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300 Commits
Author | SHA1 | Message | Date | |
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Andreas Böhler
|
097f350aeb |
ath79: add support for Alcatel HH40V
The Alcatel HH40V is a CAT4 LTE router used by various ISPs. Specifications ============== SoC: QCA9531 650MHz RAM: 128MiB Flash: 32MiB SPI NOR LAN: 1x 10/100MBit WAN: 1x 10/100MBit LTE: MDM9607 USB 2.0 (rndis configuration) WiFi: 802.11n (SoC integrated) MAC address assignment ====================== There are three MAC addresses stored in the flash ROM, the assignment follows stock. The MAC on the label is the WiFi MAC address. Installation (TFTP) =================== 1. Connect serial console 2. Configure static IP to 192.168.1.112 3. Put OpenWrt factory.bin file as firmware-system.bin 4. Press Power + WPS and plug in power 5. Keep buttons pressed until TFTP requests are visible 6. Wait for the system to finish flashing and wait for reboot 7. Bootup will fail as the kernel offset is wrong 8. Run "setenv bootcmd bootm 0x9f150000" 9. Reset board and enjoy OpenWrt Installation (without UART) =========================== Installation without UART is a bit tricky and requires several steps too long for the commit message. Basic steps: 1. Create configure backup 2. Patch backup file to enable SSH 3. Login via SSH and configure the new bootcmd 3. Flash OpenWrt factory.bin image manually (sysupgrade doesn't work) More detailed instructions will be provided on the Wiki page. Tested by: Christian Heuff <christian@heuff.at> Signed-off-by: Andreas Böhler <dev@aboehler.at> |
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Martin Kennedy
|
12f52336d2 |
ath79: Add Aruba AP-175 support
This board is very similar to the Aruba AP-105, but is outdoor-first. It is very similar to the MSR2000 (though certain MSR2000 models have a different PHY[^1]). A U-Boot replacement is required to install OpenWrt on these devices[^2]. Specifications -------------- * Device: Aruba AP-175 * SoC: Atheros AR7161 680 MHz MIPS * RAM: 128MB - 2x Mira P3S12D40ETP * Flash: 16MB MXIC MX25L12845EMI-10G (SPI-NOR) * WiFi: 2 x DNMA-H92 Atheros AR9220-AC1A 802.11abgn * ETH: IC+ IP1001 Gigabit + PoE PHY * LED: 2x int., plus 12 ext. on TCA6416 GPIO expander * Console: CP210X linking USB-A Port to CPU console @ 115200 * RTC: DS1374C, with internal battery * Temp: LM75 temperature sensor Factory installation: - Needs a u-boot replacement. The process is almost identical to that of the AP105, except that the case is easier to open, and that you need to compile u-boot from a slightly different branch: https://github.com/Hurricos/u-boot-ap105/tree/ap175 The instructions for performing an in-circuit reflash with an SPI-Flasher like a CH314A can be found on the OpenWrt Wiki (https://openwrt.org/toh/aruba/ap-105); in addition a detailed guide may be found on YouTube[^3]. - Once u-boot has been replaced, a USB-A-to-A cable may be used to connect your PC to the CP210X inside the AP at 115200 baud; at this point, the normal u-boot serial flashing procedure will work (set up networking; tftpboot and boot an OpenWrt initramfs; sysupgrade to OpenWrt proper.) - There is no built-in functionality to revert back to stock firmware, because the AP-175 has been declared by the vendor[^4] end-of-life as of 31 Jul 2020. If for some reason you wish to return to stock firmware, take a backup of the 16MiB flash before flashing u-boot. [^1]: https://github.com/shalzz/aruba-ap-310/blob/master/platform/bootloader/apboot-11n/include/configs/msr2k.h#L186 [^2]: https://github.com/Hurricos/u-boot-ap105/tree/ap175 [^3]: https://www.youtube.com/watch?v=Vof__dPiprs [^4]: https://www.arubanetworks.com/support-services/end-of-life/#product=access-points&version=0 Signed-off-by: Martin Kennedy <hurricos@gmail.com> |
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Edward Chow
|
de3d60b982 |
ath79: calibrate dlink dir-825 b1 with nvmem
Driver for both soc (2.4GHz Wifi) and pci (5 GHz) now pull the calibration data from the nvmem subsystem. This allows us to move the userspace caldata extraction for the pci-e ath9k supported wifi into the device-tree definition of the device. Currently, only ethernet devices uses the mac address of "mac-address-ascii" cells, while PCI ath9k devices uses the mac address within calibration data. Signed-off-by: Edward Chow <equu@openmail.cc> (restored switch configuration in 02_network, integrated caldata into partition) Signed-off-by: Christian Lamparter <chunkeey@gmail.com> |
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Lech Perczak
|
0eebc6f0dd |
ath79: support Ruckus ZoneFlex 7341/7343/7363
Ruckus ZoneFlex 7363 is a dual-band, dual-radio 802.11n 2x2 MIMO enterprise access point. ZoneFlex 7343 is the single band variant of 7363 restricted to 2.4GHz, and ZoneFlex 7341 is 7343 minus two Fast Ethernet ports. Hardware highligts: - CPU: Atheros AR7161 SoC at 680 MHz - RAM: 64MB DDR - Flash: 16MB SPI-NOR - Wi-Fi 2.4GHz: AR9280 PCI 2x2 MIMO radio with external beamforming - Wi-Fi 5GHz: AR9280 PCI 2x2 MIMO radio with external beamforming - Ethernet 1: single Gigabit Ethernet port through Marvell 88E1116R gigabit PHY - Ethernet 2: two Fast Ethernet ports through Realtek RTL8363S switch, connected with Fast Ethernet link to CPU. - PoE: input through Gigabit port - Standalone 12V/1A power input - USB: optional single USB 2.0 host port on the -U variants. Serial console: 115200-8-N-1 on internal H1 header. Pinout: H1 ---------- |1|x3|4|5| ---------- Pin 1 is near the "H1" marking. 1 - RX x - no pin 3 - VCC (3.3V) 4 - GND 5 - TX Installation: - Using serial console - requires some disassembly, 3.3V USB-Serial adapter, TFTP server, and removing a single PH1 screw. 0. Connect serial console to H1 header. Ensure the serial converter does not back-power the board, otherwise it will fail to boot. 1. Power-on the board. Then quickly connect serial converter to PC and hit Ctrl+C in the terminal to break boot sequence. If you're lucky, you'll enter U-boot shell. Then skip to point 3. Connection parameters are 115200-8-N-1. 2. Allow the board to boot. Press the reset button, so the board reboots into U-boot again and go back to point 1. 3. Set the "bootcmd" variable to disable the dual-boot feature of the system and ensure that uImage is loaded. This is critical step, and needs to be done only on initial installation. > setenv bootcmd "bootm 0xbf040000" > saveenv 4. Boot the OpenWrt initramfs using TFTP. Replace IP addresses as needed. Use the Gigabit interface, Fast Ethernet ports are not supported under U-boot: > setenv serverip 192.168.1.2 > setenv ipaddr 192.168.1.1 > tftpboot 0x81000000 openwrt-ath79-generic-ruckus_zf7363-initramfs-kernel.bin > bootm 0x81000000 5. Optional, but highly recommended: back up contents of "firmware" partition: $ ssh root@192.168.1.1 cat /dev/mtd1 > ruckus_zf7363_fw_backup.bin 6. Copy over sysupgrade image, and perform actual installation. OpenWrt shall boot from flash afterwards: $ ssh root@192.168.1.1 # sysupgrade -n openwrt-ath79-generic-ruckus_zf7363-squashfs-sysupgrade.bin After unit boots, it should be available at the usual 192.168.1.1/24. Return to factory firmware: 1. Copy over the backup to /tmp, for example using scp 2. Unset the "bootcmd" variable: fw_setenv bootcmd "" 3. Use sysupgrade with force to restore the backup: sysupgrade -F ruckus_zf7363_backup.bin 4. System will reboot. Quirks and known issues: - Fast Ethernet ports on ZF7363 and ZF7343 are supported, but management features of the RTL8363S switch aren't implemented yet, though the switch is visible over MDIO0 bus. This is a gigabit-capable switch, so link establishment with a gigabit link partner may take a longer time because RTL8363S advertises gigabit, and the port magnetics don't support it, so a downshift needs to occur. Both ports are accessible at eth1 interface, which - strangely - runs only at 100Mbps itself. - Flash layout is changed from the factory, to use both firmware image partitions for storage using mtd-concat, and uImage format is used to actually boot the system, which rules out the dual-boot capability. - Both radio has its own EEPROM on board, not connected to CPU. - The stock firmware has dual-boot capability, which is not supported in OpenWrt by choice. It is controlled by data in the top 64kB of RAM which is unmapped, to avoid the interference in the boot process and accidental switch to the inactive image, although boot script presence in form of "bootcmd" variable should prevent this entirely. - On some versions of stock firmware, it is possible to obtain root shell, however not much is available in terms of debugging facitilies. 1. Login to the rkscli 2. Execute hidden command "Ruckus" 3. Copy and paste ";/bin/sh;" including quotes. This is required only once, the payload will be stored in writable filesystem. 4. Execute hidden command "!v54!". Press Enter leaving empty reply for "What's your chow?" prompt. 5. Busybox shell shall open. Source: https://alephsecurity.com/vulns/aleph-2019014 - There is second method to achieve root shell, using command injection in the web interface: 1. Login to web administration interface 2. Go to Administration > Diagnostics 3. Enter |telnetd${IFS}-p${IFS}204${IFS}-l${IFS}/bin/sh into "ping" field 4. Press "Run test" 5. Telnet to the device IP at port 204 6. Busybox shell shall open. Source: https://github.com/chk-jxcn/ruckusremoteshell Signed-off-by: Lech Perczak <lech.perczak@gmail.com> |
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Lech Perczak
|
694b8e6521 |
ath79: support Ruckus ZoneFlex 7351
Ruckus ZoneFlex 7351 is a dual-band, dual-radio 802.11n 2x2 MIMO enterprise access point. Hardware highligts: - CPU: Atheros AR7161 SoC at 680 MHz - RAM: 64MB DDR - Flash: 16MB SPI-NOR - Wi-Fi 2.4GHz: AR9280 PCI 2x2 MIMO radio with external beamforming - Wi-Fi 5GHz: AR9280 PCI 2x2 MIMO radio with external beamforming - Ethernet: single Gigabit Ethernet port through Marvell 88E1116R gigabit PHY - Standalone 12V/1A power input - USB: optional single USB 2.0 host port on the 7351-U variant. Serial console: 115200-8-N-1 on internal H1 header. Pinout: H1 ---------- |1|x3|4|5| ---------- Pin 1 is near the "H1" marking. 1 - RX x - no pin 3 - VCC (3.3V) 4 - GND 5 - TX Installation: - Using serial console - requires some disassembly, 3.3V USB-Serial adapter, TFTP server, and removing a single T10 screw. 0. Connect serial console to H1 header. Ensure the serial converter does not back-power the board, otherwise it will fail to boot. 1. Power-on the board. Then quickly connect serial converter to PC and hit Ctrl+C in the terminal to break boot sequence. If you're lucky, you'll enter U-boot shell. Then skip to point 3. Connection parameters are 115200-8-N-1. 2. Allow the board to boot. Press the reset button, so the board reboots into U-boot again and go back to point 1. 3. Set the "bootcmd" variable to disable the dual-boot feature of the system and ensure that uImage is loaded. This is critical step, and needs to be done only on initial installation. > setenv bootcmd "bootm 0xbf040000" > saveenv 4. Boot the OpenWrt initramfs using TFTP. Replace IP addresses as needed: > setenv serverip 192.168.1.2 > setenv ipaddr 192.168.1.1 > tftpboot 0x81000000 openwrt-ath79-generic-ruckus_zf7351-initramfs-kernel.bin > bootm 0x81000000 5. Optional, but highly recommended: back up contents of "firmware" partition: $ ssh root@192.168.1.1 cat /dev/mtd1 > ruckus_zf7351_fw_backup.bin 6. Copy over sysupgrade image, and perform actual installation. OpenWrt shall boot from flash afterwards: $ ssh root@192.168.1.1 # sysupgrade -n openwrt-ath79-generic-ruckus_zf7351-squashfs-sysupgrade.bin After unit boots, it should be available at the usual 192.168.1.1/24. Return to factory firmware: 1. Copy over the backup to /tmp, for example using scp 2. Unset the "bootcmd" variable: fw_setenv bootcmd "" 3. Use sysupgrade with force to restore the backup: sysupgrade -F ruckus_zf7351_backup.bin 4. System will reboot. Quirks and known issues: - Flash layout is changed from the factory, to use both firmware image partitions for storage using mtd-concat, and uImage format is used to actually boot the system, which rules out the dual-boot capability. - Both radio has its own EEPROM on board, not connected to CPU. - The stock firmware has dual-boot capability, which is not supported in OpenWrt by choice. It is controlled by data in the top 64kB of RAM which is unmapped, to avoid the interference in the boot process and accidental switch to the inactive image, although boot script presence in form of "bootcmd" variable should prevent this entirely. - On some versions of stock firmware, it is possible to obtain root shell, however not much is available in terms of debugging facitilies. 1. Login to the rkscli 2. Execute hidden command "Ruckus" 3. Copy and paste ";/bin/sh;" including quotes. This is required only once, the payload will be stored in writable filesystem. 4. Execute hidden command "!v54!". Press Enter leaving empty reply for "What's your chow?" prompt. 5. Busybox shell shall open. Source: https://alephsecurity.com/vulns/aleph-2019014 - There is second method to achieve root shell, using command injection in the web interface: 1. Login to web administration interface 2. Go to Administration > Diagnostics 3. Enter |telnetd${IFS}-p${IFS}204${IFS}-l${IFS}/bin/sh into "ping" field 4. Press "Run test" 5. Telnet to the device IP at port 204 6. Busybox shell shall open. Source: https://github.com/chk-jxcn/ruckusremoteshell Signed-off-by: Lech Perczak <lech.perczak@gmail.com> |
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Michael Pratt
|
f545caf001 |
ath79: convert Engenius EPG5000 radios to nvmem-cells
Use nvmem kernel subsystem to pull radio calibration data with the devicetree instead of userspace scripts. Existing blocks for caldata_extract are reordered alphabetically. MAC address is set using the hotplug script. Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Michael Pratt
|
f9c28222c8 |
ath79: add support for Senao Engenius ESR1200
FCC ID: A8J-ESR900 Engenius ESR1200 is an indoor wireless router with a gigabit ethernet switch, dual-band wireless, internal antenna plates, and a USB 2.0 port **Specification:** - QCA9557 SOC 2.4 GHz, 2x2 - QCA9882 WLAN PCIe mini card, 5 GHz, 2x2 - QCA8337N SW 4 ports LAN, 1 port WAN - 40 MHz clock - 16 MB FLASH MX25L12845EMI-10G - 2x 64 MB RAM - UART at J1 populated, RX grounded - 6 internal antenna plates (omni-directional) - 5 LEDs, 1 button (power, 2G, 5G, WAN, WPS) (reset) **MAC addresses:** Base MAC address labeled as "MAC ADDRESS" MAC "wanaddr" is not similar to "ethaddr" eth0 *:c8 MAC u-boot-env ethaddr phy0 *:c8 MAC u-boot-env ethaddr phy1 *:c9 --- u-boot-env ethaddr +1 WAN *:66:44 u-boot-env wanaddr **Serial Access:** RX on the board for UART is shorted to ground by resistor R176 therefore it must be removed to use the console but it is not necessary to remove to view boot log optionally, R175 can be replaced with a solder bridge short the resistors R175 and R176 are next to the UART RX pin **Installation:** Method 1: Firmware upgrade page OEM webpage at 192.168.0.1 username and password "admin" Navigate to Settings (gear icon) --> Tools --> Firmware select the factory.bin image confirm and wait 3 minutes Method 2: TFTP recovery Follow TFTP instructions using initramfs.bin use sysupgrade.bin to flash using openwrt web interface **Return to OEM:** MTD partitions should be backed up before flashing using TFTP to boot openwrt without overwriting flash Alternatively, it is possible to edit OEM firmware images to flash MTD partitions in openwrt to restore OEM firmware by removing the OEM header and writing the rest to "firmware" **TFTP recovery:** Requires serial console, reset button does nothing at boot rename initramfs.bin to 'uImageESR1200' make available on TFTP server at 192.168.99.8 power board, interrupt boot by pressing '4' rapidly execute tftpboot and bootm **Note on ETH switch registers** Registers must be written to the ethernet switch in order to set up the switch's MAC interface. U-boot can write the registers on it's own which is needed, for example, in a TFTP transfer. The register bits from OEM for the QCA8337 switch can be read from interrupted boot (tftpboot, bootm) by adding print lines in the switch driver ar8327.c before 'qca,ar8327-initvals' is parsed from DTS and written. for example: pr_info("0x04 %08x\n", ar8xxx_read(priv, AR8327_REG_PAD0_MODE)); Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Michael Pratt
|
96c2119dba |
ath79: add support for Senao Engenius ESR1750
FCC ID: A8J-ESR1750 Engenius ESR1750 is an indoor wireless router with a gigabit ethernet switch, dual-band wireless, internal antenna plates, and a USB 2.0 port **Specification:** - QCA9558 SOC 2.4 GHz, 3x3 - QCA9880 WLAN PCIe mini card, 5 GHz, 3x3 - QCA8337N SW 4 ports LAN, 1 port WAN - 40 MHz clock - 16 MB FLASH MX25L12845EMI-10G - 2x 64 MB RAM - UART at J1 populated, RX grounded - 6 internal antenna plates (omni-directional) - 5 LEDs, 1 button (power, 2G, 5G, WAN, WPS) (reset) **MAC addresses:** Base MAC address labeled as "MAC ADDRESS" MAC "wanaddr" is similar to "ethaddr" eth0 *:58 MAC u-boot-env ethaddr phy0 *:58 MAC u-boot-env ethaddr phy1 *:59 --- u-boot-env ethaddr +1 WAN *:10:58 u-boot-env wanaddr **Serial Access:** RX on the board for UART is shorted to ground by resistor R176 therefore it must be removed to use the console but it is not necessary to remove to view boot log optionally, R175 can be replaced with a solder bridge short the resistors R175 and R176 are next to the UART RX pin **Installation:** Method 1: Firmware upgrade page NOTE: ESR1750 might require the factory.bin for ESR1200 instead, OEM provides 1 image for both. OEM webpage at 192.168.0.1 username and password "admin" Navigate to Settings (gear icon) --> Tools --> Firmware select the factory.bin image confirm and wait 3 minutes Method 2: TFTP recovery Follow TFTP instructions using initramfs.bin use sysupgrade.bin to flash using openwrt web interface **Return to OEM:** MTD partitions should be backed up before flashing using TFTP to boot openwrt without overwriting flash Alternatively, it is possible to edit OEM firmware images to flash MTD partitions in openwrt to restore OEM firmware by removing the OEM header and writing the rest to "firmware" **TFTP recovery:** Requires serial console, reset button does nothing at boot rename initramfs.bin to 'uImageESR1200' make available on TFTP server at 192.168.99.8 power board, interrupt boot by pressing '4' rapidly execute tftpboot and bootm **Note on ETH switch registers** Registers must be written to the ethernet switch in order to set up the switch's MAC interface. U-boot can write the registers on it's own which is needed, for example, in a TFTP transfer. The register bits from OEM for the QCA8337 switch can be read from interrupted boot (tftpboot, bootm) by adding print lines in the switch driver ar8327.c before 'qca,ar8327-initvals' is parsed from DTS and written. for example: pr_info("0x04 %08x\n", ar8xxx_read(priv, AR8327_REG_PAD0_MODE)); Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Michael Pratt
|
2f99f7e2d0 |
ath79: add support for Senao Engenius ESR900
FCC ID: A8J-ESR900 Engenius ESR900 is an indoor wireless router with a gigabit ethernet switch, dual-band wireless, internal antenna plates, and a USB 2.0 port **Specification:** - QCA9558 SOC 2.4 GHz, 3x3 - AR9580 WLAN PCIe on board, 5 GHz, 3x3 - AR8327N SW 4 ports LAN, 1 port WAN - 40 MHz clock - 16 MB FLASH MX25L12845EMI-10G - 2x 64 MB RAM - UART at J1 populated, RX grounded - 6 internal antenna plates (omni-directional) - 5 LEDs, 1 button (power, 2G, 5G, WAN, WPS) (reset) **MAC addresses:** Base MAC address labeled as "MAC ADDRESS" MAC "wanaddr" is not similar to "ethaddr" eth0 *:06 MAC u-boot-env ethaddr phy0 *:06 MAC u-boot-env ethaddr phy1 *:07 --- u-boot-env ethaddr +1 WAN *:6E:81 u-boot-env wanaddr **Serial Access:** RX on the board for UART is shorted to ground by resistor R176 therefore it must be removed to use the console but it is not necessary to remove to view boot log optionally, R175 can be replaced with a solder bridge short the resistors R175 and R176 are next to the UART RX pin **Installation:** Method 1: Firmware upgrade page OEM webpage at 192.168.0.1 username and password "admin" Navigate to Settings (gear icon) --> Tools --> Firmware select the factory.bin image confirm and wait 3 minutes Method 2: TFTP recovery Follow TFTP instructions using initramfs.bin use sysupgrade.bin to flash using openwrt web interface **Return to OEM:** MTD partitions should be backed up before flashing using TFTP to boot openwrt without overwriting flash Alternatively, it is possible to edit OEM firmware images to flash MTD partitions in openwrt to restore OEM firmware by removing the OEM header and writing the rest to "firmware" **TFTP recovery:** Requires serial console, reset button does nothing at boot rename initramfs.bin to 'uImageESR900' make available on TFTP server at 192.168.99.8 power board, interrupt boot by pressing '4' rapidly execute tftpboot and bootm **Note on ETH switch registers** Registers must be written to the ethernet switch in order to set up the switch's MAC interface. U-boot can write the registers on it's own which is needed, for example, in a TFTP transfer. The register bits from OEM for the AR8327 switch can be read from interrupted boot (tftpboot, bootm) by adding print lines in the switch driver ar8327.c before 'qca,ar8327-initvals' is parsed from DTS and written. for example: pr_info("0x04 %08x\n", ar8xxx_read(priv, AR8327_REG_PAD0_MODE)); Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Edward Chow
|
2a20dc717a |
ath79: calibrate dlink dir-825 c1 and dir-835 a1 with nvmem
Driver for both soc (2.4GHz Wifi) and pci (5 GHz) now pull the calibration data from the nvmem subsystem. This allows us to move the userspace caldata extraction for the pci-e ath9k supported wifi into the device-tree definition of the device. Currently, "mac-address-ascii" cells only works for ethernet and wmac devices, so PCI ath9k device uses the old method to calibrate. Signed-off-by: Edward Chow <equu@openmail.cc> |
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Michael Pratt
|
52992efc34 |
ath79: add support for Senao Engenius EWS660AP
FCC ID: A8J-EWS660AP Engenius EWS660AP is an outdoor wireless access point with 2 gigabit ethernet ports, dual-band wireless, internal antenna plates, and 802.3at PoE+ **Specification:** - QCA9558 SOC 2.4 GHz, 3x3 - QCA9880 WLAN mini PCIe card, 5 GHz, 3x3, 26dBm - AR8035-A PHY RGMII GbE with PoE+ IN - AR8033 PHY SGMII GbE with PoE+ OUT - 40 MHz clock - 16 MB FLASH MX25L12845EMI-10G - 2x 64 MB RAM - UART at J1 populated, RX grounded - 6 internal antenna plates (5 dbi, omni-directional) - 5 LEDs, 1 button (power, eth0, eth1, 2G, 5G) (reset) **MAC addresses:** Base MAC addressed labeled as "MAC" Only one Vendor MAC address in flash eth0 *:d4 MAC art 0x0 eth1 *:d5 --- art 0x0 +1 phy1 *:d6 --- art 0x0 +2 phy0 *:d7 --- art 0x0 +3 **Serial Access:** the RX line on the board for UART is shorted to ground by resistor R176 therefore it must be removed to use the console but it is not necessary to remove to view boot log optionally, R175 can be replaced with a solder bridge short the resistors R175 and R176 are next to the UART RX pin **Installation:** 2 ways to flash factory.bin from OEM: Method 1: Firmware upgrade page: OEM webpage at 192.168.1.1 username and password "admin" Navigate to "Firmware Upgrade" page from left pane Click Browse and select the factory.bin image Upload and verify checksum Click Continue to confirm and wait 3 minutes Method 2: Serial to load Failsafe webpage: After connecting to serial console and rebooting... Interrupt uboot with any key pressed rapidly execute `run failsafe_boot` OR `bootm 0x9fd70000` wait a minute connect to ethernet and navigate to "192.168.1.1/index.htm" Select the factory.bin image and upload wait about 3 minutes **Return to OEM:** If you have a serial cable, see Serial Failsafe instructions otherwise, uboot-env can be used to make uboot load the failsafe image ssh into openwrt and run `fw_setenv rootfs_checksum 0` reboot, wait 3 minutes connect to ethernet and navigate to 192.168.1.1/index.htm select OEM firmware image from Engenius and click upgrade **TFTP recovery:** Requires serial console, reset button does nothing rename initramfs.bin to '0101A8C0.img' make available on TFTP server at 192.168.1.101 power board, interrupt boot execute tftpboot and bootm 0x81000000 **Format of OEM firmware image:** The OEM software of EWS660AP is a heavily modified version of Openwrt Kamikaze. One of the many modifications is to the sysupgrade program. Image verification is performed simply by the successful ungzip and untar of the supplied file and name check and header verification of the resulting contents. To form a factory.bin that is accepted by OEM Openwrt build, the kernel and rootfs must have specific names... openwrt-ar71xx-generic-ews660ap-uImage-lzma.bin openwrt-ar71xx-generic-ews660ap-root.squashfs and begin with the respective headers (uImage, squashfs). Then the files must be tarballed and gzipped. The resulting binary is actually a tar.gz file in disguise. This can be verified by using binwalk on the OEM firmware images, ungzipping then untaring. Newer EnGenius software requires more checks but their script includes a way to skip them, otherwise the tar must include a text file with the version and md5sums in a deprecated format. The OEM upgrade script is at /etc/fwupgrade.sh. OKLI kernel loader is required because the OEM software expects the kernel to be no greater than 1536k and the factory.bin upgrade procedure would otherwise overwrite part of the kernel when writing rootfs. Note on PLL-data cells: The default PLL register values will not work because of the external AR8035 switch between the SOC and the ethernet port. For QCA955x series, the PLL registers for eth0 and eth1 can be see in the DTSI as 0x28 and 0x48 respectively. Therefore the PLL registers can be read from uboot for each link speed after attempting tftpboot or another network action using that link speed with `md 0x18050028 1` and `md 0x18050048 1`. The clock delay required for RGMII can be applied at the PHY side, using the at803x driver `phy-mode`. Therefore the PLL registers for GMAC0 do not need the bits for delay on the MAC side. This is possible due to fixes in at803x driver since Linux 5.1 and 5.3 Tested-by: Niklas Arnitz <openwrt@arnitz.email> Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Shiji Yang
|
cfb296b79a |
ath79: add support for D-Link DIR-629 A1
Specifications: SOC: QCA9588 CPU 720 MHz AHB 200 MHz Switch: AR8236 RAM: 64 MiB DDR2-600 Flash: 8 MiB WLAN: Wi-Fi4 2.4 GHz 3*3 LAN: LAN ports *4 WAN: WAN port *1 Buttons: reset *1 + wps *1 LEDs: ethernet *5, power, wlan, wps MAC Address: use address source label 70:62:b8:xx:xx:96 lan && wlan lan 70:62:b8:xx:xx:96 mfcdata@0x35 wan 70:62:b8:xx:xx:97 mfcdata@0x6a wlan 70:62:b8:xx:xx:96 mfcdata@0x51 Install via Web UI: Apply factory image in the stock firmware's Web UI. Install via Emergency Room Mode: DIR-629 A1 will enter recovery mode when the system fails to boot or press reset button for about 10 seconds. First, set IP address to 192.168.0.1 and server IP to 192.168.0.10. Then we can open http://192.168.0.1 in the web browser to upload OpenWrt factory image or stock firmware. Some modern browsers may need to turn on compatibility mode. Signed-off-by: Shiji Yang <yangshiji66@qq.com> |
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Wenli Looi
|
7396263680 |
ath79: convert Netgear EX7300 caldata to nvmem
Transition to specify caldata in the DTS. Signed-off-by: Wenli Looi <wlooi@ucalgary.ca> |
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Wenli Looi
|
f0eb73a888 |
ath79: consolidate Netgear EX7300 series images
This change consolidates Netgear EX7300 series devices into two images corresponding to devices that share the same manufacturer firmware image. Similar to the manufacturer firmware, the actual device model is detected at runtime. The logic is taken from the netgear GPL dumps in a file called generate_board_conf.sh. Hardware details for EX7300 v2 variants --------------------------------------- SoC: QCN5502 Flash: 16 MiB RAM: 128 MiB Ethernet: 1 gigabit port Wireless 2.4GHz (currently unsupported due to lack of ath9k support): - EX6250 / EX6400 v2 / EX6410 / EX6420: QCN5502 3x3 - EX7300 v2 / EX7320: QCN5502 4x4 Wireless 5GHz: - EX6250: QCA9986 3x3 (detected by ath10k as QCA9984 3x3) - EX6400 v2 / EX6410 / EX6420 / EX7300 v2 / EX7320: QCA9984 4x4 Signed-off-by: Wenli Looi <wlooi@ucalgary.ca> |
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Stefan Kalscheuer
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f193f2d1a0 |
ath79: convert UBNT Aircube AC WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Merge art into partition node. Signed-off-by: Stefan Kalscheuer <stefan@stklcode.de> |
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Michael Pratt
|
e085812a7d |
ath79: add support for Fortinet FAP-221-B
FCC ID: U2M-CAP4100AG Fortinet FAP-221-B is an indoor access point with 1 Gb ethernet port, dual-band wireless, internal antenna plates, and 802.3at PoE+ Hardware and board design from Senao **Specification:** - AR9344 SOC 2G 2x2, 5G 2x2, 25 MHz CLK - AR9382 WLAN 2G 2x2 PCIe, 40 MHz CLK - AR8035-A PHY RGMII, PoE+ IN, 25 MHz CLK - 16 MB FLASH MX25L12845EMI-10G - 2x 32 MB RAM W9725G6JB-25 - UART at J11 populated, 9600 baud - 6 LEDs, 1 button power, ethernet, wlan, reset Note: ethernet LEDs are not enabled because a new netifd hotplug is required in order to operate like OEM. Board has 1 amber and 1 green for each of the 3 case viewports. **MAC addresses:** 1 MAC Address in flash at end of uboot ASCII encoded, no delimiters Labeled as "MAC Address" on case OEM firmware sets offsets 1 and 8 for wlan eth0 *:1e uboot 0x3ff80 phy0 *:1f uboot 0x3ff80 +1 phy1 *:26 uboot 0x3ff80 +8 **Serial Access:** Pinout: (arrow) VCC GND RX TX Pins are populated with a header and traces not blocked. Bootloader is set to 9600 baud, 8 data, 1 stop. **Console Access:** Bootloader: Interrupt boot with Ctrl+C Press "k" and enter password "1" OR Hold reset button for 5 sec during power on Interrupt the TFTP transfer with Ctrl+C to print commands available, enter "help" OEM: default username is "admin", password blank telnet is available at default address 192.168.1.2 serial is available with baud 9600 to print commands available, enter "help" or tab-tab (busybox list of commands) **Installation:** Use factory.bin with OEM upgrade procedures OR Use initramfs.bin with uboot TFTP commands. Then perform a sysupgrade with sysupgrade.bin **TFTP Recovery:** Using serial console, load initramfs.bin using TFTP to boot openwrt without touching the flash. TFTP is not reliable due to bugged bootloader, set MTU to 600 and try many times. If your TFTP server supports setting block size, higher block size is better. Splitting the file into 1 MB parts may be necessary example: $ tftpboot 0x80100000 image1.bin $ tftpboot 0x80200000 image2.bin $ tftpboot 0x80300000 image3.bin $ tftpboot 0x80400000 image4.bin $ tftpboot 0x80500000 image5.bin $ tftpboot 0x80600000 image6.bin $ bootm 0x80100000 **Return to OEM:** The best way to return to OEM firmware is to have a copy of the MTD partitions before flashing Openwrt. Backup copies should be made of partitions "fwconcat0", "loader", and "fwconcat1" which together is the same flash range as OEM's "rootfs" and "uimage" by loading an initramfs.bin and using LuCI to download the mtdblocks. It is also possible to extract from the OEM firmware upgrade image by splitting it up in parts of lengths that correspond to the partitions in openwrt and write them to flash, after gzip decompression. After writing to the firmware partitions, erase the "reserved" partition and reboot. **OEM firmware image format:** Images from Fortinet for this device ending with the suffix .out are actually a .gz file The gzip metadata stores the original filename before compression, which is a special string used to verify the image during OEM upgrade. After gzip decompression, the resulting file is an exact copy of the MTD partitions "rootfs" and "uimage" combined in the same order and size that they appear in /proc/mtd and as they are on flash. OEM upgrade is performed by a customized busybox with the command "upgrade". Another binary, "restore" is a wrapper for busybox's "tftp" and "upgrade". Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Nick Hainke
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aa6c8c38ea |
ath79: convert Netgear WNDAP360 WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Merge art into partition node. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
|
a14170b6e9 |
ath79: fix calibration-art for some boards
"0x1000" looks suspicious. By looking at data provided by @DragonBluep I was able to identify the correct size for AR9380, AR9287 WiFis. Furthermore, PowerCloud Systems CAP324 has a AR9344 WiFi. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Davide Fioravanti
|
d9566d059c |
ath79: add support for KuWFi C910
KuWFi C910 is an 802.11n (300N) indoor router with LTE support. I can't find anywhere the OEM firmware. So if you want to restore the original firmware you must do a dump before the OpenWrt flash. According to the U-Boot, the board name is Iyunlink MINI_V2. Hardware -------- SoC: Qualcomm QCA9533 650/400/200/25/25 MHz (CPU/RAM/AHB/SPI/REF) RAM: 128 MB DDR2 16-bit CL3-4-4-10 (Nanya NT5TU64M16HG-AC) FLASH: 16 MB Winbond W25Q128 ETH: - 2x 100M LAN (QCA9533 internal AR8229 switch, eth0) - 1x 100M WAN (QCA9533 internal PHY, eth1) WIFI: - 2.4GHz: 1x QCA9533 2T2R (b/g/n) - 2 external non detachable antennas (near the power barrel side) LTE: - Quectel EC200T-EU (or -CN or -AU depending on markets) - 2 external non detachable antennas (near the sim slot side) BTN: - 1x Reset button LEDS: - 5x White leds (Power, Wifi, Wan, Lan1, Lan2) - 1x RGB led (Internet) UART: 115200-8-N-1 (Starting from lan ports in order: GND, RX, TX, VCC) Everything works correctly. MAC Addresses ------------- LAN XX:XX:XX:XX:XX:48 (art@0x1002) WAN XX:XX:XX:XX:XX:49 (art@0x1002 + 1) WIFI XX:XX:XX:XX:XX:48 LABEL XX:XX:XX:XX:XX:48 Installation ------------ Turn the router on while pressing the reset button for 4 seconds. You can simply count the flashes of the first lan led. (See notes) If done correctly you should see the first lan led glowing slowly and you should be able to enter the U-Boot web interface. Click on the second tab ("固件") and select the -factory.bin firmware then click "Update firmware". A screen "Update in progress" should appear. After few minutes the flash should be completed. This procedure can be used also to recover the router in case of soft brick. Backup the original firmware ---------------------------- The following steps are intended for a linux pc. However using the right software this guide should also work for Windows and MacOS. 1) Install a tftp server on your pc. For example tftpd-hpa. 2) Create two empty files in your tftp folder called: kuwfi_c910_all_nor.bin kuwfi_c910_firmware_only.bin 3) Give global write permissions to these files: chmod 666 kuwfi_c910_all_nor.bin chmod 666 kuwfi_c910_firmware_only.bin 4) Start a netcat session on your pc with this command: nc -u -p 6666 192.168.1.1 6666 5) Set the static address on your pc: 192.168.1.2. Connect the router to your pc. 6) Turn the router on while pressing the reset button for 8-9 seconds. You can simply count the flashes of the first lan led. If you press the reset button for too many seconds it will continue the normal boot, so you have to restart the router. (See notes) 7) If done correctly you should see the U-Boot network console and you should see the following lines on the netcat session: Version and build date: U-Boot 1.1.4-55f1bca8-dirty, 2020-05-07 Modification by: Piotr Dymacz <piotr@dymacz.pl> https://github.com/pepe2k/u-boot_mod u-boot> 8) Start the transfer of the whole NOR: tftpput 0x9f000000 0x1000000 kuwfi_c910_all_nor.bin 9) The router should start the transfer and it should end with a message like this (pay attention to the bytes transferred): TFTP transfer complete! Bytes transferred: 16777216 (0x1000000) 10) Repeat the same transfer for the firmware: tftpput 0x9f050000 0xfa0000 kuwfi_c910_firmware_only.bin 11) The router should start the transfer and it should end with a message like this (pay attention to the bytes transferred): TFTP transfer complete! Bytes transferred: 16384000 (0xfa0000) 12) Now you have the backup for the whole nor and for the firmware partition. If you want to restore the OEM firmware from OpenWrt you have to flash the kuwfi_c910_firmware_only.bin from the U-Boot web interface. WARNING: Don't use the kuwfi_c910_all_nor.bin file. This file is only useful if you manage to hard brick the router or you damage the art partition (ask on the forum) Notes ----- This router (or at least my unit) has the pepe2k's U-Boot. It's a modded U-Boot version with a lot of cool features. You can read more here: https://github.com/pepe2k/u-boot_mod With this version of U-Boot, pushing the reset button while turning on the router starts different tools: - 3-5 seconds: U-Boot web interface that can be used to replace the firmware, the art or the U-Boot itself - 5-7 seconds: U-Boot uart console - 7-10 seconds: U-Boot network console - 11+ seconds: Normal boot The LTE modem can be used in cdc_ether (ECM) or RNDIS mode. The default mode is ECM and in this commit only the ECM software is included. In order to set RNDIS mode you must use this AT command: AT+QCFG="usbnet",3 In order to use again the ECM mode you must use this AT command: AT+QCFG="usbnet",1 Look for "Quectel_EC200T_Linux_USB_Driver_User_Guide_V1.0.pdf" for other AT commands Signed-off-by: Davide Fioravanti <pantanastyle@gmail.com> |
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Nick Hainke
|
af5306ba70 |
ath79: convert WiFis based on ar7241_ubnt_unifi.dtsi to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. While working on it remove stale uboot partition label and merge art into partition node. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
|
b7ad3c5c5d |
ath79: convert Buffalo WZR-HP-G302H A1A0 WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Merge art into partition node. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
|
d4ec4f9d0b |
ath79: convert OpenMesh OM2P v1 WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Merge art into partition node. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
|
f6ca84bf02 |
ath79: convert OpenMesh OM5P-AN WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Merge art into partition node. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
|
46077860c2 |
ath79: convert boards based on ar9344_openmesh_mr600.dtsi to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Merge art into partition node. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
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08c114ee16 |
ath79: convert Winchannel WB2000 WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Signed-off-by: Nick Hainke <vincent@systemli.org> (removed mtd-cal-data property, merged art + addr nodes back into partition) Signed-off-by: Christian Lamparter <chunkeey@gmail.com> |
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Nick Hainke
|
fd456106aa |
ath79: convert Ubiquiti UniFi AP Pro WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Signed-off-by: Nick Hainke <vincent@systemli.org> (merged art node back into partition-node) Signed-off-by: Christian Lamparter <chunkeey@gmail.com> |
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Nick Hainke
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f63cf33aa7 |
ath79: convert OCEDO Raccoon WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Signed-off-by: Nick Hainke <vincent@systemli.org> (merged art into partition node, removed stale uboot label) Signed-off-by: Christian Lamparter <chunkeey@gmail.com> |
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Nick Hainke
|
783936c1f7 |
ath79: Mercury MW4530R v1 already uses nvmem-cells
Remove the caldata extraction in userspace. The board already uses
nvmem-cells since
commit
|
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Nick Hainke
|
4845b60525 |
ath79: convert boards based on senao_ap-dual.dtsi WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Nick Hainke
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21495c92dc |
ath79: convert Atheros DB120 WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Signed-off-by: Nick Hainke <vincent@systemli.org> (merged art-node back into partition-node) Signed-off-by: Christian Lamparter <chunkeey@gmail.com> |
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Nick Hainke
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1b125aabf4 |
ath79: convert Araknis AN-300-AP-I-N WiFis to nvmem-cells
Pull the calibration data from the nvmem subsystem. This allows us to move userspace caldata extraction into the device-tree definition. Signed-off-by: Nick Hainke <vincent@systemli.org> |
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Andrew Cameron
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550e5b2184 |
ath79: add support for TP-Link CPE605-v1
TP-Link CPE605-v1 is an outdoor wireless CPE for 5 GHz with one Ethernet port based on Atheros AR9344 Specifications: - 560/450/225 MHz (CPU/DDR/AHB) - 1x 10/100 Mbps Ethernet - 64 MB of DDR2 RAM - 8 MB of SPI-NOR Flash - 23dBi high-gain directional antenna and a dedicated metal reflector - Power, LAN, WLAN5G green LEDs - 3x green RSSI LEDs Flashing instructions: Flash factory image through stock firmware WEB UI or through TFTP To get to TFTP recovery just hold reset button while powering on for around 4-5 seconds and release. Rename factory image to recovery.bin Stock TFTP server IP:192.168.0.100 Stock device TFTP adress:192.168.0.254 Signed-off-by: Andrew Cameron <apcameron@softhome.net> |
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Michael Pratt
|
6de9287abd |
ath79: add support for Senao Engenius EAP1750H
FCC ID: A8J-EAP1750H Engenius EAP1750H is an indoor wireless access point with 1 Gb ethernet port, dual-band wireless, internal antenna plates, and 802.3at PoE+ **Specification:** - QCA9558 SOC - QCA9880 WLAN PCI card, 5 GHz, 3x3, 26dBm - AR8035-A PHY RGMII GbE with PoE+ IN - 40 MHz clock - 16 MB FLASH MX25L12845EMI-10G - 2x 64 MB RAM NT5TU32M16FG - UART at J10 populated - 4 internal antenna plates (5 dbi, omni-directional) - 5 LEDs, 1 button (power, eth0, 2G, 5G, WPS) (reset) **MAC addresses:** MAC addresses are labeled as ETH, 2.4G, and 5GHz Only one Vendor MAC address in flash eth0 ETH *:fb art 0x0 phy1 2.4G *:fc --- phy0 5GHz *:fd --- **Serial Access:** the RX line on the board for UART is shorted to ground by resistor R176 therefore it must be removed to use the console but it is not necessary to remove to view boot log optionally, R175 can be replaced with a solder bridge short the resistors R175 and R176 are next to the UART RX pin at J10 **Installation:** 2 ways to flash factory.bin from OEM: Method 1: Firmware upgrade page: OEM webpage at 192.168.1.1 username and password "admin" Navigate to "Firmware Upgrade" page from left pane Click Browse and select the factory.bin image Upload and verify checksum Click Continue to confirm and wait 3 minutes Method 2: Serial to load Failsafe webpage: After connecting to serial console and rebooting... Interrupt uboot with any key pressed rapidly execute `run failsafe_boot` OR `bootm 0x9fd70000` wait a minute connect to ethernet and navigate to "192.168.1.1/index.htm" Select the factory.bin image and upload wait about 3 minutes **Return to OEM:** If you have a serial cable, see Serial Failsafe instructions otherwise, uboot-env can be used to make uboot load the failsafe image ssh into openwrt and run `fw_setenv rootfs_checksum 0` reboot, wait 3 minutes connect to ethernet and navigate to 192.168.1.1/index.htm select OEM firmware image from Engenius and click upgrade **TFTP recovery:** Requires serial console, reset button does nothing rename initramfs to 'vmlinux-art-ramdisk' make available on TFTP server at 192.168.1.101 power board, interrupt boot execute tftpboot and bootm 0x81000000 NOTE: TFTP is not reliable due to bugged bootloader set MTU to 600 and try many times if your TFTP server supports setting block size higher block size is better. **Format of OEM firmware image:** The OEM software of EAP1750H is a heavily modified version of Openwrt Kamikaze. One of the many modifications is to the sysupgrade program. Image verification is performed simply by the successful ungzip and untar of the supplied file and name check and header verification of the resulting contents. To form a factory.bin that is accepted by OEM Openwrt build, the kernel and rootfs must have specific names... openwrt-ar71xx-generic-eap1750h-uImage-lzma.bin openwrt-ar71xx-generic-eap1750h-root.squashfs and begin with the respective headers (uImage, squashfs). Then the files must be tarballed and gzipped. The resulting binary is actually a tar.gz file in disguise. This can be verified by using binwalk on the OEM firmware images, ungzipping then untaring. Newer EnGenius software requires more checks but their script includes a way to skip them, otherwise the tar must include a text file with the version and md5sums in a deprecated format. The OEM upgrade script is at /etc/fwupgrade.sh. OKLI kernel loader is required because the OEM software expects the kernel to be no greater than 1536k and the factory.bin upgrade procedure would otherwise overwrite part of the kernel when writing rootfs. Note on PLL-data cells: The default PLL register values will not work because of the external AR8035 switch between the SOC and the ethernet port. For QCA955x series, the PLL registers for eth0 and eth1 can be see in the DTSI as 0x28 and 0x48 respectively. Therefore the PLL registers can be read from uboot for each link speed after attempting tftpboot or another network action using that link speed with `md 0x18050028 1` and `md 0x18050048 1`. The clock delay required for RGMII can be applied at the PHY side, using the at803x driver `phy-mode`. Therefore the PLL registers for GMAC0 do not need the bits for delay on the MAC side. This is possible due to fixes in at803x driver since Linux 5.1 and 5.3 Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Michael Pratt
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128947db42 |
ath79: use nvmem-cells for radio calibration of EAP1200H
Transition from userscript to DTS for all of ART. Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Edward Chow
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2c33fd39a5 |
ath79: calibrate TP-LINK TL-WR2543ND with nvmem
Driver for and pci wlan card now pull the calibration data from the nvmem subsystem. This allows us to move the userspace caldata extraction for the pci-e ath9k supported wifi into the device-tree definition of the device. The wifi mac address remains correct after these changes, because When both "mac-address" and "calibration" are defined, the effective mac address comes from the cell corresponding to "mac-address" and mac-address-increment. Test passed on my tplink tl-wr2543nd. Signed-off-by: Edward Chow <equu@openmail.cc> |
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Edward Chow
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e354b01baf |
ath79: calibrate all ar9344 tl-WDRxxxx with nvmem
Driver for both soc (2.4GHz Wifi) and pci (5 GHz) now pull the calibration data from the nvmem subsystem. This allows us to move the userspace caldata extraction for the pci-e ath9k supported wifi into the device-tree definition of the device. wmac's nodes are also changed over to use nvmem-cells over OpenWrt's custom mtd-cal-data property. The wifi mac address remains correct after these changes, because When both "mac-address" and "calibration" are defined, the effective mac address comes from the cell corresponding to "mac-address" and mac-address-increment. Test passed on my tplink tl-wdr4310. Signed-off-by: Edward Chow <equu@openmail.cc> |
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Lech Perczak
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6fdeb48c1e |
ath79: support Ruckus ZoneFlex 7025
Ruckus ZoneFlex 7025 is a single 2.4GHz radio 802.11n 1x1 enterprise access point with built-in Ethernet switch, in an electrical outlet form factor. Hardware highligts: - CPU: Atheros AR7240 SoC at 400 MHz - RAM: 64MB DDR2 - Flash: 16MB SPI-NOR - Wi-Fi: AR9285 built-in 2.4GHz 1x1 radio - Ethernet: single Fast Ethernet port inside the electrical enclosure, coupled with internal LSA connector for direct wiring, four external Fast Ethernet ports on the lower side of the device. - PoE: 802.3af PD input inside the electrical box. 802.3af PSE output on the LAN4 port, capable of sourcing class 0 or class 2 devices, depending on power supply capacity. - External 8P8C pass-through connectors on the back and right side of the device - Standalone 48V power input on the side, through 2/1mm micro DC barrel jack Serial console: 115200-8-N-1 on internal JP1 header. Pinout: ---------- JP1 |5|4|3|2|1| ---------- Pin 1 is near the "H1" marking. 1 - RX 2 - n/c 3 - VCC (3.3V) 4 - GND 5 - TX Installation: There are two methods of installation: - Using serial console [1] - requires some disassembly, 3.3V USB-Serial adapter, TFTP server, and removing a single T10 screw, but with much less manual steps, and is generally recommended, being safer. - Using stock firmware root shell exploit, SSH and TFTP [2]. Does not work on some rare versions of stock firmware. A more involved, and requires installing `mkenvimage` from u-boot-tools package if you choose to rebuild your own environment, but can be used without disassembly or removal from installation point, if you have the credentials. If for some reason, size of your sysupgrade image exceeds 13312kB, proceed with method [1]. For official images this is not likely to happen ever. [1] Using serial console: 0. Connect serial console to H1 header. Ensure the serial converter does not back-power the board, otherwise it will fail to boot. 1. Power-on the board. Then quickly connect serial converter to PC and hit Ctrl+C in the terminal to break boot sequence. If you're lucky, you'll enter U-boot shell. Then skip to point 3. Connection parameters are 115200-8-N-1. 2. Allow the board to boot. Press the reset button, so the board reboots into U-boot again and go back to point 1. 3. Set the "bootcmd" variable to disable the dual-boot feature of the system and ensure that uImage is loaded. This is critical step, and needs to be done only on initial installation. > setenv bootcmd "bootm 0x9f040000" > saveenv 4. Boot the OpenWrt initramfs using TFTP. Replace IP addresses as needed: > setenv serverip 192.168.1.2 > setenv ipaddr 192.168.1.1 > tftpboot 0x81000000 openwrt-ath79-generic-ruckus_zf7025-initramfs-kernel.bin > bootm 0x81000000 5. Optional, but highly recommended: back up contents of "firmware" partition: $ ssh root@192.168.1.1 cat /dev/mtd1 > ruckus_zf7025_fw1_backup.bin 6. Copy over sysupgrade image, and perform actual installation. OpenWrt shall boot from flash afterwards: $ ssh root@192.168.1.1 # sysupgrade -n openwrt-ath79-generic-ruckus_zf7025-squashfs-sysupgrade.bin [2] Using stock root shell: 0. Reset the device to factory defaullts. Power-on the device and after it boots, hold the reset button near Ethernet connectors for 5 seconds. 1. Connect the device to the network. It will acquire address over DHCP, so either find its address using list of DHCP leases by looking for label MAC address, or try finding it by scanning for SSH port: $ nmap 10.42.0.0/24 -p22 From now on, we assume your computer has address 10.42.0.1 and the device has address 10.42.0.254. 2. Set up a TFTP server on your computer. We assume that TFTP server root is at /srv/tftp. 3. Obtain root shell. Connect to the device over SSH. The SSHD ond the frmware is pretty ancient and requires enabling HMAC-MD5. $ ssh 10.42.0.254 \ -o UserKnownHostsFile=/dev/null \ -o StrictHostKeyCheking=no \ -o MACs=hmac-md5 Login. User is "super", password is "sp-admin". Now execute a hidden command: Ruckus It is case-sensitive. Copy and paste the following string, including quotes. There will be no output on the console for that. ";/bin/sh;" Hit "enter". The AP will respond with: grrrr OK Now execute another hidden command: !v54! At "What's your chow?" prompt just hit "enter". Congratulations, you should now be dropped to Busybox shell with root permissions. 4. Optional, but highly recommended: backup the flash contents before installation. At your PC ensure the device can write the firmware over TFTP: $ sudo touch /srv/tftp/ruckus_zf7025_firmware{1,2}.bin $ sudo chmod 666 /srv/tftp/ruckus_zf7025_firmware{1,2}.bin Locate partitions for primary and secondary firmware image. NEVER blindly copy over MTD nodes, because MTD indices change depending on the currently active firmware, and all partitions are writable! # grep rcks_wlan /proc/mtd Copy over both images using TFTP, this will be useful in case you'd like to return to stock FW in future. Make sure to backup both, as OpenWrt uses bot firmwre partitions for storage! # tftp -l /dev/<rcks_wlan.main_mtd> -r ruckus_zf7025_firmware1.bin -p 10.42.0.1 # tftp -l /dev/<rcks_wlan.bkup_mtd> -r ruckus_zf7025_firmware2.bin -p 10.42.0.1 When the command finishes, copy over the dump to a safe place for storage. $ cp /srv/tftp/ruckus_zf7025_firmware{1,2}.bin ~/ 5. Ensure the system is running from the BACKUP image, i.e. from rcks_wlan.bkup partition or "image 2". Otherwise the installation WILL fail, and you will need to access mtd0 device to write image which risks overwriting the bootloader, and so is not covered here and not supported. Switching to backup firmware can be achieved by executing a few consecutive reboots of the device, or by updating the stock firmware. The system will boot from the image it was not running from previously. Stock firmware available to update was conveniently dumped in point 4 :-) 6. Prepare U-boot environment image. Install u-boot-tools package. Alternatively, if you build your own images, OpenWrt provides mkenvimage in host staging directory as well. It is recommended to extract environment from the device, and modify it, rather then relying on defaults: $ sudo touch /srv/tftp/u-boot-env.bin $ sudo chmod 666 /srv/tftp/u-boot-env.bin On the device, find the MTD partition on which environment resides. Beware, it may change depending on currently active firmware image! # grep u-boot-env /proc/mtd Now, copy over the partition # tftp -l /dev/mtd<N> -r u-boot-env.bin -p 10.42.0.1 Store the stock environment in a safe place: $ cp /srv/tftp/u-boot-env.bin ~/ Extract the values from the dump: $ strings u-boot-env.bin | tee u-boot-env.txt Now clean up the debris at the end of output, you should end up with each variable defined once. After that, set the bootcmd variable like this: bootcmd=bootm 0x9f040000 You should end up with something like this: bootcmd=bootm 0x9f040000 bootargs=console=ttyS0,115200 rootfstype=squashfs init=/sbin/init baudrate=115200 ethaddr=0x00:0xaa:0xbb:0xcc:0xdd:0xee mtdparts=mtdparts=ar7100-nor0:256k(u-boot),7168k(rcks_wlan.main),7168k(rcks_wlan.bkup),1280k(datafs),256k(u-boot-env) mtdids=nor0=ar7100-nor0 bootdelay=2 filesize=52e000 fileaddr=81000000 ethact=eth0 stdin=serial stdout=serial stderr=serial partition=nor0,0 mtddevnum=0 mtddevname=u-boot ipaddr=192.168.0.1 serverip=192.168.0.2 stderr=serial ethact=eth0 These are the defaults, you can use most likely just this as input to mkenvimage. Now, create environment image and copy it over to TFTP root: $ mkenvimage -s 0x40000 -b -o u-boot-env.bin u-boot-env.txt $ sudo cp u-boot-env.bin /srv/tftp This is the same image, gzipped and base64-encoded: H4sICOLMEGMAA3UtYm9vdC1lbnYtbmV3LmJpbgDt0E1u00AUAGDfgm2XDUrTsUV/pTkFSxZoEk+o lcQJtlNaLsURwU4FikDiBN+3eDNvLL/3Zt5/+vFuud8Pq10dp3V3EV4e1uFDGBXTQeq+9HG1b/v9 NsdheP0Y5mV5U4Vw0Y1f1/3wesix/3pM/dO6v2jaZojX/bJpr6dtsUzHuktDjm//FHl4SnXdxfAS wmN4SWkMy+UYVqsx1PUYci52Q31I3dDHP5vU3ZUhXLX7LjxWN7eby+PVNNxsflfe3m8uu9Wm//xt m9rFLjXtv6fLzfEwm5fVfdhc1mlI6342Pytzldvn2dS1qfs49Tjvd3qFOm/Ta6yKdbPNffM9x5sq Ty805acL3Zfh5HTD1RDHJRT9WLGNfe6atJ2S/XE4y3LX/c6mSzZDs29P3edhmqXOz+1xF//s0y7H t3GL5nDqWT5Ui/Gii7Aoi7HQ81jrcHZY/dXkfLLiJwAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAD8 xy8jb4zOAAAEAA== 7. Perform actual installation. Copy over OpenWrt sysupgrade image to TFTP root: $ sudo cp openwrt-ath79-generic-ruckus_zf7025-squashfs-sysupgrade.bin /srv/tftp Now load both to the device over TFTP: # tftp -l /tmp/u-boot-env.bin -r u-boot-env.bin -g 10.42.0.1 # tftp -l /tmp/openwrt.bin -r openwrt-ath79-generic-ruckus_zf7025-squashfs-sysupgrade.bin -g 10.42.0.1 Verify checksums of both images to ensure the transfer over TFTP was completed: # sha256sum /tmp/u-boot-env.bin /tmp/openwrt.bin And compare it against source images: $ sha256sum /srv/tftp/u-boot-env.bin /srv/tftp/openwrt-ath79-generic-ruckus_zf7025-squashfs-sysupgrade.bin Locate MTD partition of the primary image: # grep rcks_wlan.main /proc/mtd Now, write the images in place. Write U-boot environment last, so unit still can boot from backup image, should power failure occur during this. Replace MTD placeholders with real MTD nodes: # flashcp /tmp/openwrt.bin /dev/<rcks_wlan.main_mtd> # flashcp /tmp/u-boot-env.bin /dev/<u-boot-env_mtd> Finally, reboot the device. The device should directly boot into OpenWrt. Look for the characteristic power LED blinking pattern. # reboot -f After unit boots, it should be available at the usual 192.168.1.1/24. Return to factory firmware: 1. Boot into OpenWrt initramfs as for initial installation. To do that without disassembly, you can write an initramfs image to the device using 'sysupgrade -F' first. 2. Unset the "bootcmd" variable: fw_setenv bootcmd "" 3. Concatenate the firmware backups, if you took them during installation using method 2: $ cat ruckus_zf7025_fw1_backup.bin ruckus_zf7025_fw2_backup.bin > ruckus_zf7025_backup.bin 3. Write factory images downloaded from manufacturer website into fwconcat0 and fwconcat1 MTD partitions, or restore backup you took before installation: # mtd write ruckus_zf7025_backup.bin /dev/mtd1 4. Reboot the system, it should load into factory firmware again. Quirks and known issues: - Flash layout is changed from the factory, to use both firmware image partitions for storage using mtd-concat, and uImage format is used to actually boot the system, which rules out the dual-boot capability. - The 2.4 GHz radio has its own EEPROM on board, not connected to CPU. - The stock firmware has dual-boot capability, which is not supported in OpenWrt by choice. It is controlled by data in the top 64kB of RAM which is unmapped, to avoid the interference in the boot process and accidental switch to the inactive image, although boot script presence in form of "bootcmd" variable should prevent this entirely. - On some versions of stock firmware, it is possible to obtain root shell, however not much is available in terms of debugging facitilies. 1. Login to the rkscli 2. Execute hidden command "Ruckus" 3. Copy and paste ";/bin/sh;" including quotes. This is required only once, the payload will be stored in writable filesystem. 4. Execute hidden command "!v54!". Press Enter leaving empty reply for "What's your chow?" prompt. 5. Busybox shell shall open. Source: https://alephsecurity.com/vulns/aleph-2019014 Signed-off-by: Lech Perczak <lech.perczak@gmail.com> |
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Daniel Golle
|
e586de8dbf
|
ath79: add support for Teltonika RUT300
Add support for the Teltonika RUT300 rugged industrial Ethernet router Hardware -------- SoC: Qualcomm Atheros QCA9531 RAM: 64M DDR2 (EtronTech EM68B16CWQK-25IH) FLASH: 16M SPI-NOR (Winbond W25Q128) ETH: 4x 100M LAN (QCA9533 internal AR8229 switch, eth0) 1x 100M WAN (QCA9533 internal PHY, eth1) UART: 115200 8n1, same debug port as other Teltonika devices USB: 1 single USB 2.0 host port BUTTON: Reset LED: 1x green power LED (always on) 5x yellow Ethernet port LED (controlled by Linux) WAN port LED is used as boot status and upgrade indicator as the power LED cannot be controlled in software. Use the *-factory.bin file to intially flash the device using the vendor firmware's Web-UI. Signed-off-by: Daniel Golle <daniel@makrotopia.org> |
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Edward Chow
|
79107116d1 |
ath79: calibrate TL-WDR4900 v2 with nvmem-cells
Driver for both soc (2.4GHz Wifi) and pci (5 GHz) now pull the calibration data from the nvmem subsystem. This allows us to move the userspace caldata extraction for the pci-e ath9k supported wifi into the device-tree definition of the device. wmac's nodes are also changed over to use nvmem-cells over OpenWrt's custom mtd-cal-data property. Signed-off-by: Edward Chow <equu@openmail.cc> |
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Korey Caro
|
12cee86989 |
ath79: add support to TrendNet TEW-673GRU
Add support for the TrendNet TEW-673GRU to ath79. This device was supported in 19.07.9 but was deprecated with ar71xx. This is mostly a copy of D-Link DIR-825 B1. Updates have been completed to enable factory.bin and sysupgrade.bin both. Code improvements to DTS file and makefile. Architecture | MIPS Vendor | Qualcomm Atheros bootloader | U-Boot System-On-Chip | AR7161 rev 2 (MIPS 24Kc V7.4) CPU/Speed | 24Kc V7.4 680 MHz Flash-Chip | Macronix MX25L6405D Flash size | 8192 KiB RAM Chip: | ProMOS V58C2256164SCI5 × 2 RAM size | 64 MiB Wireless | 2 x Atheros AR922X 2.4GHz/5.0GHz 802.11abgn Ethernet | RealTek RTL8366S Gigabit w/ port based vlan support USB | Yes 2 x 2.0 Initial Flashing Process: 1) Download 22.03 tew-673gru factory bin 2) Flash 22.03 using TrendNet GUI OpenWRT Upgrade Process 3) Download 22.03 tew-673gru sysupgrade.bin 4) Flash 22.03 using OpenWRT GUI Signed-off-by: Korey Caro <korey.caro@gmail.com> |
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INAGAKI Hiroshi
|
48bb71ff28 |
ath79: improve MAC address configuration of ELECOM devices
Get MAC address of WAN from HW.WAN.MAC.Address in hwconfig partition instead of calculated one from wlan's address. And added label_mac. Signed-off-by: INAGAKI Hiroshi <musashino.open@gmail.com> |
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INAGAKI Hiroshi
|
961d4230f4 |
ath79: use NVMEM for wlan caldata on ELECOM devices
Use NVMEM "calibration" implementation for ath9k/ath10k(-ct) on ELECOM WRC-300GHBK2-I and WRC-1750GHBK2-I/C instead of mtd-cal-data property or user-space script. Signed-off-by: INAGAKI Hiroshi <musashino.open@gmail.com> |
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Nick French
|
20581ee8b5 |
ath79: add support for TP-Link Deco S4
Add support for TP-Link Deco S4 wifi router The label refers to the device as S4R and the TP-Link firmware site calls it the Deco S4 v2. (There does not appear to be a v1) Hardware (and FCC id) are identical to the Deco M4R v2 but the flash layout is ordered differently and the OEM firmware encrypts some config parameters (including the label mac address) in flash In order to set the encrypted mac address, the wlan's caldata node is removed from the DTS so the mac can be decrypted with the help of the uencrypt tool and patched into the wlan fw via hotplug Specifications: SoC: QCA9563-AL3A RAM: Zentel A3R1GE40JBF Wireless 2.4GHz: QCA9563-AL3A (main SoC) Wireless 5GHz: QCA9886 Ethernet Switch: QCA8337N-AL3C Flash: 16 MB SPI NOR UART serial access (115200N1) on board via solder pads: RX = TP1 pad TX = TP2 pad GND = C201 (pad nearest board edge) The device's bootloader and web gui will only accept images that were signed using TP-Link's RSA key, however a memory safety bug in the bootloader can be leveraged to install openwrt without accessing the serial console. See developer forum S4 support page for link to a "firmware" file that starts a tftp client, or you may generate one on your own like this: ``` python - > deco_s4_faux_fw_tftp.bin <<EOF import sys from struct import pack b = pack('>I', 0x00008000) + b'X'*16 + b"fw-type:" \ + b'x'*256 + b"S000S001S002" + pack('>I', 0x80060200) \ b += b"\x00"*(0x200-len(b)) \ + pack(">33I", *[0x3c0887fc, 0x35083ddc, 0xad000000, 0x24050000, 0x3c048006, 0x348402a0, 0x3c1987f9, 0x373947f4, 0x0320f809, 0x00000000, 0x24050000, 0x3c048006, 0x348402d0, 0x3c1987f9, 0x373947f4, 0x0320f809, 0x00000000, 0x24050000, 0x3c048006, 0x34840300, 0x3c1987f9, 0x373947f4, 0x0320f809, 0x00000000, 0x24050000, 0x3c048006, 0x34840400, 0x3c1987f9, 0x373947f4, 0x0320f809, 0x00000000, 0x1000fff1, 0x00000000]) b += b"\xff"*(0x2A0-len(b)) + b"setenv serverip 192.168.0.2\x00" b += b"\xff"*(0x2D0-len(b)) + b"setenv ipaddr 192.168.0.1\x00" b += b"\xff"*(0x300-len(b)) + b"tftpboot 0x81000000 initramfs-kernel.bin\x00" b += b"\xff"*(0x400-len(b)) + b"bootm 0x81000000\x00" b += b"\xff"*(0x8000-len(b)) sys.stdout.buffer.write(b) EOF ``` Installation: 1. Run tftp server on pc with static ip 192.168.0.2 2. Place openwrt "initramfs-kernel.bin" image in tftp root dir 3. Connect pc to router ethernet port1 4. While holding in reset button on bottom of router, power on router 5. From pc access router webgui at http://192.168.0.1 6. Upload deco_s4_faux_fw_tftp.bin 7. Router will load and execture in-memory openwrt 8. Switch pc back to dhcp or static 192.168.1.x 9. Flash openwrt sysupgrade image via luci/ssh at 192.168.1.1 Revert to stock: Press and hold reset button while powering device to start the bootloader's recovery mode, where stock firmware can be uploaded via web gui at 192.168.0.1 Please note that one additional non-github commits is also needed: firmware-utils: add tplink-safeloader support for Deco S4 Signed-off-by: Nick French <nickfrench@gmail.com> |
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Michael Pratt
|
5df1b33298 |
ath79: add support for Senao Watchguard AP100
FCC ID: U2M-CAP2100AG WatchGuard AP100 is an indoor wireless access point with 1 Gb ethernet port, dual-band but single-radio wireless, internal antenna plates, and 802.3at PoE+ this board is a Senao device: the hardware is equivalent to EnGenius EAP300 v2 the software is modified Senao SDK which is based on openwrt and uboot including image checksum verification at boot time, and a failsafe image that boots if checksum fails **Specification:** - AR9344 SOC MIPS 74kc, 2.4 GHz AND 5 GHz WMAC, 2x2 - AR8035-A EPHY RGMII GbE with PoE+ IN - 25 MHz clock - 16 MB FLASH mx25l12805d - 2x 64 MB RAM - UART console J11, populated - GPIO watchdog GPIO 16, 20 sec toggle - 2 antennas 5 dBi, internal omni-directional plates - 5 LEDs power, eth0 link/data, 2G, 5G - 1 button reset **MAC addresses:** Label has no MAC Only one Vendor MAC address in flash at art 0x0 eth0 ---- *:e5 art 0x0 -2 phy0 ---- *:e5 art 0x0 -2 **Installation:** Method 1: OEM webpage use OEM webpage for firmware upgrade to upload factory.bin Method 2: root shell It may be necessary to use a Watchguard router to flash the image to the AP and / or to downgrade the software on the AP to access SSH For some Watchguard devices, serial console over UART is disabled. NOTE: DHCP is not enabled by default after flashing **TFTP recovery:** reset button has no function at boot time only possible with modified uboot environment, (see commit message for Watchguard AP300) **Return to OEM:** user should make backup of MTD partitions and write the backups back to mtd devices in order to revert to OEM reliably It may be possible to use sysupgrade with an OEM image as well... (not tested) **OEM upgrade info:** The OEM upgrade script is at /etc/fwupgrade.sh OKLI kernel loader is required because the OEM software expects the kernel to be no greater than 1536k and the factory.bin upgrade procedure would otherwise overwrite part of the kernel when writing rootfs. **Note on eth0 PLL-data:** The default Ethernet Configuration register values will not work because of the external AR8035 switch between the SOC and the ethernet port. For AR934x series, the PLL registers for eth0 can be see in the DTSI as 0x2c. Therefore the PLL registers can be read from uboot for each link speed after attempting tftpboot or another network action using that link speed with `md 0x1805002c 1`. The clock delay required for RGMII can be applied at the PHY side, using the at803x driver `phy-mode`. Therefore the PLL registers for GMAC0 do not need the bits for delay on the MAC side. This is possible due to fixes in at803x driver since Linux 5.1 and 5.3 **Note on WatchGuard Magic string:** The OEM upgrade script is a modified version of the generic Senao sysupgrade script which is used on EnGenius devices. On WatchGuard boards produced by Senao, images are verified using a md5sum checksum of the upgrade image concatenated with a magic string. this checksum is then appended to the end of the final image. This variable does not apply to all the senao devices so set to null string as default Tested-by: Steve Wheeler <stephenw10@gmail.com> Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Michael Pratt
|
9f6e247854 |
ath79: add support for Senao WatchGuard AP200
FCC ID: U2M-CAP4200AG WatchGuard AP200 is an indoor wireless access point with 1 Gb ethernet port, dual-band wireless, internal antenna plates, and 802.3at PoE+ this board is a Senao device: the hardware is equivalent to EnGenius EAP600 the software is modified Senao SDK which is based on openwrt and uboot including image checksum verification at boot time, and a failsafe image that boots if checksum fails **Specification:** - AR9344 SOC MIPS 74kc, 2.4 GHz WMAC, 2x2 - AR9382 WLAN PCI card 168c:0030, 5 GHz, 2x2, 26dBm - AR8035-A EPHY RGMII GbE with PoE+ IN - 25 MHz clock - 16 MB FLASH mx25l12805d - 2x 64 MB RAM - UART console J11, populated - GPIO watchdog GPIO 16, 20 sec toggle - 4 antennas 5 dBi, internal omni-directional plates - 5 LEDs power, eth0 link/data, 2G, 5G - 1 button reset **MAC addresses:** Label has no MAC Only one Vendor MAC address in flash at art 0x0 eth0 ---- *:be art 0x0 -2 phy1 ---- *:bf art 0x0 -1 phy0 ---- *:be art 0x0 -2 **Installation:** Method 1: OEM webpage use OEM webpage for firmware upgrade to upload factory.bin Method 2: root shell It may be necessary to use a Watchguard router to flash the image to the AP and / or to downgrade the software on the AP to access SSH For some Watchguard devices, serial console over UART is disabled. NOTE: DHCP is not enabled by default after flashing **TFTP recovery:** reset button has no function at boot time only possible with modified uboot environment, (see commit message for Watchguard AP300) **Return to OEM:** user should make backup of MTD partitions and write the backups back to mtd devices in order to revert to OEM reliably It may be possible to use sysupgrade with an OEM image as well... (not tested) **OEM upgrade info:** The OEM upgrade script is at /etc/fwupgrade.sh OKLI kernel loader is required because the OEM software expects the kernel to be no greater than 1536k and the factory.bin upgrade procedure would otherwise overwrite part of the kernel when writing rootfs. **Note on eth0 PLL-data:** The default Ethernet Configuration register values will not work because of the external AR8035 switch between the SOC and the ethernet port. For AR934x series, the PLL registers for eth0 can be see in the DTSI as 0x2c. Therefore the PLL registers can be read from uboot for each link speed after attempting tftpboot or another network action using that link speed with `md 0x1805002c 1`. The clock delay required for RGMII can be applied at the PHY side, using the at803x driver `phy-mode`. Therefore the PLL registers for GMAC0 do not need the bits for delay on the MAC side. This is possible due to fixes in at803x driver since Linux 5.1 and 5.3 **Note on WatchGuard Magic string:** The OEM upgrade script is a modified version of the generic Senao sysupgrade script which is used on EnGenius devices. On WatchGuard boards produced by Senao, images are verified using a md5sum checksum of the upgrade image concatenated with a magic string. this checksum is then appended to the end of the final image. This variable does not apply to all the senao devices so set to null string as default Tested-by: Steve Wheeler <stephenw10@gmail.com> Tested-by: John Delaney <johnd@ankco.net> Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Michael Pratt
|
146aaeafb7 |
ath79: add support for Senao WatchGuard AP300
FCC ID: Q6G-AP300 WatchGuard AP300 is an indoor wireless access point with 1 Gb ethernet port, dual-band wireless, internal antenna plates, and 802.3at PoE+ this board is a Senao device: the hardware is equivalent to EnGenius EAP1750 the software is modified Senao SDK which is based on openwrt and uboot including image checksum verification at boot time, and a failsafe image that boots if checksum fails **Specification:** - QCA9558 SOC MIPS 74kc, 2.4 GHz WMAC, 3x3 - QCA9880 WLAN PCI card 168c:003c, 5 GHz, 3x3, 26dBm - AR8035-A PHY RGMII GbE with PoE+ IN - 40 MHz clock - 32 MB FLASH S25FL512S - 2x 64 MB RAM NT5TU32M16 - UART console J10, populated - GPIO watchdog GPIO 16, 20 sec toggle - 6 antennas 5 dBi, internal omni-directional plates - 5 LEDs power, eth0 link/data, 2G, 5G - 1 button reset **MAC addresses:** MAC address labeled as ETH Only one Vendor MAC address in flash at art 0x0 eth0 ETH *:3c art 0x0 phy1 ---- *:3d --- phy0 ---- *:3e --- **Serial console access:** For this board, its not certain whether UART is possible it is likely that software is blocking console access the RX line on the board for UART is shorted to ground by resistor R176 the resistors R175 and R176 are next to the UART RX pin at J10 however console output is garbage even after this fix **Installation:** Method 1: OEM webpage use OEM webpage for firmware upgrade to upload factory.bin Method 2: root shell access downgrade XTM firewall to v2.0.0.1 downgrade AP300 firmware: v1.0.1 remove / unpair AP from controller perform factory reset with reset button connect ethernet to a computer login to OEM webpage with default address / pass: wgwap enable SSHD in OEM webpage settings access root shell with SSH as user 'root' modify uboot environment to automatically try TFTP at boot time (see command below) rename initramfs-kernel.bin to test.bin load test.bin over TFTP (see TFTP recovery) (optionally backup all mtdblocks to have flash backup) perform a sysupgrade with sysupgrade.bin NOTE: DHCP is not enabled by default after flashing **TFTP recovery:** server ip: 192.168.1.101 reset button seems to do nothing at boot time... only possible with modified uboot environment, running this command in the root shell: fw_setenv bootcmd 'if ping 192.168.1.101; then tftp 0x82000000 test.bin && bootm 0x82000000; else bootm 0x9f0a0000; fi' and verify that it is correct with fw_printenv then, before boot, the device will attempt TFTP from 192.168.1.101 looking for file 'test.bin' to return uboot environment to normal: fw_setenv bootcmd 'bootm 0x9f0a0000' **Return to OEM:** user should make backup of MTD partitions and write the backups back to mtd devices in order to revert to OEM (see installation method 2) It may be possible to use sysupgrade with an OEM image as well... (not tested) **OEM upgrade info:** The OEM upgrade script is at /etc/fwupgrade.sh OKLI kernel loader is required because the OEM software expects the kernel to be no greater than 1536k and the factory.bin upgrade procedure would otherwise overwrite part of the kernel when writing rootfs. **Note on eth0 PLL-data:** The default Ethernet Configuration register values will not work because of the external AR8035 switch between the SOC and the ethernet port. For QCA955x series, the PLL registers for eth0 and eth1 can be see in the DTSI as 0x28 and 0x48 respectively. Therefore the PLL registers can be read from uboot for each link speed after attempting tftpboot or another network action using that link speed with `md 0x18050028 1` and `md 0x18050048 1`. The clock delay required for RGMII can be applied at the PHY side, using the at803x driver `phy-mode`. Therefore the PLL registers for GMAC0 do not need the bits for delay on the MAC side. This is possible due to fixes in at803x driver since Linux 5.1 and 5.3 **Note on WatchGuard Magic string:** The OEM upgrade script is a modified version of the generic Senao sysupgrade script which is used on EnGenius devices. On WatchGuard boards produced by Senao, images are verified using a md5sum checksum of the upgrade image concatenated with a magic string. this checksum is then appended to the end of the final image. This variable does not apply to all the senao devices so set to null string as default Tested-by: Alessandro Kornowski <ak@wski.org> Tested-by: John Wagner <john@wagner.us.org> Signed-off-by: Michael Pratt <mcpratt@pm.me> |
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Lech Perczak
|
f1d112ee5a |
ath79: support Ruckus ZoneFlex 7321
Ruckus ZoneFlex 7321 is a dual-band, single radio 802.11n 2x2 MIMO enterprise access point. It is very similar to its bigger brother, ZoneFlex 7372. Hardware highligts: - CPU: Atheros AR9342 SoC at 533 MHz - RAM: 64MB DDR2 - Flash: 32MB SPI-NOR - Wi-Fi: AR9342 built-in dual-band 2x2 MIMO radio - Ethernet: single Gigabit Ethernet port through AR8035 gigabit PHY - PoE: input through Gigabit port - Standalone 12V/1A power input - USB: optional single USB 2.0 host port on the 7321-U variant. Serial console: 115200-8-N-1 on internal H1 header. Pinout: H1 ---------- |1|x3|4|5| ---------- Pin 1 is near the "H1" marking. 1 - RX x - no pin 3 - VCC (3.3V) 4 - GND 5 - TX JTAG: Connector H5, unpopulated, similar to MIPS eJTAG, standard, but without the key in pin 12 and not every pin routed: ------- H5 |1 |2 | ------- |3 |4 | ------- |5 |6 | ------- |7 |8 | ------- |9 |10| ------- |11|12| ------- |13|14| ------- 3 - TDI 5 - TDO 7 - TMS 9 - TCK 2,4,6,8,10 - GND 14 - Vref 1,11,12,13 - Not connected Installation: There are two methods of installation: - Using serial console [1] - requires some disassembly, 3.3V USB-Serial adapter, TFTP server, and removing a single T10 screw, but with much less manual steps, and is generally recommended, being safer. - Using stock firmware root shell exploit, SSH and TFTP [2]. Does not work on some rare versions of stock firmware. A more involved, and requires installing `mkenvimage` from u-boot-tools package if you choose to rebuild your own environment, but can be used without disassembly or removal from installation point, if you have the credentials. If for some reason, size of your sysupgrade image exceeds 13312kB, proceed with method [1]. For official images this is not likely to happen ever. [1] Using serial console: 0. Connect serial console to H1 header. Ensure the serial converter does not back-power the board, otherwise it will fail to boot. 1. Power-on the board. Then quickly connect serial converter to PC and hit Ctrl+C in the terminal to break boot sequence. If you're lucky, you'll enter U-boot shell. Then skip to point 3. Connection parameters are 115200-8-N-1. 2. Allow the board to boot. Press the reset button, so the board reboots into U-boot again and go back to point 1. 3. Set the "bootcmd" variable to disable the dual-boot feature of the system and ensure that uImage is loaded. This is critical step, and needs to be done only on initial installation. > setenv bootcmd "bootm 0x9f040000" > saveenv 4. Boot the OpenWrt initramfs using TFTP. Replace IP addresses as needed: > setenv serverip 192.168.1.2 > setenv ipaddr 192.168.1.1 > tftpboot 0x81000000 openwrt-ath79-generic-ruckus_zf7321-initramfs-kernel.bin > bootm 0x81000000 5. Optional, but highly recommended: back up contents of "firmware" partition: $ ssh root@192.168.1.1 cat /dev/mtd1 > ruckus_zf7321_fw1_backup.bin $ ssh root@192.168.1.1 cat /dev/mtd5 > ruckus_zf7321_fw2_backup.bin 6. Copy over sysupgrade image, and perform actual installation. OpenWrt shall boot from flash afterwards: $ ssh root@192.168.1.1 # sysupgrade -n openwrt-ath79-generic-ruckus_zf7321-squashfs-sysupgrade.bin [2] Using stock root shell: 0. Reset the device to factory defaullts. Power-on the device and after it boots, hold the reset button near Ethernet connectors for 5 seconds. 1. Connect the device to the network. It will acquire address over DHCP, so either find its address using list of DHCP leases by looking for label MAC address, or try finding it by scanning for SSH port: $ nmap 10.42.0.0/24 -p22 From now on, we assume your computer has address 10.42.0.1 and the device has address 10.42.0.254. 2. Set up a TFTP server on your computer. We assume that TFTP server root is at /srv/tftp. 3. Obtain root shell. Connect to the device over SSH. The SSHD ond the frmware is pretty ancient and requires enabling HMAC-MD5. $ ssh 10.42.0.254 \ -o UserKnownHostsFile=/dev/null \ -o StrictHostKeyCheking=no \ -o MACs=hmac-md5 Login. User is "super", password is "sp-admin". Now execute a hidden command: Ruckus It is case-sensitive. Copy and paste the following string, including quotes. There will be no output on the console for that. ";/bin/sh;" Hit "enter". The AP will respond with: grrrr OK Now execute another hidden command: !v54! At "What's your chow?" prompt just hit "enter". Congratulations, you should now be dropped to Busybox shell with root permissions. 4. Optional, but highly recommended: backup the flash contents before installation. At your PC ensure the device can write the firmware over TFTP: $ sudo touch /srv/tftp/ruckus_zf7321_firmware{1,2}.bin $ sudo chmod 666 /srv/tftp/ruckus_zf7321_firmware{1,2}.bin Locate partitions for primary and secondary firmware image. NEVER blindly copy over MTD nodes, because MTD indices change depending on the currently active firmware, and all partitions are writable! # grep rcks_wlan /proc/mtd Copy over both images using TFTP, this will be useful in case you'd like to return to stock FW in future. Make sure to backup both, as OpenWrt uses bot firmwre partitions for storage! # tftp -l /dev/<rcks_wlan.main_mtd> -r ruckus_zf7321_firmware1.bin -p 10.42.0.1 # tftp -l /dev/<rcks_wlan.bkup_mtd> -r ruckus_zf7321_firmware2.bin -p 10.42.0.1 When the command finishes, copy over the dump to a safe place for storage. $ cp /srv/tftp/ruckus_zf7321_firmware{1,2}.bin ~/ 5. Ensure the system is running from the BACKUP image, i.e. from rcks_wlan.bkup partition or "image 2". Otherwise the installation WILL fail, and you will need to access mtd0 device to write image which risks overwriting the bootloader, and so is not covered here and not supported. Switching to backup firmware can be achieved by executing a few consecutive reboots of the device, or by updating the stock firmware. The system will boot from the image it was not running from previously. Stock firmware available to update was conveniently dumped in point 4 :-) 6. Prepare U-boot environment image. Install u-boot-tools package. Alternatively, if you build your own images, OpenWrt provides mkenvimage in host staging directory as well. It is recommended to extract environment from the device, and modify it, rather then relying on defaults: $ sudo touch /srv/tftp/u-boot-env.bin $ sudo chmod 666 /srv/tftp/u-boot-env.bin On the device, find the MTD partition on which environment resides. Beware, it may change depending on currently active firmware image! # grep u-boot-env /proc/mtd Now, copy over the partition # tftp -l /dev/mtd<N> -r u-boot-env.bin -p 10.42.0.1 Store the stock environment in a safe place: $ cp /srv/tftp/u-boot-env.bin ~/ Extract the values from the dump: $ strings u-boot-env.bin | tee u-boot-env.txt Now clean up the debris at the end of output, you should end up with each variable defined once. After that, set the bootcmd variable like this: bootcmd=bootm 0x9f040000 You should end up with something like this: bootcmd=bootm 0x9f040000 bootargs=console=ttyS0,115200 rootfstype=squashfs init=/sbin/init baudrate=115200 ethaddr=0x00:0xaa:0xbb:0xcc:0xdd:0xee mtdparts=mtdparts=ar7100-nor0:256k(u-boot),13312k(rcks_wlan.main),2048k(datafs),256k(u-boot-env),512k(Board Data),13312k(rcks_wlan.bkup) mtdids=nor0=ar7100-nor0 bootdelay=2 ethact=eth0 filesize=78a000 fileaddr=81000000 partition=nor0,0 mtddevnum=0 mtddevname=u-boot ipaddr=10.0.0.1 serverip=10.0.0.5 stdin=serial stdout=serial stderr=serial These are the defaults, you can use most likely just this as input to mkenvimage. Now, create environment image and copy it over to TFTP root: $ mkenvimage -s 0x40000 -b -o u-boot-env.bin u-boot-env.txt $ sudo cp u-boot-env.bin /srv/tftp This is the same image, gzipped and base64-encoded: H4sIAAAAAAAAA+3QQW7TQBQAUF8EKRtQI6XtJDS0VJoN4gYcAE3iCbWS2MF2Sss1ORDYqVq6YMEB3rP0 Z/7Yf+aP3/56827VNP16X8Zx3E/Cw8dNuAqDYlxI7bcurpu6a3Y59v3jlzCbz5eLECbt8HbT9Y+HHLvv x9TdbbpJVVd9vOxWVX05TotVOpZt6nN8qilyf5fKso3hIYTb8JDSEFarIazXQyjLIeRc7PvykNq+iy+T 1F7PQzivmzbcLpYftmfH87G56Wz+/v18sT1r19vu649dqi/2qaqns0W4utmelalPm27I/lac5/p+OluO NZ+a1JaTz8M3/9hmtT0epmMjVdnF8djXLZx+TJl36TEuTlda93EYQrGpdrmrfuZ4fZPGHzjmp/vezMNJ MV6n6qumPm06C+MRZb6vj/v4Mk/7HJ+6LarDqXweLsZnXnS5vc9tdXheWRbd0GIdh/Uq7cakOfavsty2 z1nxGwAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAD+1x9eTkHLAAAEAA== 7. Perform actual installation. Copy over OpenWrt sysupgrade image to TFTP root: $ sudo cp openwrt-ath79-generic-ruckus_zf7321-squashfs-sysupgrade.bin /srv/tftp Now load both to the device over TFTP: # tftp -l /tmp/u-boot-env.bin -r u-boot-env.bin -g 10.42.0.1 # tftp -l /tmp/openwrt.bin -r openwrt-ath79-generic-ruckus_zf7321-squashfs-sysupgrade.bin -g 10.42.0.1 Vverify checksums of both images to ensure the transfer over TFTP was completed: # sha256sum /tmp/u-boot-env.bin /tmp/openwrt.bin And compare it against source images: $ sha256sum /srv/tftp/u-boot-env.bin /srv/tftp/openwrt-ath79-generic-ruckus_zf7321-squashfs-sysupgrade.bin Locate MTD partition of the primary image: # grep rcks_wlan.main /proc/mtd Now, write the images in place. Write U-boot environment last, so unit still can boot from backup image, should power failure occur during this. Replace MTD placeholders with real MTD nodes: # flashcp /tmp/openwrt.bin /dev/<rcks_wlan.main_mtd> # flashcp /tmp/u-boot-env.bin /dev/<u-boot-env_mtd> Finally, reboot the device. The device should directly boot into OpenWrt. Look for the characteristic power LED blinking pattern. # reboot -f After unit boots, it should be available at the usual 192.168.1.1/24. Return to factory firmware: 1. Boot into OpenWrt initramfs as for initial installation. To do that without disassembly, you can write an initramfs image to the device using 'sysupgrade -F' first. 2. Unset the "bootcmd" variable: fw_setenv bootcmd "" 3. Write factory images downloaded from manufacturer website into fwconcat0 and fwconcat1 MTD partitions, or restore backup you took before installation: mtd write ruckus_zf7321_fw1_backup.bin /dev/mtd1 mtd write ruckus_zf7321_fw2_backup.bin /dev/mtd5 4. Reboot the system, it should load into factory firmware again. Quirks and known issues: - Flash layout is changed from the factory, to use both firmware image partitions for storage using mtd-concat, and uImage format is used to actually boot the system, which rules out the dual-boot capability. - The 5GHz radio has its own EEPROM on board, not connected to CPU. - The stock firmware has dual-boot capability, which is not supported in OpenWrt by choice. It is controlled by data in the top 64kB of RAM which is unmapped, to avoid the interference in the boot process and accidental switch to the inactive image, although boot script presence in form of "bootcmd" variable should prevent this entirely. - U-boot disables JTAG when starting. To re-enable it, you need to execute the following command before booting: mw.l 1804006c 40 And also you need to disable the reset button in device tree if you intend to debug Linux, because reset button on GPIO0 shares the TCK pin. - On some versions of stock firmware, it is possible to obtain root shell, however not much is available in terms of debugging facitilies. 1. Login to the rkscli 2. Execute hidden command "Ruckus" 3. Copy and paste ";/bin/sh;" including quotes. This is required only once, the payload will be stored in writable filesystem. 4. Execute hidden command "!v54!". Press Enter leaving empty reply for "What's your chow?" prompt. 5. Busybox shell shall open. Source: https://alephsecurity.com/vulns/aleph-2019014 Signed-off-by: Lech Perczak <lech.perczak@gmail.com> |
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Lech Perczak
|
59cb4dc91d |
ath79: support Ruckus ZoneFlex 7372
Ruckus ZoneFlex 7372 is a dual-band, dual-radio 802.11n 2x2 MIMO enterprise access point. Ruckus ZoneFlex 7352 is also supported, lacking the 5GHz radio part. Hardware highligts: - CPU: Atheros AR9344 SoC at 560 MHz - RAM: 128MB DDR2 - Flash: 32MB SPI-NOR - Wi-Fi 2.4GHz: AR9344 built-in 2x2 MIMO radio - Wi-Fi 5Ghz: AR9582 2x2 MIMO radio (Only in ZF7372) - Antennas: - Separate internal active antennas with beamforming support on both bands with 7 elements per band, each controlled by 74LV164 GPIO expanders, attached to GPIOs of each radio. - Two dual-band external RP-SMA antenna connections on "7372-E" variant. - Ethernet 1: single Gigabit Ethernet port through AR8035 gigabit PHY - Ethernet 2: single Fast Ethernet port through AR9344 built-in switch - PoE: input through Gigabit port - Standalone 12V/1A power input - USB: optional single USB 2.0 host port on "-U" variants. The same image should support: - ZoneFlex 7372E (variant with external antennas, without beamforming capability) - ZoneFlex 7352 (single-band, 2.4GHz-only variant). which are based on same baseboard (codename St. Bernard), with different populated components. Serial console: 115200-8-N-1 on internal H1 header. Pinout: H1 --- |5| --- |4| --- |3| --- |x| --- |1| --- Pin 5 is near the "H1" marking. 1 - RX x - no pin 3 - VCC (3.3V) 4 - GND 5 - TX JTAG: Connector H2, similar to MIPS eJTAG, standard, but without the key in pin 12 and not every pin routed: ------- H2 |1 |2 | ------- |3 |4 | ------- |5 |6 | ------- |7 |8 | ------- |9 |10| ------- |11|12| ------- |13|14| ------- 3 - TDI 5 - TDO 7 - TMS 9 - TCK 2,4,6,8,10 - GND 14 - Vref 1,11,12,13 - Not connected Installation: There are two methods of installation: - Using serial console [1] - requires some disassembly, 3.3V USB-Serial adapter, TFTP server, and removing a single T10 screw, but with much less manual steps, and is generally recommended, being safer. - Using stock firmware root shell exploit, SSH and TFTP [2]. Does not work on some rare versions of stock firmware. A more involved, and requires installing `mkenvimage` from u-boot-tools package if you choose to rebuild your own environment, but can be used without disassembly or removal from installation point, if you have the credentials. If for some reason, size of your sysupgrade image exceeds 13312kB, proceed with method [1]. For official images this is not likely to happen ever. [1] Using serial console: 0. Connect serial console to H1 header. Ensure the serial converter does not back-power the board, otherwise it will fail to boot. 1. Power-on the board. Then quickly connect serial converter to PC and hit Ctrl+C in the terminal to break boot sequence. If you're lucky, you'll enter U-boot shell. Then skip to point 3. Connection parameters are 115200-8-N-1. 2. Allow the board to boot. Press the reset button, so the board reboots into U-boot again and go back to point 1. 3. Set the "bootcmd" variable to disable the dual-boot feature of the system and ensure that uImage is loaded. This is critical step, and needs to be done only on initial installation. > setenv bootcmd "bootm 0x9f040000" > saveenv 4. Boot the OpenWrt initramfs using TFTP. Replace IP addresses as needed: > setenv serverip 192.168.1.2 > setenv ipaddr 192.168.1.1 > tftpboot 0x81000000 openwrt-ath79-generic-ruckus_zf7372-initramfs-kernel.bin > bootm 0x81000000 5. Optional, but highly recommended: back up contents of "firmware" partition: $ ssh root@192.168.1.1 cat /dev/mtd1 > ruckus_zf7372_fw1_backup.bin $ ssh root@192.168.1.1 cat /dev/mtd5 > ruckus_zf7372_fw2_backup.bin 6. Copy over sysupgrade image, and perform actual installation. OpenWrt shall boot from flash afterwards: $ ssh root@192.168.1.1 # sysupgrade -n openwrt-ath79-generic-ruckus_zf7372-squashfs-sysupgrade.bin [2] Using stock root shell: 0. Reset the device to factory defaullts. Power-on the device and after it boots, hold the reset button near Ethernet connectors for 5 seconds. 1. Connect the device to the network. It will acquire address over DHCP, so either find its address using list of DHCP leases by looking for label MAC address, or try finding it by scanning for SSH port: $ nmap 10.42.0.0/24 -p22 From now on, we assume your computer has address 10.42.0.1 and the device has address 10.42.0.254. 2. Set up a TFTP server on your computer. We assume that TFTP server root is at /srv/tftp. 3. Obtain root shell. Connect to the device over SSH. The SSHD ond the frmware is pretty ancient and requires enabling HMAC-MD5. $ ssh 10.42.0.254 \ -o UserKnownHostsFile=/dev/null \ -o StrictHostKeyCheking=no \ -o MACs=hmac-md5 Login. User is "super", password is "sp-admin". Now execute a hidden command: Ruckus It is case-sensitive. Copy and paste the following string, including quotes. There will be no output on the console for that. ";/bin/sh;" Hit "enter". The AP will respond with: grrrr OK Now execute another hidden command: !v54! At "What's your chow?" prompt just hit "enter". Congratulations, you should now be dropped to Busybox shell with root permissions. 4. Optional, but highly recommended: backup the flash contents before installation. At your PC ensure the device can write the firmware over TFTP: $ sudo touch /srv/tftp/ruckus_zf7372_firmware{1,2}.bin $ sudo chmod 666 /srv/tftp/ruckus_zf7372_firmware{1,2}.bin Locate partitions for primary and secondary firmware image. NEVER blindly copy over MTD nodes, because MTD indices change depending on the currently active firmware, and all partitions are writable! # grep rcks_wlan /proc/mtd Copy over both images using TFTP, this will be useful in case you'd like to return to stock FW in future. Make sure to backup both, as OpenWrt uses bot firmwre partitions for storage! # tftp -l /dev/<rcks_wlan.main_mtd> -r ruckus_zf7372_firmware1.bin -p 10.42.0.1 # tftp -l /dev/<rcks_wlan.bkup_mtd> -r ruckus_zf7372_firmware2.bin -p 10.42.0.1 When the command finishes, copy over the dump to a safe place for storage. $ cp /srv/tftp/ruckus_zf7372_firmware{1,2}.bin ~/ 5. Ensure the system is running from the BACKUP image, i.e. from rcks_wlan.bkup partition or "image 2". Otherwise the installation WILL fail, and you will need to access mtd0 device to write image which risks overwriting the bootloader, and so is not covered here and not supported. Switching to backup firmware can be achieved by executing a few consecutive reboots of the device, or by updating the stock firmware. The system will boot from the image it was not running from previously. Stock firmware available to update was conveniently dumped in point 4 :-) 6. Prepare U-boot environment image. Install u-boot-tools package. Alternatively, if you build your own images, OpenWrt provides mkenvimage in host staging directory as well. It is recommended to extract environment from the device, and modify it, rather then relying on defaults: $ sudo touch /srv/tftp/u-boot-env.bin $ sudo chmod 666 /srv/tftp/u-boot-env.bin On the device, find the MTD partition on which environment resides. Beware, it may change depending on currently active firmware image! # grep u-boot-env /proc/mtd Now, copy over the partition # tftp -l /dev/mtd<N> -r u-boot-env.bin -p 10.42.0.1 Store the stock environment in a safe place: $ cp /srv/tftp/u-boot-env.bin ~/ Extract the values from the dump: $ strings u-boot-env.bin | tee u-boot-env.txt Now clean up the debris at the end of output, you should end up with each variable defined once. After that, set the bootcmd variable like this: bootcmd=bootm 0x9f040000 You should end up with something like this: bootcmd=bootm 0x9f040000 bootargs=console=ttyS0,115200 rootfstype=squashfs init=/sbin/init baudrate=115200 ethaddr=0x00:0xaa:0xbb:0xcc:0xdd:0xee bootdelay=2 mtdids=nor0=ar7100-nor0 mtdparts=mtdparts=ar7100-nor0:256k(u-boot),13312k(rcks_wlan.main),2048k(datafs),256k(u-boot-env),512k(Board Data),13312k(rcks_wlan.bkup) ethact=eth0 filesize=1000000 fileaddr=81000000 ipaddr=192.168.0.7 serverip=192.168.0.51 partition=nor0,0 mtddevnum=0 mtddevname=u-boot stdin=serial stdout=serial stderr=serial These are the defaults, you can use most likely just this as input to mkenvimage. Now, create environment image and copy it over to TFTP root: $ mkenvimage -s 0x40000 -b -o u-boot-env.bin u-boot-env.txt $ sudo cp u-boot-env.bin /srv/tftp This is the same image, gzipped and base64-encoded: H4sIAAAAAAAAA+3QTW7TQBQAYB+AQ2TZSGk6Tpv+SbNBrNhyADSJHWolsYPtlJaDcAWOCXaqQhdIXOD7 Fm/ee+MZ+/nHu58fV03Tr/dFHNf9JDzdbcJVGGRjI7Vfurhu6q7ZlbHvnz+FWZ4vFyFM2mF30/XPhzJ2 X4+pe9h0k6qu+njRrar6YkyzVToWberL+HImK/uHVBRtDE8h3IenlIawWg1hvR5CUQyhLE/vLcpdeo6L bN8XVdHFumlDTO1NHsL5mI/9Q2r7Lv5J3uzeL5bX27Pj+XjRdJZfXuaL7Vm73nafv+1SPd+nqp7OFuHq dntWpD5tuqH6e+K8rB+ns+V45n2T2mLyYXjmH9estsfD9DTSuo/DErJNtSu76vswbjg5NU4D3752qsOp zu8W8/z6dh7mN1lXto9lWx3eNJd5Ng5V9VVTn2afnSYuysf6uI9/8rQv48s3Z93wn+o4XFWl3Vg0x/5N Vbbta5X9AgAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA AAAAAAAAAAAAAAAAAAAAAAAAAID/+Q2Z/B7cAAAEAA== 7. Perform actual installation. Copy over OpenWrt sysupgrade image to TFTP root: $ sudo cp openwrt-ath79-generic-ruckus_zf7372-squashfs-sysupgrade.bin /srv/tftp Now load both to the device over TFTP: # tftp -l /tmp/u-boot-env.bin -r u-boot-env.bin -g 10.42.0.1 # tftp -l /tmp/openwrt.bin -r openwrt-ath79-generic-ruckus_zf7372-squashfs-sysupgrade.bin -g 10.42.0.1 Verify checksums of both images to ensure the transfer over TFTP was completed: # sha256sum /tmp/u-boot-env.bin /tmp/openwrt.bin And compare it against source images: $ sha256sum /srv/tftp/u-boot-env.bin /srv/tftp/openwrt-ath79-generic-ruckus_zf7372-squashfs-sysupgrade.bin Locate MTD partition of the primary image: # grep rcks_wlan.main /proc/mtd Now, write the images in place. Write U-boot environment last, so unit still can boot from backup image, should power failure occur during this. Replace MTD placeholders with real MTD nodes: # flashcp /tmp/openwrt.bin /dev/<rcks_wlan.main_mtd> # flashcp /tmp/u-boot-env.bin /dev/<u-boot-env_mtd> Finally, reboot the device. The device should directly boot into OpenWrt. Look for the characteristic power LED blinking pattern. # reboot -f After unit boots, it should be available at the usual 192.168.1.1/24. Return to factory firmware: 1. Boot into OpenWrt initramfs as for initial installation. To do that without disassembly, you can write an initramfs image to the device using 'sysupgrade -F' first. 2. Unset the "bootcmd" variable: fw_setenv bootcmd "" 3. Write factory images downloaded from manufacturer website into fwconcat0 and fwconcat1 MTD partitions, or restore backup you took before installation: mtd write ruckus_zf7372_fw1_backup.bin /dev/mtd1 mtd write ruckus_zf7372_fw2_backup.bin /dev/mtd5 4. Reboot the system, it should load into factory firmware again. Quirks and known issues: - This is first device in ath79 target to support link state reporting on FE port attached trough the built-in switch. - Flash layout is changed from the factory, to use both firmware image partitions for storage using mtd-concat, and uImage format is used to actually boot the system, which rules out the dual-boot capability. The 5GHz radio has its own EEPROM on board, not connected to CPU. - The stock firmware has dual-boot capability, which is not supported in OpenWrt by choice. It is controlled by data in the top 64kB of RAM which is unmapped, to avoid the interference in the boot process and accidental switch to the inactive image, although boot script presence in form of "bootcmd" variable should prevent this entirely. - U-boot disables JTAG when starting. To re-enable it, you need to execute the following command before booting: mw.l 1804006c 40 And also you need to disable the reset button in device tree if you intend to debug Linux, because reset button on GPIO0 shares the TCK pin. - On some versions of stock firmware, it is possible to obtain root shell, however not much is available in terms of debugging facitilies. 1. Login to the rkscli 2. Execute hidden command "Ruckus" 3. Copy and paste ";/bin/sh;" including quotes. This is required only once, the payload will be stored in writable filesystem. 4. Execute hidden command "!v54!". Press Enter leaving empty reply for "What's your chow?" prompt. 5. Busybox shell shall open. Source: https://alephsecurity.com/vulns/aleph-2019014 - Stock firmware has beamforming functionality, known as BeamFlex, using active multi-segment antennas on both bands - controlled by RF analog switches, driven by a pair of 74LV164 shift registers. Shift registers used for each radio are connected to GPIO14 (clock) and GPIO15 of the respective chip. They are mapped as generic GPIOs in OpenWrt - in stock firmware, they were most likely handled directly by radio firmware, given the real-time nature of their control. Lack of this support in OpenWrt causes the antennas to behave as ordinary omnidirectional antennas, and does not affect throughput in normal conditions, but GPIOs are available to tinker with nonetheless. Signed-off-by: Lech Perczak <lech.perczak@gmail.com> |
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Albin Hellström
|
f8c87aa2d2 |
ath79: add support for Extreme Networks WS-AP3805i
Specifications: - SoC: Qualcomm Atheros QCA9557-AT4A - RAM: 2x 128MB Nanya NT5TU64M16HG - FLASH: 64MB - SPANSION FL512SAIFG1 - LAN: Atheros AR8035-A (RGMII GbE with PoE+ IN) - WLAN2: Qualcomm Atheros QCA9557 2x2 2T2R - WLAN5: Qualcomm Atheros QCA9882-BR4A 2x2 2T2R - SERIAL: UART pins at J10 (115200 8n1) Pinout is 3.3V - GND - TX - RX (Arrow Pad is 3.3V) - LEDs: Power (Green/Amber) WiFi 5 (Green) WiFi 2 (Green) - BTN: Reset Installation: 1. Download the OpenWrt initramfs-image. Place it into a TFTP server root directory and rename it to 1D01A8C0.img Configure the TFTP server to listen at 192.168.1.66/24. 2. Connect the TFTP server to the access point. 3. Connect to the serial console of the access point. Attach power and interrupt the boot procedure when prompted. Credentials are admin / new2day 4. Configure U-Boot for booting OpenWrt from ram and flash: $ setenv boot_openwrt 'setenv bootargs; bootm 0xa1280000' $ setenv ramboot_openwrt 'setenv serverip 192.168.1.66; tftpboot 0x89000000 1D01A8C0.img; bootm' $ setenv bootcmd 'run boot_openwrt' $ saveenv 5. Load OpenWrt into memory: $ run ramboot_openwrt 6. Transfer the OpenWrt sysupgrade image to the device. Write the image to flash using sysupgrade: $ sysupgrade -n /path/to/openwrt-sysupgrade.bin Signed-off-by: Albin Hellström <albin.hellstrom@gmail.com> [rename vendor - minor style fixes - update commit message] Signed-off-by: David Bauer <mail@david-bauer.net> |
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Sebastian Schaper
|
a434795809 |
ath79: add support for ZyXEL NWA1100-NH
Specifications: * AR9342, 16 MiB Flash, 64 MiB RAM, 802.11n 2T2R, 2.4 GHz * 1x Gigabit Ethernet (AR8035), 802.3af PoE Installation: * OEM Web UI is at 192.168.1.2 login as `admin` with password `1234` * Flash factory-AASI.bin The string `AASI` needs to be present within the file name of the uploaded image to be accepted by the OEM Web-based updater, the factory image is named accordingly to save the user from the hassle of manual renaming. TFTP Recovery: * Open the case, connect to TTL UART port (this is the official method described by Zyxel, the reset button is useless during power-on) * Extract factory image (.tar.bz2), serve `vmlinux_mi124_f1e.lzma.uImage` and `mi124_f1e-jffs2` via tftp at 192.168.1.10 * Interrupt uboot countdown, execute commands `run lk` `run lf` to flash the kernel / filesystem accordingly MAC addresses as verified by OEM firmware: use address source LAN *:cc mib0 0x30 ('eth0mac'), art 0x1002 (label) 2g *:cd mib0 0x4b ('wifi0mac') Signed-off-by: Sebastian Schaper <openwrt@sebastianschaper.net> |