samples/legacy/task_profiler/README.txt - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 ZEPHYR TASK PROFILER
 ####################

 This project permits to enable profiling in zephyr application
 Profiling trace can be retrived over JTAG or UART
 - JTAG: slow but no impact on CPU execution
 - UART: much faster but impacting CPU

 On QEMU, profiler trace can be retrieved using gdb (following JTAG guidelines)
 or on virtual serial port (when enabling UART flush)

 Profiler consists in:
 1) Enabling KERNEL_EVENT_LOGGER in zephyr
   - Various config switches allows selecting events to capture
 2) Extracting profiler events via JTAG (requires debugger) or UART (requires
    profiler background task)
   - for UART: profiler background task must be added to the application
 3) Post-processing tools for getting profiler binary data and get ASCII/graphic
    output

 ---
 NOTE: KERNEL_TASK_MONITOR logs have been merged in KERNEL_EVENT_LOGGER ring
 buffer since Zephyr 1.1
 If using Zephyr version inferior to 1.1, monitor buffer can be dumped using
 JTAG and post-processed using profile_monitor.py
 The command to dump the buffer is:
 (gdb) dump binary value <monitor_file> k_monitor_buff
 Then post-processing:
 ./profile_monitor.py (--qemu) <monitor_file> <zephyr_map_file>

 Project organisation
 ====================

 This project includes:

 |_ profiler: profiler code (kernel event logger flush) and post-processing
 |  |         scripts
 |  |_ src: profiler code to integrate into zephyr application to enable
 |  |       flushing of kernel events
 |  |_ scripts: post-processing scripts
 |  |  |_ term: terminal to use to get zephyr console logs and retrieve profiler
 |  |           data into a separate file for post-processing (linux only)
 |_ microkernel: sample code to exercise profiler in microkernel
 |                          mode
 |_ nanokernel: sample code to exercise profiler in nanokernel mode

 Following guide explains how to enable profiling in your application and
 how to use profiling data

 Requirements
 ============

 To be installed on host PC:
 - python and matplotlib

 For JTAG only
 - gdb
 - For galileo
   - JTAG dongle (e.g. OLIMEX ARM-USB-OCD-H)
   - openocd

 How to enable profiler in your application
 ==========================================

 Conventions:
 $ZEPHYR_BASE = Zephyr base folder
 $APP_BASE = Application base folder
 $PROFILER_BASE = Profiler base folder i.e. $ZEPHYR_BASE/samples/task_profiler/profiler
 prof.log = profiler output file generated from Zephyr target (binary)

 1) Enable KERNEL_EVENT_LOGGER
 -----------------------------

   1.1) Kernel event logger configuration
   --------------------------------------

 Edit project configuration file (e.g. $APP_BASE/prj.conf) and add the following
 flags:

 <-- snippet
 CONFIG_RING_BUFFER=y
 CONFIG_KERNEL_EVENT_LOGGER=y
 CONFIG_NANO_TIMEOUTS=y
 CONFIG_KERNEL_EVENT_LOGGER_BUFFER_SIZE=<BUFFER_SIZE>
 -->

 <BUFFER_SIZE> may depend on use case. Note that
 - on JTAG, buffer is no more populated when full
 - on UART, buffer is flushed at UART speed every 5s (can be modified in
   src/profiler.c)

 Events have to be enabled on top of previous flags:
 - Task/fiber switches
 CONFIG_KERNEL_EVENT_LOGGER_CONTEXT_SWITCH=y
 - Interrupts logging
 CONFIG_KERNEL_EVENT_LOGGER_INTERRUPT=y
 - Sleep logging
 CONFIG_KERNEL_EVENT_LOGGER_SLEEP=y
 - Task monitor (microkernel only)
 CONFIG_TASK_MONITOR=y
 CONFIG_TASK_MONITOR_MASK=<MASK>

 <MASK> bits are defined in kernel/microkernel/include/micro_private.h
 For information:
 - Task swap event: 1
 - Task state bit change: 2
 - Kserver commands: 4
 - Kevents: 8
 If wanting to understand microkernel object usage and task bit handling,
 recommended value is 6
 Otherwise, task monitor can be disabled (to decrease logger ring buffer usage)

   1.2) Kernel event logger timestamp
   ----------------------------------

 By default, the kernel event logger is using the system timer for timestamping
 events. As system timer may not work properly depending on platform, this timer
 can be set at runtime using following flag:

 $APP_BASE/prj.conf:
 CONFIG_KERNEL_EVENT_LOGGER_CUSTOM_TIMESTAMP=y

 In that case, the profiler will set the RTC as timestamp so RTC must be enabled
 $APP_BASE/prj.conf:
 CONFIG_RTC=y

 In case the RTC cannot be used, profiler can support counters as well by
 building application with the following way:

 $APP_BASE/prj.conf:
 CONFIG_COUNTER=y

 Build command:
 make BOARD=... PROFILER_USE_COUNTER=y

 2) Enable UART flush [OPTIONAL]
 -------------------------------

   2.1) Enable profiler UART flush function
   ----------------------------------------

     2.1.1) MICROKERNEL mode
     -----------------------

 Add to $APP_BASE/prj.mdef

 % TASK NAME  PRIO ENTRY STACK GROUPS
 % ==================================
 <--snippet
   TASK PROF    10 prof    512 [EXE]
 -->

 Note:
 Task priority must be the lowest (depending on application code and zephyr
 lowest supported priority). Anyway, an application never letting lower priority
 task execute (so never going to background task) may avoid the profiler task
 to execute. In this case, NANOKERNEL below method can be used (calling
 prof_flush in the main loop, where processing will be the least impacted)

     2.1.2) NANOKERNEL mode
     ----------------------

 prof_flush function must be called from main task before going in idle mode

 <--snippet
 #include "profiler.h"

 ...

 void main(void)
 {
 ...
 	while(1) {
 ...
 		prof_flush();
 		// Going to idle e.g. calling nano_cpu_idle()
 -->

 Note that profiler src folder must be added to the Makefile:
 $APP_BASE/src/Makefile:

 <--snippet
 ccflags-y += -I${ZEPHYR_BASE}/samples/task_profiler/profiler/src
 -->

   2.2) Add path to $PROFILER_BASE folder in application Makefile
   --------------------------------------------------------------

 For example in $APP_BASE/src/Makefile:

 <--snippet
 obj-y += $PROFILER_BASE/
 -->

 Note:
 - the final "/" after $PROFILER_BASE is important
 - the path must be relative to application src folder

   2.3) Increase console UART baud rate (depending on your board)
   ------------------------------------

 On Quark X1000, maximum standard baud rate is 921600
 This is done by adding following line in $APP_BASE/prj.conf:

 <--snippet
 CONFIG_UART_NS16550_PORT_1_BAUD_RATE=921600
 -->

 Profiler has been tested at 2 Mbauds on Quark SE.

   2.4) (Galileo only) disable UART 0
   ----------------------------------

 Due to an issue with Quark X1000 UART_0 IRQ mapping, UART0 must be disabled in
 $APP_BASE/prj.conf:

 <--snippet
 CONFIG_UART_NS16550_PORT_0=n
 -->

 3) Enable profiler console for dynamic control
 ----------------------------------------------

 For having the capability to dynamically enable/disable/configure the profiler
 at runtime, shell command is supported.

 For that purpose, following flags must be enabled in project configuration file
 (e.g. $APP_BASE/prj.conf):

 <-- snippet
 CONFIG_KERNEL_EVENT_LOGGER_DYNAMIC=y
 CONFIG_CONSOLE_HANDLER=y
 -->

 command implementation.

 If done, the profiler will automatically enable a shell over UART allowing to
 use commands to start/stop/configure the profiler:

 - Start profiling:
 prof start
 - Stop profiling:
 prof stop
 - Configure profiler:
 prof cfg <cfg1> <cfg2>
 This sets the kernel event logger configuration (cfg1) and kernel monitor
 configuration (cfg2)
 By default cfg1 is set to log all events enabled at build time and cfg2 is set
 to CONFIG_TASK_MONITOR_MASK
 The new configuration is applied for the following start of the profiler.
 Any on-going profiling session isn't altered

 - Read profiler configuration
 prof cfg
 Get return like X(Y) A(B)
 X being currently used kernel event logger configuration / Y being the next
   value (Set by cfg command).
 A being the currently used kernel monitor configuration / B being the next
   value.

 WARNING: if the application has already defined its shell, then the profiler
 command can be added to the list of application commands this way (apps_cmd
 being the array of shell commands defined by the app)

 <-- snippet
 #include "profiler.h"

 const struct shell_cmd apps_cmd[] = {
 	...
 	<apps commands defined here>
 	...
 	PROF_CMD,
 	{ NULL, NULL}
 }
 -->

 Note that profiler src folder must be added to the Makefile:
 $APP_BASE/src/Makefile:

 <--snippet
 ccflags-y += -I${ZEPHYR_BASE}/samples/task_profiler/profiler/src
 -->

 Additionally, the profiler must not register its console so
 PROFILER_NO_SHELL_REGISTER must be set to 1 while building:
 export PROFILER_NO_SHELL_REGISTER=1
 or
 make BOARD=... PROFILER_NO_SHELL_REGISTER=1

 4) Build and flash project
 --------------------------

 Flags that can be used by the profiler
 PROFILER_NO_SHELL_REGISTER: when profiler dynamic control is set, the profiler
                             won't set its own console handler. In that case the
                             profiler commands must be added to the application
                             console handler

 PROFILER_USECOUNTER: in case custom timestamp is set for the kernel event
                      logger, the profiler will use RTC. This flag allows to
                      use a counter instead

 5) Get prepared for collecting profiler data
 --------------------------------------------

   5.1) for using JTAG on galileo with OpenOCD
   -------------------------------------------

 Connect OpenOCD JTAG to PC

 <--snippet
 cd $OPENOCD_FOLDER
 openocd -f interface/ftdi/olimex-arm-usb-ocd-h.cfg -f board/quark_x10xx_board.cfg
 cd $APP_BASE
 gdb outdir/$BOARD/zephyr.elf
 (gdb) target remote localhost:3333
 (gdb) c
 -->

   5.2) for using UART on any board
   --------------------------------

 - connect console UART to host PC
 - start "profterm"

 <--snippet
 cd $PROFILER_BASE/scripts/term/
 make
 cd $PROFILER_BASE/scripts
 ./profterm /dev/<TTY_USB> prof.log console.log
 -->

 <TTY_USB> being the board UART console device

 Note: profterm UART rate can be set using -s option. Otherwise default speed is
 921600.

   5.3) for using with QEMU (UART flushing mode)
   ---------------------------------------------

 Two terminals are required
 - one for running QEMU, basically redirecting serial to a virtual device
 - one for running profterm (as it would be done with a board)

 <--snippet
 cd $PROFILER_BASE/scripts/term/
 make
 -->

 Term1: QEMU must be launched the following way

 <--snippet
 cd $APP_BASE
 make BOARD=... QEMU_PTY=1 run
 -->

 QEMU will display virtually created TTY
 "char device redicected to /dev/pts/XY"

 Term2:
 <--snippet
 ./profterm /dev/pts/XY prof.log console.log
 -->

 6) Run program
 --------------

 7) Get log (JTAG only)
 ----------------------

 Break execution and dump buffer
 <--snippet
 (gdb) ** break <CTRL-C> **
 (gdb) dump binary value prof.log *(int[<BUFFER_SIZE>] *)sys_k_event_logger.ring_buf.buf
 -->

 <BUFFER_SIZE> being the buffer size defined in $APP_BASE/prj.conf file

 8) Post-processing
 ------------------

 WARNING: zephyr ELF file is required for post-processing. This file must be
 kept together with dump files in order to be able to run the post-processing.

 profile script under $PROFILER_BASE/scripts must be called in its folder for the
 moment
 Run "./profile.sh -h" for usage

 Note that if using JTAG, HW cycles per sec is not part of the dump and so HW
 cycles per sec must be provided to "profile" script using -c option (see
 profile.sh help)

 Notes:
 - python is required for the post processing. matplotlib shall be installed for
 graphical output
	ZEPHYR TASK PROFILER
	####################

	This project permits to enable profiling in zephyr application
	Profiling trace can be retrived over JTAG or UART
	- JTAG: slow but no impact on CPU execution
	- UART: much faster but impacting CPU

	On QEMU, profiler trace can be retrieved using gdb (following JTAG guidelines)
	or on virtual serial port (when enabling UART flush)

	Profiler consists in:
	1) Enabling KERNEL_EVENT_LOGGER in zephyr
	- Various config switches allows selecting events to capture
	2) Extracting profiler events via JTAG (requires debugger) or UART (requires
	profiler background task)
	- for UART: profiler background task must be added to the application
	3) Post-processing tools for getting profiler binary data and get ASCII/graphic
	output

	---
	NOTE: KERNEL_TASK_MONITOR logs have been merged in KERNEL_EVENT_LOGGER ring
	buffer since Zephyr 1.1
	If using Zephyr version inferior to 1.1, monitor buffer can be dumped using
	JTAG and post-processed using profile_monitor.py
	The command to dump the buffer is:
	(gdb) dump binary value <monitor_file> k_monitor_buff
	Then post-processing:
	./profile_monitor.py (--qemu) <monitor_file> <zephyr_map_file>

	Project organisation
	====================

	This project includes:

	\|_ profiler: profiler code (kernel event logger flush) and post-processing
	\| \| scripts
	\| \|_ src: profiler code to integrate into zephyr application to enable
	\| \| flushing of kernel events
	\| \|_ scripts: post-processing scripts
	\| \| \|_ term: terminal to use to get zephyr console logs and retrieve profiler
	\| \| data into a separate file for post-processing (linux only)
	\|_ microkernel: sample code to exercise profiler in microkernel
	\| mode
	\|_ nanokernel: sample code to exercise profiler in nanokernel mode

	Following guide explains how to enable profiling in your application and
	how to use profiling data

	Requirements
	============

	To be installed on host PC:
	- python and matplotlib

	For JTAG only
	- gdb
	- For galileo
	- JTAG dongle (e.g. OLIMEX ARM-USB-OCD-H)
	- openocd

	How to enable profiler in your application
	==========================================

	Conventions:
	$ZEPHYR_BASE = Zephyr base folder
	$APP_BASE = Application base folder
	$PROFILER_BASE = Profiler base folder i.e. $ZEPHYR_BASE/samples/task_profiler/profiler
	prof.log = profiler output file generated from Zephyr target (binary)

	1) Enable KERNEL_EVENT_LOGGER
	-----------------------------

	1.1) Kernel event logger configuration
	--------------------------------------

	Edit project configuration file (e.g. $APP_BASE/prj.conf) and add the following
	flags:

	<-- snippet
	CONFIG_RING_BUFFER=y
	CONFIG_KERNEL_EVENT_LOGGER=y
	CONFIG_NANO_TIMEOUTS=y
	CONFIG_KERNEL_EVENT_LOGGER_BUFFER_SIZE=<BUFFER_SIZE>
	-->

	<BUFFER_SIZE> may depend on use case. Note that
	- on JTAG, buffer is no more populated when full
	- on UART, buffer is flushed at UART speed every 5s (can be modified in
	src/profiler.c)

	Events have to be enabled on top of previous flags:
	- Task/fiber switches
	CONFIG_KERNEL_EVENT_LOGGER_CONTEXT_SWITCH=y
	- Interrupts logging
	CONFIG_KERNEL_EVENT_LOGGER_INTERRUPT=y
	- Sleep logging
	CONFIG_KERNEL_EVENT_LOGGER_SLEEP=y
	- Task monitor (microkernel only)
	CONFIG_TASK_MONITOR=y
	CONFIG_TASK_MONITOR_MASK=<MASK>

	<MASK> bits are defined in kernel/microkernel/include/micro_private.h
	For information:
	- Task swap event: 1
	- Task state bit change: 2
	- Kserver commands: 4
	- Kevents: 8
	If wanting to understand microkernel object usage and task bit handling,
	recommended value is 6
	Otherwise, task monitor can be disabled (to decrease logger ring buffer usage)

	1.2) Kernel event logger timestamp
	----------------------------------

	By default, the kernel event logger is using the system timer for timestamping
	events. As system timer may not work properly depending on platform, this timer
	can be set at runtime using following flag:

	$APP_BASE/prj.conf:
	CONFIG_KERNEL_EVENT_LOGGER_CUSTOM_TIMESTAMP=y

	In that case, the profiler will set the RTC as timestamp so RTC must be enabled
	$APP_BASE/prj.conf:
	CONFIG_RTC=y

	In case the RTC cannot be used, profiler can support counters as well by
	building application with the following way:

	$APP_BASE/prj.conf:
	CONFIG_COUNTER=y

	Build command:
	make BOARD=... PROFILER_USE_COUNTER=y

	2) Enable UART flush [OPTIONAL]
	-------------------------------

	2.1) Enable profiler UART flush function
	----------------------------------------

	2.1.1) MICROKERNEL mode
	-----------------------

	Add to $APP_BASE/prj.mdef

	% TASK NAME PRIO ENTRY STACK GROUPS
	% ==================================
	<--snippet
	TASK PROF 10 prof 512 [EXE]
	-->

	Note:
	Task priority must be the lowest (depending on application code and zephyr
	lowest supported priority). Anyway, an application never letting lower priority
	task execute (so never going to background task) may avoid the profiler task
	to execute. In this case, NANOKERNEL below method can be used (calling
	prof_flush in the main loop, where processing will be the least impacted)

	2.1.2) NANOKERNEL mode
	----------------------

	prof_flush function must be called from main task before going in idle mode

	<--snippet
	#include "profiler.h"

	...

	void main(void)
	{
	...
	while(1) {
	...
	prof_flush();
	// Going to idle e.g. calling nano_cpu_idle()
	-->

	Note that profiler src folder must be added to the Makefile:
	$APP_BASE/src/Makefile:

	<--snippet
	ccflags-y += -I${ZEPHYR_BASE}/samples/task_profiler/profiler/src
	-->

	2.2) Add path to $PROFILER_BASE folder in application Makefile
	--------------------------------------------------------------

	For example in $APP_BASE/src/Makefile:

	<--snippet
	obj-y += $PROFILER_BASE/
	-->

	Note:
	- the final "/" after $PROFILER_BASE is important
	- the path must be relative to application src folder

	2.3) Increase console UART baud rate (depending on your board)
	------------------------------------

	On Quark X1000, maximum standard baud rate is 921600
	This is done by adding following line in $APP_BASE/prj.conf:

	<--snippet
	CONFIG_UART_NS16550_PORT_1_BAUD_RATE=921600
	-->

	Profiler has been tested at 2 Mbauds on Quark SE.

	2.4) (Galileo only) disable UART 0
	----------------------------------

	Due to an issue with Quark X1000 UART_0 IRQ mapping, UART0 must be disabled in
	$APP_BASE/prj.conf:

	<--snippet
	CONFIG_UART_NS16550_PORT_0=n
	-->

	3) Enable profiler console for dynamic control
	----------------------------------------------

	For having the capability to dynamically enable/disable/configure the profiler
	at runtime, shell command is supported.

	For that purpose, following flags must be enabled in project configuration file
	(e.g. $APP_BASE/prj.conf):

	<-- snippet
	CONFIG_KERNEL_EVENT_LOGGER_DYNAMIC=y
	CONFIG_CONSOLE_HANDLER=y
	-->

	command implementation.

	If done, the profiler will automatically enable a shell over UART allowing to
	use commands to start/stop/configure the profiler:

	- Start profiling:
	prof start
	- Stop profiling:
	prof stop
	- Configure profiler:
	prof cfg <cfg1> <cfg2>
	This sets the kernel event logger configuration (cfg1) and kernel monitor
	configuration (cfg2)
	By default cfg1 is set to log all events enabled at build time and cfg2 is set
	to CONFIG_TASK_MONITOR_MASK
	The new configuration is applied for the following start of the profiler.
	Any on-going profiling session isn't altered

	- Read profiler configuration
	prof cfg
	Get return like X(Y) A(B)
	X being currently used kernel event logger configuration / Y being the next
	value (Set by cfg command).
	A being the currently used kernel monitor configuration / B being the next
	value.

	WARNING: if the application has already defined its shell, then the profiler
	command can be added to the list of application commands this way (apps_cmd
	being the array of shell commands defined by the app)

	<-- snippet
	#include "profiler.h"

	const struct shell_cmd apps_cmd[] = {
	...
	<apps commands defined here>
	...
	PROF_CMD,
	{ NULL, NULL}
	}
	-->

	Note that profiler src folder must be added to the Makefile:
	$APP_BASE/src/Makefile:

	<--snippet
	ccflags-y += -I${ZEPHYR_BASE}/samples/task_profiler/profiler/src
	-->

	Additionally, the profiler must not register its console so
	PROFILER_NO_SHELL_REGISTER must be set to 1 while building:
	export PROFILER_NO_SHELL_REGISTER=1
	or
	make BOARD=... PROFILER_NO_SHELL_REGISTER=1

	4) Build and flash project
	--------------------------

	Flags that can be used by the profiler
	PROFILER_NO_SHELL_REGISTER: when profiler dynamic control is set, the profiler
	won't set its own console handler. In that case the
	profiler commands must be added to the application
	console handler

	PROFILER_USECOUNTER: in case custom timestamp is set for the kernel event
	logger, the profiler will use RTC. This flag allows to
	use a counter instead

	5) Get prepared for collecting profiler data
	--------------------------------------------

	5.1) for using JTAG on galileo with OpenOCD
	-------------------------------------------

	Connect OpenOCD JTAG to PC

	<--snippet
	cd $OPENOCD_FOLDER
	openocd -f interface/ftdi/olimex-arm-usb-ocd-h.cfg -f board/quark_x10xx_board.cfg
	cd $APP_BASE
	gdb outdir/$BOARD/zephyr.elf
	(gdb) target remote localhost:3333
	(gdb) c
	-->

	5.2) for using UART on any board
	--------------------------------

	- connect console UART to host PC
	- start "profterm"

	<--snippet
	cd $PROFILER_BASE/scripts/term/
	make
	cd $PROFILER_BASE/scripts
	./profterm /dev/<TTY_USB> prof.log console.log
	-->

	<TTY_USB> being the board UART console device

	Note: profterm UART rate can be set using -s option. Otherwise default speed is
	921600.

	5.3) for using with QEMU (UART flushing mode)
	---------------------------------------------

	Two terminals are required
	- one for running QEMU, basically redirecting serial to a virtual device
	- one for running profterm (as it would be done with a board)

	<--snippet
	cd $PROFILER_BASE/scripts/term/
	make
	-->

	Term1: QEMU must be launched the following way

	<--snippet
	cd $APP_BASE
	make BOARD=... QEMU_PTY=1 run
	-->

	QEMU will display virtually created TTY
	"char device redicected to /dev/pts/XY"

	Term2:
	<--snippet
	./profterm /dev/pts/XY prof.log console.log
	-->

	6) Run program
	--------------

	7) Get log (JTAG only)
	----------------------

	Break execution and dump buffer
	<--snippet
	(gdb) break <CTRL-C>
	(gdb) dump binary value prof.log (int[<BUFFER_SIZE>] )sys_k_event_logger.ring_buf.buf
	-->

	<BUFFER_SIZE> being the buffer size defined in $APP_BASE/prj.conf file

	8) Post-processing
	------------------

	WARNING: zephyr ELF file is required for post-processing. This file must be
	kept together with dump files in order to be able to run the post-processing.

	profile script under $PROFILER_BASE/scripts must be called in its folder for the
	moment
	Run "./profile.sh -h" for usage

	Note that if using JTAG, HW cycles per sec is not part of the dump and so HW
	cycles per sec must be provided to "profile" script using -c option (see
	profile.sh help)

	Notes:
	- python is required for the post processing. matplotlib shall be installed for
	graphical output