Specification:
- MT7981 CPU using 2.4GHz and 5GHz WiFi (both AX)
- MT7531 switch
- 512MB RAM
- 128MB NAND flash with two UBI partitions with identical size
- 1 multi color LED (red, green, blue, white) connected via GCA230718
- 3 buttons (WPS, reset, LED on/off)
- 1 1Gbit WAN port
- 4 1Gbit LAN ports
Disassembly:
- There are four screws at the bottom: 2 under the rubber feets, 2 under the label.
- After removing the screws, the white plastic part can be shifted out of the blue part.
- Be careful because the antennas are mounted on the side and the top of the white part.
Serial Interface
- The serial interface can be connected to the 4 pin holes on the side of the board.
- Pins (from front to rear):
- 3.3V
- RX
- TX
- GND
- Settings: 115200, 8N1
MAC addresses:
- WAN MAC is stored in partition "Odm" at offset 0x81
- LAN (as printed on the device) is WAN MAC + 1
- WLAN MAC (2.4 GHz) is WAN MAC + 2
- WLAN MAC (5GHz) is WAN MAC + 3
Flashing via Recovery Web Interface:
- The recovery web interface always flashes to the currently active partition.
- If OpenWrt is flahsed to the second partition, it will not boot.
- Ensure that you have an OEM image available (encrypted and decrypted version). Decryption is described in the end.
- Set your IP address to 192.168.200.10, subnetmask 255.255.255.0
- Press the reset button while powering on the device
- Keep the reset button pressed until the LED blinks red
- Open a Chromium based and goto http://192.168.200.1 (recovery web interface)
- Download openwrt-mediatek-filogic-dlink_aquila-pro-ai-m30-a1-squashfs-recovery.bin
- The recovery web interface always reports successful flashing, even if it fails
- After flashing, the recovery web interface will try to forward the browser to 192.168.0.1 (can be ignored)
- If OpenWrt was flashed to the first partition, OpenWrt will boot (The status LED will start blinking white and stay white in the end). In this case you're done and can use OpenWrt.
- If OpenWrt was flashed to the second partition, OpenWrt won't boot (The status LED will stay red forever). In this case, the following steps are reuqired:
- Start the web recovery interface again and flash the **decrypted OEM image**. This will be flashed to the second partition as well. The OEM firmware web interface is afterwards accessible via http://192.168.200.1.
- Now flash the **encrypted OEM image** via OEM firmware web interface. In this case, the new firmware is flashed to the first partition. After flashing and the following reboot, the OEM firmware web interface should still be accessible via http://192.168.200.1.
- Start the web recovery interface again and flash the OpenWrt recovery image. Now it will be flashed to the first partition, OpenWrt will boot correctly afterwards and is accessible via 192.168.1.1.
Flashing via U-Boot:
- Open the case, connect to the UART console
- Set your IP address to 192.168.200.2, subnet mask 255.255.255.0. Connect to one of the LAN interfaces of the router
- Run a tftp server which provides openwrt-mediatek-filogic-dlink_aquila-pro-ai-m30-a1-initramfs-kernel.bin.
- Power on the device and select "7. Load image" in the U-Boot menu
- Enter image file, tftp server IP and device IP (if they differ from the default).
- TFTP download to RAM will start. After a few seconds OpenWrt initramfs should start
- The initramfs is accessible via 192.168.1.1, change your IP address accordingly (or use multiple IP addresses on your interface)
- Perform a sysupgrade using openwrt-mediatek-filogic-dlink_aquila-pro-ai-m30-a1-squashfs-sysupgrade.bin
- Reboot the device. OpenWrt should start from flash now
Revert back to stock using the Recovery Web Interface:
- Set your IP address to 192.168.200.2, subnetmask 255.255.255.0
- Press the reset button while powering on the device
- Keep the reset button pressed until the LED blinks red
- Open a Chromium based and goto http://192.168.200.1 (recovery web interface)
- Flash a decrypted firmware image from D-Link. Decrypting an firmware image is described below.
Decrypting a D-Link firmware image:
- Download https://github.com/RolandoMagico/firmware-utils/blob/M32/src/m32-firmware-util.c
- Compile a binary from the downloaded file, e.g. gcc m32-firmware-util.c -lcrypto -o m32-firmware-util
- Run ./m32-firmware-util M30 --DecryptFactoryImage <OriginalFirmware> <OutputFile>
- Example for firmware M30A1_FW101B05: ./m32-firmware-util M30 --DecryptFactoryImage M30A1_FW101B05\(0725091522\).bin M30A1_FW101B05\(0725091522\)_decrypted.bin
Flashing via OEM web interface is not possible, as it will change the active partition and OpenWrt is only running on the first UBI partition.
Controlling the LEDs:
- The LEDs are controlled by a chip called "GCA230718" which is connected to the main CPU via I2C (address 0x40)
- I didn't find any documentation or driver for it, so the information below is purely based on my investigations
- If there is already I driver for it, please tell me. Maybe I didn't search enough
- I implemented a kernel module (leds-gca230718) to access the LEDs via DTS
- The LED controller supports PWM for brightness control and ramp control for smooth blinking. This is not implemented in the driver
- The LED controller supports toggling (on -> off -> on -> off) where the brightness of the LEDs can be set individually for each on cycle
- Until now, only simple active/inactive control is implemented (like when the LEDs would have been connected via GPIO)
- Controlling the LEDs requires three sequences sent to the chip. Each sequence consists of
- A reset command (0x81 0xE4) written to register 0x00
- A control command (for example 0x0C 0x02 0x01 0x00 0x00 0x00 0xFF 0x01 0x00 0x00 0x00 0xFF 0x87 written to register 0x03)
- The reset command is always the same
- In the control command
- byte 0 is always the same
- byte 1 (0x02 in the example above) must be changed in every sequence: 0x02 -> 0x01 -> 0x03)
- byte 2 is set to 0x01 which disables toggling. 0x02 would be LED toggling without ramp control, 0x03 would be toggling with ramp control
- byte 3 to 6 define the brightness values for the LEDs (R,G,B,W) for the first on cycle when toggling
- byte 7 defines the toggling frequency (if toggling enabled)
- byte 8 to 11 define the brightness values for the LEDs (R,G,B,W) for the second on cycle when toggling
- byte 12 is constant 0x87
Comparison to M32/R32:
- The algorithms for decrypting the OEM firmware are the same for M30/M32/R32, only the keys differ
- The keys are available in the GPL sources for the M32
- The M32/R32 contained raw data in the firmware images (kernel, rootfs), the R30 uses a sysupgrade tar instead
- Creation of the recovery image is quite similar, only the header start string changes. So mostly takeover from M32/R32 for that.
- Turned out that the bytes at offset 0x0E and 0x0F in the recovery image header are the checksum over the data area
- This checksum was not checked in the recovery web interface of M32/R32 devices, but is now active in R30
- I adapted the recovery image creation to also calculate the checksum over the data area
- The recovery image header for M30 contains addresses which don't match the memory layout in the DTS. The same addresses are also present in the OEM images
- The recovery web interface either calculates the correct addresses from it or has it's own logic to determine where which information must be written
Signed-off-by: Roland Reinl <reinlroland+github@gmail.com>
Huawei AP5030DN is a dual-band, dual-radio 802.11ac Wave 1 3x3 MIMO
enterprise access point with two Gigabit Ethernet ports and PoE
support.
Hardware highlights:
- CPU: QCA9550 SoC at 720MHz
- RAM: 256MB DDR2
- Flash: 32MB SPI-NOR
- Wi-Fi 2.4GHz: QCA9550-internal radio
- Wi-Fi 5GHz: QCA9880 PCIe WLAN SoC
- Ethernet 1: 10/100/1000 Mbps Ethernet through Broadcom B50612E PHY
- Ethernet 2: 10/100/1000 Mbps Ethernet through Marvell 88E1510 PHY
- PoE: input through Ethernet 1 port
- Standalone 12V/2A power input
- Serial console externally available through RJ45 port
- External watchdog: SGM706 (1.6s timeout)
Serial console:
9600n8 (9600 baud, no stop bits, no parity, 8 data bits)
MAC addresses:
Each device has 32 consecutive MAC addresses allocated by
the vendor, which don't overlap between devices.
This was confirmed with multiple devices with consecutive
serial numbers.
The MAC address range starts with the address on the label.
To be able to distinguish between the interfaces,
the following MAC address scheme is used:
- eth0 = label MAC
- eth1 = label MAC + 1
- radio0 (Wi-Fi 5GHz) = label MAC + 2
- radio1 (Wi-Fi 2.4GHz) = label MAC + 3
Installation:
0. Connect some sort of RJ45-to-USB adapter to "Console" port of the AP
1. Power up the AP
2. At prompt "Press f or F to stop Auto-Boot in 3 seconds",
do what they say.
Log in with default admin password "admin@huawei.com".
3. Boot the OpenWrt initramfs from TFTP using the hidden script
"run ramboot". Replace IP address as needed:
> setenv serverip 192.168.1.10
> setenv ipaddr 192.168.1.1
> setenv rambootfile
openwrt-ath79-generic-huawei_ap5030dn-initramfs-kernel.bin
> saveenv
> run ramboot
4. Optional but recommended as the factory firmware cannot
be downloaded publicly:
Back up contents of "firmware" partition using the web interface or ssh:
$ ssh root@192.168.1.1 cat /dev/mtd11 > huawei_ap5030dn_fw_backup.bin
5. Run sysupgrade using sysupgrade image. OpenWrt
shall boot from flash afterwards.
Return to factory firmware (using firmware upgrade package downloaded from
non-public Huawei website):
1. Start a TFTP server in the directory where
the firmware upgrade package is located
2. Boot to u-boot as described above
3. Install firmware upgrade package and format the config partitions:
> update system FatAP5X30XN_SOMEVERSION.bin
> format_fs
Return to factory firmware (from previously created backup):
1. Copy over the firmware partition backup to /tmp,
for example using scp
2. Use sysupgrade with force to restore the backup:
sysupgrade -F huawei_ap5030dn_fw_backup.bin
3. Boot AP to U-Boot as described above
Quirks and known issues
-----------------------
- On initial power-up, the Huawei-modified bootloader suspends both
ethernet PHYs (it sets the "Power Down" bit in the MII control
register). Unfortunately, at the time of the initial port, the kernel
driver for the B50612E/BCM54612E PHY behind eth0 doesn't have a resume
callback defined which would clear this bit. This makes the PHY unusable
since it remains suspended forever. This is why the backported kernel
patches in this commit are required which add this callback and for
completeness also a suspend callback.
- The stock firmware has a semi dual boot concept where the primary
kernel uses a squashfs as root partition and the secondary kernel uses
an initramfs. This dual boot concept is circumvented on purpose to gain
more flash space and since the stock firmware's flash layout isn't
compatible with mtdsplit.
- The external watchdog's timeout of 1.6s is very hard to satisfy
during bootup. This is why the GPIO15 pin connected to the watchdog input
is configured directly in the LZMA loader to output the CPU_CLK/4 signal
which keeps the watchdog happy until the wdt-gpio kernel driver takes
over. Because it would also take too long to read the whole kernel image
from flash, the uImage header only includes the loader which then reads
the kernel image from flash after GPIO15 is configured.
Signed-off-by: Marco von Rosenberg <marcovr@selfnet.de>
[fixed 6.6 backport patch naming]
Signed-off-by: David Bauer <mail@david-bauer.net>
The uboot-envtools can automatically parse the dts 'u-boot,env'
compatible string. So the env config file is now useless.
Signed-off-by: Shiji Yang <yangshiji66@qq.com>
Contrary to common ipTIME NOR devices, the "Config" partition of T5004
and AX2004M contain normal U-Boot environment variables. Renaming the
partition into "u-boot-env" serves for better description, and it also
conforms to common naming practice in OpenWrt.
This patch might also be extended to A3004T, but its u-boot-env
partition layout has not been confirmed yet.
Signed-off-by: Sungbo Eo <mans0n@gorani.run>
Netgear WAX214 is a 802.11 ax dual-band AP
with PoE. (similar to Engenius EWS357APV3)
Specifications:
• CPU: Qualcomm IPQ6010 Quad core Cortex-A53
• RAM: 512MB of DDR3
• Storage: 128MB NAND (Macronix MX30UF1G18AC)
• Ethernet: 1x 1G RJ45 port (QCA8072) PoE
• WIFI:
2.4GHz: Qualcomm QCN5022 2x2 802.11b/g/n/ax 574 Mbps PHY rate
5GHz: Qualcomm QCN5052 2x2 802.11a/b/g/n/ac/ax 1201 PHY rate
• LEDs:
4 x GPIO-controlled LEDs
- 1 Power LED (orange)
- 1 LAN LED (blue)
- 1 WIFI 5g LED (blue)
- 1 WIFI 2g LED (blue)
black_small_square Buttons: 1x soft reset
black_small_square Power: 12V DC jack or PoE (802.3af )
An populated serial header is onboard, format is
1.25mm 4p (DF13A-4P-1.25H)
RX/TX is working, bootwait is active, secure boot is not
enabled.
The root password of the stock firmware is unknown,
but failsafe mode can be entered to reset the password.
Installation Instructions:
- obtain serial access
- stop auto boot (press "4", Entr boot command line
interface)
- setenv active_fw 0 (to boot from the primary rootfs,
or set to 1 to boot from the secondary rootfs
partition)
- saveenv
- tftpboot the initramfs image
- bootm
- copy
openwrt-qualcommax-ipq60xx-netgear_wax214-squashfs-factory.ubi
to the device
- write the image to the NAND:
- cat /proc/mtd and look for rootfs partition (should
be mtd11,
or mtd12 if you choose active_fw 1)
- ubiformat /dev/mtd11 -f -y
openwrt-qualcommax-ipq60xx-netgear_wax214-squashfs-factory.ubi
- reboot
Note: the firmware is senao-based. But I was unable to build
a valid senao-header into the image.
Maybe they changed the header format and senaoFW isn't
working any more.
Signed-off-by: Dirk Buchwalder <buchwalder@posteo.de>
Use the new fitblk driver on the BananaPi R2 as well as UniElec U7623.
Introduce boot device selection for fitblk's /chosen/rootdisk
handle, similar to how it is already done on MT7622, MT7986 and MT7988.
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
**Netgear LBR20** is a router with two gigabit ethernets , three wifi radios and integrated LTE cat.18 modem.
SoC Type: Qualcomm IPQ4019
RAM: 512 MiB
Flash: 256 MiB , SLC NAND, 2 Gbit (Macronix MX30LF2G18AC)
Bootloader: U-Boot
Modem: LTE CAT.18 Quectel EG-18EA , Max. 1.2Gbps downlink / 150Mbps uplink
WiFi class AC2200:
- radio0 : 5G on QCA9888 , WiFi5- 802.11a/n/ac MU-MIMO 2x2 , 887Mbps , 80MHz - limited for low channels
- radio1: 2,4G on IPQ4019 ,WiFi4- 802.11b/g/n MIMO2x2 300Mbps 40Mhz
- radio2: 5G on IPQ4019 , WiFi5- 802.11a/n/ac MU-MIMO 2x2 , 887Mbps ,80Mhz - limited for high channels (from 100 up to 165) . Becouse of DFS remember to set country before turning on.
Ethernet: 2x1GbE (WAN/LAN1, LAN2)
LEDs: section power : green and red , section on top (orbi) drived by TLC59208F: red, green ,blue and white
USB ports: No
Buttons: 2 Reset and SYNC(WPS)
Power: 12 VDC, 2,5 A
Connector type: Barrel
OpenWRT Installation
1. Simplest way is just do upgrade from webpage with *factory.img
2. You can also do it with standard tool for Netgear's debricking - NMPRFlash
3. Most advanced way is to open device , connect to UART console and :
- Prepare OpenWrt initramfs image in TFTP server root (server IP 192.168.1.10)
- Connect serial console (115200,8n1) to UART connector
- Connect TFTP server to RJ-45 port
- Stop in u-Boot and run u-Boot command:
> setenv serverip 192.168.1.10
> set fdt_high 0x85000000
> tftpboot 0x83000000 openwrt-ipq40xx-generic-netgear_lbr20-initramfs-zImage.itb
> bootm 0x83000000
- Login via ssh
- upload or download *sysupgrade.bin ( like wget ... or scp transfer)
- Install image via "sysupgrade -n" (like “sysupgrade -n /tmp/openwrt-ipq40xx-generic-netgear_lbr20-squashfs-sysupgrade.bin”)
Back to Stock
- Download firmware from official Netgear's webpage , it will be *.img file after decompressing.
- Use NMRPFlash tool ( detailed insructions on project page https://github.com/jclehner/nmrpflash )
Open the case
- Unscrew nuts and remove washers from antenna's conectors.
- There are two Torx T10 screws under the label next to antenna conectors. You have to unglue this label from left and right corner to get it
- Two parts of shell covers will slide out from eachother , you have to unglue two small rubber pads and namplate sticker on bottom to do that.
- PCB is screwed with 4Pcs of Torx T10 screws
- Before lifting up PCB remove pigtiles for LTE antennas and release them from PCB and radiator (black and white wires)
- On other side of PCB ,in left bottom corner there is already soldered with 4 pins UART connector for console. Counting from left it is +3,3V , TX , RX ,GND (reffer to this picture: https://i.ibb.co/Pmrf9KB/20240116-103524.jpg )
BDF's files are in firmware_qca-wireless https://github.com/openwrt/firmware_qca-wireless/ and in parallel sent to ath10k@lists.infradead.org.
Signed-off-by: Marcin Gajda <mgajda@o2.pl>
Hardware specification
----------------------
SoC: MediaTek MT7986A 4x A53
Flash: 128MB SPI-NAND, 8GB eMMC
RAM: 2GB DDR4
Ethernet: 2x 2.5GbE (Airoha EN8811H)
WiFi: MediaTek MT7976C 2x2 2.4G + 3x3 5G
Interfaces:
* M.2 Key-M: PCIe 2.0 x2 for NVMe SSD
* M.2 Key-B: USB 3.0 with SIM slot
* front USB 2.0 port
LED: Power, Status, WLAN2G, WLAN5G, LTE, SSD
Button: Reset, internal boot switch
Fan: PWM-controlled 5V fan
Power: 12V Type-C PD
Installation instructions for eMMC
----------------------------------
0. Set boot switch to boot from SPI-NAND (assuming stock rom or immortalwrt
running there).
1. Write GPT partition table to eMMC
Move openwrt-mediatek-filogic-bananapi_bpi-r3-mini-emmc-gpt.bin to
the device /tmp using scp and write it to /dev/mmcblk0:
dd if=/tmp/openwrt-*-r3-mini-emmc-gpt.bin of=/dev/mmcblk0
2. Reboot (to reload partition table)
3. Write bootloader and OpenWrt images
Move files to the device /tmp using scp:
- openwrt-*-bananapi_bpi-r3-mini-emmc-preloader.bin
- openwrt-*-bananapi_bpi-r3-mini-emmc-bl31-uboot.fip
- openwrt-*-bananapi_bpi-r3-mini-initramfs-recovery.itb
- openwrt-*-bananapi_bpi-r3-mini-squashfs-sysupgrade.itb
Write them to the appropriate partitions:
echo 0 > /sys/block/mmcblk0boot0/force_ro
dd if=/tmp/openwrt-*-bananapi_bpi-r3-mini-emmc-preloader.bin of=/dev/mmcblk0boot0
dd if=/tmp/openwrt-*-bananapi_bpi-r3-mini-emmc-bl31-uboot.fip of=/dev/mmcblk0p3
dd if=/tmp/openwrt-*-bananapi_bpi-r3-mini-initramfs-recovery.itb of=/dev/mmcblk0p4
dd if=/tmp/openwrt-*-bananapi_bpi-r3-mini-squashfs-sysupgrade.itb of=/dev/mmcblk0p5
sync
4. Remove the device from power, set boot switch to eMMC and boot into
OpenWrt. The device will come up with IP 192.168.1.1 and assume the
Ethernet port closer to the USB-C power connector as LAN port.
5. If you like to have Ethernet support inside U-Boot (eg. to boot via
TFTP) you also need to write the PHY firmware to /dev/mmcblk0boot1:
echo 0 > /sys/block/mmcblk0boot1/force_ro
dd if=/lib/firmware/airoha/EthMD32.dm.bin of=/dev/mmcblk0boot1
dd if=/lib/firmware/airoha/EthMD32.DSP.bin bs=16384 seek=1 of=/dev/mmcblk0boot1
Installation instructions for NAND
----------------------------------
0. Set boot switch to boot from eMMC (assuming OpenWrt is installed there
by instructions above. Using stock rom or immortalwrt does NOT work!)
1. Write things to NAND
Move files to the device /tmp using scp:
- openwrt-*-bananapi_bpi-r3-mini-snand-preloader.bin
- openwrt-*-bananapi_bpi-r3-mini-snand-bl31-uboot.fip
- openwrt-*-bananapi_bpi-r3-mini-initramfs-recovery.itb
- openwrt-*-bananapi_bpi-r3-mini-squashfs-sysupgrade.itb
Write them to the appropriate locations:
mtd write /tmp/openwrt-*-bananapi_bpi-r3-mini-snand-preloader.bin /dev/mtd0
ubidetach -m 1
ubiformat /dev/mtd1
ubiattach -m 1
volsize=$(wc -c < /tmp/openwrt-*-bananapi_bpi-r3-mini-snand-bl31-uboot.fip)
ubimkvol /dev/ubi0 -N fip -n 0 -s $volsize -t static
ubiupdatevol /dev/ubi0_0 /tmp/openwrt-*-bananapi_bpi-r3-mini-snand-bl31-uboot.fip
cd /lib/firmware/airoha
cat EthMD32.dm.bin EthMD32.DSP.bin > /tmp/en8811h-fw.bin
ubimkvol /dev/ubi0 -N en8811h-firmware -n 1 -s 147456 -t static
ubiupdatevol /dev/ubi0_1 /tmp/en8811h-fw.bin
ubimkvol /dev/ubi0 -n 2 -N ubootenv -s 126976
ubimkvol /dev/ubi0 -n 3 -N ubootenv2 -s 126976
volsize=$(wc -c < /tmp/openwrt-*-bananapi_bpi-r3-mini-initramfs-recovery.itb)
ubimkvol /dev/ubi0 -n 4 -N recovery -s $volsize
ubiupdatevol /dev/ubi0_4 /tmp/openwrt-*-bananapi_bpi-r3-mini-initramfs-recovery.itb
volsize=$(wc -c < /tmp/openwrt-*-bananapi_bpi-r3-mini-squashfs-sysupgrade.itb)
ubimkvol /dev/ubi0 -n 4 -N recovery -s $volsize
ubiupdatevol /dev/ubi0_4 /tmp/openwrt-*-bananapi_bpi-r3-mini-squashfs-sysupgrade.itb
3. Remove the device from power, set boot switch to NAND, power up and
boot into OpenWrt.
Partially based on immortalwrt support for the R3 mini, big thanks for
doing the ground work!
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
Modernize bootloader and flash memory layout of the BPi-R64 similar to
how it has also been done for the BPi-R3.
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
Add environment settings for the BananaPi BPI-R4 router board which
can boot from (and store its bootloader environment on) micro SD card,
SPI-NAND and eMMC.
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
Use function instead of duplicating the env settings on UBI for
OpenWrt-built U-Boot over and over.
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
Comfast CF-E393AX is a dual-band Wi-Fi 6 POE ceiling mount access point.
Oem firmware is a custom openwrt 21.02 snapshot version.
We can gain access via ssh once we remove the root password.
Hardware specification:
SoC: MediaTek MT7981A 2x A53
Flash: 128 MB SPI-NAND
RAM: 256MB DDR3
Ethernet: 1x 10/100/1000 Mbps built-in PHY (WAN)
1x 10/100/1000/2500 Mbps MaxLinear GPY211C (LAN)
Switch: MediaTek MT7531AE
WiFi: MediaTek MT7976D
LEDS: 1x (Red, Blue and Green)
Button: Reset
UART: 3.3v, 115200n8
--------------------------
| Layout |
| ----------------- |
| 4 | VCC GND TX RX | <= |
| ----------------- |
--------------------------
Gain SSH access:
1. Login into web interface (http://apipaddress/computer/login.html),
and download the
configuration(http://apipaddress/computer/config.html).
2. Rename downloaded backup config - 'backup.file to backup.tar.gz',
Enter 'fakeroot' command then decompress the configuration:
tar -zxf backup.tar.gz
3. Edit 'etc/shadow', update (remove) root password:
With password =
'root:$1$xf7D0Hfg$5gkjmvgQe4qJbe1fi/VLy1:19362:0:99999:7:::'
'root:$1$xf7D0Hfg$5gkjmvgQe4qJbe1fi/VLy1:19362:0:99999:7:::'
to
Without password =
'root::0:99999:7:::'
'root::0:99999:7:::'
4. Repack 'etc' directory back to a new backup file:
tar -zcf backup-ssh.tar.gz etc/
5. Rename new config tar.gz file to 'backup-ssh.file'
Exit fakeroot - 'exit'
6. Upload new configuration via web interface, now you
can SSH with the following:
'ssh -vv -o HostKeyAlgorithms=+ssh-rsa \
-o PubkeyAcceptedAlgorithms=+ssh-rsa root@192.168.10.1'.
Backup the mtd partitions
- https://openwrt.org/docs/guide-user/installation/generic.backup
7. Copy openwrt factory firmware to the tmp folder to install via ssh:
'scp -o HostKeyAlgorithms=+ssh-rsa \
-o PubkeyAcceptedAlgorithms=+ssh-rsa \
*-mediatek-filogic-comfast_cf-e393ax-squashfs-factory.bin \
root@192.168.10.1:/tmp/'
'sysupgrade -n -F \
/tmp/*--mediatek-filogic-comfast_cf-e393ax-squashfs-factory.bin'
8. Once led has stopped flashing - Connect via ssh with the
default openwrt ip address - 'ssh root@192.168.1.1'
9. SSH copy the openwrt sysupgrade firmware and upgrade
as per the default instructions.
Signed-off-by: David Bentham <db260179@gmail.com>
This reverts commit dcdcfc1511.
This is a firmware for third-party u-boot mod, which should not
be carried here by us.
Signed-off-by: Chuanhong Guo <gch981213@gmail.com>
Linksys MX4200 is a 802.11ax Tri-band router/AP.
Specifications:
* CPU: Qualcomm IPQ8174 Quad core Cortex-A53 1.4GHz
* RAM: 512MB of DDR3
* Storage: 512Mb NAND
* Ethernet: 4x1G RJ45 ports (QCA8075)
* WLAN:
* 2.4GHz: Qualcomm QCN5024 2x2 802.11b/g/n/ax 574 Mbps PHY rate
* 5GHz: Qualcomm QCN5054 2x2@80MHz or 2x2@160MHz 802.11a/b/g/n/ac/ax 2402 PHY rate
* 5GHz: Qualcomm QCN5054 4x4@80MHz or 2x2@160MHz 802.11a/b/g/n/ac/ax 2402 PHY rate
* LED-s:
* RGB system led
* Buttons: 1x Soft reset 1x WPS
* Power: 12V DC Jack
Installation instructions:
Open Linksys Web UI - http://192.168.1.1/ca or http://10.65.1.1/ca depending on your setup.
Login with your admin password. The default password can be found on a sticker under the device.
To enter into the support mode, click on the “CA” link and the bottom of the page.
Open the “Connectivity” menu and upload the squash-factory image with the “Choose file” button.
Click start. Ignore all the prompts and warnings by click “yes” in all the popups.
The Wifi radios are turned off by default. To configure the router, you will need to connect your computer to the LAN port of the device.
Then you would need to write openwrt to the other partition for it to work
- First Check booted partition
fw_printenv -n boot_part
- Then install Openwrt to the other partition if booted in slot 1:
mtd -r -e alt_kernel -n write openwrt-qualcommax-ipq807x-linksys_mx4200v(X)-squashfs-factory.bin alt_kernel
- If in slot 2:
mtd -r -e kernel -n write openwrt-qualcommax-ipq807x-linksys_mx4200v(X)-squashfs-factory.bin kernel
Replace (X) with your model version either 1 or 2
Signed-off-by: Mohammad Sayful Islam <sayf.mohammad01@gmail.com>
Reviewed-by: Robert Marko <robimarko@gmail.com>
R32 is like the M32 part of the EAGLE PRO AI series from D-Link.
Specification:
- MT7622BV SoC with 2.4GHz wifi
- MT7975AN + MT7915AN for 5GHz
- MT7531BE Switch
- 512MB RAM
- 128 MB flash
- 2 LEDs (Status and Internet, both can be either orange or white)
- 2 buttons (WPS and Reset)
Compared to M32, the R32 has the following differences:
- 4 LAN ports instead of 2
- The recory image starts with DLK6E6015001 instaed of DLK6E6010001
- Individual LEDs for power and internet
- MAC address is stored at another offset in the ODM partition
MAC addresses:
- WAN MAC is stored in partition "Odm" at offset 0x81
- LAN (as printed on the device) is WAN MAC + 1
- WLAN MAC (2.4 GHz) is WAN MAC + 2
- WLAN MAC (5GHz) is WAN MAC + 3
Flashing via Recovery Web Interface:
- Set your IP address to 192.168.0.10, subnetmask 255.255.255.0
- Press the reset button while powering on the deivce
- Keep the reset button pressed until the internet LED blinks fast
- Open a Chromium based and goto http://192.168.0.1
- Download openwrt-mediatek-mt7622-dlink_eagle-pro-ai-r32-a1-squashfs-recovery.bin
Flashing via uBoot:
- Open the case, connect to the UART console
- Set your IP address to 10.10.10.3, subnet mask 255.255.255.0. Connect to one of the LAN interfaces of the router
- Run a tftp server which provides openwrt-mediatek-mt7622-dlink_eagle-pro-ai-r32-initramfs-kernel.bin.
- You can rename the file to iverson_uImage (no extension), then you don't have to enter the whole file name in uboot later.
- Power on the device and select "1. System Load Linux to SDRAM via TFTP." in the boot menu
- Enter image file, tftp server IP and device IP (if they differ from the default).
- TFTP download to RAM will start. After a few seconds OpenWrt initramfs should start
- The initramfs is accessible via 192.168.1.1, change your IP address accordingly (or use multiple IP addresses on your interface)
- Create a backup of the Kernel1 partition, this file is required if a revert to stock should be done later
- Perform a sysupgrade using openwrt-mediatek-mt7622-dlink_eagle-pro-ai-r32-squashfs-sysupgrade.bin
- Reboot the device. OpenWrt should start from flash now
Revert back to stock using the Recovery Web Interface:
- Set your IP address to 192.168.0.10, subnetmask 255.255.255.0
- Press the reset button while powering on the deivce
- Keep the reset button pressed until the internet LED blinks fast
- Open a Chromium based and goto http://192.168.0.1
- Flash a decrypted firmware image from D-Link. Decrypting an firmware image is described below.
Decrypting a D-Link firmware image:
- Download https://github.com/RolandoMagico/firmware-utils/blob/M32/src/m32-firmware-util.c
- Compile a binary from the downloaded file, e.g. gcc m32-firmware-util.c -lcrypto -o m32-firmware-util
- Run ./m32-firmware-util R32 --DecryptFactoryImage <OriginalFirmware> <OutputFile>
- Example for firmware R32A1_FW103B01: ./m32-firmware-util R32 --DecryptFactoryImage R32A1_FW103B01.bin R32A1_FW103B01.decrypted.bin
Revert back to stock using uBoot:
- Open the case, connect to the UART console
- Set your IP address to 10.10.10.3, subnet mask 255.255.255.0. Connect to one of the LAN interfaces of the router
- Run a tftp server which provides the previously created backup of the Kernel1 partition.
- You can rename the file to iverson_uImage (no extension), then you don't have to enter the whole file name in uboot later.
- Power on the device and select "2. System Load Linux Kernel then write to Flash via TFTP." in the boot menu
- Enter image file, tftp server IP and device IP (if they differ from the default).
- TFTP download to FLASH will start. After a few seconds the stock firmware should start again
There is also an image openwrt-mediatek-mt7622-dlink_eagle-pro-ai-r32-a1-squashfs-tftp.bin which can directly be flashed via U-Boot and TFTP.
It can be used if no backup of the Kernel1 partition is reuqired.
Flahsing via OEM web interface is currently not possible, the OEM images are encrypted. Creating images is only possible manually at the moment.
The support for the M32/R32 already includes support for flashing from the OEM web interface:
- The device tree contains both partitions (Kernel1 and Kernel2) with conditions to select the correct one based on the kernel command line
- The U-Boot variable "boot_part" is set accordingly during startup to finish the partition swap after flashing from the OEM web interface
- OpenWrt sysupgrade flashing always uses the partition where it was initially flashed to (no partition swap)
Signed-off-by: Roland Reinl <reinlroland+github@gmail.com>
(based on support for ASUS RT-AX59U by liushiyou006)
SOC: MediaTek MT7986
RAM: 512MB DDR4
FLASH: 128MB SPI-NAND (Winbond W25N01GV)
WIFI: Mediatek MT7986 DBDC 802.11ax 2.4/5 GHz
ETH: MediaTek MT7531 Switch
UART: 3V3 115200 8N1 (Pinout silkscreened / Do not connect VCC)
Upgrade from AsusWRT to OpenWRT using UART
Download the OpenWrt initramfs image.
Copy the image to a TFTP server reachable at 192.168.1.70/24. Rename the image to rtax59u.bin.
Connect the PC with TFTP server to the RT-AX59U.
Set a static ip on the ethernet interface of your PC.
(ip address: 192.168.1.70, subnet mask:255.255.255.0)
Conect to the serial console, interrupt the autoboot process by pressing '4' when prompted.
Download & Boot the OpenWrt initramfs image.
$ setenv ipaddr 192.168.1.1
$ setenv serverip 192.168.1.70
$ tftpboot 0x46000000 rtax59u.bin
$ bootm 0x46000000
Wait for OpenWrt to boot. Transfer the sysupgrade image to the device using scp and install using sysupgrade.
$ sysupgrade -n <path-to-sysupgrade.bin>
Upgrade from AsusWRT to OpenWRT using WebUI
Download transit TRX file from https://drive.google.com/drive/folders/1A20QdjK7Udagu31FSszpWAk8-cGlCwsq
Upgrade firmware from WebUI (192.168.50.1) using downloaded TRX file
Wait for OpenWRT to boot (192.168.1.1).
Upgrade system with sysupgrade image using luci or uploading it through scp and executing sysupgrade command
MAC Address for WLAN 5g is not following the same algorithm as in AsusWRT.
We have increased by one the WLAN 5g to avoid collisions with other networks from WLAN 2g
when bit 28 is already set.
: Stock : OpenWrt
WLAN 2g (1) : C8:xx:xx:0D:xx:D4 : C8:xx:xx:0D:xx:D4
WLAN 2g (2) : : CA:xx:xx:0D:xx:D4
WLAN 2g (3) : : CE:xx:xx:0D:xx:D4
WLAN 5g (1) : CA:xx:xx:1D:xx:D4 : CA:xx:xx:1D:xx:D5
WLAN 5g (2) : : CE:xx:xx:1D:xx:D5
WLAN 5g (3) : : C2:xx:xx:1D:xx:D5
WLAN 2g (1) : 08:xx:xx:76:xx:BE : 08:xx:xx:76:xx:BE
WLAN 2g (2) : : 0A:xx:xx:76:xx:BE
WLAN 2g (3) : : 0E:xx:xx:76:xx:BE
WLAN 5g (1) : 0A:xx:xx:76:xx:BE : 0A:xx:xx:76:xx:BF
WLAN 5g (2) : : 0E:xx:xx:76:xx:BF
WLAN 5g (3) : : 02:xx:xx:76:xx:BF
Signed-off-by: Xavier Franquet <xavier@franquet.es>
Specifications:
SoC: MediaTek MT7981B
RAM: 256MiB
Flash: SPI-NAND 128 MiB
Switch: 1 WAN, 3 LAN (Gigabit)
Buttons: Reset, Mesh
Power: DC 12V 1A
WiFi: MT7976CN
UART: 115200n8
UART Layout:
VCC-RX-TX-GND
No. of Antennas: 6
Note: Upon opening the router, only 5 antennas were connected
to the mainboard.
Led Layout:
Power-Mesh-5gwifi-WAN-LAN3-LAN2-LAN1-2gWiFi
Buttons:
Reset-Mesh
Installation:
A. Through OpenWrt Dashboard:
If your router comes with OpenWrt preinstalled (modified by the seller),
you can easily upgrade by going to the dashboard (192.168.1.1) and then
navigate to System -> Backup/Flash firmware, then flash the firmware
B. Through TFTP
Standard installation via UART:
1. Connect USB Serial Adapter to the UART, (NOTE: Don't connect the VCC pin).
2. Power on the router. Make sure that you can access your router via UART.
3. Restart the router then repeatedly press ctrl + c to skip default boot.
4. Type > bootmenu
5. Press '2' to select upgrade firmware
6. Press 'Y' on 'Run image after upgrading?'
7. Press '0' and hit 'enter' to select TFTP client (default)
8. Fill the U-Boot's IP address and TFTP server's IP address.
9. Finally, enter the 'firmware' filename.
Signed-off-by: Ian Oderon <ianoderon@gmail.com>
Rostelecom RT-FE-1A is a wireless WiFi 5 router manufactured by Sercomm
company.
Device specification
--------------------
SoC Type: MediaTek MT7621AT
RAM: 256 MiB
Flash: 128 MiB
Wireless 2.4 GHz (MT7603EN): b/g/n, 2x2
Wireless 5 GHz (MT7615E): a/n/ac, 4x4
Ethernet: 5x GbE (WAN, LAN1, LAN2, LAN3, LAN4)
USB ports: No
Button: 2 buttons (Reset & WPS)
LEDs:
- 1x Power (green, unmanaged)
- 1x Status (green, gpio)
- 1x 2.4G (green, hardware, mt76-phy0)
- 1x 2.4G (blue, gpio)
- 1x 5G (green, hardware, mt76-phy1)
- 1x 5G (blue, gpio)
- 5x Ethernet (green, hardware, 4x LAN & WAN)
Power: 12 VDC, 1.5 A
Connector type: barrel
Bootloader: U-Boot
Installation
-----------------
1. Login to the router web interface (default http://192.168.0.1/)
under "admin" account
2. Navigate to Settings -> Configuration -> Save to Computer
3. Decode the configuration. For example, using cfgtool.py tool (see
related section):
cfgtool.py -u configurationBackup.cfg
4. Open configurationBackup.xml and find the following block:
<OBJECT name="User." type="object" writable="1" encryption="0" >
<OBJECT name="1." type="object" writable="1" encryption="0" >
<PARAMETER name="Password" type="string" value="<some value>" writable="1" encryption="1" password="1" />
</OBJECT>
5. Replace <some value> by a new superadmin password and add a line
which enabling superadmin login after. For example, the block after
the changes:
<OBJECT name="User." type="object" writable="1" encryption="0" >
<OBJECT name="1." type="object" writable="1" encryption="0" >
<PARAMETER name="Password" type="string" value="s0meP@ss" writable="1" encryption="1" password="1" />
<PARAMETER name="Enable" type="boolean" value="1" writable="1" encryption="0"/>
</OBJECT>
6. Encode the configuration. For example, using cfgtool.py tool:
cfgtool.py -p configurationBackup.xml
7. Upload the changed configuration (configurationBackup_changed.cfg) to
the router
8. Login to the router web interface (superadmin:xxxxxxxxxx, where
xxxxxxxxxx is a new password from the p.5)
9. Enable SSH access to the router (Settings -> Access control -> SSH)
10. Connect to the router using SSH shell using superadmin account
11. Run in SSH shell:
sh
12. Make a mtd backup (optional, see related section)
13. Change bootflag to Sercomm1 and reboot:
printf 1 | dd bs=1 seek=7 count=1 of=/dev/mtdblock3
reboot
14. Login to the router web interface under admin account
15. Remove dots from the OpenWrt factory image filename
16. Update firmware via web using OpenWrt factory image
Revert to stock
---------------
Change bootflag to Sercomm1 in OpenWrt CLI and then reboot:
printf 1 | dd bs=1 seek=7 count=1 of=/dev/mtdblock3
mtd backup
----------
1. Set up a tftp server (e.g. tftpd64 for windows)
2. Connect to a router using SSH shell and run the following commands:
cd /tmp
for i in 0 1 2 3 4 5 6 7 8 9; do nanddump -f mtd$i /dev/mtd$i; \
tftp -l mtd$i -p 192.168.0.2; md5sum mtd$i >> mtd.md5; rm mtd$i; done
tftp -l mtd.md5 -p 192.168.0.2
MAC Addresses
-------------
+-----+------------+---------+
| use | address | example |
+-----+------------+---------+
| LAN | label | f4:*:66 |
| WAN | label + 11 | f4:*:71 |
| 2g | label + 2 | f4:*:68 |
| 5g | label + 3 | f4:*:69 |
+-----+------------+---------+
The label MAC address was found in Factory, 0x21000
cfgtool.py
----------
A tool for decoding and encoding Sercomm configs.
Link: https://github.com/r3d5ky/sercomm_cfg_unpacker
Signed-off-by: Mikhail Zhilkin <csharper2005@gmail.com>
The previous offsets did also work, as they've wrapped back to 0x0.
However, in reality the environment starts at offset 0x0 of the
u-boot-env MMC partition.
Signed-off-by: David Bauer <mail@david-bauer.net>
Hardware
--------
SoC: MediaTek MT7981BA
RAM: 1GB DDR4 (NANYA NT5AD512M16C4-JR)
MMC: 8GB eMMC (Samsung 8GTF4R)
ETH: 1000Base-T LAN (ePHY)
2500Base-T WAN (MaxLinear GPY211C)
BTN: 1x Reset Button
LED: System (blue/white)
VPN (white)
USB: 1x USB-A (USB 3.0)
UART: 115200 8N1 - Pinout on board next to LAN port
Don't connect 3.3V!
Known Issues
------------
U-Boot vendor recovery does not seem to accept any images, neither
GL.iNet images nor OpenWrt images. Recovery requires serial access!
Installation
------------
Upload the OpenWrt sysupgrade image to the Gl.iNet Web-UI. Make sure to
not retain existing settings.
Signed-off-by: David Bauer <mail@david-bauer.net>
D-Link DAP-1720 rev A1 is a mains-powered AC1750 Wi-Fi range extender,
manufactured by Alpha Networks [8WAPAC28.1A1G].
(in square brackets: PCB silkscreen markings)
Specifications:
* CPU (Qualcomm Atheros QCA9563-AL3A [U5]):
775 MHz single core MIPS 74Kc;
* RAM (Winbond W9751G6KB-25J [U3]):
64 MiB DDR2;
* ROM (Winbond W25Q128FV [U16]):
16 MiB SPI NOR flash;
* Ethernet (AR8033-AL1A PHY [U1], no switch):
1 GbE RJ45 port (no PHY LEDs);
* Wi-Fi
* 2.4 GHz (Qualcomm Atheros QCA9563-AL3A [U5]):
3x3 802.11n;
* 5 GHz (Qualcomm Atheros QCA9880-BR4A [U9]):
3x3 802.11ac Wave 1;
* 3 foldable dual-band antennas (U.fl) [P1],[P2],[P3];
* GPIO LEDs:
* RSSI low (red/green) [D2];
* RSSI medium (green) [D3];
* RSSI high (green) [D4];
* status (red/green) [D5];
* GPIO buttons:
* WPS [SW1], co-located with status LED;
* reset [SW4], accessible via hole in the side;
* Serial/UART:
Tx-Gnd-3v3-Rx [JP1], Tx is the square pin, 1.25mm pitch;
125000-8-n-1 in U-boot, 115200-8-n-1 in kernel;
* Misc:
* 12V VCC [JP2], fed from internal 12V/1A AC to DC converter;
* on/off slide switch [SW2] (disconnects VCC mechanically);
* unpopulated footprints for a Wi-Fi LED [D1];
* unpopulated footprints for a 4-pin 3-position slide switch (SW3);
MAC addresses:
* Label = LAN;
* 2.4 GHz WiFi = LAN;
* 5 GHz WiFi = LAN+2;
Installation:
* `factory.bin` can be used to install OpenWrt from OEM firmware via the
standard upgrade webpage at http://192.168.0.50/UpdateFirmware.html
* `recovery.bin` can be used to install OpenWrt (or revert to OEM
firmware) from D-Link Web Recovery. To enter web recovery, keep reset
button pressed and then power on the device. Reset button can be
released when the red status LED is bright; it will then blink slowly.
Set static IP to 192.168.0.10, navigate to http://192.168.0.50 and
upload 'recovery.bin'. Note that in web recovery mode the device
ignores ping and DHCP requests.
Note: 802.11s is not supported by the default `ath10k` driver and
firmware, but is supported by the non-CT driver and firmware variants.
The `-smallbuffers` driver variant is recommended due to RAM size.
Co-developed-by: Anthony Sepa <protectivedad@gmail.com>
Signed-off-by: Rani Hod <rani.hod@gmail.com>
The ubootmod bootlaoder for EX5601-T0 uses two partitions
in ubi to store enviroment variables. so proper config
is needed.
Signed-off-by: Nicolò Veronese <nicveronese@gmail.com>
Specifications:
SoC: MediaTek MT7981B
RAM: 1024MiB
Flash: SPI-NAND 128 MiB
Switch: 1 WAN, 4 LAN (Gigabit)
USB: two M.2 slots for 5G modems via USB 3.0 hub, external USB 3.0 port
Buttons: Reset, Mesh
Power: DC 12V 1A
WiFi: MT7976CN
UART: 115200n8
UART Layout:
VCC-RX-TX-GND
Installation:
A. Through OpenWrt Dashboard:
If your router comes with OpenWrt preinstalled (modified by the seller),
you can easily upgrade by going to the dashboard (192.168.1.1) and then
navigate to System -> Backup/Flash firmware, then flash the firmware
B. Through TFTP
Standard installation via UART:
1. Connect USB Serial Adapter to the UART, (NOTE: Don't connect the VCC pin).
2. Power on the router. Make sure that you can access your router via UART.
3. Restart the router then repeatedly press ctrl + c to skip default boot.
4. Type > bootmenu
5. Press '2' to select upgrade firmware
6. Press 'Y' on 'Run image after upgrading?'
7. Press '0' and hit 'enter' to select TFTP client (default)
8. Fill the U-Boot's IP address and TFTP server's IP address.
9. Finally, enter the 'firmware' filename.
Based on patch adding support for similar Zbtlink ZBT-Z8103AX device by
Ian Ishmael C. Oderon.
Signed-off-by: Daniel Golle <daniel@makrotopia.org>
Specifications:
SoC: QCA9531(650MHz)
RAM: DDR2 128M
Flash: SPI NOR 16M + SPI NAND 128M
WiFi: 2.4GHz with 2 antennas(WiFi/Thread)
Ethernet:
1xLAN(10/100M)
2xWAN(10/100M)
Button: 1x Reset Button
Switch: 1x Mode switch
LED: 1x Blue LED + 1x White LED + 1x Orange LED
IOT: Thread + ZigBee/Zwave
By uboot web failsafe:
Push the reset button for 5 seconds util the power led flash faster,
then use broswer to access http://192.168.1.1
Afterwards upgrade can use sysupgrade image.
Signed-off-by: Weiping Yang <weiping.yang@gl-inet.com>
```
Specifications:
* CPU: Qualcomm IPQ8074A, SoC Version: 2.0, Quad core 1651 MHz
* RAM: 1 GiB of DDR3 466 MHz
* Flash: NAND 512 MiB (Winbond W29N04GZ)
* 6 RGB LEDs: Power, LAN1, LAN2, 2.4GHz, 5GHz H and 5GHz L
* UART: One 4-pin populated header next to the heatsink and a chip.
GND RXD TXD, beginning from the external antennas. 115200n8.
Lan:
* One 100/1000/2.5GBASE-T Gigabit Ethernet 802.3bt/at
* One 100/1000 Gigabit Ethernet
Wlan:
* 4x4 in 2.4GHz : 802.11b/g/n/ax
* 4x4 in 5.0GHz L: 802.11a/n/ac/ax
* 4x4 in 5.0GHz H: 802.11a/n/ac/ax
* OFDM and OFDMA
* Bidir and MU-MIMO
* Internal antenna 2.86/4.41/4.98 dBi (2.4GHz/5GHz L/5GHz H)
Power:
* 802.3bt/at 30.1W
* DC 12V/3.5A
Mounting: Wall and ceiling
```
```
1. Download the OpenWrt initramfs image. Copy the image to a TFTP server
2. Connect to the console on the AP, and connect the LAN port to your LAN
3. Stop auto boot to get to U-boot shell, interrupt the autoboot process by pressing '0' when prompted
4. Set active_fw in env
4. Set active_fw in env
# setenv active_fw 1
5. Transfer the initramfs image with TFTP
# setenv serverip 192.168.1.10 (IP of TFTP server host)
# setenv ipaddr 192.168.1.1 (IP used by the router for getting the image, must be in the same subnet as the TFTP host)
# tftpboot openwrt-qualcommax-ipq807x-netgear_wax630-initramfs-uImage.itb
6. Reboot and load the image
# bootm
7. SCP factory image to the AP
# scp openwrt-qualcommax-ipq807x-netgear_wax630-squashfs-factory.ubi root@192.168.1.1:/tmp/
8. Connect to device using SSH (use the LAN port)
9. Flash squashfs-factory.ubi from within the initramfs instance of OpenWRT
Before you flash, please check your mtd partitions where mtdX is the right mtd rootfs partition.
# cat /proc/mtd (To check MTD partitions)
# ubiformat /dev/mtd18 -y -f /tmp/openwrt-qualcommax-ipq807x-netgear_wax630-squashfs-factory.ubi
10. Set active_fw to 0
# /usr/sbin/fw_setenv active_fw 0
11. Reboot the AP and your done
# reboot
```
Reviewed-by: Robert Marko <robimarko@gmail.com>
Signed-off-by: Kristian Skramstad <kristian+github@83.no>
Hardware specification:
SoC: MediaTek MT7981B 2x A53
Flash: 64GB eMMC or 128 MB SPI-NAND
RAM: 512MB
Ethernet: 4x 10/100/1000 Mbps
Switch: MediaTek MT7531AE
WiFi: MediaTek MT7976C
Button: Reset, Mesh
Power: DC 12V 1A
- UART: 3.3v, 115200n8
--------------------------
| Layout |
| ----------------- |
| 4 | GND TX VCC RX | <= |
| ----------------- |
--------------------------
Gain SSH access:
1. Login into web interface, and download the configuration.
2. Enter fakeroot, decompress the configuration:
tar -zxf cfg_export_config_file.conf
3. Edit 'etc/config/dropbear', set 'enable' to '1'.
4. Edit 'etc/shadow', update (remove) root password:
'root::19523:0:99999:7:::'
5. Repack 'etc' directory:
tar -zcf cfg_export_config_file.conf etc/
* If you find an error about 'etc/wireless/mediatek/DBDC_card0.dat',
just ignore it.
6. Upload new configuration via web interface, now you can SSH to RAX3000M.
Check stroage type:
Check the label on the back of the device:
"CH EC CMIIT ID: xxxx" is eMMC version
"CH CMIIT ID: xxxx" is NAND version
eMMC Flash instructions:
1. SSH to RAX3000M, and backup everything, especially 'factory' part.
('data' partition can be ignored, it's useless.)
2. Write new GPT table:
dd if=openwrt-mediatek-filogic-cmcc_rax3000m-emmc-gpt.bin of=/dev/mmcblk0 bs=512 seek=0 count=34 conv=fsync
3. Erase and write new BL2:
echo 0 > /sys/block/mmcblk0boot0/force_ro
dd if=/dev/zero of=/dev/mmcblk0boot0 bs=512 count=8192 conv=fsync
dd if=openwrt-mediatek-filogic-cmcc_rax3000m-emmc-preloader.bin of=/dev/mmcblk0boot0 bs=512 conv=fsync
4. Erase and write new FIP:
dd if=/dev/zero of=/dev/mmcblk0 bs=512 seek=13312 count=8192 conv=fsync
dd if=openwrt-mediatek-filogic-cmcc_rax3000m-emmc-bl31-uboot.fip of=/dev/mmcblk0 bs=512 seek=13312 conv=fsync
5. Set static IP on your PC:
IP 192.168.1.254, GW 192.168.1.1
6. Serve OpenWrt initramfs image using TFTP server.
7. Cut off the power and re-engage, wait for TFTP recovery to complete.
8. After OpenWrt has booted, perform sysupgrade.
9. Additionally, if you want to have eMMC recovery boot feature:
(Don't worry! You will always have TFTP recovery boot feature.)
dd if=openwrt-mediatek-filogic-cmcc_rax3000m-initramfs-recovery.itb of=/dev/mmcblk0p4 bs=512 conv=fsync
NAND Flash instructions:
1. SSH to RAX3000M, and backup everything, especially 'Factory' part.
2. Erase and write new BL2:
mtd erase BL2
mtd write openwrt-mediatek-filogic-cmcc_rax3000m-nand-preloader.bin BL2
3. Erase and write new FIP:
mtd erase FIP
mtd write openwrt-mediatek-filogic-cmcc_rax3000m-nand-bl31-uboot.fip FIP
4. Set static IP on your PC:
IP 192.168.1.254, GW 192.168.1.1
5. Serve OpenWrt initramfs image using TFTP server.
6. Cut off the power and re-engage, wait for TFTP recovery to complete.
7. After OpenWrt has booted, erase UBI volumes:
ubidetach -p /dev/mtd0
ubiformat -y /dev/mtd0
ubiattach -p /dev/mtd0
8. Create new ubootenv volumes:
ubimkvol /dev/ubi0 -n 0 -N ubootenv -s 128KiB
ubimkvol /dev/ubi0 -n 1 -N ubootenv2 -s 128KiB
9. Additionally, if you want to have NAND recovery boot feature:
(Don't worry! You will always have TFTP recovery boot feature.)
ubimkvol /dev/ubi0 -n 2 -N recovery -s 20MiB
ubiupdatevol /dev/ubi0_2 openwrt-mediatek-filogic-cmcc_rax3000m-initramfs-recovery.itb
10. Perform sysupgrade.
Signed-off-by: Tianling Shen <cnsztl@immortalwrt.org>
Extreme Networks AP3935i/e -
https://www.extremenetworks.com/support/documentation/access-points-ap3935i-e/
SoC: IPQ8068 QYY AT46279K45060I
RAM: NANYA 1527 NT5CC256M16DP-DI 515073W0EF 7 TW
FLASH: NOR - S25FL256S1 - 32MB
NAND - Macronix MX30UF4G28AB - 512MB
LAN: Atheros AR8035-A J5150WL 1515 CN - RGMII
LAN2: Atheros AR8033-AL1A SKCSR.AJ1 1444 China - SGMII
WLAN2: QCA9990 OVV FNPV209 K451406
WLAN5: QCA9990 OVV FNPV209 K451406
SERIAL: RS232 Port (115200 8n1) Cisco console cable and
4pin Serial Header | 3.3 | GND | RX | TX
MAC address for LAN1/LAN2/WLAN 2G/WLAN 5G in uboot env
* Installation via either RJ45 console or on-board 4 PIN header
Install Method
--------------
1) Setup TFTP server, and place
openwrt-ipq806x-generic-extreme_ap3935-initramfs-uImage image
in /srv/tftp or similar
2) Connect to console on router and connect ethernet port "LAN1" to
your LAN
3) Interupt the boot with any character
4) Login with admin/new2day for default password
(use reset/FactoryDefault if password needs to be reset)
5) Set serverip to TFTP IP: set serverip 192.168.1.2
6) Set ipaddr to another IP: set ipaddr 192.168.1.101
7) Make uboot ping something to activate eth0 on boot:
set bootcmd 'ping 192.168.1.1; run boot_flash'
saveenv
8) TFTP image to RAM:
tftpboot 0x42000000
openwrt-ipq806x-generic-extreme_ap3935i-initramfs-uImage
9) Boot image: bootm 0x42000000
In OpenWRT, "LAN1" is LAN, "LAN2" is WAN
10) SFTP openwrt-ipq806x-generic-extreme_ap3935-squashfs-nand-sysupgrade.bin
image to /tmp
11) sysupgrade /tmp/openwrt-*-nand-sysupgrade.bin
Signed-off-by: Glen Lee <g2lee@yahoo.com>
```
Specifications:
* CPU: Qualcomm IPQ8072A, SoC Version: 2.0, Quad core Cortex-A53 1.6896 GHz
* RAM: 1 GiB of DDR4 600 MHz
* Flash: NAND 2x256 MiB (Macronix MX30UF2G18AC)
* 4 RGB LEDs: Power, LAN, 2.4GHz and 5GHz
* UART: Two 4-pin unpopulated headers under the LEDs.
Use the header closest to LED 4 and 5.
They are marked with a white stroke.
TX RX GND, beginning from "4". 115200n8.
Lan:
* One 100/1000/2.5GBASE-T Gigabit Ethernet (QCA8081)
Wlan:
* 4x4 in 2.4GHz: 802.11b/g/n/ax
* 4x4 in 5.0GHz: 802.11a/n/ac/ax
* OFDM and OFDMA
* Bidir and MU-MIMO
* Internal antenna 3.1/4.3 dBi (2.4GHz/5GHz)
Power:
* PoE+ 802.3at/af 25.5W
* DC 12V 2.5A
```
```
Note: The OpenWrt image is setup with DHCP and not a static IP.
1. Download the OpenWrt initramfs image. Copy the image to a TFTP server
2. Connect to console on the AP, and connect the LAN port to your LAN
3. Stop auto boot to get to U-boot shell, interrupt the autoboot process by pressing '0' when prompted
4. Set active_fw in env
# setenv active_fw 1
5. Transfer the initramfs image with TFTP
# setenv serverip 192.168.1.10 (IP of TFTP server host)
# setenv ipaddr 192.168.1.1 (IP used by the router for getting the image, must be in the same subnet as the TFTP host)
# tftpboot openwrt-qualcommax-ipq807x-netgear_wax620-initramfs-uImage.itb
6. Reboot and load the image
# bootm
7. SCP factory image to the AP
# scp openwrt-qualcommax-ipq807x-netgear_wax620-squashfs-factory.ubi root@192.168.1.1:/tmp/
8. Connect to device using SSH (use the LAN port)
9. Flash squashfs-factory.ubi from within the initramfs instance of OpenWRT
Before you flash, please check your mtd partitions where mtdX is the right mtd rootfs partition.
# cat /proc/mtd (To check MTD partitions)
# ubiformat /dev/mtd19 -y -f /tmp/openwrt-qualcommax-ipq807x-netgear_wax620-squashfs-factory.ubi
10. Set active_fw to 0
# /usr/sbin/fw_setenv active_fw 0
11. Reboot the AP and your done
# reboot
```
Signed-off-by: Kristian Skramstad <kristian+github@83.no>
