Debugging support for ARM Cortex-M Microcontrollers with the following features:
- Highly configurable. See https://github.com/Marus/cortex-debug/blob/master/debug_attributes.md
- Support J-Link, OpenOCD GDB Server, STMicroelectronic's ST-LINK GDB server (no SWO support yet), pyOCD
- Initial support for the Black Magic Probe (This has not been as heavily tested; SWO can only be captured via a serial port)
- Partial support textane/stlink (st-util) GDB Servers (SWO can only be captured via a serial port)
- Multi-core and multi-session debugging. See https://github.com/Marus/cortex-debug/wiki/Multi-core-debugging
- Disassembly of source code available along with instruction level breakpoints and stepping. The actual disassembly window is provided and managed by VSCode. See https://github.com/Marus/cortex-debug/wiki/Disassembly-Debugging
- Cortex Core Register Viewer (integrated into Variables window since V1.2)
- In some cases the st-util GDB server can report incomplete/incorrect registers, so there may be some issues here.
- SWO Decoding - "console" text output and binary data (signed and unsigned 32-bit integers, Q16.16 fixed point integers, single precision floating point values)
- The registers that are part of the DWT, TPIU, and ITM debug components will automatically be configured and do not need to be set in firmware.
- Firmware may still need to enable the SWO output pin - as this part of the setup is microcontroller dependant.
- Decoding ETM data over the SWO pin is not currently supported.
- Live graphing of decoded ITM data.
- Support for Custom ITM Data Decoders:
- Ability to define JavaScript modules to decode complex data formats streamed over one or more ITM ports. Data can be printed to a output window, or sent to the graphing system. If you are using TCP/IP instead, you can use a variety of tools to connect to the that port.
- Semi-hosting Support. In the
TERMINAL
tab, there will be a sub-window calledgdb-server
. That terminal is bidirectional and is intended for semi-hosting. This applies to those gdb-servers that do their semi-hosting on their stdio. - Support for SEGGER Real Time Trace (RTT) using OpenOCD and J-Link gdb-servers. All the features supported for SWO (text, binary, graphing) are also supported with RTT. See image above for console style output. SWO output also creates another section.
- Globals and Static scopes in the variables view
- Initial support for Rust code (most functionality is working; report any issues)
- RTOS Thread Support in
CALL STACK
window (J-Link, OpenOCD, pyOCD - RTOS supported depend on GDB server)- As a general rule do not try to use stepping instructions before the scheduler of your RTOS has started - in many cases this tends to crash the GDB servers or leave it in an inconsistent state.
- Live Watch with supported GDB servers (tested with OpenOCD, J-Link, STLink so far - since V1.6)
- We have a set of extensions that this extension relies on for various frontend services (since V1.6)
- These services are under the mcu-debug organization and lot of that content was re-factored from this extension to make them work with other debuggers and with browsers
- Visit https://marketplace.visualstudio.com/search?term=mcu-debug&target=VSCode&category=All%20categories&sortBy=Relevance\
- Highlights are a Memory Viewer, RTOS viewer, Peripheral (SVD) Viewer
- These extensions are considered as dependency of this extension and VSCode should help you install all of them. We will consider make an
Extension Pack
in the future
Cortex-Debug uses a versioning system specified by Microsoft that allows distribution of pre-releases via the marketplace. You can enable (or disable) pre-releases within VSCode for this extension and you will automatically get new pre-releases. By default, pre-releases are disabled. We use pre-releases as allow testing of bug fixes and new features. They allow you participate during the formation of a feature of how an issue gets addressed. More info about pre-releases. To summarize, extensions use semantic versioning (SemVer) system which in simple terms is major.minor.patch
. With MS convention, if the minor
version is odd
, then it is a pre-release.
- Additional Graphing Options
- Our TODO file
Requirements:
- ARM GCC Toolchain (https://developer.arm.com/open-source/gnu-toolchain/gnu-rm/downloads) - provides arm-none-eabi-gdb and related tools
- At least one of:
- J-Link Software Tools - provides the J-Link GDB Server for J-Link based debuggers (https://www.segger.com/downloads/jlink)
- OpenOCD - provides a GDB Server that can be used with a number of debuggers (http://openocd.org)
- NOTE: If a chip vendor ships it's own OpenOCD version, for sure use NOTHING but that
- NOTE: On macOS do not use the default version of OpenOCD provided by homebrew, this is not compatible with releases V0.2.4 and newer.
- You can either install from source using homebrew (
brew install open-ocd --HEAD
) or the packages from https://github.com/xpack-dev-tools/openocd-xpack/releases/ will also work.
- You can either install from source using homebrew (
- NOTE: Some linux versions and Windows may also need a more up-to-date version of OpenOCD from the xPack releases.
- Texane's st-util GDB server - Only supports ST-Link Debug Probes (https://github.com/texane/stlink)
- ST-LINK GDB server - This server is packaged with the STM32CubeIDE which must be installed. The location of the STM32CubeIDE and related tools is automatically resolved but also can be overridden using configuration settings (
armToolchainPath
,stm32cubeprogrammer
andserverpath
). - pyOCD GDB Server - GDB server that supports the CMSIS-DAP debugger on a number of mbed boards (https://github.com/mbedmicro/pyOCD)
- Black Magic Probe
See https://github.com/Marus/cortex-debug/wiki for usage information. This needs some help from the community. See https://github.com/Marus/cortex-debug/blob/master/debug_attributes.md for a summary of all properties that are available in your launch.json
git clone https://github.com/Marus/cortex-debug.git
cd cortex-debug
- Optionally switch to a branch:
git checkout <existing-branch-name>
npm install
- Optional
npm run compile
- Open VSCode in the top folder and run the task
npm watch
. This will compile the code and watch for any changes and auto compile. The first time, it may take a minute or so for it to watch the entire folder. You can see the output ofnpm watch
in the Terminal tab.
The extension is split into two main parts.
- The front-end which is what you interact with mostly
- The backend called
debug adapter
which interfaces betweengdb
,vscode/front-end
, and thegdb-server
. We just start the server and from then on the debug adapter only interacts withgdb
. All requests go togdb
and the results are read back fromgdb
usinggdb
's MI (machine interface)
If you want to debug both parts, in launch.json
use the Extension + Debug Server
configuration. It will launch a new window -- the debuggee
. In the debuggee
VSCode window, load a FW folder/workspace (VSCode remembers the last one) and add the following to debuggee
's launch.json
.
"debugServer": 4711
Now, launch a debug session and you wil be able to use the primary VSCode window to observe the Cortex-Debug extension
Parts of this extension are based upon Jan Jurzitza's (WebFreak) code-debug extension (https://github.com/WebFreak001/code-debug).
His project provided an excellent base for GDB MI parsing and interaction.