NXP X-S32Z27X-DC (DC2)

Overview

The X-S32Z27X-DC (DC2) board is based on the NXP S32Z2 Real-Time Processor, which includes two Real-Time Units (RTU) composed of four ARM Cortex-R52 cores each, with flexible split/lock configurations.

There is one Zephyr board per SoC/RTU:

  • s32z2xxdc2/s32z270/rtu0, for S32Z270/RTU0

  • s32z2xxdc2/s32z270/rtu1, for S32Z270/RTU1.

Hardware

Information about the hardware and design resources can be found at NXP S32Z2 Real-Time Processors website [1].

Supported Features

The boards support the following hardware features:

Interface

Controller

Driver/Component

Arm GIC

on-chip

interrupt_controller

Arm Timer

on-chip

timer

LINFlexD

on-chip

serial

MRU

on-chip

mbox

NETC

on-chip

ethernet

mdio

SIUL2

on-chip

pinctrl

gpio

external interrupt controller

SPI

on-chip

spi

SWT

on-chip

watchdog

CANEXCEL

on-chip

can

FLEXCAN

on-chip

can

SAR_ADC

on-chip

adc

LPI2C

on-chip

i2c

Other hardware features are not currently supported by the port.

Connections and IOs

The SoC’s pads are grouped into ports and pins for consistency with GPIO driver and the HAL drivers used by this Zephyr port. The following table summarizes the mapping between pads and ports/pins. This must be taken into account when using GPIO driver or configuring the pinmuxing for the device drivers.

Pads

Port/Pins

PAD_000 - PAD_015

PA0 - PA15

PAD_016 - PAD_030

PB0 - PB14

PAD_031

PC15

PAD_032 - PAD_047

PD0 - PD15

PAD_048 - PAD_063

PE0 - PE15

PAD_064 - PAD_079

PF0 - PF15

PAD_080 - PAD_091

PG0 - PG11

PAD_092 - PAD_095

PH12 - PH15

PAD_096 - PAD_111

PI0 - PI15

PAD_112 - PAD_127

PJ0 - PJ15

PAD_128 - PAD_143

PK0 - PK15

PAD_144 - PAD_145

PL0 - PL1

PAD_146 - PAD_159

PM2 - PM15

PAD_160 - PAD_169

PN0 - PN9

PAD_170 - PAD_173

PO10 - PO13

This board does not include user LED’s or switches, which are needed for some of the samples such as Blinky or Button. Follow the steps described in the sample description to enable support for this board.

System Clock

The Cortex-R52 cores are configured to run at 1 GHz.

Serial Port

The SoC has 12 LINFlexD instances that can be used in UART mode. The console can be accessed by default on the USB micro-B connector J119.

Watchdog

The watchdog driver only supports triggering an interrupt upon timer expiration. Zephyr is currently running from SRAM on this board, thus system reset is not supported.

Ethernet

NETC driver supports to manage the Physical Station Interface (PSI0) and/or a single Virtual SI (VSI). The rest of the VSI’s shall be assigned to different cores of the system. Refer to S32 Network Controller (NETC) to learn how to configure the Ethernet network controller.

Controller Area Network

CANEXCEL

CANEXCEL supports CAN Classic (CAN 2.0) and CAN FD modes. Remote transmission request is not supported.

Note that this board does not currently come with CAN transceivers installed for the CANEXCEL ports. To facilitate external traffic, you will need to add a CAN transceiver. Any transceiver pin-compatible with CAN 2.0 and CAN FD protocols can be used.

FlexCAN

FlexCAN supports CAN Classic (CAN 2.0) and CAN FD modes.

ADC

ADC is provided through ADC SAR controller with 2 instances. Each ADC SAR instance has 12-bit resolution. ADC channels are divided into 2 groups (precision and internal/standard).

Note

All channels of an instance only run on 1 group channel at the same time.

Programming and Debugging

Applications for the s32z2xxdc2 boards can be built in the usual way as documented in Building an Application.

Currently is only possible to load and execute a Zephyr application binary on this board from the core internal SRAM.

This board supports West runners for the following debug tools:

Follow the installation steps of the debug tool you plan to use before loading your firmware.

Set-up the Board

Connect the external debugger probe to the board’s JTAG connector (J134) and to the host computer via USB or Ethernet, as supported by the probe.

For visualizing the serial output, connect the board’s USB/UART port (J119) to the host computer and run your favorite terminal program to listen for output. For example, using the cross-platform pySerial miniterm [2] terminal:

python -m serial.tools.miniterm <port> 115200

Replace <port> with the port where the board can be found. For example, under Linux, /dev/ttyUSB0.

Debugging

You can build and debug the Hello World sample for the board s32z2xxdc2/s32z270/rtu0 with:

# From the root of the zephyr repository
west build -b s32z2xxdc2/s32z270/rtu0 samples/hello_world
west debug

In case you are using a newer PCB revision, you have to use an adapted board definition as the default PCB revision is B. For example, if using revision D:

west build -b s32z2xxdc2@D/s32z270/rtu0 samples/hello_world
west debug

At this point you can do your normal debug session. Set breakpoints and then c to continue into the program. You should see the following message in the terminal:

Hello World! s32z2xxdc2

To debug with Lauterbach TRACE32 softare run instead:

west build -b s32z2xxdc2/s32z270/rtu0 samples/hello_world
west debug
west build -t -r
west build -t trace32

Flashing

Follow these steps if you just want to download the application to the board SRAM and run.

flash command is supported only by the Lauterbach TRACE32 runner:

west build -b s32z2xxdc2/s32z270/rtu0 samples/hello_world
west flash
west build -t -r
west build -t trace32

Note

Currently, the Lauterbach start-up scripts executed with flash and debug commands perform the same steps to initialize the SoC and load the application to SRAM. The difference is that flash hides the Lauterbach TRACE32 interface, executes the application and exits.

To imitate a similar behavior using NXP S32 Debug Probe runner, you can run the debug command with GDB in batch mode:

west build -b s32z2xxdc2/s32z270/rtu0 samples/hello_world
west debug
west build -t --tool-opt='--batch'

RTU and Core Configuration

This Zephyr port can only run single core in any of the Cortex-R52 cores, either in lock-step or split-lock mode. By default, Zephyr runs on the first core of the RTU chosen and in lock-step mode (which is the reset configuration).

To build for split-lock mode, the CONFIG_DCLS must be disabled from your application Kconfig file.

By default the board configuration will set the runner arguments according to the build configuration. To debug for a core different than the default use:

west debug --core-name='R52_<rtu_id>_<core_id>_LS'

Where:

  • <rtu_id> is the zero-based RTU index

  • <core_id> is the zero-based core index relative to the RTU on which to run the Zephyr application (0, 1, 2 or 3)

For example, to build the Hello World sample for the board s32z2xxdc2/s32z270/rtu0 with split-lock core configuration:

west build -b s32z2xxdc2/s32z270/rtu0 samples/hello_world -- -DCONFIG_DCLS=n

To execute this sample in the second core of RTU0 in split-lock mode:

west debug --core-name='R52_0_1'

If using Lauterbach TRACE32, all runner parameters must be overridden from command line:

west debug --startup-args elfFile=<elf_path> rtu=<rtu_id> core=<core_id> lockstep=<yes/no>

Where <elf_path> is the path to the Zephyr application ELF in the output directory.

References