By Adam Taylor
We have now built a basic Zynq UltraScale+ MPSoC hardware design for the UltraZed board in Vivado that got us up and running. We’ve also started to develop software for the cores within the Zynq UltraScale+ MPSoC’s PS (processor system). The logical next step is to generate a simple “hello world” program, which is exactly what we are going to do for one of the cores in the Zynq UltraScale+ MPSoC’s APU (Application Processing Unit).
As with the Zynq Z-7000 SoC, we need three elements to create a simple bare-metal program for the Zynq UltraScale+ MPSoC:
- Hardware Platform Definition – This defines the underlying hardware platform configuration, address spaces, and IP modules within the design.
- Board Support Package – This uses the hardware platform to create a hardware abstraction layer (HAL) that provides the necessary drivers for the IP within the system. We need those drivers to use these hardware resources in an application.
- Application – This is the application we will be writing. In this case it will be a simple “hello world” program.
To create a new hardware platform definition, select:
File-> New -> Other -> Xilinx – Hardware Platform Specification
Provide a project name and select the hardware definition file, which was exported from Vivado. You can find the exported file within the SDK directory if you exported it local to the project.
Creating the Hardware platform
Once the hardware platform has been created within SDK, you will see the hardware definition file opens within the file viewer. Browsing through this file, you will see the address ranges of the Zynq UltraScale+ MPSoC’s ARM Cotex-A53 and Cortex-R5 processors and PMU (Performance Monitor Unit) cores within the design. A list of all IP within the processors’ address space appears at the very bottom of the file.
Hardware Platform Specification in SDK file browser
We then use the information provided within the hardware platform to create a BSP for our application. We create a new application by selecting:
File -> New -> Board Support Package
Within the create BSP dialog, we can select the processor this BSP will support, the compiler to be used, and the selected OS, In this case, we’ll use bare metal or FreeRTOS.
For this first example, we will be running the “hello world” program from the APU on processor core 0. We must be sure to target the same core as we create the BSP and application if everything is to function correctly.
Board Support Package Generation
With the BSP created, the next step is to create the application using this BSP. We can create the application in a similar manner to the BSP and hardware platform:
File -> New -> Application Project
This command opens a dialog that allows us to name the project, select the BSP, specify the processor core, and select operating system. On the first tab of the dialog, configure these settings for APU core 0, bare metal, and the BSP just created. On the second tab of the dialog box, select the pre-existing “hello world” application.
Configuring the application
Selecting the Hello World Application
At this point, we have the application ready to run on the UltraZed dev board. We can run the application using either the debugger within SDK or we can boot the device from a non-volatile memory such as an SD card.
To boot from an SD Card, we need to first create a first-stage boot loader (FSBL). To do this, we follow the same process as we do when creating a new application. The FSBL will be based on the current hardware platform but it will have its own BSP with several specific libraries enabled.
Select File -> New -> Application Project
Enter a project name and select the core and OS to support the current build as previously done for the “hello world” application. Click the “Create New” radio button for the BSP and then on the next page, select the Zynq MP FSBL template.
Configuring the FSBL application
Selecting the FSBL template
With the FSBL created, we now need to build all our applications to create the required ELF files for the FSBL and the application. If SDK is set to build automatically, these files will have been created following the creation of the FSBL. If not, then select:
Project -> Build All
Once this process completes, the final step is to create a boot file. The Zynq UltraScale+ MPSoC boots from a file named boot.bin, created by SDK. This file contains the FSBL, FPGA programming file, and the applications. We can create this file by hand and indeed later in this series we will be doing so to examine the more advanced options. However, for the time being we can create a boot.bin by right-clicking on the “hello world” application and selecting the “Create Boot Image” option.
Creating the boot image from the file, from the hello world application
This will populate the “create boot image” dialog correctly with the FSBL, FPGA bit file, and our application—provided the elf files are available.
Boot Image Creation Dialog correctly populated
Once the boot file is created, copy the boot.bin onto a microSD card and insert it into the SD card holder on the UltraZed IOCC (I/O Carrier Card). The final step, before we apply power, is to set SW2 on the UltraZed card to boot from the SD Card. The setting for this is 1 = ON, 2 = OFF, 3 = ON, and 4 = OFF. Now switch on the power on, connect to a terminal window, and you will see the program start and execute.
When I booted this on my UltraZed and IOCC combination, the following appeared in my terminal window:
Hello World Running
Next week we will look a little more at the architecture of the Zynq UltraScale+ MPSoC’s PS.
Code is available on Github as always.
If you want E book or hardback versions of previous MicroZed chronicle blogs, you can get them below.
via Xcell Daily Blog articles http://ift.tt/2fBJIws
February 16, 2017 at 08:25PM