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Gateworks Newport Family Support
Getting Started |
Newport Software |
Peripherals |
User Manuals |
Wireless / WiFi Radios |
Cellular Modems |
GPS |
3D Model |
The Gateworks Newport product family utilizes the Cavium ARM ThunderX CN80xx / CN81xx SoC (System On Chip) offering a large variety of peripherals with a focus on Networking, and Security. See here for a product comparison matrix.
Links
Please note: This is a subset of information for Newport, however, please visit our Main Wiki for all other information
Software
- Source code for Newport including keeping abreast of changes
- Firmware Images
- Firmware (up to and including the Bootloader)
- U-Boot Bootloader
- Newport Board Support Packages and Operating Systems
- Linux kernel support
- Booting Third Party Linux Distro's on Newport
- Newport JTAG Programming
Peripheral Support
- Gateworks Expansion Modules - GW16081, GW16082, GW16083
- SPI Support
- I2C Support
- GPIO Control
- LED Control
- Connector and Cable Information
- mSATA Information
- GPS Support
- CAN Bus Support
- PCI/PCIe information
- PCIe Accessory Cards
- MultiMediaCard (microSD/eMMC) Information
- Gateworks System Controller (GSC) - Temperature, voltage, RTC, GPIO, Digital IO, I/O, pushbutton, etc
- Gateworks Enclosures
Performance / Processor / Memory / Power / Thermal
Other Info
User Manual
Processor Reference Manual / Datasheet / Errata
The Cavium Website contains details about the OCTEON TX Dual and Quad core 64bit ARM based SoC's.
Additional references:
Source Code
Newport Source code for firmware, bootloader and kernel are hosted at GitHub. We highly recommend you create a GitHub account and 'Watch' these repositories to keep abreast of important feature additions, bugfixes, and firmware-releases. You can configure your GitHub account to e-mail you when changes are made to repositories here.
The following GitHub repos are used for Newport:
- images-newport - Newport pre-built firmware Firmware Images (watch)
- uboot-newport - Newport Bootloader (watch)
- linux-newport - Newport Linux Kernel (watch)
- bdk-newport - Newport BDK (used as Secondary Program Loader) (watch)
- atf-newport - Newport ATF (ARM Trusted Firmware) (watch)
Pre-built Firmware Images
The images-newport GitHub repository hosts various pre-built firmware images used for Newport:
- GSC firmware image
- firmware image (everything up to and including the bootloader stored on the embedded FLASH boot device) (see below for details)
- linux-newport.tar.bz2 - Compressed TAR archive of pre-built Linux kernel
- xenial-newport.img.gz - Compressed Disk Image containing Firmware and Ubuntu 16.04 Xenial
- xenial-newport.tar.bz2 - Compressed TAR archive of Ubuntu 16.04 Xenial arm64 root filesystem
Firmware Versioning
You can determine the firmware version of various portions of the firmware by looking for banners on the serial console. For example:
Gateworks Newport SPL (ea21abc Tue Dec 12 23:42:48 UTC 2017) GSC : v49 0x832c WDT:disabled board temp:61C RTC : 0 Model : GW6304-B ... NOTICE: Booting Trusted Firmware NOTICE: BL1: v1.3(release):OCTEONTX_SDK_6_2_0_build_26 NOTICE: BL1: Built : 15:30:07, Dec 4 2017 NOTICE: CHIP UniqueID not set ... U-Boot 2017.09-rc1-00023-g1fd1415 (Dec 12 2017 - 15:42:30 -0800) for Cavium OcteonTX CN81XX ARM V8 Core ...
- The above shows the version of the BDK used as the Secondary Program Loader (SPL) is 'ea21abc' built on Tue Dec 12 23:42:48 2017. The git sha of 'ea21abc'.
- The above shows the version of the ATF (ARM Trusted Firmware) is v1.3 built on Dec 4 2017.
- The above shows the version of U-Boot is '2017.09-rc1-00023-g1fd1415' built on Dec 12 2017.
Updating Firmware
This section provides instructions for updating both GSC firmware as well as boot device firmware.
There are two methods for updating firmware:
- on a live board using Serial Console and Ethernet (Note that currently the eMMC FLASH can only be updated on a live board booted from either eMMC or microSD)
- on removable storage (ie recovery microSD)
- using a GW16099 JTAG dongle (see below) (Note that currently only the GSC firmware can be updated via JTAG)
The various items that can be updated:
- GSC Firmware - currently only JTAG updates are supported for Newport - see below
- Firmware (Everything up to and including the Bootloader) - currently must be updated from U-Boot or Linux on a live system - see below
- Root Filesystem (Operating System) - currently must be updated from U-Boot or Linux on a live system - see below
Update Firmware via Serial Console and Ethernet
The quickest and easiest way to update your firmware is via Serial Console and Ethernet. You can do this either in the U-Boot bootloader (recommended) or within a Linux OS. If your primary boot device is corrupt, then you can boot via an alternate boot device (ie microSD).
If using U-Boot (recommended) you need to setup a TFTP server to host the files for transfer. Alternatively you could load firmware files from removable storage (microSD, mSATA, or USB for example) however the transfer rate is typically very slow compared to Gigabit Ethernet. For details on setting up a TFTP server see here.
The following instructions assume your board target IP address is 192.168.1.1 and you have a TFTP server at 192.168.1.146. Adjust environment according to your network via 'setenv ipaddr <ipaddr>' and 'setenv serverip <serverip>'.
Note that if booted from the eMMC (primary device) U-Boot mmc dev 0 is eMMC and mmc dev 1 is microSD however if you booted from the microSD (secondary device) then U-Boot mmc dev 0 is microSD and mmc dev 1 is eMMC. Be sure to use mmc list
to determine which device you should set via the mmc dev
command.
To update just the 'firmware' (everything up to and including the Bootloader) (firmware image):
mmc dev 0 # use 'mmc list' to show which device is which and select eMMC tftpboot ${loadaddr} firmware-newport.img && mmc write ${loadaddr} 0 8000
To update the 'firmware' as well as the root filesystem (xenial-newport.img.gz):
mmc list # see which device is emmc vs sd setenv dev 0 # use device of emmc assuming booted from emmc # using tftp server tftpboot ${loadaddr} xenial-newport.img.gz && gzwrite mmc ${dev} ${loadaddr} ${filesize}
Creating a microSD recovery image
If your primary boot won't boot for some reason (ie, you corrupted it during development) you can boot from a microSD (see here).
To create a bootable microSD meant for recovery purposes only needing the Bootloader you can use firmware-newport.img:
- On a Linux host:
DEVICE=/dev/sdc # set to the microSD on your host sudo dd if=firmware-newport.img of=$DEVICE
- Be careful to set the DEVICE above to the device the microSD appears as on your Linux host - you do not want to overwrite part of your hosts filesystem
- On a Newport board booted from eMMC:
mmc list # if booted from eMMC you should see microSD as dev 1 mmc dev 1 # select microSD tftpboot ${loadaddr} firmware-newport.img && mmc write ${loadaddr} 0 8000
To create a bootable microSD with the Gateworks Ubuntu image (takes longer):
- On a Linux host:
DEVICE=/dev/sdc # set to the microSD on your host zcat xenial-newport.img.gz | sudo dd of=$DEVICE # re-partition with a 3.5MB DOS partition (required by BDK) and a Linux partition at 16MB printf "3072,8191,1,,\n32768,,L,,\n" | sudo sfdisk -uS $DEVICE
- we re-partition so that the full size of your microSD is available as the firmware image has partitions setup for a 8GiB device. Even though the partition table grows to the size of your device you still need to run
resize2fs /dev/mmcblk0p2
after bootup to grow the partition to fit the space in the table. - while you could use U-Boot on a running board to program a microSD you would not be able to adjust it's partition table easily to take advantage of a larger disk.
- we re-partition so that the full size of your microSD is available as the firmware image has partitions setup for a 8GiB device. Even though the partition table grows to the size of your device you still need to run
JTAG Programming
The Gateworks JTAG adapter (GW16099) is available in the Newport Dev Kit as well as on the Gateworks web store here
All Newport boards have a 10-pin JTAG header which provides:
- JTAG Programming for embedded FLASH - see here for instructions
- Serial Console access via UART0 (/dev/ttyAMA0)
Please Note:
- Linux software is supported for programming Newport (jtag_usbv4 required). Windows is not supported at this time. (serial console through Windows does work).
- JTAG Programming of eMMC has not been made available yet. You must boot from a microSD image to program or re-program eMMC flash
- JTAG Programming of the GSC firmware is supported by the most recent version of jtag_usbv4 here
Update GSC Firmware via JTAG
To update the GSC firmware via JTAG download the jtag_usbv4
application on a Linux x86 host from here and execute as follows:
./jtag_usbv4 -m gsc_630x_v49.txt
Note that the ftdi_sio
kernel module must not be loaded (sudo rmmod ftdi_sio) and you may need to run this command as root by pre-pending a sudo depending on the configuration of your linux host.
For more details please see:
Firmware (Up to and including the Bootloader)
The 'firmware-image' for Newport is defined as the combination of the First level 'boot stub' and the additional firmware stages through the bootloader. This can be broken down into the following stages:
- Boot ROM (internal on CN80XX/CN81XX SoC): fetch first level boot stub (192KB limit) from boot device (MMC or SPI FLASH)
- SPL (Secondary Program Loader)
- Bootloader (U-Boot)
For a Secondary Program Loader, or SPL, Gateworks currently uses the Cavium Board Development Kit (BDK) provided by their OCTEON-TX Software Development Kit (SDK). In this current implementation the Boot ROM loads and executes the BDK, the BDK loads and executes the ARM Trusted Firmware (ATF) and the ATF loads and executes the U-Boot bootloader in multiple stages as such:
- First level: Bootstub (firmware/bdk)
- Second level: ATF (firmware/atf)
- Third level: U-Boot (bootloader/u-boot)
Gateworks provides a pre-built firmware-image ready to flash onto boot devices as well as source for building and/or modifying the firmware yourself.
Boot ROM
The OCTEON-TX Boot ROM code loads an image from the primary boot device which can be either MMC or SPI FLASH. For a description of available boot devices see below.
Boot Device
Some boards have multiple boot device and may allow selection of which one is the 'primary boot device':
board | Primary Boot Device | Alternate Boot Device |
---|---|---|
GW630x | on board eMMC | microSD |
To boot from the alternate boot device manually you can press-and-release the user pushbutton 5 times in a row and the board will power cycle primary power (the 3.3V LED will go off, then on again) and the board will boot from the alternate boot device.
Boards with an Alternate boot device also have a boot watchdog such that if the current boot device fails to boot within 30 seconds, the board will power cycle primary power and attempt boot from the other boot device.
U-Boot Bootloader
Gateworks supports the U-Boot Bootloader for the Newport product family. We provide pre-built firmware images (see [#firmware above) as well as source for building and/or modifying it yourself.
One of the primary features of the Bootloader is to provide access to the hwconfig
environment variable that the firmware uses for initial board configuration on power-up.
hwconfig
The U-Boot Bootloader by convention provides a hwconfig
environment variable which is used by the firmware (before U-Boot is loaded and executed) to configure board options at power-up. These options can include things such as:
- miniPCIe socket functions (ie PCIe vs mSATA vs USB3.0)
- serial configuration (ie RS232 vs RS485)
hwconfig: miniPCIe Socket Configuration
Newport board model socket options:
- GW630x:
- J9: PCIe
- J10: PCIe or SATA
- J11: PCIe or USB3.0
Note that USB2.0 is routed to all three miniPCIe sockets always but as USB3.0 shares signals with PCIe you must choose between PCIe and USB3 on sockets that support USB3.
You can get/set the hwconfig
variable within the U-Boot bootloader but you must reboot the board for it to take effect as the variable is acted upon in the Secondary Program Loader (SPL).
Examples:
- GW630x:
- J10 PCIe, J11 PCIe (default)
setenv hwconfig 'j10:pcie;j11:pcie'; saveenv
- J10 mSATA, J11 USB3.0
setenv hwconfig 'j10:sata;j11:usb3'; saveenv
- J9/J10 disabled, J11 PCIe
setenv hwconfig 'j9:disabled;j10:disabled;j11:pcie'; saveenv
- J10 PCIe, J11 PCIe (default)
Note that hwconfig
is also used for serial configuration so care should be taken to preserve that configuration if used
hwconfig: serial Configuration
Many boards in the Newport product family provide a 5-pin off-board serial connector that provides the following options:
- 1x RS485 FD (UART2)
- 1x RS485 HD (UART2)
- 1x RS232 w/ hardware flow control (UART2)
- 2x RS232 w/o hardware flow control (UART2/UART3)
By default 2x RS232 with no flow control is enabled. To configure a different option use the hwconfig
U-Boot env variable. The mode
property of the serial
option defines the initial configuration of the serial port(s). If RS485 is selected by the mode
property the term
property will select whether or not on-board termination is enabled.
The mode
property can have the following values:
- rs232 - 2x RS232 (UART2/UART3) without hardware flow control (default if not specified)
- rs232_dtr - RS232 (UART2) with hardware flow control
- rs485_hd - RS485 half-duplex
- rs485_fd - RS485 full-duplex
Examples:
- enable RS485 half duplex no on-board termination
setenv hwconfig "serial:mode=rs485_hd,term=no"; saveenv
- enable RS485 full duplex with on-board termination
setenv hwconfig "serial:mode=rs485_fd,term=yes"; saveenv
- enable RS232 with hardware flow-control:
setenv hwconfig "serial:mode=rs232_dtr"; saveenv
Note that hwconfig
is also used for serial configuration so care should be taken to preserve that configuration if used
Board Support Packages (BSP) Software
Choosing a BSP
Gateworks offers several Board Support Packages for the Newport Product family. Which one we recommend depends a bit upon what your goal is and what your experience level is.
- Ubuntu
- Recommended for developers trying to heavily leverage opensource software packages or libraries that are not supported by the other BSP's. This is the most user-friendly for developers new to Embedded Linux but will not produce a very trimmed down filesystem image.
- Uses mainline kernel.
- Supports all Newport features.
- Documentation provided to use Ubuntu pre-built packages and debootstrap to create a root filesystem in minutes
- Native compilation: no SDK or cross-toolchain needed
- OpenWrt - Coming Soon for Newport - intended for wireless routers and access points (low flash and memory footprint)
- Recommended for networking users wanting to create a headless router, VPN, basestation, wireless access point and more. Produces by far the smallest storage and memory footprint but users new to Embedded Linux will have a bit of a learning curve
- Fairly up-to-date and/or vanilla kernel support
- Latest wireless drivers (via linux-backports)
- Custom application config and init system (nice for small footprint, but can make adding support for additional packages more work)
- Wide variety of packages (including a fairly nice web-admin)
- Console-based build system (expect 60mins to build BSP for a specific board family)
- Downloadable SDK and Toolchain available to build apps on a development host without building the entire BSP
- Pre-built images available
The following table may also help in choosing what BSP is right for you:
Feature | OpenWrt | Ubuntu | Notes |
---|---|---|---|
Pre-built images | Yes | Yes | |
Storage Needed | <256MB | 2GB or larger | |
Build-System | Yes | No | 1 |
Toolchain | SDK | Native | 2 |
Web-Admin | Yes | No | 3 |
- The OpenWrt BSP contain an integrated build-system. Ubuntu has step-by-step instructions on how to build an bootable system in 10 or so steps.
- The OpenWrt BSP provides a downloadable SDK for cross-compiling applications on a development hosts. For Ubuntu native development and compilation is supported.
- The OpenWrt BSP is designed to be a wireless router and has an integrated web-admin for configuration and control.
Ubuntu
Gateworks offers a pre-built Ubuntu distribution using the latest Gateworks kernel as well as instructions on how to build your own Ubuntu based distribution.
OpenWrt Board Support Package (BSP)
Coming Soon
Newport OpenWrt BSP:
- Pre-Built Binaries
- Building/Installing OpenWrt w/ Gateworks Patches for the Newport Family
- Main OpenWrt Wiki Page
- OpenWrt SDK Toolchain
- join the maillist to follow activity
- GPIO and LED Configuration
The Newport OpenWrt BSP provides the following:
- Linux 4.x kernel (fairly vanilla)
- latest wireless drivers (compat-wireless)
- tuned for minimal FLASH/memory footprint (entire distro fits on embedded 16MB FLASH)
Third Party Linux Distros
While Gateworks cannot fully support all Linux distros, it is relatively simple to overlay a Gateworks Newport kernel onto any non-Gateworks third party Linux distro rootfs image.
The following links will describe what is needed:
- Linux kernel supporting Newport: linux/kernel
- Root Filesystem: see below
- Bootable media: linux/blockdev
Root filesystem Sources
There are several sources of pre-built root filesystems that are compatible with Newport. As Newport uses an ARM 64bit based SoC, you need to use something that is compatible with an ARMv8 instruction set. Many pre-built distributions will reference 'arm64' which means 'ARM 64-bit' which is appropriate for the CN80XX / CN81XX SoC.
Some popular third-party sources:
- Ubuntu Core - this is a minimal filesystem that you can build off of at runtime by adding packages from various repositories.
- Linaro - Linaro has several root filesystems including server, nano, developer, core, and ALIP. Each root filesystem will have different things installed for different purposes. Choose carefully which will work for you.
Notes:
- some root filesystems may require you to manually add a user before booting (ie Ubuntu Core)
- the default Newport bootloader expects to find the Image in the /boot directory on the 2nd partition of type ext2/3/4
Mainline Linux Kernel support
Gateworks actively participates in the development of the Linux kernel.
Cavium licenses CPU core IP from ARM and the name they give the CPU core within the OCTEON-TX CN80XX / CN81XX is the Cavium 'ThunderX'. Therefore many of the peripheral drivers within the Linux kernel have 'thunderx' in their name and more often then not the 'OCTEON' name refers to the older OCTEON MIP64 core.
The following table shows what OCTEON-TX CN80XX / CN81XX peripherals support is available in the mainline kernel starting from 4.13:
Feature | Support | Notes |
---|---|---|
SMP | Yes | ARCH_THUNDER |
serial UART (SBSA) | Yes | SERIAL_AMBA_PL011 drivers/tty/serial/amba-pl011.c |
watchdog Watchdog (SBSA) | Yes | ARM_SBSA_WATCHDOG drivers/watchdog/sbsa_gwdt.c |
I2C | Yes (4.9+) | I2C_THUNDERX drivers/i2c/busses/i2c-{octeon-core,thunderx-pcidrv}.c |
Networking BGX (SGMII) | Yes (4.2+) | THUNDER_NIC_BGX drivers/net/ethernet/cavium/thunder/thunder_bgx.c |
Networking RGX (RGMII) | Yes (4.9+) | THUNDER_NIC_RGX drivers/net/ethernet/cavium/thunder/thunder_xcv.c |
PCI | Yes (4.6+) | PCI drivers/pci/host/pci-thunder-{ecam,pem}.c |
SPI | Yes (4.9+) | SPI_THUNDERX drivers/spi/spi-thunderx.c |
MMC eMMC / microSD | Yes (4.12+) | MMC_CAVIUM_THUNDERX drivers/mmc/host/thunderx-mmc.c |
HW RNG (Hardware Random Number Generator) | Yes (4.9+) | HW_RANDOM_CAVIUM drivers/char/hw_random/cavium-rng*.c |
HW Compressions offload | Yes (4.12+) | DEV_CAVIUM_ZIP drivers/crypto/cavium/zip.c |
Crypto | Yes (4.11+) | DEV_CAVIUM_CPT drivers/crypto/cavium |
RTC | Yes | RTC_DRV_DS1672 drivers/rtc/rtc-ds1672.c |
LED/GPIO | Yes (4.14+) | GPIO_THUNDERX drivers/gpio/gpio-thunderx.c |
USB 3.0 | Yes | USB_XHCI_PCI |
mSATA | Yes | SATA_AHCI |
The following kernel configs should be enabled for the OCTEON-TX CN80XX / CN81XX:
- SERIAL_AMBA_PL011 - ARM SBSA UART
- MMC_CAVIUM_THUNDERX - MMC
- EDAC_THUNDERX - Error Detection and Correction (works with 'edac-util' app from 'edac-utils' package)
- GPIO_THUNDERX - General Purpose I/O
- SPI_THUNDERX - SPI Controller
- I2C_THUNDERX - I2C Controller
- THUNDERX_NIC_VF - NIC virtual function
- THUNDERX_NIC_PF - NIC physical function
- THUNDERX_NIC_BGX - Network Controller (selects MDIO_CAVIUM/MDIO_THUNDERX)
- THUNDERX_NIC_RGX - RGMII Network Controller (selects MDIO_CAVIUM/MDIO_THUNDERX)
- PCI_HOST_THUNDER_PEM - PCI host controller
- PCI_HOST_THUNDER_ECAM - Enhanced Configuration Access Mechanism for PCIe memory mapped I/O
- ARM_SBSA_WATCHDOG - ARMv8 Watchdog
- CRYPTO_DEV_CAVIUM_ZIP - Hardware Compression / Decompression off-load
- HW_RANDOM_CAVIUM - Hardware accelerated random number generator
Note that there are many kernel drivers using the name 'Octeon' but they typically refer to a different chipset and the CN80XX / CN81XX have more in common with the Cavium 'ThunderX' architecture as that is the SoC core.
For details on building a Linux kernel see here
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