openwrtv4/target/linux/ramips/base-files/etc/board.d/01_leds

445 lines
14 KiB
Text
Raw Normal View History

#!/bin/sh
. /lib/functions/uci-defaults.sh
set_wifi_led() {
ucidef_set_led_netdev "wifi_led" "wifi" "${1}" "${2:-wlan0}"
}
board=$(board_name)
boardname="${board##*,}"
board_config_update
case $board in
3g-6200n)
set_wifi_led "$boardname:amber:wlan"
;;
3g-6200nl|\
wnce2001)
set_wifi_led "$boardname:green:wlan"
;;
br-6475nd|\
mzk-w300nh2)
set_wifi_led "$boardname:amber:wlan"
;;
ai-br100)
ucidef_set_led_netdev "wan" "wan" "$boardname:blue:wan" "eth0.2"
set_wifi_led "$boardname:blue:wlan"
;;
air3gii)
set_wifi_led "$boardname:green:wlan"
;;
alfa-network,ac1200rm)
set_wifi_led "$boardname:green:wlan2g" "wlan1"
;;
alfa-network,awusfree1)
set_wifi_led "$boardname:blue:wlan"
;;
all0256n-4M|\
all0256n-8M)
ucidef_set_rssimon "wlan0" "200000" "1"
ucidef_set_led_rssi "rssilow" "RSSILOW" "all0256n:green:rssilow" "wlan0" "1" "40" "0" "6"
ucidef_set_led_rssi "rssimedium" "RSSIMEDIUM" "all0256n:green:rssimed" "wlan0" "30" "80" "-29" "5"
ucidef_set_led_rssi "rssihigh" "RSSIHIGH" "all0256n:green:rssihigh" "wlan0" "70" "100" "-69" "8"
set_wifi_led "rt2800pci-phy0::radio"
;;
ar670w|\
ar725w|\
awapn2403)
set_wifi_led "rt2800soc-phy0::radio"
;;
asl26555-8M|\
asl26555-16M)
ucidef_set_led_netdev "eth" "ETH" "asl26555:green:eth" "eth0"
set_wifi_led "asl26555:green:wlan"
;;
broadway)
set_wifi_led "$boardname:red:wps_active"
;;
ramips: add support for the HNET C108 The HNET C108 (http://www.szhwtech88.com/Product-product-cid-100-id-4374.html) is a mifi based on MT7602A, which has the following specifications: * CPU: MT7620A * 1x 10/100Mbps Ethernet. * 16 MB Flash. * 64 MB RAM. * 1x USB 2.0 port. Only power is connected, this port is meant for charging other devices. * 1x mini-PCIe slots. * 1x SIM slots. * 1x 2.4Ghz WIFI. * 1x button. * 6000 mAh battery. * 5x controllable LEDs. Works: * Wifi. * Switch. * mini-PCIe slot. Only tested with a USB device (a modem). * SIM slot. * Sysupgrade. * Button (reset). Not working (also applies to the factory firmware): * Wifi LED. It is always switched on, there is no relation to the up/down state or activity of the wireless interface. Not tested: * SD card reader. Notes: * The C108 has no dedicated status LED. I therefore set the LAN LED as status LED. Installation: The router comes pre-installed with OpenWRT, including a variant of Luci. The initial firmware install can be done through this UI, following normal procedure. I.e., access the UI and update the firmware using the sysupgrade-image. Remember to select that you do not want to keep existing settings. Recovery: If you brick the device, the C108 supports recovery using TFTP. Keep the reset button pressed for ~5sec when booting to trigger TFTP. Set the address of the network interface on your machine to 10.10.10.3/24, and rename your image file to Kernal.bin. Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-09-06 09:14:16 +00:00
c108)
ucidef_set_led_netdev "lan" "lan" "$boardname:green:lan" "eth0"
ucidef_set_led_netdev "modem" "modem" "$boardname:green:modem" "wwan0"
ramips: add support for the HNET C108 The HNET C108 (http://www.szhwtech88.com/Product-product-cid-100-id-4374.html) is a mifi based on MT7602A, which has the following specifications: * CPU: MT7620A * 1x 10/100Mbps Ethernet. * 16 MB Flash. * 64 MB RAM. * 1x USB 2.0 port. Only power is connected, this port is meant for charging other devices. * 1x mini-PCIe slots. * 1x SIM slots. * 1x 2.4Ghz WIFI. * 1x button. * 6000 mAh battery. * 5x controllable LEDs. Works: * Wifi. * Switch. * mini-PCIe slot. Only tested with a USB device (a modem). * SIM slot. * Sysupgrade. * Button (reset). Not working (also applies to the factory firmware): * Wifi LED. It is always switched on, there is no relation to the up/down state or activity of the wireless interface. Not tested: * SD card reader. Notes: * The C108 has no dedicated status LED. I therefore set the LAN LED as status LED. Installation: The router comes pre-installed with OpenWRT, including a variant of Luci. The initial firmware install can be done through this UI, following normal procedure. I.e., access the UI and update the firmware using the sysupgrade-image. Remember to select that you do not want to keep existing settings. Recovery: If you brick the device, the C108 supports recovery using TFTP. Keep the reset button pressed for ~5sec when booting to trigger TFTP. Set the address of the network interface on your machine to 10.10.10.3/24, and rename your image file to Kernal.bin. Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-09-06 09:14:16 +00:00
;;
c20i)
ucidef_set_led_switch "lan" "lan" "$boardname:blue:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:blue:wan" "switch0" "0x01"
ucidef_set_led_wlan "wlan" "wlan" "$boardname:blue:wlan" "phy0radio"
;;
c50)
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
ucidef_set_led_netdev "wlan2g" "wlan2g" "$boardname:green:wlan2g" wlan1
set_wifi_led "$boardname:green:wlan5g"
;;
cf-wr800n)
ucidef_set_led_netdev "lan" "lan" "$boardname:white:ethernet" eth0.1
set_wifi_led "$boardname:white:wifi"
;;
d240)
set_wifi_led "$boardname:blue:wifi"
;;
dcs-930l-b1)
ucidef_set_led_netdev "wifi" "WiFi" "$boardname:blue:wps"
;;
dir-300-b1|\
dir-600-b1|\
dir-620-a1)
set_wifi_led "rt2800pci-phy0::radio"
;;
dir-300-b7|\
dir-320-b1|\
dir-610-a1|\
esr-9753|\
hlk-rm04|\
sl-r7205|\
v11st-fe|\
w306r-v20|\
wt1520-4M|\
wt1520-8M)
set_wifi_led "rt2800pci-phy0::radio"
;;
dir-615-d|\
dir-615-h1)
set_wifi_led "rt2800pci-phy0::radio"
;;
dir-620-d1|\
dlink,dwr-116-a1|\
mzk-ex300np)
set_wifi_led "$boardname:green:wifi"
;;
dlink,dwr-118-a2)
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x0e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
set_wifi_led "$boardname:green:wlan2g" "wlan1"
;;
dlink,dwr-921-c1)
set_wifi_led "$boardname:green:wifi"
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x0f"
;;
dir-860l-b1)
ucidef_set_led_netdev "wan" "wan" "$boardname:green:net" "eth0.2"
;;
edimax,br-6478ac-v2)
set_wifi_led "$boardname:blue:wlan"
;;
ex2700|\
wn3000rpv3)
set_wifi_led "$boardname:green:router"
;;
ex3700)
ucidef_set_led_netdev "wlan5g" "ROUTER (green)" "$boardname:green:router" "wlan0"
ucidef_set_led_netdev "wlan2g" "DEVICE (green)" "$boardname:green:device" "wlan1"
;;
f5d8235-v1)
set_wifi_led "$boardname:blue:wireless"
;;
fonera20n)
set_wifi_led "$boardname:orange:wifi"
;;
gnubee,gb-pc1|\
gnubee,gb-pc2)
ucidef_set_led_switch "lan1" "lan1" "$boardname:green:lan1" "switch0" "0x01"
ucidef_set_led_switch "lan2" "lan2" "$boardname:green:lan2" "switch0" "0x10"
;;
gl-mt300a|\
gl-mt300n|\
gl-mt750)
set_wifi_led "$boardname:wlan"
;;
gl-mt300n-v2)
set_wifi_led "$boardname:red:wlan"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x1"
;;
hc5661|\
hc5661a)
ucidef_set_led_netdev "internet" "internet" "$boardname:blue:internet" "eth0.2"
set_wifi_led "$boardname:blue:wlan2g"
;;
hc5761)
ucidef_set_led_netdev "internet" "internet" "$boardname:blue:internet" "eth0.2"
set_wifi_led "$boardname:blue:wlan2g"
ucidef_set_led_netdev "wifi5g" "wifi5g" "$boardname:blue:wlan5g" "rai0"
;;
hc5861)
ucidef_set_led_netdev "internet" "internet" "$boardname:blue:internet" "eth0.2"
set_wifi_led "$boardname:blue:wlan2g"
ucidef_set_led_netdev "wifi5g" "wifi5g" "$boardname:blue:wlan5g" "rai0"
;;
hg255d)
set_wifi_led "$boardname:green:wlan"
ucidef_set_led_netdev "internet" "internet" "$boardname:green:internet" "eth0.2"
;;
hiwifi,hc5861b)
set_wifi_led "$boardname:green:wlan2g"
;;
hpm)
ucidef_set_led_netdev "eth" "ETH" "$boardname:green:eth" "eth0"
set_wifi_led "$boardname:green:wifi"
;;
ht-tm02)
ucidef_set_led_netdev "eth" "Ethernet" "$boardname:green:lan" "eth0"
set_wifi_led "$boardname:blue:wlan"
;;
kimax,u35wf)
set_wifi_led "$boardname:blue:wifi"
ucidef_set_led_netdev "eth" "ETH" "$boardname:green:eth" "eth0"
;;
kn|\
nbg-419n2)
set_wifi_led "rt2800pci-phy0::radio"
;;
kn_rc|\
kn_rf|\
kng_rc)
set_wifi_led "$boardname:green:wifi"
;;
lava,lr-25g001)
ucidef_set_led_netdev "wlan2g" "WiFi 2.4GHz" "$boardname:green:wlan2g" "wlan1"
ucidef_set_led_netdev "wlan5g" "WiFi 5GHz" "$boardname:green:wlan5g" "wlan0"
;;
linkits7688)
ucidef_set_led_wlan "wifi" "wifi" "linkit-smart-7688:orange:wifi" "phy0tpt"
;;
m2m)
set_wifi_led "$boardname:blue:wifi"
ucidef_set_led_netdev "eth" "Ethernet" "$boardname:green:wan" "eth0"
;;
ramips: add support for MikroTik RouterBOARD RBM11g This commit adds support for the MikroTik RouterBOARD RBM11g. =Hardware= The RBM11g is a mt7621 based device featuring one GbE port and one miniPCIe slot with a sim card socket and USB 2.0. ==Switch== The single onboard Ethernet port is connected the CPU directly. The internal switch of the mt7621 SoC is disabled. ==Flash== The device has one spi nor flash chip. It is a 128 Mbit winbond 25Q128FVS connected to CS0. ==PCIe== The board features a single miniPCIe slot. It has a dedicated mini SIM socket and a USB 2.0 port. Power to the miniPCIe slot is controlled via GPIO9. ==USB== There are no external USB ports. ==Power== The board can accept both, passive PoE and external power via a 2.1 mm barrel jack (center-positive). The input voltage range is 11-32 V. ==Serial port== The device does have an onboard UART on an unpopulated header next to the flash chip: GND: pin 2 TX: pin 7 RX: pin 6 Settings: 115200, 8N1 See below illustration for positioning of the header. 0 = screw hole * = some pin T = TX pin R = RX pin G = GND pin Pinout: +--------------- |O | __ | / \ | \__/ | | | | +---+ | |RAM| | +--+ | | | |**| <- unpopulated header with UART | |*T| +---+ | |R*| +--------+ | |**| | | | |G*| | CPU | | +--+ | | | +--+ | | | | | +--------+ | +--+ <- flash chip |O | +-----+ | | | |+--+ | | || | | | +--------------------- =Installation= To install an OpenWRT image to the device two components must be built: 1. A openwrt initramfs image 2. A openwrt sysupgrade image ===initramfs & sysupgrade image=== Select target devices "Mikrotik RBM11G" in openwrt menuconfig and build the images. This will create the images "openwrt-ramips-mt7621-mikrotik_rbm11g-initramfs-kernel.bin" and "openwrt-ramips-mt7621-mikrotik_rbm11g-squashfs-sysupgrade.bin" in the output directory. ==Installing== **Make sure to back up your RouterOS license in case you do ever want to go back to RouterOS using "/system license output" and back up the created license file.** When rebooted the board will try booting via ethernet first. If your board does not boot via ethernet automatically you will have to attach to the serial port and set ethernet as boot device within RouterBOOT. 1. Set up a dhcp server that points the bootfile to tftp server serving the "openwrt-ramips-mt7621-mikrotik_rbm11g-initramfs-kernel.bin" initramfs image 2. Connect to ethernet port on board 3. Power on the board 4. Wait for OpenWrt to boot Right now OpenWrt will be running with a SSH server listening. Now OpenWrt must be flashed to the devices flash: 1. Copy "openwrt-ramips-mt7621-mikrotik_rbm11g-squashfs-sysupgrade.bin" to the device using scp. 2. Write openwrt to flash using "sysupgrade openwrt-ramips-mt7621-mikrotik_rbm11g-squashfs-sysupgrade.bin" Once the flashing completes the board will reboot. Disconnect from the devices ethernet port or stop the DHCP/TFTP server to prevent the device from booting via ethernet again. The device should now boot straight to OpenWrt. Signed-off-by: Tobias Schramm <tobleminer@gmail.com>
2018-06-25 20:51:43 +00:00
mikrotik,rbm11g)
ucidef_set_rssimon "wlan0" "200000" "1"
ucidef_set_led_rssi "rssilow" "RSSILOW" "$boardname:green:rssi0" "wlan0" "1" "100"
ucidef_set_led_rssi "rssimediumlow" "RSSIMEDIUMLOW" "$boardname:green:rssi1" "wlan0" "20" "100"
ucidef_set_led_rssi "rssimediumhigh" "RSSIMEDIUMHIGH" "$boardname:green:rssi2" "wlan0" "40" "100"
ucidef_set_led_rssi "rssihigh" "RSSIHIGH" "$boardname:green:rssi3" "wlan0" "60" "100"
ucidef_set_led_rssi "rssiveryhigh" "RSSIVERYHIGH" "$boardname:green:rssi4" "wlan0" "80" "100"
;;
miniembplug)
set_wifi_led "$boardname:red:wlan"
;;
mir3g)
ucidef_set_led_switch "wan-amber" "WAN (amber)" "$boardname:amber:wan" "switch0" "0x02" "0x08"
ucidef_set_led_switch "lan1-amber" "LAN1 (amber)" "$boardname:amber:lan1" "switch0" "0x08" "0x08"
ucidef_set_led_switch "lan2-amber" "LAN2 (amber)" "$boardname:amber:lan2" "switch0" "0x04" "0x08"
;;
mlw221|\
mlwg2)
set_wifi_led "$boardname:blue:wifi"
;;
mr-102n)
set_wifi_led "$boardname:green:wlan"
;;
mr200)
ucidef_set_led_netdev "lan" "lan" "$boardname:white:lan" "eth0.1"
ucidef_set_led_netdev "wan" "wan" "$boardname:white:wan" "usb0"
set_wifi_led "$boardname:white:wlan"
;;
mzk-ex750np)
set_wifi_led "$boardname:red:wifi"
;;
netgear,r6120)
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x0f"
ucidef_set_led_wlan "wlan2g" "WiFi 2.4GHz" "$boardname:green:wlan2g" "phy0tpt"
ucidef_set_led_wlan "wlan5g" "WiFi 5GHz" "$boardname:green:wlan5g" "phy1tpt"
;;
oy-0001)
set_wifi_led "$boardname:green:wifi"
;;
pbr-m1)
ucidef_set_led_netdev "internet" "internet" "$boardname:blue:internet" "eth0.2"
;;
d-team,newifi-d2)
ucidef_set_led_switch "internet" "internet" "$boardname:amber:internet" "switch0" "0x10"
ucidef_set_led_netdev "wlan2g" "WiFi 2.4GHz" "$boardname:blue:wlan2g" "wlan0"
ucidef_set_led_netdev "wlan5g" "WiFi 5GHz" "$boardname:blue:wlan5g" "wlan1"
;;
psg1208)
set_wifi_led "$boardname:white:wlan2g"
;;
px-4885-4M|\
px-4885-8M)
set_wifi_led "px-4885:orange:wifi"
;;
r6220)
ucidef_set_led_netdev "wan" "wan" "$boardname:green:wan" eth0.2
set_wifi_led "$boardname:green:wifi"
;;
re350-v1)
ucidef_set_led_netdev "wifi2g" "Wifi 2.4G" "$boardname:blue:wifi2G" "wlan0"
ucidef_set_led_netdev "wifi5g" "Wifi 5G" "$boardname:blue:wifi5G" "wlan1"
ucidef_set_led_netdev "eth_act" "LAN act" "$boardname:green:eth_act" "eth0" "tx rx"
ucidef_set_led_switch "eth_link" "LAN link" "$boardname:green:eth_link" "switch0" "0x01"
;;
rp-n53)
ucidef_set_led_netdev "eth" "Network" "$boardname:white:back" "eth0"
set_wifi_led "$boardname:blue:wifi"
;;
rt-ac51u)
set_wifi_led "$boardname:blue:wifi"
;;
rt-n12p)
ucidef_set_led_netdev "lan" "lan" "$boardname:green:lan" eth0.1
ucidef_set_led_netdev "wan" "wan" "$boardname:green:wan" eth0.2
set_wifi_led "$boardname:green:air"
;;
rt-n14u)
ucidef_set_led_netdev "lan" "lan" "$boardname:blue:lan" eth0.1
ucidef_set_led_netdev "wan" "wan" "$boardname:blue:wan" eth0.2
set_wifi_led "$boardname:blue:air"
;;
ramips: add support for Skylab SKW92A in EVB Specifically, SKW92A_E16, described here: http://www.skylabmodule.com/wp-content/uploads/SkyLab_SKW92A_V1.04_datasheet.pdf Specification: - MediaTek MT7628N/N (580 Mhz) - 64 MB of RAM - 16 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x u.FL - Power by micro-USB connector at USB1 on EVB - UART via micro-USB connector at USB3 on EVB (57600 8n1) - 5x Ethernet LEDs - 1x WLAN LEDs - 1x WPS LED connected by jumper wire from I2S_CK on J20 to WPS_LED pin hole next to daughter board on EVB - WPS/Reset button (S2 on EVB) - RESET button (S1 on EVB) is *not* connected to RST hole next to daughter board Flash instruction: >From Skylab firmware: 1. Associate with SKYLAP_AP 2. In a browser, load: http://10.10.10.254/ 3. Username/password: admin/admin 4. In web admin interface: Administration / Upload Firmware, browse to sysupgrade image, apply, flash will fail with a message: Not a valid firmware. *** Warning: "/var/tmpFW" has corrupted data! 5. Telnet to 10.10.10.254, drops you into a root shell with no credentials 6. # cd /var 7. # mtd_write -r write tmpFW mtd4 Unlocking mtd4 ... Writing from tmpFW to mtd4 ... [e] 8. When flash has completed, you will have booted into your firmware. >From U-boot via TFTP and initramfs: 1. Place openwrt-ramips-mt76x8-skw92a-initramfs-kernel.bin on a TFTP server 2. Connect to serial console at USB3 on EVB 3. Connect ethernet between port 1 (not WAN) and your TFTP server (e.g. 192.168.11.20) 4. Start terminal software (e.g. screen /dev/ttyUSB0 57600) on PC 5. Apply power to EVB 6. Interrupt u-boot with keypress of "1" 7. At u-boot prompts: Input device IP (10.10.10.123) ==:192.168.11.21 Input server IP (10.10.10.3) ==:192.168.11.20 Input Linux Kernel filename (root_uImage) ==:openwrt-ramips-mt76x8-skw92a-initramfs-kernel.bin 8. Move ethernet to port 0 (WAN) on EVB 9. At new OpenWrt console shell, fetch squashfs-sysupgrade image and flash with sysupgrade. >From U-boot via TFTP direct flash: 1. Place openwrt-ramips-mt76x8-skw92a-squashfs-sysupgrade.bin on a TFTP server 2. Connect to serial console at USB3 on EVB (57600 8N1) 3. Connect ethernet between port 1 (not WAN) an your TFTP server (e.g. 192.168.11.20) 4. Start terminal software (e.g. screen /dev/ttyUSB0 57600) on PC 5. Apply power to EVB 6. Interrupt u-boot with keypress of "2" 7. At u-boot prompts: Warning!! Erase Linux in Flash then burn new one. Are you sure?(Y/N) Y Input device IP (10.10.10.123) ==:192.168.11.21 Input server IP (10.10.10.3) ==:192.168.11.20 Input Linux Kernel filename (root_uImage) ==:openwrt-ramips-mt76x8-skw92a-squashfs-sysupgrade.bin 8. When transfer is complete or as OpenWrt begins booting, move ethernet to port 0 (WAN). Signed-off-by: Russell Senior <russell@personaltelco.net>
2018-11-25 11:39:19 +00:00
skw92a)
set_wifi_led "$boardname:green:wlan"
;;
tama,w06)
ucidef_set_led_netdev "wan" "WAN" "$boardname:green:wan" "eth0"
ucidef_set_led_wlan "wlan" "WLAN" "$boardname:green:wlan" "phy0tpt"
;;
tew-714tru)
set_wifi_led "$boardname:green:wifi"
;;
tiny-ac)
set_wifi_led "$boardname:orange:wifi"
;;
ramips: add support for TP-Link TL-WR840N v4 and TL-WR841N v13 TP-Link TL-WR840N v4 and TL-WR841N v13 are simple N300 routers with 5-port FE switch and non-detachable antennas. Both are very similar and are based on MediaTek MT7628NN (aka MT7628N) WiSoC. The difference between these two models is in number of available LEDs, buttons and power input switch. This work is partially based on GitHub PR#974. Specification: - MT7628N/N (580 MHz) - 64 MB of RAM (DDR2) - 8 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x external, non-detachable antennas - UART (J1) header on PCB (115200 8n1) - TL-WR840N v4: 5x LED (GPIO-controlled), 1x button - TL-WR841N v13: 8x LED (GPIO-controlled*), 2x button, power input switch * WAN LED in TL-WR841N v13 is a dual-color, dual-leads type which isn't (fully) supported by gpio-leds driver. This type of LED requires both GPIOs state change at the same time to select color or turn it off. For now, we support/use only the green part of the LED. Factory image notes: These devices use version 3 of TP-Link header, fortunately without RSA signature (at least in case of devices sold in Europe). The difference lays in the requirement for a non-zero value in "Additional Hardware Version" field. Ideally, it should match the value stored in vendor firmware header on device ("0x4"/"0x13" for these devices) but it seems that anything other than "0" is correct. We are able to prepare factory firwmare file which is accepted and (almost) correctly flashed from the vendor GUI. As it turned out, it accepts files without U-Boot image with second header at the beginning but due to some kind of bug in upgrade routine, flashed image gets corrupted before it's written to flash. Tests showed that the GUI upgrade routine copies value of "Additional Hardware Version" from existing firmware into offset "0x2023c" in provided file, _before_ storing it in flash. In case of vendor firmware upgrade files (which all include U-Boot image and two headers), this offset points to the matching field in kernel+rootfs firmware part header. Unfortunately, in case of LEDE factory image file which contains only one header, it points to the offset "0x2023c" in kernel image. This leads to a corrupted kernel and ends up with a "soft-bricked" device. The good news is that U-Boot in these devices contains well known tftp recovery mode, which can be triggered with "reset" button. What's more, in comparison to some of older MediaTek based TP-Link devices, this recovery mode doesn't write whole file at offset "0x0" in flash, without verifying provided file in advance. In case of recovery mode in these devices, first "0x20000" bytes are always skipped and "0x7a0000" bytes from rest of the file are stored in flash at offset "0x20000". Flash instruction: Until (if at all) TP-Link fixes described problem, the only way to flash LEDE image in these devices is to use tftp recovery mode in U-Boot: 1. Configure PC with static IP 192.168.0.66/24 and tftp server. 2. Rename "lede-ramips-mt7628-tl-wr84...-squashfs-tftp-recovery.bin" to "tp_recovery.bin" and place it in tftp server directory. 3. Connect PC with one of LAN ports, press the reset button, power up the router and keep button pressed for around 6-7 seconds, until device starts downloading the file. 4. Router will download file from server, write it to flash and reboot. To access U-Boot CLI, keep pressed "4" key during boot. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com>
2017-06-21 12:16:15 +00:00
tl-wr840n-v4)
ucidef_set_led_wlan "wlan2g" "wlan2g" "$boardname:green:wlan" "phy0tpt"
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
ramips: add support for TP-Link TL-WR840N v4 and TL-WR841N v13 TP-Link TL-WR840N v4 and TL-WR841N v13 are simple N300 routers with 5-port FE switch and non-detachable antennas. Both are very similar and are based on MediaTek MT7628NN (aka MT7628N) WiSoC. The difference between these two models is in number of available LEDs, buttons and power input switch. This work is partially based on GitHub PR#974. Specification: - MT7628N/N (580 MHz) - 64 MB of RAM (DDR2) - 8 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x external, non-detachable antennas - UART (J1) header on PCB (115200 8n1) - TL-WR840N v4: 5x LED (GPIO-controlled), 1x button - TL-WR841N v13: 8x LED (GPIO-controlled*), 2x button, power input switch * WAN LED in TL-WR841N v13 is a dual-color, dual-leads type which isn't (fully) supported by gpio-leds driver. This type of LED requires both GPIOs state change at the same time to select color or turn it off. For now, we support/use only the green part of the LED. Factory image notes: These devices use version 3 of TP-Link header, fortunately without RSA signature (at least in case of devices sold in Europe). The difference lays in the requirement for a non-zero value in "Additional Hardware Version" field. Ideally, it should match the value stored in vendor firmware header on device ("0x4"/"0x13" for these devices) but it seems that anything other than "0" is correct. We are able to prepare factory firwmare file which is accepted and (almost) correctly flashed from the vendor GUI. As it turned out, it accepts files without U-Boot image with second header at the beginning but due to some kind of bug in upgrade routine, flashed image gets corrupted before it's written to flash. Tests showed that the GUI upgrade routine copies value of "Additional Hardware Version" from existing firmware into offset "0x2023c" in provided file, _before_ storing it in flash. In case of vendor firmware upgrade files (which all include U-Boot image and two headers), this offset points to the matching field in kernel+rootfs firmware part header. Unfortunately, in case of LEDE factory image file which contains only one header, it points to the offset "0x2023c" in kernel image. This leads to a corrupted kernel and ends up with a "soft-bricked" device. The good news is that U-Boot in these devices contains well known tftp recovery mode, which can be triggered with "reset" button. What's more, in comparison to some of older MediaTek based TP-Link devices, this recovery mode doesn't write whole file at offset "0x0" in flash, without verifying provided file in advance. In case of recovery mode in these devices, first "0x20000" bytes are always skipped and "0x7a0000" bytes from rest of the file are stored in flash at offset "0x20000". Flash instruction: Until (if at all) TP-Link fixes described problem, the only way to flash LEDE image in these devices is to use tftp recovery mode in U-Boot: 1. Configure PC with static IP 192.168.0.66/24 and tftp server. 2. Rename "lede-ramips-mt7628-tl-wr84...-squashfs-tftp-recovery.bin" to "tp_recovery.bin" and place it in tftp server directory. 3. Connect PC with one of LAN ports, press the reset button, power up the router and keep button pressed for around 6-7 seconds, until device starts downloading the file. 4. Router will download file from server, write it to flash and reboot. To access U-Boot CLI, keep pressed "4" key during boot. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com>
2017-06-21 12:16:15 +00:00
;;
tl-wr841n-v13)
ucidef_set_led_wlan "wlan2g" "wlan2g" "$boardname:green:wlan" "phy0tpt"
ucidef_set_led_switch "lan1" "lan1" "$boardname:green:lan1" "switch0" "0x2"
ucidef_set_led_switch "lan2" "lan2" "$boardname:green:lan2" "switch0" "0x4"
ucidef_set_led_switch "lan3" "lan3" "$boardname:green:lan3" "switch0" "0x8"
ucidef_set_led_switch "lan4" "lan4" "$boardname:green:lan4" "switch0" "0x10"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
ramips: add support for TP-Link TL-WR840N v4 and TL-WR841N v13 TP-Link TL-WR840N v4 and TL-WR841N v13 are simple N300 routers with 5-port FE switch and non-detachable antennas. Both are very similar and are based on MediaTek MT7628NN (aka MT7628N) WiSoC. The difference between these two models is in number of available LEDs, buttons and power input switch. This work is partially based on GitHub PR#974. Specification: - MT7628N/N (580 MHz) - 64 MB of RAM (DDR2) - 8 MB of FLASH - 2T2R 2.4 GHz - 5x 10/100 Mbps Ethernet - 2x external, non-detachable antennas - UART (J1) header on PCB (115200 8n1) - TL-WR840N v4: 5x LED (GPIO-controlled), 1x button - TL-WR841N v13: 8x LED (GPIO-controlled*), 2x button, power input switch * WAN LED in TL-WR841N v13 is a dual-color, dual-leads type which isn't (fully) supported by gpio-leds driver. This type of LED requires both GPIOs state change at the same time to select color or turn it off. For now, we support/use only the green part of the LED. Factory image notes: These devices use version 3 of TP-Link header, fortunately without RSA signature (at least in case of devices sold in Europe). The difference lays in the requirement for a non-zero value in "Additional Hardware Version" field. Ideally, it should match the value stored in vendor firmware header on device ("0x4"/"0x13" for these devices) but it seems that anything other than "0" is correct. We are able to prepare factory firwmare file which is accepted and (almost) correctly flashed from the vendor GUI. As it turned out, it accepts files without U-Boot image with second header at the beginning but due to some kind of bug in upgrade routine, flashed image gets corrupted before it's written to flash. Tests showed that the GUI upgrade routine copies value of "Additional Hardware Version" from existing firmware into offset "0x2023c" in provided file, _before_ storing it in flash. In case of vendor firmware upgrade files (which all include U-Boot image and two headers), this offset points to the matching field in kernel+rootfs firmware part header. Unfortunately, in case of LEDE factory image file which contains only one header, it points to the offset "0x2023c" in kernel image. This leads to a corrupted kernel and ends up with a "soft-bricked" device. The good news is that U-Boot in these devices contains well known tftp recovery mode, which can be triggered with "reset" button. What's more, in comparison to some of older MediaTek based TP-Link devices, this recovery mode doesn't write whole file at offset "0x0" in flash, without verifying provided file in advance. In case of recovery mode in these devices, first "0x20000" bytes are always skipped and "0x7a0000" bytes from rest of the file are stored in flash at offset "0x20000". Flash instruction: Until (if at all) TP-Link fixes described problem, the only way to flash LEDE image in these devices is to use tftp recovery mode in U-Boot: 1. Configure PC with static IP 192.168.0.66/24 and tftp server. 2. Rename "lede-ramips-mt7628-tl-wr84...-squashfs-tftp-recovery.bin" to "tp_recovery.bin" and place it in tftp server directory. 3. Connect PC with one of LAN ports, press the reset button, power up the router and keep button pressed for around 6-7 seconds, until device starts downloading the file. 4. Router will download file from server, write it to flash and reboot. To access U-Boot CLI, keep pressed "4" key during boot. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com>
2017-06-21 12:16:15 +00:00
;;
ramips: add support for TP-Link Archer C2 Specification: - System-On-Chip: MT7620A - CPU/Speed: 580 MHz - Flash-Chip: Winbond 25Q64BVSIG - Flash size: 8192 KiB - RAM: 64 MiB - Wireless No1: SoC-integrated: MT7620A 2.4GHz 802.11bgn - Wireless No2: On-board chip: MT7610EN 5GHz 802.11ac - Switch: RTL8367RB Gigabit Switch - USB: Yes 1 x 2.0 Preparing a TFTP recovery image for initial flashing: Currently the only method to install openwrt for the first time is via TFTP download in u-boot. After first install you can use regular updates. WARNING: This method also overwrites the bootloader partition! Create a TFTP recovery image: 1) Download a stock TP-Link Firmware file here: https://www.tp-link.com/en/download/Archer-C2_V1.html#Firmware 2) Extract u-boot from the binary file: #> dd if=c2v1_stock_firmware.bin of=c2v1_uboot.bin bs=1 skip=512 count=131072 3) Now merge the sysupgrade image and the u-boot into one binary: #> cat c2v1_uboot.bin openwrt-squashfs-sysupgrade.bin > ArcherC2V1_tp_recovery.bin The resulting image can be flashed via TFTP recovery mode. Flash instructions: 1) To flash the recovery image, start a TFTP server from IP address 192.168.0.66 and serve the recovery image named ArcherC2V1_tp_recovery.bin. 2) Connect your device to the LAN port, then press the WPS/Reset button and power it up. Keep pressing the WPS/Reset button for 10 seconds. It will try to download the recovery image and flash it. It can take up to 20-25 minutes to finish. When it reaches 100%, the router will reboot itself. Signed-off-by: Serge Vasilugin <vasilugin@yandex.ru> Signed-off-by: Franz Flasch <franz.flasch@gmx.at>
2018-05-17 09:57:00 +00:00
tplink,c2-v1)
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch1" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch1" "0x01"
set_wifi_led "$boardname:green:wlan"
;;
tplink,c20-v1)
ucidef_set_led_switch "lan" "lan" "$boardname:blue:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:blue:wan" "switch0" "0x01"
ucidef_set_led_netdev "wlan2g" "wlan2g" "$boardname:blue:wlan2g" "wlan0"
;;
tplink,c20-v4)
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
ucidef_set_led_netdev "wlan2g" "wlan2g" "$boardname:green:wlan2g" "wlan0"
;;
tplink,c50-v3)
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
ucidef_set_led_wlan "wlan2g" "wlan2g" "$boardname:green:wlan2g" "phy0tpt"
ucidef_set_led_wlan "wlan5g" "wlan5g" "$boardname:green:wlan5g" "phy1tpt"
;;
tplink,tl-wa801nd-v5)
ucidef_set_led_wlan "wlan" "wlan" "$boardname:green:wlan" "phy0tpt"
ucidef_set_led_netdev "lan" "lan" "$boardname:green:lan" "eth0"
;;
tplink,tl-mr3020-v3)
set_wifi_led "$boardname:green:wlan"
ucidef_set_led_netdev "lan" "LAN" "$boardname:green:lan" "eth0"
;;
tplink,tl-mr3420-v5|\
tplink,tl-wr842n-v5)
ucidef_set_led_wlan "wlan2g" "wlan2g" "$boardname:green:wlan" "phy0tpt"
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x1e"
ucidef_set_led_switch "wan" "wan" "$boardname:green:wan" "switch0" "0x01"
;;
tplink,tl-wr902ac-v3)
ucidef_set_led_wlan "wlan2g" "wlan2g" "$boardname:green:wlan" "phy0tpt"
ucidef_set_led_switch "lan" "lan" "$boardname:green:lan" "switch0" "0x10"
;;
u25awf-h1)
set_wifi_led "u25awf:red:wifi"
ucidef_set_led_netdev "eth" "eth" "u25awf:green:lan" "eth0"
;;
ramips: add support for UniElec U7628-01 UniElec U7628-01 is a router platform board based on MediaTek MT7628AN. The device has the following specifications: - MT7628AN (580MHz) - 64/128/256 MB of RAM (DDR2) - 8/16 MB of flash (SPI NOR) - 5x 10/100 Mbps Ethernet (MT7628 built-in switch) - 1x 2T2R 2.4 GHz Wi-Fi (MT7628) - 1x miniPCIe slot (with PCIe and USB 2.0 buses) - 1x miniSIM slot - 1x microSD slot - 1x USB 2.0 port - 7x single-color LEDs (GPIO-controlled) - 1x bi-color LED (green GPIO-controlled, red -> LED_WLAN# in miniPCIe) - 1x reset button - 1x UART header (4-pins) - 1x SDXC/GPIO header (10-pins, connected with microSD slot) - 1x DC jack for main power (12 V) The following has been tested and is working: - Ethernet switch - miniPCIe slot (tested with modem and Wi-Fi card) - miniSIM slot - sysupgrade - reset button - USB 2.0 port* Due to a missing driver (MMC over GPIO) this is not supported: - microSD card reader * Warning: USB buses in miniPCIe and regular A-type socket are connected together, without any proper analog switch or USB HUB. Installation: This board might come with a different firmware versions (MediaTek SDK, PandoraBox, Padavan, etc.). If your board comes with PandoraBox, you can install LEDE using sysupgrade. Just SSH to the router and perform forced sysupgrade (due to a board name mismatch). The default IP of this board should be: 192.168.1.1 and username/password: root/admin. In case of a different firmware, you can use web based recovery described below. Use the following command to perform the sysupgrade (for the 128MB RAM/16MB flash version): sysupgrade -n -F lede-ramips-mt76x8-u7628-01-128M-16M-squashfs-sysupgrade.bin Recovery: This board contains a Chinese, closed-source bootloader called Breed (Boot and Recovery Environment for Embedded Devices). Breed supports web recovery and to enter it, you keep the reset button pressed for around 5 seconds during boot. Your machine will be assigned an IP through DHCP and the router will use IP address 192.168.1.1. The recovery website is in Chinese, but is easy to use. Click on the second item in the list to access the recovery page, then the second item on the next page is where you select the firmware. In order to start the recovery, you click the button at the bottom. SDXC/GPIO header (J3): 1. SDXC_D3 / I2C_SCLK 2. SDXC_D2 / I2C_SD 3. SDXC_D1 / I2S_DI 4. SDXC_D0 / I2S_WS 5. SDXC_CMD / I2S_CLK 6. SDXC_CLK / GPIO0 7. SDXC_CD / UART_RXD1 8. UART_TXD1 9. 3V3 10. GND Other notes: 1. The board is available with different amounts of RAM and flash. We have only added support for the 128/16 MB configuration, as that seems to be the default. However, all the required infrastructure is in place for making support for the other configurations easy. Signed-off-by: Piotr Dymacz <pepe2k@gmail.com> Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-11-03 20:12:49 +00:00
u7628-01-128M-16M)
ucidef_set_led_switch "lan1" "lan1" "u7628-01:green:lan1" "switch0" "0x2"
ucidef_set_led_switch "lan2" "lan2" "u7628-01:green:lan2" "switch0" "0x4"
ucidef_set_led_switch "lan3" "lan3" "u7628-01:green:lan3" "switch0" "0x8"
ucidef_set_led_switch "lan4" "lan4" "u7628-01:green:lan4" "switch0" "0x10"
ucidef_set_led_switch "wan" "wan" "u7628-01:green:wan" "switch0" "0x01"
set_wifi_led "u7628-01:green:wlan"
;;
vocore-8M|\
vocore-16M)
ucidef_set_led_netdev "eth" "ETH" "vocore:orange:eth" "eth0"
;;
w502u)
set_wifi_led "rt2800pci-phy0::radio"
;;
ramips: Add support for ZTE ZXECS EBG3130 aka BDCOM WAP2100-SK On the bottom sticker it's branded as ZTE ZXECS EBG3130 device, but in factory OpenWrt image it's referenced as BDCOM WAP2100-SK device. Specifications: - SoC: MediaTek MT7620A - RAM: 128 MB - Flash: 16 MB - Ethernet: 5 FE ports - Wireless radio: 2T2R 2.4 GHz and 1T1R 5 GHz (MT7610EN, unsupported) - UART: 1 x UART on PCB marked as J2 (R=RX, T=TX, G=GND) with 115200 8N1 config - LEDs: Power, FE ports 1-5, WPS, USB, RF 2.4G, RF 5G - Other: USB port, SD card slot and 2x external antennas (non-detachable) Flashing instructions: A) The U-Boot has HTTP based firmware upgrade A1) Flashing notes We've identified so far two different batches of units, unfortunately each batch has different U-Boot bootloader flashed with different default environment variables, thus each batch has different IP address for accessing web based firmware updater. * First batch has web based bootloader IP address 1.1.1.1 * Second batch has web based bootloader IP address 192.168.1.250 In case you can't connect to either of those IPs, you can try to get the default IP address via two methods: A1.1) Serial console, then the IP address is visible during the boot ... HTTP server is starting at IP: 1.1.1.1 raspi_read: from:40004 len:6 HTTP server is ready! ... A1.2) Over telnet/SSH using this command: root@bdcom:/# grep ipaddr= /dev/mtd0 ipaddr=1.1.1.1 A2) Flashing with browser * Change IP address of PC to 1.1.1.2 with 255.255.255.0 netmask * Reboot the device and try to reach web based bootloader in the browser with the following URL http://1.1.1.1 * Quickly select the firmware sysupgrade file and click on the `Update firmware` button, this all has to be done within 10 seconds, bootloader doesn't wait any longer If done correctly, the web page should show UPDATE IN PROGRESS page with progress indicator. Once the flashing completes (it takes roughly around 1 minute), the device will reboot to the OpenWrt firmware A3) Flashing with curl sudo ip addr add 1.1.1.2/24 dev eth0 curl \ --verbose \ --retry 3 \ --retry-delay 1 \ --retry-max-time 30 \ --connect-timeout 30 \ --form "firmware=@openwrt-ramips-mt7620-BDCOM-WAP2100-SK-squashfs-sysupgrade.bin" \ http://1.1.1.1 Now power on the router. B) The U-boot is based on Ralink SDK so we can flash the firmware using UART. 1. Configure PC with a static IP address and setup an TFTP server. 2. Put the firmware into the tftp directory. 3. Connect the UART line as described on the PCB (G=GND, R=RX, T=TX) 4. Power up the device and press 2, follow the instruction to set device and tftp server IP address and input the firmware file name. U-boot will then load the firmware and write it into the flash. Signed-off-by: Petr Štetiar <ynezz@true.cz>
2018-11-13 12:10:40 +00:00
wap2100-sk)
set_usb_led "$boardname:green:usb"
set_wifi_led "$boardname:green:wlan2g"
;;
ramips: Add support for ZBT WE1026-5G The ZBT WE1026-5G (http://www.zbtlink.com/products/router/WE1026-5G.html) is the follow-up to the ZBT WE1026 and is based on MT7620. For the previous WE1026, the ZBT WE826 image could be used. However, as the name implies, the -5G comes equipped with a 5GHz wifi radio. As the WE826 only has a 2.4GHz radio, the addition of 5GHz means that a separate image is needed for the WE1026-5G. I suspect that this image will also work on the previous WE1026, but I don't have a device to test with. The WE1026-5G has following specifications: * CPU: MT7620A * 1x 10/100Mbps Ethernet. * 16 MB Flash. * 64 MB RAM. * 1x USB 2.0 port. * 1x mini-PCIe slots. * 1x SIM slots. * 1x 2.4Ghz WIFI. * 1x 5GHz wifi (MT7612) * 1x button. * 3x controllable LEDs. Works: * Wifi. * Switch. * mini-PCIe slot. Only tested with a USB device (a modem). * SIM slot. * Sysupgrade. * Button (reset). Not working: * The 5GHz WIFI LED is completely dead. I suspect the issue is the same as on other devices with Mediatek 5Ghz wifi-cards/chips. The LED is controlled by the driver, and mt76 (currently) does not support this. Not tested: * SD card reader. Notes: * The modem (labeled 3G/4G) and power LEDs are controlled by the hardware. * There is a 32MB version of this device available, but I do not have access to it. I have therefor only added support for the 16MB version, but added all the required infrastructure to make adding support for the 32MB version easy. Installation: The router comes pre-installed with OpenWRT, including a variant of Luci. The initial firmware install can be done through this UI, following normal procedure. I.e., access the UI and update the firmware using the sysupgrade-image. Remember to select that you do not want to keep existing settings. Recovery: If you brick the device, the WE1026-5G supports recovery using HTTP. Keep the reset button pressed for ~5sec when booting to start the web server. Set the address of the network interface on your machine to 192.168.1.2/24, and point your browser to 192.168.1.1 to access the recovery UI. From the recovery UI you can upload a firmware image. Signed-off-by: Kristian Evensen <kristian.evensen@gmail.com>
2017-09-10 12:44:47 +00:00
we1026-5g-16m)
ucidef_set_led_netdev "lan" "LAN" "we1026-5g:green:lan" "eth0"
set_wifi_led "we1026-5g:green:wifi"
;;
wl-wn575a3)
ucidef_set_rssimon "wlan1" "200000" "1"
ucidef_set_led_rssi "wifi-low" "wifi-low" "$boardname:green:wifi-low" "wlan1" "1" "49"
ucidef_set_led_rssi "wifi-med" "wifi-med" "$boardname:green:wifi-med" "wlan1" "50" "84"
ucidef_set_led_rssi "wifi-high" "wifi-high" "$boardname:green:wifi-high" "wlan1" "85" "100"
;;
wrh-300cr)
set_wifi_led "$boardname:green:wlan"
ucidef_set_led_netdev "lan" "lan" "$boardname:green:ethernet" "eth0"
;;
y1)
ucidef_set_led_netdev "wifi" "WIFI" "$boardname:blue:wifi" "wlan1"
ucidef_set_led_netdev "wifi5g" "WIFI5G" "$boardname:blue:wifi5g" "wlan0"
ucidef_set_led_switch "lan" "LAN" "$boardname:blue:lan" "switch0" "0x03"
;;
y1s)
ucidef_set_led_netdev "wifi" "WIFI" "$boardname:yellow:wifi" "wlan1"
ucidef_set_led_netdev "wifi5g" "WIFI5G" "$boardname:blue:wifi" "wlan0"
ucidef_set_led_netdev "wan" "WAN" "$boardname:blue:internet" "eth0.2" "tx rx"
;;
youhua,wr1200js)
ucidef_set_led_switch "internet" "INTERNET" "$boardname:green:wan" "switch0" "0x01"
;;
zbt-ape522ii)
ucidef_set_led_netdev "wlan2g4" "wlan1-link" "$boardname:green:wlan2g4" "wlan1"
ucidef_set_led_netdev "sys1" "wlan1" "$boardname:green:sys1" "wlan1" "tx rx"
ucidef_set_led_netdev "sys2" "wlan0" "$boardname:green:sys2" "wlan0" "tx rx"
;;
zbt-wa05)
set_wifi_led "$boardname:blue:air"
;;
zbt-we2026)
set_wifi_led "$boardname:green:wlan"
;;
zbt-we826-16M|\
zbt-we826-32M)
set_wifi_led "zbt-we826:green:wifi"
;;
zbtlink,zbt-we1226)
set_wifi_led "$boardname:green:wlan"
ucidef_set_led_switch "lan1" "LAN1" "$boardname:green:lan1" "switch0" "0x01"
ucidef_set_led_switch "lan2" "LAN2" "$boardname:green:lan2" "switch0" "0x02"
ucidef_set_led_switch "wan" "WAN" "$boardname:green:wan" "switch0" "0x10"
;;
zbt-wr8305rt)
set_wifi_led "$boardname:green:wifi"
;;
zorlik,zl5900v2)
ucidef_set_led_netdev "lan" "lan" "$boardname:green:lan" eth0
;;
zyxel,keenetic-extra-ii)
set_wifi_led "$boardname:green:wifi"
ucidef_set_led_switch "internet" "internet" "$boardname:green:internet" "switch0" "0x01"
;;
youku-yk1)
set_wifi_led "$boardname:blue:air"
ucidef_set_led_switch "wan" "wan" "$boardname:blue:wan" "switch0" "0x10"
;;
esac
board_config_flush
exit 0