Metadata-Version: 2.1
Name: psdb
Version: 0.9.6
Summary: Package for interfacing with ARM-compatible debug probes
Home-page: https://github.com/tgree/psdb
Author: Terry Greeniaus
Author-email: terrygreeniaus@gmail.com
License: LGPLv2
Description: psdb
        ====
        This package provides Python access to various ARM-compatible debug probes.
        
        All tools support the ``--help`` option.  It is required to use python3.  The
        easiest way to install psdb is using pip::
        
            pip3 install psdb
        
        Note that you may wish to use sudo to install psdb for all users on your
        system::
        
            sudo pip3 install psdb
        
        You may also install the package from the source using::
        
            make install
        
        which will require super-user privileges.  Alternatively, you can run all
        commands from the root of the repository without installing anything.
        
        If you are on a Linux machine, it is also recommended to install the udev
        rules file that will allow non-sudo access to the debug probes (otherwise you
        must run the psdb tools using sudo) to anybody that is a member of the 'usb'
        group::
        
            sudo addgroup usb
            sudo adduser YOUR_USER_NAME usb
            sudo cp -r etc/* /etc/
        
        This command is not necessary on macOS since USB devices are accessible
        without super-user privileges.  If your debug probe is connected when you
        install the udev rules, you may need to hot-plug it in order for the new rules
        to take effect.  Also, if you just added yourself to the usb group then you
        will need to start a new shell session for that permission to take effect.
        
        
        psdb_flash_tool
        ===============
        The flash_tool script allows you to burn ELF images into flash, retrieve the
        contents of flash and reset a target board.  On STM32, it is highly
        recommended to use the ``--connect-under-reset`` option.  This will reset the
        target MCU and halt in the reset handler before any code has a chance to
        execute and potentially interfere with the flashing operation.  This is
        especially important on the STM32WB series where the flash is shared by the
        wireless coprocessor.  Non-STM32 MCUs may not support connecting to the target
        while it is under reset (for instance, the MSP432 does not support this).
        
        To dump the full flash contents to a file, generating a raw binary image
        (useful for making a backup of the original flash contents on a board)::
        
            psdb_flash_tool --connect-under-reset --read path/to/file.bin
        
        To write a raw binary image into flash::
        
            psdb_flash_tool --connect-under-reset --write--raw-binary path/to/file.bin
        
        Flashing of ELF and Intel HEX files is also supported.  In these cases, all
        address ranges that overlap with the flash will be burnt in, and other address
        ranges will be ignored.  Note that the target sectors (and only the target
        sectors) are fully erased first, so any sectors that are under-specified in
        the ELF or HEX files will contain 0xFF in the unused regions.  To flash an ELF
        or HEX file::
        
            psdb_flash_tool --connect-under-reset --flash path/to/image.elf
            psdb_flash_tool --connect-under-reset --flash path/to/image.hex
        
        Finally, erasing the flash is also supported.  All writeable sectors will be
        erased to the value 0xFF::
        
            psdb_flash_tool --connect-under-reset --erase
        
        The flash_tool script can also be used to view and modify the STM32 option
        bytes stored in the MCU's flash.  The ``--get-options`` flag allows one to dump
        the contents of all option bytes::
        
            psdb_flash_tool --connect-under-reset --get-options
        
        While the ``--option`` argument (which takes two parameters - a
        case-insensitive option name and an option value) can be specified multiple
        times to change options::
        
            psdb_flash_tool --connect-under-reset --option nboot1 0 --option nboot0 1
        
        
        psdb_core_tool
        ==============
        The core_tool script can be used to capture the contents of flash and SRAM in
        the form of an ELF core file.  This core file, in conjunction with the
        original ELF executable, can be opened under gdb for offline diagnosis.
        Unfortunately, the standard ``arm-none-eabi-gdb`` tool cannot open core files;
        however, ``gdb-multiarch`` is able to open these without any trouble.  On Linux,
        this is as simple as installing ``gdb-multiarch`` with your package manager.
        On other systems, installing in a Docker container may be a viable alternative.
        
        The ``--peripheral-capture`` option allows the capture of all registers from
        devices listed in the target's dev array.
        
        The captured core file is independent of the build system used to generate the
        executable or the actual code installed on the microcontroller.  To debug the
        core file::
        
            gdb-multiarch path/to/executable.elf
            target core path/to/core.elf
        
        
        psdb_gdb_tool
        =============
        The gdb_tool script starts a simple gdb server that attaches to the target
        device.  It can be connected to with a remote gdb client.
        
        
        psdb_inspect_tool
        =================
        The inspect_tool script starts an interactive curses-based tool that can be
        used to view the current CPU registers, select target peripheral registers and
        select regions of target RAM or flash.  The inspect_tool script requires the
        tgcurses library to be installed (available on github/tgree).  pip will
        install tgcurses automatically.
        
        
        psdb_fus_tool
        =============
        The fus_tool script is for interacting with the ST Firmare Upgrade Services
        (FUS) on the STM32WB55 wireless MCU.  The STM32WB55 co-processor has a secure
        region of flash that includes the FUS binary itself and the wireless stack
        currently installed on the MCU.  Different wireless stacks can be installed
        and FUS itself can also be upgraded.  The binaries can be found in ST's
        `STM32CubeWB.git`_ repository under the path::
        
            Projects/STM32WB_Copro_Wireless_Binaries/STM32WB5x
        
        Sample invocations for manipulating wireless firmware::
        
            psdb_fus_tool --fw-upgrade Projects/STM32WB_Copro_Wireless_Binaries/STM32WB5x/stm32wb5x_BLE_Stack_full_fw.bin
            psdb_fus_tool --fw-delete
        
        Or, a compound command to remove the old WS firmware, install new WS firmware
        and then start the application back up::
        
            psdb_fus_tool \
                --fw-delete \
                --fw-upgrade Projects/STM32WB_Copro_Wireless_Binaries/STM32WB5x/stm32wb5x_BLE_Stack_full_fw.bin \
                --set-flash-boot
        
        Note that an invocation with ``--set-flash-boot`` is required when you are done;
        in order to properly communicate with FUS, we need to prevent any user
        firmware from starting CPU2 or trying to use the IPC channels - we do that by
        switching the system to boot from SRAM1 until we are done with it.
        
        When using this to upgrade FUS itself, you use the ``--fus-upgrade`` option
        along with the ``--bin-dir`` option.  The code will find the next valid FUS
        binary in the upgrade path for your target.  For instance, a brand new Nucleo
        STM32WB55 board has an ancient 0.5.3 version of FUS.  This cannot be directly
        upgraded to the latest 1.1.0 version of FUS but must instead stop at 1.0.2
        first.  You can then reinvoke fus_tool again if you wish to then upgrade from
        1.0.2 to 1.1.0.  Note that it is not possible to downgrade FUS, so this
        behavior allows you to stop at any desired version.  When upgrading FUS, it is
        required to first delete the current wireless stack with the ``--fw-delete``
        option.
        
        Sample invocation for updating FUS::
        
            psdb_fus_tool --bin-dir Projects/STM32WB_Copro_Wireless_Binaries/STM32WB5x --fus-upgrade
        
        Note that when upgrading FUS, the target board will reboot at least 4 times.
        
        It is recommended to upgrade to FUS 1.1.0.
        
        
        STLINK Protocol
        ===============
        We also attempt to document the STLINK protocol inside the stlink package.
        You can view it most easily from within the python interpreter::
        
            >>> import psdb.probes.stlink
            >>> help(psdb.probes.stlink.cdb)
        
        
        .. _STM32CubeWB.git: https://github.com/STMicroelectronics/STM32CubeWB
        
Keywords: stlink xds110 arm swd fus stm32 msp432
Platform: UNKNOWN
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: GNU Lesser General Public License v2 (LGPLv2)
Requires-Python: >=3.0
Description-Content-Type: text/x-rst
