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i.MX93 EVK

Overview

The i.MX93 Evaluation Kit (MCIMX93-EVK board) is a platform designed to show the most commonly used features of the i.MX 93 Applications Processor in a small and low cost package. The MCIMX93-EVK board is an entry-level development board, which helps developers to get familiar with the processor before investing a large amount of resources in more specific designs.

i.MX93 MPU is composed of one cluster of 2x Cortex-A55 cores and a single Cortex®-M33 core. Zephyr OS is ported to run on one of the Cortex®-A55 core.

  • Board features:

    • RAM: 2GB LPDDR4

    • Storage:

      • SanDisk 16GB eMMC5.1

      • microSD Socket

    • Wireless:

      • Murata Type-2EL (SDIO+UART+SPI) module. It is based on NXP IW612 SoC, which supports dual-band (2.4 GHz /5 GHz) 1x1 Wi-Fi 6, Bluetooth 5.2, and 802.15.4

    • USB:

      • Two USB 2.0 Type C connectors

    • Ethernet

    • PCI-E M.2

    • Connectors:

      • 40-Pin Dual Row Header

    • LEDs:

      • 1x Power status LED

      • 2x UART LED

    • Debug

      • JTAG 20-pin connector

      • MicroUSB for UART debug, two COM ports for A55 and M33

Supported Features

The Zephyr mimx93_evk board Cortex-A Core configuration supports the following hardware features:

Interface

Controller

Driver/Component

GIC-v4

on-chip

interrupt controller

ARM TIMER

on-chip

system clock

CLOCK

on-chip

clock_control

PINMUX

on-chip

pinmux

UART

on-chip

serial port

GPIO

on-chip

GPIO

I2C

on-chip

i2c

SPI

on-chip

spi

CAN

on-chip

can

TPM

on-chip

TPM Counter

ENET

on-chip

ethernet port

The Zephyr imx93_evk board Cortex-M33 configuration supports the following hardware features:

Interface

Controller

Driver/Component

NVIC

on-chip

interrupt controller

SYSTICK

on-chip

systick

CLOCK

on-chip

clock_control

PINMUX

on-chip

pinmux

UART

on-chip

serial port

GPIO

on-chip

GPIO

Devices

System Clock

This board configuration uses a system clock frequency of 24 MHz. Cortex-A55 Core runs up to 1.7 GHz. Cortex-M33 Core runs up to 200MHz in which SYSTICK runs on same frequency.

Serial Port

This board configuration uses a single serial communication channel with the CPU’s UART2 for A55 core and M33 core.

Board MUX Control

This board configuration uses a series of digital multiplexers to switch between different board functions. The multiplexers are controlled by a GPIO signal called EXP_SEL from onboard GPIO expander ADP5585. It can be configured to select function set “A” or “B” by dts configuration if board control module is enabled. The following dts node is defined:

board_exp_sel: board-exp-sel {
    compatible = "imx93evk-exp-sel";
    mux-gpios = <&gpio_exp0 4 GPIO_ACTIVE_HIGH>;
    mux = "A";
};

Following steps are required to configure the EXP_SEL signal:

  1. Enable Kconfig option CONFIG_BOARD_MIMX93_EVK_EXP_SEL_INIT.

  2. Select mux="A"; or mux="B"; in &board_exp_sel devicetree node.

Kconfig option CONFIG_BOARD_MIMX93_EVK_EXP_SEL_INIT is enabled if a board function that requires configuring the mux is enabled. The MUX option is automatically selected if certain board function is enabled, and takes precedence over dts config. For instance, if CONFIG_CAN is enabled, MUX A is selected even if mux="B"; is configured in dts, and an warning would be reported in the log.

User Button GPIO Option

The user buttons RFU_BTN1 and RFU_BTN2 is connected to i.MX 93 GPIO by default, but can be changed to connect to onboard GPIO expander PCAL6524 with on-board DIP switches. To do this, switch SW1006 to 0000, then switch SW1005 to 0101. An devicetree overlay is included to support this.

Run following command to test user buttons on PCAL6524:

# From the root of the zephyr repository
west build -b imx93_evk/mimx9352/a55 samples/basic/button -- -DEXTRA_DTC_OVERLAY_FILE=imx93_evk_mimx9352_exp_btn.overlay

Run the app, press RFU_BTN1 and the red LED turns on accordingly.

Note: The overlay only supports mimx9352/a55, but can be extended to support mimx9352/m33 if I2C and PCAL6524 is enabled.

Programming and Debugging (A55)

U-Boot “cpu” command is used to load and kick Zephyr to Cortex-A secondary Core, Currently it is supported in : Real-Time Edge U-Boot (use the branch “uboot_vxxxx.xx-y.y.y, xxxx.xx is uboot version and y.y.y is Real-Time Edge Software version, for example “uboot_v2023.04-2.9.0” branch is U-Boot v2023.04 used in Real-Time Edge Software release v2.9.0), and pre-build images and user guide can be found at Real-Time Edge Software.

Copy the compiled zephyr.bin to the first FAT partition of the SD card and plug the SD card into the board. Power it up and stop the u-boot execution at prompt.

Use U-Boot to load and kick zephyr.bin to Cortex-A55 Core1:

fatload mmc 1:1 0xd0000000 zephyr.bin; dcache flush; icache flush; cpu 1 release 0xd0000000

Or use the following command to kick zephyr.bin to Cortex-A55 Core0:

fatload mmc 1:1 0xd0000000 zephyr.bin; dcache flush; icache flush; go 0xd0000000

Use this configuration to run basic Zephyr applications and kernel tests, for example, with the Basic Synchronization sample:

# From the root of the zephyr repository
west build -b imx93_evk/mimx9352/a55 samples/synchronization

This will build an image with the synchronization sample app, boot it and display the following console output:

*** Booting Zephyr OS build Booting Zephyr OS build v3.7.0-2055-g630f27a5a867  ***
thread_a: Hello World from cpu 0 on imx93_evk!
thread_b: Hello World from cpu 0 on imx93_evk!
thread_a: Hello World from cpu 0 on imx93_evk!
thread_b: Hello World from cpu 0 on imx93_evk!

System Reboot (A55)

Currently i.MX93 only support cold reboot and doesn’t support warm reboot. Use this configuratiuon to verify cold reboot with Custom Shell module sample:

# From the root of the zephyr repository
west build -b imx93_evk/mimx9352/a55 samples/subsys/shell/shell_module

This will build an image with the shell sample app, boot it and execute kernel reboot command in shell command line:

uart:~$ kernel reboot cold

Programming and Debugging (M33)

Copy the compiled zephyr.bin to the first FAT partition of the SD card and plug the SD card into the board. Power it up and stop the u-boot execution at prompt.

Use U-Boot to load and kick zephyr.bin to Cortex-M33 Core:

load mmc 1:1 0x80000000 zephyr.bin;cp.b 0x80000000 0x201e0000 0x30000;bootaux 0x1ffe0000 0

Use this configuration to run basic Zephyr applications and kernel tests, for example, with the Basic Synchronization sample:

# From the root of the zephyr repository
west build -b imx93_evk/mimx9352/m33 samples/synchronization
west build -t run

This will build an image with the synchronization sample app, boot it and display the following console output:

*** Booting Zephyr OS build v3.7.0-684-g71a7d05ba60a ***
thread_a: Hello World from cpu 0 on imx93_evk!
thread_b: Hello World from cpu 0 on imx93_evk!
thread_a: Hello World from cpu 0 on imx93_evk!
thread_b: Hello World from cpu 0 on imx93_evk!

To make a container image flash.bin with zephyr.bin for SD/eMMC programming and booting from BootROM. Refer to user manual of i.MX93 MCUX SDK release.

References

More information can refer to NXP official website: NXP website.

Using the SOF-specific variant

Purpose

Since this board doesn’t have a DSP, an alternative for people who might be interested in running SOF on this board had to be found. The alternative consists of running SOF on an A55 core using Jailhouse as a way to “take away” one A55 core from Linux and assign it to Zephyr with SOF.

What is Jailhouse?

Jailhouse is a light-weight hypervisor that allows the partitioning of hardware resources. For more details on how this is done and, generally, about Jailhouse, please see: 1, 2 and 3. The GitHub repo can be found here.

How does it work?

Firstly, we need to explain a few Jailhouse concepts that will be referred to later on:

  • Cell: refers to a set of hardware resources that the OS assigned to this cell can utilize.

  • Root cell: refers to the cell in which Linux is running. This is the main cell which will contain all the hardware resources that Linux will utilize and will be used to assign resources to the inmates. The inmates CANNOT use resources such as the CPU that haven’t been assigned to the root cell.

  • Inmate: refers to any other OS that runs alongside Linux. The resources an inmate will use are taken from the root cell (the cell Linux is running in).

SOF+Zephyr will run as an inmate, alongside Linux, on core 1 of the board. This means that said core will be taken away from Linux and will only be utilized by Zephyr.

The hypervisor restricts inmate’s/root’s access to certain hardware resources using the second-stage translation table which is based on the memory regions described in the configuration files. Please consider the following scenario:

Root cell wants to use the UART which let’s say has its registers mapped in the [0x0 - 0x42000000] region. If the inmate wants to use the same UART for some reason then we’d need to also add this region to inmate’s configuration file and add the JAILHOUSE_MEM_ROOTSHARED flag. This flag means that the inmate is allowed to share this region with the root. If this region is not set in the inmate’s configuration file and Zephyr (running as an inmate here) tries to access this region this will result in a second stage translation fault.

Notes:

  • Linux and Zephyr are not aware that they are running alongside each other. They will only be aware of the cores they have been assigned through the config files (there’s a config file for the root and one for each inmate).

Architecture overview

The architecture overview can be found at this location. (latest status update as of now and the only one containing diagrams).

How to use this board?

This board has been designed for SOF so it’s only intended to be used with SOF.

TODO: document the SOF build process for this board. For now, the support for i.MX93 is still in review and has yet to merged on SOF side.