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\input texinfo @c -*-texinfo-*- @c %**start of header @setfilename openocd.info @settitle OpenOCD User's Guide @dircategory Development @direntry * OpenOCD: (openocd). OpenOCD User's Guide @end direntry @paragraphindent 0 @c %**end of header @include version.texi @copying This User's Guide documents release @value{VERSION}, dated @value{UPDATED}, of the Open On-Chip Debugger (OpenOCD). @itemize @bullet @item Copyright @copyright{} 2008 The OpenOCD Project @item Copyright @copyright{} 2007-2008 Spencer Oliver @email{spen@@spen-soft.co.uk} @item Copyright @copyright{} 2008 Oyvind Harboe @email{oyvind.harboe@@zylin.com} @item Copyright @copyright{} 2008 Duane Ellis @email{openocd@@duaneellis.com} @item Copyright @copyright{} 2009-2010 David Brownell @end itemize @quotation Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, with no Front-Cover Texts, and with no Back-Cover Texts. A copy of the license is included in the section entitled ``GNU Free Documentation License''. @end quotation @end copying @titlepage @titlefont{@emph{Open On-Chip Debugger:}} @sp 1 @title OpenOCD User's Guide @subtitle for release @value{VERSION} @subtitle @value{UPDATED} @page @vskip 0pt plus 1filll @insertcopying @end titlepage @summarycontents @contents @ifnottex @node Top @top OpenOCD User's Guide @insertcopying @end ifnottex @menu * About:: About OpenOCD * Developers:: OpenOCD Developer Resources * Debug Adapter Hardware:: Debug Adapter Hardware * About JIM-Tcl:: About JIM-Tcl * Running:: Running OpenOCD * OpenOCD Project Setup:: OpenOCD Project Setup * Config File Guidelines:: Config File Guidelines * Daemon Configuration:: Daemon Configuration * Debug Adapter Configuration:: Debug Adapter Configuration * Reset Configuration:: Reset Configuration * TAP Declaration:: TAP Declaration * CPU Configuration:: CPU Configuration * Flash Commands:: Flash Commands * NAND Flash Commands:: NAND Flash Commands * PLD/FPGA Commands:: PLD/FPGA Commands * General Commands:: General Commands * Architecture and Core Commands:: Architecture and Core Commands * JTAG Commands:: JTAG Commands * Boundary Scan Commands:: Boundary Scan Commands * TFTP:: TFTP * GDB and OpenOCD:: Using GDB and OpenOCD * Tcl Scripting API:: Tcl Scripting API * FAQ:: Frequently Asked Questions * Tcl Crash Course:: Tcl Crash Course * License:: GNU Free Documentation License @comment DO NOT use the plain word ``Index'', reason: CYGWIN filename @comment case issue with ``Index.html'' and ``index.html'' @comment Occurs when creating ``--html --no-split'' output @comment This fix is based on: http://sourceware.org/ml/binutils/2006-05/msg00215.html * OpenOCD Concept Index:: Concept Index * Command and Driver Index:: Command and Driver Index @end menu @node About @unnumbered About @cindex about OpenOCD was created by Dominic Rath as part of a diploma thesis written at the University of Applied Sciences Augsburg (@uref{http://www.fh-augsburg.de}). Since that time, the project has grown into an active open-source project, supported by a diverse community of software and hardware developers from around the world. @section What is OpenOCD? @cindex TAP @cindex JTAG The Open On-Chip Debugger (OpenOCD) aims to provide debugging, in-system programming and boundary-scan testing for embedded target devices. It does so with the assistance of a @dfn{debug adapter}, which is a small hardware module which helps provide the right kind of electrical signaling to the target being debugged. These are required since the debug host (on which OpenOCD runs) won't usually have native support for such signaling, or the connector needed to hook up to the target. Such debug adapters support one or more @dfn{transport} protocols, each of which involves different electrical signaling (and uses different messaging protocols on top of that signaling). There are many types of debug adapter, and little uniformity in what they are called. (There are also product naming differences.) These adapters are sometimes packaged as discrete dongles. which may generically be called @dfn{hardware interface dongles}. Some development boards also integrate them directly, which may let the development board can be directly connected to the debug host over USB (and sometimes also to power it over USB). For example, a @dfn{JTAG Adapter} supports JTAG signaling, and is used to communicate with JTAG (IEEE 1149.1) compliant TAPs on your target board. A @dfn{TAP} is a ``Test Access Port'', a module which processes special instructions and data. TAPs are daisy-chained within and between chips and boards. JTAG supports debugging and boundary scan operations. There are also @dfn{SWD Adapters} that support Serial Wire Debug (SWD) signaling to communicate with some newer ARM cores, as well as debug adapters which support both JTAG and SWD transports. SWD only supports debugging, whereas JTAG also supports boundary scan operations. For some chips, there are also @dfn{Programming Adapters} supporting special transports used only to write code to flash memory, without support for on-chip debugging or boundary scan. (At this writing, OpenOCD does not support such non-debug adapters.) @b{Dongles:} OpenOCD currently supports many types of hardware dongles: USB based, parallel port based, and other standalone boxes that run OpenOCD internally. @xref{Debug Adapter Hardware}. @b{GDB Debug:} It allows ARM7 (ARM7TDMI and ARM720t), ARM9 (ARM920T, ARM922T, ARM926EJ--S, ARM966E--S), XScale (PXA25x, IXP42x) and Cortex-M3 (Stellaris LM3 and ST STM32) based cores to be debugged via the GDB protocol. @b{Flash Programing:} Flash writing is supported for external CFI compatible NOR flashes (Intel and AMD/Spansion command set) and several internal flashes (LPC1700, LPC2000, AT91SAM7, AT91SAM3U, STR7x, STR9x, LM3, and STM32x). Preliminary support for various NAND flash controllers (LPC3180, Orion, S3C24xx, more) controller is included. @section OpenOCD Web Site The OpenOCD web site provides the latest public news from the community: @uref{http://openocd.berlios.de/web/} @section Latest User's Guide: The user's guide you are now reading may not be the latest one available. A version for more recent code may be available. Its HTML form is published irregularly at: @uref{http://openocd.berlios.de/doc/html/index.html} PDF form is likewise published at: @uref{http://openocd.berlios.de/doc/pdf/openocd.pdf} @section OpenOCD User's Forum There is an OpenOCD forum (phpBB) hosted by SparkFun, which might be helpful to you. Note that if you want anything to come to the attention of developers, you should post it to the OpenOCD Developer Mailing List instead of this forum. @uref{http://forum.sparkfun.com/viewforum.php?f=18} @node Developers @chapter OpenOCD Developer Resources @cindex developers If you are interested in improving the state of OpenOCD's debugging and testing support, new contributions will be welcome. Motivated developers can produce new target, flash or interface drivers, improve the documentation, as well as more conventional bug fixes and enhancements. The resources in this chapter are available for developers wishing to explore or expand the OpenOCD source code. @section OpenOCD GIT Repository During the 0.3.x release cycle, OpenOCD switched from Subversion to a GIT repository hosted at SourceForge. The repository URL is: @uref{git://openocd.git.sourceforge.net/gitroot/openocd/openocd} You may prefer to use a mirror and the HTTP protocol: @uref{http://repo.or.cz/r/openocd.git} With standard GIT tools, use @command{git clone} to initialize a local repository, and @command{git pull} to update it. There are also gitweb pages letting you browse the repository with a web browser, or download arbitrary snapshots without needing a GIT client: @uref{http://openocd.git.sourceforge.net/git/gitweb.cgi?p=openocd/openocd} @uref{http://repo.or.cz/w/openocd.git} The @file{README} file contains the instructions for building the project from the repository or a snapshot. Developers that want to contribute patches to the OpenOCD system are @b{strongly} encouraged to work against mainline. Patches created against older versions may require additional work from their submitter in order to be updated for newer releases. @section Doxygen Developer Manual During the 0.2.x release cycle, the OpenOCD project began providing a Doxygen reference manual. This document contains more technical information about the software internals, development processes, and similar documentation: @uref{http://openocd.berlios.de/doc/doxygen/index.html} This document is a work-in-progress, but contributions would be welcome to fill in the gaps. All of the source files are provided in-tree, listed in the Doxyfile configuration in the top of the source tree. @section OpenOCD Developer Mailing List The OpenOCD Developer Mailing List provides the primary means of communication between developers: @uref{https://lists.berlios.de/mailman/listinfo/openocd-development} Discuss and submit patches to this list. The @file{PATCHES.txt} file contains basic information about how to prepare patches. @section OpenOCD Bug Database During the 0.4.x release cycle the OpenOCD project team began using Trac for its bug database: @uref{https://sourceforge.net/apps/trac/openocd} @node Debug Adapter Hardware @chapter Debug Adapter Hardware @cindex dongles @cindex FTDI @cindex wiggler @cindex zy1000 @cindex printer port @cindex USB Adapter @cindex RTCK Defined: @b{dongle}: A small device that plugins into a computer and serves as an adapter .... [snip] In the OpenOCD case, this generally refers to @b{a small adapter} that attaches to your computer via USB or the Parallel Printer Port. One exception is the Zylin ZY1000, packaged as a small box you attach via an ethernet cable. The Zylin ZY1000 has the advantage that it does not require any drivers to be installed on the developer PC. It also has a built in web interface. It supports RTCK/RCLK or adaptive clocking and has a built in relay to power cycle targets remotely. @section Choosing a Dongle There are several things you should keep in mind when choosing a dongle. @enumerate @item @b{Transport} Does it support the kind of communication that you need? OpenOCD focusses mostly on JTAG. Your version may also support other ways to communicate with target devices. @item @b{Voltage} What voltage is your target - 1.8, 2.8, 3.3, or 5V? Does your dongle support it? You might need a level converter. @item @b{Pinout} What pinout does your target board use? Does your dongle support it? You may be able to use jumper wires, or an "octopus" connector, to convert pinouts. @item @b{Connection} Does your computer have the USB, printer, or Ethernet port needed? @item @b{RTCK} Do you expect to use it with ARM chips and boards with RTCK support? Also known as ``adaptive clocking'' @end enumerate @section Stand alone Systems @b{ZY1000} See: @url{http://www.zylin.com/zy1000.html} Technically, not a dongle, but a standalone box. The ZY1000 has the advantage that it does not require any drivers installed on the developer PC. It also has a built in web interface. It supports RTCK/RCLK or adaptive clocking and has a built in relay to power cycle targets remotely. @section USB FT2232 Based There are many USB JTAG dongles on the market, many of them are based on a chip from ``Future Technology Devices International'' (FTDI) known as the FTDI FT2232; this is a USB full speed (12 Mbps) chip. See: @url{http://www.ftdichip.com} for more information. In summer 2009, USB high speed (480 Mbps) versions of these FTDI chips are starting to become available in JTAG adapters. (Adapters using those high speed FT2232H chips may support adaptive clocking.) The FT2232 chips are flexible enough to support some other transport options, such as SWD or the SPI variants used to program some chips. They have two communications channels, and one can be used for a UART adapter at the same time the other one is used to provide a debug adapter. Also, some development boards integrate an FT2232 chip to serve as a built-in low coast debug adapter and usb-to-serial solution. @itemize @bullet @item @b{usbjtag} @* Link @url{http://www.hs-augsburg.de/~hhoegl/proj/usbjtag/usbjtag.html} @item @b{jtagkey} @* See: @url{http://www.amontec.com/jtagkey.shtml} @item @b{jtagkey2} @* See: @url{http://www.amontec.com/jtagkey2.shtml} @item @b{oocdlink} @* See: @url{http://www.oocdlink.com} By Joern Kaipf @item @b{signalyzer} @* See: @url{http://www.signalyzer.com} @item @b{Stellaris Eval Boards} @* See: @url{http://www.luminarymicro.com} - The Stellaris eval boards bundle FT2232-based JTAG and SWD support, which can be used to debug the Stellaris chips. Using separate JTAG adapters is optional. These boards can also be used in a "pass through" mode as JTAG adapters to other target boards, disabling the Stellaris chip. @item @b{Luminary ICDI} @* See: @url{http://www.luminarymicro.com} - Luminary In-Circuit Debug Interface (ICDI) Boards are included in Stellaris LM3S9B9x Evaluation Kits. Like the non-detachable FT2232 support on the other Stellaris eval boards, they can be used to debug other target boards. @item @b{olimex-jtag} @* See: @url{http://www.olimex.com} @item @b{flyswatter} @* See: @url{http://www.tincantools.com} @item @b{turtelizer2} @* See: @uref{http://www.ethernut.de/en/hardware/turtelizer/index.html, Turtelizer 2}, or @url{http://www.ethernut.de} @item @b{comstick} @* Link: @url{http://www.hitex.com/index.php?id=383} @item @b{stm32stick} @* Link @url{http://www.hitex.com/stm32-stick} @item @b{axm0432_jtag} @* Axiom AXM-0432 Link @url{http://www.axman.com} @item @b{cortino} @* Link @url{http://www.hitex.com/index.php?id=cortino} @end itemize @section USB-JTAG / Altera USB-Blaster compatibles These devices also show up as FTDI devices, but are not protocol-compatible with the FT2232 devices. They are, however, protocol-compatible among themselves. USB-JTAG devices typically consist of a FT245 followed by a CPLD that understands a particular protocol, or emulate this protocol using some other hardware. They may appear under different USB VID/PID depending on the particular product. The driver can be configured to search for any VID/PID pair (see the section on driver commands). @itemize @item @b{USB-JTAG} Kolja Waschk's USB Blaster-compatible adapter @* Link: @url{http://www.ixo.de/info/usb_jtag/} @item @b{Altera USB-Blaster} @* Link: @url{http://www.altera.com/literature/ug/ug_usb_blstr.pdf} @end itemize @section USB JLINK based There are several OEM versions of the Segger @b{JLINK} adapter. It is an example of a micro controller based JTAG adapter, it uses an AT91SAM764 internally. @itemize @bullet @item @b{ATMEL SAMICE} Only works with ATMEL chips! @* Link: @url{http://www.atmel.com/dyn/products/tools_card.asp?tool_id=3892} @item @b{SEGGER JLINK} @* Link: @url{http://www.segger.com/jlink.html} @item @b{IAR J-Link} @* Link: @url{http://www.iar.com/website1/1.0.1.0/369/1/index.php} @end itemize @section USB RLINK based Raisonance has an adapter called @b{RLink}. It exists in a stripped-down form on the STM32 Primer, permanently attached to the JTAG lines. It also exists on the STM32 Primer2, but that is wired for SWD and not JTAG, thus not supported. @itemize @bullet @item @b{Raisonance RLink} @* Link: @url{http://www.raisonance.com/products/RLink.php} @item @b{STM32 Primer} @* Link: @url{http://www.stm32circle.com/resources/stm32primer.php} @item @b{STM32 Primer2} @* Link: @url{http://www.stm32circle.com/resources/stm32primer2.php} @end itemize @section USB Other @itemize @bullet @item @b{USBprog} @* Link: @url{http://www.embedded-projects.net/usbprog} - which uses an Atmel MEGA32 and a UBN9604 @item @b{USB - Presto} @* Link: @url{http://tools.asix.net/prg_presto.htm} @item @b{Versaloon-Link} @* Link: @url{http://www.simonqian.com/en/Versaloon} @item @b{ARM-JTAG-EW} @* Link: @url{http://www.olimex.com/dev/arm-jtag-ew.html} @item @b{Buspirate} @* Link: @url{http://dangerousprototypes.com/bus-pirate-manual/} @end itemize @section IBM PC Parallel Printer Port Based The two well known ``JTAG Parallel Ports'' cables are the Xilnx DLC5 and the MacGraigor Wiggler. There are many clones and variations of these on the market. Note that parallel ports are becoming much less common, so if you have the choice you should probably avoid these adapters in favor of USB-based ones. @itemize @bullet @item @b{Wiggler} - There are many clones of this. @* Link: @url{http://www.macraigor.com/wiggler.htm} @item @b{DLC5} - From XILINX - There are many clones of this @* Link: Search the web for: ``XILINX DLC5'' - it is no longer produced, PDF schematics are easily found and it is easy to make. @item @b{Amontec - JTAG Accelerator} @* Link: @url{http://www.amontec.com/jtag_accelerator.shtml} @item @b{GW16402} @* Link: @url{http://www.gateworks.com/products/avila_accessories/gw16042.php} @item @b{Wiggler2} @*@uref{http://www.ccac.rwth-aachen.de/@/~michaels/@/index.php/hardware/@/armjtag, Improved parallel-port wiggler-style JTAG adapter} @item @b{Wiggler_ntrst_inverted} @* Yet another variation - See the source code, src/jtag/parport.c @item @b{old_amt_wiggler} @* Unknown - probably not on the market today @item @b{arm-jtag} @* Link: Most likely @url{http://www.olimex.com/dev/arm-jtag.html} [another wiggler clone] @item @b{chameleon} @* Link: @url{http://www.amontec.com/chameleon.shtml} @item @b{Triton} @* Unknown. @item @b{Lattice} @* ispDownload from Lattice Semiconductor @url{http://www.latticesemi.com/lit/docs/@/devtools/dlcable.pdf} @item @b{flashlink} @* From ST Microsystems; @uref{http://www.st.com/stonline/@/products/literature/um/7889.pdf, FlashLINK JTAG programing cable for PSD and uPSD} @end itemize @section Other... @itemize @bullet @item @b{ep93xx} @* An EP93xx based Linux machine using the GPIO pins directly. @item @b{at91rm9200} @* Like the EP93xx - but an ATMEL AT91RM9200 based solution using the GPIO pins on the chip. @end itemize @node About JIM-Tcl @chapter About JIM-Tcl @cindex JIM Tcl @cindex tcl OpenOCD includes a small ``Tcl Interpreter'' known as JIM-Tcl. This programming language provides a simple and extensible command interpreter. All commands presented in this Guide are extensions to JIM-Tcl. You can use them as simple commands, without needing to learn much of anything about Tcl. Alternatively, can write Tcl programs with them. You can learn more about JIM at its website, @url{http://jim.berlios.de}. @itemize @bullet @item @b{JIM vs. Tcl} @* JIM-TCL is a stripped down version of the well known Tcl language, which can be found here: @url{http://www.tcl.tk}. JIM-Tcl has far fewer features. JIM-Tcl is a single .C file and a single .H file and implements the basic Tcl command set. In contrast: Tcl 8.6 is a 4.2 MB .zip file containing 1540 files. @item @b{Missing Features} @* Our practice has been: Add/clone the real Tcl feature if/when needed. We welcome JIM Tcl improvements, not bloat. @item @b{Scripts} @* OpenOCD configuration scripts are JIM Tcl Scripts. OpenOCD's command interpreter today is a mixture of (newer) JIM-Tcl commands, and (older) the orginal command interpreter. @item @b{Commands} @* At the OpenOCD telnet command line (or via the GDB mon command) one can type a Tcl for() loop, set variables, etc. Some of the commands documented in this guide are implemented as Tcl scripts, from a @file{startup.tcl} file internal to the server. @item @b{Historical Note} @* JIM-Tcl was introduced to OpenOCD in spring 2008. @item @b{Need a crash course in Tcl?} @*@xref{Tcl Crash Course}. @end itemize @node Running @chapter Running @cindex command line options @cindex logfile @cindex directory search Properly installing OpenOCD sets up your operating system to grant it access to the debug adapters. On Linux, this usually involves installing a file in @file{/etc/udev/rules.d,} so OpenOCD has permissions. MS-Windows needs complex and confusing driver configuration for every peripheral. Such issues are unique to each operating system, and are not detailed in this User's Guide. Then later you will invoke the OpenOCD server, with various options to tell it how each debug session should work. The @option{--help} option shows: @verbatim bash$ openocd --help --help | -h display this help --version | -v display OpenOCD version --file | -f use configuration file <name> --search | -s dir to search for config files and scripts --debug | -d set debug level <0-3> --log_output | -l redirect log output to file <name> --command | -c run <command> --pipe | -p use pipes when talking to gdb @end verbatim If you don't give any @option{-f} or @option{-c} options, OpenOCD tries to read the configuration file @file{openocd.cfg}. To specify one or more different configuration files, use @option{-f} options. For example: @example openocd -f config1.cfg -f config2.cfg -f config3.cfg @end example Configuration files and scripts are searched for in @enumerate @item the current directory, @item any search dir specified on the command line using the @option{-s} option, @item any search dir specified using the @command{add_script_search_dir} command, @item @file{$HOME/.openocd} (not on Windows), @item the site wide script library @file{$pkgdatadir/site} and @item the OpenOCD-supplied script library @file{$pkgdatadir/scripts}. @end enumerate The first found file with a matching file name will be used. @quotation Note Don't try to use configuration script names or paths which include the "#" character. That character begins Tcl comments. @end quotation @section Simple setup, no customization In the best case, you can use two scripts from one of the script libraries, hook up your JTAG adapter, and start the server ... and your JTAG setup will just work "out of the box". Always try to start by reusing those scripts, but assume you'll need more customization even if this works. @xref{OpenOCD Project Setup}. If you find a script for your JTAG adapter, and for your board or target, you may be able to hook up your JTAG adapter then start the server like: @example openocd -f interface/ADAPTER.cfg -f board/MYBOARD.cfg @end example You might also need to configure which reset signals are present, using @option{-c 'reset_config trst_and_srst'} or something similar. If all goes well you'll see output something like @example Open On-Chip Debugger 0.4.0 (2010-01-14-15:06) For bug reports, read http://openocd.berlios.de/doc/doxygen/bugs.html Info : JTAG tap: lm3s.cpu tap/device found: 0x3ba00477 (mfg: 0x23b, part: 0xba00, ver: 0x3) @end example Seeing that "tap/device found" message, and no warnings, means the JTAG communication is working. That's a key milestone, but you'll probably need more project-specific setup. @section What OpenOCD does as it starts OpenOCD starts by processing the configuration commands provided on the command line or, if there were no @option{-c command} or @option{-f file.cfg} options given, in @file{openocd.cfg}. @xref{Configuration Stage}. At the end of the configuration stage it verifies the JTAG scan chain defined using those commands; your configuration should ensure that this always succeeds. Normally, OpenOCD then starts running as a daemon. Alternatively, commands may be used to terminate the configuration stage early, perform work (such as updating some flash memory), and then shut down without acting as a daemon. Once OpenOCD starts running as a daemon, it waits for connections from clients (Telnet, GDB, Other) and processes the commands issued through those channels. If you are having problems, you can enable internal debug messages via the @option{-d} option. Also it is possible to interleave JIM-Tcl commands w/config scripts using the @option{-c} command line switch. To enable debug output (when reporting problems or working on OpenOCD itself), use the @option{-d} command line switch. This sets the @option{debug_level} to "3", outputting the most information, including debug messages. The default setting is "2", outputting only informational messages, warnings and errors. You can also change this setting from within a telnet or gdb session using @command{debug_level <n>} (@pxref{debug_level}). You can redirect all output from the daemon to a file using the @option{-l <logfile>} switch. For details on the @option{-p} option. @xref{Connecting to GDB}. Note! OpenOCD will launch the GDB & telnet server even if it can not establish a connection with the target. In general, it is possible for the JTAG controller to be unresponsive until the target is set up correctly via e.g. GDB monitor commands in a GDB init script. @node OpenOCD Project Setup @chapter OpenOCD Project Setup To use OpenOCD with your development projects, you need to do more than just connecting the JTAG adapter hardware (dongle) to your development board and then starting the OpenOCD server. You also need to configure that server so that it knows about that adapter and board, and helps your work. You may also want to connect OpenOCD to GDB, possibly using Eclipse or some other GUI. @section Hooking up the JTAG Adapter Today's most common case is a dongle with a JTAG cable on one side (such as a ribbon cable with a 10-pin or 20-pin IDC connector) and a USB cable on the other. Instead of USB, some cables use Ethernet; older ones may use a PC parallel port, or even a serial port. @enumerate @item @emph{Start with power to your target board turned off}, and nothing connected to your JTAG adapter. If you're particularly paranoid, unplug power to the board. It's important to have the ground signal properly set up, unless you are using a JTAG adapter which provides galvanic isolation between the target board and the debugging host. @item @emph{Be sure it's the right kind of JTAG connector.} If your dongle has a 20-pin ARM connector, you need some kind of adapter (or octopus, see below) to hook it up to boards using 14-pin or 10-pin connectors ... or to 20-pin connectors which don't use ARM's pinout. In the same vein, make sure the voltage levels are compatible. Not all JTAG adapters have the level shifters needed to work with 1.2 Volt boards. @item @emph{Be certain the cable is properly oriented} or you might damage your board. In most cases there are only two possible ways to connect the cable. Connect the JTAG cable from your adapter to the board. Be sure it's firmly connected. In the best case, the connector is keyed to physically prevent you from inserting it wrong. This is most often done using a slot on the board's male connector housing, which must match a key on the JTAG cable's female connector. If there's no housing, then you must look carefully and make sure pin 1 on the cable hooks up to pin 1 on the board. Ribbon cables are frequently all grey except for a wire on one edge, which is red. The red wire is pin 1. Sometimes dongles provide cables where one end is an ``octopus'' of color coded single-wire connectors, instead of a connector block. These are great when converting from one JTAG pinout to another, but are tedious to set up. Use these with connector pinout diagrams to help you match up the adapter signals to the right board pins. @item @emph{Connect the adapter's other end} once the JTAG cable is connected. A USB, parallel, or serial port connector will go to the host which you are using to run OpenOCD. For Ethernet, consult the documentation and your network administrator. For USB based JTAG adapters you have an easy sanity check at this point: does the host operating system see the JTAG adapter? If that host is an MS-Windows host, you'll need to install a driver before OpenOCD works. @item @emph{Connect the adapter's power supply, if needed.} This step is primarily for non-USB adapters, but sometimes USB adapters need extra power. @item @emph{Power up the target board.} Unless you just let the magic smoke escape, you're now ready to set up the OpenOCD server so you can use JTAG to work with that board. @end enumerate Talk with the OpenOCD server using telnet (@code{telnet localhost 4444} on many systems) or GDB. @xref{GDB and OpenOCD}. @section Project Directory There are many ways you can configure OpenOCD and start it up. A simple way to organize them all involves keeping a single directory for your work with a given board. When you start OpenOCD from that directory, it searches there first for configuration files, scripts, files accessed through semihosting, and for code you upload to the target board. It is also the natural place to write files, such as log files and data you download from the board. @section Configuration Basics There are two basic ways of configuring OpenOCD, and a variety of ways you can mix them. Think of the difference as just being how you start the server: @itemize @item Many @option{-f file} or @option{-c command} options on the command line @item No options, but a @dfn{user config file} in the current directory named @file{openocd.cfg} @end itemize Here is an example @file{openocd.cfg} file for a setup using a Signalyzer FT2232-based JTAG adapter to talk to a board with an Atmel AT91SAM7X256 microcontroller: @example source [find interface/signalyzer.cfg] # GDB can also flash my flash! gdb_memory_map enable gdb_flash_program enable source [find target/sam7x256.cfg] @end example Here is the command line equivalent of that configuration: @example openocd -f interface/signalyzer.cfg \ -c "gdb_memory_map enable" \ -c "gdb_flash_program enable" \ -f target/sam7x256.cfg @end example You could wrap such long command lines in shell scripts, each supporting a different development task. One might re-flash the board with a specific firmware version. Another might set up a particular debugging or run-time environment. @quotation Important At this writing (October 2009) the command line method has problems with how it treats variables. For example, after @option{-c "set VAR value"}, or doing the same in a script, the variable @var{VAR} will have no value that can be tested in a later script. @end quotation Here we will focus on the simpler solution: one user config file, including basic configuration plus any TCL procedures to simplify your work. @section User Config Files @cindex config file, user @cindex user config file @cindex config file, overview A user configuration file ties together all the parts of a project in one place. One of the following will match your situation best: @itemize @item Ideally almost everything comes from configuration files provided by someone else. For example, OpenOCD distributes a @file{scripts} directory (probably in @file{/usr/share/openocd/scripts} on Linux). Board and tool vendors can provide these too, as can individual user sites; the @option{-s} command line option lets you say where to find these files. (@xref{Running}.) The AT91SAM7X256 example above works this way. Three main types of non-user configuration file each have their own subdirectory in the @file{scripts} directory: @enumerate @item @b{interface} -- one for each different debug adapter; @item @b{board} -- one for each different board @item @b{target} -- the chips which integrate CPUs and other JTAG TAPs @end enumerate Best case: include just two files, and they handle everything else. The first is an interface config file. The second is board-specific, and it sets up the JTAG TAPs and their GDB targets (by deferring to some @file{target.cfg} file), declares all flash memory, and leaves you nothing to do except meet your deadline: @example source [find interface/olimex-jtag-tiny.cfg] source [find board/csb337.cfg] @end example Boards with a single microcontroller often won't need more than the target config file, as in the AT91SAM7X256 example. That's because there is no external memory (flash, DDR RAM), and the board differences are encapsulated by application code. @item Maybe you don't know yet what your board looks like to JTAG. Once you know the @file{interface.cfg} file to use, you may need help from OpenOCD to discover what's on the board. Once you find the JTAG TAPs, you can just search for appropriate target and board configuration files ... or write your own, from the bottom up. @xref{Autoprobing}. @item You can often reuse some standard config files but need to write a few new ones, probably a @file{board.cfg} file. You will be using commands described later in this User's Guide, and working with the guidelines in the next chapter. For example, there may be configuration files for your JTAG adapter and target chip, but you need a new board-specific config file giving access to your particular flash chips. Or you might need to write another target chip configuration file for a new chip built around the Cortex M3 core. @quotation Note When you write new configuration files, please submit them for inclusion in the next OpenOCD release. For example, a @file{board/newboard.cfg} file will help the next users of that board, and a @file{target/newcpu.cfg} will help support users of any board using that chip. @end quotation @item You may may need to write some C code. It may be as simple as a supporting a new ft2232 or parport based adapter; a bit more involved, like a NAND or NOR flash controller driver; or a big piece of work like supporting a new chip architecture. @end itemize Reuse the existing config files when you can. Look first in the @file{scripts/boards} area, then @file{scripts/targets}. You may find a board configuration that's a good example to follow. When you write config files, separate the reusable parts (things every user of that interface, chip, or board needs) from ones specific to your environment and debugging approach. @itemize @item For example, a @code{gdb-attach} event handler that invokes the @command{reset init} command will interfere with debugging early boot code, which performs some of the same actions that the @code{reset-init} event handler does. @item Likewise, the @command{arm9 vector_catch} command (or @cindex vector_catch its siblings @command{xscale vector_catch} and @command{cortex_m3 vector_catch}) can be a timesaver during some debug sessions, but don't make everyone use that either. Keep those kinds of debugging aids in your user config file, along with messaging and tracing setup. (@xref{Software Debug Messages and Tracing}.) @item You might need to override some defaults. For example, you might need to move, shrink, or back up the target's work area if your application needs much SRAM. @item TCP/IP port configuration is another example of something which is environment-specific, and should only appear in a user config file. @xref{TCP/IP Ports}. @end itemize @section Project-Specific Utilities A few project-specific utility routines may well speed up your work. Write them, and keep them in your project's user config file. For example, if you are making a boot loader work on a board, it's nice to be able to debug the ``after it's loaded to RAM'' parts separately from the finicky early code which sets up the DDR RAM controller and clocks. A script like this one, or a more GDB-aware sibling, may help: @example proc ramboot @{ @} @{ # Reset, running the target's "reset-init" scripts # to initialize clocks and the DDR RAM controller. # Leave the CPU halted. reset init # Load CONFIG_SKIP_LOWLEVEL_INIT version into DDR RAM. load_image u-boot.bin 0x20000000 # Start running. resume 0x20000000 @} @end example Then once that code is working you will need to make it boot from NOR flash; a different utility would help. Alternatively, some developers write to flash using GDB. (You might use a similar script if you're working with a flash based microcontroller application instead of a boot loader.) @example proc newboot @{ @} @{ # Reset, leaving the CPU halted. The "reset-init" event # proc gives faster access to the CPU and to NOR flash; # "reset halt" would be slower. reset init # Write standard version of U-Boot into the first two # sectors of NOR flash ... the standard version should # do the same lowlevel init as "reset-init". flash protect 0 0 1 off flash erase_sector 0 0 1 flash write_bank 0 u-boot.bin 0x0 flash protect 0 0 1 on # Reboot from scratch using that new boot loader. reset run @} @end example You may need more complicated utility procedures when booting from NAND. That often involves an extra bootloader stage, running from on-chip SRAM to perform DDR RAM setup so it can load the main bootloader code (which won't fit into that SRAM). Other helper scripts might be used to write production system images, involving considerably more than just a three stage bootloader. @section Target Software Changes Sometimes you may want to make some small changes to the software you're developing, to help make JTAG debugging work better. For example, in C or assembly language code you might use @code{#ifdef JTAG_DEBUG} (or its converse) around code handling issues like: @itemize @bullet @item @b{Watchdog Timers}... Watchog timers are typically used to automatically reset systems if some application task doesn't periodically reset the timer. (The assumption is that the system has locked up if the task can't run.) When a JTAG debugger halts the system, that task won't be able to run and reset the timer ... potentially causing resets in the middle of your debug sessions. It's rarely a good idea to disable such watchdogs, since their usage needs to be debugged just like all other parts of your firmware. That might however be your only option. Look instead for chip-specific ways to stop the watchdog from counting while the system is in a debug halt state. It may be simplest to set that non-counting mode in your debugger startup scripts. You may however need a different approach when, for example, a motor could be physically damaged by firmware remaining inactive in a debug halt state. That might involve a type of firmware mode where that "non-counting" mode is disabled at the beginning then re-enabled at the end; a watchdog reset might fire and complicate the debug session, but hardware (or people) would be protected.@footnote{Note that many systems support a "monitor mode" debug that is a somewhat cleaner way to address such issues. You can think of it as only halting part of the system, maybe just one task, instead of the whole thing. At this writing, January 2010, OpenOCD based debugging does not support monitor mode debug, only "halt mode" debug.} @item @b{ARM Semihosting}... @cindex ARM semihosting When linked with a special runtime library provided with many toolchains@footnote{See chapter 8 "Semihosting" in @uref{http://infocenter.arm.com/help/topic/com.arm.doc.dui0203i/DUI0203I_rvct_developer_guide.pdf, ARM DUI 0203I}, the "RealView Compilation Tools Developer Guide". The CodeSourcery EABI toolchain also includes a semihosting library.}, your target code can use I/O facilities on the debug host. That library provides a small set of system calls which are handled by OpenOCD. It can let the debugger provide your system console and a file system, helping with early debugging or providing a more capable environment for sometimes-complex tasks like installing system firmware onto NAND or SPI flash. @item @b{ARM Wait-For-Interrupt}... Many ARM chips synchronize the JTAG clock using the core clock. Low power states which stop that core clock thus prevent JTAG access. Idle loops in tasking environments often enter those low power states via the @code{WFI} instruction (or its coprocessor equivalent, before ARMv7). You may want to @emph{disable that instruction} in source code, or otherwise prevent using that state, to ensure you can get JTAG access at any time.@footnote{As a more polite alternative, some processors have special debug-oriented registers which can be used to change various features including how the low power states are clocked while debugging. The STM32 DBGMCU_CR register is an example; at the cost of extra power consumption, JTAG can be used during low power states.} For example, the OpenOCD @command{halt} command may not work for an idle processor otherwise. @item @b{Delay after reset}... Not all chips have good support for debugger access right after reset; many LPC2xxx chips have issues here. Similarly, applications that reconfigure pins used for JTAG access as they start will also block debugger access. To work with boards like this, @emph{enable a short delay loop} the first thing after reset, before "real" startup activities. For example, one second's delay is usually more than enough time for a JTAG debugger to attach, so that early code execution can be debugged or firmware can be replaced. @item @b{Debug Communications Channel (DCC)}... Some processors include mechanisms to send messages over JTAG. Many ARM cores support these, as do some cores from other vendors. (OpenOCD may be able to use this DCC internally, speeding up some operations like writing to memory.) Your application may want to deliver various debugging messages over JTAG, by @emph{linking with a small library of code} provided with OpenOCD and using the utilities there to send various kinds of message. @xref{Software Debug Messages and Tracing}. @end itemize @section Target Hardware Setup Chip vendors often provide software development boards which are highly configurable, so that they can support all options that product boards may require. @emph{Make sure that any jumpers or switches match the system configuration you are working with.} Common issues include: @itemize @bullet @item @b{JTAG setup} ... Boards may support more than one JTAG configuration. Examples include jumpers controlling pullups versus pulldowns on the nTRST and/or nSRST signals, and choice of connectors (e.g. which of two headers on the base board, or one from a daughtercard). For some Texas Instruments boards, you may need to jumper the EMU0 and EMU1 signals (which OpenOCD won't currently control). @item @b{Boot Modes} ... Complex chips often support multiple boot modes, controlled by external jumpers. Make sure this is set up correctly. For example many i.MX boards from NXP need to be jumpered to "ATX mode" to start booting using the on-chip ROM, when using second stage bootloader code stored in a NAND flash chip. Such explicit configuration is common, and not limited to booting from NAND. You might also need to set jumpers to start booting using code loaded from an MMC/SD card; external SPI flash; Ethernet, UART, or USB links; NOR flash; OneNAND flash; some external host; or various other sources. @item @b{Memory Addressing} ... Boards which support multiple boot modes may also have jumpers to configure memory addressing. One board, for example, jumpers external chipselect 0 (used for booting) to address either a large SRAM (which must be pre-loaded via JTAG), NOR flash, or NAND flash. When it's jumpered to address NAND flash, that board must also be told to start booting from on-chip ROM. Your @file{board.cfg} file may also need to be told this jumper configuration, so that it can know whether to declare NOR flash using @command{flash bank} or instead declare NAND flash with @command{nand device}; and likewise which probe to perform in its @code{reset-init} handler. A closely related issue is bus width. Jumpers might need to distinguish between 8 bit or 16 bit bus access for the flash used to start booting. @item @b{Peripheral Access} ... Development boards generally provide access to every peripheral on the chip, sometimes in multiple modes (such as by providing multiple audio codec chips). This interacts with software configuration of pin multiplexing, where for example a given pin may be routed either to the MMC/SD controller or the GPIO controller. It also often interacts with configuration jumpers. One jumper may be used to route signals to an MMC/SD card slot or an expansion bus (which might in turn affect booting); others might control which audio or video codecs are used. @end itemize Plus you should of course have @code{reset-init} event handlers which set up the hardware to match that jumper configuration. That includes in particular any oscillator or PLL used to clock the CPU, and any memory controllers needed to access external memory and peripherals. Without such handlers, you won't be able to access those resources without working target firmware which can do that setup ... this can be awkward when you're trying to debug that target firmware. Even if there's a ROM bootloader which handles a few issues, it rarely provides full access to all board-specific capabilities. @node Config File Guidelines @chapter Config File Guidelines This chapter is aimed at any user who needs to write a config file, including developers and integrators of OpenOCD and any user who needs to get a new board working smoothly. It provides guidelines for creating those files. You should find the following directories under @t{$(INSTALLDIR)/scripts}, with files including the ones listed here. Use them as-is where you can; or as models for new files. @itemize @bullet @item @file{interface} ... These are for debug adapters. Files that configure JTAG adapters go here. @example $ ls interface arm-jtag-ew.cfg hitex_str9-comstick.cfg oocdlink.cfg arm-usb-ocd.cfg icebear.cfg openocd-usb.cfg at91rm9200.cfg jlink.cfg parport.cfg axm0432.cfg jtagkey2.cfg parport_dlc5.cfg calao-usb-a9260-c01.cfg jtagkey.cfg rlink.cfg calao-usb-a9260-c02.cfg jtagkey-tiny.cfg sheevaplug.cfg calao-usb-a9260.cfg luminary.cfg signalyzer.cfg chameleon.cfg luminary-icdi.cfg stm32-stick.cfg cortino.cfg luminary-lm3s811.cfg turtelizer2.cfg dummy.cfg olimex-arm-usb-ocd.cfg usbprog.cfg flyswatter.cfg olimex-jtag-tiny.cfg vsllink.cfg $ @end example @item @file{board} ... think Circuit Board, PWA, PCB, they go by many names. Board files contain initialization items that are specific to a board. They reuse target configuration files, since the same microprocessor chips are used on many boards, but support for external parts varies widely. For example, the SDRAM initialization sequence for the board, or the type of external flash and what address it uses. Any initialization sequence to enable that external flash or SDRAM should be found in the board file. Boards may also contain multiple targets: two CPUs; or a CPU and an FPGA. @example $ ls board arm_evaluator7t.cfg keil_mcb1700.cfg at91rm9200-dk.cfg keil_mcb2140.cfg at91sam9g20-ek.cfg linksys_nslu2.cfg atmel_at91sam7s-ek.cfg logicpd_imx27.cfg atmel_at91sam9260-ek.cfg mini2440.cfg atmel_sam3u_ek.cfg olimex_LPC2378STK.cfg crossbow_tech_imote2.cfg olimex_lpc_h2148.cfg csb337.cfg olimex_sam7_ex256.cfg csb732.cfg olimex_sam9_l9260.cfg digi_connectcore_wi-9c.cfg olimex_stm32_h103.cfg dm355evm.cfg omap2420_h4.cfg dm365evm.cfg osk5912.cfg dm6446evm.cfg pic-p32mx.cfg eir.cfg propox_mmnet1001.cfg ek-lm3s1968.cfg pxa255_sst.cfg ek-lm3s3748.cfg sheevaplug.cfg ek-lm3s811.cfg stm3210e_eval.cfg ek-lm3s9b9x.cfg stm32f10x_128k_eval.cfg hammer.cfg str910-eval.cfg hitex_lpc2929.cfg telo.cfg hitex_stm32-performancestick.cfg ti_beagleboard.cfg hitex_str9-comstick.cfg topas910.cfg iar_str912_sk.cfg topasa900.cfg imx27ads.cfg unknown_at91sam9260.cfg imx27lnst.cfg x300t.cfg imx31pdk.cfg zy1000.cfg $ @end example @item @file{target} ... think chip. The ``target'' directory represents the JTAG TAPs on a chip which OpenOCD should control, not a board. Two common types of targets are ARM chips and FPGA or CPLD chips. When a chip has multiple TAPs (maybe it has both ARM and DSP cores), the target config file defines all of them. @example $ ls target aduc702x.cfg imx27.cfg pxa255.cfg ar71xx.cfg imx31.cfg pxa270.cfg at91eb40a.cfg imx35.cfg readme.txt at91r40008.cfg is5114.cfg sam7se512.cfg at91rm9200.cfg ixp42x.cfg sam7x256.cfg at91sam3u1c.cfg lm3s1968.cfg samsung_s3c2410.cfg at91sam3u1e.cfg lm3s3748.cfg samsung_s3c2440.cfg at91sam3u2c.cfg lm3s6965.cfg samsung_s3c2450.cfg at91sam3u2e.cfg lm3s811.cfg samsung_s3c4510.cfg at91sam3u4c.cfg lm3s9b9x.cfg samsung_s3c6410.cfg at91sam3u4e.cfg lpc1768.cfg sharp_lh79532.cfg at91sam3uXX.cfg lpc2103.cfg smdk6410.cfg at91sam7sx.cfg lpc2124.cfg smp8634.cfg at91sam9260.cfg lpc2129.cfg stm32.cfg c100.cfg lpc2148.cfg str710.cfg c100config.tcl lpc2294.cfg str730.cfg c100helper.tcl lpc2378.cfg str750.cfg c100regs.tcl lpc2478.cfg str912.cfg cs351x.cfg lpc2900.cfg telo.cfg davinci.cfg mega128.cfg ti_dm355.cfg dragonite.cfg netx500.cfg ti_dm365.cfg epc9301.cfg omap2420.cfg ti_dm6446.cfg feroceon.cfg omap3530.cfg tmpa900.cfg icepick.cfg omap5912.cfg tmpa910.cfg imx21.cfg pic32mx.cfg xba_revA3.cfg $ @end example @item @emph{more} ... browse for other library files which may be useful. For example, there are various generic and CPU-specific utilities. @end itemize The @file{openocd.cfg} user config file may override features in any of the above files by setting variables before sourcing the target file, or by adding commands specific to their situation. @section Interface Config Files The user config file should be able to source one of these files with a command like this: @example source [find interface/FOOBAR.cfg] @end example A preconfigured interface file should exist for every debug adapter in use today with OpenOCD. That said, perhaps some of these config files have only been used by the developer who created it. A separate chapter gives information about how to set these up. @xref{Debug Adapter Configuration}. Read the OpenOCD source code (and Developer's GUide) if you have a new kind of hardware interface and need to provide a driver for it. @section Board Config Files @cindex config file, board @cindex board config file The user config file should be able to source one of these files with a command like this: @example source [find board/FOOBAR.cfg] @end example The point of a board config file is to package everything about a given board that user config files need to know. In summary the board files should contain (if present) @enumerate @item One or more @command{source [target/...cfg]} statements @item NOR flash configuration (@pxref{NOR Configuration}) @item NAND flash configuration (@pxref{NAND Configuration}) @item Target @code{reset} handlers for SDRAM and I/O configuration @item JTAG adapter reset configuration (@pxref{Reset Configuration}) @item All things that are not ``inside a chip'' @end enumerate Generic things inside target chips belong in target config files, not board config files. So for example a @code{reset-init} event handler should know board-specific oscillator and PLL parameters, which it passes to target-specific utility code. The most complex task of a board config file is creating such a @code{reset-init} event handler. Define those handlers last, after you verify the rest of the board configuration works. @subsection Communication Between Config files In addition to target-specific utility code, another way that board and target config files communicate is by following a convention on how to use certain variables. The full Tcl/Tk language supports ``namespaces'', but JIM-Tcl does not. Thus the rule we follow in OpenOCD is this: Variables that begin with a leading underscore are temporary in nature, and can be modified and used at will within a target configuration file. Complex board config files can do the things like this, for a board with three chips: @example # Chip #1: PXA270 for network side, big endian set CHIPNAME network set ENDIAN big source [find target/pxa270.cfg] # on return: _TARGETNAME = network.cpu # other commands can refer to the "network.cpu" target. $_TARGETNAME configure .... events for this CPU.. # Chip #2: PXA270 for video side, little endian set CHIPNAME video set ENDIAN little source [find target/pxa270.cfg] # on return: _TARGETNAME = video.cpu # other commands can refer to the "video.cpu" target. $_TARGETNAME configure .... events for this CPU.. # Chip #3: Xilinx FPGA for glue logic set CHIPNAME xilinx unset ENDIAN source [find target/spartan3.cfg] @end example That example is oversimplified because it doesn't show any flash memory, or the @code{reset-init} event handlers to initialize external DRAM or (assuming it needs it) load a configuration into the FPGA. Such features are usually needed for low-level work with many boards, where ``low level'' implies that the board initialization software may not be working. (That's a common reason to need JTAG tools. Another is to enable working with microcontroller-based systems, which often have no debugging support except a JTAG connector.) Target config files may also export utility functions to board and user config files. Such functions should use name prefixes, to help avoid naming collisions. Board files could also accept input variables from user config files. For example, there might be a @code{J4_JUMPER} setting used to identify what kind of flash memory a development board is using, or how to set up other clocks and peripherals. @subsection Variable Naming Convention @cindex variable names Most boards have only one instance of a chip. However, it should be easy to create a board with more than one such chip (as shown above). Accordingly, we encourage these conventions for naming variables associated with different @file{target.cfg} files, to promote consistency and so that board files can override target defaults. Inputs to target config files include: @itemize @bullet @item @code{CHIPNAME} ... This gives a name to the overall chip, and is used as part of tap identifier dotted names. While the default is normally provided by the chip manufacturer, board files may need to distinguish between instances of a chip. @item @code{ENDIAN} ... By default @option{little} - although chips may hard-wire @option{big}. Chips that can't change endianness don't need to use this variable. @item @code{CPUTAPID} ... When OpenOCD examines the JTAG chain, it can be told verify the chips against the JTAG IDCODE register. The target file will hold one or more defaults, but sometimes the chip in a board will use a different ID (perhaps a newer revision). @end itemize Outputs from target config files include: @itemize @bullet @item @code{_TARGETNAME} ... By convention, this variable is created by the target configuration script. The board configuration file may make use of this variable to configure things like a ``reset init'' script, or other things specific to that board and that target. If the chip has 2 targets, the names are @code{_TARGETNAME0}, @code{_TARGETNAME1}, ... etc. @end itemize @subsection The reset-init Event Handler @cindex event, reset-init @cindex reset-init handler Board config files run in the OpenOCD configuration stage; they can't use TAPs or targets, since they haven't been fully set up yet. This means you can't write memory or access chip registers; you can't even verify that a flash chip is present. That's done later in event handlers, of which the target @code{reset-init} handler is one of the most important. Except on microcontrollers, the basic job of @code{reset-init} event handlers is setting up flash and DRAM, as normally handled by boot loaders. Microcontrollers rarely use boot loaders; they run right out of their on-chip flash and SRAM memory. But they may want to use one of these handlers too, if just for developer convenience. @quotation Note Because this is so very board-specific, and chip-specific, no examples are included here. Instead, look at the board config files distributed with OpenOCD. If you have a boot loader, its source code will help; so will configuration files for other JTAG tools (@pxref{Translating Configuration Files}). @end quotation Some of this code could probably be shared between different boards. For example, setting up a DRAM controller often doesn't differ by much except the bus width (16 bits or 32?) and memory timings, so a reusable TCL procedure loaded by the @file{target.cfg} file might take those as parameters. Similarly with oscillator, PLL, and clock setup; and disabling the watchdog. Structure the code cleanly, and provide comments to help the next developer doing such work. (@emph{You might be that next person} trying to reuse init code!) The last thing normally done in a @code{reset-init} handler is probing whatever flash memory was configured. For most chips that needs to be done while the associated target is halted, either because JTAG memory access uses the CPU or to prevent conflicting CPU access. @subsection JTAG Clock Rate Before your @code{reset-init} handler has set up the PLLs and clocking, you may need to run with a low JTAG clock rate. @xref{JTAG Speed}. Then you'd increase that rate after your handler has made it possible to use the faster JTAG clock. When the initial low speed is board-specific, for example because it depends on a board-specific oscillator speed, then you should probably set it up in the board config file; if it's target-specific, it belongs in the target config file. For most ARM-based processors the fastest JTAG clock@footnote{A FAQ @uref{http://www.arm.com/support/faqdev/4170.html} gives details.} is one sixth of the CPU clock; or one eighth for ARM11 cores. Consult chip documentation to determine the peak JTAG clock rate, which might be less than that. @quotation Warning On most ARMs, JTAG clock detection is coupled to the core clock, so software using a @option{wait for interrupt} operation blocks JTAG access. Adaptive clocking provides a partial workaround, but a more complete solution just avoids using that instruction with JTAG debuggers. @end quotation If both the chip and the board support adaptive clocking, use the @command{jtag_rclk} command, in case your board is used with JTAG adapter which also supports it. Otherwise use @command{adapter_khz}. Set the slow rate at the beginning of the reset sequence, and the faster rate as soon as the clocks are at full speed. @section Target Config Files @cindex config file, target @cindex target config file Board config files communicate with target config files using naming conventions as described above, and may source one or more target config files like this: @example source [find target/FOOBAR.cfg] @end example The point of a target config file is to package everything about a given chip that board config files need to know. In summary the target files should contain @enumerate @item Set defaults @item Add TAPs to the scan chain @item Add CPU targets (includes GDB support) @item CPU/Chip/CPU-Core specific features @item On-Chip flash @end enumerate As a rule of thumb, a target file sets up only one chip. For a microcontroller, that will often include a single TAP, which is a CPU needing a GDB target, and its on-chip flash. More complex chips may include multiple TAPs, and the target config file may need to define them all before OpenOCD can talk to the chip. For example, some phone chips have JTAG scan chains that include an ARM core for operating system use, a DSP, another ARM core embedded in an image processing engine, and other processing engines. @subsection Default Value Boiler Plate Code All target configuration files should start with code like this, letting board config files express environment-specific differences in how things should be set up. @example # Boards may override chip names, perhaps based on role, # but the default should match what the vendor uses if @{ [info exists CHIPNAME] @} @{ set _CHIPNAME $CHIPNAME @} else @{ set _CHIPNAME sam7x256 @} # ONLY use ENDIAN with targets that can change it. if @{ [info exists ENDIAN] @} @{ set _ENDIAN $ENDIAN @} else @{ set _ENDIAN little @} # TAP identifiers may change as chips mature, for example with # new revision fields (the "3" here). Pick a good default; you # can pass several such identifiers to the "jtag newtap" command. if @{ [info exists CPUTAPID ] @} @{ set _CPUTAPID $CPUTAPID @} else @{ set _CPUTAPID 0x3f0f0f0f @} @end example @c but 0x3f0f0f0f is for an str73x part ... @emph{Remember:} Board config files may include multiple target config files, or the same target file multiple times (changing at least @code{CHIPNAME}). Likewise, the target configuration file should define @code{_TARGETNAME} (or @code{_TARGETNAME0} etc) and use it later on when defining debug targets: @example set _TARGETNAME $_CHIPNAME.cpu target create $_TARGETNAME arm7tdmi -chain-position $_TARGETNAME @end example @subsection Adding TAPs to the Scan Chain After the ``defaults'' are set up, add the TAPs on each chip to the JTAG scan chain. @xref{TAP Declaration}, and the naming convention for taps. In the simplest case the chip has only one TAP, probably for a CPU or FPGA. The config file for the Atmel AT91SAM7X256 looks (in part) like this: @example jtag newtap $_CHIPNAME cpu -irlen 4 -expected-id $_CPUTAPID @end example A board with two such at91sam7 chips would be able to source such a config file twice, with different values for @code{CHIPNAME}, so it adds a different TAP each time. If there are nonzero @option{-expected-id} values, OpenOCD attempts to verify the actual tap id against those values. It will issue error messages if there is mismatch, which can help to pinpoint problems in OpenOCD configurations. @example JTAG tap: sam7x256.cpu tap/device found: 0x3f0f0f0f (Manufacturer: 0x787, Part: 0xf0f0, Version: 0x3) ERROR: Tap: sam7x256.cpu - Expected id: 0x12345678, Got: 0x3f0f0f0f ERROR: expected: mfg: 0x33c, part: 0x2345, ver: 0x1 ERROR: got: mfg: 0x787, part: 0xf0f0, ver: 0x3 @end example There are more complex examples too, with chips that have multiple TAPs. Ones worth looking at include: @itemize @item @file{target/omap3530.cfg} -- with disabled ARM and DSP, plus a JRC to enable them @item @file{target/str912.cfg} -- with flash, CPU, and boundary scan @item @file{target/ti_dm355.cfg} -- with ETM, ARM, and JRC (this JRC is not currently used) @end itemize @subsection Add CPU targets After adding a TAP for a CPU, you should set it up so that GDB and other commands can use it. @xref{CPU Configuration}. For the at91sam7 example above, the command can look like this; note that @code{$_ENDIAN} is not needed, since OpenOCD defaults to little endian, and this chip doesn't support changing that. @example set _TARGETNAME $_CHIPNAME.cpu target create $_TARGETNAME arm7tdmi -chain-position $_TARGETNAME @end example Work areas are small RAM areas associated with CPU targets. They are used by OpenOCD to speed up downloads, and to download small snippets of code to program flash chips. If the chip includes a form of ``on-chip-ram'' - and many do - define a work area if you can. Again using the at91sam7 as an example, this can look like: @example $_TARGETNAME configure -work-area-phys 0x00200000 \ -work-area-size 0x4000 -work-area-backup 0 @end example @subsection Chip Reset Setup As a rule, you should put the @command{reset_config} command into the board file. Most things you think you know about a chip can be tweaked by the board. Some chips have specific ways the TRST and SRST signals are managed. In the unusual case that these are @emph{chip specific} and can never be changed by board wiring, they could go here. For example, some chips can't support JTAG debugging without both signals. Provide a @code{reset-assert} event handler if you can. Such a handler uses JTAG operations to reset the target, letting this target config be used in systems which don't provide the optional SRST signal, or on systems where you don't want to reset all targets at once. Such a handler might write to chip registers to force a reset, use a JRC to do that (preferable -- the target may be wedged!), or force a watchdog timer to trigger. (For Cortex-M3 targets, this is not necessary. The target driver knows how to use trigger an NVIC reset when SRST is not available.) Some chips need special attention during reset handling if they're going to be used with JTAG. An example might be needing to send some commands right after the target's TAP has been reset, providing a @code{reset-deassert-post} event handler that writes a chip register to report that JTAG debugging is being done. Another would be reconfiguring the watchdog so that it stops counting while the core is halted in the debugger. JTAG clocking constraints often change during reset, and in some cases target config files (rather than board config files) are the right places to handle some of those issues. For example, immediately after reset most chips run using a slower clock than they will use later. That means that after reset (and potentially, as OpenOCD first starts up) they must use a slower JTAG clock rate than they will use later. @xref{JTAG Speed}. @quotation Important When you are debugging code that runs right after chip reset, getting these issues right is critical. In particular, if you see intermittent failures when OpenOCD verifies the scan chain after reset, look at how you are setting up JTAG clocking. @end quotation @subsection ARM Core Specific Hacks If the chip has a DCC, enable it. If the chip is an ARM9 with some special high speed download features - enable it. If present, the MMU, the MPU and the CACHE should be disabled. Some ARM cores are equipped with trace support, which permits examination of the instruction and data bus activity. Trace activity is controlled through an ``Embedded Trace Module'' (ETM) on one of the core's scan chains. The ETM emits voluminous data through a ``trace port''. (@xref{ARM Hardware Tracing}.) If you are using an external trace port, configure it in your board config file. If you are using an on-chip ``Embedded Trace Buffer'' (ETB), configure it in your target config file. @example etm config $_TARGETNAME 16 normal full etb etb config $_TARGETNAME $_CHIPNAME.etb @end example @subsection Internal Flash Configuration This applies @b{ONLY TO MICROCONTROLLERS} that have flash built in. @b{Never ever} in the ``target configuration file'' define any type of flash that is external to the chip. (For example a BOOT flash on Chip Select 0.) Such flash information goes in a board file - not the TARGET (chip) file. Examples: @itemize @bullet @item at91sam7x256 - has 256K flash YES enable it. @item str912 - has flash internal YES enable it. @item imx27 - uses boot flash on CS0 - it goes in the board file. @item pxa270 - again - CS0 flash - it goes in the board file. @end itemize @anchor{Translating Configuration Files} @section Translating Configuration Files @cindex translation If you have a configuration file for another hardware debugger or toolset (Abatron, BDI2000, BDI3000, CCS, Lauterbach, Segger, Macraigor, etc.), translating it into OpenOCD syntax is often quite straightforward. The most tricky part of creating a configuration script is oftentimes the reset init sequence where e.g. PLLs, DRAM and the like is set up. One trick that you can use when translating is to write small Tcl procedures to translate the syntax into OpenOCD syntax. This can avoid manual translation errors and make it easier to convert other scripts later on. Example of transforming quirky arguments to a simple search and replace job: @example # Lauterbach syntax(?) # # Data.Set c15:0x042f %long 0x40000015 # # OpenOCD syntax when using procedure below. # # setc15 0x01 0x00050078 proc setc15 @{regs value@} @{ global TARGETNAME echo [format "set p15 0x%04x, 0x%08x" $regs $value] arm mcr 15 [expr ($regs>>12)&0x7] \ [expr ($regs>>0)&0xf] [expr ($regs>>4)&0xf] \ [expr ($regs>>8)&0x7] $value @} @end example @node Daemon Configuration @chapter Daemon Configuration @cindex initialization The commands here are commonly found in the openocd.cfg file and are used to specify what TCP/IP ports are used, and how GDB should be supported. @anchor{Configuration Stage} @section Configuration Stage @cindex configuration stage @cindex config command When the OpenOCD server process starts up, it enters a @emph{configuration stage} which is the only time that certain commands, @emph{configuration commands}, may be issued. Normally, configuration commands are only available inside startup scripts. In this manual, the definition of a configuration command is presented as a @emph{Config Command}, not as a @emph{Command} which may be issued interactively. The runtime @command{help} command also highlights configuration commands, and those which may be issued at any time. Those configuration commands include declaration of TAPs, flash banks, the interface used for JTAG communication, and other basic setup. The server must leave the configuration stage before it may access or activate TAPs. After it leaves this stage, configuration commands may no longer be issued. @section Entering the Run Stage The first thing OpenOCD does after leaving the configuration stage is to verify that it can talk to the scan chain (list of TAPs) which has been configured. It will warn if it doesn't find TAPs it expects to find, or finds TAPs that aren't supposed to be there. You should see no errors at this point. If you see errors, resolve them by correcting the commands you used to configure the server. Common errors include using an initial JTAG speed that's too fast, and not providing the right IDCODE values for the TAPs on the scan chain. Once OpenOCD has entered the run stage, a number of commands become available. A number of these relate to the debug targets you may have declared. For example, the @command{mww} command will not be available until a target has been successfuly instantiated. If you want to use those commands, you may need to force entry to the run stage. @deffn {Config Command} init This command terminates the configuration stage and enters the run stage. This helps when you need to have the startup scripts manage tasks such as resetting the target, programming flash, etc. To reset the CPU upon startup, add "init" and "reset" at the end of the config script or at the end of the OpenOCD command line using the @option{-c} command line switch. If this command does not appear in any startup/configuration file OpenOCD executes the command for you after processing all configuration files and/or command line options. @b{NOTE:} This command normally occurs at or near the end of your openocd.cfg file to force OpenOCD to ``initialize'' and make the targets ready. For example: If your openocd.cfg file needs to read/write memory on your target, @command{init} must occur before the memory read/write commands. This includes @command{nand probe}. @end deffn @deffn {Overridable Procedure} jtag_init This is invoked at server startup to verify that it can talk to the scan chain (list of TAPs) which has been configured. The default implementation first tries @command{jtag arp_init}, which uses only a lightweight JTAG reset before examining the scan chain. If that fails, it tries again, using a harder reset from the overridable procedure @command{init_reset}. Implementations must have verified the JTAG scan chain before they return. This is done by calling @command{jtag arp_init} (or @command{jtag arp_init-reset}). @end deffn @anchor{TCP/IP Ports} @section TCP/IP Ports @cindex TCP port @cindex server @cindex port @cindex security The OpenOCD server accepts remote commands in several syntaxes. Each syntax uses a different TCP/IP port, which you may specify only during configuration (before those ports are opened). For reasons including security, you may wish to prevent remote access using one or more of these ports. In such cases, just specify the relevant port number as zero. If you disable all access through TCP/IP, you will need to use the command line @option{-pipe} option. @deffn {Command} gdb_port [number] @cindex GDB server Specify or query the first port used for incoming GDB connections. The GDB port for the first target will be gdb_port, the second target will listen on gdb_port + 1, and so on. When not specified during the configuration stage, the port @var{number} defaults to 3333. When specified as zero, GDB remote access ports are not activated. @end deffn @deffn {Command} tcl_port [number] Specify or query the port used for a simplified RPC connection that can be used by clients to issue TCL commands and get the output from the Tcl engine. Intended as a machine interface. When not specified during the configuration stage, the port @var{number} defaults to 6666. When specified as zero, this port is not activated. @end deffn @deffn {Command} telnet_port [number] Specify or query the port on which to listen for incoming telnet connections. This port is intended for interaction with one human through TCL commands. When not specified during the configuration stage, the port @var{number} defaults to 4444. When specified as zero, this port is not activated. @end deffn @anchor{GDB Configuration} @section GDB Configuration @cindex GDB @cindex GDB configuration You can reconfigure some GDB behaviors if needed. The ones listed here are static and global. @xref{Target Configuration}, about configuring individual targets. @xref{Target Events}, about configuring target-specific event handling. @anchor{gdb_breakpoint_override} @deffn {Command} gdb_breakpoint_override [@option{hard}|@option{soft}|@option{disable}] Force breakpoint type for gdb @command{break} commands. This option supports GDB GUIs which don't distinguish hard versus soft breakpoints, if the default OpenOCD and GDB behaviour is not sufficient. GDB normally uses hardware breakpoints if the memory map has been set up for flash regions. @end deffn @anchor{gdb_flash_program} @deffn {Config Command} gdb_flash_program (@option{enable}|@option{disable}) Set to @option{enable} to cause OpenOCD to program the flash memory when a vFlash packet is received. The default behaviour is @option{enable}. @end deffn @deffn {Config Command} gdb_memory_map (@option{enable}|@option{disable}) Set to @option{enable} to cause OpenOCD to send the memory configuration to GDB when requested. GDB will then know when to set hardware breakpoints, and program flash using the GDB load command. @command{gdb_flash_program enable} must also be enabled for flash programming to work. Default behaviour is @option{enable}. @xref{gdb_flash_program}. @end deffn @deffn {Config Command} gdb_report_data_abort (@option{enable}|@option{disable}) Specifies whether data aborts cause an error to be reported by GDB memory read packets. The default behaviour is @option{disable}; use @option{enable} see these errors reported. @end deffn @anchor{Event Polling} @section Event Polling Hardware debuggers are parts of asynchronous systems, where significant events can happen at any time. The OpenOCD server needs to detect some of these events, so it can report them to through TCL command line or to GDB. Examples of such events include: @itemize @item One of the targets can stop running ... maybe it triggers a code breakpoint or data watchpoint, or halts itself. @item Messages may be sent over ``debug message'' channels ... many targets support such messages sent over JTAG, for receipt by the person debugging or tools. @item Loss of power ... some adapters can detect these events. @item Resets not issued through JTAG ... such reset sources can include button presses or other system hardware, sometimes including the target itself (perhaps through a watchdog). @item Debug instrumentation sometimes supports event triggering such as ``trace buffer full'' (so it can quickly be emptied) or other signals (to correlate with code behavior). @end itemize None of those events are signaled through standard JTAG signals. However, most conventions for JTAG connectors include voltage level and system reset (SRST) signal detection. Some connectors also include instrumentation signals, which can imply events when those signals are inputs. In general, OpenOCD needs to periodically check for those events, either by looking at the status of signals on the JTAG connector or by sending synchronous ``tell me your status'' JTAG requests to the various active targets. There is a command to manage and monitor that polling, which is normally done in the background. @deffn Command poll [@option{on}|@option{off}] Poll the current target for its current state. (Also, @pxref{target curstate}.) If that target is in debug mode, architecture specific information about the current state is printed. An optional parameter allows background polling to be enabled and disabled. You could use this from the TCL command shell, or from GDB using @command{monitor poll} command. Leave background polling enabled while you're using GDB. @example > poll background polling: on target state: halted target halted in ARM state due to debug-request, \ current mode: Supervisor cpsr: 0x800000d3 pc: 0x11081bfc MMU: disabled, D-Cache: disabled, I-Cache: enabled > @end example @end deffn @node Debug Adapter Configuration @chapter Debug Adapter Configuration @cindex config file, interface @cindex interface config file Correctly installing OpenOCD includes making your operating system give OpenOCD access to debug adapters. Once that has been done, Tcl commands are used to select which one is used, and to configure how it is used. @quotation Note Because OpenOCD started out with a focus purely on JTAG, you may find places where it wrongly presumes JTAG is the only transport protocol in use. Be aware that recent versions of OpenOCD are removing that limitation. JTAG remains more functional than most other transports. Other transports do not support boundary scan operations, or may be specific to a given chip vendor. Some might be usable only for programming flash memory, instead of also for debugging. @end quotation Debug Adapters/Interfaces/Dongles are normally configured through commands in an interface configuration file which is sourced by your @file{openocd.cfg} file, or through a command line @option{-f interface/....cfg} option. @example source [find interface/olimex-jtag-tiny.cfg] @end example These commands tell OpenOCD what type of JTAG adapter you have, and how to talk to it. A few cases are so simple that you only need to say what driver to use: @example # jlink interface interface jlink @end example Most adapters need a bit more configuration than that. @section Interface Configuration The interface command tells OpenOCD what type of debug adapter you are using. Depending on the type of adapter, you may need to use one or more additional commands to further identify or configure the adapter. @deffn {Config Command} {interface} name Use the interface driver @var{name} to connect to the target. @end deffn @deffn Command {interface_list} List the debug adapter drivers that have been built into the running copy of OpenOCD. @end deffn @deffn Command {adapter_name} Returns the name of the debug adapter driver being used. @end deffn @section Interface Drivers Each of the interface drivers listed here must be explicitly enabled when OpenOCD is configured, in order to be made available at run time. @deffn {Interface Driver} {amt_jtagaccel} Amontec Chameleon in its JTAG Accelerator configuration, connected to a PC's EPP mode parallel port. This defines some driver-specific commands: @deffn {Config Command} {parport_port} number Specifies either the address of the I/O port (default: 0x378 for LPT1) or the number of the @file{/dev/parport} device. @end deffn @deffn {Config Command} rtck [@option{enable}|@option{disable}] Displays status of RTCK option. Optionally sets that option first. @end deffn @end deffn @deffn {Interface Driver} {arm-jtag-ew} Olimex ARM-JTAG-EW USB adapter This has one driver-specific command: @deffn Command {armjtagew_info} Logs some status @end deffn @end deffn @deffn {Interface Driver} {at91rm9200} Supports bitbanged JTAG from the local system, presuming that system is an Atmel AT91rm9200 and a specific set of GPIOs is used. @c command: at91rm9200_device NAME @c chooses among list of bit configs ... only one option @end deffn @deffn {Interface Driver} {dummy} A dummy software-only driver for debugging. @end deffn @deffn {Interface Driver} {ep93xx} Cirrus Logic EP93xx based single-board computer bit-banging (in development) @end deffn @deffn {Interface Driver} {ft2232} FTDI FT2232 (USB) based devices over one of the userspace libraries. These interfaces have several commands, used to configure the driver before initializing the JTAG scan chain: @deffn {Config Command} {ft2232_device_desc} description Provides the USB device description (the @emph{iProduct string}) of the FTDI FT2232 device. If not specified, the FTDI default value is used. This setting is only valid if compiled with FTD2XX support. @end deffn @deffn {Config Command} {ft2232_serial} serial-number Specifies the @var{serial-number} of the FTDI FT2232 device to use, in case the vendor provides unique IDs and more than one FT2232 device is connected to the host. If not specified, serial numbers are not considered. (Note that USB serial numbers can be arbitrary Unicode strings, and are not restricted to containing only decimal digits.) @end deffn @deffn {Config Command} {ft2232_layout} name Each vendor's FT2232 device can use different GPIO signals to control output-enables, reset signals, and LEDs. Currently valid layout @var{name} values include: @itemize @minus @item @b{axm0432_jtag} Axiom AXM-0432 @item @b{comstick} Hitex STR9 comstick @item @b{cortino} Hitex Cortino JTAG interface @item @b{evb_lm3s811} Luminary Micro EVB_LM3S811 as a JTAG interface, either for the local Cortex-M3 (SRST only) or in a passthrough mode (neither SRST nor TRST) This layout can not support the SWO trace mechanism, and should be used only for older boards (before rev C). @item @b{luminary_icdi} This layout should be used with most Luminary eval boards, including Rev C LM3S811 eval boards and the eponymous ICDI boards, to debug either the local Cortex-M3 or in passthrough mode to debug some other target. It can support the SWO trace mechanism. @item @b{flyswatter} Tin Can Tools Flyswatter @item @b{icebear} ICEbear JTAG adapter from Section 5 @item @b{jtagkey} Amontec JTAGkey and JTAGkey-Tiny (and compatibles) @item @b{jtagkey2} Amontec JTAGkey2 (and compatibles) @item @b{m5960} American Microsystems M5960 @item @b{olimex-jtag} Olimex ARM-USB-OCD and ARM-USB-Tiny @item @b{oocdlink} OOCDLink @c oocdlink ~= jtagkey_prototype_v1 @item @b{redbee-econotag} Integrated with a Redbee development board. @item @b{redbee-usb} Integrated with a Redbee USB-stick development board. @item @b{sheevaplug} Marvell Sheevaplug development kit @item @b{signalyzer} Xverve Signalyzer @item @b{stm32stick} Hitex STM32 Performance Stick @item @b{turtelizer2} egnite Software turtelizer2 @item @b{usbjtag} "USBJTAG-1" layout described in the OpenOCD diploma thesis @end itemize @end deffn @deffn {Config Command} {ft2232_vid_pid} [vid pid]+ The vendor ID and product ID of the FTDI FT2232 device. If not specified, the FTDI default values are used. Currently, up to eight [@var{vid}, @var{pid}] pairs may be given, e.g. @example ft2232_vid_pid 0x0403 0xcff8 0x15ba 0x0003 @end example @end deffn @deffn {Config Command} {ft2232_latency} ms On some systems using FT2232 based JTAG interfaces the FT_Read function call in ft2232_read() fails to return the expected number of bytes. This can be caused by USB communication delays and has proved hard to reproduce and debug. Setting the FT2232 latency timer to a larger value increases delays for short USB packets but it also reduces the risk of timeouts before receiving the expected number of bytes. The OpenOCD default value is 2 and for some systems a value of 10 has proved useful. @end deffn For example, the interface config file for a Turtelizer JTAG Adapter looks something like this: @example interface ft2232 ft2232_device_desc "Turtelizer JTAG/RS232 Adapter" ft2232_layout turtelizer2 ft2232_vid_pid 0x0403 0xbdc8 @end example @end deffn @deffn {Interface Driver} {usb_blaster} USB JTAG/USB-Blaster compatibles over one of the userspace libraries for FTDI chips. These interfaces have several commands, used to configure the driver before initializing the JTAG scan chain: @deffn {Config Command} {usb_blaster_device_desc} description Provides the USB device description (the @emph{iProduct string}) of the FTDI FT245 device. If not specified, the FTDI default value is used. This setting is only valid if compiled with FTD2XX support. @end deffn @deffn {Config Command} {usb_blaster_vid_pid} vid pid The vendor ID and product ID of the FTDI FT245 device. If not specified, default values are used. Currently, only one @var{vid}, @var{pid} pair may be given, e.g. for Altera USB-Blaster (default): @example ft2232_vid_pid 0x09FB 0x6001 @end example The following VID/PID is for Kolja Waschk's USB JTAG: @example ft2232_vid_pid 0x16C0 0x06AD @end example @end deffn @deffn {Command} {usb_blaster} (@option{pin6}|@option{pin8}) (@option{0}|@option{1}) Sets the state of the unused GPIO pins on USB-Blasters (pins 6 and 8 on the female JTAG header). These pins can be used as SRST and/or TRST provided the appropriate connections are made on the target board. For example, to use pin 6 as SRST (as with an AVR board): @example $_TARGETNAME configure -event reset-assert \ "usb_blaster pin6 1; wait 1; usb_blaster pin6 0" @end example @end deffn @end deffn @deffn {Interface Driver} {gw16012} Gateworks GW16012 JTAG programmer. This has one driver-specific command: @deffn {Config Command} {parport_port} [port_number] Display either the address of the I/O port (default: 0x378 for LPT1) or the number of the @file{/dev/parport} device. If a parameter is provided, first switch to use that port. This is a write-once setting. @end deffn @end deffn @deffn {Interface Driver} {jlink} Segger jlink USB adapter @c command: jlink_info @c dumps status @c command: jlink_hw_jtag (2|3) @c sets version 2 or 3 @end deffn @deffn {Interface Driver} {parport} Supports PC parallel port bit-banging cables: Wigglers, PLD download cable, and more. These interfaces have several commands, used to configure the driver before initializing the JTAG scan chain: @deffn {Config Command} {parport_cable} name Set the layout of the parallel port cable used to connect to the target. This is a write-once setting. Currently valid cable @var{name} values include: @itemize @minus @item @b{altium} Altium Universal JTAG cable. @item @b{arm-jtag} Same as original wiggler except SRST and TRST connections reversed and TRST is also inverted. @item @b{chameleon} The Amontec Chameleon's CPLD when operated in configuration mode. This is only used to program the Chameleon itself, not a connected target. @item @b{dlc5} The Xilinx Parallel cable III. @item @b{flashlink} The ST Parallel cable. @item @b{lattice} Lattice ispDOWNLOAD Cable @item @b{old_amt_wiggler} The Wiggler configuration that comes with some versions of Amontec's Chameleon Programmer. The new version available from the website uses the original Wiggler layout ('@var{wiggler}') @item @b{triton} The parallel port adapter found on the ``Karo Triton 1 Development Board''. This is also the layout used by the HollyGates design (see @uref{http://www.lartmaker.nl/projects/jtag/}). @item @b{wiggler} The original Wiggler layout, also supported by several clones, such as the Olimex ARM-JTAG @item @b{wiggler2} Same as original wiggler except an led is fitted on D5. @item @b{wiggler_ntrst_inverted} Same as original wiggler except TRST is inverted. @end itemize @end deffn @deffn {Config Command} {parport_port} [port_number] Display either the address of the I/O port (default: 0x378 for LPT1) or the number of the @file{/dev/parport} device. If a parameter is provided, first switch to use that port. This is a write-once setting. When using PPDEV to access the parallel port, use the number of the parallel port: @option{parport_port 0} (the default). If @option{parport_port 0x378} is specified you may encounter a problem. @end deffn @deffn Command {parport_toggling_time} [nanoseconds] Displays how many nanoseconds the hardware needs to toggle TCK; the parport driver uses this value to obey the @command{adapter_khz} configuration. When the optional @var{nanoseconds} parameter is given, that setting is changed before displaying the current value. The default setting should work reasonably well on commodity PC hardware. However, you may want to calibrate for your specific hardware. @quotation Tip To measure the toggling time with a logic analyzer or a digital storage oscilloscope, follow the procedure below: @example > parport_toggling_time 1000 > adapter_khz 500 @end example This sets the maximum JTAG clock speed of the hardware, but the actual speed probably deviates from the requested 500 kHz. Now, measure the time between the two closest spaced TCK transitions. You can use @command{runtest 1000} or something similar to generate a large set of samples. Update the setting to match your measurement: @example > parport_toggling_time <measured nanoseconds> @end example Now the clock speed will be a better match for @command{adapter_khz rate} commands given in OpenOCD scripts and event handlers. You can do something similar with many digital multimeters, but note that you'll probably need to run the clock continuously for several seconds before it decides what clock rate to show. Adjust the toggling time up or down until the measured clock rate is a good match for the adapter_khz rate you specified; be conservative. @end quotation @end deffn @deffn {Config Command} {parport_write_on_exit} (@option{on}|@option{off}) This will configure the parallel driver to write a known cable-specific value to the parallel interface on exiting OpenOCD. @end deffn For example, the interface configuration file for a classic ``Wiggler'' cable on LPT2 might look something like this: @example interface parport parport_port 0x278 parport_cable wiggler @end example @end deffn @deffn {Interface Driver} {presto} ASIX PRESTO USB JTAG programmer. @deffn {Config Command} {presto_serial} serial_string Configures the USB serial number of the Presto device to use. @end deffn @end deffn @deffn {Interface Driver} {rlink} Raisonance RLink USB adapter @end deffn @deffn {Interface Driver} {usbprog} usbprog is a freely programmable USB adapter. @end deffn @deffn {Interface Driver} {vsllink} vsllink is part of Versaloon which is a versatile USB programmer. @quotation Note This defines quite a few driver-specific commands, which are not currently documented here. @end quotation @end deffn @deffn {Interface Driver} {ZY1000} This is the Zylin ZY1000 JTAG debugger. @quotation Note This defines some driver-specific commands, which are not currently documented here. @end quotation @deffn Command power [@option{on}|@option{off}] Turn power switch to target on/off. No arguments: print status. @end deffn @end deffn @anchor{JTAG Speed} @section JTAG Speed JTAG clock setup is part of system setup. It @emph{does not belong with interface setup} since any interface only knows a few of the constraints for the JTAG clock speed. Sometimes the JTAG speed is changed during the target initialization process: (1) slow at reset, (2) program the CPU clocks, (3) run fast. Both the "slow" and "fast" clock rates are functions of the oscillators used, the chip, the board design, and sometimes power management software that may be active. The speed used during reset, and the scan chain verification which follows reset, can be adjusted using a @code{reset-start} target event handler. It can then be reconfigured to a faster speed by a @code{reset-init} target event handler after it reprograms those CPU clocks, or manually (if something else, such as a boot loader, sets up those clocks). @xref{Target Events}. When the initial low JTAG speed is a chip characteristic, perhaps because of a required oscillator speed, provide such a handler in the target config file. When that speed is a function of a board-specific characteristic such as which speed oscillator is used, it belongs in the board config file instead. In both cases it's safest to also set the initial JTAG clock rate to that same slow speed, so that OpenOCD never starts up using a clock speed that's faster than the scan chain can support. @example jtag_rclk 3000 $_TARGET.cpu configure -event reset-start @{ jtag_rclk 3000 @} @end example If your system supports adaptive clocking (RTCK), configuring JTAG to use that is probably the most robust approach. However, it introduces delays to synchronize clocks; so it may not be the fastest solution. @b{NOTE:} Script writers should consider using @command{jtag_rclk} instead of @command{adapter_khz}, but only for (ARM) cores and boards which support adaptive clocking. @deffn {Command} adapter_khz max_speed_kHz A non-zero speed is in KHZ. Hence: 3000 is 3mhz. JTAG interfaces usually support a limited number of speeds. The speed actually used won't be faster than the speed specified. Chip data sheets generally include a top JTAG clock rate. The actual rate is often a function of a CPU core clock, and is normally less than that peak rate. For example, most ARM cores accept at most one sixth of the CPU clock. Speed 0 (khz) selects RTCK method. @xref{FAQ RTCK}. If your system uses RTCK, you won't need to change the JTAG clocking after setup. Not all interfaces, boards, or targets support ``rtck''. If the interface device can not support it, an error is returned when you try to use RTCK. @end deffn @defun jtag_rclk fallback_speed_kHz @cindex adaptive clocking @cindex RTCK This Tcl proc (defined in @file{startup.tcl}) attempts to enable RTCK/RCLK. If that fails (maybe the interface, board, or target doesn't support it), falls back to the specified frequency. @example # Fall back to 3mhz if RTCK is not supported jtag_rclk 3000 @end example @end defun @node Reset Configuration @chapter Reset Configuration @cindex Reset Configuration Every system configuration may require a different reset configuration. This can also be quite confusing. Resets also interact with @var{reset-init} event handlers, which do things like setting up clocks and DRAM, and JTAG clock rates. (@xref{JTAG Speed}.) They can also interact with JTAG routers. Please see the various board files for examples. @quotation Note To maintainers and integrators: Reset configuration touches several things at once. Normally the board configuration file should define it and assume that the JTAG adapter supports everything that's wired up to the board's JTAG connector. However, the target configuration file could also make note of something the silicon vendor has done inside the chip, which will be true for most (or all) boards using that chip. And when the JTAG adapter doesn't support everything, the user configuration file will need to override parts of the reset configuration provided by other files. @end quotation @section Types of Reset There are many kinds of reset possible through JTAG, but they may not all work with a given board and adapter. That's part of why reset configuration can be error prone. @itemize @bullet @item @emph{System Reset} ... the @emph{SRST} hardware signal resets all chips connected to the JTAG adapter, such as processors, power management chips, and I/O controllers. Normally resets triggered with this signal behave exactly like pressing a RESET button. @item @emph{JTAG TAP Reset} ... the @emph{TRST} hardware signal resets just the TAP controllers connected to the JTAG adapter. Such resets should not be visible to the rest of the system; resetting a device's the TAP controller just puts that controller into a known state. @item @emph{Emulation Reset} ... many devices can be reset through JTAG commands. These resets are often distinguishable from system resets, either explicitly (a "reset reason" register says so) or implicitly (not all parts of the chip get reset). @item @emph{Other Resets} ... system-on-chip devices often support several other types of reset. You may need to arrange that a watchdog timer stops while debugging, preventing a watchdog reset. There may be individual module resets. @end itemize In the best case, OpenOCD can hold SRST, then reset the TAPs via TRST and send commands through JTAG to halt the CPU at the reset vector before the 1st instruction is executed. Then when it finally releases the SRST signal, the system is halted under debugger control before any code has executed. This is the behavior required to support the @command{reset halt} and @command{reset init} commands; after @command{reset init} a board-specific script might do things like setting up DRAM. (@xref{Reset Command}.) @anchor{SRST and TRST Issues} @section SRST and TRST Issues Because SRST and TRST are hardware signals, they can have a variety of system-specific constraints. Some of the most common issues are: @itemize @bullet @item @emph{Signal not available} ... Some boards don't wire SRST or TRST to the JTAG connector. Some JTAG adapters don't support such signals even if they are wired up. Use the @command{reset_config} @var{signals} options to say when either of those signals is not connected. When SRST is not available, your code might not be able to rely on controllers having been fully reset during code startup. Missing TRST is not a problem, since JTAG level resets can be triggered using with TMS signaling. @item @emph{Signals shorted} ... Sometimes a chip, board, or adapter will connect SRST to TRST, instead of keeping them separate. Use the @command{reset_config} @var{combination} options to say when those signals aren't properly independent. @item @emph{Timing} ... Reset circuitry like a resistor/capacitor delay circuit, reset supervisor, or on-chip features can extend the effect of a JTAG adapter's reset for some time after the adapter stops issuing the reset. For example, there may be chip or board requirements that all reset pulses last for at least a certain amount of time; and reset buttons commonly have hardware debouncing. Use the @command{adapter_nsrst_delay} and @command{jtag_ntrst_delay} commands to say when extra delays are needed. @item @emph{Drive type} ... Reset lines often have a pullup resistor, letting the JTAG interface treat them as open-drain signals. But that's not a requirement, so the adapter may need to use push/pull output drivers. Also, with weak pullups it may be advisable to drive signals to both levels (push/pull) to minimize rise times. Use the @command{reset_config} @var{trst_type} and @var{srst_type} parameters to say how to drive reset signals. @item @emph{Special initialization} ... Targets sometimes need special JTAG initialization sequences to handle chip-specific issues (not limited to errata). For example, certain JTAG commands might need to be issued while the system as a whole is in a reset state (SRST active) but the JTAG scan chain is usable (TRST inactive). Many systems treat combined assertion of SRST and TRST as a trigger for a harder reset than SRST alone. Such custom reset handling is discussed later in this chapter. @end itemize There can also be other issues. Some devices don't fully conform to the JTAG specifications. Trivial system-specific differences are common, such as SRST and TRST using slightly different names. There are also vendors who distribute key JTAG documentation for their chips only to developers who have signed a Non-Disclosure Agreement (NDA). Sometimes there are chip-specific extensions like a requirement to use the normally-optional TRST signal (precluding use of JTAG adapters which don't pass TRST through), or needing extra steps to complete a TAP reset. In short, SRST and especially TRST handling may be very finicky, needing to cope with both architecture and board specific constraints. @section Commands for Handling Resets @deffn {Command} adapter_nsrst_assert_width milliseconds Minimum amount of time (in milliseconds) OpenOCD should wait after asserting nSRST (active-low system reset) before allowing it to be deasserted. @end deffn @deffn {Command} adapter_nsrst_delay milliseconds How long (in milliseconds) OpenOCD should wait after deasserting nSRST (active-low system reset) before starting new JTAG operations. When a board has a reset button connected to SRST line it will probably have hardware debouncing, implying you should use this. @end deffn @deffn {Command} jtag_ntrst_assert_width milliseconds Minimum amount of time (in milliseconds) OpenOCD should wait after asserting nTRST (active-low JTAG TAP reset) before allowing it to be deasserted. @end deffn @deffn {Command} jtag_ntrst_delay milliseconds How long (in milliseconds) OpenOCD should wait after deasserting nTRST (active-low JTAG TAP reset) before starting new JTAG operations. @end deffn @deffn {Command} reset_config mode_flag ... This command displays or modifies the reset configuration of your combination of JTAG board and target in target configuration scripts. Information earlier in this section describes the kind of problems the command is intended to address (@pxref{SRST and TRST Issues}). As a rule this command belongs only in board config files, describing issues like @emph{board doesn't connect TRST}; or in user config files, addressing limitations derived from a particular combination of interface and board. (An unlikely example would be using a TRST-only adapter with a board that only wires up SRST.) The @var{mode_flag} options can be specified in any order, but only one of each type -- @var{signals}, @var{combination}, @var{gates}, @var{trst_type}, and @var{srst_type} -- may be specified at a time. If you don't provide a new value for a given type, its previous value (perhaps the default) is unchanged. For example, this means that you don't need to say anything at all about TRST just to declare that if the JTAG adapter should want to drive SRST, it must explicitly be driven high (@option{srst_push_pull}). @itemize @item @var{signals} can specify which of the reset signals are connected. For example, If the JTAG interface provides SRST, but the board doesn't connect that signal properly, then OpenOCD can't use it. Possible values are @option{none} (the default), @option{trst_only}, @option{srst_only} and @option{trst_and_srst}. @quotation Tip If your board provides SRST and/or TRST through the JTAG connector, you must declare that so those signals can be used. @end quotation @item The @var{combination} is an optional value specifying broken reset signal implementations. The default behaviour if no option given is @option{separate}, indicating everything behaves normally. @option{srst_pulls_trst} states that the test logic is reset together with the reset of the system (e.g. NXP LPC2000, "broken" board layout), @option{trst_pulls_srst} says that the system is reset together with the test logic (only hypothetical, I haven't seen hardware with such a bug, and can be worked around). @option{combined} implies both @option{srst_pulls_trst} and @option{trst_pulls_srst}. @item The @var{gates} tokens control flags that describe some cases where JTAG may be unvailable during reset. @option{srst_gates_jtag} (default) indicates that asserting SRST gates the JTAG clock. This means that no communication can happen on JTAG while SRST is asserted. Its converse is @option{srst_nogate}, indicating that JTAG commands can safely be issued while SRST is active. @end itemize The optional @var{trst_type} and @var{srst_type} parameters allow the driver mode of each reset line to be specified. These values only affect JTAG interfaces with support for different driver modes, like the Amontec JTAGkey and JTAG Accelerator. Also, they are necessarily ignored if the relevant signal (TRST or SRST) is not connected. @itemize @item Possible @var{trst_type} driver modes for the test reset signal (TRST) are the default @option{trst_push_pull}, and @option{trst_open_drain}. Most boards connect this signal to a pulldown, so the JTAG TAPs never leave reset unless they are hooked up to a JTAG adapter. @item Possible @var{srst_type} driver modes for the system reset signal (SRST) are the default @option{srst_open_drain}, and @option{srst_push_pull}. Most boards connect this signal to a pullup, and allow the signal to be pulled low by various events including system powerup and pressing a reset button. @end itemize @end deffn @section Custom Reset Handling @cindex events OpenOCD has several ways to help support the various reset mechanisms provided by chip and board vendors. The commands shown in the previous section give standard parameters. There are also @emph{event handlers} associated with TAPs or Targets. Those handlers are Tcl procedures you can provide, which are invoked at particular points in the reset sequence. @emph{When SRST is not an option} you must set up a @code{reset-assert} event handler for your target. For example, some JTAG adapters don't include the SRST signal; and some boards have multiple targets, and you won't always want to reset everything at once. After configuring those mechanisms, you might still find your board doesn't start up or reset correctly. For example, maybe it needs a slightly different sequence of SRST and/or TRST manipulations, because of quirks that the @command{reset_config} mechanism doesn't address; or asserting both might trigger a stronger reset, which needs special attention. Experiment with lower level operations, such as @command{jtag_reset} and the @command{jtag arp_*} operations shown here, to find a sequence of operations that works. @xref{JTAG Commands}. When you find a working sequence, it can be used to override @command{jtag_init}, which fires during OpenOCD startup (@pxref{Configuration Stage}); or @command{init_reset}, which fires during reset processing. You might also want to provide some project-specific reset schemes. For example, on a multi-target board the standard @command{reset} command would reset all targets, but you may need the ability to reset only one target at time and thus want to avoid using the board-wide SRST signal. @deffn {Overridable Procedure} init_reset mode This is invoked near the beginning of the @command{reset} command, usually to provide as much of a cold (power-up) reset as practical. By default it is also invoked from @command{jtag_init} if the scan chain does not respond to pure JTAG operations. The @var{mode} parameter is the parameter given to the low level reset command (@option{halt}, @option{init}, or @option{run}), @option{setup}, or potentially some other value. The default implementation just invokes @command{jtag arp_init-reset}. Replacements will normally build on low level JTAG operations such as @command{jtag_reset}. Operations here must not address individual TAPs (or their associated targets) until the JTAG scan chain has first been verified to work. Implementations must have verified the JTAG scan chain before they return. This is done by calling @command{jtag arp_init} (or @command{jtag arp_init-reset}). @end deffn @deffn Command {jtag arp_init} This validates the scan chain using just the four standard JTAG signals (TMS, TCK, TDI, TDO). It starts by issuing a JTAG-only reset. Then it performs checks to verify that the scan chain configuration matches the TAPs it can observe. Those checks include checking IDCODE values for each active TAP, and verifying the length of their instruction registers using TAP @code{-ircapture} and @code{-irmask} values. If these tests all pass, TAP @code{setup} events are issued to all TAPs with handlers for that event. @end deffn @deffn Command {jtag arp_init-reset} This uses TRST and SRST to try resetting everything on the JTAG scan chain (and anything else connected to SRST). It then invokes the logic of @command{jtag arp_init}. @end deffn @node TAP Declaration @chapter TAP Declaration @cindex TAP declaration @cindex TAP configuration @emph{Test Access Ports} (TAPs) are the core of JTAG. TAPs serve many roles, including: @itemize @bullet @item @b{Debug Target} A CPU TAP can be used as a GDB debug target @item @b{Flash Programing} Some chips program the flash directly via JTAG. Others do it indirectly, making a CPU do it. @item @b{Program Download} Using the same CPU support GDB uses, you can initialize a DRAM controller, download code to DRAM, and then start running that code. @item @b{Boundary Scan} Most chips support boundary scan, which helps test for board assembly problems like solder bridges and missing connections @end itemize OpenOCD must know about the active TAPs on your board(s). Setting up the TAPs is the core task of your configuration files. Once those TAPs are set up, you can pass their names to code which sets up CPUs and exports them as GDB targets, probes flash memory, performs low-level JTAG operations, and more. @section Scan Chains @cindex scan chain TAPs are part of a hardware @dfn{scan chain}, which is daisy chain of TAPs. They also need to be added to OpenOCD's software mirror of that hardware list, giving each member a name and associating other data with it. Simple scan chains, with a single TAP, are common in systems with a single microcontroller or microprocessor. More complex chips may have several TAPs internally. Very complex scan chains might have a dozen or more TAPs: several in one chip, more in the next, and connecting to other boards with their own chips and TAPs. You can display the list with the @command{scan_chain} command. (Don't confuse this with the list displayed by the @command{targets} command, presented in the next chapter. That only displays TAPs for CPUs which are configured as debugging targets.) Here's what the scan chain might look like for a chip more than one TAP: @verbatim TapName Enabled IdCode Expected IrLen IrCap IrMask -- ------------------ ------- ---------- ---------- ----- ----- ------ 0 omap5912.dsp Y 0x03df1d81 0x03df1d81 38 0x01 0x03 1 omap5912.arm Y 0x0692602f 0x0692602f 4 0x01 0x0f 2 omap5912.unknown Y 0x00000000 0x00000000 8 0x01 0x03 @end verbatim OpenOCD can detect some of that information, but not all of it. @xref{Autoprobing}. Unfortunately those TAPs can't always be autoconfigured, because not all devices provide good support for that. JTAG doesn't require supporting IDCODE instructions, and chips with JTAG routers may not link TAPs into the chain until they are told to do so. The configuration mechanism currently supported by OpenOCD requires explicit configuration of all TAP devices using @command{jtag newtap} commands, as detailed later in this chapter. A command like this would declare one tap and name it @code{chip1.cpu}: @example jtag newtap chip1 cpu -irlen 4 -expected-id 0x3ba00477 @end example Each target configuration file lists the TAPs provided by a given chip. Board configuration files combine all the targets on a board, and so forth. Note that @emph{the order in which TAPs are declared is very important.} It must match the order in the JTAG scan chain, both inside a single chip and between them. @xref{FAQ TAP Order}. For example, the ST Microsystems STR912 chip has three separate TAPs@footnote{See the ST document titled: @emph{STR91xFAxxx, Section 3.15 Jtag Interface, Page: 28/102, Figure 3: JTAG chaining inside the STR91xFA}. @url{http://eu.st.com/stonline/products/literature/ds/13495.pdf}}. To configure those taps, @file{target/str912.cfg} includes commands something like this: @example jtag newtap str912 flash ... params ... jtag newtap str912 cpu ... params ... jtag newtap str912 bs ... params ... @end example Actual config files use a variable instead of literals like @option{str912}, to support more than one chip of each type. @xref{Config File Guidelines}. @deffn Command {jtag names} Returns the names of all current TAPs in the scan chain. Use @command{jtag cget} or @command{jtag tapisenabled} to examine attributes and state of each TAP. @example foreach t [jtag names] @{ puts [format "TAP: %s\n" $t] @} @end example @end deffn @deffn Command {scan_chain} Displays the TAPs in the scan chain configuration, and their status. The set of TAPs listed by this command is fixed by exiting the OpenOCD configuration stage, but systems with a JTAG router can enable or disable TAPs dynamically. @end deffn @c FIXME! "jtag cget" should be able to return all TAP @c attributes, like "$target_name cget" does for targets. @c Probably want "jtag eventlist", and a "tap-reset" event @c (on entry to RESET state). @section TAP Names @cindex dotted name When TAP objects are declared with @command{jtag newtap}, a @dfn{dotted.name} is created for the TAP, combining the name of a module (usually a chip) and a label for the TAP. For example: @code{xilinx.tap}, @code{str912.flash}, @code{omap3530.jrc}, @code{dm6446.dsp}, or @code{stm32.cpu}. Many other commands use that dotted.name to manipulate or refer to the TAP. For example, CPU configuration uses the name, as does declaration of NAND or NOR flash banks. The components of a dotted name should follow ``C'' symbol name rules: start with an alphabetic character, then numbers and underscores are OK; while others (including dots!) are not. @quotation Tip In older code, JTAG TAPs were numbered from 0..N. This feature is still present. However its use is highly discouraged, and should not be relied on; it will be removed by mid-2010. Update all of your scripts to use TAP names rather than numbers, by paying attention to the runtime warnings they trigger. Using TAP numbers in target configuration scripts prevents reusing those scripts on boards with multiple targets. @end quotation @section TAP Declaration Commands @c shouldn't this be(come) a {Config Command}? @anchor{jtag newtap} @deffn Command {jtag newtap} chipname tapname configparams... Declares a new TAP with the dotted name @var{chipname}.@var{tapname}, and configured according to the various @var{configparams}. The @var{chipname} is a symbolic name for the chip. Conventionally target config files use @code{$_CHIPNAME}, defaulting to the model name given by the chip vendor but overridable. @cindex TAP naming convention The @var{tapname} reflects the role of that TAP, and should follow this convention: @itemize @bullet @item @code{bs} -- For boundary scan if this is a seperate TAP; @item @code{cpu} -- The main CPU of the chip, alternatively @code{arm} and @code{dsp} on chips with both ARM and DSP CPUs, @code{arm1} and @code{arm2} on chips two ARMs, and so forth; @item @code{etb} -- For an embedded trace buffer (example: an ARM ETB11); @item @code{flash} -- If the chip has a flash TAP, like the str912; @item @code{jrc} -- For JTAG route controller (example: the ICEpick modules on many Texas Instruments chips, like the OMAP3530 on Beagleboards); @item @code{tap} -- Should be used only FPGA or CPLD like devices with a single TAP; @item @code{unknownN} -- If you have no idea what the TAP is for (N is a number); @item @emph{when in doubt} -- Use the chip maker's name in their data sheet. For example, the Freescale IMX31 has a SDMA (Smart DMA) with a JTAG TAP; that TAP should be named @code{sdma}. @end itemize Every TAP requires at least the following @var{configparams}: @itemize @bullet @item @code{-irlen} @var{NUMBER} @*The length in bits of the instruction register, such as 4 or 5 bits. @end itemize A TAP may also provide optional @var{configparams}: @itemize @bullet @item @code{-disable} (or @code{-enable}) @*Use the @code{-disable} parameter to flag a TAP which is not linked in to the scan chain after a reset using either TRST or the JTAG state machine's @sc{reset} state. You may use @code{-enable} to highlight the default state (the TAP is linked in). @xref{Enabling and Disabling TAPs}. @item @code{-expected-id} @var{number} @*A non-zero @var{number} represents a 32-bit IDCODE which you expect to find when the scan chain is examined. These codes are not required by all JTAG devices. @emph{Repeat the option} as many times as required if more than one ID code could appear (for example, multiple versions). Specify @var{number} as zero to suppress warnings about IDCODE values that were found but not included in the list. Provide this value if at all possible, since it lets OpenOCD tell when the scan chain it sees isn't right. These values are provided in vendors' chip documentation, usually a technical reference manual. Sometimes you may need to probe the JTAG hardware to find these values. @xref{Autoprobing}. @item @code{-ignore-version} @*Specify this to ignore the JTAG version field in the @code{-expected-id} option. When vendors put out multiple versions of a chip, or use the same JTAG-level ID for several largely-compatible chips, it may be more practical to ignore the version field than to update config files to handle all of the various chip IDs. @item @code{-ircapture} @var{NUMBER} @*The bit pattern loaded by the TAP into the JTAG shift register on entry to the @sc{ircapture} state, such as 0x01. JTAG requires the two LSBs of this value to be 01. By default, @code{-ircapture} and @code{-irmask} are set up to verify that two-bit value. You may provide additional bits, if you know them, or indicate that a TAP doesn't conform to the JTAG specification. @item @code{-irmask} @var{NUMBER} @*A mask used with @code{-ircapture} to verify that instruction scans work correctly. Such scans are not used by OpenOCD except to verify that there seems to be no problems with JTAG scan chain operations. @end itemize @end deffn @section Other TAP commands @deffn Command {jtag cget} dotted.name @option{-event} name @deffnx Command {jtag configure} dotted.name @option{-event} name string At this writing this TAP attribute mechanism is used only for event handling. (It is not a direct analogue of the @code{cget}/@code{configure} mechanism for debugger targets.) See the next section for information about the available events. The @code{configure} subcommand assigns an event handler, a TCL string which is evaluated when the event is triggered. The @code{cget} subcommand returns that handler. @end deffn @anchor{TAP Events} @section TAP Events @cindex events @cindex TAP events OpenOCD includes two event mechanisms. The one presented here applies to all JTAG TAPs. The other applies to debugger targets, which are associated with certain TAPs. The TAP events currently defined are: @itemize @bullet @item @b{post-reset} @* The TAP has just completed a JTAG reset. The tap may still be in the JTAG @sc{reset} state. Handlers for these events might perform initialization sequences such as issuing TCK cycles, TMS sequences to ensure exit from the ARM SWD mode, and more. Because the scan chain has not yet been verified, handlers for these events @emph{should not issue commands which scan the JTAG IR or DR registers} of any particular target. @b{NOTE:} As this is written (September 2009), nothing prevents such access. @item @b{setup} @* The scan chain has been reset and verified. This handler may enable TAPs as needed. @item @b{tap-disable} @* The TAP needs to be disabled. This handler should implement @command{jtag tapdisable} by issuing the relevant JTAG commands. @item @b{tap-enable} @* The TAP needs to be enabled. This handler should implement @command{jtag tapenable} by issuing the relevant JTAG commands. @end itemize If you need some action after each JTAG reset, which isn't actually specific to any TAP (since you can't yet trust the scan chain's contents to be accurate), you might: @example jtag configure CHIP.jrc -event post-reset @{ echo "JTAG Reset done" ... non-scan jtag operations to be done after reset @} @end example @anchor{Enabling and Disabling TAPs} @section Enabling and Disabling TAPs @cindex JTAG Route Controller @cindex jrc In some systems, a @dfn{JTAG Route Controller} (JRC) is used to enable and/or disable specific JTAG TAPs. Many ARM based chips from Texas Instruments include an ``ICEpick'' module, which is a JRC. Such chips include DaVinci and OMAP3 processors. A given TAP may not be visible until the JRC has been told to link it into the scan chain; and if the JRC has been told to unlink that TAP, it will no longer be visible. Such routers address problems that JTAG ``bypass mode'' ignores, such as: @itemize @item The scan chain can only go as fast as its slowest TAP. @item Having many TAPs slows instruction scans, since all TAPs receive new instructions. @item TAPs in the scan chain must be powered up, which wastes power and prevents debugging some power management mechanisms. @end itemize The IEEE 1149.1 JTAG standard has no concept of a ``disabled'' tap, as implied by the existence of JTAG routers. However, the upcoming IEEE 1149.7 framework (layered on top of JTAG) does include a kind of JTAG router functionality. @c (a) currently the event handlers don't seem to be able to @c fail in a way that could lead to no-change-of-state. In OpenOCD, tap enabling/disabling is invoked by the Tcl commands shown below, and is implemented using TAP event handlers. So for example, when defining a TAP for a CPU connected to a JTAG router, your @file{target.cfg} file should define TAP event handlers using code that looks something like this: @example jtag configure CHIP.cpu -event tap-enable @{ ... jtag operations using CHIP.jrc @} jtag configure CHIP.cpu -event tap-disable @{ ... jtag operations using CHIP.jrc @} @end example Then you might want that CPU's TAP enabled almost all the time: @example jtag configure $CHIP.jrc -event setup "jtag tapenable $CHIP.cpu" @end example Note how that particular setup event handler declaration uses quotes to evaluate @code{$CHIP} when the event is configured. Using brackets @{ @} would cause it to be evaluated later, at runtime, when it might have a different value. @deffn Command {jtag tapdisable} dotted.name If necessary, disables the tap by sending it a @option{tap-disable} event. Returns the string "1" if the tap specified by @var{dotted.name} is enabled, and "0" if it is disabled. @end deffn @deffn Command {jtag tapenable} dotted.name If necessary, enables the tap by sending it a @option{tap-enable} event. Returns the string "1" if the tap specified by @var{dotted.name} is enabled, and "0" if it is disabled. @end deffn @deffn Command {jtag tapisenabled} dotted.name Returns the string "1" if the tap specified by @var{dotted.name} is enabled, and "0" if it is disabled. @quotation Note Humans will find the @command{scan_chain} command more helpful for querying the state of the JTAG taps. @end quotation @end deffn @anchor{Autoprobing} @section Autoprobing @cindex autoprobe @cindex JTAG autoprobe TAP configuration is the first thing that needs to be done after interface and reset configuration. Sometimes it's hard finding out what TAPs exist, or how they are identified. Vendor documentation is not always easy to find and use. To help you get past such problems, OpenOCD has a limited @emph{autoprobing} ability to look at the scan chain, doing a @dfn{blind interrogation} and then reporting the TAPs it finds. To use this mechanism, start the OpenOCD server with only data that configures your JTAG interface, and arranges to come up with a slow clock (many devices don't support fast JTAG clocks right when they come out of reset). For example, your @file{openocd.cfg} file might have: @example source [find interface/olimex-arm-usb-tiny-h.cfg] reset_config trst_and_srst jtag_rclk 8 @end example When you start the server without any TAPs configured, it will attempt to autoconfigure the TAPs. There are two parts to this: @enumerate @item @emph{TAP discovery} ... After a JTAG reset (sometimes a system reset may be needed too), each TAP's data registers will hold the contents of either the IDCODE or BYPASS register. If JTAG communication is working, OpenOCD will see each TAP, and report what @option{-expected-id} to use with it. @item @emph{IR Length discovery} ... Unfortunately JTAG does not provide a reliable way to find out the value of the @option{-irlen} parameter to use with a TAP that is discovered. If OpenOCD can discover the length of a TAP's instruction register, it will report it. Otherwise you may need to consult vendor documentation, such as chip data sheets or BSDL files. @end enumerate In many cases your board will have a simple scan chain with just a single device. Here's what OpenOCD reported with one board that's a bit more complex: @example clock speed 8 kHz There are no enabled taps. AUTO PROBING MIGHT NOT WORK!! AUTO auto0.tap - use "jtag newtap auto0 tap -expected-id 0x2b900f0f ..." AUTO auto1.tap - use "jtag newtap auto1 tap -expected-id 0x07926001 ..." AUTO auto2.tap - use "jtag newtap auto2 tap -expected-id 0x0b73b02f ..." AUTO auto0.tap - use "... -irlen 4" AUTO auto1.tap - use "... -irlen 4" AUTO auto2.tap - use "... -irlen 6" no gdb ports allocated as no target has been specified @end example Given that information, you should be able to either find some existing config files to use, or create your own. If you create your own, you would configure from the bottom up: first a @file{target.cfg} file with these TAPs, any targets associated with them, and any on-chip resources; then a @file{board.cfg} with off-chip resources, clocking, and so forth. @node CPU Configuration @chapter CPU Configuration @cindex GDB target This chapter discusses how to set up GDB debug targets for CPUs. You can also access these targets without GDB (@pxref{Architecture and Core Commands}, and @ref{Target State handling}) and through various kinds of NAND and NOR flash commands. If you have multiple CPUs you can have multiple such targets. We'll start by looking at how to examine the targets you have, then look at how to add one more target and how to configure it. @section Target List @cindex target, current @cindex target, list All targets that have been set up are part of a list, where each member has a name. That name should normally be the same as the TAP name. You can display the list with the @command{targets} (plural!) command. This display often has only one CPU; here's what it might look like with more than one: @verbatim TargetName Type Endian TapName State -- ------------------ ---------- ------ ------------------ ------------ 0* at91rm9200.cpu arm920t little at91rm9200.cpu running 1 MyTarget cortex_m3 little mychip.foo tap-disabled @end verbatim One member of that list is the @dfn{current target}, which is implicitly referenced by many commands. It's the one marked with a @code{*} near the target name. In particular, memory addresses often refer to the address space seen by that current target. Commands like @command{mdw} (memory display words) and @command{flash erase_address} (erase NOR flash blocks) are examples; and there are many more. Several commands let you examine the list of targets: @deffn Command {target count} @emph{Note: target numbers are deprecated; don't use them. They will be removed shortly after August 2010, including this command. Iterate target using @command{target names}, not by counting.} Returns the number of targets, @math{N}. The highest numbered target is @math{N - 1}. @example set c [target count] for @{ set x 0 @} @{ $x < $c @} @{ incr x @} @{ # Assuming you have created this function print_target_details $x @} @end example @end deffn @deffn Command {target current} Returns the name of the current target. @end deffn @deffn Command {target names} Lists the names of all current targets in the list. @example foreach t [target names] @{ puts [format "Target: %s\n" $t] @} @end example @end deffn @deffn Command {target number} number @emph{Note: target numbers are deprecated; don't use them. They will be removed shortly after August 2010, including this command.} The list of targets is numbered starting at zero. This command returns the name of the target at index @var{number}. @example set thename [target number $x] puts [format "Target %d is: %s\n" $x $thename] @end example @end deffn @c yep, "target list" would have been better. @c plus maybe "target setdefault". @deffn Command targets [name] @emph{Note: the name of this command is plural. Other target command names are singular.} With no parameter, this command displays a table of all known targets in a user friendly form. With a parameter, this command sets the current target to the given target with the given @var{name}; this is only relevant on boards which have more than one target. @end deffn @section Target CPU Types and Variants @cindex target type @cindex CPU type @cindex CPU variant Each target has a @dfn{CPU type}, as shown in the output of the @command{targets} command. You need to specify that type when calling @command{target create}. The CPU type indicates more than just the instruction set. It also indicates how that instruction set is implemented, what kind of debug support it integrates, whether it has an MMU (and if so, what kind), what core-specific commands may be available (@pxref{Architecture and Core Commands}), and more. For some CPU types, OpenOCD also defines @dfn{variants} which indicate differences that affect their handling. For example, a particular implementation bug might need to be worked around in some chip versions. It's easy to see what target types are supported, since there's a command to list them. However, there is currently no way to list what target variants are supported (other than by reading the OpenOCD source code). @anchor{target types} @deffn Command {target types} Lists all supported target types. At this writing, the supported CPU types and variants are: @itemize @bullet @item @code{arm11} -- this is a generation of ARMv6 cores @item @code{arm720t} -- this is an ARMv4 core with an MMU @item @code{arm7tdmi} -- this is an ARMv4 core @item @code{arm920t} -- this is an ARMv5 core with an MMU @item @code{arm926ejs} -- this is an ARMv5 core with an MMU @item @code{arm966e} -- this is an ARMv5 core @item @code{arm9tdmi} -- this is an ARMv4 core @item @code{avr} -- implements Atmel's 8-bit AVR instruction set. (Support for this is preliminary and incomplete.) @item @code{cortex_a8} -- this is an ARMv7 core with an MMU @item @code{cortex_m3} -- this is an ARMv7 core, supporting only the compact Thumb2 instruction set. It supports one variant: @itemize @minus @item @code{lm3s} ... Use this when debugging older Stellaris LM3S targets. This will cause OpenOCD to use a software reset rather than asserting SRST, to avoid a issue with clearing the debug registers. This is fixed in Fury Rev B, DustDevil Rev B, Tempest; these revisions will be detected and the normal reset behaviour used. @end itemize @item @code{dragonite} -- resembles arm966e @item @code{dsp563xx} -- implements Freescale's 24-bit DSP. (Support for this is still incomplete.) @item @code{fa526} -- resembles arm920 (w/o Thumb) @item @code{feroceon} -- resembles arm926 @item @code{mips_m4k} -- a MIPS core. This supports one variant: @item @code{xscale} -- this is actually an architecture, not a CPU type. It is based on the ARMv5 architecture. There are several variants defined: @itemize @minus @item @code{ixp42x}, @code{ixp45x}, @code{ixp46x}, @code{pxa27x} ... instruction register length is 7 bits @item @code{pxa250}, @code{pxa255}, @code{pxa26x} ... instruction register length is 5 bits @item @code{pxa3xx} ... instruction register length is 11 bits @end itemize @end itemize @end deffn To avoid being confused by the variety of ARM based cores, remember this key point: @emph{ARM is a technology licencing company}. (See: @url{http://www.arm.com}.) The CPU name used by OpenOCD will reflect the CPU design that was licenced, not a vendor brand which incorporates that design. Name prefixes like arm7, arm9, arm11, and cortex reflect design generations; while names like ARMv4, ARMv5, ARMv6, and ARMv7 reflect an architecture version implemented by a CPU design. @anchor{Target Configuration} @section Target Configuration Before creating a ``target'', you must have added its TAP to the scan chain. When you've added that TAP, you will have a @code{dotted.name} which is used to set up the CPU support. The chip-specific configuration file will normally configure its CPU(s) right after it adds all of the chip's TAPs to the scan chain. Although you can set up a target in one step, it's often clearer if you use shorter commands and do it in two steps: create it, then configure optional parts. All operations on the target after it's created will use a new command, created as part of target creation. The two main things to configure after target creation are a work area, which usually has target-specific defaults even if the board setup code overrides them later; and event handlers (@pxref{Target Events}), which tend to be much more board-specific. The key steps you use might look something like this @example target create MyTarget cortex_m3 -chain-position mychip.cpu $MyTarget configure -work-area-phys 0x08000 -work-area-size 8096 $MyTarget configure -event reset-deassert-pre @{ jtag_rclk 5 @} $MyTarget configure -event reset-init @{ myboard_reinit @} @end example You should specify a working area if you can; typically it uses some on-chip SRAM. Such a working area can speed up many things, including bulk writes to target memory; flash operations like checking to see if memory needs to be erased; GDB memory checksumming; and more. @quotation Warning On more complex chips, the work area can become inaccessible when application code (such as an operating system) enables or disables the MMU. For example, the particular MMU context used to acess the virtual address will probably matter ... and that context might not have easy access to other addresses needed. At this writing, OpenOCD doesn't have much MMU intelligence. @end quotation It's often very useful to define a @code{reset-init} event handler. For systems that are normally used with a boot loader, common tasks include updating clocks and initializing memory controllers. That may be needed to let you write the boot loader into flash, in order to ``de-brick'' your board; or to load programs into external DDR memory without having run the boot loader. @deffn Command {target create} target_name type configparams... This command creates a GDB debug target that refers to a specific JTAG tap. It enters that target into a list, and creates a new command (@command{@var{target_name}}) which is used for various purposes including additional configuration. @itemize @bullet @item @var{target_name} ... is the name of the debug target. By convention this should be the same as the @emph{dotted.name} of the TAP associated with this target, which must be specified here using the @code{-chain-position @var{dotted.name}} configparam. This name is also used to create the target object command, referred to here as @command{$target_name}, and in other places the target needs to be identified. @item @var{type} ... specifies the target type. @xref{target types}. @item @var{configparams} ... all parameters accepted by @command{$target_name configure} are permitted. If the target is big-endian, set it here with @code{-endian big}. If the variant matters, set it here with @code{-variant}. You @emph{must} set the @code{-chain-position @var{dotted.name}} here. @end itemize @end deffn @deffn Command {$target_name configure} configparams... The options accepted by this command may also be specified as parameters to @command{target create}. Their values can later be queried one at a time by using the @command{$target_name cget} command. @emph{Warning:} changing some of these after setup is dangerous. For example, moving a target from one TAP to another; and changing its endianness or variant. @itemize @bullet @item @code{-chain-position} @var{dotted.name} -- names the TAP used to access this target. @item @code{-endian} (@option{big}|@option{little}) -- specifies whether the CPU uses big or little endian conventions @item @code{-event} @var{event_name} @var{event_body} -- @xref{Target Events}. Note that this updates a list of named event handlers. Calling this twice with two different event names assigns two different handlers, but calling it twice with the same event name assigns only one handler. @item @code{-variant} @var{name} -- specifies a variant of the target, which OpenOCD needs to know about. @item @code{-work-area-backup} (@option{0}|@option{1}) -- says whether the work area gets backed up; by default, @emph{it is not backed up.} When possible, use a working_area that doesn't need to be backed up, since performing a backup slows down operations. For example, the beginning of an SRAM block is likely to be used by most build systems, but the end is often unused. @item @code{-work-area-size} @var{size} -- specify work are size, in bytes. The same size applies regardless of whether its physical or virtual address is being used. @item @code{-work-area-phys} @var{address} -- set the work area base @var{address} to be used when no MMU is active. @item @code{-work-area-virt} @var{address} -- set the work area base @var{address} to be used when an MMU is active. @emph{Do not specify a value for this except on targets with an MMU.} The value should normally correspond to a static mapping for the @code{-work-area-phys} address, set up by the current operating system. @end itemize @end deffn @section Other $target_name Commands @cindex object command The Tcl/Tk language has the concept of object commands, and OpenOCD adopts that same model for targets. A good Tk example is a on screen button. Once a button is created a button has a name (a path in Tk terms) and that name is useable as a first class command. For example in Tk, one can create a button and later configure it like this: @example # Create button .foobar -background red -command @{ foo @} # Modify .foobar configure -foreground blue # Query set x [.foobar cget -background] # Report puts [format "The button is %s" $x] @end example In OpenOCD's terms, the ``target'' is an object just like a Tcl/Tk button, and its object commands are invoked the same way. @example str912.cpu mww 0x1234 0x42 omap3530.cpu mww 0x5555 123 @end example The commands supported by OpenOCD target objects are: @deffn Command {$target_name arp_examine} @deffnx Command {$target_name arp_halt} @deffnx Command {$target_name arp_poll} @deffnx Command {$target_name arp_reset} @deffnx Command {$target_name arp_waitstate} Internal OpenOCD scripts (most notably @file{startup.tcl}) use these to deal with specific reset cases. They are not otherwise documented here. @end deffn @deffn Command {$target_name array2mem} arrayname width address count @deffnx Command {$target_name mem2array} arrayname width address count These provide an efficient script-oriented interface to memory. The @code{array2mem} primitive writes bytes, halfwords, or words; while @code{mem2array} reads them. In both cases, the TCL side uses an array, and the target side uses raw memory. The efficiency comes from enabling the use of bulk JTAG data transfer operations. The script orientation comes from working with data values that are packaged for use by TCL scripts; @command{mdw} type primitives only print data they retrieve, and neither store nor return those values. @itemize @item @var{arrayname} ... is the name of an array variable @item @var{width} ... is 8/16/32 - indicating the memory access size @item @var{address} ... is the target memory address @item @var{count} ... is the number of elements to process @end itemize @end deffn @deffn Command {$target_name cget} queryparm Each configuration parameter accepted by @command{$target_name configure} can be individually queried, to return its current value. The @var{queryparm} is a parameter name accepted by that command, such as @code{-work-area-phys}. There are a few special cases: @itemize @bullet @item @code{-event} @var{event_name} -- returns the handler for the event named @var{event_name}. This is a special case because setting a handler requires two parameters. @item @code{-type} -- returns the target type. This is a special case because this is set using @command{target create} and can't be changed using @command{$target_name configure}. @end itemize For example, if you wanted to summarize information about all the targets you might use something like this: @example foreach name [target names] @{ set y [$name cget -endian] set z [$name cget -type] puts [format "Chip %d is %s, Endian: %s, type: %s" \ $x $name $y $z] @} @end example @end deffn @anchor{target curstate} @deffn Command {$target_name curstate} Displays the current target state: @code{debug-running}, @code{halted}, @code{reset}, @code{running}, or @code{unknown}. (Also, @pxref{Event Polling}.) @end deffn @deffn Command {$target_name eventlist} Displays a table listing all event handlers currently associated with this target. @xref{Target Events}. @end deffn @deffn Command {$target_name invoke-event} event_name Invokes the handler for the event named @var{event_name}. (This is primarily intended for use by OpenOCD framework code, for example by the reset code in @file{startup.tcl}.) @end deffn @deffn Command {$target_name mdw} addr [count] @deffnx Command {$target_name mdh} addr [count] @deffnx Command {$target_name mdb} addr [count] Display contents of address @var{addr}, as 32-bit words (@command{mdw}), 16-bit halfwords (@command{mdh}), or 8-bit bytes (@command{mdb}). If @var{count} is specified, displays that many units. (If you want to manipulate the data instead of displaying it, see the @code{mem2array} primitives.) @end deffn @deffn Command {$target_name mww} addr word @deffnx Command {$target_name mwh} addr halfword @deffnx Command {$target_name mwb} addr byte Writes the specified @var{word} (32 bits), @var{halfword} (16 bits), or @var{byte} (8-bit) pattern, at the specified address @var{addr}. @end deffn @anchor{Target Events} @section Target Events @cindex target events @cindex events At various times, certain things can happen, or you want them to happen. For example: @itemize @bullet @item What should happen when GDB connects? Should your target reset? @item When GDB tries to flash the target, do you need to enable the flash via a special command? @item Is using SRST appropriate (and possible) on your system? Or instead of that, do you need to issue JTAG commands to trigger reset? SRST usually resets everything on the scan chain, which can be inappropriate. @item During reset, do you need to write to certain memory locations to set up system clocks or to reconfigure the SDRAM? How about configuring the watchdog timer, or other peripherals, to stop running while you hold the core stopped for debugging? @end itemize All of the above items can be addressed by target event handlers. These are set up by @command{$target_name configure -event} or @command{target create ... -event}. The programmer's model matches the @code{-command} option used in Tcl/Tk buttons and events. The two examples below act the same, but one creates and invokes a small procedure while the other inlines it. @example proc my_attach_proc @{ @} @{ echo "Reset..." reset halt @} mychip.cpu configure -event gdb-attach my_attach_proc mychip.cpu configure -event gdb-attach @{ echo "Reset..." reset halt @} @end example The following target events are defined: @itemize @bullet @item @b{debug-halted} @* The target has halted for debug reasons (i.e.: breakpoint) @item @b{debug-resumed} @* The target has resumed (i.e.: gdb said run) @item @b{early-halted} @* Occurs early in the halt process @ignore @item @b{examine-end} @* Currently not used (goal: when JTAG examine completes) @item @b{examine-start} @* Currently not used (goal: when JTAG examine starts) @end ignore @item @b{gdb-attach} @* When GDB connects @item @b{gdb-detach} @* When GDB disconnects @item @b{gdb-end} @* When the target has halted and GDB is not doing anything (see early halt) @item @b{gdb-flash-erase-start} @* Before the GDB flash process tries to erase the flash @item @b{gdb-flash-erase-end} @* After the GDB flash process has finished erasing the flash @item @b{gdb-flash-write-start} @* Before GDB writes to the flash @item @b{gdb-flash-write-end} @* After GDB writes to the flash @item @b{gdb-start} @* Before the target steps, gdb is trying to start/resume the target @item @b{halted} @* The target has halted @ignore @item @b{old-gdb_program_config} @* DO NOT USE THIS: Used internally @item @b{old-pre_resume} @* DO NOT USE THIS: Used internally @end ignore @item @b{reset-assert-pre} @* Issued as part of @command{reset} processing after @command{reset_init} was triggered but before either SRST alone is re-asserted on the scan chain, or @code{reset-assert} is triggered. @item @b{reset-assert} @* Issued as part of @command{reset} processing after @command{reset-assert-pre} was triggered. When such a handler is present, cores which support this event will use it instead of asserting SRST. This support is essential for debugging with JTAG interfaces which don't include an SRST line (JTAG doesn't require SRST), and for selective reset on scan chains that have multiple targets. @item @b{reset-assert-post} @* Issued as part of @command{reset} processing after @code{reset-assert} has been triggered. or the target asserted SRST on the entire scan chain. @item @b{reset-deassert-pre} @* Issued as part of @command{reset} processing after @code{reset-assert-post} has been triggered. @item @b{reset-deassert-post} @* Issued as part of @command{reset} processing after @code{reset-deassert-pre} has been triggered and (if the target is using it) after SRST has been released on the scan chain. @item @b{reset-end} @* Issued as the final step in @command{reset} processing. @ignore @item @b{reset-halt-post} @* Currently not used @item @b{reset-halt-pre} @* Currently not used @end ignore @item @b{reset-init} @* Used by @b{reset init} command for board-specific initialization. This event fires after @emph{reset-deassert-post}. This is where you would configure PLLs and clocking, set up DRAM so you can download programs that don't fit in on-chip SRAM, set up pin multiplexing, and so on. (You may be able to switch to a fast JTAG clock rate here, after the target clocks are fully set up.) @item @b{reset-start} @* Issued as part of @command{reset} processing before @command{reset_init} is called. This is the most robust place to use @command{jtag_rclk} or @command{adapter_khz} to switch to a low JTAG clock rate, when reset disables PLLs needed to use a fast clock. @ignore @item @b{reset-wait-pos} @* Currently not used @item @b{reset-wait-pre} @* Currently not used @end ignore @item @b{resume-start} @* Before any target is resumed @item @b{resume-end} @* After all targets have resumed @item @b{resume-ok} @* Success @item @b{resumed} @* Target has resumed @end itemize @node Flash Commands @chapter Flash Commands OpenOCD has different commands for NOR and NAND flash; the ``flash'' command works with NOR flash, while the ``nand'' command works with NAND flash. This partially reflects different hardware technologies: NOR flash usually supports direct CPU instruction and data bus access, while data from a NAND flash must be copied to memory before it can be used. (SPI flash must also be copied to memory before use.) However, the documentation also uses ``flash'' as a generic term; for example, ``Put flash configuration in board-specific files''. Flash Steps: @enumerate @item Configure via the command @command{flash bank} @* Do this in a board-specific configuration file, passing parameters as needed by the driver. @item Operate on the flash via @command{flash subcommand} @* Often commands to manipulate the flash are typed by a human, or run via a script in some automated way. Common tasks include writing a boot loader, operating system, or other data. @item GDB Flashing @* Flashing via GDB requires the flash be configured via ``flash bank'', and the GDB flash features be enabled. @xref{GDB Configuration}. @end enumerate Many CPUs have the ablity to ``boot'' from the first flash bank. This means that misprogramming that bank can ``brick'' a system, so that it can't boot. JTAG tools, like OpenOCD, are often then used to ``de-brick'' the board by (re)installing working boot firmware. @anchor{NOR Configuration} @section Flash Configuration Commands @cindex flash configuration @deffn {Config Command} {flash bank} name driver base size chip_width bus_width target [driver_options] Configures a flash bank which provides persistent storage for addresses from @math{base} to @math{base + size - 1}. These banks will often be visible to GDB through the target's memory map. In some cases, configuring a flash bank will activate extra commands; see the driver-specific documentation. @itemize @bullet @item @var{name} ... may be used to reference the flash bank in other flash commands. A number is also available. @item @var{driver} ... identifies the controller driver associated with the flash bank being declared. This is usually @code{cfi} for external flash, or else the name of a microcontroller with embedded flash memory. @xref{Flash Driver List}. @item @var{base} ... Base address of the flash chip. @item @var{size} ... Size of the chip, in bytes. For some drivers, this value is detected from the hardware. @item @var{chip_width} ... Width of the flash chip, in bytes; ignored for most microcontroller drivers. @item @var{bus_width} ... Width of the data bus used to access the chip, in bytes; ignored for most microcontroller drivers. @item @var{target} ... Names the target used to issue commands to the flash controller. @comment Actually, it's currently a controller-specific parameter... @item @var{driver_options} ... drivers may support, or require, additional parameters. See the driver-specific documentation for more information. @end itemize @quotation Note This command is not available after OpenOCD initialization has completed. Use it in board specific configuration files, not interactively. @end quotation @end deffn @comment the REAL name for this command is "ocd_flash_banks" @comment less confusing would be: "flash list" (like "nand list") @deffn Command {flash banks} Prints a one-line summary of each device that was declared using @command{flash bank}, numbered from zero. Note that this is the @emph{plural} form; the @emph{singular} form is a very different command. @end deffn @deffn Command {flash list} Retrieves a list of associative arrays for each device that was declared using @command{flash bank}, numbered from zero. This returned list can be manipulated easily from within scripts. @end deffn @deffn Command {flash probe} num Identify the flash, or validate the parameters of the configured flash. Operation depends on the flash type. The @var{num} parameter is a value shown by @command{flash banks}. Most flash commands will implicitly @emph{autoprobe} the bank; flash drivers can distinguish between probing and autoprobing, but most don't bother. @end deffn @section Erasing, Reading, Writing to Flash @cindex flash erasing @cindex flash reading @cindex flash writing @cindex flash programming One feature distinguishing NOR flash from NAND or serial flash technologies is that for read access, it acts exactly like any other addressible memory. This means you can use normal memory read commands like @command{mdw} or @command{dump_image} with it, with no special @command{flash} subcommands. @xref{Memory access}, and @ref{Image access}. Write access works differently. Flash memory normally needs to be erased before it's written. Erasing a sector turns all of its bits to ones, and writing can turn ones into zeroes. This is why there are special commands for interactive erasing and writing, and why GDB needs to know which parts of the address space hold NOR flash memory. @quotation Note Most of these erase and write commands leverage the fact that NOR flash chips consume target address space. They implicitly refer to the current JTAG target, and map from an address in that target's address space back to a flash bank. @comment In May 2009, those mappings may fail if any bank associated @comment with that target doesn't succesfuly autoprobe ... bug worth fixing? A few commands use abstract addressing based on bank and sector numbers, and don't depend on searching the current target and its address space. Avoid confusing the two command models. @end quotation Some flash chips implement software protection against accidental writes, since such buggy writes could in some cases ``brick'' a system. For such systems, erasing and writing may require sector protection to be disabled first. Examples include CFI flash such as ``Intel Advanced Bootblock flash'', and AT91SAM7 on-chip flash. @xref{flash protect}. @anchor{flash erase_sector} @deffn Command {flash erase_sector} num first last Erase sectors in bank @var{num}, starting at sector @var{first} up to and including @var{last}. Sector numbering starts at 0. Providing a @var{last} sector of @option{last} specifies "to the end of the flash bank". The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @deffn Command {flash erase_address} [@option{pad}] address length Erase sectors starting at @var{address} for @var{length} bytes. Unless @option{pad} is specified, @math{address} must begin a flash sector, and @math{address + length - 1} must end a sector. Specifying @option{pad} erases extra data at the beginning and/or end of the specified region, as needed to erase only full sectors. The flash bank to use is inferred from the @var{address}, and the specified length must stay within that bank. As a special case, when @var{length} is zero and @var{address} is the start of the bank, the whole flash is erased. @end deffn @deffn Command {flash fillw} address word length @deffnx Command {flash fillh} address halfword length @deffnx Command {flash fillb} address byte length Fills flash memory with the specified @var{word} (32 bits), @var{halfword} (16 bits), or @var{byte} (8-bit) pattern, starting at @var{address} and continuing for @var{length} units (word/halfword/byte). No erasure is done before writing; when needed, that must be done before issuing this command. Writes are done in blocks of up to 1024 bytes, and each write is verified by reading back the data and comparing it to what was written. The flash bank to use is inferred from the @var{address} of each block, and the specified length must stay within that bank. @end deffn @comment no current checks for errors if fill blocks touch multiple banks! @anchor{flash write_bank} @deffn Command {flash write_bank} num filename offset Write the binary @file{filename} to flash bank @var{num}, starting at @var{offset} bytes from the beginning of the bank. The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @anchor{flash write_image} @deffn Command {flash write_image} [erase] [unlock] filename [offset] [type] Write the image @file{filename} to the current target's flash bank(s). A relocation @var{offset} may be specified, in which case it is added to the base address for each section in the image. The file [@var{type}] can be specified explicitly as @option{bin} (binary), @option{ihex} (Intel hex), @option{elf} (ELF file), @option{s19} (Motorola s19). @option{mem}, or @option{builder}. The relevant flash sectors will be erased prior to programming if the @option{erase} parameter is given. If @option{unlock} is provided, then the flash banks are unlocked before erase and program. The flash bank to use is inferred from the address of each image section. @quotation Warning Be careful using the @option{erase} flag when the flash is holding data you want to preserve. Portions of the flash outside those described in the image's sections might be erased with no notice. @itemize @item When a section of the image being written does not fill out all the sectors it uses, the unwritten parts of those sectors are necessarily also erased, because sectors can't be partially erased. @item Data stored in sector "holes" between image sections are also affected. For example, "@command{flash write_image erase ...}" of an image with one byte at the beginning of a flash bank and one byte at the end erases the entire bank -- not just the two sectors being written. @end itemize Also, when flash protection is important, you must re-apply it after it has been removed by the @option{unlock} flag. @end quotation @end deffn @section Other Flash commands @cindex flash protection @deffn Command {flash erase_check} num Check erase state of sectors in flash bank @var{num}, and display that status. The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @deffn Command {flash info} num Print info about flash bank @var{num} The @var{num} parameter is a value shown by @command{flash banks}. The information includes per-sector protect status, which may be incorrect (outdated) unless you first issue a @command{flash protect_check num} command. @end deffn @anchor{flash protect} @deffn Command {flash protect} num first last (@option{on}|@option{off}) Enable (@option{on}) or disable (@option{off}) protection of flash sectors in flash bank @var{num}, starting at sector @var{first} and continuing up to and including @var{last}. Providing a @var{last} sector of @option{last} specifies "to the end of the flash bank". The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @deffn Command {flash protect_check} num Check protection state of sectors in flash bank @var{num}. The @var{num} parameter is a value shown by @command{flash banks}. @comment @option{flash erase_sector} using the same syntax. This updates the protection information displayed by @option{flash info}. (Code execution may have invalidated any state records kept by OpenOCD.) @end deffn @anchor{Flash Driver List} @section Flash Driver List As noted above, the @command{flash bank} command requires a driver name, and allows driver-specific options and behaviors. Some drivers also activate driver-specific commands. @subsection External Flash @deffn {Flash Driver} cfi @cindex Common Flash Interface @cindex CFI The ``Common Flash Interface'' (CFI) is the main standard for external NOR flash chips, each of which connects to a specific external chip select on the CPU. Frequently the first such chip is used to boot the system. Your board's @code{reset-init} handler might need to configure additional chip selects using other commands (like: @command{mww} to configure a bus and its timings), or perhaps configure a GPIO pin that controls the ``write protect'' pin on the flash chip. The CFI driver can use a target-specific working area to significantly speed up operation. The CFI driver can accept the following optional parameters, in any order: @itemize @item @var{jedec_probe} ... is used to detect certain non-CFI flash ROMs, like AM29LV010 and similar types. @item @var{x16_as_x8} ... when a 16-bit flash is hooked up to an 8-bit bus. @end itemize To configure two adjacent banks of 16 MBytes each, both sixteen bits (two bytes) wide on a sixteen bit bus: @example flash bank $_FLASHNAME cfi 0x00000000 0x01000000 2 2 $_TARGETNAME flash bank $_FLASHNAME cfi 0x01000000 0x01000000 2 2 $_TARGETNAME @end example To configure one bank of 32 MBytes built from two sixteen bit (two byte) wide parts wired in parallel to create a thirty-two bit (four byte) bus with doubled throughput: @example flash bank $_FLASHNAME cfi 0x00000000 0x02000000 2 4 $_TARGETNAME @end example @c "cfi part_id" disabled @end deffn @subsection Internal Flash (Microcontrollers) @deffn {Flash Driver} aduc702x The ADUC702x analog microcontrollers from Analog Devices include internal flash and use ARM7TDMI cores. The aduc702x flash driver works with models ADUC7019 through ADUC7028. The setup command only requires the @var{target} argument since all devices in this family have the same memory layout. @example flash bank $_FLASHNAME aduc702x 0 0 0 0 $_TARGETNAME @end example @end deffn @deffn {Flash Driver} at91sam3 @cindex at91sam3 All members of the AT91SAM3 microcontroller family from Atmel include internal flash and use ARM's Cortex-M3 core. The driver currently (6/22/09) recognizes the AT91SAM3U[1/2/4][C/E] chips. Note that the driver was orginaly developed and tested using the AT91SAM3U4E, using a SAM3U-EK eval board. Support for other chips in the family was cribbed from the data sheet. @emph{Note to future readers/updaters: Please remove this worrysome comment after other chips are confirmed.} The AT91SAM3U4[E/C] (256K) chips have two flash banks; most other chips have one flash bank. In all cases the flash banks are at the following fixed locations: @example # Flash bank 0 - all chips flash bank $_FLASHNAME at91sam3 0x00080000 0 1 1 $_TARGETNAME # Flash bank 1 - only 256K chips flash bank $_FLASHNAME at91sam3 0x00100000 0 1 1 $_TARGETNAME @end example Internally, the AT91SAM3 flash memory is organized as follows. Unlike the AT91SAM7 chips, these are not used as parameters to the @command{flash bank} command: @itemize @item @emph{N-Banks:} 256K chips have 2 banks, others have 1 bank. @item @emph{Bank Size:} 128K/64K Per flash bank @item @emph{Sectors:} 16 or 8 per bank @item @emph{SectorSize:} 8K Per Sector @item @emph{PageSize:} 256 bytes per page. Note that OpenOCD operates on 'sector' sizes, not page sizes. @end itemize The AT91SAM3 driver adds some additional commands: @deffn Command {at91sam3 gpnvm} @deffnx Command {at91sam3 gpnvm clear} number @deffnx Command {at91sam3 gpnvm set} number @deffnx Command {at91sam3 gpnvm show} [@option{all}|number] With no parameters, @command{show} or @command{show all}, shows the status of all GPNVM bits. With @command{show} @var{number}, displays that bit. With @command{set} @var{number} or @command{clear} @var{number}, modifies that GPNVM bit. @end deffn @deffn Command {at91sam3 info} This command attempts to display information about the AT91SAM3 chip. @emph{First} it read the @code{CHIPID_CIDR} [address 0x400e0740, see Section 28.2.1, page 505 of the AT91SAM3U 29/may/2009 datasheet, document id: doc6430A] and decodes the values. @emph{Second} it reads the various clock configuration registers and attempts to display how it believes the chip is configured. By default, the SLOWCLK is assumed to be 32768 Hz, see the command @command{at91sam3 slowclk}. @end deffn @deffn Command {at91sam3 slowclk} [value] This command shows/sets the slow clock frequency used in the @command{at91sam3 info} command calculations above. @end deffn @end deffn @deffn {Flash Driver} at91sam7 All members of the AT91SAM7 microcontroller family from Atmel include internal flash and use ARM7TDMI cores. The driver automatically recognizes a number of these chips using the chip identification register, and autoconfigures itself. @example flash bank $_FLASHNAME at91sam7 0 0 0 0 $_TARGETNAME @end example For chips which are not recognized by the controller driver, you must provide additional parameters in the following order: @itemize @item @var{chip_model} ... label used with @command{flash info} @item @var{banks} @item @var{sectors_per_bank} @item @var{pages_per_sector} @item @var{pages_size} @item @var{num_nvm_bits} @item @var{freq_khz} ... required if an external clock is provided, optional (but recommended) when the oscillator frequency is known @end itemize It is recommended that you provide zeroes for all of those values except the clock frequency, so that everything except that frequency will be autoconfigured. Knowing the frequency helps ensure correct timings for flash access. The flash controller handles erases automatically on a page (128/256 byte) basis, so explicit erase commands are not necessary for flash programming. However, there is an ``EraseAll`` command that can erase an entire flash plane (of up to 256KB), and it will be used automatically when you issue @command{flash erase_sector} or @command{flash erase_address} commands. @deffn Command {at91sam7 gpnvm} bitnum (@option{set}|@option{clear}) Set or clear a ``General Purpose Non-Volatile Memory'' (GPNVM) bit for the processor. Each processor has a number of such bits, used for controlling features such as brownout detection (so they are not truly general purpose). @quotation Note This assumes that the first flash bank (number 0) is associated with the appropriate at91sam7 target. @end quotation @end deffn @end deffn @deffn {Flash Driver} avr The AVR 8-bit microcontrollers from Atmel integrate flash memory. @emph{The current implementation is incomplete.} @comment - defines mass_erase ... pointless given flash_erase_address @end deffn @deffn {Flash Driver} ecosflash @emph{No idea what this is...} The @var{ecosflash} driver defines one mandatory parameter, the name of a modules of target code which is downloaded and executed. @end deffn @deffn {Flash Driver} lpc2000 Most members of the LPC1700 and LPC2000 microcontroller families from NXP include internal flash and use Cortex-M3 (LPC1700) or ARM7TDMI (LPC2000) cores. @quotation Note There are LPC2000 devices which are not supported by the @var{lpc2000} driver: The LPC2888 is supported by the @var{lpc288x} driver. The LPC29xx family is supported by the @var{lpc2900} driver. @end quotation The @var{lpc2000} driver defines two mandatory and one optional parameters, which must appear in the following order: @itemize @item @var{variant} ... required, may be @option{lpc2000_v1} (older LPC21xx and LPC22xx) @option{lpc2000_v2} (LPC213x, LPC214x, LPC210[123], LPC23xx and LPC24xx) or @option{lpc1700} (LPC175x and LPC176x) @item @var{clock_kHz} ... the frequency, in kiloHertz, at which the core is running @item @option{calc_checksum} ... optional (but you probably want to provide this!), telling the driver to calculate a valid checksum for the exception vector table. @quotation Note If you don't provide @option{calc_checksum} when you're writing the vector table, the boot ROM will almost certainly ignore your flash image. However, if you do provide it, with most tool chains @command{verify_image} will fail. @end quotation @end itemize LPC flashes don't require the chip and bus width to be specified. @example flash bank $_FLASHNAME lpc2000 0x0 0x7d000 0 0 $_TARGETNAME \ lpc2000_v2 14765 calc_checksum @end example @deffn {Command} {lpc2000 part_id} bank Displays the four byte part identifier associated with the specified flash @var{bank}. @end deffn @end deffn @deffn {Flash Driver} lpc288x The LPC2888 microcontroller from NXP needs slightly different flash support from its lpc2000 siblings. The @var{lpc288x} driver defines one mandatory parameter, the programming clock rate in Hz. LPC flashes don't require the chip and bus width to be specified. @example flash bank $_FLASHNAME lpc288x 0 0 0 0 $_TARGETNAME 12000000 @end example @end deffn @deffn {Flash Driver} lpc2900 This driver supports the LPC29xx ARM968E based microcontroller family from NXP. The predefined parameters @var{base}, @var{size}, @var{chip_width} and @var{bus_width} of the @code{flash bank} command are ignored. Flash size and sector layout are auto-configured by the driver. The driver has one additional mandatory parameter: The CPU clock rate (in kHz) at the time the flash operations will take place. Most of the time this will not be the crystal frequency, but a higher PLL frequency. The @code{reset-init} event handler in the board script is usually the place where you start the PLL. The driver rejects flashless devices (currently the LPC2930). The EEPROM in LPC2900 devices is not mapped directly into the address space. It must be handled much more like NAND flash memory, and will therefore be handled by a separate @code{lpc2900_eeprom} driver (not yet available). Sector protection in terms of the LPC2900 is handled transparently. Every time a sector needs to be erased or programmed, it is automatically unprotected. What is shown as protection status in the @code{flash info} command, is actually the LPC2900 @emph{sector security}. This is a mechanism to prevent a sector from ever being erased or programmed again. As this is an irreversible mechanism, it is handled by a special command (@code{lpc2900 secure_sector}), and not by the standard @code{flash protect} command. Example for a 125 MHz clock frequency: @example flash bank $_FLASHNAME lpc2900 0 0 0 0 $_TARGETNAME 125000 @end example Some @code{lpc2900}-specific commands are defined. In the following command list, the @var{bank} parameter is the bank number as obtained by the @code{flash banks} command. @deffn Command {lpc2900 signature} bank Calculates a 128-bit hash value, the @emph{signature}, from the whole flash content. This is a hardware feature of the flash block, hence the calculation is very fast. You may use this to verify the content of a programmed device against a known signature. Example: @example lpc2900 signature 0 signature: 0x5f40cdc8:0xc64e592e:0x10490f89:0x32a0f317 @end example @end deffn @deffn Command {lpc2900 read_custom} bank filename Reads the 912 bytes of customer information from the flash index sector, and saves it to a file in binary format. Example: @example lpc2900 read_custom 0 /path_to/customer_info.bin @end example @end deffn The index sector of the flash is a @emph{write-only} sector. It cannot be erased! In order to guard against unintentional write access, all following commands need to be preceeded by a successful call to the @code{password} command: @deffn Command {lpc2900 password} bank password You need to use this command right before each of the following commands: @code{lpc2900 write_custom}, @code{lpc2900 secure_sector}, @code{lpc2900 secure_jtag}. The password string is fixed to "I_know_what_I_am_doing". Example: @example lpc2900 password 0 I_know_what_I_am_doing Potentially dangerous operation allowed in next command! @end example @end deffn @deffn Command {lpc2900 write_custom} bank filename type Writes the content of the file into the customer info space of the flash index sector. The filetype can be specified with the @var{type} field. Possible values for @var{type} are: @var{bin} (binary), @var{ihex} (Intel hex format), @var{elf} (ELF binary) or @var{s19} (Motorola S-records). The file must contain a single section, and the contained data length must be exactly 912 bytes. @quotation Attention This cannot be reverted! Be careful! @end quotation Example: @example lpc2900 write_custom 0 /path_to/customer_info.bin bin @end example @end deffn @deffn Command {lpc2900 secure_sector} bank first last Secures the sector range from @var{first} to @var{last} (including) against further program and erase operations. The sector security will be effective after the next power cycle. @quotation Attention This cannot be reverted! Be careful! @end quotation Secured sectors appear as @emph{protected} in the @code{flash info} command. Example: @example lpc2900 secure_sector 0 1 1 flash info 0 #0 : lpc2900 at 0x20000000, size 0x000c0000, (...) # 0: 0x00000000 (0x2000 8kB) not protected # 1: 0x00002000 (0x2000 8kB) protected # 2: 0x00004000 (0x2000 8kB) not protected @end example @end deffn @deffn Command {lpc2900 secure_jtag} bank Irreversibly disable the JTAG port. The new JTAG security setting will be effective after the next power cycle. @quotation Attention This cannot be reverted! Be careful! @end quotation Examples: @example lpc2900 secure_jtag 0 @end example @end deffn @end deffn @deffn {Flash Driver} ocl @emph{No idea what this is, other than using some arm7/arm9 core.} @example flash bank $_FLASHNAME ocl 0 0 0 0 $_TARGETNAME @end example @end deffn @deffn {Flash Driver} pic32mx The PIC32MX microcontrollers are based on the MIPS 4K cores, and integrate flash memory. @example flash bank $_FLASHNAME pix32mx 0x1fc00000 0 0 0 $_TARGETNAME flash bank $_FLASHNAME pix32mx 0x1d000000 0 0 0 $_TARGETNAME @end example @comment numerous *disabled* commands are defined: @comment - chip_erase ... pointless given flash_erase_address @comment - lock, unlock ... pointless given protect on/off (yes?) @comment - pgm_word ... shouldn't bank be deduced from address?? Some pic32mx-specific commands are defined: @deffn Command {pic32mx pgm_word} address value bank Programs the specified 32-bit @var{value} at the given @var{address} in the specified chip @var{bank}. @end deffn @deffn Command {pic32mx unlock} bank Unlock and erase specified chip @var{bank}. This will remove any Code Protection. @end deffn @end deffn @deffn {Flash Driver} stellaris All members of the Stellaris LM3Sxxx microcontroller family from Texas Instruments include internal flash and use ARM Cortex M3 cores. The driver automatically recognizes a number of these chips using the chip identification register, and autoconfigures itself. @footnote{Currently there is a @command{stellaris mass_erase} command. That seems pointless since the same effect can be had using the standard @command{flash erase_address} command.} @example flash bank $_FLASHNAME stellaris 0 0 0 0 $_TARGETNAME @end example @end deffn @deffn Command {stellaris recover bank_id} Performs the @emph{Recovering a "Locked" Device} procedure to restore the flash specified by @var{bank_id} and its associated nonvolatile registers to their factory default values (erased). This is the only way to remove flash protection or re-enable debugging if that capability has been disabled. Note that the final "power cycle the chip" step in this procedure must be performed by hand, since OpenOCD can't do it. @quotation Warning if more than one Stellaris chip is connected, the procedure is applied to all of them. @end quotation @end deffn @deffn {Flash Driver} stm32x All members of the STM32 microcontroller family from ST Microelectronics include internal flash and use ARM Cortex M3 cores. The driver automatically recognizes a number of these chips using the chip identification register, and autoconfigures itself. @example flash bank $_FLASHNAME stm32x 0 0 0 0 $_TARGETNAME @end example Some stm32x-specific commands @footnote{Currently there is a @command{stm32x mass_erase} command. That seems pointless since the same effect can be had using the standard @command{flash erase_address} command.} are defined: @deffn Command {stm32x lock} num Locks the entire stm32 device. The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @deffn Command {stm32x unlock} num Unlocks the entire stm32 device. The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @deffn Command {stm32x options_read} num Read and display the stm32 option bytes written by the @command{stm32x options_write} command. The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @deffn Command {stm32x options_write} num (@option{SWWDG}|@option{HWWDG}) (@option{RSTSTNDBY}|@option{NORSTSTNDBY}) (@option{RSTSTOP}|@option{NORSTSTOP}) Writes the stm32 option byte with the specified values. The @var{num} parameter is a value shown by @command{flash banks}. @end deffn @end deffn @deffn {Flash Driver} str7x All members of the STR7 microcontroller family from ST Microelectronics include internal flash and use ARM7TDMI cores. The @var{str7x} driver defines one mandatory parameter, @var{variant}, which is either @code{STR71x}, @code{STR73x} or @code{STR75x}. @example flash bank $_FLASHNAME str7x 0x40000000 0x00040000 0 0 $_TARGETNAME STR71x @end example @deffn Command {str7x disable_jtag} bank Activate the Debug/Readout protection mechanism for the specified flash bank. @end deffn @end deffn @deffn {Flash Driver} str9x Most members of the STR9 microcontroller family from ST Microelectronics include internal flash and use ARM966E cores. The str9 needs the flash controller to be configured using the @command{str9x flash_config} command prior to Flash programming. @example flash bank $_FLASHNAME str9x 0x40000000 0x00040000 0 0 $_TARGETNAME str9x flash_config 0 4 2 0 0x80000 @end example @deffn Command {str9x flash_config} num bbsr nbbsr bbadr nbbadr Configures the str9 flash controller. The @var{num} parameter is a value shown by @command{flash banks}. @itemize @bullet @item @var{bbsr} - Boot Bank Size register @item @var{nbbsr} - Non Boot Bank Size register @item @var{bbadr} - Boot Bank Start Address register @item @var{nbbadr} - Boot Bank Start Address register @end itemize @end deffn @end deffn @deffn {Flash Driver} tms470 Most members of the TMS470 microcontroller family from Texas Instruments include internal flash and use ARM7TDMI cores. This driver doesn't require the chip and bus width to be specified. Some tms470-specific commands are defined: @deffn Command {tms470 flash_keyset} key0 key1 key2 key3 Saves programming keys in a register, to enable flash erase and write commands. @end deffn @deffn Command {tms470 osc_mhz} clock_mhz Reports the clock speed, which is used to calculate timings. @end deffn @deffn Command {tms470 plldis} (0|1) Disables (@var{1}) or enables (@var{0}) use of the PLL to speed up the flash clock. @end deffn @end deffn @subsection str9xpec driver @cindex str9xpec Here is some background info to help you better understand how this driver works. OpenOCD has two flash drivers for the str9: @enumerate @item Standard driver @option{str9x} programmed via the str9 core. Normally used for flash programming as it is faster than the @option{str9xpec} driver. @item Direct programming @option{str9xpec} using the flash controller. This is an ISC compilant (IEEE 1532) tap connected in series with the str9 core. The str9 core does not need to be running to program using this flash driver. Typical use for this driver is locking/unlocking the target and programming the option bytes. @end enumerate Before we run any commands using the @option{str9xpec} driver we must first disable the str9 core. This example assumes the @option{str9xpec} driver has been configured for flash bank 0. @example # assert srst, we do not want core running # while accessing str9xpec flash driver jtag_reset 0 1 # turn off target polling poll off # disable str9 core str9xpec enable_turbo 0 # read option bytes str9xpec options_read 0 # re-enable str9 core str9xpec disable_turbo 0 poll on reset halt @end example The above example will read the str9 option bytes. When performing a unlock remember that you will not be able to halt the str9 - it has been locked. Halting the core is not required for the @option{str9xpec} driver as mentioned above, just issue the commands above manually or from a telnet prompt. @deffn {Flash Driver} str9xpec Only use this driver for locking/unlocking the device or configuring the option bytes. Use the standard str9 driver for programming. Before using the flash commands the turbo mode must be enabled using the @command{str9xpec enable_turbo} command. Several str9xpec-specific commands are defined: @deffn Command {str9xpec disable_turbo} num Restore the str9 into JTAG chain. @end deffn @deffn Command {str9xpec enable_turbo} num Enable turbo mode, will simply remove the str9 from the chain and talk directly to the embedded flash controller. @end deffn @deffn Command {str9xpec lock} num Lock str9 device. The str9 will only respond to an unlock command that will erase the device. @end deffn @deffn Command {str9xpec part_id} num Prints the part identifier for bank @var{num}. @end deffn @deffn Command {str9xpec options_cmap} num (@option{bank0}|@option{bank1}) Configure str9 boot bank. @end deffn @deffn Command {str9xpec options_lvdsel} num (@option{vdd}|@option{vdd_vddq}) Configure str9 lvd source. @end deffn @deffn Command {str9xpec options_lvdthd} num (@option{2.4v}|@option{2.7v}) Configure str9 lvd threshold. @end deffn @deffn Command {str9xpec options_lvdwarn} bank (@option{vdd}|@option{vdd_vddq}) Configure str9 lvd reset warning source. @end deffn @deffn Command {str9xpec options_read} num Read str9 option bytes. @end deffn @deffn Command {str9xpec options_write} num Write str9 option bytes. @end deffn @deffn Command {str9xpec unlock} num unlock str9 device. @end deffn @end deffn @section mFlash @subsection mFlash Configuration @cindex mFlash Configuration @deffn {Config Command} {mflash bank} soc base RST_pin target Configures a mflash for @var{soc} host bank at address @var{base}. The pin number format depends on the host GPIO naming convention. Currently, the mflash driver supports s3c2440 and pxa270. Example for s3c2440 mflash where @var{RST pin} is GPIO B1: @example mflash bank $_FLASHNAME s3c2440 0x10000000 1b 0 @end example Example for pxa270 mflash where @var{RST pin} is GPIO 43: @example mflash bank $_FLASHNAME pxa270 0x08000000 43 0 @end example @end deffn @subsection mFlash commands @cindex mFlash commands @deffn Command {mflash config pll} frequency Configure mflash PLL. The @var{frequency} is the mflash input frequency, in Hz. Issuing this command will erase mflash's whole internal nand and write new pll. After this command, mflash needs power-on-reset for normal operation. If pll was newly configured, storage and boot(optional) info also need to be update. @end deffn @deffn Command {mflash config boot} Configure bootable option. If bootable option is set, mflash offer the first 8 sectors (4kB) for boot. @end deffn @deffn Command {mflash config storage} Configure storage information. For the normal storage operation, this information must be written. @end deffn @deffn Command {mflash dump} num filename offset size Dump @var{size} bytes, starting at @var{offset} bytes from the beginning of the bank @var{num}, to the file named @var{filename}. @end deffn @deffn Command {mflash probe} Probe mflash. @end deffn @deffn Command {mflash write} num filename offset Write the binary file @var{filename} to mflash bank @var{num}, starting at @var{offset} bytes from the beginning of the bank. @end deffn @node NAND Flash Commands @chapter NAND Flash Commands @cindex NAND Compared to NOR or SPI flash, NAND devices are inexpensive and high density. Today's NAND chips, and multi-chip modules, commonly hold multiple GigaBytes of data. NAND chips consist of a number of ``erase blocks'' of a given size (such as 128 KBytes), each of which is divided into a number of pages (of perhaps 512 or 2048 bytes each). Each page of a NAND flash has an ``out of band'' (OOB) area to hold Error Correcting Code (ECC) and other metadata, usually 16 bytes of OOB for every 512 bytes of page data. One key characteristic of NAND flash is that its error rate is higher than that of NOR flash. In normal operation, that ECC is used to correct and detect errors. However, NAND blocks can also wear out and become unusable; those blocks are then marked "bad". NAND chips are even shipped from the manufacturer with a few bad blocks. The highest density chips use a technology (MLC) that wears out more quickly, so ECC support is increasingly important as a way to detect blocks that have begun to fail, and help to preserve data integrity with techniques such as wear leveling. Software is used to manage the ECC. Some controllers don't support ECC directly; in those cases, software ECC is used. Other controllers speed up the ECC calculations with hardware. Single-bit error correction hardware is routine. Controllers geared for newer MLC chips may correct 4 or more errors for every 512 bytes of data. You will need to make sure that any data you write using OpenOCD includes the apppropriate kind of ECC. For example, that may mean passing the @code{oob_softecc} flag when writing NAND data, or ensuring that the correct hardware ECC mode is used. The basic steps for using NAND devices include: @enumerate @item Declare via the command @command{nand device} @* Do this in a board-specific configuration file, passing parameters as needed by the controller. @item Configure each device using @command{nand probe}. @* Do this only after the associated target is set up, such as in its reset-init script or in procures defined to access that device. @item Operate on the flash via @command{nand subcommand} @* Often commands to manipulate the flash are typed by a human, or run via a script in some automated way. Common task include writing a boot loader, operating system, or other data needed to initialize or de-brick a board. @end enumerate @b{NOTE:} At the time this text was written, the largest NAND flash fully supported by OpenOCD is 2 GiBytes (16 GiBits). This is because the variables used to hold offsets and lengths are only 32 bits wide. (Larger chips may work in some cases, unless an offset or length is larger than 0xffffffff, the largest 32-bit unsigned integer.) Some larger devices will work, since they are actually multi-chip modules with two smaller chips and individual chipselect lines. @anchor{NAND Configuration} @section NAND Configuration Commands @cindex NAND configuration NAND chips must be declared in configuration scripts, plus some additional configuration that's done after OpenOCD has initialized. @deffn {Config Command} {nand device} name driver target [configparams...] Declares a NAND device, which can be read and written to after it has been configured through @command{nand probe}. In OpenOCD, devices are single chips; this is unlike some operating systems, which may manage multiple chips as if they were a single (larger) device. In some cases, configuring a device will activate extra commands; see the controller-specific documentation. @b{NOTE:} This command is not available after OpenOCD initialization has completed. Use it in board specific configuration files, not interactively. @itemize @bullet @item @var{name} ... may be used to reference the NAND bank in most other NAND commands. A number is also available. @item @var{driver} ... identifies the NAND controller driver associated with the NAND device being declared. @xref{NAND Driver List}. @item @var{target} ... names the target used when issuing commands to the NAND controller. @comment Actually, it's currently a controller-specific parameter... @item @var{configparams} ... controllers may support, or require, additional parameters. See the controller-specific documentation for more information. @end itemize @end deffn @deffn Command {nand list} Prints a summary of each device declared using @command{nand device}, numbered from zero. Note that un-probed devices show no details. @example > nand list #0: NAND 1GiB 3,3V 8-bit (Micron) pagesize: 2048, buswidth: 8, blocksize: 131072, blocks: 8192 #1: NAND 1GiB 3,3V 8-bit (Micron) pagesize: 2048, buswidth: 8, blocksize: 131072, blocks: 8192 > @end example @end deffn @deffn Command {nand probe} num Probes the specified device to determine key characteristics like its page and block sizes, and how many blocks it has. The @var{num} parameter is the value shown by @command{nand list}. You must (successfully) probe a device before you can use it with most other NAND commands. @end deffn @section Erasing, Reading, Writing to NAND Flash @deffn Command {nand dump} num filename offset length [oob_option] @cindex NAND reading Reads binary data from the NAND device and writes it to the file, starting at the specified offset. The @var{num} parameter is the value shown by @command{nand list}. Use a complete path name for @var{filename}, so you don't depend on the directory used to start the OpenOCD server. The @var{offset} and @var{length} must be exact multiples of the device's page size. They describe a data region; the OOB data associated with each such page may also be accessed. @b{NOTE:} At the time this text was written, no error correction was done on the data that's read, unless raw access was disabled and the underlying NAND controller driver had a @code{read_page} method which handled that error correction. By default, only page data is saved to the specified file. Use an @var{oob_option} parameter to save OOB data: @itemize @bullet @item no oob_* parameter @*Output file holds only page data; OOB is discarded. @item @code{oob_raw} @*Output file interleaves page data and OOB data; the file will be longer than "length" by the size of the spare areas associated with each data page. Note that this kind of "raw" access is different from what's implied by @command{nand raw_access}, which just controls whether a hardware-aware access method is used. @item @code{oob_only} @*Output file has only raw OOB data, and will be smaller than "length" since it will contain only the spare areas associated with each data page. @end itemize @end deffn @deffn Command {nand erase} num [offset length] @cindex NAND erasing @cindex NAND programming Erases blocks on the specified NAND device, starting at the specified @var{offset} and continuing for @var{length} bytes. Both of those values must be exact multiples of the device's block size, and the region they specify must fit entirely in the chip. If those parameters are not specified, the whole NAND chip will be erased. The @var{num} parameter is the value shown by @command{nand list}. @b{NOTE:} This command will try to erase bad blocks, when told to do so, which will probably invalidate the manufacturer's bad block marker. For the remainder of the current server session, @command{nand info} will still report that the block ``is'' bad. @end deffn @deffn Command {nand write} num filename offset [option...] @cindex NAND writing @cindex NAND programming Writes binary data from the file into the specified NAND device, starting at the specified offset. Those pages should already have been erased; you can't change zero bits to one bits. The @var{num} parameter is the value shown by @command{nand list}. Use a complete path name for @var{filename}, so you don't depend on the directory used to start the OpenOCD server. The @var{offset} must be an exact multiple of the device's page size. All data in the file will be written, assuming it doesn't run past the end of the device. Only full pages are written, and any extra space in the last


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