This folder contains a python script that communicates with the boot loader of the Texas Instruments CC2538, CC26xx and CC13xx SoCs (System on Chips). It can be used to erase, program, verify and read the flash of those SoCs with a simple USB to serial converter.
To run this script you need a Python interpreter, Linux and Mac users should be fine, Windows users have a look here: Python Download.
To communicate with the uart port of the SoC you need a usb to serial converter:
This script uses the pyserial package to communicate with the serial port and chip (https://pypi.org/project/pyserial/). You can install it by running
pip install pyserial.
If you want to be able to program your device from an Intel Hex file, you will need to install the IntelHex package: https://pypi.python.org/pypi/IntelHex (e.g. by running
pip install intelhex).
The script will try to auto-detect whether your firmware is a raw binary or an Intel Hex by using python-magic:
(https://pypi.python.org/pypi/python-magic). You can install it by running
pip install python-magic. Please bear in mind that installation of python-magic may have additional dependencies, depending on your OS: (https://github.com/ahupp/python-magic#dependencies).
If python-magic is not installed, the script will try to auto-detect the firmware type by looking at the filename extension, but this is sub-optimal. If the extension is
.ihex, the script will assume that the firmware is an Intel Hex file. In all other cases, the firmware will be treated as raw binary.
Once you connected the SoC you need to make sure the serial boot loader is enabled. A chip without a valid image (program), as it comes from the factory, will automatically start the boot loader. After you upload an image to the chip, the "Image Valid" bits are set to 0 to indicate that a valid image is present in flash. On the next reset the boot loader won't be started and the image is immediately executed.
To make sure you don't get "locked out", i.e. not being able to communicate over serial with the boot loader in the SoC anymore, you need to enable the boot loader backdoor in your image (the script currently only checks this on firmware for the 512K model). When the boot loader backdoor is enabled the boot loader will be started when the chip is reset and a specific pin of the SoC is pulled high or low (configurable).
The boot loader backdoor can be enabled and configured with the 8-bit boot loader backdoor field in the CCA area in flash. If you set this field to 0xF3FFFFFF the boot loader will be enabled when pin PA3 is pulled low during boot. This translates to holding down the
select button on the SmartRF06 board while pushing the
EM reset button.
If you did lock yourself out or there is already an image flashed on your SoC, you will need a jtag programmer to erase the image. This will reset the image valid bits and enable the boot loader on the next reset. The SmartRF06EB contains both a jtag programmer and a USB to uart converter on board.
The script has been tested with SmartRF06EB + CC2650 EM. The physical wiring on the CC2650 Sensortag does not meet the ROM bootloader's requirements in terms of serial interface configuration. For that reason, interacting with the Sensortag via this script is (and will remain) impossible.
For sensortags CC1350STK: It is possible to solder cables to R21 and R22 for flashing using the Serial Bootloader. This issue has instructions about flashing the CC1350STK sensortag.
For the CC13xx and CC26xx families, the ROM bootloader is configured through the
BL_CONFIG 'register' in CCFG.
BOOTLOADER_ENABLE should be set to
0xC5 to enable the bootloader in the first place.
This is enough if the chip has not been programmed with a valid image. If a valid image is present, then the remaining fields of
BL_CONFIG and the
ERASE_CONF register must also be configured correctly:
BANK_ERASEcommand is enabled: The
BANK_ERASE_DIS_Nbit in the
ERASE_CONFregister in CCFG must be set.
BANK_ERASEis enabled by default.
If you are using CC13xx/CC26xxware, the relevant settings are under
startup_files/ccfg.c. This is the case if you are using Contiki.
Similar to the CC2538, the bootloader will be activated if, at the time of reset, failure analysis is enabled and the selected DIO is found to be at the active level.
As an example, to bind the bootloader backdoor to KEY_SELECT on the SmartRF06EB, you need to set the following:
BOOTLOADER_ENABLE = 0xC5(Bootloader enable.
BL_LEVEL = 0x00(Active low.
BL_PIN_NUMBER = 0x0B(DIO 11.
BL_ENABLE = 0xC5(Enable "failure analysis".
These settings are very useful for development, but enabling failure analysis in a deployed firmware may allow a malicious user to read out the contents of your device's flash or to erase it. Do not enable this in a deployment unless you understand the security implications.
The script will automatically select the first serial looking port from a USB to uart converter in
/dev (OSX, Linux) for uploading. Be careful as on the SmartRF06B board under Linux this might be the jtag interface as apposed to the uart interface. In this case select the correct serial port manually with the
-p option. Serial port selection under Windows needs testing.
Before uploading your image make sure you start the boot loader on the SoC (
reset on CC2538DK).
You can find more info on the different options by executing
python cc2538-bsl.py -h.
If you found a bug or improved some part of the code, please submit an issue or pull request.