The JTAG Library for Arduino
This library has four interesting things.
First, it is a JTAG test access point (TAP) manipulation library. The code tries to be processor agnostic as much as possible, so that it can be used in the future in other platforms. JTAG is a powerfull interface, there are many things that you can do besides programming devices. For example, you can do boundary scan tests, and even debug and take complete control of some hardware.
Second, it is a XSVF file player. That way, it is possible to program CPLDs and FPGAs through the JTAG port.
Third, there is a XSVF disassembler written in python, so that you can learn what is happening in the XSVF file you are using to program your device.
And finally, there is a XSVF assembler, also written in python, so that you can recompile or write your own XSVF programs yourself in a maintainable and documented way, since the grammar supports comments.
Remember that Arduino compatible devices are usually powered with 5 Volts, while most CPLDs and FPGAs will use a 3.3 Volts interface. In my original project, I have used 3 voltage dividers for TCK, TMS and TDI. Each divider consisted of one 330 Ohms resistor in series with a 180 Ohms resistor. One leg of the 330 Ohms resistor goes to the ground, one leg of the 180 Ohms resistor goes to the Arduino. Where two legs meet, this is where you should connect your JTAG cable.
Those seem to be a bit low values for a voltage divider, but consider the fact that you will most likely have around 100 Ohms impedance in your JTAG homemade cable, and higher resistor values will most likely create reflections on your signals that will ruin the operation of the JTAG TAP.
TDO and VREF can be tied straight to the arduino pins, but I suggest using a 100 Ohms resistor on TDO, just to be sure to make reflections low. The big problem here is not TDO itself, but the crosstalk that can happen between TDO and TCK in your target board. Trust me, I've been there.
Using VREF is important so that your Arduino knows your JTAG cable it is actually connected to something. Also, VREF could be used to power buffers to convert the Arduino signals to the right voltage level whithout the resistors I mentioned before.
The pin configuration I used was this:
Signal | Arduino pin |
---|---|
TMS | 8 |
TDI | 9 |
TDO | 10 |
TCK | 11 |
VREF | 12 |
Before using this software
You will need:
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An Arduino compatible board, along with some way to program it (PC with USB and Arduino IDE or some other hardware device).
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Python with the library pyserial installed.
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The proper connection, be it a cable or a few loose wire jumpers.
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A CPLD, FPGA or any other JTAG interface board to connect to. It is worth mentioning that Dangerous Prototypes has two very interesting CPLD boards. I have personally used a XC2C64A breakout board. They also have a similar breakout board for the XC9572XL.
Installing the library
This software has been tested under the Arduino IDE version 1.6.5, but should work fine with version 1.0. The library should be unpacked to the "libraries" directory inside your Arduino "sketches" directory.
Compiling
One quick suggestion: in order to get the most of the USB bandwidth, it is possible to increase the size of the receive buffer of the Arduino. I have also changed the default compiler optimization level. I added a file called "platform.local.txt" to the folder "~/arduino-1.6.5/hardware/arduino/avr" that had the following:
name=Arduino 256S AVR Boards
version=1.6.7
# AVR compile variables
# ---------------------
# This can be overriden in boards.txt
build.extra_flags=
# These can be overridden in platform.local.txt
compiler.c.extra_flags=-DSERIAL_BUFFER_SIZE=256 -DSERIAL_RX_BUFFER_SIZE=256 -O2
compiler.c.elf.extra_flags=
compiler.S.extra_flags=
compiler.cpp.extra_flags=-DSERIAL_BUFFER_SIZE=256 -DSERIAL_RX_BUFFER_SIZE=256 -O2
compiler.ar.extra_flags=
compiler.objcopy.eep.extra_flags=
compiler.elf2hex.extra_flags=
The best information about the location of the file "platform.local.txt" I found was here.
Another suggestion: if speed is really an issue, instead of using "JTAGPortArduino", use "JTAGPortAVR". Take a look at PlayXSVFJTAVR.{cpp,h}. JTAGPortAVR uses the same pin configuration I have mentioned before, but since all the pins are on AVR's PORTB, all pins are written at once, so the JTAG port code is more efficient.
Using it to play XSVF
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The example sketch "JTAGTest" has been used in all my tests. Upload it to your Arduino board. Now you have a XSVF JTAG player.
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Inside the folder libraries/JTAG/extras/python, there is a python script called xsvf. It has some command line parameters, but the default ones should be ok. You can use it to send more than one file in a sequence to your board. For example, suppose you are in a command prompt in the libraries/JTAG folder. Then, the following command will send the following four XSVF files to your Arduino board:
$ ./extras/python/xsvf extras/xsvf/XC2C64A/{idcode.xsvf,blank_check.xsvf,erase.xsvf,VHDL-CPLDIntro3LEDinverse.xsvf}
Help is available for the command line parameters:
$ ./extras/python/xsvf --help
usage: xsvf [-h] [-c {upload,disasm}] [-v] [-p PORT] [-b BAUD]
fileName [fileName ...]
XSVF file processor.
positional arguments:
fileName XSVF file names. (type FileType('rb'))
optional arguments:
-h, --help show this help message and exit
-c {upload,disasm}, --command {upload,disasm}
command to execute. (default=upload)
-v, --version show program's version number and exit
-p PORT, --port PORT Serial port device name (default=/dev/ttyACM0)
-b BAUD, --baud BAUD BAUD rate (type int, default=115200)
Parameters can be in a file, one per line, using @"file name"
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In subfolders of the folder "extras/xsvf" you can find several XSVF files that you can use to test your hardware. Notice that you MUST use a XSVF file generated for your particular hardware. You can generate XSVF files with the software "impact", which comes with the Xilinx bundle.
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A failure in the execution of "blank_check.xsvf" means that the CPLD is not blank. The same file should be successful after the execution of "erase.xsvf".
Interesting links
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Youtube video: Como programar CPLD Xilinx con Arduino
Credits
I have used Xilinx [XAPP503 - SVF and XSVF File Formats for Xilinx Devices] (http://www.xilinx.com/support/documentation/application_notes/xapp503.pdf), appendix B as the reference for XSVF.
This software is actually a major rewrite of code and ideas inspired on many other projects. As far as I could trace it:
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Clifford Wolf's libxsvf. Definitely worth taking a look.
About me
You may contact me on github.