Timesys Getting Started Guide for Freescale LX2160A RDB
Contents
- Introduction
- Prerequisites
- Preparing the Target
- Preparing the Host
- Booting the Board
- Additional Information
Introduction
This document will describe in detail the procedures for booting a Linux kernel image and mounting a root file system from an SD Card on the Freescale LX2160A RDB.Prerequisites
Host Requirements
To properly boot the Freescale LX2160A RDB using software from Timesys, your host machine must meet the following requirements:- Modern GNU/Linux Distribution. Timesys recommends one of the following distributions:
- Ubuntu (Most recent release or LTS)
- Fedora (Most recent release)
- Root or sudo permission on the Development Host.
- A copy of the Linux Kernel (Image-5.10-ts-aarch64) and Root File System (rootfs.tar.gz) for the Target Board downloaded from Factory. These are found in the output directory of your online build, or in the directory build_aarch64-timesys-linux-<libc>/images/ on the command line.
- An available USB port on your Development Host.
- A SD card slot or adapter on your Development Host.
Target Requirements
To boot the Freescale LX2160A RDB, you will need the following items:- Freescale LX2160A RDB
- SD Card
- Mini USB Cable
- Connect the USB Debug port of the board to a USB port of your workstation using the USB Cable.
- Connect the power supply to your board.
- Set aside the SD card, you will need to intialize it from the Development Host before booting the board.
Preparing the Target
Configuring Serial Communication
The LX2160ARDB uses a serial debug port to communicate with the host machine. The commands discussed in this section are meant to be performed by a privileged user account. This requires the root login or prepending each command with sudo.
Using Minicom
- Start minicom on your host machine in configuration mode. As root:
# minicom -o -s -w
- A menu of configuration should appear. Use the Down-arrow key to scroll down and select the Serial port setup option, and press Enter.
- Verify that the listed serial port is the same one that is connected to the target board. If it is not, press A, and enter the correct device. This is /dev/ttyUSB0 on most Linux distributions.
- Set the Bps/Par/Bits option by pressing the letter E and using the next menu to set the appropriate values. You press the key that corresponds to the value 115200, then press Enter.
- Set Hardware flow control to No using the F key.
- Set Software flow control to No using the G key.
- Press Enter to return to the main configuration menu, and then press Esc to exit this menu.
- Reset the board, and wait for a moment. If you do not see output from the board, press Enter several times until you see the prompt. If you do not see any output from the board, and have verified that the serial terminal connection is setup correctly, contact your board vendor.
TIP: If you experience an error similar to Device /dev/ttyUSB0 is locked when starting minicom, it usually means that another process is using the serial port (which is usually another instance of minicom). You can find the process that is currently using the serial port by executing the following:
/dev/ttyUSB0: 28358
PID TTY STAT TIME COMMAND
28923 pts/0 S+ 0:00 minicom
This process can also be killed directly with fuser as root. Please use this command with caution:
Using GNU Screen
To quickly connect to a board using Gnu Screen, execute the following:
For more information about using screen, please consult the man page, or view the manual online at http://www.gnu.org/software/screen/manual/screen.html
Preparing the Secure Digital Card
The LX2160ARDB boots from an SD card. Some kits may be shipped with one that contains a sample kernel and RFS preloaded. We will be replacing these with the kernel and RFS from Factory. If you are using a blank SD card or have trouble replacing the software on the preloaded one, see Partitioning the SD Card. Otherwise, skip directly to Writing Boot Files to the SD Card.
Before you begin, you should determine the name of your SD card on your host system. To do so:
- Connect the SD card to your host system. Many modern systems have SD card slots on the case, or you can purchase a USB SD Card Reader for around $15 US.
- Determine the device name of the SD Card. This can be done using dmesg. In the following example, the device is /dev/sdX, which contains one partition sdX1.
$ dmesg | tail
[88050.184080] sd 4:0:0:0: [sdX] 1990656 512-byte hardware sectors: (1.01 GB/972 MiB)
[88050.184821] sd 4:0:0:0: [sdX] Write Protect is off
[88050.184824] sd 4:0:0:0: [sdX] Mode Sense: 03 00 00 00
[88050.184827] sd 4:0:0:0: [sdX] Assuming drive cache: write through
[88050.185575] sd 4:0:0:0: [sdX] 1990656 512-byte hardware sectors: (1.01 GB/972 MiB)
[88050.186323] sd 4:0:0:0: [sdX] Write Protect is off
[88050.186325] sd 4:0:0:0: [sdX] Mode Sense: 03 00 00 00
[88050.186327] sd 4:0:0:0: [sdX] Assuming drive cache: write through
[88050.186330] sdX: sdX1
Partitioning the SD card
If you want to use a different SD card or its contents become corrupted, you can use the fdisk tool to create a single Linux partition on your SD card. Please note that all data on the card will be lost upon completion of these steps.
- Unmount the partition if it was automounted by using the umount command.
$ umount /dev/sdX1
- As root, run the fdisk utility on the drive.
$ sudo fdisk /dev/sdX
- In fdisk, Delete the existing partition table and create a new one using the o command.
Command (m for help): o
Building a new DOS disklabel with disk identifier 0x8b025602.
Changes will remain in memory only, until you decide to write them.
After that, of course, the previous content won't be recoverable.
- Create a new primary partition using the n command. You will need to leave space for the U-Boot image before the start of the first partition. 4096 should be sufficient.
Command (m for help): n
Partition type:
p primary (0 primary, 0 extended, 4 free)
e extended
Select (default p): p
Partition number (1-4, default 1): 1
First sector (2048-30679039, default 2048): 4096
Last sector, +sectors or +sizeK,M,G (2048-30679039, default 30679039):
Using default value 30679039
- Verify that the partition table is correct by using the p command. It should look similar to the following:
Command (m for help): p
Disk /dev/sdX: 15.7 GB, 15707668480 bytes
64 heads, 32 sectors/track, 14980 cylinders, total 30679040 sectors
Units = sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
Disk identifier: 0x6eaae8f8
Device Boot Start End Blocks Id System
/dev/sdX1 4096 30679039 14773960 83 Linux
- This step will destroy all data on the SD Card - Write the partition table to the card using the w command.
Command (m for help): w
The partition table has been altered!
Calling ioctl() to re-read partition table.
WARNING: If you have created or modified any DOS 6.x
partitions, please see the fdisk manual page for additional
information.
Syncing disks.
- Format the first partition of the SD card with the ext4 filesystem using the mkfs.ext4 tool.
$ sudo /sbin/mkfs.ext4 -L rfs /dev/sdX1
Writing Boot Files to the SD Card
- Mount the partition. You can remove and reinsert the card to trigger the automount, or you can use the mount command to mount the partition to an arbitrary location.
$ sudo mount /dev/sdX1 /media/rfs
- Copy U-Boot files to the SD card:
$ sudo dd if=fip.bin of=/dev/sdX bs=1K seek=1024
$ sudo dd if=bl2_sd.pbl of=/dev/sdX bs=1K seek=4
$ sudo dd if=fip_ddr.bin of=/dev/sdX bs=1K seek=8192
$ sudo dd if=mc_lx2160a_10.31.1.itb of=/dev/sdX bs=512 seek=20480
$ sudo dd if=dpl-eth.19.dtb of=/dev/sdX bs=512 seek=26624
$ sudo dd if=dpc-usxgmii.dtb of=/dev/sdX bs=512 seek=28672
841+1 records in
841+1 records out
430824 bytes (431 kB) copied, 0.0669761 s, 6.4 MB/s
- As root, extract the rootfs.tar.gz archive to the card.
$ sudo tar xzf rootfs.tar.gz -C /media/rfs
- If you have included the kernel image in your rootfs, this next step is not necessary
As root, create the boot directory on the RFS partition of the card.
$ sudo mkdir /media/rfs/boot
- As root, copy the uImage file, Image-5.10-ts-aarch64, to the boot directory on the RFS partition of the card.
$ sudo cp Image-5.10-ts-aarch64 /media/rfs/boot/
$ sudo cp lx2160a_rdb.dtb /media/rfs/boot/
- Unmount the card before removing it from the Development Host. Then place the card in the SD card slot on the LX2160ARDB.
$ sudo umount /dev/sdX*
- Remove the SD Card from the host machine, and insert it into the SD Card slot on the target board. You should hear the card 'click' into place.
Preparing the Host
No additional host setup is required to boot from SD.
Booting the Board
Set Environment Variables
You must set a few environment variables in order to boot the board from the SD card. This is done with the setenv and saveenv commands in U-Boot.
On the target, set the following environment variables:
Variable | Value | |||||
bootargs | console=ttyAMA0,115200 root=/dev/mmcblk0p1 rw rootwait | |||||
load_kernel | ext4load mmc 0:1 0x84080000 boot/Image-5.10-ts-aarch64 | |||||
load_dtb | ext4load mmc 0:1 0x90000000 boot/lx2160a_rdb.dtb | |||||
bootcmd | mmc rescan\; run load_kernel load_dtb\; booti 0x84080000 - 0x90000000 |
Example
> setenv bootargs console=ttyAMA0,115200 root=/dev/mmcblk0p1 rw rootwait
> setenv load_kernel ext4load mmc 0:1 0x84080000 boot/Image-5.10-ts-aarch64
> setenv load_dtb ext4load mmc 0:1 0x90000000 boot/lx2160a_rdb.dtb
> setenv bootcmd mmc rescan\; run load_kernel load_dtb\; booti 0x84080000 - 0x90000000
> saveenv
Load The Kernel
You can use the mmc subsystem to load the kernel from the SD card.
Example
> ext4load mmc 0:1 0x84080000 boot/Image-5.10-ts-aarch64
reading boot/Image-5.10-ts-aarch64
3008612 bytes read
Load The Device Tree
You can use the mmc subsystem to load the device tree file (dtb) from the SD card.
Example
> ext4load mmc 0:1 0x90000000 boot/lx2160a_rdb.dtb
reading boot/lx2160a_rdb.dtb
24612 bytes read
Boot the Kernel
The booti command is used to boot the kernel. It loads the file that was previously loaded using the ext4load command.
Example
## Booting kernel from Legacy Image at 0x84080000 ..
Image Name: Linux-5.10-ts-aarch64
Image Type: ARM Linux Kernel Image (uncompressed)
Data Size: 3008548 Bytes = 2.9 MB
Load Address: 80008000
Entry Point: 80008000
Verifying Checksum ... OK
Loading Kernel Image ... OK
## Flattened Device Tree blob at 0x90000000
Booting using the fdt blob at 0x90000000
Loading Kernel Image ... OK
OK
Additional Information
Factory Documentation