex_direct_begin_default,
+ "order", "may_writepage",
+ "gfp_flags");
+$regex_direct_end = generate_traceevent_regex(
+ "vmscan/mm_vmscan_direct_reclaim_end",
+ $regex_direct_end_default,
+ "nr_reclaimed");
+$regex_kswapd_wake = generate_traceevent_regex(
+ "vmscan/mm_vmscan_kswapd_wake",
+ $regex_kswapd_wake_default,
+ "nid", "order");
+$regex_kswapd_sleep = generate_traceevent_regex(
+ "vmscan/mm_vmscan_kswapd_sleep",
+ $regex_kswapd_sleep_default,
+ "nid");
+$regex_wakeup_kswapd = generate_traceevent_regex(
+ "vmscan/mm_vmscan_wakeup_kswapd",
+ $regex_wakeup_kswapd_default,
+ "nid", "zid", "order", "gfp_flags");
+$regex_lru_isolate = generate_traceevent_regex(
+ "vmscan/mm_vmscan_lru_isolate",
+ $regex_lru_isolate_default,
+ "isolate_mode", "classzone_idx", "order",
+ "nr_requested", "nr_scanned", "nr_skipped", "nr_taken",
+ "lru");
+$regex_lru_shrink_inactive = generate_traceevent_regex(
+ "vmscan/mm_vmscan_lru_shrink_inactive",
+ $regex_lru_shrink_inactive_default,
+ "nid", "nr_scanned", "nr_reclaimed", "nr_dirty", "nr_writeback",
+ "nr_congested", "nr_immediate", "nr_activate_anon",
+ "nr_activate_file", "nr_ref_keep",
+ "nr_unmap_fail", "priority", "flags");
+$regex_lru_shrink_active = generate_traceevent_regex(
+ "vmscan/mm_vmscan_lru_shrink_active",
+ $regex_lru_shrink_active_default,
+ "nid", "zid",
+ "lru",
+ "nr_scanned", "nr_rotated", "priority");
+$regex_writepage = generate_traceevent_regex(
+ "vmscan/mm_vmscan_writepage",
+ $regex_writepage_default,
+ "page", "pfn", "flags");
+
+sub read_statline($) {
+ my $pid = $_[0];
+ my $statline;
+
+ if (open(STAT, "/proc/$pid/stat")) {
+ $statline = <STAT>;
+ close(STAT);
+ }
+
+ if ($statline eq '') {
+ $statline = "-1 (UNKNOWN_PROCESS_NAME) R 0";
+ }
+
+ return $statline;
+}
+
+sub guess_process_pid($$) {
+ my $pid = $_[0];
+ my $statline = $_[1];
+
+ if ($pid == 0) {
+ return "swapper-0";
+ }
+
+ if ($statline !~ /$regex_statname/o) {
+ die("Failed to math stat line for process name :: $statline");
+ }
+ return "$1-$pid";
+}
+
+# Convert sec.usec timestamp format
+sub timestamp_to_ms($) {
+ my $timestamp = $_[0];
+
+ my ($sec, $usec) = split (/\./, $timestamp);
+ return ($sec * 1000) + ($usec / 1000);
+}
+
+sub process_events {
+ my $traceevent;
+ my $process_pid;
+ my $cpus;
+ my $timestamp;
+ my $tracepoint;
+ my $details;
+ my $statline;
+
+ # Read each line of the event log
+EVENT_PROCESS:
+ while ($traceevent = <STDIN>) {
+ if ($traceevent =~ /$regex_traceevent/o) {
+ $process_pid = $1;
+ $timestamp = $4;
+ $tracepoint = $5;
+
+ $process_pid =~ /(.*)-([0-9]*)$/;
+ my $process = $1;
+ my $pid = $2;
+
+ if ($process eq "") {
+ $process = $last_procmap{$pid};
+ $process_pid = "$process-$pid";
+ }
+ $last_procmap{$pid} = $process;
+
+ if ($opt_read_procstat) {
+ $statline = read_statline($pid);
+ if ($opt_read_procstat && $process eq '') {
+ $process_pid = guess_process_pid($pid, $statline);
+ }
+ }
+ } else {
+ next;
+ }
+
+ # Perl Switch() sucks majorly
+ if ($tracepoint eq "mm_vmscan_direct_reclaim_begin") {
+ $timestamp = timestamp_to_ms($timestamp);
+ $perprocesspid{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN}++;
+ $perprocesspid{$process_pid}->{STATE_DIRECT_BEGIN} = $timestamp;
+
+ $details = $6;
+ if ($details !~ /$regex_direct_begin/o) {
+ print "WARNING: Failed to parse mm_vmscan_direct_reclaim_begin as expected\n";
+ print " $details\n";
+ print " $regex_direct_begin\n";
+ next;
+ }
+ my $order = $1;
+ $perprocesspid{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN_PERORDER}[$order]++;
+ $perprocesspid{$process_pid}->{STATE_DIRECT_ORDER} = $order;
+ } elsif ($tracepoint eq "mm_vmscan_direct_reclaim_end") {
+ # Count the event itself
+ my $index = $perprocesspid{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_END};
+ $perprocesspid{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_END}++;
+
+ # Record how long direct reclaim took this time
+ if (defined $perprocesspid{$process_pid}->{STATE_DIRECT_BEGIN}) {
+ $timestamp = timestamp_to_ms($timestamp);
+ my $order = $perprocesspid{$process_pid}->{STATE_DIRECT_ORDER};
+ my $latency = ($timestamp - $perprocesspid{$process_pid}->{STATE_DIRECT_BEGIN});
+ $perprocesspid{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index] = "$order-$latency";
+ }
+ } elsif ($tracepoint eq "mm_vmscan_kswapd_wake") {
+ $details = $6;
+ if ($details !~ /$regex_kswapd_wake/o) {
+ print "WARNING: Failed to parse mm_vmscan_kswapd_wake as expected\n";
+ print " $details\n";
+ print " $regex_kswapd_wake\n";
+ next;
+ }
+
+ my $order = $2;
+ $perprocesspid{$process_pid}->{STATE_KSWAPD_ORDER} = $order;
+ if (!$perprocesspid{$process_pid}->{STATE_KSWAPD_BEGIN}) {
+ $timestamp = timestamp_to_ms($timestamp);
+ $perprocesspid{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE}++;
+ $perprocesspid{$process_pid}->{STATE_KSWAPD_BEGIN} = $timestamp;
+ $perprocesspid{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE_PERORDER}[$order]++;
+ } else {
+ $perprocesspid{$process_pid}->{HIGH_KSWAPD_REWAKEUP}++;
+ $perprocesspid{$process_pid}->{HIGH_KSWAPD_REWAKEUP_PERORDER}[$order]++;
+ }
+ } elsif ($tracepoint eq "mm_vmscan_kswapd_sleep") {
+
+ # Count the event itself
+ my $index = $perprocesspid{$process_pid}->{MM_VMSCAN_KSWAPD_SLEEP};
+ $perprocesspid{$process_pid}->{MM_VMSCAN_KSWAPD_SLEEP}++;
+
+ # Record how long kswapd was awake
+ $timestamp = timestamp_to_ms($timestamp);
+ my $order = $perprocesspid{$process_pid}->{STATE_KSWAPD_ORDER};
+ my $latency = ($timestamp - $perprocesspid{$process_pid}->{STATE_KSWAPD_BEGIN});
+ $perprocesspid{$process_pid}->{HIGH_KSWAPD_LATENCY}[$index] = "$order-$latency";
+ $perprocesspid{$process_pid}->{STATE_KSWAPD_BEGIN} = 0;
+ } elsif ($tracepoint eq "mm_vmscan_wakeup_kswapd") {
+ $perprocesspid{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD}++;
+
+ $details = $6;
+ if ($details !~ /$regex_wakeup_kswapd/o) {
+ print "WARNING: Failed to parse mm_vmscan_wakeup_kswapd as expected\n";
+ print " $details\n";
+ print " $regex_wakeup_kswapd\n";
+ next;
+ }
+ my $order = $3;
+ $perprocesspid{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD_PERORDER}[$order]++;
+ } elsif ($tracepoint eq "mm_vmscan_lru_isolate") {
+ $details = $6;
+ if ($details !~ /$regex_lru_isolate/o) {
+ print "WARNING: Failed to parse mm_vmscan_lru_isolate as expected\n";
+ print " $details\n";
+ print " $regex_lru_isolate/o\n";
+ next;
+ }
+ my $isolate_mode = $1;
+ my $nr_scanned = $5;
+ my $file = $8;
+
+ # To closer match vmstat scanning statistics, only count isolate_both
+ # and isolate_inactive as scanning. isolate_active is rotation
+ # isolate_inactive == 1
+ # isolate_active == 2
+ # isolate_both == 3
+ if ($isolate_mode != 2) {
+ $perprocesspid{$process_pid}->{HIGH_NR_SCANNED} += $nr_scanned;
+ if ($file =~ /_file/) {
+ $perprocesspid{$process_pid}->{HIGH_NR_FILE_SCANNED} += $nr_scanned;
+ } else {
+ $perprocesspid{$process_pid}->{HIGH_NR_ANON_SCANNED} += $nr_scanned;
+ }
+ }
+ } elsif ($tracepoint eq "mm_vmscan_lru_shrink_inactive") {
+ $details = $6;
+ if ($details !~ /$regex_lru_shrink_inactive/o) {
+ print "WARNING: Failed to parse mm_vmscan_lru_shrink_inactive as expected\n";
+ print " $details\n";
+ print " $regex_lru_shrink_inactive/o\n";
+ next;
+ }
+
+ my $nr_reclaimed = $3;
+ my $flags = $13;
+ my $file = 0;
+ if ($flags =~ /RECLAIM_WB_FILE/) {
+ $file = 1;
+ }
+ $perprocesspid{$process_pid}->{HIGH_NR_RECLAIMED} += $nr_reclaimed;
+ if ($file) {
+ $perprocesspid{$process_pid}->{HIGH_NR_FILE_RECLAIMED} += $nr_reclaimed;
+ } else {
+ $perprocesspid{$process_pid}->{HIGH_NR_ANON_RECLAIMED} += $nr_reclaimed;
+ }
+ } elsif ($tracepoint eq "mm_vmscan_writepage") {
+ $details = $6;
+ if ($details !~ /$regex_writepage/o) {
+ print "WARNING: Failed to parse mm_vmscan_writepage as expected\n";
+ print " $details\n";
+ print " $regex_writepage\n";
+ next;
+ }
+
+ my $flags = $3;
+ my $file = 0;
+ my $sync_io = 0;
+ if ($flags =~ /RECLAIM_WB_FILE/) {
+ $file = 1;
+ }
+ if ($flags =~ /RECLAIM_WB_SYNC/) {
+ $sync_io = 1;
+ }
+ if ($sync_io) {
+ if ($file) {
+ $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC}++;
+ } else {
+ $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC}++;
+ }
+ } else {
+ if ($file) {
+ $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC}++;
+ } else {
+ $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC}++;
+ }
+ }
+ } else {
+ $perprocesspid{$process_pid}->{EVENT_UNKNOWN}++;
+ }
+
+ if ($sigint_pending) {
+ last EVENT_PROCESS;
+ }
+ }
+}
+
+sub dump_stats {
+ my $hashref = shift;
+ my %stats = %$hashref;
+
+ # Dump per-process stats
+ my $process_pid;
+ my $max_strlen = 0;
+
+ # Get the maximum process name
+ foreach $process_pid (keys %perprocesspid) {
+ my $len = length($process_pid);
+ if ($len > $max_strlen) {
+ $max_strlen = $len;
+ }
+ }
+ $max_strlen += 2;
+
+ # Work out latencies
+ printf("\n") if !$opt_ignorepid;
+ printf("Reclaim latencies expressed as order-latency_in_ms\n") if !$opt_ignorepid;
+ foreach $process_pid (keys %stats) {
+
+ if (!$stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[0] &&
+ !$stats{$process_pid}->{HIGH_KSWAPD_LATENCY}[0]) {
+ next;
+ }
+
+ printf "%-" . $max_strlen . "s ", $process_pid if !$opt_ignorepid;
+ my $index = 0;
+ while (defined $stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index] ||
+ defined $stats{$process_pid}->{HIGH_KSWAPD_LATENCY}[$index]) {
+
+ if ($stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index]) {
+ printf("%s ", $stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index]) if !$opt_ignorepid;
+ my ($dummy, $latency) = split(/-/, $stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index]);
+ $total_direct_latency += $latency;
+ } else {
+ printf("%s ", $stats{$process_pid}->{HIGH_KSWAPD_LATENCY}[$index]) if !$opt_ignorepid;
+ my ($dummy, $latency) = split(/-/, $stats{$process_pid}->{HIGH_KSWAPD_LATENCY}[$index]);
+ $total_kswapd_latency += $latency;
+ }
+ $index++;
+ }
+ print "\n" if !$opt_ignorepid;
+ }
+
+ # Print out process activity
+ printf("\n");
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s %8s %8s\n", "Process", "Direct", "Wokeup", "Pages", "Pages", "Pages", "Pages", "Time");
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s %8s %8s\n", "details", "Rclms", "Kswapd", "Scanned", "Rclmed", "Sync-IO", "ASync-IO", "Stalled");
+ foreach $process_pid (keys %stats) {
+
+ if (!$stats{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN}) {
+ next;
+ }
+
+ $total_direct_reclaim += $stats{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN};
+ $total_wakeup_kswapd += $stats{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD};
+ $total_direct_nr_scanned += $stats{$process_pid}->{HIGH_NR_SCANNED};
+ $total_direct_nr_file_scanned += $stats{$process_pid}->{HIGH_NR_FILE_SCANNED};
+ $total_direct_nr_anon_scanned += $stats{$process_pid}->{HIGH_NR_ANON_SCANNED};
+ $total_direct_nr_reclaimed += $stats{$process_pid}->{HIGH_NR_RECLAIMED};
+ $total_direct_nr_file_reclaimed += $stats{$process_pid}->{HIGH_NR_FILE_RECLAIMED};
+ $total_direct_nr_anon_reclaimed += $stats{$process_pid}->{HIGH_NR_ANON_RECLAIMED};
+ $total_direct_writepage_file_sync += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC};
+ $total_direct_writepage_anon_sync += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC};
+ $total_direct_writepage_file_async += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC};
+
+ $total_direct_writepage_anon_async += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC};
+
+ my $index = 0;
+ my $this_reclaim_delay = 0;
+ while (defined $stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index]) {
+ my ($dummy, $latency) = split(/-/, $stats{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$index]);
+ $this_reclaim_delay += $latency;
+ $index++;
+ }
+
+ printf("%-" . $max_strlen . "s %8d %10d %8u %8u %8u %8u %8.3f",
+ $process_pid,
+ $stats{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN},
+ $stats{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD},
+ $stats{$process_pid}->{HIGH_NR_SCANNED},
+ $stats{$process_pid}->{HIGH_NR_FILE_SCANNED},
+ $stats{$process_pid}->{HIGH_NR_ANON_SCANNED},
+ $stats{$process_pid}->{HIGH_NR_RECLAIMED},
+ $stats{$process_pid}->{HIGH_NR_FILE_RECLAIMED},
+ $stats{$process_pid}->{HIGH_NR_ANON_RECLAIMED},
+ $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC} + $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC},
+ $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC} + $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC},
+ $this_reclaim_delay / 1000);
+
+ if ($stats{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN}) {
+ print " ";
+ for (my $order = 0; $order < 20; $order++) {
+ my $count = $stats{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN_PERORDER}[$order];
+ if ($count != 0) {
+ print "direct-$order=$count ";
+ }
+ }
+ }
+ if ($stats{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD}) {
+ print " ";
+ for (my $order = 0; $order < 20; $order++) {
+ my $count = $stats{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD_PERORDER}[$order];
+ if ($count != 0) {
+ print "wakeup-$order=$count ";
+ }
+ }
+ }
+
+ print "\n";
+ }
+
+ # Print out kswapd activity
+ printf("\n");
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s\n", "Kswapd", "Kswapd", "Order", "Pages", "Pages", "Pages", "Pages");
+ printf("%-" . $max_strlen . "s %8s %10s %8s %8s %8s %8s\n", "Instance", "Wakeups", "Re-wakeup", "Scanned", "Rclmed", "Sync-IO", "ASync-IO");
+ foreach $process_pid (keys %stats) {
+
+ if (!$stats{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE}) {
+ next;
+ }
+
+ $total_kswapd_wake += $stats{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE};
+ $total_kswapd_nr_scanned += $stats{$process_pid}->{HIGH_NR_SCANNED};
+ $total_kswapd_nr_file_scanned += $stats{$process_pid}->{HIGH_NR_FILE_SCANNED};
+ $total_kswapd_nr_anon_scanned += $stats{$process_pid}->{HIGH_NR_ANON_SCANNED};
+ $total_kswapd_nr_reclaimed += $stats{$process_pid}->{HIGH_NR_RECLAIMED};
+ $total_kswapd_nr_file_reclaimed += $stats{$process_pid}->{HIGH_NR_FILE_RECLAIMED};
+ $total_kswapd_nr_anon_reclaimed += $stats{$process_pid}->{HIGH_NR_ANON_RECLAIMED};
+ $total_kswapd_writepage_file_sync += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC};
+ $total_kswapd_writepage_anon_sync += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC};
+ $total_kswapd_writepage_file_async += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC};
+ $total_kswapd_writepage_anon_async += $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC};
+
+ printf("%-" . $max_strlen . "s %8d %10d %8u %8u %8i %8u",
+ $process_pid,
+ $stats{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE},
+ $stats{$process_pid}->{HIGH_KSWAPD_REWAKEUP},
+ $stats{$process_pid}->{HIGH_NR_SCANNED},
+ $stats{$process_pid}->{HIGH_NR_FILE_SCANNED},
+ $stats{$process_pid}->{HIGH_NR_ANON_SCANNED},
+ $stats{$process_pid}->{HIGH_NR_RECLAIMED},
+ $stats{$process_pid}->{HIGH_NR_FILE_RECLAIMED},
+ $stats{$process_pid}->{HIGH_NR_ANON_RECLAIMED},
+ $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC} + $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC},
+ $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC} + $stats{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC});
+
+ if ($stats{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE}) {
+ print " ";
+ for (my $order = 0; $order < 20; $order++) {
+ my $count = $stats{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE_PERORDER}[$order];
+ if ($count != 0) {
+ print "wake-$order=$count ";
+ }
+ }
+ }
+ if ($stats{$process_pid}->{HIGH_KSWAPD_REWAKEUP}) {
+ print " ";
+ for (my $order = 0; $order < 20; $order++) {
+ my $count = $stats{$process_pid}->{HIGH_KSWAPD_REWAKEUP_PERORDER}[$order];
+ if ($count != 0) {
+ print "rewake-$order=$count ";
+ }
+ }
+ }
+ printf("\n");
+ }
+
+ # Print out summaries
+ $total_direct_latency /= 1000;
+ $total_kswapd_latency /= 1000;
+ print "\nSummary\n";
+ print "Direct reclaims: $total_direct_reclaim\n";
+ print "Direct reclaim pages scanned: $total_direct_nr_scanned\n";
+ print "Direct reclaim file pages scanned: $total_direct_nr_file_scanned\n";
+ print "Direct reclaim anon pages scanned: $total_direct_nr_anon_scanned\n";
+ print "Direct reclaim pages reclaimed: $total_direct_nr_reclaimed\n";
+ print "Direct reclaim file pages reclaimed: $total_direct_nr_file_reclaimed\n";
+ print "Direct reclaim anon pages reclaimed: $total_direct_nr_anon_reclaimed\n";
+ print "Direct reclaim write file sync I/O: $total_direct_writepage_file_sync\n";
+ print "Direct reclaim write anon sync I/O: $total_direct_writepage_anon_sync\n";
+ print "Direct reclaim write file async I/O: $total_direct_writepage_file_async\n";
+ print "Direct reclaim write anon async I/O: $total_direct_writepage_anon_async\n";
+ print "Wake kswapd requests: $total_wakeup_kswapd\n";
+ printf "Time stalled direct reclaim: %-1.2f seconds\n", $total_direct_latency;
+ print "\n";
+ print "Kswapd wakeups: $total_kswapd_wake\n";
+ print "Kswapd pages scanned: $total_kswapd_nr_scanned\n";
+ print "Kswapd file pages scanned: $total_kswapd_nr_file_scanned\n";
+ print "Kswapd anon pages scanned: $total_kswapd_nr_anon_scanned\n";
+ print "Kswapd pages reclaimed: $total_kswapd_nr_reclaimed\n";
+ print "Kswapd file pages reclaimed: $total_kswapd_nr_file_reclaimed\n";
+ print "Kswapd anon pages reclaimed: $total_kswapd_nr_anon_reclaimed\n";
+ print "Kswapd reclaim write file sync I/O: $total_kswapd_writepage_file_sync\n";
+ print "Kswapd reclaim write anon sync I/O: $total_kswapd_writepage_anon_sync\n";
+ print "Kswapd reclaim write file async I/O: $total_kswapd_writepage_file_async\n";
+ print "Kswapd reclaim write anon async I/O: $total_kswapd_writepage_anon_async\n";
+ printf "Time kswapd awake: %-1.2f seconds\n", $total_kswapd_latency;
+}
+
+sub aggregate_perprocesspid() {
+ my $process_pid;
+ my $process;
+ undef %perprocess;
+
+ foreach $process_pid (keys %perprocesspid) {
+ $process = $process_pid;
+ $process =~ s/-([0-9])*$//;
+ if ($process eq '') {
+ $process = "NO_PROCESS_NAME";
+ }
+
+ $perprocess{$process}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN} += $perprocesspid{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN};
+ $perprocess{$process}->{MM_VMSCAN_KSWAPD_WAKE} += $perprocesspid{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE};
+ $perprocess{$process}->{MM_VMSCAN_WAKEUP_KSWAPD} += $perprocesspid{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD};
+ $perprocess{$process}->{HIGH_KSWAPD_REWAKEUP} += $perprocesspid{$process_pid}->{HIGH_KSWAPD_REWAKEUP};
+ $perprocess{$process}->{HIGH_NR_SCANNED} += $perprocesspid{$process_pid}->{HIGH_NR_SCANNED};
+ $perprocess{$process}->{HIGH_NR_FILE_SCANNED} += $perprocesspid{$process_pid}->{HIGH_NR_FILE_SCANNED};
+ $perprocess{$process}->{HIGH_NR_ANON_SCANNED} += $perprocesspid{$process_pid}->{HIGH_NR_ANON_SCANNED};
+ $perprocess{$process}->{HIGH_NR_RECLAIMED} += $perprocesspid{$process_pid}->{HIGH_NR_RECLAIMED};
+ $perprocess{$process}->{HIGH_NR_FILE_RECLAIMED} += $perprocesspid{$process_pid}->{HIGH_NR_FILE_RECLAIMED};
+ $perprocess{$process}->{HIGH_NR_ANON_RECLAIMED} += $perprocesspid{$process_pid}->{HIGH_NR_ANON_RECLAIMED};
+ $perprocess{$process}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC} += $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_SYNC};
+ $perprocess{$process}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC} += $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_SYNC};
+ $perprocess{$process}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC} += $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_FILE_ASYNC};
+ $perprocess{$process}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC} += $perprocesspid{$process_pid}->{MM_VMSCAN_WRITEPAGE_ANON_ASYNC};
+
+ for (my $order = 0; $order < 20; $order++) {
+ $perprocess{$process}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN_PERORDER}[$order] += $perprocesspid{$process_pid}->{MM_VMSCAN_DIRECT_RECLAIM_BEGIN_PERORDER}[$order];
+ $perprocess{$process}->{MM_VMSCAN_WAKEUP_KSWAPD_PERORDER}[$order] += $perprocesspid{$process_pid}->{MM_VMSCAN_WAKEUP_KSWAPD_PERORDER}[$order];
+ $perprocess{$process}->{MM_VMSCAN_KSWAPD_WAKE_PERORDER}[$order] += $perprocesspid{$process_pid}->{MM_VMSCAN_KSWAPD_WAKE_PERORDER}[$order];
+
+ }
+
+ # Aggregate direct reclaim latencies
+ my $wr_index = $perprocess{$process}->{MM_VMSCAN_DIRECT_RECLAIM_END};
+ my $rd_index = 0;
+ while (defined $perprocesspid{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$rd_index]) {
+ $perprocess{$process}->{HIGH_DIRECT_RECLAIM_LATENCY}[$wr_index] = $perprocesspid{$process_pid}->{HIGH_DIRECT_RECLAIM_LATENCY}[$rd_index];
+ $rd_index++;
+ $wr_index++;
+ }
+ $perprocess{$process}->{MM_VMSCAN_DIRECT_RECLAIM_END} = $wr_index;
+
+ # Aggregate kswapd latencies
+ my $wr_index = $perprocess{$process}->{MM_VMSCAN_KSWAPD_SLEEP};
+ my $rd_index = 0;
+ while (defined $perprocesspid{$process_pid}->{HIGH_KSWAPD_LATENCY}[$rd_index]) {
+ $perprocess{$process}->{HIGH_KSWAPD_LATENCY}[$wr_index] = $perprocesspid{$process_pid}->{HIGH_KSWAPD_LATENCY}[$rd_index];
+ $rd_index++;
+ $wr_index++;
+ }
+ $perprocess{$process}->{MM_VMSCAN_DIRECT_RECLAIM_END} = $wr_index;
+ }
+}
+
+sub report() {
+ if (!$opt_ignorepid) {
+ dump_stats(\%perprocesspid);
+ } else {
+ aggregate_perprocesspid();
+ dump_stats(\%perprocess);
+ }
+}
+
+# Process events or signals until neither is available
+sub signal_loop() {
+ my $sigint_processed;
+ do {
+ $sigint_processed = 0;
+ process_events();
+
+ # Handle pending signals if any
+ if ($sigint_pending) {
+ my $current_time = time;
+
+ if ($sigint_exit) {
+ print "Received exit signal\n";
+ $sigint_pending = 0;
+ }
+ if ($sigint_report) {
+ if ($current_time >= $sigint_received + 2) {
+ report();
+ $sigint_report = 0;
+ $sigint_pending = 0;
+ $sigint_processed = 1;
+ }
+ }
+ }
+ } while ($sigint_pending || $sigint_processed);
+}
+
+signal_loop();
+report();
diff --git a/Documentation/trace/ring-buffer-design.rst b/Documentation/trace/ring-buffer-design.rst
new file mode 100644
index 000000000..c5d77fcbb
--- /dev/null
+++ b/Documentation/trace/ring-buffer-design.rst
@@ -0,0 +1,983 @@
+.. SPDX-License-Identifier: GPL-2.0 OR GFDL-1.2-no-invariants-only
+
+===========================
+Lockless Ring Buffer Design
+===========================
+
+Copyright 2009 Red Hat Inc.
+
+:Author: Steven Rostedt <srostedt@redhat.com>
+:License: The GNU Free Documentation License, Version 1.2
+ (dual licensed under the GPL v2)
+:Reviewers: Mathieu Desnoyers, Huang Ying, Hidetoshi Seto,
+ and Frederic Weisbecker.
+
+
+Written for: 2.6.31
+
+Terminology used in this Document
+---------------------------------
+
+tail
+ - where new writes happen in the ring buffer.
+
+head
+ - where new reads happen in the ring buffer.
+
+producer
+ - the task that writes into the ring buffer (same as writer)
+
+writer
+ - same as producer
+
+consumer
+ - the task that reads from the buffer (same as reader)
+
+reader
+ - same as consumer.
+
+reader_page
+ - A page outside the ring buffer used solely (for the most part)
+ by the reader.
+
+head_page
+ - a pointer to the page that the reader will use next
+
+tail_page
+ - a pointer to the page that will be written to next
+
+commit_page
+ - a pointer to the page with the last finished non-nested write.
+
+cmpxchg
+ - hardware-assisted atomic transaction that performs the following::
+
+ A = B if previous A == C
+
+ R = cmpxchg(A, C, B) is saying that we replace A with B if and only
+ if current A is equal to C, and we put the old (current)
+ A into R
+
+ R gets the previous A regardless if A is updated with B or not.
+
+ To see if the update was successful a compare of ``R == C``
+ may be used.
+
+The Generic Ring Buffer
+-----------------------
+
+The ring buffer can be used in either an overwrite mode or in
+producer/consumer mode.
+
+Producer/consumer mode is where if the producer were to fill up the
+buffer before the consumer could free up anything, the producer
+will stop writing to the buffer. This will lose most recent events.
+
+Overwrite mode is where if the producer were to fill up the buffer
+before the consumer could free up anything, the producer will
+overwrite the older data. This will lose the oldest events.
+
+No two writers can write at the same time (on the same per-cpu buffer),
+but a writer may interrupt another writer, but it must finish writing
+before the previous writer may continue. This is very important to the
+algorithm. The writers act like a "stack". The way interrupts works
+enforces this behavior::
+
+
+ writer1 start
+ <preempted> writer2 start
+ <preempted> writer3 start
+ writer3 finishes
+ writer2 finishes
+ writer1 finishes
+
+This is very much like a writer being preempted by an interrupt and
+the interrupt doing a write as well.
+
+Readers can happen at any time. But no two readers may run at the
+same time, nor can a reader preempt/interrupt another reader. A reader
+cannot preempt/interrupt a writer, but it may read/consume from the
+buffer at the same time as a writer is writing, but the reader must be
+on another processor to do so. A reader may read on its own processor
+and can be preempted by a writer.
+
+A writer can preempt a reader, but a reader cannot preempt a writer.
+But a reader can read the buffer at the same time (on another processor)
+as a writer.
+
+The ring buffer is made up of a list of pages held together by a linked list.
+
+At initialization a reader page is allocated for the reader that is not
+part of the ring buffer.
+
+The head_page, tail_page and commit_page are all initialized to point
+to the same page.
+
+The reader page is initialized to have its next pointer pointing to
+the head page, and its previous pointer pointing to a page before
+the head page.
+
+The reader has its own page to use. At start up time, this page is
+allocated but is not attached to the list. When the reader wants
+to read from the buffer, if its page is empty (like it is on start-up),
+it will swap its page with the head_page. The old reader page will
+become part of the ring buffer and the head_page will be removed.
+The page after the inserted page (old reader_page) will become the
+new head page.
+
+Once the new page is given to the reader, the reader could do what
+it wants with it, as long as a writer has left that page.
+
+A sample of how the reader page is swapped: Note this does not
+show the head page in the buffer, it is for demonstrating a swap
+only.
+
+::
+
+ +------+
+ |reader| RING BUFFER
+ |page |
+ +------+
+ +---+ +---+ +---+
+ | |-->| |-->| |
+ | |<--| |<--| |
+ +---+ +---+ +---+
+ ^ | ^ |
+ | +-------------+ |
+ +-----------------+
+
+
+ +------+
+ |reader| RING BUFFER
+ |page |-------------------+
+ +------+ v
+ | +---+ +---+ +---+
+ | | |-->| |-->| |
+ | | |<--| |<--| |<-+
+ | +---+ +---+ +---+ |
+ | ^ | ^ | |
+ | | +-------------+ | |
+ | +-----------------+ |
+ +------------------------------------+
+
+ +------+
+ |reader| RING BUFFER
+ |page |-------------------+
+ +------+ <---------------+ v
+ | ^ +---+ +---+ +---+
+ | | | |-->| |-->| |
+ | | | | | |<--| |<-+
+ | | +---+ +---+ +---+ |
+ | | | ^ | |
+ | | +-------------+ | |
+ | +-----------------------------+ |
+ +------------------------------------+
+
+ +------+
+ |buffer| RING BUFFER
+ |page |-------------------+
+ +------+ <---------------+ v
+ | ^ +---+ +---+ +---+
+ | | | | | |-->| |
+ | | New | | | |<--| |<-+
+ | | Reader +---+ +---+ +---+ |
+ | | page ----^ | |
+ | | | |
+ | +-----------------------------+ |
+ +------------------------------------+
+
+
+
+It is possible that the page swapped is the commit page and the tail page,
+if what is in the ring buffer is less than what is held in a buffer page.
+
+::
+
+ reader page commit page tail page
+ | | |
+ v | |
+ +---+ | |
+ | |<----------+ |
+ | |<------------------------+
+ | |------+
+ +---+ |
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+This case is still valid for this algorithm.
+When the writer leaves the page, it simply goes into the ring buffer
+since the reader page still points to the next location in the ring
+buffer.
+
+
+The main pointers:
+
+ reader page
+ - The page used solely by the reader and is not part
+ of the ring buffer (may be swapped in)
+
+ head page
+ - the next page in the ring buffer that will be swapped
+ with the reader page.
+
+ tail page
+ - the page where the next write will take place.
+
+ commit page
+ - the page that last finished a write.
+
+The commit page only is updated by the outermost writer in the
+writer stack. A writer that preempts another writer will not move the
+commit page.
+
+When data is written into the ring buffer, a position is reserved
+in the ring buffer and passed back to the writer. When the writer
+is finished writing data into that position, it commits the write.
+
+Another write (or a read) may take place at anytime during this
+transaction. If another write happens it must finish before continuing
+with the previous write.
+
+
+ Write reserve::
+
+ Buffer page
+ +---------+
+ |written |
+ +---------+ <--- given back to writer (current commit)
+ |reserved |
+ +---------+ <--- tail pointer
+ | empty |
+ +---------+
+
+ Write commit::
+
+ Buffer page
+ +---------+
+ |written |
+ +---------+
+ |written |
+ +---------+ <--- next position for write (current commit)
+ | empty |
+ +---------+
+
+
+ If a write happens after the first reserve::
+
+ Buffer page
+ +---------+
+ |written |
+ +---------+ <-- current commit
+ |reserved |
+ +---------+ <--- given back to second writer
+ |reserved |
+ +---------+ <--- tail pointer
+
+ After second writer commits::
+
+
+ Buffer page
+ +---------+
+ |written |
+ +---------+ <--(last full commit)
+ |reserved |
+ +---------+
+ |pending |
+ |commit |
+ +---------+ <--- tail pointer
+
+ When the first writer commits::
+
+ Buffer page
+ +---------+
+ |written |
+ +---------+
+ |written |
+ +---------+
+ |written |
+ +---------+ <--(last full commit and tail pointer)
+
+
+The commit pointer points to the last write location that was
+committed without preempting another write. When a write that
+preempted another write is committed, it only becomes a pending commit
+and will not be a full commit until all writes have been committed.
+
+The commit page points to the page that has the last full commit.
+The tail page points to the page with the last write (before
+committing).
+
+The tail page is always equal to or after the commit page. It may
+be several pages ahead. If the tail page catches up to the commit
+page then no more writes may take place (regardless of the mode
+of the ring buffer: overwrite and produce/consumer).
+
+The order of pages is::
+
+ head page
+ commit page
+ tail page
+
+Possible scenario::
+
+ tail page
+ head page commit page |
+ | | |
+ v v v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+There is a special case that the head page is after either the commit page
+and possibly the tail page. That is when the commit (and tail) page has been
+swapped with the reader page. This is because the head page is always
+part of the ring buffer, but the reader page is not. Whenever there
+has been less than a full page that has been committed inside the ring buffer,
+and a reader swaps out a page, it will be swapping out the commit page.
+
+::
+
+ reader page commit page tail page
+ | | |
+ v | |
+ +---+ | |
+ | |<----------+ |
+ | |<------------------------+
+ | |------+
+ +---+ |
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+ ^
+ |
+ head page
+
+
+In this case, the head page will not move when the tail and commit
+move back into the ring buffer.
+
+The reader cannot swap a page into the ring buffer if the commit page
+is still on that page. If the read meets the last commit (real commit
+not pending or reserved), then there is nothing more to read.
+The buffer is considered empty until another full commit finishes.
+
+When the tail meets the head page, if the buffer is in overwrite mode,
+the head page will be pushed ahead one. If the buffer is in producer/consumer
+mode, the write will fail.
+
+Overwrite mode::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+ ^
+ |
+ head page
+
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+ ^
+ |
+ head page
+
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+ ^
+ |
+ head page
+
+Note, the reader page will still point to the previous head page.
+But when a swap takes place, it will use the most recent head page.
+
+
+Making the Ring Buffer Lockless:
+--------------------------------
+
+The main idea behind the lockless algorithm is to combine the moving
+of the head_page pointer with the swapping of pages with the reader.
+State flags are placed inside the pointer to the page. To do this,
+each page must be aligned in memory by 4 bytes. This will allow the 2
+least significant bits of the address to be used as flags, since
+they will always be zero for the address. To get the address,
+simply mask out the flags::
+
+ MASK = ~3
+
+ address & MASK
+
+Two flags will be kept by these two bits:
+
+ HEADER
+ - the page being pointed to is a head page
+
+ UPDATE
+ - the page being pointed to is being updated by a writer
+ and was or is about to be a head page.
+
+::
+
+ reader page
+ |
+ v
+ +---+
+ | |------+
+ +---+ |
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-H->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+
+The above pointer "-H->" would have the HEADER flag set. That is
+the next page is the next page to be swapped out by the reader.
+This pointer means the next page is the head page.
+
+When the tail page meets the head pointer, it will use cmpxchg to
+change the pointer to the UPDATE state::
+
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-H->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+"-U->" represents a pointer in the UPDATE state.
+
+Any access to the reader will need to take some sort of lock to serialize
+the readers. But the writers will never take a lock to write to the
+ring buffer. This means we only need to worry about a single reader,
+and writes only preempt in "stack" formation.
+
+When the reader tries to swap the page with the ring buffer, it
+will also use cmpxchg. If the flag bit in the pointer to the
+head page does not have the HEADER flag set, the compare will fail
+and the reader will need to look for the new head page and try again.
+Note, the flags UPDATE and HEADER are never set at the same time.
+
+The reader swaps the reader page as follows::
+
+ +------+
+ |reader| RING BUFFER
+ |page |
+ +------+
+ +---+ +---+ +---+
+ | |--->| |--->| |
+ | |<---| |<---| |
+ +---+ +---+ +---+
+ ^ | ^ |
+ | +---------------+ |
+ +-----H-------------+
+
+The reader sets the reader page next pointer as HEADER to the page after
+the head page::
+
+
+ +------+
+ |reader| RING BUFFER
+ |page |-------H-----------+
+ +------+ v
+ | +---+ +---+ +---+
+ | | |--->| |--->| |
+ | | |<---| |<---| |<-+
+ | +---+ +---+ +---+ |
+ | ^ | ^ | |
+ | | +---------------+ | |
+ | +-----H-------------+ |
+ +--------------------------------------+
+
+It does a cmpxchg with the pointer to the previous head page to make it
+point to the reader page. Note that the new pointer does not have the HEADER
+flag set. This action atomically moves the head page forward::
+
+ +------+
+ |reader| RING BUFFER
+ |page |-------H-----------+
+ +------+ v
+ | ^ +---+ +---+ +---+
+ | | | |-->| |-->| |
+ | | | |<--| |<--| |<-+
+ | | +---+ +---+ +---+ |
+ | | | ^ | |
+ | | +-------------+ | |
+ | +-----------------------------+ |
+ +------------------------------------+
+
+After the new head page is set, the previous pointer of the head page is
+updated to the reader page::
+
+ +------+
+ |reader| RING BUFFER
+ |page |-------H-----------+
+ +------+ <---------------+ v
+ | ^ +---+ +---+ +---+
+ | | | |-->| |-->| |
+ | | | | | |<--| |<-+
+ | | +---+ +---+ +---+ |
+ | | | ^ | |
+ | | +-------------+ | |
+ | +-----------------------------+ |
+ +------------------------------------+
+
+ +------+
+ |buffer| RING BUFFER
+ |page |-------H-----------+ <--- New head page
+ +------+ <---------------+ v
+ | ^ +---+ +---+ +---+
+ | | | | | |-->| |
+ | | New | | | |<--| |<-+
+ | | Reader +---+ +---+ +---+ |
+ | | page ----^ | |
+ | | | |
+ | +-----------------------------+ |
+ +------------------------------------+
+
+Another important point: The page that the reader page points back to
+by its previous pointer (the one that now points to the new head page)
+never points back to the reader page. That is because the reader page is
+not part of the ring buffer. Traversing the ring buffer via the next pointers
+will always stay in the ring buffer. Traversing the ring buffer via the
+prev pointers may not.
+
+Note, the way to determine a reader page is simply by examining the previous
+pointer of the page. If the next pointer of the previous page does not
+point back to the original page, then the original page is a reader page::
+
+
+ +--------+
+ | reader | next +----+
+ | page |-------->| |<====== (buffer page)
+ +--------+ +----+
+ | | ^
+ | v | next
+ prev | +----+
+ +------------->| |
+ +----+
+
+The way the head page moves forward:
+
+When the tail page meets the head page and the buffer is in overwrite mode
+and more writes take place, the head page must be moved forward before the
+writer may move the tail page. The way this is done is that the writer
+performs a cmpxchg to convert the pointer to the head page from the HEADER
+flag to have the UPDATE flag set. Once this is done, the reader will
+not be able to swap the head page from the buffer, nor will it be able to
+move the head page, until the writer is finished with the move.
+
+This eliminates any races that the reader can have on the writer. The reader
+must spin, and this is why the reader cannot preempt the writer::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-H->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The following page will be made into the new head page::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+After the new head page has been set, we can set the old head page
+pointer back to NORMAL::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+After the head page has been moved, the tail page may now move forward::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+
+The above are the trivial updates. Now for the more complex scenarios.
+
+
+As stated before, if enough writes preempt the first write, the
+tail page may make it all the way around the buffer and meet the commit
+page. At this time, we must start dropping writes (usually with some kind
+of warning to the user). But what happens if the commit was still on the
+reader page? The commit page is not part of the ring buffer. The tail page
+must account for this::
+
+
+ reader page commit page
+ | |
+ v |
+ +---+ |
+ | |<----------+
+ | |
+ | |------+
+ +---+ |
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-H->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+ ^
+ |
+ tail page
+
+If the tail page were to simply push the head page forward, the commit when
+leaving the reader page would not be pointing to the correct page.
+
+The solution to this is to test if the commit page is on the reader page
+before pushing the head page. If it is, then it can be assumed that the
+tail page wrapped the buffer, and we must drop new writes.
+
+This is not a race condition, because the commit page can only be moved
+by the outermost writer (the writer that was preempted).
+This means that the commit will not move while a writer is moving the
+tail page. The reader cannot swap the reader page if it is also being
+used as the commit page. The reader can simply check that the commit
+is off the reader page. Once the commit page leaves the reader page
+it will never go back on it unless a reader does another swap with the
+buffer page that is also the commit page.
+
+
+Nested writes
+-------------
+
+In the pushing forward of the tail page we must first push forward
+the head page if the head page is the next page. If the head page
+is not the next page, the tail page is simply updated with a cmpxchg.
+
+Only writers move the tail page. This must be done atomically to protect
+against nested writers::
+
+ temp_page = tail_page
+ next_page = temp_page->next
+ cmpxchg(tail_page, temp_page, next_page)
+
+The above will update the tail page if it is still pointing to the expected
+page. If this fails, a nested write pushed it forward, the current write
+does not need to push it::
+
+
+ temp page
+ |
+ v
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+Nested write comes in and moves the tail page forward::
+
+ tail page (moved by nested writer)
+ temp page |
+ | |
+ v v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The above would fail the cmpxchg, but since the tail page has already
+been moved forward, the writer will just try again to reserve storage
+on the new tail page.
+
+But the moving of the head page is a bit more complex::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-H->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The write converts the head page pointer to UPDATE::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+But if a nested writer preempts here, it will see that the next
+page is a head page, but it is also nested. It will detect that
+it is nested and will save that information. The detection is the
+fact that it sees the UPDATE flag instead of a HEADER or NORMAL
+pointer.
+
+The nested writer will set the new head page pointer::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+But it will not reset the update back to normal. Only the writer
+that converted a pointer from HEAD to UPDATE will convert it back
+to NORMAL::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+After the nested writer finishes, the outermost writer will convert
+the UPDATE pointer to NORMAL::
+
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+
+It can be even more complex if several nested writes came in and moved
+the tail page ahead several pages::
+
+
+ (first writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-H->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The write converts the head page pointer to UPDATE::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+Next writer comes in, and sees the update and sets up the new
+head page::
+
+ (second writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The nested writer moves the tail page forward. But does not set the old
+update page to NORMAL because it is not the outermost writer::
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+Another writer preempts and sees the page after the tail page is a head page.
+It changes it from HEAD to UPDATE::
+
+ (third writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-U->| |--->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The writer will move the head page forward::
+
+
+ (third writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-U->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+But now that the third writer did change the HEAD flag to UPDATE it
+will convert it to normal::
+
+
+ (third writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+
+Then it will move the tail page, and return back to the second writer::
+
+
+ (second writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+
+The second writer will fail to move the tail page because it was already
+moved, so it will try again and add its data to the new tail page.
+It will return to the first writer::
+
+
+ (first writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+The first writer cannot know atomically if the tail page moved
+while it updates the HEAD page. It will then update the head page to
+what it thinks is the new head page::
+
+
+ (first writer)
+
+ tail page
+ |
+ v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+Since the cmpxchg returns the old value of the pointer the first writer
+will see it succeeded in updating the pointer from NORMAL to HEAD.
+But as we can see, this is not good enough. It must also check to see
+if the tail page is either where it use to be or on the next page::
+
+
+ (first writer)
+
+ A B tail page
+ | | |
+ v v v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |-H->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+If tail page != A and tail page != B, then it must reset the pointer
+back to NORMAL. The fact that it only needs to worry about nested
+writers means that it only needs to check this after setting the HEAD page::
+
+
+ (first writer)
+
+ A B tail page
+ | | |
+ v v v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |-U->| |--->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
+
+Now the writer can update the head page. This is also why the head page must
+remain in UPDATE and only reset by the outermost writer. This prevents
+the reader from seeing the incorrect head page::
+
+
+ (first writer)
+
+ A B tail page
+ | | |
+ v v v
+ +---+ +---+ +---+ +---+
+ <---| |--->| |--->| |--->| |-H->
+ --->| |<---| |<---| |<---| |<---
+ +---+ +---+ +---+ +---+
diff --git a/Documentation/trace/rv/da_monitor_instrumentation.rst b/Documentation/trace/rv/da_monitor_instrumentation.rst
new file mode 100644
index 000000000..6c67c7b57
--- /dev/null
+++ b/Documentation/trace/rv/da_monitor_instrumentation.rst
@@ -0,0 +1,171 @@
+Deterministic Automata Instrumentation
+======================================
+
+The RV monitor file created by dot2k, with the name "$MODEL_NAME.c"
+includes a section dedicated to instrumentation.
+
+In the example of the wip.dot monitor created on [1], it will look like::
+
+ /*
+ * This is the instrumentation part of the monitor.
+ *
+ * This is the section where manual work is required. Here the kernel events
+ * are translated into model's event.
+ *
+ */
+ static void handle_preempt_disable(void *data, /* XXX: fill header */)
+ {
+ da_handle_event_wip(preempt_disable_wip);
+ }
+
+ static void handle_preempt_enable(void *data, /* XXX: fill header */)
+ {
+ da_handle_event_wip(preempt_enable_wip);
+ }
+
+ static void handle_sched_waking(void *data, /* XXX: fill header */)
+ {
+ da_handle_event_wip(sched_waking_wip);
+ }
+
+ static int enable_wip(void)
+ {
+ int retval;
+
+ retval = da_monitor_init_wip();
+ if (retval)
+ return retval;
+
+ rv_attach_trace_probe("wip", /* XXX: tracepoint */, handle_preempt_disable);
+ rv_attach_trace_probe("wip", /* XXX: tracepoint */, handle_preempt_enable);
+ rv_attach_trace_probe("wip", /* XXX: tracepoint */, handle_sched_waking);
+
+ return 0;
+ }
+
+The comment at the top of the section explains the general idea: the
+instrumentation section translates *kernel events* into the *model's
+event*.
+
+Tracing callback functions
+--------------------------
+
+The first three functions are the starting point of the callback *handler
+functions* for each of the three events from the wip model. The developer
+does not necessarily need to use them: they are just starting points.
+
+Using the example of::
+
+ void handle_preempt_disable(void *data, /* XXX: fill header */)
+ {
+ da_handle_event_wip(preempt_disable_wip);
+ }
+
+The preempt_disable event from the model connects directly to the
+preemptirq:preempt_disable. The preemptirq:preempt_disable event
+has the following signature, from include/trace/events/preemptirq.h::
+
+ TP_PROTO(unsigned long ip, unsigned long parent_ip)
+
+Hence, the handle_preempt_disable() function will look like::
+
+ void handle_preempt_disable(void *data, unsigned long ip, unsigned long parent_ip)
+
+In this case, the kernel event translates one to one with the automata
+event, and indeed, no other change is required for this function.
+
+The next handler function, handle_preempt_enable() has the same argument
+list from the handle_preempt_disable(). The difference is that the
+preempt_enable event will be used to synchronize the system to the model.
+
+Initially, the *model* is placed in the initial state. However, the *system*
+might or might not be in the initial state. The monitor cannot start
+processing events until it knows that the system has reached the initial state.
+Otherwise, the monitor and the system could be out-of-sync.
+
+Looking at the automata definition, it is possible to see that the system
+and the model are expected to return to the initial state after the
+preempt_enable execution. Hence, it can be used to synchronize the
+system and the model at the initialization of the monitoring section.
+
+The start is informed via a special handle function, the
+"da_handle_start_event_$(MONITOR_NAME)(event)", in this case::
+
+ da_handle_start_event_wip(preempt_enable_wip);
+
+So, the callback function will look like::
+
+ void handle_preempt_enable(void *data, unsigned long ip, unsigned long parent_ip)
+ {
+ da_handle_start_event_wip(preempt_enable_wip);
+ }
+
+Finally, the "handle_sched_waking()" will look like::
+
+ void handle_sched_waking(void *data, struct task_struct *task)
+ {
+ da_handle_event_wip(sched_waking_wip);
+ }
+
+And the explanation is left for the reader as an exercise.
+
+enable and disable functions
+----------------------------
+
+dot2k automatically creates two special functions::
+
+ enable_$(MONITOR_NAME)()
+ disable_$(MONITOR_NAME)()
+
+These functions are called when the monitor is enabled and disabled,
+respectively.
+
+They should be used to *attach* and *detach* the instrumentation to the running
+system. The developer must add to the relative function all that is needed to
+*attach* and *detach* its monitor to the system.
+
+For the wip case, these functions were named::
+
+ enable_wip()
+ disable_wip()
+
+But no change was required because: by default, these functions *attach* and
+*detach* the tracepoints_to_attach, which was enough for this case.
+
+Instrumentation helpers
+-----------------------
+
+To complete the instrumentation, the *handler functions* need to be attached to a
+kernel event, at the monitoring enable phase.
+
+The RV interface also facilitates this step. For example, the macro "rv_attach_trace_probe()"
+is used to connect the wip model events to the relative kernel event. dot2k automatically
+adds "rv_attach_trace_probe()" function call for each model event in the enable phase, as
+a suggestion.
+
+For example, from the wip sample model::
+
+ static int enable_wip(void)
+ {
+ int retval;
+
+ retval = da_monitor_init_wip();
+ if (retval)
+ return retval;
+
+ rv_attach_trace_probe("wip", /* XXX: tracepoint */, handle_preempt_enable);
+ rv_attach_trace_probe("wip", /* XXX: tracepoint */, handle_sched_waking);
+ rv_attach_trace_probe("wip", /* XXX: tracepoint */, handle_preempt_disable);
+
+ return 0;
+ }
+
+The probes then need to be detached at the disable phase.
+
+[1] The wip model is presented in::
+
+ Documentation/trace/rv/deterministic_automata.rst
+
+The wip monitor is presented in::
+
+ Documentation/trace/rv/da_monitor_synthesis.rst
diff --git a/Documentation/trace/rv/da_monitor_synthesis.rst b/Documentation/trace/rv/da_monitor_synthesis.rst
new file mode 100644
index 000000000..0dbdcd1e6
--- /dev/null
+++ b/Documentation/trace/rv/da_monitor_synthesis.rst
@@ -0,0 +1,147 @@
+Deterministic Automata Monitor Synthesis
+========================================
+
+The starting point for the application of runtime verification (RV) technics
+is the *specification* or *modeling* of the desired (or undesired) behavior
+of the system under scrutiny.
+
+The formal representation needs to be then *synthesized* into a *monitor*
+that can then be used in the analysis of the trace of the system. The
+*monitor* connects to the system via an *instrumentation* that converts
+the events from the *system* to the events of the *specification*.
+
+
+In Linux terms, the runtime verification monitors are encapsulated inside
+the *RV monitor* abstraction. The RV monitor includes a set of instances
+of the monitor (per-cpu monitor, per-task monitor, and so on), the helper
+functions that glue the monitor to the system reference model, and the
+trace output as a reaction to event parsing and exceptions, as depicted
+below::
+
+ Linux +----- RV Monitor ----------------------------------+ Formal
+ Realm | | Realm
+ +-------------------+ +----------------+ +-----------------+
+ | Linux kernel | | Monitor | | Reference |
+ | Tracing | -> | Instance(s) | <- | Model |
+ | (instrumentation) | | (verification) | | (specification) |
+ +-------------------+ +----------------+ +-----------------+
+ | | |
+ | V |
+ | +----------+ |
+ | | Reaction | |
+ | +--+--+--+-+ |
+ | | | | |
+ | | | +-> trace output ? |
+ +------------------------|--|----------------------+
+ | +----> panic ?
+ +-------> <user-specified>
+
+DA monitor synthesis
+--------------------
+
+The synthesis of automata-based models into the Linux *RV monitor* abstraction
+is automated by the dot2k tool and the rv/da_monitor.h header file that
+contains a set of macros that automatically generate the monitor's code.
+
+dot2k
+-----
+
+The dot2k utility leverages dot2c by converting an automaton model in
+the DOT format into the C representation [1] and creating the skeleton of
+a kernel monitor in C.
+
+For example, it is possible to transform the wip.dot model present in
+[1] into a per-cpu monitor with the following command::
+
+ $ dot2k -d wip.dot -t per_cpu
+
+This will create a directory named wip/ with the following files:
+
+- wip.h: the wip model in C
+- wip.c: the RV monitor
+
+The wip.c file contains the monitor declaration and the starting point for
+the system instrumentation.
+
+Monitor macros
+--------------
+
+The rv/da_monitor.h enables automatic code generation for the *Monitor
+Instance(s)* using C macros.
+
+The benefits of the usage of macro for monitor synthesis are 3-fold as it:
+
+- Reduces the code duplication;
+- Facilitates the bug fix/improvement;
+- Avoids the case of developers changing the core of the monitor code
+ to manipulate the model in a (let's say) non-standard way.
+
+This initial implementation presents three different types of monitor instances:
+
+- ``#define DECLARE_DA_MON_GLOBAL(name, type)``
+- ``#define DECLARE_DA_MON_PER_CPU(name, type)``
+- ``#define DECLARE_DA_MON_PER_TASK(name, type)``
+
+The first declares the functions for a global deterministic automata monitor,
+the second for monitors with per-cpu instances, and the third with per-task
+instances.
+
+In all cases, the 'name' argument is a string that identifies the monitor, and
+the 'type' argument is the data type used by dot2k on the representation of
+the model in C.
+
+For example, the wip model with two states and three events can be
+stored in an 'unsigned char' type. Considering that the preemption control
+is a per-cpu behavior, the monitor declaration in the 'wip.c' file is::
+
+ DECLARE_DA_MON_PER_CPU(wip, unsigned char);
+
+The monitor is executed by sending events to be processed via the functions
+presented below::
+
+ da_handle_event_$(MONITOR_NAME)($(event from event enum));
+ da_handle_start_event_$(MONITOR_NAME)($(event from event enum));
+ da_handle_start_run_event_$(MONITOR_NAME)($(event from event enum));
+
+The function ``da_handle_event_$(MONITOR_NAME)()`` is the regular case where
+the event will be processed if the monitor is processing events.
+
+When a monitor is enabled, it is placed in the initial state of the automata.
+However, the monitor does not know if the system is in the *initial state*.
+
+The ``da_handle_start_event_$(MONITOR_NAME)()`` function is used to notify the
+monitor that the system is returning to the initial state, so the monitor can
+start monitoring the next event.
+
+The ``da_handle_start_run_event_$(MONITOR_NAME)()`` function is used to notify
+the monitor that the system is known to be in the initial state, so the
+monitor can start monitoring and monitor the current event.
+
+Using the wip model as example, the events "preempt_disable" and
+"sched_waking" should be sent to monitor, respectively, via [2]::
+
+ da_handle_event_wip(preempt_disable_wip);
+ da_handle_event_wip(sched_waking_wip);
+
+While the event "preempt_enabled" will use::
+
+ da_handle_start_event_wip(preempt_enable_wip);
+
+To notify the monitor that the system will be returning to the initial state,
+so the system and the monitor should be in sync.
+
+Final remarks
+-------------
+
+With the monitor synthesis in place using the rv/da_monitor.h and
+dot2k, the developer's work should be limited to the instrumentation
+of the system, increasing the confidence in the overall approach.
+
+[1] For details about deterministic automata format and the translation
+from one representation to another, see::
+
+ Documentation/trace/rv/deterministic_automata.rst
+
+[2] dot2k appends the monitor's name suffix to the events enums to
+avoid conflicting variables when exporting the global vmlinux.h
+use by BPF programs.
diff --git a/Documentation/trace/rv/deterministic_automata.rst b/Documentation/trace/rv/deterministic_automata.rst
new file mode 100644
index 000000000..d0638f95a
--- /dev/null
+++ b/Documentation/trace/rv/deterministic_automata.rst
@@ -0,0 +1,184 @@
+Deterministic Automata
+======================
+
+Formally, a deterministic automaton, denoted by G, is defined as a quintuple:
+
+ *G* = { *X*, *E*, *f*, x\ :subscript:`0`, X\ :subscript:`m` }
+
+where:
+
+- *X* is the set of states;
+- *E* is the finite set of events;
+- x\ :subscript:`0` is the initial state;
+- X\ :subscript:`m` (subset of *X*) is the set of marked (or final) states.
+- *f* : *X* x *E* -> *X* $ is the transition function. It defines the state
+ transition in the occurrence of an event from *E* in the state *X*. In the
+ special case of deterministic automata, the occurrence of the event in *E*
+ in a state in *X* has a deterministic next state from *X*.
+
+For example, a given automaton named 'wip' (wakeup in preemptive) can
+be defined as:
+
+- *X* = { ``preemptive``, ``non_preemptive``}
+- *E* = { ``preempt_enable``, ``preempt_disable``, ``sched_waking``}
+- x\ :subscript:`0` = ``preemptive``
+- X\ :subscript:`m` = {``preemptive``}
+- *f* =
+ - *f*\ (``preemptive``, ``preempt_disable``) = ``non_preemptive``
+ - *f*\ (``non_preemptive``, ``sched_waking``) = ``non_preemptive``
+ - *f*\ (``non_preemptive``, ``preempt_enable``) = ``preemptive``
+
+One of the benefits of this formal definition is that it can be presented
+in multiple formats. For example, using a *graphical representation*, using
+vertices (nodes) and edges, which is very intuitive for *operating system*
+practitioners, without any loss.
+
+The previous 'wip' automaton can also be represented as::
+
+ preempt_enable
+ +---------------------------------+
+ v |
+ #============# preempt_disable +------------------+
+ --> H preemptive H -----------------> | non_preemptive |
+ #============# +------------------+
+ ^ |
+ | sched_waking |
+ +--------------+
+
+Deterministic Automaton in C
+----------------------------
+
+In the paper "Efficient formal verification for the Linux kernel",
+the authors present a simple way to represent an automaton in C that can
+be used as regular code in the Linux kernel.
+
+For example, the 'wip' automata can be presented as (augmented with comments)::
+
+ /* enum representation of X (set of states) to be used as index */
+ enum states {
+ preemptive = 0,
+ non_preemptive,
+ state_max
+ };
+
+ #define INVALID_STATE state_max
+
+ /* enum representation of E (set of events) to be used as index */
+ enum events {
+ preempt_disable = 0,
+ preempt_enable,
+ sched_waking,
+ event_max
+ };
+
+ struct automaton {
+ char *state_names[state_max]; // X: the set of states
+ char *event_names[event_max]; // E: the finite set of events
+ unsigned char function[state_max][event_max]; // f: transition function
+ unsigned char initial_state; // x_0: the initial state
+ bool final_states[state_max]; // X_m: the set of marked states
+ };
+
+ struct automaton aut = {
+ .state_names = {
+ "preemptive",
+ "non_preemptive"
+ },
+ .event_names = {
+ "preempt_disable",
+ "preempt_enable",
+ "sched_waking"
+ },
+ .function = {
+ { non_preemptive, INVALID_STATE, INVALID_STATE },
+ { INVALID_STATE, preemptive, non_preemptive },
+ },
+ .initial_state = preemptive,
+ .final_states = { 1, 0 },
+ };
+
+The *transition function* is represented as a matrix of states (lines) and
+events (columns), and so the function *f* : *X* x *E* -> *X* can be solved
+in O(1). For example::
+
+ next_state = automaton_wip.function[curr_state][event];
+
+Graphviz .dot format
+--------------------
+
+The Graphviz open-source tool can produce the graphical representation
+of an automaton using the (textual) DOT language as the source code.
+The DOT format is widely used and can be converted to many other formats.
+
+For example, this is the 'wip' model in DOT::
+
+ digraph state_automaton {
+ {node [shape = circle] "non_preemptive"};
+ {node [shape = plaintext, style=invis, label=""] "__init_preemptive"};
+ {node [shape = doublecircle] "preemptive"};
+ {node [shape = circle] "preemptive"};
+ "__init_preemptive" -> "preemptive";
+ "non_preemptive" [label = "non_preemptive"];
+ "non_preemptive" -> "non_preemptive" [ label = "sched_waking" ];
+ "non_preemptive" -> "preemptive" [ label = "preempt_enable" ];
+ "preemptive" [label = "preemptive"];
+ "preemptive" -> "non_preemptive" [ label = "preempt_disable" ];
+ { rank = min ;
+ "__init_preemptive";
+ "preemptive";
+ }
+ }
+
+This DOT format can be transformed into a bitmap or vectorial image
+using the dot utility, or into an ASCII art using graph-easy. For
+instance::
+
+ $ dot -Tsvg -o wip.svg wip.dot
+ $ graph-easy wip.dot > wip.txt
+
+dot2c
+-----
+
+dot2c is a utility that can parse a .dot file containing an automaton as
+in the example above and automatically convert it to the C representation
+presented in [3].
+
+For example, having the previous 'wip' model into a file named 'wip.dot',
+the following command will transform the .dot file into the C
+representation (previously shown) in the 'wip.h' file::
+
+ $ dot2c wip.dot > wip.h
+
+The 'wip.h' content is the code sample in section 'Deterministic Automaton
+in C'.
+
+Remarks
+-------
+
+The automata formalism allows modeling discrete event systems (DES) in
+multiple formats, suitable for different applications/users.
+
+For example, the formal description using set theory is better suitable
+for automata operations, while the graphical format for human interpretation;
+and computer languages for machine execution.
+
+References
+----------
+
+Many textbooks cover automata formalism. For a brief introduction see::
+
+ O'Regan, Gerard. Concise guide to software engineering. Springer,
+ Cham, 2017.
+
+For a detailed description, including operations, and application on Discrete
+Event Systems (DES), see::
+
+ Cassandras, Christos G., and Stephane Lafortune, eds. Introduction to discrete
+ event systems. Boston, MA: Springer US, 2008.
+
+For the C representation in kernel, see::
+
+ De Oliveira, Daniel Bristot; Cucinotta, Tommaso; De Oliveira, Romulo
+ Silva. Efficient formal verification for the Linux kernel. In:
+ International Conference on Software Engineering and Formal Methods.
+ Springer, Cham, 2019. p. 315-332.
diff --git a/Documentation/trace/rv/index.rst b/Documentation/trace/rv/index.rst
new file mode 100644
index 000000000..15fa96610
--- /dev/null
+++ b/Documentation/trace/rv/index.rst
@@ -0,0 +1,14 @@
+====================
+Runtime Verification
+====================
+
+.. toctree::
+ :maxdepth: 2
+ :glob:
+
+ runtime-verification.rst
+ deterministic_automata.rst
+ da_monitor_synthesis.rst
+ da_monitor_instrumentation.rst
+ monitor_wip.rst
+ monitor_wwnr.rst
diff --git a/Documentation/trace/rv/monitor_wip.rst b/Documentation/trace/rv/monitor_wip.rst
new file mode 100644
index 000000000..a95763438
--- /dev/null
+++ b/Documentation/trace/rv/monitor_wip.rst
@@ -0,0 +1,55 @@
+Monitor wip
+===========
+
+- Name: wip - wakeup in preemptive
+- Type: per-cpu deterministic automaton
+- Author: Daniel Bristot de Oliveira <bristot@kernel.org>
+
+Description
+-----------
+
+The wakeup in preemptive (wip) monitor is a sample per-cpu monitor
+that verifies if the wakeup events always take place with
+preemption disabled::
+
+ |
+ |
+ v
+ #==================#
+ H preemptive H <+
+ #==================# |
+ | |
+ | preempt_disable | preempt_enable
+ v |
+ sched_waking +------------------+ |
+ +--------------- | | |
+ | | non_preemptive | |
+ +--------------> | | -+
+ +------------------+
+
+The wakeup event always takes place with preemption disabled because
+of the scheduler synchronization. However, because the preempt_count
+and its trace event are not atomic with regard to interrupts, some
+inconsistencies might happen. For example::
+
+ preempt_disable() {
+ __preempt_count_add(1)
+ -------> smp_apic_timer_interrupt() {
+ preempt_disable()
+ do not trace (preempt count >= 1)
+
+ wake up a thread
+
+ preempt_enable()
+ do not trace (preempt count >= 1)
+ }
+ <------
+ trace_preempt_disable();
+ }
+
+This problem was reported and discussed here:
+ https://lore.kernel.org/r/cover.1559051152.git.bristot@redhat.com/
+
+Specification
+-------------
+Grapviz Dot file in tools/verification/models/wip.dot
diff --git a/Documentation/trace/rv/monitor_wwnr.rst b/Documentation/trace/rv/monitor_wwnr.rst
new file mode 100644
index 000000000..80f1777b8
--- /dev/null
+++ b/Documentation/trace/rv/monitor_wwnr.rst
@@ -0,0 +1,45 @@
+Monitor wwnr
+============
+
+- Name: wwrn - wakeup while not running
+- Type: per-task deterministic automaton
+- Author: Daniel Bristot de Oliveira <bristot@kernel.org>
+
+Description
+-----------
+
+This is a per-task sample monitor, with the following
+definition::
+
+ |
+ |
+ v
+ wakeup +-------------+
+ +--------- | |
+ | | not_running |
+ +--------> | | <+
+ +-------------+ |
+ | |
+ | switch_in | switch_out
+ v |
+ +-------------+ |
+ | running | -+
+ +-------------+
+
+This model is borken, the reason is that a task can be running
+in the processor without being set as RUNNABLE. Think about a
+task about to sleep::
+
+ 1: set_current_state(TASK_UNINTERRUPTIBLE);
+ 2: schedule();
+
+And then imagine an IRQ happening in between the lines one and two,
+waking the task up. BOOM, the wakeup will happen while the task is
+running.
+
+- Why do we need this model, so?
+- To test the reactors.
+
+Specification
+-------------
+Grapviz Dot file in tools/verification/models/wwnr.dot
diff --git a/Documentation/trace/rv/runtime-verification.rst b/Documentation/trace/rv/runtime-verification.rst
new file mode 100644
index 000000000..c46b61494
--- /dev/null
+++ b/Documentation/trace/rv/runtime-verification.rst
@@ -0,0 +1,231 @@
+====================
+Runtime Verification
+====================
+
+Runtime Verification (RV) is a lightweight (yet rigorous) method that
+complements classical exhaustive verification techniques (such as *model
+checking* and *theorem proving*) with a more practical approach for complex
+systems.
+
+Instead of relying on a fine-grained model of a system (e.g., a
+re-implementation a instruction level), RV works by analyzing the trace of the
+system's actual execution, comparing it against a formal specification of
+the system behavior.
+
+The main advantage is that RV can give precise information on the runtime
+behavior of the monitored system, without the pitfalls of developing models
+that require a re-implementation of the entire system in a modeling language.
+Moreover, given an efficient monitoring method, it is possible execute an
+*online* verification of a system, enabling the *reaction* for unexpected
+events, avoiding, for example, the propagation of a failure on safety-critical
+systems.
+
+Runtime Monitors and Reactors
+=============================
+
+A monitor is the central part of the runtime verification of a system. The
+monitor stands in between the formal specification of the desired (or
+undesired) behavior, and the trace of the actual system.
+
+In Linux terms, the runtime verification monitors are encapsulated inside the
+*RV monitor* abstraction. A *RV monitor* includes a reference model of the
+system, a set of instances of the monitor (per-cpu monitor, per-task monitor,
+and so on), and the helper functions that glue the monitor to the system via
+trace, as depicted bellow::
+
+ Linux +---- RV Monitor ----------------------------------+ Formal
+ Realm | | Realm
+ +-------------------+ +----------------+ +-----------------+
+ | Linux kernel | | Monitor | | Reference |
+ | Tracing | -> | Instance(s) | <- | Model |
+ | (instrumentation) | | (verification) | | (specification) |
+ +-------------------+ +----------------+ +-----------------+
+ | | |
+ | V |
+ | +----------+ |
+ | | Reaction | |
+ | +--+--+--+-+ |
+ | | | | |
+ | | | +-> trace output ? |
+ +------------------------|--|----------------------+
+ | +----> panic ?
+ +-------> <user-specified>
+
+In addition to the verification and monitoring of the system, a monitor can
+react to an unexpected event. The forms of reaction can vary from logging the
+event occurrence to the enforcement of the correct behavior to the extreme
+action of taking a system down to avoid the propagation of a failure.
+
+In Linux terms, a *reactor* is an reaction method available for *RV monitors*.
+By default, all monitors should provide a trace output of their actions,
+which is already a reaction. In addition, other reactions will be available
+so the user can enable them as needed.
+
+For further information about the principles of runtime verification and
+RV applied to Linux:
+
+ Bartocci, Ezio, et al. *Introduction to runtime verification.* In: Lectures on
+ Runtime Verification. Springer, Cham, 2018. p. 1-33.
+
+ Falcone, Ylies, et al. *A taxonomy for classifying runtime verification tools.*
+ In: International Conference on Runtime Verification. Springer, Cham, 2018. p.
+ 241-262.
+
+ De Oliveira, Daniel Bristot. *Automata-based formal analysis and
+ verification of the real-time Linux kernel.* Ph.D. Thesis, 2020.
+
+Online RV monitors
+==================
+
+Monitors can be classified as *offline* and *online* monitors. *Offline*
+monitor process the traces generated by a system after the events, generally by
+reading the trace execution from a permanent storage system. *Online* monitors
+process the trace during the execution of the system. Online monitors are said
+to be *synchronous* if the processing of an event is attached to the system
+execution, blocking the system during the event monitoring. On the other hand,
+an *asynchronous* monitor has its execution detached from the system. Each type
+of monitor has a set of advantages. For example, *offline* monitors can be
+executed on different machines but require operations to save the log to a
+file. In contrast, *synchronous online* method can react at the exact moment
+a violation occurs.
+
+Another important aspect regarding monitors is the overhead associated with the
+event analysis. If the system generates events at a frequency higher than the
+monitor's ability to process them in the same system, only the *offline*
+methods are viable. On the other hand, if the tracing of the events incurs
+on higher overhead than the simple handling of an event by a monitor, then a
+*synchronous online* monitors will incur on lower overhead.
+
+Indeed, the research presented in:
+
+ De Oliveira, Daniel Bristot; Cucinotta, Tommaso; De Oliveira, Romulo Silva.
+ *Efficient formal verification for the Linux kernel.* In: International
+ Conference on Software Engineering and Formal Methods. Springer, Cham, 2019.
+ p. 315-332.
+
+Shows that for Deterministic Automata models, the synchronous processing of
+events in-kernel causes lower overhead than saving the same events to the trace
+buffer, not even considering collecting the trace for user-space analysis.
+This motivated the development of an in-kernel interface for online monitors.
+
+For further information about modeling of Linux kernel behavior using automata,
+see:
+
+ De Oliveira, Daniel B.; De Oliveira, Romulo S.; Cucinotta, Tommaso. *A thread
+ synchronization model for the PREEMPT_RT Linux kernel.* Journal of Systems
+ Architecture, 2020, 107: 101729.
+
+The user interface
+==================
+
+The user interface resembles the tracing interface (on purpose). It is
+currently at "/sys/kernel/tracing/rv/".
+
+The following files/folders are currently available:
+
+**available_monitors**
+
+- Reading list the available monitors, one per line
+
+For example::
+
+ # cat available_monitors
+ wip
+ wwnr
+
+**available_reactors**
+
+- Reading shows the available reactors, one per line.
+
+For example::
+
+ # cat available_reactors
+ nop
+ panic
+ printk
+
+**enabled_monitors**:
+
+- Reading lists the enabled monitors, one per line
+- Writing to it enables a given monitor
+- Writing a monitor name with a '!' prefix disables it
+- Truncating the file disables all enabled monitors
+
+For example::
+
+ # cat enabled_monitors
+ # echo wip > enabled_monitors
+ # echo wwnr >> enabled_monitors
+ # cat enabled_monitors
+ wip
+ wwnr
+ # echo '!wip' >> enabled_monitors
+ # cat enabled_monitors
+ wwnr
+ # echo > enabled_monitors
+ # cat enabled_monitors
+ #
+
+Note that it is possible to enable more than one monitor concurrently.
+
+**monitoring_on**
+
+This is an on/off general switcher for monitoring. It resembles the
+"tracing_on" switcher in the trace interface.
+
+- Writing "0" stops the monitoring
+- Writing "1" continues the monitoring
+- Reading returns the current status of the monitoring
+
+Note that it does not disable enabled monitors but stop the per-entity
+monitors monitoring the events received from the system.
+
+**reacting_on**
+
+- Writing "0" prevents reactions for happening
+- Writing "1" enable reactions
+- Reading returns the current status of the reaction
+
+**monitors/**
+
+Each monitor will have its own directory inside "monitors/". There the
+monitor-specific files will be presented. The "monitors/" directory resembles
+the "events" directory on tracefs.
+
+For example::
+
+ # cd monitors/wip/
+ # ls
+ desc enable
+ # cat desc
+ wakeup in preemptive per-cpu testing monitor.
+ # cat enable
+ 0
+
+**monitors/MONITOR/desc**
+
+- Reading shows a description of the monitor *MONITOR*
+
+**monitors/MONITOR/enable**
+
+- Writing "0" disables the *MONITOR*
+- Writing "1" enables the *MONITOR*
+- Reading return the current status of the *MONITOR*
+
+**monitors/MONITOR/reactors**
+
+- List available reactors, with the select reaction for the given *MONITOR*
+ inside "[]". The default one is the nop (no operation) reactor.
+- Writing the name of a reactor enables it to the given MONITOR.
+
+For example::
+
+ # cat monitors/wip/reactors
+ [nop]
+ panic
+ printk
+ # echo panic > monitors/wip/reactors
+ # cat monitors/wip/reactors
+ nop
+ [panic]
+ printk
diff --git a/Documentation/trace/stm.rst b/Documentation/trace/stm.rst
new file mode 100644
index 000000000..1ed49dde0
--- /dev/null
+++ b/Documentation/trace/stm.rst
@@ -0,0 +1,143 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+===================
+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::
+
+ $ 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
+
+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.
+
+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
+==========
+
+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::
+
+ $ 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_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
diff --git a/Documentation/trace/sys-t.rst b/Documentation/trace/sys-t.rst
new file mode 100644
index 000000000..3d8eb9273
--- /dev/null
+++ b/Documentation/trace/sys-t.rst
@@ -0,0 +1,62 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+===================
+MIPI SyS-T over STP
+===================
+
+The MIPI SyS-T protocol driver can be used with STM class devices to
+generate standardized trace stream. Aside from being a standard, it
+provides better trace source identification and timestamp correlation.
+
+In order to use the MIPI SyS-T protocol driver with your STM device,
+first, you'll need CONFIG_STM_PROTO_SYS_T.
+
+Now, you can select which protocol driver you want to use when you create
+a policy for your STM device, by specifying it in the policy name:
+
+# mkdir /config/stp-policy/dummy_stm.0:p_sys-t.my-policy/
+
+In other words, the policy name format is extended like this:
+
+ <device_name>:<protocol_name>.<policy_name>
+
+With Intel TH, therefore it can look like "0-sth:p_sys-t.my-policy".
+
+If the protocol name is omitted, the STM class will chose whichever
+protocol driver was loaded first.
+
+You can also double check that everything is working as expected by
+
+# cat /config/stp-policy/dummy_stm.0:p_sys-t.my-policy/protocol
+p_sys-t
+
+Now, with the MIPI SyS-T protocol driver, each policy node in the
+configfs gets a few additional attributes, which determine per-source
+parameters specific to the protocol:
+
+# mkdir /config/stp-policy/dummy_stm.0:p_sys-t.my-policy/default
+# ls /config/stp-policy/dummy_stm.0:p_sys-t.my-policy/default
+channels
+clocksync_interval
+do_len
+masters
+ts_interval
+uuid
+
+The most important one here is the "uuid", which determines the UUID
+that will be used to tag all data coming from this source. It is
+automatically generated when a new node is created, but it is likely
+that you would want to change it.
+
+do_len switches on/off the additional "payload length" field in the
+MIPI SyS-T message header. It is off by default as the STP already
+marks message boundaries.
+
+ts_interval and clocksync_interval determine how much time in milliseconds
+can pass before we need to include a protocol (not transport, aka STP)
+timestamp in a message header or send a CLOCKSYNC packet, respectively.
+
+See Documentation/ABI/testing/configfs-stp-policy-p_sys-t for more
+details.
+
+* [1] https://www.mipi.org/specifications/sys-t
diff --git a/Documentation/trace/timerlat-tracer.rst b/Documentation/trace/timerlat-tracer.rst
new file mode 100644
index 000000000..db17df312
--- /dev/null
+++ b/Documentation/trace/timerlat-tracer.rst
@@ -0,0 +1,182 @@
+###############
+Timerlat tracer
+###############
+
+The timerlat tracer aims to help the preemptive kernel developers to
+find sources of wakeup latencies of real-time threads. Like cyclictest,
+the tracer sets a periodic timer that wakes up a thread. The thread then
+computes a *wakeup latency* value as the difference between the *current
+time* and the *absolute time* that the timer was set to expire. The main
+goal of timerlat is tracing in such a way to help kernel developers.
+
+Usage
+-----
+
+Write the ASCII text "timerlat" into the current_tracer file of the
+tracing system (generally mounted at /sys/kernel/tracing).
+
+For example::
+
+ [root@f32 ~]# cd /sys/kernel/tracing/
+ [root@f32 tracing]# echo timerlat > current_tracer
+
+It is possible to follow the trace by reading the trace file::
+
+ [root@f32 tracing]# cat trace
+ # tracer: timerlat
+ #
+ # _-----=> irqs-off
+ # / _----=> need-resched
+ # | / _---=> hardirq/softirq
+ # || / _--=> preempt-depth
+ # || /
+ # |||| ACTIVATION
+ # TASK-PID CPU# |||| TIMESTAMP ID CONTEXT LATENCY
+ # | | | |||| | | | |
+ <idle>-0 [000] d.h1 54.029328: #1 context irq timer_latency 932 ns
+ <...>-867 [000] .... 54.029339: #1 context thread timer_latency 11700 ns
+ <idle>-0 [001] dNh1 54.029346: #1 context irq timer_latency 2833 ns
+ <...>-868 [001] .... 54.029353: #1 context thread timer_latency 9820 ns
+ <idle>-0 [000] d.h1 54.030328: #2 context irq timer_latency 769 ns
+ <...>-867 [000] .... 54.030330: #2 context thread timer_latency 3070 ns
+ <idle>-0 [001] d.h1 54.030344: #2 context irq timer_latency 935 ns
+ <...>-868 [001] .... 54.030347: #2 context thread timer_latency 4351 ns
+
+
+The tracer creates a per-cpu kernel thread with real-time priority that
+prints two lines at every activation. The first is the *timer latency*
+observed at the *hardirq* context before the activation of the thread.
+The second is the *timer latency* observed by the thread. The ACTIVATION
+ID field serves to relate the *irq* execution to its respective *thread*
+execution.
+
+The *irq*/*thread* splitting is important to clarify in which context
+the unexpected high value is coming from. The *irq* context can be
+delayed by hardware-related actions, such as SMIs, NMIs, IRQs,
+or by thread masking interrupts. Once the timer happens, the delay
+can also be influenced by blocking caused by threads. For example, by
+postponing the scheduler execution via preempt_disable(), scheduler
+execution, or masking interrupts. Threads can also be delayed by the
+interference from other threads and IRQs.
+
+Tracer options
+---------------------
+
+The timerlat tracer is built on top of osnoise tracer.
+So its configuration is also done in the osnoise/ config
+directory. The timerlat configs are:
+
+ - cpus: CPUs at which a timerlat thread will execute.
+ - timerlat_period_us: the period of the timerlat thread.
+ - stop_tracing_us: stop the system tracing if a
+ timer latency at the *irq* context higher than the configured
+ value happens. Writing 0 disables this option.
+ - stop_tracing_total_us: stop the system tracing if a
+ timer latency at the *thread* context is higher than the configured
+ value happens. Writing 0 disables this option.
+ - print_stack: save the stack of the IRQ occurrence. The stack is printed
+ after the *thread context* event, or at the IRQ handler if *stop_tracing_us*
+ is hit.
+
+timerlat and osnoise
+----------------------------
+
+The timerlat can also take advantage of the osnoise: traceevents.
+For example::
+
+ [root@f32 ~]# cd /sys/kernel/tracing/
+ [root@f32 tracing]# echo timerlat > current_tracer
+ [root@f32 tracing]# echo 1 > events/osnoise/enable
+ [root@f32 tracing]# echo 25 > osnoise/stop_tracing_total_us
+ [root@f32 tracing]# tail -10 trace
+ cc1-87882 [005] d..h... 548.771078: #402268 context irq timer_latency 13585 ns
+ cc1-87882 [005] dNLh1.. 548.771082: irq_noise: local_timer:236 start 548.771077442 duration 7597 ns
+ cc1-87882 [005] dNLh2.. 548.771099: irq_noise: qxl:21 start 548.771085017 duration 7139 ns
+ cc1-87882 [005] d...3.. 548.771102: thread_noise: cc1:87882 start 548.771078243 duration 9909 ns
+ timerlat/5-1035 [005] ....... 548.771104: #402268 context thread timer_latency 39960 ns
+
+In this case, the root cause of the timer latency does not point to a
+single cause but to multiple ones. Firstly, the timer IRQ was delayed
+for 13 us, which may point to a long IRQ disabled section (see IRQ
+stacktrace section). Then the timer interrupt that wakes up the timerlat
+thread took 7597 ns, and the qxl:21 device IRQ took 7139 ns. Finally,
+the cc1 thread noise took 9909 ns of time before the context switch.
+Such pieces of evidence are useful for the developer to use other
+tracing methods to figure out how to debug and optimize the system.
+
+It is worth mentioning that the *duration* values reported
+by the osnoise: events are *net* values. For example, the
+thread_noise does not include the duration of the overhead caused
+by the IRQ execution (which indeed accounted for 12736 ns). But
+the values reported by the timerlat tracer (timerlat_latency)
+are *gross* values.
+
+The art below illustrates a CPU timeline and how the timerlat tracer
+observes it at the top and the osnoise: events at the bottom. Each "-"
+in the timelines means circa 1 us, and the time moves ==>::
+
+ External timer irq thread
+ clock latency latency
+ event 13585 ns 39960 ns
+ | ^ ^
+ v | |
+ |-------------| |
+ |-------------+-------------------------|
+ ^ ^
+ ========================================================================
+ [tmr irq] [dev irq]
+ [another thread...^ v..^ v.......][timerlat/ thread] <-- CPU timeline
+ =========================================================================
+ |-------| |-------|
+ |--^ v-------|
+ | | |
+ | | + thread_noise: 9909 ns
+ | +-> irq_noise: 6139 ns
+ +-> irq_noise: 7597 ns
+
+IRQ stacktrace
+---------------------------
+
+The osnoise/print_stack option is helpful for the cases in which a thread
+noise causes the major factor for the timer latency, because of preempt or
+irq disabled. For example::
+
+ [root@f32 tracing]# echo 500 > osnoise/stop_tracing_total_us
+ [root@f32 tracing]# echo 500 > osnoise/print_stack
+ [root@f32 tracing]# echo timerlat > current_tracer
+ [root@f32 tracing]# tail -21 per_cpu/cpu7/trace
+ insmod-1026 [007] dN.h1.. 200.201948: irq_noise: local_timer:236 start 200.201939376 duration 7872 ns
+ insmod-1026 [007] d..h1.. 200.202587: #29800 context irq timer_latency 1616 ns
+ insmod-1026 [007] dN.h2.. 200.202598: irq_noise: local_timer:236 start 200.202586162 duration 11855 ns
+ insmod-1026 [007] dN.h3.. 200.202947: irq_noise: local_timer:236 start 200.202939174 duration 7318 ns
+ insmod-1026 [007] d...3.. 200.203444: thread_noise: insmod:1026 start 200.202586933 duration 838681 ns
+ timerlat/7-1001 [007] ....... 200.203445: #29800 context thread timer_latency 859978 ns
+ timerlat/7-1001 [007] ....1.. 200.203446: <stack trace>
+ => timerlat_irq
+ => __hrtimer_run_queues
+ => hrtimer_interrupt
+ => __sysvec_apic_timer_interrupt
+ => asm_call_irq_on_stack
+ => sysvec_apic_timer_interrupt
+ => asm_sysvec_apic_timer_interrupt
+ => delay_tsc
+ => dummy_load_1ms_pd_init
+ => do_one_initcall
+ => do_init_module
+ => __do_sys_finit_module
+ => do_syscall_64
+ => entry_SYSCALL_64_after_hwframe
+
+In this case, it is possible to see that the thread added the highest
+contribution to the *timer latency* and the stack trace, saved during
+the timerlat IRQ handler, points to a function named
+dummy_load_1ms_pd_init, which had the following code (on purpose)::
+
+ static int __init dummy_load_1ms_pd_init(void)
+ {
+ preempt_disable();
+ mdelay(1);
+ preempt_enable();
+ return 0;
+
+ }
diff --git a/Documentation/trace/tracepoint-analysis.rst b/Documentation/trace/tracepoint-analysis.rst
new file mode 100644
index 000000000..716326b9f
--- /dev/null
+++ b/Documentation/trace/tracepoint-analysis.rst
@@ -0,0 +1,338 @@
+=========================================================
+Notes on Analysing Behaviour Using Events and Tracepoints
+=========================================================
+:Author: Mel Gorman (PCL information heavily based on email from Ingo Molnar)
+
+1. Introduction
+===============
+
+Tracepoints (see Documentation/trace/tracepoints.rst) can be used without
+creating custom kernel modules to register probe functions using the event
+tracing infrastructure.
+
+Simplistically, tracepoints represent important events that can be
+taken in conjunction with other tracepoints to build a "Big Picture" of
+what is going on within the system. There are a large number of methods for
+gathering and interpreting these events. Lacking any current Best Practises,
+this document describes some of the methods that can be used.
+
+This document assumes that debugfs is mounted on /sys/kernel/debug and that
+the appropriate tracing options have been configured into the kernel. It is
+assumed that the PCL tool tools/perf has been installed and is in your path.
+
+2. Listing Available Events
+===========================
+
+2.1 Standard Utilities
+----------------------
+
+All possible events are visible from /sys/kernel/debug/tracing/events. Simply
+calling::
+
+ $ find /sys/kernel/debug/tracing/events -type d
+
+will give a fair indication of the number of events available.
+
+2.2 PCL (Performance Counters for Linux)
+----------------------------------------
+
+Discovery and enumeration of all counters and events, including tracepoints,
+are available with the perf tool. Getting a list of available events is a
+simple case of::
+
+ $ perf list 2>&1 | grep Tracepoint
+ ext4:ext4_free_inode [Tracepoint event]
+ ext4:ext4_request_inode [Tracepoint event]
+ ext4:ext4_allocate_inode [Tracepoint event]
+ ext4:ext4_write_begin [Tracepoint event]
+ ext4:ext4_ordered_write_end [Tracepoint event]
+ [ .... remaining output snipped .... ]
+
+
+3. Enabling Events
+==================
+
+3.1 System-Wide Event Enabling
+------------------------------
+
+See Documentation/trace/events.rst for a proper description on how events
+can be enabled system-wide. A short example of enabling all events related
+to page allocation would look something like::
+
+ $ for i in `find /sys/kernel/debug/tracing/events -name "enable" | grep mm_`; do echo 1 > $i; done
+
+3.2 System-Wide Event Enabling with SystemTap
+---------------------------------------------
+
+In SystemTap, tracepoints are accessible using the kernel.trace() function
+call. The following is an example that reports every 5 seconds what processes
+were allocating the pages.
+::
+
+ global page_allocs
+
+ probe kernel.trace("mm_page_alloc") {
+ page_allocs[execname()]++
+ }
+
+ function print_count() {
+ printf ("%-25s %-s\n", "#Pages Allocated", "Process Name")
+ foreach (proc in page_allocs-)
+ printf("%-25d %s\n", page_allocs[proc], proc)
+ printf ("\n")
+ delete page_allocs
+ }
+
+ probe timer.s(5) {
+ print_count()
+ }
+
+3.3 System-Wide Event Enabling with PCL
+---------------------------------------
+
+By specifying the -a switch and analysing sleep, the system-wide events
+for a duration of time can be examined.
+::
+
+ $ perf stat -a \
+ -e kmem:mm_page_alloc -e kmem:mm_page_free \
+ -e kmem:mm_page_free_batched \
+ sleep 10
+ Performance counter stats for 'sleep 10':
+
+ 9630 kmem:mm_page_alloc
+ 2143 kmem:mm_page_free
+ 7424 kmem:mm_page_free_batched
+
+ 10.002577764 seconds time elapsed
+
+Similarly, one could execute a shell and exit it as desired to get a report
+at that point.
+
+3.4 Local Event Enabling
+------------------------
+
+Documentation/trace/ftrace.rst describes how to enable events on a per-thread
+basis using set_ftrace_pid.
+
+3.5 Local Event Enablement with PCL
+-----------------------------------
+
+Events can be activated and tracked for the duration of a process on a local
+basis using PCL such as follows.
+::
+
+ $ perf stat -e kmem:mm_page_alloc -e kmem:mm_page_free \
+ -e kmem:mm_page_free_batched ./hackbench 10
+ Time: 0.909
+
+ Performance counter stats for './hackbench 10':
+
+ 17803 kmem:mm_page_alloc
+ 12398 kmem:mm_page_free
+ 4827 kmem:mm_page_free_batched
+
+ 0.973913387 seconds time elapsed
+
+4. Event Filtering
+==================
+
+Documentation/trace/ftrace.rst covers in-depth how to filter events in
+ftrace. Obviously using grep and awk of trace_pipe is an option as well
+as any script reading trace_pipe.
+
+5. Analysing Event Variances with PCL
+=====================================
+
+Any workload can exhibit variances between runs and it can be important
+to know what the standard deviation is. By and large, this is left to the
+performance analyst to do it by hand. In the event that the discrete event
+occurrences are useful to the performance analyst, then perf can be used.
+::
+
+ $ perf stat --repeat 5 -e kmem:mm_page_alloc -e kmem:mm_page_free
+ -e kmem:mm_page_free_batched ./hackbench 10
+ Time: 0.890
+ Time: 0.895
+ Time: 0.915
+ Time: 1.001
+ Time: 0.899
+
+ Performance counter stats for './hackbench 10' (5 runs):
+
+ 16630 kmem:mm_page_alloc ( +- 3.542% )
+ 11486 kmem:mm_page_free ( +- 4.771% )
+ 4730 kmem:mm_page_free_batched ( +- 2.325% )
+
+ 0.982653002 seconds time elapsed ( +- 1.448% )
+
+In the event that some higher-level event is required that depends on some
+aggregation of discrete events, then a script would need to be developed.
+
+Using --repeat, it is also possible to view how events are fluctuating over
+time on a system-wide basis using -a and sleep.
+::
+
+ $ perf stat -e kmem:mm_page_alloc -e kmem:mm_page_free \
+ -e kmem:mm_page_free_batched \
+ -a --repeat 10 \
+ sleep 1
+ Performance counter stats for 'sleep 1' (10 runs):
+
+ 1066 kmem:mm_page_alloc ( +- 26.148% )
+ 182 kmem:mm_page_free ( +- 5.464% )
+ 890 kmem:mm_page_free_batched ( +- 30.079% )
+
+ 1.002251757 seconds time elapsed ( +- 0.005% )
+
+6. Higher-Level Analysis with Helper Scripts
+============================================
+
+When events are enabled the events that are triggering can be read from
+/sys/kernel/debug/tracing/trace_pipe in human-readable format although binary
+options exist as well. By post-processing the output, further information can
+be gathered on-line as appropriate. Examples of post-processing might include
+
+ - Reading information from /proc for the PID that triggered the event
+ - Deriving a higher-level event from a series of lower-level events.
+ - Calculating latencies between two events
+
+Documentation/trace/postprocess/trace-pagealloc-postprocess.pl is an example
+script that can read trace_pipe from STDIN or a copy of a trace. When used
+on-line, it can be interrupted once to generate a report without exiting
+and twice to exit.
+
+Simplistically, the script just reads STDIN and counts up events but it
+also can do more such as
+
+ - Derive high-level events from many low-level events. If a number of pages
+ are freed to the main allocator from the per-CPU lists, it recognises
+ that as one per-CPU drain even though there is no specific tracepoint
+ for that event
+ - It can aggregate based on PID or individual process number
+ - In the event memory is getting externally fragmented, it reports
+ on whether the fragmentation event was severe or moderate.
+ - When receiving an event about a PID, it can record who the parent was so
+ that if large numbers of events are coming from very short-lived
+ processes, the parent process responsible for creating all the helpers
+ can be identified
+
+7. Lower-Level Analysis with PCL
+================================
+
+There may also be a requirement to identify what functions within a program
+were generating events within the kernel. To begin this sort of analysis, the
+data must be recorded. At the time of writing, this required root:
+::
+
+ $ perf record -c 1 \
+ -e kmem:mm_page_alloc -e kmem:mm_page_free \
+ -e kmem:mm_page_free_batched \
+ ./hackbench 10
+ Time: 0.894
+ [ perf record: Captured and wrote 0.733 MB perf.data (~32010 samples) ]
+
+Note the use of '-c 1' to set the event period to sample. The default sample
+period is quite high to minimise overhead but the information collected can be
+very coarse as a result.
+
+This record outputted a file called perf.data which can be analysed using
+perf report.
+::
+
+ $ perf report
+ # Samples: 30922
+ #
+ # Overhead Command Shared Object
+ # ........ ......... ................................
+ #
+ 87.27% hackbench [vdso]
+ 6.85% hackbench /lib/i686/cmov/libc-2.9.so
+ 2.62% hackbench /lib/ld-2.9.so
+ 1.52% perf [vdso]
+ 1.22% hackbench ./hackbench
+ 0.48% hackbench [kernel]
+ 0.02% perf /lib/i686/cmov/libc-2.9.so
+ 0.01% perf /usr/bin/perf
+ 0.01% perf /lib/ld-2.9.so
+ 0.00% hackbench /lib/i686/cmov/libpthread-2.9.so
+ #
+ # (For more details, try: perf report --sort comm,dso,symbol)
+ #
+
+According to this, the vast majority of events triggered on events
+within the VDSO. With simple binaries, this will often be the case so let's
+take a slightly different example. In the course of writing this, it was
+noticed that X was generating an insane amount of page allocations so let's look
+at it:
+::
+
+ $ perf record -c 1 -f \
+ -e kmem:mm_page_alloc -e kmem:mm_page_free \
+ -e kmem:mm_page_free_batched \
+ -p `pidof X`
+
+This was interrupted after a few seconds and
+::
+
+ $ perf report
+ # Samples: 27666
+ #
+ # Overhead Command Shared Object
+ # ........ ....... .......................................
+ #
+ 51.95% Xorg [vdso]
+ 47.95% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1
+ 0.09% Xorg /lib/i686/cmov/libc-2.9.so
+ 0.01% Xorg [kernel]
+ #
+ # (For more details, try: perf report --sort comm,dso,symbol)
+ #
+
+So, almost half of the events are occurring in a library. To get an idea which
+symbol:
+::
+
+ $ perf report --sort comm,dso,symbol
+ # Samples: 27666
+ #
+ # Overhead Command Shared Object Symbol
+ # ........ ....... ....................................... ......
+ #
+ 51.95% Xorg [vdso] [.] 0x000000ffffe424
+ 47.93% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1 [.] pixmanFillsse2
+ 0.09% Xorg /lib/i686/cmov/libc-2.9.so [.] _int_malloc
+ 0.01% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1 [.] pixman_region32_copy_f
+ 0.01% Xorg [kernel] [k] read_hpet
+ 0.01% Xorg /opt/gfx-test/lib/libpixman-1.so.0.13.1 [.] get_fast_path
+ 0.00% Xorg [kernel] [k] ftrace_trace_userstack
+
+To see where within the function pixmanFillsse2 things are going wrong:
+::
+
+ $ perf annotate pixmanFillsse2
+ [ ... ]
+ 0.00 : 34eeb: 0f 18 08 prefetcht0 (%eax)
+ : }
+ :
+ : extern __inline void __attribute__((__gnu_inline__, __always_inline__, _
+ : _mm_store_si128 (__m128i *__P, __m128i __B) : {
+ : *__P = __B;
+ 12.40 : 34eee: 66 0f 7f 80 40 ff ff movdqa %xmm0,-0xc0(%eax)
+ 0.00 : 34ef5: ff
+ 12.40 : 34ef6: 66 0f 7f 80 50 ff ff movdqa %xmm0,-0xb0(%eax)
+ 0.00 : 34efd: ff
+ 12.39 : 34efe: 66 0f 7f 80 60 ff ff movdqa %xmm0,-0xa0(%eax)
+ 0.00 : 34f05: ff
+ 12.67 : 34f06: 66 0f 7f 80 70 ff ff movdqa %xmm0,-0x90(%eax)
+ 0.00 : 34f0d: ff
+ 12.58 : 34f0e: 66 0f 7f 40 80 movdqa %xmm0,-0x80(%eax)
+ 12.31 : 34f13: 66 0f 7f 40 90 movdqa %xmm0,-0x70(%eax)
+ 12.40 : 34f18: 66 0f 7f 40 a0 movdqa %xmm0,-0x60(%eax)
+ 12.31 : 34f1d: 66 0f 7f 40 b0 movdqa %xmm0,-0x50(%eax)
+
+At a glance, it looks like the time is being spent copying pixmaps to
+the card. Further investigation would be needed to determine why pixmaps
+are being copied around so much but a starting point would be to take an
+ancient build of libpixmap out of the library path where it was totally
+forgotten about from months ago!
diff --git a/Documentation/trace/tracepoints.rst b/Documentation/trace/tracepoints.rst
new file mode 100644
index 000000000..0cb8d9ca3
--- /dev/null
+++ b/Documentation/trace/tracepoints.rst
@@ -0,0 +1,175 @@
+==================================
+Using the Linux Kernel Tracepoints
+==================================
+
+:Author: Mathieu Desnoyers
+
+
+This document introduces Linux Kernel Tracepoints and their use. It
+provides examples of how to insert tracepoints in the kernel and
+connect probe functions to them and provides some examples of probe
+functions.
+
+
+Purpose of tracepoints
+----------------------
+A tracepoint placed in code provides a hook to call a function (probe)
+that you can provide at runtime. A tracepoint can be "on" (a probe is
+connected to it) or "off" (no probe is attached). When a tracepoint is
+"off" it has no effect, except for adding a tiny time penalty
+(checking a condition for a branch) and space penalty (adding a few
+bytes for the function call at the end of the instrumented function
+and adds a data structure in a separate section). When a tracepoint
+is "on", the function you provide is called each time the tracepoint
+is executed, in the execution context of the caller. When the function
+provided ends its execution, it returns to the caller (continuing from
+the tracepoint site).
+
+You can put tracepoints at important locations in the code. They are
+lightweight hooks that can pass an arbitrary number of parameters,
+which prototypes are described in a tracepoint declaration placed in a
+header file.
+
+They can be used for tracing and performance accounting.
+
+
+Usage
+-----
+Two elements are required for tracepoints :
+
+- A tracepoint definition, placed in a header file.
+- The tracepoint statement, in C code.
+
+In order to use tracepoints, you should include linux/tracepoint.h.
+
+In include/trace/events/subsys.h::
+
+ #undef TRACE_SYSTEM
+ #define TRACE_SYSTEM subsys
+
+ #if !defined(_TRACE_SUBSYS_H) || defined(TRACE_HEADER_MULTI_READ)
+ #define _TRACE_SUBSYS_H
+
+ #include <linux/tracepoint.h>
+
+ DECLARE_TRACE(subsys_eventname,
+ TP_PROTO(int firstarg, struct task_struct *p),
+ TP_ARGS(firstarg, p));
+
+ #endif /* _TRACE_SUBSYS_H */
+
+ /* This part must be outside protection */
+ #include <trace/define_trace.h>
+
+In subsys/file.c (where the tracing statement must be added)::
+
+ #include <trace/events/subsys.h>
+
+ #define CREATE_TRACE_POINTS
+ DEFINE_TRACE(subsys_eventname);
+
+ void somefct(void)
+ {
+ ...
+ trace_subsys_eventname(arg, task);
+ ...
+ }
+
+Where :
+ - subsys_eventname is an identifier unique to your event
+
+ - subsys is the name of your subsystem.
+ - eventname is the name of the event to trace.
+
+ - `TP_PROTO(int firstarg, struct task_struct *p)` is the prototype of the
+ function called by this tracepoint.
+
+ - `TP_ARGS(firstarg, p)` are the parameters names, same as found in the
+ prototype.
+
+ - if you use the header in multiple source files, `#define CREATE_TRACE_POINTS`
+ should appear only in one source file.
+
+Connecting a function (probe) to a tracepoint is done by providing a
+probe (function to call) for the specific tracepoint through
+register_trace_subsys_eventname(). Removing a probe is done through
+unregister_trace_subsys_eventname(); it will remove the probe.
+
+tracepoint_synchronize_unregister() must be called before the end of
+the module exit function to make sure there is no caller left using
+the probe. This, and the fact that preemption is disabled around the
+probe call, make sure that probe removal and module unload are safe.
+
+The tracepoint mechanism supports inserting multiple instances of the
+same tracepoint, but a single definition must be made of a given
+tracepoint name over all the kernel to make sure no type conflict will
+occur. Name mangling of the tracepoints is done using the prototypes
+to make sure typing is correct. Verification of probe type correctness
+is done at the registration site by the compiler. Tracepoints can be
+put in inline functions, inlined static functions, and unrolled loops
+as well as regular functions.
+
+The naming scheme "subsys_event" is suggested here as a convention
+intended to limit collisions. Tracepoint names are global to the
+kernel: they are considered as being the same whether they are in the
+core kernel image or in modules.
+
+If the tracepoint has to be used in kernel modules, an
+EXPORT_TRACEPOINT_SYMBOL_GPL() or EXPORT_TRACEPOINT_SYMBOL() can be
+used to export the defined tracepoints.
+
+If you need to do a bit of work for a tracepoint parameter, and
+that work is only used for the tracepoint, that work can be encapsulated
+within an if statement with the following::
+
+ if (trace_foo_bar_enabled()) {
+ int i;
+ int tot = 0;
+
+ for (i = 0; i < count; i++)
+ tot += calculate_nuggets();
+
+ trace_foo_bar(tot);
+ }
+
+All trace_<tracepoint>() calls have a matching trace_<tracepoint>_enabled()
+function defined that returns true if the tracepoint is enabled and
+false otherwise. The trace_<tracepoint>() should always be within the
+block of the if (trace_<tracepoint>_enabled()) to prevent races between
+the tracepoint being enabled and the check being seen.
+
+The advantage of using the trace_<tracepoint>_enabled() is that it uses
+the static_key of the tracepoint to allow the if statement to be implemented
+with jump labels and avoid conditional branches.
+
+.. note:: The convenience macro TRACE_EVENT provides an alternative way to
+ define tracepoints. Check http://lwn.net/Articles/379903,
+ http://lwn.net/Articles/381064 and http://lwn.net/Articles/383362
+ for a series of articles with more details.
+
+If you require calling a tracepoint from a header file, it is not
+recommended to call one directly or to use the trace_<tracepoint>_enabled()
+function call, as tracepoints in header files can have side effects if a
+header is included from a file that has CREATE_TRACE_POINTS set, as
+well as the trace_<tracepoint>() is not that small of an inline
+and can bloat the kernel if used by other inlined functions. Instead,
+include tracepoint-defs.h and use tracepoint_enabled().
+
+In a C file::
+
+ void do_trace_foo_bar_wrapper(args)
+ {
+ trace_foo_bar(args);
+ }
+
+In the header file::
+
+ DECLARE_TRACEPOINT(foo_bar);
+
+ static inline void some_inline_function()
+ {
+ [..]
+ if (tracepoint_enabled(foo_bar))
+ do_trace_foo_bar_wrapper(args);
+ [..]
+ }
diff --git a/Documentation/trace/uprobetracer.rst b/Documentation/trace/uprobetracer.rst
new file mode 100644
index 000000000..3a1797d70
--- /dev/null
+++ b/Documentation/trace/uprobetracer.rst
@@ -0,0 +1,186 @@
+=========================================
+Uprobe-tracer: Uprobe-based Event Tracing
+=========================================
+
+:Author: Srikar Dronamraju
+
+
+Overview
+--------
+Uprobe based trace events are similar to kprobe based trace events.
+To enable this feature, build your kernel with CONFIG_UPROBE_EVENTS=y.
+
+Similar to the kprobe-event tracer, this doesn't need to be activated via
+current_tracer. Instead of that, add probe points via
+/sys/kernel/debug/tracing/uprobe_events, and enable it via
+/sys/kernel/debug/tracing/events/uprobes/<EVENT>/enable.
+
+However unlike kprobe-event tracer, the uprobe event interface expects the
+user to calculate the offset of the probepoint in the object.
+
+You can also use /sys/kernel/debug/tracing/dynamic_events instead of
+uprobe_events. That interface will provide unified access to other
+dynamic events too.
+
+Synopsis of uprobe_tracer
+-------------------------
+::
+
+ p[:[GRP/][EVENT]] PATH:OFFSET [FETCHARGS] : Set a uprobe
+ r[:[GRP/][EVENT]] PATH:OFFSET [FETCHARGS] : Set a return uprobe (uretprobe)
+ p[:[GRP/][EVENT]] PATH:OFFSET%return [FETCHARGS] : Set a return uprobe (uretprobe)
+ -:[GRP/][EVENT] : Clear uprobe or uretprobe event
+
+ GRP : Group name. If omitted, "uprobes" is the default value.
+ EVENT : Event name. If omitted, the event name is generated based
+ on PATH+OFFSET.
+ PATH : Path to an executable or a library.
+ OFFSET : Offset where the probe is inserted.
+ OFFSET%return : Offset where the return probe is inserted.
+
+ FETCHARGS : Arguments. Each probe can have up to 128 args.
+ %REG : Fetch register REG
+ @ADDR : Fetch memory at ADDR (ADDR should be in userspace)
+ @+OFFSET : Fetch memory at OFFSET (OFFSET from same file as PATH)
+ $stackN : Fetch Nth entry of stack (N >= 0)
+ $stack : Fetch stack address.
+ $retval : Fetch return value.(\*1)
+ $comm : Fetch current task comm.
+ +|-[u]OFFS(FETCHARG) : Fetch memory at FETCHARG +|- OFFS address.(\*2)(\*3)
+ \IMM : Store an immediate value to the argument.
+ NAME=FETCHARG : Set NAME as the argument name of FETCHARG.
+ FETCHARG:TYPE : Set TYPE as the type of FETCHARG. Currently, basic types
+ (u8/u16/u32/u64/s8/s16/s32/s64), hexadecimal types
+ (x8/x16/x32/x64), "string" and bitfield are supported.
+
+ (\*1) only for return probe.
+ (\*2) this is useful for fetching a field of data structures.
+ (\*3) Unlike kprobe event, "u" prefix will just be ignored, becuse uprobe
+ events can access only user-space memory.
+
+Types
+-----
+Several types are supported for fetch-args. Uprobe tracer will access memory
+by given type. Prefix 's' and 'u' means those types are signed and unsigned
+respectively. 'x' prefix implies it is unsigned. Traced arguments are shown
+in decimal ('s' and 'u') or hexadecimal ('x'). Without type casting, 'x32'
+or 'x64' is used depends on the architecture (e.g. x86-32 uses x32, and
+x86-64 uses x64).
+String type is a special type, which fetches a "null-terminated" string from
+user space.
+Bitfield is another special type, which takes 3 parameters, bit-width, bit-
+offset, and container-size (usually 32). The syntax is::
+
+ b<bit-width>@<bit-offset>/<container-size>
+
+For $comm, the default type is "string"; any other type is invalid.
+
+
+Event Profiling
+---------------
+You can check the total number of probe hits per event via
+/sys/kernel/debug/tracing/uprobe_profile. The first column is the filename,
+the second is the event name, the third is the number of probe hits.
+
+Usage examples
+--------------
+ * Add a probe as a new uprobe event, write a new definition to uprobe_events
+ as below (sets a uprobe at an offset of 0x4245c0 in the executable /bin/bash)::
+
+ echo 'p /bin/bash:0x4245c0' > /sys/kernel/debug/tracing/uprobe_events
+
+ * Add a probe as a new uretprobe event::
+
+ echo 'r /bin/bash:0x4245c0' > /sys/kernel/debug/tracing/uprobe_events
+
+ * Unset registered event::
+
+ echo '-:p_bash_0x4245c0' >> /sys/kernel/debug/tracing/uprobe_events
+
+ * Print out the events that are registered::
+
+ cat /sys/kernel/debug/tracing/uprobe_events
+
+ * Clear all events::
+
+ echo > /sys/kernel/debug/tracing/uprobe_events
+
+Following example shows how to dump the instruction pointer and %ax register
+at the probed text address. Probe zfree function in /bin/zsh::
+
+ # cd /sys/kernel/debug/tracing/
+ # cat /proc/`pgrep zsh`/maps | grep /bin/zsh | grep r-xp
+ 00400000-0048a000 r-xp 00000000 08:03 130904 /bin/zsh
+ # objdump -T /bin/zsh | grep -w zfree
+ 0000000000446420 g DF .text 0000000000000012 Base zfree
+
+0x46420 is the offset of zfree in object /bin/zsh that is loaded at
+0x00400000. Hence the command to uprobe would be::
+
+ # echo 'p:zfree_entry /bin/zsh:0x46420 %ip %ax' > uprobe_events
+
+And the same for the uretprobe would be::
+
+ # echo 'r:zfree_exit /bin/zsh:0x46420 %ip %ax' >> uprobe_events
+
+.. note:: User has to explicitly calculate the offset of the probe-point
+ in the object.
+
+We can see the events that are registered by looking at the uprobe_events file.
+::
+
+ # cat uprobe_events
+ p:uprobes/zfree_entry /bin/zsh:0x00046420 arg1=%ip arg2=%ax
+ r:uprobes/zfree_exit /bin/zsh:0x00046420 arg1=%ip arg2=%ax
+
+Format of events can be seen by viewing the file events/uprobes/zfree_entry/format.
+::
+
+ # cat events/uprobes/zfree_entry/format
+ name: zfree_entry
+ ID: 922
+ format:
+ field:unsigned short common_type; offset:0; size:2; signed:0;
+ field:unsigned char common_flags; offset:2; size:1; signed:0;
+ field:unsigned char common_preempt_count; offset:3; size:1; signed:0;
+ field:int common_pid; offset:4; size:4; signed:1;
+ field:int common_padding; offset:8; size:4; signed:1;
+
+ field:unsigned long __probe_ip; offset:12; size:4; signed:0;
+ field:u32 arg1; offset:16; size:4; signed:0;
+ field:u32 arg2; offset:20; size:4; signed:0;
+
+ print fmt: "(%lx) arg1=%lx arg2=%lx", REC->__probe_ip, REC->arg1, REC->arg2
+
+Right after definition, each event is disabled by default. For tracing these
+events, you need to enable it by::
+
+ # echo 1 > events/uprobes/enable
+
+Lets start tracing, sleep for some time and stop tracing.
+::
+
+ # echo 1 > tracing_on
+ # sleep 20
+ # echo 0 > tracing_on
+
+Also, you can disable the event by::
+
+ # echo 0 > events/uprobes/enable
+
+And you can see the traced information via /sys/kernel/debug/tracing/trace.
+::
+
+ # cat trace
+ # tracer: nop
+ #
+ # TASK-PID CPU# TIMESTAMP FUNCTION
+ # | | | | |
+ zsh-24842 [006] 258544.995456: zfree_entry: (0x446420) arg1=446420 arg2=79
+ zsh-24842 [007] 258545.000270: zfree_exit: (0x446540 <- 0x446420) arg1=446540 arg2=0
+ zsh-24842 [002] 258545.043929: zfree_entry: (0x446420) arg1=446420 arg2=79
+ zsh-24842 [004] 258547.046129: zfree_exit: (0x446540 <- 0x446420) arg1=446540 arg2=0
+
+Output shows us uprobe was triggered for a pid 24842 with ip being 0x446420
+and contents of ax register being 79. And uretprobe was triggered with ip at
+0x446540 with counterpart function entry at 0x446420.
diff --git a/Documentation/trace/user_events.rst b/Documentation/trace/user_events.rst
new file mode 100644
index 000000000..9f181f342
--- /dev/null
+++ b/Documentation/trace/user_events.rst
@@ -0,0 +1,238 @@
+=========================================
+user_events: User-based Event Tracing
+=========================================
+
+:Author: Beau Belgrave
+
+Overview
+--------
+User based trace events allow user processes to create events and trace data
+that can be viewed via existing tools, such as ftrace and perf.
+To enable this feature, build your kernel with CONFIG_USER_EVENTS=y.
+
+Programs can view status of the events via
+/sys/kernel/debug/tracing/user_events_status and can both register and write
+data out via /sys/kernel/debug/tracing/user_events_data.
+
+Programs can also use /sys/kernel/debug/tracing/dynamic_events to register and
+delete user based events via the u: prefix. The format of the command to
+dynamic_events is the same as the ioctl with the u: prefix applied.
+
+Typically programs will register a set of events that they wish to expose to
+tools that can read trace_events (such as ftrace and perf). The registration
+process gives back two ints to the program for each event. The first int is
+the status bit. This describes which bit in little-endian format in the
+/sys/kernel/debug/tracing/user_events_status file represents this event. The
+second int is the write index which describes the data when a write() or
+writev() is called on the /sys/kernel/debug/tracing/user_events_data file.
+
+The structures referenced in this document are contained within the
+/include/uapi/linux/user_events.h file in the source tree.
+
+**NOTE:** *Both user_events_status and user_events_data are under the tracefs
+filesystem and may be mounted at different paths than above.*
+
+Registering
+-----------
+Registering within a user process is done via ioctl() out to the
+/sys/kernel/debug/tracing/user_events_data file. The command to issue is
+DIAG_IOCSREG.
+
+This command takes a packed struct user_reg as an argument::
+
+ struct user_reg {
+ u32 size;
+ u64 name_args;
+ u32 status_bit;
+ u32 write_index;
+ };
+
+The struct user_reg requires two inputs, the first is the size of the structure
+to ensure forward and backward compatibility. The second is the command string
+to issue for registering. Upon success two outputs are set, the status bit
+and the write index.
+
+User based events show up under tracefs like any other event under the
+subsystem named "user_events". This means tools that wish to attach to the
+events need to use /sys/kernel/debug/tracing/events/user_events/[name]/enable
+or perf record -e user_events:[name] when attaching/recording.
+
+**NOTE:** *The write_index returned is only valid for the FD that was used*
+
+Command Format
+^^^^^^^^^^^^^^
+The command string format is as follows::
+
+ name[:FLAG1[,FLAG2...]] [Field1[;Field2...]]
+
+Supported Flags
+^^^^^^^^^^^^^^^
+None yet
+
+Field Format
+^^^^^^^^^^^^
+::
+
+ type name [size]
+
+Basic types are supported (__data_loc, u32, u64, int, char, char[20], etc).
+User programs are encouraged to use clearly sized types like u32.
+
+**NOTE:** *Long is not supported since size can vary between user and kernel.*
+
+The size is only valid for types that start with a struct prefix.
+This allows user programs to describe custom structs out to tools, if required.
+
+For example, a struct in C that looks like this::
+
+ struct mytype {
+ char data[20];
+ };
+
+Would be represented by the following field::
+
+ struct mytype myname 20
+
+Deleting
+-----------
+Deleting an event from within a user process is done via ioctl() out to the
+/sys/kernel/debug/tracing/user_events_data file. The command to issue is
+DIAG_IOCSDEL.
+
+This command only requires a single string specifying the event to delete by
+its name. Delete will only succeed if there are no references left to the
+event (in both user and kernel space). User programs should use a separate file
+to request deletes than the one used for registration due to this.
+
+Status
+------
+When tools attach/record user based events the status of the event is updated
+in realtime. This allows user programs to only incur the cost of the write() or
+writev() calls when something is actively attached to the event.
+
+User programs call mmap() on /sys/kernel/debug/tracing/user_events_status to
+check the status for each event that is registered. The bit to check in the
+file is given back after the register ioctl() via user_reg.status_bit. The bit
+is always in little-endian format. Programs can check if the bit is set either
+using a byte-wise index with a mask or a long-wise index with a little-endian
+mask.
+
+Currently the size of user_events_status is a single page, however, custom
+kernel configurations can change this size to allow more user based events. In
+all cases the size of the file is a multiple of a page size.
+
+For example, if the register ioctl() gives back a status_bit of 3 you would
+check byte 0 (3 / 8) of the returned mmap data and then AND the result with 8
+(1 << (3 % 8)) to see if anything is attached to that event.
+
+A byte-wise index check is performed as follows::
+
+ int index, mask;
+ char *status_page;
+
+ index = status_bit / 8;
+ mask = 1 << (status_bit % 8);
+
+ ...
+
+ if (status_page[index] & mask) {
+ /* Enabled */
+ }
+
+A long-wise index check is performed as follows::
+
+ #include <asm/bitsperlong.h>
+ #include <endian.h>
+
+ #if __BITS_PER_LONG == 64
+ #define endian_swap(x) htole64(x)
+ #else
+ #define endian_swap(x) htole32(x)
+ #endif
+
+ long index, mask, *status_page;
+
+ index = status_bit / __BITS_PER_LONG;
+ mask = 1L << (status_bit % __BITS_PER_LONG);
+ mask = endian_swap(mask);
+
+ ...
+
+ if (status_page[index] & mask) {
+ /* Enabled */
+ }
+
+Administrators can easily check the status of all registered events by reading
+the user_events_status file directly via a terminal. The output is as follows::
+
+ Byte:Name [# Comments]
+ ...
+
+ Active: ActiveCount
+ Busy: BusyCount
+ Max: MaxCount
+
+For example, on a system that has a single event the output looks like this::
+
+ 1:test
+
+ Active: 1
+ Busy: 0
+ Max: 32768
+
+If a user enables the user event via ftrace, the output would change to this::
+
+ 1:test # Used by ftrace
+
+ Active: 1
+ Busy: 1
+ Max: 32768
+
+**NOTE:** *A status bit of 0 will never be returned. This allows user programs
+to have a bit that can be used on error cases.*
+
+Writing Data
+------------
+After registering an event the same fd that was used to register can be used
+to write an entry for that event. The write_index returned must be at the start
+of the data, then the remaining data is treated as the payload of the event.
+
+For example, if write_index returned was 1 and I wanted to write out an int
+payload of the event. Then the data would have to be 8 bytes (2 ints) in size,
+with the first 4 bytes being equal to 1 and the last 4 bytes being equal to the
+value I want as the payload.
+
+In memory this would look like this::
+
+ int index;
+ int payload;
+
+User programs might have well known structs that they wish to use to emit out
+as payloads. In those cases writev() can be used, with the first vector being
+the index and the following vector(s) being the actual event payload.
+
+For example, if I have a struct like this::
+
+ struct payload {
+ int src;
+ int dst;
+ int flags;
+ };
+
+It's advised for user programs to do the following::
+
+ struct iovec io[2];
+ struct payload e;
+
+ io[0].iov_base = &write_index;
+ io[0].iov_len = sizeof(write_index);
+ io[1].iov_base = &e;
+ io[1].iov_len = sizeof(e);
+
+ writev(fd, (const struct iovec*)io, 2);
+
+**NOTE:** *The write_index is not emitted out into the trace being recorded.*
+
+Example Code
+------------
+See sample code in samples/user_events.