Difference between revisions of "BELK-AN-001: Asymmetric Multiprocessing (AMP) on Bora – Linux FreeRTOS"

Info Box Applies to Bora Applies to BORA Xpress

History[edit | edit source]

Introduction[edit | edit source]

This application note describes how to build the software components required to set up asymmetric multi-processing (AMP for short) configuration required to run Linux OS on first Cortex-A9 core and FreeRTOS on second Cortex-A9 core of the Zynq SOC.

Asymmetric Multiprocessing (AMP) allows a multiprocessor/multicore system to run multiple Operating Systems (OS) that are independent of each other. In other words, each CPU has its own private memory space, which contains the OS and the applications that are to run on that CPU. In addition, there can be some shared memory space that is used for multiprocessor communication. This is contrasted with Symmetric Multiprocessing (SMP), in which one OS runs on multiple CPUs using a public shared memory space. Thanks to AMP, developers can use open-source Linux and FreeRTOS operating systems and the RPMsg Inter Processor Communication (IPC) framework between the Zynq's two high-performance ARM® Cortex™-A9 processors to quickly implement applications that need to deliver deterministic, real-time responsiveness for markets such as automotive, industrial and others with similar requirements. For further information, please refer to this link.

Two different examples are here provided. The first one – HelloWorld – shows basic functionalities while the second – RPMsg-based application – exploits more sophisticated techniques to handle inter-processors communication and synchronization. This latter configuration is based on RPMsg mechanism as described in Xilinx document UG978 (v2013.04, April 22, 2013).

PDF version of this Application Note can be downloaded here.

AMP on Bora[edit | edit source]

The following sections detail how to build the software components required to set up asymmetric multi-processing (AMP for short) configuration required to run Linux OS on first Cortex-A9 core and FreeRTOS on second Cortex-A9 core. The prerequisites are:

• Vivado® Design Suite version 2013.3 with Xilinx SDK (Webpack license is minimum requirements)
• Python 2.7.x (C:\Python27 must be the installation directory on Windows)
• Bora Embedded Linux Kit (Please refer to BELK Quick Start Guide for further details) version 2.0.0.
• BORA FreeRTOS repository (please refer to section TBD)

Building the software components[edit | edit source]

Vivado project[edit | edit source]

• log into the development host
• Assuming that a local repository has not been created, clone the remote Bora git repository (the -b option is used to automatically checkout the current branch):

git clone git@git.dave.eu:dave/bora/bora.git -b bora

• Enter the git directory
• Switch to bora branch (not required if this is already the current branch):

git checkout bora

Set project directory variable:

export PROJ_DIR=$(pwd)/../bora-build-YYYYMMDD-nobk

Configure Vivado settings (1):

. /opt/Xilinx/Vivado/2013.3/settings64.sh

Launch Vivado with build_project script (2):

vivado -mode tcl -source build_project.tcl -notrace -tclargs "-bitstream"

(1) In a 32 bit system, Vivado settings are configured with the following command /opt/Xilinx/Vivado/2013.3/settings32.sh

(2) Passing the -tclargs "-bitstream" parameters allows for automatic building of the FPGA bitstream.

FSBL[edit | edit source]

Once the Vivado project build is completed, the hardware configuration can be exported starting the SDK to build the FSBL. From the SDK GUI:

• Create a new application project, as shown in the picture below:

• Configure the application settings as shown in the pictures below:

• Click finish to launch FSBL build process
• Create the binary from the FSBL ELF chosing one of the following options:
  • manually launch the command: arm-xilinx-eabi-objcopy -v -O binary $PROJ_DIR/bora.sdk/SDK/SDK_Export/bora_FSBL/Debug/bora_FSBL.elf $PROJ_DIR/bora.sdk/SDK/SDK_Export/bora_FSBL/Debug/bora_FSBL.bin
  • configure the automatic binary generation on project build. In Project Explorer, right-click on bora_FSBL project and select C/C++ Build Settings and add the command arm-xilinx-eabi-objcopy -v -O binary ${ProjName}.elf ${ProjName}.bin on Post-build steps

N.B. When the Vivado project is modified, the binary must be re-generated with the following command:

python fpga-bit-to-bin.py --flip $PROJ_DIR/bora.runs/bora_run_impl/bora_design_wrapper.bit $PROJ_DIR/bora.runs/bora_run_impl/bora_design_wrapper.bin

FreeRTOS applications[edit | edit source]

The following sections describe the steps required to configure and build both the Helloworld and the RPMsg-based examples.

Importing the FreeRTOS repository into the SDK[edit | edit source]

• Assuming that a local repository has not been created, clone the remote freeRTOS git repository:

git clone git@git.dave.eu:dave/bora/freertos.git

• Enter the git directory
• Switch to freertos-AMP branch:

git checkout freertos-AMP

• In SDK gui import new repository: Xilinx Tools->Repositories

• Click New... to add a new repository under Local or Global Repositories, and select the freeRTOS repository directory:

• Click Rescan Repositories , Apply and OK
• At the end of the procedure, applications based on freeRTOS operating system can be built

Building Example #1: HelloWorld application[edit | edit source]

The first example shows basic AMP functionalities. On FreeRTOS side, UART0 is used to implement a simple console. This port is routed via EMIO signals to pin-strip connector of BoraEVB. Since these signals are driven by FPGA Bank #34, these pins are 3.3V. Thus a RS232 transceiver or an USB/UART bridge should be used in order to connect the console on a PC. The signals are routed to the JP17 connector of the BoraEVB as reported below:

• JP17.4 – UART0_TX
• JP17.6 – UART0_RX

Please follow the steps listed below to build a HelloWorld application that prints a message on UART0 (via EMIO) on FreeRTOS running on Bora core #2.

• From the SDK GUI, create e new application project:

• Configure the application settings as shown in the pictures and table below:

• • Project name: helloworld_freeRTOS
  • Hardware Platform: hw_platform_0
  • Processor: ps7_cortexa9_1
  • OS Plaftorm: freertos_zynq
  • Language: C
  • Board Support Package: Create New
  • Type: FreeRTOS Hello World AMP template
• Click finish to launch the application build process
• Create the binary from the application ELF chosing one of the following options:
  • manually launch the command: arm-xilinx-eabi-objcopy -v -O binary $PROJ_DIR/bora.sdk/SDK/SDK_Export/hellowordl_freeRTOS/Debug/hellowordl_freeRTOS.elf $PROJ_DIR/bora.sdk/SDK/SDK_Export/hellowordl_freeRTOS/Debug/hellowordl_freeRTOS.bin
  • configure the automatic binary generation on project build. In Project Explorer, right-click on helloworld_freeRTOS project and select C/C++ Build Settings and add the command arm-xilinx-eabi-objcopy -v -O binary ${ProjName}.elf ${ProjName}.bin on Post-build steps.

Building Example #2: RPMsg-based application[edit | edit source]

The procedure needed to build this application is similar to the one used to build HelloWorld application. The only difference is that the FreeRTOS Latency AMP template must be selected. In this case please note that:

• the standard Linux infrastructure will be used to load the firmware for the second core
• Linux will start in SMP mode, running on both cores; then CPU1 will be shutdown and FreeRTOS firmware will be loaded and run.

This example application exploits TTC1 timer to measure IRQ latencies as described in Xilinx UG978. In addition to that, GPIO0 (pin JP21.16 on BoraEVB) will be toggled every time ISR is invoked.

Once the build process is completed, the executable file in .elf format will be generated (we suggest to name it freertos). Creating the .bin file is not required.

• Project name: RPMsg_freeRTOS
• Hardware Platform: hw_platform_0
• Processor: ps7_cortexa9_1
• OS Plaftorm: freertos_zynq
• Language: C
• Board Support Package: Create New
• Type: FreeRTOS Latency AMP

To run this example, Linux kernel (1) must be rebuilt too (2). First of all copy the freertos executable file in .elf format (freertos) into the directory firmware of Linux kernel tree (3). Then configure the kernel using bora_amp_defconfig as configuration file and enter the following command line, that changes the default load address of kernel and launches the building of both the kernel image and the modules:

bash# make UIMAGE_LOADADDR=0x10008000 uImage modules
[...]
  OBJCOPY arch/arm/boot/zImage
  Kernel: arch/arm/boot/zImage is ready
  UIMAGE  arch/arm/boot/uImage
Image Name:   Linux-3.9.0-bora-1.1.0-xilinx-00
Created:      Thu Nov 21 15:55:07 2013
Image Type:   ARM Linux Kernel Image (uncompressed)
Data Size:    3217192 Bytes = 3141.79 kB = 3.07 MB
Load Address: 10008000
Entry Point:  10008000
  Image arch/arm/boot/uImage is ready

The file arch/arm/boot/uImage is the binary image of the kernel that must be used to boot the system. The following kernel modules, resulting from the kernel build procedure, must be copied from the building directory to the root file system (usually into /lib/modules/<kernel version>/kernel, but any other directory can be used):

  LD [M]  drivers/remoteproc/remoteproc.ko
  LD [M]  drivers/remoteproc/zynq_remoteproc.ko
  LD [M]  drivers/rpmsg/rpmsg_freertos_statistic.ko
  LD [M]  drivers/rpmsg/virtio_rpmsg_bus.ko
  LD [M]  drivers/virtio/virtio.ko
  LD [M]  drivers/virtio/virtio_ring.ko
  LD [M]  net/rpmsg/rpmsg_proto.ko

For further details on kernel modules, please refer to this link.

(1) The kernel branch must be bora.

(2) It is assumed that the development environment is already set up as described in BELK Quick Start Guide.

(3) The name of the binary file copied into the firmware directory must be freertos.

Linux Device Tree[edit | edit source]

The Flattened Device Tree (FDT) is a data structure for describing the hardware in a system (for further information, please refer to http://elinux.org/Device_Tree). Both Example #1 and Example #2 requires some modifications to the standard Bora device tree (to initialiaze UART0 port and to properly initialize the RPMsg infrastructure, respectively). Please use the kernel branch bora, that already includes the aforementioned patches (for further details, please refer to the arch/arm/boot/dts/bora.dts file and commit descriptions on the Linux git repository). For detailed instructions on how to build the Linux kernel and the Device Tree, please refer to the BELK Quick Start Guide TBD.

Running the demo applications[edit | edit source]

Additional resources[edit | edit source]

• http://www.wiki.xilinx.com/Multi-OS+Support+%28AMP+%26+Hypervisor%29
• http://www.xilinx.com/support/documentation/sw_manuals/petalinux2013_04/ug978-petalinux-zynq-amp.pdf