Difference between revisions of "DhruvaGole/ProjectReport"
DhruvaG2000 (talk | contribs) (→Description) |
DhruvaG2000 (talk | contribs) (→Proposed method of Implementation) |
||
Line 54: | Line 54: | ||
C, C++, PRU, dtb, GNU Make, ARM Assembly | C, C++, PRU, dtb, GNU Make, ARM Assembly | ||
− | === | + | ===Implementation Details=== |
− | The Bela cape is normally used in combination with the TI AM3358 | + | The Bela cape is normally used in combination with the TI AM3358 processor present on the BeagleBone Black. The hardware was partially working on the BBAI using only ALSA([https://en.wikipedia.org/wiki/Advanced_Linux_Sound_Architecture Advanced Linux Sound Architecture]*) and the SPI driver [https://github.com/giuliomoro/beaglebone-ai-bela]. However, the Bela real-time code on ARM and PRU was not running on the BBAI yet. <br> |
− | + | Brief Summary: | |
− | |||
− | |||
− | |||
− | |||
− | The project | + | # Created a device tree overlay using [https://elinux.org/Beagleboard:BeagleBone_cape_interface_spec Cape Compatibility layer] to port [https://github.com/beagleboard/bb.org-overlays/blob/master/src/arm/BB-BONE-AUDI-02-00A0.dts BB-BONE-AUDI] which worked but had a few frequency issues on the BBAI. The Overlay I wrote has been accepted by BeagleBone maintainer Robert Nelson, and you can find it to here: https://github.com/beagleboard/BeagleBoard-DeviceTrees/pull/36 |
+ | # Created a device tree overlay for the BELA Cape to work on the BBAI using the Cape Compatibility layer. It has been tested and is available on github: https://github.com/DhruvaG2000/BeagleBoard-DeviceTrees/blob/v4.19.x-ti-overlays/src/arm/overlays/BBAI-BELA-00A1.dts | ||
+ | # Adapted to the Bela PRU and ARM code and workflow to use the PRU using the [https://www.kernel.org/doc/Documentation/remoteproc.txt Remote Processor Framework] instead of the almost oudated UIO PRUSS. | ||
+ | # Updated the Bela code to use the McASP, GPIO and McSPI on the AM5729 SoC of the BBAI | ||
+ | # Install a Xenomai patched kernel and run the full Bela stack. | ||
+ | # I also ported a debugger for PRU called [ PRUDebug]. | ||
+ | |||
+ | This project involved dealing with pinmuxing (using overlays), PRU assembly, C and C++ for Linux user space applications. Also studied the Technical Reference Manual for the Sitara family of SoCs. ([https://www.ti.com/lit/ug/spruhz6l/spruhz6l.pdf AM5729] and the AM335x. | ||
+ | |||
+ | |||
+ | ;What is RProc? | ||
+ | The remoteproc framework allows different platforms/architectures to | ||
+ | control (power on, load firmware, power off) those remote processors while | ||
+ | abstracting the hardware differences, so the entire driver doesn't need to be | ||
+ | duplicated. In addition, this framework also adds rpmsg virtio devices | ||
+ | for remote processors that supports this kind of communication. This way, | ||
+ | platform-specific remoteproc drivers only need to provide a few low-level | ||
+ | handlers | ||
+ | Reference: https://www.kernel.org/doc/Documentation/remoteproc.txt | ||
+ | |||
+ | ;What is a Device Tree Overlay? | ||
+ | Sometimes it is not convenient to describe an entire system with a | ||
+ | single FDT(Flattened Device Tree). For example, processor modules that are plugged into one or | ||
+ | more modules (a la the BeagleBone), or systems with an FPGA peripheral | ||
+ | that is programmed after the system is booted. | ||
+ | For these cases it is proposed to implement an overlay feature | ||
+ | so that the initial device tree data can be modified by userspace at | ||
+ | runtime by loading additional overlay FDTs that amend the original data. ([ ref.]) | ||
+ | <br> | ||
+ | How is an overlay compiled?<br> | ||
+ | dtc (Device Tree Compiler) - converts between the human editable device tree source "dts" format and the compact device tree blob "dtb" representation usable by the kernel or assembler source. <br> Once an overlay is compiled, it generates a '''.dtbo''' file which we can then use in the next stage. <br> | ||
+ | |||
+ | How does one load a DT Overlay? <br> | ||
+ | It's simple, just edit the file '''/boot/uEnv.txt''' and then edit the following lines: | ||
+ | enable_uboot_overlays=1 | ||
+ | |||
+ | uboot_overlay_addr4=/lib/firmware/BBAI-AUDI-02-00A0.dtbo | ||
+ | |||
+ | and on the next boot, this new overlay should be loaded automatically. | ||
;Syntax Analysis | ;Syntax Analysis | ||
− | The places within the Bela core code that | + | The places within the Bela core code that required intervention are: |
− | # in the Makefile, update the workflow to build the PRU code for remoteproc | + | # in the Makefile, update the workflow to build the PRU code for remoteproc. Also implemented auto-detection of which processor the code was being compiled on which was passed on at compilation to the codes. |
# in core/PRU.cpp, use remoteproc instead of the libprussdrv API | # in core/PRU.cpp, use remoteproc instead of the libprussdrv API | ||
# in pru/pru_rtaudio.p, the hardcoded McASP constants should be replaced with board-dependent ones. | # in pru/pru_rtaudio.p, the hardcoded McASP constants should be replaced with board-dependent ones. |
Revision as of 03:07, 3 August 2021
Contents
Proposal-Bela support for BBAI
Youtube Video
About
Student: Dhruva Gole
Mentors: Giulio Moro, Stephen Arnold and Robert Manzke
Code: My Fork of Bela and Official Bela Code Repository
Wiki: https://forum.beagleboard.org/t/bela-support-for-bbai-later-ti-chips/29257/7
GSoC: GSoC entry
Status
This project proposal has been accepted as part of GSoC 2021.
Aim
This project proposes to provide restructuring and improvement of existing Bela Software Code to allow for compatibility and easier transition to newer Texas Instrument Sitara Processors (like the AM5729 in the BeagleBone AI).
About Student
College ID: 181030017
Github: https://github.com/DhruvaG2000
School: Veermata Jijabai Technological Inst.
Country: India
Primary language : English, Marathi, Hindi
Typical work hours: 10AM - 7PM Indian Standard Time
About the project
Project name: Bela support for the BeagleBone AI
My Blog: My blog related to this project and my findings.
Logs : I maintain weekly progress updates here: https://dhruvag2000.github.io/Blog-GSoC21/logs/
Description
- What is Bela?
As given on the official website, Bela is a hardware and software system for creating beautiful interaction with sensors and sound. Bela consists of a Bela cape on top of a BeagleBone Black computer (uptil now).
Bela has a lot of analog and digital inputs and outputs for hooking up sensors and controlling other devices, and most importantly Bela has stereo audio i/o allowing you to interact with the world of sound.
Both Bela systems use the same Bela software. It uses a customized Debian distribution which - most notably - uses a Xenomai kernel instead of a stock kernel. Xenomai is co-kernel for Linux which allows to achieve hard real-time performance on Linux machines (http://xenomai.org/). It thus takes advantage of features of the BeagleBone computers and can achieve extremely fast audio and sensor processing times.
Although the proposal Title mentions support for AI, I will try to develop a standardized setup that allows an easy jump across all TI chips.
- Applications of Bela
Bela is ideal for creating anything interactive that uses sensors and sound. So far, Bela has been used to create:
- musical instruments and audio effects
- kinetic sculptures
- wearable devices
- interactive sound installations
and many more applications that are listed here
- Why add support for BBAI/newer TI chips?
The Beagle Black was launched over 7 years ago in 2013 and newer and better TI Sitara Processors have been launched ever since. It would be better to have a more standardized setup that allows an easier jump across TI chips. Soon, newer boards with different and more efficient chips like the AM5X and the TI C66x digital-signal-processor (DSP) cores in the BBAI are coming up that will need to be compatible with the Bela Software and Hardware.
- Programming languages and tools to be used
C, C++, PRU, dtb, GNU Make, ARM Assembly
Implementation Details
The Bela cape is normally used in combination with the TI AM3358 processor present on the BeagleBone Black. The hardware was partially working on the BBAI using only ALSA(Advanced Linux Sound Architecture*) and the SPI driver [1]. However, the Bela real-time code on ARM and PRU was not running on the BBAI yet.
Brief Summary:
- Created a device tree overlay using Cape Compatibility layer to port BB-BONE-AUDI which worked but had a few frequency issues on the BBAI. The Overlay I wrote has been accepted by BeagleBone maintainer Robert Nelson, and you can find it to here: https://github.com/beagleboard/BeagleBoard-DeviceTrees/pull/36
- Created a device tree overlay for the BELA Cape to work on the BBAI using the Cape Compatibility layer. It has been tested and is available on github: https://github.com/DhruvaG2000/BeagleBoard-DeviceTrees/blob/v4.19.x-ti-overlays/src/arm/overlays/BBAI-BELA-00A1.dts
- Adapted to the Bela PRU and ARM code and workflow to use the PRU using the Remote Processor Framework instead of the almost oudated UIO PRUSS.
- Updated the Bela code to use the McASP, GPIO and McSPI on the AM5729 SoC of the BBAI
- Install a Xenomai patched kernel and run the full Bela stack.
- I also ported a debugger for PRU called [ PRUDebug].
This project involved dealing with pinmuxing (using overlays), PRU assembly, C and C++ for Linux user space applications. Also studied the Technical Reference Manual for the Sitara family of SoCs. (AM5729 and the AM335x.
- What is RProc?
The remoteproc framework allows different platforms/architectures to control (power on, load firmware, power off) those remote processors while abstracting the hardware differences, so the entire driver doesn't need to be duplicated. In addition, this framework also adds rpmsg virtio devices for remote processors that supports this kind of communication. This way, platform-specific remoteproc drivers only need to provide a few low-level handlers Reference: https://www.kernel.org/doc/Documentation/remoteproc.txt
- What is a Device Tree Overlay?
Sometimes it is not convenient to describe an entire system with a
single FDT(Flattened Device Tree). For example, processor modules that are plugged into one or
more modules (a la the BeagleBone), or systems with an FPGA peripheral
that is programmed after the system is booted.
For these cases it is proposed to implement an overlay feature
so that the initial device tree data can be modified by userspace at
runtime by loading additional overlay FDTs that amend the original data. ([ ref.])
How is an overlay compiled?
dtc (Device Tree Compiler) - converts between the human editable device tree source "dts" format and the compact device tree blob "dtb" representation usable by the kernel or assembler source.
Once an overlay is compiled, it generates a .dtbo file which we can then use in the next stage.
How does one load a DT Overlay?
It's simple, just edit the file /boot/uEnv.txt and then edit the following lines:
enable_uboot_overlays=1
uboot_overlay_addr4=/lib/firmware/BBAI-AUDI-02-00A0.dtbo
and on the next boot, this new overlay should be loaded automatically.
- Syntax Analysis
The places within the Bela core code that required intervention are:
- in the Makefile, update the workflow to build the PRU code for remoteproc. Also implemented auto-detection of which processor the code was being compiled on which was passed on at compilation to the codes.
- in core/PRU.cpp, use remoteproc instead of the libprussdrv API
- in pru/pru_rtaudio.p, the hardcoded McASP constants should be replaced with board-dependent ones.
All these changes will be made so that the same code base can run on all supported boards (e.g.: BBAI, BBB) with build- or runtime- checks. To explain in short how I aim to establish a common code base for supporting all boards, I will start off by enumerating different boards once we detect which board it is. Then in the libraries, the constants (like pin numbers and their symlinks) will be set accordingly and the rest of the code base will become much easier to use without the need to hard code anything.
- PRU
- The current Bela core code uses pasm to build the PRU assembly pru/pru_rtaudio.p and uses libprussdrv, which binds to the uio_pruss kernel driver to load the firmware to the PRU and handle access to the PRU RAM. Both pasm and libprussdrv are now deprecated, replaced by the clpru toolchain and remoteproc driver respectively.
- The PRU firmware contains hardcoded values for the address of the McASP, McSPI and GPIO peripherals. These addresses will change for the BBAI, so these constants need to become conditional. ✓(yet to be tested, but base address for the McASP of the bbai has been updated)
- As the Bela PRU firmware is written in assembly for pasm, instead of rewriting or updating it in such a way that it will stop working on the current Bela images, we will use the workflow detailed below.
- Workflow for building the existing pasm PRU code with clpru
The workflow below works as a proof of concept, but needs further testing.
- Build the .p file as is with pasm with -V2 -b. This generates a .bin file that contains the assembled program
- I will be using the disassembler Giulio Moro put together hacking the one that was inside prudebug. (Find it here(built with gcc da.c -o prudis) . (Note: A disassembler is a computer program that translates machine language into assembly language)
- Process the bin through the disassembelr and make it ready to be included inside an __asm__ directive (i.e.: add quotes and prepend a space at the beginning of each line):
prudis file.bin | sed 's/^\(.*\)$/" \1\\n"/' > included_assembly.h
4. have the following in main.c:
void main() { __asm__ __volatile__ ( #include "included_assembly.h" ); }
5. build main.c with the regular clpru toolchain
6. I will also need to change these MCASP addresses in pru/pru_rtaudio.p :
#define MCASP0_BASE 0x48038000 #define MCASP1_BASE 0x4803C000
#define MCASP0_DATAPORT 0x46000000 #define MCASP1_DATAPORT 0x46400000
Additionally, I will need to compare the McASP and McSPI sections of the AM5729 and AM3358 manuals to verify that all the registers of the McASP and McSPI peripherals kept the same meaning and offsets between the two chips, or adjust the code accordingly.
- PINMUXING
I am yet to figure out pinmuxing to make sure the relevant pins are set to the correct function (they are NOT by default). I will see here https://elinux.org/BeagleBoard/GSoC/2020_Projects/Cape_Compatibility and/or ask on the BB slack about for the best way to go about it. I have so far created a basic AUDIO overlay (named BBAI-AUDI-02-00A0.dts) that has been merged into the beagleboard / BeagleBoard-DeviceTrees repository.
- PRU->ARM INTERRUPTS
Bela can work with a PRU->ARM interrupt, which is default these days, but requires an rtdm driver, which is another layer of complications. As an intermediate step to avoid further complications, I will try to run it without the PRU->ARM interrupt by adding BELA_USE_DEFINE=BELA_USE_POLL to my make command line. After building the Xenomai kernel, I will build the rtdm_ kernel and revert to using PRU->ARM interrupts.
- PRU transitioning from libprussdrv to rproc
The Remote Processor Framework (rproc) allows different platforms/architectures to control (power on, load firmware, power off) those remote processors while abstracting the hardware differences, so the entire driver doesn't need to be duplicated. I will need to change the initialization code in PRU.cpp that is currently relying on lib prussdrv and move to rproc . Not sure if rproc provides some functionalities to access the PRU's RAM the way prussdrv_map_prumem() used to, but that essentially gives access to a previously mmap'ed area of memory , so it should be easy to replace, as long as I am able to find the correct addresses in the TRM. On the latest Bela code there's a Mmap class which can make this somehow simpler ref. here.
- XENOMAI kernel
Xenomai kernel (v4.19.94-ti-xenomai-r64) has been built and tested for the BBAI. I have installed the xenomai kernel and libraries through the default procedure to update kernel. I have also managed to successfully build the entire Bela core code on the BBAI so far.
- Hardware required
The hardware listed below will be necessary for testing if my code implementation works correctly on the hardware.
- BeagleBone AI.
- Bela cape: The original Bela board.
Timeline
Mar 29 | Applications open | Students register with GSoC, work on proposal with mentors. |
Apr 13 | Proposal complete | Submitted to https://summerofcode.withgoogle.com ✓ |
May 17 | Proposal accepted or rejected |
|
Jun 07 | Pre-work complete, Coding officially begins! |
(some points above are ref. from here ) |
Jun 17 | Milestone #1, |
|
June 24 | Milestone #2 |
|
June 30 | Milestone #3 |
|
July 12 18:00 UTC | Milestone #4 |
Mentors and students can begin submitting Phase 1 evaluations |
July 16 18:00 UTC | Phase 1 Evaluation deadline | |
July 23 | Milestone #5 |
|
July 30 | Milestone #6 |
|
Aug 06 | Milestone #7 |
|
August 10 | Milestone #8 |
|
August 16 - 26 18:00 UTC | Final week: Students submit their final work product and their final mentor evaluation | |
August 23 - 30 18:00 UTC | Mentors submit final student evaluations |
Experience and approach
- I have used C++, C and Python programming languages over the past 3 years in a variety of projects involving embedded systems using the ESP32, Arduino UNO, ESP8266 and am also well-versed with freeRTOS.
- I have an aptitude for writing good reports and blogs, and have written a small blog on how to use a debugger.
- I recently did a project using ESP32, in which I used the DHT11 sensor to display humidity and temperature on a local HTML server . Other than that I have worked on developing hardware and making documentation for a 3 DOF arm based on an ESP32 custom board.
- I also interned at an embedded device startup where I
- Interfaced ADS1115 ADC with the ESP32 and used it to read battery voltage.
- Used UART for ESP32 and SIMCOM SIM 7600IE communication to gain LTE support.
- Published local sensor data to the cloud via LTE.
- I actively contribute to open source (most recently, I contributed to the ADS1115 library for ESP32 on the unclerus repo and can be seen here).
- Currently I am working on designing a Development board for the Raspberry Pico (RP2040) using KiCAD.
- I also do a lot of mini projects throughout the year, you can find my several more interesting projects at my github page
Contingency
I believe that if I get stuck on my project and my mentor isn’t around, I will use the resources that are available to me. Some of those information portals are listed below.
- Derek Molloy's beagle bone guide provides all the information needed for getting up and running with my beagle.
- remoteproc
- BBAI vs BBB pin headers Google Sheet
- beaglebone pru gpio example
- official BELA website
- Ask on the BeagleBoard.org forum
Benefit
If successfully completed, this project will add support for the Bela cape + Xenomai + PRU on the BeagleBone AI, and also the code will be easier to port to other Texas Instruments systems-on-chip.
By going through the steps needed to have the Bela environment running on BBAI, we will go through refactoring and rationalisation, using mainline drivers and APIs where possible. This will make Bela easier to maintain and to port to new platforms, benefiting the project's longevity and allowing it to expand its user base.
-Giulio Moro
Misc
Completed all the requirements listed on the ideas page.
The code for the cross-compilation task can be found here submitted through pull request #149.